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Hauptstraße 119 – 121 Telefon +49-6205-3948-0 E-Mail [email protected] D-68804 Altlußheim Telefax +49-6205-37560 Web www.et-system.de

LAB/SLV1 and LAB/SLV1-BSS User manual Version information

Version: 1.0

Software upgrade might change or add product features. Please acquire the latest

version of the manual from our website or contact technical support.


Summary of Safety Requirement

Please review the following safety precautions carefully before putting the

equipment into operation so as to avoid any personal injury or damage to the

equipment and any product connected to it. To prevent potential hazards, please

follow the instructions specified in this manual to use the instrument properly.

Use Proper Cables

Please choose the proper specification cable according to the equipment

specification within the local country could be used.

Ground the Equipment

The equipment is grounded through the Protective Earth Bus. To avoid electric

shock, connect the earth terminal to the Protective Earth terminal before connecting

any input or output terminals.

Use Proper Overvoltage Protection

Ensure that no overvoltage (such as that caused by a bolt of lightning) can reach the

product. Otherwise, the operator might be exposed to the danger of an electric shock.

Avoid Circuit or Wire Exposure

Do not touch exposed junctions and components when the unit is powered on.

Keep Equipment Surfaces Clean and Dry

To avoid dust or moisture from affecting the performance of the equipment, keep the

surfaces of the equipment clean and dry.

I


Safety Notices and Symbols

Safety Notices in this Manual:

WARNING Indicates a potentially hazardous situation or practice which, if not avoided, will

result in serious injury or death.

CAUTION Indicates a potentially hazardous situation or practice which, if not avoided, could

result in damage to the product or loss of important data.

Safety Terms in this Manual: DANGER It calls attention to an operation, if not correctly performed, could result in injury

or hazard immediately.

WARNING

CAUTION

It calls attention to an operation, if not correctly performed, could result in

potential injury or hazard. It calls attention to an operation, if not correctly performed, could result in

damage to the product or other devices connected to the product.

Safety Symbols on the Product or in this Manual:

Hazardous Safety Warning Protective Earth Test Ground Chassis Ground Voltage Terminal

II


Important Safety Instructions

Please read this manual thoroughly before putting the equipment into

operation. Pay regard to the following safety instructions and keep this manual

nearby for future purpose.

INITIAL OPERATION

This operating manual is based on the state of technology at the time of printing.

However, it is possible that despite regular control and correction, the present document

contains printing errors or deficiencies. ET System electronic GmbH assumes no liability

for any technical, printing or translational errors within this manual.

UNPACKING

Please make sure that the shipping carton and the packaging is free of damage. If

external damage is found, it is important to record the type of damage. Please keep

the original packaging to ensure the device is adequately protected in case it needs

to be transported in the future or claims for compensation need to be asserted.

SETTING UP

To avoid electric shocks and product failure, the device should be installed in a

temperature and humidity controlled indoor environment. The ambient temperature

must not exceed 40℃. The device must never be exposed to liquids or extreme

humidity.

VISUAL INSPECTION

The unit must be examined immediately for defects or damages in transit. Damage

caused during transport may be loose or broken control knobs and bent or broken

connectors. Do not use the device if any physical damage is apparent. Please inform

the carriers and a representative of ET System electronic immediately.

MAINS OPERATION

Make sure to verify the model number and voltage stated on the nameplate.

Damages due to wrong power feed are not covered by guarantee conditions.

III


CAUTION

The unit must only be operated when connected directly to the mains. To

avoid damage, do not connect the unit to isolating transformers, auto-

transformers, magnetic current limiters or similar devices.

INTENDED USE The device corresponds to protection class I and has a galvanic isolation between the input and the output circuit. The device must be grounded on the input side, since the grounding ensures protection against contact. In the case of locally variable devices, the earth is connected to the device by means of a cold-plug connector, and the ground is connected to the screw terminal provided for locally-variable devices (screw contacts at the grid input). In the case of devices with high leakage current (marking on the device), the existing grounding bolt must additionally be connected to the domestic installation earth. For compliance with the EMC and safety regulations (CE, approvals), the device may only be operated with PE connected. The device may only be operated by trained personnel and in accordance with the instructions for use. Typical fields of application are laboratories, industry and service engineering. Applications which can lead to injuries or death in the event of a fault in the device are not permitted.

