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Legal InformationThe Schneider Electric brand and any registered trademarks of Schneider ElectricIndustries SAS referred to in this guide are the sole property of Schneider ElectricSA and its subsidiaries. They may not be used for any purpose without the owner'spermission, given in writing. This guide and its content are protected, within themeaning of the French intellectual property code (Code de la propriétéintellectuelle français, referred to hereafter as "the Code"), under the laws ofcopyright covering texts, drawings and models, as well as by trademark law. Youagree not to reproduce, other than for your own personal, noncommercial use asdefined in the Code, all or part of this guide on any medium whatsoever withoutSchneider Electric's permission, given in writing. You also agree not to establishany hypertext links to this guide or its content. Schneider Electric does not grantany right or license for the personal and noncommercial use of the guide or itscontent, except for a non-exclusive license to consult it on an "as is" basis, at yourown risk. All other rights are reserved.
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As standards, specifications, and designs change from time to time, please ask forconfirmation of the information given in this publication.
400–1600 kW 480 V
Table of Contents
Technical Data.............................................................................................5
Model List ..................................................................................................5Symmetra MW with Internal Bypass .......................................................5Symmetra MW with External Bypass ......................................................5
Efficiency ...................................................................................................5Efficiency Curves ..................................................................................6
Batteries ....................................................................................................8Efficiency DC to AC...............................................................................8Typical Battery Runtimes in Minutes for VRLA Batteries...........................8Battery Discharge Current ...................................................................10
Compliance..............................................................................................10Regulatory Approvals..........................................................................10
Communication and Management ............................................................. 11Relay Board Functions ........................................................................ 11
Facility Planning ........................................................................................13
Specifications for Systems with Internal Bypass ..........................................13Input Specifications for Systems with Internal Bypass ............................13Output Specifications for Systems with Internal Bypass .........................14Bypass Specifications for Systems with Internal Bypass ........................14Battery Specifications for Systems with Internal Bypass.........................15Recommended Cable Sizes Per Phase for Systems with InternalBypass...............................................................................................15Required Breaker Settings for Systems with Internal Bypass..................16
Specifications for Systems with External Bypass.........................................18Input Specifications for Systems with External Bypass...........................18Output Specifications for Systems with External Bypass ........................19Bypass Specifications for Systems with External Bypass .......................19Battery Specifications for Systems with External Bypass........................20Recommended Cable Sizes Per Phase for Systems with ExternalBypass...............................................................................................20Required Breaker Settings for Systems with External Bypass.................21
Recommended Cable, Bolt, and Lug Sizes for Copper and AluminumConductors ..............................................................................................23
Torque specifications ........................................................................23
Physical ...................................................................................................24Weights and Dimensions .....................................................................24Shipping Dimensions ..........................................................................24Clearance ..........................................................................................25
Environmental ..........................................................................................35Heat Dissipation .................................................................................35
Anchoring Hole Positions ..........................................................................35Anchoring Hole Positions 400 kW System.............................................36Anchoring Hole Positions 600 kW System.............................................38Anchoring Hole Positions 800 kW System with Internal Bypass ..............40Anchoring Hole Positions 1000 kW System with Internal Bypass ............42Anchoring Hole Positions 800 kW System with External Bypass .............44Anchoring Hole Positions 1000 kW System with ExternalBypass...............................................................................................48Anchoring Hole Positions 1200 kW System...........................................52Anchoring Hole Positions 1400 kW System...........................................54Anchoring Hole Positions 1600 kW System...........................................56
990–5245B–001 3
400–1600 kW 480 V
External Bypass Anchoring Hole Positions............................................58
Drawings ....................................................................................................59
Symmetra MW 400 kW 480 V with Internal Bypass .....................................59
Symmetra MW 600 kW 480 V with Internal Bypass .....................................60
Symmetra MW 800 kW 480 V with Internal Bypass .....................................61
Symmetra MW 1000 kW 480 V with Internal Bypass....................................62
Symmetra MW 800 kW 480 V with External Bypass ....................................63
Symmetra MW 1000 kW 480 V with External Bypass ..................................64
Symmetra MW 1200 kW 480 V with External Bypass ..................................65
Symmetra MW 1400 kW 480 V with External Bypass ..................................66
Symmetra MW 1600 kW 480 V with External Bypass ..................................67
Options .......................................................................................................68
Hardware Options.....................................................................................68Batteries ............................................................................................68Symmetra Accessories........................................................................68Symmetra Power Module ....................................................................68
Configuration Options ...............................................................................68
Schneider Electric Limited Factory Warranty........................................69
4 990–5245B–001
Technical Data 400–1600 kW 480 V
Technical Data
Model List
Symmetra MW with Internal Bypass
• Symmetra MW 400 kW 480 V
• Symmetra MW 600 kW 480 V
• Symmetra MW 800 kW 480 V
• Symmetra MW 1000 kW 480 V
Symmetra MW with External Bypass
• Symmetra MW 800 kW 480 V
• Symmetra MW 1000 kW 480 V
• Symmetra MW 1200 kW 480 V
• Symmetra MW 1400 kW 480 V
• Symmetra MW 1600 kW 480 V
Efficiency
25% load 50% load 75% load 100% load
400 kW 480 V 94.1 96.3 96.9 97.0
600 kW 480 V 94.1 96.3 96.9 97.0
800 kW 480 V 94.1 96.3 96.9 97.0
1000 kW 480 V 94.1 96.3 96.9 97.0
1200 kW 480 V 94.1 96.3 96.9 97.0
1400 kW 480 V 94.1 96.3 96.9 97.0
1600 kW 480 V 93.9 96.2 96.9 97.2
990–5245B–001 5
400–1600 kW 480 V Technical Data
1600 kW
Batteries
Efficiency DC to AC
400 kW 600 kW 800 kW 1000 kW 1200 kW 1400 kW 1600 kWEfficiencyat nominalbatteryvoltage (%)
96 96 96 96 96 96 96
Typical Battery Runtimes in Minutes for VRLA Batteries
NOTE: The runtimes are intended as a guide only, and Schneider Electricdisclaims the responsibility for these runtimes.
