3G3EV-A2015M [OMRON]
Compact Low-noise Inverter;
| 型号: | 3G3EV-A2015M |
| 厂家: | 
OMRON ELECTRONICS LLC |
| 描述: | Compact Low-noise Inverter |
| 文件: | 总89页 (文件大小:692K) |
| 中文: | 中文翻译 | 下载: | 下载PDF数据表文档文件 |
USER’S MANUAL
SYSDRIVE 3G3EVSERIES
(Standard Models)
Compact Low-noise Inverter
Thank you for choosing this SYSDRIVE 3G3EV-series product. Proper use
and handling of the product will ensure proper product performance, will
length product life, and may prevent possible accidents.
Please read this manual thoroughly and handle and operate the product
with care.
NOTICE
1. This manual describes the functions of the product and relations with other
products. You should assume that anything not described in this manual is
not possible.
2. Although care has been given in documenting the product, please contact
your OMRON representative if you have any suggestions on improving this
manual.
3. The product contains potentially dangerous parts under the cover. Do not
attempt to open the cover under any circumstances. Doing so may result in
injury or death and may damage the product. Never attempt to repair or dis-
assemble the product.
4. We recommend that you add the following precautions to any instruction
manuals you prepare for the system into which the product is being installed.
S Precautions on the dangers of high-voltage equipment.
S Precautions on touching the terminals of the product even after power has
been turned off. (These terminals are live even with the power turned off.)
5. Specifications and functions may be changed without notice in order to im-
prove product performance.
Items to Check Before Unpacking
Check the following items before removing the product from the package:
S Has the correct product been delivered (i.e., the correct model number and
specifications)?
S Has the product been damaged in shipping?
S Are any screws or bolts loose?
Table of Contents
Chapter 1. Getting Started . . . . . . . . . . . . . . . . . . . . . . . . . . 1-1
1-1 Items to be Checked when Unpacking . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1-2
1-2 Precautions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1-3
Chapter 2. Overview . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2-1
2-1 Features . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2-2
2-2 Component Names . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2-4
Chapter 3. Design . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-1
3-1 Installation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-2
3-1-1 Outside/Mounting Dimensions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-2
3-1-2 Installation Conditions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-5
3-2 Wiring . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-7
3-2-1 Terminal Blocks . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-7
3-2-2 Wiring Around the Main Circuit . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-11
3-2-3 Wiring Control Circuit Terminals . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-18
Chapter 4. Preparing for Operation . . . . . . . . . . . . . . . . . . 4-1
4-1 Preparation Procedure . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-2
4-2 Using the Digital Operator . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-3
4-2-1 Name and Function of Each Component . . . . . . . . . . . . . . . . . . . . . . . 4-3
4-2-2 Outline of Operation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-5
4-2-3 Setting Constants . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-8
4-3 Test Run . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-25
4-3-1 Checking Wiring . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-25
4-3-2 Turning Power On and Checking Indicator Display . . . . . . . . . . . . . . 4-25
4-3-3 Initializing Constants . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-25
4-3-4 Setting a V/f Pattern . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-25
4-3-5 Setting Rated Motor Amperage . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-26
4-3-6 Setting the Reference Frequency . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-26
4-3-7 Operating the Inverter with the Digital Operator . . . . . . . . . . . . . . . . 4-26
4-3-8 Checking Output Frequency and Amperage . . . . . . . . . . . . . . . . . . . . 4-26
4-3-9 Checking Operation during Reverse Rotation . . . . . . . . . . . . . . . . . . . 4-26
4-3-10 Checking Operation with Mechanical System Connected . . . . . . . . . . 4-26
4-3-11 Checking Operation Performed by Controller . . . . . . . . . . . . . . . . . . . 4-26
i
Table of Contents
Chapter 5. Operation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5-1
5-1 Protective and Diagnostic Functions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5-2
5-2 Troubleshooting . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5-8
5-2-1 Constants Fail to Set . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5-8
5-2-2 Motor Fails to Operate . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5-8
5-2-3 Motor Rotates in the Wrong Direction . . . . . . . . . . . . . . . . . . . . . . . . 5-9
5-2-4 Motor Deceleration is Too Slow . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5-10
5-2-5 Vertical-axis Load Drops when Brakes are Applied . . . . . . . . . . . . . . 5-10
5-2-6 Motor Burns . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5-11
5-2-7 Controller Receives Noise when Inverter is Started . . . . . . . . . . . . . . 5-11
5-2-8 AM Radio Receives Noise when Inverter is Started . . . . . . . . . . . . . . 5-11
5-2-9 Ground Fault Interrupter is Actuated when Inverter is Started . . . . . . 5-12
5-2-10 Mechanical System Makes Noise . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5-12
5-2-11 Motor Does Not Operate with EF Warning . . . . . . . . . . . . . . . . . . . . . 5-12
5-3 Maintenance and Inspection . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5-13
Chapter 6. Specifications . . . . . . . . . . . . . . . . . . . . . . . . . . . 6-1
6-1 Specifications of Main Unit . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6-2
Chapter 7. Appendix A . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7-1
7-1 Notes on Using Inverter for Motor . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7-2
7-2 Frequency Reference by Amperage Input . . . . . . . . . . . . . . . . . . . . . . . . . . . 7-4
7-3 List of Product Models . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7-7
ii
1
Chapter 1
Getting Started
1-1 Items to be Checked when Unpacking
1-2 Precautions
Getting Started
Chapter 1
1-1 Items to be Checked when Unpacking
H Checking the Product
On delivery, always check that the delivered product is the SYSDRIVE 3G3EV Inverter
that you ordered.
Should you find any problems with the product, immediately contact your nearest local
sales representative.
D Checking the Nameplate
Inverter model
Input specifications
Output specifications
D Checking the Model
3G3EV-A2002M-E
Special Specification
Specifications
Maximum applicable motor capacity
Voltage class
Installation type
Series name: 3G3EV Series
Specifications
Maximum Applicable Motor
Capacity
Blank Standard model
001
002
004
007
015
0.1 kW
M
R
Multi-function model
SYSMAC BUS model
0.2 (0.37) kW
0.4 (0.55) kW
0.75 (1.1) kW
1.5 kW
Note The figures in parentheses indi-
cate capacities for 400-VAC class
models.
1-2
Getting Started
Chapter 1
Voltage Class
Special Specification
2
Three-phase 200-VAC input
-E
English Models
B
Single/Three-phase 200-VAC
input
-CUE UL/CUL and EC Directives
Models
Blank Japanese Models
Installation Type/Option
A
P
Panel mounting
Option
D Checking for Damage
Check the overall appearance and check for damage or scratches resulting from trans-
portation.
H Checking Accessories
Note that this manual is the only accessory provided with the 3G3EV (Standard Model).
Set screws and other necessary parts must be prepared by customers.
1-2 Precautions
To ensure safe operation of the 3G3EV, note the following items:
H Always Hold the Heat Sink During Removal.
When moving the 3G3EV, always hold the heat sink (aluminum portion on the rear of the
Unit).
Heat sink
H Watch Out for Residual Voltage On Charged Portions
After the power is turned off, residual voltage remains in the capacitor inside the
Inverter. Therefore, touching terminals immediately after turning the power off may
cause an electrical shock.
1-3
Getting Started
Chapter 1
If an inspection or some other task is to be performed, always wait at least one minute
from the time all indicators on the front panel go off.
(Note that this warning is applicable whenever you perform any task after turning the
main circuit off.)
H Do Not Remove the Digital Operator When the Main Circuit is
Still On.
Always turn the main circuit off before removing the digital operator.
Removing the digital operator with the main circuit ON may cause an electrical shock
and damage the equipment.
H Do Not Modify Wiring or Check Signals When the Main Circuit
is On.
Always turn the main circuit off before modifying wiring or checking signals.
Touching terminals while the main circuit is on may cause an electrical shock and dam-
age the equipment.
H Do Not Conduct a Dielectric Strength Test.
Because the 3G3EV Inverter is an electronic control unit using semiconductor, never
conduct a dielectric strength test or an insulation resistance test for the control circuit.
H Modify Constant Settings Correctly.
Always modify the constant settings according to the procedures described in this
manual.
1-4
2
Chapter 2
Overview
2-1 Features
2-2 Component Names
Overview
Chapter 2
2-1 Features
H Easy to Use
D Basic Constants Displayed On Indicators
Constants for basic operations such as frequency setting and acceleration/deceleration
time setting are displayed on dedicated indicators. Therefore, constant numbers can be
confirmed easily.
D Minimum Constant Setting Items
Constant setting items have been minimized to enable even first-time users to set
constants easily.
H Easy to Install
D Very Small and Lightweight
The 3G3EV Inverter is approximately half the size of our Low-noise General-purpose
Inverters in terms of volume and weight percentage. This improves space efficiency and
operating efficiency (including easier removal).
D Optional DIN Track
An optional DIN track is available. This DIN track enables the user to mount the 3G3EV
Inverter on the DIN track with a one-touch operation.
2-2
Overview
Chapter 2
H Easy to Wire
D Easy Wiring without Having to Open the Front Cover
This Inverter can be wired just by opening the terminal block cover.
D Separate Input and Output Terminal Blocks
Power input terminals are located in the upper section, while motor output terminals are
in the lower section. In this way, the input and output terminal blocks are separated ac-
cording to the contactors, so incorrect wiring can be prevented.
D Soldering No Longer Necessary
No connector means no soldering.
H Easy to Operate
D Switching the Operation Mode with a One-touch Operation
For example, after a test run is performed using the Digital Operator, it can be easily
switched to a production run using control terminals with a one-touch operation.
D Checking a Test Run with Various Monitors
Output frequency, output current, and the direction of motor rotation appear in the dis-
play section of the Digital Operator, so the mechanical system can be easily monitored
during a test run.
H Low Noise
An insulated gate bipolar transistor (IGBT) power element has been adopted to elimi-
nate metallic noise.
H High-torque Operation Even in Low Speed Range
A torque rate of 150% can be achieved even in a low speed range where output frequen-
cy is only 3 Hz. Thus, acceleration time can be reduced.
H Various Input Power Supplies
A 400-VAC-class Inverter has been newly added to the 3G3EV Series to cope with vari-
ous power supplies.
• Three-phase 200-VAC input:
• Single/Three-phase 200-VAC input: 0.1 to 1.5 kW
• Three-phase 400-VAC input: 0.2 to 1.5 kW
0.1 to 1.5 kW
2-3
Overview
Chapter 2
2-2 Component Names
H Main Unit
Main Circuit Terminals (Input)
Power input Braking resistor
terminals
connection terminals
L1 N/L2 L3
Run indicator
Digital Operator
Alarm indicator
Control circuit terminals
(output)
Control circuit
terminals (input)
MA MB MC
SF SR S1 SC FS FR FC
Ground terminal
Motor output
terminals
Main Circuit Terminals (Output)
Note This diagram shows the Inverter with all terminal block covers removed.
2-4
Overview
Chapter 2
H Digital Operator
Data display section
Monitor item indicators
In-service item indicators (green indicators)
These items can be monitored or set even
during operation.
Display
section
Stopped item indicators (red indicators)
These items can be set only when the
Inverter is stopped.
Operation
keys
Constant item indicators
Enter Key
Mode Key
Increment Key
RUN Key
Decrement Key
STOP/RESET Key
2-5
3
Chapter 3
Design
3-1 Installation
3-2 Wiring
Design
Chapter 3
3-1 Installation
3-1-1 Outside/Mounting Dimensions
Note All dimensions are in millimeters.
H 3G3EV-A2001(-j) to 3G3EV-A2004(-j) (0.1 to 0.4 kW):
Three-phase 200-VAC Input
H 3G3EV-AB001(-j) to 3G3EV-AB002(-j) (0.1 to 0.2 kW):
Single/Three-phase 200-VAC Input
4.5 dia.
Note 1. For the 3G3EV-A2001(-j), 3G3EV-A2002(-j), and 3G3EV-AB001(-j), a U-
shaped notch (4.5 mm wide) is provided instead of the upper mounting hole (4.5
mm in diameter).
Note 2. Install the Inverter with two M4 bolts.
3-2
Design
Chapter 3
D Three-phase 200-VAC Input Model
3G3EV
model
Output
0.1 kW
0.2 kW
0.4 kW
W
H
D
W1
56
H1
118
T
Weight
(kg)
68
128
75
88
3
3
5
Approx.
