KR101838470B1 - Battery test system - Google Patents

Abstract

A battery test system according to an embodiment of the present invention includes an inverter for converting power supplied from a battery into three phases; A motor emulator for receiving the three-phase power from the inverter to charge and discharge the battery; A DC / DC converter for converting power supplied from the battery to a low voltage; And a load bank receiving the low voltage power from the DC / DC converter.

Description

Battery Test System {BATTERY TEST SYSTEM}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a battery test system, and more particularly, to a battery test system that enables a battery environment in an actual electric vehicle to be reproduced in a facility in a laboratory.

In an electric vehicle, a battery is currently connected to a module of 10 unit cells to become a battery module, and 20 to 30 and more than 50 of such modules are applied to a vehicle.

The best way to manage these modules is to measure the voltage and temperature per cell and charge and discharge them appropriately, or measure the voltage and temperature of hundreds of cells with a single ECU (Electric Control Unit). It is actually impossible to do. The voltage and temperature are measured at an appropriate level, and the battery management apparatus using the voltage and temperature is appropriately operated.

The battery management system of an electric vehicle should be continuously tested on the vehicle due to its limitation of application, and its stability as a performance and management device should be verified. In particular, the battery management device senses and evaluates the proper degree of charge and discharge, the self-discharge of the battery due to self-discharge of the battery and various other reasons, internal pollution caused by electric shock, It should be down.

However, current electric vehicles are time consuming to manufacture and it is difficult to carry out continuous tests due to limitations of other driving devices during testing. Therefore, a test system similar to the vehicle system is essential, and to what degree close to actuality will enhance the reliability of the device.

In order to check the state of the battery, conventionally, a battery to be tested is attached to a test vehicle to which various test apparatuses are connected, and then, in a state in which the engine of the vehicle is operated or stopped under the same condition as the running state of the vehicle, By operating electrical and electronic equipment, we test battery condition, output, efficiency, charge / discharge pattern, and durability as well as battery suitability.

However, when the experiment is performed in such a manner, a wide test site is required to allow the vehicle to enter the vehicle, and exhaust gas or noise is generated as the engine of the vehicle is operated.

Further, since the operator must manually turn on and off various electric and electronic equipments after connecting various test equipments to the vehicle, there is a problem that the work is very troublesome. Particularly, it is difficult to maintain an accurate rotation speed due to the nature of the engine of the vehicle, and there is a problem in that an operator may make a mistake in the process of manually operating the electric and electronic equipment of the vehicle, resulting in inaccurate experimental results.

In addition, in testing a battery, it is necessary to test various types of electrical loads by assuming that the user additionally installs various types of electric and electronic devices in addition to equipment basically provided in the vehicle. In the case of conducting experiments using a general vehicle, it is practically difficult to apply various electric loads arbitrarily, so that the experiment is very limited.

Korean Patent Publication No. 2003-0039496 discloses a battery management and test system for an electric vehicle. The disclosed battery management and test system for an electric vehicle includes a main controller for controlling an overall test sequence such as charge, discharge, and rest cycle; A charge / discharge test device for discharging the battery according to a discharge pattern programmed in accordance with a signal of the main controller, and controlling the discharge to be stopped when a problem occurs; An inverter and a motor control unit for recognizing a driving mode setting and a charging mode of the electric vehicle, a DC / DC converter for supplying a 12V power supply and auxiliary battery charging, and a mounting type charger for setting and charging the charging mode An electric vehicle control unit; A contactor box provided so as to automatically shut off the circuit; A battery management device configured to detect and manage all performance states of the battery mounted on the electric vehicle; A test information display panel for displaying information on a charging and discharging cycling sequence of the battery and a current test state; An AC relay for setting a charging mode start relay and an AC 220V to the on-board charging device so that the control unit and the battery management device can operate in a charging mode; A junction box used as a test point for collectively distributing all the signal lines and measuring various signals during the test; And a computer for displaying and storing test data of the battery management apparatus relating to the battery charging and discharging cycling.

In addition, since the environment in which the battery mounted on the vehicle is exposed can not be reproduced, it affects the battery performance and hinders the proximity to the actual vehicle.

The present invention is a technique for constructing a battery test system capable of testing a battery management system in an environment most similar to an actual vehicle in a test room. In order to charge and discharge the battery in the form most similar to the actual vehicle, it is necessary to connect the inverter and the motor. However, in order to drive the motor, it is necessary to install the dynamo for the motor, and the management factor and the risk factors increase, which causes the size and cost of the equipment to increase drastically.

