1
THYRO-P
THYRISTOR-LEISTUNGSSTELLER / THYRISTOR POWER CONTROLLER
KOMMUNIKATIONSFÄHIG / COMMUNICATION CAPABLE
October 2014
8000003232 DE/EN - V9
2
1
THYRO-P
THYRISTOR-LEISTUNGSSTELLER / THYRISTOR POWER CONTROLLER
KOMMUNIKATIONSFÄHIG / COMMUNICATION CAPABLE
October 2014
8000003232 DE/EN - V9
2
SAFETY INSTRUCTIONS
THE SAFETY INSTRUCTIONS AND OPERATING MANUAL ARE TO BE CAREFULLY
READ PRIOR TO INSTALLATION AND COMMISSIONING.
OBLIGATION TO GIVE INSTRUCTIONS
The following safety and operating instructions must be carefully read before assembly, installation
and commissioning of Thyro-P by those persons working with or on Thyro-P.
These operating instructions are part of the Power Controller Thyro-P.
The operator of this device is obliged to provide these operating instructions to all persons
transporting, commissioning, maintaining or performing other work on the Thyro-P without any
restrictions.
In accordance with the Product Liability Act, the manufacturer of a product has an obligation to
provide explanations and warnings as regards:
• the use of the product other than for the intended use,
• the residual product risk and
• operating error and its consequences.
The information given below must be understood in this respect. It is to warn the product
user and protect him and his systems.
PROPER USE
• The Thyristor Power Controller is a component which may only be used for control and regulation
of electrical energy in industrial alternating current or 3-phase networks.
• The Thyristor Power Controller may at maximum be operated using the maximum admissible
connected load according to information on the type plate.
• The Thyristor Power Controller may only be operated in connection with a suitable and series
connected power supply disconnecting device.
• As a component the Thyristor Power Controller is unable to operate alone and must be projected
for its intended use to minimize residual risks.
• The Thyristor Power Controller may only be operated in the sense of its intended use; otherwise,
personal hazards (for instance electrical shock, burns) and hazards for systems (for instance overload) may be caused.
RESIDUAL HAZARDS OF THE PRODUCT
• Even in case of proper use, in case of fault, it is possible that control of currents, voltages and
power is no longer performed in the load circuit by the Thyristor Power Controller.
In case of destruction of the power components (for instance breakdown or high resistance), the
following situations are possible: power interruption, half-wave operation, continuous power flow.
If such a situation occurs, then load voltages and currents are produced from the physical dimensions of the overall power circuit. It must be ensured by system design that no uncontrolled large
currents, voltages or power results. It is not possible to totally exclude that during operation of
Thyristor power controllers other loads show abnormal behavior. The physically determined
network reactions, depending on the operating mode, must be considered.
DANGER OF ELECTRIC SHOCKS
Even if the Thyristor Power Controller is not triggered, the load circuit is not disconnected from the
mains.
It is possible to safely disconnect the Thyristor Power Controller as under IEC 60950
3
MALOPERATION AND THE RESULTS
With maloperation, it is possible that power, voltage or current levels which are higher than planned
reach the Thyristor Power Controller or load. On principle, this can lead to the Power Controller or
load being damaged. It is important that preset parameters are not adjusted in any way that may
cause the Power Controller to overload.
TRANSPORT
Thyristor Power Controllers are only to be transported in their original packaging (protection
against damage, e.g. due to impact, being knocked, soiling).
INSTALLATION
• If the Thyristor Power Controller is brought into the operations room from a cold environment,
moisture can occur. Prior to it being commissioned, the Thyristor Power Controller must be
absolutely dry. For this reason, wait for a minimum period of two hours before commissioning.
• Install the device upright.
CONNECTION
• Prior to connection, it must be ensured that the voltage information on the type plate corresponds with the mains voltage.
• The electrical connection is carried out at the designated points with the required cross section
and the appropriate screw cross sections.
OPERATION
• The Thyristor Power Controller may only be connected to the mains voltage if it has been ensured
that any hazard to people and system, especially in the load section, has been eliminated.
• Protect the device from dust and moisture.
• Do not block vents.
MAINTENANCE, SERVICE, MALFUNCTIONS
The icons used below are explained in the chapter safety regulations.
CAUTION
Should smoke, smell or fire occur the Power Controller must be disconnected from the mains
immediately.
CAUTION
For maintenance and repair work, the Power Controller must be disconnected from all external voltage sources and protected against restarting. Make sure to wait minimum 1 minute after switch-off
(discharge time of the attenuation capacitors). The voltage-free state is to be determined by means
of suitable measuring instruments. This work is only to be carried out by a skilled electrician. The
electrical regulations which are locally valid are to be adhered to.
CAUTION
The Thyristor Power Controller contains hazardous voltages. Repairs may generally only be performed by qualified and trained maintenance personnel.
4
CAUTION
Hazard of electrical shock. Even after disconnection from the mains voltage, capacitors may still
contain a dangerously high power level.
CAUTION
Hazard of electrical shock. Even when the Thyristor Power Controller is not triggered, the load
circuit is not disconnected from the mains.
ATTENTION
Different components in the power section are screwed in place using exact torques. For safety
reasons, power components repairs must be performed by Advanced Energy Industries GmbH.
5
TABLE OF CONTENTS
Safety instructions
List of illustrations and tables
Safety regulations
Remarks on the present operating instructions and Thyro-P
2
7
8
11
1.Introduction
1.1 General
1.2 Specific characteristics
1.3 Type designation
13
13
13
14
2.Functions
2.1 Operating modes
2.2 Set point control characteristic
2.3 Control types
2.3.1 Controlled value
2.4Indications
2.4.1 LED indications
2.4.2 Relay indications K1-K2-K3
2.5Monitoring
2.5.1 Monitoring of mains voltage
2.5.2 Load monitoring
2.5.2.1 Absolute value monitoring current
2.5.2.2 Relative monitoring
2.5.2.3 Overview monitoring
2.5.3 Fast current monitoring
2.5.4 Fan monitoring
15
15
16
19
19
20
20
20
21
21
22
22
22
25
25
26
3. Operation
3.1 Local operating and control unit LBA-2
3.2 LBA-2 tool
3.3 Cabinet installation kit (SEK)
3.4 Thyro-Tool Family
3.5 Error acknowledgement / Data logger
3.6 LBA-2 menu structure
27
27
31
36
36
37
40
4.
45
45
45
46
46
46
46
47
47
47
47
48
50
51
53
54
External connections
4.1 Power supply for Thyro-P
4.2 Power supply for the control device A70
4.3 Power supply for the ventilator
4.4RESET
4.5 Controller inhibit
4.6QUIT
4.7 Set point value inputs
4.8 ASM input
4.9 dASM input – dASM output
4.10 Analog outputs
4.11 Current transformer
4.12 Voltage transformer
4.13 Other connections and terminal strips
4.14Synchronization
4.15 Component mounting diagram control device
5.Interfaces
5.1 RS232 interface
5.2 Fiber optic interface
5.2.1 Fiber optic distribution system
55
56
57
57
6
5.3 Bus interfaces (optional) 60
6.
Mains load optimization for operating mode TAKT
6.1. dASM mains load optimization
6.2 SYT-9 procedure
6.3 Software synchronization
6.3 ASM procedure (patented)
61
61
67
67
68
7.
Mains load optimization VSC
69
8.
Connecting diagrams
71
9.
Special Remarks
9.1Installation
9.2 Protection against contact IP20
9.3Commissioning
9.4Service
9.5 Checklist
79
79
79
80
80
80
10.
Type Overview 10.1 Type range 400 Volt
10.2 Type range 500 Volt
10.3 Type range 690 Volt
82
82
83
85
11. Technical data
86
12. Dimensional Drawings
90
13. Accessories and Options
103
14. Approvals and Conformities
104
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LIST OF ILLUSTRATIONS AND TABLES
Fig. 1 Fig. 2 Fig. 3 Fig. 4 Fig. 5 Fig. 6 Fig. 7 Fig. 8 Fig. 9 Fig. 10 Fig. 11 Fig. 12 Fig. 13 Fig. 14 Fig. 15 Fig. 16 Fig. 17 Fig. 18 Fig. 19 Fig. 20 Fig. 21 Fig. 22 Fig. 23 Fig. 24 Fig. 25 Fig. 26 Fig. 27 Fig. 28 Control characteristic for U control
Total set point
Switch-on fault bridging
Absolute value monitoring
Relative monitoring
Start screen LBA-2
Main menu LBA-2 (sample)
Example entries LOG file
Access levels
Language selection
Folder selection
Calendar navigation
Calendar navigation with no LOG files found
Standard zoom keys
Y scaling panel
Value panel
Event panel details
Example calendar
Example for user interface Thyro-Tool Family
Component mounting diagram control device
Interfaces of Thyro-P
Connection of a PC to Thyro-P via RS232
X10 allocation
Signal converter RS232 / fiber optic
Schematic diagram fiber optic Thyro-P with LLV and PC
Wiring of the dASM signal cables
LEDs on the RJ45 connectors
ASM wiring
17
18
21
22
22
27
28
29
30
33
33
33
33
34
34
35
35
35
36
54
55
56
57
58
59
62
62
68
Tab. 1 Tab. 2 Tab. 3 Tab. 4 Tab. 5 Tab. 6 Tab. 7 Tab. 8 Tab. 9 Tab. 10 Tab. 11 Tab. 12 Tab. 13 Tab. 14 Tab. 15 Tab. 16 Tab. 17 Tab. 18 Tab. 19 Behavior in case of load change
Partial load breakdown with heating elements switched in parallel, undercurrent, relative monitoring
Partial short-circuit with heating elements switched in series, overcurrent, relative monitoring
Overview monitoring
Error and data logger messages
LBA-2 menu structure
Terminal strip X1
RESET
Controller lock
QUIT
Current transformer
Voltage transformer
Voltage measurement jumper
Terminal strip X2 for K1, K2, K3
Terminal strip X5 in the control device
Terminal strip X6
Terminal strip X7
Synchronization jumper
Fiber optic distances
20
23
24
25
39
40
45
46
46
47
48
50
50
51
52
52
53
53
58
8
SAFETY REGULATIONS
IMPORTANT INSTRUCTIONS AND EXPLANATIONS
Operation and maintenance according to regulation as well as observance of the listed safety
regulations is required for protection of the staff and to preserve readiness to operate. Personnel
installing/uninstalling the devices, commissioning them, operating them, maintaining them must
know and observe these safety regulations. All work may only be performed by specialist personnel
trained for this purpose using the tools, devices, test instruments and consumables provided for
this purpose and in good shape.
In the present operating instructions, important instructions are marked using the terms
„CAUTION“, „ATTENTION“ and „REMARK“ as well as using the icons explained below.
CAUTION
This instruction shows work and operating procedures to be observed exactly to exclude hazards
for persons.
ATTENTION
This instruction refers to work and operating procedures to be observed exactly to avoid damage
or destruction of Thyro-P or parts thereof.
REMARK
This is where remarks about technical requirements and additional information is given, which the
user has to observe.
ACCIDENT PREVENTION RULES
The accident prevention rules of the application country and the generally applicable safety
regulations must be observed in any case.
CAUTION
Before starting any work on Thyro-P, the following safety regulations must be observed:
• switch voltage-free,
• secure against switching on,
• determine if it is voltage-free,
• ground and short-circuit it,
• cover or block neighboring parts under voltage.
QUALIFIED PERSONNEL
Thyro-P may only be transported, installed, connected, commissioned, maintained and operated
by specialists in command of the respective applicable safety and installation regulations. All work
must be monitored by the responsible specialist personnel. The specialist personnel must be
authorized for the work required by the person responsible for the safety of the system.
Specialists are persons who
- have received training and have experience in the respective field of work,
- know the respective applicable standards, regulations, terms and accident prevention rules,
- have been familiarized with the function and operating conditions of Thyro-P,
- are able to detect and avoid hazards.
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WORK OBSERVING SAFETY REGULATIONS
Before removing safety installations for performance of maintenance and repair work or other work,
measures due to operation must be initiated.
Work observing safety regulations also means to point out faulty behavior to colleagues and to
notify the office or person responsible about defects detected.
INTENDED USE
CAUTION
The Thyristor Power Controller may only be employed in the sense of its purpose of use (see the
section of the chapter safety instructions under the same name), otherwise hazards for persons (for
instance electrical shock, burns) and systems (for instance overload) may occur.
Any unauthorized reconstruction and modification of Thyro-P, use of spare and exchange parts not
approved by Advanced Energy Industries as well as any other use of Thyro-P is not allowed. The
person responsible for the system must ensure that
- hints on safety and operating instructions are available and observed,
- operation conditions and specifications are observed,
- protective installations are used,
- required maintenance work is performed,
- maintenance personnel are immediately notified or Thyro-P is immediately put out of commission
if abnormal voltages or noises, higher temperatures, vibrations or similar occur to determine the
causes.
These operating instructions contain all information required by specialists for use of Thyro-P.
Additional information and hints for unqualified persons and for use of Thyro-P outside of industrial
installations are not contained in these operating instructions.
The warranty obligation of the manufacturer applies only if these operating instructions are observed.
LIABILITY
In case of use of Thyro-P for applications not provided for by the manufacturer, no liability is
assumed. The responsibility for required measures to avoid hazards to persons and property is
borne by the operator respectively the user. In case of complaints, please immediately notify us
stating:
- type name,
- production number,
10
- objection,
- duration of use,
- ambient conditions,
- operating mode.
GUIDELINES
The devices of the type range Thyro-P conform to the currently applicable EN 50178 and
EN 60146-1-1.
The CE mark on the device confirms observation of the general EG guidelines for 2006/95/EC
(LVD) – low voltage and for 2004/108/EC (EMC) – electromagnet compatibility, if the instructions on
installation and commissioning described in the operating instructions are observed.
Regulations and definitions for qualified personnel are contained in DIN 57105/VDE 0105 Part 1.
Safe isolation to VDE 0160 (EN 50178 Chapter 3)
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REMARKS ON THE PRESENT OPERATING INSTRUCTIONS AND THYRO-P
VALIDITY
These operating instructions refer to latest technical specification of Thyro-P at the time of publication and are for information purposes only. Every effort has been taken to ensure the accuracy of
this specification, however, in order to maintain our technological lead and for product enhancement, we are continually improving our products which could, without notice, result in amendments
or omissions to this specification. Advanced Energy Industries cannot accept responsibility for
damage, injury, loss or expenses resulting therefrom.
HANDLING
These operating instructions for Thyro-P are organized so that all work required for commissioning,
maintenance and repair may be performed by corresponding specialist personnel.
If hazards to personnel and property cannot be excluded for certain work, then this work is marked
using certain icons. The meaning of these icons may be found in the prior chapter safety regulations.
ABBREVIATIONS
In this description, the following specific abbreviations are used:
AEI
dASM ASM LBA-2
LBA
SEK
LL
LLS
LLE
LLV.V
LLV.4
MOSI SP SYT =
Advanced Energy Industries GmbH
=
digital mains load optimization, dynamic
= automatic synchronization in multiple power controller applications
(dynamic mains load optimization, not for new installations)
=
Local operating and display unit with touch display
=Local operating and display unit (not for new installations)
=
cabinet installation kit
=
fiber optic
=
fiber optic transmitter
=
fiber optic receiver
=
fiber optic distribution supply
=
fiber optic distribution, 4-fold
=
heating system for molybdenum discilicide
=
set point
=
synchronized clock
WARRANTY
Customer shall provide written particulars, enclosing the delivery note, within 8 working days to
Advanced Energy Industries on becoming aware of any defects in the goods during the Warranty
period and shall use
its best endeavors to provide Advanced Energy Industries with all necessary access, facilities and
information to enable Advanced Energy Industries to ascertain or verify the nature and cause of the
defect and carry out its warranty obligations.
If goods are found not to be defective or if any defect is attributable to Customer’s design or
material in operation of the goods, Advanced Energy Industries will levy a testing charge and where
relevant will return the
goods to Customer at Customer’s expense, and shall be entitled to payment in advance of the
whole testing and transport charge before such return.
Advanced Energy Industries accepts no liability for defects caused by the Customer’s design or installation of the goods; or if the goods have been modified or repaired otherwise than as authorized
12
in writing by Advanced Energy Industries; or if the defect arises because of the fitting of the goods
to unsuitable equipment.
Advanced Energy Industries will cancel all possible obligations incurred by Advanced Energy Industries and its dealers, such as warranty commitments, service agreements, etc., without prior notice
if other than original AEI spare parts or spare parts purchased from Advanced Energy Industries are
used for maintenance or repair.
CONTACT
TECHNICAL QUERIES
If you have any technical queries regarding the subjects dealt with in these operating instructions,
please get in touch with our team for power controllers:
Phone: +49 (0) 2902 763 -520 or
Phone: +49 (0) 2902 763 -290
powercontroller@aei.com
COMMERCIAL QUERIES
If you have any commercial queries on power controllers, please get in touch with:
Phone: +49 (0) 2902 763 -558
powercontroller@aei.com
ADDRESS
Advanced Energy Industries GmbH
Branch office Warstein-Belecke
Emil-Siepmann-Straße 32
D-59581 Warstein
Phone: +49 (0) 2902 763-0
INTERNET
Further information on our company or our products can be found on the internet under
www.advanced-energy.com
COPYRIGHT
Passing on, duplication and/or takeover of these operating instructions using electronic or mechanical means, even in excerpts, is subject to express prior written approval of Advanced Energy
Industries.
© Copyright Advanced Energy Industries. All rights reserved.
COPYRIGHT NOTICE
Thyro-P is an internationally registered trademark of Advanced Energy Industries.
Windows and Windows NT are registered trademarks of Microsoft Corporation.
All other company and product names are (registered) trademarks of their respective owners.
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1. INTRODUCTION
For transport, assembly, installation, commissioning, operation and decommissioning, the safety
instructions contained in these operating instructions must be applied in any case and made
available to all persons handling this product.
CAUTION
It is important that preset parameters are not adjusted in any way that may cause the Power Controller to overload. In case of uncertainties or missing information, please contact your supplier.
1.1 GENERAL
Thyro-P is a communication enabled SCR thyristor power controller. Below, it is also referred to
simply as power controller. The Thyro-P power controller can be installed everywhere where voltages, currents or power have to be controlled precisely in 1- or 3-phase networks. Several modes of
operation and control, good coupling ability to process and automation technology, high control
precision by application of a 32 bit processor and simple handling ensure that Thyro-P is also suitable for new applications.
Thyro-P offers new ways for mains load optimization:
• In operating mode TAKT, the optional digital mains load optimization of dASM ensures that multiple power controller applications can be used in an optimal way for the network so that system
perturbations are mainly avoided.
• For applications which have to use phase angle firing due to required high dynamic, Thyro-P...VSC
offers to minimize significantly harmonics by its VSC technology.
Thyro-P is suitable in particular for
• direct supply of ohmic loads
• for loads with large Rhot/Rcold ratio
• as primary power controller for a transformer with subsequent load
Due to use of high quality thyristors, the Thyristor Power Controller Thyro-P has a type range
up to 2900A, the nominal design loads reach up to about 2860kW.
1.2 SPECIFIC CHARACTERISTICS
Thyro-P is characterized by a multitude of specific characteristics, for instance:
• easy handling
• menu-driven user interface (options: LBA-2 with touch display, Thyro-Tool Family)
• type range 230-690 Volts, 5-2900A, single, double, triple phase
• broadband power supply AC 200-500V, 45-65Hz
• ohmic load and transformer load
• as well as load with large Rhot/Rcold for 1P and 3P
• soft start function for transformer load
• load circuit monitoring
• automatical rotating field recognition for 2P and 3P
• U, U2, I, I2, P control as well as without control
• operating modes TAKT, VAR, VSC_VAR, SSSD, MOSI (optional sub operating mode of TAKT and
VAR)
• mains load optimization dASM for applications with multiple power controllers in operating
mode TAKT
• control of analog set points or via interfaces
• fiber optic and RS232 interfaces as standard
• electrical separation according to EN 50178 chap. 3
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• Measured values are given at analog outputs
• 4 set point channels incl. motor potentiometer to set parameters
The specific characteristics especially include the following options:
• LBA-2 local touch display with integrated process data recorder of up to 6 channels
• LBA-2 is downward compatible with LBA and can replace it.
• Cabinet installation kit (SEK) for LBA-2 with touch display. The SEK allows the installation of
LBA-2 in cabinet doors. It comes with wiring and installation frame.
• Bus connection via bus adaptor cards to plug into the Thyro-P Power Controller, coupling to
different bus systems, for instance Profibus, other bus systems upon enquiry.
• The PC-Software Thyro-Tool Family for effective commissioning and simple visualization tasks.
Functions are for instance loading, storing, modification, comparing and printing of parameters,
set points and actual value processing, line diagrams of process data (including printing and
storing option), bar diagrams, simultaneous display of process data from different power controllers, simultaneous connection of up to 998 Thyro-P Power Controllers.
• Patented ASM procedure for dynamic mains load optimization. The ASM procedure (automated
synchronization of multiple power controller applications) is used for dynamic mains load optimization. It reacts to changes in load and set point, minimizes mains load peaks and associated mains
feedback. Minimizing of mains load peaks means cost savings in operating and investment cost.
• For new systems it is recommended to use the high performance dASM instead of ASM.
NOTE:
After purchasing Thyro-Tool Family software updates (if available) can be downloaded for free from
our homepage.
1.3 TYPE DESIGNATION
The type designation of the thyristor power controllers are derived from the construction of its
power section:
TYPE RANGE DESIGNATION
FEATURES
Thyro-P
1P1-phase power section,
for single phase operation
2P
2-phase power section
3-phase loads in thress phase economic circuit
(not for phase-angle firing VAR)
3P3-phase power section,
for three phase operation
.P400
Type voltage 230-400 Volt, 45-65 Hz
.P500
Type voltage 500 Volt, 45-65 Hz
.P690
Type voltage 690 Volt, 45-65 Hz
.P ...-0037
Type current 37A (Typecurrent range 5A-2900 A)
.. ...-.... . H
Integrated semi-conductor fuse (all Thyro-P)
.. ...-.... . F
Forced air cooling with integrated ventilators
The complete type range can be found in the TYPE OVERVIEW in chapter 10.
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2. FUNCTIONS
For optimum adjustment to different products and production processes as well as differently
electrical loads, the most favorable operating and control modes may be set according to the
following overview.
2.1 OPERATING MODES
This chapter gives an overview of the different operating modes.
FULL WAVE SWITCH (TAKT)
Depending on the prescribed set point, the
mains voltage is periodically switched. In this
operating mode, almost no harmonics are
created. Whole multiples of the mains periods are switched. The operating mode „full
wave switch“ is especially suited for loads with
thermal inertia. For mains load optimization the
optional feature dASM or the optional ASM
feature (not for new installations) can be used
with this operating mode.
For operating mode TAKT, also SSSD ramp can be used. This is useful in case of switching on a
transformer. The SSSD ramp will only be used once after reset or impulse inhibit.
Key parameters are
TAKT cycle period T0[sec]
Soft-Start SST
[msec]
Soft-Down SDN
[msec]
PHASE-ANGLE FIRING (VAR, WITH 1P AND 3P)
Depending on the prescribed set point, the sine oscillation of the mains voltage is gated using a
larger or smaller control angle a. This operating mode is characterized by high control dynamics.
In operating mode phase-angle firing, it is possible to compensate harmonics of the mains voltage
by using circuit variants (e.g. vector group transformer).
To prevent sudden changes of modulation, SSSD feature can be used. It works as a restrictor for
peaks.
Key parameters are
Soft-Start SST
[msec]
Soft-Down SDN
[msec]
16
SOFT-START-SOFT-DOWN (SSSD)
The operating mode SSSD operated similar to operating mode TAKT. However, it can be used
especially advantageous in operation of large single loads to reduce pulse-shaped mains loads and
therefore to reduce voltage variations. Switching on and off of turn on-time Ts occurs by applying
periods with phase-angle firing (VAR). Please see following diagram.
Key parameters are
TAKT cycle period T0[sec]
Soft-Start SST
[msec]
Soft-Down SDN
[msec]
MOSI operation for 1P and 3P
MOSI is a sub-operating mode of the operating modes TAKT and VAR for sensitive heating materials with a high Rhot/Rcold ratio, for instance molybdenum disilicide. The Power Controller always
starts with phase-angle maximum value and actual value to avoid high current amplitudes during
the heating-up phase and then automatically switches to the set operating mode.
For the sub-operating mode MOSI, the key parameters are:
MOSI:RAMP/ STELL
Rate of angular displacement 1
[°el/s]
Rate of angular displacement 2
[°el/s]
Peak current
I max[A]
MAINS LOAD OPTIMIZATION (WITH dASM OR OPTIONAL ASM PROCESS)
For systems in which several power controllers are employed in full wave switch mode TAKT, it is
possible that individual power controllers are synchronized so that a regular mains load is achieved
by defined switching of the individual power controller. This avoids load peaks by random simultaneous switching of many power controllers and load troughs are filled up. The
upstream transformer and/or the upstream feed point may be designed for a lower load. Besides
savings in investment and operating costs it also results in considerable lower system perturbations.
