Simphoenix E500 Series Universal Low Power Inverter

Product Information

Specifications

• Model: E500 Series Universal Low-Power Inverter
• Version: V1.3
• Revision Date: Jan. 2018

Product Introduction

1.1 Description of Inverter Model

The E500 Series Universal Low-Power Inverter is a versatile device designed to convert and control low-power electrical energy.

1.2 Model of Inverter Series

The E500 Series includes various models with different specifications to cater to different power requirements.

1.3 Product Appearance and Name of Components

The inverter features a compact and sturdy design with clearly labeled components for easy identification and operation.

1.4 Product Technical Indicators and Specifications

The inverter has specific technical indicators and specifications that define its performance capabilities and operating parameters.

Inverter Installation

2.1 Environmental Requirements

Prior to installation, ensure that the inverter is placed in a suitable environment that meets the specified requirements for temperature, humidity, and ventilation.

2.2 Installation Dimension of Inverters

The user manual provides detailed instructions on the correct dimensions and positioning for installing the inverter.

Operating Panel

4.1 Function Description of Keys

The operating panel of the inverter consists of various keys with specific functions. The user manual provides a comprehensive description of each key’s purpose.

4.2 Panel Operating Method

The user manual guides users on how to operate the inverter using the keys on the panel, including step-by-step instructions for different functions.

4.3 List of Status Monitoring Parameters

A list of status monitoring parameters is provided to help users monitor the inverter’s performance and diagnose any potential issues.

4.4 Simple Operation of the Inverter

A simplified operation guide is included in the user manual for users who prefer a quick and straightforward approach to operating the inverter.

Function Parameter Table

A comprehensive function parameter table is provided in the user manual, detailing various settings and configurations that can be adjusted to meet specific requirements.

Fault Diagnosis and Countermeasures

7.1 Protection Function and Countermeasures

The inverter is equipped with protection functions to prevent damage and ensure safe operation. The user manual provides information on these functions and corresponding countermeasures.

7.2 Fault Record Query

In case of any faults, the user manual offers instructions on how to query fault records for troubleshooting purposes.

7.3 Fault Reset

If a fault occurs, the user manual provides guidance on how to reset the inverter to resume normal operation.

Appendix I: Simphoenix Self-Defined Communication Protocol

The user manual includes an appendix that explains the self-defined communication protocol used by Simphoenix devices for communication purposes.

Precautions

Precautions of Unpacking Inspection

When unpacking the inverter, it is essential to inspect for any transportation damage or component damage. Verify that the model and specifications on the inverter nameplate match your order.

Nameplate of the Inverter

The inverter body has a nameplate indicating the model, rated parameters, and serial number of the inverter.

Label on the Outer Box

The outer box of the inverter has a label with information such as the model, rated input voltage, net weight, gross weight, volume, and serial number.

Weight and Dimension

The user manual provides the net weight and gross weight information for different models of the E500 Series Universal Low-Power Inverter.

FAQs

• Q: How do I reset the inverter after a fault occurs?
  • A: To reset the inverter after a fault, follow the instructions provided in section 7.3 of the user manual.
• Q: Where can I find the list of status monitoring parameters?
  • A: The list of status monitoring parameters can be found in section 4.3 of the user manual.
• Q: How do I query fault records for troubleshooting?
  • A: Instructions on how to query fault records can be found in section 7.2 of the user manual.

Preface

Thanks for choosing the E500 series universal low-power inverter produced by Shenzhen Simphoenix Electric Technologies Co., Ltd. This Manual is the operating manual for E500 series universal low-power inverters. It provides all relevant instructions and precautions for installation, wiring, functional parameters, daily care and maintenance, fault diagnosis and troubleshooting of E500 series inverters. In order to use this series of inverters correctly, guarantee product’s best performance and ensure safety of users and equipment, be sure to read this manual carefully before using E500 series inverters. Improper use may cause abnormity and malfunction of the inverter, reduce its service life and even damage equipments and lead to personal injury and death etc. This user manual is delivered with the device. Please keep it properly for future overhaul and maintenance. Owing to constant improvement of products, all data may be changed without further notice.
SHENZHEN SIMPHOENIX ELECTRIC TECHNOLOGY CO., Ltd.
User Manual of E500 Series Universal Low-Power Inverter Version V1.3 Revision Date: Jan. 2018

Precautions I

Precautions

E500 series universal low-power inverters are applicable to general industrial three-phase AC asynchronous motors. If this inverter is used for equipment which is failed and may cause personal injury (e.g. nuclear control system, aviation system, safety equipment and instruments), please take care and consult with the manufacturer; if it is used for dangerous equipment, that equipment should be provided with safety protecting measures to prevent accident expansion in the case of inverter failure. The inverter is produced under strict quality assurance system. However, in order to protect your personal safety and equipment and property safety, before using this inverter, please read this chapter carefully and conduct transportation, installation, operation, commissioning and inspection according to relevant requirements.

1. Precautions of unpacking inspection

When unpacking, please confirm if

(1) There is any damage during transportation and any components are damaged

or dropped.

(2) The model and specifications stated on the inverter nameplate is consistent

with your order. If there is any omission or damage, please contact your

supplier promptly.

Nameplate of the inverter

On the left side of the inverter body, there is a nameplate marked with the

model and rated parameters of the inverter.

TYPE SOURCE OUTPUT SERIAL No.

E500-2S0007 1PH 220V 50/60Hz
1.9KVA 5.0A XXXXXXXXXX

Inverter model Rated input voltage phase, voltage and frequency Rated output capacity and current Product serial number

Shenzhen Simphoenix Electric Technology Co.,Ltd

Bar code

Label on the outer box

TYPE: SOURCE: NET WEIGHT: GROSS WEIGHT: VOLUME: SERIAL No.:

E500-2S0007 1PH 220V 50/60Hz
0.82 KG 1.0 KG 195115175(mm) XXXXXXXXXX

Inverter model Rated input voltage phase, voltage and frequency Net weight Gross weight Volume Serial number

Shenzhen Simphoenix Electric Technology Co.,Ltd

Bar code

E500 Series Universal Low-Power Inverter

II Precautions

Weight and dimension

Model
E500-2S0004(B) E500-2S0007(B) E500-4T0007(B) E500-4T0015(B)/E500-2S0015(B) E500-4T0022(B)/E500-2S0022(B) E500-4T0030(B)/E500-2S0030(B) E500-4T0040(B)/E500-2S0040(B) E500-4T0055/ E500-4T0075 E500-2S0055/ E500-2S0075
E500-4T0090

Net weight (KG)
0.8 0.8 1.4 1.4 1.4 1.9 1.9 3.2
4.3 4.3

Gross weight (KG)
1.0 1.0 1.6 1.6 1.6 2.2 2.2 3.7
4.8 4.8

Outer box dimension(mm)
195×115×175 195×115×175 223×135×195 223×135×195 223×135×195 270×160×215 270×160×215 300×185×220
370×245×240 370×245×240

We have strict quality assurance system for the products in terms of manufacturing, packing and transportation. In case of any careless omission, please contact us or local agent immediately. We will address the problem at first time.

2. Safety precautions
In this manual, the wordings of “Danger” and “Caution” are defined as below.

Danger: Serious damage to the equipment or personal injuries may be caused if operating without following requirements.

Caution: Moderate injuries or minor injuries of personnel and material loss may be caused if operating without following requirements.
2.1 Installation 1. The inverter shall not be installed on combustibles. 2. The frequency inverter shall not be installed at places with direct sunlight. 3. The frequency inverter of this series shall not be installed in the environment
of explosive gases, for fear of the danger of explosion. 4. No foreign matter is allowed to be dropped into the frequency inverter, for
fear of causing fires or injury. 5. During installation, the frequency inverter shall be installed at the place able
to bear its weight; otherwise, it may fall down or damage properties.
E500 Series Universal Low-Power Inverter

Precautions III
The inverter shall not be dismantled or modified without authorization. 2.2 Wiring 1. Wire diameter shall be selected according to applicable electric code, and
wiring shall be done by qualified technicians. 2. Wiring shall not be started unless the power supply of the inverter is
completely disconnected. 3. The grounding terminal of the inverter must be reliably grounded; otherwise,
there can be a danger of electric shock. 4. Before wiring, make sure the power supply has been disconnected for over
10minutes; otherwise, there may be a danger of electric shock. 5. The electronic elements in the inverter is quite sensitive to static electricity,
hence no foreign articles shall be placed into the inverter or contact the main board.
No alternating current power supply is allowed to be connected onto the U, V, and W of the inverter.
2.3 Maintenance
Wiring, inspection and other maintenance work shall not be done until the power supply is disconnected for 10 minutes.
3. Precautions of use
In this manual, the wordings of “Tip” and “Attention” are defined as below:
Tip: To give some useful information.
Attention: To indicate any precautions during operation.
1. The inverter shall be installed in the place with good ventilation.
E500 Series Universal Low-Power Inverter

IV Precautions 2. The motor’s temperature can be a little higher than that of industrial frequency
power during operation of the inverter, which is abnormal. 3. With long-term operation at low speed, the operation life of motor can be
affected due to the poorer heat dissipation effect. In this case, special frequency inverter shall be selected or the motor’s load shall be decreased. 4. When the altitude is over 1000m, the inverter shall be derated. Increase of altitude for every 1500 m shall be ground for derating by 10%. 5. If the operating environment is beyond the allowed conditions of the inverter, please consult the manufacturer.
The inverter’s output terminal shall not be connected to any filter capacitor or other RC absorption equipment.
4. Scrapping precautions
Following attentions shall be paid when the inverter and its components are abandoned. Explosion of the electrolytic capacitor: electrolytic capacitor in the frequency inverter may cause explosion while burning. Waste gas from plastic burning: harmful and toxic gas may be produced during combustion of plastic and rubber products of the inverter. Disposal: please dispose of inverters as industrial wastes.
5 To prevent the drive from demaged
1: please observe the (ESD) electrostatic prevention regulations while using the product,otherwise the static electricity might cuase some damage of the inner components. 2: do not try to do withstand voltage test on any part of the inverter because we are using some precision components like EMC and lighting protection design, they will have a highly chance causing performance degradation or even broken.
E500 Series Universal Low-Power Inverter

Product Introduction

1.1 Description of inverter model

Product Introduction 1

1.2 Model of inverter series

Inverter model

Rated capacity (KVA)

Rated output current (A)

Adaptive motor power
(KW)

E500-2S0004(B)

1.1

3.0

0.4

E500-2S0007(B)

1.9

5.0

0.75

E500-2S0015(B)

2.9

7.5

1.5

E500-2S0022(B)

3.8

10.0

2.2

E500-2S0030(B)

5.3

14.0

3.0

E500-2S0040(B)

6.3

16.5

4.0

E500-4T0007(B)

1.6

E500-4T0015(B)

3.0

E500-4T0022(B)

3.6

E500-4T0030(B)

5.0

2.5

0.75

4.5

1.5

5.5

2.2

7.5

3.0

E500-4T0040(B)

6.3

9.5

4.0

E500-2S0055

9.5

25

5.5

E500-2S0075

12.6

33

7.5

E500-4T0055

8.6

13.0

5.5

E500-4T0075

11.2

17.0

7.5

E500-4T0090

13.8

21.0

9.0

1.3 Product appearance and name of components

Operating panel Housing

Control loop cable inlet Main loop cable inlet Bottom installation hole Bottom guide rail fastener

Figure 1-1 Appearance and Part Name of Category I Inverters Applicable models: E500-2S0004 (B) / E500-2S0007 (B)

E500 Series Universal Low-Power Inverter

Product Introduction

Operating panel Housing
Control loop cable inlet Main loop cable inlet Bottom installation hole Bottom guide rail fastener

Operating panel Housing Control loop cable inlet Main loop cable inlet Bottom installation hole

Figure 1-2 Appearance and Component Name of Category Inverters Applicable models: E500-2S0015(B)E500-2S0022(B)/ E500-4T0007(B)E500-4T0022(B)

Figure 1-3 Appearance and Component Name of Category III Inverters Applicable models: E500-2S0030(B)E500-2S0040(B)/ E500-4T0030(B)E500-4T0040(B)

Operaing panel Upper shell Lower shell Lower looer Control loop cable inlet
M ain loop cable inlet Bottom installation hole

Operaing panel Upper shell Lower shell Lower looer Control loop cable inlet
Main loop cable inlet
Bottom installation hole

Figure 1-4 Appearance and Component Name of Category IV Inverters Applicable models: E500-4T0055E500-4T0075/ E500-2S0055

Figure 1-4 Appearance and Component Name of Category V Inverters Applicable models: E500-2S0075/ E500-4T0090

1.4 Product technical indicators and specifications Power range of E500 series: E500-2S0007~ E500-2S0075/E500-4T007~ E500-4T0090 Technical index and typical function of E500 series

E500 Series Universal Low-Power Inverter

Product Introduction 3

Input

Rated voltage, frequency
Allowed variation range of voltage

Three phase (4T# series) Single phase (2S# series)

380V 50/60Hz

220V 50/60Hz

300V ~ 460V

180V ~ 260V

Voltage

0 ~ 380V

0~220V

Output

Frequency Overload capacity

Control mode

Frequency Analog

set

terminal input

resolution Digital setting

0.0~400Hz 110%–long term; 150%–1 minute; 180%–2 second VVVF space voltage vector /SVC (open loop vector) control
0.1% of the maximum output frequency
0.1Hz

Control Frequency Analog input

Characte- precision Digital input

ristics

V/F curve

(Voltage frequency

characteristics )

Torque increase

Within 0.1% of the maximum output frequency Within 0.1% of the set output frequency
Reference frequency can be set within 5400Hz, and multi-node V/F curve can be randomly set.
Manual setting: 0.020.0% of rated output.

Automatic current limiting and voltage limiting

Control Characte-
ristics

Under voltage limiting during running

Multispeed cont0rol

Optional built-in PID controller

RS485 communication and linkage control

Typical functions Frequency
setting

Analog input
Digital input

Output signal

Relay and OC output
Analog output

Automatically detect motor’s stator current and voltage and control it within allowable range according to special algorithm, regardless of any running process like acceleration, deceleration or static running.
Especially for users of low-grid voltage and frequently fluctuating grid voltage. Even within the voltage range lower than allowable value, the system can maintain longest running time according to special algorithm and residual capacity distribution strategy.
7-section programmable multispeed control and 5 kinds of running modes available for selection
Internal integrated optimized PID controller, allowing for simple closed-loop control.
SIMPHOENIX user-defined protocol or MODBUS protocol.
DC voltage 0-10V, and DC current 0-20mA (optional)
Operating panel setting, potentiometer setting, RS485 port setting, UP/DW terminal control, and multiple combined setting with analog input.
One channel OC output and One channel relay output (TA, TC), with up to 16 kinds of optional meanings.
One channel 0-10V voltage signal, and upper and lower limit can be set.

E500 Series Universal Low-Power Inverter

Product Introduction

Automatic voltage regulation running

Setting of acceleration and deceleration time Timer
Running function

Display of

Display operation panel

Running status
Alarm content

Three kinds of voltage regulation modes including dynamic, static and none are available for selection according to different requirements, so as to achieve most stable running effect.
0.1600.0Sec continues setting, and deceleration and acceleration curve S type and liner mode are optional.
One built-in timer
Setting of upper and lower limiting frequency, REV running limiting, RS485 communication, and control of progress increase and decrease of frequency, etc.
Output frequency, output current, output voltage, motor revolution, set frequency, module temperature, analog input and output and so on.
The nearest 4 times of fault records, five items of running parameter records at the time of latest fault trip including, the output frequency, output current, output voltage, DC voltage and modular temperature.

