Emerson 60HZ, 480V user manual 4.3Installing Parallel System, 4.3.1Conditions for Parallel System

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4.3Installing Parallel System

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4.3Installing Parallel System

The basic installation procedure of parallel system is the same as that of single module system. The following sections introduce only the installation procedures specific to the parallel system.

4.3.1Conditions for Parallel System

Each UPS module must have the same bypass source.

The outputs of all UPS modules are connected altogether.

The main inputs can be from different sources, but the phase rotation sequence of main inputs, bypass inputs and outputs must be correct and the same.

The parallel logic cable and load sharing cable must be connected in a ring correctly (see Figure 18).

NOTE

When paralleling UPS's with different power ratings, the power rating of the largest UPS can be no more than four times the power rating of the smallest UPS

4.3.2Cabinet Installation

Parallel system composed of two or more UPS modules using parallel cabinet

The UPS modules that will form the parallel system should be placed side-by-side. Each battery cabi- net is placed next to its corresponding UPS module.

The parallel cabinet should be placed in the middle of the system.

4.3.3Preliminary Checks

Each UPS module should have the same firmware and the same hardware version. Refer to the instructions in 4.3.1 - Conditions for Parallel System.

4.3.4Power Cables

Wiring of power cables is similar to that of a single module system (See 2.1 - Power Cabling). The bypass sources of all modules should be the same, and the outputs should be connected altogether cor- rectly.

Power cables are field-supplied. Power cables to the UPS’s of the paralleling cabinet must be routed through either the top or bottom entry access of the UPS.

NOTE

The system input and/or output circuit breaker is to be field-supplied. See Table 8 for current rating.

NOTE

The length and specifications of power cables including the bypass input cables and UPS output cables should be the same, thus the load can be shared evenly in bypass mode.

4.3.5Parallel Control Cables Parallel System Control Cables

Make the connections listed below on the parallel logic board (M3) inside the Liebert NX. (See Figure 23 for the location of the parallel logic board):

Shielded and double-insulated control cables, available in lengths of up to 100 feet (30m), must be interconnected in a ring configuration between UPS modules as shown below. The ring configuration ensures high reliability of the control (refer to Figure 18).

