This Altivar 320 variable speed drive can feed 3-phase synchronous and asynchronous motors. Its book form factor allows for a simple and compact installation in your automation cabinets. It works at a rated power up to 7.5kW / 10hp and a rated voltage from 380V to 500V AC. Its robust design with IEC 60721-3-3 class 3C3 coated printed circuit boards allows to extend machine availability in harsh environmental conditions, for example at ambient temperatures of up to 60°C without the need of additional cooling. It incorporates functions suitable for the most common applications, including torque and speed accuracy at very low speed, high dynamic performance with flux vector control without sensor and extended frequency range for high-speed motors. It also incorporates parallel connection of motors and special drives using the voltage/frequency ratio and static speed accuracy and energy saving for open-loop synchronous motors. The drive software includes 5 safety functions that help machines meet safety requirements, whether or not they are used in conjunction with a Preventa safety module. These safety functions are configured using SoMove software. Altivar Machine ATV320 was designed for Original Equipment Manufacturers (OEMs) that meets simple and advanced application requirements covered for packaging, material handling, textile, material working, mechanical actuators and hoisting. It conforms to international standards IEC/EN 61800-5-1 and IEC/EN 61800-3 (immunity and conducted and radiated EMC emissions). It is also CE, UL, CSA, NOM, EAC and RCM certified. Mounting accessories and external options (braking resistors, line chokes, motor chokes, additional EMC filters) are available with Altivar Machine ATV320 drives. The type of external accessories and options depends on the drive rating. It is designed to be mounted in vertical position (+/- 10 °) on a panel, thanks to 4 fixing holes. It is fully integrated inside Schneider Electric’s EcoStruxure Machine through DTM. It is possible to configure, control, and diagnose ATV320 drives directly in SoMachine and SoMove software by means of the same software brick (DTM).

• Prop 65
• WARNING: This product can expose you to chemicals including: Lead and lead compounds, which is known to the State of California to cause cancer and birth defects or other reproductive harm. For more information go to www.P65Warnings.ca.gov

• Communications & Management Attributes
• Communication : VW3A3608, VW3A3616, VW3A3627, VW3A3618, VW3A3628, VW3A3601, VW3A3607
• Complementary Attributes
• Maximum Switching Current : relay output R1A, R1B, R1C resistive, cos phi = 1 3 A 250 V AC, relay output R1A, R1B, R1C resistive, cos phi = 1 3 A 250 V AC, relay output R1A, R1B, R1C resistive, cos phi = 1 3 A 250 V AC, relay output R1A, R1B, R1C resistive, cos phi = 1 3 A 250 V AC, relay output R1A, R1B, R1C resistive, cos phi = 1 3 A 250 V AC, relay output R1A, R1B, R1C resistive, cos phi = 1 3 A 250 V AC, relay output R1A, R1B, R1C resistive, cos phi = 1 3 A 250 V AC, relay output R1A, R1B, R1C resistive, cos phi = 1 3 A 30 V DC, relay output R1A, R1B, R1C resistive, cos phi = 1 3 A 30 V DC, relay output R1A, R1B, R1C resistive, cos phi = 1 3 A 30 V DC, relay output R1A, R1B, R1C resistive, cos phi = 1 3 A 30 V DC, relay output R1A, R1B, R1C resistive, cos phi = 1 3 A 30 V DC, relay output R1A, R1B, R1C resistive, cos phi = 1 3 A 30 V DC, relay output R1A, R1B, R1C resistive, cos phi = 1 3 A 30 V DC, relay output R1A, R1B, R1C, R2A, R2C inductive, cos phi = 0.4 7 ms 2 A 250 V AC, relay output R1A, R1B, R1C, R2A, R2C inductive, cos phi = 0.4 7 ms 2 A 250 V AC, relay output R1A, R1B, R1C, R2A, R2C inductive, cos phi = 0.4 7 ms 2 A 250 V AC, relay output R1A, R1B, R1C, R2A, R2C inductive, cos phi = 0.4 7 ms 2 A 250 V AC, relay output R1A, R1B, R1C, R2A, R2C inductive, cos phi = 0.4 7 ms 2 A 250 V AC, relay output R1A, R1B, R1C, R2A, R2C inductive, cos phi = 0.4 7 ms 2 A 250 V AC, relay output R1A, R1B, R1C, R2A, R2C inductive, cos phi = 0.4 7 ms 2 A 250 V AC, relay output R1A, R1B, R1C, R2A, R2C inductive, cos phi = 0.4 7 ms 2 A 250 V AC, relay output R1A, R1B, R1C, R2A, R2C inductive, cos phi = 0.4 7 ms 2 A 30 V DC, relay output R1A, R1B, R1C, R2A, R2C inductive, cos phi = 0.4 7 ms 2 A 30 V DC, relay output R1A, R1B, R1C, R2A, R2C inductive, cos phi = 0.4 7 ms 2 A 30 V DC, relay output R1A, R1B, R1C, R2A, R2C inductive, cos phi = 0.4 7 