Eaton Electrical SPI9000 user manual September

Page 87

SPI9000 Inverter Unit FI9 – FI14 User Manual

September 2006

Check in Monitoring Menu M1 that the value of Output Frequency changes according to the change of frequency reference.

Press the STOP button on the keypad.

9.Perform the start-up tests without the motor being connected to the process. If this is not possible, make sure that each test can be done safely prior to performing it. Inform your co-workers of the tests.

Switch off the DC supply voltage and wait until the drive has stopped as advised on Page 6-1, Safety Precautions.

Connect the motor cable to the motor and to the motor cable terminals of the inverter.

Make sure that all Start/Stop switches are in Stop positions.

Switch the supply voltage ON.

Repeat Test A or B in step 8.

10.Connect the motor to the process (if the start-up test was performed without the motor being connected). Inform our co-workers of the tests.

Before running the tests, make sure that this can be done safely.

Repeat Test A or B in step 8.

MN04004002E

For more information visit: www.EatonElectrical.com

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Contents SPI9000 Inverter Unit FI9 FI14 Page Important Notice Please Read Contents List of Figures SPI9000 Inverter Unit Block DiagramList of Tables 25 HMI Acknowledge TimeoutSafety Definitions and SymbolsHazardous High Voltage September Vii Motor and Equipment Safety Grounding and ground fault protectionFI9 FI14 Inverter Unit Catalog Numbering System OverviewI 0 1 6 a 0 4 a 1 N Receiving and InspectionStorage MaintenanceTechnical Data Standard Features of SPI Inverter UnitsSPI9000 Inverter Unit Block Diagram Power Ratings 380 500V AC, 50/60 Hz, Three-Phase Inverters RatingsSupply Voltage 465 800V DC, Motor Voltage 380 500V AC Supply Voltage 640 1100V DC, Motor Voltage 525 690V AC 525 690V AC, 50/60 Hz, Three-Phase Inverters RatingsMotor Connection Control CharacteristicsTechnical Information Description Specification Supply ConnectionControl Connections EMC at Default SettingsSafety Description Specification Ambient ConditionsDC Currents for 465 800V DC Supply Voltage DC Currents for 640 1100V DC Supply VoltageStructure Inom Output Motor COS IDC Input Dimensions Approximate Dimensions in Inches mm Inverters Voltage DiaMounting SPI9000 FI10 Inverter Dimensions SPI9000 FI12 Inverter Dimensions Frames FI9 to FI14 Fan CoolingInstallation Space Required Cooling Air Power LossesApproximate Dimensions in Inches mm Frame Voltage Mounting Space RequirementsFI9/FI10 Basic Wiring Diagram with Charging Power WiringFI9/FI10 Basic Wiring Diagram without Charging FI12 Basic Wiring Diagram with Charging FI12 Basic Wiring Diagram without Charging FI13 Basic Wiring Diagram with Charging FI13 Basic Wiring Diagram without Charging FI14 Basic Wiring Diagram with Charging FI14 Basic Wiring Diagram without Charging Fuses, 465 800V DC Inverters Power ConnectionsDC Supply and Motor Cables Cable Types Required to Meet StandardsFuses, 640 1100V DC Inverters Fuses Used in 640 1100V DC InvertersInformation about fuses Cable Sizes for 380 500V AC Inverter Supply and Motor Cables 380 500V ACTerminal Sizes for 380 500V AC Terminal Sizes 380 500V ACCable Sizes for 525 690V AC Inverter Supply and Motor Cables 525 690V ACTerminal Sizes for 525 690V AC Terminal Sizes 525 690V ACInstallation Instructions Cable DistancesDistance Between Cables Shielded Inches m Cable in Feet m Frame Sizes Tightening Torque Cable Installation and the UL StandardsCable and Motor Insulation Checks Terminal Tightening TorquesSeptember Control Board Control WiringInverters Connected in Parallel Control Wiring DetailsOption Board A9 Wiring Diagram Control Cables Tightening Torques of Option Board TerminalsTerminal Screw Tightening Torque Lb-in Galvanic Isolation Barriers Galvanic Isolation BarriersTerminal Signal Technical Information Control I/O Terminal Signals on Option Board A9Digital Input Signal Inversions Control I/O Terminal Signals on Option Board A2Control I/O Terminal Signals on Option Board A3 10 Jumper Blocks on Option Board A9 Jumper Selections on Option Board A911 Jumper Selection for Option Board A9 September Indicators on the Keypad Display Menu InformationKeypad Operation Control Place Indicators Drive Status IndicatorsDrive Status Indicators Control Place IndicatorsText Lines Keypad PushbuttonsStatus LEDs Green Green Red Status LEDs Green Green RedButton Descriptions Keypad Display Data Menu NavigationKeypad Navigation Chart Monitoring Menu Monitoring Menu M1Parameter Menu M2 Monitored SignalsKeypad Control Menu M3 Parameter Value Change ProcedureSelection of Control Place Keypad Reference Selection of Control PlaceActive Faults Menu M4 Keypad DirectionStop Button Activated Fault Type Symbol Meaning Fault Time Data RecordData Units Description Fault Time Recorded DataFault History Menu M5 Real Time RecordSystem Menu M6 10 Fault History Menu10 System Menu Functions Code Function Min Max Unit Default Cust Selections10 System Menu Functions 11 Selection of Language Application Selection Selection of LanguageCopy Parameters Parameter Sets S6.3.1Upload parameters to keypad To keypad, S6.3.2 Download parameters to drive From keypad, S6.3.3 Automatic Parameter Backup P6.3.415 Parameter Comparison Parameter ComparisonPassword S6.5.1 SafetyStart-Up Wizard P6.5.3 Parameter Lock P6.5.2Multimonitoring Items P6.5.4 Default Page P6.6.1Backlight Time P6.6.5 Default page in the operating menu P6.6.2Timeout Time P6.6.3 Contrast Adjustment P6.6.4Internal Brake Resistor Connection P6.7.1 Hardware SettingsFan Control P6.7.2 HMI Acknowledge Timeout P6.7.311 Counter Pages Number of retries to receive HMI acknowledgement P6.7.4System info Total Counters13 Software Information Pages 12 Resettable CountersTrip Counters Software S6.8.315 Hardware Information Pages Applications S6.8.414 Applications Information Pages Hardware S6.8.5Expander Board Menu M7 Expander Boards S6.8.6Further Keypad Functions Code Parameter Min Max Default Cust SelectionsSeptember Start-Up Safety PrecautionsSequence of Operation September September Appendix a Fault Codes Table A-1 Fault CodesFault Code Possible Cause Solution Eeprom Programmable Faults only Table A-1 Fault Codes September MN04004002E September Page Company Information

