victron energy 12-500-20-120V AC Pure Sine Wave Inverter Instruction manual

victron energy 12-500-20-120V AC Pure Sine Wave Inverter Instruction manual

Victron energy 12-500-20-120V is a high-performance pure sine wave inverter designed to convert 12V DC power to 120V AC power. This inverter provides clean power for sensitive electronic devices, such as computers, TVs, and appliances. It features a powerful 500W output, making it suitable for a wide range of applications on boats, off-grid systems, or as a backup power source.

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Victron Energy 12-500-20-120V AC Pure Sine Wave Inverter Manual | Manualzz
Energy Unlimited
Reinout Vader
Electricity on Board
(And other off-grid applications)
Revision 9
June 2011
Electricity plays an increasing role on board yachts. Modern navigation and communication
equipment depends on it, as well as the growing list of household appliances that are taken
on board.
This is the concept text for a booklet about electricity on board small and large yachts. The
intention of the book is twofold:
Firstly I try to cover in depth a few matters that over and again are subject to discussion
and misunderstanding, such as batteries and management of batteries, or electric power
consumption of refrigerators, freezers and air conditioning.
My second intention is to help designers, electricians and boat owners to decide on how to
manage and generate electricity on board. Several new products and concepts have
substantially broadened the range of alternatives here.
Together with some unavoidable theory, I use examples of small and large yachts to clarify
the consequences of choosing one alternative or another. The consequences are
sometimes so unexpected and far reaching that, writing it all down, I have also helped my
own understanding!
Reinout Vader
© Victron Energy
1
Copyright © 2000 Victron Energy B.V.
All Rights Reserved
This publication or part thereof, may not be reproduced in any form by any method, for any purpose.
VICTRON ENERGY B.V. MAKES NO WARRANTY, EITHER EXPRESSED OR IMPLIED, INCLUDING BUT
NOT LIMITED TO ANY IMPLIED WARRANTIES OF MERCHANTABILITY OR FITNESS FOR A
PARTICULAR PURPOSE, REGARDING VICTRON ENERGIE PRODUCTS AND MAKES SUCH VICTRON
ENERGY PRODUCTS AVAILABLE SOLELY ON AN “AS-IS” BASIS.
IN NO EVENT SHALL VICTRON ENERGY B.V. BE LIABLE TO ANYONE FOR SPECIAL, COLLATERAL,
INCIDENTAL, OR CONSEQUENTIAL DAMAGES IN CONNECTION WITH OR ARISING OUT OF
PURCHASE OR USE OF VICTRON ENERGY PRODUCTS. THE SOLE AND EXCLUSIVE LIABILITY TO
VICTRON ENERGY B.V., REGARDLESS OF THE FORM OF ACTION, SHALL NOT EXCEED THE
PURCHASE PRICE OF THE VICTRON ENERGY PRODUCTS DESCRIBED HEREIN.
For conditions of use and permission to use this book for publication in other than the Dutch language,
contact Victron Energy B.V.
Victron Energy B.V. reserves the right to revise and improve its products as it sees fit.
Victron Energy B.V.
De Paal 35
1351 JG Almere-Haven
P.O. Box 50016
1305 AA Almere-Haven
Tel : +31 (0)36 535 97 00
Fax : +31 (0)36 535 97 40
E-mail : mailto:[email protected]
Website : http://www.victronenergy.com/
2
© Victron Energy
Electricity on Board
(And other off-grid applications)
Table of contents
1. Introduction
2. The battery: preventing premature aging
The battery is the heart of every small-scale energy system. No battery, no storage of electric energy. At the same
time the battery is a costly and delicate component. This chapter specifically addresses the battery’s vulnerability.
2.1. Introduction
2.2. Battery chemistry
2.2.1.
2.2.2.
2.2.3.
2.2.4.
What happens in a battery cell as it discharges
What happens during charging
The diffusion process
Service life: shedding, oxidation, and sulphation
2.3. The most common types of lead-acid battery
2.3.1.
2.3.2.
2.3.3.
2.3.4.
2.3.5.
2.3.6.
2.3.7.
2.3.8.
Lead-antimony and lead-calcium
Wet or flooded versus starved (gel or AGM) electrolyte
The flat-plate automotive battery (wet)
The flat-plate semi-traction battery (wet)
The traction or deep-cycle battery (wet)
The sealed (VLRA) gel battery
The sealed (VLRA) AGM battery
The sealed (VLRA) spiral-cell battery
2.4. Function and use of the battery
2.5. The lead-acid battery in practice
2.5.1.
2.5.2.
2.5.3.
2.5.4.
2.5.5.
2.5.6.
2.5.7.
2.5.8.
2.5.9.
2.5.10.
How much does a battery cost?
Dimensions and weight
Effect on capacity of rapid discharging
Capacity and temperature
Premature aging 1. The battery is discharged too deeply
Premature aging 2. Charging too rapidly and not fully charging
Premature aging 3. Undercharging
Premature aging 4. Overcharging
Premature aging 5. Temperature
Self-discharge
3. Monitoring a battery’s state of charge. ‘The battery monitor’.
The battery monitor indicates a battery’s state of charge, and can also be used to automatically start charging
systems, or indicate that charging is required.
With larger battery systems a monitor with an amp-hour counter is indispensable. To start charging once the “voltage
drops” is simply too late. The battery is then discharged too deeply and harm will already be done.
3.1. The different ways of measuring a battery’s state of charge
3.1.1.
3.1.2.
3.1.3.
Specific gravity (SG) of the electrolyte
Battery voltage
Amp-hour meter
3.2. The battery monitor is an amp-hour meter
© Victron Energy
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3.3. Energy efficiency of a battery
3.4. Charge efficiency of a battery
3.5. Effect on capacity of rapid discharging
3.6. Is capacity “lost” at high rates of discharge?
3.7. Useful features of a battery monitor
3.7.1. Event counting
3.7.2. Data logging
4. Battery charging: the theory
Different types of battery have to be charged in different ways.
This section reviews the optimum charging characteristics of the most commonly used types of lead-acid battery.
4.1. Introduction
4.2. Three step (I U° U) charging
4.2.1. The bulk charge
4.2.2. The absorption charge
4.2.3. The float charge
4.3. Equalizing
4.4. Temperature compensation
4.5. Overview
4.6. Conclusion: how should a battery be charged?
4.6.1. The house battery
4.6.2. The starter battery
4.6.3. The bow thruster battery
5. Charging batteries with an alternator or a battery charger
The alternator with a standard voltage regulator as used in automotive applications is far from being the best solution,
and certainly not where several batteries, separated by a diode isolator, need to be charged.
5.1. The alternator
5.2. When the alternator has to charge more than one battery
5.2.1. Introduction
5.2.2. The problem
5.2.3. A wide range of solutions
5.2.3.1. Keeping it simple and low cost: the microprocessor controlled battery combiner
5.2.3.2. Increase alternator voltage
5.2.3.3. A multistep regulator with temperature and voltage compensation
5.2.3.4. The starter battery
5.2.3.5. The bow thruster battery
5.3. Battery chargers. From AC to DC current
5.3.1. Introduction
5.3.2. Optimised charging
5.3.3. Charging more than one bank
5.3.3.1. The multiple output battery charger
5.3.3.2. A dedicated charger for each battery
5.3.3.3. Using microprocessor controlled battery combiners
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© Victron Energy
6. Electric equipment and energy consumption
The daily energy consumption of continuous and long duration low power consumers (refrigerator and freezer) is
often underestimated, while the energy consumption of short time high power consumers (electric winches, bow
thruster, washing machine, electric cooker) is often overestimated.
6.1. Introduction
6.2. Power and energy
6.3. Refrigeration
6.3.1.
6.3.2.
6.3.3.
6.3.4.
Introduction
Theory of the heat pump
The refrigerator and freezer in practice
Air conditioning
6.4. Electric winches, windlass and bow thruster
6.5. A battery powered washing machine and dishwasher?
6.6. Ever thought that electric cooking on battery power was possible?
6.7. The diving compressor
6.8. How to deal with the inrush current of AC electric motors
6.9. Conclusion
7. Generators
7.1. AC generators
7.1.1.
7.1.2.
7.1.3.
7.1.4.
The diesel engine will last longer if it has to work
A hybrid or battery assisted AC system
Don’t forget the problem of limited shore power
3000 rpm or 1500 rpm (in a 60 Hz environment: 3600 rpm or 1800 rpm)
7.2. DC generators
© Victron Energy
5
8. Micro power generation: thinking different
This chapter brings us to the central theme of this book: how to optimise safety and comfort, and at the same time
reduce weight and size of the power supply system.
8.1. Introduction
8.2. New technology makes the DC concept more attractive
8.2.1. The DC concept
8.2.2. DC generators
8.2.3. Unlimited inverter power
8.3. The AC concept can be improved with PowerControl
8.3.1. The AC concept
8.3.2. The AC concept with generator free period
8.3.3. PowerControl
8.4. New: the hybrid or battery assisted AC concept, or “achieving the impossible” with PowerAssist
8.4.1. PowerAssist
8.4.2. Other advantages when operating Multi’s together with a generator
8.4.3. Shore power
8.5. Thinking different
8.5.1. Daily energy needed
8.5.2. Battery capacity
8.5.3. Shore power
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© Victron Energy
9. Up to 4 kWh required per day (170 Watt average)
9.1. Introduction
9.2. Equipment and current consumption
9.2.1. Navigation instruments
9.2.2. GPS
9.2.3. VHF
9.2.4. Tricolour navigation light or anchor light
9.2.5. Autopilot
9.2.6. Radio
9.2.7. Cabin lighting
9.2.8. Refrigerator
9.3. Consumption over a 24 hour period when sailing
9.4. At anchor or moored without 230 V shore pick-up
9.5. The extra’s
9.5.1. Electronic navigation system
9.5.2. SSB
9.5.3. Radar
9.5.4. Microwave oven
9.5.5. Space heating
9.5.6. Air conditioning
9.5.7. Water maker
9.6. How to recharge the battery
9.6.1. Generate current with the main engine
9.6.2. Increase battery capacity
9.6.3. A second or bigger alternator
9.6.4. Solar cells
9.6.5. Wind generator
9.6.6. Water generator
9.6.7. Shore power
9.7. Conclusion
© Victron Energy
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10. Up to 14 kWh required per day (600 W average)
10.1. Introduction
10.2. Equipment: the minimum
10.2.1.
10.2.2.
10.2.3.
10.2.4.
10.2.5.
10.2.6.
10.2.7.
Navigation equipment
Navigation light and anchor light
Autopilot
Refrigerator and freezer
Cabin lighting
Radio
Other consumers
10.3. Sailing
10.4. At anchor or moored without 230 V shore power pick-up
10.5. The extra’s
10.5.1.
10.5.2.
10.5.3.
10.5.4.
Hot water kettle
Electric cooker
Small washing machine
Small dishwasher
10.6. Energy generation
10.6.1.
10.6.2.
10.6.3.
10.6.4.
10.6.5.
10.6.6.
10.6.7.
10.6.8.
With alternators on the main engine
Alternative sources of energy
With an AC generator
PowerControl and PowerAssist
The AC generator on a relatively small boat: conclusion
The DC generator
Efficiency of a diesel generator
The energy supply on a motor yacht of 9 to 15 metres or a yacht at anchor
10.7. Conclusion
10.7.1. A 12 kW generator
10.7.2. A 6 kW generator with PowerAssist
11. Up to 48 kWh required per day (2 kW average)
11.1. Introduction
11.2. The major consumers
11.3. Energy generation
11.3.1.
11.3.2.
11.3.3.
11.3.4.
11.3.5.
11.3.6.
With an AC generator running 24 hours a day
Adding a battery for a generator free period
Using parallel Multi’s with PowerControl, and the DC concept for shore power
Multi’s with PowerAssist
The DC generator
Using a small auxiliary DC generator to reduce generator hours, battery capacity and fuel consumption
11.4. Conclusion
11.4.1. A 20 kW generator with generator free period
11.4.2. Implementing PowerControl and the DC concept for shore power, and adding an auxiliary genset to
reduce battery capacity
11.4.3. Using a smaller generator with PowerAssist, the DC concept for shore power, and an aux. genset
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© Victron Energy
12. Up to 240 kWh required per day (10 kW average)
12.1. Introduction
12.2. The major consumers
12.3. Energy generation
12.3.1. AC generators
12.3.2. Adding a battery for a generator free period and battery assisted generator operation (PowerAssist)
12.3.3. Adding an 8 kW auxiliary AC generator
12.4. The alternatives for 10 kW average consumption compared
13. Conclusion
13.1. Consumption of electric energy on board
13.2. Energy generation
13.3. The DC concept
13.4. PowerAssist: the hybrid or battery assisted AC concept
13.5. The house battery
© Victron Energy
9
1. Introduction
Victron Energy has been supplying components and systems for autonomous energy supply for some 25 years. These
might be systems for sail- or motorboats, inland navigation vessels, off-grid houses, for many types of vehicles, and a
nearly endless range of other, often unexpected, applications.
We know from experience that generating and storing electrical energy on a small-scale is a complex business. The
components of an autonomous system are costly and vulnerable. For example, the battery, that indispensable storage
medium in a small-scale system, often goes flat quickly and unexpectedly, so that the “power fails” and eventually the
harm caused by excessive discharge means premature investment in a new battery.
Developments in the field of autonomous energy-supply on board sail- and motorboats are exemplary. The amount of
electric (domestic) equipment on board boats is increasing rapidly, while at the same time the space and weight available
for energy generation and storage are being kept to an absolute minimum. It goes without saying that living space and
sailing characteristics take a higher priority.
Growing demands imposed on autonomous energy systems have spurred the development of new products and
concepts. This overview presents new products and concepts, with specific attention being paid to optimum system
component integration and day-to-day operation of the complete system.
Where system components are discussed, brands are only mentioned if the products are unique, that is to say available
exclusively under that brand, or if other brands are very hard to obtain. The unique Victron Energy products mentioned
are:
-
Battery chargers with adaptive software to automatically optimize charging.
Parallel connection of inverters and combined inverter-battery chargers
The parallel connection option (if needed even in 3-phase configuration) means that there are no limits anymore to the
amount of AC power that can be supplied from a battery. As will be shown, this opens the possibility to run all kinds of
domestic equipment, including the washing machine and the electric cooker, from the battery. Although the peak power
consumption of such equipment is high, the amount of amp-hours needed is quite manageable and much lower than one
would expect.
PowerControl is an often overlooked but very convenient feature of the Victron Phoenix Combi and its even
more versatile successor, the Phoenix Multi: by constantly monitoring the total power drawn from the on-board generator
or shore supply, the Phoenix Multi will automatically reduce battery charging when otherwise an overload situation would
occur (for example when high power household equipment is switched on).
The next step: PowerAssist. The revolutionary Phoenix MultiPlus, also an inverter-battery charger, actually
runs in parallel with shore power or an AC generator, and uses the battery as a buffer to “help” the shore power or
generator during periods of peak power demand.
The implications of PowerAssist are truly far reaching:
Traditionally the on-board generator had to be dimensioned to the peak power required. The use of power hungry
equipment such as air conditioning, a washing machine or an electric stove would require a big and heavy generator and
the required shore power capacity would often not even be available. With PowerAssist, shore power and the onboard generator can be reduced to less than half the rating that normally would be required!
While this overview is directed mainly towards boats, many products and solutions are also applicable in other
autonomous energy systems such as can be found in off-grid houses, motor homes, or special purpose
commercial vehicles.
10
© Victron Energy
2. The battery: preventing premature aging
2.1. Introduction
I like engines. When they go wrong you can listen, and look, and smell, and then take them apart. Parts can be
replaced, repaired or overhauled. Then put it all together again, and there they go!
With a battery you can’t do that. The battery is a secretive product. From the outside there is nothing to tell us
about its quality, possible aging or state of charge. Nor is it possible to take it apart. It could be sawn open, but
that ruins it for good and only highly qualified specialists could analyse the content and may be, in certain cases,
they could trace the cause of failure.
A battery, when it fails, has to be replaced. That’s it.
A battery is expensive, bulky and very very heavy. Just think: with 10 litres of diesel (= 8.4 kg) and a diesel
generator you can charge a battery of 24 V 700 Ah (energy content 24 x 700 = 16.8 kWh). Such a battery has a
3
volume of 300 dm (= 300 litres) and weighs 670 kg!
Also, batteries are very vulnerable. Overcharging, undercharging, discharging too deeply, charging too fast,
excessive temperature…. All these issues can occur and the consequences can be disastrous.
The purpose of this chapter is to explain why batteries fail, and what to do to make them last longer. And if you
want to have a look inside a faulty battery, don’t open it yourself. It is extremely dirty work and for the price of a
new pair of trousers (the sulphuric acid of the battery will ruin them) buy the standard work of Nigel Calder,
“Boatowner’s Mechanical and Electrical Manual”, and enjoy the many close-up’s of failed batteries in chapter 1.
2.2. Battery chemistry
2.2.1.
What happens in a cell as it discharges
As a cell discharges lead sulphate forms on both the positive and negative plates through absorption of
acid from the electrolyte. The quantity of electrolyte in the cells remains unchanged. However, the acid
content in the electrolyte reduces, something noticeable in the change of the specific gravity.
2.2.2.
What happens during charging
During charging the process is reversed. On both plates acid is released, while the positive plate
converts into lead oxide and the negative plate into porous, sponge-like lead. Once charged the battery
can no longer take up energy, and any further energy added is used to decompose water into hydrogen
gas and oxygen gas. This is an extremely explosive mixture and explains why the presence of an open
flame or sparks in the vicinity of a battery during charging can be very hazardous. It is therefore
necessary to ensure that a battery compartment has effective ventilation.
2.2.3.
The diffusion process
When a battery is being discharged, ions have to move through the electrolyte and through the active
material of the plates to come into contact with the lead and lead oxide that has not yet been chemically
converted into lead sulphate. This moving of ions through the electrolyte is called diffusion. When the
battery is being charged the reverse process takes place. The diffusion process is relatively slow, and
as you can imagine, the chemical reaction will first take place at the surface of the plates, and later (and
also slower) deep inside the active material of the plates.
2.2.4.
Service life
Depending on construction and use, the service life of a battery ranges from a few years to up to 10
years or more. The main reasons for batteries to age are:
Shedding of the active material. Intensive cycling (= discharging and recharging a battery) is
the main reason for this to happen. The effect of repetitive chemical transformation of the active
material in the plate grid tends to reduce cohesion, and the active material falls of the plates and sinks
to the bottom of the battery.
Corrosion of the positive plate grid. This happens when a battery is being charged, especially
at the end of the charge cycle when the voltage is high. It also is a slow but continuous process when a
battery is float charged. Oxidation will increase internal resistance and, finally, result in disintegration of
the positive plates.
© Victron Energy
11
Sulphation. While the previous two reasons for a battery to age cannot be prevented,
sulphation should not happen if a battery is well taken care of. When a battery discharges the active
mass in both the positive and negative plates is transformed into very small sulphate crystals. When left
discharged, these crystals tend to grow and harden and form an impenetrable layer that cannot be
reconverted back into active material. The result is decreasing capacity, until the battery becomes
useless.
2.3. The most common types of lead-acid battery
2.3.1.
Lead-antimony and lead-calcium
Lead is alloyed with antimony (with the addition of some other elements such as selenium or tin in small
quantities) or with calcium to make the material harder, more durable and easier to process. For the
user it is important to know that compared to lead-calcium batteries, batteries alloyed with antimony
have a higher rate of internal self-discharge and require a higher charge voltage, but also will sustain a
larger number of charge-discharge cycles.
2.3.2.
Wet or flooded versus starved (gel or AGM) electrolyte
The electrolyte in a battery is either liquid (wet or flooded batteries), or starved: formed into a gel (the
gel battery) or absorbed in microporous material (the AGM battery).
When nearly fully charged, wet or flooded batteries will start “gassing”, which is the result of water being
decomposed into oxygen- and hydrogen gas.
In batteries with starved electrolyte oxygen gas formed at the positive plates migrates to the negative
plates where, after a complicated chemical reaction, it is “recombined” with hydrogen into water. No gas
will escape from the battery. Hydrogen gas is formed only if the charge voltage is too high. In case of
excessive charge voltage oxygen and hydrogen gas will escape through a safety valve. That is why
these batteries are also called VRLA (Valve Regulated Lead Acid) batteries.
Then batteries may be distinguished on the basis of their mechanical construction and purpose:
2.3.3.
The flat-plate automotive battery (flooded)
This is the battery used in cars. Not suitable for frequent deep discharging as it has thin plates with a
large surface area – designed purely for short-term high discharge currents (engine starting).
Nevertheless flat-plate heavy-duty truck starter batteries are often employed as house batteries in
smaller boats.
2.3.4.
The flat-plate semi-traction battery (flooded)
This battery has thicker plates and better separators between the plates to help prevent buckling of the
plates and shedding of the active material under cyclic use. It can be used for light duty cycling and is
often referred to as a ‘leisure’ duty battery.
2.3.5.
The traction or deep-cycle battery (wet)
This is either a thick-plate or a tubular-plate battery. Used for example in forklift trucks, it is discharged
down to 60-80% every day and then recharged overnight – day after day. This is what is referred to as
cyclic duty.
The deep-cycle battery must be charged, at least from time to time, at a relatively high voltage. How
high depends on chemical and constructive details and on the charging time available.
Note: The high charging voltage is needed to reconvert all sulphate into active material, and to help
prevent stratification of the electrolyte. The sulphuric acid (H2SO4) produced as the battery is being
charged has a higher density than water and does tend to settle downwards so that the acid
concentration at the bottom of the battery becomes higher than at the top. Once the gassing voltage is
reached, charging is continued with plenty of current (and therefore a high voltage). The resulting gas
generation ‘stirs’ the electrolyte and ensures that it becomes well mixed again.
For the electrolyte in a usually very tall tubular-plate battery to mix well, more gas generation is needed
than in a much lower flat-plate battery.
The tubular-plate battery is extremely robust and accepts a very high number of charge-discharge
cycles. It is an excellent low cost substitute for sealed gel- or AGM batteries.