ms 2 A 30 V DC, relay output R1A, R1B, R1C, R2A, R2C inductive, cos phi = 0.4 7 ms 2 A 30 V DC, relay output R1A, R1B, R1C, R2A, R2C inductive, cos phi = 0.4 7 ms 2 A 30 V DC, relay output R1A, R1B, R1C, R2A, R2C inductive, cos phi = 0.4 7 ms 2 A 30 V DC, relay output R1A, R1B, R1C, R2A, R2C inductive, cos phi = 0.4 7 ms 2 A 30 V DC, relay output R2A, R2C resistive, cos phi = 1 5 A 250 V AC, relay output R2A, R2C resistive, cos phi = 1 5 A 250 V AC, relay output R2A, R2C resistive, cos phi = 1 5 A 250 V AC, relay output R2A, R2C resistive, cos phi = 1 5 A 250 V AC, relay output R2A, R2C resistive, cos phi = 1 5 A 250 V AC, relay output R2A, R2C resistive, cos phi = 1 5 A 250 V AC, relay output R2A, R2C resistive, cos phi = 1 5 A 250 V AC, relay output R2A, R2C resistive, cos phi = 1 5 A 30 V DC, relay output R2A, R2C resistive, cos phi = 1 5 A 30 V DC, relay output R2A, R2C resistive, cos phi = 1 5 A 30 V DC, relay output R2A, R2C resistive, cos phi = 1 5 A 30 V DC, relay output R2A, R2C resistive, cos phi = 1 5 A 30 V DC, relay output R2A, R2C resistive, cos phi = 1 5 A 30 V DC, relay output R2A, R2C resistive, cos phi = 1 5 A 30 V DC
• Minimum Switching Current : relay output R1A, R1B, R1C, R2A, R2C 5 mA 24 V DC, relay output R1A, R1B, R1C, R2A, R2C 5 mA 24 V DC, relay output R1A, R1B, R1C, R2A, R2C 5 mA 24 V DC, relay output R1A, R1B, R1C, R2A, R2C 5 mA 24 V DC, relay output R1A, R1B, R1C, R2A, R2C 5 mA 24 V DC
• US Rated Supply Voltage : 380...500 V - 15...10 %, 380...500 V - 15...10 %
• Brake Chopper Integrated : true
• Maximum Associated Fuse Rating : 40 A
• Maximum Horse Power Rating : 10 hp
• Maximum Input Current Per Phase : 26.5 A
• Maximum Output Voltage : 500 V
• Maximum Acceleration Under Shock Impact During Operation : 150 m/s² at 11 ms
• Maximum Acceleration Under Shock Load During Storage : 150 m/s² at 11 ms
• Maximum Acceleration Under Shock Load During Transport : 150 m/s² at 11 ms
• Maximum Acceleration Under Vibrational Stress During Operation : 10 m/s² at 13...200 Hz
• Maximum Acceleration Under Vibratory Load During Storage : 10 m/s² at 13...200 Hz
• Maximum Acceleration Under Vibratory Load During Transport : 10 m/s² at 13...200 Hz
• Maximum Deflection Under Vibratory Load During Operation : 1.5 mm at 2...13 Hz
• Maximum Deflection Under Vibratory Load During Storage : 3.5 mm at 2...13 Hz
• Maximum Deflection Under Vibratory Load During Transport : 3.5 mm at 2...13 Hz
• Environment Attributes Additional
• Energy Model Manufacturing A1 A3 : Energy model used: Indonesia
• Energy Model Installation A5 : Electricity mix; AC; < 1kV; EU-27
• Energy Model Use B6 : Electricity mix; AC; < 1kV; EU-27
• Energy Model End Of Life C1 C4 : Electricity mix; AC; < 1kV; EU-27
• Components For Re Use Kg Total Life Cycle : 0
• Components For Re Use Kg Manufacturing A1 A3 : 0
• Components For Re Use Kg Distribution A4 : 0
• Components For Re Use Kg Installation A5 : 0
• Components For Re Use Kg Operational Energy Use B6 : 0
• Components For Re Use Kg End Of Life C1 C4 : 0
• Depletion Of Abiotic Resources Elements Kg Equivalent Sb Total Life Cycle : 0.0073632
• Depletion Of Abiotic Resources Elements Kg Equivalent Sb Manufacturing A1 A3 : 0.006847
• Depletion Of Abiotic Resources Elements Kg Equivalent Sb Distribution A4 : 0.000000029436
• Depletion Of Abiotic Resources Elements Kg Equivalent Sb Installation A5 : 0.0000000038075
• Depletion Of Abiotic Resources Elements Kg Equivalent Sb Operational Energy Use B6 : 0.00051612
• Depletion Of Abiotic Resources Elements Kg Equivalent Sb End Of Life C1 C4 : 0.000000020275
• Depletion Of Abiotic Resources Fossil Fuels Mj Total Life Cycle : 68169
• Depletion Of Abiotic Resources Fossil Fuels Mj Manufacturing A1 A3 : 724.71
• Depletion Of Abiotic Resources Fossil Fuels Mj Distribution A4 : 10.334
• Depletion Of Abiotic Resources Fossil Fuels Mj Installation A5 : 1.6898
• Depletion Of Abiotic Resources Fossil Fuels Mj Operational Energy Use B6 : 67424
• Depletion Of Abiotic Resources Fossil Fuels Mj End Of Life C1 C4 : 8.6219
• Exported Energy Mj By Energy Vector Total Life Cycle : 0
• Exported Energy Mj By Energy Vector Manufacturing A1 A3 : 0
• Exported Energy Mj By Energy Vector Distribution A4 : 0
• Exported Energy Mj By Energy Vector Installation A5 : 0
• Exported Energy Mj By Energy Vector Operational Energy Use B6 : 0
• Exported Energy Mj By Energy Vector End Of Life C1 C4 : 0