0.5
Approx.
0.6
Approx.
0.9
A2001(-j)
A2002(-j)
A2004(-j)
110
D Single/Three-phase 200-VAC Input Model
3G3EV
model
Output
0.1 kW
0.2 kW
W
H
D
W1
H1
118
T
Weight
(kg)
68
128
56
75
108
3
3
Approx.
0.5
Approx.
0.6
AB001(-j)
AB002(-j)
3-3
Design
Chapter 3
H 3G3EV-A2007(-j) to 3G3EV-A2015(-j) (0.75 to 1.5 kW):
Three-phase 200-VAC Input
3G3EV-AB004(-j) to 3G3EV-AB015(-j) (0.4 to 1.5 kW):
Single/Three-phase 200-VAC Input
3G3EV-A4002(-j) to 3G3EV-A4015(-j) (0.2 to 1.5 kW):
Three-phase 400-VAC Input
Two, 4.5 dia.
Note Install the Inverter with four M4 bolts.
D Three-phase 200-VAC Input Model
3G3EV
model
Output
W
H
D
W1
H1
118
Weight (kg)
108
128
96
0.75 kW
1.5 kW
130
155
Approx. 1.3
Approx. 1.5
A2007(-j)
A2015(-j)
D Single/Three-phase 200-VAC Input Model
3G3EV
model
Output
W
H
D
W1
H1
118
Weight
(kg)
108
130
128
130
170
96
118
0.4 kW
0.75 kW
1.5 kW
Approx. 1.3
Approx. 1.3
Approx. 2.0
AB004(-j)
AB007(-j)
AB015(-j)
3-4
Design
Chapter 3
D Three-phase 400-VAC Input Model
3G3EV
model
Output
W
H
D
W1
H1
118
Weight
(kg)
108
128
96
0.2 kW
0.4 kW
0.75 kW
1.5 kW
92
Approx. 1.0
Approx. 1.0
Approx. 1.5
Approx. 2.0
A4002(-j)
A4004(-j)
A4007(-j)
A4015(-j)
110
140
170
130
118
3-1-2 Installation Conditions
H Installation Site
• Install the Inverter under the following conditions:
Ambient temperature for operation: –10°C to 50°C
Humidity: 90% RH or less (non-condensing)
• Install the Inverter in a clean location free from oil mist and dust. Alternatively, install it
in a totally enclosed panel that is completely shielded from suspended dust.
• When installing or operating the Inverter, always take special care so that metal pow-
der, oil, water, or other foreign matter do not get in the Inverter.
• Do not install the Inverter on inflammables such as wood.
H Direction of Installation
• Install the Inverter on a vertical surface so that the characters on the nameplate are
oriented upward.
H Installation Space
• When installing the Inverter, always provide the following installation space to allow
normal heat dissipation from the Inverter:
100 mm min.
100 mm min.
W= 30 mm min.
Air
Side
Air
3-5
Design
Chapter 3
H Ambient Temperature Control
• To enhance operation reliability, the Inverter should be installed in an environment free
from extreme temperature rises.
• If the Inverter is installed in an enclosed environment such as a box, use a cooling fan
or air conditioner to maintain the internal air temperature below 50°C.
• The surface temperature of the Inverter may reach 30°C higher than the ambient tem-
perature. Therefore, keep all thermally susceptible devices and wires away from the
Inverter.
H Protecting the Inverter from Foreign Matter during Installation
• Place a cover over the Inverter to shield it from metal powder produced by drilling dur-
ing installation.
(Upon completion of installation, always remove the cover from the Inverter. Other-
wise, ventilation will be affected, causing the invert to overheat.)
3-6
Design
Chapter 3
3-2 Wiring
3-2-1 Terminal Blocks
H Name of Each Terminal Block
Main Circuit Terminals (Input)
Power input Braking resistor
terminals
connection terminals
Control circuit
terminals (output)
Control circuit
terminals (input)
MA MB MC
SF SR S1 SC FS FR FC
Ground
terminal
Main circuit terminals
(output)
Motor Output Terminals (Output)
Note This diagram shows an Inverter with all terminal block covers removed.
3-7
Design
Chapter 3
H Main Circuit Terminals
D Input Terminals (Top Section)
Terminal
symbol
Name and description
Power input terminals
R (L1)
A2j: Three-phase 200 to 230 VAC, 50/60 Hz
ABj: Single-phase 200 to 240 VAC, 50/60 Hz
Three-phase 200 to 230 VAC, 50/60 Hz
S (L2/N)
T (L3)
A4j: Three-phase 380 to 460 VAC, 50/60 Hz
Note: Single-phase power must be input between terminals R to S.
Braking resistor connection terminals (see note)
B1
B2
Terminals for connecting an optional braking resistor
Note Before shipping, a resin plate is attached to each braking resistor connection ter-
minal to prevent incorrect wiring.
When connecting a braking resistor, always remove the resin plates with a pair of
long-nose pliers.
D Output Terminals (Bottom Section)
Terminal
symbol
Name and description
U
V
W
Motor output terminals
Three-phase power output terminals for operating the motor. (Never connect
an AC power supply to these terminals.)
A2j, ABj: Three-phase 200 to 230 VAC
A4j:
Three-phase 380 to 460 VAC
Note: Depending on input voltage
Ground terminal
Always use a ground terminal with one of the following ground resistances:
100 Ω or less for 200-VAC class
10 Ω or less for 400-VAC class.
(Connect also to the power supply neutral to conform to the EC Directives.)
Be sure to connect a grounding line to the FG terminal and also connect
directly to the FG terminal of the motor.
Terminal block screw (M3.5)
Crimp
terminal
6.2 mm max.
3-8
Design
Chapter 3
H Control Circuit Terminals
D Input Terminals (On Right-hand Side)
No external power supply is required because a built-in power supply is provided.
Terminal
symbol
Name and description
Interface
SF
Forward/Stop
When the terminal is ON, the motor rotates in
the forward direction. When the terminal is OFF,
the motor stops.
SR
Reverse/Stop
24 VDC, 8 mA
When the terminal is ON, the motor reverses.
When the terminal is OFF, the motor stops.
(See note 3)
S1
SC
Multi-function input (see note 1)
Sequence input common
Input terminal common to SF, SR, and S1
Frequency reference power supply
FS
Output voltage: 12 VDC
Permissible amperage: 20 mA
FR
FC
Frequency reference input (see note 2)
0 to 10 VDC is input.
Input impedance
Frequency reference common
Note 1. Constant No. 06 (n06) is used to set this function. This constant is factory-set to
“fault reset.”
Note 2. FR can be switched to an amperage input terminal (4 to 20 mA) by setting the
internal DIP switch and constant No. 02 (operation mode selection). For details,
refer to 7-2 Frequency Reference by Amperage Input.
Note 3. The circuit for a 400-VAC-class Inverter is as shown below.
SW2
24 V
SF
GND
SR
S1 to S3
SC
3.3 K
360
0.1µ
GND
3-9
Design
Chapter 3
D Output Terminals (On Left-hand Side)
Terminal
symbol
Name and description
Interface
MA
MB
MC
Multi-function contact output (contact a)
(see note)
Multi-function contact output (contact b)
(see note)
30 VDC
250 VAC
Multi-function contact output (common)
Note Constant No. 09 (n09) is used to set the function. This constant is factory set to
“operation in progress.”
H Standard Connection Diagram
Braking resistor (option)
Power supply:
Three-phase, 200 to 230 VAC,
50/60 Hz
Three-phase, 380 to 460 VAC,
50/60 Hz
L1
N/L2
L3
Molded-case circuit
breaker (MCCB)
Forward/Stop
Reverse/Stop
Multi-function contact output
(Contact a)
Multi-function input
(Contact b)
Sequence input common
Common
Frequency
reference
rheostat
(2 kΩ,
1/4 W min.)
3-10
Design
Chapter 3
Note 1. If a 3G3EV-ABjjj is used in single-phase input mode, single-phase 200 to
240 VAC power with a frequency of 50/60 Hz must be input between terminals
R and S.
Note 2. For the 3-wire sequence, refer to the wiring on page 4-12.
Note 3. The input sequence power is built in.
3-2-2 Wiring Around the Main Circuit
System reliability and noise resistance are affected by the wiring method
used. Therefore, always follow the instructions given below when connect-
ing the Inverter to peripheral devices and other parts.
H Wire Size and Molded-Case Circuit Breaker to be Used
For the main circuit and ground, always use 600-V polyvinyl chloride (PVC) cables.
If the cable is long and may cause voltage drops, increase the wire size according to the
cable length.
Model
Terminal
symbol
Terminal
screw
Wire size
(mm2)
Molded-case
circuit breaker
capacity (A)
M3.5
0.75 to 2
R S T B1 B2
10
5
3G3EV-A2001(-j)
3G3EV-AB001(-j)
3G3EV-A2002(-j)
3G3EV-AB002(-j)
3G3EV-A4002(-j)
3G3EV-A2004(-j)
3G3EV-AB004(-j)
3G3EV-A4004(-j)
3G3EV-A2007(-j)
3G3EV-AB007(-j)
3G3EV-A4007(-j)
3G3EV-A2015(-j)
3G3EV-AB015(-j)
3G3EV-A4015(-j)
U V W
M3.5
M3.5
M3.5
M3.5
0.75 to 2
0.75 to 2
0.75 to 2
5
R S T B1 B2
U V W
5
R S T B1 B2
U V W
R S T B1 B2
U V W
10
20
5
R S T B1 B2
U V W
0.75 to 2
1.25 to 2
0.75 to 2
10
20
10
Note Tighten the M3.5 terminal screw to the torque of 0.8 N S m.
3-11
Design
Chapter 3
Determining the Wire Size
Determine the wire size for the main circuit so that line voltage drop is within 2% of the
rated voltage.
Line voltage drop VD is calculated as follows:
VD (V) = p3 x wire resistance (Ω/km) x wire length (m) x amperage (A) x 10–3
H Wiring on the Input Side of Main Circuit
D Installing a Molded-case Circuit Breaker
Always connect the power input terminals (R, S, and T) and power supply via a molded-
case circuit breaker. Power must be supplied instantaneously. Unstable power startup
will not start the Inverter.
D Installing a Ground Fault Interrupter
If a ground fault interrupter is to be connected to the wire on the primary side (R, S, and
T) of the main circuit, use either of the following interrupters to prevent malfunctions:
• Ground fault interrupter with a sensitivity amperage of 200 mA or more and with an
operating time of 0.1 second or more
• Ground fault interrupter with high-frequency countermeasures (for Inverter)
D Installing a Magnetic Contactor
This Inverter can be used without a magnetic contactor (MC) on the power supply side.
If the power supply for the main circuit is to be shut off because of the sequence, a mag-
netic contactor can be used instead of a molded-case circuit breaker.
However, when a magnetic contactor is installed on the primary side of the main circuit
to forcibly stop a load, note that regenerative braking does not work and the load coasts
to a stop.
• A load can be started and stopped by opening and closing the magnetic contactor on
the primary side. Note, however, that frequently opening and closing the magnetic
contactor may cause the Inverter to break down.
• When the Inverter is operated with a Digital Operator, automatic operation cannot be
performed after recovery from a power interruption.
D Connecting Input Power Supply to the Terminal Block
Because the phase sequence of input power supply is irrelevant to the phase sequence
(R, S, T) of the terminal block, input power supply can be connected to any terminal on
the terminal block.
3-12
Design
Chapter 3
D Installing an AC Reactor
If the Inverter is connected to a large-capacity power transformer (600 kW or more) or
the phase advance capacitor is switched, an excessive peak current may flow through
the input power circuit, causing the converter unit to break down. To prevent this, install
an optional AC reactor on the input side of the Inverter. This also improves the power
factor on the power supply side.
D Installing a Surge Absorber
Always use a surge absorber or diode for the inductive loads to be connected to the
Inverter. These inductive loads include magnetic contactors, electromagnetic relays,
solenoid valves, solenoids, and magnetic brakes.
D Wiring of Braking Resistor/Braking Resistor Unit
When using an Inverter for loads with a large inertia or for vertical axis loads, regenera-
tive energy will be fed back.
If the regenerative energy exceeds the Inverter capacity, overvoltage will be detected in
the main circuit. In such a case, use a Braking Resistor or Braking Resistor Unit.
