Specifications
-
Lineup in Japan
-
FRENIC-VG
-
Product information
- Unit Type, Stack Type, Converters
- Comprehensive Line-up
- Improved Control Performance
- A Wide Range of Applications
- Easier Maintenance
- Easier Maintenance and Greater Reliability
- Adaptation to Environment and Safety
- How to expand the capacity range of the inverters (Stack Type)
- How to expand the capacity range of the PWM converters (Stack Type)
- Variation
- Applicable SiC Hybrid Module Model
- Specifications
- External Dimensions
-
Catalog Download
- Document Download
-
Product information
- FRENIC-MEGA (G2)
-
FRENIC-MEGA (G1)
-
Product information
- Best vector control for the general-purpose inverter in the class
- Accommodating various applications
- Wide model variation meeting the customer needs
- Supports for simple maintenance
- Network building
- Prolonged service life and improved life judgment function
- Consideration for environment
- Global compatibility
- Function Safety
- Variation
- Specifications
- External Dimensions
-
Catalog Download
- Document Download
-
Product information
-
FRENIC-Ace (E3)
- Product information
- Variation
- Specifications
- External Dimensions
-
Catalog Download
- Document Download
- FRENIC-Ace (E2)
- FRENIC-Mini
-
FRENIC-HVAC
- Product information
- Variation
- Specifications
- External Dimensions
-
Catalog Download
- Document Download
-
FRENIC-Eco
-
Product information
- Product appearance
- Exploded view of main body
- Keypad switches and functions
- Monitor display & key operation
- New energy-saving
- Long life design of inverters
- Simplified maintenance
- Optimum functions for HVAC
- Environment and panel design
- Operator-friendly features
- Network compatibility
- Global compatibility
- Variation
- Specifications
- External Dimensions
-
Catalog Download
- Document Download
-
Product information
-
FRENIC-Lift(LM1S)
- Product information
- Variation
- Specifications
- External Dimensions
-
Catalog Download
- Document Download
-
FRENIC-eRHR
- Product information
- Variation
- Specifications
- External Dimensions
-
Catalog Download
- Document Download
-
FRENIC-eRHC
- Product information
- Variation
- Specifications
- External Dimensions
-
Catalog Download
- Document Download
-
FRENIC-VG
-
Lineup in Europe
-
FRENIC-VG
-
Product information
- Unit Type, Stack Type, Converters
- Comprehensive Line-up
- Improved Control Performance
- A Wide Range of Applications
- Easier Maintenance
- Easier Maintenance and Greater Reliability
- Adaptation to Environment and Safety
- How to expand the capacity range of the inverters (Stack Type)
- How to expand the capacity range of the PWM converters (Stack Type)
- Variation
- Applicable SiC Hybrid Module Model
- Specifications
- External Dimensions
-
Catalog Download
- Document Download
-
Product information
- FRENIC-MEGA (G2)
-
FRENIC-MEGA (G1)
-
Product information
- Best vector control for the general-purpose inverter in the class
- Accommodating various applications
- Wide model variation meeting the customer needs
- Supports for simple maintenance
- Network building
- Prolonged service life and improved life judgment function
- Consideration for environment
- Global compatibility
- Function Safety
- Variation
- Specifications
- External Dimensions
-
Catalog Download
-
Product information
-
FRENIC-Ace (E3)
- Product information
- Variation
- Specifications
- External Dimensions
-
Catalog Download
- Document Download
- FRENIC-Ace (E2)
- FRENIC-Mini
- FVR-Micro
-
FRENIC-HVAC
- Product information
- Variation
- Specifications
- External Dimensions
-
Catalog Download
- Document Download
-
FRENIC-Eco
-
Product information
- Product appearance
- Exploded view of main body
- Keypad switches and functions
- Monitor display & key operation
- New energy-saving
- Long life design of inverters
- Simplified maintenance
- Optimum functions for HVAC
- Environment and panel design
- Operator-friendly features
- Network compatibility
- Global compatibility
- Variation
- Specifications
- External Dimensions
-
Catalog Download
- Document Download
-
Product information
- FRENIC-AQUA
-
FRENIC-Lift(LM1S)
- Product information
- Variation
- Specifications
- External Dimensions
-
Catalog Download
- Document Download
-
FRENIC-Lift(LM2A)
- Product information
- Variation
- Specifications
- External Dimensions
-
Catalog Download
- Document Download
-
FRENIC-eRHR
- Product information
- Variation
- Specifications
- External Dimensions
-
Catalog Download
- Document Download
-
FRENIC-eRHC
- Product information
- Variation
- Specifications
- External Dimensions
-
Catalog Download
- Document Download
-
FRENIC-VG
-
Lineup in North America
-
FRENIC-VG
-
Product information
- Unit Type, Stack Type, Converters
- Comprehensive Line-up
- Improved Control Performance
- A Wide Range of Applications
- Easier Maintenance
- Easier Maintenance and Greater Reliability
- Adaptation to Environment and Safety
- How to expand the capacity range of the inverters (Stack Type)
- How to expand the capacity range of the PWM converters (Stack Type)
- Variation
- Applicable SiC Hybrid Module Model
- Specifications
- External Dimensions
-
Catalog Download
- Document Download
-
Product information
- FRENIC-MEGA (G2)
-
FRENIC-MEGA (G1)
-
Product information
- Best vector control for the general-purpose inverter in the class
- Accommodating various applications
- Wide model variation meeting the customer needs
- Supports for simple maintenance
- Network building
- Prolonged service life and improved life judgment function
- Consideration for environment
- Global compatibility
- Function Safety
- Variation
- Specifications
- External Dimensions
-
Catalog Download
-
Product information
-
FRENIC-Ace (E3)
- Product information
- Variation
- Specifications
- External Dimensions
-
Catalog Download
- Document Download
- FRENIC-Ace (E2)
- FRENIC-Mini
-
FRENIC-HVAC
- Product information
- Variation