• Hazardous Waste Disposed Of Kg Total Life Cycle : 34.582
• Hazardous Waste Disposed Of Kg Manufacturing A1 A3 : 22.512
• Hazardous Waste Disposed Of Kg Distribution A4 : 0
• Hazardous Waste Disposed Of Kg Installation A5 : 1.2962
• Hazardous Waste Disposed Of Kg Operational Energy Use B6 : 3.0967
• Hazardous Waste Disposed Of Kg End Of Life C1 C4 : 7.6771
• Materials For Energy Recovery Kg Total Life Cycle : 0.60065
• Materials For Energy Recovery Kg Manufacturing A1 A3 : 0.0039055
• Materials For Energy Recovery Kg Distribution A4 : 0
• Materials For Energy Recovery Kg Installation A5 : 0
• Materials For Energy Recovery Kg Operational Energy Use B6 : 0
• Materials For Energy Recovery Kg End Of Life C1 C4 : 0.59674
• Materials For Recycling Kg Total Life Cycle : 4.7277
• Materials For Recycling Kg Manufacturing A1 A3 : 0.55023
• Materials For Recycling Kg Distribution A4 : 0
• Materials For Recycling Kg Installation A5 : 1.2763
• Materials For Recycling Kg Operational Energy Use B6 : 0
• Materials For Recycling Kg End Of Life C1 C4 : 2.9012
• Net Use Of Fresh Water M3 Total Life Cycle : 21538
• Net Use Of Fresh Water M3 Manufacturing A1 A3 : 0.31048
• Net Use Of Fresh Water M3 Distribution A4 : 0.000065829
• Net Use Of Fresh Water M3 Installation A5 : 0.00014574
• Net Use Of Fresh Water M3 Operational Energy Use B6 : 21538
• Net Use Of Fresh Water M3 End Of Life C1 C4 : 0.0015194
• Non Hazardous Waste Disposed Of Kg Total Life Cycle : 22216
• Non Hazardous Waste Disposed Of Kg Manufacturing A1 A3 : 68.862
• Non Hazardous Waste Disposed Of Kg Distribution A4 : 0.026134
• Non Hazardous Waste Disposed Of Kg Installation A5 : 0.0057353
• Non Hazardous Waste Disposed Of Kg Operational Energy Use B6 : 22147
• Non Hazardous Waste Disposed Of Kg End Of Life C1 C4 : 0.026231
• Ozone Depletion Kg Equivalent Cfc 11 Total Life Cycle : 0.00039451
• Ozone Depletion Kg Equivalent Cfc 11 Manufacturing A1 A3 : 0.0000074476
• Ozone Depletion Kg Equivalent Cfc 11 Distribution A4 : 0.00000000149
• Ozone Depletion Kg Equivalent Cfc 11 Installation A5 : 0.0000000074961
• Ozone Depletion Kg Equivalent Cfc 11 Operational Energy Use B6 : 0.00038695
• Ozone Depletion Kg Equivalent Cfc 11 End Of Life C1 C4 : 0.000000096995
• Radioactive Waste Disposed Of Kg Total Life Cycle : 14.819
• Radioactive Waste Disposed Of Kg Manufacturing A1 A3 : 0.028081
• Radioactive Waste Disposed Of Kg Distribution A4 : 0.000018614
• Radioactive Waste Disposed Of Kg Installation A5 : 0.000008748
• Radioactive Waste Disposed Of Kg Operational Energy Use B6 : 14.791
• Radioactive Waste Disposed Of Kg End Of Life C1 C4 : 0.000057246
• Total Use Of NRE PrE Resources And PrE Resources Used As RawMats Mj TLC : 104520
• Total Use Of NRE PrE Resources And PrE Resources Used As RawMats Mj Mfg A1 A3 : 949.67
• Total Use Of NRE PrE Resources And PrE Resources Used As RawMats Mj Dist A4 : 10.386
• Total Use Of NRE PrE Resources And PrE Resources Used As RawMats Mj Inst A5 : 1.8551
• Total Use Of NRE PrE Resources And PrE Resources Used As RawMats Mj OpEnergy B6 : 103550
• Total Use Of NRE PrE Resources And PrE Resources Used As RawMats Mj EoL C1 C4 : 9.4717
• Total Use Of Primary Energy During The Life Cycle Mj Total Life Cycle : 119640
• Total Use Of Primary Energy During The Life Cycle Mj Manufacturing A1 A3 : 983.15
• Total Use Of Primary Energy During The Life Cycle Mj Distribution A4 : 10.4
• Total Use Of Primary Energy During The Life Cycle Mj Installation A5 : 1.8572
• Total Use Of Primary Energy During The Life Cycle Mj Operational Energy Use B6 : 118640
• Total Use Of Primary Energy During The Life Cycle Mj End Of Life C1 C4 : 9.4805
• Total Use Of RE PrE Resources And PrE Resources Used As RawMats Mj TLC : 15120
• Total Use Of RE PrE Resources And PrE Resources Used As RawMats Mj Mfg A1 A3 : 33.477
• Total Use Of RE PrE Resources And PrE Resources Used As RawMats Mj Dist A4 : 0.01386
• Total Use Of RE PrE Resources And PrE Resources Used As RawMats Mj Inst A5 : 0.002087
• Total Use Of RE PrE Resources And PrE Resources Used As RawMats Mj OpEnergy B6 : 15086
• Total Use Of RE PrE Resources And PrE Resources Used As RawMats Mj EoL C1 C4 : 0.0088287
• Use Of Non Renewable Primary Energy Resources Used As Raw Materials Mj Total Life Cycle : 59.518
• Use Of Non Renewable Primary Energy Resources Used As Raw Materials Mj Manufacturing A1 A3 : 59.518
• Use Of Non Renewable Primary Energy Resources Used As Raw Materials Mj Distribution A4 : 0