Korean Patent Publication No. 2003-0039496

SUMMARY OF THE INVENTION The present invention has been made in order to solve the above problems, and it is an object of the present invention to provide a battery test system in which a motor emulator instead of a motor dynamo interlocks with an inverter to minimize the size and cost of equipment, .

In addition, the combination of motor emulator, inverter, DC / DC converter, and load bank is used to create a charge / discharge environment with the same conditions as the vehicle and to operate the battery under the same conditions as the temperature and humidity environment in which the battery is exposed in the vehicle. So that the battery can be tested in an environment substantially similar to an actual vehicle.

According to an aspect of the present invention, there is provided a battery test system comprising: an inverter for converting power supplied from a battery into three phases; A DC / DC converter for converting a power supplied from the battery to a low voltage; And a load bank for receiving the low voltage power from the DC / DC converter, wherein the motor emulator is driven by receiving power from the battery in association with the inverter, and the power generated by the motor emulator or the stored surplus power Is supplied to the inverter to charge the battery, and the three-phase power is supplied from the inverter to discharge the battery.

In the battery test system according to an embodiment of the present invention, the DC / DC converter converts the power of the battery into a power required by the load bank, and converts the power of the battery into a power of 12V .

Also, a battery test system according to an embodiment of the present invention includes: the battery to be tested; A relay box serving as a switch for supplying and blocking power of the battery; And a battery management system (BMS) that measures the voltage, temperature, and current of the battery in real time and calculates a state of charge (SOC) based on the measured data. system; And a monitoring and control system for controlling the charging / discharging sequence of the battery and displaying the control result.

The battery test system according to an embodiment of the present invention may further include an environment recollection device interlocked with the monitoring and control system to set an environment around the battery.

Also, in the battery test system according to an embodiment of the present invention, the environment includes a temperature and a humidity at which the battery is exposed.

According to the battery test system according to the embodiment of the present invention, the motor emulator in place of the dynamo for the motor interlocks with the inverter, so that the size and cost of the equipment can be minimized and the vehicle proximity can be maintained at the best.

In addition, the combination of motor emulator, inverter, DC / DC converter, and load bank is used to create a charge / discharge environment with the same conditions as the vehicle and to operate the battery under the same conditions as the temperature and humidity environment in which the battery is exposed in the vehicle. So that the battery can be tested in an environment substantially similar to an actual vehicle.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a configuration diagram schematically showing the configuration of a battery test system according to an embodiment of the present invention; FIG.
Figure 2 illustrates systems that work in conjunction with a battery test system in accordance with one embodiment of the present invention.
3 is a view showing an environment reproducing apparatus applied to a battery test system according to an embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a block diagram schematically showing a configuration of a battery test system according to an embodiment of the present invention.

As shown in FIG. 1, the battery test system 100 includes an inverter 110, a motor emulator 130, a DC / DC converter 150, and a load bank 170.

The DC / DC converter 150 is a device that converts the type of electricity (DC (DC) to AC (AC)) into the inverter 110 and downs the high voltage DC to the low voltage DC.

As described above, the inverter 110 converts the power supplied from the battery 210 into three phases.

The motor emulator 130 receives the three-phase power from the inverter 110 to charge and discharge the battery 210.

A high voltage AC for driving the motor emulator 130 is obtained at a high voltage DC of the battery 210 and a high voltage AC generated at the motor emulator 130 is converted to a high voltage DC for charging the battery 210 And it is the inverter 110 that plays a role.

The inverter 110 can control the output of the motor emulator 130 by controlling the frequency and voltage of the high voltage AC supplied to the motor emulator 130.

The DC / DC converter 150 converts the power supplied from the battery 210 to a low voltage. The DC / DC converter 150 converts the power of the battery 210 into a power required by the load bank 170, and converts the power of the battery 210 to a power of 12V.

A low voltage DC that can drive the load bank 170 that reproduces various electric components in addition to the motor emulator 130 is required. To this end, a device for converting the high voltage DC to low voltage DC of the battery 210 is connected to the DC / (150).

As described above, the load bank 170 receives the low voltage power from the DC / DC converter 150. The load bank 170 can produce a wide range of electrical load states depending on its capacity.

2 is a diagram illustrating systems interlocked with a battery test system in accordance with an embodiment of the present invention.

The battery test system 100 is interlocked with the battery management system 200 and the monitoring and control system 300.

The battery management system 200 includes the battery 210, the relay box 230, and a battery management system (BMS) 250, as shown in FIG.

The relay box 230 serves as a switch for supplying and disconnecting the power of the battery 210 to the inverter 110 and the DC / DC converter 150.