For new installations the dASM process is recommended due to its quicker and easier handling (see
chapter 6.1).
2.2 SET POINT CONTROL CHARACTERISTIC
The set point control characteristic of Thyro-P may be easily adapted for the control output signal
of the upstream process controller or automation system. All signals customary on the market may
be used. The adaption is made by changing the starting and ending points of the control characteristic. Inverted operation (ending value is smaller than the starting value in voltage or current) is also
possible.
The effective set point is the total set point. It is formed by adding the four set points as shown in
fig. 2.
In the simplest case all the set point values are added algebraically. The prerequisite for a set point
to influence the total set point value is that it must be enabled by the set point Enable Register.
• Set point 1 (X5.2.10 - X5.1.13 ground) 0-20mA default
17
• Set point 2 (X5.2.11 - X5.1.13 ground) 0-5V default
The inputs set point 1, 2 are two electrically equal analogue inputs for current or voltage signals,
with subsequent A/D converter (resolution 0.025% of the final value), and they may be set to the
following signal ranges:
0(4)-20mA (Ri = ca. 250 V / max. 24mA)
0-5
V
(Ri = ca. 8,8 kV / max. 12V)
0-10
V
(Ri = ca. 5 kV / max. 12V)
see ATTENTION
The following table shall be used for the hardware configuration of the set point inputs (see also
FILE COMPONENT MOUNTING DIAGRAM CONTROL DEVICE, figure 10). If the hardware configuration is changed, the Thyro-P parameters must be changed accordingly with the LBA-2 or the
Thyro-Tool Family.
X221 for Set point input 1
JUMPER X221 Signal range
Set point input 1
closed*
0(4) -20mA(X5.2.10)
open
0-5V / 0-10V
(X5.2.10)
X222 for Set point input 2
JUMPER X222 Signal range
Set point input 2
closed
0(4)-20mA (X5.2.11)
open*0-5V / 0-10V
(X5.2.11)
* default
ATTENTION
If the open-circuit voltage of the connected set point exceeds 12V in the 20mA signal range, the
set point inputs can be destroyed, if the belonging JUMPER (X221, X222) is open.
Within the stated input ranges, these values with the control characteristic may be adjusted to any
common signal characteristic.
FIG. 1 CONTROL CHARACTERISTIC FOR U CONTROL
For a set point poti (e.g. 5-10 kV) 5V supply voltage can be taken from terminal X5.2.5 (Ri = 220V,
short-circuit-proof).
18
SET POINT CONTROL CHARACTERISTICS
The set point control characteristic (Fig. 1) of Thyro-P may be easily adapted for the control output
signal of the upstream process controller or automation system. All signals customary on the market
may be used.
The adaption is made by changing the starting and ending points of the control characteristic. Inverted operation (ending value is smaller than the starting value in voltage or current) is also possible.
• Set point 3:
Set point of the superordinate system or PC via RS232 or fiber optic connection (standard) X30, X31
or via the optional bus interface.
• Set point 4:
Set point input (motor potentiometer function) settings as for set point 3 but additionally via LBA-2.
Set point 4 is stored in case of mains failure.
EFFECTIVE TOTAL SET POINT VALUE
The algebraic addition of the results of set point (1,2) to set point 3 and 4 gives the (effective) total
set point value for the set point control characteristic as shown in the following figure.
Set point 1 *
1
X5.2 10
M (5V)
ADD
ST_A ST_E
IADD
X5.1 13
PRO
Set point 2 *
2
X5.2 11
M (5V)
IPRO
ST_A ST_E
X5.1 13
Set point 3
REMOTE
Bus interface or
Fibre optic interface
FIG. 2
TOTAL
SET POINT
Set point
(1, 2)
Set point 4
Motorpoti function
Local operating and
display unit LBA-2 or RS232
* 0 - 5 Volt
0 - 10 Volt
0(4) - 20 mA
4
ADD
Total
set point
within these limits any linear
control characteristic is possible.
Set point
EnableRegister
8
The prerequisite for a set point to influence the total set point value is that it must be enabled by
the set point Enable Register. Set point 1 and 2 can be linked using the following functions. The
result of this link is called set point (1,2).
Set point link
ADD Set point (1,2) = Set point 1 + Set point 2
IADD Set point (1,2) = Set point 1 - Set point 2
_Pro
Set point (1,2) = Set point 1 * Set point 2 [%]
100%
_IPro Set point (1,2) = Set point 1 * (1 - Set point 2 [%] )
100%
VALUE RANGE OF SET POINT (1,2)
For the link result of set point (1,2) the following value range applies:
0 m Set point (1,2) m Set point max (Umax, Imax, Pmax).
19
SET POINT ENABLE REGISTER
The set point Enable Register (AD_P_SW_ENABLE, adr. 94) enables the 4 set points to be shut off
or enabled independently. Only enabled set point inputs are part of the effective total set point
value.
The shut off or inactive set points are shown by the LBA-2 and can thus, if necessary, be checked
before connecting.
The set point Enable Register can be changed from all service units (Bus, Thyro-Tool Family, LBA-2).
Example:
8
1
1
0
0
0
4
1
0
1
0
0
2
1
0
0
1
0
1
1
0
0
1
0
VALUE ABBR.
15
STD
8
LOC
4
REMOTE
3
ANA 0
EXPLANATION
Standard (all ON)
Motor potentiometer set point 4 (LOCAL)
Bus set point 3
Analog-set points 1,2
All set points inactive
2.3 CONTROL TYPES
Thyro-P has five control types effective as underlying controls. Mains voltage variations and load
changes are directly and therefore quickly adjusted by bypassing of the slow temperature control
system.
Before commissioning of the power controller and selection of a control type, you should be
familiar with the operating procedure respectively the effect for application (further see TAB. 1:
BEHAVIOR IN CASE OF LOAD CHANGE in the following chapter).
2.3.1 CONTROLLED VALUE
The controlled value effective on the load is proportionate to the total set point, depending on the
control type:
CONTROL TYPE
P control
U control
U2 control
I control
I2 control
CONTROL VALUE (PROPORTIONATE TO THE TOTAL SET POINT)
output (active) power, P
output voltage, Urms
output voltage, U2rms
output current, Irms
output current, I2rms
LIMITING OF SIGNALS
Independent of the control type set, additionally minimum and maximum limiting values may be
set. For this purpose, also refer to Fig. 1 control characteristic.
The maximum limiting values determine the maximum modulation of the load.
The minimum limiting values should ensure minimum modulation via the control angle (for instance
minimum heating of the load).
20
CONTROLLER RESPONSE
If the load resistance changes, for instance due to temperature effect, ageing or load fault, then the
values (depending on control type) effective on the load change as follows:
LOAD RESISTANCE DECREASES
CONTROLLIMIT
P
LOAD RESISTANCE
INCREASES
ULOADILOADP
EFFECTIVE*
LIMITATIONS
ULOADILOAD
TYPE
UUrms maxlarger=
larger smaller=
smaller
Irms max
U (UxU)
larger smaller=
smaller
Irms maxPmax
2
Urms max
larger=
Pmax
IIrms max
smaller smaller=
larger
larger=
Urms maxPmax
I (IxI)
smaller smaller=
larger
larger=
Urms maxPmax
2
Irms max
PPmax= smaller
larger=
largersmaller Urms maxIrms max
without control
larger
=larger
smaller=
smallerUrms maxIrms max
Pmax
* If
one of the limits is exceeded, then the signaling relay K2 and the LED Limit react
(default values of parameter settings).
General modulation limit
Ts=Ts max
a=amax
TAB. 1 BEHAVIOR IN CASE OF LOAD CHANGE
2.4 INDICATIONS
2.4.1 LED INDICATIONS
The LEDs on the front side signal the following states:
• ON
• CONTROL
• LIMIT
• PULSE LOCK
• FAULT
• OVERHEAT
green:operating indication, power supply controller board
red: RESET active
modulation percentage indication, flashing*
limitation is active, relay K2 switches*
Controller Lock active, but load control is continued at pulse limits
(default value = 0)*
fault present*
overheating of power section
(in case of ..HF types, check ventilator)*
* Default setting
Activation of the integrated semiconductor fuse may be signaled using the fault indicating relay K1
rest current, contactor, otherwise separate supply of the control device required). In case of power
controllers from model current 495A, additional signaling is performed via an indicator at the semiconductor fuse.
2.4.2 RELAY INDICATIONS K1-K2-K3
The Thyro-P power controller is fitted with three relays. Each of these relays has a change over
contact, in principle a value has been allocated in the event register. The default values for
parameter settings are listed in chapter 3.5 ERROR ACKNOWLEDGEMENT / DATA LOGGER.
The connection terminals are specified in chapter 4 EXTERNAL CONNECTIONS.
ALARM RELAY K1
The relay K1 is activated if a fault is detected in the system. The effective direction, whether it
should close or open in case of fault, may be set using the parameter Relay ON at message or
Relay OFF at message by using LBA-2 or Thyro-Tool Family. Which indications lead to switching of
the relay may also be set.
Recommendation: keep the default setting.
21
LIMITING RELAY K2
The relay K2 only closes (in default setting) if at least one of the following values is exceeded:
• 1. max. admissible effective value of the load current
• 2. max. admissible effective value of the load voltage
• 3. max. admissible active power of the load
The relay releases if none of the values is exceeded anymore. It is possible to set which indications
lead to switching of the relay. Recommendation: keep the default setting.
OPTIONAL RELAY K3
If changes are made to the default relay settings due to the application, then preferably the relay
K3 should be re-parameterized.
It is possible to realize functions like for instance a follow-up relay for ventilator control or by pass
the alarm relay at startup of the system. It may also be used as a further alarm relay or limiting relay,
by re-parameterization.
The illustration shows the relay K3 for bridging the startup alarm.
2.5 MONITORING
delay adjustable
(with Thyro-Tool Family: LED/Output: K3/Monoflop time)
FIG. 3 SWITCH-ON FAULT BRIDGING
Faults occurring in the power controller or in the load circuit are signaled (s. error messages of
LBA-2). Signaling is performed via LED Fault and via relay with potential-free change-over contact.
The fault buffer may be read via LBA-2 or the interface after selecting the status line. Simultaneously with the fault signal, the pulse shutdown may optionally also be set (Pulse inhibit On / Off).
The number and content of occurred warnings or errors are shown in the status line of LBA-2 touch
display. By selecting the status line, the message can be retrieved.
2.5.1 MONITORING OF MAINS VOLTAGE
The power controller is equipped with mains voltage monitoring. The limits may be set for U mains
min and U mains max. If limits are reached, a status message will be generated.
22
2.5.2. LOAD MONITORING
It is possible to monitor load by absolute monitoring of heating elements with Rhot/Rcold ≈ 1 and
relative monitoring of heating elements with Rhot/Rcold ≠ 1.
2.5.2.1 ABSOLUTE VALUE MONITORING CURRENT
This function allows monitoring of a freely selectable absolute current limit. The parameters for
the value may be set in ampere.
i
I < threshold
TL
indication 16,17 (Chap. 3.4)
tV
FIG. 4: ABSOLUTE VALUE MONITORING
This absolute value monitoring lends itself to one or more load resistances organized in parallel or
in series. Generally, the effective current value measured is continuously compared with a presettable absolute current limit for undercurrent or overcurrent. If these limits are undercut or exceeded
an indication occurs after Tv =10 mains periods. In case of resistor elements organized in parallel,
it is therefore possible, using the lower current limit, to detect a partial load interruption. Using the
upper current limit, in case of resistors switched in series, short-circuiting of an element may be
detected.
2.5.2.2 RELATIVE MONITORING
This monitoring is sensible if the resistance value of the load slowly changes. Changes in resistance
may for instance be caused by temperature changes or by ageing. The current (b) of the Power
Controller is regarded as 100% load current (current in fault-free state) after activation of the RESET
or CONTROLLER LOCK. The RESET is automatically activated after each startup, restart or after
mains outage. In case of relatively slow changes of the current, due to characteristics of the above
mentioned heating elements, automatic adjustment of the internal reference value to 100% is
performed (b‘).
FIG. 5: RELATIVE MONITORING
Quick current changes, which may for instance occur in case of partial short-circuit, may be
detected by overcurrent monitoring (max., a – a‘).
Quick current changes, which may for instance occur in case of load breakdown may be detected
by undercurrent monitoring (min., c – c‘).
23
NOTE FOR LOAD MONITORING:
Load threshold I
Load threshold U
35LSB
35LSB
If a Thyro-P 3P is used in phase-angle operating mode, the star point of the load and the star point
of the (built-in) voltage transformers should be connected together to ensure an accurate load
monitoring. Please contact us in case of need..
The values in the following table apply to ohmic loads.
Different values apply may be required for specific heating resistors, for instance IR radiators.
The adjustable % values shown in the tables are load current variations on the present operating
values.
NOTE
Values < 10% should be chosen carefully because it
can cause wrong error messages, e.g. due to strong
fluctuations in mains voltage.
Star connection
without neutral conductor
HEATING
ELEMENTS
1P
Delta connection
Star connection
with separate star points
Star connection
with neutral conductor
2P*/3P 3P
IN PARALLEL FOR
EACH STRAND
STAR CONNECTION STAR CONNECTION DELTA
STAR CONNECTION
WITH SEPARATE
WITHOUT CONNEC- CONNECTION WITH CONNECTED
STARPOINTS TED NEUTRAL
NEUTRAL
CONDUCTOR
CONDUCTOR
5
10% 10%
8%
6%
10%
413%
13%10% 7%
13%
317%
17%13%10%
17%
225%
25%20%12%
25%
150%
50%50%21%
50%
* for Thyro-P 2P: additional external converters in phase L2 are possible.
TAB.2 PARTIAL LOAD BREAKDOWN WITH HEATING ELEMENTS SWITCHED IN PARALLEL,
UNDERCURRENT, RELATIVE MONITORING
24
Star connection
without neutral conductor
HEATING
ELEMENTS
1P
Star connection
with neutral conductor
Delta connection
2P* / 3P
3P
IN SERIES FOR
EACH STRAND
STAR CONNECTION
DELTA CONNECTION
WITHOUT CONNECTED
STAR CONNECTION
WITH CONNECTED
NEUTRAL CONDUCTOR
6
10%
7%
6%
5
13%
8%
7%
4
17%
10%
9%
3
25%14%
13%
2
50%25%
26%
NEUTRAL CONDUCTOR
10%
13%
17%
25%
50%
TAB.3 PARTIAL SHORT-CIRCUIT WITH HEATING ELEMENTS SWITCHED IN SERIES, OVERCURRENT, RELATIVE MONITORING
* for Thyro-P 2P: additional external converters in phase L2 are possible.
Thyro-P determines the load conductance separately for each phase. These values are available
from LBA-2, Thyro-Tool Family and the Bus interface. The current resistance can be determined
by reading out and converting from the conductance.
25
2.5.2.3 OVERVIEW MONITORING
The following table offers an overview of the possible monitoring functions of the thyristor power
controller Thyro-P.
TYPE OF
PARAMETER
MONITORING
SETTINGS
Unet max
mains overvoltage
input in volts
Unet min
mains undervoltage input in volts
Iload max-REL
overcurrent
0-100%
overcurrent relative Re: measured load current
after each RESET/control lock
Iload max-ABS
overcurrent
input in ampere
absolute
Iload min-REL
undercurrent
0 to 99%
relative
Re: measured load current
after each RESET/control lock
Iload min-ABS
undercurrent input in ampere
absolute
pulse switch
pulse switch off
ON: pulse switch off after
off by software
fault indication
OFF: in case of fault
K1 alarm relay K1
ON: relay K1 closed-circuit
released in case of fault
OFF: relay K1
pulled-in in case of fault DEFAULT /
REMARKS
Type voltage + 20%
Type voltage - 20%
REL_ABS = REL
UE_S = ON
REL_ABS = ABS
UE_S = ON
REL_ABS = REL
UN_S = ON
REL_ABS = ABS
UN_S = ON
indication is always
issued
in case of synchronization
SYT 9, RESET of all Power
Controllers is required
the alarm relay switches
upon activation of
RESET
TAB. 4 OVERVIEW MONITORING
2.5.3 F
AST CURRENT MONITORING
(„SHORT CIRCUIT MONITORING“)
Each mains half-wave, the measured actual value of current (per regulated phase) will be compared
to an adjustable limit. If limits are exceeded, a status message will be generated. The message is:
I2t current limit is exceeded
The message can be analyzed by the following parameters:
Fast current monitoring L1
[A]
Fast current monitoring L2
[A]
Fast current monitoring L3
[A]
The messages can be analyzed via relay, LED, data logger, pulse switch off (quit the message).
26
2.5.4 FAN MONITORING
The separately ventilated power controllers (-...HF) are fitted with thermal monitoring. The temperature is measured on the heat sink. In case of a temperature overrange, a fault indication is issued:
Unit excess temp.
As a standard the device will be switched off and LED Overheat will be lit.
ATTENTION
When using the device under UL conditions, this feature has to be switched on.
27
3. OPERATION
This chapter presents the operating options of Thyro-P using local operating and display unit LBA-2
and visualization and commissioning software Thyro-Tool Family.
LBA-2
for Thyro-P parameterization and process data
LBA-2 Toolfor visualization /analysis of saved process data and messages of
LBA-2
SEK
for operating of Thyro-P with LBA-2 on cabinet doors
Thyro-Tool Family
for Thyro-P parameterization and process visualization
3.1 LOCAL OPERATING AND CONTROL UNIT LBA-2
The new local display and control unit LBA-2 can be used as a substitute for its predecessor LBA
model and enables easy operation for Thyro-P thyristor power controllers. The LBA-2 is equipped
with a graphic touch display and SD card and is designed to be used either with Bluetooth (model
2.000.000.409) or without Bluetooth (model 2.000.000.408). For both versions the process data
recorder feature is included (see chapter 3.1.5 LINE CHART)
With the menu based graphic user interface, LBA-2 offers an intuitive operating of Thyro-P – if
requested, further information for configuration and parameterization can be seen in the menu
structure table.
If LBA-2 is not in use (parameterized) for a longer duration, the display will dim its brightness.
3.1.1 START SCREEN
Thyro-P
The start screen of LBA-2 is its central display which is the first to see after starting LBA-2. It can be
switched to:
•
Line chart (6 values, optional)
•
Operation display (6 values, optional)
•
Bar chart (4 values, optional)
•
Data logger
The values, which have been selected for the line chart, will be saved as process data on the SD
card by LBA-2. They can be analyzed by the free LBA-2 Tool (see chapter 3.2 LBA-2 TOOL).
The four buttons on the start screen have the following functions:
The house symbol will return the user to the start screen from any submenu.
FIG. 6:
START SCREEN LBA-2
The list symbol will take the user to the main menu of the LBA-2 with further menus to
parameterize and to configure
• LBA-2
• Thyro-P
The OFF button operates as a data backup before shutting down LBA-2.
NOTE
The LBA-2 must be shut down in order to save all settings and data prior to removing
the LBA-2 from the power controller.
By using the logo key, the user can switch between the line chart display, the bar chart
display, the operation display and the data logger.
28
3.1.2 SETTINGS LBA-2
Thyro-P
Thyro-P
FIG. 7: MAIN MENU LBA-2 (SAMPLE)
To change anything on LBA-2, the button SETTINGS in the main menu has to be pressed. By using
the button LBA-2 the following menus will be available:
Settings for LBA-2
• Operation display, bar chart, and line chart settings
• Display settings
• Startscreen
• Languages
• Bluetooth
• Authorization and passwords
• Information about the device
• Address
• Reset to factory settings
3.1.3 SETTINGS THYRO-P
To change anything on Thyro-P, the button SETTINGS in the main menu has to be pressed.
By using the button Thyro-P the following menus will be available:
Settings for Thyro-P
• Operating mode
• Control mode
• Control parameters
• Limits
• Analog outputs
• Setpoint inputs
• Relays / LED / pulse inhibit
• Address
• Hardware
• Monitoring
• Temperature
• Data logger Thyro-P
29
3.1.4 EASYSTART
This menu enables the user to easily adjust the Thyro-P. For details on the EasyStart function and its
selection possibilities, see table LBA-2 MENU STRUCTURE.
When the user first starts LBA-2, the EasyStart will be displayed. Once the EasyStart prompt has
been conducted successfully on LBA-2, it will not appear each time LBA-2 is started. Irrespective of
this, EasyStart can be selected at any time if required via the LBA-2 menu.
3.1.5 LINE CHART / PROCESS DATA RECORDER
The line chart shows up to 6 values. The chronological process of these values is recorded automatically and saved on the SD card (measuring interval is approx. 1sec.). Therefore a process data
recorder is provided to the user with up to 6 channels. The SD card has an amount of memory for
max. 6 channels which lasts approx. 2.7 years. Occurring messages (data logger) will also be saved
on the SD card and can be analyzed by LBA-2 Tool in combination with the saved signal sequence
of the 6 channels. For further details on how to set the line chart, please see table LBA-2 MENU
STRUCTURE.
The values selected for the line chart will be saved in the folder SD-Card:\Log. This is the case when
• the date changes (at 0.00 hours)
• the LBA-2 is switched off via OFF button
When the SD card is full, the oldest data will be deleted first and the current data then saved. The
data names correspond to the date the process data were measured:
The values selected for the line chart (up to six) will be saved on the 4GB SD card, which is included
with delivery under the file named SD-Card:\Log.
FIG. 8: EXAMPLE ENTRIES LOG FILE
Example of LOG file:
131004.LOG
(the process data were measured on October 4th, 2013
NOTE
In the event the LBA-2 is disconnected from the power supply without switching the OFF button
(e.g., when switching off the Thyro-P or when “removing „the LBA-2), the measured process data
will be lost and will not be saved.
3.1.6 LOAD / SAVE DATA
In addition to the process data from the line chart, Thyro-P parameter sets and LBA-2 settings can
be stored on the SD card.
The submenus can be found in table LBA-2 MENU STRUCTURE.
30
Additional parameter sets and configurations can be stored permanently in the EEProm of the
LBA-2.
3.1.7 BLUETOOTH
This option is only available with model no 2.000.000.409. It can be switched on and off in the
submenu of the LBA-2.
It offers a wireless operation of Thyro-P
• Via Thyro-App* (by Android smartphone or tablet PC)
• Thyro-Tool Family (e.g. by laptop and Bluetooth)
*free download from www.advanced-energy.com
As soon as the LBA-2 is connected via Bluetooth using the Thyro-App to a Smartphone or Tablet
PC, or to a PC via the Thyro-Tool Family, the display of the LBA-2 shows a Bluetooth symbol and all
other functions of the LBA-2 will be automatically deactivated. Therefore operations via display and
via Bluetooth are not possible at the same time. Once the Bluetooth connection has ended, the
display of the LBA-2 is active again.
NOTE
When using the Bluetooth feature, all other functions are deactivate except the BLUETOOTH ACTIV SYMBOL – this also applies to the PROCESS DATA recorder.
3.1.8 PASSWORDS / AUTHORIZATION
Thyro-P
Thyro-P
FIG. 9: ACCESS LEVELS
Password Level 1: 160387
Access to parameter settings or EasyStart function
Password Level 2: 311263
Access to detailed parameter settings of the power controller
CAUTION
To avoid unauthorized access, change your password settings the first time you use the LBA-2.
Only 6-digit numerical password combinations are possible!
31
3.1.9 UPLOAD NEW LBA-2 FIRMWARE
This function enables, if required, current LBA-2 firmware to be uploaded (if available).
The software update can be copied by PC or Notebook on to the SD card of the corresponding
LBA-2. Do not open up a new folder on the SD card, but copy the file in the SD card’s root directory and if necessary, replace the existing file. As soon as the SD card is inserted in the LBA-2, and the
latter is inserted into the active Thyro-P, the firmware update will load automatically. A progress bar
will appear that shows the remaining waiting time.
3.1.10 LANGUAGES
In the standard version of LBA-2 are the following languages available: German, English, Chinese,
French, Swedish, Czech, Turkish and Spanish.
The languages can be selected in the LBA-2 menu, see table LBA-2 MENU STRUCTURE.
On request further languages can be implemented.
3.2 LBA-2 TOOL
The LBA-2 Tool (free of charge) offers users to store data on the SD card and to analyze the according process data in combination with data logger entries via PC or Notebook. First the LBA-2 Tool
program must be installed on your PC or Notebook. The LBA-2 Tool can be downloaded from the
AEI website:
www.advanced-energy.com
All downloaded data have to be copied into a directory. LBA-2 Tool.exe starts up the application.
Then the LOG files, in the folder LOG, can be selected and opened by the LBA-2 Tool. To use the
files with LBA-2 Tool, the LOG files can be saved locally on the PC or another medium.
Display of events
Calendar navigation
Y scale panel
Value panel
Zoom & daily
navigation
Select LOG file
Slider
Slider - Labels
Diagram
PDF export
Language selection
32
3.2.1 OVERVIEW
33
3.2.2 LANGUAGES
The languages available in the LBA-2 Tool are German, English, Chinese, French, Swedish, Czech,
Turkish and Spanish.