Symmetra MW 400 kW
Battery Type Number of Strings At 80% Load At 90% Load At 100% Load
Enersys HX300 2 7 6 5
Enersys HX505 2 15 14 13
Enersys HX400 3 22 17 16
Symmetra MW 600 kW
Battery Type Number of Strings At 80% Load At 90% Load At 100% Load
Enersys HX505 2 9 7 5
Enersys HX505 3 17 14 12
Enersys HX505 4 26 23 17
8 990–5245B–001
Technical Data 400–1600 kW 480 V
Symmetra MW 800 kW
Battery Type Number of Strings At 80% Load At 90% Load At 100% Load
C&D TechnologiesUPS12-490MR
3 9 7 5
Enersys HX505 4 17 15 13
Enersys HX505 5 23 19 17
Symmetra MW 1000 kW
Battery Type Number of Strings At 80% Load At 90% Load At 100% Load
Enersys HX505 4 12 10 8
Enersys HX505 5 18 15 13
Enersys HX540 5 20 17 14
Symmetra MW 1200 kW
Battery Type Number of Strings At 80% Load At 90% Load At 100% Load
Enersys HX505 4 9 7 5
Enersys HX540 5 14 12 10
C&D TechnologiesUPS12–1000
4 24 22 19
Symmetra MW 1400 kW
Battery Type Number of Strings At 80% Load At 90% Load At 100% Load
Enersys HX505 5 10 8 7
C&D TechnologiesUPS12–1000
4 19 17 15
Symmetra MW 1600 kW
Battery Type Number of Strings At 80% Load At 90% Load At 100% Load
Enersys HX540 5 9 7 5
C&D TechnologiesUPS12–1000
4 14 12 11
C&D TechnologiesUPS12–1000
5 21 19 17
990–5245B–001 9
400–1600 kW 480 V Technical Data
Battery Discharge Current
400 kW 600 kW 800 kW 1000 kW 1200 kW 1400 kW 1600 kWIbat at Vbatnominal,100% load
542 814 1085 1356 1627 1899 2170
Ibat at Vbatmin, 100%load
638 958 1276 1595 1917 2237 2556
Compliance
Regulatory Approvals
• FCC Part 15 Class A
• UL 1778 2nd Edition
• UL Listed
• cUL Listed
• TÜV
10 990–5245B–001
Technical Data 400–1600 kW 480 V
Communication and Management
Relay Board Functions
Relay Board 1 Functions
Relay Function Mode Special Comments
Output 1 Common alarm Fail safe
Output 2 Normal operation Active on
Output 3 Bypass operation Active on
Output 4 Battery operation Active on
Output 5 VDC out of tolerance Fail safe
Output 6 Battery condition fault Fail safe Battery fault detected bybattery monitor.
Output 7 Maintenance bypassoperation
Active on
Output 8 Mains out of tolerance Fail safe
Output 9 Bypass out of tolerance Fail safe
Output 10 Output out of tolerance Fail safe
Output 11 MCCB open Fail safe Battery breakers open.
Output 12 System overload Fail safe
Output 13 Good utility Active on If UPS goes into bypass, thisrelay goes on without delay.
Output 14 Boost charge active Fail safe
Output 15 Fan fault Fail safe
Output 16 Temperature fault Fail safe Temperature switch active orfaulty temperature sensor.
Input 1 Generator active Master will handlesignal
Input for indicating that agenerator is active. This willbe used to reduce the chargepower. This also activates theuse of online delay.
Input 2 Battery room ventilationfault
Individual Input for indicating that theventilation in battery rooms isdefect. This will be used toreduce the charge power.
Input 3 DC ground fault detection Individual
Input 4 Reserved for future use Master will handlesignal
Input 5 Plant clocksynchronization
Master will handlesignal
Input for real time clocksynchronization.
Input 6 Power tie detection Master will handlesignal
Input from PLC to detect ifpower tie is active.
Input 7 Force battery operation Individual This input will force the unit tobattery operation whenactivated in normal operationand report it in the event log.
Input 8 Reserved for future use
990–5245B–001 11
400–1600 kW 480 V Technical Data
Relay Board 2 Functions
NOTE: Relay board 2 is not available in 400 and 600 kVA systems.
Relay Function Mode Special Comments
Output 1 Info level alarm Fail safe
Output 2 Warning level alarm Fail safe
Output 3 Severe level alarm Fail safe
Output 4 Input frequency too high Fail safe
Output 5 Input frequency too low Fail safe
Output 6 Output frequency toohigh
Fail safe
Output 7 Output frequency too low Fail safe
Output 8 Bypass source fault Fail safe
Output 9 Close Q7 pulse Active on No delay
Output 10 Close Q8 pulse Active on No delay
Output 11 Power tie mode active Active on No delay
Output 12 Close Q2 Fail safe No delay
Output 13 Reserved for future use
Output 14 Reserved for future use
Output 15 Reserved for future use
Output 16 Reserved for future use
Input 1 Reserved for future use
Input 2 Reserved for future use
Input 3 Reserved for future use
Input 4 Reserved for future use
Input 5 Reserved for future use
Input 6 Reserved for future use
Input 7 Reserved for future use
Input 8 Reserved for future use
12 990–5245B–001
Facility Planning 400–1600 kW 480 V
Facility Planning
Specifications for Systems with Internal Bypass
Input Specifications for Systems with Internal Bypass
Model 400 kW 600 kW 800 kW 1000 kWConnections 3PH+G
Input voltage (V) 480
Input voltage range ± 15% of nominal (while providing nominal charging to the battery system)
Input frequency (Hz) 60 ± 0.5% to 8.0% configurable
Total harmonic distortion(THDI)
≤ 5%
Nominal input current (A)1 496 744 992 1240
Maximum input current(A)2
546 818 1091 1364
Input current limitation(A)3
625 938 1251 1564
Input power factor 1 at 100% load and no less than 0.97 at loads greater than 25% of system ratingwith no additional filters
Soft start Linear start from 0–100% input current and shall not exhibit inrush. Configurablefrom 1 to 40 seconds
Maximum short circuitwithstand (kA)
200
990–5245B–001 13
1. Input current based on rated load.2. Input current based on full battery recharge + nominal input voltage + rated load.3. Current limitation (A) through electronic current limiting is based on full battery recharge + nominal load and –15% input voltage.
400–1600 kW 480 V Facility Planning
Output Specifications for Systems with Internal Bypass
Model 400 kW 600 kW 800 kW 1000 kWVoltage 480 V
Connections 3PH+G
Output capacity 200% for 60 seconds (normal operation)125% for 10 minutes (normal operation)150% for 30 seconds (battery operation)125% continuous (bypass operation)1000% for 105 milliseconds (bypass operation)
Voltage tolerance ±1% for a 100% balanced load±3% for a 100% unbalanced load±5% at low DC shutoff
Nominal output current(A)
481 722 962 1203
Maximum output current(A)4
601 903 1203 1504
Output frequency (Hz) 60
Slew rate (Hz/sec) Selectable: 0.25, 0.5, 1, 2, 4
Total harmonic distortion(THDU)
≤ 3% for a 100% linear load≤ 5% for a 100% non-linear load (no crest factor limitation)
Output power factor 0.9 leading to 0.8 lagging without derating
Dynamic load response VFI SS111
Output voltage regulation ±1% for 100% balanced linear load±3% for 100% unbalanced linear load
Bypass Specifications for Systems with Internal Bypass
Model 400 kW 600 kW 800 kW 1000 kW
Connections 3PH+G
Input frequency (Hz) 60
Nominal input current (A) 481 722 962 1203
14 990–5245B–001
4. This current is at 125% of rated load and is electronically current-limited to a maximum of 10 minutes. Thisvalue is only provided so the engineer can ensure that the selected AC output circuit over-current device’s time-current characteristic will support this condition.