Protection/alarm function

Over current, overvoltage, under voltage, overheat, short circuit, internal memory fault, etc

Surrounding temperature

Surrounding humidity

Environment

Surrounding environment

Altitude

Protecting grade

Cooling mode

Installation mode

-10ºC to +40ºC (no freezing)
90% below (no frosting) Indoor (Free of direct sunlight, corrosion, flammable gas, oil mist and dusts) Below 1000m IP20 Forced air cooling Rail type /wall- mounted

E500 Series Universal Low-Power Inverter

Inverter Installation 5
2 Inverter Installation
2.1 Environmental requirements This series of inverters are wall-mounted products and shall be vertically installed to facilitate air circulation and heat dissipation. Following attentions shall be paid for selecting installation environments.
1. The ambient temperature shall be within -1040. High-temperature and humid places shall be avoided, and the inverter shall be better placed in a place with humidity lower than 90% and without frosting.
2. Direct sunshine should be avoided. 3. The inverter should be away from flammable, explosive and corrosive
gas and liquid. 4. The environment should be free of dust, floating fibers and metal
particles. 5. The installation surface should be solid without ventilation. 6. The inverter should be away from electromagnetic
interference sources. 7. Please install the cover board of cooling holes if there is too much
powder in the using environment. (Refer to Fig 2-1-A).
cover board of cooling holes
Fig 2-1-A Installation for cover board of cooling holes
If you have any special installation requirements, please contact us in advance. See Figure 2-1-Bfor installation spacing and distance requirement for single inverter. Enough space should be leaved around the inverter. For installation of multiple inverters, baffle plate should be applied between inverters to ensure good heat dissipation, as shown in Figure 2-1-C.
E500 Series Universal Low-Power Inverter

Inverter Installation

Fan exhaust

120mm

120mm above

50m5m0mm above

! WARNING
1.Refer to the instruction manual before installation and operation.
2.Do not connect AC power to output terminals UVW. 3.Do not remove any cover while applying power
and at least 10min. after disconnecting power. 4.Securely ground(earth) the equipment.

5500mmmm above

Inverter

Baffleplate

Inverter

120mm

120mm above

Figure 2-1-B Installation Spacing Distance

Figure 2-1-C Installation of Multiple Inverters

2.2 Installation dimension of inverters 2.2.1 Installation dimension of inverters

W

D

W1

E500

H1 H

Figure 2-2-A Inverter Installation Dimension 1 Applicable models: E500-2S0004 (B) ~E500-2S0007 (B), shown in Figure 2-2-A

E500 Series Universal Low-Power Inverter

Inverter Installation 7

W

D

W1

H

H1

E500

2S0015

Figure 2-2-B Inverter Installation Dimension 2
Applicable models: E500-2S0015 (B) ~2S0040 (B)/E500-4T0007 (B) ~4T0040 (B), As shown in Figure 2-2-B.

D

W

H1

W

W1

Figure 2-2-C Inverter Installation Dimension 3 Applicable models: E500-2S0055 (B) / E500-4T0055~4T0075, As shown in Figure 2-2-C.
E500 Series Universal Low-Power Inverter

8 Inverter Installation

D

W

W1

H1 H

Figure 2-2-D Inverter Installation Dimension 4

Applicable models: E500-2S0075 (B) / E500-4T0090, As shown in Figure 2-2-D.

The specific installation dimensions of E500 series inverters are shown in following table:

Inverter model (three-phase
380V)
–
–

Inverter model (single-phase W1
220V)
E500-2S0004(B) 67.5
E500-2S0007(B)

W H1 H

D

Screw specification

81.5 132.5 148 134.5

M4

E500-4T0007(B)

–

E500-4T0015(B) E500-2S0015(B) 86.5 101.5 147.5 165 154.5

M4

E500-4T0022(B) E500-2S0022(B)

E500-4T0030(B) E500-2S0030(B)

100 110 190 205 169.5

M5

E500-4T0040(B) E500-2S0040(B)

E500-4T0055 E500-4T0075

–

135 121 248 234 186

M4

E500-4T0090

E500-2S0055 E500-2S0075

160 146 275 261 190

M5

E500 Series Universal Low-Power Inverter

2.2.2 Installation dimensions of optional
60.7

Inverter Installation 9
41.1 28.8 17.6

68.7
62.2 25.5 16.4 58.7

Figure 2-2-E Small Keyboard Installation Dimension
36.7 17.6
20.7
Figure 2-2-F Installation Dimension of Small Keyboard Base Note: Assemble with M3 screws and pay attention to the whole site and opening dimension within the dotted lines.
72

17.3 80

85

21.4

69
Figure 2-2-G Installation Dimension of Small Keyboard Base E500 Series Universal Low-Power Inverter

80.5

10 Inverter Installation 69.5
Figure 2-2-H Opening Dimension of Small Keyboard Base Note: See Figure 2-2-F for the recommended opening dimension of small keyboard base
E500 Series Universal Low-Power Inverter

Inverter Wiring 11

Inverter Wiring

3.1 Wiring precautions (1) Make sure intermediate circuit breaker is connected between the
frequency inverter and power supply to avoid expanded accident when the frequency inverter is faulty. (2) In order to reduce electromagnetic interference, please connect surge sorber on the coil of electromagnetic contactor, relay and etc. in the surrounding circuit of the frequency inverter. (3) Please use shielded wire of above 0.3mm² for the wiring of such analog signals as frequency setting terminal AI and instrument loop (AO), etc. The shielding layer shall be connected on the grounding terminal E of the frequency inverter with wiring length less than 30m. (4) The stranded wire or shielded wire of above 0.75mm² shall be selected for the wiring of input and output loop (X1-X4) of relay; and the shielded layer shall be connected to the common port CM of control terminals, with wiring length less than 50m. (5) The control wire shall be separated from the power line of major loop; it shall be at a distance of above 10cm for parallel wiring and vertical for cross wiring. (6) The connecting wire between the inverter and the motor shall be less than 30m; and when it is longer than 30m, the carrier frequency of the inverter shall be appropriately reduced. (7) All leading wires shall be fully fastened with terminals to ensure good contact. (8) The pressurization of all the leading wires shall be in compliance with the voltage class of the frequency inverter.
Absorption capacitor or other RC absorbers shall not be installed at U, V and W output end of the frequency inverter, as shown in figure 3-1.
E500 Series Universal Low-Power Inverter

12 Function Parameter Table
U Inverter V
W

Motor
M
RCabsorber

Figure 3-1 Forbidding connecting a RC absorber at the output terminal

3.2 Wiring of peripheral elements

Brakingresistor

AsAuCCppPlyower

PP R/L1

PB U

S/L2
E550

T Air switch Contactor AC reactor
AC

! WARNING 1.R efer to the instructi on manual beforeinstallation and operati on. 2.D o not connect AC power to output terminalsU VW. 3.D o not remove any cover whil e appl ying power and at least10min. after disconnecting power. 4.Securel yground(earth) the equi pment.
EE550500

Figure 3-2 Inverter Wiring

V W
Motor

Power supply The inverter shall be provided with power in accordance with specification of input power supply designated by this operating manual
Air switch 1) When the frequency inverter is maintained or not in use for a long time, the air switch will separate the frequency inverter from the power supply; 2) When the input side of the frequency inverter has failures like short circuit, the air switch can provide protection.

E500 Series Universal Low-Power Inverter

Inverter Wiring 13

Contactor

It can conveniently control power-supply and power disconnection of the

inverter, and the power-on and power-off of the motor.

AC reactor

1. To promote power factor;

2. To reduce harmonic input of the inverter against the grid;

3. Weaken influenced caused by unbalanced voltage of three-phase power

supply.

Brake resistance

When the motor is at the dynamic braking status, it can avoid producing over

high pumping voltage in the DC loop.

Recommended specifications are shown in following table:

Inverter model
E500-2S0004 E500-2S0007 E500-2S0015 E500-2S0022 E500-2S0030 E500-2S0040 E500-4T0007 E500-4T0015 E500-4T0022 E500-4T0030 E500-4T0040 E500-2S0055 E500-2S0075 E500-4T0055 E500-4T0075 E500-4T0090

Adaptive motor (KW) 0.4 0.75 1.5 2.2 3.0 4.0 0.75 1.5 2.2 3.0 4.0 5.5 7.5
5.5 7.5 9.0

Wire specification (main loop) (mm2) 1.5 2.5 2.5 4.0 6.0 6.0 1.0 1.5 2.5 3.0 4.0 10 10
6 6 10

Air circuit breaker (A) 16 20 32 32 40 40 10 16 16 20 32 63 80
32 40 50

Electromagnetic contactor (A) 6 12 18 18 32 32 6 12 12 18 18 32 45
22 32 32

E500 Series Universal Low-Power Inverter

14 Function Parameter Table

Main loop screw specification/ tightening torque, as listed below

VFD model E500-2S0004

Screw specification
M3.5

Tightening torque N*m
0.7~0.9

Recommended lug model no PTV1.25-9

E500-2S0007

M3.5

0.7~0.9

PTV2-9

E500-2S0015

M3.5

0.7~0.9

PTV5.5-13

E500-2S0022

M3.5

0.7~0.9

PTV5.5-13

E500-2S0030

M3.5

0.7~0.9

PTV5.5-13

E500-2S0040

M3.5

0.7~0.9

PTV5.5-13

E500-4T0007

M3.5

0.7~0.9

PTV1.25-9

E500-4T0015

M3.5

0.7~0.9

PTV1.25-9

E500-4T0022

M3.5

0.7~0.9

PTV2-9

E500-4T0030

M3.5

0.7~0.9

PTV5.5-13

E500-4T0040 E500-2S0055 E500-2S0075 E500-4T0055 E500-4T0075

M3.5 M4 M4 M4 M4

0.7~0.9 1.2~1.5 1.2~1.5 1.2~1.5 1.2~1.5

PTV5.5-13 RNY5.5-4S RNY5.5-4S RNY5.5-4S RNY5.5-4S

E500-4T0090

M4

1.2~1.5

RNY5.5-4S

General control board/extension card connection terminal

General control terminal
control board/extension card terminal
control board/extension card terminal

Screw specification
M2
M3

Tightening torque(N*m)
0.1~0.2
0.3~0.4

Recommended lug model no E0.5-6
E0.75-6

Lug model no PTV1.25-9

PVT/E series

PTV2-9 PTV5.5-13
E0.5-6

E0.75-6

W(mm) F(mm) L(mm) H(mm) d1(mm) D(mm) T(mm)

1.9

9

19

10

1.7 4.2 0.8

1.9

9

19

10

2.3 4.7 0.8

2.8

13

26

13

3.4

6.5

1

1.1

6

12

6

1

2.6

/

1.1

6

12.3 6.3

1.2

2.8

/

E500 Series Universal Low-Power Inverter

Inverter Wiring 15

W

T

F

L

H

d1 D

PVT/E series

Lug model no d2mm) W(mm) F(mm) L(mm) H(mm) d1(mm) D(mm) T(mm)

RN

RNY

4.3

7.2

5.9 22.5

13

3.4

6.7

1

series 5.5-4S

W

d2

T

F

L

H

d1 D
RNY series

E500 Series Universal Low-Power Inverter

16 Function Parameter Table
3.3 Basic wiring

Three-phase circuitbreaker

×

R

Three-phase power supply

×

S

×

T

X1

X2

Pinrpougtratemrmmianballe

X3 X4

CM

E

0~01~01V0(V0~200~m2A0)mA Frequencysetting

VS AI GND

U

Motor

V W

M ~

E

To earth

Ta

Tc Failure alarm output

PP

To braking resistor

PB

24V AuxiliaryDCpower supply

AO GND

Voltmet0e~r (100-1V0V)

Open-circuit OC collector output

CM

Figure 3-3 Basic Wiring of Inverter

E500 Series Universal Low-Power Inverter

Inverter Wiring 17

3.4 Wiring of main loop terminal Category I main loop terminal Applicable models : E500-2S0004(B)E500-2S0007(B)

L1 L2 PB PP E U V W

Earthing Braking resistor P2o2w0eVr supply input

Motor

Symbol PP PB
L1, L2 U, V, W
E

Function DC side voltage positive terminal Braking resistor can be connected between PP and PB To grid single-phase AC 220V power supply To three-phase AC 220V motor
Earthing terminal

Category II main loop terminal Applicable models : E500-2S00015(B)E500-2S0022(B) &
E500-4T00007(B)E500-4T0022 (B)

L1 L2 R S T PP PB U V W E

Brakingresistor / SPionwgeler-spuhpapsley/thinrpeeu-tphase

Moto

Earthing

Symbol PP PB
L1 , L2 , T RS
U, V, W E

Function
DC side voltage positive terminal Braking resistor can be connected between PP and PB
To grid single-phase AC 220V/ three-phase 380V power supply
To three-phase AC 220V/380V motor Earthing terminal

Category III main loop terminal Applicable models : E500-2S0030 (B)~E500-2S0040(B) &
E500-4T00030(B)~E500-4T0040(B)

L1 L2 PP PB R S T E U V W

Earthing Braking resistor Single-ph/ase/three-phase
Power supply input

Motor

Symbol PP
PB L1 , L2 , T RS U, V, W
E

Function
DC side voltage positive terminal Braking resistor can be connected between PP and PB
To grid single-phase AC 220V/ three-phase 380V power supply
To three-phase AC 220V/380V motor
Earthing terminal

E500 Series Universal Low-Power Inverter

18 Function Parameter Table Category IV main loop terminal

Applicable models : E500-4T0055E500-4T0075

RST E U V W

E a rth in g
Three-phase power supply input

M otor

Symbol RST UVW
E

Function To grid three-phase 380V power supply To three-phase 380V motor
Earthing terminal

Category V main loop terminal Applicable models : E500-2S0055E500-2S0075 & E500-4T0090

L1 L2 R S T E UVW

Earthing
Single-phase/three phase power supply input

Motor

Symbol L1 L2 T RS UVW
E

Function To grid single-phase AC 220V/ three-phase 380V power supply To three- phase AC 220V/380V motor
Earthing terminal

3.5 Wiring of control loop terminal (1) Diagram of control loop terminal

Voltage/current input jumper terminal

(2) Function description of control loop terminal

Type Power supply Analog input

Terminal symbol

Terminal function

Remarks

VS

Externally providing +10V (0~20mA) power supply

–

External providing +24V

24V (0~50mA) power supply

–

(CM terminal is the power

gVroalntadg)e. signal input terminal

AI (when jumper terminal is

Input range : 0~10V

connected to V terminal)

E500 Series Universal Low-Power Inverter

GND X1 X2 Control terminal X3
X4

Analog output AO

OC output

OC

Programmable TA

output

TC

RS+ Communication
RS-

Inverter Wiring 19

Current signal input terminal (when jumper terminal is connected to A terminal)
Common port of analog input signal (VS power grand)
Multifunctional input terminal 1
Multifunctional input terminal 2
Multifunctional input terminal 3
Multifunctional input terminal 4

Input range : 0~20mA
–
The specific function of multifunctional input terminal is to be set by parameter [F1.08] ­ [F1.11], effective when the terminal and CM end is closed. X4 has function of pulse width speed adjusting (function code F1.11=0), and PWM wave period is set by F0.23.