Note Be sure to create a sequence that will turn OFF the Inverter power supply when
resistor overheating occurs. When using a Braking Resistor, be sure to install a
thermal relay to detect resistor overheating. When using a Braking Resistor Unit,
use an error output contact. Otherwise, a fire may occur.
3G3EV Model
Braking Resistor
(Duty Cycle 3%ED)
Braking Resistor
Unit
Minimum
connected
(Duty Cycle 10%ED) resistance
3G3IV-PERF150WJ401 ---
(400 Ω)
200 Ω
200 Ω
200 Ω
80 Ω
A2001(-j)/AB001(-j)
A2002(-j)/AB002(-j)
A2004(-j)/AB004(-j)
A2007(-j)/AB007(-j)
A2015(-j)/AB015(-j)
3G3IV-PERF150WJ201 3G3IV-PLKEB20P7
(200 Ω)
(200 Ω 70 W)
3G3IV-PERF150WJ101 3G3IV-PLKEB21P5
60 Ω
(100 Ω) (100 Ω 260 W)
3G3IV-PERF150WJ751 3G3IV-PLKEB40P7
(750 Ω) (750 Ω 70 W)
750 Ω
510 Ω
240 Ω
A4002(-j)/A4004(-j)
A4007(-j)
3G3IV-PERF150WJ401 3G3IV-PLKEB41P5
(400 Ω) (400 Ω 260 W)
A4015(-j)
Note Do not use a Resistor whose resistance is below the minimum connected resis-
tance. Otherwise, the Inverter will be damaged.
3-13
Design
Chapter 3
D Installing a Noise Filter on the Power Supply Side
Install a noise filter to eliminate noise transmitted between the power line and the
Inverter.
Wiring Example 1
Power
supply
3G3IV-PHF
3G3EV
Noise
filter
SYSMAC,
etc.
Other controllers
Note Use a special-purpose noise filter for Inverters.
Wiring Example 2
Powe
supply
3G3EV
General-
purpose
oise filter
SYSMAC,
etc.
Other controllers
3G3EV
Power
supply
General-
purpose
noise filter
SYSMAC,
etc.
Other controllers
Note Do not use a general-purpose noise filter.
H Wiring on the Output Side of Main Circuit
D Connecting the Terminal Block to the Load
Connect output terminals U, V, and W to motor lead wires U, V, and W, respectively.
3-14
Design
Chapter 3
D Never Connect Power Supply to Output Terminals
CautionNever connect a power supply to output terminals U, V, and W.
If voltage is applied to the output terminals, the internal mechanism of the
Inverter will be damaged.
D Never Short or Ground the Output Terminals
CautionIf the output terminals are touched with bare hands or the output wires come
into contact with the Inverter casing, an electric shock or grounding will occur.
This is extremely hazardous. Also, be careful not to short the output wires.
D Do Not Use a Phase Advance Capacitor or Noise Filter
Never connect a phase advance capacitor or LC/RC noise filter to the output circuit. Do-
ing so may result in damage to the Inverter or cause other parts to burn.
D Do Not Use an Electromagnetic Switch
Do not connect an electromagnetic switch or magnetic contactor to the output circuit. If a
load is connected to the Inverter during operation, an inrush current will actuate the
overcurrent protective circuit in the Inverter.
D Installing a Thermal Relay
This Inverter has an electronic thermal protection function to protect the motor from
overheating. If, however, more than one motor is operated with one Inverter or a multi-
polar motor is used, always install a thermal relay (THR) between the Inverter and the
motor and set to “0.0” (no thermal protection) for constant No. 31 (“THR” indicator).
In this case, program the sequence so that the magnetic contactor on the input side of
the main circuit is turned off by the contact of the thermal relay.
D Installing a Noise Filter on the Output Side
Connect a noise filter to the output side of the Inverter to reduce radio noise and induc-
tion noise.
3G3EV
3G3IV-PLF
Power supply
Noise
filter
Induction noise Radio noise
Signal line
Controller
AM radio
3-15
Design
Chapter 3
Induction Noise: Electromagnetic induction generates noise on the signal line, causing
the controller to malfunction.
Radio Noise:
Electromagnetic waves from the Inverter and cables cause the
broadcasting radio receiver to make noise.
D How to Prevent Induction Noise
As described above, a noise filter can be used to prevent induction noise from being
generated on the output side. Alternatively, cables can be routed through a grounded
metal pipe to prevent induction noise. Keeping the metal pipe at least 30 cm away from
the signal line considerably reduces induction noise.
MCCB
Metal pipe
3G3EV
Power supply
30 cm min.
Signal line
Controller
D How to Prevent Radio Noise
Radio noise is generated from the Inverter as well as the input and output lines. To re-
duce radio noise, install noise filters on both input and output sides, and also install the
Inverter in a totally enclosed steel box.
The cable between the Inverter and the motor should be as short as possible.
Steel box
Metal pipe
3G3EV
Power supply
Noise
filter
Noise
filter
3-16
Design
Chapter 3
D Cable Length between Inverter and Motor
If the cable between the Inverter and the motor is long, the high-frequency leakage cur-
rent will increase, causing the Inverter output current to increase as well. This may affect
peripheral devices. To prevent this, adjust the carrier frequency (set in n37) as shown in
the table below.
Cable length between Inverter and motor 50 m max.
100 m max.
Carrier frequency (n37)
10 kHz max. (1, 2, 3, 4) 5 kHz max. (1, 2)
H Ground Wiring
• Always use a ground terminal with the following ground resistance.
200-VAC Class: 100 Ω or less
400-VAC Class: 10 Ω or less
• For 400-VAC-class models that conform to EC Directives, also connect to the neutral
of the power supply.
• Do not share the ground wire with other devices such as a welder or power tool.
• Always use a ground wire that complies with technical standards on electrical equip-
ment. Route the ground wire so that the total length is as short as possible.
• When using more than one Inverter, be careful not to loop the ground wire.
3-17
Design
Chapter 3
3-2-3 Wiring Control Circuit Terminals
The control signal line must be 50 m or less and must be separated from
the power line. If frequency references are input externally, use a twisted-
pair shielded line.
H Wiring Sequence Input/Output Terminals
Wire the sequence input terminals (SF, SR, S1, and SC) and the multi-function contact
output terminals (MA, MB, and MC) as described below.
D Wires to be Used
Wire type
Single wire
Stranded wire
Wire size
0.5 to 1.25 mm2
0.5 to 0.75 mm2
Wire to be used
Polyethylene-shielded cable
D Wiring Method
• Wire each terminal as follows:
a) Loosen the terminal screw with a thin-slotted screwdriver.
b) Insert the wire from underneath the terminal block.
c) Tighten the terminal screw firmly.
• Always separate the control signal line from the main circuit cables and other power
cables.
Thin-slotted screwdriver
Control circuit
terminal block
Length of
stripped portion:
Approx. 5.5 mm
Do not solder this portion.
(Otherwise, faulty contact may result.)
Wire
H Wiring Frequency Reference Input Terminals
If frequency references are input using a D/A unit (digital-to-analog converter) or exter-
nal power supply, wire the frequency reference input terminals (FR and FC) as de-
scribed below.
3-18
Design
Chapter 3
D Wires to be Used
Always use twisted-pair shielded wires to prevent malfunctions due to noise.
Wire type
Single wire
Stranded wire
Wire size
0.5 to 1.25 mm2
0.5 to 1.25 mm2
Wire to be used
Polyethylene-insulated cable for
instrumentation (with shield)
D Wiring Method
• The wiring procedure is the same as for sequence input/output terminals, described
previously.
• Always separate the cables from the main circuit cables and other power cables.
• Connect the shield to the ground terminal of the Inverter. Do not connect to the control-
ler.
• Insulate the shield with tape to prevent it from coming into contact with other signal
lines and devices.
H Tightening Torque of Control Circuit Terminals
Tighten the control circuit terminals to the torque of 0.5 N S m which is the same torque
as for the M3 screws.
Note 1. Applying a torque of greater than 0.5 N S m may damage the terminal block.
Note 2. If the tightening torque is insufficient, wires may be disconnected.
3-19
4
Chapter 4
Preparing for
Operation
4-1 Preparation Procedure
4-2 Using the Digital Operator
4-3 Test Run
Preparing for Operation
Chapter 4
4-1 Preparation Procedure
1. Installation:
Install the Inverter according to installation conditions. Refer to page 3-2.
Check that all the installation conditions are met.
2. Wiring:
Connect the Inverter to power supply and peripheral devices. Refer to page 3-7.
Select peripheral devices that meet the specifications, and wire them correctly.
3. Turning the Power On:
Check the necessary items, then turn the power on.
Always check that the power voltage is correct and the power input terminals (R, S,
and T) are wired correctly.
SPower voltage
200-VAC class:
400-VAC class:
Three-phase, 200 to 230 VAC, 50/60 Hz
Three-phase, 380 to 460 VAC, 50/60 Hz
When a 3G3EV-ABjjj is used in single-phase input mode, the power voltage
must be as follows: single-phase, 200 to 240 VAC, 50/60 Hz (use terminals R and
S)
Check that the motor output terminals (U, V, and W) and motor are connected cor-
rectly.
Check that the control circuit terminals and controller are connected correctly.
4. Checking Display Status:
Check the Inverter for errors.
If everything is normal, the indicators below become as follows when the power is
turned on:
SRUN indicator: Flashing
SALARM indicator: Not lit
SConstant item indicators: “FREF,” “FOUT,” or “IOUT” is lit.
SData display: Data corresponding to the constant item indicators is displayed.
If an error exists, the ALARM indicator lights up. In this case, take the necessary ac-
tion as described in Section 5 Operation.
5. Setting Constants:
Use the Digital Operator to set constants required for operation. Refer to page 4-3.
Specify each constant as described in this manual.
4-2
Preparing for Operation
Chapter 4
6. Test Run:
Perform a no-load test run and an actual loading test run to check that the motor and
peripheral devices operate normally. Refer to page 4-25.
Check the direction of motor rotation and check that the limit switches operate nor-
mally. Operate the Inverter with the Digital Operator first, then with the controller.
7. Production Run:
The Inverter is ready to run. If any error has occurred, refer to Section 5 Operation.
4-2 Using the Digital Operator
4-2-1 Name and Function of Each Component
H Name of Each Component
Data display section
Monitor item indicators
Display
section
In-service item indicators (green indicators)
These items can be monitored or set even
during operation.
Stopped item indicators (red indicators)
These items can be set only when the
Inverter is stopped.
Operation
keys
Constant item indicators
Mode Key
Enter Key
Decrement Key
Increment Key
RUN Key
STOP/RESET Key
4-3
Preparing for Operation
Chapter 4
H Function of Each Component
D Display Sections
Data display section
Reference frequency values, output frequency values, output
current values, constant settings, and error codes are
displayed.
Monitor item indicators
When this indicator is lit, an output frequency value (Hz) is
displayed in the data display section.
When this indicator is lit, an output current value (effective
current: A) is displayed in the data display section.
Constant item indicators The value set in the constant corresponding to the lit indicator
is displayed in the data display section. A new value can be
set.
Note In-service item indicators (green indicators):
These items can be monitored or the constant for each item can be set even
during operation.
Stopped item indicators (red indicators):
Constants for these items can be set only when the Inverter is stopped.
In this display, the direction of motor rotation is displayed during operation.
D Operation Keys
Mode Key
Press this key to switch between monitor item indicators
and constant item indicators.
Enter Key
Press this key to register the value set in a constant.
Increment Key
Press this key to increase a constant no. or the value of a
constant.
Decrement Key Press this key to decrease a constant no. or the value of a
constant.
RUN Key
Press this key to start the Inverter. (This key is valid only
when Digital Operator run mode is selected and all
indicators in the stopped item indicators are not lit.)
STOP/RESET
Key
Press this key to stop the Inverter. (This key is valid only
when Digital Operator run mode is selected.) Also, press
this key to reset the Inverter when an error has occurred.
Note When the constant n01 is set to “0,” no items other than FREF and n01 can be set.
If settings cannot be changed using the operation keys, set n01 to “1.”
4-4
Preparing for Operation
Chapter 4
4-2-2 Outline of Operation
H Switching Data Display during Operation
Press the Mode Key to switch data display.