Facility Planning 400–1600 kW 480 V
Battery Specifications for Systems with Internal Bypass
Model 400 kW 600 kW 800 kW 1000 kWNominal voltage (VDC) 2 x 384
Float voltage (VDC) 2 x 438
Boost voltage (VDC) 2 x 460
End of discharge voltage(VDC)
2 x 326
Battery current at full load(A)
542 814 1085 1356
Maximum current (at endof discharge) (A)
638 958 1276 1595
Maximum charging power 10% of nominal output
Recommended Cable Sizes Per Phase for Systems with Internal Bypass
Input, output, battery1, and battery2 circuit cables must be run in separate conduitsor raceways. Cables must be rated at 600 V as a minimum.
Recommendation: All cables must be sized in accordance with 2014 NEC 210-19FPN No. 4 branch feeder voltage drop of 3%. Voltage drop is not considered in thebelow chart. Application-specific input cable ampacity can vary from the belowchart.
Equipment Grounding Conductors must be sized in accordance with Table 250.122of the 2014 NEC and must be installed in accordance with Article 250 Section VIand Section VII of the 2014 NEC. Grounding Electrode Conductors must be sizedin accordance with Article 250.66 and Table 250.66 of the 2014 NEC and shouldbe installed in accordance with Article 250 Section III of the 2014 NEC.
Temperature rating of conductors: 90 °C (194 °F). Reference: Table 310-16 ofNEC, 75 °C column. Use stranded copper or aluminum conductors. 75 °C (167 °F)cable terminal connectors assumed.
Reference: NEC Handbook 2014. Consult local codes for possible variations.
All cable ratings are supplied as guidelines only. These guidelines arerecommendations only, and should not be considered substitutes for review andcompliance with NEC, national, or local codes. Consult with your licensed engineerfor site-specific applications. 30 °C (86 °F) assumed. Over-current protectionprovided by others.
Model 400 kW 600 kW 800 kW 1000 kWInput Copper 2 x 350 kcmil 3 x 400 kcmil 4 x 500 kcmil 5 x 500 kcmil
Aluminum 2 x 500 kcmil 3 x 600 kcmil 5 x 500 kcmil 5 x 600 kcmil
Output Copper 2 x 350 kcmil 3 x 350 kcmil 4 x 500 kcmil 5 x 500 kcmil
Aluminum 2 x 500 kcmil 3 x 500 kcmil 5 x 500 kcmil 5 x 600 kcmil
Battery5 Copper 2 x 350 kcmil 3 x 400 kcmil 4 x 500 kcmil 5 x 500 kcmil
Aluminum 2 x 500 kcmil 3 x 600 kcmil 5 x 500 kcmil 5 x 600 kcmil
990–5245B–001 15
5. Per battery string.
400–1600 kW 480 V Facility Planning
Required Breaker Settings for Systems with Internal Bypass
A breaker coordination study is required to ensure the highest availability of theUPS. This breaker coordination study should be performed focusing onmaintaining the characteristics of the Symmetra MW.
Q1, Q5, and Upstream Breakers – Minimum Settings
Duration (S) Total load(%)
Event/Operation
Current (A)
400 kW 600 kW 800 kW 1000 kW< 0.005 – Internal fault
clearing18 kA6 18 kA6 18 kA6 18 kA6
∞ 130 Overload on-line
6477 9387 12517 16127
∞ 100 On-line 498 747 996 1245∞ 110 On-line +
max. batterycharge
558 822 1096 1370
Q2 and Downstream Breakers – Minimum Settings
Duration (S) Total load(%)
Event/Operation
Current (A)
400 kW 600 kW 800 kW 1000 kW< 0.005 – Internal fault
clearing18 kA6 18 kA6 18 kA6 18 kA6
60 200 Overload on-line
962 1444 1925 2406
600 125 Overload on-line
601 902 1203 1504
∞ 100 On-line 481 722 962 1203
Q4 Settings in Parallel Systems with Two UPS Units
Duration (S) Total load(%)
Event/Operation
Current (A)
400 kW 600 kW 800 kW 1000 kW< 0.005 – Internal fault
clearing18 kA6 18 kA6 18 kA6 18 kA6
60 200 Overload on-line
1924 2888 3849 4812
600 125 Overload on-line
1202 1805 2406 3008
∞ 100 On-line 962 1444 1925 2406
16 990–5245B–001
6. In the absence of a coordination study conducted by an engineer, the recommended instantaneous trip settingfor breakers Q1, Q2, Q4, Q5, and Q6 is 18 kA.7. Only applicable to Q1.
Facility Planning 400–1600 kW 480 V
Q4 Settings in Parallel Systems with Three UPS Units
Duration (S) Total load(%)
Event/Operation
Current (A)
400 kW 600 kW 800 kW 1000 kW< 0.005 – Internal fault
clearing18 kA8 18 kA8 18 kA8 18 kA8
60 200 Overload on-line
2886 4332 5774 7218
600 125 Overload on-line
1804 2708 3462 4512
∞ 100 On-line 1443 2166 2887 3609
In the absence of a proper breaker coordination study and if only the actual Ip onthe unit’s input terminals is known, this table must be used to optimize theinstantaneous trip setting or to choose a breaker with a usable fixed instantaneoustrip value.
Ip9 [kA] I peak let-through [kA] I setting [kA]
200 16 18
140 14 16
100 13 15
50 10.5 12
30 9 11
18 kA is the maximum peak let-through current (including safety factor) presentduring clearing of an internal fault in a 200 kW section or a power module. Thismaximum peak let-through current is based on and applicable to utility withprospective short-circuit currents (Ip) up to 200 kA. During or after a controlled faultclearing, none of the breakers are allowed to trip on the instantaneous trip settingbelow the specified value. This is also applicable to upstream breakers, and acheck of the instantaneous trip setting in this part of the installation is required.
The instantaneous trip setting calculated by an engineer in a breaker coordinationstudy must not disable the functionality of clearing and surviving an internal faultunless there is a written agreement between Schneider Electric and the customer.