- Specifications
- External Dimensions
-
Catalog Download
- Document Download
-
FRENIC-Eco
-
Product information
- Product appearance
- Exploded view of main body
- Keypad switches and functions
- Monitor display & key operation
- New energy-saving
- Long life design of inverters
- Simplified maintenance
- Optimum functions for HVAC
- Environment and panel design
- Operator-friendly features
- Network compatibility
- Global compatibility
- Variation
- Specifications
- External Dimensions
-
Catalog Download
-
Product information
-
FRENIC-eRHR
- Product information
- Variation
- Specifications
- External Dimensions
-
Catalog Download
- Document Download
-
FRENIC-eRHC
- Product information
- Variation
- Specifications
- External Dimensions
-
Catalog Download
- Document Download
-
FRENIC-VG
-
Lineup in China
-
FRENIC-VG
-
Product information
- Unit Type, Stack Type, Converters
- Comprehensive Line-up
- Improved Control Performance
- A Wide Range of Applications
- Easier Maintenance
- Easier Maintenance and Greater Reliability
- Adaptation to Environment and Safety
- How to expand the capacity range of the inverters (Stack Type)
- How to expand the capacity range of the PWM converters (Stack Type)
- Variation
- Applicable SiC Hybrid Module Model
- Specifications
- External Dimensions
-
Catalog Download
- Document Download
-
Product information
- FRENIC-MEGA (G2)
-
FRENIC-MEGA (G1)
-
Product information
- Best vector control for the general-purpose inverter in the class
- Accommodating various applications
- Wide model variation meeting the customer needs
- Supports for simple maintenance
- Network building
- Prolonged service life and improved life judgment function
- Consideration for environment
- Global compatibility
- Function Safety
- Variation
- Specifications
- External Dimensions
-
Catalog Download
- Document Download
-
Product information
-
FRENIC-Ace (E3)
- Product information
- Variation
- Specifications
- External Dimensions
-
Catalog Download
- Document Download
- FRENIC-Ace (E2)
- FRENIC-Mini
- FVR-Micro
-
FRENIC VP
- Product information
- Variation
- Specifications
- External Dimensions
-
Catalog Download
-
For Europe
- For China
-
- Document Download
- FRENIC-Lift(LM1S)
- FRENIC-eRHR
-
FRENIC-eRHC
- Product information
- Variation
- Specifications
- External Dimensions
-
Catalog Download
- Document Download
-
FRENIC-VG
-
Lineup in Asia
-
FRENIC-VG
-
Product information
- Unit Type, Stack Type, Converters
- Comprehensive Line-up
- Improved Control Performance
- A Wide Range of Applications
- Easier Maintenance
- Easier Maintenance and Greater Reliability
- Adaptation to Environment and Safety
- How to expand the capacity range of the inverters (Stack Type)
- How to expand the capacity range of the PWM converters (Stack Type)
- Variation
- Applicable SiC Hybrid Module Model
- Specifications
- External Dimensions
-
Catalog Download
- Document Download
-
Product information
- FRENIC-MEGA (G2)
-
FRENIC-MEGA (G1)
-
Product information
- Best vector control for the general-purpose inverter in the class
- Accommodating various applications
- Wide model variation meeting the customer needs
- Supports for simple maintenance
- Network building
- Prolonged service life and improved life judgment function
- Consideration for environment
- Global compatibility
- Function Safety
- Variation
- Specifications
- External Dimensions
-
Catalog Download
- Document Download
-
Product information
-
FRENIC-Ace (E3)
- Product information
- Variation
- Specifications
- External Dimensions
-
Catalog Download
- Document Download
- FRENIC-Ace (E2)
- FRENIC-Mini
- FVR-Micro
-
FRENIC-HVAC
- Product information
- Variation
- Specifications
- External Dimensions
-
Catalog Download
- Document Download
-
FRENIC-Eco
-
Product information
- Product appearance
- Exploded view of main body
- Keypad switches and functions
- Monitor display & key operation
- New energy-saving
- Long life design of inverters
- Simplified maintenance
- Optimum functions for HVAC
- Environment and panel design
- Operator-friendly features
- Network compatibility
- Global compatibility
- Variation
- Specifications
- External Dimensions
-
Catalog Download
- Document Download
-
Product information
- FRENIC-AQUA
- FRENIC eHVAC
-
FRENIC-Lift(LM1S)
- Product information
- Variation
- Specifications
- External Dimensions
-
Catalog Download
- Document Download
-
FRENIC-eRHR
- Product information
- Variation
- Specifications
- External Dimensions
-
Catalog Download
- Document Download
-
FRENIC-eRHC
- Product information
- Variation
- Specifications
- External Dimensions
-
Catalog Download
- Document Download
-
FRENIC-VG
-
Lineup in Taiwan
-
FRENIC-VG
-
Product information
- Unit Type, Stack Type, Converters
- Comprehensive Line-up
- Improved Control Performance
- A Wide Range of Applications
- Easier Maintenance
- Easier Maintenance and Greater Reliability
- Adaptation to Environment and Safety
- How to expand the capacity range of the inverters (Stack Type)
- How to expand the capacity range of the PWM converters (Stack Type)
- Variation
- Applicable SiC Hybrid Module Model
- Specifications
- External Dimensions
-
Catalog Download
- Document Download
-
Product information
- FRENIC-MEGA (G2)
-
FRENIC-MEGA (G1)
-
Product information
- Best vector control for the general-purpose inverter in the class
- Accommodating various applications
- Wide model variation meeting the customer needs
- Supports for simple maintenance
- Network building
- Prolonged service life and improved life judgment function
- Consideration for environment
- Global compatibility
- Function Safety
- Variation
- Specifications
- External Dimensions
-
Catalog Download
- Document Download
-
Product information
-
FRENIC-Ace (E3)
- Product information
- Variation
- Specifications
- External Dimensions
-
Catalog Download
- Document Download
- FRENIC-Ace (E2)
-
FRENIC-Eco
-
Product information