INFO & CONTACT ADDRESSES

ET System electronic GmbH was founded in 1986 in the heart of the Rhine-Neckar-Triangle. As a subsidiary of a leading electricity utility group, the company quickly took on a leading role in the area of laboratory power electronics and associated electrical measurement. The existing know-how in power technologies in the 90s gave rise to the “Power Solutions” product division as a strong extension of the historical “Test & Measurement” range. Since 1997, we have been working successfully as an independent, privately held company with customers in all lines of business from industry, medical care, railway technology and automotive electronics. By means of our high vertical range of manufacture and our ever expanding development division we can fast and flexibly adjust to our customers’ requirements. Necessary approvals such as CSA, UL, VDE, TÜV etc. are flexibly carried out by qualified personnel. The approvals procedures are performed within the scope of development planning and thus do not negatively impact the start of manufacturing. Permanent manufacturing control through accredited laboratories and an ISO 9001 compliant quality management system guarantee a constant high-level series-production quality. We offer repairs and adjustment for units outside of our warranty period. Please contact your local distributor for further information:

IV

Germany Great Britain France Korea

ET System electronic GmbH Hauptstraße 119-121

68804 Altlußheim

Germany

ET Power Systems Ltd. The Bridge Business Centre

Chesterfield S41 9FG

United Kingdom

ET Systeme electronic 4 rue Ampère

38080 L’Isle d’Abeau

France

ET System electronic Korea Corporation

DaeHyeon Techno World 1203 19,Ojengongeup-gil,

Uiwang-si, Gyeonggi-do 437-753

Republic of Korea

Phone: +49 (0) 6205 39480

Fax: +49 (0) 6205 37560

Phone: +44 (0) 1246 452909

Fax: +44 (0) 1246 452942

Phone: +33 (0) 474 278234

Fax: +33 (0) 474 278068

Phone: +82 (0) 31 451 4491

Fax : +82 (0) 31 453 4459

em@il: [email protected] web: www.et-system.de

em@il: [email protected] web: www.et-system.com

em@il: [email protected] web: www.et-system.fr

em@il: [email protected] [email protected] web: www.et-system.kr


SLV1 & BSS Series Overview1

Main Features Fast transition between source and sink

Simulation of battery

Electrical isolation to grid

TFT display with touch operation

Emergency Stop button on front panel

Indicator light for working status on front panel

Forced air cooling

Highly dynamic inverter

Three operation mode of constant voltage,

constant current, constant power

DC output contactor

External sense terminals for line drop compensation

Insulation monitoring

Customer specific design BSS-60-1000

Characteristic of Output for BSS-60-1000

1 Note: SLV1 & BSS series have similar functions, but different output characteristic, please refer to the curve below, and detailed characteristic refer to datasheet of product

V


Characteristic of Output for SLV1-60-1000

Applications

Application Scenarios

Simulation of battery or energy storage system, test Battery simulation performance of motor and motor’s Energy Recovery

System

Testing battery Cycle life, Capacity, Performance of charge & discharge

Testing PV inverter Simulation of photovoltaic characteristics

(Option)

VI


Document Overview

Chapter 1 Quick Start

Introduce the appearance, front panel, rear panel as well as user interface of power

source. In addition, it provides the detailed procedures of power connection, power-

on inspection and fuse replacement.

Chapter 2 GUI Control Software

Introduce the function and operation method of product’s control software in detail.

Chapter 3 Remote Control

Introduce how to realize the remote control of the equipment.

Appendix A — Specification of SLV1

Series List the specifications of SLV1 Series.

Appendix B — Specification of BSS

Series List the specifications of BSS Series.

VII


Content

Chapter 1 Quick Start ........................................................ ......................................... 1

1.1 General Inspection ........................................................................................................ 2

1.2 Appearance and outline ................................................................................................ 3

1.3 Front Panel .................................................................................................................... 3

1.4 Rear Panel .................................................................................................................... 4

1.5 Connect to Power .......................................................................................................... 5

1.6 Power-on Inspection ...................................................................................................... 6

1.7 Replace the Fuse .......................................................................................................... 7

1.8 User Interface ................................................................................................................ 8

Chapter 2 Control Software ........................................................................................ 9

2.1 Setting ......................................................................................................................... 10

2.2 Normal Mode ............................................................................................................... 11

2.2.1 Constant Voltage Mode ........................................................................................ 11

2.2.2 Constant Current Mode ........................................................................................ 12

2.2.3 Constant Power Mode .......................................................................................... 13

2.2.4 Constant Resistance Mode (OPTION)................................................................... 13

2.3 Battery Mode ............................................................................................................... 14

2.3.1 Battery Simulation ................................................................................................. 14

2.3.2 Battery Tester ....................................................................................................... 15

2.4 PV Mode (OPTION)............................................................................................... 17

2.4.1 I-V Curve Setting .................................................................................................. 17

2.4.2 Dynamic MPPT Test ............................................................................................. 19

2.4.2 Static MPPT Test .................................................................................................. 20

2.5 Wave Monitoring ......................................................................................................... 20

2.6 Fault Monitoring ........................................................................................................... 22

2.7 Query ....................................................................................................................... .... 23

2.7.1 History Log ............................................................................................................ 23

2.7.2 History Data .......................................................................................................... 23

Chapter 3 Remote Control ....................................................................................... 25

3.1 Computer Setting ........................................................................................................ 25

3.2 Software Setting .......................................................................................................... 25

3.3 Remote Control ........................................................................................................... 26

Appendix A — Specification of SLV1 Series ............................................................ 27

Appendix B — Specification of BSS Series .............................................................. 31


Chapter 1 Quick Start

The contents of this chapter are as follows:

General Inspection

Appearance and outline

Front Panel

Rear Panel

Connect to Power

Power-on Inspection

Replace the Fuse

User Interface

1 / 44


1.1 General Inspection

1. Inspect the packaging

If the packaging has been damaged, do not dispose the damaged packaging or

cushioning materials until the shipment has been checked for completeness and has

passed both electrical and mechanical inspection.