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© Victron Energy
2.3.6.
The sealed (VRLA) gel battery
Here the electrolyte is immobilised as gel. Familiar as the Sonnenschein Dryfit A200, Sportline or Exide
Prevailer battery.
2.3.7.
The sealed (VRLA) AGM battery
AGM stands for Absorbed Glass Mat. In these batteries the electrolyte is absorbed (“sucked up”) into a
glass-fibre mat between the plates by capillary action. In an AGM battery the charge carriers, hydrogen
ions (H2) and sulphate ions (SO4), move more easily between the plates than in a gel battery. This
makes an AGM battery more suitable for short-time delivery of very high currents than a gel battery.
Examples of AGM batteries are the Concorde Lifeline and the Northstar battery.
2.3.8.
The sealed (VRLA) spiral cell battery
Known as the Optima battery (Exide now has a similar product), this is a variant of the VRLA AGM
battery. Each cell consists of 1 negative and 1 positive plate that are spiralled, thereby achieving higher
mechanical rigidity and extremely low internal resistance. The spiral cell battery can deliver very high
discharge currents, accepts very high recharge currents without overheating and is also, for a VRLA
battery, very tolerant regarding charge voltage.
2.4. Function and use of the battery
In an autonomous energy system the battery acts as buffer between the current sources (DC generator,
charger, solar panel, wind generator, alternator) and the consumers. In practice this means cyclic use, but in
fact a quite special “irregular” variation of cyclic use. This contrasts with the forklift truck example where the
duty cycle is very predictable.
As boats are often also left unused for long periods of time, so are their batteries.
For instance on a sailing yacht the following situations can arise:
The yacht is under sail or at anchor in a pleasant bay. Those aboard would not want any noise, so all
electricity comes from the battery. The main engine or a diesel generator is used once or twice a day for a few
hours to charge the house battery sufficiently to ride through the next generator-free period. This is cyclic use,
where, significantly, the charging time is too brief to fully charge the battery.
The yacht is travelling under power for several hours. The alternators on the main engine then have the
time to charge the battery properly.
The yacht is moored at the quayside. The battery chargers are connected to shore power supply and
the battery is under float charge 24 hours a day. If the DC concept is used (section 8.2) several shallow
discharges may occur every day.
The yacht is out of service during wintertime. The batteries are either left disconnected for several
months, left under float charge from a battery charger, or are kept charged by a solar panel or wind generator.
The number of cycles per year, the ambient temperature and many other factors influencing a battery’s service
life will vary user by user. The following briefly discusses all of these factors.
© Victron Energy
13
2.5. The lead-acid battery in practice
2.5.1.
How much does a battery cost?
Here we only intend to give a rough estimate of price. Besides all the considerations of quality and use,
cost is, of course, important.
Battery type
Application
Commonly used system
voltage, capacity and
energy content
V
Ah
kWh
Price
indication
ex. VAT
USD or EURO
Price indication
per kWh
Start
Cranking
12
100
1.2
100
USD or EURO per
kWh
80
Spiral-cell
Semi-traction
Cranking, bow-thruster
House battery up to
approx. 600 Ah
House battery up to
approx. 600 Ah.
Also cranking and bow
thruster
House battery up to
approx. 2000 Ah
House battery up to
approx. 600 Ah
12
12
60
200
0.72
2.4
250
300
350
125
12
230
2.8
600
210
24
1000
24
4.500
190
12
200
2.4
500
210
House battery up to
approx. 1500 Ah
24
1500
36
11.000
305
VRLA
AGM battery
Traction
(tubular-plate)
VRLA-gel
Sonnenschein
Dryfit A200
VRLA-gel
Sonnenschein
Dryfit A600
The table shows that cost varies greatly dependant on the choice of battery, and particularly that wet batteries are less
expensive than VRLA batteries.
VRLA batteries do offer great ease of use, they:
-
are maintenance free.
do not gas (provided that the battery is not charged with excessive voltage).
can be installed in places with difficult access.
On the other hand sealed batteries are very sensitive to overcharging (the exception is the spiral-cell battery).
Overcharging results in gassing (through the safety valve) which means water loss that can never be replenished,
resulting in capacity loss and premature aging.
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© Victron Energy
2.5.2.
Dimensions and weight
Battery type
V
Ah
kWh
Volume
3
dm
Weight
kg
Specific
weight Wh / kg
28
Specific
volume
3
Wh / dm
75
Start
12
100
1.2
16
Spiral-cell
12
60
0.72
8.5
17.2
81
42
Semi-traction
12
200
2.4
33
60
73
40
VRLA
AGM battery
Traction
(tubular-plate)
VRLA-gel
Sonnenschein Dryfit
A200
VRLA-gel
Sonnenschein Dryfit
A600
12
230
2.8
33
62
85
45
24
1000
24
280
770
85
32
12
200
2.4
33
70
72
34
24
1500
36
600
1440
60
25
43
This table very clearly shows how heavy and cumbersome batteries are.
Coming back to the comparison in section 2.1:
Compared to the energy released by combustion of diesel fuel, for example, batteries are simply no rivals.
Burning 10 litres (weight 8.4 kg) of fuel generates approx. 100 kWh of thermal energy. So when consuming
10 litres of diesel fuel a diesel generator with an average efficiency of 20% will be able to generate 20 kWh
of electric energy. This is the energy needed to charge a 24 V 700 Ah battery. Such a battery has a volume
3
of 300 dm (= 300 litres) and weighs 670 kg!
Another telling comparison is heating water. Bringing 1 litre (= 1 kg) of water to the boil in an electric kettle
requires 0.1 kWh. To supply the required 0.1 kWh, approx. 4 kg of battery is needed!
2.5.3.
Effect on capacity of rapid discharging
The capacity of a battery is dependent on the rate of discharge. The faster the rate of discharge, the
less Ah capacity will be available. This is related to the diffusion process (sect. 2.2.3). In general the
rated capacity is quoted for a discharge time of 20 hours (discharge current I = C / 20).
For a 200 Ah battery this means that the rated capacity can be delivered at a discharge current of 200
Ah / 20 hours = 10 Ampères.
With a discharge current of 200 A the same battery becomes “flat” far sooner. For instance a 200 Ah gel
battery then has an effective capacity of only 100 Ah and therefore becomes flat after 30 minutes. (see
also chapter 3: The battery monitor).
The following tables give an impression of the capacity as a function of the discharge current.
nd
The 2 column of the first table gives the rated capacity as quoted by the manufacturer with the
associated discharge time. Often this is 20 hours, but it can also be 10 hours or 5 hours.
The tables show how capacity falls off steeply with increasing discharge current, and that AGM batteries
(especially the spiral-cell battery) perform better than gel batteries under high discharge currents.
© Victron Energy
15
Type
Discharge
current
Rated capacity
and related
discharge time
A (rated)
Start
Discharge
time
Discharge
current
hours
A (C / 5)
Effective
capacity 1.83 V /
cell (11 V)
Ah
%
Discharge
time
hours
5
100 Ah / 20 h
20
Spiral-cell
2.8
56 Ah / 20 h
20
11.2
52
93
4.6
Semi-traction
10
200 Ah / 20 h
20
40
150
75
3.75
11.5
230 Ah / 20 h
20
46
198
86
4.3
200
1000 Ah / 5 h
5
200
1000
100
5
10
200 Ah / 20 h
20
40
158
79
4
150
1500 Ah / 10 h
10
300
900
60
3
VRLA
AGM battery
Traction
(tubular-plate)
VRLA-gel
Sonnenschein Dryfit
A200
VRLA-gel
Sonnenschein Dryfit
A600
Type
Discharge
current
A (C / 2)
Effective
Discharge
capacity 1.83 V
time
/ cell (11 V)
Ah
%
Minutes
Discharge
current
A (C / 1)
Effective
capacity 1.75 V /
cell (10.5 V)
Ah
%
Discharge
time
Minutes
Start
Spiral-cell
28
43
77
92
56
42
75
45
Semi-traction
100
110
55
66
200
90
45
27
VRLA
AGM battery
Traction
(tubular-plate)
VRLA-gel
Sonnenschein Dryfit
A200
VRLA-gel
Sonnenschein Dryfit
A600
115
157
68
82
230
142
62
37
500
700
70
80
1000
400
40
24
100
120
60
72
200
100
50
30
750
375
25
15
1500
0*
0
0*
*
With a discharge current of 1500 A (C / 1) the voltage of an A600 battery drops almost immediately to
1.65 V / cell (i.e. 9.9 V and 19.8 V for a 12 V respectively 24 V system).
Discharge current is often expressed as a proportion of the rated capacity. For example for a 200 Ah
battery C / 5 means a discharge current of 40 A (= 200 Ah / 5).
2.5.4.
Capacity and temperature
The effective capacity of a battery varies in reverse proportion to temperature:
- 10°C
80 %
16
10°C
92 %
15°C
95 %
20°C
100 %
© Victron Energy
25°C
103 %
30°C
105 %
2.5.5.
Premature aging 1. The battery is discharged too deeply.
The deeper a battery is discharged, the faster it will age due to shedding (sect. 2.2.4.), and once a
certain limit is exceeded (approx. 80% depth of discharge) the aging process advances
disproportionately fast.
Additionally, if the battery is left discharged the plates will begin to sulphate (sect. 2.2.4.).
As was also explained in section 2.2.4, a battery ages even when kept charged and doing nothing,
mainly due to oxidation of the positive plate grid.
The following table gives a rough idea of the number of charge/discharge cycles that batteries can
withstand until the end of their service life, and how they could be destroyed by sulphation or due to
plate corrosion.
Batteries are considered to have reached the end of their service life when the capacity they can hold
has reduced to 80% of the rated capacity.
Number of cycles until end of
service life
Type
DoD 80 %
Start
Resistance to
100 % discharging
DoD 60 %
Not suitable for cyclic use
5
Spiral-cell
400
650
Semi-traction
200
350
VRLA
AGM battery
Traction
(tubular-plate)
250
800
1500
2500
250
450
Survives up to 1 month in
discharged state
4–5
600
900
Survives 1 month in
discharged state
15 – 18
VRLA-gel
Sonnenschein Dryfit
A200
VRLA-gel
Sonnenschein Dryfit
A600
Irreparably sulphated
within a few days
Irreparably sulphated
within a few days
Survives up to 1 month in
short-circuited state
Survives up to 1 month in
discharged state
Expected service life in
float or shallow cycle use at
20°C ambient temperature
Years
10
5
4 - 10
10 – 15
Although most batteries will recover from a full discharge, it is nevertheless very detrimental to their service
life. Batteries should never be fully discharged, and certainly not left in discharged state.
It should also be noted here that the voltage of a battery that is in use is not a good measure for its level of
discharge. Battery voltage is affected too much by other factors such as discharge current and temperature.
Only once the battery is almost fully discharged (DoD 80% to 90%) will voltage drop rapidly. Recharging
should have been started before this happens. Therefore a battery monitor (chapter 3) is highly
recommended to manage large, expensive battery banks effectively.
2.5.6.
Premature aging 2. Charging too rapidly and not fully charging.
Batteries can be quickly charged and will absorb a high charge current until the gassing voltage is
reached. While charging with such high current might work well a few times, this will actually shorten the
service life of most batteries substantially (the exception: spiral-cell and some other AGM batteries).
This is due to accelerated loss of cohesion of the active material, which results in shedding. Generally it
is recommended to keep the charging current down to at most C / 5, in other words a fifth or 20 % of the
rated capacity.
When a battery is charged with currents exceeding C / 5, its temperature can rise steeply. Temperature
compensation of the charging voltage then becomes an absolute necessity (see sect. 2.5.9).
My own experience is that charging a 50 % discharged 12 V 100 Ah flooded battery at 33 A (C / 3)
results in a temperature increase of 10 to 15°C. The maximum temperature is reached at the end of the
bulk phase. Bigger batteries will become even hotter (because the amount of heat generated increases
with volume and the dissipation of heat increases with the available surface) as well as batteries with a
high internal resistance, or batteries which have been discharged more deeply.
© Victron Energy
17
An example:
Suppose a 50 foot sailing yacht has a 24 V service battery with a capacity of 800 Ah. The maximum
charging current would then be C / 5 = 160 A. Then 320 Ah could be charged in 2 hours. If
simultaneously there is 15 A consumption, the charging equipment will have to deliver 175 A. During the
remaining 22 hours of a 24-hour period an average of 320 Ah / 22 h = 14.5 A can be used, which
means a discharge of only 320 / 800 = 40 %. This does not seem much, but unfortunately it is the
maximum attainable when the generator period is limited to 2 hours. If used in this manner the cycling
process will stabilise between a DoD of 20 % (beyond this point the charging voltage increases and the
current accepted by the battery decreases) and a DoD of 20 % + 40 % = 60 %. Discharging more
deeply and charging more rapidly would result in considerable loss of service life.
In the example described above the battery is being used in partially charged state (between 20 %
and 60 % DoD).
Next to sulphation, there are two more reasons why the number of cycles in the partial state-of-charge
mode should be limited:
1) Stratification of the electrolyte.
This problem is specific to batteries with liquid electrolyte: see sect. 2.3.6.
As a rule of thumb, one should not extend partial state-of-charge operation beyond approx. 30 cycles,
and much less in case of very deep discharges.
2) Cell unbalance.
Cells of a battery never are identical. Some cells do have a slightly lower capacity than others. Some
cells will also have lower charge efficiency (see sect. 3.4.) than others. When a battery is cycled but not
fully charged, these weaker cells will tend to lag further and further behind the better cells. To fully
charge all cells, the battery has to be equalized (which means that the better cells will have to be
overcharged, see sect. 4.3.).
Unbalance will increase faster in case of very deep discharges or a very high charge rate. In order to
prevent excessive cell unbalance, a battery should be fully recharged at least every 30 to 60 cycles.
2.5.7.
Premature aging 3. Undercharging.
As discussed in section 2.2.4, sulphation will occur when a battery is left in fully discharged condition.
Sulphating will also take place, although at a slower rate, when a battery is left partially discharged. It is
therefore recommended to never leave a battery more than 50 % discharged and to recharge to the full
100 % regularly, for example every 30 days.
Batteries, especially modern low antimony flooded batteries, often are undercharged because the
charge voltage is insufficient (see chapter 4).
Along with discharging too deeply, not fully charging is the major cause of premature aging of a
battery.
2.5.8.
Premature aging 4. Overcharging.
rd
Charging too much is, in sequence, the 3 main cause of service life reduction of a battery.
Overcharging results in excessive gassing and therefore loss of water. In wet batteries water loss
through excessive gassing can simply be replenished (yet the accelerated corrosion of the positive
plates which takes place simultaneously is irreparable). However, sealed batteries which gas
excessively cannot be replenished, and are therefore much more susceptible to overcharging. A
frequent cause of excessive charging is the lack of temperature compensation or batteries being
simultaneously charged using diode isolators (see chapter 5).
2.5.9.
Premature aging 5. Temperature.
The temperature of a battery can vary greatly for various reasons:
Rapid discharging and, to a much greater extent, rapid charging heats up a battery (see sect.
2.5.6 and 2.5.8).
A battery’s location. In the engine room of a boat temperatures of 50°C or more can occur. In a
vehicle the temperature can vary from - 20°C to + 50°C.
A high average working temperature results in accelerated aging because the rate of the chemical
decomposition process in the battery increases with temperature. A battery manufacturer generally
specifies service life at 20°C ambient temperature. The service life of a battery halves for every 10°C of
rise in temperature.
18
© Victron Energy
The following table gives an impression of service life at different temperatures.
Battery type
Service life in shallow cycling or float use (years)
20°C
25°C
30°C
Start
5
3.6
2.5
Spiral-cell
10
7
5
Semi-traction
5
3.6
2.5
VRLA
AGM battery
Traction
(tubular-plate)
VRLA-gel
Sonnenschein Dryfit A200
VRLA-gel
Sonnenschein Dryfit A600
8
6
4
10
7
5
5
3.6
2.5
16
11
8
Finally, temperature plays a big part in charging batteries. The gassing voltage and consequently the
optimum absorption and float voltages are inversely proportional to temperature.
This means that at a fixed charge voltage a cold battery will be insufficiently charged and a hot battery
will be overcharged.
See section 4.4. for more information on temperature and battery charging.
2.5.10. Self-discharge
A battery at rest loses capacity as a consequence of self-discharge. The rate of self-discharge depends
on the type of battery and temperature.
Type
Alloy
Start
Spiral-cell
Semi-traction
VRLA
AGM battery
Traction
(tubular-plate)
VRLA-gel
Sonnenschein Dryfit A200
VRLA-gel Sonnenschein
Dryfit A600
Antimony (1,6 %)
Self-discharge per month at
20°C
6%
Self-discharge per
month at 10°C
3%
Pure lead
4%
2%
Antimony (1,6 %)
6%
3%
Calcium
3%
1.5 %
Antimony (5 %)
12 %
6%
Calcium
2%
1%
Calcium
2%
1%
When not in use, open lead-antimony batteries must be recharged after no more than 4 months, unless
the average ambient temperature is low.
Sealed batteries can be left without recharge for a period of 6 to 8 months.
When not in use for a long period of time, it is important to disconnect the battery from the electric
system, so that no accelerated discharging can take place as a result of current leaks elsewhere in the
system.
© Victron Energy
19
3. Monitoring a battery’s state of charge.
‘The battery monitor’
3.1. The different ways of measuring a battery’s state of charge
3.1.1.
Specific gravity (SG) of the electrolyte
As explained in sect. 2.2.1, the electrolyte of a lead-acid battery consists of a mixture of water and
sulphuric acid. When fully charged, the active material in the negative plates is pure sponge lead; in the
positive plates it is lead oxide. The concentration of sulphuric acid in the electrolyte (and consequently
the SG) is then high.
During discharging the sulphuric acid from the electrolyte reacts with the active material in the positive
and negative plates forming lead sulphate and water. This reduces the sulphuric acid concentration and
consequently the SG of the electrolyte.
During discharging, the depth of discharge (DoD) of the battery can be tracked quite well by using a
hydrometer to monitor the SG of the electrolyte. The SG will decrease as shown in the following table:
Depth of discharge (%)
0
25
50
75
100
Specific gravity
Between 1,265 and 1,285
1,225
1,190
1,155
1,120
Battery voltage
12.65 +
12.45
12.24
12.06
11.89
During charging the reverse process takes place and sulphuric acid forms once again. Because
sulphuric acid is heavier than water, in batteries with liquid electrolyte (this does not apply for gel and
AGM batteries) it settles downwards, so that the acid concentration increases at the bottom of the
battery. However, above the plates the acid concentration in the liquid does not increase until the
gassing level is reached!
Some useful information about electrolyte:
Stratification
Only once the gassing voltage (2.39 V per cell, or 14.34 V for a12 V battery at 20°C) is reached will the
electrolyte slowly become well mixed again by the gas bubbles.
The time needed depends on the construction of the battery and on the amount of gassing. The amount
of gassing in turn depends on the charge voltage, on the amount of antimony doping and age of the
battery.
Batteries with relatively high antimony doping (2.5 % or more) in general do gas sufficiently during the
absorption charge for the electrolyte to become homogeneous again.
Modern low antimony batteries (1.6 % or less antimony content) however gas so little that a normal
charge cycle is not sufficient. It then takes weeks of float charging (with very little gassing) before the
electrolyte is well mixed again. As a result flooded batteries, after having been fully charged, may
nevertheless show a low hydrometer reading!
Note: Vibration and motion in a boat or vehicle will in general adequately mix electrolyte.
Temperature correction for hydrometer readings:
SG varies inversely with temperature. For every 14°C of temperature increase above 20°C, the
hydrometer reading will decrease with 0.01. So a reading of 1.27 at 34°C is equivalent to a reading of
1.28 at 20°C.
Specific gravity variations per region:
The SG values as mentioned in the table above are typical for a moderate climate.
In hot climates SG is reduced as shown in the table below in order to diminish the effect of temperature
on service life of a battery
Fully charged SG, moderate climate:
Fully charged SG, sub tropical climate:
Fully charged SG, tropical climate:
20
1.265
1.250
1.235
© Victron Energy
- 1.285
- 1.265
- 1.250
3.1.2.
Battery voltage
Battery voltage too can be used as a rough indication of the battery’s state of charge (see preceding
table, section 3.1.1).
Important: the battery should be left undisturbed for several hours (no charging or discharging) before a
valid voltage measurement is possible.
3.1.3.
Amp-hour meter
This is the most practical and accurate way to monitor a battery’s state of charge. The product designed
for this is the battery monitor. The following sections look in more detail at the use of the battery
monitor.
3.2. The battery monitor is an amp-hour meter
The battery monitor’s main function is to follow and indicate the DoD of a battery, in particular to prevent
unexpected total discharge.
A battery monitor keeps track of the current flowing in and out of the battery. Integration of this current over
time (which if the current would be a fixed amount of amps, boils down to multiplying current and time) gives
the amount of amp-hours flowing in or out of the battery.
For example: a discharge current of 10 A for 2 hours means that the battery has been discharged by
10 x 2 = 20 Ah.
3.3. Energy efficiency of a battery
When a battery is charged or discharged losses occur. The total quantity of electric energy that the battery
takes up during charging is approx. 25 % greater than the energy given out during discharging, which means
an efficiency of 75 %. High charge and discharge rates will further reduce efficiency. The greatest loss occurs
because the voltage is higher during charging than during discharging, and this occurs in particular during
absorption. Batteries that do not gas much (low antimony batteries) and that have a low internal resistance are
the most efficient.
When a battery is used in the partial state-of-charge mode (see the example in section 2.5.6.), its energy
efficiency will be quite high: approx. 89 %.
To calculate Ah charge or discharge of a battery, a battery monitor only makes use of current and time, so
compensation for the overall efficiency is not needed.
3.4. Charge efficiency of a battery
When a battery is charged, more Ah has to be “pumped” in the battery than can be retrieved during the next
discharge. This is called charge efficiency, or Ah or Coulomb efficiency (1 Ah = 3600 C).