- Product appearance
- Exploded view of main body
- Keypad switches and functions
- Monitor display & key operation
- New energy-saving
- Long life design of inverters
- Simplified maintenance
- Optimum functions for HVAC
- Environment and panel design
- Operator-friendly features
- Network compatibility
- Global compatibility
- Variation
- Specifications
- External Dimensions
-
Catalog Download
- Document Download
-
Product information
-
FRENIC-Lift(LM1S)
- Product information
- Variation
- Specifications
- External Dimensions
-
Catalog Download
- Document Download
-
FRENIC-eRHR
- Product information
- Variation
- Specifications
- External Dimensions
-
Catalog Download
- Document Download
-
FRENIC-eRHC
- Product information
- Variation
- Specifications
- External Dimensions
-
Catalog Download
- Document Download
-
FRENIC-VG
-
Lineup in Korea
-
FRENIC-VG
-
Product information
- Unit Type, Stack Type, Converters
- Comprehensive Line-up
- Improved Control Performance
- A Wide Range of Applications
- Easier Maintenance
- Easier Maintenance and Greater Reliability
- Adaptation to Environment and Safety
- How to expand the capacity range of the inverters (Stack Type)
- How to expand the capacity range of the PWM converters (Stack Type)
- Variation
- Applicable SiC Hybrid Module Model
- Specifications
- External Dimensions
-
Catalog Download
- Document Download
-
Product information
- FRENIC-MEGA (G2)
-
FRENIC-MEGA (G1)
-
Product information
- Best vector control for the general-purpose inverter in the class
- Accommodating various applications
- Wide model variation meeting the customer needs
- Supports for simple maintenance
- Network building
- Prolonged service life and improved life judgment function
- Consideration for environment
- Global compatibility
- Function Safety
- Variation
- Specifications
- External Dimensions
-
Catalog Download
- Document Download
-
Product information
-
FRENIC-Ace (E3)
- Product information
- Variation
- Specifications
- External Dimensions
-
Catalog Download
- Document Download
- FRENIC-Ace (E2)
- FRENIC-Mini
- FRENIC-Eco
-
FRENIC-Lift(LM1S)
- Product information
- Variation
- Specifications
- External Dimensions
-
Catalog Download
- Document Download
-
FRENIC-eRHR
- Product information
- Variation
- Specifications
- External Dimensions
-
Catalog Download
- Document Download
-
FRENIC-eRHC
- Product information
- Variation
- Specifications
- External Dimensions
-
Catalog Download
- Document Download
-
FRENIC-VG
Unit Type
HD specification for heavy overload (Unit Type)
Three-phase 200V series
Three-phase 400V series
-
Note 1
-
The specification above are established when the function code F80 = 0 (HD specification) is applied.
-
Note 2
-
When using a DC reactor, refer to the following.
-
・ Type FRN□VG1S-□J
-
55kW or below: provided as option, 75kW or above: provided as standard.
-
*1
-
The rated output voltage is 220V for 200V series and 440V for 400V series.
-
*2
-
When the inverter output frequency converter value is 10Hz or less, the inverter may trip early due to overload depending on the conditions such as ambient temperature.
-
*3
-
When the inverter output frequency converter value is 5Hz or less, the inverter may trip early due to overload depending on the conditions such as ambient temperature.
-
*4
-
200V series: Make an individual order for 220 to 230V/50Hz.
400V series: The inverters with the power supply of 380 to 398V/50Hz and 380 to 430V/60Hz must be switched using a connector inside the inverter.
The output of the inverter with 380V may drop depending on situations. For details, refer to Chapter 10 in the FRENIC-VG User Manual "Unit Type, Function Code Edition" 24A7-□-0019.
-
*5
-
The auxiliary power input is used as an AC fan power input when combining the unit such as high power factor PWM converter with power regenerative function.(Generally not used.)
-
*6
-
Voltage unbalance [%] = (Max. voltage [V] - Min. voltage [V]) / (Three-phase average voltage [V]) × 67
Use an AC reactor if the voltage unbalance exceeds 2%.
-
*7
-
The value is calculated on assumption that the inverter is connected with a power supply capacity of 500kVA (or 10 times the inverter capacity if the inverter capacity exceeds 50kVA) and %X is 5%.
-
*8
-
The values shown apply when a DC reactor is used.
If using a generator for the power source, it may burn out with high-frequency current from the inverter. Use a generator with 3 to 4 times the specified power supply capacity.
(When DC reactor not connected: approx. 4 times specified power supply capacity, when DC reactor connected: approx. 3 times specified power supply capacity)
-
*9
-
The inverter may automatically reduce carrier frequency in accordance with ambient temperature or output current in order to protect itself.
If the carrier frequency auto reduction selection (H104: digit 100) is cancelled, the unit continuous rated current will drop depending on the carrier frequency setting, and therefore caution is advised.
(For details, refer to Chapter 2 in the FRENIC-VG User Manual "Unit Type, Function Code Edition" 24A7-□-0019.)
-
Note 1
-
The specifications above are established when the function code F80 = 3 (MD specification) is applied.
If using with the MD specification, specify MD specification when placing your order.
With the type FRN□ VG1S-□ J, a DC reactor with nominal applied motor capacity is provided as standard.
-
Note 2
-
When using a DC reactor, refer to the following.
-
・ Type FRN□ VG1S-□ J
-
Provided as standard. (Specify MD specification when placing your order.)
-
*1
-
When the rated output voltage is 440V
-
*2
-
When the converted inverter output frequency is less than 1Hz, the inverter may trip earlier in some ambient temperature conditions if the motor is overloaded
-
*3
-
When the power supply is 380 to 398V at 50 Hz or 380 to 430V at 60Hz, a connector inside the inverter must be reconnected accordingly.