SPI9000 specifications

The Eaton Electrical SPI9000 is a cutting-edge power management system designed to enhance efficiency and reliability in electrical distribution. This state-of-the-art solution integrates advanced technologies to optimize performance, making it an ideal choice for various industrial and commercial applications.

One of the standout features of the SPI9000 is its scalability. Businesses can easily adapt the system to meet their unique power needs, whether for a single facility or multiple sites. This flexibility is crucial in today's fast-paced environment, where operational demands can shift rapidly. The system is engineered to grow alongside your business, providing robust power management as requirements evolve.

At the heart of the SPI9000 is its intelligent monitoring capability. The system utilizes real-time data analytics to monitor energy consumption, detect anomalies, and predict maintenance needs. This proactive approach not only helps in reducing downtime but also cultivates a culture of energy efficiency within organizations. By leveraging insights derived from data, companies can make informed decisions that lead to significant cost savings.

The SPI9000 incorporates advanced communications technology, allowing seamless integration with existing building management systems. This interoperability is vital for creating smart grids and enhancing overall control of electrical networks. Additionally, the system supports various communication protocols, including Modbus, BACnet, and Ethernet, ensuring compatibility with a wide range of devices and applications.

Safety is paramount in any electrical system, and the SPI9000 excels in this regard. It features enhanced protective measures, including overcurrent protection, short-circuit protection, and arc flash detection, ensuring the safety of both personnel and equipment. These safety features not only safeguard investments but also contribute to creating a safer working environment.

Energy efficiency is another cornerstone of the SPI9000 design. The system is equipped with advanced power quality monitoring features, which help identify and mitigate issues related to harmonics, voltage sags, and swells. By maintaining optimal power quality, the SPI9000 ensures that equipment operates efficiently, extending its lifespan while reducing energy costs.

In summary, the Eaton Electrical SPI9000 is a versatile and efficient power management solution that brings together scalability, intelligent monitoring, advanced communication capabilities, enhanced safety features, and energy efficiency. Thanks to its innovative technologies and characteristics, the SPI9000 serves as an indispensable tool for modern businesses seeking to streamline their electrical operations and enhance their energy management strategies.