Programmable voltage signal output terminal (external voltage meter (set by [F1.05]

Voltage signal output 0-10V

Programmable open-circuit collector output, set by
parameter [F1.13]

Maximum load current 150mA and maximum withstanding voltage 24V.

TA-TC normally open;
When TA-TC is closed, effective when parameter [F1.14] selects output.

Contact capacity:
AC 250V, 1A resistive load

485 communication port

–

485 communication port

–

E500 Series Universal Low-Power Inverter

20 Function Parameter Table

Operating Panel

Runningindicator Digitaldisplay
Return UP Setting

RUN Hz
MIN
ESC
SET

V A MAX
RUN STOP

Digitaldisplay data unit sec
% rmp Panel potentiometer
Shift
Run,stop, restore

Down
Figure 4-1 Operating Panel Sketch
Note: E500 series keyboard port can be compatible with SIMPHOENIX E300 and E310 series, and other series keyboard is not compatible. Do not make confusion.

4.1 Function description of keys

Keys Digital display A, Hz, V RUN
ESC
SET

Function Description
Display the current operating status parameters and setting parameters of the frequency inverter. Display the measurement unit corresponding to the main digital display data. Operating indicator, indicating the inverter is running, and there is output voltage at the output terminals U, V and W. Data modification key. It is used to modify functional code or parameters. At the status monitoring mode, if the frequency command channel is at the digital setting mode ([F0.00]=0), press this key to directly modify the frequency set value. Back key. At the normal monitoring mode, press this key to enter the non-normal monitoring mode/monitoring parameter inquiry mode to see the operating status parameters of the inverter. At any other operating status, separately press this key to back to the previous status.
Set key. Confirm the current status or parameter (parameters are stored in the internal memorizer) and enter the next function menu.

E500 Series Universal Low-Power Inverter

Operating Panel 21

Keys

Function Description

RUN STOP

RUN/STOP command key. When the command channel selects control panel ([F0.02] =###0), this key is effective. The key is a trigger key. When the inverter is at the stop status, press this key to input stop command to stop running. At the inverter fault status, this key is also used as the fault reset key.

Shift key. When modifying data with any data modification key, press

this key to select the data digit to be modified, and the selected digit will

flash.

Panel potentiometer. When the inverter’s running frequency is set by the

potentiometer on the operating meter (F0.00=3), rotate the potentiometer

M IN

M A X knob counterclockwise to decrease running frequency, and rotate it

clockwise to increase running frequency.

4.2 Panel operating method (1) Status parameter inquiry (example)

E500 Series Universal Low-Power Inverter

22 Function Parameter Table (2) Parameter inquiry and modification (example)

4.3 List of status monitoring parameters

Monitoring code

Content

Unit

d-00

Inverter’s current output frequency

Hz

d-01

Inverter’s current output current (effective value)

A

d-02

Inverter’s current output voltage (effective value)

V

d-03

Motor revolution

rpm

d-04

Voltage at the DC terminal in the inverter

V

d-05

Inverter’s input AC voltage (effective value)

V

d-06

Set frequency

Hz

d-07

Analog input AI

V

d-08

Running liner speed

d-09

Set liner speed

E500 Series Universal Low-Power Inverter

Monitoring code d-10 d-11 d-12 d-13 d-14 d-15 d-16 d-17 d-18 d-19 d-20 d-21 d-22 d-23 d-24 d-25 d-26 d-27 d-28 d-29 d-30 d-31

Operating Panel 23

Content

Unit

Input terminal status

Module temperature

ºC

Analog output AO

V

Timer value

Reserve

Reserve

Reserve

Reserve

Reserve

Reserve

Reserve

Reserve

Reserve

First fault record

Second fault record

Third fault record

Forth fault record

Output frequency at the time of recent fault

Hz

Output currency at the time of recent fault

A

Output voltage at the time of recent fault

V

DC voltage at the time of recent fault

V

Module temperature at the time of recent fault

4.4 Simple operation of the inverter

4.4.1 Initial setting

(1) Channel selection for frequency input ([F0.00])

Inverter’s initial setting varies from each other according to different models.

When the parameter is set to 0, the inverter’s frequency setting will be set

through the panel digit.

(2) Selection of running command input channel ([F0.02])

The inverter’s initial setting varies according to different models. When this

parameter is set to [F0.02] =###0, the inverter’s start and stop control will be

completed through

RUN STOP

key on the operating panel.

E500 Series Universal Low-Power Inverter

24 Function Parameter Table 4.4.2 Simple running
It is absolutely forbidden to connect the power cord to the output U, V, W of the frequency inverter.

Three-phase circuitbreaker

Three-phase power supply

×

R

×

S

×

T

Motor U

V

M

W

E

Earthing

Figure 4-2 Simple Running Wiring Diagram

Connect wires as per Figure 4-2;

Switch on the power supply after confirming that the wires are connected

correctly, and the inverter will firstly display “P.oFF” and then “0”.

Confirm that the frequency setting channel is at the digit setting model

([F0.00] = 0);

It is required to set parameter [F0.12] and [F0.13] according to the rated

nameplate data on the inverter’s dragging motor.

Press

RUN STOP

key to start the inverter and the inverter will input 0 frequency,

displaying “0.0”.

Press Up of

key to increase set frequency, and the output frequency of the

inverter will increase and the motor revolution will also increase.

Check if the motor run normally. In case of any abnormity, stop running the

motor immediately and disconnect power supply. Do not run the motor until fault

cause is found.

Press Down on the

key to decrease set frequency.

Press

RUN STOP

key again to stop running and cut off the power supply.

The default value of the carrier frequency is fixed (1.5-10 KHz). If the motor is completely empty-load, slight oscillation may occur sometimes in the operation under high carrier frequency. At this time, please reduce the setting value of the carrier frequency. (Parameter [F0.08]).

E500 Series Universal Low-Power Inverter

Function Parameter Table 25

5 Function Parameter Table

Parameter Function Type Code

Name

F0.00

Frequency input channel

Setting Range and Description
0: Digital setting
1: External analog quantity
2: External communication
3: Panel potentiometer
4: Selection of external terminal
5: Combined setting
6: PWM pulse-width given

F0.01

Frequency 0.0Hz ~ Upper digital setting limiting frequency

LED Units: Selection of running command channel 0: Keyboard control
1: External terminal control
2: communication port

Basic running parameter group

F0.02

Selection of running command
channel and mode

LED Tens: Running command mode selection 0: Two-line mode 1 1: Two-line mode 2 2: Three-line mode 3: Special mode for terminal machine
LED Hundreds: REV prevention 0: REV prevention void 1: REV prevention effective

F0.03 F0.04 F0.05 F0.06

LED Kilobit: Power-on auto start 0: Power-on auto start forbidden 1: Power-on auto start allowed

Lower limiting frequency

0.0Hz ~ [F0.04]

Upper limiting frequency

[F0.03] ~ 400.0Hz

Acceleration time

0.1 ~ 600.0 Sec

Deceleration time

0.1 ~ 600.0 Sec

Minimum Default unit setting

1

3

0.1

0.0

1

1000

0.1

0.0

0.1

50.0

0.1

5.0

0.1

5.0

Modification limit

E500 Series Universal Low-Power Inverter

26 Function Parameter Table

Parameter Function Type Code

Name

F0.07

Acceleration and deceleration characteristic parameter

Setting Range and Description
0: Straight line acceleration and deceleration 1: S Curve acceleration and deceleration

Minimum Default unit setting

1

0

Modification limit

F0.08 Carrier frequency 1.5 ~ 10.0kHz

0.1

8.0

Basic running parameter group

F0.09

Reserve

1: Only allowing

to rewrite F0.01

parameter and this

parameter

F0.10

Parameter write and protection

2: Only allowing to rewrite this parameter

1

Other values: All

parameters are

allowed to be

rewritten.

F0.11 Torque boost 0.0 ~ 20.0 (%)

0.1

F0.12

Basic running 5.0Hz ~ Upper frequency limiting frequency

0.1

F0.13

Maximum output 25 ~ 250V/

voltage

50 ~ 500V

1

F0.14

Jog acceleration time

0.1~ 600.0 S

0.1

F0.15

Jog deceleration time

0.1~ 600.0 S

0.1

F0.16

FWD jog frequency

0.0Hz~[F0.04]

0.1

F0.17

REV jog frequency

0.0Hz~[F0.04]

0.1

LED Units: running direction 0: Consistent with the set direction 1: Reverse to the set direction

LED Tens: Jog

priority selection

F0.18

Auxiliary

0: Highest

function setting 1: Lowest

1

×
0
6.0 50.0 220/ 440 5.0 5.0 10.0 10.0
0000

LED Hundreds: External terminal Up/Down frequency power-off save 0: Invalid 1: Valid

E500 Series Universal Low-Power Inverter

Function Parameter Table 27

Parameter Function Type Code

Name

Lower limiting

F0.19

frequency

functioning mode

Setting Range and Description
0: Output lower limiting frequency when it is lower than the lower limiting frequency 1: Output zero frequency when it is lower than the lower limiting frequency

Minimum Default unit setting

1

0

Modification limit

F0.20

Reserve

F0.21 F0.22

Parameter protection password
UP/DW speed

0~3999 0.1~50.0Hz

1

0

0.1

5.0

F0.23 PWM period 1.0~10.0ms

0.1

5.0

F0.24

Reserve

F1.00

AI input lower limiting voltage

0.0 V ~ [F1.01]

0.1

0.0 F1.00

F1.01

AI input upper limiting voltage

[F1.00] ~ 10.0 V

0.1

10.0 F1.01

F1.02

AI input filter time

0.01~1.00S

0.01

0.01 F1.02

F1.03

Minimum set frequency

0.0Hz ~ [F1.04]

0.1

0.0 F1.03

F1.04

Maximum set frequency

[F1.03] ~ [F0.04]

0.1

50.0 F1.04

Input and output parameter group

0: output

F1.05

Analog output frequency

selection

1: output current

1

2: output voltage

0

F1.05

F1.06

AO output lower limit

0.0V ~ [F1.07]

0.1

0.0 F1.06

F1.07 F1.08 F1.09 F1.10 F1.11 F1.12 F1.13

AO output upper limit

[F1.06] ~ 10.0V

Function selection of 0~29 input terminal 1

Function selection of 0~29 input terminal 2

Function selection Of 0~29 input terminal 3

Function selection Of 0~29 input terminal 4

Input channel characteristic
selection

0000~1111H

OC output function selection

0~15

0.1

10.0 F1.07

1

11

F1.08

1

1

F1.09

1

2

F1.10

1

3

F1.11

1

0000 F1.12

1

0

F1.13

E500 Series Universal Low-Power Inverter

28 Function Parameter Table

Parameter Function Type Code

Name

Setting Range and Description

F1.14

Relay output TA/TC function 0~15
selection

F1.15

OC and relay output
characteristic selection

LED Units: OC output selection 0: OC output positive characteristics 1: OC output negative characteristics
LED Tens: relay output selection 0: relay output positive characteristics (normally open) 1: relay output negative characteristics (normally closed)

Input and output parameter group

F1.16

Relay action delay

0.0S~5.0S

Frequency F1.17 reaching detecting 0.0 ~ 20.0Hz
amplitude

F1.18

FDT ( frequency level) setting

0.0 ~[F0.04]

F1.19

FDT output delay time

0.0 ~ 5.0 Sec

F1.20

Overload alarm level

50 ~200 (%)

F1.21

Overload alarm delay time

0.0 ~ 60.0 Sec

F1.22

Reserve

Minimum Default Modificaunit setting tion limit

1

8

F1.14

1

0000

0.1

0

0.1

5.0

0.1

10.0

0.1

2.0 ×

1

110

0.1

2.0 ×

F1.23 F1.24
F1.25 F1.26 F1.27

Reserve
Batter number of terminal machine
Designated counting value Final counting
value
Reserve

1~100 1~[F1.26] [F1.25]~60000

1

10

1

5

1

100

E500 Series Universal Low-Power Inverter

Function Parameter Table 29

Parameter Function Type Code

Name

Setting Range and Minimum Default Modifica-

Description

unit setting tion limit

Input and output parameter group

0: External voltage + panel potentiometer 1: External voltage+ panel potentiometer +

Digital setting

2:Communication +

external voltage

3: Communication

+ external voltage +

panel potentiometer

4:Communication +

digital-panel

Frequency input potentiometer

F1.28

channel

5:Communication –

1

0

combination external voltage

6:Communication + external voltage panel potentiometer 7:External voltage + digital – panel potentiometer 8:Panel potentiometer Digital setting 9:UP/DW+ External voltage

10: UP/DW + panel potentiometer + external voltage

F1.29 –

Reserve

F1.31

F2.00 Start frequency 0.0 ~ 50.0Hz

0.1

1.0

Auxiliary running parameter group

F2.01

Start frequency duration

0.0 ~ 20.0 Sec

0.1

F2.02

Stop mode

0: Deceleration stop 1: Free stop

1

F2.03

Stop DC braking frequency

0.0~[F0.04]

0.1

F2.04

Stop DC braking current

0 ~ 100 (%)

1

F2.05

Stop DC braking time

0.0 ~ 20.0 Sec

1

F2.06

Acceleration torque level

110 ~ 200 (%)

1

Motor overload

F2.07

protecting 50 ~ 110 (%)

1

coefficient

Dynamic

F2.08

braking Initial

300 ~ 400V/ 600 ~ 800V

1

voltage (1)

0.0 × 0 3.0 10 × 0.0 180
110
370 740

F2.09

Reserve

E500 Series Universal Low-Power Inverter

30 Function Parameter Table

Parameter Function Type Code

Name

Setting Range and Description

F2.10

Reserve

F2.11 V/F frequency 1 0.0~[F2.13]

F2.12 V/F voltage 1 0~[F2.14]

F2.13 V/F frequency 2 [F2.11]~[F2.15]

F2.14 V/F voltage 2 [F2.12]~[F2.16]

F2.15 V/F frequency 3 [F2.13]~[F0.12]

F2.16 V/F voltage 3 [F2.14]~[F0.13]

Continued

F2.17 F2.18
F2.19 F2.20

Reserve
Automatic voltage
regulation
Pairs of motor poles
Reserve

0: Void 1: Effective 2: Deceleration void
1~16

F2.21 F3.00 F3.01 F3.02 F3.03

Reserve
Multi-speed frequency 1
Multi-speed frequency 2
Multi-speed frequency 3
Multi-speed frequency 4

0.0Hz ~ Upper limiting frequency
0.0Hz ~ upper limiting frequency
0.0Hz ~ upper limiting frequency
0.0Hz ~ upper limiting frequency

Multispeed and senior running parameter group

F3.04 F3.05 F3.06 F3.07 F3.08 F3.09
F3.10

Multi-speed frequency 5
Multi-speed frequency 6
Multi-speed frequency 7 Liner speed coefficient
setting Monitoring parameter
selection Parameter inquiry and modification authority
Parameter initialization

