Power Distribution, Inc. PowerHub 2 300-750 kVA Power Distribution Unit Installation and Operation

Power Distribution, Inc. PowerHub 2 300-750 kVA Power Distribution Unit Installation and Operation
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Below you will find brief information for PowerHub 2 300-750 kVA. This high-capacity, high-power-density power distribution unit offers a wide range of features, including a transformer with voltage transformation, adjustment, and isolation, as well as main circuit breakers, subfeed breakers, and transient suppression. The PowerHub 2 is front-accessible for all maintenance, and it can be configured as a manual dual redundant PDU.

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PowerHub 2 300-750 kVA PDU Installation Manual | Manualzz

WaveStar®

PowerHub 2

Power Distribution Unit

300-750 kVA

Installation and Operation

Ctrl Nr: DOC15315

Revision: 004

PowerHub 2 PDU 300-750 kVA

Thank you for your recent purchase of a WaveStar® PowerHub 2 Power Distribution Unit from Power

Distribution, Inc.

For safety reasons as well as to ensure optimal performance of your WaveStar® PowerHub 2 Power

Distribution Unit, please carefully read the instructions before trying to install, operate, service or maintain the system.

For any questions regarding the installation, operation, service or maintenance of your WaveStar®

PowerHub 2 Power Distribution Unit, please contact us:

Power Distribution, Inc. | 4200 Oakleys Court | Richmond, VA 23223

+1.800.225.4838

| [email protected]

WaveStar® Power Hub 2

Power Distribution Unit

300

– 750 kVA

Installation and Operation

DOC15315 Rev 004

© 2017 by Power Distribution, Inc. All rights reserved.

DynaCool On-demand Cooling System, JCOMM, PDI, PDIQ, Powercube, Quad-Wye, QuikSwitch, ToughRail Technology, and

WaveStar are registered trademarks of Power Distribution Inc. All other trademarks are held by their respective owners.

Power Distribution, Inc. (PDI)

Power Distribution, Inc. (PDI) designs, manufactures, and services mission critical power distribution, static switching, and power monitoring equipment for corporate data centers, alternative energy, industrial and commercial customers around the world. For over 30 years, PDI has served the data center and alternative energy markets providing flexible solutions with the widest range of products in the industry.

2

Contents

Contents

Safety ............................................................................................... 8

1 General Description .................................................................. 9

2

3

4

5

1.1

Product Summary .................................................................................. 9

1.2

Electrical Specification ............................................................................ 9

1.3

Environmental Specification ................................................................... 10

1.4

Standards ........................................................................................... 10

1.5

PDU Module Descriptions ....................................................................... 10

PDU Enclosure ........................................................................ 13

2.1

Enclosure Specifications ........................................................................ 13

2.1.1

Panels and Covers...................................................................... 13

2.1.2

Clearances ................................................................................ 13

2.1.3

Front Access PDU ....................................................................... 13

2.2

Cable Landing ...................................................................................... 15

2.3

PDU Mounting ...................................................................................... 15

Transformer ........................................................................... 16

3.1

Standard and Optional Transformer Parameters ....................................... 17

3.2

Transformer Temperature Alarms ........................................................... 17

3.3

Transformer Voltage Adjustment Taps .................................................... 17

Power Distribution ................................................................. 19

4.1

Main Circuit Breakers ............................................................................ 23

4.1.1

Main Input Circuit Breaker .......................................................... 23

4.1.2

Main Output Circuit Breaker (Optional) ......................................... 23

4.2

Output Subfeed Circuit Breakers ............................................................ 24

4.2.1

Circuit Breaker Frame Type ......................................................... 24

4.2.2

Subfeed Breaker Optional Features .............................................. 25

4.3

Transient Suppression .......................................................................... 25

4.3.1

Surge Protective Device .............................................................. 25

4.3.2

Transient Suppression Network ................................................... 25

4.4

Emergency Power Off (EPO) .................................................................. 25

4.5

Fuse Panel ........................................................................................... 26

Monitoring .............................................................................. 27

5.1

Monitoring Overview ............................................................................. 27

5.2

Monitoring Compartment ....................................................................... 27

3

PowerHub 2 PDU 300-750 kVA

6

7

5.3

WaveStar Monitors ............................................................................... 28

5.4

PDU M4G Board ................................................................................... 28

5.4.1

Layout and Connections .............................................................. 28

5.4.2

PDU M4G Board Points List (Modbus Register List) ......................... 31

5.5

Contractor Boards ................................................................................ 31

5.5.1

Basic Contractor Board ............................................................... 32

5.5.2

Enhanced Contractor Board ......................................................... 33

5.5.3

BCMS Acquisition Board (HV) ...................................................... 34

5.6

BCMS Subfeed Monitoring ..................................................................... 34

5.6.1

Subfeed Output Circuit Monitoring ............................................... 34

5.7

Dry Contact Network ............................................................................ 37

5.7.1

Dry Contacts for Subfeed Circuit Breakers (optional) ...................... 37

5.7.2

Surge Protective Device Status .................................................... 39

Manual Dual PDU Configuration ............................................. 41

6.1

Closed-Transition Power Source Transfer ................................................. 41

6.2

Manual Dual PDU Layout and Wiring ....................................................... 41

6.3

Two-Stage or One-Stage Permissive Signal ............................................. 41

6.3.1

Two-Stage Permissive Signal ....................................................... 41

6.3.1

One-Stage Permissive Signal ....................................................... 46

6.3.2

Connecting the External Dry Contact ............................................ 46

6.4

Power Transfer Procedures: Closed Transition .......................................... 46

6.4.1

Manual Transfer Mechanisms ....................................................... 46

6.4.2

Conditions Prerequisite to Initiating a Power Source Transfer .......... 47

6.4.3

Transfer from Primary Source to Alternate Source.......................... 48

6.4.4

Transfer from Alternate Source to Primary Source.......................... 48

6.5

Power Transfer Procedure: Open Transition ............................................. 48

Installation Planning: Placement and Power Connections ...... 49

7.1

Placement ........................................................................................... 49

7.2

Raised Floor ........................................................................................ 49

7.2.1

Raised Floor Loading .................................................................. 49

7.2.2

Cabling ..................................................................................... 49

7.2.3

Raised Floor Cable Entry ............................................................. 49

7.3

System Grounding Recommendations ..................................................... 49

7.3.1

Power System Grounding ............................................................ 50

7.3.2

Grounding Conductors ................................................................ 50

4

Contents

8

7.3.3

High Frequency (RF) Grounding (computer rooms) ........................ 51

7.4

Input Power Connections ....................................................................... 51

Installation Planning: PDU Network ....................................... 53

8.1

Physical Network .................................................................................. 53

8.1.1

Supported Protocols ................................................................... 53

8.1.2

ModBus RTU .............................................................................. 53

8.1.1

Biasing and Termination ............................................................. 53

8.1.2

Wiring ...................................................................................... 54

8.1.3

Customer Network Connections ................................................... 54

8.1.4

Color Monitor Backpanel ............................................................. 54

8.1.5

WaveStar Monitor Backpanel ....................................................... 55

8.2

Modbus Addresses ................................................................................ 55

8.2.1

Points List Addresses .................................................................. 55

8.2.2

Monitor Address ......................................................................... 56

8.2.3

Address Mapping Downstream of the Monitor ................................ 56

8.3

Modbus Commands and Replies ............................................................. 57

8.3.1

Command Packets ..................................................................... 57

8.3.2

Supported Commands and Replies ............................................... 57

8.4

Modbus Registers: Data and Parameters ................................................. 57

8.5

Reading and Writing Modbus Registers .................................................... 58

8.6

SNMP.................................................................................................. 58

PDU Installation ..................................................................... 59 9

9.1

Receiving and Unpacking....................................................................... 59

9.2

Placing the PDU ................................................................................... 59

9.3

Inspection ........................................................................................... 60

9.4

Output Distribution Cable(s) Installation ................................................. 60

9.5

Torque Specifications ............................................................................ 61

9.5.1

MCCB’s, MCSW’s, Contactors, and Other Electrical Components ....... 61

9.5.2

Structural Fasteners ................................................................... 62

9.6

Torque Value Quick Reference ............................................................... 62

9.6.1

Terminal Blocks and Distribution Breakers .................................... 62

10 PDU Initial Start-Up ............................................................... 63

10.1

PDU Post-Installation Inspection ............................................................ 63

10.2

Start-Up Procedure ............................................................................... 63

5

PowerHub 2 PDU 300-750 kVA

11 PDU Procedures ..................................................................... 65

11.1

Shutdown Signals ................................................................................. 65

11.2

Manual or Automatic Restart .................................................................. 65

11.3

Manual Dual PDU Procedures ................................................................. 65

12 Alarms and Troubleshooting .................................................. 66

12.1

Reading Alarms with Modbus ................................................................. 66

12.2

Summary Alarms ................................................................................. 66

12.3

Reading Alarms at the WaveStar Display ................................................. 67

12.4

Troubleshooting Guidelines .................................................................... 67

13 Service ................................................................................... 68

13.1

Start Up .............................................................................................. 68

13.2

Warranty ............................................................................................. 68

13.3

Maintenance ........................................................................................ 69

13.4

Time and Materials ............................................................................... 70

Bibliography ................................................................................... 71

Glossary ......................................................................................... 72

Appendix 1: Main Output Circuit Breaker Options ........................... 73

6

Contents

Figures

Figure 1 Front Access to Operator Controls, Components, and Customer Connections ........................... 12

Figure 2 General Assembly Drawing .......................................................................................................... 14

Figure 3 PDU Rear View, Covers Off, Transformer Compartment ............................................................. 16

Figure 4 Transformer Nameplate Sample ................................................................................................... 18

Figure 5 Transformer Taps and Main Circuit Breakers ............................................................................... 18

Figure 6 Power Distribution Components ................................................................................................... 20

Figure 7 PowerHub 2 PDU One-Line Diagram with 480/208VAC .............................................................. 21

Figure 8 PowerHub 2 One-Line Diagram with 230/400 VAC ...................................................................... 22

Figure 9 Fuse Panel .................................................................................................................................... 26

Figure 10 PDU Monitoring Components Part 1: Monitoring Compartment ................................................ 27

Figure 11 WaveStar Monitors Display Screens .......................................................................................... 28

Figure 12 PDU (M4G) Board Connections ................................................................................................. 30

Figure 13 Basic Contractor Board ............................................................................................................... 32

Figure 14 Enhanced Contractor Board ....................................................................................................... 33

Figure 15 BCMS HV Board ......................................................................................................................... 36

Figure 16 PDU Monitoring Components Part 2: Outside the Monitoring Compartment ............................. 37

Figure 17 Dry Contacts for Subfeed Circuit Breakers ................................................................................. 38

Figure 18 Surge Protective Device (SPD) Status ....................................................................................... 39

Figure 19 PowerHub 2 Manual Dual PDU General Assembly Drawing for a 400 kVA PDU ...................... 43

Figure 20 PowerHub 2 Manual Dual PDU One-Line Drawing for a 400 kVA PDU .................................... 44

Figure 21 Schematic for Manual Dual Power Transfer using Kirk Keys ..................................................... 45

Figure 22 Connecting External Permissive Dry Contact ............................................................................. 46

Figure 23 Dual Main Input Breakers and Kirk Key Mechanisms ................................................................ 47

Figure 24 Single Point Ground Conductor Connections ............................................................................. 50

Figure 25 Ground and Neutral Busbars ...................................................................................................... 51

Figure 26 Main Input Breaker with Extended Bus Option ........................................................................... 52

Figure 27 WaveStar Color Monitor Backpanel Connections ...................................................................... 54

Figure 28 WaveStar Monitor Modbus Connections .................................................................................... 55

Figure 29 Network Segmentation with Monitor ........................................................................................... 56

Figure 30 Modbus Upstream Address Remapping with Monitor ................................................................ 57

Tables

Table 1 Transformer Standard and Optional Parameters ........................................................................... 17

Table 2 Main Input Circuit Breaker Sizing by kVA and VAC ....................................................................... 23

Table 3 Main Output Circuit Breaker Characteristics .................................................................................. 23

Table 4 Subfeed Q-frame Circuit Breakers ................................................................................................. 24

Table 5 Subfeed J-frame Circuit Breakers .................................................................................................. 24

Table 6 Subfeed L-frame Circuit Breakers .................................................................................................. 24

Table 7 PDU Dry Contacts Table ................................................................................................................ 40

Table 8 Transfer Initiate Switch Prerequisite Conditions ............................................................................ 48

Table 9 Phase Wire Color Coding .............................................................................................................. 61

Table 10 Structural Fasteners Torque Table .............................................................................................. 62

Table 11 Troubleshooting Guidelines ......................................................................................................... 67

Table 12 Main Output Circuit Breaker UL/IEC Interrupting Ratings ........................................................... 73

7

PowerHub 2 PDU 300-750 kVA

Safety

Please pay special attention to the use of “Danger” symbols throughout this manual indicating electrical or other safety hazards. Following these safety instructions is extremely important to avoid possible injury or death.