The consigner or carrier shall be liable for the damage to the product resulting from

shipment. Factory would not be responsible for free maintenance/rework or

replacement of the product.

2. Inspect the product

In case of any mechanical damage, missing parts, or failure in passing the electrical

and mechanical tests, contact your local sales representative.

3. Check the accessories

Please check the accessories according to the packing lists. If the accessories are

damaged or incomplete, please contact your local sales representative.

2 / 44


1.2 Appearance and outline

The equipment adopts integrated

module design, the appearance is

simple and generous.

The front panel is composed of a

touch TFT LCD panel, a power

switch, indicator lights and an

emergency stop button.

The rear panel is composed of a

communication port and a line

voltage drop compensation terminal.

Figure 1-1 Front View Figure 1-2 Rear View

1.3 Front Panel

This section introduces the front panel of SLV1 & BSS series by taking BSS-100-

1000 (as shown in the figure below) as an example. The differences of models are

introduced separately.

Figure 1-3 Front Panel of SLV1 & BSS series

3 / 44


1. LCD

12 inches TFT display. It is used to display the system parameter setting, system

output state, menu items, prompt messages, etc. The touch displayer panel is a

capacitive touch TFT screen, and is based on Windows operating system. GUI

Control software is designed on the platform of LabView.

2. LED Indicator of Status

LEDs indicate the working state of the power source in a concise manner. It includes

work indicator of power, indicator of standby mode, indicator of running and fault

indicator.

AC On While the input line is powered on, the light will be lit.

Standby System is standby.

Run System is running normally.

Fault There is a system error.

3. Rotary Switch

Turn on or off the power source. When the rotary switch is turned on, the power

source would be in standby mode.

4. Emergency Stop Button

The emergency stop button is only used when an unexpected emergency occurs. Do

not press this button in normal working condition.

1.4 Rear Panel

This section introduces the rear panel of SLV1 & BSS series by taking BSS-100-

1000 (as shown in the figures below) as examples. The introduction of each part is

as in Table 1-1.

Figure 1-4 Rear Panel of SLV1 & BSS series

4 / 44


LAN This interface is a communication interface used for remote control

Debug The Debug port is reserved for firmware update or debug

External Sense Terminal of voltage compensation for long distance

The output voltages at the load can be directly monitored via the external sense on

the back of the power source, which is usually for long distance power transfer.

1.5 Connect to Power

SLV1 & BSS series power source supports the world grid standards, but a particular

product supports the GRID SYSTEM only for one country or region. Before the power

source is used, it is necessary to verify that the product specifications are consistent with

the Local GRID. And please connect the power following the steps below.

1. Check the input power

Make sure that specifications of the power source are consistent with the local GRID,

such as voltage and frequency.

2. Check the fuse

When the product leaves factory, the specified fuse is installed. Please check

whether the fuse matches the actual input voltage according to the "Input Power

Requirements" at the rear panel of the product.

5 / 44


3. Connect the AC power

Connect the power source to AC power supply with proper

specification cable according to the product specification

within the local country could be used. Wiring methods refer

to the following steps.

A. Remove the lowest cover plate after opening the front

cabinet door, there are eight connection terminals in the

cabinet. Shown as figure 1-5.

B. Connect the Earthing Terminal Bus to Earth Line, make

sure the equipment is well grounded.

C. Connect the four connection terminals left-side with

power line, L1, L2, L3 and N are arranged from left to

right. D. Connect the four connection terminals right-side

with equipment to be powered, L1, L2, L3 and N are also

arranged from left to right.

Figure 1-5 Connection terminals of Power Source

WARNING

To avoid electric shock, make sure that the input line is power off, and the

power source is correctly grounded.

1.6 Power-on Inspection

Turn on the rotary switch at the front panel, the power source initializes and executes

self-test. If the power source passes the self-test, the control software will be displayed

6 / 44


on LCD display, and the standby indicator will be lit; otherwise, the indicator of fault

will be lit.

CAUTION

When powering on the equipment after powering off it, make sure that the

time interval between the two operations is greater than 5s.

1.7 Replace the Fuse

The fuse specification is related to the product model and actual input voltage, as

shown in the table below. You can also refer to the "Input Power Requirements" at

the rear panel of the product. To replace the fuse, please refer to figure 1-6, and

follow the steps below.

1. Turn off the power source, and make sure the

input power has been cut off.

2. Remove the fuses to be replaced and replace

them with specified ones (please refer to the "Input

Power Requirements" at the rear panel of the

product).