0.0Hz ~ upper limiting frequency 0.0 Hz~ upper limiting frequency 0.0 Hz~ upper limiting frequency
0.01 ~ 100.00
0 ~ 22
0 ~ 9999
0: No action 1: Standard initialization 2: Fault elimination record 3: Complete initialization 4~9: Invalid

Minimum Default Modificaunit setting tion limit

E500 Series Universal Low-Power Inverter

Function Parameter Table 31

Parameter Function Type Code

Name

Setting Range and Description

F3.11

Under voltage 180 ~ 230V / protection level 360 ~ 460V

F3.12

Overvoltage 350 ~ 400V / suppression level 700 ~ 800V

F3.13

Current amplitude limiting level

150 ~ 250 (%)

F3.14 Program version 1A00 ~ 1A99

F3.15

Reserve

F3.16

Reserve

Units: PLC action selection 0: No action 1: Action 2: Conditional

Multispeed and senior running parameter group

F3.17
F3.18 F3.19 F3.20 F3.21 F3.22 F3.23 F3.24 F3.25

Multi-speed running mode
Stage 1 running time
Stage 2 running time
Stage 3 running time
Stage 4 running time
PLC multi-speed running direction PLC running scheduled stop
Fault self-recovery
times Fault self-recovery time

Tens: PLC operating mode selection 0: Single cycle mode 1:Single cycle stop mode 2: Final value keeping mode 3: Set value keeping mode 4: Continuous cycle mode
0.0S~6000.0S
0.0S~6000.0S
0.0S~6000.0S
0.0S~6000.0S
0000~1111H
0~9999(min)
0~5
0.0~60.0

Minimum Default unit setting

Modification limit

E500 Series Universal Low-Power Inverter

32 Function Parameter Table

Parameter Function Type Code

Name

Setting Range and Minimum Default Modifica-

Description

unit setting tion limit

LED Units:

function setting

0: Swing frequency

function closed

1: Swing frequency

function effective

2: Swing frequency

F3.26

Swing frequency function running setting conditionally

1

effective

0000

Multispeed and senior running parameter group

LED Tens: Center frequency setting 0: Digital setting 1: Frequency channel selection

F3.27

Swing frequency amplitude

0.0~50.0%

0.1

10.0

F3.28

Kick frequency amplitude

0.0~80.0%

0.1

0

F3.29

Triangular wave descending time

0.1~300.0 S

0.1

1.0

F3.30

Triangular wave ascending time

0.1~300.0 S

0.1

1.0

Swing frequency F3.31 center frequency 0.0~[F0.04] setting

0.1

0.0

F3.32 –
F3.34

Reserve

LED Units: Baud rate selection 0: Reserve 1: 1200 bps 2: 2400 bps 3: 4800 bps 4: 9600 bps 5: 19200 bps

parameter group

LED Tens: Data

format selection

0: No check

F4.00

Communication 1:Even parity check

setting

2: Odd parity check

1

0114 ×

LED Hundreds: protocol selection 0: SIMPHOENIX self-defined protocol 1: MODBUS communication protocol

LED Kilobit: Reserve

F4.01 Local address 0 ~ 30

1

1

E500 Series Universal Low-Power Inverter

Function Parameter Table 33

Parameter Function Type Code

Name

F4.02

Local response delay

Setting Range and Description
0 ~ 1000ms
LED Units: Inverter main/slave setting 0: This inverter is a slave machine 1: This inverter is a main machine

Minimum Default unit setting

1

5

Modification limit

LED Tens: Selection

of action after

Setting of communication

F4.03

communication failure

auxiliary

0: Stop

1

function (1) 1: Maintaining

current status

0010

parameter group

LED Hundreds: Data return selection 0: Data normal return 1: No data return

F4.04
F4.05 F4.06
F4.10 F5.00
F5.01
F5.02
F5.03
F5.04 F5.05 F5.06

LED Kilobit: Reserve

Communication overtime 0.1 ~ 10.0 Sec
detection time (1)

Linkage setting ratio (1)

0.1 ~ 10.0

Reserve

PID function selection
PID set channel
PID digital setting
PID feed forward enabling
Reserve PID feedback
correction Ratio grain

0: PID closed 1: PID enabled 0: PID Digital setting 1: frequency input channel setting
0.0%~100.0%
Units: 0: Void 1: Feed forward setting ( frequency input channel )

PID

F5.07 Integral time 0.01~10.00

0.01

0.20

F5.08 Derivative time 0.0~10.00

0.01

0.0

E500 Series Universal Low-Power Inverter

34 Function Parameter Table

Parameter Function Type Code

Name

Setting Range and Description

F5.09

PID adjustment frequency range

0.0~100.0%

F5.10

Breakage detection value

0.0~50.0%

PID

F5.11
F5.12 –
F5.22

Breakage detection delay 0.1~10.0 Sec
time
Reserve

F6.00

Cutting function selection

0: Drag

1: Cut

Minimum Default Modificaunit setting tion limit

0.1

100.0

0.1

5.0

0.1

5.0

1

0

F6.01 F6.02 F6.03

Cutting length
Correction of liner speed coefficient
Start delay

0.100~2.000 0.100~10.000 0.01~10.00

0.001 0.001 0.01

0.700 1.000 3.00

F6.04 Stop delay 0.01~10.00

0.01 4.00

Special function

F6.05 F6.06 F6.07

Reserve
Liner cutting operating mode
Forward time

0~2 0~60.0S

1

0

0.1

5.0

F6.08 Backward time 0~60.0S

0.1

4.0

High-frequency

F6.09

relay

[F6.10]~100%

Start frequency

1

99

F6.10

High-frequency relay
Disconnection frequency 1

0~[F6.09]

1

98

F6.11

High-frequency relay
Disconnection frequency 2

100~200%

1

120

F7.00

Control mode selection

0V/F control 1SVC (open loop
vector) control

1

0

F7.01 Motor power

0.2~7.5KW

0.1

1.5

Vector control function

F7.02 Rated voltage

100~500

1

220

F7.03 Rated current

0.10~30.0A

0.01

6.40

F7.04 Rated frequency 20.0~300.0HZ 0.1

50.0

F7.05 Rated revolution 200~10000

1

1400

F7.06 No-load current 0.01~20.00A 0.01

3.00

F7.07 F7.08 F7.09

Stator resistance
Stator inductance
Reserve

0.001~30.000 0.001~10.000H

0.001 0.001

1.790 228

E500 Series Universal Low-Power Inverter

Function Parameter Table 35

Parameter Function Type Code
F7.10

Name Reserve

Setting Range and Description

F7.11 F7.12

Reserve Reserve

F7.13 F7.14
F7.15 F7.16

Reserve Pre-excitation
time
Motor parameter identification
Reserve

0~3.0S
0Off 1Static dentification

Vector control function

F7.17

Reserve

F7.18 F7.19
F7.20 F7.21 F7.22 F7.23 F7.24 F7.25

Reserve
Speed loop proportional coefficient
Speed loop integral time
Max. FWD torque limit Max. RED torque limit
Reserve
Speed estimate coefficient
Reserve

0.10~1.5 0.1~10.00 0~200% 0~200%
0.1~5.0

F7.26

Reserve

Minimum Default Modificaunit setting tion limit

Notes: 1.E500 series standard inverters have no F6 function, it is only for part of the derived models. 2.F7 vector control function is only for inverters whose software version is 1207 and above.

E500 Series Universal Low-Power Inverter

36 Function Parameter Table

6 Function details
6.1 Basic running parameter group

F0.00 Selection of frequency input channel/mode Setting range: 0 ~ 5

It is used to select setting channel/mode of inverter’s running frequency. 0: Digital setting The inverter’s set frequency is set by parameter [F0.01]. 1: External analog quantity The running frequency is set by external input voltage signal (0~10V) or current signal (0~20mA); for relevant characteristics, please refer to parameter [F1.00] and [F1.01]. 2: External communication To receive frequency setting commands of upper computer or main inverter through serial RS485 port.

3: panel potentiometer

The running frequency is set by the potentiometer on the operating panel.

4: External terminal selection

The frequency input channel is confirmed by external multifunctional terminal

(the selection of functional terminals is confirmed by the parameter [F1.08] [F1.11]).

Frequency setting channel selection 2
0
0
1 1

Frequency setting channel selection 1
0
1
0 1

Frequency setting channel
Digital setting External input signal
(0~10V/0~20mA) RS485 port
panel potentiometer

Note: It is “1” when the terminal and CM is engaged.

5: Combined setting

It is selected by [F1.28] group parameters.

E500 Series Universal Low-Power Inverter

Functional Details 37

6:

PWM pulse-width given

External terminal X4: PWM pulse-width given, when X4 inputs maximum
duty ratio, it responds to upper limit frequency, conversely lower limit.
frequency while minimum duty ratio.
F0.01 Frequency digital setting Setting range: 0.0 Hz ~upper limiting frequency

When frequency input channel selects digital setting ([F0.00] = 0), inverter’s

output frequency is determined by this value. When the operating panel is at the

normal monitoring status, simply press

key to modify this parameter.

F0.02 Selection of running command channel and mode Setting range: 0000~1132

This functional parameter is used to select inverter’s running command channel

and functions of

RUN STOP

key ( fratile decimal system setting)

LED Units: running command channel selection

0: Keyboard control

The inverter’s running command is controlled by

RUN STOP

key on the keyboard.

In this mode, the status of external control terminal X1~X4 (FWD running

function) can influence inverter’s output phase sequence. When the external

terminals X1~X4 (FWD running function) is connected to CM, the inverter’s

output phase sequence is negative, and when X1~X4 is disconnected with CM,

the inverter’s output phase sequence is positive.

1: External terminal control
The inverter’s running command is controlled by the connection and disconnection status between the multifunctional terminals X1~X4 (FWD or REV control function) and CM terminal, and its mode is determined by LED tens.

2: Serial communication port Inverter’s running command receives commands of upper commuter or main inverter through serial port. When the local inverter is set as the slave in linkage

E500 Series Universal Low-Power Inverter

38 Function Parameter Table

control, this mode should be selected as well. LED Tens: selection of running command mode

0: Two-line mode1 (default mode)

command

Stop command

FEW command REV command

Terminal status

FW
RDEV CM

FWD REV CM

FWD REV CM

FWD REV CM

Two-line mode requires selecting one input terminal X1~X4 as forward control

temrinal FWD and the other input terminal X1~X4 as reverse control terminal REV (refer to parameter [F1.08][F1.11]).

1: Two-line mode 2

command Terminal
status

Stop
FWD CM

Running
FWD CM

FWD
REV CM

REV
REV CM

2: Three-line mode Three-line control mode requires selecting one input terminal (X1~X4) as forward control terminal FWD, one input terminal (X1~X4) as three-line running control terminal SW1, and one input terminal (X1~X4) as reverse control model REV (refer to parameter [F1.08]~[F1.11]). Parameter [F1.08]~[F1.11] is used to select any one from input terminals X1X4. Switch function is described as below:
1. SW1 (three-line running control terminal) -inverter stop trigger switch 2. SW2 (FWD) – FEW trigger switch 3. SW3 (REV) – REV trigger switch

SW1 SW2 SW3

X? FWD REV

CM

Output frequency
SW1 SW2 SW3

Time

Figure 6-1 Wiring Diagram in Three-line Control Mode

Figure 6-2 Frequency Output Diagram in Three-line Control Mode

E500 Series Universal Low-Power Inverter

Functional Details 39
3: Special mode for terminal machine: This function is only applicable to special occasions such as terminal machine. X1 is used as the approach switch counting and stop signal, and X2 is start signal. LED Hundreds: REV prevention 0: REV prevention void 1: REV prevention effective LED Kilobit: Power-on auto start 0: Power-on auto start forbidden 1: Power-on auto start allowed

F0.03 Lower limiting frequency

Setting range: 0.0 Hz ~ [F0.04]

This parameter is the minimum output frequency allowed for the inverter. For the functioning mode when it is lower than the lower limiting frequency, please refer to parameter [F0.19].

F0.04 Upper limiting frequency

Setting range: [F0.3] ~ 400.0Hz

F0.05 Acceleration time F0.06 Deceleration time

Setting range: 0.1 ~ 600.0Sec Setting range: 0.1 ~ 600.0Sec

It is used to define the velocity of increasing and decreasing of inverter’s output frequency. Acceleration time: the time required for output frequency accelerating from 0.0Hz to the upper limiting frequency [F0.04]. Acceleration time: the time required for output frequency decelerating from upper limiting frequency [F0.04] to 0.0Hz.

E500 Series Universal Low-Power Inverter

40 Function Parameter Table
F0.07 Acceleration and deceleration characteristics parameter Setting range: 0~1
It is used to set the acceleration and deceleration characteristic parameter of inverters (fratile binary system setting). LED UNITS: setting of inverter’s acceleration and deceleration curve type. Refer to Figure 6-3. 0: Straight line acceleration and deceleration The inverter’s output frequency increases or decreases at fixed speed. For most loads, this mode can be selected. 1: S curve acceleration and deceleration The inverter’s output frequency increases or decreases at varying speed. This function is mainly to reduce noise and ventilation at acceleration and deceleration and reduce load impact at start and stop.
Output frequency(HHZz) Straight line

SSCurve
Time (SSeecc) Figure 6-3 Acceleration and Deceleration Curve

F0.08

Carrier frequency

Setting range: 1.5 ~ 10.0 KHz

This parameter is to determine the switch frequency of inverter’s internal power module. The carrier frequency mainly influences the audio noise and heat effect during running. When mute running is required, it is applicable to appropriately increase the value of the carrier frequency, but the maximum load allowable for the inverter may be somewhat reduced, accompanied by somewhat increase of interference of the inverter to the outside world. For the circumstances where the motor wire is too long, it may lead to leaking current between motor wires and between the wire and the ground. When the ambient temperature is too high and

E500 Series Universal Low-Power Inverter

Functional Details 41
the motor load is too high, or the inverter is failed due to above reasons, it is suggested to appropriately decrease the carrier frequency to improve thermal characteristics of the inverter.

F0.09

Reserve

F0.10

Parameter write protection

Setting range: 0 ~ 9999

This function is used to prevent improper modification of data. 1: Only allowing for modifying function parameter [F0.01] and this parameter. 2: Only allowing for modifying this parameter. Other values: all parameters can be modified. When it is forbidden to modify parameters, if it is intended to modify data, “- -” will be displayed.

Some parameters cannot be modified during running. If it is attempted to modify these parameters, “” will be displayed. To modify parameters, stop the inverter at first.

F0.11

Torque boost

Setting range: 0.0 ~ 20.0%

It is used to improve inverter’s low-frequency torque characteristics. During running at low frequency, it will make compensation for boosting inverter’s output voltage, as shown in Figure 6-4.

Boost voltage =

[F0.11] 100

× [F0.13]

E500 Series Universal Low-Power Inverter

42 Function Parameter Table
Voltage [F0.13] [F 0 .11 ] Boost voltage

[F0.12] Frequency Figure 6-4 Torque Boost Sketch

F0.12 F0.13

Basic running frequency Maximum output voltage

Setting range: 5. 0Hz ~ upper limiting frequency Setting range: 25 ~ 250V/50 ~ 500V

The basic running frequency is the minimum frequency at the maximum voltage of inverter output. It is generally the motor’s rated frequency. The maximum output voltage is the output voltage corresponding to the inverter output basic running frequency, and it is the motor’s rated voltage. The two items of function parameters need to be set according to motor parameter, and do not need any modification unless in special cases.