The charge efficiency of a battery is almost 100 %, as long as no gas generation takes place. Gassing means
that part of the charging current is not transformed into chemical energy that is stored in the plates, but used to
decompose water into oxygen and hydrogen gas (this is also true for the “oxygen only” end of charge phase of
a sealed battery, see section 2.3.2.). The “amp-hours” stored in the plates can be retrieved during the next
discharge whereas the “amp-hours” used to decompose water are lost.
The extent of the losses, and therefore the charge efficiency depends on:
A.
The type of battery: low gassing = high charge efficiency.
B.
The way in which the battery is charged. If a battery is mainly used in partial state of charge (see the
example in section 2.5.6.) and only charged up to 100 % now and again, the average charge efficiency will be
higher than if a battery is recharged to 100 % after each discharge.
C.
Charge current and voltage. When charging with a high current and therefore also a high voltage and a
high temperature, gassing will start earlier and will be more intensive. This will reduce charge efficiency (and
also the overall energy efficiency).
In practice charge efficiency will range in between 80 % and 95 %. A battery monitor must take the charge
efficiency into account, otherwise its reading will tend to be too optimistic. If the charge efficiency has to be preset manually it is advisable to initially choose a low value, for example 85 %, and adjust later to suit practice
and experience.
© Victron Energy
21
3.5. Effect on capacity of rapid discharging
As discussed in sect. 2.5.3. The capacity of a battery is dependent on the rate of discharge. The faster the rate
of discharge, the less Ah capacity will be available.
Back in 1897, a scientist named Peukert discovered that the relationship between the discharge current I and
the discharge time T (from fully charged to fully discharged) may be described approximately as follows:
n
Cp = I x T
where Cp is a constant (the Peukert capacity) and n is the Peukert exponent. The Peukert exponent is always
greater than 1. The greater n is, the poorer the battery performs under high rates of discharge.
Peukert’s exponent may be calculated as follows from measurements on a battery or using discharge tables or
graphs.
If we read (from a discharge table) or measure discharge time T1 and T2 for two different discharge currents (I1
and I2), then:
n
n
Cp = I 1 x T1 = I 2 x T2
and therefore:
n = log( T2 / T1) / log (I1 / I2)
As shown in the tables of section 2.5.3, increasing the discharge current from C / 20 to C / 1 (= increasing the
discharge current of a 200 Ah battery from 200 / 20 = 10 A to 200 / 1 = 200 A) can reduce effective capacity by
as much as 50 % for a mono block gel battery.
A battery monitor should therefore compensate capacity for the rate of discharge.
In practice this is quite complicated because the discharge rate of a house battery will vary over time.
3.6. Is capacity “lost” at high rates of discharge?
Section 2.5.3 cites the example of a battery where the rated capacity under a 20-hour discharge was 200 Ah,
thus C20 = 200 Ah. The corresponding discharge current is:
I20 = C20 / 20 = 10 A
Under a discharge current of 200 A the battery was flat in 30 minutes. So although we started with a 200 Ah
battery, it was flat after discharging only 100 Ah.
This does not mean that, with a discharge current of 200 A, the 100 Ah capacity difference (C20 - C1 = 200 –
100 = 100 Ah) has “disappeared”. What happens is that the chemical process (diffusion, see sect. 2.2.3.) is
progressing too slowly, so that the voltage becomes unacceptably low. A battery discharged with 200 A and
“flat” in 30 minutes will therefore also be (nearly) fully charged again after recharging 100 Ah, while the same
battery which is discharged with I20 = 10 A and is flat in 20 hours will be nearly fully charged after recharging
200 Ah.
In fact a battery which has been discharged at a very high rate will recover over time and the remaining
capacity can be retrieved after the battery has been left at rest for several hours or a day.
22
© Victron Energy
3.7. Other Useful features of a battery monitor
In my opinion, apart from a voltmeter and an alarm function, very useful features are event counting and data
logging
3.7.1.
Event counting
Event counting means that specific events; especially events that are potentially damaging or that on
the contrary are needed for battery maintenance are stored in a memory of the battery monitor.
Such events could be:
over voltage
under voltage
number of charge-discharge cycles
100 % discharge
100 % recharge
3.7.2.
Data logging
Data logging would mean that, in addition to specific events, at regular intervals the status of the battery
is stored in order to be able to reproduce a history of use at a later date.
© Victron Energy
23
4. Battery charging: the theory
4.1. Introduction
Writing about battery charging would be easy if there was one recipe, independent of the conditions of use and
valid for all types of lead acid batteries. But this is not the case.
Additional complicating factors are that there is often more than one charging device connected to the battery,
and that the net charging current is not known because of consumers that are also connected to the battery.
Voltage limited charging is the best way to eliminate the influence of consumers as far as possible. And
working with 2 voltage limits, the absorption and float voltage limits discussed later in this chapter, is a good
and generally accepted method to charge batteries which have been deeply discharged, as fast as possible.
A further refinement of the standard 3 stage (bulk – absorption – float) method is adaptive charging: see
sect 5.3.2.
4.2. Three step (I U° U) charging
4.2.1.
The bulk charge
When starting to charge a battery, voltage immediately jumps to approx. 2.1 V / cell (12.6 V for a 12 V
battery and 25.2 V for a 24 V battery) and then slowly rises until the first voltage limit is reached.
This is the current limited or bulk phase of the charge cycle, during which the battery will accept the full
available charge current.
For big battery banks it is advisable to limit the current to C / 5 or, even better, C / 10, meaning that 10
to 20 % of the total capacity is charged per hour. For example 100 A to 200 A for a 1000 Ah battery.
A less expensive smaller battery bank is often charged, although this may reduce service life, at a
higher rate, for example C / 3.
A deeply discharged battery will accept a current of this order of magnitude until it is about 80 %
charged. It will then reach the first voltage limit. From there onwards, instead of “absorbing” all of the
current being “offered”, charge acceptance reduces rapidly. Therefore this first voltage limit is called the
absorption voltage and the subsequent phase of the charge cycle the absorption phase.
A high bulk-charging rate will heat the battery, increase gassing and increase the absorption time
needed to fully charge the battery. In other words: a high charging current will only shorten charge time
to a limited extent.
In any case the charge current must be limited to C / 5 or less once the gassing voltage has
been reached (at 20°C the gassing voltage is approximately 2.4 V / cell, or respectively 14.4 V
and 28.8 V). Otherwise the active mass will be pushed out of the plates due to excessive
gassing.
4.2.2.
The absorption charge
When the pre-set absorption voltage limit has been reached, charging is limited to the amount of current
that the battery will absorb at this voltage.
During the absorption phase the current will steadily decrease as the battery reaches its fully charged
state.
As explained in sect. 2.2.3, charging (and discharging) a battery means that a diffusion process must
take place
The diffusion process in fact explains a lot about charging and discharging batteries:
When a battery has been subjected to a fast but shallow discharge, little diffusion deep inside
the active material has taken place and the chemical reaction is limited to the surface of the plates. To
recharge, a short or even no absorption time at all will be needed (the battery in a car is charged at a
fixed 14 V). To recover from a long and deep discharge, a long absorption period will be needed in
order to reconvert the active material deep inside the plates.
24
© Victron Energy
Thin plate starter batteries need less absorption charging than thick plate or tubular plate
heavy-duty batteries.
Absorption is a trade off between voltage (increasing the voltage results in stronger electric
fields which will increase diffusion speed) and time. Applying a high voltage will however heat up the
battery, increase gassing to a level where the active material is pushed out of the plates and, in case of
VRLA batteries, cause venting which will dry out and destroy the battery.
So what does this mean in terms of absorption voltage and absorption time?
We can distinguish between 3 groups of batteries:
1) Flooded lead-antimony batteries
Here we have a rather wide trade-off band of absorption voltage against time, ranging from 2.33 V / cell
(14 V) and a long absorption time to 2.6 V / cell (15.6 V) and a much shorter absorption time.
To avoid excessive gassing, charge current should be limited to at most C / 5 (20 % of the rated
capacity) or, even better, C / 10 of the capacity of the battery (for example 40 A for a 400 Ah battery)
once the gassing voltage has been reached. This can be achieved by either current limiting or by
limiting the rate of voltage increase to about 0.1 V per cell per hour (0.6 V per hour for a 12 V battery or
1.2 V per hour for a 24 V battery). See section 5.3.2.
It is also important to know that batteries do not need to be fully recharged after every discharge. It is
very acceptable to recharge to 80 % or 90 % (partial state of charge operation, preferably including
some gassing to limit stratification) on average and to fully recharge once every month.
2) The Spiral cell AGM battery stands apart because it is sealed and nevertheless accepts a wide
absorption voltage range.
3) Other VLRA batteries have a limited absorption voltage range that should never be exceeded.
Higher voltages will result in venting. The battery will dry out and be destroyed.
4.2.3.
The float charge
After the battery has been fully charged it is kept at a lower constant voltage to compensate for selfdischarge, i. e. to keep it fully charged.
As mentioned earlier, if maintained for long periods of time (several months) the float voltage may not
deviate more than 1 % from the voltage recommended by the manufacturer, after compensating for
temperature.
Excessive voltage results in accelerated aging due to corrosion of the positive plates. The rate of
positive plate grid corrosion will roughly double with every 50 mV of increase in cell voltage (0.3 V
respectively 0.6 V for 12 V and 24 V batteries).
Insufficient voltage will not keep the battery fully charged, which will eventually cause sulphation.
Regarding float voltage we must distinguish between flooded and VLRA batteries:
1) The recommendations for float charging flooded batteries vary from 2.15 V to 2.33 V per cell
(12.9 V to 14 V for a 12 V battery). The flooded battery types that have been discussed have not been
designed for float charging over long periods of time (i. e. several months or years).
When float charged at the higher end of the 2.15 V to 2.33 V range, service live will be shortened due to
corrosion of the positive plate grids, and batteries with a high antimony content will need frequent
topping up with demineralised water.
When float charged at 2.15 V per cell, aging and gassing will be under control, but a regular refreshing
charge at a higher (absorption) voltage will be needed to maintain the fully charged state.
In other words: the high end of the 2.15 V to 2.33 V range is fine for a few days or weeks, but not for a 6
months winter period.
© Victron Energy
25
The following table shows how much water is lost due to gassing in case of a relatively new low antimony battery
(gassing increases with age):
Battery
(fully charged)
V / cell
Batt. V
Open-circuit
Float
Float
Float
Float
Absorption
Absorption
Absorption
Absorption
2.13
2.17
2.2
2.25
2.3
2.33
2.4
2.45
2.5
12.8
13
13.2
13.5
13.8
14
14.4
14.7
15
Gas
generation
per 100 Ah
battery
capacity
20 cc / h
25 cc / h
60 cc / h
90 cc / h
150 cc / h
180 cc / h
500 cc / h
1l/h
1.5 l / h
Water
Topping
consumption
up
per 100 Ah
interval
battery capacity
0.1 l / year
0.1 l / year
0.3 l / year
0.4 l / year
0.6 l / year
0.8 l / year
2.2 l / year
4.2 l / year
6.5 l / year
5y
5y
1.5 y
1y
10 m
7m
3m
Water
lost per
charge
cycle
2 cc
3 cc
4 cc
Ah
”lost” per
100 Ah
batt.
capacity
44 / y
54 / y
130 / y
200 / y
300 / y
2 / cycle
3 / cycle
4 / cycle
Gas generation and water consumption is based on a 6 cell (= 12 V) battery.
The topping up interval is based upon 0.5 l of water lost per 100 Ah. The water surplus in the battery is
approximately 1 l / 100 Ah.
The formulas:
a) 1g of water can be decomposed into 1.85 l of oxygen + hydrogen gas
b) 1 Ah “lost” due to gassing generates 3.7 l of gas in a 6 cell (= 12 V) battery
The table shows that a float voltage of 13.5 V (13.5 V is an often recommended float level for the
flooded batteries under consideration here, as lower float voltages do not completely compensate selfdischarge) or higher will result in topping up needed more than once a year. Please also note that
batteries with more antimony doping will consume 2 to 5 times more water!
To my opinion, instead of trying to find a delicate balance between insufficient voltage to compensate
for self-discharge and to much gassing at a higher voltage, it would be better to leave the battery open
circuited and recharge, depending on temperature, at least once every 4 months, or to reduce float
voltage to a very low level, for example 2.17 V per cell (13 V respectively 26 V), and also recharge
regularly at a higher voltage. This regular refreshing charge should be a feature of the battery charger.
See section 5.3.2.
2) All VLRA batteries mentioned can be float charged for long periods of time, although some studies
have shown that a treatment similar to the one proposed here for flooded batteries will increase service
life (see for example “Batterie Technik” by Heinz Wenzl, Expert Verlag, 1999).
4.3.
Equalizing
When not charged sufficiently, batteries will deteriorate due to the following reasons:
sulphation
stratification (flooded batteries only)
cell unbalance, (see sect. 2.5.6).
Batteries will in general reach their fully charged state, including equalization, during the absorption
charge or when float charged for a sufficiently long period of time.
If they have been used in partial state of discharge mode for some time, they will recover by:
repetitive cycling and charging with the appropriate absorption voltage and time
an absorption or float charge during a longer period of time
a real equalization charge, see below.
An equalizing charge is done by first charging the battery as usual, and then continue charging with a
low current (3 % to 5 % of its Ah capacity, i. e. 3 to 5 A for a 100 Ah battery) and let the voltage increase
to 15-16 V (30-32 V for a 24 V battery) until the specific gravity (SG) stops increasing. This will take 3 to
6 hours and by then all cells should give the same reading. Be sure to isolate the battery from all loads
sensitive to over-voltage during this period.
Especially heavy-duty traction batteries may need a periodic equalization charge.
26
© Victron Energy
How often should a battery be equalized?
It all depends on type and usage. For batteries with high antimony doping, the best way to find out is to
check SG after a normal charge:
If all cells are equal and at 1.28, there is no need to equalize
If all cells are between 1.24 and 1.28, it would be good to equalize when convenient, but there
is no urgency
If the SG of some cells is less than 1.24, an equalization is recommended.
If all cells are below 1.24, the battery is undercharged and the absorption time or voltage
should be increased.
On VLRA batteries and low antimony flooded batteries the SG cannot be measured, respectively the
reading will be unreliable. The easiest way to check if they are really charged to the full 100 % is to
monitor the charge current during the absorption charge. The charge current should steadily decrease
and then stabilise: a sign that the chemical transformation of the active mass has been completed and
that the main remaining chemical activity is gassing (decomposition of water into oxygen and
hydrogen).
4.4. Temperature compensation
As has already been mentioned in sect. 2.5.9, temperature is of importance when charging batteries. The
gassing voltage and consequently the optimum absorption and float voltages are inversely proportional to
temperature.
This means that in case of a fixed charging voltage a cold battery will be insufficiently charged and a hot battery
will be overcharged.
Both effects are very harmful. Deviations of more than 1 % of the correct (temperature dependent) float voltage
can result in a considerable reduction of service life (according to some studies up to 30 % when the battery is
float charged for long periods of time), particularly if the voltage is too low and the battery does not reach or
stay at 100 % charge, so that the plates start to sulphate.
On the other hand over-voltage can lead to overheating, and an overheated battery can suffer “thermal
runaway”. Because the gassing voltage decreases with increasing temperature, the absorption and float
charge current will increase when the battery heats up, and the battery becomes even hotter, etc. Thermal
runaway quickly results in destruction of the battery (the excessive gassing pushes the active mass out of the
plates), and there can be a risk of explosion due to internal short-circuits and high quantities of oxygen and
hydrogen gas coming out of the battery.
The charging voltage, as quoted by European battery manufacturers, applies at 20°C battery temperature and
may be kept constant as long as the temperature of the battery remains reasonably constant (15°C to 25°C).
Although manufacturers’ recommendations differ to some extent, a temperature compensation of - 4 mV / °C
per cell is a generally accepted average. This means – 24 mV / °C for a 12 V battery and – 48 mV / °C for a 24
V battery.
Where the manufacturer specifies an absorption voltage of for example 28.2 V at 20°C, then at 30°C the
absorption voltage must be reduced to 27.7 V. This is a difference of 0.5 V that certainly cannot be neglected.
When in addition to an ambient temperature of 30°C, the internal temperature of the battery rises another 10°C,
which is quite normal during charging, the absorption voltage must be reduced to 27.2 V. Without temperature
compensation the charge voltage would have been 28.2 V which would quickly destroy a gel or AGM bank
worth some ten thousand dollars!
What the above means is that temperature compensation is important, and must be implemented,
especially on large, expensive house batteries, and when a high rate of charge current is used.
All charging voltages mentioned in this and in other chapters are subject to temperature
compensation.
© Victron Energy
27
4.5. Overview
The following table gives an overview of how batteries can be recharged after a 50 % discharge. In practice
recommendations can vary from one manufacturer to another and also depend on how the battery is used.
Always ask your supplier for instructions!
Type
Automotive
Spiral-cell
Alloy
Approximate absorption time at
20°C after 50 % DoD
Float voltage at 20°C
Antimony (1.6 %)
4 h at 2.50 V / cell (15.0 V)
6 h at 2.45 V / cell (14.7 V)
8 h at 2.40 V / cell (14.4 V)
10 h at 2,33 V / cell (14 V)
4 h at 2.50 V / cell (15.0 V)
8 h at 2.45 V / cell (14,7 V)
16 h at 2.40 V / cell (14.4 V)
1 week at 2.30 V / cell (13.8 V)
5 h at 2.50 V / cell (15.0 V)
7 h at 2.45 V / cell (14.7 V)
10 h at 2.40 V / cell (14.4 V)
12 h at 2.33 V / cell (14 V)
6 h at 2.50 V / cell (15.0 V)
8 h at 2.45 V / cell (14.7 V)
10 h at 2.40 V / cell (14.4 V)
2.33 V / cell (14 V)
after a few days decrease
to:
2.17 V / cell (13 V)
2.3 V / cell (13.8 V)
Pure lead
Semi-traction
Antimony (1.6 %)
Traction
(tubular-plate)
Antimony (5 %)
VRLA-gel
Sonnenschein Dryfit
A200
VRLA-gel
Sonnenschein Dryfit
A600
Calcium
4 h at 2.40 V / cell (14.4 V)
voltage not to be exceeded!
Calcium
4 h at 2.34 V / cell (14.04 V)
voltage not to be exceeded!
2.33 V / cell (14 V)
after a few days decrease
to:
2.17 V / cell (13 V)
2.3 V / cell (13.8 V)
after a few days decrease
to:
2.17V / cell (13 V)
2.3 V / cell (13.8 V)
2.25 V / cell (13.5 V)
Notes:
1) In practice, when shore power is not available, batteries on a boat tend to be charged as fast as possible, with
shortened absorption time or no absorption period at all (partial state of discharge operation). This is quite
acceptable, as long as a charge to the full 100 % is applied regularly (see sect. 4.3).
2) When charging at a voltage exceeding the gassing voltage, either the current should be limited to at most 5 % of
the Ah capacity of the battery, or the charge process should be carefully monitored and the voltage reduced if the
current tends to increase to more than 5 % of the Ah capacity.
3) When float charging batteries at 2,17 V per cell a regular refreshing charge will be needed.
4) About service life and overcharging:
Starter- or bow thruster batteries are often charged in parallel with the house battery (see sect. 5.2). The
consequence is that these batteries will frequently be charged at a high voltage (15 V or even more) although they
are already fully charged. If this is the case, VRLA batteries should not be used for this purpose because they will
start venting and dry out. The exception is the spiral-cell VLRA battery, that can be charged at up to 15 V without
venting.
Flooded and spiral cell batteries will survive, but age faster. The main aging factor will be corrosion of the positive
plate grid, and the corrosion rate doubles for every 50 mV of voltage increase per cell. This means that an Optima
battery for example, which would last 10 years at its recommended float voltage of 13.8 V, would age 4 times faster
at 15 V (((15 – 13.8) / 6) / 0.05 = 4), reducing service live to 2.5 years if it would constantly be charged at 15 V.
Similar results are obtained for flooded batteries. While this calculation is theory and has not been tested in practice,
it nevertheless shows that regular overcharging during short periods (in practice only during the absorption charge
period of the house battery) of starter or bow thruster batteries does not decrease service live to an unacceptably low
period.
28
© Victron Energy
4.6. Conclusion: how should a battery be charged?
As mentioned earlier, there is no simple recipe that can be applied to all batteries and operating conditions.
Also, there is no greater variety of operating conditions and types of batteries than can be found on a yacht.
To get a better idea of how batteries are used and what this means for charging, let us again take the example
from section 2.4. Let us assume that the yacht has 3 batteries on board: a house battery, a starter battery and
a bow thruster battery.
How are these different batteries used, and how should they be charged?
4.6.1.
The house battery
In sect. 2.4 and 2.5.6 three conditions of use were described:
1) Cyclic use, in the partial state of charge mode, when sailing or at anchor. Important here is charging
as fast as the battery permits. Temperature compensation is a must to prevent early failure due to
overheating and excessive gassing.
2) A mixture between float use and short, shallow discharges when motoring or moored. The risk here
is that a 3-step alternator regulator (when motoring) or a charger, (when connected to shore power) is
frequently triggered by these shallow discharges to go into bulk and then absorption mode. The result
could be that the battery is continually subjected to absorption charging and will be overcharged.
Therefore, ideally, the length of the absorption phase should be in accordance with the preceding DoD.
See section 5.3.2. for the adaptive charging method, a Victron Energy innovation.
Flooded batteries, if being float charged without any discharge occurring, should be switched to the
lower 2.17 V per cell level and be regularly topped up with an absorption charge at 2.4 V / cell or more.
Again, see section 5.3.2.
3) For long periods of time the battery is left open circuited or float charged, in wintertime for example.
As discussed in sect. 4.2.3, most flooded batteries will deteriorate quickly if float charged at 2.3 V per
cell for a long time. Ideally charge voltage should be lowered to between 2.15 V and 2.2 V per cell, or
left open circuited and recharged regularly. When the average temperature is 20°C or less, at least
every 4 months. At higher temperatures they should be recharged more often.
