Eaton Electrical SPI9000 Technical Information, Description Specification Supply Connection

Page 16

SPI9000 Inverter Unit FI9 – FI14 User Manual

September 2006

Table 1-4: Technical Information

Description

Specification

 

 

 

 

Supply Connection

 

 

 

 

 

Input Voltage Vin

465 – 800V DC; 380 – 500V AC (-0%. to +0%)

 

 

640 – 1100V DC; 525 – 690V AC (-0% to +0%)

 

The waviness of the inverter supply voltage, which is formed in

 

rectification of the electric network’s alternating voltage in basic

 

frequency, must be less than 50V peak-to-peak.

 

 

 

Input Current Iin

(sqrt3 x Umot x Imot x cosϕ) / (Vin x 0.98)

 

DC Bank Capacitance

FI9 380 – 500V: 4950 μF; FI9 525 – 690V:

3733 μF

 

FI10 380 – 500V: 9900 μF; FI10 525 – 690V:

7467 μF

 

FI12 380 – 500V: 19800 μF; FI12 525 – 690V: 14933 μF

 

FI13 380 – 500V: 29700 μF; FI13 525 – 690V: 22400 μF

 

 

 

Starting Delay

5 seconds (FI9 and greater)

 

 

 

 

Motor Connection

 

 

 

 

 

Output Voltage

3 ~ 0 – Vin / 1.4

 

Continuous Output Current

IH: Ambient temperature max. +50°C,

 

 

overload 1.5 x IH (1 min./10 min.)

 

 

IL: Ambient temperature max. +40°C,

 

 

overload 1.1 x IL (1 min./10 min.)

 

Starting Torque

IS for two seconds (torque motor dependent)

Peak Current

IS for 2 seconds every 20 seconds

 

Output Frequency

0 – 320 Hz; 7200 Hz (special)

 

 

 

 

Frequency Resolution

Application dependent

 

 

 

 

Control Characteristics

 

 

 

 

 

Control Method

Frequency control V/f

 

 

Open loop: Sensorless vector control

 

 

Closed loop: Frequency control

 

 

Closed loop: Vector control

 

 

 

Switching Frequency

380 – 500V, 1 – 10 kHz; Factory default 3.6 kHz

(See Parameter 2.6.9)

525 – 690V, 1 – 6 kHz; Factory default 1.5 kHz

 

 

 

Frequency Reference

 

 

Analog Input

Resolution 0.1% (10 bits); Accuracy ±1%

 

Panel Reference

Resolution 0.01 Hz

 

 

 

 

Field Weakening Point

30 – 320 Hz

 

 

 

 

Acceleration Time

0 – 3000 sec

 

 

 

 

Deceleration Time

0 – 3000 sec

 

 

 

 

Braking Torque

DC brake: 30% * TN (without brake)

 

Ambient Conditions

 

 

 

 

 

Ambient Operating Temperature

-10°C (no frost) to +40°C: IH

 

 

-10°C (no frost) to +40°C: IL

 

Storage Temperature

-40 to 158°F (-40 to 70°C)

 

 

 

Relative Humidity

0 – 95% RH, non-condensing, non-corrosive,

 

no dripping water

 

 

 

 

Air Quality:

 

 

– Chemical Vapors

IEC 721-3-3, unit in operation, Class 3C2

 

– Mechanical Particles

IEC 721-3-3, unit in operation, Class 3S2

 

 

 

Altitude

100% load capacity (no derating) up to 1,000m

 

1% derating for each 100m above 1000 (maximum, 3000m)

 

 

 