Figure 1-6 Fuse mounting position

7 / 44


WARNING

To avoid personal injuries, cut off the input of power before replacing the

fuse; to avoid electric shock or fire, replace a fuse corresponding to power

supply specification before connecting to power, and the power source is

correctly grounded.

1.8 User Interface

SLV1 & BSS series power source provides three operation mode (Normal Mode, Battery

Mode and PV Mode). The default mode is Normal Mode while the software is launched.

User can select the appropriate mode according to the application scenarios.

Also, the power source can be controlled in local and remote style. Both of which

have same interface and operation. The modes will be described in Chapter 2.

While the Power knob is turn on, it takes several seconds to initialize the controller

and other units. Make sure that the power’s output connection terminals are correctly

connected. Then, All the functions and parameters can be set and run via touch

panel displayer or GUI software.

8 / 44


Chapter 2 Control Software

The contents of this chapter are as follows:

Setting

Normal Mode

Battery Mode

PV Mode

Wave Monitoring

Fault Monitoring

Query

9 / 44


2.1 Setting

Before performing any test, to protect the device from accidental damage, the values

of Overvoltage protection(OVP) and Overcurrent protection(OIP) should be set

according to test requirements. Generally, the protection value should be slightly

higher than the normal supply voltage.

There are two steps to set the value of OVP and OIP. First, click the ’Hardware limits’

option of menu ‘Setting’ in Test Panel, the input boxes will appear at the bottom of

the test panel as shown in Figure 2-1. Then input appropriate value of OVP and OIP,

and click the ‘Apply’ button at last.

Before performing any test, make sure the hardware limits are set correctly, which

include overvoltage protection (OVP) and overcurrent protection (OCP) values.

Figure 2-1 Setting of Hardware Limits

CAUTION Default path of control software installed on the power source’s controller

is “C:\Software\”, The path can’t be changed, otherwise the software will

be not launched while power source powering on.

10 / 44


2.2 Normal Mode

In Normal Mode, according to the control parameters it can be divided into constant

voltage mode (CV Mode), constant current (CC Mode), constant power (CP Mode)

and constant resistance (CR Mode) mode. While one of which is selected, the other

mode’s controls will be disabled and grayed out.

In CV mode, the output voltage equals the voltage setting value and the output

current is determined by the load; in CC mode, the output current equals the current

setting value and the output voltage is determined by the load; in CP mode, the

output power keeps the constant value set by operator. This section introduces the

operation method. At the same time, the real-time value measured will be displayed

on the top area of the control software panel, such as voltage, current, power and

resistance. The curve of voltage and current will be displayed on the wave control

shown as figure 2-2.

2.2.1 Constant Voltage Mode

In constant voltage mode, the parameter of voltage could be adjusted only, while the

value of voltage is set, the voltage will be output after pressing the power on button.

Figure 2-2. Panel of Constant Voltage Mode

11 / 44


However, there is important step to follow for safety, user must confirm the operation

of “Power On” by click the “Start” button on pop-up window shown as figure 2-3.

Figure 2-3. Confirm Operation

2.2.2 Constant Current Mode

In constant current mode, the parameter of current could be adjusted only shown as

figure 2-4, while the value of current is set, the current will be output after pressing

the power on button. Same as the constant voltage mode, user must confirm the

operation of “Power On” by click the “Start” button.

Figure 2-4. Panel of Constant Current Mode

CAUTION

To avoid damage to the equipment, verify the capacity of the load and

make sure it is in good connection with the load before powering on the

power supply.

12 / 44


2.2.3 Constant Power Mode

In constant Power mode, the parameter of power could be adjusted only shown as

figure 2-5, while the value of power is set, the power will be output after pressing the

power on button. User must confirm the operation of “Power On” by click the “Start”

button also.

Figure 2-5. Panel of Constant Power Mode

2.2.4 Constant Resistance Mode (OPTION)

In constant resistance mode, the parameter of resistance could be adjusted only

shown as figure 2-6, while the value of resistance is set, the output power of power

supply will be determined by the load. Also, user must confirm the operation of

“Power On” by click the “Start” button.

13 / 44


Figure 2-6. Panel of Constant Resistance Mode

2.3 Battery Mode

There are two category operation mode for battery mode, battery simulation and

battery tester. While the power supply runs as battery simulator, the output electrical

characteristics of output just simulate the characteristics of the battery. While running

as battery tester, it performs as a charger or discharger of battery.

2.3.1 Battery Simulation

While running as simulator of battery or energy storage system, it can be used to test

performance of motor and motor’s Energy Recovery System.

Battery type, the numbers of batteries in series and parallel, cutoff limits, nominal

voltage, rated capacity and initial SOC can be set according to actual demand shown

as figure 2-7.

14 / 44


Figure 2-7 Battery Simulation Mode

2.3.2 Battery Tester

The power supply can also perform as a charger of discharger of battery, usually it is

used to test cycle life, capacity, performance of charge & discharge.