By ensuring the unit’s fault clearing ability (survival skills) i.e. using the correctinstantaneous trip settings in the switchgear (installation), maximum poweravailability in normal operation is obtained for the load.
NOTE: The instantaneous trip setting can be calculated when the utility/mains Ip isknown. An incorrect trip setting can result in limiting the system functionality andjeopardize the load support.
NOTE: The instantaneous trip setting must not be derated even though the UPSsystem is derated in system output power. The system size has no influence on theinstantaneous trip setting.
NOTE: For derated systems, contact Schneider Electric for the correct breakersettings and breaker frame sizes.
NOTE: For upstream breakers not mentioned in the table, contact SchneiderElectric for the correct breaker settings for on-line, overload, and trip currents.
990–5245B–001 17
8. In the absence of a coordination study conducted by an engineer, the recommended instantaneous trip settingfor breakers Q1, Q2, Q4, Q5, and Q6 is 18 kA.9. Abridgement for Prospective short-circuit current. This is the current that would flow in the fault circuit if thefuse was replaced by a link with an infinitely small impedance.
400–1600 kW 480 V Facility Planning
Specifications for Systems with External Bypass
Input Specifications for Systems with External Bypass
Model 800 kW 1000 kW 1200 kW 1400 kW 1600 kWConnections 3PH+G
Input voltage (V) 480
Input voltage range ± 15% of nominal (while providing nominal charging to the battery system)
Input frequency (Hz) 60 ± 0.5% to 8.0% configurable
THDI ≤ 5%
Nominal input current(A)10
992 1240 1488 1736 1984
Maximum inputcurrent (A)11
1091 1364 1637 1910 2182
Input currentlimitation (A)12
1251 1564 1876 2189 2502
Input power factor 1 at 100% load and notless than 0.97 at loads greater than 25% of system rating withno additional filters
Soft start Linear start from 0–100% input current and shall not exhibit inrush. Configurable from 1to 40 seconds
Maximum shortcircuit withstand (kA)
200
18 990–5245B–001
10. Input current based on rated load.11. Input current based on full battery recharge + nominal input voltage + rated load.12. Current limitation (A) through electronic current limiting is based on full battery recharge + nominal load and –15% input voltage.
Facility Planning 400–1600 kW 480 V
Output Specifications for Systems with External Bypass
Model 800 kW 1000 kW 1200 kW 1400 kW 1600 kWVoltage 480 V
Connections 3PH+G
Output capacity 200% for 60 seconds (normal operation)125% for 10 minutes (normal operation)150% for 30 seconds (battery operation)125% continuous (bypass operation)1000% for 500 milliseconds (bypass operation)
Voltage tolerance ±1% for a 100% balanced load±3% for a 100% unbalanced load±5% at low DC shutoff
Nominal outputcurrent (A)
962 1203 1444 1684 1925
Maximum outputcurrent (A)13
1203 1504 1804 2105 2406
Output frequency(Hz)
60 60 60 60 60
Slew rate (Hz/sec) Selectable: 0.25, 0.5, 1, 2, 4
THDU ≤ 3% for a 100% linear load≤ 5% for a 100% non-linear load (no crest factor limitation)
Output power factor 0.9 leading to 0.8 lagging without derating
Dynamic loadresponse
VFI SS111
Output voltageregulation
±1% for 100% balanced linear load±3% for 100% unbalanced linear load
Bypass Specifications for Systems with External Bypass
Model 800 kW 1000 kW 1200 kW 1400 kW 1600 kW
Connections 3PH+G
Input frequency (Hz) 60
Nominal input current(A)
962 1203 1444 1684 1925
990–5245B–001 19
13. This current is at 125% of rated load and is electronically current-limited to a maximum of 10 minutes. Thisvalue is only provided so the engineer can ensure that the selected AC output circuit over-current device’s time-current characteristic will support this condition.
400–1600 kW 480 V Facility Planning
Battery Specifications for Systems with External Bypass
Model 800 kW 1000 kW 1200 kW 1400 kW 1600 kWNominal voltage(VDC)
2 x 384
Float voltage(VDC)
2 x 438
Boost voltage(VDC)
2 x 460
End ofdischargevoltage (VDC)
2 x 326
Battery currentat full load (A)
1085 1356 1627 1899 2170
Maximumcurrent (at endof discharge) (A)
1276 1595 1917 2337 2556
Maximumcharging power
10% of nominal output
Recommended Cable Sizes Per Phase for Systems with External Bypass
Input, output, battery1, and battery2 circuit cables must be run in separate conduitsor raceways. Cables must be rated at 600 V as a minimum.
Recommendation: All cables must be sized in accordance with 2014 NEC 210-19FPN No. 4 branch feeder voltage drop of 3%. Voltage drop is not considered in thebelow chart. Application-specific input cable ampacity can vary from the belowchart.
Equipment Grounding Conductors must be sized in accordance with Table 250.122of the 2014 NEC and must be installed in accordance with Article 250 Section VIand Section VII of the 2014 NEC. Grounding Electrode Conductors must be sizedin accordance with Article 250.66 and Table 250.66 of the 2014 NEC and shouldbe installed in accordance with Article 250 Section III of the 2014 NEC.
Temperature rating of conductors: 90 °C (194 °F). Reference: Table 310-16 ofNEC, 75 °C column. Use stranded copper or aluminum conductors. 75 °C (167 °F)cable terminal connectors assumed.
Reference: NEC Handbook 2014. Consult local codes for possible variations.
All cable ratings are supplied as guidelines only. These guidelines arerecommendations only, and should not be considered substitutes for review andcompliance with NEC, national, or local codes. Consult with your licensed engineerfor site-specific applications. 30 °C (86 °F) assumed. Over-current protectionprovided by others.
Model 800 kW 1000 kW 1200 kW 1400 kW 1600 kWInput Copper 4 x 500 kcmil 5 x 500 kcmil 5 x 500 kcmil 6 x 500 kcmil 7 x 500 kcmil
Aluminum 5 x 500 kcmil 5 x 600 kcmil 6 x 600 kcmil 7 x 600 kcmil 8 x 600 kcmil
Output Copper 4 x 500 kcmil 5 x 500 kcmil 5 x 500 kcmil 5 x 500 kcmil 6 x 500 kcmil
Aluminum 5 x 500 kcmil 5 x 600 kcmil 6 x 600 kcmil 6 x 600 kcmil 7 x 600 kcmil
Battery14 Copper 4 x 500 kcmil 5 x 500 kcmil 5 x 500 kcmil 6 x 500 kcmil 7 x 500 kcmil
Aluminum 5 x 500 kcmil 5 x 600 kcmil 6 x 600 kcmil 7 x 600 kcmil 8 x 600 kcmil
20 990–5245B–001
14. Per battery string.
Facility Planning 400–1600 kW 480 V
Required Breaker Settings for Systems with External Bypass
A breaker coordination study is required to ensure the highest availability of theUPS. This breaker coordination study should be performed focusing onmaintaining the characteristics of the Symmetra MW.