• Use Of Non Renewable Primary Energy Resources Used As Raw Materials Mj Installation A5 : 0
• Use Of NRE PrE Resources Used As RawMats Mj OpEnergy B6 : 0
• Use Of Non Renewable Primary Energy Resources Used As Raw Materials Mj End Of Life C1 C4 : 0
• Use Of NRE PrE Excluding NRE PrE Resources Used As RawMats Mj TLC : 104460
• Use Of NRE PrE Excluding NRE PrE Resources Used As RawMats Mj Mfg A1 A3 : 890.15
• Use Of NRE PrE Excluding NRE PrE Resources Used As RawMats Mj Dist A4 : 10.386
• Use Of NRE PrE Excluding NRE PrE Resources Used As RawMats Mj Inst A5 : 1.8551
• Use Of NRE PrE Excluding NRE PrE Resources Used As RawMats Mj OpEnergy B6 : 103550
• Use Of NRE PrE Excluding NRE PrE Resources Used As RawMats Mj EoL C1 C4 : 9.4717
• Use Of Non Renewable Secondary Fuels Mj Total Life Cycle : 0
• Use Of Non Renewable Secondary Fuels Mj Manufacturing A1 A3 : 0
• Use Of Non Renewable Secondary Fuels Mj Distribution A4 : 0
• Use Of Non Renewable Secondary Fuels Mj Installation A5 : 0
• Use Of Non Renewable Secondary Fuels Mj Operational Energy Use B6 : 0
• Use Of Non Renewable Secondary Fuels Mj End Of Life C1 C4 : 0
• Use Of Renewable Primary Energy Resources Used As Raw Materials Mj Total Life Cycle : 26.25
• Use Of Renewable Primary Energy Resources Used As Raw Materials Mj Manufacturing A1 A3 : 26.25
• Use Of Renewable Primary Energy Resources Used As Raw Materials Mj Distribution A4 : 0
• Use Of Renewable Primary Energy Resources Used As Raw Materials Mj Installation A5 : 0
• Use Of RE PrE Resources Used As RawMats Mj OpEnergy B6 : 0
• Use Of RE PrE Resources Used As RawMats Mj BLB SysBound D : 0
• Use Of RE PrE Excluding RE PrE Resources Used As RawMats Mj TLC : 15093
• Use Of RE PrE Excluding RE PrE Resources Used As RawMats Mj Mfg A1 A3 : 7.2274
• Use Of RE PrE Excluding RE PrE Resources Used As RawMats Mj Dist A4 : 0.01386
• Use Of RE PrE Excluding RE PrE Resources Used As RawMats Mj Inst A5 : 0.002087
• Use Of RE PrE Excluding RE PrE Resources Used As RawMats Mj OpEnergy B6 : 15086
• Use Of RE PrE Excluding RE PrE Resources Used As RawMats Mj EoL C1 C4 : 0.0088287
• Use Of Renewable Secondary Fuels Mj Total Life Cycle : 0
• Use Of Renewable Secondary Fuels Mj Manufacturing A1 A3 : 0
• Use Of Renewable Secondary Fuels Mj Distribution A4 : 0
• Use Of Renewable Secondary Fuels Mj Installation A5 : 0
• Use Of Renewable Secondary Fuels Mj Operational Energy Use B6 : 0
• Use Of Renewable Secondary Fuels Mj End Of Life C1 C4 : 0
• Use Of Secondary Materials Kg Total Life Cycle : 0.38471
• Use Of Secondary Materials Kg Manufacturing A1 A3 : 0.38471
• Use Of Secondary Materials Kg Distribution A4 : 0
• Use Of Secondary Materials Kg Installation A5 : 0
• Use Of Secondary Materials Kg Operational Energy Use B6 : 0
• Use Of Secondary Materials Kg End Of Life C1 C4 : 0
• Air Pollution M3 Total Life Cycle : 262700
• Air Pollution M3 Manufacturing A1 A3 : 6929.1
• Air Pollution M3 Distribution A4 : 31.29
• Air Pollution M3 Installation A5 : 13.091
• Air Pollution M3 Operational Energy Use B6 : 255660
• Air Pollution M3 End Of Life C1 C4 : 66.063
• Water Pollution M3 Total Life Cycle : 252810
• Water Pollution M3 Manufacturing A1 A3 : 7183.8
• Water Pollution M3 Distribution A4 : 120.96
• Water Pollution M3 Installation A5 : 13.986
• Water Pollution M3 Operational Energy Use B6 : 245110
• Water Pollution M3 End Of Life C1 C4 : 378.94
• Acidification Of Soil And Water Kg Equivalent So2 Total Life Cycle : 25.027
• Photochemical Ozone Formation Kg Equivalent C2h4 Total Life Cycle : 1.3804
• Water Eutrophication Kg Equivalent P04 3 Total Life Cycle : 1.5864
• Acidification Of Soil And Water Kg Equivalent So2 Manufacturing A1 A3 : 0.24382
• Acidification Of Soil And Water Kg Equivalent So2 Distribution A4 : 0.0033585
• Acidification Of Soil And Water Kg Equivalent So2 Installation A5 : 0.00036751
• Acidification Of Soil And Water Kg Equivalent So2 Operational Energy Use B6 : 24.778
• Acidification Of Soil And Water Kg Equivalent So2 End Of Life C1 C4 : 0.0020118
• Global Warming Kg Equivalent Co2 Total Life Cycle : 5997.6
• Global Warming Kg Equivalent Co2 Manufacturing A1 A3 : 54.12
• Global Warming Kg Equivalent Co2 Distribution A4 : 0.73556
• Global Warming Kg Equivalent Co2 Installation A5 : 0.11923
• Global Warming Kg Equivalent Co2 Operational Energy Use B6 : 5940
• Global Warming Kg Equivalent Co2 End Of Life C1 C4 : 2.5798