15 / 44


Figure 2-8 Battery Tester Mode

Figure 2-9 Test Step of Battery Test

In battery tester mode, the setting parameters include:

Mode

The charge type, including CC, CV, CP mode

Value of charge mode, such as 20A in CC mode, can be positive or negative,

Value while positive the power supply performs as a charger, and negative

performs as a discharger.

While

Terminating condition of charge or discharge. It could be the voltage, current

or duration of charge/discharge.

Value

The value of termination condition. While the real-time parameter reaches

the value, the next step will be executed.

Rest If needing a break between two steps, set a rest time in this control.

Selected Only this control is checked, the step will be executed.

WARNING

To avoid fire, please confirm the specification of battery and set the

parameters carefully due to the characteristics of different batteries.

16 / 44


2.4 PV Mode (OPTION)

Simulation of PV arrays can be done with PV option. The equipment can be used to

simulate IV curves of various solar panels, under various temperature and irradiance

condition, and to test the MPPT characteristics according to EN 50530:2010.

2.4.1 I-V Curve Setting

I-V curves are created by entering simple parametric data. Each curve consists of

1024 data points. Irradiation level or temperature can be modified to test the

behavior of a grid tied inverter under realistic conditions for cloud shadowing and

panel temperature rise. There are three methods for setting I-V curve, such as PV1,

PV2 and Shadow.

For Setting of PV1

Figure 2-10 I-V Curve Setting for PV1

While setting, make sure that the parameters of PV array are set, such as I/U

Characteristic, temperature of environment, Irradiance, Uoc, Isc, Ump and Imp. Then

the I-V curve will be displayed on the Wave display area after the “Calculate” button

is pressed.

Notice: Uoc must be greater than Ump, Isc must be greater than Imp.

17 / 44


For Setting of PV2

Figure 2-11 I-V Curve Setting for PV2

In PV2 setting page, the temperature of PV module, Irradiance, Uoc, Isc and FF can

be set, and I-V curve will be displayed on the Wave display area after the “Set”

button is pressed. For Setting of Shadow

Figure 2-12 I-V Curve Setting for Shadow 18 / 44


In Shadow setting page, the temperature of PV module, Irradiance, Uoc, Isc, Ump

and Imp be set for two modules at most, and I-V curve will be displayed on the Wave

display area after the “Set” button is pressed.

2.4.2 Dynamic MPPT Test

Multiple IV curves can be stored and performed in sequence, and time for each step

can be modified individually.

Figure 2-13 Dynamic MPPT Test Window

The efficiency test of dynamic maximum power point tracking (MPPT) is performed

according to illumination = f(time). The irradiation conditions of 1000W/m2 at 25

degrees Celsius correspond to 100%.

The MPPT test consists of 3 test procedures, such as 10%-50% PDCn test, 30%-

100% PDCn test and SLOW switch machine test.

The default values of test procedures are referenced to EN 50530:2010. However,

user can modify the value according to the actual test requirements.

19 / 44


2.4.2 Static MPPT Test

Figure 2-14 Static MPPT Test Window

According to EN 50530:2010, the measurement of the static MPPT efficiency must

be performed with test specifications as defined in Table 1 in the third section of

fourth chapter. These parameters can be set to the actual values required.

2.5 Wave Monitoring

The output waveform can be viewed in wave window. This window can be invoked

by clicking the ‘Wave’ option in ‘Measurement’ menu. The window is shown as

Figure 2-15.

20 / 44


Figure 2-15 Wave Monitoring

In this window, the parameters below can be shown by checking on the

corresponding checkbox.

Output voltages, currents are displayed. The voltage and current of input are RMS

values.

Two cursors are available to help user to get readings on the chart. If this function is

required, please check the ‘Cursor1’ and ‘Cursor2’.

Label

Operation Description

Attribution

Sampling time Numeric display X axis shows sampling time. If the sampling time is

longer, it will capture more data.

Cursor 1 Check box Check “Cursor 1” to active cursor. Click on screen to

move white mark and show X, Y axis value.

Cursor 2 Check box Check “Cursor 2”to active cursor. Click on screen to

move white mark and show X, Y axis value.

Save Check box if “Save” is checked on, the measurement data will be

stored.

21 / 44


Pause (Reading) Button The function of this button can be switched between

“reading” and “pause”. In “reading” function, real-time

waveforms are displayed; and when “pause”,

waveforms can be operated and played back.

Restore Button While ‘Save’ is checked on, the stored waveform will

displayed on the wave window.

Zoom In Button Only functional when “pause”.

History Data Button Clicking this button will invoke the History Data

window. History Data is to be described in the following

chapters.

2.6 Fault Monitoring

While the indicator of test windows turns red, specific faults can be viewed in the

window by click ‘Fault’ menu. The Fault window is shown as Figure 2-16.