F0.14 Jog acceleration time F0.15 Jog deceleration time

Setting range: 0.1 ~600.0Sec Setting range: 0.1 ~600.0Sec

The transit acceleration and deceleration time between initial running frequency and jog frequency.

F0.16 FWD jog frequency F0.17 REV jog frequency

Setting range: 0.0Hz ~[F0.04] Setting range: 0.0Hz~[F0.04]

Jog running is a special running mode of the inverter. Within the effect period of jog signals, the inverter runs at the frequency set by this parameter. No matter the inverter is initially stopped or running, it can receive jog signals.

F0.18 Setting of auxiliary functions

Setting range: 0000 ~ 0011

E500 Series Universal Low-Power Inverter

Functional Details 43

LED UNITS: Running direction 0: Consistent with the set direction 1: Reverse with the set direction

LED Tens: Jog priority selection

0: Jog priority highest

1. Jog priority lowest

LED Hundreds: External terminal Up/Down frequency power-off save

0: Function invalid

1. Function enable

If the jog priority is set to the highest, the pripirty of each freqeuncy source is as

below:

Priority level Priority

High

1

Set frequency source Jog frequency (jog running effective)

2

External terminal selection multi-speed frequency

Low

3

Selection of frequency setting channel ([F0.00] parameter)

F0.19 Lower limiting frequency functioning mode Setting range: 0000 ~ 0001
0: Output lower limiting frequency [F0.03] when it is lower than the lower limiting frequency [F0.03] 1: Output zero frequency when it is lower than the lower limiting frequency [F0.03] This parameter is used to set hysteresis to avoid fluctuation around the set frequency zero point. When the set frequency is lower than f(f=lower limiting frequency-2Hz), the inverter runs at zero frequency. When the set frequency is higher than the lower limiting frequency, the inverter runs at the set frequency. Refer to Figure 6-5.
Actual setfrequency F[[00..0044] FF[[00.0033]]

F2[0H.0z4]

FF[[00..0044]] Originalset frequency

Figure 6-5 Sketch of the Function of Lower limiting frequency E500 Series Universal Low-Power Inverter

44 Function Parameter Table F0.20 Reserve F0.21 Parameter password protection Setting range: 0000 ~ 3999

F0.22 UP/DW speed

Setting range: 0.1~50.0Hz

When [F0.00]=5, [F1.28]=9 or 10, and input terminal selects UP or DW function, frequency can be set through external terminals. This parameter is used to set the increasing and decreasing speed of the frequency set by external terminal.

F0.23 PWM period

Setting range: 1.0~10.0ms

When F1.11=0, multi-functional terminal X4 is for the function of PWM pulse
width speed adjusting. This parameter is for setting PWM period 6.2 analog input output parameter group

The function parameter group [F1.00] ~ [F1.01 defines the upper and lower limit of external input signal as the frequency setting signal. E500 series inverters allow for inputting analog voltage signal and analog current signal; the analog current signal 0-20mA is corresponding to the voltage signal 0-10V.

F1.00 AI input lower limiting voltage

Setting range: 0.0V ~ [F1.01]

F1.01 AI input upper limiting voltage Setting range: [F1.00] ~ 10.0 V

[F1.00] and [F1.01] defines AI range of analog input channel, which shall be set

according to actual conditions of access signal.

F1.02 AI input filter time

Setting range: 0.01 ~ 1.00Sec

When external analog input quantity is subject to filter processing to effectively eliminate interfering signals, if it is set to large value, the interfering capability is strong but it will slow down response speed to setting signals.

E500 Series Universal Low-Power Inverter

Functional Details 45

F1.03 F1.04

Minimum set frequency Maximum set frequency

Setting range: 0.0Hz ~ [F1.04] Setting range: [F1.03] ~ [F0.04]

The corresponding relationship between the analog input quantity and set frequency is shown in Figure 6-6.

Frequency

F[1.04]

Output frequency

F[1.03]

Figure 6-6

F[1.00]

FF[[11.0.0]1] VVoollttaagge e

[F1.00 ] [F1.01 ]

Corresponding relationship sketch of analog input quantity and set frequency

F1.05 Analog output selection

Setting range: 0 ~ 2

Select the meaning of analog output terminal AO (setting of fratile decimal system).

LED Units: Define meaning of analog output AO

0: output frequency The analog output (AO) amplitude is proportional to the inverter’s output frequency. The setting upper limit of analog output ([F1.07]) is corresponding to the upper limiting frequency.

1: output current The analog output (AO) amplitude is proportional to the inverter’s output current. The setting upper limit ([F1.07]) of the analog output is corresponding to two times of the inverter’s rated current.

2: Output voltage The analog output (AO) amplitude is proportional to the inverter’s output voltage. And the setting upper limit ([F1.07]) of the analog output is corresponding to the maximum output voltage ([F0.13]).

E500 Series Universal Low-Power Inverter

46 Function Parameter Table

F1.06 F1.07

AO output lower limit AO output upper limit

Setting range: 0.0 V ~ [F1.07] Setting range: [F1.06] ~ 10.0 V

Define the maximum value and minimum value of analog output AO output signal. Refer to figure 6-7.

A O

AO

[F1.06]

0 1

Rate

currenUt pper

limiting

frequency

Output Output

frequency voltage

2

Max./rate voltage Output current

Figure 6-7 Analog output content of analog output terminal

F1.08 F1.09 F1.10 F1.11

Function selection for input terminal 1 Function selection for input terminal 2 Function selection for input terminal 3 Function selection for input terminal 4

Setting range: 0 ~ 29 Setting range: 0 ~ 29 Setting range: 0 ~ 29 Setting range: 0 ~ 29

Function definition of switch quantity input terminal X1 X4, which is described as below:

0: control terminal X1-X3 are as spare terminalX4 as PWM pulse speed control terminal

1: Multi-speed control 1

2: Multi-speed control 2

3: Multi-speed control 3

The combination of multi-speed control terminals can be used to select multi- speed output frequency. The frequency setting at each stage is to be determined by the multi-speed control parameter functional group ([F3.00] [F3.06]).

E500 Series Universal Low-Power Inverter

Functional Details 47
4: FWD jog control 5: REV jog control When the external terminal of running command channel selection is effective, this parameter can define the input terminal of external jog signals. 6: Frequency set channel selection 1 7: Frequency set channel selection 2 When the frequency input channel is set to be external terminal selection (F0.00=4), the frequency set channel of the inverter will be determined by the status of these two terminals, and for its corresponding relationship, please refer to description of parameter [F0.00]. 8: Free stop control If terminal corresponding to this parameter is engaged, the inverter will lock output. 9: Three-line running control When the running command terminal combination mode is set to three-line mode, the external terminal defined by this parameter is inverter stop trigger switch. See functional code [F0.02] for the three-line control mode in details. 10: DC braking control At the inverter stop status, if the terminal defined by this parameter is engaged, when the output frequency is lower than the DC braking initial frequency, the DC braking function will be enabled until the terminal is disconnected. See description of [F2.03] ~[F2.05] for relevant parameters of DC braking. 11: FWD control 12: REV control 13: Fault reset When the inverter is at the faulty status, engaging the terminal set by parameter can clear inverter’s fault. 14: Reserve 15: Reserve
E500 Series Universal Low-Power Inverter

48 Function Parameter Table
16: External fault input When the terminal set by this parameter is engaged, it indicates that the external equipment is faulty. At this time, in order to ensure safety of the equipment, the inverter will lock the input and displays the external fault signal Fu.16. 17: Disconnection input When the terminal set by this parameter is engaged, it indicates disconnection fault of external equipments. At this time, in order to guarantee equipment safety, the inverter will lock output, and displays the external fault signal Fu.17. 18: PLC effective When the programmable PLC running condition [F3.17] is selected to be effective, the external terminal defined by this parameter can enable effecting and cut-off of PLC operation. 19: Swing frequency running effective When the swinging frequency function condition is selected to be effective ([F3.26] =XXX1), the external terminal defined by this parameter can enable effecting and cut-off of swing frequency running. 20: UP 21: DW The running frequency of the inverter can be set through external terminals, hence allowing for remote frequency setting. When the terminal is effective, the set frequency increases or decreases at set speed. When the terminal is void, the set frequency is maintained unchanged. When the two terminals are effective simultaneously, the set frequency is maintained unchanged. When the UP is effective, the frequency increases and when DW is effective, the frequency decreases. 22: Internal counting clock Only Terminal 3 can be as count input terminal. 23: Internal counting clock clearing 24: Reciprocating running effective 25: Terminal machine running battering effective
E500 Series Universal Low-Power Inverter

26: Reserve 27: Reserve 28: Splitting machine infrared signal 29: Splitting machine approaching switch signal

Functional Details 49

F1.12 Selection of input channel characteristics Setting range: 0000~ 1111H

It is used to select characteristics of external digital input:

LED UNITS: Define characteristics of X1 input channel

0: positive characteristics

1: negative characteristics

LED Tens: Define characteristics of X 2 input channels

0: positive characteristic

1: negative characteristic

LED Hundreds: Define characteristics of X 3 input channels

0: positive characteristic

1: negative characteristic

LED Kilobits: Define characteristics of X 4 input channels

0: positive characteristic

1: negative characteristic

The positive characteristic is effective when the terminal is engaged and void

when the terminal is disconnected. The negative characteristic is effective when

the terminal is disconnected and void when the terminal is engaged.

F1.13 F1.14

Output terminal OC function selection Relay output TA/TC function selection

Setting range: 0 ~ 15 Setting range: 0 ~ 15

It is used to define the contents indicated by the collector open-circuit output terminal OC and relay output contact. See Figure 6-8 for the internal wiring diagram of the collector open-circuit output terminal. When the function is set to be effective, the output is at low level, and when the function is void, the output is at the high-resistance status. Relay contact output: when the output function is set to be effective, the normally open contact TA-TC is connected.

E500 Series Universal Low-Power Inverter

50 Function Parameter Table

D

R

1

2
Figure 6-8 internal circuit of OC output terminal
For connecting external inductive elements (e.g. relay coil), freewheel diode D must to be connected in parallel.
0: Inverter is running When the inverter is running, it outputs effective signals, and when the inverter is at stop, it outputs void signals. 1: Frequency reaching When the inverter’s output frequency is approaching the set frequency within certain range (which is defined by parameter [F1.17]), it outputs effective signals, otherwise, it outputs void signals.

Port output

[F1.17]

Frequency

Figure 6-9 Frequency reaching signal
2: Frequency level detection (FDT) When the inverter’s output frequency exceeds FDT frequency level, after the set delay time, it outputs effective signals. When the inverter’s output frequency is lower than the FDT frequency level, after the same delay time, it outputs void
E500 Series Universal Low-Power Inverter

signals.

Output terminal

Ferquency

High resister
Output frequency

Higgh resistor

Functional Details 51

[F1.18]

FDT level

[F1.19]

T [F1.19]

Figure 6-10 Frequency Level Detection Signal (FDT)

3: Overload detection
When the inverter’s output current exceeds the overload alarm level, after the set alarm delay time, it outputs effective signals. When the inverter’s output current is lower than the overload alarm level, after the same delay time, it outputs void signals.

Figure 6-11 Overload Alarm 4: Frequency reaching upper limit When the inverter’s output frequency reaches the upper limiting frequency, this terminal outputs effective signals; otherwise, it outputs void signals. 5: Frequency reaching lower limiting When the inverter’s output frequency reaches the lower limiting frequency, this
E500 Series Universal Low-Power Inverter

52 Function Parameter Table
terminal outputs effective signals; otherwise, it outputs void signals. 6: Running at zero speed When the inverter’s running command is effective and the output frequency is at 0, this terminal outputs effective signals; otherwise, it outputs void signals. 7: Under voltage stop When the inverter’s DC side voltage is lower than the specified value, the inverter stops running, and this terminal outputs effective signals; otherwise, it outputs void signals. 8: Inverter fault When the inverter stops running due to fault, it outputs effective signals; and when the inverter runs normally, it is at void status. 9: Disconnection fault When the inverter stops running due to disconnection fault, it outputs effective signals; and when the inverter runs normally, it is at void status. 10: PLC cycle completion When the inverter stops running due to disconnection fault, it outputs effective signals; and when the inverter runs normally, it is at void status. 11: High-frequency output When the output frequency reaches the set action frequency [F6.09], it outputs effective signals, and when the output frequency is lower than the disconnecting action frequency [F6.10], it outputs void signals. 12: Reaching specified count value When the internal counter reaches the specified count value [F1.25], it outputs effective signals, and outputs void signals when the next time of pulse is reaching. 13: Reaching final value cycle When the internal counter reaches the final count value [F1.26], it outputs effective signals, and outputs void signals when the next time of pulse is reaching. 14: Reserve 15: Reserve
E500 Series Universal Low-Power Inverter

Functional Details 53

F1. 15 OC and relay output characteristics Setting range: 0000 ~ 0011
Select polarity of OC output and relay output according to digits. When it is set to “1”, the output polarity is reverse.

F1. 16 Relay action delay

Setting range: 0.0 ~ 5.0 Sec

This parameter is used to set the delay time for change of status of relay output signals

F1. 17 Frequency reaching detecting amplitude Setting range: 0.0 ~ 20.0 Hz
It is used to set the frequency reaching detection amplitude defined by the output terminal. When the inverter’s output frequency is within the positive and negative detection amplitude of the set frequency, the output terminal outputs effective signals. Refer to Figure 6-9.

F1.18 F1.19

FDT (frequency level) setting FDT output delay time

Setting range: 0.0 ~ 400 Hz Setting range: 0.0 ~ 5.0 Sec

This parameter group is used to set frequency detection level. When the output frequency is higher than the FDT set value, after the set delay time, the output terminal outputs effective signals. When the output frequency is lower than the FDT set value, after the same delay time, the output terminal outputs void signals.

F1.20 F1.21

Overload alarm level Overload alarm delay time

Setting range: 50 ~ 200% Setting range: 0.0 ~ 60.0Sec

This parameter is used to set the overload alarm level and alarm delay time. When the output current is higher than the set value of [F1.20], afte the delay time set by [F1.21], the output terminal outputs effective signals (low level). Refer to figure 6-11.

E500 Series Universal Low-Power Inverter

54 Function Parameter Table

F1.22 F1.23

Reserve Reserve

F1.24 Batter number of terminal machine Setting range: 1~100

F1.25 Specified count value

Setting range: 1~[F1.26]

F1.26 Final count value

Setting range: [F1.25]~60000

Count related to F1.24, F1.25, F1.26, which only can use external termincal X3. Please refer to parameter [F1.10] setting as 22.

F1.27 Reserve

F1.28 Frequency input channel combination Setting range: 0~10

This parameter is only effective when the frequency input channel is set to

combined setting. The inverter’s set frequency is determined by the liner combination of multiple frequency input channel. See following table for the defined combination mode.

By means of combined setting, the inverter’s frequency output can be controlled by multiple channels.