Q1, Q5, and Upstream Breakers – Minimum Settings
Duration(S)
Total load(%)
Event/Operation
Current (A)
800 kW 1000 kW 1200 kW 1400 kW 1600 kW< 0.005 – Internal
faultclearing
18 kA15 18 kA15 18 kA15 18 kA15 18 kA15
∞ 130 Overloadon-line
125116 161216 187616 218916 249016
∞ 100 On-line 996 1245 1494 1743 1992∞ 110 On-line +
max.batterycharge
1096 1370 1643 1917 2191
Q2, Q4, Q6, and Downstream Breakers – Minimum Settings
Duration(S)
Total load(%)
Event/Operation
Current (A)
800 kW 1000 kW 1200 kW 1400 kW 1600 kW< 0.005 – Internal
faultclearing
18 kA15 18 kA15 18 kA15 18 kA15 18 kA15
60 200 Overloadon-line
192517 240617 288617 336817 385017
600 125 Overloadon-line
1203 1504 1804 2105 2406
∞ 100 On-line 962 1203 1443 1684 1925
990–5245B–001 21
15. In the absence of a coordination study conducted by an engineer, the recommended instantaneous trip settingfor breakers Q1, Q2, Q4, Q5, and Q6 is 18 kA.16. Only applicable to Q1.17. Only applicable to Q2 and Q4.
400–1600 kW 480 V Facility Planning
Q4, Q5, and Q6 Settings in Parallel Systems with Two UPS Units
Duration(S)
Total load(%)
Event/Operation
Current (A)
800 kW 1000 kW 1200 kW 1400 kW 1600 kW< 0.005 – Internal
faultclearing
18 kA18 18 kA18 18 kA18 18 kA18 18 kA18
60 200 Overloadon-line
384919 481219 577219 673619 770019
600 125 Overloadon-line
240619 300819 360819 421019 481319
∞ 100 On-line 1925 2406 2886 3368 3850
Q4, Q5, and Q6 Settings in Parallel Systems with Three UPS Units
Duration(S)
Total load(%)
Event/Operation
Current (A)
800 kW 1000 kW 1200 kW 1400 kW 1600 kW< 0.005 – Internal
faultclearing
18 kA18 18 kA18 18 kA18 18 kA18 18 kA18
60 200 Overloadon-line
577419 721819 865819 1010019 1155019
600 125 Overloadon-line
346219 451219 541219 631519 721919
∞ 100 On-line 2887 3609 4329 5052 5775
In the absence of a proper breaker coordination study and if only the actual Ip onthe unit’s input terminals is known, this table must be used to optimize theinstantaneous trip setting or to choose a breaker with a usable fixed instantaneoustrip value.
Ip20 [kA] I peak let-through [kA] I setting [kA]
200 16 18
140 14 16
100 13 15
50 10.5 12
30 9 11
18 kA is the maximum peak let-through current (including safety factor) presentduring clearing of an internal fault in a 200 kW section or a power module. Thismaximum peak let-through current is based on and applicable to utility withprospective short-circuit currents (Ip) up to 200 kA. During or after a controlled faultclearing, none of the breakers are allowed to trip on the instantaneous trip settingbelow the specified value. This is also applicable to upstream breakers, and acheck of the instantaneous trip setting in this part of the installation is required.
22 990–5245B–001
18. In the absence of a coordination study conducted by an engineer, the recommended instantaneous trip settingfor breakers Q1, Q2, Q4, Q5, and Q6 is 18 kA.19. Only applicable to Q4.20. Abridgement for Prospective short-circuit current. This is the current that would flow in the fault circuit if thefuse was replaced by a link with an infinitely small impedance.
Facility Planning 400–1600 kW 480 V
The instantaneous trip setting calculated by an engineer in a breaker coordinationstudy must not disable the functionality of clearing and surviving an internal faultunless there is a written agreement between Schneider Electric and the customer.
By ensuring the unit’s fault clearing ability (survival skills) i.e. using the correctinstantaneous trip settings in the switchgear (installation), maximum poweravailability in normal operation is obtained for the load.
NOTE: The instantaneous trip setting can be calculated when the utility/mains Ip isknown. An incorrect trip setting can result in limiting the system functionality andjeopardize the load support.
NOTE: The instantaneous trip setting must not be derated even though the UPSsystem is derated in system output power. The system size has no influence on theinstantaneous trip setting.
NOTE: For derated systems, contact Schneider Electric for the correct breakersettings and breaker frame sizes.
NOTE: For upstream breakers not mentioned in the table, contact SchneiderElectric for the correct breaker settings for on-line, overload, and trip currents.
Recommended Cable, Bolt, and Lug Sizes for Copper andAluminum ConductorsCable Size Bolt Hole Size Hole Spacing Lug Width Lug P/N Crimp Tool
(CT2920) andDies
350 kcmil 12.7 mm(0.5 in)
44.45 mm(1.75 in)
38.1 mm(1.50 in)
PanduitLAB350–12–2
CD-920–500BROWN P872 CRIMPS
400 kcmil 12.7 mm(0.5 in)
44.45 mm(1.75 in)
42.2 mm(1.66 in)
PanduitLAB400–12–2
CD-920–600GREEN P944 CRIMPS
500 kcmil 12.7 mm(0.5 in)
44.45 mm(1.75 in)
43.7 mm(1.72 in)
PanduitLAB500–12–2
CD-920–500APINK P994 CRIMPS
600 kcmil 12.7 mm(0.5 in)
44.45 mm(1.75 in)
43.7 mm(1.72 in)
PanduitLAB600–12–2
CD-920–750BLACK P1064 CRIMPS
Torque specifications
Bolt Size M8 13.5 Nm (10 lb-ft)
Bolt Size M10 30 Nm (22 lb-ft)
Bolt Size M12 40 Nm (30 lb-ft)
Bolt Size M14 75 Nm (55 lb-ft)
990–5245B–001 23
400–1600 kW 480 V Facility Planning
Physical
Weights and Dimensions
Weights and Dimensions for Systems with Internal Bypass
UPS System Weight kg (lbs) Height mm (in) Width mm (in) Depth mm (in)
400 kW 2426 (5349) 2032 (80) 2114 (83) 1067 (42)
600 kW 3368 (7426) 2032 (80) 2536 (100) 1067 (42)
800 kW21 4591 (10115) 2032 (80) 3539 (139) 1067 (42)
1000 kW21 5445 (11998) 2032 (80) 3959 (156) 1067 (42)
Weights and Dimensions for Systems with External Bypass
NOTE:Weights and dimensions are without the external bypass.