During operation, only the items in the in-service item indicators section
can be monitored and the constants for these items can be set.
If the power is turned off when the FOUT or IOUT indicator is lit, the same
indicator lights up next time the power is turned on. Otherwise, the FREF
indicator always lights up.
Example of Indicator
data display
Description
Reference frequency (Hz)
60.0
60.0
0.2
Output frequency monitoring
(Hz)
Output current monitoring
(effective current: A)
Acceleration time
(seconds)
10.0
10.0
Deceleration time
(seconds)
Forward/Reverse rotation selection
f%r
f%r: Forward rotation
reU: Reverse rotation
4-5
Preparing for Operation
Chapter 4
H Switching Data Display when Inverter is Stopped
Press the Mode Key to switch data display.
When the Inverter is stopped, all items can be monitored and the constant
for each item can be set.
Example Indi-
Description
of data
display
cator
Output frequency
monitoring (Hz)
0.0
Note The indicators displayed
when the power is
turned on are the same
as shown in the previous
section “Switching Data
Display during Opera-
tion.”
Output current monitoring
(effective current: A)
0.0
Acceleration time
(seconds)
10.0
10.0
Deceleration time
(seconds)
Forward/Reverse rotation selection
f%r: Forward rotation reU: Reverse rotation
Maximum frequency (Hz)
f%r
60.0
200
60.0
0.6
Maximum voltage (V)
Maximum voltage
frequency (Hz)
Electronic thermal
reference current (A)
n02
n04
Operation
mode selection
1
Constant no.
n01
60.0
Reference
frequency (Hz)
4-6
Preparing for Operation
Chapter 4
H Monitor Display
The 3G3EV allows the user to monitor the reference frequency, output fre-
quency, output current, and the direction of rotation.
D Operation Method
Key
operation
Indicator Example of
data display
Description
Press the Mode Key until the FREF indicator
lights up. The reference frequency (Hz) is
displayed.
60.0
Press the Mode Key. The output frequency (Hz) is
displayed.
60.0
0.2
Press the Mode Key. The output current value
(effective current: A) is displayed.
Note 1. The direction of rotation can be always monitored during operation. The indica-
tors in the lower two rows of the display section flash indicating the direction of
rotation. The indicator flashing speed varies according to the speed of rotation.
Indicator flashing sequence
during forward rotation
The indicators flash
counterclockwise when the motor
rotates in the forward direction.
Note 2. The constant item indicators section has the F/R indicator, but this indicator is
used to indicate a command when the Inverter is operated with the Digital Oper-
ator.
4-7
Preparing for Operation
Chapter 4
4-2-3 Setting Constants
The 3G3EV (Standard Model) allows the user to set 18 different constants.
The constants for basic operations are allocated to dedicated indicators,
so the user need not refer to the constant nos. The constants allocated to
dedicated indicators can be also set by lighting the PRGM indicator.
Note that the operation methods using dedicated indicators and the PRGM
indicator are different.
H Setting Constants
D Setting Constants Using a Dedicated Indicator
Example:
Changing acceleration time from 10 seconds to 50 seconds.
Key
operation
Indicator Example of
data display
Explanation
Press the Mode Key until the ACC indicator lights
up.
10.0
Flashing
Press the Increment Key. The data display section
flashes (indicating that the data is yet to be
registered).
10.1
Flashing
Press the Increment Key until “50.0” appears in
the data display section. Holding down the key
changes data quickly.
50.0
50.0
Press the Enter Key to complete the setting
procedure.
Flashing
10.0
50.0
50.0
Note If the new data is not to be registered, press the Mode Key instead of the Enter
Key. The new data becomes invalid and the next item is displayed.
4-8
Preparing for Operation
Chapter 4
D Setting Constants Using the PRGM Indicator
Example:
Changing the value of constant no. 02 (operation mode selection) to “2.”
Key
operation
Indicator Example of
data display
Explanation
Press the Mode Key until the PRGM indicator
lights up.
n01
n02
Press the Increment Key. “n02” appears in the
data display section.
Press the Enter Key. The value of constant no. 02
is displayed.
0
Flashing
2
Change the value to “2” by pressing the Increment
Key. The data display section flashes (indicating
that the value is yet to be registered).
Press the Enter Key. The data display section
stops flashing.
2
After approximately 0.5 second, the data display
section returns to the constant no. display (“n02”).
n02
Flashing
n01
n02
0
2
2
n02
(After 0.5
second)
Note 1. If the new data is not to be registered, press the Mode Key instead of the Enter
Key. The new data becomes invalid and the constant no. display (“n02”) is re-
turned.
Note 2. Holding down the Increment Key or Decrement Key changes data quickly.
4-9
Preparing for Operation
Chapter 4
H List of Constants
Constant Dedicated
no. indicator
n01
Description
Setting range
Factory setting
Constant write-inhibit selec- 0, 1, 8, 9
tion/constant initialization
Operation mode selection
1
n02
0 to 5
0
n03
n04
Interruption mode selection 0, 1
0
Forward/reverse rotation
selection
For, rEv
For
n06
n09
Multi-function input selec-
tion
0 to 4
1
1
Multi-function output selec- 0, 1, 2
tion
n11
n12
Frequency reference 1
0.0 to 400
6.0 (Hz)
0.0 (Hz)
Frequency reference 2
0.0 to 400
n20
n21
Acceleration time
Deceleration time
0.0 to 999
0.0 to 999
10.0 (seconds)
10.0 (seconds)
n24
n25
Maximum frequency
Maximum voltage
50.0 to 400
60.0 (Hz)
1 to 255
(see note 1)
200 (V)
(see note 1)
n26
n31
Maximum voltage frequency 1.6 to 400
60.0 (Hz)
Electronic thermal reference 0.0 to see note 2 See note 2
current
n33
n36
n37
Stall prevention during de-
celeration
0, 1
0
Operation after recovery
from power interruption
0, 1, 2
0
Carrier frequency
1, 2, 3, 4
(see note 3)
4
(see note 4)
n39
n40
n61
n64
Frequency reference gain
Frequency reference bias
Stop Key selection
0.10 to 2.55
–99 to 99
0, 1
1.00
0 (%)
0
Operator’s frequency set-
ting method
0, 1
0
n68
Error history
(Display only)
Note 1. The upper limit of the setting range and the factory setting for the 400-VAC class
are double the above values.
4-10
Preparing for Operation
Chapter 4
Note 2. The setting range and factory setting for n31 (electronic thermal reference cur-
rent) depend on the Inverter model. For details, refer to page 4-19.
Normally, set the rated motor amperage in n31.
Note 3. The setting range for the 400-VAC models is “1 to 5.”
Note 4. The factory setting for the 3G3EV-A4015-CUE is “3.”
Note 5. Displaying the constant no. corresponding to an indicator in the “Dedicated
indicator” column lights the indicator.
Note 6. Constant no. 02 (n02) and subsequent constants can be set only when
constant no. 01 (n01) is set to 1.
Constants in the shaded areas in the above table may not be usable depending on the
PROM number (software version).
Con-
stant
no.
PROM no. (software version)
200
199 or lower
220 or higher
n03 No
Yes
Yes
n39 Setting range: 0.10 to 2.00 Setting range: 0.10 to 2.00 Setting range: 0.10 to 2.55
n61 No
n64 No
Yes
No
Yes
Yes
Note “Yes” indicates that the constant can be set.
“No” indicates that the constant cannot be set.
H Details of Each Constant
Constant Write-Inhibit Selection/Constant Initialization
Setting range 0, 1, 8, 9 Factory setting 1
n01
One of the following four values can be selected:
Value
Description
0
1
8
9
Only n01 can be set.
Constants n01 to n68 can be displayed and set.
All constants are returned to factory settings.
The Inverter is initialized in 3-wire sequence mode.
Note 1. If other constants are to be set, always set “1” in n01.
Note 2. Setting “9” (3-wire sequence mode) in n01 allows the user to start and stop the
Inverter with automatic recovery type push-button switches.
4-11
Preparing for Operation
Chapter 4
Example of 3-wire Sequence Mode
Stop
switch
Run
switch
(contact b) (contact a)
Run command (starts Inverter when “closed”)
Stop command (stops Inverter when “opened”)
Forward/Reverse rotation command (rotates
motor in forward direction when “opened”;
rotates motor in reverse direction when “closed”)
Common
Example of Operation
Forward rotation
Motor operation
Reverse rotation
Run command
Stop command
Forward/Reverse
rotation command
n02
Operation Mode Selection
Setting range 0 to 5
Factory setting 0
This constant is used to specify whether the Inverter is to be operated with a Digital
Operator or external signals.
Value
Run command
Digital Operator
Control terminal
Digital Operator
Control terminal
Digital Operator
Control terminal
Frequency reference
Digital Operator (n11)
DIP switch setting
0
1
2
3
4
5
OFF
OFF
OFF
OFF
Digital Operator (n11)
Control terminal (voltage input)
Control terminal (voltage input)
Control terminal (amperage input) ON
Control terminal (amperage input) ON
Note 1. The above setting operation can be performed when constant no. 02 is se-
lected. This operation is also possible when the dedicated indicator (“MODE”)
is lit.
4-12
Preparing for Operation
Chapter 4
Note 2. The DIP switch is located inside the Inverter. Use this switch to change the set-
ting when frequency references are to be input in terms of amperage (4 to 20
mA). For details, refer to Section 7-2 Frequency Reference by Amperage Input.
For voltage input, never set the DIP switch to ON. Doing so may damage the
equipment.
Interruption Mode Selection
n03
Setting range 0, 1
Factory setting 0
This constant is used to specify the interruption mode when the STOP/RESET Key is
pressed or the operation command is OFF.
Value
Description
0
1
Frequency deceleration stop
Free running
Example of Frequency Deceleration Stop
Deceleration time 1
(n21)
Minimum output frequency determined
with constant set in n29: Factory-set to
1.5 kHz
Output frequency
Time
Interruption DC control time determined
with constant set in n47: Factory-set to 0.5
second
Forward rotation
(Reverse rotation)
ON
OFF
Operation command
Example of Free Running
Inertia of motor
Output frequency
Time
Forward rotation
(Reverse rotation)
ON
OFF
Operation command
Note This constant is available for models with a PROM number (software version) of
“200” or higher.
4-13
Preparing for Operation
Chapter 4
Forward/Reverse Rotation Selection
n04
Setting range
Factory setting
f%r, reU
f%r
(forward rota-
tion)
This constant is used to specify the direction of motor rotation when the Inverter is oper-
ated with the Digital Operator.
Value
Description
Forward rotation
Reverse rotation
f%r
reU
Note 1. While the Inverter is being operated with the Digital Operator, the direction of
motor rotation can be changed by lighting the F/R indicator with the Mode Key
first, pressing the Increment or Decrement Key to change the setting, then
pressing the Enter Key.
Note 2. The direction (forward/reverse) of motor rotation depends on the motor model
used. Refer to the instruction manual for the motor.
Multi-Function Input Selection
n06
Setting range 0 to 4
Factory setting 1
One of the following values can be selected for the multi-function input (S1) function:
Value
Description
0
1
2
3
4
Forward/reverse rotation command (3-wire sequence)
Fault reset (fault reset when ON)
External fault (contact a: external fault when ON)
External fault (contact b: external fault when OFF)
Multi-step speed command (frequency reference 2 when ON)
Multi-Function Output Selection
n09
Setting range 0, 1, 2
Factory setting 1
One of the following three values can be specified for the multi-function contact output
(MA and MB) function. When the Inverter enters the state corresponding to the specified
value, MA is turned on and MB is turned off.
Value
Description
0
1
2
Fault occurrence
Operation in progress (frequency reference is being output)
Frequency matching (see note)
4-14
Preparing for Operation
Chapter 4
Note MA is turned on when the difference between the reference frequency and the
output frequency falls within 2 Hz. MA is turned off when the difference exceeds
±4 Hz.
Example of Operation
Reference frequency
Detection range
±2 Hz
Release range
±4 Hz
Output
frequency
Frequency
matching (for MA)
4-15
Preparing for Operation
Chapter 4
n11
Frequency Reference 1
Setting range 0.0 to 400 (Hz) Factory setting 6.0 (Hz)
n12
Frequency Reference 2
Setting range 0.0 to 400 (Hz) Factory setting 0.0 (Hz)
• These constants are used to set reference frequency values.