Set value
0

Combination mode
External voltage setting + panel setting

Set value
1

Combined setting
External voltage setting + panel setting + digital setting

2

Communication setting + external voltage setting

3

Communication setting + external voltage setting+ panel setting

4

Communication setting – panel setting + digital setting

5

Communication setting – external voltage setting

6

Serial setting + external voltage setting – panel setting

8 Panel setting – digital setting

7

External voltage setting ­ panel setting + digital setting

9

UP/DW frequency +external voltage setting

10

UP/DW frequency + panel setting + external voltage setting

E500 Series Universal Low-Power Inverter

6.3 Auxiliary running parameter group

Functional Details 55

F2.00 F2.01

Start frequency Start frequency duration

Setting range: 0.0 ~ 50.0Hz Setting range: 0.0 ~ 20.0Sec

This functional parameter group is used to define characteristics relevant with start mode. See Figure 6-12. For the system with large inertia, heavy load and high requirements of start torque, the start frequency can effectively overcome the problem of difficulty start. The start frequency duration (parameter code [F2.01])) means the running duration at the start frequency, and can be set according to actual requirements. When it is set to 0, the start frequency is void.

Frequency Set frequency
[F2.00] [F2. 01]

Start

Decelerationstop without DCbraking
Free stop Time

Figure 6-12 Start and Stop Frequency Output Curve

F2.02 Stop mode

Setting range: 0 ~ 1

0: Deceleration stop The inverter stops after its output frequency decreases gradually according to the set acceleration time. 1: Free stop When stopping, the inverter outputs zero frequency and locks output signals, and the motor rotates freely and then stops. At the free stop, it is required to restart the motor after the motor has completed stopped running. Otherwise, over current or overvoltage fault may occur.

E500 Series Universal Low-Power Inverter

56 Function Parameter Table

F2.03 F2.04 F2.05

DC braking initial frequency at stop DC current at stop DC braking time at stop

Setting range: 0.0 ~ [F0.04] Setting range: 0.0 ~ 100% Setting range: 0 ~20.0 Sec.

This parameter group is used to set DC braking parameters at stop. During the process of DC braking initial frequency ([F2.03]) at stop setting inverter stop, when the output frequency is lower than the set parameter, the inverter will lock output and enable DC braking function. The stop DC braking action time is to be set by parameter [F2.05]. The stop DC braking action time is set to 0, the stop DC braking function is ineffective. Stop DC braking current means the percentage of inverter’s rated current.

F2.06 Acceleration torque level

Setting range: 110 ~ 200

This parameter is used to set the allowed output level of torque current at acceleration. The torque limiting level during inverter acceleration is set by [F2.06]. It is set to the percentage of inverter’s rated current. For example, if it is set to 150%, it means the output current is 150% of the rated current at maximum. When the inverter’s output current is higher than the level specified by these parameters, the acceleration and deceleration time will be prolonged automatically so as to confine the output current within this level range. Refer to Figure 6-13. Therefore, if the acceleration time is required to be shorter, acceleration torque level needs to be increased.

Freq uen cy

Acc elera tion tim e ad justment

Acceler atio n t orq ue [F[2F2..0066] ]

Tim e Tim e

E500 Series Universal Low-Power Inverter

Functional Details 57
Figure 6-13 Sketch of acceleration torque and braking torque F2.07 Motor overload protecting coefficient Setting range: 50 ~ 110 () This parameter is used to set inverter’s sensitivity of thermal relay protection for load motor. When the rated current of the load motor is not matching with the inverter’s rated current, it is applicable to set this value to provide correct thermal protection over the motor. When it is set to 110%, the inverter will disable the motor overload protection function. The set value of this parameter is determined by following formula.
Motorratedcurrent [F2.07]= Inver terra tedoutpourcurrent×100%
When one inverter and multiple motors run in parallel, the inverter’s thermal relay protection function will be disabled. In order to effectively protect motors, it is suggested to install a thermal protecting relay at the inlet wire terminal for each motor.
F2.08 Dynamic braking initial voltage Setting range: 300~400V/600~800V This parameter is effective for inverters with built-in braking unit and is used to define action parameters of inverter’s built-in braking unit. When the inverter’s internal DC side voltage is higher than dynamic braking initial voltage, the built-in braking unit acts. If external braking resistor is connected, the inverter’s internal DC side pumping voltage energy will be released through the braking resistor so as to reduce the DC voltage. When the DC side voltage reduces to certain value ([F2.08]-50V), the inverter’s built- in braking unit is closed, as shown in Figure 6-14.
E500 Series Universal Low-Power Inverter

58 Function Parameter Table

DC side voltage
[F2[F.20.088]] [F2[.F028.0]8-5]-500VV

Brakingunit action

Figure 6-14 Dynamic Braking

Time

F2.09 ~ F2.10 Reserve

F2.11 F2.12 F2.13 F2.14 F2.15 F2.16

V/F frequency 1 V/F voltage 1 V/F frequency 2 V/F voltage 2 V/F frequency 3 V/F voltage 3

Setting range: 0.0~[F2.13] Setting range: 0.0~[F2.14] Setting range: [F2.11]~[F2.15] Setting range: [F2.12]~[F2.16] Setting range: [F2.13]~[F0.12] Setting range: [F2.14]~[F0.13]

This functional parameter group is used to flexibly set user desired V/F curve. See figure 6-15.

Voltage F[0.13] [F2.16] [F2.14] [F2.12] [F0.11] [F2.11] [F2.13] [F2.15] [F0.12] Frequency

Figure 6-15 Setting of V/F Customized Curve

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Functional Details 59

F2.17

Reserve

F2.18

Automatic voltage regulation

Setting range: 0~2

The automatic voltage regulation function is for protecting inverter’s voltage

from fluctuating with input voltage fluctuation. When the grid voltage varies

greatly and it desired that the motor has comparatively stable stator voltage and

current, this function should be enabled.

0: invalid

1: Deceleration time is invalid

2: Effective

F2.19

Pairs of motor polarity

Setting range: 1~16

This parameter is mainly used to calculate motor revolution.

F2.20~F2.21 Reserve

6.4 Multi-speed and senior running parameter group

F3.00 F3.01 F3.02 F3.03 F3.04 F3.05 F3.06

Multi-speed frequency 1 Multi-speed frequency 2 Multi-speed frequency 3 Multi- speed frequency 4 Multi-speed frequency 5 Multi-speed frequency 6 Multi-speed frequency 7

Setting range: 0.0Hz ~ Upper limiting frequency Setting range: 0.0Hz ~ Upper limiting frequency Setting range: 0.0Hz ~ Upper limiting frequency Setting range: 0.0Hz ~ Upper limiting frequency Setting range: 0.0Hz ~ Upper limiting frequency Setting range: 0.0Hz ~ Upper limiting frequency Setting range: 0.0Hz ~ Upper limiting frequency

It is to set terminals with this parameter function code to control multi- speed running output frequency.

F3.07 Liner speed coefficient setting

Setting range0.01 ~ 100.00

This parameter is used to set the running liner speed and display value of liner speed. It can be also used to display other physical quantity proportional to output frequency.

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60 Function Parameter Table
Running liner speed (d-8) = F3.07 X Output frequency (d-0) Set liner speed (d-9) = F3.07 X Set frequency (d-6)

F3.08 Monitoring parameter selection

Setting range: 0 ~ 22

This parameter is used to determine the display contents on the operating panel at the monitoring status. The monitoring parameter selection is used to determine the display content on the LED. The physical quantity corresponding to the display data can be referred to the status monitoring parameter table.

F3.09 Parameter inquiry and modification authority Setting range: 0 ~ 9999
This parameter is the check code for obtaining authority of inquiring and modifying some internal parameters.

F3.10 Parameter initialization

Setting range: 0 ~ 9

It is used to change inverter’s parameters into default value. 0: No action 1: Standard initialization: (All parameters in F0~F6 except F0.00, F0.02, F0.05, F0.06, F0.08, F0.11, F0.13 and F3.14 are restored to the default settings) 2: Clearing fault records 3: Complete initialization: (all parameters in F0~F6 group except for F3.14 is restored to default settings and fault records are cleared). 4~9: Invalid

F3.11 Under voltage protection level Setting range: 180 ~230V/360 ~460V
This parameter specifies allowable lower limiting voltage at the DC side when the inverter works normally. For some occasions with low grid, it is applicable
E500 Series Universal Low-Power Inverter

Functional Details 61
to appropriately reduce under voltage protection level so as to ensure normal operation of the inverter. Note: when the grid voltage is too low, the motor’s output torque will reduce. For occasions with constant power load and constant torque load, excessive low grid voltage will cause incease of inverter input current, hence leading to reduction of inverter operation reliablity.

F3.12 Overvoltage limiting action level Setting range: 350 ~400V/700 ~800V

This parameter specifies the threshold value of voltage stall protection during motor decelration. When the pumping voltage at the internal DC side of the Inverter caused by deceleration has exceeded this value, the decerlation time will be automatically prolonged. See figure 6-16.

Frequency

Decelerationtime adjustment

DC voltage
[ F 3[F.31.122]]

Time

Time Figure 6-16 Voltage Stall Protection during Deceleration

F3.13 Current amplitude limiting level

Setting range: 150 ~ 250()

This parameter specifies maximum current allowed to be output by the inverter, which is expressed by the percentage of rated current of the inverter. No watter what working status (acceleration, deceleration and steady running) the inverter is at, when the inverter’s output current exceeds the value specified by this parameter, the inverter will adjust the output frequency to control the current within the specified range to avoid over current tripping.

E500 Series Universal Low-Power Inverter

62 Function Parameter Table Inverter’s control software version number is read only.

F3.15 ~F3.16

Reserve

F3.17 Multi-speed running mode

Setting range: 0000~0042H

Setting of basic characteristics of multi-speed running(fratile decimal system setting)
LED UNITS: Simple PLC action selection
0: Simple PLC void
1: Simple PLC effective
2: Simple PLC conditionally effective When LED Units is selected to 1 (PLC effective), after the inverter has started, at the frequency channel priority allowed status, the inverter will enter the simple PLC running status. When the LED Units is selected to 2 (PLC conditionally effective), when external PLC input terminal is effective(PLC input terminal is selected by parameter [F1.08][F1.11]), the inverter will run at the simple PLC mode; when the external input terminal is void, the inverter will automatically enter the frequency setting mode with lower priority.

LED Tens: Selection of simple PLC running mode
0: Single cycle mode The inverter will firstly runs at the set frequency of the first-section speed, and outputs frequency at each speed according to setting time. If the set running time is 0 at certain section of speed, it will skip over this speed section. The inverter will stop output after end of one cycle, and will not start the next cycle unless the effective running command is input again.
1: Single cycle stop mode
The basic running way is the same as the mode 0, and the difference is that the inverter firstly reduces the output frequency to 0 according to the specified acceleration time after completion of running at certain speed, and then outputs

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Functional Details 63
the next section of frequency. 2: Mode of keeping final value The basic running way is the same as the mode 0. After the completion of the single cycle, the inverter will not stop after completion of a single cycle and continues running at the last speed for which the time is not set to zero. Other process is the same as model 1. 3: Keeping setting value mode The basic running way is the same as the mode 0. After the completion of the single cycle, the inverter will not stop after completion of a single cycle and continues running at the last speed for which the time is not set to zero. Other process is the same as model 1. 4: Continuous cycling mode The basic running way is the same as the mode 0. The inverter will start cycling from the first speed after completion of one cycle. The inverter runs in a cycle of 8 different speeds. That is to say, after completion of running at the 8th speed, it will start running in a cycle from the first speed.

F3.18 Stage 1 running time F3.19 Stage 2 running time F3.20 Stage 3 running time F3.21 Stage 4 running time

Setting range: 0.0 ~ 6000 Sec Setting range: 0.0 ~ 6000 Sec Setting range: 0.0 ~ 6000 Sec Setting range: 0.0 ~ 6000 Sec

[F3.18][F3.21] Multi-speed frequency 14 running time

Note: the running time at different stage means the time from the end time of previous stage to the end time of the current stage, including the acceleration time or deceleration time for running to the current stage frequency.

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64 Function Parameter Table

F3.22 PLC multi-stage running direction Setting range: 0000 ~1111H

Define PLC multi-speed running direction (fratile binary system setting)

LED UNITS: Stage 1 direction selection

0: FEW

1: REV

LED Tens: Stage 2 direction selection

0: FEW

1: REV

LED Hundreds: Stage 3 direction selection

0: FEW

1: REV

LED Kilobit: Stage 4 direction selection

0: FEW

1: REV

F3.23 PLC running timer

Setting range: 0 ~9999Min

When programmable multi-speed running function is selected, this parameter can be used to set programmable multi-speed running time. When the set time is reached, it will automatically stop. For restoring running, it is required to input stop command before the start command. When this parameter is set to 0, timed running stop is void.

F3.24 Fault self-recovery times

Setting range: 0~5

F3.25 Fault self-recovery time

Setting range: 0.0~60.0Sec

During running of the inverter, load fluctuation, grid fluctuation and other accidental factors may cause accidental shutdown of the inverter. At this time, in order to ensure system’s working continuity, the inverter can be allowed to make automatic resetting for some kinds of faults and restore running. The self-recovery interval means the interval from the fault start to the self-recovery. If the inverter cannot restore to normal condition within the set self-recovery times, it will output fault signal. After successful self-recovery, the inverter is at stop and ready status.

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Functional Details 65
F3.26 Swing frequency running setting Setting range: 0000~0012H
This parameter is used to set basic characteristics of swing frequency running (fratile decimal system setting) LED Units: Swing frequency function enabling selection 0: Swing frequency function disabled 1: Swing frequency function effective 2: Swing frequency function conditionally effective When the external swing frequency input terminal is effective (the swing frequency input terminal is selected by functional parameter [F1.08][F1.11]), the inverter runs in swing frequency mode. LED Tens: Center frequency setting 0: digital setting, [F3.31] setting 1: Frequency channel selection is set by frequency channel

F3.27 Swing frequency amplitude

Setting range: 0.0~50.0%

Swing frequency amplitude is the ratio of swing frequency extent. Swing frequency amplitude=[F3.27]×Upper limiting frequency

F3.28 Kick frequency amplitude

Setting range: 0.0~80.0%

The kick frequency is the amplitude of rapid descending after the frequency reaches the upper limit of swing frequency and is also the amplitude of rapid ascending after the frequency reaches the lower limit frequency. Kick frequency =[F3.28] × Swing frequency amplitude

F3.29 Triangular wave descending time F3.30 Triangular wave ascending time

Setting range: 0.1~300.0Sec Setting range: 0.1~300.0Sec

When the triangular wave descending time is the running time from the swing frequency upper limit to swing frequency lower limit during running at the swing

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66 Function Parameter Table
frequency, i.e. the decceleration time during runing cycle at swing frequency. When the triangular wave ascending time is the running time from the swing frequency lower limit to swing frequency upper limit during running at the swing frequency, i.e. the acceleration time during runing cycle at swing frequency.

F3.31 Swing frequency center frequency setting Setting range: 0.0~[F0.04]

Swing frequency center frequency means the center value of inverter’s output frequency at the swing frequency runing status. See Figure 6-17 for detailed process of swing frequency running

Running frequency

Kick frequency [F3.28]

Swing frequency center frequency Swing frequency amplitude [F3.27] [F3.29] [F3.30]

Time

Figure 6-17 Swing Frequency Runing Process

6.5 Communication functional parameter group

F4.00 Communication setting

Setting range: 0000 ~ 0125

This parameter is used to set characteristics relevant with communication (fratile decimal system setting)

LED Units: Baud rate selection

0: Reserve

1: 1200bps

2: 2400bps

3: 4800bps

4: 9600bps

5: 19200bps

When serial port communication is adopted, the communication parties must

have the same baud rate.