Figure 2-16 Fault Window

The Fault monitoring window shows details of faults. There is no error if indicators

are “Green”, otherwise indicators turn “Red”. Click [Reset] button to reset the system

after faults are removed. If faults are not cleared, restart the system. Contact factory

if the faults CANNOT be cleared.

22 / 44


2.7 Query

In this section, the functions of history log and history data is provided for browsing

history information.

2.7.1 History Log

Clicking ‘History Log’ option in Query menu, the history log function will be invoked,

and the alarm history and historical events within 30 days are displayed. The log

information including time of event and fault. And the logs fall into two categories of

alarm history and event history.

Figure 2-17 History Log Window

Alarm history records alarm history within 30 days, and Event history records

operation history within 30 days.

2.7.2 History Data

Select file name or group name, get a thumbnail waveform ‘File Content’: Read saved

file by default; or click ‘Read Wave’ to open file path, and choose which file to read.

23 / 44


Figure 2-18 History Data Window

Label

Operation Description

Attribution

Read Wave Button Read waveform data. "Start time" and "Sampling time"

determine the data to be read.

Zoom in Button Zoom in waveform between white dash line and green

dash line

Restore Button Restore all waveforms.

24 / 44


Chapter 3 Remote Control

3.1 Computer Setting

The remote-control software uses LAN interface to communicate with the power

supply. Before launching the remote-control software, network configuration of

computer that remote-control software is running should be configured as following

table.

IP Adress 192.168.1.X (X can be any number between 3 and 254)

Subnet Mask 255.255.255.0

STEP A:

Before the control software is installed on the remote computer, please download the

“LabVIEW Run-Time Engine 2014 SP1 - (32-bit) - Windows”, the file name

downloaded is “LVRTE2014SP1_f7Patchstd.exe”. The web link is:

http://www.ni.com/download/labview-run-time-engine-2014-sp1/5198/en/

While the file is downloaded, please install the “LabVIEW Run-Time Engine 2014

SP1 - (32-bit) - Windows”.

STEP B:

Unzip and copy the remote-control software “DC Software 1.0(Client).rar” to some

directory wanted, and then create desktop shortcuts for executable file “DC Software

1.0.exe”.

STEP C:

Run the desktop shortcuts for executable file “DC Software 1.0.exe” as administrator,

all facilities of the software is available.

3.2 Software Setting

And the default network configuration of power supply is shown in table below.

Network configuration can be activated in ‘communication’ option of ‘configuration’

menu. However, it is not recommended to change the default configuration. The

network configuration page is shown as figure 3-1.

IP Adress 192.168.1.2

Port 502

25 / 44


Figure 3-1 Network Configuration

3.3 Remote Control

The remote-control software has same outline of interface and operation with the

software embedded on the power supply’s controller. If the remote-control mode is

desired, method of operation refers to chapter 3.

CAUTION

The power can be controlled via the GUI control software on the touch

panel and remote-control software at the same time, but it’s not

recommended. The proposed approach is that one of the control software

controls the operation of the power supply and the other monitors the

operating parameters.

26 / 44


Appendix A — Specification of SLV1 Series

General Specification

Model2

SLV1 20 SLV1 40 SLV1 60 SLV1 100 SLV1 200 SLV1 300 SLV1 500

Rated Power 20kW 40kW 60kW 100kW 200kW 300kW 500kW

Current Range

5~150V 0~±133A 0~±267A 0~±400A 0~±667A 0~±1333A 0~±2000A 0~±3333A

5~300V 0~±67A 0~±133A 0~±200A 0~±333A 0~±667A 0~±1000A 0~±1667A

Voltage

5~600V 0~±33A 0~±67A 0~±100A 0~±167A 0~±333A 0~±500A 0~±833A Spec.

5~1000V 0~±20A 0~±40A 0~±60A 0~±100A 0~±200A 0~±300A 0~±500A

5~1500V 0~±13A 0~±27A 0~±40A 0~±67A 0~±133A 0~±200A 0~±333A

Max Current3

35A 70A 105A 175A 350A 525A 875A

Environment Specification

Operating Temperature 0℃ to +40℃, full load

Cooling Forced air cooling

Humidity 20~80% RH (no condensing)

Electrical Specification

Voltage supply L-L: 380V@50Hz, 3 Phase + N + PE

Operation Mode CV, CC, CP and optional CR

Efficiency ≥ 90%

Power Factor ≥ 0.95

Program Accuracy of Voltage 0.1 % of F.S.

Program Accuracy of Current 0.3 % of F.S.

Program Accuracy of Power 0.3 % of F.S.

Program Resolution of Voltage 0.2‰ of F.S.

Program Resolution of Current 0.2‰ of F.S. 2 The Full model name refer to Options Section. For SLV1 20, it identifies the power of product is 20kW

3 For line current at 360V LL

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Program Resolution of Power 0.2‰ of F.S.

Ripples &Noises 0.1 % of F.S.

Line Regulation 0.1 % of F.S.