The output of the inverter with 380V may drop depending on situations. For details, refer to Chapter 10 in the FRENIC-VG User Manual "Unit Type, Function Code Edition" 24A7-□-0019.
-
*4
-
The auxiliary power input is used as an AC fan power input when combining the unit such as high power factor PWM converter with power regenerative function.(Generally not used.)
-
*5
-
Voltage unbalance [%] = (Max. voltage [V] - Min. voltage [V]) / (Three-phase average voltage [V]) × 67
Use an AC reactor if the voltage unbalance exceeds 2%.
-
*6
-
The value is calculated on assumption that the inverter is connected with a power supply capacity of 10 times the inverter capacity and %X is 5%.
-
*7
-
The values shown apply when a DC reactor is used.
If using a generator for the power source, it may burn out with high-frequency current from the inverter. Use a generator with 3 to 4 times the specified power supply capacity.
(When DC reactor not connected: approx. 4 times specified power supply capacity, when DC reactor connected: approx. 3 times specified power supply capacity)
-
*8
-
Depending on the load condition, motor heating may increase with low carrier frequency, and therefore the MD specification should be specified when ordering the motor.
-
*9
-
If running a synchronous motor at low carrier frequency, there is a risk of demagnetization due to permanent magnet overheating as a result of output current harmonics.
The carrier frequency is low (2 to 4kHz), and therefore the motor allowable carrier frequency must always be checked. If unable to use the motor with low carrier frequency (2 to 4kHz), consider the HD specification (H80 = 0).
Three-phase 200V series
Three-phase 400V series
-
Note 1
-
The specification above are established when the function code F80 = 0 (HD specification) is applied.
-
Note 2
-
When using a DC reactor, refer to the following.
-
・ Type FRN□VG1S-□E
-
All capacities are provided as option.
-
*1
-
The rated output voltage is 220V for 200V series and 440V for 400V series.
-
*2
-
When the inverter output frequency converter value is 10Hz or less, the inverter may trip early due to overload depending on the conditions such as ambient temperature.
-
*3
-
When the inverter output frequency converter value is 5Hz or less, the inverter may trip early due to overload depending on the conditions such as ambient temperature.
-
*4
-
200V series: Make an individual order for 220 to 230V/50Hz.
400V series: The inverters with the power supply of 380 to 398V/50Hz and 380 to 430V/60Hz must be switched using a connector inside the inverter.
The output of the inverter with 380V may drop depending on situations. For details, refer to Chapter 10 in the FRENIC-VG User Manual "Unit Type, Function Code Edition" 24A7-□-0019.
-
*5
-
The auxiliary power input is used as an AC fan power input when combining the unit such as high power factor PWM converter with power regenerative function.(Generally not used.)
-
*6
-
Voltage unbalance [%] = (Max. voltage [V] - Min. voltage [V]) / (Three-phase average voltage [V]) × 67
Use an AC reactor if the voltage unbalance exceeds 2%.
-
*7
-
The value is calculated on assumption that the inverter is connected with a power supply capacity of 500kVA (or 10 times the inverter capacity if the inverter capacity exceeds 50kVA) and %X is 5%.
-
*8
-
The values shown apply when a DC reactor is used.
If using a generator for the power source, it may burn out with high-frequency current from the inverter. Use a generator with 3 to 4 times the specified power supply capacity.
(When DC reactor not connected: approx. 4 times specified power supply capacity, when DC reactor connected: approx. 3 times specified power supply capacity)
-
*9
-
The inverter may automatically reduce carrier frequency in accordance with ambient temperature or output current in order to protect itself.
If the carrier frequency auto reduction selection (H104: digit 100) is cancelled, the unit continuous rated current will drop depending on the carrier frequency setting, and therefore caution is advised.
(For details, refer to Chapter 2 in the FRENIC-VG User Manual "Unit Type, Function Code Edition" 24A7-□-0019.)
-
Note 1
-
The specifications above are established when the function code F80 = 3 (MD specification) is applied.
If using with the MD specification, specify MD specification when placing your order.
With the type FRN□ VG1S-□ J, a DC reactor with nominal applied motor capacity is provided as standard.
-
Note 2
-
When using a DC reactor, refer to the following.
-
・ Type FRN□VG1S-□E
-
Option.
-
*1
-
When the rated output voltage is 440V
-
*2
-
When the converted inverter output frequency is less than 1Hz, the inverter may trip earlier in some ambient temperature conditions if the motor is overloaded
-
*3
-
When the power supply is 380 to 398V at 50 Hz or 380 to 430V at 60Hz, a connector inside the inverter must be reconnected accordingly.
The output of the inverter with 380V may drop depending on situations. For details, refer to Chapter 10 in the FRENIC-VG User Manual "Unit Type, Function Code Edition" 24A7-□-0019.
-
*4
-
The auxiliary power input is used as an AC fan power input when combining the unit such as high power factor PWM converter with power regenerative function.(Generally not used.)
-
*5
-
Voltage unbalance [%] = (Max. voltage [V] - Min. voltage [V]) / (Three-phase average voltage [V]) × 67
Use an AC reactor if the voltage unbalance exceeds 2%.
-
*6
-
The value is calculated on assumption that the inverter is connected with a power supply capacity of 10 times the inverter capacity and %X is 5%.
-
*7
-
The values shown apply when a DC reactor is used.
If using a generator for the power source, it may burn out with high-frequency current from the inverter. Use a generator with 3 to 4 times the specified power supply capacity.
(When DC reactor not connected: approx. 4 times specified power supply capacity, when DC reactor connected: approx. 3 times specified power supply capacity)
-
*8
-
Depending on the load condition, motor heating may increase with low carrier frequency, and therefore the MD specification should be specified when ordering the motor.