From my personal experience and from numerous discussions with boat owners, I do also prefer to
leave sealed Exide/Sonnenschein Dryfit A200 batteries or equivalent open circuited or on a lower
than recommended float level instead of float charging them at 13.8 V, because, although in theory they
can be float charged during long periods of time, only too often the result was damage due to
overcharging.
4.6.2.
The starter battery
The starter battery is subject to 2 conditions of use:
-
Shallow discharge due to starting the engine once or twice a day.
No discharge at all. The best would be no recharge either, apart from an absorption charge
once in a while.
In practice however the starter battery will very often be charged in parallel with the house battery,
which is acceptable as long as the right type of battery is used and some decrease of service live is
accepted (see note, sect. 4.5).
4.6.3.
The bow thruster battery
When used, discharge can be deep, and fast recharge will be required. In general the most practical
solution is to charge the bow thruster battery in parallel with the house battery. Often spiral-cell batteries
are used, because of their very high peak current capability. These same batteries will accept a wide
recharge voltage range and are very tolerant to overcharging.
© Victron Energy
29
5. Charging batteries with an alternator or a battery
charger
5.1. The alternator
The main engine of a boat is normally fitted with a standard automotive alternator. Standard automotive
alternators have a built-in regulator with temperature compensation. The temperature is measured in the
regulator itself. This is a suitable arrangement for cars, where the battery temperature will be roughly the same
as the temperature of the regulator.
Moreover, in cars the battery will virtually always be fully charged. The battery will only be discharged to a small
extent during engine starting. After that the alternator delivers sufficient power, even with the engine idling, to
supply all consumers and to recharge the battery. Because the battery is actually never deeply discharged,
and in general plenty of charging time is available, the absorption phase discussed in chapter 4 is superfluous.
The alternator charges with a current dependent on engine rpm until the pre-set float voltage is reached. Then
the alternator transfers to constant voltage. Generally the voltage is pre-set at 2.33 V / cell at 20°C, i.e. 14 V for
12 V systems and 28 V for 24 V systems.
This charging system works perfectly given the following conditions:
the battery is a flat-plate automotive battery
the battery is nearly always fully charged
the temperature difference between the regulator on the alternator and the battery is limited
the voltage drop along the cable between battery and alternator is negligible (i.e. less than 0.1 V,
including switches, isolators, etc.).
Problems occur as soon as one of the above conditions is no longer fulfilled.
The following sections shortly discuss the practice of charging batteries with an alternator.
For an exhaustive discussion of alternators, alternator regulators, isolators and other related equipment, I
recommend reading Nigel Calder’s standard work “Boatowners Mechanical and Electrical Manual” as well as a
visit to the websites of Ample Power (amplepower.com), Balmar (balmar.net) and Heart Interface
(xantrex.com).
5.2. When the alternator has to charge more than one battery
5.2.1.
Introduction
The bare minimum on a boat is two batteries: one to start the main engine and a house (or accessory or
service) battery. To make sure that the engine can always be started, all accessories (navigation
equipment, lighting, autopilot, refrigerator, etc.) are supplied by the house battery.
The starter battery (sometimes 2, for 2 engines) should have no other load than the starter motor of the
main engine and must never be allowed to discharge, otherwise the engine cannot be started.
Often there is a third battery on board, the bow thruster battery, and there may be even a fourth, the
electronics (navigation) battery.
The batteries are separated from one another by relays, diode isolators, or other devices that will be
briefly discussed in the next sections. In larger systems the starter battery often has its own dedicated
alternator. Battery voltages may also be different, some 12 V (starting and electronics) others 24 V
(house and bow thruster)
5.2.2.
The problem
When using a standard automotive alternator-regulator to charge several batteries simultaneously, the
following problems arise:
In a boat, cable runs are often much longer than in cars so that there is more voltage drop
2
between alternator and battery (example: the voltage drop along a 5 metre long, 10 mm cross-section
cable is 0.5 V at a current of 50 A).
30
© Victron Energy
Diode battery isolators cause additional voltage drop: 0.4 to 0.8 V for silicon diodes and 0.1 to
0.4 V for FET transistors used as diodes.
The alternator in the engine compartment registers an ambient temperature of 40°C or even
higher while the house battery, lower down in the boat, is much colder e.g. 20°C. This results in an
additional under-voltage of approx. 0.6 V or even 1.2 V for 12 V or 24 V systems respectively.
The house battery will usually be deeply discharged and should really be charged with a high
(absorption) voltage. This is particularly the case when the alternator on the main engine is the only
source of power and runs briefly every day to charge the batteries.
In contrast, the starter battery and often also the bow thruster battery are practically always
fully charged and do not need any absorption charging.
Often different battery types are used for starting, for the bow thruster and for house service.
These different batteries all have their own charging recipe.
5.2.3.
A wide range of solutions
It would be exaggerating to say that there are as many solutions as boats, but there are certainly many
ways to, more or less, overcome the above-mentioned problems. Several, but certainly not all, will be
discussed hereafter:
5.2.3.1 Keeping it simple and low cost: the microprocessor controlled battery combiner
Let the alternator charge the starter battery, and connect the service battery to the starter battery
with a battery combiner (for ex. a Cyrix battery combiner from Victron Energy). When one of the 2
batteries is being charged (the starter battery by the alternator or the service battery by a battery
charger), the Cyrix will sense the increasing voltage and connect both batteries in parallel. As soon
as the voltage decreases the Cyrix will disconnect the batteries from each other.
The advantage is simplicity and cost: the alternator does not have to be modified or replaced. The
drawback is a somewhat longer recharge time of the house battery because bulk charge will stop at
approximately 30 % DoD (or worse in case of important voltage drop in cabling or a low alternator
voltage due to high temperature) and then be followed by float charge. This means that the battery
will be cycled between 30 % and 70 % DoD. The solution is to oversize the house battery by 20 %
to 50 % and do a 100 % recharge when shore power is available.
5.2.3.2 Increase alternator voltage
Most alternators with built-in regulators can be modified so as to deliver a higher voltage. Adding a
diode in series with the voltage sense input of the regulator increases output voltage by approx.
0.6 V.
This is a job for the specialist. We will not dwell on it here, but it is a low cost improvement that,
together with 5.2.3.1, will charge batteries quite fast. Severe overcharging is a risk only in case of
very intensive motoring every day, and even that problem can be solved by temporarily switching
off the alternator (but never disconnect the main output of the alternator from the battery with the
engine running, because the resulting voltage spike might damage the rectifier diodes in the
alternator).
5.2.3.3 A multi-step regulator with temperature and voltage compensation
When choosing a multi-step regulator (bulk-absorption-float, see chapter 4), I would suggest to go
for the best and choose a model with:
Voltage sensing. This requires additional voltage sensing wires to measure and regulate
voltage directly on the terminal posts of the house battery or on the DC bus. Voltage-drop in cabling
and isolators is then automatically compensated.
Temperature compensation. This requires a temperature sensor to be mounted on the house
battery.
This solution is often used when an additional high output alternator is fitted.
5.2.3.4 The starter battery.
The solutions as suggested in 5.2.3.2 or 5.2.3.3 will improve charging of the house battery, but
what about the starter battery?
Let us assume that when the main engine is running, the batteries are charged in parallel by using
battery combining relays, or a diode or FET isolator. Nearly all of the charging current will then flow
© Victron Energy
31
to the house battery because this battery has the greatest capacity, the lowest internal resistance,
and is partially or fully discharged. This means that the voltage drop across the isolator and wiring
from alternator to house battery will be higher than from alternator to starter battery. It might very
well be that to achieve an absorption voltage of, say, 14.4 V on the house battery, the output
voltage of the alternator has to increase to 15.4 V (i. e. a voltage drop of 1 V from the alternator to
the house battery).
With 15.4 V on the alternator output the voltage on the starter battery could very well be 15 V (!)
because only a small percentage of the current flows to the starter battery. The result is that the
starter battery, already fully charged, is “forced” to 15 V although it should be floated at, say,
13.8 V.
What to do?
a) Improve the situation by reducing voltage loss as much as possible and leave it at that. The
starter battery might need early replacement, depending on how frequently the conditions referred
to above occur and which type of starter battery is used.
Gel batteries or flat plate AGM batteries are not recommended here, because they are relatively
sensitive to overcharging (they will start venting and dry out). A wet battery (low cost) will survive if
topped up with water when needed, and an Optima AGM spiral cell battery is also a good option
because of its wide charge voltage range and its tolerance to overcharging. See sect. 4.5 for an
estimate of battery service live when overcharged.
b) Add 1 or 2 diodes in the wiring to the starter battery to reduce voltage. Now the risk becomes
undercharging, if the service battery is only occasionally charged sufficiently to reach the
absorption voltage level (think of a sailing yacht on a long trip).
c) Insert a series regulator in the wiring to the starter battery, like the “eliminator” from Ample
Power.
d)
Charge the starter battery with a separate dedicated alternator.
5.2.3.5 The bow thruster battery
Optima is the ideal battery for this application. It can deliver extremely high currents and also
withstands high recharge currents as well as a wide recharge voltage range. So alternative a) of
5.2.3.4 would be advisable.
5.3. Battery chargers. From AC current to DC current
5.3.1.
Introduction
In chapter 3 and 4 we have discussed how batteries should be charged, and how batteries will fail if not
properly charged.
In section 5.2 it became apparent that charging batteries with the alternator on the main engine is a
question of compromising.
With battery chargers it’s somewhat less complicated, because most high output chargers have
temperature and voltage sensing facilities. Some also have 2 or 3 outputs. And nearly all have 3-step
charging.
There is a great variety of chargers to choose from and it is also much easier to install dedicated
chargers for the different batteries on board than adding additional alternators on the main engine.
5.3.2.
Optimised charging
I hope it became clear from the previous chapters that charging batteries requires careful consideration,
especially when conditions of use do change over time.
Victron Energy has incorporated in its latest battery chargers the knowledge that resulted from practical
experience, discussions with battery manufacturers, and numerous lab tests on a wide range of
batteries.
The innovation of the charger is in its microprocessor controlled ‘adaptive’ battery management
system:
The user can make his choice between 5 different charging recipes depending on which
battery type has to be charged. All recipes can be modified to fit a particular battery type and brand.
32
© Victron Energy
When recharging a battery, the Phoenix charger will automatically adjust absorption time to the
preceding DoD. When only shallow discharges occur (a yacht connected to shore power for example)
the absorption time is kept short to prevent overcharging. After a deep discharge the absorption time is
automatically increased to make sure that the battery is fully recharged.
If the absorption voltage setting exceeds 14.4 V, the BatterySafe mode is activated: the rate of
increase of voltage once 14.4 V has been reached is limited in order to prevent excessive gassing. The
BatterySafe feature allows for very high charge rates without risking damage due to excessive gassing.
The charging recipes for flooded batteries include two float charge levels. If only very shallow
discharges occur, a float level of 2.3 V / cell (13.8 V respectively 27.6 V) is maintained, with regular
short absorption charges. In case of no discharge at all, after a time which depends on the intensity of
previous use, the charger switches to the Storage mode: the float level is decreased to 2.17 V / cell
(13 V respectively 26 V), with a regular short absorption charge. The Storage mode will carry flooded
batteries through their winter rest without any additional care needed (except for topping up, if needed,
with demineralised water before the winter rest starts!).
5.3.3. Charging more than one bank
The problem has been discussed under section 5.2. There are 2 solutions to the problem. The second
best solution is the multiple output battery charger
5.3.3.1 The multiple output battery charger
In its simplest and most common configuration a multiple output battery charger has 2 or 3 outputs,
which each can supply the full rated output current and are isolated from each other by diodes. The
charge voltage is regulated on the primary side of the diodes and is slightly increased to compensate
for the average voltage drop over the diodes. Including the cable to the battery terminals the voltage
drop at full output current can exceed 1.5 Volt. At close to no load the voltage drop will reduce to less
than 0.5 Volt. This means that a charge voltage of for ex. 14.4 V will drop to 13.4 V at the full output
current. This is OK as long as during charging DC loads on the system are small or nonexistent: at
the end of the charge cycle the current will drop off and the 14.4 V absorption voltage will eventually
be reached.
Temperature compensation
Temperature compensation will not be accurate because the different banks will also have different
temperatures. Temperature compensation is especially important in case of sealed VRLA batteries,
see section 4.4.
Voltage sensing
Compensation of the voltage drop by measuring the charge voltage directly on the terminals of one of
the batteries will result in a perfect charge of one bank, and possibly overcharging others, see for ex.
note 4 of section 4.5.
5.3.3.2 A dedicated charger for each battery
This is the best solution, at a price. A compromise can be to take good care of the expensive house
bank, if needed including temperature compensation and voltage sensing, and to use a smaller multi
output charger for the other batteries.
5.3.3.3 The microprocessor controlled battery combiner
Charge the expensive house bank with a good charger, including temperature compensation and
voltage sensing. And connect other batteries to the house battery with microprocessor controlled
battery combiners, for ex. the Cyrix battery combiners from Victron Energy.
The Cyrix will also make sure that all batteries are parallel connected to the alternator when the main
engine is running, see 5.2.3.1.
© Victron Energy
33
6. Electric equipment and energy consumption
6.1. Introduction
Now that we know, more or less, how to charge batteries, it is time to discuss the consumers, which will
discharge the batteries.
In order to better understand the impact on energy consumption of the different consumers on board, it is
advisable to think in 3 categories:
Continuous consumers, which could for example, be the standby power taken by the VHF or the SSB,
the refrigerator and the freezer.
Long duration consumers (navigation lights, autopilot, cabin lighting, water maker, air conditioning)
that need power from between one hour to several hours a day.
Short duration consumers (pumps, electric winches, bow thruster, microwave, washing machine,
dishwasher, electric stove) that need power for between a few seconds up to, say, one hour per day.
In my experience everybody, myself included, tends to underestimate the daily energy consumption of
continuous and long duration consumers and to overestimate energy consumption of short duration
consumers.
6.2. Power and energy
Especially when the source of electricity is a battery, it is important to differentiate between power and energy.
Power is instantaneous, it is energy per second, and is measured in Watts (W) or Kilowatts (1 kW = 1000 W).
Energy is power multiplied by time. A battery stores energy, not power.
Low power but consumed over a long period can result in a lot of energy consumed and drain a battery. Power
is measured in Watt-hours (Watts x hours, or Wh) or Kilowatt-hours (1 kWh = 1000 Wh).
Energy is also the product of battery capacity (Ampere-hours) and voltage: Wh = Ah x V and
kWh = Ah x V x 1000.
So a power of 2 kW during 1 hour is 2 kW x 1 hour = 2 kWh of electric energy, and will drain
2 kWh / 12 V = 2000 Wh / 12 V = 167 Ah from a 12 V battery.
2 kW during 1 second (i. e. 1 / 3600 of an hour) amounts to (2000 / 3600) / 12 = 0.046 Ah. Next to nothing!
2 kW during 1 minute (i. e. 1 / 60 of an hour) amounts to (2000 / 60) / 12 = 2,7 Ah. A notebook battery would
do this (if it could deliver very high currents)!
2 kW during 10 hours will drain 2000 x 10 / 12 = 1667 Ah. A huge battery!
As a preparation for the chapters to come, some examples of power and energy consumption of household
appliances and other equipment are discussed in the next sections.
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6.3. Refrigeration
6.3.1.
Introduction
More often than not, refrigeration on board is a nightmare, or at least a headache.
On small yachts the refrigerator often takes more energy from the battery than all other equipment
together.
On medium sized yachts it is the refrigerator plus freezer that will drain the battery.
And on larger yachts it is because of the air conditioning that a generator has to run day and night.
In order to understand why, and see whether anything can be done about it, some theoretical
background is needed. This is the subject of the next section.
6.3.2.
Theory of the heat pump
Nearly all refrigeration systems are of the compressor heatpump type.
Operation is as follows:
The compressor, driven by a DC or AC electric motor compresses a gas (freon, until this was forbidden
because it destroys the ozone layer in the upper atmosphere) which is cooled down in what is called the
condenser. The condenser often is a small radiator with a fan in the cupboard under the sink, or it is a
much larger naturally ventilated radiator at the back of the refrigerator (normal household type
refrigerator), or it can be water-cooled. In the condenser the gas condenses to liquid and in that process
a lot of heat is taken from it. The liquid then moves to the evaporator, which is the cold plate in the
refrigerator or freezer. There the pressure is reduced and the liquid evaporates. To evaporate a lot of
heat has to be absorbed; this heat is removed from the refrigerator or freezer. The gas then goes to the
compressor, and so on.
The amount of energy needed for drawing a certain quantity of heat from the surroundings with a heat
pump may be calculated with the formula;
CoP = nr x nc = nr x Tlow / (Thigh – Tlow)
where CoP is the Coefficient of Performance, Tlow is the temperature of the evaporator expressed in
degrees Kelvin (=°C + 273), Thigh is the temperature of the condenser, likewise expressed in degrees
Kelvin, and nr is a factor (the efficiency, always less than 1) which gives the CoP in practice compared
to the theoretical CoP nc.
(Note: the CoP formula used here is a simplification of what happens in practice, but it is nevertheless
an adequate tool to find out what measures can be taken to reduce electricity consumption)
An example for a refrigerator:
Temperature cold side: -5°C i.e. Tlow = 268°K (this is not the average temperature in the refrigerator
but the temperature of the evaporator or cold plate in the refrigerator).
Temperature hot side: 45°C i.e. Thigh = 318°K
Efficiency: 25 %
Then the CoP is:
CoP = 0.25 x 268 / (318 – 268) = 1.34
This means that for every kWh of heat that leaks in through the refrigerator’s insulation, or is drawn
away from food or drink put into the refrigerator while still warm, 1 / 1.34 = 0.75 kWh of electric energy is
needed to “pump” this heat out again.
6.3.3.
The refrigerator and freezer in practice
When running, the average compressor motor of a refrigerator or freezer takes about 50 W, or 4.2 A
from a 12 V battery. The compressor motor is controlled by a thermostat that switches it on when the
temperature increases to a pre-set value, and switches it of again after the temperature has been
brought down to a few degrees below the pre-set value. The on / off ratio is called the duty cycle.
A duty cycle of 100 % results in a daily capacity drain from a battery of 4.2 A x 24 h = 101 Ah. A
nightmare!
A duty cycle of 50% results in 50 Ah daily consumption and a duty cycle of 25 % translates to 25 Ah
daily consumption.
What we want is low energy consumption. How can this be achieved?
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35
1) Improve the CoP, either by decreasing the temperature difference between the evaporator and the
condenser, or by increasing the efficiency of the compressor.
If for example the temperature of the condenser were to be reduced by outside water cooling to 20°C
(this requires a high quality water cooled condenser), instead of the 45°C which is not uncommon when
the evaporator sits in the cupboard under the sink, then we would have:
CoP = 0.25 x 268 / (293 – 268) = 2.68
So, now only 1 / 2.68 = 0.37 kWh is needed per kWh of heat leakage. In other words: 50 % less
electricity needed!
Further improvement would be achievable by increasing the surface of the evaporator in the refrigerator
so that a temperature of a few degrees above 0 cools the fridge to the same temperature as the -5°C in
our example.
And then the efficiency of the compressor and motor could be improved. This is a difficult one, as all
small compressors have similar specifications.
2) Improve insulation
Let us first look at how much energy is needed to cool down food or drinks in a refrigerator.
It is important to know here that the specific heat of water is 1.16 Wh per °C.
The specific heat of other drinks and food is similar. This means that to cool down 1 litre of water or
other drinks, or 1 kg of food, by 1°C, 1.16 Wh of heat has to be removed.
So, if you were to put 5 litres of mineral water, warmed up in the sun to 35°C, into the refrigerator and
allow it to cool to 10°C, then 5 x (35 - 10) x 1.16 = 0.145 kWh of heat must be drawn from the
refrigerator.
At a CoP of 1.34, the amount of electrical energy needed is 0.145 / 1.34 = 0.108 kWh, i.e.
0.108 / 12 = 9 Ah out of a 12 V battery. Not to bad, 9 Ah, even though we have assumed a very low
CoP.
Conclusion:
It is bad insulation and / or a bad CoP, and not cooling down the drinks and food that are the reason for
high power consumption of the refrigerator and freezer on board.
Therefore: insulate!
The benchmark for energy consumption is standard household equipment, which nowadays has
excellent insulation:
The yearly energy consumption of a modern refrigerator is about 100 kWh, which translates to
100 / 365 = 0.27 kWh per day, or 0.27 x 1000 / 24 = 11 W (!) average power consumption. If fitted with
a 12V DC compressor, Ah consumption would be 0.27 x 1000 / 12 = 23 Ah per day from a 12 V battery.
The yearly energy consumption of a modern freezer is about twice as high, and would take 46 Ah per
day from a 12 V battery.
If permanent AC power from an inverter is available anyway (see chapter 8) it is certainly advisable to
install a standard household refrigerator and freezer.
6.3.4.
Air conditioning
Air conditioning requires enormous amounts of electric energy. Especially small airco sets, with 1 kW to
5 kW cooling power (3.400 to 17.000 Btu) in general have a low efficiency. If a generator is running
anyway, no problem, except perhaps for fuel consumption. But as soon as soon as air conditioning also
has to run on battery power, efficiency becomes extremely important.
Just like the refrigerator and freezer, an air conditioner is a heat pump with a compressor-motor, a
condenser (on a boat always water-cooled because of the high power involved) and an evaporator.
What does the CoP formula tell us when applied to air conditioning?
Let us assume:
-condenser temperature: 27 °C (cooling water of 25 °C)
-evaporator temperature: 15 °C (room temperature of 25 °C)
-efficiency: 25 %
Then CoP = 0.25 x 288 / (300 – 288) = 6
Well, in practice the CoP of a small airco system ranges between 2 and 3!
This has mainly to do with a much higher condenser temperature and a much lower evaporator
temperature than we have assumed.
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Assuming a CoP of 2.5, 2 kW of cooling power will require 2 / 2.5 = 0.8 kW of electric power, which
would, in 10 hours time, draw 0.8 x 1000 x 10 / 24 = 333 Ah from a 24 V battery.