DANGER!

This symbol is used throughout this manual to indicate the presence of high voltages, representing a hazard for electric shock, burn or explosion. Follow the instructions carefully to avoid serious or fatal injury.

Follow safe electrical work practices:

 Disconnect and lock-out all power supplying equipment before working on or installing PDU components. Use a properly rated voltage sensing device to confirm power is OFF.

 Electrical equipment should be installed, operated, serviced, and maintained only by qualified personnel and in accordance with all local safety codes. Power Distribution, Inc. assumes no responsibility for any consequences arising out of the use of this manual. This document should not be viewed as sufficient by otherwise non-qualified personnel to operate, service, or maintain the equipment discussed.

 Read, understand, and follow the instructions before installing this product.

 Install PDU in an appropriate environment per local regulations.

 ESD sensitive equipment. Ground yourself, discharge any static charge and ensure that the device is effectively grounded before handling the unit.

8

General Description

1 General Description

1.1 Product Summary

The WaveStar® PowerHub 2 300-750 kVA Power Distribution Unit (PDU) is a large capacity, high-powerdensity central power distribution module:

 300 kVA to 750 kVA transformer with a choice of transformer vectors, taps, and transformer inrush limits

 Wide range of circuit breakers and breaker form factors

 Integrated Transient Suppression Network (TSN), optional Surge Protective Device (SPD) and optional lightning arrestor

The PowerHub 2 is a front-accessible PDU (Figure 1) with front-access for these functions:

 Operator controls and monitoring

 Customer power, network, and dry contact connections

 Circuit breakers

 Replaceable PCBs, fuses, and other maintenance

The PDU has extensive monitoring capabilities:

 WaveStar® monitoring for transformer, main power feeds, subfeeds, and other PDU functions

 Integration with the PDI family of Branch Circuit Monitoring System (BCMS) monitoring products

 An extensive dry contact network

 WaveStar® Color Monitor

 Modbus RTU, Modbus TCP/IP, TCP/IP (for Monitor web pages), and SNMP protocols

The PDU design provides customers PDU placement flexibility with a small total space footprint:

 The PDU is front-accessible for all maintenance, requiring 36" service clearance only at the front and 6" ventilation clearance on the back plus one side.

 Cable entry to the PDU is from the top or bottom with removable conduit plates.

 The PDU can be placed on fixed floor, reinforced raised floor, or floor stand (12"- 48" H).

 Welded busbar construction, front-accessibility, and top/bottom cable entry allow the PDU to be positioned near walls or other equipment, requiring less space and service clearances than similarly sized PDUs.

The PDU can also be configured as a manual dual redundant PDU with two input sources manually switched using Kirk Keys (see Chapter 6 Manual Dual PDU Configuration).

1.2 Electrical Specification

The PDU has these electrical characteristics:

 kVA rating 300-750 kVA.

 Input frequency 60 Hz ± 5 Hz or 50 Hz ± 5 Hz.

 Input: 3-phase, 3-wire plus ground

9

PowerHub 2 PDU 300-750 kVA

 Input source voltage: o @ 50 Hz: 380V-415V o @ 60 Hz: 600, 480 or 208V

 Output: 3-phase, 4-wire plus ground

 Output Voltage: o @ 50 Hz: 575, 415/240, or 380/230V o @ 60 Hz: 600, 575, 480, or 208/120V

 All wiring per the National Electrical Code (NEC).

 Welded copper bus connections with 200% neutral.

 Computer grade single-point ground in accordance with the requirements of the NEC.

1.3 Environmental Specification

The PDU can be stored and operated within the following environmental conditions:

 Acceptable temperature ranges: o Storage temperature -36⁰C to +70⁰C (-33⁰F to 158⁰F). o Operating temperature 0⁰C to 40⁰C (32⁰F to 104⁰F).

 Relative humidity range from 0% to 95% non-condensing.

 Altitude to a maximum of 10,000 ft. The PDU is de-rated above 10,000 ft.

1.4 Standards

The PowerHub 2 PDU is listed to the applicable portions of Underwriters Laboratories standards UL1062

(PDU Standard) and UL 1950 and is CSA-certified.

It is also designed and assembled in conformance to all relevant standards of manufacturing and construction including, but not limited to, the following standards:

 UL67

 UL50

 UL489 Circuit Breaker Enclosures

 UL891

 NFPA

 IEEE 519-1991

 ANSI/UL 1449 3 rd

edition: Surge Protection Device (SPD)

 ANSI C33.4

 NEMA ST-20

 NEMA AB-1

 NEMA-PB-1

 NEC

 IBC 2010, seismic zone 4, California standard

1.5 PDU Module Descriptions

The PowerHub 2 enclosure and functional modules are described in the following chapters:

 Chapter 2, PDU Enclosure

10

General Description

 Chapter 3, Transformer

 Chapter 4, Power Distribution

 Chapter 5, PDU Monitoring

 Chapter 6, Manual Dual PDU Configuration

Later chapters describe installation and operation of the PDU.

11

PowerHub 2 PDU 300-750 kVA

Operator controls are all front-accessible.

Front access to monitoring components and to customer network connections are in the central

Monitoring Compartment on left PDU door.

Circuit breakers are behind locked viewing panels.

Customer connections (power, monitoring, dry contacts, and networking) and replaceable components are all front-accessible.

Figure 1 Front Access to Operator Controls, Components, and Customer Connections

12

PDU Enclosure

2 PDU Enclosure

2.1 Enclosure Specifications

Dimensions The cabinet enclosure is NEMA-1 rated with these dimensions:

 60" W x 84" H x 40" D, if the PDU has the standard transformer, or

 60" W x 84" H x 42" D, if required by specific transformer K-factors, conductor materials, temperature rise, or other specific transformer requirements.

Weight The 500 kVA PDU weighs approximately 3800 lbs. with the standard transformer.

Paint The cabinet enclosure is primed and painted inside and out with a suitable powder coat enamel,

IBM Pearl White or “computer hardware off-white.” Custom paint requirements can be specified by the customer.

See the General Assembly Drawing, Figure 2, for PDU views with dimensions.

2.1.1 Panels and Covers

Panels All removable panels use captive hardware and either lift off or incorporate ¼-turn latches.

Circuit breaker covers All circuit breakers and switches are mounted behind closed doors with key access to limit access to only authorized personnel. The PDU has an exterior hinged output circuit breaker cover door with a transparent window.

The PDU incorporates dead front panels over the output circuit breakers. The dead front panels allow screw-on plates to cover unused breakers positions.

2.1.2 Clearances

Service clearance: 36" front only access

Ventilation clearances (minimum):

 6" both sides, OR

 6" rear plus one side

2.1.3 Front Access PDU

The cabinet enclosure is front access only, including

 All operator controls and EPO button

 Power, network, and dry contact connections

 Circuit breakers and PCBs

 All routine maintenance

 Transformer taps

13

PowerHub 2 PDU 300-750 kVA

Figure 2 General Assembly Drawing

14

PDU Enclosure

2.2 Cable Landing

The PDU is designed for top or bottom cable input and output in the front half of the cabinet. Top and bottom cable landing panels are removable. The cable landing panels are galvanized solid plate (not prepunched) and are not painted. If aluminum conductors are used, there may be limitations on conduit.

2.3 PDU Mounting

The PDU can be mounted on

 Fixed floor

 Raised floor (PDI recommends that raised flooring be reinforced.)

 Universal floor stand: To match raised floor heights from 12" to 48", the PDU can be mounted on a floor stand, ranging from 12" to 48" high. The PDU-floor stand combination meets seismic zone

4 requirements, California Standard, IBC 2010.

15

PowerHub 2 PDU 300-750 kVA

3 Transformer

The PDU has an integral three (3) phase, copper-wound, high isolation transformer rated between 300 kVA and 750 kVA.

The transformer is specifically designed for the PDU and its applications and provides the following:

 Voltage transformation: several voltage options and vectors

 Voltage adjustment: transformer taps

 High isolation

 Conditioning

 Electrostatic shielding

The transformer compartment is the rear module of the PDU and has a large ventilation area (Figure 3).

A universal footing template inside the PDU secures the transformer to its base.

Each transformer is tested to the C57.121.91 standard.

Ventilation Area

Transformer

Nameplate

Transformer

Compartment

Ventilation

Area

Figure 3 PDU Rear View, Covers Off, Transformer Compartment

16

Transformer

3.1 Standard and Optional Transformer Parameters

The standard transformer and options are shown in the following table.

Parameter

Input Voltage

Output Voltage

Frequency

Impedance

Efficiency

Standard Transformer

480V Delta

208 /120V Wye

60 Hz

3

– 5%

DOE2016

K-Factor

Conductor Material

Inrush

Taps

Temperature Rise

K9

Copper (CU)

8

– 10x

< 750 kVA: ±2 x 2.5-3.5%

≥ 750 kVA: ±1 x 2.5-3.5%

150

⁰C

Delta-Wye Vector

Applicable Standard UL-1561

IEEE Standard C57.12.01

Average sound level

Insulation

NEMA ST-20

Class 240S

Table 1 Transformer Standard and Optional Parameters

3.2 Transformer Temperature Alarms

Options

208

– 600V

208

– 600V

50 Hz

Up to 6%

CEC, CSA, Non-DOE2016 for certain exempt categories,

NEMA Premium, TP1 (CSA)

K4, K13, K20

Aluminum (AL)

5x

Taps optional. Custom taps available, percentage subject to physical location

80

⁰C, 115⁰C, 130⁰C, 150⁰C,

175

⁰C

Delta Zig-Zag

Delta Quad-Wye

IEC 60076, CSA22.2 No 66,

CEC 400

The standard transformer has six (6) thermal overload devices to monitor core temperature in each winding.

180C Warning The first set of thermal devices is calibrated to 180⁰C, the warning threshold. If any winding reaches 180

⁰C core temperature, the thermal overload protection device closes a set of contacts for annunciation of a potential over-temperature condition.

195C Shutdown The second set of thermal devices is calibrated to 195⁰C, the shutdown threshold. If any winding reaches 195

⁰C core temperature, the thermal overload protection device closes a set of contacts for annunciation of an over-temperature condition and initiates an automatic PDU shutdown.

3.3 Transformer Voltage Adjustment Taps

Transformer taps compensate for variation in incoming voltage from the nominal value. Taps on the transformer primary let you adjust the turn’s ratio, providing a constant value of secondary voltage to the load.

The transformer nameplate (Figure 4) is located near the transformer (Figure 3) and includes transformer taps cable connections with the resulting input voltage along with other transformer specifications.

Transformer taps are changed from the front of the PDU (Figure 5).

17

PowerHub 2 PDU 300-750 kVA

Transformer taps cable connections table for adjusting incoming voltage.

Figure 4 Transformer Nameplate Sample

Main Output Circuit Breaker (from transformer)

Required by NEC if more than (6) distribution breakers

Main Input Circuit Breaker to transformer from customer power feed

Transformer Taps are behind the red panel.