The language selected for the application changes the language during runtime. The language
selected will be stored in the user’s Windows profile and will be applied again when the program is
restarted.
FIG. 10: LANGUAGE SELECTION
3.2.3 SELECT LOG FILE FOLDER
A folder with valid log files can be selected via the folder selection. Once the folder is selected, it
will be stored in the user’s Windows profile and will be applied again when the program is restarted.
Selecting a folder means that the folder will be scanned and all files opened in order to see whether the log files are valid. If there is no read permission for the folder, no data can be located. Data
that cannot be opened will be ignored. Data that do not have the required log file identification will
be ignored.
FIG. 11: FOLDER SELECTION
3.2.4 CALENDAR NAVIGATION
If no valid log files can be found in the selected folder, Calendar navigation will display crossed out
date values. If valid log files are located, the valid date values will be visible. Dates between the first
and last valid dates, which are invalid will also be crossed out. After selecting a new folder, the last
valid log date will be selected.
When clicking onto a valid date, a diagram from that day will be illustrated.
FIG. 12:
CALENDAR NAVIGATION
FIG. 13:
CALENDAR NAVIGATION WITH NO LOG FILES
FOUND
34
3.2.5 TIME AXIS
STANDARD ZOOM
Once the program has been turned on, each diagram will be displayed with the 24h zoom setting.
This corresponds to the data stored in the log file. By clicking on the other zoom settings, the data
view will be reduced accordingly. With the aid of the displayed scrollbar under the diagram, the
data view can be shifted horizontally along the time axis.
The buttons Back and Next, next to the standard zoom, direct to the previous or following day of
an saved LOG file.
FIG. 14: STANDARD ZOOM KEYS
DETAILED ZOOM
By sliding the mouse horizontally on the diagram, a new X axis view can be selected. Thus you can
zoom in to a one-minute section. The detailed view that is then displayed can be magnified again
only after entering a standard zoom setting.
3.2.6 VALUE AXES
With the Y scaling panel, the axes can be changed for the units (up to 6 values) that appear in the
diagram. By deactivating the AUTO checkbox, the part of the axis that is automatically calculated
can be set by the user. Therefore the displayed area and the resolution of measured signal might be
optimized. The horizontal lines for the main section of an axis can be displayed in the diagram by
the checkbox line.
The settings for the Y axes will be maintained during navigation.
The modification is relevant for all Y axes having the same unit. Several axes with the same unit can
be created, e.g. when two currents are displayed.
FIG. 15:
Y SCALING PANEL
The slider can be used to read values on specific points in the diagram. The slider of the time axis
(X axis) can be set to any position by using the mouse. By clicking with the left side of mouse directly on the slider, it can be moved to another position. When the slider is released, the slider labels
show the values of line chart (color like selected in the relating line chart) and their according units.
With both buttons the slider can be moved either one second to the right or left. Is the slider on
the leftmost or rightmost of the diagram (parking position), then no labels are be shown.
While zooming, the slider maintains its position on the X axis. If, however, the slider is located at
a position on the X axis, which is not a part of the zoomed section, then it will be put into parking
position on the left or right depending on where it was previously located.
35
3.2.7 VALUES DISPLAY
The values display panel can change the appearance of the diagram with regard to the value
sequences. By deactivating the checkboxes, the value sequences can be switched off and with the
help of color settings, the color of the values sequences (bar chart) can be changed.
By pressing the UP and DOWN buttons, the value times series can be displayed as a diagram in an
active drawing layer above or below the other times series.
During navigation the settings for the times series will not be deleted.
FIG. 16:
VALUE PANEL
3.2.8 EVENT REPORTS
Messages can be seen in combination with line chart data when recorded during Thyro-P operation.
FIG. 17:
EVENT PANEL DETAILS
By clicking on the SHOW EVENTS button, the event panel will be displayed. If an error, a warning,
or information event is selected on this panel, it will appear in the diagram as a colored area. The
slider will return to the start of the Event.
If the event does not lie within the zoomed section, the displayed section will be moved accordingly.
Only one event will be displayed at a time in the diagram. If the event panel is closed, the currently
displayed event will also be closed.
3.2.9 PDF EXPORT
By clicking on the EXPORT TO PDF button, the current-status diagram, together with a legend of
the time series, will be saved in a PDF file.
3.2.10 EXAMPLE
TASK
For all production days in September 2013 process data have to be checked for thyristor current
supply of the 10.00 o’clock change of charges.
STEP BY STEP SOLUTION
1. Select the first day of production of the month (13.11.2013) in the calendar.
2. Press the Standard-Zoom-Button 24h to show the whole day.
3. Draw up Detail-Zoom frame
(by using the left side of mouse from approx. 9:45 a.m. to 10.15 a.m.)
4. Check the curve progression
5. By using the NEXT button (right hand side to standard zoom button) the data set of the next
recording day (17.11.2013) can be seen
Repeat 4 and 5 until all production days have been checked. If necessary a PDF can be created.
FIG. 18:
EXAMPLE CALENDAR
36
3.3 CABINET INSTALLATION KIT (SEK)
The cabinet installation kit (optional: model 2.000.000.405) enables the LBA-2 to be mounted on
a cabinet door with a thickness of up to 4mm. It consists of one 96x72mm adapter frame (cut-out
dimensions 92x68mm) and a cable. The LBA-2 is connected to the RS232 interface of the Thyro-P
via the cable. The LBA-2 clicks into the adapter frame and can only be removed when the cabinet
door is open. In this way the technician can set the parameters (e.g. adjustments to retooling)
and manual setpoint setting (motor potentiometer) as well as reading of the actual values without
opening the door.
The SEK offers an operation of Thyro-P with closed cabinet doors.
If the LBA-2 is connected to the power controller via a long cable and cannot be operated, it can
be provided by increase of supply voltage (by opening the R155 wire jumper in the control unit).
WARNING
When the R155 wire jumper is open, the LBA-2 should not be connected to the power controller
without cables (risk of damage). The position of the wire jumper can be seen on the layout diagram
of circuit board of the control unit (see chapter 4).
3.4 THYRO-TOOL FAMILY
Thyro-Tool Family is optional software for commissioning and visualization under Windows 95/98/
NT 4.0/XP and higher. It includes all functions of Thyro-Tool P and it is connected to Thyro-P via
RS232 interface.
Thyro-Tool Family may be employed as an alternative to LBA-2 and as already stated above has the
following functions, for which several windows may be opened simultaneously:
• set point and actual value processing with overview display for 22 set point/actual value input
options for motor potentiometer and total set points.
• loading, storing, modification and printing of parameters
• comparison of parameters
FIG. 19: EXAMPLE FOR USER INTERFACE THYRO-TOOL FAMILY
37
It is possible to compare two sets of parameters (power controller or data file). It is thus possible, to
detect deviations from the desired configuration.
• line diagrams of process data with printing function, as well as storage of faults (diverse measured
values from different thyristor power controllers may be displayed simultaneously).
• bar diagram display
It is possible to simultaneously display several bar diagrams. Each diagram has its own window.
These can be adjusted in size and location. The configuration of the display may be stored.
• simultaneous display of data and parameters from several power controllers
• simultaneous connection of up to 998 Thyro-P power controllers using fiber optic distributors
• settings of the interface (baud rate, com...)
3.5 ERROR ACKNOWLEDGEMENT / DATA LOGGER
Unexpected operation of Thyro-P can be diagnosed by
• LEDs on the front panel of the control device
• comparing parameters with Thyro-Tool Family (where the changed parameters can be listed)
• reading out the error memory of the Thyro-P (data logger) with LBA-2 or Thyro-Tool Family
Errors and messages that occur will be recorded in the status register of the Thyro-P data logger at
the time they occur and will not be lost even after a power failure. Up to 16 entries are possible and
are displayed by LBA-2. If there are further entries, the initial ones will be overwritten, i.e., the 16
most up-to-date events will be accessible.
LBA-2: Data logs
dd.mm.yyyy hh:mm:ss
[Abbreviated error description]
The entries in the data logger are also available after power failure.
38
3.5.1 LBA-2
Thyro-P
DISPLAY OF ERROR MESSAGES
If there are status messages, a red or yellow reference will appear in the LBA-2 status line (see
illustration).
Yellow:
Red:
Status messages / Warnings
Error messages
Incl. further status messages
By pressing the status field, individual events can be displayed on the LBA-2 in the data logger
view. Then previous events can also be seen. Occurring messages, which are recorded by the data
logger, are also secured just like the process data of line chart and are therefore documented. The
number of saved messages is nearly unlimited which can be used for analyzing purposes.
The data logger can also be set up as start screen.
NOTE
If the SD card is removed for analyzing purposes, it is required to shut down the LBA-2 by using the
OFF button.
ACKNOWLEDGE ERROR MESSAGES
Error messages and warning can be reset in the LBA-2 menu (page 2/2: ACKNOWLEDGE ERRORS).
ACTIVATE MESSAGES FOR DATA LOGGER
To activate messages in Thyro-P data logger, they have to be parameterized. This has to done by
the LBA-2 menu:
After selecting menu SETTINGS / THYRO-P (page 3/3) / DATA LOGGER, the messages are shown
in order and can be selected.
3.5.2 THYRO-TOOL FAMILY
Using the Thyro-Tool Family and active line chart, errors and messages that occur will be displayed
in a window and stored on the hard drive as per the line chart. Via a bus interface option (e.g.,
Profibus DPV1, Profinet, Modbus TCP, EthernetIP, Modbus RTU, DeviceNet), a message will be
communicated automatically. As already mentioned, the status messages generated from the
Thyro-P (errors, warnings, messages) refer either to the load or the power controller in the ThyroTool Family. Depending on the application, either warnings or status messages will be displayed.
As a deviation from the default factory setting, all messages can be switched on the data logger, on
the relays and on the LEDs. The default factory settings are as follows:
Thyro-Tool Family
LBA-2
-
X
X
No extension
-
-
X
External error message
-
X
X
External message to forward, e.g. to relay
After reset
-
-
X
Mains failure detection of control device
supply
X
X
X
Controller inhibit is active
-
X
X
All parameters are useless
(factory and customer parameter)
X
X
X
dyn., non regulated values are at limit
X
X
X
Fast current shut-off
-
X
X
Incorrect no. of dASM
devices
-
X
X
Undercurrent in load circuit
X
X
X
Overcurrent in load circuit
X
X
X
i2t current limit is exceeded
-
X
X
-
-
X
Mains failure detection for MOPO feature
Controller inhibit
X
Invalid data in EEProm
Limit
Unit excess temp.
Mains OK
X
X
X
X
X
X
Reset trigger
Communication error
Pulse inhibit
X
LED Overheat
X
LED Fault
-
LED Pulse Lock
Negative power
LED Limit
X
K3
X
-
LED Control Lock
-
-
K2
-
Optical fiber interface active
K1
RS232 interface active
X = Default settings
Data logger
Bus
39
Comments
Test external converter on correct connection
RS232 or fibre optic interfaces,
dyn. Messages
No bus card available
(message after approx. 10sec)
Peak value message U, I
Load monitoring:
Undercurrent message
Load monitoring:
Overcurrent message
Undervoltage at mains input
X
X
X
Mains voltage monitoring L1 / L2 / L3
Overvoltage at mains input
X
X
X
Mains voltage monitoring L1 / L2 / L3
X
X
X
Synchronization error e.g. by soft mains or
wiring error
dASM power threshold is
exceeded
-
X
X
MOSI: Peak current limit
X
X
X
X
X
X
SYNC error
Temperature sensor
Sensor breakage /
short circuit
X
X
TAB. 5 ERROR AND DATA LOGGER MESSAGES
X
X
X
40
3.6 LBA-2 MENU STRUCTURE
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41
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42
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inputs
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analog (10)
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43
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&#!&
*-&#2
$&!(&'
(#&#!
# "&('#&
28#")&(#"+*"'*#"
&
*
28'(("'" "&('#"&
*#$-#-&#2$&!(&.(#"#"&
#$&!(&.(#"(#-&#2+'"'*#"&
&!""( -'*-&#2$&!(&.(#"&#!(#&#!
Acknowledge errors
"#+ #&&#&'"+&""'
27
28
2
TAB. 6 LBA-2 MENU STRUCTURE
''+#& * 7
''+#& * 8
$''+#&$&#(($&!(&
45
4. EXTERNAL CONNECTIONS
This chapter describes external connections of Thyro-P as well as all available terminal strips and
signals as necessary. The connections of the interfaces
• X10
• X30
• X31
• X20
• X40
• X41
RS232 (optional with Bluetooth adapter or LBA-2)
Fiber optic receiver
Fiber optic sender
Bus interfaces
dASM input
dASM output
are described in chapter 5.
Shielded cables grounded on Thyro-P must be used for the connections of control signals (set point
inputs and analogue outputs).
For the connections to RESET, controller inhibit and QUIT, twisted cables must be used.
Bus interfaces can be found in chapter 5 INTERFACES.
To operate Thyro-P at least the following signals described up to chapter 4.6 QUIT must be connected.
4.1 POWER SUPPLY FOR THYRO-P
Details on connecting power supply can be taken from the chapters TECHNICAL DATA and CONNECTING DIAGRAMS. This particularly applies when using the control device in UL applications.
4.2 POWER SUPPLY FOR THE CONTROL DEVICE A70
The Thyristor Power Controller Thyro-P is fitted with a wide-band power supply. The mains connection is designed for input voltages from 230V -20% to 500V +10% and nominal frequencies from
45Hz to 65Hz. The power consumption is max. 30W. Depending on the switch mode power supply,
a 100VA control transformer must be used.
For the type ranges 400V (230-400V) and 500V nominal mains voltage, the control device is supplied directly from the power section. It is therefore a unit ready to connect.
If the power controller is connected to the power supply, for types ranges 230-400V and 500V the
control unit of Thyro-P is therefore already connected to current supply. 1- and 2-phase Thyro-P
units need on A1-X1.3 an additional wiring in accordance to the connecting diagram (chapter 8).
The control device of 690V types has to be feed separately.
TERMINAL STRIP X1
X1
mains supply connected internally
1phase
2
N or phase
TAB. 7 TERMINAL STRIP X1
REMARK
If required, e.g. when operating with Profibus, the control device can also be supplied separately.
With supply voltages outside the nominal range the control device must be supplied separately
with an input voltage within the above-mentioned voltage range. The phase position of this control
voltage is optional. In this case the plug (A70/X1) must be pulled.
46
CAUTION
The pulled plug has mains voltage of the load circuit! The new connecting lines must be fused
according to the applicable regulations (for applicable plug, see chapter 13).
4.3 POWER SUPPLY FOR THE VENTILATOR
With Thyro-P Thyristor Power Controllers furnished with integrated ventilators (HF types), the ventilator must be supplied with a voltage of 230V 50/60Hz according to the connecting plans and the
dimensional drawings. The ventilator’s power consumption is given in chapter 11 TECHNICAL
DATA.
ATTENTION
The ventilator must run when the Power Controller is switched on.
4.4 RESET
The input RESET (terminals X5.2.12-X5.1.14) is separated from the remaining system by an optoelectronic coupler. By opening the RESET jumper the Thyristor Power Controller is locked (load:
24V/20mA), i.e. the power sections are no longer triggered. On activating RESET, LED “ON” lights
up red.
Functional procedure:
TERMINALSFUNCTION
X5.12-14 closed
Enables the device
X5.12-14 openDevice is out of operation, communication via interfaces not possible
TAB. 8 RESET
The hardware RESET must be applied when synchronizing the software of several Power Controllers
(chapter 6.3 SOFTWARE SYNCHRONIZATION). If the Power Controller is equipped with a Bus
option, a Bus RESET also ensues from the hardware RESET. Apart from opening the jumper terminal
X5.2.12-X5.1.14, the hardware RESET is also activated by supply voltage OFF or by reducing the
supply voltage at the Power Controller (A70-X1) to below 160V.
4.5 CONTROLLER INHIBIT
The input controller lock (terminals X5.2.15 and X5.1.14) is electrically identical to the input RESET
(electrical data as under 4.4.).
ATTENTION
When activating controller lock, the LED „PULSE LOCK“ is lit and the control device remains completely in operation. The total set point is therefore without effect, but the min. limiting values (TSMIN, HIME) remain active. This enables securing a certain quantity of electrical energy at the load.
TERMINALSFUNCTION
X5.15-14 closed
power controller operating
X5.15-14 open
control pulses OFF (default value) or pulse limit
TAB. 9 CONTROLLER LOCK
All other functions of the power controller remain in operation. The state of the signalling relay
does not change (parameter-dependent) and communications remains active. After closing the
controller lock jumper, the controller is back in operation.
4.6 QUIT
The input acknowledge (Quit, X5.2.19) has a circuit identical with the input RESET. It must be
47
short-circuited against ground (X5.1.14) so that any faults are acknowledged. The fault signalling
relay is reset. The input must remain closed for at least 2 line periods to perform acknowledgement.
After acknowledgement, the contactor must in turn be opened.
Function:
TERMINALSFUNCTION
X5.19-14 open
controller operating
X5.19-14 closed*
faults are reset
* for at least 2 line periods
TAB. 10 QUIT
If the QUIT contact is reopened the Controller will reassume operation with its preset operating
and control modes as well as its set point and limiting values.
4.7 SET POINT VALUE INPUTS
The set point inputs are described in chapter 2.2. SET POINT CONTROL CHARACTERISTIC.
4.8 ASM INPUT
This input (analogue voltage signal) is for measuring the total current signal of the external resistance. For further details see chapter 6.4 ASM PROCEDURE.
4.9 dASM INPUT - dASM OUTPUT
The connections dASM input (X40) and dASM output (X41) are located at the bottom of Thyro-P
control device and have to be wired only if dASM function is used.
The wiring has to be done with patch cables (Ethernet CAT 5 8-pole) and only for a length of up to
100m between 2 power controllers.
4.10 ANALOG OUTPUTS
The electrical values for current, voltage and power at the load as well as the set point are recorded
by the Power Controller Thyro-P and may be optionally displayed using an external instrument or
logged using a graph recorder.
For connection of external instruments, there are three actual value outputs (terminals X5.2.32,
X5.2.33, X5.2.34, against X5.1.13). The selectable signal levels are 0-10 volts, 0-20mA, 4-20mA or setting different parameters at a maximum compliance voltage of 10V. In case of active ASM procedure, only two of these three analog outputs are freely available (terminal X5.2.32, X5.2.34).
Each output has its own D/A converter. By setting parameters, it is possible to adjust the outputs
to stored-program controls, measuring instruments, etc.
For instance, the following values may be output:
• currents, voltages or power of the individual phases, total power
• minimum or maximum values
• set points
• phase angles
The signals of the analog outputs are updated in each line (VAR) or TAKT period. Actual values
always relate to the previous period. In operation mode VAR at a net period (e.g. 50Hz:20ms) and
in operation mode TAKT at T0 (e.g. 1 sec.). Different factors (e.g. set point variations, load varia-
48
tions, limiting and the influence of operating modes with SSSD and MOSI) give the actual value
signals dynamic rations which can be smoothed with a smoothing stage. The MEAN (VALUE) parameter is applied here. The following setting is recommended: MEAN(VALUE) = 25.
4.11 CURRENT TRANSFORMER
By standard, each power section of the power controller has a current transformer. When using
external current transformers, for instance on the secondary side of a transformer, these must be
connected to the terminals X7.1 and X7.2 and terminated using a load resistor.
Each external voltage transformer must be connected with an load resistor.
CAUTION
Danger of electric shocks.
Current transformers must not be used without load resistors (secondary side), otherwise high
voltages can occur at the terminals.
ATTENTION
Danger of damaging Thyro-P.
Current transformers must not be used without load resistors (secondary side), otherwise high
voltages can occur at the terminals.
The load resistor must be designed so that at nominal current a voltage drop of 0.9 - 1.1Vrms
occurs at the burden resistance.
The value of the used load resistor has to be entered with Thyro-Tool Family or LBA-2 in parameter
U_Load resistor.
REMARK
The internal current transformers of Thyro-P, which are not needed when using external current
current transformers, are jumpered by load resistor R40 on the control boards.
If load current monitoring of the phase 2 (not controlled) is desired for Thyro-P 2P,
then an external current transformer and an external voltage transformer must be provided for
this purpose.
CURRENT TRANSFORMER
phase L1
phase L2
phase L3
TERMINAL X7.2
.11(k)
.21(k)
.31(k)
TERMINAL X7.1
.12(l)
.22(l)
.32(l)
TAB. 11 CURRENT TRANSFORMER
The following parameters must be checked or adjusted:
HARDWARE-PARAMETER
Current transformer ratio ü:1,
e.g. at 100A/5A transformer is ü=20
Type current in A
(Primary current of transformer, e.g. 100A)
UE_I
U_load resistor in V
U_load resistor
(Voltage at load resistor)
LIMITATIONS
Ieff max
A IEMA
xxxx
I_TYP
This is conform to voltage at load resistor at nominal current of transformer.
49
REMARK
Current measuring in not-controlled phases
Thyro-P 2P
Although phase 2 is not controlled in Thyro-P 2P, it is possible to take measuring values during this
phase. A current transformer corresponding to T1 must be used and burdened (see type overview).
It is connected as in table 23 to X7.1.22 – X7.2.21.
Thyro-P 1P
As only phase 1 is controlled with Thyro-P 1P, the measuring systems of phase 2 and 3 can be used
freely. The corresponding current transformers (with max. 1V at nominal current) must be applied
and burdened. Connection is carried out as in table 23 to terminal strips X7.1.22 – X7.2.21 for
“phase 2”, and to X7.1.32 – X7.2.31 for “phase” 3.
The measuring values given do not influence the controller and are available for Bus interfaces,
display and analog outputs. Parameter values must not be changed.
REMARK
Examples on how to calculate the Ohm value of load resistors
Example 1 Thyro-P 1P400-110 H
• the power controller is Thyro-P 1P 400-110H with 110A type current
• the transformer has a transformation ratio of tr = 100:1
The currents of transformer are at nominal current of Thyro-P
• Primary current
Irms primary = 110 A.
• Secondary current Irms secondary = 1.10 A.
The load resistor has to be dimensioned so that the voltage at load resistor is approx. 1Veff (0.9 1.1) at nominal current.
1 Vrms
R burden = ———————
I secondary (of transformer)
e.g.
1 Vrms
R burden = ——————— = 0,909 Ω
1,10 A
It would be ideal to use a load resistor of 0,909 Ω. If a resistor is not available with this value, it is
possible to use a similar resistor. Minimum and maximum value of used resistor are:
0.9 Vrms R burden min = ———————
I secondary (of transformer)
e.g.
0.9 Vrms
R burden min = ——————— = 0,818 Ω
1.10 A
1.1 Vrms R burden max = ———————
I secondary (of transformer)
e.g.
1.1 Vrms
R burden max = ——————— = 1 Ω
1.10 A
After selecting a resistor, which value must be between 0,818 Ω and 1 Ω, the value has to be entered with Thyro-Tool Family or LBA-2 in parameter U_Load resistor.
50
Example 2 Thyro-P 3P400-110 H
• the power controller is a 3-phase power controller of Thyro-P 3P 400-110H with 110A type
current
• three similar current transformers with transformation ratio of tr = 100:1
The calculation and selection of the three similar load resistor has to be done according to
example 1.
After selecting the resistors, which value must be between 0,818 Ω and 1 Ω, the the value has to
be entered with Thyro-Tool Family or LBA-2 in parameter U_Load resistor.
4.12 VOLTAGE TRANSFORMER
As standard, each power section is fitted with a voltage transformer for recording the load voltage.
It is possible to measure voltages of up to 690V. The voltage transformers are wired to the control
device A70 by the works.
LOAD VOLTAGE
phase L1
phase L2
phase L3
TERMINAL X7.2
.15
.25
.35
TERMINAL X7.1
.16
.26
.36
TAB. 12 VOLTAGE TRANSFORMER
In case of the power controller Thyro-P 2P, the voltage transformers output the voltages L1-L2 and
L3-L1. To achieve a good resolution of the voltage measurement, 3 measuring ranges are provided.
Selection of the ranges is performed by means of 4-pin bars, which have been set to the Power
Controller type voltage by the works. The pin bars are found on the control device A70 above the
terminal X7.
MAINSJUMPERS
VOLTAGE
X501, X502, X503
230V
1 - 2
400V
2 - 3
500V respectively 690V 3 - 4
MAX.
MEASURING
253V
440V
760V
TAB. 13 VOLTAGE MEASUREMENT JUMPER
If the jumpers are changed, then a change of parameters is required.
Hardware parameters
Type voltage
U_TYP
U rms max
UEMA
X501-3,1-2,2-3,3-4TYP-BEREICH
Mains voltage
U_NETZ_ANW
(Thyro-Tool Family)
Voltage readings of Thyro-P is equipped with 3 measurement ranges:
1. range: max. 15V (with internal transformer 230V)
2. range: max. 28V (with internal transformer 400V)
3. range: max. 45V (with internal transformer 500V / 690V)
The correct input voltage range (jumper) has to be selected when using an external voltage transformer.