-
*9
-
If running a synchronous motor at low carrier frequency, there is a risk of demagnetization due to permanent magnet overheating as a result of output current harmonics.
The carrier frequency is low (2 to 4kHz), and therefore the motor allowable carrier frequency must always be checked. If unable to use the motor with low carrier frequency (2 to 4kHz), consider the HD specification (H80 = 0).
Three-phase 200V series
Three-phase 400V series
-
Note 1
-
The specification above are established when the function code F80 = 0 (HD specification) is applied.
-
Note 2
-
When using a DC reactor, refer to the following.
-
・ Type FRN□VG1S-□E
-
All capacities are provided as option.
-
*1
-
The rated output voltage is 220V for 200V series and 440V for 400V series.
-
*2
-
When the inverter output frequency converter value is 10Hz or less, the inverter may trip early due to overload depending on the conditions such as ambient temperature.
-
*3
-
When the inverter output frequency converter value is 5Hz or less, the inverter may trip early due to overload depending on the conditions such as ambient temperature.
-
*4
-
200V series: Make an individual order for 220 to 230V/50Hz.
400V series: The inverters with the power supply of 380 to 398V/50Hz and 380 to 430V/60Hz must be switched using a connector inside the inverter.
The output of the inverter with 380V may drop depending on situations. For details, refer to Chapter 10 in the FRENIC-VG User Manual "Unit Type, Function Code Edition" 24A7-□-0019.
-
*5
-
The auxiliary power input is used as an AC fan power input when combining the unit such as high power factor PWM converter with power regenerative function.(Generally not used.)
-
*6
-
Voltage unbalance [%] = (Max. voltage [V] - Min. voltage [V]) / (Three-phase average voltage [V]) × 67
Use an AC reactor if the voltage unbalance exceeds 2%.
-
*7
-
The value is calculated on assumption that the inverter is connected with a power supply capacity of 500kVA (or 10 times the inverter capacity if the inverter capacity exceeds 50kVA) and %X is 5%.
-
*8
-
The values shown apply when a DC reactor is used.
If using a generator for the power source, it may burn out with high-frequency current from the inverter. Use a generator with 3 to 4 times the specified power supply capacity.
(When DC reactor not connected: approx. 4 times specified power supply capacity, when DC reactor connected: approx. 3 times specified power supply capacity)
-
*9
-
The inverter may automatically reduce carrier frequency in accordance with ambient temperature or output current in order to protect itself.
If the carrier frequency auto reduction selection (H104: digit 100) is cancelled, the unit continuous rated current will drop depending on the carrier frequency setting, and therefore caution is advised.
(For details, refer to Chapter 2 in the FRENIC-VG User Manual "Unit Type, Function Code Edition" 24A7-□-0019.)
-
Note 1
-
The specifications above are established when the function code F80 = 3 (MD specification) is applied.
If using with the MD specification, specify MD specification when placing your order.
With the type FRN□ VG1S-□ J, a DC reactor with nominal applied motor capacity is provided as standard.
-
Note 2
-
When using a DC reactor, refer to the following.
-
・ Type FRN□VG1S-□E
-
Option.
-
*1
-
When the rated output voltage is 440V
-
*2
-
When the converted inverter output frequency is less than 1Hz, the inverter may trip earlier in some ambient temperature conditions if the motor is overloaded
-
*3
-
When the power supply is 380 to 398V at 50 Hz or 380 to 430V at 60Hz, a connector inside the inverter must be reconnected accordingly.
The output of the inverter with 380V may drop depending on situations. For details, refer to Chapter 10 in the FRENIC-VG User Manual "Unit Type, Function Code Edition" 24A7-□-0019.
-
*4
-
The auxiliary power input is used as an AC fan power input when combining the unit such as high power factor PWM converter with power regenerative function.(Generally not used.)
-
*5
-
Voltage unbalance [%] = (Max. voltage [V] - Min. voltage [V]) / (Three-phase average voltage [V]) × 67
Use an AC reactor if the voltage unbalance exceeds 2%.
-
*6
-
The value is calculated on assumption that the inverter is connected with a power supply capacity of 10 times the inverter capacity and %X is 5%.
-
*7
-
The values shown apply when a DC reactor is used.
If using a generator for the power source, it may burn out with high-frequency current from the inverter. Use a generator with 3 to 4 times the specified power supply capacity.
(When DC reactor not connected: approx. 4 times specified power supply capacity, when DC reactor connected: approx. 3 times specified power supply capacity)
-
*8
-
Depending on the load condition, motor heating may increase with low carrier frequency, and therefore the MD specification should be specified when ordering the motor.
-
*9
-
If running a synchronous motor at low carrier frequency, there is a risk of demagnetization due to permanent magnet overheating as a result of output current harmonics.
The carrier frequency is low (2 to 4kHz), and therefore the motor allowable carrier frequency must always be checked. If unable to use the motor with low carrier frequency (2 to 4kHz), consider the HD specification (H80 = 0).
Three-phase 200V series
Three-phase 400V series
-
Note 1
-
The specification above are established when the function code F80 = 0 (HD specification) is applied.
-
Note 2
-
When using a DC reactor, refer to the following.
-
・ Type FRN□VG1S-□C
-
All capacities are provided as option.
-
*1
-
The rated output voltage is 220V for 200V series and 440V for 400V series.
-
*2
-
When the inverter output frequency converter value is 10Hz or less, the inverter may trip early due to overload depending on the conditions such as ambient temperature.
-
*3
-
When the inverter output frequency converter value is 5Hz or less, the inverter may trip early due to overload depending on the conditions such as ambient temperature.
-
*4
-
200V series: Make an individual order for 220 to 230V/50Hz.
400V series: The inverters with the power supply of 380 to 398V/50Hz and 380 to 430V/60Hz must be switched using a connector inside the inverter.