Transformer Taps obscured behind CT.

Figure 5 Transformer Taps and Main Circuit Breakers

18

Power Distribution

4 Power Distribution

This chapter describes the Power Distribution Module of the PDU, including

 Main Input Breakers to transformer and optional Main Output Breaker from the transformer

 Subfeed distribution breakers

 Transient and surge protection

 Emergency Power Off (EPO) and Remote EPO (REPO)

See 1.2 Electrical Specification for voltage and frequency specifications. Grounding and wiring is described in 7.3 System Grounding Recommendations and 7.4 Input Power Connections. The following illustration (Figure 6) shows the locations of power distribution components. Typical one-line electrical diagrams using different input and output voltages are shown in Figures 7 and 8.

19

PowerHub 2 PDU 300-750 kVA

(2) Conduit Plates

Figure 6 Power Distribution Components

Conduit Plates

Phase ABC

Busbars

Hard Glastic

Separates ABC

Busbar Sets

Distribution Subfeed

Circuit Breakers

(2 columns)

Ground Busbar

Connections

Lightning Arrestor

Surge Protective

Device (SPD)

Main Output Circuit

Breaker (Optional)

200% Neutral

Busbar Connections

Customer Input

Power Connections

(Extended Bus

Option Shown)

Main Input Circuit

Breaker

20

Power Distribution

Figure 7 PowerHub 2 PDU One-Line Diagram with 480/208VAC

21

PowerHub 2 PDU 300-750 kVA

Figure 8 PowerHub 2 One-Line Diagram with 230/400 VAC

22

PowerHub 2 PDU 300-750 kVA

4.1 Main Circuit Breakers

The PDU has a Main Input Circuit Breaker to the transformer and an optional Main Output Circuit Breaker from the transformer to the Distribution Subfeeds (Figures 5-8).

The main input bus is also compatible with a main lug only (MLO) power feed

—that is, without a main breaker.

4.1.1 Main Input Circuit Breaker

Each PDU has a 600V, 480V, or 400V thermal-magnetic main input circuit breaker with optional electronic trip, sized in compliance with NEC 2011. At 480VAC the Main Input Breaker is a 600A manually operated, thermal-magnetic breaker with minimum 22 kAIC to maximum 65kAIC. An electronic trip breaker rated 700A can be substituted if an L-frame breaker is used.

The Main Input Circuit Breaker amperage and kAIC ratings vary by transformer size and input voltage and are given in the following table:

kVA CB @ 400VAC

(35 kAIC)

600A

CB @ 480VAC

(35 kAIC)

500A (if electronic) 300

400 800A

1000A

1200A

600A (thermal-magnetic)

700A (electronic trip, L-frame only)

800A 500

625 1000A

Table 2 Main Input Circuit Breaker Sizing by kVA and VAC

CB @ 600VAC

(22 kAIC)

400A

500A

700A

800A

4.1.2 Main Output Circuit Breaker (Optional)

The optional Main Output Circuit Breaker from the transformer to the output subfeeds is required by the

NEC if there are six (6) or more subfeeds. The standard output circuit breaker is from Square D

(Schneider Electric) and its characteristics are given below:

Frame Type R-Frame

Voltage Rating

Interrupting Rating

600 VAC

65 kAIC@240Vac

35 kAIC@480Vac

18 kAIC@600Vac

3-Pole Number of Poles

Circuit Breaker Rating 80% Rated

Electronic Trip Unit

Trip Function

Basic (ET1.0I)

Fixed Long-Time Adjustable Instantaneous Trip

Table 3 Main Output Circuit Breaker Characteristics

23

PowerHub 2 PDU 300-750 kVA

600V is the maximum rated voltage of the PDU. A 600VAC circuit breaker can be used with any voltage less than 600V. Circuit breakers are available in 80% and 100% ratings with other trip options. Other

Main Output Circuit Breakers are also available. See

“Appendix 1: Main Output Circuit Breaker Options and kAIC Ratings.

4.2 Output Subfeed Circuit Breakers

4.2.1 Circuit Breaker Frame Type

The PDU design accommodates a full line of Schneider Electric output subfeed circuit breakers mounted in two columns:

 Panel-mount circuit breakers (Q-, J-, and L-frame)

 L-frame plug-in circuit breakers

Circuit breakers must be of the same frame throughout the circuit breaker column. Electronic trip breakers are used when available.

The number of circuit breakers that can be installed in the PDU per frame type is given in the following tables along with amperage sizing and kAIC ratings (the values are for copper conductors unless otherwise noted). The main output bussing is designed for 65 kAIC minimum at 240VAC.

Circuit Breaker Frame

Amperage 150

Q Frame

25/65 kAIC

(Thermal-magnetic only)

175 225

Circuit Breaker Quantity 14

Table 4 Subfeed Q-frame Circuit Breakers

14 14

Circuit Breaker Frame

Amperage

150

Circuit Breaker Quantity

16

Table 5 Subfeed J-frame Circuit Breakers

Circuit Breaker Frame

175

16

J Frame

25/65/100 kAIC

225

16

L Frame (65/100 kAIC)

L Frame Plug-in (65 kAIC)

*Numbers in ( ) are for Aluminum conductors.

250

16

Amperage 250

Circuit Breaker Quantity 12

Table 6 Subfeed L-frame Circuit Breakers

400

12

500

12 (9)*

600

9 (7)*

24

Power Distribution

4.2.2 Subfeed Breaker Optional Features

Subfeed circuit breakers can have these features:

 Output circuit breakers are available in 80% (standard) or 100% (optional) ratings, where applicable.

 Control wiring for all subfeed circuit breakers enabling these features:

 Shunt trip on output breakers

 Dry contact annunciation on shunt trip

 Auxiliary status indicator for circuit breaker

See 5.8.1 Dry Contacts for Subfeed Circuit Breakers (optional) and Table 7 PDU Dry Contacts

Table for more information on subfeed dry contacts.

4.3 Transient Suppression

The PDU has three features for transient suppression:

Input An optional Lightning Arrestor or Surge Protective Device (SPD) protects the input to the transformer.

Output An optional SPD protects the transformer output to the distribution subfeed circuits.

Integrated The PDU can have an optional integrated Transient Suppression Network (TSN).

4.3.1 Surge Protective Device

As an optional feature, the PDU can incorporate a Surge Protective Device (SPD Type 2) rated either 100 kA or 200 kA on the input to or output from the transformer. The SPD complies with ANSI/UL1449 3 rd edition.

4.3.2 Transient Suppression Network

The PDU can have an optional internal high-energy TSN available for 208VAC

Δ, 480VAC Δ, and

600VAC Δ systems. The TSN includes

 a solid-state bipolar clamping device that suppresses both positive and negative transients from either the line or the critical load, and

integral capacitors for noise attenuation.

The TSN has these characteristics:

 Total surge capacitance is 40,000 amperes.

 The TSN turns on in less than 5 ns.

4.4 Emergency Power Off (EPO)

The PDU has an internally powered 120VAC shunt trip mechanism to operate a local Emergency Power

Off (EPO) and to effectively interface with the WaveStar monitoring system.

25

PowerHub 2 PDU 300-750 kVA

The PDU has a common EPO circuit, designed to accept a normally open (NO) dry contact signal. A

24VDC remote shunt trip signal is available to interface with Remote Emergency Power Off (REPO) stations.

4.5 Fuse Panel

The Fuse Panel is located in the left-side circuit breaker panel making all fuses readily accessible from the PDU front. There are 23 fuse positions as shown in Figure 9.

The Fuse Panel is located in the left-side circuit breaker panel.

Fuses F1-F10 are reserved for high voltage and the following fuse positions are currently assigned:

F1

– Input Voltage Sense Fuse

F2

– Input Voltage Sense Fuse

F3

– Input Voltage Sense Fuse

F4

– Output Voltage Sense Fuse

F5

– Output Voltage Sense Fuse

F6

– Output Voltage Sense Fuse

F7

– Power Supply Input Fuse

F8

– F10 Reserved for future use

Fuses F11-F23 are reserved for low voltage and all are reserved for future use.

Figure 9 Fuse Panel

26

Monitoring

5 Monitoring

5.1 Monitoring Overview

The PowerHub 2 has a comprehensive set of standard and optional monitoring features:

 WaveStar monitoring of the PDU transformer, Contractor Board, and power input to and output from the transformer

 WaveStar Branch Circuit Monitoring System (BCMS) monitoring of subfeeds

 Extensive dry contact network

 Choice of WaveStar® Monitors

 Choice of Modbus RTU, Modbus TCP/IP, or SNMP for communication to Building Management

System (BMS) (see Chapter 7 Installation Planning: PDU Network)

5.2 Monitoring Compartment

PDU M4G Board

WaveStar Color

Monitor

Backpanel

BCMS Board

(spare)

BCMS Board

Enhanced

Contractor Board

The Monitoring Compartment is housed in the left front door of the PDU.

Figure 10 PDU Monitoring Components Part 1: Monitoring Compartment

27

PowerHub 2 PDU 300-750 kVA

The WaveStar Monitoring Compartment (Figure 10) contains the WaveStar Monitor or Color Monitor and

PDI control and monitoring boards. The compartment is part of the left front PDU door. The panel door of the compartment swings open for access to PCBs and connections without opening the PDU door, providing easy access to PCBs and wiring.

5.3 WaveStar Monitors

There are two display choices for WaveStar monitoring (Figure 11):

 The WaveStar Color Monitor is the standard PDU monitor: a 7-inch color touchscreen that can monitor up to twenty (20) downstream devices. For information, see WaveStar® Color Monitor,

Setup and Operation PM375103.

 The WaveStar Monitor, a 5.25-in monochrome display with six operator buttons, can be substituted for the WaveStar Color Monitor. It can monitor up to ten (10) downstream devices. For information, see WaveStar® Monitor, Setup and Operation DOC15314.

WaveStar Color Monitor screen

7-inch Color Touchscreen

WaveStar Monitor screen

5.25-inch Six-Button Display

Figure 11 WaveStar Monitors Display Screens

WaveStar Monitors can be also used in conjunction with a WaveStar® BCMS Hub, which provides a consolidated power monitoring station for approximately (70) PDI devices.

5.4 PDU M4G Board

5.4.1 Layout and Connections

For the following connections, reference Figure 12

, “M4G Board Layout and Connections.”

Transformer CT (current) and voltage connections (top edge of Figure 12):

 CT connections, output current (ABC), Output 1 and Output 2

 CT Connection G-N: o Pins 1-2: Ground CT connection o Pins 3-4: Neutral CT connection

 Input 1 Voltage-G connection: Input Delta connection is 3-wire plus ground (no neutral).

 Output 1 Voltage-N connection: Output Wye connection is 4-wire plus ground.

28

Monitoring

 Input 2 or Output 2 Voltage provides a configurable second input or output voltage, used with dual input or output PDUs.

Power and Power Signals:

120VAC Input Power connection provides power to the PDU M4G Board.

24VDC Output Power connection provides power to WaveStar Color Monitor or Monitor

Power Off Controls: o Remote EPO connection from the Contractor REPO Connection (J6), see Figure 12.

Customer REPO dry contact connection is to the Contractor Board. o Local EPO connection o Thermal wires for transformer temperature measurements, which can cause PDU shutdown.

Shunt Trip: The board outputs two voltages for tripping the Main Breaker Shunt Trip: o 170VDC: 170 VDC is rectified from 120VAC input power o 24VDC

 The Restart Switch determines whether restart is automatic or manual after a voltage loss. o Switch down: PDU restart must be done manually after voltage is restored. o Switch up: PDU restart is automatic after power is restored. o See section 10.2 Manual or Automatic Restart for additional information. o NOTE: The Restart Switch requires 170VDC input to the main breaker shunt trip to function. It is not operable with the 24VDC input to the main breaker shunt trip.