The battery management device 250 continuously monitors the state of the battery 210 so that the battery 210 can be safely charged when the battery 210 is charged and transmits the monitored information to the monitoring and control system 300, So that the charging operation is performed.

The monitoring and control system 300 calculates the amount of power that can be supplied to the battery test system 100 based on the charge state information measured by the battery management device 250.

The battery management device 250 measures the voltage, temperature, and current of the battery 210 in real time, calculates the SOC of the battery 210 based on the measured data, The charging control algorithm having the characteristics of the charging control algorithm is considered and the corresponding information should be transmitted to the monitoring and control system 300.

The battery management apparatus 250 calculates the energy stored in the battery 210 and transmits the stored energy to the monitoring and control system 300 so that the battery 210, which can be supplied to the battery test system 100, So that the power reserve can be determined.

On the other hand, when the battery test system 100 stores surplus electric power, the battery management device 250 may store the state information of the battery 210 in order to calculate the amount of power that the battery 210 can receive. Monitoring and control system 300 of the present invention.

As described above, the monitoring and control system 300 controls the charging / discharging sequence of the battery 210 and displays the control result. The monitoring and control system 300 monitors the operation status of the battery test system 100 and the battery management system 200 and displays the operation status. The operator can confirm the state of the battery 210, the output, the efficiency, the charge / discharge pattern, etc. of the battery 210 based on the displayed control result.

3 is a view showing an environment reproducing apparatus applied to a battery test system according to an embodiment of the present invention.

The battery test system 100 may further utilize the environment reproducing apparatus 400, as shown in FIG.

The environment reproducing apparatus 400 interlocks with the monitoring and control system 300 to set the environment around the battery 210. [ For example, the environment may include the temperature and humidity at which the battery 210 is exposed. The environment reproducing apparatus 400 may include a temperature sensor, a humidity sensor, a temperature controller, a humidity controller, and the like.

The environment reproducing apparatus 400 controls the ambient temperature and humidity of the air, which are necessary for charging / discharging the battery 210. The environment reproducing apparatus 400 isolates the battery 210 from the outside so that the characteristics of the battery 210 are not affected by surrounding factors such as temperature and humidity.

In addition, the environment reproducing apparatus 400 may simulate a vehicle running condition according to a combination of various conditions such as a cold period, a cold period, a night and a day, and evaluate the charge / discharge state and performance of the battery 210 in real time do.

As described above, according to the battery test system of the present invention, the motor emulator instead of the motor dynamo is interlocked with the inverter to minimize the size and cost of the equipment, keep the vehicle proximity to the best, By combining the converter and the load bank, the charge / discharge environment of the same condition as the vehicle is established, and the battery is exposed to the environment reproduction device to operate in the same condition as the temperature and humidity environment in which the battery is exposed in the vehicle, The effect can be obtained.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, Modification is possible. Accordingly, the spirit of the present invention should be understood only in accordance with the following claims, and all equivalents or equivalent variations thereof are included in the scope of the present invention.

100: Battery test system
110: Inverter
130: Motor emulator
150: DC / DC converter
170: Roadbank
200: Battery management system
210: Battery
230: relay box
250: Battery management device (BMS)
300: Monitoring and control system
400: environment reproduction device

Claims (5)

An inverter for converting power supplied from the battery into three phases;
A motor emulator for receiving the three-phase power from the inverter to charge and discharge the battery;
A DC / DC converter for converting power supplied from the battery to a low voltage; And
A load bank receiving the low voltage power from the DC / DC converter;
, ≪ / RTI &
The motor emulator is driven by receiving power from the battery in cooperation with the inverter. The motor emulator supplies power generated by the motor emulator or stored surplus power to the inverter to charge the battery, and receives three phase power from the inverter And discharging the battery. The method according to claim 1,
Wherein the DC / DC converter converts the power of the battery into a power required by the load bank, and converts the power of the battery into a power of 12V. The method according to claim 1,
The battery test system includes:
The battery to be tested; A relay box serving as a switch for supplying and disconnecting the power of the battery to the inverter and the DC / DC converter; And a battery management system (BMS) that measures the voltage, temperature, and current of the battery in real time and calculates a state of charge (SOC) based on the measured data. system; And
A monitoring and control system for controlling the charging and discharging sequence of the battery and displaying the result of the control;
Wherein the battery test system is interlocked with the battery test system. The method of claim 3,
The battery test system includes:
An environment reproducing device interlocked with the monitoring and control system to set an environment around the battery;
Further comprising a battery test system. 5. The method of claim 4,
Wherein the environment includes temperature and humidity at which the battery is exposed.

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