• Photochemical Ozone Formation Kg Equivalent C2h4 Manufacturing A1 A3 : 0.018412
• Photochemical Ozone Formation Kg Equivalent C2h4 Distribution A4 : 0.00023966
• Photochemical Ozone Formation Kg Equivalent C2h4 Installation A5 : 0.000039874
• Photochemical Ozone Formation Kg Equivalent C2h4 Operational Energy Use B6 : 1.3615
• Photochemical Ozone Formation Kg Equivalent C2h4 End Of Life C1 C4 : 0.00018303
• Water Eutrophication Kg Equivalent P04 3 Manufacturing A1 A3 : 0.088675
• Water Eutrophication Kg Equivalent P04 3 Distribution A4 : 0.00077354
• Water Eutrophication Kg Equivalent P04 3 Installation A5 : 0.000086351
• Water Eutrophication Kg Equivalent P04 3 Operational Energy Use B6 : 1.496
• Water Eutrophication Kg Equivalent P04 3 End Of Life C1 C4 : 0.00086959
• Important Information Attributes
• Persona Type Ids : EU, OM, OM8
• Persona Type Names : End User, Original Equipment Manufacturer, OEM - Control Panelbuilder
• Apparent Power : 16.2 kVA 500 V heavy duty), 16.2 kVA 500 V heavy duty), 16.2 kVA 500 V heavy duty)
• Asynchronous Motor Control Profile : voltage/frequency ratio, 5 points, flux vector control without sensor, standard, voltage/frequency ratio - Energy Saving, quadratic U/f, flux vector control without sensor - Energy Saving, voltage/frequency ratio, 2 points
• Electromagnetic Compatibility : electrostatic discharge immunity test level 3 conforming to IEC 61000-4-2, electrostatic discharge immunity test level 3 conforming to IEC 61000-4-2, electrostatic discharge immunity test level 3 conforming to IEC 61000-4-2, radiated radio-frequency electromagnetic field immunity test level 3 conforming to IEC 61000-4-3, radiated radio-frequency electromagnetic field immunity test level 3 conforming to IEC 61000-4-3, radiated radio-frequency electromagnetic field immunity test level 3 conforming to IEC 61000-4-3, electrical fast transient/burst immunity test level 4 conforming to IEC 61000-4-4, electrical fast transient/burst immunity test level 4 conforming to IEC 61000-4-4, electrical fast transient/burst immunity test level 4 conforming to IEC 61000-4-4, 1.2/50 µs - 8/20 µs surge immunity test level 3 conforming to IEC 61000-4-5, 1.2/50 µs - 8/20 µs surge immunity test level 3 conforming to IEC 61000-4-5, 1.2/50 µs - 8/20 µs surge immunity test level 3 conforming to IEC 61000-4-5, conducted radio-frequency immunity test level 3 conforming to IEC 61000-4-6, conducted radio-frequency immunity test level 3 conforming to IEC 61000-4-6, conducted radio-frequency immunity test level 3 conforming to IEC 61000-4-6, voltage dips and interruptions immunity test conforming to IEC 61000-4-11, voltage dips and interruptions immunity test conforming to IEC 61000-4-11
• Line Current : 26.5 A 380 V heavy duty), 26.5 A 380 V heavy duty), 26.5 A 380 V heavy duty), 18.7 A 500 V heavy duty), 18.7 A 500 V heavy duty), 18.7 A 500 V heavy duty)
• Linearity Error : AI1, AI2, AI3 +/- 0.2...0.5 % of maximum value analog input, AI1, AI2, AI3 +/- 0.2...0.5 % of maximum value analog input, AI1, AI2, AI3 +/- 0.2...0.5 % of maximum value analog input, AQ1 +/- 0.3 % analog output, AQ1 +/- 0.3 % analog output, AQ1 +/- 0.3 % analog output
• Method Of Access : slave CANopen, slave CANopen
• Motor Power KW : 7.5 kW heavy duty, 7.5 kW heavy duty
• Motor Slip Compensation : automatic whatever the load, adjustable 0...300 %, not available in voltage/frequency ratio (2 or 5 points)
• Option Card : communication module, CANopen, communication module, CANopen, communication module, EtherCAT, communication module, EtherCAT, communication module, Profibus DP V1, communication module, Profibus DP V1, communication module, PROFINET, communication module, PROFINET, communication module, Ethernet Powerlink, communication module, Ethernet Powerlink, communication module, EtherNet/IP, communication module, EtherNet/IP, communication module, DeviceNet, communication module, DeviceNet
• Power Dissipation In W : fan 229.0 W 380 V 4 kHz, fan 229.0 W 380 V 4 kHz, fan 229.0 W 380 V 4 kHz, fan 229.0 W 380 V 4 kHz
• Protection Type : input phase breaks drive, input phase breaks drive, overcurrent between output phases and earth drive, overcurrent between output phases and earth drive, overheating protection drive, overheating protection drive, short-circuit between motor phases drive, short-circuit between motor phases drive, thermal protection drive, thermal protection drive