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Contents User Manual–40-200kVA, 480V,60Hz Liebert NX UPSAC Power For Business-CriticalContinuityPage TABLE OF CONTENTS 4.0 OPTIONS 9.0 OPERATING INSTRUCTIONS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . FIGURES Figure 39 Main component location drawing Liebert NX 480V, CB2, CB3, CB4 configurations . . . . . . . . . TABLES SAVE THESE INSTRUCTIONS IMPORTANT SAFETY INSTRUCTIONSBattery Cabinet Precautions • Remove watches, rings and other metal objects AC input AC output GLOSSARY OF SYMBOLSRisk of electrical shock Requests the user to consult the manual1.0INSTALLATION 1.1External Inspections1.3Preliminary Checks 1.2.1Storing for Delayed Installation1.2Internal Inspections 1.4UPS Location1.6Mechanical Considerations Battery Location1.5Considerations in Moving the Liebert NX 1.4.3Special Considerations for Parallel Systems1.6.3Cable Entry 1.6.2Floor Installation1.6.1Clearances System CompositionFront of Units Liebert NX Battery CabinetLiebert Bypass2.1.1Cable Rating 2.1Power Cabling2.0ELECTRICAL CONNECTIONS Lug Size and Torque Requirements2.1.2UPS Input Configuration 2.1.3Cabling Guidelines2.1.4Cable Connections Liebert NX 40-120kVAConnectionsLiebert NX 160-200kVAConnections Figure 4 Input and output busbars2.1.6Protective Devices 2.1.5Safety Ground2.1.7Cabling Procedure UPS Rectifier and Bypass Input SupplyFrequency Converter Mode Common Input ConnectionsDual Input Connections Figure 5 Monitor board U2 2.2.1Monitor Board Features2.2Control Cables 2.3Dry Contacts 2.3.1Input Dry Contacts 2.3.2Maintenance Bypass Cabinet InterfaceTable 2 Maintenance bypass cabinet interface Figure 7 Input dry contactsTable 3 BCB control interface 2.3.3Battery Circuit Breaker Control Interface2.3.4Output Dry Contacts Output dry contact relaysEPO - NO Figure 9 EPO wiring2.3.5EPO Input—Optional EPO - NC3.1Introduction 3.2Safety3.0BATTERY INSTALLATION Figure 10 Battery cabinets for Liebert NX 3.3External Battery Cabinet Installation3.3.1Battery Cabinets Figure 11 Battery cabinet—details 3.3.2Connecting the Batteries3.3.3Installation Considerations 3.4Non-StandardBatteries 3.3.4Connecting the Battery Cabinet to the UPSFigure 12 Battery tray and supports 3.5BCB Shunt TripThis power must be UPS protected 3.6Alber Monitoring System—Optional4.0OPTIONS 4.1.2LBS Cable and Settings4.1Load Bus Synchronization 4.1.1Performance Requirements4.2.1General 4.2Configuring Parallel System Operation4.2.2Features of Parallel System Liebert NX UPS 40-200kVA 480V, 3W Input 480V DC Battery InputFigure 15 Parallel system block diagram 480V, 3W UOB Output4.2.3Operating Principles Redundancy Paralleling •Battery Mode Operation•Maintenance Bypass Mode Operation 4.2.4Operation Modes Summary4.3.4Power Cables 4.3Installing Parallel System4.3.2Cabinet Installation 4.3.1Conditions for Parallel SystemFor startup procedure, 9.2 - UPS Startup Auxiliary Dry Contact CablesX2:3 4.3.6Emergency Power Off EPOFigure 20 Connecting EPO push button X2:4UPS mechanical characteristics 5.0UPS SPECIFICATIONSEnvironmental characteristics 5.4UPS Electrical Characteristics Table 8 UPS terminalUPS terminal continued Table 9 Rectifier input power5.4.1Input Rectifier Table 10 Input voltage window with derating5.4.3Inverter Output Table 11 Liebert approved replacement batteries5.4.2DC Intermediate Circuit Table 12 DC intermediate circuit5.4.4 Bypass Input Table 14 Bypass inputLeft Side FrontFront Detail AParallel Board 1239mm FRONT VIEWLEFT VIEW 2000mmTOP VIEW Front of UPS BOTTOM VIEW Front of UPSInstallation Drawings DETAIL A 8.83 DETAIL A224mm 609.3 24 872.2 34.3 U3819205 SECTION A-A RIGHT SIDEFRONT TOP VIEWDetail B Detail ATop View without BCB Cover Plate49 Battery Cabinet Right-SideViews A D NX 160-200KVAUPS Module Front View A CBB D CDBattery Breaker 845 33.2 965 38 2000 78.7 FrontTop Right Side Right Side FrontSystem Input FrontRear UPS OutputWithout Covers System FRONTUPS Output Breakers Ground Busbar Kirk-KeyREAR FRONTDoor Open A B1-B4 FRONT Without Covers RIGHT SIDE Without Exterior Panels LEFT SIDE Without Exterior Panels 965 38 in 200078.7 in LEFT SIDE Isometric View7.1General Description 7.0OPERATION7.1.2Operating Modes Battery Mode7.1.1Bypass Supplies Normal ModeMaintenance Mode Parallel Redundancy Mode System ExpansionFigure 45 Overview of control