6.4. Electric winches, windlass and bow thruster
More and more common, even on smaller boats, these products will draw very high currents, but for a short
period.
An electric winch or windlass on a 15 m boat is in general powered by a 1 horsepower motor (1 HP =
0.736 kW) and will draw at nominal load 736 / 12 = 61 A from a 12 V battery (current draw can increase to
several hundreds Amps if the winch is under a near stalling load!). If operated for 1 minute, the Ah consumption
will be 61 / 60 = 1 Ah (see sect. 6.2). So energy consumption is not the issue, but it is very important to
properly dimension the fuse, contactors, cabling, and batteries to withstand the high currents and eliminate the
risk of fire due to overheating.
A bow thruster will often take even more power, for example 300 A from a 24 V battery if fitted with a
10 HP motor. Current draw will be 10 x 736 / 24 = 300 A. One minute of operation will result in 300 / 60 = 5 Ah
taken from the battery.
6.5. A battery powered washing machine and dishwasher?
A washing cycle at 60 °C with a standard household washing machine takes 0.9 kWh of electric energy, or
900 / 24 = 38 Ah from a 24 V battery. At 40°C this reduces to 0.6 kWh or 600 / 24 = 25 Ah from a 24 V battery.
The energy required for dishwashing is of the same order of magnitude.
Most of the energy goes into heating the water (hence the large difference in energy consumption between a
60 °C cycle and a 40 °C cycle), and using hot fill (supplying the washing machine and dishwasher with water at
the right temperature instead of cold water) would further reduce energy consumption to a few hundred Wh!
A standard household dryer, though, takes 3 kWh, which means 3000 / 24 = 125 Ah from a 24 V battery. This
is because preheated air is used to evaporate all the remaining moisture. And I do not know of any dryer
heating the air with a hot water heat exchanger instead of an electric heater…
A wash-dry cycle of a small washer-dryer as is often used on boats will take approx. 2.7 kWh.
6.6. Ever thought that electric cooking on battery power was feasible?
I didn’t, until I made the calculations and verified in practice.
And since that time I have a two-hob electric induction stove on my trimaran, powered by a 24 V 200 Ah house
battery and a 2.5 kW Multi.
When compared to other electric stove, my preference goes to induction. With electric induction it is not the hob
that is heated, but the bottom of the pan directly. The heating is therefore extremely fast and the hob does not
become hotter than the bottom of the pan, which increases safety.
For that reason electric induction is also 20 % more efficient than other electric stoves (this is not just theory, I
have measured it).
But now the theoretical background, which is very simple:
As stated in section 6.3.3, the heat capacity of water is 1.16 Wh per °C. Bringing 1 litre of water of 20 °C to the
boil would therefore take 1.16 x (100 – 20) = 93 Wh. In practice it takes more than 100 Wh, depending on the
heat capacity of the pan and other losses, which can be reduced by starting with warm water from the boiler
instead. So the figure to remember is 100 Wh per litre.
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And now the actual cooking:
Today the meal is spaghetti with a home made sauce and a pudding to finish. We are cooking for 4 persons.
For the spaghetti we bring 4 litres of water to the boil, add the spaghetti, bring the pan to the boil again and
leave it boiling slowly for 8 minutes. Power consumption: 400 Wh to boil the water, 100 Wh to boil it once more,
and 400 W for 8 minutes to keep the spaghetti boiling, total 400 + 100 + 400 x 8 / 60 = 550 Wh.
For the sauce we fry the onions (150 Wh), add the meat and fry again (150 Wh), add fresh tomatoes, herbs, etc
and bring the sauce to the boil (1 litre, so 100 Wh) and leave the sauce simmering for 20 minutes
(200 W during 20 minutes), total 150 + 150 + 100 + 200 x 20 / 60 = 470 Wh.
For the desert we heat 2 litres of cold milk right from the refrigerator (300 Wh), plus 3 minutes of simmering (30
Wh), total 300 + 30 = 330 Wh.
Total energy needed: 550 + 470 + 330 = 1350 Wh, or 1350 / 24 = 56 Ah from a 24 V battery.
I have also verified the above in practice and the result is that for most meals with 3 hot courses and intended
for 4 persons indeed 1200 to 1400 Wh, or 50 to 60 Ah from a 24 V battery is needed.
6.7. The diving compressor
I like diving. What I do not like is that after the dive I have to lift anchor, head for a harbour and lug my bottles to
a diving club in order to have them refilled. Why not install a diving compressor on board?
A small diving compressor is powered by an electric motor of around 3 kW, and the start-up current is about 10
times the rated current. It will trip the shore power circuit breaker in the harbour, and a diesel generator will
have to be substantially over dimensioned to start it.
The solution is to drive the compressor with a 3-phase motor and ad a variable frequency drive, with a three
phase output to drive the motor and a single phase input to connect to an inverter, diesel generator or shore
power. The 1 to 3-phase frequency drive (readily available up to 3 kW output power from several frequency
drive manufacturers, like ABB, Hitachi or Mitsubishi) will eliminate the start up surge and allow the 3-phase
motor to be supplied by a single phase supply.
Can the house battery + an inverter be used to run the compressor?
The answer is yes. I do it myself all the time.
It takes about 30 minutes to fill a 10 l bottle, which translates to (3 kW / 24 V) x 0.5 = 62 Ah drained from a 24 V
battery.
6.8. How to deal with the inrush current of AC electric motors
Electric motors rated in the kW range have very high inrush currents and an inverter or diesel generator has to
be substantially over dimensioned to run them (examples: pumps, air conditioning, and the diving compressor
discussed in the previous section). As discussed in the previous section, a solution is to use 3-phase motors
and a 1 to 3-phase variable frequency drive.
6.9. Conclusion
The refrigerator, a continuous consumer of electricity, will if not carefully
engineered, drain the battery and consume more energy than high power but
short time consumers like a washing machine, dishwasher or even an
electric stove.
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7. Generators
7.1. AC Generators
7.1.1.
A diesel engine will last longer if it has to work
In order to generate a stable 50 Hz or 60 Hz output, the diesel engine powering the generator must
rotate at a fixed and stable frequency. For 50 Hz output this is 3000 rpm or 1500 rpm, depending on the
number of poles of the generator (3000 rpm / 60 seconds = 50 rotations per second = 50 Hz). When a
diesel engine runs at relatively high rpm and with nearly no load the internal temperature will be low and
service life will be reduced.
It is therefore not recommended to run a genset 24 hrs per day, with nearly no load. And the noise,
fumes and odours are not to look forward to either.
7.1.2.
A hybrid or battery assisted AC system
A first improvement is to run the generator during periods of high power demand only, and install a
battery and inverters to generate AC when the generator is off.
An even better system is obtained by operating one or more Phoenix Multi’s or MultiPlus units in parallel
with the genset (see for example par. 10.6).
The advantages are:
- uninterrupted AC supply
- relatively more load on the generator, less space needed, less noise and less weight because a
smaller genset can be used: the MultiPlus will absorb peak loads taking energy from the battery, and
recharge whenever “surplus” power is available (see for ex. par. 10.6.5. or “Achieving the impossible”
and many other examples on our website).
7.1.3.
Don’t forget the problem of limited shore power
A washing machine, dishwasher, electric cooker, air-conditioning: it is all feasible with a big enough
generator. But in Europe power from the shore side is often limited to 16 A or even less
(16 A x 230 V = 3,68 kW). Here also the MultiPlus can help to increase available power to the required
level.
7.1.4.
3000 rpm or 1500 rpm (in a 60 Hz environment: 3600 rpm or 1800 rpm)
A, more expensive, 1500 rpm genset is the right choice if intensive use is to be expected.
A 3000 rpm genset is in general designed for a limited number of operating hours, and is not made to
operate at full load for long periods of time.
Some generator suppliers are wildly optimistic about the maximum output of their product. A way to find
out is to look for gensets from different suppliers but with the same engine and then compare the rated
output.
7.2. DC Generators
Next to conventional 50/60 Hz AC generators, some generator suppliers are also offering DC generators.
Outputs of up to 10 kW, which means a battery charging current of up to some 300 A at 28 V, are attainable.
DC generators are smaller and lighter, and have a higher efficiency than AC generators. Moreover, engine rpm
can be harmonised with power demand, so that efficiency remains high even under partial load.
The idea is to use the DC generator to charge the batteries, and use inverters to supply the AC load. Sizing of
the DC generator is a question of acceptable running hours per day.
Please keep in mind however that the battery should be sized for the huge charge current. For a charge current
of 300 A for example, battery capacity should be 300 A / 5 = 1500 Ah (see par. 2.5.6.)
It should be noted here that some manufacturers of AGM batteries claim much higher charge currents without
appreciable reduction of service life.
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8. Micro power generation: thinking different
8.1. Introduction
For the purpose of this book micro power generation is defined as power generation for systems
requiring, on average, between a few hundred Watts and up to 10 kW of electric power. Over a period of
24 hours this equates to in between 24 x 0.2 = 4.8 kWh and 24 x 10 = 240 kWh of electric energy per
day.
As will be shown, 240 kWh is the upper range of the amount of electric energy needed by a few families
to live comfortably, be it in a small community of one or a number of houses, in a mobile home or on
board a boat.
It is within this range that several recent technical developments make it worthwhile to “rethink” power
generation.
A very important characteristic of the application considered here is that the amount of electric power
required will at times be nearly zero and at other moments increase to several times the average.
When a petrol or diesel fuel powered AC generator is used to supply the required electricity, it has to be
sized for the highest power demand that is to be expected, and therefore will run at practically no load
during most of the time. Very inefficient in terms of wear and fuel consumption, not to speak about
noise, maintenance and pollution.
A problem more specific to boats (and motor homes) is shore power. The rating of the shore power
outlet is often insufficient to supply a washing machine, an electric stove or air conditioning. And when
crossing the Atlantic voltage is different and frequency is 60 Hz instead of 50 Hz, or the other way
round.
Of increasing importance on boats is also weight and volume.
In the following sections new technologies and concepts to improve the performance of micro power
generation are presented and discussed.
8.2. New technology makes the DC concept more attractive
8.2.1.
The DC concept
In the DC concept the battery is the hart of the system.
All power generated or taken from a shore power outlet is converted to DC or generated as DC. The
sources of electric power are connected to a DC bus, to which the battery is also connected.
Likewise, all consumers are either DC or are supplied from the DC bus by an inverter.
In the DC concept the battery is a buffer of electric energy that compensates for any imbalance between
energy suppliers and energy consumers.
In fact all smaller boats do use the DC concept:
Power is generated by one or more alternators on the main engine, and often also by alternate sources
like solar or wind power, or a water generator. All sources of electric power are connected to a DC bus,
to which the house battery is also connected. All consumers, such as navigation equipment, cabin
lighting, etc. are supplied from the DC bus.
As electronic power conversion technology improves, more and more household appliances, which do
require an AC supply, are also being connected to the DC bus, with an inverter.
In the next sections 2 new developments that substantially increase the attractiveness of the DC
concept are presented.
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8.2.2.
DC generators
Next to conventional 50/60 Hz AC generators, some generator suppliers are offering DC generators.
DC generators are smaller and lighter, and have a higher efficiency than AC generators. Moreover,
engine rpm can be harmonised with current demand, so that fuel efficiency remains high even under
partial load.
8.2.3.
Unlimited inverter power
Sinusoidal inverters have now become generally accepted.
New is the possibility to connect inverters in parallel.
Victron Energy has developed inverters and inverter-chargers (bi-directional converters) that can be
parallel connected in either single or three-phase configuration.
The parallelable inverter/ charger modules are the Multi 12/2500/120 and Multi 24/3000/70, which have
a continuous output power of 2 kW at 12 V input and 2.5 kW at 24 V input respectively.
Up to 6 modules can be connected in parallel per phase. Taking as an example the 24 V model, the
output power which can be reached is as follows:
Single phase
6 x Multi i 24/3000
Continuous output
6 x 2.5 = 15 kW
P30
18kW
Maximum output
30 kW
Three phase
18 x Multi 24/3000
Continuous output
18 x 2.5 = 45 kW
P30
54 kW
Maximum output
90 kW
Where previously installation of an AC generator was a must, parallel inverters are now an
alternative.
8.3. The AC concept can be improved with PowerControl
8.3.1.
The AC concept
In the AC concept one or more petrol or diesel fuel-powered generators are the hart of the system.
Whenever AC power is needed a generator is started. The generator has to be rated to meet the
highest power demand that is expected.
In general the generator, together with a battery charger, is also used to charge one or more small
service batteries for navigation equipment, lighting, DC pumps, etc.
Likewise, shore power has to be rated to meet the highest power demand that is expected. Shore
power must also match the frequency and voltage of the on-board AC equipment. If not, a frequency
converter (also called shore converter) is needed.
The AC concept is the preferred solution when a lot of power is required.
8.3.2.
The AC concept with generator free period
As power demand decreases, the drawbacks of the AC concept become more and more prominent.
The generator will operate without any load at all for long periods of time, or will have to be started and
stopped frequently, often operating with hardly any load. This of course means noise, pollution, fuel
consumption, wear and maintenance while at same time, on average, electric power consumption is
low.
A way to improve on this situation is the generator free period, which requires in addition to the
generator a big battery, battery chargers and inverters. When the generator is off, all consumers are
supplied with energy stored in the battery. Periodically, in general when a lot of AC power is required
anyway, the generator is started and then also used to recharge the battery.
Although much better than the “generator only” concept, there still is a lot of room for further
improvement. This is the subject of the next sections.
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8.3.3.
PowerControl
The AC concept with generator free period is at its best when the generator runs for as short a time as
possible. This means that a substantial amount of power will be needed to quickly recharge the battery.
The generator then needs to be rated for the maximum AC load to be expected plus the power needed
for the battery chargers.
A more effective solution is PowerControl.
With PowerControl the output current of the generator is continuously monitored and the power taken
to recharge the battery is automatically adjusted so that the total load of the generator remains within a
pre-set limit.
This is a feature that comes with the remote control panel of the Phoenix Combi and and its successor:
the Phoenix Multi.
An example:
A boat is equipped with a generator and a Phoenix Multi 24/3000/70.
The generator is used to run a small washing machine that takes 2 kW when the water heater is on and
150 W when only the motor driving the tumbler is running. Average load: 500 W.
The battery to be recharged is 24 V 400 Ah. The maximum charge current from the Multi is 70 A.
Maximum AC load to be expected: 2 kW for the washing machine plus 2.1 kW to recharge the battery
(70 A x 30 V = 2.1 kW).
Generator rating needed: 2 + 2.1 = 4.1 kW minimum, if one wants to run the washing machine and
charge the battery simultaneously. In practice, in order to avoid running the generator at full load (and
risking overload conditions), a 5 kW model should be chosen.
Alternatively, battery charging could be stopped when running the washing machine. This would
increase the running time of the generator and result in an average load of only 500 W during the
washing period. Generator needed: minimum 2 kW, in practice 3 kW.
With the PowerControl feature on the Multi one could still use a 3 kW generator and simultaneously
run the washing machine and charge the battery. With help of the Multi remote panel, the current limit of
the generator would be set at, for example, 10.5 A which would limit the output power of the generator
to a safe 10.5 A x 230 V = 2.4 kW, which is 80 % of the rated 3 kW. After starting the generator, the
Multi would automatically switch from inverter mode to charger mode and start charging the battery with
70 A.
When switching on the washing machine, the Multi will continue to charge at 70 A when only the motor
of the washing machine is running (80 % of the time). The load of the generator would then be
150 W + 2.1 kW = 2.25 kW, less than the pre-set limit of 2.4 kW.
As soon as the heater switches on (20 % of the time) the washing machine takes 2 kW, so that only
2.4 kW - 2 kW = 400 W is left for charging the battery. With PowerControl the Multi will then
automatically reduce charge current to approx. 400 W / 30 V = 13 A.
The example shows that with PowerControl the generator is used much more effectively. For 80 % of
the time that the washing machine was on, the battery has also been charged with the maximum
available charge current.
Without PowerControl the battery charger would have been switched off during the entire washing
period.
Similarly, with PowerContol charging would be reduced, but not stopped, while using the microwave, a
hot water kettle, an AC motor powered water maker, etc.
The example above is also applicable to shore power. The current limit should then be set at the rating
of the circuit breaker protecting the shore power outlet. Of course this rating should be sufficient to
supply the most power hungry piece of equipment on board. In our example this would be the washing
machine, so in Europe the minimum shore power rating should be 2 kW / 230 V = 9 A.
Often the rating is lower, for example 6 A or even 4 A, not enough to run the washing machine. This
brings us to PowerAssist, the subject of the next section.
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8.4. New: the hybrid or battery assisted AC concept, or “achieving the
impossible” with PowerAssist
8.4.1.
PowerAssist
The next level in generator and shore power support is to actually help the generator or shore supply
when otherwise an overload would occur.
This is what the Phoenix MultiPlus does with PowerAssist.
Continuing our example of section 8.3.3., one may want to run a 2 kW air conditioning compressor and
at the same time do the washing, bringing the peak power to 4 kW. Or to heat water in a hot water kettle
(2 kW), or simply make coffee (1 kW), or use an electric stove (6 kW) instead of gas.
With the MultiPlus this is all feasible. When the AC power required increases beyond a pre-set limit, the
Multi will stop charging the battery and operate as an inverter in parallel with the generator or shore
power. In our example the generator would be boosted from 3 kW to 3 + 2.5 = 7.5 kW. As will be shown
in the next chapters, the saving in weight and fuel consumption of the electric power supply system can
be substantial.
The MultiPlus solves the problem of insufficient shore or generator power by adding additional
power taken from the battery.
8.4.2.
Other advantages when operating Multi’s together with a generator
In the previous sections we explained the advantages of PowerControl and PowerAssist: the
possibility to use a smaller generator, or to reduce generator running hours, to increase the AC load, or
to boost shore power.
Other advantages are:
Uninterrupted AC power
AC power will always be available, either from the Multi’s, or from the generator or shore power.
A digital clock or the settings of a video recorder will not be reset every time that the generator is
stopped.
Immediate availability of AC power
When installing sufficient Multi power any AC appliance on board can be switched on without the need
to start the generator first.
Redundancy
When several Multi’s are operating in parallel, a faulty unit (although unlikely that this would happen)
can be isolated from the healthy ones. There is a second AC redundancy because of the presence of
the Multi’s and a generator. And finally there are at least 2 sources of DC power to recharge the battery:
one or more Multi’s and the alternator on the main engine.
8.4.3.
Shore power
We have seen that one way to cope with insufficient shore power is the MultiPlus: with PowerAssist
shore power can be boosted to up to 4 times its nominal rating.
An alternative is to use the DC concept for shore power. In other words: use a battery charger to
convert shore power to DC and convert DC back to AC with the inverters or Multi’s which are on board
anyway. The house battery will supply additional energy when a lot of power is required on board, and
will be recharged by the battery charger during periods of low power demand.
For more details, see sect. 8.5.3.
© Victron Energy
43
8.5. Thinking different
8.5.1.
Daily energy needed
Both for the DC concept and the battery assisted AC concept the first question to ask is not “what is the
maximum AC power to be expected?” and then size inverters and the generator to that power.
Instead the first question should be “what is the daily electric energy need?”
It is the daily energy need that determines the rating of the source of electric power.
The daily run-time needed to produce the required energy is calculated with the following formula:
run-time (hours) = daily energy need (kWh) / output of the source(s) of electric power (kW)
Alternatively, if the requirement is to limit generator run-time to a certain amount of hours, the formula
is:
output of the source(s) of electric power = daily energy need / run-time
Some examples:
8.5.1.1 Daily energy needed: 4 kWh (see chapter 9)
Source: alternator on the main engine supplying 100 A into a 12 V system, i. e.
100 A x 12 V = 1.2 kW
Daily run-time needed: 4 kWh / 1.2 kW = 3.3 h
(In practice the run-time will be somewhat longer due to losses in the system and possibly a
reduced current absorption capacity of the battery at the end of the charge cycle, but for a first
approximation the calculation is ok)
8.5.1.2 Daily energy needed: 14 kWh (see chapter 10)
Source: diesel generator, but should not run more than 4 hours per day
Minimum rating of the generator: 14 kWh / 4 h = 3.5 kW
8.5.2.
Battery capacity
When power generation is limited to a few hours per day (alternator on the main engine or generator
with generator free period), the size of the battery is determined by the amount of energy that the
battery has to supply during the periods that the main engine or generator are off: the generator free
period.
In practice, due to the short recharge periods, the battery will be recharged to not more than 80 %
(20 % DoD). The battery also should not be discharged to more than 70 % (70 % DoD). This would
mean a usable battery capacity of at most 70 % - 20 % = 50 %. We should include a safety margin:
when a battery has been discharged to 70 % there is no margin left if anything unexpected happens.
There is no general rule for the amount of margin, but let’s take 10 %. This leaves us with 40 % usable
capacity and a DoD of 60 %. Then we have to build-in a factor of 0.8 to account for 20 % capacity loss
when the battery gets older: 40 % x 0.8 = 32 %.
And finally, if we discharge a battery faster, or slower, than rated (the rated discharge time is in general
20 hours, see sect. 2.5.3) another correction factor will have to be applied. In most cases the time
between recharges of the house battery is 8 to 12 h, and 32 % discharge in 8 hours is equivalent to
32 x 24 / 8 = 96 % discharge in 20 h. Very close to the rated discharge time, so no additional correction
needed for batteries rated at 20 h, and a positive correction for tubular plate traction batteries, for
Exide / Sonnenschein A600 cells (see sect.2.5.3.).
(I imagine a breath of relief here: the usable capacity would have gone to nearly zero if even more
corrections had to be applied)
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Conclusion:
Calculating battery capacity is quite complicated. The purpose of this book is to look at the big picture,
so we need a rule of thumb.
Practice:
The rule of thumb from practice is that in case of 2 recharges per day, battery capacity should at least
be twice the daily Ah consumption.