Load Regulation 0.1 % of F.S. (typ)

Over Current X1.2, 60 seconds

Current rise time (10% to + 90%) < 5 ms (200 V, 800 V), <7.5 ms (1500 V)

Current rise time (-90% to + 90%) < 10 ms

Regulation time < 8 ms (0 - 100 % load change)

Short circuit proof < 2.0 KA

Overvoltage protection 0 – 110 % Umax

Overcurrent protection 0 – 110 % Imax

Protection type IP 20

Isolation between Line to Chassis 20MΩ，1kV

Output to Chassis 20MΩ，1kV

Communication Specification

Communication interface 100Mbps LAN

Communication protocol SCPI / TCP-IP

Mechanical specification

Model Dimensions / H×D×W Weight

SLV1-20-150 1700mm × 800mm × 800mm 800 Kg

SLV1-20-300 1700mm × 800mm × 800mm 800 Kg

SLV1-20-600 1700mm × 800mm × 800mm 800 Kg

SLV1-20-1000 2100mm × 800mm × 800mm 1100 Kg

SLV1-20-1500 1300mm × 800mm × 800mm 1300 Kg

SLV1-40-150 1700mm × 800mm × 800mm 900 Kg

SLV1-40-300 1700mm × 800mm × 800mm 900 Kg

SLV1-40-600 1700mm × 800mm × 800mm 900 Kg

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SLV1-40-1000 2100mm × 800mm × 800mm 1200 Kg

SLV1-40-1500 2300mm × 800mm × 800mm 1400 Kg

SLV1-60-150 1900mm × 800mm × 800mm 1000 Kg

SLV1-60-300 1900mm × 800mm × 800mm 1000 Kg

SLV1-60-600 1900mm × 800mm × 800mm 1000 Kg

SLV1-60-1000 2300mm × 800mm × 800mm 1300 Kg

SLV1-60-1500 1900mm × 800mm × 1600mm 1500 Kg

SLV1-100-150 1900mm × 800mm × 1600mm 1800 Kg

SLV1-100-300 1900mm × 800mm × 1000mm 1800 Kg

SLV1-100-600 1900mm × 800mm × 1000mm 1800 Kg

SLV1-100-1000 1900mm × 800mm × 1600mm 1800 Kg

SLV1-100-1500 1900mm × 800mm × 1600mm 2000 Kg

SLV1-200-150 2100mm × 800mm × 2400mm 3000 Kg

SLV1-200-300 2100mm × 800mm × 1600mm 2600 Kg

SLV1-200-600 2100mm × 800mm × 1600mm 2600 Kg

SLV1-200-1000 2100mm × 800mm × 2400mm 3000 Kg

SLV1-200-1500 2100mm × 800mm × 1600mm 2800 Kg

SLV1-300-150 2300mm × 800mm × 2400mm 3400 Kg

SLV1-300-300 2300mm × 800mm × 1600mm 2800 Kg

SLV1-300-600 2300mm × 800mm × 1600mm 2600 Kg

SLV1-300-1000 2300mm × 800mm × 2400mm 3200 Kg

SLV1-300-1500 2300mm × 800mm × 2400mm 3600 Kg

SLV1-500-150 2300mm × 800mm × 3200mm 4600 Kg

SLV1-500-300 2300mm × 800mm × 2400mm 3800 Kg

SLV1-500-600 2300mm × 800mm × 2400mm 3800 Kg

SLV1-500-1000 2300mm × 800mm × 2400mm 4000 Kg

SLV1-500-1500 2300mm × 800mm × 2400mm 4000 Kg

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Options

S L V 1 - 1 0 0 - 1 0 0 0 - X X X

Options

Voltage：1000V

Power：100kW

Bidirectional DC Source

Options Description

- CCR Customized current range, contact factory

- CVR Customized voltage range, contact factory

- PV Simulate I-V curves of various solar panels

- CR Constant Resister Mode

1. Specifications are warranted over an ambient temperature range of 25°± 5° C. Note: For applications over 500kW, capacity increases can be achieved in parallel, and maximum

capacity up to 1000kW.

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Appendix B — Specification of BSS Series

General Specification

Model4

BSS 20

BSS 40

BSS 60

BSS 100

BSS 200

BSS 300

BSS 500

Rated Power 20kW 40kW 60kW 100kW 200kW 300kW 500kW

Current Range

0~150V 0~±266A 0~±534A 0~±800A 0~±1334A 0~±2666A 0~±4000A 0~±6666

A

0~300V 0~±134A 0~±266A 0~±400A 0~±666A 0~±1334A 0~±2000A 0~±3334

A

Voltage

0~600V 0~±66A

0~±134A

0~±200A

0~±334A

0~±666A

0~±1000A

0~±1666A Spec.