29

PowerHub 2 PDU 300-750 kVA

G-N CT

Connection

Output 2

Current

ABC

Output 1

Current

ABC

Input 1

Voltage-G

Input 2 or

Output 2

Voltage

Output 1

Voltage-N

120 VAC input

(board power)

Transformer

Restart

Switch:

Down =

Manual/

Up=Auto

Processor

24VDC

Output for Shunt

Trip

170VDC

Output signal for

Shunt Trip

Output

Relay for switching input feeds

24VDC Output

Power to

WaveStar Monitor

4 Digital

Inputs

Setup

USB

Connection

Upstream / Downstream

Modbus Connections

Thermal Wires

Local EPO

24VDC Output also powers the

Enhanced Contractor Board.

Ribbon Cable Connection to

Contractor Board

Remote EPO

Figure 12 PDU (M4G) Board Connections

Other Input and Output Signals

Four Digital Inputs or Alarms: Digital inputs or alarms are primarily used for internal PDU signalling, such as a Surge Protective Device signal or Door Open condition. Digital feeds can be assigned by PDI during M4G board setup, when names can also be assigned to the inputs.

These inputs turn on bits in the M4G points list. See PDU M4G Board Points List, Modbus

Register 90. Defaults are o Digital Input 1 o Digital Input 2 o Digital Input 3 o Door Open

Output Relay: Output relay: used with a dual input PDU to signal transfer of input feed to the other feed; a phase synchronization check is performed before enabling the relay.

30

Monitoring

USB Connection: Used by PDI representatives to program setpoints, contractor board relays, etc., the

PDU M4G and Contractor Boards. PDU board setpoints cannot be altered through normal Modbus register access to prevent registers being accidentally altered. See M4G points list for further information.

Modbus Connections on the PDU M4G board are to/from the monitor.

5.4.2 PDU M4G Board Points List (Modbus Register List)

The PDU M4G Points List contains measurements and setpoints for the PDU M4G Acquisition Board and its associated Contractor Board. It has two groups of data:

 Measurements and Alarms o Current and voltages measurements from the critical load transformer o Alarms from PDU M4G Board and Contractor Board

 Setpoints for o Alarm thresholds o Contractor board setup, such as enabling building alarms and specifying names

PDI representatives must specify Modbus register setpoints or Contractor Board setup options using a special setup program connected to the M4G USB port.

The PDU M4G Board points list can be downloaded. See Bibliography for instructions on downloading points lists.

5.5 Contractor Boards

A Contractor Board is an extension of the PDU M4G Board, functioning as a terminal block to the PDU

Board and connected to the PDU Board by a ribbon cable. It is housed in the WaveStar Monitoring

Compartment with the PDU Board.

Internal PDU signaling, such as the four Digital Inputs, is terminated on the PDU M4G Board. External signaling is terminated to a Contractor Board:

 All dry contact signals for Remote Emergency Power Off (REPO), building alarms, output relays, communication ports, and other control wiring must be terminated onto a Contractor Board.

 All interface wiring (for building alarms, AC alarms, halon alarms, remote power off systems, etc.) should be run within the PDU cabinet for termination on the Contractor Board.

 All interface wiring and contacts are to be provided by others.

The customer has a choice of two (2) Contractor Boards, which act as an extension of the PDU M4G

Board for making customer connections for remote control and monitoring:

 Basic Contractor Board

 Enhanced Contractor Board, which can connect twice as many output relays and building alarms

31

PowerHub 2 PDU 300-750 kVA

5.5.1 Basic Contractor Board

(4) Building Alarms: NO

Dry Contact Connections from Customer

Ribbon Cable to PDU

M4G Board

Remote EPO

Connection to PDU

M4G Board

Modbus Upstream to Customer BMS

Modbus

Downstream to

Devices in Monitor

Chain

(4) Remote Relays, NO Dry

Contacts

Leftmost relay is triggered by

PDU Summary Alarm by default.

Remote EPO NO Dry

Contact Connection from Customer

Figure 13 Basic Contractor Board

The Basic Contractor Board has these connections (Figure 13):

Inputs:

 Remote EPO: Dry contact connection point for input of an REPO signal. Connect external dry contacts to terminals marked +24V EPO RET (Figure 13). The REPO signal is sent to the PDU

Board via the REMOTE EPO connection, which is not a customer connection point. Note:

Connection of voltage to this point can cause damage to the unit!

 Four (4) Building Alarms (Figure 13). Alarm names can be specified by PDI in PDU Board setup.

Outputs:

 Four (4) remote relays that output dry contact (NO) signals (Figure 13). (Note: Remote relays can accept dry contacts rated up to 2A/250V.) o Relays are programmable using the USB setup connection on the PDU M4G Board. PDI programs the relay inputs, usually in in manufacturing. So for example, a relay can be programmed to turn on when a specific Building Alarm, such as a fire alarm, is received.

The building management system or other control system receives the relay input, receives the signal and can cause PDU shutdown with an REPO signal.

32

Monitoring o By default, the first, left-most relay is programmed to close when the PDU Summary

Alarm, PDU Board points list, Modbus Register 70, is in alarm (Figure 13).

ModBus Connection: 4-wire configuration connection is located on the customer connection terminal block.

ModBus Connections: The board has customer connections for upstream and downstream 4-wire

Modbus (Figure 13).

5.5.2 Enhanced Contractor Board

The Enhanced Contractor Board (Figure 14) provides twice as many relays and building alarms as the

Basic Contractor Board. The Enhanced Contractor Board is used in other PDI products and many of the connectors are not used on PDUs.

24VDC power from

PDU M4G Board

REPO signal to

PDU M4G Board

Modbus

Upstream

Modbus

Downstream

Outputs:

- Remote Relays

- RR1-RR8

- Dry contacts (NO)

Input:

- Remote EPO

Connection (Dry contacts (NO))

Inputs:

-Building Alarms

BA1-BA8 (Dry contacts (NO))

Modbus

Upstream: paralleled connectors

Modbus

Downstream: paralleled connectors

NOTE: Customer connections are all at the bottom of the board.

Remote

Figure 14 Enhanced Contractor Board

Relays

RR1-RR8

NO dry contacts

24VDC Power Input: Unlike the Basic Contractor Board, the Enhanced Contractor Board has a processor and uses 24VDC power from the PDU M4G Board.

Inputs:

 Remote EPO: Dry contact connection point for input of a REPO signal to system. Connection of voltage to this point can cause damage to the unit. Connect external dry contacts to terminals

33

PowerHub 2 PDU 300-750 kVA marked +24V EPO RET (Figure 14). The REPO signal is sent to the PDU Board via the REMOTE

EPO connection, which is not a customer connection point.

 Eight (8) Building Alarms (Figure 14). Alarm names can be specified by PDI in PDU Board setup.

Outputs:

 Eight (8) remote relays that output dry contact (NO) signals (Figure 14). (Note: Remote relays can accept dry contacts rated up to 2A/250V.) o Relays are programmable using the USB setup connection on the PDU M4G Board. PDI programs the relay inputs, usually in in manufacturing. So for example, a relay can be programmed to turn on when a specific Building Alarm, such as a fire alarm, is received.

The building management system (BMS) or other control system receives the relay input, receives the signal and can cause PDU shutdown with an REPO signal. o By default, the first relay RR1 is programmed to close when the PDU Summary Alarm,

PDU Board points list, Modbus Register 70, is in alarm.

ModBus Connection: 4-wire configuration connection is located on the customer connection terminal block.

5.5.3 BCMS Acquisition Board (HV)

The PDU can have two BCMS Data Acquisition Boards High-Voltage Boards (Figure 15).

BCMS High Voltage Board Each BCMS is contained on a single PCB. The PCB has one main processor and six current processors. Current processors process CT readings.

Both main and current processors have software specific to the board type and points lists used on the board. PCB software is loaded in manufacturing using “Programming Connections.”

The High Voltage BCMS PCB has connectors for the following:

 Two voltage sources

 Cable harnesses to CTs on two panelboards (odd/even side connections)

 Cable harnesses to two main or subdistribution feeds

 A Modbus network connection

 A USB connection for setup

 A power connection

5.6 BCMS Subfeed Monitoring

5.6.1 Subfeed Output Circuit Monitoring

PDU subfeeds are monitored with the following:

 Each subfeed can have CTs for monitoring ABC phases and NG.

 Resistor Boards: Subfeed CTs are terminated onto a Resistor Board. One Resistor Board can connect up to (14) 3-phase circuits (ABC) or (10) circuits if neutrals are also monitored (ABCN).

The standard PDU configuration has one Resistor Board for each circuit breaker row. (See Figure

16 for position in PDU.)

34

Monitoring

 Branch Circuit Monitoring: the Resistor Boards are both connected to a single Branch Circuit

Monitoring System (BCMS) Acquisition Board. BCMS. A spare BCMS board can be mounted in the Monitoring Compartment. (See Figure 16 for location in PDU and Monitoring Compartment.)

 The BCMS board is loaded with the Enhanced Subfeeds Points List.

BCMS HV board is shown in Figure 15.

35

PowerHub 2 PDU 300-750 kVA

Figure 15 BCMS HV Board

36

Monitoring

Flexible Cable

Carrier for

Monitoring

Connections

Subfeed Circuit

Breakers Dry

Contacts:

- Trip

- Trip Alarms

- Auxiliary

Status

Current

Transformers

(CTs) for

Subfeeds

Subfeed Circuit

Breakers Dry

Contacts:

- Trip

- Trip Alarms

- Auxiliary

Status

Current

Transformers

(CTs) for

Subfeeds

Current

Transformers

(CTs) for

Neutral Bus

Current

Transformers

(CTs) for

Neutral Bus

Resistor Board

Resistor Board

Surge Protective

Device:

- Status Lights

- Dry Contact

Connection

Current

Transformers

(CTs) for Input

Phases

Current

Transformers

(CTs) for Input

Phases

Figure 16 PDU Monitoring Components Part 2: Outside the Monitoring Compartment

5.7 Dry Contact Network

In addition to the Modbus network, the PDU has an extensive network of dry contacts providing input signals and alarm and status annunciation. Table 7 lists available dry contact input and output signals.

5.7.1 Dry Contacts for Subfeed Circuit Breakers (optional)

Subfeeds have optional dry contacts to

 Trip a circuit breaker remotely

 Present a trip alarm

37

PowerHub 2 PDU 300-750 kVA

 Present circuit breaker status

See Figure 17 for subfeed dry contact layout.

Breaker Trip Signal (input)

- Black = Signal

- White = Neutral

Breaker Trip Alarm (output)

- White = Common

- Blue = Normally open

- Grey = Normally closed

Changes state when breaker is tripped or reset

Breaker Auxiliary Contact

(output)

- White = Common

- Blue = Normally open

- Grey = Normally closed

Changes state when breaker contacts change state (open or close)

Optional Subfeed Dry Contacts provide a set of dry contacts for each subfeed circuit breaker.

Each circuit breaker can have a dry contact set.

Figure 17 Dry Contacts for Subfeed Circuit Breakers

38

Monitoring

5.7.2 Surge Protective Device Status

The optional SPD incorporates a remote signaling contact for inclusion in the PDU dry contact system and a visual status indicator at the bottom of the right front subfeed breaker panel (Figure 18)

Status Lights for the optional Surge Protective

Device (SPD) are visible at the bottom of the right-side circuit breaker panel.

- Status lights for each phase ABC

- A green status light indicates normal operation.

- A red status light indicates loss of protection and SPD may need replacing.

- Non-illuminated status light indicates loss of power.

Terminal Block for SPD dry contact connection

Figure 18 Surge Protective Device (SPD) Status

39

PowerHub 2 PDU 300-750 kVA

Device

Monitors

PDU board

Input Signals

4 Digital Inputs

Output Signals

Summary Alarm

Signal Meaning Dry Contact Spec

NA=Not Applicable

An alarm is present on a device in the Monitor’s device chain.

0.5A @ 120VAC

0.5A @ 30VDC

NA Signals internal to PDU with assignable meanings. Digital

Input 4 = PDU door open

(default assignment).

Signal to immediately power down PDU.