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Functional Details 67

LED Tens: Data format selection

0: No check

1: Even check

2: Odd check

When serial port communication is adopted, the communication parties must

have the same baud rate.

LED Hundreds: Protocol selection

0: RS485 protocol

1: MODBUS communication protocol

LED Kilobit: Reserve

F4.01 Local address

Setting range: 0 ~ 30

The local address set for communication of this inverter is only effective when this inverter is used as the slave machine. During communication, this inverter only sends back response frame for data frames corresponding to the local address, and receives command. With the SIMPHOENIX self-defined protocol, the address 31 is the broadcasting address, and 0 represents the broadcasting address in the case of MODBUS communication. For broadcasting data, the slave machine executes command but does not give feedback of corresponding data (see the appendix of communication protocol).

F4.02 Local response delay

Setting range: 0 ~ 1000 ms

The waiting time till sending response data frame after the local inverter has correctly received information code of the upper computer.

F4.03 Setting of communication auxiliary function Setting range: 0000 ~ 0011
LED UNITS: Main and slave inverter setting 0: This inverter is the main inverter 1: This inverter is a slave inverter When multiple inverters requires linkage synchronous control, one of inverters should be set as the main inverter.
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68 Function Parameter Table

LED Tens: Action selection after communication failure

0: Shutdown

1: Maintaining current status

LED Hundreds: Data return selection

0: Normal return of data

1: Do not return data

LED Kilobit: Reserve

F4.04 Communication overtime detection time Setting range: 0.1 ~ 10.0 Sec
When this inverter has not received correct data signal beyond the interval defined by this parameter, it is judged that the inverter has subject to communication failure. Then, it is appliciable to select shutdown or continuing running according to the work mode after communication failure set by [F4.03].

F4.05 Linkage setting ratio

Setting range: 0.1 ~ 10.0

This parameter defines the ratio of main machine and slave machine output frequency at the mode of linkage control. This group parameter of the main inverter does not function. When linkage synchronous control trough RS485 port is achieved, the running command of the slave inverter is completely synchronous with the main machine. The frequency command of the slave machine is calculated according to following method: Slave inverter frequency command = Main inverter frequency command × [F4.05]

6.6 PID parameter group PID control is subject to calculation of ratio, integral and differential according to the difference between the feedback value the controlled system and the target value, so as to adjust the inverter’s output frequency and maintain the controlled system stable with the target signals. The principle is shown in Figure 6-18.

E500 Series Universal Low-Power Inverter

+ Target value
Feedbackvalue

11 Ti S
Td*S+1
P

Functional Details 69 Cosnystrtoemlled

Figure 6-18 PID Function Sketch

F5.00 PID function selection 0: PID function disabled

Setting range: 0 ~ 1 1: PID function enabled

F5.01 PID setting channel

Setting range: 0 ~ 1

It is used to select the setting channel of the PID target value.

0: Digital setting by [F5.02]

1: frequency input channel setting

PID’s set target value is a relative value. The setting 100% is corresponding to

100% of feedback system of the controlled system.

PID feedback channel is fixed as AI input, and its upper limit (100%) and lower

limit (0%) are corresponding to AI input upper limit voltage [F1.00] and AI

input lower limit voltage [F1.01].

F5.02 PID digital setting

Setting range: 0.0~100.0%

The base value of this parameter is the system’s maximum feedback signal.

F5.03 PID feed forward enabling

Setting range: 0000~0001H

0: Feed forward function disabled 1: Feed forward function enabled System’s response speed at start can be increasd.

F5.04 Reserve

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70 Function Parameter Table

F5.06 Ratio grain

Setting range: 0.0~10.0

F5.07 Integral time

Setting range: 0.01~10.00Sec

It iFs5p.0a8rameDteerrigvraotiuvpe otifminener PID controlled. Setting range: 0.00~10.00Sec

F5.09 PID adjustment frequency range Setting range: 0 ~ 100%

This parameter is used to set the upper limit frequency to be a adjusted by PID, which is the percentage of maximum output frequency corresponding to the maximum PID value.

F5.10 Breakage detection lower limiting value Setting range: 0.0 ~50.0%

F5.11 Breakage detection delay time

Setting range: 0.1 ~10.0Sec

If the system’s feedback value is less than the breakage detection lower limiting value, it is deemed that the system is at the break ge status and the system starts detecting breakage. After the delay time, if the system is still at the breakage status, then it is deemed that there is a breakage fault.

6.7 Special machine parameter group

F6.00 Cutting function selection

Setting range: 0000~0001H

This parameter is used to select if this inverter is used for cutter dragging or

cutting control.

0: As the dragging control

1: As the cutting control

F6.01 F6.02

Cutting length Correction of liner speed coefficient

Setting range: 0.01~10.00 Setting range: 0.01~10.00

This group of parameters is effective for cutting control. The cutting length is the set value of required wood length in the unit of meter. [F6.02] parameter is used for length correction which will be done according to mechanical characteristics.

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Functional Details 71

F6.03 F6.04

Start delay Stop delay

Setting range:: 0.01~10.00 Setting range: 0.01~10.00

This group of parameters defines the cutting start delay and stop delay, which is related to the length of the first plate and last plate.

F6.05 Reserve

F6.06 Liner cutting running mode

Setting range: 0 ~2

This parameter is used to select if it is needed to enable liner cutter function. 0: Disable cutter function 1: Liner cutter mode 1(this mode is applicable to high-speed wire mode) 2: Liner cutter mode 2 (this mode is applicable to the medium-speed wire mode)

F6.07 Forward time F6.08 Return time

Setting range: 0~60.0Sec Setting range: 0~60.0Sec

This group of parameters defines the forward and backward time in the next cycle in the reciprocating mode.

F6.09 High-frequency relay start frequency

Setting range: [F6.10]~100%

F6.10 High-frequency relay disconnection frequency 1 Setting range: 0~[F6.09]

F6.11 High-frequency relay disconnection frequency 2 Setting range: 100~200%

This group of parameters is used to set the conditions for engaging or disengaging high-frequency relay. When the inverter’s output frequency is higher than the frequency set by [F6.09]*, the high-frequency relay is engaged. When it is lower than the frequency set by [F6.10], the high- frequency relay is disengaged. In the liner cutting mode 2, when the inverter’s output frequency is higher than frequency set by [F6.11], the high- frequency relay is disengaged.

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72 Function Parameter Table
6.8Vector control parameter group

F7.00 Control mode selection

Setting range: 0~1

This parameter is used to select control mode: 0: V/F control 1: SVC (open loop vector) control

F7.01~ F7.05 Motor rated parameter

Setting range: —-

To guarantee the control performance, please refer to AC asynchronous motor nameplate parameters:
1 Set the nameplate parameters correctly. 2Motor and inverter power should match with each other. Generally, inverter is only allowed to drive 2-level smaller or 1-level larger motor. Once rated frequency (F7.01) changed, following parameters will be matched automatically, please modify them in order.

F7.06~ F7.08 Motor internal parameter

Setting rangte: —-

This group of parameter will be automatically updated after parameter identification, users have no need to set it.

F7.09~ F7.13 Reserve

F7.14 Pre-excitation time

Setting range: 0~3.0S

This parameter group is used to define pre-excitation time before motor start.
It needs a certain amount of time (approximately equal to the rotor time constant) to form AC asynchronous motor air-gap flux. When motor is under stop state before starting, air-gap flux must be formed in advance to obtain a sufficient start torque.
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Functional Details 73

F7.15 Motor parameter identification

Setting range: 0~1

Motor parameter tuning function can start only under vector control mode(F7.00=1).
0 Off 1 Static identification During parameter tuning process, motor remains stop state and it has no requirements on the connection relationship with motor shaft, but the tuning accuracy is relatively low.

F7.16~ F7.18 Reserve

F7.19 Speed loop proportional coefficient

Setting range: 0.10~1.5

F7.20 Speed loop integral time

Setting range: 0.1~10.00

This parameter group is used to adjust the proportional gain, integral time and differential coefficient of the speed regulator, please refer to parameter setting principle as following:
1 Proportional gain P: when the value is bigger, the response is faster, but its system stability is worse. Excessive gain may cause speed oscillation.
2Integral time constant 1: when the value is smaller, the response is faster and speed overshoot is larger, then its system stability is worse. Generally, this paramter is proportional to the system inertia. When the inertia is large, the parameter value should be large too.

F7.21 Max. FWD torque limit F7.22 Max. RED torque limit

Setting range: 0~200% Setting range: 0~200%

E500 Series Universal Low-Power Inverter

74 Function Parameter Table This parameter is used to set the output range of the regulator,
limiting instantaneous positive and negative torque of the system. The set value is a percentage in accordance with the rated torque.
F7.23 Reserve

F7.24 Speed estimate coefficient

Setting range: 0.1~5.0

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Fault Diagnosis And Countermeasures 75

7 Fault Diagnosis And Countermeasures

7.1 Protection function and countermeasures

Fault Code Fault Description

Possible Reasons

Solutions

Fu.01

Over current occurs in inverter
acceleration running process

1. The acceleration time is too short.
2. Start the rotating motor directly.
3. The torque boost is preset as too large.
4. The network voltage is too low.

1. Extend acceleration time. 2. Restart the motor after stop 3. Reduce voltage of torque
boost. 4. Check the network voltage
and reduce power.

Fu.02

Over current occurs in inverter
deceleration running process

The acceleration time is too short.

Increase the acceleration time

Fu.03

Over current occurs in inverter
running or stop condition

1. Load changes suddenly 2. The network voltage is
too low.

1. Reduce the load fluctuation.
2. Check the power voltage.

Fu.04

Overvoltage 1. The input voltage is too occurs in inverter high.
acceleration 2. Put the power on and running process off frequently.

1. Check the power. 2. Lower the setting of
acceleration torque level.

Fu.05

Overvoltage 1. The acceleration time is occurs in inverter too short.
deceleration 2. The input voltage is running process abnormal.

1. Extend the acceleration time.
2. Check the power voltage. 3. Install braking resistor or
reselect braking resistor.

Fu.06

Overvoltage occurs in inverter running process

1. The power voltage is abnormal.
2. There is energy feedback load.

1. Check the power voltage. 2. Install the braking unit and
braking resistor or reselect braking resistor.

Fu.07

Overvoltage occurs in inverter
stop condition

The power voltage is abnormal.

Check the power voltage.

Fu.08

Under-voltage occurs in inverter running process

1. The power voltage is abnormal.
2. There is starting operation of heavy load in network.

1. Check the power voltage. 2. Supply power separately.

Fu.09 ~Fu.11

Reserve

Fu.12

1. The load is too large. 2. The acceleration time is
too short. Inverter overload 3.The torque boost is too
high. 4. The network voltage is
too low.

1. Reduce load or change a larger capacity inverter.
2. Extend the acceleration time.
3. Reduce the voltage of torque boost.
4. Check the network voltage.

E500 Series Universal Low-Power Inverter

76 Fault Diagnosis And Countermeasures

Fault Code Fault Description

Possible Reasons

Fu.13

Motor overload

1. The load is too large. 2. The acceleration time is
too short. 3. The protection factor
Setting is too small. 4. The torque boost is too
high.

Fu.14

1. Air duct obstruction

Inverter overheat

2. The environment temperature is too high.

3. The fan is damaged.

Fu.15

Reserve

Fu.16

External

The exterior fault input

equipment fault terminal is ineffective.

Fu.17 ~Fu.19 Fu.20
Fu.21 Fu.22
Fu.23

Reserve

Current detection error

The current detection devices or circuit is damaged.

Temperature The temperature sensor is sensor fault off-line.

Reserve
PID feedback off-line

1 The feedback signal is lost.
2. The setting of off-line detection threshold value is not appropriate.

Solutions
1. Reduce load. 2. Extend the acceleration
time. 3. Increase the overload
protection factor of motor. 4. Reduce torque boost.
1. Clean air duct or improve ventilation condition.
2. Improve the ventilation condition and reduce the carrier frequency.
3. Change fan.
1. Check the exterior equipment.
2. Disconnect the external fault input terminal.
1. Check socket line. 2. Ask for manufacturers’
assistance.
1. Check socket line. 2. Ask for manufacturers’
assistance.
1. Check line. 2. Reduce threshold value of
off-line detection.

Fu.24 ~Fu.39

Reserve

Fu.40

Internal data The read-write errors of EEPROM error control parameters

Ask for manufacturers’ assistance.

7.2 Fault record query The series of inverters recorded the recent fault code occurred in the last four times and the inverter output parameters of the last fault; query of these information will contribute to find fault causes.

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Fault Diagnosis And Countermeasures 77

Monitoring project

content

d-23 The first fault record

d-24 The second fault record

d-25 The third fault record

d-26 The fourth fault record The output frequency of
d-27 the last fault recently

Monitoring project

content

d-28

The output current of the last

fault recently

The output voltage of the

d-29

last fault recently

The direct voltage of the last d-30
fault recently

The module temperature of d-31
the last fault recently

The fault information and condition monitoring parameters are stored in a unified manner; please refer to the keyboard operation method to query information.

7.3 Fault reset

The fault causes must be identified and removed completely prior to reset, otherwise it may cause permanent damage to the inverter.
If the inverter can’t be reset or fault occurs after reset, it’s necessary to find out causes, otherwise continuous reset will damage the inverter.
The protection actions of overload and overheat should be delayed for 5 minutes when reset.

To recover to the normal operation when the inverter fault occurs, it’s optional to choose any of the following operations.

Method I: Press

RUN STOP

key when displaying fault

code.

Method II: Disconnect after closure of external multi-function terminals X1~X4

(fault reset) and CM.

Method III: Send the fault reset command via RS485 interface.

Method IV: Cut off power supply.