If for example daily consumption is 128 Ah (see sect. 9.3), battery capacity should be 256 Ah. Assuming
a constant discharge rate over 24 hours, our 256 Ah battery would be subjected to a discharge of
128 / 2 = 64 Ah over a period of 12 hours.
Theory:
The rule of thumb derived from theory is that the usable battery capacity is 32 % of the nominal
capacity. Assuming a maximum period of 12 h between recharges and a consumption of
128 / 2 = 64 Ah during that period, 32 % usable capacity would in this example mean that we need a
battery of 64 Ah / 0.32 = 200 Ah.
The positive difference between practice and theory of 265 - 200 = 65 Ah can be seen as compensation
for the fact that the discharge rate is not constant but will depend on which consumers are switched on,
and when. Recharge periods may also vary in length.
In other words: theory leads to the same result as the rule of thumb.
We now have two simple methods to estimate the capacity needed for the house battery:
1) The capacity of the house battery should be at least three times the expected discharge
during the generator free period. (100 % / 32 % = 3.1)
2) If the house battery is recharged two times per day, its capacity should be at least twice the
daily Ah consumption.
Two examples:
Maximum amount of energy that will be taken from the battery during the generator free period: 4 kWh
Minimum capacity of the battery (12 V system): 4 kWh x 3 / 12 V = 1000 Ah
Minimum capacity of the battery (24 V system): 4 kWh x 3 / 24 V = 500 Ah
Daily amount of energy that will be taken from the battery: 4 kWh, i. e. 4000 / 12 = 333 Ah for a 12 V
system
Recharges per day: 2
Minimum size of the battery (12 V system): 333 x 2 = 666 Ah
8.5.3.
Shore power
When the generator on board has been sized to supply the maximum expected power need, quite
naturally, the shore power connection will also have to be rated to supply the maximum expected power
consumption on board.
Let’s assume that the microwave oven, rated at 1500 W, is the most power hungry appliance. At
1500 W, the microwave will take 1500 / 230 = 6.5 A from a 230 V shore outlet. This is already more
than the usual 4 A or 6 A shore outlet rating. If at the same time the electric water heater switches on
(4 to 5 A) and your coffee machine (4 A) is just starting to spread the lovely smell of freshly made
coffee, your power draw increases to 6.5 + 4 + 5 = 15.5 A. In other words: you are not far from tripping
even a 16 A shore outlet!
Not to mention a washing machine (9 to13 A), a dishwasher (also 9 to 13 A) or an electric stove (16 to
35 A).
The result is that the generator has to be started even when moored in the marina. Not the way to
make friends on the neighbouring boats.
The solution is to think differently and to implement the DC or the hybrid concept for shore
power. Once more the question then is not “what is the maximum AC power to be expected?” but
instead “what is the daily electric energy need?”
The microwave for example takes 6.5 A, but only for 5 minutes, at most. If this current could be
averaged over 50 minutes, then the 6.5 A would reduce to one tenth (0.65 A) but during a ten times
longer period: 50 minutes instead of 5 minutes.
This is exactly what the DC or the hybrid concept do: using the house battery to average peaks
in power consumption (“peakshving”).
© Victron Energy
45
The example described in chapter 9, where indeed a microwave oven is the most power hungry
appliance, will show that the daily energy consumption when moored is 1.6 kWh, which translates to an
average power of 1600 / 24 = 66 W, or 5.6 A taken from a 12 V house battery. And 66 W is a current of
only 66 / 230 = 0.3 A from the shore power outlet!
In practice, due to losses and some reserve to charge the battery, shore current will be 2 to 4 times
higher, but even 1 A still is next to nothing.
The example from chapter 10 shows that with more electric equipment on board, shore power can be
reduced from 8 kW (3 phase 16 A shore outlet needed) to a mere 1.3 kW (6 A 230 V shore outlet).
What the examples show is that the DC or hybrid concept reduces the shore power rating needed by a
factor of 4 to 10, making it much easier to find a suitable berth in today’s overcrowded marina’s.
But reduction of shore power rating is not the only advantage of the DC and the hybrid concept,
here is the complete list:
Up to ten times less shore power needed
As will be shown in more detail in the next chapters, implementing the DC or hybrid concept really
results in a breathtaking reduction of the required shore outlet rating.
The average power demand is in general less than one ¼ or even, depending on the power
1
consumption profile on board, less than /10 of the peak power demand. Therefore the battery charger
needed to connect to shore power will also be quite small and represents a small investment compared
to the total cost of the electric infrastructure on board.
And a low power shore socket to connect to will be much easier to find in an overcrowded marina than a
16 A or a 3 phase socket!
Built-in clean, stable and no-break AC power
Whatever goes wrong with shore power, the battery + inverters or Multi’s are there to guarantee
uninterrupted power.
DC concept only: built-in frequency and voltage conversion
Battery chargers will operate on a 50 Hz and on a 60 Hz supply. With an autotransformer or a wide
input range (90 V to 260 V AC) battery charger one can connect to shore power anywhere in the
world, without the need for an expensive and cumbersome shore power converter.
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9. Up to 4 kWh required per day (170 Watt average)
9.1. Introduction
It is now time to go on board and see how things work out in practice.
Of course all boats are different, depending on purpose, budget and ownership. Some boats are equipped to
cross the Atlantic or to sail around the world. Others are intended to travel along rivers and canals. And still
others go out fishing for a day. Some boats are sailed and maintained by the owner, others are part of a
charter fleet. Then similar electric installations can be found in mobile homes for example, or off-grid houses.
I have chosen here to take sea-going yachts as the example, because that is what I know about first hand. It is
not very difficult to adapt the reasoning given in this and the following chapters to other applications.
The first boat we will board is fairly simple in terms of electric installation, and electric power consumption has
been kept as low as possible. It would typically be a motorboat of up to 9 metres or a sailing boat of up to 12
metres.
The boat has a 12 V electrical system and, to start with, we list all electric equipment and current consumption.
9.2. Equipment and current consumption
9.2.1.
Navigation instruments (wind set, log, depth sounder, etc): less than 0.2 A
9.2.2.
GPS: about 0.2 A
9.2.3.
VHF
Standby consumption is low (approx. 0.1 A). Transmitting does take a good deal of current (approx. 5
A) yet is brief, so that consumption in Ah remains quite low.
9.2.4.
Tricolour navigation light or anchor light: 25 W
(25 W / 12 V = 2.1 A)
9.2.5.
Autopilot
The autopilot can be one of the biggest consumers if used for long periods of time. The motor’s current
consumption is easily 5 A. When running with a duty cycle of 30 % the average consumption would be
5 x 0.30 = 1.5 A.
Please bear in mind that this is a very rough approximation. Power consumption of the autopilot will in
practice depend on the boat, trimming, the seas, etc.
9.2.6.
Radio
Particularly on longer cruises, the (car) radio is often turned on. Its current consumption is about 1 A.
9.2.7.
Cabin lighting
These days lighting consists of halogen lamps (10 W to 20 W) and fluorescent tubes (approx. 8 W).
Incandescent bulbs are not recommended because they take up to 5 times more current for the same
amount of light produced. Assuming 10 lighting points and thrifty use, consumption would be limited to
approx. 10 Ah per 24-hour period.
9.2.8.
Refrigerator
Refrigeration has been discussed in sect. 6.2.
In this example we will assume that we have a refrigerator on board with a 50 W compressor running
with a 50 % duty cycle. In my experience this is an average refrigerator in terms of energy consumption,
when cruising in a temperate climate.
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47
9.3. Consumption over a 24-hour period when sailing
Our starting point is one 24-hour period under sail (when travelling under power the current consumption is not
of importance, because the alternator on the main engine can easily keep up with consumption).
We will now determine the battery capacity needed for supplying all consumers during one 24-hour period.
In the table that follows the consumers have been divided into continuous (C), long duration (L), and short
duration (S) consumers.
Consumers
Consumption
Watt
C
C
C
S
C
L
L
L
S
S
Navigation instruments
GPS
VHF standby
transmitting
Refrigerator, air-cooled heat exchanger
Tricolour navigation light or anchor light
Autopilot
Radio
Cabin lighting
Other
Total consumption per 24-hour period
Average consumption per 24-hour period
50
25
Amp
0.2
0.2
0.1
5
4.2
2.1
5
1
200
Time / 24- %
Consumption / 24hours
on
hour period
Hours
% kWh Ah (12 V)
24
5
24
5
24
2
0.2
1
24
50
50
8
17
20
30
30
3
3
0.6
10
5
1.5
64
128
5.3
Minimum battery capacity required, assuming 2 recharges per day (see sect. 8.4.2)
256
It is noticeable that the refrigerator is by far and away the biggest consumer. The refrigerator’s current consumption could
be halved by using a more expensive water-cooled heat exchanger instead of an air-cooled heat exchanger and by
improving insulation. The total consumption per 24-hour period would then reduce to 103 Ah. Using a gas refrigerator
(only useable on motorboats in calm waters) would even reduce current consumption to 78 Ah.
9.4. At anchor or moored without 230V shore power pick-up
Once again, our starting point is one 24-hour period, but this time the following applies for motorboats and
sailing boats.
Consumers
C
L
L
S
S
Refrigerator, air-cooled heat exchanger
Masthead light
Radio
Cabin lighting, ten 20 W lighting points
Other
Total consumption per 24-hour period
Average consumption per 24-hour period
Consumption
Watt
50
25
Amp
4.2
1
200
Time / 24hours
Hours
24
8
3
0.6
% Consumption / 24on hour period
% kWh Ah (12 V)
50
50
0.2
17
3
10
5
1.0
42
85
3.5
Minimum battery capacity required, assuming 2 recharges per day (see sect. 8.4.2)
170
9.5. The extra’s
Even the relatively small boats that we are considering here often have (or the crew might wish to have!) some
extra safety and comfort on board. A few optional extras are suggested below. For some an inverter is needed.
Because today inverter efficiencies are higher than 90%, the losses in the inverter are ignored in the energy
consumption calculations.
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9.5.1.
Electronic navigation system
Quite common today even on smaller yachts.
9.5.2.
SSB
Very useful on ocean trips.
9.5.3.
Radar
Increases safety when sailing at night or in bad weather.
9.5.4.
Microwave oven
A microwave oven uses a great deal of energy (up to 1.5 kW) for a brief time. When the microwave is
used for 12 minutes per day the consumption in Ah out of a 12 V battery is 1500 x 0.2 / 12 = 25 Ah.
9.5.5.
Space heating
One should always opt for a diesel burner so that current consumption stays confined to diesel pump
and fans. The current consumption is then kept down to approx. 5 A.
9.5.6.
Air conditioning
Especially when operating on battery power, it is important to carefully look at the expected energy
consumption.
9.5.7.
Water maker
Some very efficient water makers are now available that work on 12 V DC. Current consumption is only
10 to 20 A for 30 to 60 litres of fresh water per hour. This has made a water maker (and thus also a
freshwater deck shower!) a realistic extra for small boats used for blue water cruising.
The following table sums up the additional luxury that could be found on smaller boats. Power
consumption has been based on a crew of 2 or 3.
Consumers
Consumption
Watt
C
C
L
S
L
L
L
Electronic navigation system
SSB
Radar
Microwave oven
Heater
Air-conditioning, cooling capacity 2 kW
Water maker, 150 litres per day
Consumption per 24-hour period
Average consumption per 24-hour period
Time / 24hours
Amp
2
12
3
1500
5
700
10
Hours
24
0.1
8
0.2
6 x 0.5 = 3
6 x 0.5 = 3
5
Consumption / 24hour period
kWh Ah (12 V)
48
7
24
0.3
25
15
1
(90)
50
2.0
85
169
7
With all the additional equipment on board (except for the airco), the total energy need per day amounts to:
when sailing: 1.5 + 2.0 = 3.5 kWh, or 128 + 169 = 297 Ah
at anchor : 1.0 + 2.0 = 3.0 kWh, or 85 + 169 = 254 Ah
Which translates to the following minimum battery capacity and average discharge current:
when sailing: 297 x 2 = approx. 600 Ah and 12.3 A discharge current
at anchor : 254 x 2 = approx. 500 Ah and 10.5 A discharge current
We are now going to see how to produce the required energy, for the “basic” yacht (1.0 to.1.5 kWh needed), and
for the “full featured” yacht (3.0 to 3.5 kWh needed).
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49
9.6. How to recharge the battery
9.6.1.
Generate current with the main engine.
The main engine usually has a 14 V / 60 A alternator fitted. This means that the alternator will deliver
60 A at 6000 rpm. Suppose that the diameter ratio between the engine pulley and the alternator pulley
is 2:1, then the main engine would have to run at 3000 rpm to attain 60 A charging current. In practice
nobody does this, because it makes too much noise. For generating current the engine generally runs
between 1500 and 2000 rpm. The charging current will then be 40 % to 80 % of the rated value, i.e. 30
to 50 A.
This means that to charge the house battery, 2 to 3 engine hours are needed per day for the “basic”
yacht and 7 to 8 engine hours per day for the full-featured yacht.
Not an attractive proposition, unless:
-you are intending to travel under power a good distance every day
-the boat is mainly used for day trips
If the intention is to live on board for days or weeks without shore power available, running the engine
for several hours per day only for recharging the battery (i. e. at nearly no load) is bad for the engine,
and very unpleasant for the crew and eventual neighbours.
How can this be done better?
9.6.2.
Increase battery capacity so that you can sail or lie at anchor for several days.
This is a simple and inexpensive solution that only makes sense, however, if you always expect to be
travelling for longer periods under power within a few days, or will have shore power available.
9.6.3.
A second or bigger alternator
Please refer to chapter 4 and 5 for precautions to take.
Increasing the charge current to 80 A would result in an acceptable 1 to 2 daily engine hours for the
basic yacht. But bear in mind that there is a limit to the charge current that a battery will accept without
damage, see section 2.5.6.
Automotive batteries, Optima, and the Sonnenschein Dryfit A200 or Sportline VLRA battery can be
charged at a C / 3 rate up to 80 % capacity, with an absorption voltage limit of 2.4 V / cell (in particular
a VLRA battery must be temperature compensated due to heat generation at this high charge
rate!). Charging at 80 A and C / 3 requires a battery capacity of 80 x 3 = 240 Ah which is less than the
258 Ah required for the basic sailing yacht. As discussed earlier, more capacity will increase service life.
Some other batteries should be charged at C / 5 or less so that at least 80 x 5 = 400 Ah is required.
To limit engine run time to 2 hours (2 sessions of 1 hour) on the full featured yacht would require 150 A
alternator output and a battery of 297 Ah x 2 = 594 Ah (still only 3 batteries of 230 Ah each), or, if the
maximum charge rate is C / 5, a 150 A x 5 = 750 Ah battery.
Please also note that alternators have a low efficiency (about 50 %), that means the power taken from
the engine would be 150 x 15 / 0.5 = 4.5 kW
Two remarks about efficiency here:
1) In order to account for losses in the battery (energy efficiency in partial state-of-charge operation:
approximately 89 %, see sect. 3.3.), in cabling, in diode isolators or battery chargers and, for some
consumers, an inverter, a recharge voltage of 15 V respectively 30 V will be assumed in all calculations
regarding battery charging. In other words: an efficiency of η = 12 / 15 = 80 % is assumed.
-discharging a battery with 150 Ah at 12 V means an energy consumption of 150 Ah x 12 V = 1.8 kWh
-recharging 150 Ah at “15 V” means an energy supply of 150 Ah x 15 v = 2.25 kWh
-the difference, 2.25 – 1.8 = 0.45 kWh, is lost in the process.
2) An energy consumption of 4 kWh, the subject of this chapter, and for nearly the full 100 % via the
battery, requires 4 kWh / 0.8 = 5 kWh to be supplied by the alternator. With 50 % alternator + belt
efficiency, the main engine will have to supply 5 kW / 0.5 = 10 kWh. And then the engine runs with a
load of only 10 to 20 %, meaning a fuel efficiency of something like 10%…
Efficiency of the complete chain: η = 0.8 x 0.5 x 0.1 = 0.04 (= 4 %).
9.6.4.
Solar cells
In the summer in the Netherlands, for example, solar cells, mounted horizontally, deliver approx.
2
2
2
300 Wh per day and per m (1 m = 2 off 50 W panels). This boils down to 25 Ah per day and per m in
a 12 V battery. In the Mediterranean area this rises to approx. 35 Ah, and in the Caribbean to 50 Ah.
Solar cells can therefore make a considerable contribution, especially on multihulls and motorboats that
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often have a lot of deck or roof space available.
9.6.5.
Wind generator
A wind generator with a rotor diameter of 1 metre delivers approx. 25 W (2 A in a 12 V battery) at a wind
speed of 10 knots. A contribution of 40 to 80 Ah per 24-hour period can be expected.
Where current consumption on board is low, solar cells and a wind generator can make a considerable
contribution and drastically reduce engine running hours needed to generate power.
Even on somewhat bigger yachts, solar cells and / or a wind generator are very suitable for charging the
batteries and keeping them 100 % charged during periods that the boat is not used. However, good
charge regulators are very important to prevent overcharging.
9.6.6.
Water generator (shaft or towed)
Under sail, extra current can be generated with a propeller shaft generator (disadvantage: significant
drag, noise, and wear and tear), or with a small stand alone water generator, transom-hung or towed.
The latter will generate about 12 W, or 1 A per knot of speed through the water, i.e. 40 to 100 Ah in a
12 V battery per 24-hour period, and adequately covers the increase in current consumption while
under sail compared to lying at anchor.
The additional drag of about 30 kg will, however, reduce speed by about 0.5 knot.
9.6.7.
Shore power
The best way to connect to shore power is with a battery charger, in other words, to also use the DC
concept (see sect. 8.2.1 and 8.5.3). As will be shown below, the rule of thumb here is that the battery
charger should be able to supply at least twice the daily energy need, and 3 to 4 times the daily energy
need if a discharged house battery must be recharged within a day.
For the full-featured yacht for example, the daily energy need when moored, (which means no power
needed for the masthead light, navigation, SSB, radar and water maker) is 132 Ah or 1.6 kWh.
At twice the daily energy need the battery charger should supply 1.6 kWh x 2 / 24 h = 133 W,
which at 12 V amounts to 133 / 12 = 11 A.
The average DC current consumption is 11 / 2 = 5.5 A, which leaves us with 5.5 A to recharge the
battery. The minimum battery capacity was 500 Ah, so a recharge from 50 % DoD to 80-90 % DoD (to
be followed by a substantial absorption period) would take approx. (500 / 2) / 5.5 = 46 h.
At 4 times the daily energy need the battery charger should supply 22 A, which leaves 16.5 A
to recharge the battery. A recharge to 80-90 % would then take 15 h.
In practice one would install either a 25 A or a 50 A battery charger. The 50 A charger would take a
maximum current of 50 A x 15 V / 230 V = 3.3 A from the shore outlet. So even a 4 A outlet will do.
Alternatively, if AC power is required when sailing, a 1200 VA Phoenix Multi or MultiPlus could be
installed: it has sufficient power for the microwave oven and doubles as a 50 A battery charger.
9.7. Conclusion
One or more sources of alternative energy such as solar cells, a wind generator, or a water generator
can contribute a very substantial 1 to 2.5 kWh (100 to 200 Ah in a 12 V battery) to the daily energy required.
The practical limit to daily recharging a 12 V battery with alternators on the main engine is about 4 kWh,
or 300 Ah at 14 V. This is however sufficient for all the extra luxury as listed in sect. 9.5!
At 24 V, and again with 150 A alternator output (a load of 8.4 kW on the main engine!) one could move up to
8 kW daily energy consumption.
An inefficient refrigerator (50 W compressor running at 100 % duty cycle) will consume up to 100 Ah per
day of your precious battery capacity.
Implementing the DC or the hybrid concept also to connect to shore power will limit the required rating
of the shore outlet to 4 A.
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10. Up to 14 kWh required per day (600 W average)
10.1. Introduction
In chapter 9 we saw that up to 4 kWh of electric energy required per day, a relatively simple DC system is
perfectly adequate.
Next to the basic consumers, for which about 1.5 kWh was required, 2.5 kWh was available daily to operate
additional equipment, increasing safety and / or comfort on board.
The required battery capacity did range from 250 Ah / 12 V for the “basic” yacht to 600 Ah / 12 V, for a “full
featured” yacht.
Even above 4 kWh per day, a system with powerful alternators on the main engine is feasible (and the main
engine will be more reliable than a small 3000-rpm genset). For reasons of noise, redundancy, and efficiency it
is, however, certainly worthwhile to explore alternatives.
The available alternatives are:
An AC diesel genset to directly supply AC consumers: the AC concept.
A (smaller) battery assisted AC genset: the battery assisted AC concept.
A DC genset: extension of the DC concept of the previous chapter to higher power ratings.
A daily energy consumption of 14 kWh is quite substantial and could very well be the average consumption in
your land based home. Check your electricity bill!
In terms of boats, we are looking at motorboats and catamaran sailing yachts of up to 15 metres (49 ft) or
monohull sailing boats of up to 18 metres (59 ft).
The calculations that follow are based on a 24 V house battery. To convert to 12 V, simply double current and
Ah required.
To start with, the list of standard electric equipment:
10.2. Equipment: the minimum
10.2.1. Navigation equipment
A navigation computer is almost standard on bigger boats. Including GPS, VHF, SSB, radar, Inmarsat,
average current consumption rises to between 2 A and 5 A at 24 V.
10.2.2. Navigation light and anchor light: 25 W
10.2.3. Autopilot
Power consumption depends on model, the seas, trimming, etc.
Average: between 5 A and 10 A when on, with 30 % duty cycle.
10.2.4. Refrigerator and freezer
We assume an installation with two 50 W compressors and water-cooled heat exchangers.
Furthermore, we assume that in order to keep consumption low, specific attention has been paid to
insulation. This can limit the duty cycle of the refrigerator compressor to 25 % and of the freezer
compressor to 50 %.
10.2.5. Cabin lighting
More light fittings and less thrifty usage than on smaller boats.
Average: 20 Ah per 24-hour period.
10.2.6. Radio
More power and more loudspeakers than on smaller boats: approximately 2 A
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10.2.7. Other consumers
We are assuming more use of pumps (e.g. for the shower) and we are working on 10 Ah at 24 V.