UPS System Weight kg (lbs) Height mm (in) Width mm (in) Depth mm (in)
800 kW 3995 (8809) 2032 (80) 3716 (146) 1067 (42)
1000 kW 4893 (10765) 2032 (80) 4138 (163) 1067 (42)
1200 kW 6310 (13914) 2032 (80) 4646 (183) 1067 (42)
1400 kW 7016 (15470) 2032 (80) 5068 (200) 1067 (42)
1600 kW 7309 (16080) 2032 (80) 5490 (216) 1067 (42)
Shipping Dimensions
Shipping Dimensions for Systems with Internal Bypass
UPS System Package Height mm (in) Width mm (in) Depth mm (in)
400 kW UPS 2235 (88) 2280 (90) 1280 (50)
Power module x 2 570 (22) 1450 (57) 910 (36)
600 kW 600 kW inverter 2235 (88) 1676 (66) 1280 (50)
I/O with staticswitch
2235 (88) 1676 (66) 1280 (50)
Power module x 3 570 (22) 1450 (57) 910 (36)
800 kW21 800 kW inverter 2235 (88) 1880 (74) 1280 (50)
I/O with staticswitch
2235 (88) 2062 (81) 1280 (50)
Power module x 4 570 (22) 1450 (57) 910 (36)
1000 kW21 1000 kW Inverter 2235 (88) 2280 (90) 1280 (50)
I/O with staticswitch
2235 (88) 2062 (81) 1280 (50)
Power module x 5 570 (22) 1450 (57) 910 (36)
24 990–5245B–001
21. Only available in 480 V
Facility Planning 400–1600 kW 480 V
Shipping Dimensions for Systems with External Bypass
UPS System Package Height mm (in) Width mm (in) Depth mm (in)
800 kW 800 kW inverter 2235 (88) 1880 (74) 1280 (50)
Input/Output 2200 (87) 1300 (52) 1280 (50)
Control 2200 (87) 1300 (52) 1280 (50)
Power module x 4 570 (22) 1450 (57) 910 (36)
External bypass 2200 (87) 1300 (52) 1280 (50)
1000 kW 1000 kW Inverter 2235 (88) 2280 (90) 1280 (50)
Input/Output 2200 (87) 1300 (52) 1280 (50)
Control 2200 (87) 1300 (52) 1280 (50)
Power module x 5 570 (22) 1450 (57) 910 (36)
External bypass 2200 (87) 1300 (52) 1280 (50)
1200 kW 600 kW inverter x 2 2235 (88) 1676 (66) 1280 (50)
Control/input/output 2235 (88) 2286 (90) 1280 (50)
Power module x 6 570 (22) 1450 (57) 910 (36)
1400 kW 600 kW inverter 2235 (88) 1676 (66) 1280 (50)
800 kW inverter 2235 (88) 1880 (74) 1280 (50)
Control/input/output 2235 (88) 2286 (90) 1280 (50)
Power module x 7 570 (22) 1450 (57) 910 (36)
1600 kW 800 kW inverter x 2 2235 (88) 1880 (74) 1280 (50)
Control/input/output 2235 (88) 2286 (90) 1280 (50)
Power module x 8 570 (22) 1450 (57) 910 (36)
Clearance
NOTE: Clearance dimensions are published for airflow and service access only.Consult with your local safety codes and standards for additional requirements inyour local area.
Systems without NEMA 12 Drip Cover
NOTE: If the system does not include a NEMA 12 drip cover, allow for 500 mm freespace above the system.
NOTE: The recommended clearances allow for the crane (crane height 356 mm)to install power modules.
990–5245B–001 25
400–1600 kW 480 V Facility Planning
Symmetra MW with Internal Bypass
Symmetra MW 400 kW
Symmetra MW 600 kW
26 990–5245B–001
400–1600 kW 480 V Facility Planning
Symmetra MW with External Bypass
External Bypass
Symmetra MW 800 kW UPS
28 990–5245B–001
Facility Planning 400–1600 kW 480 V
Symmetra MW 1000 kW UPS
Symmetra MW 1200 kW UPS
990–5245B–001 29
400–1600 kW 480 V Facility Planning
Symmetra MW 1400 kW UPS
Symmetra MW 1600 kW UPS
Systems with NEMA 12 Drip Cover
NOTE: In installation with a NEMA 12 drip cover, the space requirement above thesystem is 200 mm and the space requirement to the left and right of the system is30 mm.
30 990–5245B–001
Facility Planning 400–1600 kW 480 V
NOTE: The recommended clearances allow for the crane (crane height 356 mm)to install power modules.
Symmetra MW with Internal Bypass
Symmetra MW 400 kW
Symmetra MW 600 kW
990–5245B–001 31
400–1600 kW 480 V Facility Planning
Symmetra MW with External Bypass
External Bypass
Symmetra MW 800 kW UPS
32 990–5245B–001
Facility Planning 400–1600 kW 480 V
Symmetra MW 1000 kW UPS
Symmetra MW 1200 kW UPS
990–5245B–001 33
400–1600 kW 480 V Facility Planning
Symmetra MW 1400 kW UPS
Symmetra MW 1600 kW UPS
34 990–5245B–001
Facility Planning 400–1600 kW 480 V
EnvironmentalOperating environment 0 - 40 °C (32 – 104 °F)
Operating relative humidity 0 - 95%
Operating elevation 0-1000 m (0–3333 ft): 11000–1500 m (3333–4921 ft): derating factor 0.951500–2000 m (4921–6562 ft): derating factor 0.912000–2500 m (6562–8202 ft): derating factor 0.86
Storage temperature -50 - 40 °C (-58 — 104 °F)
Storage relative humidity 0 - 95%
Storage elevation 0-15000 m (0–50000 ft)
Audible noise at 1 meter from surface of unit 400 kW: 72 dBA600 kW: 73 dBA800 kW: 74 dBA1000 kW: 74 dBA1200 kW: 75 dBA1400 kW: 75 dBA1600 kW: 76 dBA
Protection class NEMA 1 with NEMA 21 optional
Colour Light grey
Heat Dissipation
Heat Dissipation for Systems with Internal Bypass
Model 400 kW 600 kW 800 kW 1000 kW
Heat dissipation kBTU/hr22
45 63.4 84.4 105.5
Heat Dissipation for Systems with External Bypass
Model 800 kW 1000 kW 1200 kW 1400 kW 1600 kWHeat dissipationkBTU/hr22
84.4 105.5 126.6 147.78 168.8
Anchoring Hole PositionsFor easy determination of hole positions and required hole drilling for the anchors,refer to the drawings on the following pages.