• The unit of setting is as follows:
0.0 to 99.9 (Hz): 0.1 (Hz)
100 to 400 (Hz): 1 (Hz)
• The reference frequency value can be changed even during operation. To change the
reference frequency value when the Inverter is being operated with the Digital Opera-
tor, light the FREF indicator with the Mode Key first, press the Increment or Decrement
Key to change the value, then press the Enter Key.
• If one of values 2 to 5 is set in n02 (operation mode selection), the n11 setting is disre-
garded and control input (voltage or current) becomes valid.
• When using n12 (frequency reference 2), always set “4” (multi-step speed command)
in n06 (multi-function input selection). The multi-step speed command is always valid
regardless of the n02 setting.
• If the n12 setting is to be changed during operation, perform the above procedure
when the multi-step speed command (S1) is ON.
Example of Multi-Step Speed Operation
setting
Output frequency
setting
Forward/stop (SF)
Multi-step speed
command (S1)
4-16
Preparing for Operation
Chapter 4
Acceleration Time
n20
Setting range 0.0 to 999
Factory setting 10.0 (seconds)
(seconds)
Deceleration time
n21
Setting range 0.0 to 999
Factory setting 10.0 (seconds)
(seconds)
• These constants are used to set acceleration time (required to increase the output fre-
quency from the stopped state to the maximum frequency) and deceleration time (re-
quired to decrease the output frequency from the maximum frequency to the stopped
state).
(Set the maximum frequency in n24.)
• The unit of setting is as follows:
0.0 to 99.9 (seconds): 0.1 (second)
100 to 999 (seconds): 1 (second)
• Acceleration and deceleration times can be changed even during operation. If, for ex-
ample, acceleration time is to changed, light the ACC indicator with the Mode Key first,
press the Increment or Decrement Key to change the value, then press the Enter Key.
Deceleration time can be also changed in the same way. (Light the DEC indicator be-
fore changing the deceleration time.)
These constant settings are always valid regardless of whether the Inverter is oper-
ated with the Digital Operator or control input.
Explanation of n20 and n21 Settings
Output frequency
DC braking
(50% of Inverter
rated current)
Maximum frequency
0.5 second
Time
Acceleration time
Deceleration time
4-17
Preparing for Operation
Chapter 4
Maximum Frequency
n24
Setting range 50.0 to 400
Factory setting 60.0 (Hz)
(Hz)
Unit of setting 50.0 to 99.9 (Hz) : 0.1 (Hz)
100 to 400 (Hz) : 1 (Hz)
n25
Maximum Voltage
Setting range 1 to 255 (510) Factory setting 200 (400) (V)
(V)
Unit of setting 1 (V)
Maximum Voltage Frequency (Basic Frequency)
n26
Setting range 1.6 to 400 (Hz) Factory setting 60.0 (Hz)
Unit of setting 1.6 to 99.9 (Hz) : 0.1 (Hz)
100 to 400 (Hz) : 1 (Hz)
Note The values in parentheses are for the 400-VAC class.
• These three constants are used to set a V/f pattern.
• Check the motor specifications and set each constant as follows:
n24: Maximum frequency or rated frequency
n25: Rated voltage
n26: Rated frequency
• The value set in n24 (maximum frequency) must be equal to or greater than the value
set in n26 (maximum voltage frequency). Otherwise, an error will result.
Explanation of n24, n25, and n26 Settings
Maximum voltage
Output voltage
(V)
Output
frequency (Hz)
(24 V)
Maximum voltage
frequency (basic
frequency)
Maximum
frequency
4-18
Preparing for Operation
Chapter 4
Electronic Thermal Reference Current
n31
Setting range 0.0 to
Factory setting See note 2
(see note 1) (A)
Unit of setting 0.1 (A)
• This constant is used to set an electronic thermal reference value to protect the motor
from overheating.
Set the rated motor amperage in this constant.
• If 0.0 is set in this constant, “no thermal protection” is assumed, so motor overload will
not be detected.
• The setting range and factory setting for this constant are as follows:
Note 1. This can be set to a maximum of 120% of the Inverter rated current.
Note 2. Set to the normal rated current of the maximum applicable motor.
Stall Prevention during Deceleration
n33
Setting range 0, 1
Factory setting 0
This constant is used to select the action to prevent overvoltage during deceleration.
Value
Description
Stall prevention during deceleration
No stall prevention during deceleration
0
1
Note 1. If a braking resistor is to be connected, always set “1” (no stall prevention during
deceleration) in this constant.
Note 2. If “0” (stall prevention during deceleration) is set in this constant, deceleration
time will be automatically lengthened to prevent overvoltage.
Explanation of Stall Prevention during Deceleration
Output
frequency
Deceleration time is controlled
to prevent overvoltage
Time
(Setting)
Deceleration time
4-19
Preparing for Operation
Chapter 4
Operation after Recovery from Power Interruption
n36
Setting range 0, 1, 2
Factory setting 0
This constant is used to select the processing to be performed after recovery from an
instantaneous power interruption.
Value
Description
0
1
2
Discontinues operation.
Continues operation only if power interruption is within 0.5 second.
Continues operation unconditionally (with no error output).
Note If “1” or “2” is selected to continue operation, the Inverter automatically searches
the motor speed (even when the motor is in a free-running state) and continues
smooth operation. This function is called the speed search function.
Explanation of Speed Search Function
Free-running state
Motor speed
Inverter starts operating
Time
Carrier Frequency
Setting range 1, 2, 3, 4
(see note 1)
n37
Factory setting 4 (10 kHz)
(see note 2)
This constant is used to set a pulse-width-modulated (PWM) carrier frequency.
Value
Carrier frequency
1
2
3
4
5
2.5 (kHz)
5 (kHz)
7.5 (kHz)
10 (kHz)
12.5 (kHz)
Note As the cable between the Inverter and the motor becomes longer, a high-frequen-
cy leakage current from the cable increases, causing the Inverter output current
to increase as well. This may also affect peripheral devices. To prevent this, ad-
just the carrier frequency according to the following standards:
SCable length of 50 meters or less: 10 kHz or less
SCable length of 50 to 100 meters: 5 kHz or less
Note 1. The setting range for the 400-VAC class is “1 to 5.”
4-20
Preparing for Operation
Chapter 4
Note 2. The factory setting for the 3G3EV-A4015-CUE is “3.”
Note 3. With the 400-VAC class, the continuous output current cannot be used to 100%
of the rated value if the constant is set to “5” for Inverters of 0.75 kW or less or if it
is set to “4” or “5” for an Inverter of 1.5 kW.
Set the constant so that the continuous output current does not exceed the val-
ues shown in the following tables.
400-VAC Inverters of 0.75 kW or Less
Carrier frequency set value
1 to 4
Max. continuous output current
Up to 100% of the rated output
Up to 90% of the rated output
5
400-VAC Inverter of 1.5 kW
Carrier frequency set value
Max. continuous output current
1 to 3
Up to 100% of the rated output
Up to 85% of the rated output
Up to 75% of the rated output
4
5
4-21
Preparing for Operation
Chapter 4
Frequency Reference Gain
n39
Setting range 0.10 to 2.55
Factory setting 1.00 (times)
(times)
Unit of setting 0.01 (times)
Frequency Reference Bias
n40
Setting range –99 to 99 (%) Factory setting 0 (%)
Unit of setting 1 (%)
• These constants are used to set the relationship between analog voltage and refer-
ence frequencies when frequency references are input through control terminals FR
and FC.
• Frequency reference gain (n39): Specify the input voltage corresponding to the maxi-
mum frequency (n24) as a multiple of 10 V.
• Frequency reference bias (n40): Specify the reference frequency corresponding to in-
put voltage 0 V as a percentage of the maximum frequency (n24).
Explanation of Frequency Reference Gain and Bias
Gain setting = 10 V x (n39 setting)
Bias setting = Maximum frequency x (n40 setting)/100
Reference frequency
Maximum frequency
Bias setting
Input voltage
Gain setting
Example of Setting:
Operating the Inverter so that the Maximum Frequency is Reached when
the Voltage Increases from 0 to 5 V
Maximum frequency
Reference frequency
Settings:
n39 = 0.50 (times)
n40 = 0 (%)
Input voltage
4-22
Preparing for Operation
Chapter 4
Stop Key Selection
n61
Setting range 0, 1
Factory setting 0
• When inputting Inverter operation from the control terminals, the Stop Key on the Digi-
tal Operator can be set to “enabled” or “disabled.”
Value
Description
0
1
Stop Key enabled
Stop Key disabled
Note 1. When operating the Inverter from the Digital Operator, the Stop Key is always
enabled irrespective of its setting.
Note 2. This constant is available for models with a PROM number (software version)
of “200” or higher.
Operator’s Frequency Setting Method
n64
Setting range 0, 1
Factory setting 0
• Used for setting the frequency from the Digital Operator.
• Select the Enter Key operation when setting the frequency command from the Digital
Operator.
Value
Description
0
1
Enter Key required for changing frequency
Enter Key not required for changing frequency (may be changed using
Increment and Decrement Keys.)
Error History
n68
This constant can only be displayed. It cannot be set.
• Information about the last error is recorded in this constant. Use this information for
troubleshooting purposes.
• The display format is as follows:
8.8.8.
Error code
Note This constant is available for models with a PROM number (software version) of
“220” or higher.
4-23
Preparing for Operation
Chapter 4
• Recorded are Inverter errors and other errors that actuate a protective mechanism.
Warning (automatically recovered error) is not recorded.
• If no error has occurred, the indicator is not lit.
• All error codes are listed below.
Error code
%c
Description
Overcurrent (OC)
Error category
Errors that actuate protective
mechanism
Main circuit overvoltage (OV)
Main circuit undervoltage (UV1)
Control power supply fault (UV2)
Radiation fin overheated (OH)
Motor overload (OL1)
Inverter overload (OL2)
External fault (EF1)
Initial memory error
ROM error
Constant error
A/D converter error
%U
uU1
uU2
%h
%l1
%l2
ef1
f00
f01
f04
f05
f06
Inverter errors
Option error
4-24
Preparing for Operation
Chapter 4
4-3 Test Run
After wiring is complete, perform a test run of the Inverter as follows. First,
start the motor through the Digital Operator without connecting the motor
to the mechanical system. Next, connect the motor to the mechanical sys-
tem and perform a test run. Finally, operate the controller to make sure that
the sequence of operations is correct.
This section only describes how to perform a test run using the Digital
Operator.
4-3-1 Checking Wiring
• Check that terminals R, S, and T receive power supply.
200-VAC Class
Three-phase input: 200 to 230 VAC, 50/60 Hz
Single-phase input: 200 to 240 VAC, 50/60 Hz (terminal R and S)
(Single-phase input is only applicable to 3G3EV-ABjjj.)
400-VAC Class
Three-phase input: 380 to 460 VAC, 50/60 Hz
• Check that terminals U, V, and W are correctly connected to the motor power cables.
• Do not connect the mechanical system to the motor. (The motor must be in no-load
status.)
• If signal lines are connected to control terminals, turn terminals SF and SR off.
4-3-2 Turning Power On and Checking Indicator Display
• Check that the ALARM indicator is not lit.
• Check that the RUN indicator is flashing.
4-3-3 Initializing Constants
n01
• Set “8” or “9” (3-wire sequence mode) in constant no. 01 to initialize constants.
4-3-4 Setting a V/f Pattern
• Set the maximum frequency (“FMAX” or constant no. 24), maximum voltage (“VMAX”
or constant no. 25), and maximum voltage frequency (“FBAS” or constant no. 26) ac-
cording to the operating conditions.
4-25
Preparing for Operation
Chapter 4
4-3-5 Setting Rated Motor Amperage
• Set the rated motor amperage in constant no. 31 (electronic thermal reference current)
or with the “THR” indicator lit.
4-3-6 Setting the Reference Frequency
• Set the frequency corresponding to the motor speed in constant no. 11 (frequency ref-
erence 1) or with the “FREF” indicator lit.
4-3-7 Operating the Inverter with the Digital Operator
• Press the RUN Key to rotate the motor in the forward direction. (If the PRGM indicator
is lit in the constant item indicators section, press the Mode Key once to light the FREF
indicator. If a red indicator in the stopped item indicators section is lit, the run command
cannot be accepted.)