10.3. Sailing
As has been done in chapter 9, we will know calculate the power consumption over a 24 hour period, when
sailing.
Consumers
Consumption
Watt
C
L
L
C
S
S
S
Navigation equipment
Navigation light
Autopilot
Refrigerator & freezer, water cooled
Radio
Cabin lighting
Other
Total consumption per 24-h period
Average consumption per 24-h period
25
Amp
2
1
5
50 + 50
2
400
Time / 24hours
Hours
24
8
20
24
3
1.2
% on Consumption / 24hour period
%
kWh Ah (24 V)
1.2
48
0.2
8
30
0.8
30
25 + 50
0.9
38
0.1
6
0.5
20
0.2
10
3.8
160
160
6.7
Minimum battery capacity required, assuming 2 recharges per day (see sect. 8.4.2)
320
What can be learned from this table:
By investing in efficiency and insulation, the power consumption of the refrigerator and freezer is now in
line with that of other consumers. All too often bad design results in the compressors running nearly full time,
which would add another 60 Ah to daily power consumption!
When sailing, the minimum energy consumption on a 12 to 18 m sailing boat is approx. 4 kWh per day.
This is equivalent to about 160 Ah from a 24 V battery or 320 Ah from a 12 V battery.
The average DC current taken from the battery is only 6.7 A at 24 V, not of any significance when
motoring
10.4. At anchor or moored without 230V shore power pick-up
The following table is valid for motor boats as well as sailing boats
Consumers
L
L
S
S
S
Anchor light
Refrigerator & freezer, water cooled
Radio
Cabin lighting
Other
Total consumption per 24-h period
Average consumption per 24-h period
Consumption
Watt
25
50 + 50
Amp
2
400
Time / 24hours
Hours
8
24
3
1.2
% on Consumption / 24hour period
%
kWh
Ah (24 V)
0.2
8
25 + 50
0.9
38
0.1
6
0.5
20
0.2
10
2.0
82
82
3.4
Minimum battery capacity required, assuming 2 recharges per day (see sect. 8.4.2)
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53
10.5. The extra’s
From the extra’s mentioned in section 9.5 of the previous chapter, the electronic navigation system, SSB and
radar have been included in the list of section 10.2.
In addition to the other extra’s mentioned in 9.5 there are a few more to consider, now that we are looking at
bigger boats.
10.5.1. Hot water kettle
Very convenient for boiling water. The heat capacity of 1 litre of water is 1.16 Wh per °C, see sect. 6.6.
So bringing 1 litre of water to the boil will take approx. 100 Wh, i.e. 4.2 Ah from a 24 V battery.
10.5.2. Electric stove
Gas on board is hazardous and lugging gas bottles about is no pleasant task. With 2 electric hobs of
2 kW each the peak power required will be 4 kW (i.e. almost 200 A at 24 V), 4 hobs will require a
maximum of 6 to 8 kW. Cooking a meal for 4 people takes approx. 1.2 kWh, i.e. 50 Ah (see sect. 6.6).
10.5.3. Small washing machine
This has been touched on in sect. 6.5.
The energy consumption for a wash-dry cycle is about 2.7 kWh.
Most of the electricity needed is for heating the water and for the drying cycle. Hot fill (= supplying the
washing machine with hot instead of cold water) and no drying cycle would reduce energy consumption
to about 0.5 kWh.
10.5.4.
Small dishwasher
Consumption approx. 1 kWh
Hot fill would reduce energy consumption to less than 0.5 kWh.
We will now calculate the total consumption per 24-hour period if all this luxury would be taken on
board, assuming a crew of 4 and a tropical climate, so that instead of the heater, the air conditioning is
used.
In our example the air conditioning is switched on for 12 hours per day and the compressor runs with an
average duty cycle of 50 %.
Similarly a high-pressure pump type water maker is used instead of the much more energy efficient DC
water-hydraulic type.
We also assume that the washing machine and dishwasher are operated without hot fill.
Consumers
Consumption
Microwave oven
Kettle, 6 litres per day
Electric cooker, 4 persons
Heater
Air conditioning, cooling capacity 4 kW
Water maker, 200 litres per day
Small washing machine, once every 2 days
Small dishwasher, daily
Miscellaneous
Watt
1500
2000
6000
Amp
3
1400
2000
2000
Consumption per 24-hour period
Time /
24-hours
Hours
0.25
6 x 0.5 = 3
12 x 0.5 = 6
Consumption /
24-hour period
kWh Ah (24 V)
0.4
16
0.6
25
1.2
50
(9)
8.4
350
1.4
60
0.5 x 2.7
56
1.0
42
10
25
609
The table shows that air conditioning is an especially power hungry consumer, although we have
assumed only 12 hours of operation per day. With 8.4 kWh of energy needed per day, which would
translate into 350 Ah per day if running (with an inverter) from the battery, air conditioning requires more
energy than all other equipment together!
A 1500 Ah battery would be needed to achieve a generator free period of 20 hours. Although such
installations do exist, the more common solution is to run a generator whenever the airco is on, and to
cope with the noise, maintenance and fuel consumption.
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Now, if we want reduce power consumption, the first step, if airco is a must, is reduce it to the minimum,
and also to replace the water maker by the more efficient (and much less noisy) DC water-hydraulic
type. The result is as follows:
Consumers
Consumption
Watt
1500
2000
6000
Microwave oven
Kettle, 6 litres per day
Electric stove, 4 persons on board
Heater
Air conditioning, cooling capacity 2 kW
Watermaker, 200 litres per day
Small washing machine, once every 2 days
Small dishwasher, daily
More pumps
700
Amp
3
29
10
2000
2000
Consumption per 24-hour period
Time /
24-hours
Hours
0.25
6 x 0.5 = 3
12.x 0.5 = 6
3.3
Consumption /
24-hour period
kWh Ah (24 V)
0.4
16
0.6
25
1.2
50
(9)
4.2
175
1.4
33
0.5 x 2.7
56
1.0
42
10
9.6
407
Together with the basic consumption on a sailing boat, consumption per 24-hour period now adds up to:
- with air conditioning:
min. 160 + 407 = 567 Ah and max. 160 + 609 = 796 Ah
at a current of, on average:
min. 567 Ah / 24 V = 24 A and max 796 Ah / 24 V = 33 A
total energy consumption per 24-hour period: min 567 x 24 = 13.6 kWh and max 796 x 24 = 19.1 kWh
- without air conditioning:
160 + 232 = 392 Ah per 24 hour period
at a current of, on average:
392 / 24 = 16 A.
total energy consumption per 24-hour period: 392 x 24 = 9.4 kWh.
10.6. Energy generation
10.6.1. With alternators on the main engine
This is certainly possible, see chapter 9.
10.6.2. Alternative sources of energy
As explained in chapter 9, solar cells can be an excellent means to recharge the battery when the boar
is left in the slip for a week or more.
2
When sailing, solar cells (1 m ), a wind generator (1 metre diameter) and a water generator (say 60 W
at 5 knots speed through the water) together deliver almost 2.4 kWh (= 100 Ah in a 24 V battery) per
24-hour period. In other words: the contribution of alternative sources of energy can reduce engine
hours substantially if not much more than the basic equipment is on board.
But when the daily energy needed increases further, other means of generating electricity are needed.
The alternatives will be discussed in the next sections.
10.6.3. With an AC generator
The time-honoured method to cope with the high power demand of for example a washing machine or
electric stove is installation of an AC diesel generator, to be started when power demand is high. The
generator would for example run every evening for 2 to 4 hours during cooking and until the dishwasher
has finished. During these same 4 hours one could run the washing machine and dryer, the water
maker, the battery chargers, and heat-up the boiler (either electric or with cooling water from the
generator).
If needed, one could have a second generator period of 1 or 2 hours during breakfast in the morning.
In general the generator period is kept as short as possible, for the following reasons:
noise and vibration
wear and maintenance
preventing operation with insufficient load, as this will increase wear and maintenance
fuel consumption
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Furthermore, for reasons of reliability and endurance, it is advisable to chose a 1500 rpm (50 Hz) or
1800 rpm (60 Hz) model, powered by a 2 or more cylinder motor.
Battery sizing
Knowing how long the generator will run, in our example during at least 4 hours per day, we can
calculate how many Ah the battery has to supply during the generator free period:
a)
If under sail, roughly 24 - 4 = 20 hours of the basic power consumption as outlined in sect.
10.3, or 160 x 20 / 24 = 133 Ah.
b)
Regarding other equipment, let us assume that the microwave, kettle and two thirds of the airconditioning time will also come within the generator free period. This means
16 + 25 + 175 x 2/3 = 158 Ah.
Total: 133 + 158 = 291 Ah. For this we then need a battery of at least 600 Ah, (2 recharge periods per
day, see sect 8.5.2.) and with a little reserve (airco use during the night), that becomes 800 Ah.
Inverters and battery chargers
In the inverter mode, the Multi 24/3000/70 combined inverter-battery charger will in general provide
sufficient power because the generator can be started whenever more than 2 kW AC power is needed.
But as a charger the Multi only delivers 4 x 70= 280 Ah during the 4 hour generator period. During that
period 291 Ah have to be charged, plus yet another 4 hours basic load, i.e. 6,7 x 4 = 27 Ah. With a little
margin we then arrive at 100 A charging current. So, in addition to the Multi, a 24 V / 50 A charger
needs to be installed.
The generator
For the electric stove 6 kW would be needed, plus 100 A x 30 V = 3 kW for battery charging. Total:
9 kW. With some margin to run additional equipment (the airco, for ex.) the right choice would be a
12 kW genset.
Shore power connection and frequency converter
In our example the shore power pick-up can be limited to approx. 8 kW (35 A at 230 V in Europe),
because there is far more time available to charge the battery.
A 50/60 Hz shore converter will be needed to connect to shore power on both sides of the Atlantic.
Halfway through the calculation you probably thought that this is not practical in a 15 meter sailing boat
or a 13 meter motor yacht. The system becomes too big, costly, heavy and complicated. Indeed!
Consequently, the kind of installation described above only tends to be found in rather bigger boats, for
example a 20 meter sailing yacht or a 15 meter motor yacht.
What can be done to make it work on smaller boats?
1) The obvious solution would be to drop the electric stove, and use gas instead.
Then a 6 kW generator running during 4 to 8 hours a day, depending on the amount of air conditioning,
would do.
(Often the generator is downsized even more, to a 1 cylinder 3,5 kW model. Using any equipment with
AC electric motors, like AC powered air conditioning, a water maker or a diving compressor then
becomes problematic because the generator will not be able to supply the start- up current needed).
2) Secondly, air conditioning could be limited to generator running hours.
3) And thirdly, by implementing the DC concept when on shore power (see sect. 8.2. and 8.5.3.), shore
power can be reduced from 8 kW to approximately 1.2 kW (in Europe this would mean a single phase
230 V 6 A shore connection). 50 / 60 Hz frequency conversion then comes as a built-in feature of the
system.
To implement the DC concept, shore power should be connected to a 40 A or 50 A battery charger, and
all AC consumers on board will be supplied by 2 or 3 parallel inverters of 2.5 kW each (or preferably
Multi’s, see next section).
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10.6.4. PowerControl and PowerAssist
Using Multi’s and PowerControl together with a generator has the following advantages (see also
chapter 8):
Uninterrupted AC supply. When the generator is off, the Multi’s will supply AC on board. After
the generator has been switched on, the AC load will automatically be transferred to the generator and
the Multi’s will switch to battery charger mode. The reverse will happen when the generator is stopped.
The PowerControl feature will eliminate any risk of overload on the generator. The battery
charge current will automatically be reduced if, together with other consumers, power demand by the
Multi’s (which with 2 Multi’s could be as high as 2 x 70 A x 30 V = 4.2 kW) would otherwise result in an
overload. Thanks to PowerControl the generator discussed in section 10.6.4. can be downsized from
12 kW to 8 kW (installation with electric stove) or from 6 kW to 3 kW (without electric stove).
PowerAssist: the MultiPlus as generator booster
This is the option on the Phoenix MultiPlus to allow parallel operation with a generator or with shore
power (see also chapter 8).
Let us first look at parallel operation with a generator, for example the 6 kW generator on the yacht
under sail from the previous section.
Operating 2 Multi’s in parallel with the generator would increase continuous AC output from 6 kW to
11 kW, and increase peak output to more than 15 kW. This brings the electric stove back on board.
Whenever power decreases to less than a pre-set limit (which in our example would be 5 kW for the
6 kW generator, in order not to run the generator continuously at full load), the Multi’s would take the
surplus power from the generator to recharge the batteries, at up to 2 x 70 = 140 A.
Similarly, when operating in parallel with shore power, which would be rated for example at 16 A (In
Europe this would amount to 16 x 230= 3680 W, or 3,7 kW) the 2 Multi’s would increase available AC
power on board to some 8 kW.
No need anymore to start the generator in the marina!
10.6.5. The AC generator on a relatively small boat: conclusion
Sizing a generator to the peak power that may be required results in a big and heavy machine, and the
shore power connection needed will be well above the rating that is generally available. If, in addition, a
50/60 Hz shore converter is needed the system becomes extremely expensive and cumbersome.
Instead of compromising with regard to comfort on board, new technology can be used to reduce cost,
size and weight of the power supply system.
By adding a 24 V 800 Ah battery, 3 Multi’s with PowerAssist and a 50 A battery charger to the system
we have been able to:
-
Introduce 2 generator free periods per day of in total 20 hours.
-
Reduce the rating of the generator from 12 kW (3 phase) to 6 kW (single phase).
outlet)
Reduce shore power required from 8 kW (3 phase 16 A) to a mere 1.3 kW (6 A 230 V shore
-
Eliminate the need for a 50/60 Hz shore converter
-
Achieve uninterrupted AC power on board
-
Substantially increase redundancy and therefore safety.
10.6.6. The DC generator
Next to conventional 50/60 Hz AC generators, some generator suppliers are also offering DC
generators. Outputs of up to 10 kW, that means a battery charging current of up to some 300 A at 28 V,
are available. DC generators are smaller and lighter, and have a higher efficiency than AC generators.
Moreover, engine speed can be harmonised with power demand, so that efficiency remains high even
under partial load.
The idea is to use the DC generator to charge the batteries, and use inverters to supply the AC load.
Sizing of the DC generator is a question of acceptable running hours per day. With 14 kWh of electrical
energy required per day, a 6 kW DC generator, for example, would run for 2-3 hours per day.
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10.6.7. Efficiency of a diesel powered generator
The efficiency of a diesel powered generator exceeds 30 % at full load. The efficiency drops as the %
load reduces. On a boat a genset will run at low load most of the time. Typically the average efficiency
will be 10 to 20 %. The efficiency can be substantially improved with PowerControl or PowerAssist
(see sect. 8.3.3 and 8.4.).
10.6.8. The energy supply on a motor yacht of 9 to 15 metres or a yacht at anchor.
Even with the complete wish list of section 10.5 installed, the alternators on the main engines of a motor
yacht can easily supply the average consumption of 24 A at 24 V DC when cruising. In other words, if
one expects to motor for several hours nearly every day or to have shore power available every night,
14 kWh of daily energy consumption can be taken care of without installing a separate generator.
At anchor consumption will reduce to approx. 22 A, because navigation equipment is switched off.
When at anchor for longer periods a generator will be needed, as discussed in sect. 10.6.3 to 10.6.6.
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10.7. Conclusion.
The following table summarises the alternatives that have been discussed.
Generating up to 14 kWh per day (600 W average)
5 kW DC generator
DC generator
Hours per 24-hour period
Consumption per 24-hours
Weight
6 kW AC generator
with PowerAssist
12 kW
AC generator
3 to 8
9 litres
67 dBA
250 kg
4 to 8
11 litres
69 dBA
350 kg
3 to 8
7 litres
150 kg
AC generator
Hours per 24-hour period
Consumption
Noise
Weight
Battery
Capacity
Weight
24 V / 800 Ah
700 kg
24 V / 800 Ah
700 kg
24 V / 800 Ah
700 kg
Shore power
Rating
Battery chargers
6A
50 A
6 A (DC concept)
50 A 8 kg
3-phase 8 kW
50 A
8 kg
Yes, no separate
shore converter
needed
Yes, no separate
shore converter
needed
No, additional shore
converter needed
7.5 kW (3 x MultiPlus)
2.5 kW Multi
Weight
7.5 kW (3 x Phoenix
Inverter 2.5 kW)
54 kg
54 kg
18 kg
Total weight of installation
962 kg
1012 kg
1076 kg
2 weeks fuel
98 litres
126 litres
154 litres
Total weight incl. 2 weeks fuel
990 kg
1118 kg
1205 kg
50 / 60 Hz shore power conversion
DC-AC inverters
Output
8 kg
What can we learn from the table?
10.7.1. Let us first have a look at the conventional solution: the 12 kW generator:
This solution is heavy and takes a lot of valuable space.
With PowerControl, whereby charge current is automatically reduced whenever otherwise an overload
would occur, a smaller generator, for example 9 kW, would be sufficient.
The average load of a 12 kW generator would be:
-if 4 running hours per day: 14 / (4 x 12) = 29 %
-if 6 running hours per day: 14 / (6 x 12) = 19 %
And in the case of a 9 kW generator:
-if 4 running hours per day: 14 / (4 x 9) = 39 %
-if 6 running hours per day: 14 / (6 x 9) = 26 %
Shore power requirement will be in the order of 8 kW, unless for shore power the DC or the hybrid
concept is implemented, then a 6 A (= 1,38 kW) outlet would be sufficient.
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10.7.2. A better solution in terms of weight and space required is a 6 kW generator with PowerAssist, or
a 5 kW DC generator
Implementing PowerAssist with a 6 kW AC generator would in our example of the fully featured yacht
require 2 Multi’s. Using the DC concept when on shore power would require 3 Multi’s.
With PowerAssist most of the AC power would be supplied directly by the AC generator and the
average DC charge current needed would not exceed 75 A for a 4 hour generator period.
If most of the time the daily requirement is much less than 14 kWh, one could opt for a 1 cylinder
3.5 kW generator.
Warning:
Especially low power AC gensets fitted with a synchronous generator tend to overheat when used at full
load: derating of up to 30 % is often necessary to prevent catastrophic failure!
Nearly all small gensets are fitted with a synchronous generator. The notable exception is Fischer
Panda, who uses asynchronous generators.
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11. Up to 48 kWh required per day (2 kW average)
11.1. Introduction
In chapter 10 we looked at boats requiring up to 14 kWh of electric energy per day. We concluded that 14 kWh
per day is sufficient for 1 household of 4 to 6 persons whether they live on a boat or in a house, with all usual
electric household equipment at their disposal, as long as air conditioning is either not needed or if limited use is
made of it.
We also saw that a daily electric energy need of 4 to 14 kWh is typical for motorboats or catamaran sailing
yachts of 9 to 15 meters or mono hull sailing yachts of 12 to 18 meters.
On a yacht of just a few metres longer, electricity consumption tends to increase disproportionately. Such
yachts, whether chartered or not, often carry a professional crew and instead of 4 to 6 persons the yacht carries
8 to 12. Cruising is mostly in subtropical or tropical waters and airco is on for 12 hours or even 24 hours a day.
The power supply problem is usually solved as follows:
- Running an AC generator for 24 hours per day, or
- Installing a big battery to achieve a generator free period of 8 to 20 hours, and again use AC generators to
supply high power electric equipment such as the electric stove, ovens, washing machines and battery
chargers.
The required shore power is also significant (and severely limits the options when seeking a berth in a marina)
because the battery is in general not used as a peak shaver (PowerAssist functionality). An expensive and
heavy shore power converter will be needed to convert 60 Hz shore power to 50 Hz or the other way round.
Let us first have a look on board a yacht with an average daily energy requirement of 48 kWh, which amounts to
an average power consumption of 2 kW.
11.2. The major consumers
The most important continuous and long duration consumers:
- Refrigerators and freezers: 300 W average
- Air conditioning: 12 kW (41.000 BTU) running on one or more compressors together rated at 3 kW
The most important short duration high power consumers:
- A 6 hob electric stove + ovens: 12 kW peak power
- A 300 l per hour high pressure pump type water maker: 3 kW (15 kW start-up)
- Washing machine(s) and dishwasher(s): peak power between 6 and 12 kW
- Possibly a diving compressor
Other consumers are of less importance for dimensioning the system. We just assume an average consumption
of 2 kW.
11.3. Energy generation
11.3.1. With an AC generator running 24 hours a day
Assuming that other major short duration consumers are off during cooking, and that in practice the hobs
and ovens will never run at full power simultaneously, a 15 kW generator would be the minimum. In
practice a 20 kW (3 phase, to match shore power) generator would be installed. Often this generator is
also fitted with a hydraulic power take off for the bow thruster.
If the choice is to run a generator permanently, one could opt to add a second, smaller generator of, say
5 kW, to cover the periods that much less power is required.
Batteries and battery chargers would remain very small in this case.
Although looking simple and low cost at first sight, this solution has some serious drawbacks:
- In order to avoid a dead ship every time AC power has to be transferred from one generator to the other
or from generator to shore supply, complicated and expensive synchronisation systems will have to be
added.
- A 20 kW (32 A 3-phase) shore power connection will be required.
- An expensive and heavy 20 kW shore power converter will be needed to connect to shore power on
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both sides of the Atlantic.
- A 20 kW generator running 24 hours a day would have an average load of only 2 / 20 = 10 %! Not good
for the generator and not good for fuel consumption. Adding a second, smaller, generator would increase
this figure to some 20 %. Better, but still bad.
- And then of course the noise, vibration, smell and pollution 24 hours a day…(and do keep in mind that
there are more and more marina’s and nature reserves where running a generator is forbidden).
11.3.2. Adding a battery for a generator free period
This alternative brings us back to 10.6.3, but with more power required.
Battery sizing
Battery capacity will depend on the required generator free period, and especially on whether at all, or how
much, air conditioning is required during the generator free period. Let us assume here that the generator
will be running at least twice a day, whenever the electric stove & ovens are in use, when the water maker
is on and during washing and / or dishwashing. In other words: during some 8 hours per day.