The chosen input voltage range has to be set by Thyro-Tool Family or LBA-2 (Parameter: Voltage
range).
51
Afterwards the voltage transformer ratio Uprimary / Usecondary has to be entered in parameter (Voltage
transformer ratio: UE_U).
Example:
Usage of an external voltage transformer with Uprimary = 500V and U secondary = 25V.
Measurement range 2 will be selected due to Usecondary = 25V.
The following settings are necessary:
- Jumper of measuring channel (X501, X502, X503) to 2-3
- Parameter „Voltage range switchover“ (for LBA-2: „Voltage range“) has to be set to 400V
(for LBA-2: „Voltage range“ to 400V)
- Parameter „Voltage transformer ratio“ to 20 (500V/25V=20)
(for LBA-2: „Voltage transformer ratio“ to 20)
- Parameter „Power controller connection voltage“ (U_Type; for LBA-2: „Type voltage“) to primary
voltage of used transformer (here 500V)
(for LBA-2: „Type voltage“ to the primary voltage of used transformer (here 500V))
REMARK
Voltage readings in not-controlled phases
Thyro-P 2P
Although phase 2 is not controlled with Thyro-P 2P, it is possible to take measuring values during
this phase. The voltage transformer suitable for standard rail assembly (order no. 2000000399) is
to be used. Connection is made as in table 21 to X7.1.26 – X7.2.25. The maximum induced voltage
of the transformer (incl. over-voltage) must be less than 50 volts.
Thyro-P 1P
As only phase 1 is controlled with Thyro-P 1P, the reading systems of phase 2 and 3 can be used
freely. The voltage transformer suitable for rail assembly (order no. 2000000399) is to be used.
Connection is made as in table 23 to terminals X7.1.26 – X7.2.25 for “phase 2” and X7.1.36 –
X7.2.35 for “phase 3”.
The measuring values do not influence the controller and are available for Bus interfaces, display
and analog outputs. Parameter values must not be changed.
4.13 OTHER CONNECTIONS AND TERMINAL STRIPS
ROOT*
BREAK CONTACTCLOSER
Alarm relay K1
X2.7
X2.8
X2.9
Limiting K2
X2.10X2.11X2.12
Option K3
X2.13X2.14X2.15
* tie point
TAB. 14 TERMINAL STRIP X2 FOR K1, K2, K3
X5.1
FUNCTION X5.2FUNCTION
5
+5V 5
+5V
52
13 13 13 13 13 13 21 14 14 14 14 20 ground 5V ground 5V ground 5V ground 5V ground 5V ground 5V +3,3V
ground 24V ground 24V ground 24V ground 24V +24V* 10 11 32 33 34 16 17 12 15 18 19 20 set point 1
set point 2
analog output 1
analog output 2
analog output 3
ASM input
GSE input
RESET
controller lock
SYT9 connection
QUIT
+24V*
* Loading: IX5.1.20 + IX5.2.20 + IX21.9 m max. 80mA
TAB. 15 TERMINAL STRIP X5 IN THE CONTROL DEVICE
Terminal strip X6 in the control device
At the terminal strip X6, wiring between the control device A70 and the control cards A1, A3 and
A5 of the power section is performed by the works. Allocation of the terminal strip is as follows:
X6Name
11 thyristor L1 neg.
12 +5V
13 thyristor L1 pos.
21 thyristor L2 neg.
22 +5V
23 thyristor L2 pos.
31 thyristor L3 neg.
32 +5V
33 thyristor L3 pos.
41 input temperature sensor
42 ground temperature sensor
TAB. 16 TERMINAL STRIP X6
Each thyristor is controlled by 20mA current supply switching to ground.
The ventilator monitor is connected to the terminals X6.41 and X6.42 in separately ventilated
devices (..HF). The temperature of the power section is monitored using a PT 1000 temperature
sensor. In case of overheating of the power section, for instance caused by outage of the ventilator,
a fault indication is generated and the alarm relay is activated (default values). The temperature may
be enquired by the interfaces.
4.14 SYNCHRONIZATION
By standard, each power section is fitted with a transformer for an input voltage of up to 690V.
53
After filtering, the synchronization signal for control of the thyristors is generated from the secondary
voltage. The connections are wired by the works. This includes the following terminals:
TERMINAL STRIP X7
X7.1
12 14 16 22 24 26 32 34 36 X7.2NAME
11 current transformer phase L1
13 sync phase L1
15 load voltage phase L1
21 current transformer phase L2
23 sync phase L2
25 load voltage phase L2
31 current transformer phase L3
33 sync phase L3
35 load voltage phase L3
TAB. 17 TERMINAL STRIP X7
For the synchronization the following jumpers are necessary on the componentry of the control
device.
THYRO-P
1P
2P
3P
SHORT CIRCUIT JUMPER
X507X508
X507
-
-
TAB. 18 SYNCHRONIZATION JUMPER
54
4.15 COMPONENT MOUNTING DIAGRAM CONTROL DEVICE
H104
H105
H106
S102
H102
BR806
V132
V116
BR155
BR155
(Connection for LBA-2)
S101
T101
V114
V112
H103
X10
P7
H401
X700
X701
X702
X707
X706
BR807
H402
X713
X24
G800
X703
H404
V700
H403
X800
X603
K1
X5.1
X602
V600
H405
K2
K3
R101
X508
X507
5
5
for poti, etc.
X509
10
M 5V setpoint 1 13
M 5V setpoint 2 13
11
X510
GND 5V, 0-20mA, 10V 13
32
GND 5V, 0-20mA, 10V 13
33
X201
GND 5V, 0-20mA, 10V 13
34
GND 5V 13
X221
16
-3,3V 21
17
X222
12 GND 24V, open=blocked 14
15 GND 24V, open=blocked 14
M 24V 14
18
V261
GND 24V, short circuit 14
19
+24V 20
V271
20
application reference
signal
R147
V220
pulse lock
controller lock
SYT 9
acknowledgement
+24V output
function
H101
P8
H400
X 5.2
+5V output
setpoint 1
setpoint 2
analog output 1
analog output 2
analog output 3
ASM input
R125
BR808
V281
X501
X502
X503
C137
X30
35
33
31
25
23
21
15
13
11
42
41
33
32
31
23
22
21
13
12
11
36
34
32
26
24
22
16
14
12
X31
X6
X7.1 (-)
X7.2 (+)
External power supply
load voltage L3
sync L3
current transformer L3
load voltage L2
sync L2
current transformer L2
load voltage L1
sync L1
current transformer L1
ground temp. sensor
input temp. sensor
thyristor L3 neg
+3,3V
thyristor L3 pos
thyristor L2 neg
+3,3V
thyristor L2 pos
thyristor L1 neg
+3,3V
thyristor L1 pos
FIG. 20 COMPONENT MOUNTING DIAGRAM CONTROL DEVICE
1
2
X1
55
5. INTERFACES
Necessary process optimization as well as the requirements made of high, continuous and documentable quality in production processes often require the use of digital process communications.
It allows interlinking of many signals and enables their evaluation in an efficient manner.
LBA-2
per RS232
X40 / X41 dASM
FIG. 21 INTERFACES OF THYRO-P
56
With the power controller Thyro-P, the following interfaces may be used for this (see also fig. 11 on
previous page):
• X10, RS232 (optional with Bluetooth adapter or LBA-2)
• X30, fibre optic receiver
• X31, fibre optic transmitter
as well as optional interfaces, for instance
• X20, bus interface, e.g. for Profibus DPV1, Profinet, DeviceNet, Ethernet IP, Modbus RTU or
Modbus TCP
• X40 dASM input
• X41 dASM output
All internally processed data like current, voltage, power, set point value, limitations, etc. may be
enquired, processed and modified during operation (online operation) in master-slave process.
Under assistance of corresponding automation technology, it is possible to do without connection
of process controls, potentiometers, instruments, LBA-2, etc.
The existing interfaces may operate simultaneously, so that for instance the following system
configuration would be possible: a stored-program control via Profibus supplies the set points,
a PC visualizes (fibre optic interface/Thyro-Tool Family) the data and on location the device status
and selected operating values are displayed via LBA-2 (using the RS232).
Therefore, the power controller Thyro-P is transparent to all levels of production and the process
may therefore be securely handled.
5.1 RS232 INTERFACE
The isolated RS232 interface is provided for direct connection of an LBA-2 (with cabinet installation
kit also indirect via cable) or a PC. Setting of parameters of the interface is performed using ThyroTool Familiy or LBA-2. The default baud rate is set to 9600 baud, no parity, 8 data bits, 1 stop bit.
The following illustration shows connection of a Thyro-P to a PC using the RS232 interface (also
possible via fiber optic or Profibus).
RS232
COM 1
or
COM 2
FIG. 22 CONNECTION OF A PC TO
THYRO-P VIA RS232
For connecting the PC, an RS232 cable is required. On the Thyro-P side, a 9-pin sub-D plug and on
the PC side a 9-pin sub-D socket must be available.
57
The connecting socket X10 of the power controller is allocated as follows (1:1 connection):
FIG. 23 X10 ALLOCATION
ATTENTION
The LBA-2 receives its power supply (+5V) via pin 8 of the socket X10. It is imperative that this voltage is not short-circuited. Otherwise, damage to Thyro-P may be incurred.
If a PC is connected to the RS232 interface, then this pin should be left unconnected, since it is not
needed for data transfer.
Generally, all devices with an RS232 interface may communicate with Thyro-P. The protocol used
may simply be created by the user himself.
For this purpose, a detailed description of the protocol used may be requested from Advanced
Energy Industries (refer to application document).
5.2 FIBER OPTIC INTERFACE
This widely used interface (LL, X30 LLE blue, X31 LLS grey) for quick and secure data transfer is
fitted to Thyro-P as standard and enables connection of up to 998 Thyro-P power controllers. Due
to the good interference immunity, larger distances can be bridged and data can be transferred at
higher speeds.
To install a fiber optic system, the following interface components can be used.
5.2.1 FIBER OPTIC DISTRIBUTION SYSTEM
Using the components described below, a complete fiber optic system for connection of up to 998
Thyro-P may be created.
SIGNAL CONVERTER RS232 / FIBER OPTIC
Connection of the fiber optic to the PC interface (RS232) is performed using the fiber optic / RS232
signal converter shown below. Power supply is via the plug-in power supply enclosed.
58
to the plug-in power supply
fiber optic transmitter (LLS) X30
fiber optic receiver (LLE) X31
FIG. 24 SIGNAL CONVERTER RS232/FIBER OPTIC
LLV.V
The fiber optic distributor supply LLV.V is the basic component for the fiber optic system. It serves
to connect star distributors and to amplify the light signals received. Its power supply is sufficient
for supply of five fiber optic distribution components of the type LLV.4.
The amplification of LLV.V in the fiber optic data path is sufficient for increasing the distance for
each LLV.V by about 50 m, so that overall longer transmission paths are possible then.
LLV.4
The fiber optic distributor LLV.4 is connected to the base component LLV.V. It is able to distribute
the optical signal to respectively receive from four connections and therefore multiplies the signal
from the computer to Thyro-P by four units each. The maximum distance from LLV.4 to Thyro-P
should not exceed about 25 m.
In case of optimum installation conditions (number of bends, connection mounting, etc.), the distances stated in the following table may be realized:
DEVICEPC
PC
– –
LLV.V
50 m
LLV.4
––
Thyro-P 25 m
LLV.V
50 m
50 m
50 m
25 m
LLV.4
– –
– –
– –
25 m
TAB. 19 FIBER OPTIC DISTANCES
THYRO-P
25 m
25 m
25 m
––
59
The following figure shows the fibre optic system with LLV, Thyro-P and PC.
FIG. 25 SCHEMATIC DIAGRAM FIBER OPTIC THYRO-P WITH LLV AND PC
60
5.3 BUS INTERFACES (OPTIONAL)
The control device of Thyro-P may be optionally fitted with interface cards, e.g.
- Profibus DPV1
- Profinet
- DeviceNet
- Ethernet IP
- Modbus RTU
- Modbus TCP
All available interface cars support the usage of motor potentiometer feature for set point processing.
If the motor potentiometer feature is not used, signals can be transmitted on three inputs (Input 0,
Input 1 and Input 2) of the bus interface via bus to the higher control system.
Further information are available in the corresponding operating manuals.
Further interface cards are available on request.
61
6. MAINS LOAD OPTIMIZATION FOR OPERATING MODE TAKT
In operating mode TAKT, mains load optimization is possible for multiple power controller applications in the following described ways. The most efficient way is to use the digital and dynamic
dASM process. Furthermore it is possible to use previous dynamic ASM procedure or statistic SYT-9
procedure for mains load optimization. By using mains load optimization there are considerable
advantages: reductions of mains load peaks and reaction shares, smaller design sizes (e.g. of transformer, power supply and other installation) and associated lower operating- and investment costs.
6.1 dASM MAINS LOAD OPTIMIZATION
The complete digital dASM procedure offers the option of dynamic mains load optimization when
multiple Thyro-P power controllers operate in operating mode TAKT.
FOR COMMISSIONING
While being easy to handle, Thyro-P offers the following important advantages with its digital and
dynamic operating mains load optimization:
• Considerable reduction of peaks loads for the mains
• Evenly distributed load for the mains
• Consideration of setpoint changes at mains load optimization
• Consideration of load changes at mains load optimization
NOTE
dASM can be applied whenever multiple Thyro-P power controllers operate together on a common
grid supply in the operating mode TAKT.
OTHER FEATURES
The grid load optimization dASM of the Thyro-P provides the following additional features:
• Grid load optimization for up to 32 Thyro-P power controllers in the operating mode TAKT
• Grid load optimization on the basis of power consumption of the connected loads
• Dynamic grid load optimization, i.e. including the observance of set point- or of the load alterations
• Digital operation and communication
• Grid load optimization of the dASM group within up to circa 5 seconds
• Suitable for 1 or 3 phase applications (Thyro-P 1P or Thyro-P 2P / Thyro-P 3P)
• The simplest dASM wiring with RJ45 patch cables (Ethernet CAT 5 8-pole) with a cable length
between 2 power controllers of up to 100m (depending on surrounding conditions)
• Simple parameterization (only for the master: power limit, number of devices)
• Monitoring of the grid load (power limit)
APPROACH FOR dASM APPLICATION
• In design it is important to ensure an even distribution of the electric load onto the three-phase
system being used.
• Installation, parameterization and initiation of the individual Thyro-P devices in the operating
mode TAKT (with the same TAKT cycle period T0)
• Checking the power wiring is correct for the phases
• Wiring the RJ45 patch cables (Ethernet CAT 5 8-pole) for dASM communication
• Commissioning of the dASM group
Installation der dA
ASM-Steuerlleitungen
62
g auf das dAS
SM Verfahren
n sind ein paa
ar einfache R
Regeln bei de
er elektrischen Installatio
In Bezug
Steuerge
eräte sind zu beachten:
Für
undcontrol
3--phasige
- ofF
Installation
the1dASM
cablesLastten sind getrennte dASM--Gruppen zu verdrahten.
With regards
to the dASM procedure
there
a fewdASM
simple
rules which
need tophasen
be adhered
to am g
- LLeistungsstel
ler und Laste
enare
einer
M-Gruppe
mü
üssen
ngleich
gleichen Netz
when installing
the
control
devices:
a
angeschlosse
en werden.
• For 1 and 3 phase loads separate dASM groups must be wired up.
D
Der Anschlus
errfolgt
an der
Unterseite
Steuergerrätes gemäß
s der
• Power- controllers
and loads
of a RJ45-P
dASM Patchkabel
group must be
connected
to the
same grid de
ines
phase.
n
nachfolgende
en
Abbildung
an
den
Buch
hsen
X41
(Au
usgang)
und
X40
(Eingang):
• The connection of of the RJ45 patch cables (Ethernet CAT 5 8-pole) is made on the underside of
the control device in accordance with the following illustration to connectors X41 (output) and
X40 (input):
L1
L2, N
X41
X40
X41
Abb. 1 Veerdrahtung derr dASM‐Signalleeitungen Unit 1 (M)
Unit 2
X40
Unit 3
FIG.
26 Über
WIRING
OF THEsow
dASM
CABLES
rprüfung
wohl SIGNAL
der RJ45
5-Verdrahtung
Zur
als auch de
er fehlerfrei laufenden
l
dA
ASM-Datenü
auf den d
dASM-Steuerrleitungen die
enen die 4 LE
EDs an den RJ45
R
Buchsen
n.
The 4 LEDs
on the RJ45 connectors serve to check the RJ45 wiring as well as that the dASM data
transmissions via the dASM control cables are running smoothly.
LED 1
LED 2
LE
ED 3
LED 4
Abb. 2 LED
Ds an den RJ45 Buchsen FIG. 27 LEDS ON THE RJ45 CONNECTORS
63
The LEDS can be interpreted as follows:
CONNECTOR
LED
X40
1
X40
1
X40
1
X40
1
X40
1
X40
1
X40
2
X40
2
X40
2
COLOUR
STATUS
INTERPRETATION
OFF
A connection to the preceding device (in the
direction of the master) is in place
FLASHING
Not all data could be sent to the preceding (in
the direction of the master) device (dynamic
communication error)
If LED 3 is also flashing then a ring has been
made with the RJ45 cables
yellow
There is no RJ45 cable connected
ON
green
Connector incorrectly connected
(the RJ45 cable is not inserted into X41 of the
preceding Thyro-P)
OFF
An incorrect cable was used (e.g. cross-over
cable instead of the necessary patch cable)
FLASHING
Thyro-P is switched off
ON
Thyro-P is master
Thyro-P is connected to the preceding device (in
the direction of the master)
CONNECTOR
LED
X41
3
X41
3
X41
3
X41
3
X41
3
COLOUR
STATUS
INTERPRETATION
OFF
Connection to the next slave is in place
More than 32 units are connected in the dASM
group
FLASHING
yellow
There is no RJ45 cable connected
ON
X41
3
X41
4
X41
4
X41
4
If LED 1 is also flashing then a ring has been
made with the RJ45 cables (then: no device is
master, no dASM functionality)
Connector incorrectly connected (the RJ45
cable is not inserted into X40 of the preceding
Thyro-P)
An incorrect cable was used (e.g. cross-over
cable instead of the necessary patch cable)
green
OFF
No additional units are connected
FLASHING
The additional units form their own group
ON
Additional units are in the same group
64
Installation of the power units for dASM operation
Amongst other things the following points are important for successful installation of dASM grid
load optimization
• Power/grid connection of all power controllers to be executed in phase
(see the diagrams of the following examples 1, 2, 3).
• dASM control cable connection (RJ45 patch cable) running from dASM master to the final Thyro-P
unit (see the diagrams of the following examples 1, 2, 3)
L1
L2, N
Installations examples
Example 1
This diagram shows 3 one phase Thyro-P
power controllers with in phase grid connection, connected to 2 phases of a three-phase
network or a single-phase network, along
with dASM wiring. The dASM grid load optimization is operating on the example with all
connected and switched on Thyro-P units 1-3.
dASM group of unit 1 (M): 3 x Thyro-P
The device labelled unit 1 is operating in this
configuration as the dASM master of dASM
group 1. In total the dASM group can consist
Unit 1 (M)
Unit 2
Unit 3
of up to 32 Thyro-P devices. Additional
dASM groups of up to 32 Thyro-P devices operating independently of one another group can be
connected to the same grid so the number of Thyro-P devices which can be operated with dASM
grid load optimization can, in principle, be as large as desired.
Alongside the dASM control cable connection (RJ45 patch cable), which is required for all units, the
power/grid connection, in each case in phase, is a prerequisite for the formation of a dASM group.
X41
X40
X41
X40
L1
L2, N
X41
Unit 1 (M)
X40
Unit 2
X41
X40
Unit 3 (M)
dASM group from unit 1 (M): 2 x Thyro-P
dASM group from unit 3 (M): 1 x Thyro-P
Example 1a
This diagram shows 3 single-phase Thyro-P
power controllers with a grid connection
which is not in phase, connected to 2 phases of an three-phase network, or a singlephase network, also with dASM wiring.
Due to the connection of unit 3 not being
in phase with regards to the preceding
unit 2, unit 3 autonomously forms a new
master (however operates independently
from units 1 and 2). This is why the grid load
optimization in this example only operates
with units 1 and 2, which means that, as a
result of the connection not being in phase,
the switching here, in comparison with the
switching in example 1, does not lead to
optimal grid load optimization.
65
Example 2
In the following diagram 3 dASM groups are connected to the three-phase network with three
single-phase Thyro-P devices each.
L1
L2
L3
X41
Unit 1 (M)
X40
X41
Unit 2
X40
Unit 3
X41
Unit 4 (M)
X40
X41
Unit 5 (M)
X40
Unit 6
RJ 45
patchcable
X41
Unit 7 (M)
X40
X41
Unit 8
X40
Unit 9
Even in a case where patch cables were connected between units 3 and 4, or 6 and 7, this configuration would generate the 3 dASM groups illustrated. This is caused by the varying activation of the
Thyro-P devices in the power grid (unit 3 ≠ unit 4 unit 6 ≠ unit 7).
The first Thyro-P in the dASM group in each case takes on the ʺmasterʺ function for grid load optimization of the dASM group. For an activation unit setup with 3 dASM groups up to 3 X 32 = 96
Thyro-P devices could be connected.
Because as many dASM groups with 32 Thyro-P devices each can be realized for grid load optimization, assemblies which are as large as desired (with as many Thyro-P devices in total as desired)
can be equipped with grid load optimization.
Example 3 shows the following configuration:
dASM group from unit 1 (M): 3 x Thyro-P
dASM group from unit 4 (M): 3 x Thyro-P
dASM group from unit 7 (M): 3 x Thyro-P
Example 2a:
In contrast to example 2 the power wiring of Thyro-P unit 4 is not connected in phase with units 5,
6. This is why, in the diagram which follows, the following configurations have arisen:
dASM group 1:
dASM group 2:
dASM group 3:
dASM group 4:
unit 1 (M): 3 x Thyro-P
unit 4 (M): 1 x Thyro-P
unit 5 (M): 2 x Thyro-P
unit 7 (M): 3 x Thyro-P
L1
L2
L3
X41
Unit 1 (M)
X40
Unit 2
X41
X40
Unit 3
X41
Unit 4 (M)
X40
Unit 5
X41
X40
Unit 6
RJ 45
patchcable
Unit 7 (M)
X41
X40
Unit 8
X41
X40
Unit 9
As a result of the connection not being in phase in this switching arrangement, in contrast with the
switching arrangement from example 2, a suboptimal grid load optimization occurs.
66
Example 3
The following illustration shows a total of 6 power controllers with symmetrical load distribution in a
three-phase network:
4 Thyro-P 2P power controllers
2 Thyro-P 3P power controllers
All ThyroP units in the following diagram are set up with an in phase grid connection.
L1
L2
L3
X41
Unit 1 (M)
X40
Unit 2
X41
X40
X41
Unit 3
X40
Unit 4
X41
X40
Unit 5
X41
X40
Unit 6
The device labelled unit 1 operates in this configuration as a dASM master for all units, as units 5
and 6 are connected in phase with units 1 to 4.
dASM commissioning
To ensure optimal functionality of the dASM grid load optimization the following must be adhered
to when commissioning:
• Check Thyro-P for in phase grid connection
• Check wiring of patch cable
• Select operating mode TAKT (with same TAKT cycle period) for all Thyro-P devices
• Parameterization of the master units:
o dASM NO. OF DEVICES
o dASM POWER THRESHOLD [W]
• Start up of the dASM group (=>switch-on)
dASM notification
The dASM grid load optimization generates the following notifications in the master unit should
errors arise:
• dASM device number is incorrect:
check patch cable connections/parameter dASM device number
• dASM power limit has been exceeded: reduce set points of the assembly as appropriate
The notifications generated can be reported via:
• data logger,
• LED,
• Relay,
• LBA-2 (in preparation) or
• Thyro-Tool Family
ERRORS IN dASM COMMUNICATION
Should the dASM communication become interrupted (for example, an interruption between unit
6 and unit 7) during operation of the assembly e.g. as the result of a cable break or similar, then a
new master is automatically generated in the system beyond the point of interruption during operation – the dASM system continues to run and unit 1 now operates only as a master for units 1-6 and
displays that only 6 units are present in the dASM network. Notification: “dASM device number is
incorrect“.
67
L1
L2
L3
X41
Unit 1
(M)
X40
Unit 2
X41
X40
Unit 3
X41
X40
Unit 4
X41
X40
Unit 5
X41
X40
Unit 6
X41
X40
Unit 7
(M)
X41
X40
Unit 8
X41
X40
Unit 9
X41
X40
Unit 10
Unit 7 now operates additionally as a master for units 7-10.
The quality of grid load optimization of the two now newly formed dASM groups (units 1-6, units
7-10) is of a similar level to the previously formed dASM group units 1-10.