panel 8.0OPERATOR CONTROL AND DISPLAY PANEL8.1.1Display Panel Layout Liquid Crystal Display LCD Mimic display LED2Load indicator Figure 47 Mimic display indicators locationBypass indicator Inverter indicatorButton cover EPO button Inverter Off button Fault Clear buttonFigure 48 Location of control buttons Silence On/Off button Inverter On buttonFigure 50 Sections of the LCD Data and settingsFigure 49 Buzzer location UPS systemTable 17 Icons for navigation keys 8.8LCD Menus and Data Items Figure 51 Menu treeOperator Control and Display Panel 8.9Language Selection Figure 52 Language selection8.10Current Date and Time Figure 53 Set date and timeMessages CurrentStatus History Log records menu8.12Types of LCD Screens 8.12.2Default ScreenFigure 56 Default screen 8.12.1Opening Display8.12.4Screen Saver Window Press any key back to main menu8.12.3UPS Help Screen Figure 57 Help screen8.13Pop-UpWindows 8.13.4 Battery Capacity Test Confirmation8.13.5Battery Self-TestAborted, Condition Not Met 8.13.3System Self-TestTable 20 UPS operating modes 9.1Liebert NX Operating Modes9.0OPERATING INSTRUCTIONS 9.1.1Circuit Breakers 9.2.1Startup Procedure9.2UPS Startup Figure 59 Circuit breakers•Close CB5 CB1, CB2, CB3 and CB5 are closed Switch from Normal Mode to Bypass Mode Switch from Bypass Mode to Normal Mode9.4Auto Restart 9.5Emergency Shutdown With EPO9.7.1Battery Undervoltage Pre-Warning 9.7Battery Protection9.8Multi-ModuleSystem Procedures 9.7.2Battery End-of-DischargeEOD Protection3.Close Input breaker CB1 9.9Commissioning a Parallel System 9.10Parallel System Startup10.0OPTIONS 10.1.2Power Output10.1Communication and Other User Terminals 10.1.1Analog Input InterfaceTable 21 Liebert NX communication options 10.1.5Configuring Baud Rates10.1.4Communication and Monitoring Figure 62 Liebert IntelliSlot Web card display Relay Card Table 22 Relay Card pin configurationTable 23 Relay card jumper configuration MultiPort 4 Card Figure 63 MultiPort 4 card pin assignment10.2LBS Mode—LoadBus Synchronization 10.2.1Remote Alarm MonitorFigure 64 Dust filter replacement 10.3Replacing Dust FiltersTable 25 Battery torque rating 11.0SPECIFICATIONS AND TECHNICAL DATATable 24 Torque specifications Specifications and Technical DataTable 27 Parallel system current table 11.3Cable size and tightening torques Specifications and Technical Data Table 38 C&D Dynasty battery run times in minutes 11.4Battery Run TimesTable 37 Enersys battery run times in minutes Table 38 C&D Dynasty battery run times in minutes UPS Status Messages APPENDIX A - UPS STATUS MESSAGESTable 39 UPS status messages Event Message Table 39 UPS status messagesUPS Status Messages Description / Suggested Action if anyTable 39 UPS status messages UPS Status MessagesTable 39 UPS status messages UPS Status MessagesTable 39 UPS status messages UPS Status MessagesUPS Status Messages Page Technical Support/ Service Ensuring The High AvailabilityOf Mission-CriticalData And Applications reducedcapitalequipment andoperatingcosts
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60HZ, 480V specifications

The Emerson 40-120KVA UPS is a high-performing uninterruptible power supply designed to ensure the reliability and continuity of critical operations across various industries. This UPS operates at 480VAC and 60Hz, making it suitable for environments where high-power demands are common.

One of the standout features of this UPS system is its modular design, which allows for easy scalability. Organizations can expand their power capacity as their needs grow, making the Emerson 40-120KVA UPS a future-proof investment. The system operates with high efficiency, minimizing energy consumption and operational costs. This is vital for data centers and industrial applications where energy management is increasingly important.

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The Emerson 40-120KVA UPS also meets stringent safety and compliance standards, ensuring reliable operation in demanding environments. Its robust design is suitable for a variety of applications, including information technology, telecommunications, and industrial processes. Overall, the Emerson 40-120KVA UPS stands out as a reliable, efficient, and versatile solution for businesses aiming to safeguard their critical power supply against any disruption.