NA PDU

(Contractor

Board)

Remote

Emergency

Power Off

(REPO)

4-8 Building

Alarms

PDU

(Contractor

Board)

PDU

(Contractor

Board)

Subfeed breaker(s)

(optional)

Subfeed breaker(s)

(optional)

Subfeed breaker(s)

(optional)

Surge

Protective

Device (SPD)

(optional)

Breaker trip

External

Permissive

Signal (with

Manual Dual

PDU only)

Assignable meanings. NA

Enable Solenoid

Key Release

Unit

4-8 Remote Relays Assignable meanings

Relay 1 = Summary Alarm for

PDU by default

Trip subfeed circuit breaker

OK/not OK signal

Up to 2A/250V

Breaker trip alarm Signals that subfeed circuit breaker has tripped or has been reset

Max 5A/600V

24VDC recommended

Auxiliary contacts

Max 5A/600V

24VDC recommended

Signals that subfeed circuit breaker contacts have changed state (open or closed)

Max 5A/600V

24VDC recommended

NC contact is closed when SPD is functional and powered.

600V wire required. Contact ratings:

0.3 A @ 125VDC

0.3 A @ 110 VDC

1.0 A @ 30 VDC

Stage 1 permissive signal, enabling SKRU; can be jumpered to be permanently enabled (see 6.3 Two-Stage or

One-Stage Permissive

Signal).

NA

Table 7 PDU Dry Contacts Table

40

Manual Dual PDU Configuration

6 Manual Dual PDU Configuration

The PowerHub 2 PDU can be configured as a Manual Dual PDU. The dual inputs are switched manually using Kirk Keys with a transfer initiate switch. A remote dry contact can be used to enable or disable the transfer initiate switch.

6.1 Closed-Transition Power Source Transfer

The manual dual power source transfer is a closed transition power transfer. This means that power to the load is never broken or interrupted during the transfer. Both power sources must be synchronized.

When both power sources are synchronized, the alternate power source is enabled, so that both sources are feeding the PDU and load. The primary source is then taken offline, leaving the alternate source feeding the load.

6.2 Manual Dual PDU Layout and Wiring

The PowerHub 2 Manual Dual PDU is the same as the standard PDU with these differences:

 Two M-frame circuit breakers are Main Input Circuit Breakers for the two main power feeds.

 There is no Main Output Circuit Breaker. One M-frame Main Input Breaker occupies the same location as the in the standard PDU.

 Because the NEC requires an output breaker if there are more than six (6) subfeeds, the number of subfeeds is currently limited to six (6).

 The main breakers have Kirk Key locking mechanisms. There is also a Solenoid Key Release

Unit (SKRU), located between the main breakers, which operators use to make the closedtransition, make-before-break power source transfer.

 For the external permissive signal, a terminal block is installed in the Monitoring Compartment for a dry contact connection.

The General Assembly Drawing for the PowerHub 2 Manual Dual PDU is given in Figure 19.

The One-Line Drawing is given in Figure 20.

The Schematic for the sync relay and Kirk Key interlock system is given in Figure 21.

6.3 Two-Stage or One-Stage Permissive Signal

Permissive signals allow the SKRU solenoid key to be released, letting the operator manipulate the main breakers to execute the power source transfer.

6.3.1 Two-Stage Permissive Signal

The PDU has a two-stage permissive signal for releasing the key from the SKRU key interlock:

Stage 1: An external dry contact signal enables the SKRU transfer initiate switch. The dry contact signal may originate, for example, from a UPS or the Building Management System.

41

PowerHub 2 PDU 300-750 kVA

Stage 2: An operator initiates the power source transfer using SKRU transfer initiate switch, Kirk

Key locks, and the main breakers.

42

Manual Dual PDU Configuration

Figure 19 PowerHub 2 Manual Dual PDU General Assembly Drawing for a 400 kVA PDU

43

PowerHub 2 PDU 300-750 kVA

400VAC 3PH

3W+G, 50 Hz

400VAC 3PH

3W+G, 50 Hz

400 kVA TRANSFORMER

400Y-400D/230VAC

3W+G, 50 Hz

K13, 150ºC, 50HZ

400VAC 3PH

3W+G, 50 Hz

Figure 20 PowerHub 2 Manual Dual PDU One-Line Drawing for a 400 kVA PDU

44

Manual Dual PDU Configuration

Figure 21 Schematic for Manual Dual Power Transfer using Kirk Keys

45

PowerHub 2 PDU 300-750 kVA

6.3.1 One-Stage Permissive Signal

If the external dry contact signal is not used, the terminal block connection (TB8) should have a jumper installed to permanently enable the SKRU transfer initiate switch (see Figure 22 below). This creates a single-stage permissive signal using only the Kirk Key system on the PDU front panel.

6.3.2 Connecting the External Dry Contact

The customer connects the normally open (NO) dry contact for the external permissive signal to TB8 in the Monitoring Compartment (Figure 22).

If the dry contact signal is not used, the terminal block should be jumpered to create a permanently enabled signal.

TB8: Connect NO external dry contact permissive signal to TB8.

If dry contact is not connected, install a jumper at the connection point for a permanent enabling signal.

Terminal block for connecting external dry contact permissive signal is located in the Monitoring Compartment.

Figure 22 Connecting External Permissive Dry Contact

6.4 Power Transfer Procedures: Closed Transition

6.4.1 Manual Transfer Mechanisms

The two Main Input Circuit Breakers have locks using Kirk Keys controlling access to the breakers with a

Solenoid Key Release Unit (SKRU), shown in Figure 23. There are three locks:

 The breaker for the active power source is closed with a key in its lock.

 The breaker for the inactive power source is locked open without a key in its lock.

46

Manual Dual PDU Configuration

 The third lock is in the Solenoid Key Release Unit (SKRU), which has a key that is released by a “permissive signal” to the solenoid. The operator removes the key and inserts it into the lock for the inactive power source, allowing that breaker to be closed, enabling the closed transition transfer.

Kirk Key lock, Source 1

SKRU Key Interlock

Transfer Initiate Switch:

Press to initiate transfer

Light On = Source 1 available.

Light On = Source 2 available.

Kirk Key lock, Source 2

Main Input Breaker,

Power Source 1

Solenoid Key

Release Unit (SKRU)

Main Input Breaker,

Power Source 2

Figure 23 Dual Main Input Breakers and Kirk Key Mechanisms

6.4.2 Conditions Prerequisite to Initiating a Power Source Transfer

For the transfer initiate switch to execute the closed transition transfer, both power sources must be available and synchronized. These prerequisite conditions are shown in the following table (Table 8), which is also shown on the schematic drawing (Figure 21).

Primary Power

Available?

Alternate Power

Available?

Both Sources

Synchronized?

Transfer to

Primary Power

Allowed?

Transfer to

Secondary

Power Allowed?

Yes

Yes

No

Yes

Yes

No

Yes

Yes

Yes

No

Yes

No

No

No

Yes

No

No

No

47

PowerHub 2 PDU 300-750 kVA

Table 8 Transfer Initiate Switch Prerequisite Conditions

6.4.3 Transfer from Primary Source to Alternate Source

The external permissive dry contact signal must be closed to enable the power transfer and the two power sources must be synchronized.

To transfer power input from the Primary Source to the Alternate Source (see layout, Figure 23):

1. Depress the transfer initiate switch. Unlock and remove the key from the SKRU key interlock.

2. Insert the key into the lock for alternate power source. Unlock alternate source lock and close the breaker. (Both power sources are now feeding the PDU and load.)

3. Open circuit breaker for the primary source and lock open. Remove the key from primary source lock.

4. Insert the key into the SKRU key lock and turn to lock.

6.4.4 Transfer from Alternate Source to Primary Source

The external permissive dry contact signal must be closed to enable the power transfer.

To transfer power input from the Alternate Source to the Primary Source (see layout, Figure 23):

1. Depress the transfer initiate switch. Unlock and remove the key from the SKRU (solenoid) key interlock.

2. Insert the key into the primary source lock. Unlock and close primary source circuit breaker. (Both power sources are now feeding the PDU and load.)

3. Open circuit breaker for alternate source and lock open. Remove the key from alternate source breaker lock.

4. Insert the key into the SKRU (solenoid) key interlock and turn to lock.

6.5 Power Transfer Procedure: Open Transition

During maintenance you may wish to switch power sources in an open transition transfer. Power continuity from one source to the other is not maintained. The load is dropped. The solenoid and SKRU key are not used.

To do an open transition transfer to the other source, simply swap the key from one breaker to the other:

1. Open (turn off) the primary breaker.

2. Turn the key and remove it from the primary breaker lock to extend the bar.

3. Insert the key in the alternate breaker lock and turn the key to retract the bar.

4. Close the alternate breaker, applying power to the PDU from the alternate source voltage.

Warning!

Closing the alternate circuit breaker to re-energize the PDU can result in inrush on the upstream power sources, such as a UPS. Verify that your upstream power sources can handle the inrush.

48

PowerHub 2 PDU 300-750 kVA

7 Installation Planning: Placement and

Power Connections

7.1 Placement

Follow the National Electrical Code (NEC) and local electrical codes for clearance requirements in addition to PDU clearances given in 2.1.2 Clearances. See 1.3 Environmental Specification for operating conditions.

7.2 Raised Floor

If the PDU is placed on a raised floor, properly mount the PDU c-channels to the floor mounting supports.

7.2.1 Raised Floor Loading

The PDU at 500 kVA weighs approximately 3800 lbs. The weight of the unit should be considered in planning the PDU location. Additional floor bracing is recommended for all units. The raised floor system must be able to support both the PDU as well as any other associated equipment. PDI recommends that the end user properly compute raised floor loading and supply proper floor bracing when needed.

7.2.2 Cabling

The PDU location should be specified on a floor plan showing distribution cable runs and associated equipment.

Distribution cable runs should also be recorded on the panelboard schedule. Each schedule identifies the panelboard circuit and the associated computer or peripheral.

7.2.3 Raised Floor Cable Entry

When applicable, provisions must be made for cable entry through the raised floor once the PDU has been properly located. The cable entry configuration should be free of any sharp edges and designed to allow permanent access for the distribution cables and input power cables.

7.3 System Grounding Recommendations

The proper grounding of your PDI PDU is critical to the operation of the unit. Improper grounding of a system may create unsafe conditions as well as electrical noise that may cause data processing problems.

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PowerHub 2 PDU 300-750 kVA

PDI has conducted a great deal of research on system grounding and makes the recommendations in the following sections.

Important!

Grounding for this equipment must comply with NEC and local building and electrical codes.

7.3.1 Power System Grounding

The primary concern is to provide a safe system that both complies with the electrical code (NEC article

250 in the USA, Canadian Electrical Code Section, 10, IEEE wiring regulations and chapter 54 in the UK) and ensures proper and safe equipment operation.

The PDU contains a factory wired, green grounding conductor to a single ground point inside the PDU cabinet (Figure 24). From this single ground point, each piece of equipment should be separately grounded via a green grounding conductor within the flexible output computer grade cable.

Neutral Busbars

Single Point Green Grounding

Conductor can be attached to a neutral busbar at the front lower left or front lower right.

Figure 24 Single Point Ground Conductor Connections

7.3.2 Grounding Conductors

An isolation grounding conductor identical in size, insulation material, and thickness to the grounded and ungrounded branch circuit supply conductors should be installed as part of the branch circuit that supplies the system. This grounding conductor should be marked green (or green with yellow stripe) when using a four (4) wire system.

This grounding conductor should be grounded at the nearest available grounding electrode in accordance with all electrical codes. The output cabling receptacles of the PDU should be the same grounding type.

The grounding conductors serving these receptacles should be terminated at the PDU ground bus.

The PDU has ground busbars and neutral busbars symmetrically arranged on the left and right side of the

PDU for grounding circuit breakers and other equipment (Figure 25).