The output of the inverter with 380V may drop depending on situations. For details, refer to Chapter 10 in the FRENIC-VG User Manual "Unit Type, Function Code Edition" 24A7-□-0019.
-
*5
-
The auxiliary power input is used as an AC fan power input when combining the unit such as high power factor PWM converter with power regenerative function.(Generally not used.)
-
*6
-
Voltage unbalance [%] = (Max. voltage [V] - Min. voltage [V]) / (Three-phase average voltage [V]) × 67
Use an AC reactor if the voltage unbalance exceeds 2%.
-
*7
-
The value is calculated on assumption that the inverter is connected with a power supply capacity of 500kVA (or 10 times the inverter capacity if the inverter capacity exceeds 50kVA) and %X is 5%.
-
*8
-
The values shown apply when a DC reactor is used.
If using a generator for the power source, it may burn out with high-frequency current from the inverter. Use a generator with 3 to 4 times the specified power supply capacity.
(When DC reactor not connected: approx. 4 times specified power supply capacity, when DC reactor connected: approx. 3 times specified power supply capacity)
-
*9
-
The inverter may automatically reduce carrier frequency in accordance with ambient temperature or output current in order to protect itself.
If the carrier frequency auto reduction selection (H104: digit 100) is cancelled, the unit continuous rated current will drop depending on the carrier frequency setting, and therefore caution is advised.
(For details, refer to Chapter 2 in the FRENIC-VG User Manual "Unit Type, Function Code Edition" 24A7-□-0019.)
-
Note 1
-
The specifications above are established when the function code F80 = 3 (MD specification) is applied.
If using with the MD specification, specify MD specification when placing your order.
With the type FRN□ VG1S-□ J, a DC reactor with nominal applied motor capacity is provided as standard.
-
Note 2
-
When using a DC reactor, refer to the following.
-
・ Type FRN□VG1S-□C
-
Option.
-
*1
-
When the rated output voltage is 440V
-
*2
-
When the converted inverter output frequency is less than 1Hz, the inverter may trip earlier in some ambient temperature conditions if the motor is overloaded
-
*3
-
When the power supply is 380 to 398V at 50 Hz or 380 to 430V at 60Hz, a connector inside the inverter must be reconnected accordingly.
The output of the inverter with 380V may drop depending on situations. For details, refer to Chapter 10 in the FRENIC-VG User Manual "Unit Type, Function Code Edition" 24A7-□-0019.
-
*4
-
The auxiliary power input is used as an AC fan power input when combining the unit such as high power factor PWM converter with power regenerative function.(Generally not used.)
-
*5
-
Voltage unbalance [%] = (Max. voltage [V] - Min. voltage [V]) / (Three-phase average voltage [V]) × 67
Use an AC reactor if the voltage unbalance exceeds 2%.
-
*6
-
The value is calculated on assumption that the inverter is connected with a power supply capacity of 10 times the inverter capacity and %X is 5%.
-
*7
-
The values shown apply when a DC reactor is used.
If using a generator for the power source, it may burn out with high-frequency current from the inverter. Use a generator with 3 to 4 times the specified power supply capacity.
(When DC reactor not connected: approx. 4 times specified power supply capacity, when DC reactor connected: approx. 3 times specified power supply capacity)
-
*8
-
Depending on the load condition, motor heating may increase with low carrier frequency, and therefore the MD specification should be specified when ordering the motor.
-
*9
-
If running a synchronous motor at low carrier frequency, there is a risk of demagnetization due to permanent magnet overheating as a result of output current harmonics.
The carrier frequency is low (2 to 4kHz), and therefore the motor allowable carrier frequency must always be checked. If unable to use the motor with low carrier frequency (2 to 4kHz), consider the HD specification (H80 = 0).
Three-phase 200V series
Three-phase 400V series
-
Note 1
-
The specification above are established when the function code F80 = 0 (HD specification) is applied.
-
Note 2
-
When using a DC reactor, refer to the following.
-
・ Type FRN□VG1S-□E
-
All capacities are provided as option.
-
*1
-
The rated output voltage is 220V for 200V series and 440V for 400V series.
-
*2
-
When the inverter output frequency converter value is 10Hz or less, the inverter may trip early due to overload depending on the conditions such as ambient temperature.
-
*3
-
When the inverter output frequency converter value is 5Hz or less, the inverter may trip early due to overload depending on the conditions such as ambient temperature.
-
*4
-
200V series: Make an individual order for 220 to 230V/50Hz.
400V series: The inverters with the power supply of 380 to 398V/50Hz and 380 to 430V/60Hz must be switched using a connector inside the inverter.
The output of the inverter with 380V may drop depending on situations. For details, refer to Chapter 10 in the FRENIC-VG User Manual "Unit Type, Function Code Edition" 24A7-□-0019.
-
*5
-
The auxiliary power input is used as an AC fan power input when combining the unit such as high power factor PWM converter with power regenerative function.(Generally not used.)
-
*6
-
Voltage unbalance [%] = (Max. voltage [V] - Min. voltage [V]) / (Three-phase average voltage [V]) × 67
Use an AC reactor if the voltage unbalance exceeds 2%.
-
*7
-
The value is calculated on assumption that the inverter is connected with a power supply capacity of 500kVA (or 10 times the inverter capacity if the inverter capacity exceeds 50kVA) and %X is 5%.
-
*8
-
The values shown apply when a DC reactor is used.
If using a generator for the power source, it may burn out with high-frequency current from the inverter. Use a generator with 3 to 4 times the specified power supply capacity.
(When DC reactor not connected: approx. 4 times specified power supply capacity, when DC reactor connected: approx. 3 times specified power supply capacity)
-
*9
-
The inverter may automatically reduce carrier frequency in accordance with ambient temperature or output current in order to protect itself.
If the carrier frequency auto reduction selection (H104: digit 100) is cancelled, the unit continuous rated current will drop depending on the carrier frequency setting, and therefore caution is advised.