• Check that the motor rotates smoothly without making noise.
• Check that the direction of rotation is correct.
4-3-8 Checking Output Frequency and Amperage
• Light the FOUT indicator (output frequency monitor) and make sure that the displayed
value matches the reference frequency.
• Light the IOUT indicator (output current monitor) and check for overcurrent.
4-3-9 Checking Operation during Reverse Rotation
• Rotate the motor in the reverse direction and check the same items as above.
4-3-10 Checking Operation with Mechanical System
Connected
• Press the STOP/RESET Key to stop the motor.
• Connect the mechanical system to the motor and check the same items as above.
4-3-11 Checking Operation Performed by Controller
• Light the MODE indicator and set the actual operation mode.
• Operate the Inverter with the controller, check for noise resulting from mechanical res-
onance, and check that the sequence of operations is correct.
4-26
5
Chapter 5
Operation
5-1 Protective and Diagnostic Functions
5-2 Troubleshooting
5-3 Maintenance and Inspection
Operation
Chapter 5
5-1 Protective and Diagnostic Functions
The 3G3EV has excellent protective and diagnostic functions. The RUN
and ALARM indicators on the front panel indicate the current Inverter sta-
tus, and the data display section also displays information about an error
that has occurred. These functions therefore enable the user to take the
appropriate actions to correct most errors.
H List of Error Codes
Indicator
Inverter
status
Data
display
Description
RUN
Flashes
Lit
ALARM
Not lit
Not lit
Normal
---
---
ef
Ready to run
Normal operation in progress
Simultaneous input of forward and re-
verse rotation commands
Warning
Flashes
Flashes
Lit
Flashes
Lit
Main circuit undervoltage (UV)
Main circuit overvoltage (OV)
Radiation fin overheated (OH)
Digital Operator stopped (STP)
Overcurrent (OC)
Main circuit overvoltage (OV)
Main circuit undervoltage (UV1)
Control power supply fault (UV2)
Radiation fin overheated (OH)
Motor overload (OL1)
Inverter overload (OL2)
External fault (EF1)
Initial memory error
ROM error
Constant error
A/D converter error
Option error
Control circuit error
uU
%U
%h
Protective Not lit
mecha-
%c
%U
nism actu-
ated
uU1
uU2
%h
%l1
%l2
ef1
f00
f01
f04
f05
f06
(Not lit)
Inverter
error
Not lit
Not lit
Lit
Not lit
5-2
Operation
Chapter 5
H Data Display and Action to be Taken when Warning Status
Arises
The ALARM indicator flashes when warning status arises. The data display section also
flashes.
When warning status arises, no error code is output.
Eliminating the cause recovers the system automatically.
Data
Description
Action
display
ef
Simultaneous input of forward and • Review the sequence.
reverse rotation commands
flashing
Forward and reverse rotation
commands were simultaneously input
for 0.5 second or more. The Inverter
decelerates and stops the motor.
Main circuit undervoltage (UV)
• Check the power voltage.
uU
flashing
The DC voltage of the main circuit
dropped below the low-voltage
detection level when the Inverter was
stopped.
• Check the power input line for discon-
nection.
• Check the terminal block screws for
looseness.
Main circuit overvoltage (OV)
• Check the power voltage.
%U
flashing
The DC voltage of the main circuit
exceeded the overvoltage detection
level when the Inverter was stopped.
Radiation fin overheated (OH)
• Check the ambient temperature.
%h
flashing
The radiation fin overheated when the
Inverter was stopped.
• Install a cooling fan or air conditioner.
Digital Operator stopped (STP)
• Open both SF and SR.
flashing
The STOP/RESET Key on the Digital
Operator was pressed while the
Inverter was being operated using
control circuit terminals SF and SR.
The Inverter decelerates and stops
the motor.
5-3
Operation
Chapter 5
H Data Display and Action to be Taken when Protective
Mechanism is Actuated
The ALARM indicator lights up when the protective mechanism is actuated. In this
event, Inverter output is shut off, and the motor coasts to a stop.
Check the cause of the error, take the necessary action, and perform fault reset or turn
the power off, then on.
Data
Description
Cause and action
display
%c
Overcurrent (OC)
• The output side of the Inverter is
shorted or grounded.
The Inverter output current
instantaneously exceeded 250% of the
rated amperage.
• Load inertia is excessive.
• The acceleration and deceleration
time settings are too short.
• A special motor is used.
• The motor was started during free
running.
• The magnetic contactor on the output
side of the Inverter was opened and
closed.
• Determine the cause of the error, take
the necessary action, and reset the
system.
Main circuit overvoltage (OV)
%U
• The deceleration time setting is too
short.
Because regenerative energy from the
motor was excessive, the DC voltage
of the main circuit exceeded
approximately 410 V.
• Increase the deceleration time.
• Connect a braking resistor (or braking
resistor unit).
(400-VAC Class, 820 V)
• The regenerative energy becomes
excessive when returning from the
overshoot during acceleration.
• Connect a braking resistor (or braking
resistor unit).
5-4
Operation
Chapter 5
Data
Description
Cause and action
display
uU1
Main circuit undervoltage (UV1)
• The input power voltage dropped.
• Open-phase occurred.
The DC voltage of the main circuit
dropped below the specified level.
3G3EV-A2jjj: Approximately 200 V
or less
• An instantaneous power interruption
occurred.
3G3EV-ABjjj: Approximately
160 V or less
3G3EV-A4jjj-CUE: Approximately
400 V or less
• Check the power voltage.
• Check the power input line for discon-
nection.
• Check the terminal block screws for
looseness.
Control power supply fault (UV2)
• Turn the power off, then on.
uU2
%h
A voltage fault occurred in control
power supply.
• If this problem persists, replace the
Unit.
Radiation fin overheated (OH)
• Load is excessive.
The radiation fin overheated because
of ambient temperature rise or Inverter
temperature rise due to overload.
Reduce the load.
• The V/f characteristics are inappropri-
ate.
Reset constant Nos. 24 to 26.
• The acceleration/deceleration time or
cycle time is too short.
Increase the acceleration/de-
celeration time or cycle time.
• The ambient temperature is too high.
Install a cooling fan or air con-
ditioner.
5-5
Operation
Chapter 5
Data
Description
Cause and action
display
%l1
Motor overload (OL1)
• Review the load size, V/f characteris-
tics, acceleration/deceleration time,
and cycle time.
The electronic thermal relay actuated
the motor overload protection function.
• Set the rated motor amperage in
constant No. 31 (electronic thermal
reference current).
• The maximum voltage frequency
(FBAS) was set too low (V/f charac-
teristics setting error) and caused
overcurrent.
• Set the maximum voltage frequency
to the rated motor frequency.
• Operated more than one motor with
one Inverter.
• Set constant No. 31 (electronic ther-
mal reference current) to “0.0 (A).”
Inverter overload (OL2)
• Review the load size, V/f characteris-
tics, acceleration/deceleration time,
and cycle time.
%l2
ef1
The electronic thermal relay actuated
the Inverter overload protection
function.
• Review the Inverter capacity.
• Review the external circuits.
External fault (EF1)
The Inverter received abnormal input
from external circuits.
• Review the external sequence.
• Check the signal line of multi-function
contact input for disconnection.
5-6
Operation
Chapter 5
H Data Display and Action to be Taken when Inverter Error
Occurs
The first character of an error code is always “F” when an Inverter error occurs. (Howev-
er, all indicators are not lit when a control circuit error occurs.)
If an Inverter error occurs, turn the power off, then on. If the problem persists, replace the
Unit.
Data
Description
Action
display
• Turn the power off, then on.
Initial memory error
f00
• If the problem persists, replace the
Unit.
ROM error
f01
f04
Constant error
• Write down all the constant settings,
initialize the constants, and reset the
constants.
• Turn the power off, then on.
• If the problem persists, replace the
Unit.
A/D converter error
Option error
• Turn the power off, then on.
f05
f06
• If the problem persists, replace the
Unit.
• Turn the power off, then reinstall the
Digital Operator.
The Digital Operator has an error or
faulty contact.
• If the problem persists, replace the
Unit.
(Not lit)
Control circuit error
• Check the power cables.
• Replace the Unit.
An error occurred in the control power
supply or hardware.
5-7
Operation
Chapter 5
5-2 Troubleshooting
If the Inverter or motor does not operate properly when the system is
started, constant settings or wiring may be incorrect. In this case, take the
appropriate action as described below. (If an error code is displayed, refer
to 5-1 Protective and Diagnostic Functions.)
5-2-1 Constants Fail to Set
H erris Displayed in the Data Display Section.
• If an attempt is made to set a value outside the allowable range, erris displayed in the
data display section. The value is canceled and the data display section re-displays
the original value. For example, this error occurs when:
SAn attempt is made to set a reference frequency value higher than the maximum
frequency value.
SAn attempt is made to set a maximum voltage frequency (basic frequency) value
higher than the maximum frequency value.
Check the setting range, then set the constant correctly.
H The Display Does Not Change when the Increment or
Decrement Key is Pressed.
• Value “0” is set in n01 (constant write-inhibit selection)
Set “1” in n01.
• The Digital Operator is not connected properly.
Turn the power off. After all indicators on the front panel go off, remove the Digital
Operator, then reinstall it.
5-2-2 Motor Fails to Operate
H The Motor Does Not Operate when the RUN Key on the Digital
Operator is Pressed.
• Operation mode was not selected correctly.
If “1,” “3,” or “5” is set in n02, the motor does not operate when the RUN Key on the
Digital Operator is pressed.
Always set “0,” “2,” or “4” in n02.
5-8
Operation
Chapter 5
• The reference frequency is too low.
When the reference frequency is less than 1.5 Hz, the Inverter cannot operate.
Change the reference frequency to 1.5 Hz or more.
• The sequence input method is wrong.
If the 3-wire sequence input mode is selected as an external terminal function instead
of the actual 2-wire sequence input mode, the motor will not run, in which case change
the constant or change to the sequence input that matches the constant setting.
H The Motor Does Not Operate when an External Run Signal is
Input.
• Operation mode is selected incorrectly.
If “0,” “2,” or “4” is set in n02, the motor does not operate when a run signal is input.
Always set “1,” “3,” or “5” in n02.
• The reference frequency is too low.
When the reference frequency is less than 1.5 Hz, the Inverter does not operate.
Change the reference frequency to 1.5 Hz or more.
H The Motor Stops during Acceleration or when a Load is
Connected.
• Load is too high.
The 3G3EV has a stall prevention function and full automatic torque boost function.
However, if acceleration or load is too high, the motor response limit will be exceeded.
To prevent this, increase acceleration time or reduce load. Motor capacity should be
also increased.
5-2-3 Motor Rotates in the Wrong Direction
• The motor output line is connected incorrectly.
If terminals U, V, and W on the Inverter are correctly connected to terminals U, V, and W
on the motor, the motor rotates in the forward direction when a forward rotation com-
mand is input. Since the forward direction of rotation depends on the motor manufac-
turer and model, check the motor specifications.
5-9
Operation
Chapter 5
To reverse the direction of rotation, switch the wires of two phases of U, V, and W as
shown below.
Inverter
Motor
Forward rotation
Reverse rotation
5-2-4 Motor Deceleration is Too Slow
H Deceleration Time is Too Long Even if a Braking Resistor is
Connected.
• Value 0 (stall prevention during deceleration) is set in n33.
When a braking resistor is connected, always set “1” (no stall prevention during decel-
eration) in n33. If “0” is set, the braking resistor will not be used.
• The deceleration time set in n21 is too long.
Check the deceleration time setting.
• Motor torque is insufficient.
If the constant settings are normal and overvoltage does not occur, motor capacity is
insufficient.
Motor capacity should be increased.
5-2-5 Vertical-axis Load Drops when Brakes are
Applied
• Sequence is incorrect.
The Inverter remains in DC braking status (50% of the n31 setting) for 0.5 second after
deceleration is complete. Modify the sequence so that brakes are applied when the
Inverter enters DC braking status.
• Brakes are inappropriate.
Always use control brakes, not holding brakes.
5-10
Operation
Chapter 5
5-2-6 Motor Burns
• The dielectric strength of the motor is insufficient.