• Refresh Time : logic input DI1...DI4)8 ms, logic input DI1...DI4)8 ms, logic input DI1...DI4)8 ms, relay output R1A, R1B, R1C)2 ms, relay output R1A, R1B, R1C)2 ms, relay output R1A, R1B, R1C)2 ms, relay output R2A, R2C)2 ms, relay output R2A, R2C)2 ms, relay output R2A, R2C)2 ms
• Sampling Duration : 2 ms AI1, AI2, AI3) - analog input, 2 ms AI1, AI2, AI3) - analog input, 2 ms AI1, AI2, AI3) - analog input, 2 ms AQ1) - analog output, 2 ms AQ1) - analog output, 2 ms AQ1) - analog output
• Speed Accuracy : +/- 10 % of nominal slip 0.2 Tn to Tn, +/- 10 % of nominal slip 0.2 Tn to Tn
• Switching Frequency : 2...16 kHz adjustable, 2...16 kHz adjustable, 4...16 kHz with derating factor, 4...16 kHz with derating factor
• Transient Overtorque : 170-200 % of nominal motor torque, 170-200 % of nominal motor torque
• Environmental Class During Storage : class 1C3 according to EN 60721-3, class 1S2 according to EN 60721-3
• Environmental Class During Transport : class 2C3 according to EN 60721-3, class 2S1 according to EN 60721-3
• Local Data Status : Publishable
• Local Publishable Date : 2025-11-12
• Device Type : Variable speed drive - VSD Compacts
• Serviceability : No
• Traceability : Yes
• Field Service Division : IDIBS
• Average Life Duration : 10 year(s)
• Legacy WEEE Scope : In
• Scope Perimeter : At least in Europe
• EOLI Availability Display : Yes
• End Of Life Doc Ref : ENVEOLI1708004EN
• Reach Full Compliance Status : Reference contains Substances of Very High Concern above the threshold
• Reach Full Compliance Status Id : CONTAINS_SVHC
• Reach Compliance Directive : Reference contains Substances of Very High Concern above the threshold
• ROHS EUR In Scope : No
• ROHS EUR Status : Compliant with Exemptions
• ROHS EUR Full Compliance Status : Pro-active compliance (Product out of EU RoHS legal scope)
• ROHS EUR Full Compliance Status Id : PRO_ACTIVE_COMPLIANCE
• China ROHS In Scope : Yes
• Green Premium Status For Reporting : Green Premium product
• With Recycled Cardboard : Yes
• Without Single Use Plastic : No
• Product Contributes To Saved And Avoided Emissions : YES_SSI2
• Return Indicator : Y
• WD Status : 1 - GSC certified
• Function Option Id : STANDARD
• Function Option : Standard
• Market Segmentation Id : INDUSTRIAL
• Market Segmentation : Industrial
• 1 Phase Low Current Possible : false
• 4 Quadrant Operation Possible : true
• Application In Domestic And Commercial Area Permitted : false
• Base Load Current At High Overload : 17.0 A
• Braking To Standstill : by DC injection
• Capacity Of Dc Link : 1110 µF
• Computer Port : true
• Design Of Frequency Changer : U converter
• Encoder Protocol : RS 422
• Format Of The Drive : book
• Housing Material : plastic
• Maximum Associated Fuse Rating : 40 A
• Maximum Input Current Per Phase : 26.5 A
• Nominal Switching Frequency : 4 kHz
• Operating Element Present : true
• Optical Interface Present : false
• Package Weight Lbs : 5.620 kg
• Power Loss Per Device Current Dependent : 229.0 W
• Power Loss Static Current Independent : 229.0 W
• Product Availability : Stock - Normally stocked in distribution facility
• Product Or Component Type : variable speed drive
• Product Specific Application : complex machines
• Range Of Product : Altivar Machine ATV320
• Relative Symmetric Mains Voltage Tolerance : 10 %
• Relative Symmetric Network Frequency Tolerance : 5 %
• Returnability : Yes
• Supporting Protocol For As Interface Safety At Work : false
• Supporting Protocol For Bacnet : false
• Supporting Protocol For Can : true
• Supporting Protocol For Data Highway : false
• Supporting Protocol For Devicenet : true
• Supporting Protocol For Devicenet Safety : false
• Supporting Protocol For Ethernet Ip : true
• Supporting Protocol For Foundation Fieldbus : false
• Supporting Protocol For Interbus : false
• Supporting Protocol For Knx : false
• Supporting Protocol For Lon : false
• Supporting Protocol For Modbus : true
• Supporting Protocol For Other Bus Systems : true
• Supporting Protocol For Profibus : true
• Supporting Protocol For Profinet Cba : false
• Supporting Protocol For Profinet Io : true
• Supporting Protocol For Profisafe : false
• Supporting Protocol For Safetybus P : false
• Supporting Protocol For Sercos : false
• Supporting Protocol For Suconet : false
• Supporting Protocol For TCP IP : true
• Sustainable Packaging : No
• Synchronous Motor Control Profile : vector control without sensor
• Total Lifecycle Carbon Footprint : 5 998 kg CO2 eq.