6.2 SYT-9 PROCEDURE
A process for static mains load optimization: minimizes mains load peaks and associated mains
reaction shares. For the SYT-9 process, set points and load changes are not automatically included
in mains load optimization.
The SYT-9 process requires an additional component. For Thyro-P, it should only be employed in
connection with already installed controllers (Thyro-M, Thyrotakt MTL) under SYT-9 process.
Then, the pulse of the SYT card must be connected to the terminal X5.1:18 and ground to X5.1:14.
On the Thyro-P Power Controller, the jumper X201 (behind X5) must be pulled off. For this purpose,
the texts BAL 00180 and operating instructions SYT-9 must be observed as described under Thyro-M.
THYRO-P
SYT9 NO. 1
THYRO-P
SYT9 NO. 1
NO.
NO.
1
X5.2.5- A10
1
X5.2.18- C10
2
- A12
2
- C12
3
- A14
3
- C14
4
- A16
4
- C16
5
- A18
5
- C18
6
- A20
6
- C20
7
- A22
7
- C22
8
- A24
8
- C24
9
- A26
9
- C26
Connection of up to 9 Thyro-P at one SYT9-Module
6.3 SOFTWARE SYNCHRONIZATION
By means of different settings in the storage location SYNC_Adresse, a different startup of the individual power controllers (counter x 10ms) may be achieved. The counter is set to 0 after switching
on the mains or RESET. While the counter is running, the power controller is switched passive, as
during controller lock.
It is possible to enter values in SYNC_Adresse larger than the clock time T0. Then, startup of the
power controller is only during the next clock time. For instance, in an emergency power plant,
slow switching of the total load is possible. The max. delay is 65535 x 10ms. This value also forms
the base setting for the ASM process.
68
6.4 ASM PROCEDURE (PATENTED)
In systems, in which several equal power controllers are operated in the operating mode TAKT, the
ASM process may be sensibly used for dynamic and automatic mains load optimization in multiple
Power Controller applications. This patented world premiere independently minimizes mains load
peaks and therefore mains reaction shares during the current process. In case of the ASM process
(automated synchronization of multiple controller applications), changes in set point and load (for
instance due to temperature-dependent load) are included in mains load optimization online. Especially when using heating elements with a large aging effect, which during new operation have high
current amplitudes with short startup time, lower investment cost may be achieved. For the ASM
process the controller requires an ASM control device. An additional burden resistor is used for all
controllers. Schematic wiring of power controllers for the ASM process can be seen in the following
illustration:
When using the ASM option, the analog output 2 (X5.2.33 against ground X5.1.13) becomes an
output proportionate to the current during the on-period TS. All power controllers connected to
synchronization work on the same external burden. The burden resistor is calculated approximately
as
Rburden [kV] = 10V / (n x 20mA)
n = number of power controller
The burden voltage is measured at the ASM input. The Power Controller searches within the clock
control the place with the lowest mains load.
Due to this automated, independent procedure, the process chain is ensured through the temperature control circuit and the power controller without effects; negative effects like flicker and subharmonics of the mains frequency are balanced out during a current dynamic process. In this case,
unfavorable short-term overlapping may occur, for instance after set point jumps or voltage swing.
The application document ASM-procedure gives further information on this.
Power
Controller 1
X5.2.16
D
A
0-20mA
D
A
Iact. val. 2
Iact. val. 2
A
ASM input
D
ASM input
A
Power
Controller 2
X5.2.33
twisted/shielded
U burden
X5.1.13
total burden
FIG. 28 ASM WIRING
U burden = ( I +...+ I ) x R burden
1
n
U burden = 0 - 10 volts
D
0-20mA
69
7. MAINS LOAD OPTIMIZATION VSC
General
Alongside being highly dynamic, regulated heating processes with power controllers in VSC
connection offer considerable advantages for practical usage in terms of reducing operating costs
through savings in electricity charges. This is a result of
- Considerable reduction in reactive power
- Considerable improvement of power factors
- Significant reduction in grid harmonics.
V1
V2
W1
W2
U1
U2
The Thyro-P…VSC now also provides the user with series power controllers as an option for grid
load optimized, highly dynamic heating processes. Primary or secondary VSC connections in two or
U1
U2 realized.
V1
V2
three stage format
can be
BASIC CONNECTIONS
PRIMARY VSC
Thyro-P
Thyro-P
Transformator
R for large
Netzload cur-rents (e.g. ITransformator
R Last smaller
This Netz
VSC connection
> IController) with
1P...VSC is
2 particularly suitableLast
1P...VSC 3
Load
voltages.
One
transformer
for
each
load.
The
illustrations
show
the
two
and
three
stage
VSC conPrimäre VSC 2-stufig
Primäre VSC 3-stufig
nection. Details can be found in the Thyro-P…VSC connecting diagrams.
*
*
V1
V2
W1
W2
U1
U2
V1
V2
U1
U2
*
Thyro-P
1P...VSC 2
Mains
2-stage VSC (primary)
WARNING
Transformer
U1
U2
V1
V2
R Load
Mains
Thyro-P
1P...VSC 3
3-stage VSC (primary)
Transformer
U1
U2
V1
V2
R Load
As inherent to their functional principle, a higher voltage occurs than the mains voltage at spots
marked with *. The transformer is to be constructed as there are not more than 690 V present.
W1
W2
Otherwise it can lead to considerable damage to the device.
SECONDARY VSC
Trans-
Trans-
Thyro-P
Thyro-P
R Last
Netz
R
Netz
formator
1P...VSC 3 from one transforThis VSC
connection
is particularly
if lots of heaters
are being supplied
formator
1P...VSC 2 suitableLast
mer.Sekundäre
Through
the improvement of the power factorSekundäre
a larger
transformer can dispense more active
VSC 3-stufig
VSC 2-stufig
power and, as such, supply additional loads, if required.
Mains
Transformer
2-stage VSC (secondary)
U1
U2
U1
U2
V1
V2
V1
V2
W1
W2
Thyro-P
1P...VSC 2
R Load
Mains
Transformer
3-stage VSC (secondary)
Thyro-P
1P...VSC 3
R Load
70
OTHER FEATURES
If load monitoring is required with the VSC connection then external converters are needed on the
secondary side.
The wiring required by the type series Thyro-P…VSC is different with regards to both the power
and control connections when compared with standard power controllers from the type series
Thyro-P.
OPERATING WITH LBA-2
To operate the VSC power controllers you need software for the LBA-2 version V1.2. or higher.
If you only have older versions then you can get a free update for the LBA-2 from our support team.
OPERATING WITH THE THYRO-TOOL FAMILY
The Thyro-Tool Family from version 4.06 can be used to operate the VSC power controllers.
If you have already purchased an older version of the Thyro-Tool Family software you can upgrade
the software with a free update from our home page.
OPERATING MODES
The power controllers in the series Thyro-P 1P...VSC only have one operating mode: VSC_VAR
REGULATION MODES
All regulation modes of the Thyro-P are available as regulation modes: U, U², I, I², P.
In primary VSC regulation mode U and U² are less suited.
LOAD MONITORING
For the application of load monitoring external converters are needed for L1 on the secondary side
(also see the Thyro-P VSC connecting diagrams in chapter 8 as well as chapters 4.10 and 4.11 of
operating instructions). The parameters for this can be configured with the Thyro-Tool Family or
LBA-2.
Parameterization:
• Operating mode
• Number of VSC stages
• External converters
• Overlapping*
* Using overlapping parameters
The overlapping process is for linearization of the control characteristic line and can be used on
request. In this case the next higher step will already be activated before full conducting the small
step. The change is only marginal regarding cos phi.
Within a half wave cycle up to 3 thyristor stages can be activated, however, in reality only one is
ever switched on. As such, the advantages of a very good level of efficiency in terms of the thyristor
controllers is retained in full.
71
8. CONNECTING DIAGRAMS
8.1 THYRO-P 1P 1-PHASE POWER CONTROLLER
8.2 THYRO-P 2P 2-PHASE POWER CONTROLLER
8.3 THYRO-P 3P 3-PHASE POWER CONTROLLER
8.4 THYRO-P VSC 2 2-STEP PRIMARY VSC
8.5 THYRO-P VSC 3 3-STEP PRIMARY VSC
8.6 THYRO-P VSC 2 2-STEP SECONDARY VSC
8.7 THYRO-P VSC 3 3-STEP SECONDARY VSC
-X1 2 1
3
4
6
5
230 VAC -20%
to
500 VAC +10%
Input
14
3
4
16
12
X7.1
11
X7.2 15
-X3 5 6 1 2
Power Section Driver A1
X6 11 12 13
2
8
9
10 11 12
K2
K1
X2 7
Limit
Alarm
13 14 15
K3
Option
Relay Outputs
X7.1
X7.2
23
X6 21 22 23
5
X5.1
X5.2 5
5V / 1mA
10
13
11
13
17
5 21
16
13
26
22
X7.1
21
X7.2 25
18
X41 32
RJ45
patch cable
X40
Analog Outputs
(actual values)
Power Section Driver A3
24
Mains Load Optimization
Analog
DC
Inputs Eliminator
Input
#)
#)
(set point)
ASM
SYT9
dASM
Output
dynamic
static
dynamic
Power
Supply
Thyro-P Control Device
13
1
+5V
#1)
X7.1
X7.2
-X2
+5V
Broad band
Power Supply
-X3 3 4
M (5V)
-F3
-R40
Set point 1
M (5V)
Set point 2
-F2
1 -X4
GSE Input
+5V
+3,3V
2
2
ASM Input
M(5V)
-X1
AK
SYT9-Input
G2
dASM-Input
G1
dASM-Output
K
13
Output 1
M (5V)
A1
33
13
Output 2
M (5V)
X1 1
* external fuse is required:
2A slow acting
34
13
Output 3
M (5V)
X50
Control Inputs
12
#2)
14
RESET
M (24V)
PE
15
#2)
14
Controller lock
M (24V)
L2,
N
19
14
QUIT
M (24V)
4
(K2)
(7K)
Output
X5.1
20
X5.2 20
34
X6 31 32 33
Fibre Optic
Connector
X30
X31
System
X10
Connector
for
Connector
BUSfor LBA-2* Interface
or PC **
RS 232
Interfaces
Ohmic Load
Example
A70
X6 41 42
ϑ
Temperature
Sensor
R95
U2
X21 1
2
example: Profibus DP
Bus-Option ***
*
LBA-2, Local Operating & Display Unit
** Thyro-Tool Family Software for PC
*** e.g. Profibus DP, Modbus RTU,
ProfiNet/Ethernet IP/Modbus TCP, DeviceNet
36
32
X7.1
31
X7.2 35
Power Section Driver A5
33
24V / 80mA
Power
Supply
X7.1
X7.2
+24V
2
(G2)
(6G)
+24V
1
(G1)
(4G)
Receiver
3
(K1)
(5K)
X24
-F1
PE
A
Ground M1
L1
3
Input 0 (M1)
Thyro-P 1P
4
Input 1 (M1)
T1
Transmitter
only for HF-types
5
Ground M24
AK
6
Ground M2
V1
7
Input 2 (M2)
K
8
Input 3 (M2)
9
Options
R Load
X20
#) option
Remarks
X7 2 3 230V, 50/60 Hz
+24V
These connections must
be wired by the user
#1) for 690V types: separate power supply is required
all other types: separate power supply is possible
#2) Default setting
U1
72
8.1 THYRO-P 1P 1-PHASE POWER CONTROLLER
#1)
-X1 2 1
3
4
6
230 VAC -20%
to
500 VAC +10%
Input
Broad band
Power Supply
13
14
2
3
4
9
10 11 12
K2
K1
8
Limit
Alarm
13 14 15
K3
Option
Relay Outputs
1 -X4
16
12
X7.1
11
X7.2 15
-X3 5 6 1 2
Power Section Driver A1
X6 11 12 13
-X2 1
-R40
X7.1
X7.2
23
X6 21 22 23
5
X5.1
X5.2 5
5V / 1mA
10
13
11
13
17
5 21
16
13
26
22
X7.1
21
X7.2 25
18
X41 32
RJ45
patch cable
X40
Analog Outputs
(actual values)
Power Section Driver A3
24
Mains Load Optimization
Analog
DC
Inputs Eliminator
Input
#)
#)
(set point)
ASM
SYT9
dASM
Output
dynamic
static
dynamic
Power
Supply
Thyro-P Control Device
X7.1
X7.2
-X3 3 4
X2 7
-F3
-F2
+5V
2
2
+5V
-X1 5
AK
M (5V)
G2
Set point 1
M (5V)
Set point 2
G1
GSE Input
+5V
+3,3V
K
ASM Input
M(5V)
A1
SYT9-Input
PE
dASM-Input
X1 1
* external fuse is required:
2A slow acting
dASM-Output
X50
13
Output 1
M (5V)
-F5
33
13
Output 2
M (5V)
W1
34
13
Control Inputs
12
#2)
14
RESET
M (24V)
L3
15
#2)
14
Controller lock
M (24V)
L2
Output 3
M (5V)
-X1 2 1
3
4
6
-X1 5
19
14
3
(K1)
(5K)
A
X7.1
X7.2
Output
24V / 80mA
X5.1
20
X5.2 20
34
1
2
3
X6 31 32 33
4
G2
G1
-X2
2
(G2)
(6G)
1
(G1)
(4G)
Fibre Optic
Connector
X30
X31
X10
1
System
-X4
T5
A70
X6 41 42
Temperature
Sensor
ϑ
X21 1
2
example: Profibus DP
Bus-Option ***
3
4
5
6
7
8
9
R Load
Example
Ohmic Load
in Star-Connection
R95
W2
U2
*
LBA-2, Local Operating & Display Unit
** Thyro-Tool Family Software for PC
*** e.g. Profibus DP, Modbus RTU,
ProfiNet/Ethernet IP/Modbus TCP, DeviceNet
36
32
X7.1
31
X7.2 35
Connector
for
Connector
BUSfor LBA-2* Interface
or PC **
RS 232
Interfaces
2
-X3 5 6 1 2
-R40
AK
4
(K2)
(7K)
AK
Power Section Driver A5
33
K
V5
K
-X3 3 4
Power
Supply
-F3
-F2
A5
QUIT
M (24V)
4
(K2)
(7K)
+24V
2
(G2)
(6G)
+24V
1
(G1)
(4G)
Receiver
3
(K1)
(5K)
X24
A
PE
-F1
Ground M1
L1
Input 0 (M1)
Thyro-P 2P
Input 1 (M1)
T1
Transmitter
only for HF-types
Ground M24
AK
Ground M2
U1
Input 2 (M2)
V1
+24V
#) option
Remarks
X7 2 3 230V, 50/60 Hz
Input 3 (M2)
Options
X20
These connections must
be wired by the user
#1) for 690V types: separate power supply is required
all other types: separate power supply is possible
#2) Default setting
K
73
8.2 THYRO-P 2P 2-PHASE POWER CONTROLLER
230 VAC -20%
to
500 VAC +10%
Input
13
14
K
1
2
3
4
G2
2
9
10 11 12
K2
K1
8
Limit
Alarm
13 14 15
K3
Option
Relay Outputs
1 -X4
16
12
X7.1
11
X7.2 15
-X3 5 6 1 2
-R40
AK
Power Section Driver A1
X6 11 12 13
-X2
G1
-F3
-F2
23
-X3 3
X7.1
X7.2
A3
1
2
5
X5.1
X5.2 5
5V / 1mA
10
13
11
13
17
5 21
16
13
3
X6 21 22 23
-X2
G1
4
AK
G2
18
X41 32
RJ45
patch cable
X40
2
1
26
22
X7.1
21
X7.2 25
Analog Outputs
(actual values)
13
2
-X3 5 6 1
-R40
4
(K2)
(7K)
2
(G2)
(6G)
AK
Power Section Driver A3
24
4
K
1
(G1)
(4G)
Mains Load Optimization
Analog
DC
Inputs Eliminator
Input
#)
#)
(set point)
ASM
SYT9
dASM
Output
dynamic
static
dynamic
Power
Supply
Thyro-P Control Device
X7.1
X7.2
-X3 3 4
X2 7
-F3
-F2
Broad band
Power Supply
2
X1 1
#1)
-X1 2 1
3
4
A1
+5V
PE
+5V
X50
M (5V)
-F5
Set point 1
M (5V)
Set point 2
L3
GSE Input
+5V
+3,3V
W1
ASM Input
M(5V)
6
3
(K1)
(5K)
SYT9-Input
-X1 5
-X1 2 1
3
4
6
-X1 5
A
dASM-Input
-F3
dASM-Output
L2
Output 1
M (5V)
V1
33
13
Output 2
M (5V)
34
13
Control Inputs
-X4
T3
12
#2)
14
RESET
M (24V)
V3
15
#2)
14
Controller lock
M (24V)
K
Output 3
M (5V)
-X1 2 1
3
4
6
-X1 5
19
14
3
(K1)
(5K)
A
X7.1
X7.2
Output
24V / 80mA
X5.1
20
X5.2 20
34
X6 31 32 33
4
-X2 1
3
G2
G1
2
2
(G2)
(6G)
1
(G1)
(4G)
Fibre Optic
Connector
X30
X31
X10
1
System
-X4
A70
X6 41 42
ϑ
Temperature
Sensor
R95
W2
V2
U2
X21 1
2
example: Profibus DPV1
Bus-Option ***
*
LBA-2, Local Operating & Display Unit
** Thyro-Tool Family Software for PC
*** e.g. Profibus DP, Modbus RTU,
ProfiNet/Ethernet IP/Modbus TCP, DeviceNet
36
32
X7.1
31
X7.2 35
Connector
for
Connector
BUSfor LBA-2* Interface
or PC **
RS 232
Interfaces
2
-X3 5 6 1 2
-R40
AK
T5
Example
Ohmic Load
in -Connection
4
(K2)
(7K)
AK
Power Section Driver A5
33
K
V5
K
-X3 3 4
Power
Supply
-F3
-F2
A5
QUIT
M (24V)
4
(K2)
(7K)
+24V
2
(G2)
(6G)
+24V
1
(G1)
(4G)
Receiver
3
(K1)
(5K)
X24
A
PE
-F1
Ground M1
L1
3
Input 0 (M1)
Thyro-P 3P
4
Input 1 (M1)
T1
Transmitter
only for HF-types
5
Ground M24
AK
6
Ground M2
U1
7
Input 2 (M2)
V1
8
Input 3 (M2)
9
Options
X20
R Load
#) option
Remarks
X7 2 3 230V, 50/60 Hz
+24V
These connections must
be wired by the user
#1) for 690V types: separate power supply is required
all other types: separate power supply is possible
#2) Default setting
K
74
8.3 THYRO-P 3P 3-PHASE POWER CONTROLLER
#1)
-X1 2 1
3
4
230 VAC -20%
to
500 VAC +10%
Input
Broad band
Power Supply
13
14
2
3
4
9
10 11 12
K2
K1
8
Limit
Alarm
13 14 15
K3
Option
Relay Outputs
1
16
12
X7.1
11
X7.2 15
-X3 5 6 1 2
Power Section Driver A1
X6 11 12 13
-X2 1
-R40
2
5
X5.1
X5.2 5
5V / 1mA
-X4
-F3
-F2
23
-X3 3
X7.1
X7.2
A3
1
10
13
11
13
17
5 21
16
13
2
3
X6 21 22 23
-X2
G1
4
AK
G2
18
X41 32
RJ45
patchcable
X40
33
13
34
13
T3
2
12
*
#2)
#1)
#2)
14
15
#2)
14
19
T1.2 (W2)*
T1.1 (U2)*
14
Output
X5.1
20
X5.2 20
34
X6 31 32 33
Fibre Optic
Connector
X30
X31
System
X10
Connector
for
Connector
BUSfor LBA * Interface
or PC **
RS 232
Interfaces
ϑ
A70
Temperaturesensor
X6 41 42
R95
X21 1
example: Profibus DP
Bus-Option ***
*
LBA-2, Local Operating & Display Unit
** Thyro-Tool Family Software for PC
*** e.g. Profibus DP, Modbus RTU,
ProfiNet/Ethernet IP/Modbus TCP, DeviceNet
36
32
X7.1
31
X7.2 35
Power Section Driver A5
33
24V / 80mA
Power
Supply
X7.1
X7.2
Terminal description on the device
These connections must be wired by the user
Delivery state
Separate power supply for all other types possible
Separate power supply for 690V types is required
Remarks
Control Inputs
1 -X4
26
22
X7.1
21
X7.2 25
Analog Outputs
(actual values)
13
2
-X3 5 6 1
-R40
4
(K2)
(7K)
2
(G2)
(6G)
AK
Power Section Driver A3
24
4
K
1
(G1)
(4G)
Analog
DC
MLO
Inputs Eliminator Mains Load Optimization
Input
#)
(set point)
ASM
SYT9
dASM
Output
dynamic
static
dynamic
Thyro-P Control Device
X7.1
X7.2
-X3 3 4
X2 7
-F3
-F2
AK
+5V
2
G2
+5V
X1 1
G1
M (5V)
K
Set point 1
M (5V)
Set point 2
A1
GSE Input
+5V
+3,3V
N
ASM Input
M(5V)
6
3
(K1)
(5K)
SYT9-Input
-X1 5
-X1 2 1
3
4
A
dASM-Input
L1.2 (W1)*
dASM-Output
-F3
Output 1
M (5V)
6
V3
Output 2
M (5V)
-X1 5
K
Output 3
M (5V)
4
(K2)
(7K)
RESET
M (24V)
2
(G2)
(6G)
Controller lock
M (24V)
1
(G1)
(4G)
QUIT
M (24V)
3
(K1)
(5K)
+24V
-F1
+24V
A
PE
L1
2
Ground M1
Thyro-P 1P...VSC 2
3
Input 0 (M1)
T1
4
Input 1 (M1)
AK
Receiver
only for ...HF - units
5
Ground M24
L1.1 (U1)*
6
Ground M2
V1
7
Input 2 (M2)
K
8
Input 3 (M2)
X50
Transmitter
X7 2 3 230V, 50/60 Hz
9
+24V
PE
R Load
75
8.4 THYRO-P VSC 2 2-STEP PRIMARY VSC
X20
#1)
1
-X1 2
3
230 VAC -20%
to
500 VAC +10%
Input
13
14
2
3
4
2
9
10 11 12
K2
K1
8
Limit
Alarm
13 14 15
K3
Option
Relay Outputs
1 -X4
16
12
X7.1
11
X7.2 15
-X3 5 6 1 2
-R40
AK
Power Section Driver A1
X6 11 12 13
-X2 1
G2
5
X5.1
X5.2 5
5V / 1mA
-F3
-F2
23
-X3 3
X7.1
X7.2
A3
1
10
13
11
13
17
5 21
16
13
2
3
X6 21 22 23
-X2
G1
1
(G1)
(4G)
4
AK
G2
18
X41 32
RJ45
patchcable
X40
2
1
26
22
X7.1
21
X7.2 25
Analog Outputs
(actual values)
13
2
-X3 5 6 1
-R40
4
(K2)
(7K)
2
(G2)
(6G)
AK
Power Section Driver A3
24
4
K
3
(K1)
(5K)
A
Analog
DC
MLO
Inputs Eliminator Mains Load Optimization
Input
#)
(set point)
ASM
SYT9
dASM
Output
dynamic
static
dynamic
Thyro-P Control Device
X7.1
X7.2
-X3 3 4
X2 7
-F3
-F2
Broad band
Power Supply
2
G1
+5V
X1 1
K
+5V
A1
M (5V)
N
Set point 1
M (5V)
Set point 2
-F5
GSE Input
+5V
+3,3V
L1.3 (W1)*
ASM Input
M(5V)
-F3
SYT9-Input
4
V3
dASM-Input
6
K
dASM-Output
-X1 5
-X1 2 1
3
4
6
-X1 5
4
(K2)
(7K)
Output 1
M (5V)
2
(G2)
(6G)
33
13
Output 2
M (5V)
1
(G1)
(4G)
34
13
Control Inputs
-X4
T3
12
#2)
14
RESET
M (24V)
3
(K1)
(5K)
15
#2)
14
Controller lock
M (24V)
L1.2 (V1)*
Output 3
M (5V)
-X1 2 1
3
4
6
-X1 5
19
14
3
(K1)
(5K)
A
X7.1
X7.2
X5.1
20
X5.2 20
24V / 80mA
Output
34
X6 31 32 33
4
-X2 1
3
G2
G1
2
2
(G2)
(6G)
1
(G1)
(4G)
Fibre Optic
Connector
X30
X31
X10
1
System
-X4
A70
X6 41 42
ϑ
Temperaturesensor
R95
X21 1
2
3
example: Profibus DP
Bus-Option ***
*
LBA-2, Local Operating & Display Unit
** Thyro-Tool Family Software for PC
*** e.g. Profibus DP, Modbus RTU,
ProfiNet/Ethernet IP/Modbus TCP, DeviceNet
36
32
X7.1
31
X7.2 35
Connector
for
Connector
BUSfor LBA * Interface
or PC **
RS 232
Interfaces
2
T5
T1.3 (W2)*
T1.2 (V2)*
T1.1 (U2)*
-X3 5 6 1 2
-R40
AK
4
(K2)
(7K)