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Installation Planning: Placement and Power Connections

Ground busbars Ground busbars

Neutral busbar

Neutral busbar

Figure 25 Ground and Neutral Busbars

7.3.3 High Frequency (RF) Grounding (computer rooms)

In addition to the power grounding system, a reference grounding system for high frequency noise is desirable (with the two systems being bonded together for the same reference potential). A grid made up of (2) two foot squares will provide an effective signal reference grounding system. The raised floor can be used if it has firmly connected metal stringers providing good electrical connections. If raised floor is not available, a grid can be fabricated by laying a mesh (2 foot square) of braided copper strap directly on the concrete sub floor (electrically connected at each intersection point). The frames of all the data processing equipment, including the PDU, should be connected (by the shortest possible distance) to the reference grid with braided copper. Finally, the reference grid should be bonded to the PDU for a single point potential ground reference.

For optimum performance all distances for power and high frequency grounding should be kept to an absolute minimum. To summarize, a radial grounding of this type (utilizing a single ground point) will ensure that your facility is electrically safe, complies with all code requirements, and will be essentially free of ground caused computer noise and problems.

7.4 Input Power Connections

Customers can make input power connections directly to the input breaker or with the Extended Bus

Option directly to the Extended Bus. Input wiring is the responsibility of the customer or the Installing

Contractor and must comply with NEC standards.

Extended Busbar Option connections can accommodate double-hole compression lugs and top and bottom connections to the bus.

Note: Due to high kVA in the PDU, busbar holes for power connection are 1/2" in diameter.

See Figure 26 for input power connection locations.

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PowerHub 2 PDU 300-750 kVA

A

B

C

Main Input Breaker

Extended Bus Option Connections

A

B

C

Conduit Plates (shown upside down for shipping)

Figure 26 Main Input Breaker with Extended Bus Option

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Installation Planning: PDU Network

8 Installation Planning: PDU Network

8.1 Physical Network

8.1.1 Supported Protocols

Modbus RTU is the standard protocol both upstream and downstream of the Monitor.

The WaveStar Color Monitor also supports Modbus TCP/IP upstream of the Monitor and the WaveStar

Monitor can use Modbus TCP/IP upstream with a protocol converter.

Both Monitors also support SNMP V1.

8.1.2 ModBus RTU

The standard WaveStar Color Monitor has a 4- or 2-wire plus ground, RS-422/RS-485 compatible interface. The communications parameters for the interface are

 9600 baud (default) with options for 19200 and 38400 baud

 8 bit, even parity, and 1 stop are standard with options for odd parity and no parity.

For 4-wire Modbus, all commands are sent to the Monitor on one pair and all replies from the Monitor are on the other pair. The pair on which the Monitor sends will be in a high impedance state until the Monitor responds to a command.

For 2-wire Modbus, all commands are sent to the Monitor and all replies from the Monitor are sent on the same pair. The pair will be in a high impedance state until the Monitor responds to a command. For 2wire communications the transmit + and receive + must be jumpered together as well as the transmit - and receive -. You must also verify that the packet is complete before another transmit is initiated. The interface is isolated.

8.1.1 Biasing and Termination

Because there is only one Modbus master, the master can and should drive its transmit pair continuously and, of course, never drive the receive line, except in an effort to be 2-wire compatible. However, most adapters do not drive the transmit pair until the start of the first character sent, and only continue to drive the transmit pair a few milliseconds after the last character. Consequently, for these adapters the master’s transmit pair is usually just floating most of the time.

Slaves do not drive the master’s receive pair until they send the master a response. As soon as they are finished, they must stop driving the master’s receive pair. This is necessary for other slaves to send responses on the master’s receive pair. Therefore, most of the time the master’s receive pair is just floating.

PDI devices do not require the Modbus chain to be terminated with a resistor. If other manufacturers’ equipment is connected in the Modbus device chain, consult their termination requirements.

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PowerHub 2 PDU 300-750 kVA

8.1.2 Wiring

RS485/RS422 cable length can be up to 4000 ft if the cable conforms to these specifications:

 The cable must be shielded with two (2) twisted pairs and shield/ground.

 The two transmit lines must be in one (1) twisted pair and the two (2) receive lines must be in the other twisted pair.

 The cable resistance should be 27 ohms/1000ft @ 1 kHz or less.

 The mutual capacitance should be 14pf/ft @ 1 kHz or less.

RS422 is typically 4-wire. RS485 is typically 2-wire and is slower than RS422.

8.1.3 Customer Network Connections

Customer Modbus network connections are made to the PDU’s Basic Contractor (Figure 13) or Enhanced

Contractor Board (Figure 14).

8.1.4 Color Monitor Backpanel

Transformer (*Note: AC 230V is optional and requires a different transformer.)

Fuse

Summary alarm dry contact (NO)

RESET button

Modbus

Upstream

Connectors

AC

120V/

230V*

Input

24VDC

Input

Battery

J11 Ethernet port

Figure 27 WaveStar Color Monitor Backpanel Connections

Modbus

Downstream

Connectors

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Installation Planning: PDU Network

The Color Monitor backpanel (Figure 27) has these connections:

 Power connections: 120V AC, 230V AC, and 24VDC (230V is optional and requires a different transformer.)

 Modbus connections: o Downstream (to Monitor device chain) is always 4-wire Modbus o Upstream is 4-wire or 2-wire, jumper selected

 Summary Alarm: Dry contact (NO) signals when any device in the Monitor’s device chain has an alarm condition.

The backpanel also has a RESET button: If the Monitor hangs, you can reset it by pressing this button.

8.1.5 WaveStar Monitor Backpanel

The WaveStar Monitor (monochrome) has Modbus connections and a summary alarm dry contact connection on its backpanel (Figure 28).

WaveStar Monitor summary alarm dry contact connection

WaveStar Monitor downstream Modbus connector

WaveStar Monitor upstream Modbus connector

Figure 28 WaveStar Monitor Modbus Connections

8.2 Modbus Addresses

8.2.1 Points List Addresses

Each “device” in a Monitor’s chain is a points list with its own Modbus address. A PCB may have more than one points list or multiple PCBs may be represented collectively by one points list:

 The standard WaveStar Color Monitor or the optional WaveStar Monitor is represented by a single points list.

 A PDU M4G board and contractor board are represented by a single points list.

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PowerHub 2 PDU 300-750 kVA

 A BCMS HV Data Acquisition Board can have three points lists with separate Modbus addresses but typically has two. In the PDU, each subfeed breaker column is represented by one points list.

8.2.2 Monitor Address

Each connected monitor must have a unique Modbus address between 1 and 247. The Monitor assigns additional sequential addresses for each device in its device chain. The Modbus address of the Monitor and the number of devices in its device chain are specified in the Monitor’s setup screen.

Note: Improper configuration of a WaveStar monitor may block other monitors or devices on the chain.

8.2.3 Address Mapping Downstream of the Monitor

Customers should be aware of Modbus addressing differences upstream vs. downstream of a WaveStar

Monitor.

In a Modbus network there can be only one master, typically the BMS, and only the master can poll a downstream device. However, the Monitor must also poll its downstream devices. Because there cannot be two Modbus masters, when both a Monitor and a BMS are present, the network must be divided into segments at the Monitor with one master per segment (Figure 29):

Upstream segment: BMS is master to the Monitor; Monitor is slave to the BMS.

Downstream segment: Monitor is master to its downstream devices.

Figure 29 Network Segmentation with Monitor

The BMS cannot directly address devices downstream of the Monitor because the Monitor is an endpoint of the BMS’s network segment. Instead, the Monitor maps its downstream device addresses to upstream segment addresses, sequentially assigned based on its own Modbus address. When the BMS requests data from a device downstream of a monitor, it addresses the downstream device indirectly through the

Monitor. Downstream devices are only visible to the BMS through these remapped addresses.

The Monitor caches data from its downstream devices. It responds to BMS requests with cached data or retrieves fresh data from the downstream device.

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Installation Planning: PDU Network

Plan for downstream Modbus addresses to be remapped based on the Monitor’s address. These remapped addresses are what the BMS must use to address the downstream BCMS devices (Figure 30).

Figure 30 Modbus Upstream Address Remapping with Monitor

8.3 Modbus Commands and Replies

8.3.1 Command Packets

The Monitor never initiates communications, rather it responds to command packets sent to it. Each command packet sent to the Monitor has an address byte that includes the address of the destination of that monitor. It does not respond to packets addressed to “0”.

8.3.2 Supported Commands and Replies

The following commands and replies are typical for both Monitors. See the points list for specifics

.

Report slave ID o Sent Hex: 01 11 C0 2C o Reply Hex: 01 11 0D EA FE 52 50 50 20 44 69 73 70 6C 61 79 A3 A6

Read holding registers o Sent Hex: 01 03 00 00 00 01 84 0A o Reply Hex: 01 03 02 00 00 B8 44

Write single register o Sent Hex: 01 06 00 00 00 00 89 CA o Reply Hex: 01 06 00 00 00 00 89 CA

The flag and data numbers shown here are in “human-readable” numbers.

8.4 Modbus Registers: Data and Parameters

A points lists or Modbus register map is a list of sequentially numbered 2-byte Modbus registers. Most analog channel values are single 2-byte registers representing a parameter such as input voltage, current, etc. KWH measurements use (2) contiguous 2-byte Modbus registers. Some parameters require scaling and are so noted in the points list.

The first analog channel or Modbus register in a points list is numbered 1 but, in software, it is accessed by an index value of 0. Because adjacent registers have similar readings, being one register off is not

57

PowerHub 2 PDU 300-750 kVA necessarily apparent. Consequently, it is common for a Modbus system to be off one register, and it is important to verify that the registers are correct early in the configuration procedure.

8.5 Reading and Writing Modbus Registers

A Modbus master communicates with PDI devices using Modbus commands directed at Modbus register locations in the device’s points list.

A device responds to Modbus commands addressed to any Modbus register in its points list. (If the device is downstream of a monitor or Hub, the BMS must address the points list using the remapped

Modbus addresses in the monitor or Hub.)

Use standard Modbus read and write commands to retrieve or write registers in the points lists:

1. Retrieve up to 200 bytes or 100 Modbus register values with a single read.

2. Use write commands to alter set points, such as alarm and warning thresholds.

3. Reset alarms and warnings by reading the warning or alarm register and writing it back with the alarm and warning bits turned off.

4. Separate Modbus requests to a BCMS by at least 400 ms.

8.6 SNMP

When SNMP is used upstream from a Monitor, upstream addresses are not remapped. Use the PDI

SNMP MIB, available from PDI service.

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PDU Installation

9 PDU Installation

DANGER!

A licensed electrician must install each unit.

Startup by a PDI certified technician is required to validate the warranty.

Severe or fatal injury can result from electrical shock during contact with high

voltage conductors, monitoring PCBs, or similar equipment.

Disconnect power before drilling holes, attaching cables or conduit, or

connecting PDUs to other power distribution equipment.

Use Lock Out/Tag Out procedures.

Wear suitable personal protective clothing and use protective equipment for

performing mechanical and electrical installations.

Leave ample space for attaching and routing wires.

9.1 Receiving and Unpacking

PDI carefully packages every PDU to ensure damage-free delivery to your job site. PDI recommends that you perform the following unpacking and inspection procedures immediately after your PDU has arrived.

Report any damage immediately to your PDI Service Team by calling (800) 225-4838. All freight damage claims should be initiated with the freight carrier immediately.

1. Remove the outer layer of protective shrink wrap from the unit.

2.

Cabinet: Inspect packaging, exterior panels, and doors for any visible damage (i.e. scratches dents, cracks, or torn packaging). If any damage is noted, please call the PDI Service Team at (800) 225-4838.

3.

Any damages must be noted on the bill of lading with a detailed description of the damages incurred. A claim should be filed with the freight company at the time of delivery. Failure to properly document all damages may result in the unit’s warranty being voided.

9.2 Placing the PDU

Note: Do not remove the safety bands securing the PDU to the pallet until all handling by a forklift or pallet jack is complete and the PDU is near its final position.

1.

Move the PDU, still secured to its pallet, to near its operating position as is practicable with a forklift truck or pallet jack.

2.