• Variant : standard version
• Volume Of Cooling Air : 60 m3/h
• Weee Label : The product must be disposed on European Union markets following specific waste collection and never end up in rubbish bins.
• With Safety Function Safe Programmable Logic : false
• EMC Limit Value Complied : true
• Permitted Relative Humidity During Transport : class 2K5 according to EN 60721-3
• With Safety Function Safe Brake Management Sbc Sbt : false
• With Safety Function Safe Direction SDI : false
• With Safety Function Safe Operating Stop Sos : false
• With Safety Function Safe Position Sp : false
• With Safety Function Safe Speed Monitor Ssm : false
• With Safety Function Safe Stop 1 SS1 : true
• With Safety Function Safe Torque Off Sto : true
• With Safety Function Safely Limited Position Slp : false
• With Safety Function Safely Limited Speed Sls : true
• With Sft Fct Safe Stop 2 Ss2 : false
• Relationship Type : Compatible relationship
• Application In Industrial Area Permitted : true
• Supporting Protocol For Interbus Safety : false
• Pep Code : ENVPEP1708004EN
• Pep Verification Date : 2018-01-01
• PCR Version : PCR-ed3-EN-2015 04 02
• Type Of Verification For The Pep : Independent external review
• Functional Unit Description : To adapt the speed and torque of synchronous, asynchronous or reluctance motor to the machine's operating point during 10 years and a 80% use rate, in accordance with the relevant standards.
• Functional Unit Unit : unité (unit)
• Product Kit Identifier : N
• Support B296 B318ing Protocol For Asi : false
• Huella De Carbono De La Fase De Distribución A4 : 0.7 kg CO2 eq.
• Huella De Carbono De La Fase De Fabricación A1 A A3 : 54 kg CO2 eq.
• Huella De Carbono De La Fase De Fin De Vida C1 A C4 : 3 kg CO2 eq.
• Huella De Carbono De La Fase De Instalación A5 : 0.1 kg CO2 eq.
• Huella De Carbono De La Fase De Uso B2 B3 B4 B6 : 5 940 kg CO2 eq.
• Environment Attributes Main
• Ambient Air Temperature For Operation : -10-50 °C without derating, -10-50 °C without derating, 50-60 °C with derating factor, 50-60 °C with derating factor
• EU ROHS Directive : Compliant By Exemption​, Pro-active compliance (Product out of EU RoHS legal scope)
• Environmental Class During Operation : class 3C3 according to IEC 60721-3-3, class 3S2 according to IEC 60721-3-3
• ROHS Exemption Information : Yes
• Take Back : No
• Recycled Metal Content At Cr Level : 0 %
• China ROHS Regulation : X
• Mercury Free : Yes
• Carbon Footprint : 5997.6
• Ambient Air Transport Temperature : -25-70 °C
• Circularity Profile : ENVEOLI1708004EN
• Environmental Disclosure : ENVPEP1708004EN
• Packaging Made With Recycled Cardboard : Yes
• Packaging Without Single Use Plastic : No
• Reach Regulation : Reference contains Substances of Very High Concern above the threshold
• Permitted Relative Humidity During Operation : class 3K5 according to EN 60721-3
• Permitted Relative Humidity During Storage : class 1K5 according to EN 60721-3
• Pep Code : ENVPEP1708004EN
• Pep Verification Date : 2018-01-01
• PCR Version : PCR-ed3-EN-2015 04 02
• Type Of Verification For The Pep : Independent external review
• General Attributes
• Product Or Component Type : variable speed drive
• Range Of Product : Altivar Machine ATV320
• Output Attributes
• Analogue Output Type : software-configurable current AQ1 0...20 mA 800 Ohm 10 bits, software-configurable current AQ1 0...20 mA 800 Ohm 10 bits, software-configurable current AQ1 0...20 mA 800 Ohm 10 bits, software-configurable current AQ1 0...20 mA 800 Ohm 10 bits, software-configurable current AQ1 0...20 mA 800 Ohm 10 bits, software-configurable voltage AQ1 0...10 V DC 470 Ohm 10 bits, software-configurable voltage AQ1 0...10 V DC 470 Ohm 10 bits, software-configurable voltage AQ1 0...10 V DC 470 Ohm 10 bits, software-configurable voltage AQ1 0...10 V DC 470 Ohm 10 bits, software-configurable voltage AQ1 0...10 V DC 470 Ohm 10 bits, software-configurable voltage AQ1 0...10 V DC 470 Ohm 10 bits