AK
Power Section Driver A5
33
K
V5
K
-X3 3 4
Power
Supply
-F3
-F2
A5
QUIT
M (24V)
A
+24V
-F1
+24V
L1
PE
Thyro-P 1P...VSC 3
Ground M1
T1
Input 0 (M1)
AK
4
Input 1 (M1)
L1.1 (U1)*
Receiver
only for ...HF - units
5
Ground M24
V1
6
Ground M2
K
7
Input 2 (M2)
X50
Transmitter
230V, 50/60 Hz
X7 2 3
8
Input 3 (M2)
Remarks
9
+24V
RLoad
Separate power supply for all other types possible
Separate power supply for 690V types is required
#1)
X20
Delivery state
Terminal description on the device
#2)
These connections must be wired by the user
*
PE
76
8.5 THYRO-P VSC 3 3-STEP PRIMARY VSC
#1)
-X1 2 1
3
4
230 VAC -20%
to
500 VAC +10%
Input
Broad band
Power Supply
13
14
2
3
4
9
10 11 12
K2
K1
8
Limit
Alarm
13 14 15
K3
Option
Relay Outputs
1 -X4
16
12
X7.1
11
X7.2 15
-X3 5 6 1 2
Power Section Driver A1
X6 11 12 13
-X2 1
-R40
2
5
X5.1
X5.2 5
5V / 1mA
-F3
-F2
23
-X3 3
X7.1
X7.2
A3
1
10
13
11
13
17
5 21
16
13
2
3
X6 21 22 23
-X2
G1
1
(G1)
(4G)
4
2
-X3 5 6 1
26
22
X7.1
21
X7.2 25
-R40
1
AK
G2
2
4
(K2)
(7K)
2
(G2)
(6G)
AK
18
X41 32
RJ45
patchcable
X40
Analog Outputs
(actual values)
Power Section Driver A3
24
4
K
3
(K1)
(5K)
Analog
DC
MLO
Inputs Eliminator Mains Load Optimization
Input
(set point)
ASM
SYT9
dASM
Output
dynamic
static
dynamic
Thyro-P Control Device
X7.1
X7.2
-X3 3 4
X2 7
-F3
-F2
AK
+5V
2
G2
+5V
X1 1
G1
M (5V)
K
Set point 1
M (5V)
Set point 2
A1
GSE Input
+5V
+3,3V
N
ASM Input
M(5V)
6
A
SYT9-Input
-F3
dASM-Input
L1.2 (W1)*
dASM-Output
-X1 5
-X1 2 1
3
4
6
V3
13
Output 1
M (5V)
-X1 5
K
33
13
Output 2
M (5V)
4
(K2)
(7K)
34
13
12
Terminal description on the device
#2)
14
15
#2)
14
19
14
X5.1
20
X5.2 20
Output
34
X6 31 32 33
Fibre Optic
Connector
X30
X31
System
X10
Connector
for
Connector
BUSfor LBA * Interface
or PC **
RS 232
Interfaces
A70
X6 41 42
ϑ
Temperaturesensor
R95
RLoad
X21 1
2
3
example: Profibus DP
Bus-Option ***
*
LBA-2, Local Operating & Display Unit
** Thyro-Tool Family Software for PC
*** e.g. Profibus DP, Modbus RTU,
ProfiNet/Ethernet IP/Modbus TCP, DeviceNet
36
32
X7.1
31
X7.2 35
Power Section Driver A5
33
24V / 80mA
X7.1
X7.2
These connections must be wired by the user
Delivery state
*
Separate power supply for all other types possible
Separate power supply for 690V types is required
#2)
#1)
Remarks
T1.2 (W2)*
Control Inputs
-X4
T3
RESET
M (24V)
2
(G2)
(6G)
Controller lock
M (24V)
1
(G1)
(4G)
QUIT
M (24V)
3
(K1)
(5K)
X24
A
PE
-F1
Output 3
M (5V)
T1.1 (U2)*
Ground M1
Thyro-P 1P...VSC 2
Input 0 (M1)
T1
4
Input 1 (M1)
AK
Receiver
only for ...HF - units
5
Ground M24
V1
6
Ground M2
K
7
Input 2 (M2)
L1.1 (U1)*
8
Input 3 (M2)
X50
Transmitter
X7 2 3 230V, 50/60 Hz
9
+24V
PE
L1
77
8.6 THYRO-P VSC THYRO-P VSC 2 2-STEP SECONDARY VSC
X20
Separate power supply for all other types possible
Separate power supply for 690V types is required
#1)
Remarks
These connections must be wired by the user
Terminal descrition on the device
*
Delivery state
#2)
1
-X1 2
3
4
230 VAC -20%
to
500 VAC +10%
Input
13
14
2
3
4
2
9
10 11 12
K2
K1
8
Limit
Alarm
13 14 15
K3
Option
Relay Outputs
1 -X4
16
12
X7.1
11
X7.2 15
-X3 5 6 1 2
-R40
AK
Power Section Driver A1
X6 11 12 13
-X2 1
G2
5
X5.1
X5.2 5
5V / 1mA
-F3
-F2
23
-X3 3
X7.1
X7.2
A3
1
10
13
11
13
17
5 21
16
13
2
3
X6 21 22 23
-X2
G1
1
(G1)
(4G)
4
AK
G2
18
X41 32
RJ45
patchcable
X40
2
1
26
22
X7.1
21
X7.2 25
Analog Outputs
(actual values)
13
2
-X3 5 6 1
-R40
4
(K2)
(7K)
2
(G2)
(6G)
AK
Power Section Driver A3
24
4
K
3
(K1)
(5K)
Analog
DC
MLO
Inputs Eliminator Mains Load Optimization
Input
#)
(set point)
ASM
SYT9
dASM
Output
dynamic
static
dynamic
Thyro-P Control Device
X7.1
X7.2
-X3 3 4
X2 7
-F3
-F2
Broad band
Power Supply
#1)
2
G1
+5V
X1 1
K
+5V
A1
M (5V)
N
Set point 1
M (5V)
Set point 2
-F5
GSE Input
+5V
+3,3V
L1.3 (W1)*
ASM Input
M(5V)
6
A
SYT9-Input
-F3
dASM-Input
L1.2 (V1)*
dASM-Output
-X1 5
-X1 2 1
3
4
6
V3
Output 1
M (5V)
-X1 5
K
33
13
Output 2
M (5V)
4
(K2)
(7K)
34
13
Control Inputs
-X4
T3
12
#2)
14
RESET
M (24V)
2
(G2)
(6G)
15
#2)
14
Controller lock
M (24V)
1
(G1)
(4G)
Output 3
M (5V)
-X1 2 1
3
4
6
-X1 5
19
14
3
(K1)
(5K)
A
X7.1
X7.2
X5.1
20
X5.2 20
Output
24V / 80mA
34
X6 31 32 33
4
-X2 1
3
G2
G1
2
2
(G2)
(6G)
1
(G1)
(4G)
Fibre Optic
Connector
X30
X31
X10
1
System
-X4
A70
X6 41 42
ϑ
Temperaturesensor
R95
RLoad
X21 1
2
3
example: Profibus DP
Bus-Option ***
*
LBA-2, Local Operating & Display Unit
** Thyro-Tool Family Software for PC
*** e.g. Profibus DP, Modbus RTU,
ProfiNet/Ethernet IP/Modbus TCP, DeviceNet
36
32
X7.1
31
X7.2 35
Connector
for
Connector
BUSfor LBA * Interface
or PC **
RS 232
Interfaces
2
T5
T1.3 (W2)*
T1.2 (V2)*
-X3 5 6 1 2
-R40
AK
4
(K2)
(7K)
AK
Power Section Driver A5
33
K
V5
K
-X3 3 4
Power
Supply
-F3
-F2
A5
QUIT
M (24V)
3
(K1)
(5K)
+24V
A
PE
-F1
+24V
T1.1 (U2)*
Ground M1
AK
Input 0 (M1)
Thyro-P 1P...VSC 3
4
Input 1 (M1)
T1
Receiver
only for ...HF - units
5
Ground M24
L1.1 (U1)*
6
Ground M2
V1
7
Input 2 (M2)
K
8
Input 3 (M2)
X50
Transmitter
230V, 50/60 Hz
X7 2 3
9
+24V
PE
L1
78
8.7 THYRO-P VSC 3 3-STEP SECONDARY VSC
X20
79
9. SPECIAL REMARKS
9.1 INSTALLATION
The installation orientation of Thyro-P is vertical, so that ventilation of the thyristors fastened to
heat sinks is ensured. In case of cabinet mounting, additionally sufficient ventilation of the cabinet must be ensured. The distance between Power Controller and the bottom should be at least
100mm; the distance to the ceiling 150mm. The devices may be installed next to each other without lateral distance. Heating up of the device by heat sources must be avoided. The dissipation of
the Power Controller is stated in the table chapter 10 TYPE OVERVIEW.
Grounding must be performed according to local regulations of the utility company (grounding
screw for protective conductor connection).
9.2 PROTECTION AGAINST CONTACT IP20
ATTENTION
Energized parts.
The device shall immediately be disconnected from the power supply before installation.
The Thyro-P is designed according to IP20 protection code.
CAUTION
To ensure protection during operation, the correct mounting is necessary of the added IP20 protection devices at each electric connection.
In the following description mounting of the protection devices is shown, this handling also applies
to 2- or 3- phase units of Thyro-P.
For devices of 16A/37A/75A/110A applies:
• The blind cover for non-used connections has to be pressed into the device cover until it snaps
into place.
• For devices of 110A, the covers have to be adjusted by the customer in accordance to the needed gaps while IP20 protection code has to be considered. Therefore gaps have to be chosen as
small as possible, so that needed IP20 protection code is ensured.
The cover has to be pressed into the device cover until it snaps into place.
For devices of 80A/130A/170A/200A/280A applies:
• The covers have to be adjusted by the customer in accordance to the needed gaps while IP20
protection code has to be considered. Therefore gaps have to be chosen as small as possible, so
that needed IP20 protection code is ensured.
• Afterwards the blind cover for non-used connections has to be pressed into the device cover
until it snaps into place.
For devices of 495A/650A applies:
Before connecting the device, the coverage has to be removed.
The connections coming from the customer side have to be connected to the copper bars of the
device.
Please be consider that an adequate IP20 protection has to be secured.
Then the according coverages have to be fixed again on the device.
For devices of 1000A-1500A applies:
Before connecting the device, the coverage has to be removed.
The connections coming from the customer side have to be connected to the copper bars of the
device.
80
Afterwards safe gaps (according to IP20) have to be cut into the covers.
Please be consider that an adequate IP20 protection has to be secured.
Then the according coverages have to be fixed again on the device.
9.3 COMMISSIONING
The device must be connected to the mains and the associated load according to the wiring
diagrams.
REMARK
If the units Thyro-P 1P (or Thyro-P 3P in „open delta“) and/or Thyro-P 2P are operated at over 600
V and without load at the output side, voltages can occur above input voltage at the connection
points U2,V2 and W2. In this case, additional 690V snubber boards are to be used (see chapter 13
ACCESSORIES AND OPTIONS).
Depending on connection system of the load (star, delta, etc.), it must be ensured that the load voltage transformers in the power sections are wired correctly (terminal strip X1 of the power section).
The correct terminals may be found in the connecting diagrams.
On delivery, the device is parameterized adjusted to the respective power section. The operating
mode TAKT (Thyro-P 1P / Thyro-P 2P) is set. If a different operating mode is desired, then the user
must set this using the LBA-2, PC, etc. Generally, the standard parameters (see menu list) should
be reviewed and adjusted to the respective conditions for use by the user (for instance operating
mode, control mode, limitations, monitoring, times, characteristics, actual value outputs, fault indications, relays, time and date, etc.).
Besides the load, some control signals must be connected as well (refer to chapter 4). The following
signals are always required for operation of the device:
Set point
RESET
Regular inhibit
(terminal 10 or 11/or via interfaces)
(on ground, on terminal 12, jumper set as standard)
(on ground, on terminal 15, jumper set as standard)
If the RESET is not connected, then the device is in reset state and is not operating (LED „ON“
shows red light), i.e. no communications is possible via interface. Further details of the RESET are
described in chapter 4.4. If the regulator inhibit is not connected, then the device is fully operable,
but the power section is only controlled using the values of the minimal limitations (LED „PULSE
LOCK“ is on). Further details on the regulator inhibit may be found in the chapter 4.5 of the same
name.
ATTENTION
The controller lock may also be set via the interfaces!
ATTENTION
The control device is to be operated only with casing.
9.4 SERVICE
The devices delivered have been tested according to the state of the art and have been produced
to a high quality standard (DIN EN ISO 9001). In the event of any faults or problems despite such
controls, please contact our technical support team (see page 12 CONTACT).
9.5 CHECKLIST
No frontside LED is on:
• for 690V devices, the power supply for the control device A70 to be provided by the customer is
missing. (Attention, maximum nominal input voltage 500V)
81
• check voltage at terminal X1.1 and X1.2 of the control device A70
• check semiconductor fuse and the fuses F2 and F3 on the controller card A1.
CAUTION
In any case, set the device de-energized and check if it is de-energized
Terminal X1.3 on the controller card A1 not connected.
• if the semiconductor fuse is defective, then the following parameters must be checked in case of
transformer load for the operating modes TAKT and SSSD:
phase angle of the first half-wave (phase angle 1) = 60 degrees;
possibly optimize. Check for the model type 1P, 2P or 3P
Menu: Parameters/Operating mode/Number of phases controlled 1 2 3)
No load current
• RESET X5.2.12 is not jumpered for X5.1.14 (LED ON lit in red)
• supply voltage of the control device outside of the tolerable range
• controller lock X5.2.15 is not jumpered for X5.1.14 (LED PULSE LOCK is on)
• no set point is set. Using the LBA-2, check the total set point (effective total), or measure set point
on X5.2.10 and X5.2.11.
- set points are not cleared
- parameterization of the set point inputs 20mA, 5V, 10V, does not matched to output of the
temperature controller
- check jumper X221 and X222 for current and voltage range
- parameters STA and STE of the control characteristic are wrong
- parameter for linkage of the set points is not set to ”ADD“
• parameters IEMA, UEMA, PMA are set too small
• controller parameters Ti and Kp are set too large.
CAUTION
Check fuses on the controller cards A1, A3, A5. In any case, set the device de-energized and check
if it is de-energized.
• Load connection by the customer is missing (only for type 1P).
Check connection on A1 terminal X1.3.
• Check synchronization voltage at the control device A70 at the terminal blocks X7.1 and X7.2.
The thyristors are set to full scale
• Was the set point set via motor potentiometer function? Check value using the LBA-2.
• Check the control characteristic (Control start, Control end, Addition).
• Controller feedback signal available? Check current transformer and voltage transformer
connections at the terminal blocks X7.1 and X7.2.
• Parameters Turn on-time Ts min and Back pulse limit position, Umin, Imin, Pmin are larger than 0.
• Controller parameters Ti and Kp are set too small.
• Parameters Imax, Umax, Pmax are set too large or the load current is too small.
Measures in case of other maloperation of the device:
• Evaluation of incident register (data logger) with LBA-2 or Thyro-Tool Family.
• Checking Thyro-P parameter.
• Checking wiring of Thyro-P.
• Correct number of controlled phases (parameters).
• With activated trouble signal relay Evaluation which faults led to a response, eliminate the fault.
82
10. TYPE OVERVIEW
10.1 TYPE RANGE 400 VOLT
TYPE VOLTAGE 230-400 VOLTS
TYPE CURRENT TYPE POWER
DISSIPA-
DIMENSIONS
WEIGHT
(A)
TION
(MM)
(W)
W
(NET ABOUT DRAW. CHARACTE- TRANSF.
KG)
(NO.) RISTIC (NO.) T1
(KVA)
H
D
320
320
320
320
320
320
320
320
370
412
412
762
762
577
577
229
229
229
229
229
229
229
229
229
340
340
505
505
445
470
DIM.
TEMP.
CURRENT
BURDEN
SEMICON-
RESISTOR
DUCTOR FUSE*
R40 (Ω)
F1 (A)
THYRO-P 1P
5H
16H
3.6
25H
37H
8
75H
17
110H
25
130H
30
170H
39
280HF
64
495HF
114
650HF
149
1000HF
230
1500HF
345
2100HF
483
2900HF
667
2
6
10
15
30
44
52
68
112
198
260
400
600
840
1160
58
71
83
105
130
175
190
220
365
595
750
1450
1775
2600
3400
150
150
150
150
150
150
200
200
200
175
175
242
242
521
603
6
6
6
6
6
6
8
8
9
15
15
35
35
50
62
260
260
260
260
260
260
263
266
265
266
266
268
285
270
271
1
1
1
1
1
2
2
2
2
3
3
4
5
6
7
400/1
400/1
400/1
100/1
100/1
100/1
150/1
200/1
300/1
500/1
700/1
1000/1
1500/1
2000/1
3000/1
82.5
27.4
15.4
2.70
1.30
0.91
1.10
1.10
1.00
1.00
1.00
1.00
1.00
0.91
1.00
50
50
50
50
100
180
200
315
350
630
900
2x1000
4x900
4x1000
4x1500
272
272
272
272
275
275
277
278
278
280
280
282
282
283
283
1
1
1
2
2
2
2
3
3
4
5
6
6
7
7
400/1
100/1
100/1
100/1
150/1
200/1
300/1
500/1
700/1
1000/1
1500/1
2000/1
2000/1
3000/1
3000/1
27.4
2.70
1.30
0.91
1.10
1.10
1.00
1.00
1.00
1.00
1.00
1.00
1.00
1.00
1.00
50
50
100
180
200
315
350
630
900
2x1000
4x900
4x1000
4x1000
4x1500
4x1500
1
1
1
2
2
2
2
3
3
4
5
6
7
400/1
100/1
100/1
100/1
150/1
200/1
300/1
500/1
700/1
1000/1
1500/1
2000/1
3000/1
27.4
2.70
1.30
0.91
1.10
1.10
1.00
1.00
1.00
1.00
1.00
1.00
1.10
50
50
100
180
200
315
350
630
900
2x1000
4x900
4x1000
4x1500
THYRO-P 2P
16H
6 11
37H
15 25
75H
30 52
110H
44 76
130H
52 90
170H
68 118
280HF
111 194
495HF
197 343
650HF
259 450
1000HF
398 693
1500HF
597 1039
2000HF 1385
2100HF
796 2750
HF
1905
2900
HF 1905
107
175
220
310
350
410
700
1150
1465
2865
3510
4800
4800
6200
6200
225 320 229
10
225 320 229
10
225 320 229
10
225 320 229
10
325 320 229
12
325 320 229
12
325 404 229
15
261 502 340
22
261 502 340
22
410 762 505
54
410 762 505
54
526 837 445
84
526 837 445
84
603837470107
603837470107
228
330
400
540
560
650
1070
1800
2265
4370
5335
6900
8700
300 320 229
300 320 229
300 320 229
300 320 229
450 320 229
450 320 229
450 404 229
348 527 340
348 527 340
575 762 505
575 762 505
526 1094 445
603 1094 470
THYRO-P 3P
16H
37H
75H
110H
130H
170H
280HF
495HF
650HF
1000HF
1500HF
1850HF
2600HF
6
15
30
44
52
68
111
197
259
398
597
736
1035
11
25
52
76
90
118
194
343
450
693
1039
1281
1801
14
284
14
284
14
284
14
284
17
287
17
287
20
289
30
290
30
290
74
292
74
119
294
152
295
* number of fuses per path of power section, built in
508
83
10.2 TYPE RANGE 500 VOLT
TYPE VOLTAGE 500 VOLTS
TYPE CURRENT TYPE POWER
DISSIPA-
DIMENSIONS
WEIGHT
(A)
TION
(MM)
(W)
W
(NET ABOUT DRAW. CHARACTE- TRANSF.
KG)
(NO.) RISTIC (NO.) T1
(KVA)
H
D
DIM.
TEMP.
CURRENT
BURDEN
SEMICON-
RESISTOR
DUCTOR FUSE*
R40 (Ω)
F1 (A)
508
THYRO-P 1P
5 H
16 H
2.5
8
58
71
150
150
320 229
320 229
6
6
260
260
1
1
400/1
400/1
82.5
27.4
50
50
25 H
37 H
75H
110H
130H
170H
280HF
495HF
650HF
1000HF
1500HF
2100HF
12
83
150
320 229
6
260
1
400/1
15.4
50
18
38
55
65
85
140
248
325
500
750
1050
105
130
175
190
220
365
595
750
1450
1775
2600
150
150
150
200
200
200
175
175
242
242
521
320
320
320
320
320
370
412
412
762
762
577
229
229
229
229
229
229
340
340
505
505
445
6
6
6
8
8
9
15
15
35
35
50
260
260
260
263
263
265
266
266
268
268
270
1
1
2
2
2
2
3
3
4
5
6
100/1
100/1
100/1
150/1
200/1
300/1
500/1
700/1
1000/1
1500/1
2000/1
2.70
1.30
0.91
1.10
1.10
1.00
1.00
1.00
1.00
1.00
0.91
50
100
180
200
315
350
630
900
2x1000
4x900
4x1000
2900HF
1450
3400
603
577 470
62
271
7
3000/1
1.00
4x1500
THYRO-P 2P
16 H
37 H
75H
110H
130H
170H
280HF
495HF
650HF
1000HF
1500HF
2000HF
2750
HF
14
107
225
320 229
10
272
1
400/1
27.4
50
32
65
95
112
147
242
429
563
866
1300
1732
175
220
310
350
410
700
1150
1465
2865
3510
4800
225
225
225
325
325
325
261
261
410
410
526
320
320
320
320
320
404
502
502
762
762
837
10
10
10
12
12
15
22
22
54
54
84
272
272
272
275
275
277
278
278
280
280
282
1
1
2
2
2
2
3
3
4
5
6
100/1
100/1
100/1
150/1
200/1
300/1
500/1
700/1
1000/1
1500/1
2000/1
2.70
1.30
0.91
1.10
1.10
1.00
1.00
1.00
1.00
1.00
1.00
50
100
180
200
315
350
630
900
2x1000
4x900
4x1000
2381
6200 603837470107
283
7
3000/1
1.00
4x1500
229
229
229
229
229
229
340
340
505
505
445
THYRO-P 3P
16 H 14
37 H 32
75H
65
110H
95
130H
112
170H
147
280HF
242
495HF
429
650HF
563
1000HF
866
1500HF
1300
1850HF
1602
2600HF
2251
228
330
400
540
560
650
1070
1800
2265
4370
5335
6900
8700
300
320 229
14
284
1
400/1
27.4
50
300 320 229
300 320 229
300 320 229
450 320 229
450 320 229
450 404 229
348 527 340
348 527 340
575 762 505
575 762 505
526 1094 445
603 1094 470
14
14
14
17
17
20
30
30
74
74
119
152
284
284
284
287
287
289
290
290
292
292
294
295
1
1
2
2
2
2
3
3
4
5
6
7
100/1
100/1
100/1
150/1
200/1
300/1
500/1
700/1
1000/1
1500/1
2000/1
3000/1
2.70
1.30
0.91
1.10
1.10
1.00
1.00
1.00
1.00
1.00
1.00
1.10
50
100
180
200
315
350
630
900
2x1000
4x900
4x1000
4x1500
* number of fuses per path of power section, built in
84
TYPE VOLTAGE 500 VOLTS
TYPE CURRENT TYPE POWER
DISSIPA-
DIMENSIONS
WEIGHT
(A)
TION
(MM)
(W)
W
(NET ABOUT DRAW. CHARACTE- TRANSF.
KG)
(NO.) RISTIC (NO.) T1
(KVA)
H
D
320
320
320
320
320
320
397
414
414
685
685
837
229
229
229
229
229
229
229
340
340
505
505
445
DIM.
TEMP.