NOTE: Applicable only to systems with NEMA 12 drip cover: If installing the UPSand external bypass up against a wall, leave a gap of at least 30 mm (1.2 in)between the cabinets and the wall.
NOTE: Anchoring hole size must be 15 mm (0.6 in).
990–5245B–001 35
22. Heat dissipation calculated at rated load capacity
400–1600 kW 480 V Facility Planning
Anchoring Hole Positions 400 kW System
Anchoring Hole Positions when Placed against a Wall on the Right Side
36 990–5245B–001
Facility Planning 400–1600 kW 480 V
Anchoring Hole Positions when Placed against a Wall on the Left Side
990–5245B–001 37
400–1600 kW 480 V Facility Planning
Anchoring Hole Positions 600 kW System
Anchoring Hole Positions when Placed against a Wall on the Right Side
38 990–5245B–001
Facility Planning 400–1600 kW 480 V
Anchoring Hole Positions when Placed against a Wall on the Left Side
990–5245B–001 39
400–1600 kW 480 V Facility Planning
Anchoring Hole Positions 800 kW System with Internal Bypass
Anchoring Hole Positions when Placed against a Wall on the Right Side
40 990–5245B–001
Facility Planning 400–1600 kW 480 V
Anchoring Hole Positions when Placed against a Wall on the Left Side
990–5245B–001 41
400–1600 kW 480 V Facility Planning
Anchoring Hole Positions 1000 kW System with Internal Bypass
Anchoring Hole Positions when Placed against a Wall on the Right Side
42 990–5245B–001
Facility Planning 400–1600 kW 480 V
Anchoring Hole Positions when Placed against a Wall on the Left Side
990–5245B–001 43
400–1600 kW 480 V Facility Planning
Anchoring Hole Positions 800 kW System with External Bypass
UPS Anchoring Hole Positions when Placed against a Wall on the Right Side –Configuration 1
44 990–5245B–001
Facility Planning 400–1600 kW 480 V
UPS Anchoring Hole Positions when Placed against a Wall on the Right Side –Configuration 2
990–5245B–001 45
400–1600 kW 480 V Facility Planning
UPS Anchoring Hole Positions when Placed against a Wall on the Left Side –Configuration 1
46 990–5245B–001
Facility Planning 400–1600 kW 480 V
UPS Anchoring Hole Positions when Placed against a Wall on the Left Side –Configuration 2
990–5245B–001 47
400–1600 kW 480 V Facility Planning
Anchoring Hole Positions 1000 kW System with External Bypass
UPS Anchoring Hole Positions when Placed against a Wall on the Right Side –Configuration 1
48 990–5245B–001
Facility Planning 400–1600 kW 480 V
UPS Anchoring Hole Positions when Placed against a Wall on the Right Side –Configuration 2
990–5245B–001 49
400–1600 kW 480 V Facility Planning
UPS Anchoring Hole Positions when Placed against a Wall on the Left Side –Configuration 1
50 990–5245B–001
Facility Planning 400–1600 kW 480 V
UPS Anchoring Hole Positions when Placed against a Wall on the Left Side –Configuration 2
990–5245B–001 51
400–1600 kW 480 V Facility Planning
Anchoring Hole Positions 1200 kW System
UPS Anchoring Hole Positions when Placed against a Wall on the Right Side
52 990–5245B–001
Facility Planning 400–1600 kW 480 V
UPS Anchoring Hole Positions when Placed against a Wall on the Left Side
990–5245B–001 53
400–1600 kW 480 V Facility Planning
Anchoring Hole Positions 1400 kW System
UPS Anchoring Hole Positions when Placed against a Wall on the Right Side
54 990–5245B–001
Facility Planning 400–1600 kW 480 V
UPS Anchoring Hole Positions when Placed against a Wall on the Left Side
990–5245B–001 55
400–1600 kW 480 V Facility Planning
Anchoring Hole Positions 1600 kW System
UPS Anchoring Hole Positions when Placed against a Wall on the Right Side
56 990–5245B–001
Facility Planning 400–1600 kW 480 V
UPS Anchoring Hole Positions when Placed against a Wall on the Left Side
990–5245B–001 57
400–1600 kW 480 V Facility Planning
External Bypass Anchoring Hole Positions
External Bypass Anchoring Hole Positions when Placed against a Wall on the Right Side
External Bypass Anchoring Hole Positions when Placed against a Wall on the Left Side
58 990–5245B–001
Drawings 400–1600 kW 480 V
DrawingsNOTE: A comprehensive set of drawings is available on the engineering website atengineer.apc.com.
NOTE: These drawings are for reference ONLY — subject to change withoutnotice.
Symmetra MW 400 kW 480 V with Internal Bypass
990–5245B–001 59
400–1600 kW 480 V Options
Options
Hardware Options
Batteries
• SYMW Premium Battery Cabinet Set, No Battery (SYMWB)
• Symmetra MW Premium Battery Cabinet with 5 minute battery at 400 kW(SYMWB-B)
• Symmetra MW Premium Battery Cabinet with 5 minute Battery at 400 kW,Battery Management (SYMWB-BM)
• Symmetra MW Value Battery Cabinet (SYMWBV)
• SYMW Value Battery Cabinet Set, 5 Min. Battery at 400 kW (SYMWBV-B)
Symmetra Accessories
• Emergency Power Off (EPO) (EPW9)
Symmetra Power Module
• Symmetra MW 200 kW power module 480 V (SYPM200KG)
Configuration Options• 480 V 4–wire
• Single or dual feed
• Top or bottom feed
• Internal N+1 redundancy
• Parallel up to four units for capacity or redundancy
• Seismic bracket kits
• External bypass for 800–1600 kW systems
• Internal bypass for 400–1000 kW systems
• Generator compatible
• Standard battery cabinet for third-party front access batteries
• UPSSync for synchronizing output of several UPS units
• MegaTie
• Touchscreen LCD display
• High resistance ground option
• Air filter Kit
• RS485 communications
• Ethernet 10/100 Base T
• Optional Relay I/O board
68 990–5245B–001
Schneider Electric Limited FactoryWarranty 400–1600 kW 480 V
Schneider Electric Limited FactoryWarranty
Three Phase Power Products or Cooling Solutions One-Year Factory Warranty
The limited warranty provided by Schneider Electric in this Statement of LimitedFactory Warranty applies only to products you purchase for your commercial orindustrial use in the ordinary course of your business.