Surge arises when the motor (inductive load) is connected to the output side of the
Inverter. Normally, the maximum surge voltage is approximately three times the power
voltage. Therefore, the dielectric strength of the motor to be used must be higher than
the maximum surge voltage.
It is recommended that motors specifically for Inverters be used, especially for the
400-VAC-class Inverters.
5-2-7 Controller Receives Noise when Inverter is
Started
• Noise derives from Inverter switching.
Take the following actions to prevent noise:
SReduce the carrier frequency of the Inverter.
The number of internal switching times is reduced, so noise can be reduced to
some extent.
SImprove the frame ground.
A current generated by internal switching normally leaks into the frame ground.
Therefore, connect the ground terminal with a sufficiently thick and short wire of 100
Ω or less.
SInstall an input noise filter.
Install an input noise filter (3G3IV-PHF) on the power input side of the Inverter.
SInstall an output noise filter.
Install an output noise filter (3G3IV-PLF) on the output side of the Inverter.
SProvide a separate power supply for the sensor.
If the sensor malfunctions, provide a dedicated power supply for the sensor and
install a noise filter on the power supply. For the signal line, use a shielded cable.
5-2-8 AM Radio Receives Noise when Inverter is
Started
• Noise derives from Inverter switching.
Take the following actions to prevent noise:
SReduce the carrier frequency of the Inverter.
The number of internal switching times is reduced, so noise can be reduced to
some extent.
5-11
Operation
Chapter 5
SInstall an input noise filter.
Install an input noise filter (3G3IV-PHF) on the power input side of the Inverter.
SInstall an output noise filter.
Install an output noise filter (3G3IV-PLF) on the output side of the Inverter.
SUse metal box and piping.
Metal can block off radio waves. Therefore, enclose the Inverter with a metal
(steel) box to prevent radio waves from being emitted from the Inverter.
5-2-9 Ground Fault Interrupter is Actuated when
Inverter is Started
• Leakage current flows through the Inverter.
Because switching is performed inside the Inverter, a leakage current flows through
the Inverter. This leakage current may actuate the ground fault interrupter, shutting the
power off.
Use a ground fault interrupter with a high leakage-current detection value (sensitivity
amperage of 200 mA or more, operating time of 0.1 second or more) or the one with
high-frequency countermeasures (for Inverter).
Reducing the carrier frequency value is also relatively effective.
Note also that a leakage current increases in proportion to the cable length. Normally,
an approximately 5 mA leakage current is generated per meter (cable length).
5-2-10 Mechanical System Makes Noise
• The carrier frequency and the natural frequency of the mechanical system resonates.
Take the following actions:
SAdjust the carrier frequency.
Adjusting the carrier frequency (n37) may prevent resonance from occurring.
SInstall vibration-proof rubber.
Install vibration-proof rubber on the motor base.
5-2-11 Motor Does Not Operate with EF Warning
• EF Warning (simultaneous input of forward and reverse commands) is a warning
alarm that is issued when forward and reverse commands are simultaneously input for
longer than 500 ms. Check the Inverter’s sequence input.
• The Inverter input may be set to the ON state due to the current leaked in from the con-
trol output.
5-12
Operation
Chapter 5
Under the wiring condition shown below, if the control output power supply is lower than
24 VDC or if it is set to OFF, current may flow in the direction shown by the arrows and
may operate the Inverter input. In such a case, insert a diode in the A section shown
below.
A section
24 V
SF
SR
S1 to
S3
3.3 K
360
0.1µ
SC
GND
5-3 Maintenance and Inspection
H Daily Inspection
While the system is operating, check the following items:
• Check the motor for noise.
• Check for abnormal heating.
• Check if the ambient temperature is too high.
• Check if the output current monitor display indicates a higher value than usual.
5-13
Operation
Chapter 5
H Regular Maintenance
Check the items below during regular maintenance.
Before starting inspection, always turn the power off, then wait at least one minute after
all indicators on the front panel go off. Touching terminals immediately after turning the
power off may cause an electrical shock.
• Check the terminal block screws for looseness.
• Check if electrically conductive dust or oil mist adheres to the terminal block.
• Check the Inverter set screws for looseness.
• Check if dust or dirt builds up on the heat sink (aluminum portion on the rear of the
Unit).
• Check if dust builds up in the air vents.
• Check if the appearance is normal.
• Check if the cooling fan for the control panel operates normally. (Check for noise or
abnormal vibration, and also check if the total hours of operation has exceeded the
value shown in the specifications.)
H Regular Parts Maintenance
An Inverter consists of many different parts. It can provide its full performance only when
these parts operate normally. Some electronic parts require maintenance depending on
the service conditions. To allow the Inverter to operate normally over an extended peri-
od of time, always perform regular inspection and parts replacement according to the
service life of each part.
Regular inspection intervals vary according to the Inverter installation environment and
service conditions.
The maintenance interval for this Inverter is shown below. Use this information as a
guide to regular maintenance.
The standard interval for regular maintenance is as follows:
Electrolytic capacitor: Approximately 5 years (8 hours of operation per day)
As for service conditions, it is assumed that the ambient temperature of the Inverter
is 40°C, and the Inverter is used under rated operating conditions (rated torque) and
is installed as specified in the User’s Manual.
To extend maintenance intervals, ambient temperatures should be lowered, and power-
on time should be minimized.
Note For the maintenance method, contact your nearest local sales representative.
5-14
6
Chapter 6
Specifications
6-1 Specifications of Main Unit
Specifications
Chapter 6
6-1 Specifications of Main Unit
H Rating
A2001(-j) A2002(-j) A2004(-j) A2007(-j) A2015(-j)
Model 3G3EV-
Three
phase,
200 VAC
Power
supply
Rated voltage
and frequency
Three-phase, 200 to 230 VAC, 50/60 Hz
Allowable
voltage
–15% to 10 %
fluctuation
Allowable
frequency
fluctuation
±5%
Heating value (W)
Weight (kg)
11.9
0.5
18.8
0.6
33.2
0.9
51.7
1.3
71.6
1.5
AB001(-j) AB002(-j) AB004(-j) AB007(-j) AB015(-j)
Single
phase/
Three
phase,
200 VAC
Model 3G3EV-
Power
supply
Rated voltage
Single-phase, 200 to 240 VAC, 50/60 Hz
and frequency Three-phase, 200 to 230 VAC, 50/60 Hz
Allowable
voltage
–15% to 10 %
fluctuation
Allowable
frequency
fluctuation
±5%
Heating value (W)
Weight (kg)
12.6
0.5
20.3
25.3
1.3
55.3
1.3
78.4
2.0
0.6
0.2
Maximum applicable motor
capacity (kW)
0.1
0.4
0.75
1.5
Output
specifi-
cations
Rated output capacity
(kVA)
Rated output current (A) 0.8
0.3
0.6
1.5
1.1
3.0
1.9
5.0
2.7
7.0
Rated output voltage
Three-phase, 200 to 230 VAC
(Corresponds to the input voltage)
Maximum output
frequency
Cooling method
400 Hz (Parameter setting)
Self-cooling
6-2
Specifications
Chapter 6
---
A4002(-j) A4004(-j) A4007(-j) A4015(-j)
Model 3G3EV-
Three
phase,
400 VAC
Power
supply
Rated voltage
and frequency
Three-phase, 380 to 460 VAC, 50/60 Hz
Allowable
voltage
–15% to 10 %
fluctuation
Allowable
frequency
fluctuation
±5%
Heating value (W)
Weight (kg)
---
---
25.5
1.0
34.7
1.0
56.0
1.5
78.5
2.0
Maximum applicable motor capacity ---
0.2 (0.37) 0.4 (0.55) 0.75 (1.1) 1.5 (1.5)
(kW)
Output
specifi-
cations
Rated output capacity
(kVA)
Rated output current (A)
Rated output voltage
---
---
0.9
1.2
1.4
1.8
2.6
3.4
3.7
4.8
Three-phase, 380 to 460 VAC
(Corresponds to the input voltage)
Maximum output
frequency
400 Hz (Parameter setting)
Cooling method
Self-cooling
H General Specifications
Installation type
Installation site
Panel mounting
Indoor (free from corrosive gases and dust)
Ambient temperature for
operation
–10° to 50°C
Humidity
90% or less (no-condensing)
Ambient temperature for storage –20° to 60°C
Altitude
1,000 m max.
Less than 20 Hz: 1G {9.8 m/s2} or less
20 to 50 Hz:
Vibration resistance
0.2G {1.96 m/s2} or less
Cable length between Inverter
and motor
100 m max.
6-3
Specifications
Chapter 6
H Control Characteristics
Control method
Sine-wave PWM method (automatic torque boost)
Frequency control
range
1.5 to 400 Hz
Frequency accuracy
(temperature
fluctuation)
Digital command:
±0.01% (–10°C to 50°C)
Analog command:
±1% (25 ±10°C)
Frequency setting
resolution
Digital command:
0.1 Hz (less than 100 Hz), 1 Hz (100 Hz or more)
Analog command:
0.06 Hz (60 Hz)
Frequency output
resolution
0.1 Hz (operation resolution)
Overload resistance
1 minute or less when 150% of rated output current is received
0 to 10 VDC (20 kΩ) or 4 to 20 mA (250 Ω)
Note This setting can be switched using the internal DIP switch.
Frequency setting
signal
Acceleration/Decelerati 0.0 to 999 seconds (acceleration and deceleration times are
on time
set separately)
Braking torque
(continuous
regenerative braking)
Approximately 20%
Note 125% to 220% when braking resistor is externally
installed.
Voltage/Frequency
characteristics
Simple V/f pattern setting
6-4
Specifications
Chapter 6
H Protection Functions
Motor protection
Electronic thermal protection
When 250% of the rated output amperage is exceeded
Instantaneous
overcurrent protection
Overload protection
When 150% of the rated output amperage is exceeded for one
minute
Overvoltage protection Stops the system when DC voltage of the main circuit exceeds
approximately 410 V (400-VAC Class approximately 820 V)
Voltage drop protection
3G3EV-A2jjj: Stops the system when voltage drops below
approximately 200 V
3G3EV-ABjjj: Stops the system when voltage drops below
approximately 160 V
3G3EV-A4jjj: Stops the system when voltage drops below
approximately 400 V
Protection from
instantaneous power
interruption
Stops the system when a power interruption lasts for 15 ms or
more.
Operation can be continued by setting constant No. 36 as
follows:
• Operation is continued if a power interruption only lasts for
approximately 0.5 second or less.
• Operation is continued unconditionally.
Radiation fin overheat Detects a fin temperature of 110 ±10°C
protection
Ground protection
Overcurrent level protection
6-5
Specifications
Chapter 6
H Operation Specifications
Three photocoupler input terminals (24 VDC, 8 mA)
Control input
• Forward/stop [SF]
• Reverse/stop [SR]
• Multi-function input [S1] (set in constant No. 06)
Select either of “fault reset,” “external fault,” and “multi-step
speed command.”
Note When 3-wire sequence mode (constant No. 01 = “9”) is se-
lected, the terminals become as follows:
• Run command [SF]
• Stop command [SR]
• Forward/reverse rotation command [S1]
One analog input terminal (0 to 10 VDC or 4 to 20 mA)
• Frequency reference input [Between FC and FR]
Control output
One SPDT relay contact output terminal [MA, MB]
(30 VDC and 1A; 250 VAC and 1A)
• Multi-function contact output (set in constant No. 09)
Select either of “fault occurrence,” “operation in progress,” and
“frequency matching.”
6-6
7
Chapter 7
Appendix A
7-1 Notes on Using Inverter for Motor
7-2 Frequency Reference by Amperage Input
7-3 List of Product Models
Appendix A
Chapter 7
7-1 Notes on Using Inverter for Motor
H Using Inverter for Existing Standard Motor
When a standard motor is operated with this Inverter, a power loss is slightly higher than
when operated with a commercial power supply.
In addition, cooling effects also decline in the low-speed range, resulting in an increase
in the motor temperature. Therefore, motor torque should be reduced in the low speed
range.
The figure on the right-hand side shows allowable load characteristics of a standard
motor.
If 100% torque is continuously required in the low-speed range, use a special motor for
use with Inverters.
Allowable Load Characteristics of Standard Motor
25% ED (or 15 minutes)
40% ED (or 20 minutes)
60% ED (or 40 minutes)
Continuous
Frequency (Hz)
D High-speed Operation
When using the motor at a high speed (60 Hz or more), note that problems may arise in
dynamic balance, bearing durability, and so on.