CURRENT
BURDEN
SEMICON-
RESISTOR
DUCTOR FUSE*
R40 (Ω)
F1 (A)
THYRO-P 1P...VSC2
16 H
37 H
75 H
110 H
130 H
170 H
280 HF
495 HF
650 HF
1000 HF
1500 HF
2000 HF
8
18
38
55
65
85
140
248
325
500
750
1050
70
105
130
175
190
220
365
595
750
1450
1775
2600
225
225
225
225
325
325
325
261
261
410
410
526
10
272
10
10
10
12
275
12
15
277
22
278
22
54
280
54
84
282
1
1
1
2
2
2
2
3
3
4
5
6
100/1
100/1
100/1
100/1
150/1
200/1
300/1
500/1
700/1
1000/1
1500/1
2000/1
2.70
2.70
1.30
0.91
1.10
1.10
1.00
1.00
1.00
1.00
1.00
0.91
40
50
100
180
200
315
350
630
900
2 x 1000
4 x 900
4 x 1000
2750 HF
1450
3400
603 837 470 107
283
7
3000/1
1.00
4 x 1500
THYRO-P 1P...VSC3 16 H
37 H
75 H
110 H
130 H
170 H
280 HF
495 HF
650 HF
1000 HF
1500 HF
1850 HF
2600 HF
8
18
38
55
65
85
140
248
325
500
750
1050
1450
70
105
130
175
190
220
365
595
750
1450
1775
2600
3400
300 320 229
300 320 229
300 320 229
300 320 229
450 320 229
450 320 229
450 397 229
348 430 340
348 430 340
575 685 505
575 685 505
526 1094 445
603 1094 470
14
284
14
14
14
17
287
17
20
289
30
290
30
74
292
74
119
294
152
295
1
1
1
2
2
2
2
3
3
4
5
6
7
100/1
100/1
100/1
100/1
150/1
200/1
300/1
500/1
700/1
1000/1
1500/1
2000/1
3000/1
2.7
2.7
1.3
0.91
1.1
1.1
1
1
1
1
1
0.91
1
40
50
100
180
200
315
350
630
900
2 x 1000
4 x 900
4 x 1000
4 x 1500
* number of fuses per path of power section, built in
85
10.3 TYPE RANGE 690 VOLT
TYPE VOLTAGE 690 VOLTS
TYPE CURRENT TYPE POWER
DISSIPA-
DIMENSIONS
WEIGHT
(A)
TION
(MM)
(W)
W
(NET ABOUT DRAW. CHARACTE- TRANSF.
KG)
(NO.) RISTIC (NO.) T1
(KVA)
THYRO-P 1P
80 H
55
200HF
300HF
500HF
780HF
1400HF
2000HF
2600HF
138
207
345
538
966
1380
1794
125
260
360
625
910
1900
3200
3450
200
200
175
175
242
242
521
603
H
D
320
370
412
412
762
762
577
577
229
229
340
340
505
505
445
470
8
9
15
15
35
35
62
62
DIM.
TEMP.
263
265
266
266
268
268
270
271
1
2
3
3
4
5
6
7
CURRENT
100/1
200/1
300/1
500/1
1000/1
1500/1
2000/1
3000/1
BURDEN
SEMICON-
RESISTOR
DUCTOR FUSE*
R40 (Ω)
F1 (A)
1.20
1.00
1.00
1.00
1.20
1.00
1.00
1.10
100
250
350
630
2x630
4x700
4x900
4x1400
THYRO-P 2P
80 H
35
225
325 320 229
12
275
1
100/1
1.20
100
200HF
300HF
500HF
780HF
1400HF
1850HF
2400
HF
239
358
597
932
1673
2210
2868
THYRO-P 3P
80 H
95
200HF
300HF
500HF
780HF
1400HF
1700HF
2200HF
239
358
597
932
1673
2031
2619
485
640
1225
1700
3750
5700
6400
325 404 229
15
261 502 340
22
261 502 340
22
410 762 505
54
410 762 505
54
526 837 445
84
603837470107
277
278
278
280
280
282
283
2
3
3
4
5
6
7
200/1
300/1
500/1
1000/1
1500/1
2000/1
3000/1
1.00
1.00
1.00
1.20
1.00
1.00
1.20
250
350
630
2x630
4x700
4x900
4x1400
350
740
1020
1825
2740
5600
8000
9000
450 320 229
450 404 229
348 527 340
348 527 340
575 762 505
575 762 505
526 1094 445
603 1094 470
287
289
290
290
292
292
294
295
1
2
3
3
4
5
6
7
100/1
200/1
300/1
500/1
1000/1
1500/1
2000/1
3000/1
1.20
1.00
1.00
1.00
1.20
1.00
1.10
1.30
100
250
350
630
2x630
4x700
4x900
4x1400
12
275
15
277
22
278
22
54
280
54
84
282
1
2
3
3
4
5
6
100/1
200/1
300/1
500/1
1000/1
1500/1
2000/1
1.2
1
1
1
1.2
1
1
100
250
350
630
2 x 630
4 x 700
4 x 900
283
7
3000/1
1.1
4 x 1400
17
287
20
289
30
290
30
74
292
74
119
294
152
295
1
2
3
3
4
5
6
7
100/1
200/1
300/1
500/1
1000/1
1500/1
2000/1
3000/1
1.2
1
1
1
1.2
1
1
1.1
100
250
350
630
2 x 630
4 x 700
4 x 900
4 x 1400
17
20
30
30
74
74
119
152
THYRO-P 1P...VSC2
80 H
200 HF
300 HF 500 HF
780 HF
1400 HF
1850 HF
55
138
207
345
538
966
1380
125
260
360
625
910
1900
3200
325
325
261
261
410
410
526
320
397
414
414
685
685
837
2400 HF 1794
3450
603
837 470
THYRO-P 1P...VSC3
80 H
55
125
450
200 HF
300 HF 500 HF
780 HF
1400 HF
1700 HF
2200 HF 138
207
345
538
966
1380
1794
260
360
625
910
1900
3200
3450
229
229
340
340
505
505
445
320 229
450 397 229
348 430 340
348 430 340
575 685 505
575 685 505
526 1094 445
603 1094 470
107
* number of fuses per path of power section, built in
86
11. TECHNICAL DATA
TYPE VOLTAGE
...P400...
230 volts -20%
to
400 volts +10%
...P500...
230 volts -20%
to
500 volts +10%
...P690...
500 volts -20%
to
690 volts +10%
MAINS FREQUENCY
all models 45Hz to 65Hz
LOAD DESCRIPTION ohmic load (minimum 100W)
ohmic load Rhot/Rcold ratio up to 20 (MOSI operation)
transformer load
TRANSFORMERThe induction of the load side transformer should not exceed
OPERATING MODES
1.45T in case of mains overvoltage when using grain-oriented,
cold-rolled plates. This corresponds to a nominal induction of
approx. 1.3T.
TAKT =full oscillation clock = default setting for the
models 1P, 2P and 3P
VAR = phase-angle firing = only for the models 1P and 3P
SSSD = soft-start-soft-down; a combination of
„VAR“ and „TAKT“, for the models 1P, 2P and 3P,
i.e. reduced mains surge load
VSC_VAR = phase-angle firing in voltage sequence control
SET POINT INPUTSThe power controller Thyro-P has 4 set point inputs.
The set point inputs are indirectly connected to the mains
(SELV, PELV).
Set points 1, 2: external set point input
signal ranges:
0(4) - 20 mA
Ri = ca. 250 V / max. 24mA*
0
- 5 V
Ri = ca. 8,8 kV / max. 12V
0
- 10 V
Ri = ca. 5 kV / max. 12V
* refer to ”ATTENTION” in chapter 2.2
Set point 3: connection for fiber optic (LL) from the superordinate PC or automation system
Set point 4: set point assignment via RS232
(for instance LBA-2)
ANALOG OUTPUTS
3 outputs: signal level 0-10 V, 0-20mA or 4-20mA. The maximum
burden voltage is 10V
CONTROL CHARACTERISTIC
The control characteristic is established by the maximum value
of the dimensions to be controlled and the key values of the
set point. Using these key values, the linear control characteristic may be set at will.
Every controller (for instance temperature controller), whose
output signal is in the range of 0-20mA/0-5V/0-10V may be
easily adapted to the power controller.
CONTROL TYPESVoltage control Urms
Voltage control U2rms = default setting
Current control Irms
Current control I2rms
87
Power control P
Without control
PRECISIONU-control: Better than ± 0.5%
I-Control: ± 0,5%
P-Control: ± 1%
All specifications are relating to the respective final value.
LIMITATIONSVoltage limitation Urms
Current limitation Irms = default setting
Effective power limitation P
Peak current limitation, MOSI operation
Upon reaching one of these limits, the LED ”Limit“ on the
front panel of Thyro-P is on and the relay K2 is activated.
(terminal strip X2, terminals 10/11/12)
Relay K1, K2, K3
Contact load:
AC max: 250V/6A (1500VA)
AC min: >10VA;
DC max: 300V/0.25A (62.5W)
DC min : 5V/20mA
contactor material:AgCdO
WITH UL APPLICATIONS
AC max:
250V/4A
AMBIENT TEMPERATURE 35°C external cooling (F models)
45°C self-air cooling
At higher temperatures it is possible to operate with reduced
type current:
I/IRATED CURRENT
COOLANT
TEMPERATURE
[°C]
-10 bis 25
30
35
40
45
50
55
FORCED COOLING
(VENTILATOR TYPES)
1.10
1.05
1.00
0.96
0.91
0.87
0.81
SELF COOLING
1.10
1.10
1.10
1.05
1.00
0.95
0.88
WITH UL APPLICATIONS UP TO +40°C
I/IRating
1.2
Coolant temperature
1.1
Self cooling
1.0
0.9
0.8
Forced cooling
0.7
0.6
20
25
30
35
40
45
50
55
60
65
88
TABLE TERMINAL SCREWS THYRO-P 1P, 2P, 3P
CONNECTOR
37H, 75H
M 6
80H
M 8
110H
M 6
130H, 170H
M 8
200HF, 280HF, 300HF
M 10
495HF, 500HF, 650HF
780HF, 1000HF, 1400HF,
M 12
1500HF, 1700HF, 1850HF,
2000HF, 2100HF, 2200HF,
2400HF, 2600HF, 2750HF,
2900HF
EARTHING SCREW
U1, V1, W1, U2, V2, W2
M 6
M 10
M 6
M 10
M 10
M 12
WITH UL APPLICATIONS
POWER CONNECTION
USE ONLY 60°/75°C COPPER CONDUCTORS (UL SPECIFICATION)
STUD TORQUE FOR TABLE TERMINAL SCREWS
[Nm]
SCREW
M 2
M 6
M 8
M 10
M 12
MIN
0.2
3.0
11.5
22.0
38.0
RATEDMAX
0.25 0.3
4.4 5.9
17.0 22.5
33.0 44
56.0 75
[Pound inches]
SCREW
M 2
M 6
M 8
M 10
M 12
MIN
1.9
26.1
101.8
194.7
336.3
RATEDMAX
2.2 2.5
38.9 52.2
150.5 199.1
292.1 389.4
495.6 663.8
FAN 230 V
50-60 HZ
THYRO-P (HF-TYPES)
1P
200HF, 280HF
300HF, 495HF, 500HF, 650HF
780HF, 1000HF, 1400HF, 1500HF
2000HF, 2100HF, 2600HF, 2900HF
2P / 1P...VSC 2
200HF, 280HF
300HF, 495HF, 500HF, 650HF
780HF, 1000HF, 1400HF, 1500HF
1850HF, 2000HF, 2400HF, 2750HF
3P / 1P...VSC 3
200HF, 280HF
300HF, 495HF, 500HF, 650HF
780HF, 1000HF, 1400HF, 1500HF
1700HF, 1850HF, 2200HF, 2600HF
TYPE CURRENT
50HZ 60HZ I [A]
I [A]
AIR VOLUME SOUND PRESS.
IN 1 m DIST.
3
[m /h]
[ca. dbA]
0.22
0.50
0.55
1.00
0.22
0.38
0.60
1.20
120
150
580
2200
53
67
75
81
0.50
0.50
1.00
1.00
0.38
0.38
1.20
1.20
200
230
1200
2100
67
67
81
81
0.50
1.20
1.00
1.00
0.38
0.85
1.20
1.20
260
450
1600
2000
67
72
81
81
Fans (for HF types) must be running when Thyro-P is operating. Connection according to connecting diagrams in chapter 8.
When operating conditions are below +10°C, a longer start-up time of the fan has to be considered. Therefore the adjustable range should amount at least double of the specified continuous
current.
89
REMARK
In general the fan is subject to abrasion, therefore fan typical actions are recommended to check
the fan on regular basis (scheduled maintenance), including testing of propeller on abrasion /
deposition / corrosion and abnormal operating noise.
The used fans are quality products and have a life time of L10=37500 h. Depending on working
conditions, it is recommended to change them after approx. 5 years.
90
12. DIMENSIONAL DRAWINGS
1
2
3
4
5
6
7
8
9
10
11
12
A
A
Seitenansicht / siede view
Vorderansicht / front view
B
B
X10
C
C
*
320
12,598
300
11,811
X24
D
D
Cu 25x2; M6
Cu 0,987x0,078; M6
X5.1
X5.2
Cu 17x2; M6
Cu 0,669x0,078; M6
X2
U1
U2
E
E
X30
F
32,5
1,280
Observe protection note to DIN 34.
86,5
3,406
103,5
4,075
X31
F
12,25
,482
M6 für Erdung
M6 for earthing
6,5
,256
X50
34,5
1,358
35
1,378
179,5
7,067
32
1,260
229
9,016
50
1,969
50
1,969
25
,984
150
5,906
G
G
Thyro-P 1P ...- 37 H
Thyro-P 1P ...- 75 H
Thyro-P 1P ...-110 H
*) Zum entrigeln Federhacken nach rechts drücken.
*) press the spring hook to the right for unlocking.
Baugröße: 1
size: 1
Free size tolerances Surfaces
H
1
2
3
1
2
4
5
3
4
6
5
7
6
8
7
9
10
Mass: ca. 6,0 kg.
1:1
Material:
Blank:
MB Thyro-P 1P...-...H...
Scale
Bgr. 1
MB Thyro-P 1P...-...H...
size 1
12
A1
en
9100002526_MB-00
9
8
Name
Date
Editor 03.02.2014 j.panitz
Check
11 Norm.
Stat. Alteration
Date
Name Origin:
repl.for:
repl.by:
A
A
Vorderansicht / front view
Seitenansicht / side view
B
B
X10
C
C
*
320
12,598
300
11,811
X24
D
D
X5.1
X5.2
Cu 43x5; O9
Cu 1,692x0,196; O0,354
X2
X50
X30
E
E
Cu 25x5; O9
Cu 0,984x0,196; O0,354
X31
U2
Observe protection note to DIN 34.
F
37,9
1,494
57,4
2,260
U1
F
M10 für Erdung
M10 for earthing
18
,699
6,5
,256
64
2,520
138,5
5,453
30
1,181
66,5
2,618
229
9,016
150
5,906
200
7,874
G
G
*) Zum entrigeln Federhacken nach rechts drücken.
*) press the spring hook to the right for unlocking.
Thyro-P 1P ... -130 H
Thyro-P 1P ... -170 H
Thyro-P 1P 690- 80 H
Thyro-P 1P (80 H, 130 H, 170 H)
Dimensional Drawing 263
Baugröße: 2
size: 2
Free size tolerances Surfaces
H
Name
Date
Editor 04.02.2014 j.panitz
Check
Norm.
1
2
3
4
5
6
7
8
9
Stat. Alteration
Date
Name Origin:
1:1
Material:
Blank:
MB Thyro-P 1P...-...H...
Mass: ca.7,5 kg.
Scale
Bgr. 2
MB Thyro-P 1P...-...H...
size 2
9100002527_MB-00
A1
en
repl.for:
repl.by:
Page
1
1 Pa.
Page
1
1 Pa.
91
1
2
3
4
5
6
7
8
9
10
11
12
A
A
Vorderansicht / front view
Seitenansicht / side view
X7
B
B
C
C
X10
D
370
14,567
350
13,780
D
*
X24
X5.1
X5.2
E
E
Cu 43x5; O11
Cu 1,692x0,196; O0,433
X2
X50
Cu 25x5; O11
Cu 0,984x0,196; O0,433
X30
Observe protection note to DIN 34.
X31
F
U2
U1
37,9
1,492
F
M10 für Erdung
M10 for earthing
G
138,5
5,453
17,75
,699
64
2,520
66,5
2,618
Thyro-P 1P ... -280 H
Thyro-P 1P 690- 200 H
229
9,016
35
1,378
G
150
5,906
200
7,874
Baugröße: 2F
size: 2F
*) Zum entrigeln Federhacken nach rechts drücken.
*) press the spring hook to the right for unlocking.
H
Thyro-P 1P (200 HF, 280 HF)
1
2
3
1
4
5
2
6
3
1:1
Material:
Blank:
MB Thyro-P 1P...-...H...
Mass:ca. 9 kg.
Free size tolerances Surfaces
Scale
Name
Date
Editor 03.02.2014 j.panitz
Check
Norm.
MB Thyro-P 1P...-...H...
Bgr. 2F
Dimensional Drawing 265
7
4
5
Vorderansicht / front view
size 2F
9100002528_MB-00
9
8
Stat. Alteration
Date
Name Origin:
repl.for:
6
repl.by:
A1
en
Page
1
1 Pa.
7
8
Seitenansicht / side view
A
B
495 HF
650 HF
412
16,203
X24
370
14,567
350
13,780
X5.1
X5.2
1P ... - 495 HF
1P ... - 650 HF
M10 für Erdung
M10 for earting
X2
X30
X31
Cu 46x3 O11
Cu 1.811x0,118 O 0,433
U1
U2
10
,394
40
1,575
34,5
1,358
U1
U2
14 26
,551 1,024
X50
C
X7
D
Observe protection note to DIN 34.
90
3,543
6,5
,256
12,5
,492
36
1,412
24,5
,965
22
,866
17
,651
62,5
2,461
134
5,276
62,5
2,461
76
2,992
340
13,386
175
6,890
Seitenansicht / siede view
300 HF
E
T1
1P 690 - 300 HF
L1
U2
U1
60
2,362
Cu 40x3 O11
Cu 1,574x0,118 O 0,443
144
5,669
F
76
2,992
Thyro-P 1P (300 HF, 495 HF, 500 HF, 650 HF)
K0,17
Free size tolerances Surfaces
Name
Date
Dimensional Drawing
266
j.panitz
Editor 03.02.2014
Check
Norm.
1
2
3
4
5
Scale 1:2,5
Material:
Blank:
MB Thyro-P 1P...-...H...
Mass
Bgr. K0,1
MB Thyro-P 1P...-...H...
9100002535_MB-00
Stat. Alteration
Date
Name Origin:
repl.for:
repl.by:
92
1
2
3
4
5
6
8
9
10
11
12
Seitenansicht / side view
Vorderansicht / front view
A
7
A
55
2,165
X7
X24
X5.1
X5.2
B
B
X2
X30
X31
X50
C
762
30,000
650
25,591
C
D
D
O14 für Erdung
O,551 for earthing
3P 690-1400 HF
3P ... -1500 HF
U2
U2
U1
E
57
2,244
99,5
3,917
137
5,394
E
Observe protection note to DIN 34.
F
37
1,457
198
7,795
232
9,134
242
9,528
17
,669
35
1,378
9x19
,354x,590
123
4,843
17
,669
26
1,024
U1
Cu 60x10 O14
Cu 2,236x0,939 O 0,551
225
8,858
295
11,614
313
12,323
26
1,024
90
3,543
26
1,024
F
Seitenansicht / side view
3P 690 - 780 HF
3P ... -1000 HF
40
1,575
Cu 40x10 O14
Cu 1,574x0,939 O 0,551
U2
U1
G
102,5
4,035
G
336
13,228
80
3,150
K0,08
H
1
2
3
4
5
6
7
8
9
1:2,5
Material:
Blank:
MB Thyro-P 1P...-...H...
Mass:36 Kg
Free size tolerances Surfaces
Scale
Name
Date
Editor 27.01.2014 j.panitz
Check
Norm.
MB Thyro-P 1P...-...H...
Bgr. K0,08
9100002538_MB-00
Stat. Alteration
Date
Name Origin:
Thyro-P 1P (780 HF, 1000 HF, 1400 HF, 1500 HF) Dimensional Drawing 268
Thyro-P 1P (2000 HF, 2100 HF) Dimensional Drawing 270
repl.for:
repl.by:
size K0,08
A1
en
Page
1
1 Pa.
93
Thyro-P 1P (2600 HF, 2900 HF) 1
2
1
3
2
4
3
Dimensional Drawing 271
5
4
6
5
7
6
8
7
9
Vorderansicht / front view Vorderansicht / front view
A
A
B
B
C
10
9
11
Seitenansicht / side view
X10
X10
X24
X24
10
12
11
Seitenansicht / side view
C
*
*
W1
U1
W1
U2
W2
U2
W2
B
B
C
C
X5.1
X5.2
X2
X2
X30
X30
X31
X31
Cu 25x2; M6
Cu 0,987x0,078; M6
Cu 17x2; M6
Cu 0,669x0,078; M6
Cu 17x2; M6
Cu 0,669x0,078; M6
D
D
E
E
32,5
1,280
12,5
,492
M6 für Erdung
M6 for earthing
Observe protection note to DIN 34.
Observe protection note to DIN 34.
X5.1
X5.2
86,5
3,406
86,5
3,406
E
M6 für Erdung
M6 for earthing
35
1,378
F
G
G
H
H
12,5
,492
6,5
,256
X50
6,5
,256
X50
179,9
7,083
35
1,378
110
4,331
179,9 32
7,0831,260
229
9,016
110
4,331
175
6,890
225
8,858
Thyro-P 2P ...- 37 H
Thyro-P 2P ...- 75 H
Thyro-P 2P ...-110 H
Thyro-P 2P (5 H, 16 H, 25 H, 37 H, 75 H, 110 H) 1
3
2
F
F
175
6,890
225
8,858
*) Zum entrigeln Federhacken nach rechts*) drücken.
Zum entrigeln Federhacken nach rechts drücken.
*) press the spring hook to the right for *)unlocking.
press the spring hook to the right for unlocking.
2
32
1,260
229
9,016
Baugröße: 1
size: 1
1
A
103,5
4,075
U1
32,5
1,280
E
A
Cu 25x2; M6
Cu 0,987x0,078; M6
D
103,5
4,075
D
12
*
320
12,598
300
11,811
320
12,598
300
11,811
*
F
8
4
3
5
4
6
5
Thyro-P 2P ...- 37 H
Thyro-P 2P ...- 75 H
Thyro-P 2P ...-110G H
Free size
tolerances
Mass:
ca.10
Kg.
Free size tolerances Surfaces
1:1
Scale
Baugröße:
Name
Date
Editor 03.02.2014 j.panitz
Check
Norm.
MB Thyro-P 2P...-...H...
1
size: 1
Material:
Blank:
MB Thyro-P 2P...-...H...
Bgr. 1Editor
Surfaces
Name
Date
03.02.2014 j.panitz
G
1:1
Material:
Blank:
MB Thyro-P 2P...-...H...
6
8
7
9
8
Stat. Alteration
Date9
9100002529_MB-00
Name Origin:
Stat. Alteration
repl.for:
Date
Name Origin:
repl.by:
size 1
A1
en
Page
1
1 Pa.
Mass: ca.10 Kg.
Scale
Dimensional Drawing 272
7
Check
Norm.
Bgr. 1
MB Thyro-P 2P...-...H...
size 1
9100002529_MB-00
A1
en
repl.for:
repl.by:
Page
1
1 Pa.
94
1
2
3
4
5
6
7
8
9
10
11
12
A
A
Vorderansicht / front view
Seitenansicht / side view
B
B
X10
C
C
*
*
320
12,598
300
11,811
X24
D
D
X5.1
Cu 43x5; O9
Cu 1,692x0,196; O0,354
X5.2
X2
X30
U1
W2
W1
U2
E
37,9
1,492
Observe protection note to DIN 34.
F
Cu 25x5; O9
Cu 0,984x0,196; O0,354
X31
E
M10 für Erdung
M10 for earthing
F
6,5
,256
X50
18
,709
64
2,520
138,5
5,453
30
1,181
189
7,441
66,5
2,618
229
9,016
30
1,181
275
10,827
325
12,795
G
G
*) Zum entrigeln Federhacken nach rechts drücken.
*) press the spring hook to the right for unlocking.
Thyro-P 2P ... -130 H
Thyro-P 2P ... -170 H
Thyro-P 2P 690- 80 H
Baugröße: 2
size:2
H
Thyro-P 2P (80 H, 130 H, 170 H) 1
2
1
Name
Date
Editor 04.02.2014 j.panitz
Check
Norm.
3
2
4
3
5
4
6
5
7
6
7
8
Mass: ca. 11,5 kg.
1:1
Material:
Blank:
MB Thyro-P 2P...-...H...
Scale
8
size 2
A1
en
9100002530_MB-00
9
Stat. Alteration
9
Date
Name Origin:
10
Vorderansicht / front view
X7
Free size tolerances Surfaces
MB Thyro-P
2P...-...H...
Bgr. 2 275
Dimensional
Drawing
repl.for:
repl.by:
11
Page
1
1 Pa.
12
Seitenansicht / side view
A
A
B
B
C
C
404
15,906
X10
D
370
14,567
350
13,780
D
*
*
X24
X5.1
Cu 43x5; O11
Cu 1,692x0,196; O0,433
X5.2
E
E
X2
Cu 25x5; O11
Cu 0,984x0,196; O0,433
X30
Observe protection note to DIN 34.
F
U2
W2
W1
57,4
2,260
U1
38
1,496
F
X31
M10 für Erdung
M10 for earthing
G
6,5
,256
18
,709
64
2,520
138,5
5,453
X50
189
7,441
Thyro-P 2P ... -280 H
Thyro-P 2P 690- 200 H
Baugröße: 2F
size: 2F
*) Zum entrigeln Federhacken nach rechts drücken.