Terms of WarrantySchneider Electric warrants that the product shall be free from defects in materialsand workmanship for a period of one year from the date of product start-up whenstart-up is performed by Schneider Electric-authorized service personnel andoccurs within six months of the Schneider Electric shipment date. This warrantycovers repairing or replacing any defective parts including on-site labor and travel.In the event that the product fails to meet the foregoing warranty criteria, thewarranty covers repairing or replacing defective parts at the sole discretion ofSchneider Electric for a period of one year from the shipment date. For SchneiderElectric cooling solutions, this warranty does not cover circuit breaker resetting,loss of refrigerant, consumables, or preventive maintenance items. Repair orreplacement of a defective product or part thereof does not extend the originalwarranty period. Any parts furnished under this warranty may be new or factory-remanufactured.
Non-transferable WarrantyThis warranty is extended to the first person, firm, association or corporation(herein referred to by “You” or “Your”) for whom the Schneider Electric productspecified herein has been purchased. This warranty is not transferable orassignable without the prior written permission of Schneider Electric.
Assignment of WarrantiesSchneider Electric will assign you any warranties which are made bymanufacturers and suppliers of components of the Schneider Electric product andwhich are assignable. Any such warranties are assigned “AS IS” and SchneiderElectric makes no representation as to the effectiveness or extent of suchwarranties, assumes no responsibility for any matters which may be warranted bysuch manufacturers or suppliers and extends no coverage under this Warranty tosuch components.
Drawings, DescriptionsSchneider Electric warrants for the warranty period and on the terms of thewarranty set forth herein that the Schneider Electric product will substantiallyconform to the descriptions contained in the Schneider Electric Official PublishedSpecifications or any of the drawings certified and agreed to by contract withSchneider Electric if applicable thereto (“Specifications”). It is understood that the
990–5245B–001 69
400–1600 kW 480 VSchneider Electric Limited Factory
Warranty
Specifications are not warranties of performance and not warranties of fitness for aparticular purpose.
ExclusionsSchneider Electric shall not be liable under the warranty if its testing andexamination disclose that the alleged defect in the product does not exist or wascaused by end user or any third person misuse, negligence, improper installationor testing. Further, Schneider Electric shall not be liable under the warranty forunauthorized attempts to repair or modify wrong or inadequate electrical voltage orconnection, inappropriate on-site operation conditions, corrosive atmosphere,repair, installation, start-up by non-Schneider Electric designated personnel, achange in location or operating use, exposure to the elements, Acts of God, fire,theft, or installation contrary to Schneider Electric recommendations orspecifications or in any event if the Schneider Electric serial number has beenaltered, defaced, or removed, or any other cause beyond the range of the intendeduse.
THERE ARE NOWARRANTIES, EXPRESS OR IMPLIED, BY OPERATION OFLAW OR OTHERWISE, OF PRODUCTS SOLD, SERVICED OR FURNISHEDUNDER THIS AGREEMENT OR IN CONNECTION HEREWITH. SCHNEIDERELECTRIC DISCLAIMS ALL IMPLIED WARRANTIES OF MERCHANTABILITY,SATISFACTION AND FITNESS FOR A PARTICULAR PURPOSE. SCHNEIDERELECTRIC EXPRESS WARRANTIES WILL NOT BE ENLARGED, DIMINISHED,OR AFFECTED BYAND NO OBLIGATION OR LIABILITY WILL ARISE OUT OF,SCHNEIDER ELECTRIC RENDERING OF TECHNICAL OR OTHER ADVICE ORSERVICE IN CONNECTION WITH THE PRODUCTS. THE FOREGOINGWARRANTIES AND REMEDIES ARE EXCLUSIVE AND IN LIEU OFALL OTHERWARRANTIES AND REMEDIES. THE WARRANTIES SET FORTH ABOVECONSTITUTE SCHNEIDER ELECTRIC SOLE LIABILITYAND PURCHASER’SEXCLUSIVE REMEDY FOR ANY BREACH OF SUCH WARRANTIES.SCHNEIDER ELECTRIC WARRANTIES RUN ONLY TO PURCHASER AND ARENOT EXTENDED TO ANY THIRD PARTIES.
IN NO EVENT SHALL SCHNEIDER ELECTRIC, ITS OFFICERS, DIRECTORS,AFFILIATES OR EMPLOYEES BE LIABLE FOR ANY FORM OF INDIRECT,SPECIAL, CONSEQUENTIAL OR PUNITIVE DAMAGES, ARISING OUT OF THEUSE, SERVICE OR INSTALLATION, OF THE PRODUCTS, WHETHER SUCHDAMAGES ARISE IN CONTRACT OR TORT, IRRESPECTIVE OF FAULT,NEGLIGENCE OR STRICT LIABILITY ORWHETHER SCHNEIDER ELECTRICHAS BEEN ADVISED IN ADVANCE OF THE POSSIBILITY OF SUCHDAMAGES, SPECIFICALLY, SCHNEIDER ELECTRIC IS NOT LIABLE FOR ANYCOSTS, SUCH AS LOST PROFITS OR REVENUE, LOSS OF EQUIPMENT,LOSS OF USE OF EQUIPMENT, LOSS OF SOFTWARE, LOSS OF DATA,COSTS OF SUBSTITUANTS, CLAIMS BY THIRD PARTIES, OR OTHERWISE.
NO SALESMAN, EMPLOYEE OR AGENT OF SCHNEIDER ELECTRIC ISAUTHORIZED TO ADD TO OR VARY THE TERMS OF THIS WARRANTY.WARRANTY TERMS MAY BE MODIFIED, IF ATALL, ONLY IN WRITING SIGNEDBYAN SCHNEIDER ELECTRIC OFFICER AND LEGAL DEPARTMENT.
Warranty ClaimsCustomers with warranty claims issues may access the SCHNEIDER ELECTRICworldwide customer support network through the SCHNEIDER ELECTRIC website: http://www.SCHNEIDER ELECTRIC.com/support/contact/. Select yourcountry from the country selection pull-down menu. Open the Support tab at thetop of the web page to obtain contact information for customer support in yourregion.
70 990–5245B–001
Schneider Electric35 rue Joseph Monier92500 Rueil MalmaisonFrance
+ 33 (0) 1 41 29 70 00www.schneider-electric.com
As standards, specifications, and design change fromtime to time, please ask for confirmation of theinformation given in this publication.
© 2014 – Schneider Electric. All rights reserved.990–5245B–001