D Torque Characteristics
When the motor is operated with the Inverter, torque characteristics differ from when
operated with a commercial power supply. Check the load torque characteristics of the
machine to be used with the motor.
7-2
Appendix A
Chapter 7
D Vibration
The 3G3EV series employs high carrier PWM control to reduce motor vibration. When
the motor is operated with this Inverter, motor vibration is almost the same as when op-
erated with a commercial power supply.
However, motor vibration may become greater in the following cases:
• Resonance with the natural frequency of mechanical system
Take special care when a machine that has been operated at a constant speed is to
be operated in variable speed mode. If resonance occurs, install vibration-proof rub-
ber on the motor base.
• Imbalanced rotor
Take special care when the motor is operated at a high speed (60 Hz or more).
D Noise
Noise is almost the same as when the motor is operated with a commercial power sup-
ply. However, motor noise becomes louder when the motor is operated at a speed high-
er than the rated speed (60 Hz).
H Using Inverter for Special Motors
D Pole-changing Motor
The rated amperage of pole-changing motors differs from that of standard motors.
Select, therefore, an appropriate Inverter according to the maximum amperage of the
motor to be used. Before changing the number of poles, always make sure that the mo-
tor has stopped. Otherwise, the overvoltage protection or overcurrent protection mech-
anism will be actuated, resulting in an error.
D Submersible Motor
The rated amperage of submersible motors is higher than that of standard motors.
Therefore, always select an Inverter by checking its rated amperage. When the dis-
tance between the motor and the Inverter is long, use a cable thick enough to prevent
motor torque reduction.
D Explosion-proof Motor
When an explosion-proof motor or increased safety type motor is to be used, it must be
subject to an explosion-proof test in conjunction with the Inverter. This is also applicable
when an existing explosion-proof motor is to be operated with the Inverter. However,
since the Inverter itself is not explosion-proof, always install it in a safe place.
7-3
Appendix A
Chapter 7
D Gearmotor
The speed range for continuous operation differs according to the lubrication method
and motor manufacturer. In particular, continuous operation of an oil-lubricated motor in
the low speed range may result in burning. If the motor is to be operated at a speed high-
er than 60 Hz, consult with the manufacturer.
D Synchronous Motor
This motor is not suitable for Inverter control. If a group of synchronous motors is individ-
ually turned on and off, synchronism may be lost.
D Single-phase Motor
This motor is not suitable for Inverter control. It should be replaced with a three-phase
motor.
H Power Transmission Mechanism (Speed Reducers, Belts,
Chains, and so on)
If an oil-lubricated gearbox or speed reducer is used in the power transmission mecha-
nism, note that oil lubrication will be affected when the motor operates only in the low
speed range. Note also that the power transmission mechanism will make noise and
experience problems with service life and durability if the motor is operated at a speed
higher than 60 Hz.
7-2 Frequency Reference by Amperage Input
Frequency references can be input in terms of amperage (4 to 20 mA) by
changing the setting of the DIP switch inside the Inverter.
H Using the DIP Switch
1. Changing constant settings
Before using the DIP switch, always set “4” or “5” in constant no. 02 (operation mode
selection).
Note n02 = 4: Run commands are input through the Digital Operator, and frequency
references are input through control terminals.
n02 = 5: Both run commands and frequency references are input through control
terminals.
2. Turning power off
Turn the power off, wait at least one minute after all indicators on the front panel go
off, then perform the following tasks.
7-4
Appendix A
Chapter 7
3. Removing the Digital Operator
SInsert a finger in the recessed section below the Digital Operator, then lift the under-
neath of the Digital Operator.
SWhen the connector comes off, grip the lower edges of the Digital Operator, and
slide it down until it comes off.
4. Checking the DIP switch setting
The DIP switch is located in the lower part of the recessed section from which the
Digital Operator was removed.
7-5
Appendix A
Chapter 7
“SW1” is marked near the switch.
Switch indicator
V: Voltage input
I: Amperage input
DIP switch
5. Changing the DIP switch setting
To use amperage input mode, set this switch to ON by sliding it to the right.
(factory setting)
6. Reinstalling the Digital Operator
After changing the switch setting, reinstall the Digital Operator by reversing the re-
moval procedure. Make sure that the Digital Operator snaps in the connector.
CautionIf frequency references are input in terms of voltage, never change the DIP
switch setting (OFF). If voltage is input when the DIP switch is set to ON, the
resistor may burn, resulting in damage to the equipment.
7-6
Appendix A
Chapter 7
7-3 List of Product Models
H Inverter
Specifications
Model
Standard
models
Three-phase 200 VAC input
0.1 kW
0.2 kW
0.4 kW
0.75 kW
1.5 kW
3G3EV-A2001(-j)
3G3EV-A2002(-j)
3G3EV-A2004(-j)
3G3EV-A2007(-j)
3G3EV-A2015(-j)
Single/Three-phase 200 VAC input 0.1 kW
3G3EV-AB001(-j)
3G3EV-AB002(-j)
3G3EV-AB004(-j)
3G3EV-AB007(-j)
3G3EV-AB015(-j)
0.2 kW
0.4 kW
0.75 kW
1.5 kW
Three-phase 400 VAC input
Three-phase 200 VAC input
0.2 kW
0.4 kW
0.75 kW
1.5 kW
3G3EV-A4002(-j)
3G3EV-A4004(-j)
3G3EV-A4007(-j)
3G3EV-A4015(-j)
Multi-function
models
0.1 kW
0.2 kW
0.4 kW
0.75 kW
1.5 kW
3G3EV-A2001M(-j)
3G3EV-A2002M(-j)
3G3EV-A2004M(-j)
3G3EV-A2007M(-j)
3G3EV-A2015M(-j)
Single/Three-phase 200 VAC input 0.1 kW
3G3EV-AB001M(-j)
3G3EV-AB002M(-j)
3G3EV-AB004M(-j)
3G3EV-AB007M(-j)
3G3EV-AB015M(-j)
0.2 kW
0.4 kW
0.75 kW
1.5 kW
Three-phase 400 VAC input
Three-phase 200 VAC input
0.2 kW
0.4 kW
0.75 kW
1.5 kW
3G3EV-A4002M(-j)
3G3EV-A4004M(-j)
3G3EV-A4007M(-j)
3G3EV-A4015M(-j)
SYSMAC BUS
models
0.1 kW
0.2 kW
0.4 kW
0.75 kW
1.5 kW
3G3EV-A2001R(-j)
3G3EV-A2002R(-j)
3G3EV-A2004R(-j)
3G3EV-A2007R(-j)
3G3EV-A2015R(-j)
Single/Three-phase 200 VAC input 0.1 kW
3G3EV-AB001R(-j)
3G3EV-AB002R(-j)
3G3EV-AB004R(-j)
3G3EV-AB007R(-j)
0.2 kW
0.4 kW
0.75 kW
7-7
Appendix A
Chapter 7
H Braking Resistor (Duty Cycle 3% ED)
Specifications
Model
200-VAC class
0.1 kW/0.2 kW
0.4 kW/0.75 kW
1.5 kW
0.75 kW or less
1.5 kW
400 Ω
200 Ω
100 Ω
750 Ω
400 Ω
3G3IV-PERF150WJ401
3G3IV-PERF150WJ201
3G3IV-PERF150WJ101
3G3IV-PERF150WJ751
3G3IV-PERF150WJ401
400-VAC class
H Braking Resistor Unit (Duty Cycle 10% ED)
Specifications
Model
200-VAC class
400-VAC class
0.4kW/0.75 kW
1.5 kW
0.75 kW or less
1.5 kW
200 Ω, 70 W
100 Ω, 260 W
750 Ω, 70 W
400 Ω, 260 W
3G3IV-PLKEB20P7
3G3IV-PLKEB21P5
3G3IV-PLKEB40P7
3G3IV-PLKEB41P5
H AC Reactor (for Three-Phase)
Specifications
Model
0.1 to 0.4 kW
0.75 kW
2.5 A 4.2 mH
5 A 2.1 mH
10 A 1.1 mH
3G3IV-PUZBAB2.5A4.2MH
3G3IV-PUZBAB5A2.1MH
3G3IV-PUZBAB10A1.1MH
1.5 kW
H Input Noise Filter (for Three-Phase)
Specifications
Model
3G3IV-PHF3005AZ
3G3IV-PHF3010AZ
3G3IV-PHF3015AZ
0.1 to 0.4 kW
0.75 kW
5 A
10A
15 A
1.5 kW
H Output Noise Filter
Specifications
Model
0.1 to 1.5 kW
10 A
3G3IV-PLF310KA
H Variable Resistor Unit
Specifications
2 k Ω 0.5 W
Model
3G3EV
3G3EV-PETX3200
7-8
Appendix A
Chapter 7
H DIN Track
Specifications
Model
3G3EV-PSPAT3
3G3EV-PSPAT4
3G3EV-A2001(-j) to 3G3EV-A2004(-j)
3G3EV-AB001(-j) and 3G3EV-AB002(-j)
3G3EV-A2007(-j) to 3G3EV-A2015(-j)
3G3EV-AB004(-j) and 3G3EV-AB007(-j)
3G3EV-A4002(-j) to 3G3EV-A4007(-j)
7-9
Appendix A
Chapter 7
List of Constants Used with 3G3EV
Standard Model
Constant Indi-
no. cators
n01
Description
Setting range
Setting
Constant
write-inhibit
selection
/constant
initialization
0: Only n01 can be set.
1: All constants can be set.
8: Constant settings are initialized.
9: Inverter is initialized in 3-wire
sequence mode.
n02
Mode operation
selection
Run command
Frequency
reference
0
1
2
Digital Operator Digital Operator
Control terminal Digital Operator
Digital Operator Control terminal
(voltage input)
3
4
Control terminal Control terminal
(voltage input)
Digital Operator Control terminal
(amperage
input)
5
Control terminal Control terminal
(amperage
input)
Stop mode
selection
n03
n04
0: Deceleration stop
1: Free running
Forward
/Reverse
rotation
f%r: forward rotation
reU: reverse rotation
selection
n06
Multi-function
input selection
0: Forward/reverse rotation command
1: Fault reset
2: External fault (external fault when ON)
3: External fault (external fault when
OFF)
4: Multi-step speed command
0: Fault occurrence
1: Operation in progress
2: Frequency matching
n09
Multi-function
output selection
n11
n12
n20
Frequency
reference 1
0.0 to 400 (Hz)
[6.0]
[0.0]
Frequency
reference 2
0.0 to 400 (Hz)
Acceleration
time
0.0 to 999 (seconds)
[10.0]
7-10
Appendix A
Chapter 7
Constant Indi-
Description
Setting range
0.0 to 999 (seconds)
Setting
[10.0]
no.
cators
n21
Deceleration
time
n24
n25
n26
Maximum
frequency
50.0 to 400 (Hz)
[60.0]
Maximum
voltage
1 to 255 (V) (see note 1)
1.6 to 400 (Hz)
[200]
Maximum
voltage
[60.0]
frequency (basic
frequency)
n31
Electronic
thermal
0.0 to 120% of rated Inverter amperage
Specify the rated motor amperage.
reference
current
n33
n36
Stall prevention
during
deceleration
0: Stall prevention
1: No stall prevention
Operation after
recovery from
power
0: Discontinues operation.
1: Continues operation only if the power
interruption is within 0.5 second.
2: Continues operation unconditionally.
1: 2.5 (kHz) (see note 2)
2: 5 (kHz)
interruption
n37
Carrier
frequency
3: 7.5 (kHz)
4: 10 (kHz)
n39
n40
n61
n64
Frequency
reference gain
0.10 to 2.00 (times)
[1.00]
[0]
Frequency
reference bias
–99 to 99 (%)
Stop Key
selection
0, 1
0, 1
[0]
Operator’s
frequency
[0]
setting method
Note 1. The upper limit of setting range and the factory settings for the 400-VAC-class
Inverters are double the above values.
Note 2. The setting range of the 400-VAC-class Inverter is “1 to 5.” The factory setting of
the 3G3EV-A4015M-CUE is “3.”
Note 3. Values in shaded sections or values in brackets represent factory settings.
7-11
相关型号:
©2020 ICPDF网 联系我们和版权申明