*) press the spring hook to the right for unlocking.
H
Thyro-P 2P (200 HF, 280 HF) 2
3
G
30
1,181
275
10,827
325
12,795
1
66,5
2,618
229
9,016
30
1,181
4
5
6
7
8
9
1:1
Material:
Blank:
MB Thyro-P 2P...-...H...
Mass: ca. 15 kg.
Free size tolerances Surfaces
Scale
Name
Date
Editor 04.02.2014 j.panitz
Check
Norm.
MB Thyro-P 2P...-...H...
Bgr. 2F
9100002531_MB-00
Stat. Alteration
size 2F
A1
en
Page
1
1 Pa.
Dimensional Drawing 277
Date
Name Origin:
repl.for:
repl.by:
95
1
2
3
4
5
Vorderansicht / front view
6
7
8
Seitenansicht / side view
A
B
M10 für Erdung
M10 for earthing
412
16,207
370
14,567
350
13,780
X24
X5.1
X5.2
26
1,024
X50
34,5
1,358
U1
U2
W1 W2
U2
Cu 46x3 O11
Cu 1.811x0,118 O 0,433
U1
40 14
1,575 ,551
C
X7
10
,394
6,5
,256
90
3,543
Observe protection note to DIN 34.
D
2P ... - 495 HF
2P ... - 650 HF
X2
X30
X31
12,5
,492
22
,866
30,5
1,201
134
5,276
200
7,874
261
10,276
76
2,992
340
13,386
Seitenansicht / side view
E
U2
2P 690 - 300 HF
U1
60
2,362
Cu 40x3 O11
Cu 1,574x0,118 O 0,443
144
5,669
76
2,992
Thyro-P 2P (300 HF, 495 HF, 500 HF, 650 HF) 1
2
1
2
4
4
5
7
M
1:2,5
Material:
Blank:
MB Thyro-P 2P...-...H...
Scale
Bgr. K
MB Thyro-P 2P...-...H...
9100002536_MB-00
5
6
Vorderansicht / front view
Stat. Alteration
8
Name Origin:
Date
9
10
repl.for:
repl.by:
11
12
Seitenansicht / side view
X7
A
55
2,165
A
Free size tolerances Surfaces
Dimensional Drawing 278
3
3
K0,17
Name
Date
Editor 03.02.2014 j.panitz
Check
Norm.
F
X24
X5.1
X5.2
B
B
X2
X30
X31
X50
C
O14 für Erdung
O,551 for earthing
762
30,000
650
25,591
C
U1
U2
W1
3P 690-1400 HF
3P ... -1500 HF
U2
W2
U1
57
2,244
Observe protection note to DIN 34.
F
35
1,378
9x19
,354x,590
37
1,457
123
4,852
166,5
6,555
365
14,370
399
15,709
410
16,142
E
99,5
3,917
E
17
,669
D
Cu 60x10 O14
Cu 2,236x0,939 O 0,551
26
1,024
D
225
8,858
295
11,614
313
12,323
26
1,024
90
3,543
26
1,024
F
Seitenansicht / side view
3P 690 - 780 HF
3P ... -1000 HF
Cu 40x10 O14
Cu 1,574x0,939 O 0,551
G
U2
40
1,575
G
102,5
4,035
U1
K0,08
330
12,992
H
1
2
3
4
Thyro-P 2P (780 HF, 1000 HF, 1400 HF, 1500 HF) 5
6
7
86
3,386
8
9
1:2,5
Material:
Blank:
MB Thyro-P 2P...-...H...
Mass: 55 Kg
Free size tolerances Surfaces
Scale
Name
Date
Editor 23.07.1999 j.panitz
Check
Norm.
MB Thyro-P 2P...-...H...
size K0,08
9100002539_MB-00
Stat. Alteration
Date
Name Origin:
Dimensional Drawing 280
repl.for:
repl.by:
Bgr. K0,08
A1
en
Page
1
1 Pa.
96
1
2
3
4
5
6
7
8
9
10
11
A
X7
X10
X2
X5.2
X5.1
X24
B
X30
X31
C
X50
Cu 80x10; ø14
U1
U2
W1
W2
837
32.953
675
26.575
Cu 3.149x0.393; ø 0.551
257
10.118
Observe protection
Schutzvermerk
nachnote
DIN to
34DIN
beachten.
34.
D
70
2.756
130
5.118
40
1.575
E
F
40
1.575
9x15
210
8.268
225
8.858
31
1.220
365
14.370
0.54x0.590
ø9 für Erdung
15
.591
395
15.551
63
2.480
ø 0.354 for earthing
91
3.583
549
21.614
284
11.161
445
17.526
470 bei 2P 690-1850 HF
G
18.5 for 2P 690- 1850 HF
Freimafltoleranz.
Free size tolerances
K 0,05
K 0,048
Thyro-P 2P (1850 HF, 2000 HF)
Dimensional Drawing 282
H
01
1
2
3
4
Oberfl‰chen
Surfaces
5
6
7
8
Stat.
Zust.
Text EN
Alteration
ƒnderung
1999
Datum
Date
Name
Bearb.
Editor
18.06.
pA.
Gepr.
Check
18.06.
Le
Weight:ca
1:2.5
Thyro-P
Norm.
2P ...-2000 HF
2P 690-1850 HF
Origin:
Urspr.:
repl.for:
Ers.f.:
2000000282 MB
02.05.06 Pa.
Date
Datum
Maflstab
Scale
Name
Norm.
repl.by:
Ers.d.:
97
Thyro-P 2P (2400 HF, 2750 HF)
1
A
1
2
2
3
3
Dimensional Drawing 283
4
4
5
5
6
6
7
7
8
8
9
10
10
11
11
12
12
A
B
B
X10
C
*
*
X24
X24
X5.1
X5.1
X5.2
X5.2
X2
U1
U1
U2
U2
V1
V1
V2
V2
W1
W1
W2
W2
Cu 17x2; M6
Cu 17x2; M6
Cu 0,669x0,078; M6 Cu 0,669x0,078; M6
X30
X30
X31
X31
D
D
E
E
F
F
G
G
86,5
3,406
86,5
3,406
32,5
1,280
32,5
1,280
M6 für12,5
Erdung
M6 for ,492
earthing
35
1,378
12,5
,492
179,7
7,075
6,5
,256
X50 6,5
,256
X50
179,7
7,075
229
9,016
35
1,378
110
4,331
110
4,331
185
7,283
32
1,260
32
1,260
229
9,016
185
7,283
250
9,843
300
11,811
G
Thyro-P 3P ...- Thyro-P
37 H 3P ...- 37 H
Thyro-P 3P ...- Thyro-P
75 H 3P ...- 75 H
Thyro-P 3P ...-110
H 3P ...-110 H
Thyro-P
*) Zum entrigeln*) Federhacken
rechts drücken.
Zum entrigelnnach
Federhacken
nach rechts drücken.
*) press the spring
hooktheto spring
the right
*) press
hookfortounlocking.
the right for unlocking.
Thyro-P 3P (5 H, 16 H, 25 H, 37 H, 75 H, 110H)
H
C
105,5
4,154
105,5
4,154
Observe protection note to DIN 34.
Observe protection note to DIN 34.
M6 für Erdung
M6 for earthing
250
9,843
300
11,811
G
C
X2
E
F
B
Cu 25x2; M6
Cu 25x2; M6
Cu 0,987x0,078; M6 Cu 0,987x0,078; M6
D
E
B
*
320
12,598
300
11,811
320
12,598
300
11,811
D
*
*
A
X10
C
*
A
Seitenansicht
Seitenansicht
/ side view/ side view
Vorderansicht
Vorderansicht
/ front view/ front view
F
9
Dimensional Drawing 284
Baugröße: 1
size: 1
H
Baugröße: Free
1 size tolerances
size: 1
tolerances
SurfacesFree size
1:1 Surfaces
Scale
Material:
Blank:
1:1 Mass: ca. 13,5 kg. Mass: ca. 13,5 kg.
Material:
Blank:
Thyro-P
size 1 3P...-...H...
size 1
Scale
Name
Name
Date
Date
Thyro-P
3P...-...H... MB
j.panitz
04.02.2014
Editor 04.02.2014 j.panitz Editor MB
Check
Check
Norm.
Norm.
MB Thyro-P 3P...-...H...
MB Thyro-Psize
3P...-...H...
1
A1
1
1
2
2
3
3
4
4
5
5
6
6
7
7
8
8
9
9
Stat. Alteration
Date
Stat. Alteration
Name Origin:
Date
Page
1
9100002532_MB-00
9100002532_MB-00
en 1 Pa.
Name Origin: repl.for:
repl.for:repl.by:
repl.by:
size 1
A1
en
Page
1
1 Pa.
98
1
2
3
4
5
6
7
8
9
10
11
12
A
A
Vorderansicht / front view
Seitenansicht / side view
B
B
X10
C
C
*
*
*
320
12,598
300
11,811
X24
D
D
X5.1
Cu 43x5; O9
Cu 1,692x0,196; O0,354
X5.2
X2
X30
Cu 25x5; O9
Cu 0,984x0,196; O0,354
X31
E
U1
U2
V1
V2
E
W2
Observe protection note to DIN 34.
F
37,9
1,492
57,4
2,260
W1
F
M10 für Erdung
M10 for earthing
6,5
,256
138,5
5,453
X50
18
,709
64
2,520
189
7,441
66,5
2,618
229
9,016
30
1,181
30
1,181
314
12,362
30
1,181
400
15,748
450
17,717
G
G
Thyro-P 3P ... -130 H
Thyro-P 3P ... -170 H
Thyro-P 3P 690- 80 H
*) Zum entrigeln Federhacken nach rechts drücken.
*) press the spring hook to the right for unlocking.
Baugröße: 2
size: 2
H
Thyro-P 3P (80 H, 130 H, 170 H)
1
2
1
3
2
3
Mass: ca. 17,0 kg.
Scale
Name
Date
Editor 04.02.2014 j.panitz
Check
Norm.
MB Thyro-P 3P...-...H...
Bgr. 2
Dimensional Drawing 287size 2
4
5
4
6
5
7
6
7
8
A1
en
9100002533_MB-00
9
8
Stat. Alteration
9
Date
Name Origin:
10
repl.for:
repl.by:
11
Page
1
1 Pa.
12
Seitenansicht / side view
Vorderansicht / front view
X7
1:1
Material:
Blank:
MB Thyro-P 3P...-...H...
Free size tolerances Surfaces
A
A
B
B
C
C
370
14,567
350
13,780
404
15,906
X10
D
*
*
*
D
X24
X5.1
X5.2
E
Cu 43x5; O11
Cu 1,692x0,196; O0,433
E
X2
X30
U2
V2
V1
W1
F
W2
57,4
2,260
U1
Cu 25x5; O11
Cu 0,984x0,196; O0,433
37,9
1,492
F
Observe protection note to DIN 34.
X31
6,5
,256
M10 für Erdung
M10 for earthing
138,5
5,453
X50
64
2,520
66,5
2,618
229
9,016
18,04
,710
G
G
30
1,181
189
7,441
30
1,181
314
12,362
30
1,181
Thyro-P 3P ... -280 H
Thyro-P 3P 690- 200 H
400
15,748
450
17,717
Baugröße: 2F
size: 2F
*) Zum entrigeln Federhacken nach rechts drücken.
*) press the spring hook to the right for unlocking.
H
1
2
3
Thyro-P 3P (200 HF, 280 HF)
4
5
6
7
8
9
1:1
Material:
Blank:
MB Thyro-P 3P...-...H...
Mass: ca. 20 kg.
Free size tolerances Surfaces
Scale
Name
Date
Editor 04.02.2014 j.panitz
Check
Norm.
MB Thyro-P 3P...-...H...
Bgr. 2F
9100002534_MB-00
Stat. Alteration
Date
Name Origin:
repl.for:
size 2F
A1
en
repl.by:
Dimensional Drawing 289
Page
1
1 Pa.
99
1
2
3
4
5
6
7
8
Seitenansicht / side view
Vorderansicht / front view
A
437
17,207
B
M10 für Erdung
M10 for earthing
C
X2
X30
X31
U1 U2
V1 V2
U2
Cu 46x3 O11
Cu 1.811x0,118 O 0,433
U1
40 14
1,575 ,551
34,5
1,358
X50
W1 W2
X7
90
3,543
10
,394
6,5
,256
90
3,543
Observe protection note to DIN 34.
D
3P ... - 495 HF
3P ... - 650 HF
26
1,024
527
20,750
370
14,567
350
13,781
X24
X5.1
X5.2
22
,866
12,5
,492
36,5
1,437
36 17
1,412 ,650
134
5,276
275
10,827
86,5
3,406
70
2,756
340
13,386
Seitenansicht / sideview
86,5
3,406
348
13,701
3P 690 - 300 HF
E
U1
Cu 40x3 O11
Cu 1,574x0,118 O 0,443
60
2,362
U2
144
5,652
76
2,992
K0,17
Free size tolerances Surfaces
Name
Date
Editor 27.01.2014 j.panitz
Check
Norm.
F
1
2
3
Thyro-P 3P (300 HF, 495 HF, 500 HF, 650 HF)
4
5
1:2,5
Material:
Blank:
MB Thyro-P 3P...-...H...
Mass: 31,5 Kg
Scale
Bgr. K0,17
MB Thyro-P 3P...-...H...
9100002537_MB-00
Stat. Alteration
Date
Name Origin:
Dimensional Drawing 290
repl.for:
repl.by:
size K0,
A2
en
Page
1
1
100
1
2
3
4
5
6
7
Vorderansicht / front view
8
9
10
11
12
Seitenansicht / side view
X7
55
2,165
A
X24
X5.1
X5.2
B
X2
X30
X31
X50
762
30,000
650
25,591
C
780 HF
3P 690-1400 HF
3P ... -1500 HF
O14 für Erdung
O,551 for earthing
Cu 60x10 O14
Cu 2,236x0,939 O 0,551
U2
U2
V1
V2
W1
U1
W2
57
2,244
E
99,5
3,917
137
5,394
U1
166,5
6,555
17
,669
Observe protection note to DIN 34.
531
20,906
565
22,244
575
22,638
17
,669
225
8,858
295
11,614
313
12,323
26
1,024
90
3,543
26
1,024
Seitenasicht / side view
3P 690 - 780 HF
3P ... -1000 HF
1000 HF 1500 HF
U2
U1
102,5
4,035
G
Cu 40x10 O14
Cu 1,574x0,939 O 0,551
40
1,575
F
35
1,378
166,5
6,555
9x19
,354x,590
37
1,457
123
4,843
26
1,024
D
330
12,992
86
3,386
K0,08
H
Thyro-P 3P (780 HF, 1000 HF, 1400 HF, 1500 HF)
1
2
3
4
5
6
7
8
Dimensional Drawing 292
9
Stat. Alteration
Date
Mass: 76 K
1:2,5
Material:
Blank:
Thyro-P 3P...-...H... Bgr. K0,08
Free size tolerances Surfaces
Scale
Name
Date
Editor 23.07.1999 j.panitz
Check
Norm.
Thyro-P 3P...-...H... size K0,08
Name Origin:
9100002540_MB-00
repl.for:
repl.by:
A
en
101
1
2
3
4
5
6
7
1
2
3
4
5
6
7
8
9
10
11
8
9
10
11
457
17.973
457
17.973
X7
X7
A
A
X10
X5.2 X5.2
X5.1 X5.1
B
B
X2 X2
X24 X24
X10
X30
X31
X30
X31
X50
X50
Cu 80x10; ø14
Cu3.149x0.393;ø0.551
80x10; ø14
Cu
Cu 3.149x0.393;ø0.551
C
U1
U1
U2
U2
V1
V1
V2
V2
W1
W1
W2
W2
D
Schutzvermerk
Observe
protection
nach
note
DIN
to
34note
DIN
beachten.
Observe
Schutzvermerk
protection
nach
DIN34.
to
34DIN
beachten.
34.
D
10941094
43.071
43.071
925 925
36.417
36.417
C
E
257 257
10.118
10.118
E
130 130
5.118
5.118
F
40
1.575
40
1.575
G
G
210
8.268
210
8.268
225
8.858
225
8.858
284
31
1.220
31
1.220
70 70
2.756
2.756
40 40
1.575
1.575
F
9x15
9x15
365
14.370
365
395
14.370
15.551
395
63
2.480
63
2.480
15
15
.591
91
3.583
91
3.583
.591
15.551 549
21.614
549
11.161
284
11.161
445
17.520
445
ø9 für Erdung
ø9 für Erdung
ø 0.354 for earthing
ø 0.354 for earthing
21.614
17.520
K 0,05
0,05
K 0,048
K 0,048
470 bei 3P 690-1700 HF
470 bei 3P 690-1700 HF
18.5 for 3P 690-1700 HF
Freimafltoleranz.
Free size tolerances
Oberfl‰chen
Surfaces
Maflstab
Scale
1:2.5
Free size tolerances
Freimafltoleranz.
Oberfl‰chen
Surfaces
Maflstab
Scale
1:2.5
Datum
Date
Name
Thyro P
Thyro P
1999
18.5 for 3P 690-1700 HF
1999
Bearb.
Editor
Datum
Date
18.06.
Name
pA.
H
Bearb.
Editor
Gepr.
Check
18.06.
pA.
Le
H
Gepr.
Check
Norm.
18.06.
Le
Norm.
3P 690-1700 HF
2 000 000 294
2 000 000 294
01
Text EN
02.05.06 Pa.
02.05.06 Pa. Name
Date
Datum
Norm.
Origin:
Urspr.:
repl.for:
Ers.f.:
Date
Datum
Norm.
Origin:
Urspr.:
repl.for:
Ers.f.:
1
2
3
4
5
6
7
8
01Zust.
Stat.
Text
EN
Alteration
ƒnderung
1
2
3
4
5
6
7
8
Stat.
Zust.
Alteration
ƒnderung
Thyro-P 3P (1700 HF, 1850 HF)
3P ...-1850 HF
3P 690-1700
...-1850 HFHF
Name
Dimensional Drawing 294
102
Thyro-P 3P (2200 HF, 2600 HF)
Dimensional Drawing 295
103
13. ACCESSORIES AND OPTIONS
ORDER NO.
DESCRIPTION
2.000.000.380Thyro-Tool Family, commissioning and visualization tool for simple visualization
tasks; software under Windows 95/NT4.0 and later
2.000.000.408
LBA-2 with touch display, Bluetooth and SD card
2.000.000.409
with touch display, Bluetooth and SD card
2.000.000.407
Thyro-P Bluetooth adapter
2.000.000.405
SEK, cabinet installation kit for LBA-2 installation in cabinet door
2.000.000.393
2.000.000.392
2.000.000.394
2.000.000.396
Interface card Profibus DPV1 with motor potentiometer feature
Interface card Modbus RTU with motor potentiometer feature
Interface card DeviceNet with motor potentiometer feature
Interface card Ethernet (Profinet, Ethernet IP, Modbus TCP)
2.000.003.203
Snubber board 690V for Thyro-P 1P, 2P, 3P > 600 V
6.000.000.244
DC eliminator for Thyro-P 1P in VAR
2.000.000.400
Control unit for Thyro-P 1P, 2P and 3P
2.000.000.401Control device as described above plus ASM process for dynamic mains load
optimization (not for new systems)
2.000.000.399
Voltage converter 690V/43V (UE_U=016), for DIN rail mounting
8.000.007.874
Connector 2 pol., for A70, X1
0048764
Data cable to PC (RS232), without crossing
37.295.190
37.259.800
37.259.900
0017381
0017574
LL/RS232C connector interface 9-pole incl. power supply
Fiber optic splitter, supply voltage LLV.V
LLV.4, Fiber optic splitter
Fiber optic connector
Fiber optic cables
104
14. APPROVALS AND CONFORMITIES
Due to European harmonization and international reconciliation, the standards will be subject to
years of adjustment and renumbering. The detailed schedule therefore contains the current standards as well, even if the date for their expiry has already been set. There is no product norm for
Thyristor Power Controllers, so that a sensible norm structure must be created from the corresponding basic norms, which ensures safe application and opportunity for comparison.
CAUTION
Thyristor Power Controllers are non-valid devices for disconnection and may therefore be operated
only in connection with a suitable mains isolating device (for instance switch) connected on line side.
Approvals and conformities are available for Thyro-P:
• Quality standard according to ISO 9001
• Registration in acc. to UL 508, file no. E 135074
Investigated under consideration to Canadian National Standard C22.2 No. 14-95
• UL Markings:
· Field wiring terminal markings (see chapter 4 EXTERNAL CONNECTIONS)
· Use 60/75°C Copper Conductors only
· Tightening torque (pound inches) see chapter 11 TECHNICAL DATA
· Devices are suitable for the following short circuit current ratings:
Devices rated 300A
„Suitable For Use On A Circuit Capable Of Delivering Not More Than 100kA rms Symmetrical
Amperes, xxx Volts Maximum, When Protected by RK5 Class Fuses, sized max. 600A / 600V“
Devices rated 495A and 695A:
„Suitable For Use On A Circuit Capable Of Delivering Not More Than 100kA rms Symmetrical
Amperes, xxx Volts Maximum“
NOTE:
xxx = max. allowable voltage depending upon rating of the device
• „Branch circuit protection must be provided and sized according National Electrical Code and any
additional local codes“
• CE conformity
Low Voltage Directive 73/23 EEC;
EMV Directive 89/336 EEC;
Marking Directive 93/68 EEC
• Interference suppression
The RegTP confirms the compliance with the interference suppression regulations for the power
control device
105
IN DETAIL:
CONDITIONS FOR USE OF THE DEVICE
­­Built-in unit VDE 0160 5.5.1.3
DIN EN 50 178
VDE 0106 T 100:3.83
General requirements VDE 0558 T 11 DIN EN 60146-1-1
Design, vertical installation
VDE 0558 T 1
Operating conditions DIN EN 60 146-1-1; K. 2.5
Operating location, industry sector
VDE 0875 part 3 CISPR 6
Temperature performance VDE 0558 T 1
DIN EN 60 146-1-1; K 2.2
Storage temperature -25°C - +55°C
Transport temperature -25°C - +70°C
Operating temperature
-10°C - +35°C for external cooling (≥ 280A)
-10°C - +45°C for self-air cooling
-10°C - +55°C for reduced type current -2%/°C
with UL applications up to +40°C
Load class 1
DIN EN 60 146-1-1 T.2
Humidity class B
DIN 40040 DIN EN 50 178 Tab. 7
Overvoltage voltage category ÜIII VDE 0110 T1 DIN EN 50 178 Tab. 3
Degree of pollution 2
VDE 0160 T 100 DIN EN 50 178 Tab. 2
Air pressure
900 mbar ≤ 1000 m above zero level
Safe isolation
up to 500V mains voltage: VDE 0160 chapter 5.6
DIN EN 50 178 chapter 3
Air and creeping distances according
casing/mains potential ≥ 5,3 mm
to DIN EN 50178
casing/control potential ≥ 5,3 mm
mains voltage/control potential ≥ 7,2 mm and 10 mm
in the power section
interface/control potential ≥ 2,5 mm
mains voltage/interface ≥ 7,2 mm
mains voltage among themselves ≥ 5,5 mm
Test voltage
VDE 0160 Tab.6
DIN EN 50 178 Tab 18
Tests according to DIN EN 60 146-1-1 4.
EMV noise emission VDE 0839 T81-2
EN 61000-6-4
Radio interference suppression (control device)
class A DIN EN 55011
VDE 0875 T11
EMV noise resistance VDE 0839-6-2
Compatibility level class 3
VDE 0839 T2-4
ESD ≥ 8 kV
VDE 0847 T4-2:3.96 Electromagnetic fields ≥ 10V/m
Burst on mains lines ≥ 2kV
VDE 0847 T4-4:3.96 Burst on control lines
≥ 0,5kV
Surge on mains lines
≥ 2kV
Surge on control lines
≥ 0,5kV
Line-conducted CISPR 11
EN
EN
EN
EN
EN
61000-6-2
61000-2-4
61000-4-2
61000-4-3
61000-4-4
EN 61000-4-5
EN 61000-4-6
Further norms are observed, for instance voltage dips according to 61000-4-11 are ignored by the control
device, or registered by triggering of monitoring. Generally, an automated start is made after the mains
returns within tolerances.
Therefore, the conditions of the norm EN 61326 (controller standard) are also observed, even though this
norm by its structure is not applicable to power electronics > 10 respectively > 25A.
106
107
108
109
World Headquarters
1625 Sharp Point Drive
Fort Collins, CO 80525 USA
970.221.4670 Main
970.221.5583 Fax
www.advanced-energy.com
Specifications are subject to change without notice.
© 2014 Advanced Energy Industries, Inc. All rights reserved. Advanced Energy® and Thyro-P™ are trademarks of Advanced
Energy Industries, Inc.
110
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