0~1000V 0~±40A 0~±80A 0~±120A 0~±200A 0~±400A 0~±600A 0~±1000

A

0~1500V 0~±26A 0~±54A 0~±80A 0~±134A 0~±266A 0~±400A 0~±666A

Max Current5

35A 70A 105A 175A 350A 525A 875A

Environment Specification

Operating Temperature 0℃ to +40℃, full load

Cooling Forced air cooling

Humidity 20~80% RH (no condensing)

Electrical Specification

Voltage supply L-L: 380V@50Hz, 3 Phase + N + PE

Operation Mode CV, CC, CP and optional CR

Efficiency ≥ 90%

Power Factor ≥ 0.95

Program Accuracy of Voltage 0.1% of F.S.

Program Accuracy of Current 0.1% of F.S.

Program Accuracy of Power 0.1% of F.S.

Program Resolution of Voltage 0.02% of F.S.

Program Resolution of Current 0.02% of F.S.

4 The Full model name refer to Options Section. For BSS 20, it identifies the power of product is 20kW

5 For line current at 360V LL

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Program Resolution of Power 0.02% of F.S.

Ripples &Noises 0.1 % of F.S.

Line Regulation 0.1 % of F.S.

Load Regulation 0.1 % of F.S. (typ)

Over Current X1.2, 60 seconds

Current rise time (10% to + 90%) < 1 ms (200 V, 800 V), <1.3 ms (1500 V)

Current rise time (-90% to + 90%) < 2 ms

Regulation time < 1.5 ms (0 - 100 % load change)

Short circuit proof < 2.0 KA

Overvoltage protection 0 – 110 % Umax

Overcurrent protection 0 – 110 % Imax

Protection type IP 20

Isolation between Line to Chassis 20MΩ，1kV

Output to Chassis 20MΩ，1kV

Communication Specification

Communication interface 100Mbps LAN

Communication protocol SCPI / TCP-IP

Mechanical specifications

Model Dimensions / H×D×W Weight

BSS -20-150 1700mm × 800mm × 800mm 800 Kg

BSS -20-300 1700mm × 800mm × 800mm 800 Kg

BSS -20-600 1700mm × 800mm × 800mm 800 Kg

BSS -20-1000 2100mm × 800mm × 800mm 1100 Kg

BSS -20-1500 2300mm × 800mm × 800mm 1300 Kg

BSS -40-150 2100mm × 800mm × 800mm 1200 Kg

BSS -40-300 1700mm × 800mm × 800mm 900 Kg

BSS -40-600 1700mm × 800mm × 800mm 900 Kg

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BSS -40-1000 2100mm × 800mm × 800mm 1200 Kg

BSS -40-1500 2300mm × 800mm × 800mm 1400 Kg

BSS -60-150 2300mm × 800mm × 800mm 1300 Kg

BSS -60-300 1900mm × 800mm × 800mm 1000 Kg

BSS -60-600 1900mm × 800mm × 800mm 1000 Kg

BSS -60-1000 2300mm × 800mm × 800mm 1300 Kg

BSS -60-1500 1900mm × 800mm × 1600mm 1500 Kg

BSS -100-150 2300mm × 800mm × 1600mm 2400 Kg

BSS -100-300 1900mm × 800mm × 1600mm 1800 Kg

BSS -100-600 1900mm × 800mm × 1000mm 1800 Kg

BSS -100-1000 1900mm × 800mm × 1600mm 1800 Kg

BSS -100-1500 2300mm × 800mm × 1600mm 2200 Kg

BSS -200-150 1900mm × 800mm × 3200mm 4600 Kg

BSS -200-300 1900mm × 800mm × 2400mm 3400 Kg

BSS -200-600 2100mm × 800mm × 1600mm 2600 Kg

BSS -200-1000 1900mm × 800mm × 2400mm 3400 Kg

BSS -200-1500 1900mm × 800mm × 2400mm 3200 Kg

BSS -300-150 2100mm × 800mm × 4000mm 5600 Kg

BSS -300-300 2300mm × 800mm × 2400mm 4400 Kg

BSS -300-600 2300mm × 800mm × 1600mm 2800 Kg

BSS -300-1000 2100mm × 800mm × 2400mm 4000 Kg

BSS -300-1500 2300mm × 800mm × 2400mm 4400 Kg

BSS -500-150 2300mm × 800mm × 5600mm 8800 Kg

BSS -500-300 2300mm × 800mm × 3200mm 4600 Kg

BSS -500-600 2300mm × 800mm × 2400mm 3800 Kg

BSS -500-1000 2300mm × 800mm × 2400mm 4000 Kg

BSS -500-1500 2300mm × 800mm × 2400mm 4000 Kg

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Options

B S S - 1 0 0 - 1 0 0 0 - X X X

Options

Voltage：1000V

Power：100kW

Battery SImulation Source/Sink

Options Description

- CCR Customized current range, contact factory

- CVR Customized voltage range, contact factory

- PV Simulate I-V curves of various solar panels

- CR Constant Resister Mode

1. Specifications are warranted over an ambient temperature range of 25°± 5° C. Note: For applications over 500kW, capacity increases can be achieved in parallel, and maximum

capacity up to 1000kW.

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