(For details, refer to Chapter 2 in the FRENIC-VG User Manual "Unit Type, Function Code Edition" 24A7-□-0019.)
-
Note 1
-
The specifications above are established when the function code F80 = 3 (MD specification) is applied.
If using with the MD specification, specify MD specification when placing your order.
With the type FRN□ VG1S-□ J, a DC reactor with nominal applied motor capacity is provided as standard.
-
Note 2
-
When using a DC reactor, refer to the following.
-
・ Type FRN□VG1S-□E
-
Option.
-
*1
-
When the rated output voltage is 440V
-
*2
-
When the converted inverter output frequency is less than 1Hz, the inverter may trip earlier in some ambient temperature conditions if the motor is overloaded
-
*3
-
When the power supply is 380 to 398V at 50 Hz or 380 to 430V at 60Hz, a connector inside the inverter must be reconnected accordingly.
The output of the inverter with 380V may drop depending on situations. For details, refer to Chapter 10 in the FRENIC-VG User Manual "Unit Type, Function Code Edition" 24A7-□-0019.
-
*4
-
The auxiliary power input is used as an AC fan power input when combining the unit such as high power factor PWM converter with power regenerative function.(Generally not used.)
-
*5
-
Voltage unbalance [%] = (Max. voltage [V] - Min. voltage [V]) / (Three-phase average voltage [V]) × 67
Use an AC reactor if the voltage unbalance exceeds 2%.
-
*6
-
The value is calculated on assumption that the inverter is connected with a power supply capacity of 10 times the inverter capacity and %X is 5%.
-
*7
-
The values shown apply when a DC reactor is used.
If using a generator for the power source, it may burn out with high-frequency current from the inverter. Use a generator with 3 to 4 times the specified power supply capacity.
(When DC reactor not connected: approx. 4 times specified power supply capacity, when DC reactor connected: approx. 3 times specified power supply capacity)
-
*8
-
Depending on the load condition, motor heating may increase with low carrier frequency, and therefore the MD specification should be specified when ordering the motor.
-
*9
-
If running a synchronous motor at low carrier frequency, there is a risk of demagnetization due to permanent magnet overheating as a result of output current harmonics.
The carrier frequency is low (2 to 4kHz), and therefore the motor allowable carrier frequency must always be checked. If unable to use the motor with low carrier frequency (2 to 4kHz), consider the HD specification (H80 = 0).
Three-phase 200V series
Three-phase 400V series
-
Note 1
-
The specification above are established when the function code F80 = 0 (HD specification) is applied.
-
Note 2
-
When using a DC reactor, refer to the following.
-
・ Type FRN□VG1S-□J
-
55kW or below: provided as option, 75kW or above: provided as standard.
-
*1
-
The rated output voltage is 220V for 200V series and 440V for 400V series.
-
*2
-
When the inverter output frequency converter value is 10Hz or less, the inverter may trip early due to overload depending on the conditions such as ambient temperature.
-
*3
-
When the inverter output frequency converter value is 5Hz or less, the inverter may trip early due to overload depending on the conditions such as ambient temperature.
-
*4
-
200V series: Make an individual order for 220 to 230V/50Hz.
400V series: The inverters with the power supply of 380 to 398V/50Hz and 380 to 430V/60Hz must be switched using a connector inside the inverter.
The output of the inverter with 380V may drop depending on situations. For details, refer to Chapter 10 in the FRENIC-VG User Manual "Unit Type, Function Code Edition" 24A7-□-0019.
-
*5
-
The auxiliary power input is used as an AC fan power input when combining the unit such as high power factor PWM converter with power regenerative function.(Generally not used.)
-
*6
-
Voltage unbalance [%] = (Max. voltage [V] - Min. voltage [V]) / (Three-phase average voltage [V]) × 67
Use an AC reactor if the voltage unbalance exceeds 2%.
-
*7
-
The value is calculated on assumption that the inverter is connected with a power supply capacity of 500kVA (or 10 times the inverter capacity if the inverter capacity exceeds 50kVA) and %X is 5%.
-
*8
-
The values shown apply when a DC reactor is used.
If using a generator for the power source, it may burn out with high-frequency current from the inverter. Use a generator with 3 to 4 times the specified power supply capacity.
(When DC reactor not connected: approx. 4 times specified power supply capacity, when DC reactor connected: approx. 3 times specified power supply capacity)
-
*9
-
The inverter may automatically reduce carrier frequency in accordance with ambient temperature or output current in order to protect itself.
If the carrier frequency auto reduction selection (H104: digit 100) is cancelled, the unit continuous rated current will drop depending on the carrier frequency setting, and therefore caution is advised.
(For details, refer to Chapter 2 in the FRENIC-VG User Manual "Unit Type, Function Code Edition" 24A7-□-0019.)
-
Note 1
-
The specifications above are established when the function code F80 = 3 (MD specification) is applied.
If using with the MD specification, specify MD specification when placing your order.
With the type FRN□ VG1S-□ J, a DC reactor with nominal applied motor capacity is provided as standard.
-
Note 2
-
When using a DC reactor, refer to the following.
-
・ Type FRN□ VG1S-□ J
-
Provided as standard. (Specify MD specification when placing your order.)
-
*1
-
When the rated output voltage is 440V
-
*2
-
When the converted inverter output frequency is less than 1Hz, the inverter may trip earlier in some ambient temperature conditions if the motor is overloaded
-
*3
-
When the power supply is 380 to 398V at 50 Hz or 380 to 430V at 60Hz, a connector inside the inverter must be reconnected accordingly.
The output of the inverter with 380V may drop depending on situations. For details, refer to Chapter 10 in the FRENIC-VG User Manual "Unit Type, Function Code Edition" 24A7-□-0019.
-
*4
-
The auxiliary power input is used as an AC fan power input when combining the unit such as high power factor PWM converter with power regenerative function.(Generally not used.)