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78

SIMPHOENIX Self-Defined Communication Protocol

Appendix I: SIMPHOENIX Self-defined Communication Protocol
1.1 Overview E500 model provides standard RS485 communication port, so users can realize centralized monitoring (send running command, set inverter running parameters and read inverter working status) by PC/PLC to meet specific application requirements. The protocol content of the appendix is designed to achieve the above functions.
1.1.1 Protocol Content The serial communication protocol defines the transmitted information content and applicable format in the serial communication protocol, including: main machine polling (or broadcast) format; main machine encoding method; the content includes the function code of the required action, data transmission and error checking, etc. The slave machine response also employs the same structure; the content includes action confirmation, feedback data and error checking, etc. If slave machine goes wrong or fails to complete the required actions of man machine when receiving information, a fault message will be organized and sent to the main machine as response.
1.1.2 Application Scope 1. Applicable products
The series of SIMPHOENIX inverters, e.g. C300 series, C320 series, the E500 series, E280 series, etc. can be compatible with the communication protocols of the other brands of inverters.
2. Applicable methods (1) Inverter is accessed to the PC/PLC control network with “One main machine
and multiple slave machines” and RS485 bus. (2) Inverter is accessed to the “Point-to-point” PC/PLC monitoring background
furnished with RS485 / RS232 interface (conversion interface).
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SIMPHOENIX Self-Defined Communication Protocol 79
1.2 Bus Structure and Protocol Specification 1.2.1 Bus Structure
1. Physical layer Standard RS485 bus.
2. Transmission mode Asynchronous serial and half-duplex transmission mode. Either main machine or slave machine can send data at the same time, while the other one can receive data only. The data will be sent frame by frame in message format in the process of serial asynchronous communication.
3. Topology mode Single main station system is compatible with 32 stations at most with one station for main machine and the other 31 stations for slave machine. The setting range of slave address is 0-30, while 31(1FH) is the broadcast communication address. The slave address must be unique in the network. In fact, point-to-point mode is identified as special applications case of topology mode with “One main machine and multiple slave machines”, namely the condition of existing only one slave machine.
1.2.2 Protocol Specification E500 series is applicable to MODBUS (please refer to Appendix II for details) and SIMPHOENIX custom communication protocol, which is to be described as follows: SIMPHOENIX custom communication protocol is a serial master-slave communication protocol, only one device (main machine) in the network can set up protocol (named as query/command), while the other devices (slave machine) can provide data to response query/command of main machine or operate the corresponding actions in line with query/command of main machine. Here, main machine refers to personal computer (PC), industrial personal computer (IPC) or programmable logic controller (PLC), etc., while slave machine refers to the inverter. Main machine can separately access some slave machine and send broadcast message to all slave machine. As for query/command for separate
E500 Series Universal Low-Power Inverter

80 SIMPHOENIX Self-Defined Communication Protocol
access sent by main machine, slave machine should feedback one message (named as response); as for broadcast message sent by main machine, it’s not necessary for slave machine to make any feed- back to main machine. 1. Communication setting F4.00=X0XX, select SIMPHOENIX custom communication protocol. 2. Data structure Available in three types of data transmission formats:
(1) 1-bit start bit, 8-bit data bit, 1-bit stop bit, no check. (2) 1-bit start bit, 8-bit data bit, 1-bit stop bit, even parity check (factory settings). (3) 1-bit start bit, 8-bit data bit, 1-bit stop bit, odd parity check. 3. Baud rate Available in five types of Baud rates: 1200bps, 2400 bps, 4800 bps, 9600 bps, 19200 bps. 4. Communication mode (1) Adopt point-to-point communication mode with main machine for polling and slave machine for response. (2) Employ inverter keyboard to set up inverter serial interface communication parameters, including local address, Baud rate and data format.
The main machine must be preset with the same Baud rate and data format with the inverter.
5. Communication rules (1) More than 5 bytes of start interval time between data frames should be
guaranteed and only messages in compliance with the specified start interval time is valid after being identified.
(2) The main machine connection waiting time and maximum response time of inverter are 8 bytes transmission time; if timeout occurs, it will be determined as communication fault.
E500 Series Universal Low-Power Inverter

Setting Data Setting Data Setting Data Setting Data

SIMPHOENIX Self-Defined Communication Protocol 81 (3) If the inverter fails to receive any message after detecting time from communication timeout (function code: F4.04), it’s identified as off-line fault, and then the inverter determines operating status of slave machine in line with setting content set by communication aid function (function code: F4.03). (In case of receiving message from main station in the period, it’s necessary to make control based on control word of new message). 1.2.3 Message structure The frame size of each message is between 11 and 18 bytes (depend on data format) and the character type can be ASC II code and hexadecimal value. Data representation rules: hexadecimal, high-order first and then low-order, shown as below: (1) The ASC II code of data 3800H is expressed as the following:
Data location 9 10 11 12
Data value (hexadecimal) 33 38 30 30
(2) The hexadecimal value of data 3800H is expressed as the following (invalid bit is filled with hexadecimal “0”):
Data location 9 10 11 12
Data value (hexadecimal) 00 00 38 00
E500 Series Universal Low-Power Inverter

Setting Data Setting Data Setting Data Setting Data

82 SIMPHOENIX Self-Defined Communication Protocol 1. Command frame of main machine
0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17

Frame end Checksum Checksum Checksum Checksum Setting Data Setting Data Setting Data Setting Data Data address Data address Data classification Operation command Operation command Command classification Slave address Slave address
Frame header

Sending sequence

Define

Station address

Command area

Address area

Data area

Check area 0DH

2. Response frame of slave machine General description of data definition in data frame 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17

Frame end

Checksum

Checksum

Checksum

Checksum

Running data

Running data

Running data

Running data

Data address

Data address

Data classification

Status feedback

Status feedback

Slave machine response

Slave address

Slave address

Sending sequence

Frame header

Define

Station address

Response area

Address area

Data area

Check area

0DH

(1) Frame header The communication protocol specifies that “2AH” (refers to ASC II code of character “*”) and “5AH” are valid frame header. When frame header is “2AH”, all data following frame header is default as ASC II character; when frame header is “5AH”, all data following frame header is default as hexadecimal value and the redundant invalid bytes are filled with “0”. Independent “2AH” or “5AH” cannot be identified as valid frame header, a waiting time of more than 5 transmission bytes must be guaranteed in advance, which is considered as the starting condition of forming one frame data. (2) Slave address The setting range of inverter local address is 0 30 and 31(1FH) is broadcast communication address.

E500 Series Universal Low-Power Inverter

SIMPHOENIX Self-Defined Communication Protocol 83

(3) Command classification Command classification exists in the data frame sent by main machine, which is used to define tasks of the frame data to be completed. Frame size varies based on different command classification. Command classification is defined as below:

Data 0 1 2
3
4
5 6F

Operation

Read status and feature information of slave machine
Read running parameters of slave machine
Read function code parameters Modify function code parameters in inverter RAM area and to be lost after power down (Not to be saved) Send control command Modify function code parameters in inverter EPROM area and to be saved after power down Reserve

(4) Operation command The upper machine transmits operation command to slave machine, which exists in all types of data frame (main machine send the 4th and 5th bit). The operation command is defined as below:

Data 00H

Operation Invalid command

01H

FWD running start

02H

REV running start

Data 10H 11H 12H

Operation
Set running frequency of slave machine
Frequency setting of tape running in FWD running start
Frequency setting of tape running in REV running start

03H

Stop

13H

Frequency setting of tape running in stop condition

… … … …

20H

Fault reset of slave machine

30H Reserve

21H

Emergent stop of slave machine

31H Reserve

If don’t need to send operation command, please send invalid command “00H”.

E500 Series Universal Low-Power Inverter

84 SIMPHOENIX Self-Defined Communication Protocol

(5) Slave machine response The response of slave machine to data sent by main machine is mainly used to feedback implementation of slave machine to command frame of main machine, which exists in all types of data frame. The slave machine response is defined as below:

Data

Meaning

0

Slave machine receives data, normal operation

Data

Meaning

1

The received data range is over ranging

2

Slave machine running forbids modifying data

3

Data modification is forbidden by password

4

Try to read-write reserve/hidden parameters

The specified parameter code

6

or address are illegal (over

ranging)

5

Reserve

When transmitting data in ASC

7

II code, illegal ASC II character

exists.

8

Illegal command classification or operation command

9F

Reserve

When the data of response byte of slave machine is “6-8”, the response frame size is 11 bytes.

The frame format is shown as below:

Station address

Command / Response area

Check area

0DH

Frame end Checksum Checksum Checksum Checksum
Slave machine response Slave address Slave address Frame header
Slave machine response Definition

E500 Series Universal Low-Power Inverter

SIMPHOENIX Self-Defined Communication Protocol 85

(6) Status feedback The basic running status of slave machine responded from slave machine to main machine exists in all types of data frame (Slave machine responds the 4th and 5th bit).

Data

Operation

00H

The direct voltage of slave machine is not ready

Data

Operation

10H

Reserve

01H

In FWD running of slave machine

11H

In FWD acceleration process

02H

In REV running of slave machine

12H

In REV acceleration process

03H

Slave machine stop

13H

Instant stop and restart

04H

In FWD inching running of slave machine

14H

FWD deceleration

05H

In REV inching running of slave machine

15H

REV deceleration

06H

Reserve

16H

The slave machine is in DC braking status

20H

The slave machine is in fault status

21H

Instant stop of slave machine

(7) Checksum The sum of ASC II code value (ASC II code format)/hexadecimal value from slave address to setting data/running data. (8) Frame end Hexadecimal “0DH” is ASC II code of “CR”.

When the slave machine is in fault status, namely status feedback data is “20H”, the 7th and 8th data (data address) of feedback data frame represents fault code.

E500 Series Universal Low-Power Inverter

86 SIMPHOENIX Self-Defined Communication Protocol
1.3 Description of frame format
When frame header, frame end and checksum in data frame sent by main machine are abnormal, slave machine possibly fails to make normal response.
1.3.1 Command classification 0- Read status and feature information of slave machine Main machine sending frame size is 14 bytes, while slave machine response frame size is 18 types.
0 1 2 3 4 5 6 7 8 9 10 11 12 13

0

00

Frame end Checksum Checksum Checksum Checksum
Data classification Operation command Operation command
Slave address Slave address Frame header Sent by main machine

0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17

Frame end Checksum Checksum Checksum Checksum Feature information Feature information Feature information Feature information Feature information Feature information Data classification Status feedback Status feedback Slave machine response Slave address Slave address Frame header Slave machine response

Note: In accordance with different data classification value in the frame sent by main machine, the slave machine will feedback different feature information.

Data classification (Sent by main machine)
6 Read model 0 information of slave machine Read series 1 information of slave machine

Feature information (Slave machine response )

7

8

9

10

11

12

Voltage class

0

Power Power Power Power

Reserve Reserve Reserve Reserve Reserve Reserve

E500 Series Universal Low-Power Inverter

SIMPHOENIX Self-Defined Communication Protocol 87

Data classification (Sent by main machine)

Feature information (Slave machine response )

2
3 4F

6 Read program version of slave machine
Read operation information of slave machine
Reserve

7

8

9

10

11

12

Reserve Reserve #

Main machine control

Main machine frequency

Reserve

setting

Reserve #

Reserve #

Reserve #

For example: If the data classification value in the frame sent by main machine

is 0, the feedback information of slave machine is 400015,which means that 4

represents voltage class­380V; 0 is feature information value; 0015 represents power­1.5kw.

1.3.2 Command classification 1- Read running parameters of slave machine Main machine sending frame size is 14 bytes, while slave machine response frame size is 18 types.
0 1 2 3 4 5 6 7 8 9 10 11 12 13

1

0

Frame end Checksum Checksum Checksum Checksum Data subentry Data subentry
Operation command Operation command
Slave address Slave address Frame header Sent by main machine

0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 0

Frame end Checksum Checksum Checksum Checksum Running data Running data Running data Running data Data subentry Data subentry
Status feedback Status feedback Slave machine response Slave address Slave address Frame header Slave machine response

E500 Series Universal Low-Power Inverter

88 SIMPHOENIX Self-Defined Communication Protocol

Data subentry: is corresponding to number of monitoring parameter items of the

inverter; as for E500 series inverter, the number of monitoring parameter items

is shown as below:

Monitoring item d.0 d.1

Data subentry
00 01

Slave machine response data
output frequency output voltage

… …
… … … …

d-31

31

The module temperature of the last fault recently

The monitoring parameter of inverter refers to Chapter 4 of E500 series inverter operation manual: Article 4.3 List of status monitoring parameter.

1.3.3 Command classification 2- Read function code parameters Main machine sending frame size is 14 bytes, while slave machine response frame size is 18 types.
0 1 2 3 4 5 6 7 8 9 10 11 12 13

2

Frame end Checksum Checksum Checksum Checksum Data address Data address Data classification Operation command Operation command
Slave address Slave address Frame header Sent by main machine

0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17

Frame end Checksum Checksum Checksum Checksum Parameter data Parameter data Parameter data Parameter data Data address Data address Data classification Status feedback Status feedback Slave machine response Slave address Slave address Frame header Slave machine response

The data classification and data address refer to command classification 3 and 5.
E500 Series Universal Low-Power Inverter

Frame end Checksum Checksum Checksum Checksum Setting data Setting data setting Data Setting Data Data address Data address Data classification Operation command Operation command
Slave address Slave address Frame header Sent by main machine

Frame end Checksum Checksum Checksum Checksum Setting data Setting data Setting data Setting data Data address Data address Data classification Status feedback Status feedback Slave machine response Slave address Slave address Frame header Slave machine response

SIMPHOENIX Self-Defined Communication Protocol 89 1.3.4 Command classification 3- Modify function code parameters in inverter RAM area. 1.3.5 Command classification 5- Modify function code parameters in inverter EPROM area Main machine sending frame size is 18 bytes, while slave machine response frame size is 18 types.
0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 3 or 5
0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17
Definition of data classification:
F0 F1 F2 F3 F4 F5 F6 F7 F8 F9 FC FE FF FH FL FP
0 1 2 3 4 5 6 7 8 9ABCDEF The relative address of function code, e.g. the data address of F0.08, F1.08, F2.08 and F#.08 is 8, but data classification varies. Note: When slave machine fails to complete main machine command, the feedback setting data is 0000.
E500 Series Universal Low-Power Inverter

Function

code block classification

Data

Frame end Checksum Checksum Checksum Checksum Setting data Setting data Setting data Setting data Operation command Operation command
Slave address Slave address Frame header Sent by main machine

Frame end Checksum Checksum Checksum Checksum Running data Running data Running data Running data Monitoring item Monitoring item
Status feedback Status feedback Slave machine response Slave address Slave address Frame header Slave machine response

90 SIMPHOENIX Self-Defined Communication Protocol 1.3.6 Command classification 4- Send control command Main machine sending frame size is 15 bytes, while slave machine response frame size is 18 types. In normal operation of inverter, the type of frame data is applicable to maximum extent.
0 1 2 3 4 5 6 7 8 9 10 11 12 13 14
4
0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17
0
The setting data in the frame sent by main machine is the set frequency sent from main machine to slave machine. The running data in the slave machine response frame is running parameter sent by main machine, which is determined by setting content of monitoring item (function code: [F3.08]) in inverter functional parameter list, and slave machine responds the item monitoring value.
The inverter functional parameter list refers to Chapter 5 of E500 series inverter operation manual: Functional parameter list.
E500 Series Universal Low-Power Inverter

SIMPHOENIX Self-Defined Communication Protocol 91

1.4 Example

1.4.1 Read status and feature information of slave machine (Command

classification 0)

Data setting: Read model of slave machine

Sent by main
machine

Frame header

Number of bits

1

Slave address
2

Command type 1

Operation command
2

Data classification
1

Data subentry
2

Checksum 4

Frame end 1

2A 30 30

30

Example

5A 00 00

00

30 31 00 01

30

30 30

30 31 38 31

0D

00

00 00

00 00 00 01

0D

Description

Frame header

Address 00

No. 0 command

Start

No data classification

Hexadecimal Frame accumulation end

Data feedback: the model is 2S0004.

Slave machine response

Frame header

Slave address

Number of bits

1

2

Slave Status

Data

response feedback classification

1

2

1

Feature information
6

Checksum

Frame end

4

1

2A 30 30

30

30 33

30

Example

5A 00 00

00

00 03

00

32 30 30 30 30 34
02 00 00 00 00 04

30 32 34 39

0D

00 00 00 09

0D

No.0

Description

Frame header

slave machine

response

Slave Slave machine machine No data receives in stop classification
data condition

02voltage class -2S 04power 0.4KW

Hexadecimal accumulation Frame
or decimal end accumulation

1.4.2 Read running parameters of slave machine (Command clas

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