Carefully cut the safety bands, making sure that they do not scrape the exterior of the unit or scratch the paint. Use eye, face, and hand protections to guard against injury when bands are cut.

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PowerHub 2 PDU 300-750 kVA

3.

Remove the PDU from its pallet using a fork-lift truck. Use extreme caution to ensure the unit is properly centered on the forks.

4.

Once the unit is completely off the pallet, carefully remove the under layer of protective shrink wrap. The unit is now ready to be placed in its final position and prepared for installation. The

PDU has a bottom forklift slot to aid moving it into an MDC.

If any further assistance is needed, please call the PDI Service Team at (800) 225-4838.

9.3 Inspection

The installer or installing contractor should perform a complete internal inspection of the PDU after the

PDU has been placed in its operating position and before electrical hookup. The following items must be included in the inspection checklist:

1. Transformers: Inspect the transformers for any loose connections or displacement during shipment. Check to make sure all terminal lugs are tight and secure.

2. Internal feeders: Ensure all lug connections are tight and secure.

3. Main input feeder: a. Check the main input feeder connections at the main breaker to be sure vibration has not loosened the terminal screws. b. Check the feeders from the load side of the main breaker to the primary side of both transformers.

4. Check all other lugs (i.e. neutral bus, ground bus, terminal blocks, etc.).

9.4 Output Distribution Cable(s) Installation

Warning!

Power distribution cables and assemblies should be installed by a qualified electrical contractor and/or a factory authorized PDI representative.

The PDU should be de-energized before attempting to install any output cables or assemblies.

For assistance call PDI at (800) 225-4838.

The PDU should be in its permanent position with all input power cables properly connected before going any further. If the unit is resting on raised floor tiles, verify the proper cutouts have been made before continuing. Be careful not to remove an excessive amount of floor tiles that could cause the flooring to become unstable.

Optional output distribution cables may have been shipped already attached to the unit. If this is the case, they should be removed from the pallet and uncoiled. After they are uncoiled, they should be inspected before installation. Remove necessary floor tiles and lay out the cables to their respective equipment.

After the cables have been properly laid out, replace all removed floor tiles.

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PDU Installation

With the output cables unattached and the unit in its permanent position, the following procedures should be followed:

1. Open the access door to the distribution panelboard or subfeed breaker.

2. Remove cable entry cover panel.

3. Install the appropriate circuit breakers, if not factory-installed.

4. Locate an appropriate sized pre-punched conduit knock out.

5. Remove locknut from distribution cable end.

6. Feed cable conductor up through knock out and re-install locknut.

7. Tighten locknut securely.

8. Remove the necessary floor tiles and route the cable to its respective equipment.

9. Replace floor tiles.

10. Strip insulation approximately 1/2 inch from the end of the cable.

11. Connect phase wires to the output circuit breaker terminals according to the color-coding chart below (USA) or according to color coding as per local standards:

Country Color coding (Phase A,B,C)

United States (208V)

United States (480V)

Table 9 Phase Wire Color Coding

Black, Red, Blue

Brown, Orange, Yellow

12. Connect the ground wire (green or green with yellow tracer) to the distribution panel ground bus.

13. If the cable requires a neutral wire (white), connect this wire to the distribution panel neutral bus.

14. Checks to make sure all connections are securely tightened.

15. Reinstall and properly align all panels previously removed.

16. Mark (with pencil) installed breakers on the distribution panel schedule.

17. Check for proper phase rotation and voltage before attaching the other end of cable to its associated equipment.

Important Considerations on Output Cables:

Output cables on k-rated PDUs must have a neutral wire

that is twice the size of the phase wires.

Special care must be taken when assigning circuit breaker

positions for proper load balancing.

Care should be taken when placing the output cables in the

units to properly align and lace these due to the limited area for placing cables. Please call the PDI factory for any assistance needed to insure the placement of these cables.

9.5 Torque Specifications

9.5.1 MCCB’s, MCSW’s, Contactors, and Other Electrical Components

Always tighten electrical component (CBs, contactors, etc.) connections to the manufacturer’s torque specifications furnished with the component. There are some guidelines for electrical components if no

61

PowerHub 2 PDU 300-750 kVA manufacturer data is available. Tighten connections using Belleville type (spring) washers until washers are flat.

9.5.2 Structural Fasteners

Structural fasteners are typically used for fastening the PDU to a supplied floorstand or concrete slab. If structural fasteners are required per assembly instructions, refer to the table below for typical torque values. Tighten steel hardware parts (except electrical connections) to the values given in the following table.

Bolt Diameter

1/4”

5/16”

3/8”

7/16”

1/2”

Table 10 Structural Fasteners Torque Table

Tightening Torque (in-lb)

85

201

350

575

875

9.6 Torque Value Quick Reference

Use the following as a reference only. Always check the breaker or component labeling and/or instructions for proper torque values. DO NOT OVER TORQUE!

Always use the manufacturer’s hardware on CBs, contactors, etc. Once connections are torqued and sealed, make sure that removable lug covers are reinstalled.

9.6.1 Terminal Blocks and Distribution Breakers

Torque ratings vary depending on item in use. Please refer to label on the item.

 3.0 lb-ft of torque is typically required for distribution breakers.

 There is a wide variation of torque requirements for terminal blocks with various sizes.

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PDU Initial Start-Up

10 PDU Initial Start-Up

Note: Before applying utility power to the unit for the first time, the electrician performing the installation and/or a factory authorized representative should be present to verify that the following steps are correctly performed.

10.1 PDU Post-Installation Inspection

After installing the PDU and attaching cables, re-inspect the PDU:

1. Visually inspect for and remove any debris that may have fallen into the PDU during installation.

2. Transformers: Inspect the transformers for any loose connections or displacement during shipment. Check to make sure all terminal lugs are tight and secure.

3. Internal feeders: Ensure all lug connections are tight and secure.

4. Main input feeder: a. Check the main input feeder connections at the main breaker to be sure vibration has not loosened the terminal screws. b. Check the feeders from the load side of the main breaker to the primary side of both transformers.

5. Check all other lugs (i.e. neutral bus, ground bus, terminal blocks, etc.).

6.

Output Distribution Cable Assemblies: Cable coils must be inspected for cuts and/or damaged conduits.

10.2 Start-Up Procedure

1.

Confirm that the PDU’s main input circuit breaker is in the “off” position.

2.

Ensure that all of the PDU’s output circuit breakers are in the “off” position.

3. The installing contractor or electrician should now verify that the input voltage to the unit matches the input voltage rating of the unit as identified on the PDU nameplate found on the outside of the front door.

4. Ensure that the input voltage has proper phase rotation and safe grounding practices as indicated above.

Warning!

Steps 1-4 must be executed before applying incoming power to the PDU.

5. Apply power to the unit.

6. Measure for the proper PDU input voltage. This should match the units rating (+ 5% to -10% from nominal rating).

7. Check the phase rotation (clockwise) and voltage.

8. En ergize the PDU main breaker by setting the toggle to the “on” position.

Note: If the main breaker trips when energized, contact PDI Service at (800) 225-4838 for

diagnostic assistance.

9. Perform an EPO check: Depress the external EPO button and verify that the main breaker shunt trips.

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PowerHub 2 PDU 300-750 kVA

10.

Manually reset the main breaker to the “on” position. This may require that you first manually trip the lever all the way to the “off” position.

11. Check the output voltages.

12. The PDU is now ready to sequentially energize the branch circuit breakers.

Note: Equipment attached to the PDU may require special start up procedures. Please consult the individual manufacturers for these requirements.

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PDU Procedures

11 PDU Procedures

11.1 Shutdown Signals

The PDU can be shut down by the PDU M4G board with a signal to trip the main breaker. The trip signal is sent using either the 170VDC or 24VDC output connections.

The PDU board will trip the main breaker if it receives any of the following signals (refer to Figure 11 for connections):

 Local EPO signal to the PDU board

 Remote EPO (REPO) signal from the Contractor Board to the PDU board: the customer REPO signal is terminated at the Contractor Board and forwarded to the M4G board.

 Thermal wires register a temperature in the PDU transformer core that exceeds the transformer temperature limit specified.

11.2 Manual or Automatic Restart

The Restart Switch on the PDU board determines if restart is automatic after a voltage loss. For the

Restart Switch to function the 170VDC output connection on the PDU M4G Board must be connected to the main breaker trip unit

—the Restart Switch does not work with the 24VDC voltage connection.

 If the Restart Switch is set to Manual (down), the main breaker is tripped when the PDU loses voltage. When the PDU receives voltage again, the main breaker must then be manually reset and closed to power up the PDU and resume operation. This is the default position: the PDU is shipped with the Restart Switch set to Manual.

 If the Restart Switch is set to Automatic (up), the main breaker is not tripped on a voltage loss.

The PDU resumes operation if voltage is in the correct range.

See 5.4 PDU M4G Board Layout and Connections for location of the Restart Switch.

11.3 Manual Dual PDU Procedures

For dual input PDUs, power source transfer procedures are given in these sections:

6.4 Power Transfer Procedures: Closed Transition

6.5 Power Transfer Procedure: Open Transition

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PowerHub 2 PDU 300-750 kVA

12 Alarms and Troubleshooting

Alarms can be issued from the following PDU monitoring components through their points lists:

 PDU (M4G) Board, monitors conditions in the critical load transformer and inputs from the

Contractor Board.

 Two BCMS Panelboard points lists (Panelboard 1 and Panelboard 2) monitor the panelboard main feeds and branch circuits.

 The WaveStar Monitor also has a points list and can present a basic communication alarm for each device in its Modbus chain.

Alarms can be read in two ways:

Modbus. A BMS or other Modbus master device, such as a WaveStar Hub, can read the points list for each component.

WaveStar Monitor. Alarms for each device can be displayed on the Alarm Screen.

12.1 Reading Alarms with Modbus

Each device has its own points list with summary alarm Modbus registers indicating that an alarm is present on that device. The user can check alarm specifics through the BMS or go to the PDU and check the WaveStar Monitor Banner/Alarm Screen.

The BMS should read these summary alarm registers regularly to be appraised of power conditions requiring immediate attention.

12.2 Summary Alarms

Monitors Both Monitor options have a summary alarm that is issued whenever a device in its chain has an alarm or warning. Summary alarms can be issued in these ways:

 Dry contact connection on the Monitor backpanel

 Modbus Points List, summary alarm point or register: the summary alarm is point is in the Alarm

Register (register 01), which can be read with Modbus RTU.

 SNMP trap

When a summary alarm is issued, an operator can go to the Monitor to check the list of active alarms.

Alarms in the Monitor points list are for communication failures with devices in its Modbus chain. These and the summary alarm are contained in the Alarm Register (register 01).

PDU The PDU M4G Board points list (Rev E) has Summary Alarm and Summary Alarm Latched registers

(registers 70-71). The point list covers both the PDU board and its associated Contractor Board.

Subfeeds The Enhanced Subfeeds points list has a Latched Summary Alarm Register (504).

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Alarms and Troubleshooting

12.3 Reading Alarms at the WaveStar Display

Alarms for all devices in the Monitor’s Modbus chain are reflected to the Monitor and displayed on the

Alarm Screen. Alarm tables by device type (such as monitor, PDU, subfeeds) are given in the respective

Monitor manual. See WaveStar® Color Monitor, Setup and Operation PM375103 and WaveStar®

Monitor, Setup and Operation DOC15314.

12.4 Troubleshooting Guidelines

S

YMPTOM

P

ROBABLE

C

AUSE

R

EMEDY

No power to unit

Individual output circuit has no power.

No output from unit but indicators are on

No upstream communication

No audible indication

No able to scroll thru screens

Not able to see

PDU output readings

Unable to see

BCMS (optional) panels on front panel

Unit not connected to power source.

Main Breaker not enabled.

Output circuit breaker and/or cable are not connected to

PDU.

Main breaker is turned off or has tripped

Not able to remotely communicate to the monitor

No audible when an alarm occurs

Cannot see panel information

No output voltages or currents are displayed

No BCMS currents are displayed on monitor screens.