-
*5
-
Voltage unbalance [%] = (Max. voltage [V] - Min. voltage [V]) / (Three-phase average voltage [V]) × 67
Use an AC reactor if the voltage unbalance exceeds 2%.
-
*6
-
The value is calculated on assumption that the inverter is connected with a power supply capacity of 10 times the inverter capacity and %X is 5%.
-
*7
-
The values shown apply when a DC reactor is used.
If using a generator for the power source, it may burn out with high-frequency current from the inverter. Use a generator with 3 to 4 times the specified power supply capacity.
(When DC reactor not connected: approx. 4 times specified power supply capacity, when DC reactor connected: approx. 3 times specified power supply capacity)
-
*8
-
Depending on the load condition, motor heating may increase with low carrier frequency, and therefore the MD specification should be specified when ordering the motor.
-
*9
-
If running a synchronous motor at low carrier frequency, there is a risk of demagnetization due to permanent magnet overheating as a result of output current harmonics.
The carrier frequency is low (2 to 4kHz), and therefore the motor allowable carrier frequency must always be checked. If unable to use the motor with low carrier frequency (2 to 4kHz), consider the HD specification (H80 = 0).
Three-phase 200V series
Three-phase 400V series
-
Note 1
-
The specification above are established when the function code F80 = 0 (HD specification) is applied.
-
Note 2
-
When using a DC reactor, refer to the following.
-
・ Type FRN□VG1S-□J
-
55kW or below: provided as option, 75kW or above: provided as standard.
-
*1
-
The rated output voltage is 220V for 200V series and 440V for 400V series.
-
*2
-
When the inverter output frequency converter value is 10Hz or less, the inverter may trip early due to overload depending on the conditions such as ambient temperature.
-
*3
-
When the inverter output frequency converter value is 5Hz or less, the inverter may trip early due to overload depending on the conditions such as ambient temperature.
-
*4
-
200V series: Make an individual order for 220 to 230V/50Hz.
400V series: The inverters with the power supply of 380 to 398V/50Hz and 380 to 430V/60Hz must be switched using a connector inside the inverter.
The output of the inverter with 380V may drop depending on situations. For details, refer to Chapter 10 in the FRENIC-VG User Manual "Unit Type, Function Code Edition" 24A7-□-0019.
-
*5
-
The auxiliary power input is used as an AC fan power input when combining the unit such as high power factor PWM converter with power regenerative function.(Generally not used.)
-
*6
-
Voltage unbalance [%] = (Max. voltage [V] - Min. voltage [V]) / (Three-phase average voltage [V]) × 67
Use an AC reactor if the voltage unbalance exceeds 2%.
-
*7
-
The value is calculated on assumption that the inverter is connected with a power supply capacity of 500kVA (or 10 times the inverter capacity if the inverter capacity exceeds 50kVA) and %X is 5%.
-
*8
-
The values shown apply when a DC reactor is used.
If using a generator for the power source, it may burn out with high-frequency current from the inverter. Use a generator with 3 to 4 times the specified power supply capacity.
(When DC reactor not connected: approx. 4 times specified power supply capacity, when DC reactor connected: approx. 3 times specified power supply capacity)
-
*9
-
The inverter may automatically reduce carrier frequency in accordance with ambient temperature or output current in order to protect itself.
If the carrier frequency auto reduction selection (H104: digit 100) is cancelled, the unit continuous rated current will drop depending on the carrier frequency setting, and therefore caution is advised.
(For details, refer to Chapter 2 in the FRENIC-VG User Manual "Unit Type, Function Code Edition" 24A7-□-0019.)
-
Note 1
-
The specifications above are established when the function code F80 = 3 (MD specification) is applied.
If using with the MD specification, specify MD specification when placing your order.
With the type FRN□ VG1S-□ J, a DC reactor with nominal applied motor capacity is provided as standard.
-
Note 2
-
When using a DC reactor, refer to the following.
-
・ Type FRN□ VG1S-□ J
-
Provided as standard. (Specify MD specification when placing your order.)
-
*1
-
When the rated output voltage is 440V
-
*2
-
When the converted inverter output frequency is less than 1Hz, the inverter may trip earlier in some ambient temperature conditions if the motor is overloaded
-
*3
-
When the power supply is 380 to 398V at 50 Hz or 380 to 430V at 60Hz, a connector inside the inverter must be reconnected accordingly.
The output of the inverter with 380V may drop depending on situations. For details, refer to Chapter 10 in the FRENIC-VG User Manual "Unit Type, Function Code Edition" 24A7-□-0019.
-
*4
-
The auxiliary power input is used as an AC fan power input when combining the unit such as high power factor PWM converter with power regenerative function.(Generally not used.)
-
*5
-
Voltage unbalance [%] = (Max. voltage [V] - Min. voltage [V]) / (Three-phase average voltage [V]) × 67
Use an AC reactor if the voltage unbalance exceeds 2%.
-
*6
-
The value is calculated on assumption that the inverter is connected with a power supply capacity of 10 times the inverter capacity and %X is 5%.
-
*7
-
The values shown apply when a DC reactor is used.
If using a generator for the power source, it may burn out with high-frequency current from the inverter. Use a generator with 3 to 4 times the specified power supply capacity.
(When DC reactor not connected: approx. 4 times specified power supply capacity, when DC reactor connected: approx. 3 times specified power supply capacity)
-
*8
-
Depending on the load condition, motor heating may increase with low carrier frequency, and therefore the MD specification should be specified when ordering the motor.
-
*9
-
If running a synchronous motor at low carrier frequency, there is a risk of demagnetization due to permanent magnet overheating as a result of output current harmonics.
The carrier frequency is low (2 to 4kHz), and therefore the motor allowable carrier frequency must always be checked. If unable to use the motor with low carrier frequency (2 to 4kHz), consider the HD specification (H80 = 0).