• Discrete Output Type : open collector DQ+ 0-1 kHz 30 V DC 100 mA, open collector DQ+ 0-1 kHz 30 V DC 100 mA, open collector DQ+ 0-1 kHz 30 V DC 100 mA, open collector DQ+ 0-1 kHz 30 V DC 100 mA, open collector DQ+ 0-1 kHz 30 V DC 100 mA, open collector DQ+ 0-1 kHz 30 V DC 100 mA, open collector DQ- 0-1 kHz 30 V DC 100 mA, open collector DQ- 0-1 kHz 30 V DC 100 mA, open collector DQ- 0-1 kHz 30 V DC 100 mA, open collector DQ- 0-1 kHz 30 V DC 100 mA, open collector DQ- 0-1 kHz 30 V DC 100 mA, open collector DQ- 0-1 kHz 30 V DC 100 mA
• Relay Output Type : configurable relay logic R1A 1 NO 100000 cycles, configurable relay logic R1A 1 NO 100000 cycles, configurable relay logic R1A 1 NO 100000 cycles, configurable relay logic R1A 1 NO 100000 cycles, configurable relay logic R1B 1 NC 100000 cycles, configurable relay logic R1B 1 NC 100000 cycles, configurable relay logic R1B 1 NC 100000 cycles, configurable relay logic R1B 1 NC 100000 cycles, configurable relay logic R1C, configurable relay logic R1C, configurable relay logic R2A 1 NO 100000 cycles, configurable relay logic R2A 1 NO 100000 cycles, configurable relay logic R2A 1 NO 100000 cycles, configurable relay logic R2A 1 NO 100000 cycles, configurable relay logic R2C, configurable relay logic R2C
• Maximum Output Voltage : 500 V
• Input Attributes
• Analogue Input Type : AI1 voltage 0...10 V DC 30 kOhm 10 bits, AI1 voltage 0...10 V DC 30 kOhm 10 bits, AI1 voltage 0...10 V DC 30 kOhm 10 bits, AI1 voltage 0...10 V DC 30 kOhm 10 bits, AI1 voltage 0...10 V DC 30 kOhm 10 bits, AI1 voltage 0...10 V DC 30 kOhm 10 bits, AI2 bipolar differential voltage +/- 10 V DC 30 kOhm 10 bits, AI2 bipolar differential voltage +/- 10 V DC 30 kOhm 10 bits, AI2 bipolar differential voltage +/- 10 V DC 30 kOhm 10 bits, AI2 bipolar differential voltage +/- 10 V DC 30 kOhm 10 bits, AI2 bipolar differential voltage +/- 10 V DC 30 kOhm 10 bits, AI2 bipolar differential voltage +/- 10 V DC 30 kOhm 10 bits, AI3 current 0...20 mA (or 4-20 mA, x-20 mA, 20-x mA or other patterns by configuration) 250 Ohm 10 bits, AI3 current 0...20 mA (or 4-20 mA, x-20 mA, 20-x mA or other patterns by configuration) 250 Ohm 10 bits, AI3 current 0...20 mA (or 4-20 mA, x-20 mA, 20-x mA or other patterns by configuration) 250 Ohm 10 bits, AI3 current 0...20 mA (or 4-20 mA, x-20 mA, 20-x mA or other patterns by configuration) 250 Ohm 10 bits, AI3 current 0...20 mA (or 4-20 mA, x-20 mA, 20-x mA or other patterns by configuration) 250 Ohm 10 bits
• Discrete Input Type : STO safe torque off, 24 V DC1.5 kOhm, STO safe torque off, 24 V DC1.5 kOhm, STO safe torque off, 24 V DC1.5 kOhm, STO safe torque off, 24 V DC1.5 kOhm, STO safe torque off, 24 V DC1.5 kOhm, DI1...DI6 logic inputs, 24 V DC 30 V), DI1...DI6 logic inputs, 24 V DC 30 V), DI1...DI6 logic inputs, 24 V DC 30 V), DI1...DI6 logic inputs, 24 V DC 30 V), DI1...DI6 logic inputs, 24 V DC 30 V), DI5 programmable as pulse input 0-30 kHz, 24 V DC 30 V), DI5 programmable as pulse input 0-30 kHz, 24 V DC 30 V), DI5 programmable as pulse input 0-30 kHz, 24 V DC 30 V), DI5 programmable as pulse input 0-30 kHz, 24 V DC 30 V), DI5 programmable as pulse input 0-30 kHz, 24 V DC 30 V), DI5 programmable as pulse input 0-30 kHz, 24 V DC 30 V)
• Number Of Input Phases : 3