Table 11 Troubleshooting Guidelines

Connect unit to power source.

Turn on or reset main circuit breaker.

Connect output circuit to PDU and energize circuit.

Check LCD Display for active alarms, then reset main breaker.

Press the ESC key and verify remote upstream address, baud rate, & parity are set correctly.

Press the ESC key and verify the horn is enabled.

Press the enter button firmly to view

PDU information

Once on the input screen, use the

Up or down arrows to access output screens.

Verify a BCMS is connected to the downstream port and press the esc key to setup the number of additional panelboards added.

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PowerHub 2 PDU 300-750 kVA

13 Service

13.1 Start Up

PDI START UP is mandatory for all PDU’s purchased and is a sure way of getting your power quality equipment up and running as you need it. By following our standard START UP procedures, you can be assured that your power equipment will perform to your requirements. Features and benefits include these:

 PDI START UP services provide a factory-trained customer support engineer to oversee visual inspection of the installation and system calibration.

 PDI START UP service also provides factory-trained customer support engineers to assist with operational training.

13.2 Warranty

PDI’s Standard Warranty

PDI’s standard warranty covers the PDU for 18 months following shipment or 12 months after initial system start up, whichever comes first. After the end of the warranty period, service requests are handled on a time and material basis unless a preventative maintenance contract is in effect.

• U.S. – Full Coverage of Parts and Labor

• International – Parts Only Coverage Standard

Extended Warranty

Please contact a PDI service representative for detailed information about extended warranties.

Tel: (800) 225-4838 | Email:

[email protected]

Warranty Agreement

PDI warrants that its products will perform as specified in PDI publications, providing such products are properly installed, cared for, and properly operated under the specified environmental conditions.

Standard products manufactured by PDI are warranted to be free from defects in workmanship and material for a period of twelve (12) months from initial start up or eighteen (18) months from date of

shipment, whichever comes first. Any products which are defective in workmanship or material will be repaired or replaced at the option of PDI. The obligation of PDI hereunder shall be limited solely to repair and replacement at its factory of products that fall within the foregoing limitations and shall be conditioned upon receipt by PDI of written notice within the warranty period of any alleged defects or deficiency. No products shall be returned to PDI without its prior consent.

Where it is impractical to return suspected faulty equipment to PDI for repair or replacement, PDI will provide on-site service upon request. Replacement parts and on-site labor necessary for fitting replacement parts and removal of faulty parts will be undertaken at no charge. Charges will, however, be made for travel to and from the installation site. Where an on-site warranty is in effect, the no-charge labor shall be between 8 a.m. and 6 p.m., Monday through Friday, excluding holidays. If the customer

68

Service requests service outside the above hours, the customer agrees to pay the incremental difference between

PDI's overtime and normal labor rates.

All warranties hereunder are contingent upon the initial start-up being done by PDI trained or other authorized personnel and upon proper use in the application for which the product was intended and do not cover products which have been modified or repaired without PDI approval or which have been subjected to neglect, accident, improper installation or application or on which the original identification marks have been removed or altered. These warranties will not apply if adjustment, repair or parts replacement is required because of accident, neglect, misuse, secondary transportation or other causes other than ordinary use.

PDI's liability under this warranty shall be in lieu of any warranty or condition implied by law as the quality or fitness for any particular use of the goods, and save as provided in this clause, PDI shall not be under any liability, whether in contract, tort or otherwise for consequential damages resulting from defects in PDI products.

This warranty shall apply to all products manufactured by PDI unless this agreement is modified by addendum.

For questions, please contact the PDI service department at (800) 225-4838 or email us at

[email protected]

.

13.3 Maintenance

PDI Maintenance Contracts

PDI offers maintenance contracts to help ensure the ongoing reliability of critical power systems.

Maintenance contracts are customizable to meet specific needs (number of PM visits per year, scope of coverage (e.g. parts not included), length of contract, etc.).

Maintenance contracts include:

1. Rapid Service Response

PDI Maintenance Service responds 24 hours a day, 7 days a week without additional costs for weekends, nights or holidays.

2. Two comprehensive Preventative Maintenance Visits Annually

 Infrared Scanners provide information that can determine impending failures on connections and busing.

 Harmonic Analyzers provide real time information on the effects of harmonic currents on the power distribution system.

Other services include:

 Thorough visual inspection of all parts (bulbs, displays, missing hardware and cleanliness)

 Verification of monitor calibration

 Inspection of load balance, KVA usage and building alarms

 Test and analysis report

3. Guaranteed Parts Availability

PDI guarantees parts availability to service customer equipment in timely fashion.

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PowerHub 2 PDU 300-750 kVA

Please contact a PDI service representative for detailed information about Preventative Maintenance

Contracts.

Tel: (800) 225-4838 | Email: [email protected]

13.4 Time and Materials

In most cases the customer will be covered by START UP service or Maintenance Contracts; however, there may be times when the customer needs PDI service and lacks the benefits that these two packages provide. Therefore, PDI provides Time and Material coverage for those in need of our customer support engineers.

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PowerHub 2 PDU 300-750 kVA

Bibliography

Points Lists

Points lists for PDUs can be downloaded from the PDI website. Go to Service Software

Downloads: http://www.pdicorp.com/brands/pdi/services/customer-service/service-software-downloads

For the PDU M4G Board points list, download Wavestar® PDU Customer CD, a zip file.

Unzip the file and open the directory \Wavestar PDU Customer CD to find the following points lists and use the latest revision given:

PDU M4G Board points list is “M4G acquisition points list”.

For BCMS points lists, download BCMS II Customer CD Info, a zip file. Unzip the file and open the directory \Points List for BCMS Version to find the following points list for subfeeds and use the latest revision given:

BCMS ESF (Enhanced Subfeeds) points list is “BCMS Points List Fourteen Sub”.

Manuals for Related Products

WaveStar® Color Monitor, Setup and Operation, PM375103

WaveStar® PowerPak Power Distribution Unit, Installation and Operation, PM375118

PowerPak 2 Power Distribution Unit, Installation and Operation, PM375116

Modular Compact Remote Power Panel, Installation and Operation, PM375115

PowerWave 2™ Bus System 250A – 800A Installation and Operation, PM375106

PowerWave 2™ Bus System Branch Circuit Monitoring System, Setup and Operation,

PM375107

WaveStar® BCMS Hub, Installation and Operation, PM375108

JCOMM® Installation and Operation PM375100

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PowerHub 2 PDU 300-750 kVA

Glossary

KWH

M4G

NEC

NEMA

NC

NO

PDU

REPO

FIPS

Icu

Lcs kAIC

ANSI

BCMS

BMS

EPO

TSN

TVSS

SKRU

SPD

UBC

UL

American National Standards Institute

Branch Circuit Monitoring System

Building Management System

Emergency Power Off

Federal Information Processing Standards

Interrupting capacity ultimate

Interrupting capacity service

Kilo amps interrupting capacity

Kilowatt hour

PDU acquisition board, interfacing to WaveStar Monitor (graphical interface)

National Electrical Code

National Electrical Manufacturer’s Association

Normally Closed (dry contact)

Normally Open (dry contact)

Power Distribution Unit

Remote Emergency Power Off

Transient Suppression Network

Transient Voltage Surge Suppressor

Solenoid Key Release Unit

Surge Protective Device

Uniform Building Code

Underwriters Laboratories

72

A1: Main Output Circuit Breaker Options

Appendix 1: Main Output Circuit Breaker

Options

The optional Main Output Circuit Breaker from the transformer secondary to the output subfeeds is required by the NEC if there are six (6) or more subfeeds. For this circuit breaker, PDI provides Square D

(Schneider Electric) circuit breakers in several frame formats and kAIC ratings. For example, the smallest

PowerHub 2 PDU at 300 kVA may use M-frame breakers instead of the standard R-frame circuit breaker.

Main output circuit breakers may be 80- or 100-percent rated and may have different trip options.

Voltage Circuit breakers rated at a certain voltage can be used at any lesser voltage. For example, a breaker rated at 600V can be used at 400V.

Interrupting ratings kAIC ratings are provided for 60 Hz (UL) and 50 or 60 Hz (IEC) at various voltages in the table below (Table 12). Interrupting ratings are not available for all voltages because vendors test only at selected voltages. If a kAIC value is not listed for your output voltage, use the kAIC value for the next higher output voltage that is listed. The relationship of kAIC to voltage is not necessarily linear; therefore, do not extrapolate the kAIC value.

Consult with your sales representative and PDI Applications Engineering for circuit breakers appropriate to your application. The part number of your breaker will be given in your submittals.

Table 12 Main Output Circuit Breaker UL/IEC Interrupting Ratings

UL/CSA Rating (60 Hz) IEC 60947-2 Rating (50/60 Hz)

Square D

Circuit

Breaker

3 Phase 240 VAC 380/415 VAC

240 VAC 480 VAC 600 VAC lcu lcs lcu lcs

MG

65 kA 35 kA 18 kA 50 kA 25 kA 35 kA 20 kA

100 kA 65kA 25 kA 65 kA 35 kA 50 kA 25 kA

MJ

PG

PJ

65 kA

100 kA

35 kA

65 kA

18 kA

25 kA

50 kA

65 kA

25 kA

35 kA

35 kA

50 kA

20 kA

25 kA

PK

PL

65kA

125 kA

50 kA

100 kA

50 kA

25 kA

50 kA

125 kA

RG

65 kA 35 kA 18 kA 50 kA

RJ

RK

100 kA

65 kA

65 kA

65 kA

25 kA

65 kA

65 kA

85 kA

RL

125 kA 100 kA 50 kA 125 kA lcu=Interrupting capacity ultimate; lcs=Interrupting capacity service

25 kA

65 kA

25 kA

35 kA

65 kA

65 kA

50 kA

85 kA

35 kA

50 kA

70 kA

85 kA

25 kA

45 kA

20 kA

25 kA

55 kA

45 kA

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PowerHub 2 PDU 300-750 kVA

74

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Key Features

  • 300 kVA to 750 kVA transformer
  • Front-accessible for all maintenance
  • Wide range of circuit breakers
  • Integrated Transient Suppression Network
  • Extensive monitoring capabilities
  • Optional Surge Protective Device
  • Manual dual redundant PDU configuration
  • WaveStar monitoring
  • Modbus RTU, Modbus TCP/IP, and SNMP protocols
  • Top or bottom cable input and output

Frequently Answers and Questions

What is the input voltage and frequency of the PowerHub 2?
The input voltage is 3-phase, 3-wire plus ground with a range of 380V-415V at 50 Hz or 600, 480 or 208V at 60 Hz. The input frequency is 60 Hz ± 5 Hz or 50 Hz ± 5 Hz.
What are the available transformer vectors and taps?
The standard transformer has a Delta-Wye vector with copper conductors and ±2 x 2.5-3.5% taps. Options include Delta Zig-Zag, Delta Quad-Wye, and aluminum conductors with customizable taps.
What are the monitoring capabilities of the PowerHub 2?
The PowerHub 2 includes WaveStar monitoring of the transformer, main power feeds, subfeeds, and other PDU functions. It can also integrate with the PDI family of Branch Circuit Monitoring System (BCMS) monitoring products, offers an extensive dry contact network, and supports Modbus RTU, Modbus TCP/IP, and SNMP protocols for communication to a Building Management System (BMS).
What are the environmental specifications of the PowerHub 2?
The PowerHub 2 can be stored and operated within the following environmental conditions: Storage temperature -36⁰C to +70⁰C (-33⁰F to 158⁰F), operating temperature 0⁰C to 40⁰C (32⁰F to 104⁰F), relative humidity range from 0% to 95% non-condensing, and altitude to a maximum of 10,000 ft.
What are the installation requirements for the PowerHub 2?
The PowerHub 2 can be mounted on fixed floor, reinforced raised floor, or a floor stand ranging from 12" to 48" high. It requires a minimum of 36" front access clearance and 6" clearance on either both sides or the rear plus one side for ventilation.

Related manuals

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