1-6

For more information visit: www.EatonElectrical.com

MN04004002E

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Contents SPI9000 Inverter Unit FI9 FI14 Page Important Notice Please Read Contents SPI9000 Inverter Unit Block Diagram List of Figures25 HMI Acknowledge Timeout List of TablesDefinitions and Symbols SafetyHazardous High Voltage September Vii Grounding and ground fault protection Motor and Equipment SafetyOverview I 0 1 6 a 0 4 a 1 NReceiving and Inspection FI9 FI14 Inverter Unit Catalog Numbering SystemMaintenance Technical DataStandard Features of SPI Inverter Units StorageSPI9000 Inverter Unit Block Diagram 380 500V AC, 50/60 Hz, Three-Phase Inverters Ratings Power RatingsSupply Voltage 465 800V DC, Motor Voltage 380 500V AC 525 690V AC, 50/60 Hz, Three-Phase Inverters Ratings Supply Voltage 640 1100V DC, Motor Voltage 525 690V ACControl Characteristics Technical InformationDescription Specification Supply Connection Motor ConnectionEMC at Default Settings SafetyDescription Specification Ambient Conditions Control ConnectionsDC Currents for 640 1100V DC Supply Voltage DC Currents for 465 800V DC Supply VoltageStructure Inom Output Motor COS IDC Input Approximate Dimensions in Inches mm Inverters Voltage Dia DimensionsMounting SPI9000 FI10 Inverter Dimensions SPI9000 FI12 Inverter Dimensions Fan Cooling Frames FI9 to FI14Installation Space Power Losses Approximate Dimensions in Inches mm Frame VoltageMounting Space Requirements Required Cooling AirPower Wiring FI9/FI10 Basic Wiring Diagram with ChargingFI9/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 Power Connections DC Supply and Motor CablesCable Types Required to Meet Standards Fuses, 465 800V DC InvertersFuses Used in 640 1100V DC Inverters Fuses, 640 1100V DC InvertersInformation about fuses Inverter Supply and Motor Cables 380 500V AC Cable Sizes for 380 500V ACTerminal Sizes 380 500V AC Terminal Sizes for 380 500V ACInverter Supply and Motor Cables 525 690V AC Cable Sizes for 525 690V ACTerminal Sizes 525 690V AC Terminal Sizes for 525 690V ACCable Distances Installation InstructionsDistance Between Cables Shielded Inches m Cable in Feet m Frame Sizes Cable Installation and the UL Standards Cable and Motor Insulation ChecksTerminal Tightening Torques Tightening TorqueSeptember Control Wiring Control BoardControl Wiring Details Inverters Connected in ParallelOption Board A9 Wiring Diagram Tightening Torques of Option Board Terminals Control CablesTerminal Screw Tightening Torque Lb-in Galvanic Isolation Barriers Galvanic Isolation BarriersControl I/O Terminal Signals on Option Board A9 Terminal Signal Technical InformationControl I/O Terminal Signals on Option Board A2 Digital Input Signal InversionsControl I/O Terminal Signals on Option Board A3 Jumper Selections on Option Board A9 10 Jumper Blocks on Option Board A911 Jumper Selection for Option Board A9 September Menu Information Indicators on the Keypad DisplayKeypad Operation Drive Status Indicators Drive Status IndicatorsControl Place Indicators Control Place IndicatorsKeypad Pushbuttons Status LEDs Green Green RedStatus LEDs Green Green Red Text LinesButton Descriptions Menu Navigation Keypad Display DataKeypad Navigation Chart Monitoring Menu M1 Monitoring MenuMonitored Signals Parameter Menu M2Parameter Value Change Procedure Keypad Control Menu M3Selection of Control Place Selection of Control Place Keypad ReferenceKeypad Direction Active Faults Menu M4Stop Button Activated Fault Time Data Record Fault Type Symbol MeaningFault Time Recorded Data Fault History Menu M5Real Time Record Data Units Description10 Fault History Menu System Menu M6Code Function Min Max Unit Default Cust Selections 10 System Menu Functions10 System Menu Functions Selection of Language 11 Selection of Language Application SelectionParameter Sets S6.3.1 Copy ParametersUpload parameters to keypad To keypad, S6.3.2 Automatic Parameter Backup P6.3.4 Download parameters to drive From keypad, S6.3.3Parameter Comparison 15 Parameter ComparisonSafety Password S6.5.1Parameter Lock P6.5.2 Start-Up Wizard P6.5.3Default Page P6.6.1 Multimonitoring Items P6.5.4Default page in the operating menu P6.6.2 Timeout Time P6.6.3Contrast Adjustment P6.6.4 Backlight Time P6.6.5Hardware Settings Internal Brake Resistor Connection P6.7.1HMI Acknowledge Timeout P6.7.3 Fan Control P6.7.2Number of retries to receive HMI acknowledgement P6.7.4 System infoTotal Counters 11 Counter Pages12 Resettable Counters Trip CountersSoftware S6.8.3 13 Software Information PagesApplications S6.8.4 14 Applications Information PagesHardware S6.8.5 15 Hardware Information PagesExpander Boards S6.8.6 Expander Board Menu M7Code Parameter Min Max Default Cust Selections Further Keypad FunctionsSeptember Safety Precautions Start-UpSequence of Operation September September Table A-1 Fault Codes Appendix a 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.

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