Furthermore, we assume an average battery load during the generator free periods of 1.5 kW (= 63 A),
which results in
1.5 x (24 – 8) = 24 kWh or 24 kWh / 24 V = 1000 Ah taken from the battery per day. Applying the rule of
thumb from sect. 8.5.2, a battery of 2000 Ah will be needed.
Of the 48 kWh required per day, in this example 24 kWh is supplied by the battery, and the remaining
24 kWh directly by the generator.
The generator
The generator will have to recharge 1000 Ah within 8 hours. We then need a recharge current slightly
exceeding 1000 / 8 = 125 A, for example 175 A. For the generator this means a load of
175 x 30 = 5.25 kW. This can be done with the 20 kW generator mentioned earlier, provided the battery
chargers are switched off when peak power is required for cooking plus some other electric appliances
being used at the same time.
The energy to be supplied by the generator will be 1000 Ah x 30 V = 30 kWh for the battery, plus the
24 kWh directly to the AC appliances, total 30 + 24 = 54 kWh, battery charge-discharge losses included.
By adding a 2000 Ah battery to the system, we have:
- achieved 2 generator free periods per day of on average 8 hours each
- reduced generator use from 24 to 8 hours per day
- increased the average load of the 20 kW generator from 2 kW to 54 / 8 = 6.75 kW, battery chargedischarge losses included.
But we still need a 15 kW shore power connection and a shore converter.
11.3.3. Using parallel Multi’s with PowerControl, and the DC concept for shore power:
- for automatic generator load dependent battery charging
- to reduce required shore power to 3.5 kW
- and have frequency conversion nearly for free
Installing 5 Multi’s in between the 20 kW generator and the battery will result in the following:
- Instead of a three phase generator, a single phase model could be used: shore power will also be single
phase (see below) and phase balancing problems will be eliminated.
- The Powercontrol feature will eliminate any risk of overload on the generator. The battery recharge
current will automatically be reduced if power demand by the Multi’s (which could be as high as
5 x 70 A x 30 V = 10.5 kW if a fast recharge is needed, but would in general be limited to 5.25 kW)
together with other consumers would otherwise result in an overload.
- Uninterrupted AC supply. When the generator is off or power is needed for the bow thruster, the Multi’s
will supply AC on board. After the generator has been switched on the AC load will automatically be
transferred to the generator and the Multi’s will switch to battery charger mode.
- By implementing the DC concept, shore power can be reduced from 15 kW to 3.5 kW (in Europe this
would mean a single phase 230 V 16 A shore connection instead of a three phase connection) and
frequency conversion is a built-in feature of the system. To implement the DC concept, shore power
should be connected to a 100 A battery charger (or, for redundancy, 3 off 50 A chargers) which charge(s)
the battery, and all AC consumers on board will be supplied by the 5 parallel Multi’s. The 5 parallel Multi’s
are rated at 10 kW continuous output power and 15 kW short term.
At first sight 100 A might seem a bit tight: the 48 kWh required per day translates to
(48 kWh / 24 h) / 24 V = 83 A. But on the other hand being able to run the ship on a 16 A shore outlet is
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very attractive. In practice, when moored, energy consumption will be at most 40 kWh per day and on
average much less because the water maker, navigation equipment, etc. will not be used, and the crew
will be out on shore leave.
11.3.4. Going 1 step further: using the MultiPlus and PowerAssist to reduce generator size by 50 %
With 54 kWh of electric energy needed and running the generator for at least 8 hours per day, the
generator should be rated at 54 / 8 = 6.75 kW, that with some margin brings us to 10 kW (see sect. 8.3.
and 8.4.).
Operating 5x MultiPlus’s in parallel with the generator would increase available AC power to
10 + 5 x 2.5 = 22.5 kW.
When AC power demand increases beyond a pre-set limit, for example 8 kW in order not to run the
generator at full load, the Multi’s will start supplying additional AC power. The available energy from the
2000 Ah battery (24 x 2000 x 0.5 = 24 kWh) is more than sufficient to cover short time power demand
iwhen the Multi’s have to kick in.
When power demand drops below 8 kW, the Multi’s will use the surplus power from the generator to
recharge the batteries. The maximum recharge current of 5 parallel Multi’s is 5 x 70 = 350 A, which would
take 350 A x 30 = 10.5 kW from the generator. Much more than needed and even more than the generator
can supply.
The AC generator: conclusion
By adding a 2000 Ah battery, 5 Multi’s with PowerAssist and a 100 A battery charger to the system we
have been able to:
- Introduce 2 generator free periods per day of in total 16 hours.
- Reduce the rating of the generator from 20 kW (3 phase) to 10 kW (single phase).
- Reduce shore power required from 15 kW (3 phase 25 A) to a mere 3.5 kW (16 A 230 V shore outlet)
- Eliminate the need for a 15 kW shore converter
- Achieve uninterrupted AC power on board
- Substantially increase redundancy and therefore safety.
11.3.5. The DC generator
An alternative for the 10 kW AC generator would be a 10 kW DC generator. Please refer to section 10.6.7.
11.3.6. Using a small auxiliary DC generator to reduce generator hours, battery capacity and fuel
consumption
On a big boat a small genset can be made inaudible and completely vibration free. So why not run a small
genset during most of the day to reduce battery capacity?
- Battery capacity could be reduced substantially, for example to 1000 Ah which is the minimum needed
to run 5 Multi’s.
- Main generator running hours can be reduced further, from 8 hours to approx. 6 hours, and even down
to 1 or 2 hours when no airco is needed.
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11.4. Conclusion
The alternatives for 48 kWh per day compared:
Generating 48 kWh per day (2 kW average)
Aux. genset, 5kW
Hours per 24-hour period
Consumption per 24-hour
period
Weight
Main generator
Hours per 24-hour period
Consumption per 24-hour
period
Weight
Battery
Capacity
Weight
Shore power
Rating (in Europe)
Auto transformer
110 – 230 V
Weight 15 kW shore
converter
Chargers / Inverters
Battery chargers
Inverters
Weight
Total weight of the
installation
10 kW AC generator with 20 kW AC generator with
PowerAssist, plus an
PowerControl plus an
aux. genset
aux. genset
20 kW AC generator
with generator free
period
12
8 litres
12
8 litres
n/a
n/a
150 kg
150 kg
n/a
6
15 litres
6
20 litres
8
30 litres
300 kg
450 kg
450 kg
24 V 1000 Ah
1000 kg
24 V 1000 Ah
1000 kg
24 V 2000 Ah
2000 kg
3,5 kW
16 A 1-phase
Not needed if battery
chargers with universal
90-265 VAC input are
used
Not needed
3,5 kW
15 kW
16 A 1-phase
32 A 3-phase
Not needed if battery
n/a
chargers with universal 90265 VAC input are used
Not needed
545 kg
100 A 12 kg
12.5 kW
(5 x MultiPlus)
90 kg
100 A 12 kg
10 kW
(4 x Multi)
72 kg
200 A 24 kg
2.5 kW
1552 kg
1684 kg
3037 kg
18 kg
Note: savings due to usable heat output of the aux. genset not included)
What can we learn from the table?
11.4.1. The 20 kW generator with generator free period (right-hand column)
This alternative is heavy, and the 2000 Ah battery is expensive, with the risk of high expenses in case of
a mistake regarding battery management or an accident, like a cell failure for example.
The alternative, operating the generator 24 h per day is also not very attractive.
A second generator of for example 6 kW could be used to cover most of the day, running with an
average load of 1.5 kW, with the 20 kW generator coming in when more power is required.
The shore converter is the other expensive and heavy component in this configuration.
64
© Victron Energy
11.4.2. Implementing PowerControl and the DC concept for shore power, and adding an auxiliary
genset to reduce battery capacity (middle column)
Implementing the DC concept solves the shore power problem (see sect.11.3.3.).
By adding an auxiliary genset (AC or DC), battery capacity could be reduced to 1000 Ah, reducing
weight by 1000 kg.
11.4.3. Using a smaller generator with PowerAssist, the DC concept for shore power, and an auxiliary
genset (left-hand column)
The main difference compared to section 11.4.2 is the smaller generator (10 kW instead of 20 kW),
reducing weight by another 130 kg.
© Victron Energy
65
12. Up to 240 kWh required per day (10 kW average)
12.1. Introduction
In chapter 11 we saw that size, weight and complexity of the power supply system could be significantly
reduced by designing a well balanced system consisting of a 10 kW generator assisted by Multi’s, and also a
relatively small service battery assisted by an aux. genset.
In this chapter we will look at still higher power requirements
12.2. The major consumers
An average consumption of 10 kW is applicable for boats of up to approx. 30 metres.
- The biggest consumer of electricity will in general be air conditioning, running day and night when cruising in
tropical areas. The rated cooling capacity would for example be 100,000 BTU (= 30 kW). With a CoP
(Coefficient of Performance, see section 6.2.) of 4 this means that 30 / 4 = 7.5 kW would be needed when the
air conditioning has to work at full power.
On average over a 24-hour period the air conditioning’s consumption will be at most 5 kW, and that
immediately explains half of the total power consumption.
- The other major consumers are galley appliances, washer-dryers, the water maker and lighting. Current
consumption will be less at night than during the day, for example in a proportion of 5 to 15 kW.
12.3. Energy generation
12.3.1. AC generators
The main generator could, for example, be rated at 50 kW, enough to cover the power required to throw
a big party.
A second generator of, say, 8 kW could be used when less people are on board.
This set-up has the same drawbacks as mentioned under sect. 11.3.1:
- In order to avoid a dead ship every time AC power has to be transferred from one generator to the
other or from generator to shore supply, synchronisation systems are needed.
- A 50 kW shore power connection will be required.
- An expensive and heavy shore power converter will be needed to connect to shore power on the other
side of the Atlantic.
- One 50 kW generator running 24 hours a day would have an average load of only 10 / 50 = 20 %. Not
good for the generator and not good for fuel consumption. Adding a second, smaller, generator would
increase this figure to some 30 %. Better, but still bad.
- And then of course the noise, vibration, smell and pollution 24 hours a day…(and do keep in mind that
there are more and more harbours and nature reserves where running a generator is forbidden).
66
© Victron Energy
12.3.2. Adding a battery for a generator free period and battery assisted generator operation
(PowerAssist)
This alternative only makes sense if the peak power of 50 kW is an exceptional situation and of short
duration, with power demand staying below 20 kW most of the time.
The battery
If power consumption can be reduced to an average of 4.5 kW over sizeable periods of time, for
example 8 hours during the night and 6 to 8 hours during the day, the maximum daily amount of energy
to be supplied by the battery would be 4.5 x 16 = 72 kWh or 72 kWh / 24 V = 3000 Ah. With our rule
of thumb from sect.8.5.2, a battery of 6000 Ah would be needed.
The generator, Multi’s and shore power
Now we have to think differently, forget about peak power required and instead look at the daily energy
needed (see sect.8.5.)
Of the 240 kWh required per day, in this example 72 kWh is supplied by the battery, and the remaining
168 kWh directly by the generator
The amount of energy needed to recharge the battery is 3000 Ah x 30 V = 90 kWh.
The daily energy to be supplied by the generator therefore amounts to 168 + 90 = 258 kWh.
The generator, running during at least 8 hours per day, should be rated at 258 / 8 = 32 kW. With some
margin, 40 kW would be installed.
Adding 3 Multi’s per phase will increase continuous output power by 9 x 2.5 = 22.5 kW to
40 + 22.5 = 62.5 kW.
When AC power demand increases beyond a pre-set limit, for example 35 kW in order not to run the
generator at full load, the Multi’s will start supplying additional AC power. The available energy from the
6000 Ah battery (24 x 6000 x 0.5 = 72 kWh) is more than sufficient to cover short time peak power
demand.
When power demand drops below 35 kW, the Multi’s will use the surplus power from the generator to
recharge the batteries. The maximum recharge current of 9 parallel Multi’s is 9 x 70 = 630 A, which
would take 630 A x 30 = 18.9 kW from the generator. Much more than needed: the average recharge
current needed is 3000 Ah / 8 h = 375 A.
One attractive feature of the Multi’s is that they will automatically balance the load of the generator:
the Multi’s will take most power from the phase(s) which otherwise would have the smallest load.
A solution to reduce shore power is again to implement the DC or the hybrid concept. The daily energy
required of 240 kWh translates to (240 kWh / 24 h) / 24 V = 416 A at 24 V, which could be supplied by 6
off 100 A rectifiers. Shore power required would then be 18 kW (32 A 3-phase).
Alternatively, because the 18 kW is not so much less than the 50 kW peak power required, the Multi’s
could operate in shore power support mode, which would likewise limit shore power to 18 kW, but
frequency conversion would not be possible.
By adding a 6000 Ah battery, 15 Multi’s with PowerAssist and 6 off 100 A battery chargers to the
system, we have been able to:
- Introduce 2 generator free periods per day of in total 16 hours.
- Reduce the rating of the generator from 50 kW (3 phase) to 40 kW (3 phase).
- Reduce shore power required from 50 kW (3 phase 75 A) to 20 kW (3-phase 32 A)
- Eliminate the need for a 50 kW shore converter
- Achieve uninterrupted AC power on board
- Substantially increase redundancy and therefore safety.
12.3.3. Adding an 8 kW auxiliary AC generator
On a big boat a small genset can be made inaudible and completely vibration free. So why not run a
small genset during most of the day to reduce battery capacity?
- Battery capacity could be reduced substantially, for example to 2000 Ah which is the minimum needed
to run 9 Multi’s.
- Running this (single phase) genset in parallel with 3 of the 9 Multi’s will provide up to
8 + 7.5 = 15.5 kW of AC power on one phase and 7.5 kW on the other 2 phases.
© Victron Energy
67
- Main generator running hours can be drastically reduced.
- Running 24 hours a day, the auxiliary generator could also supply all hot water needed on board.
12.4. The alternatives for 10kW average consumption compared
Generating 240 kW per day (10 kW average)
40 kW generator with 9 Multi’s and
PowerAssist.
Service battery of 2000 Ah
Aux. genset 8 kW
AC Concept
Generators
Output
Hours per 24-hour period
1x40 kW + 1x 8 kW
1x 4 hr and 1x 20 hr
1x 50 kW + 1x 10 kW
1x 10 hr and 1x 14 hr
Consumption per 24-hour period
Weight
95 litres
800 kg
120 litres
1200 kg
Battery
Capacity
Weight
2000 Ah
2000 kg
400 Ah
400 kg
Shore power
Rating
Weight auto transformer
18 kW
3 x 32 A
50 kW
3 x 100 A
n/a
Weight 50 kW shore converter
Not needed
1300 kg
DC-AC inverter
Output
Weight
22.5 kW (9 Multi’s)
162 kg
6 kW
54 kg
Battery chargers
Current
Weight
600 A
80 kg
75 A
10 kg
Total weight
3000 kg
2964 kg
2 weeks fuel consumption (see
note)
1330 litres
1680 litres
Total weight incl. fuel for 2 weeks
4017 kg
4375 kg
Note: savings due to usable heat output of the auxiliary genset not included)
What can we learn from the table?
The main lesson is that with 240 kWh of electric energy required per day, the limits of the new components and concepts
presented in this book have been reached.
The battery needed to implement PowerAssist and the DC concept becomes really cumbersome and very expensive.
Only when a battery free period is a must, or when the energy needed is, for most of the time, much less than 240 kWh
per day, will PowerAssist or the DC concept be attractive options.
68
© Victron Energy
13. Conclusion
13.1. Consumption of electric energy on board
- On small boats the refrigerator and freezer often are the most important consumers. Spending some money
on good insulation and a good water-cooled refrigeration system can reduce battery capacity and recharge
time needed dramatically.
- Similarly, small air conditioning systems can be incredibly inefficient.
- The impact on energy consumption of continuous and long duration consumers (mainly navigation and
refrigeration equipment) is often underestimated.
- The impact of short duration consumers (microwave, electric stove, washing machine, pumps, electric
winches) is often overestimated.
13.2. Energy generation
- The first step to have more energy available on board is to increase alternator output by installing a second
or bigger alternator and to increase battery capacity to at the very least 3 times the alternator output (C / 3
charging rate). Otherwise the battery will overheat and not absorb the available charge current.
- When designing a small autonomous power supply system one should, in the first instance, ignore the
maximum power required, but consider the total amount of electric energy needed over a 24 hour period.
- A problem that is often overlooked when installing an AC generator on board is shore power. When no
additional measures are taken the shore power rating must match (or even exceed, because of electric boiler
heating) the rating of the generator. How easy is it to find to find
- in Europe: a berth with more than 16 A (3.7 kVA) shore power?
- in North America: a berth with more than 50 A (5.5 kVA) shore power?
13.3. The DC concept
- In the DC concept a battery sits in between the consumers and suppliers of electrical power. The battery
supplies additional energy when demand exceeds supply, and absorbs energy when supply exceeds demand.
- With the DC concept high power consumers (the electric stove) can operate together with low power
suppliers (for ex. a 230 V / 4 A shore power outlet).
- The DC concept doubles as a 50 / 60 Hz shore power converter
13.4. PowerAssist: the hybrid or battery assisted AC concept
- Similarly to the DC concept, PowerAssist uses a battery to supply or absorb electric power, but now the link
between suppliers and consumers is AC instead of DC. One or more Multi’s operating in parallel with a
generator or shore power will provide additional AC power when demand exceeds supply and absorb AC
power to recharge the batteries when supply exceeds demand.
- Similarly to the DC concept, PowerAssist allows high power consumers to operate with a lower power
generator or shore supply.
- Like the DC concept, PowerAssist saves space and weight. Additionally the average load of the generator
will be much higher. This will increase service life, decrease maintenance and decrease fuel consumption.
- PowerAssist is not suitable for frequency conversion. Maximum flexibility is obtained by adding battery
chargers to the system, and using the DC concept when connected to shore power.
© Victron Energy
69
The house battery
-The useful capacity of the house battery is at most 50 % of its rated capacity. This is because a battery should not
regularly be discharged more than 70 % (70 % DoD) and in general will not be recharged to more than 80 %
(20 % DoD).
-On bigger boats, with a substantial house battery to cover a generator free period, a small auxiliary genset can be
used to reduce size and weight of the battery and at the same time produce useful heat for the boilers and for space
heating.
70
© Victron Energy
Index
AC concept, 41, 61, 69
AC generator, 55, 56
derating, 60
efficiency, 58
adaptive charging, 32
air conditioning, 36, 49
alternator, 30, 50
efficiency, 50
engine hours, 50
battery
absorption time, 28
AGM, 13
bow thruster battery, 29, 32
capacity, 44, 56, 62, 67
capacity and discharge time, 15, 22
capacity and temperature, 16
charge efficiency, 21
charge voltage, 28
corrosion, 11
cost, 14
cycling, 17
diffusion, 24
diffusion process, 11
dimensions and weight, 15
energy efficiency, 21
equalizing, 26
flat-plate automotive, 12
float voltage, 28
flooded, 12, 20
gassing, 18, 26
gassing voltage, 20
gel, 13
lead-antimony, 12
lead-calcium, 12
overcharging, 18, 28
rapid discharging, 15, 22
self-discharge, 19
shedding, 11
specific gravity, 20
spiral cell, 13, 25
starter battery, 29, 31
stratification, 12, 18
sulphation, 12, 17, 18
temperature, 18
temperature compensation, 27
thermal runaway, 27
traction or deep-cycle, 12
tubular plate, 12
undercharging, 18
venting, 25
VLRA, 25
VRLA, 12
water / gas per Ah, 26
battery capacity
usable capacity, 44
battery charger, 32
adaptive charging, 32
BatterySafe mode, 33
BatteryStorage mode, 33
charging more than one bank, 33
battery charging, 24
absorption, 24
absorption time, 28
bulk, 24
float, 25
float voltage, 28
overcharging, 28
battery monitor, 20
BatterySafe mode, 33
BatteryStorage mode, 33
Coefficient of Performance, 35
cooking, 38
DC concept, 40, 45
DC generator, 41, 57
dishwasher, 37, 54
diving compressor, 38
efficiency
AC generator, 58
alternator, 50
electric stove, 37, 54
energy, 34
14 kWh per day, 52
240 kWh per day, 66
4 kWh per day, 47
48 kWh per day, 61
diesel fuel, 15
water, 15, 54
energy consumption
air conditioning, 36, 49
bow thruster, 37
dishwasher, 54
diving compressor, 38
electric stove, 37, 54
electric winch, 37
freezer, 35
hot water kettle, 54
microwave oven, 49
refrigerator, 35
washing machine, 37, 54
water maker, 49
windlass, 37
freezer, 35
frequency converter, 56
generator free period, 41
heat pump, 35
hydrometer, 20
inrush current of 3-phase electric motor, 38
inverter
parallel connected, 10, 41
microwave oven, 49
Multi, 10, 41, 56
PowerControl, 41
MultiPlus, 10
PowerAssist, 43
multistep regulator, 31
Peukert, 22
power, 34
PowerAssist, 10, 43, 57, 69
PowerControl, 10, 42, 57
refrigeration, 35
refrigerator, 35
shore power, 43, 45, 51
DC-concept, 45
frequency and voltage conversion, 46
reducing peak power needed, 45
solar energy, 50
© Victron Energy
71
variable frequency drive, 38
washing machine, 37, 54
water generator, 51
72
water maker, 49
wind generator, 51
© Victron Energy

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Key Features

  • Pure sine wave output
  • 500W continuous power
  • Compact size
  • Built-in protection
  • Remote control capability

Frequently Answers and Questions

What are the advantages of a pure sine wave inverter?
A pure sine wave inverter provides cleaner power than a modified sine wave inverter, which is essential for sensitive electronics that can be damaged by distorted waveforms.
How much power can this inverter handle?
This inverter has a 500W continuous power output, but it can also handle short-term power surges up to 1000W.
Can I use this inverter for my home appliances?
Yes, this inverter can power a wide range of household appliances, as long as they do not exceed the inverter's power rating.

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