KR20150139346A - Apparatus and method for simulating battery pack having function of calibration - Google Patents

Abstract

Disclosed are a battery pack simulation apparatus, capable of accurately checking performance of a battery pack management device arranged in a battery pack, and a battery pack simulation method. According to the present invention, the battery pack simulation apparatus includes: an output module for outputting a setting value to the battery pack management device; a read module for reading received data from the battery pack management device if receiving the data corresponding to the setting value, which is output from the output module; a comparison module for comparing the received data with a target value; and a correction module for correcting the setting value, output by the output module, by using a result of the comparison, performed by the comparison module, and then transmitting the corrected setting value to the output module.

Description

[0001] Apparatus and method for simulating a battery pack having a calibration function [0002]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a technique for simulating a battery pack, and more particularly, to a battery pack management system for automatically checking a set value output from a battery pack simulation apparatus, And more particularly, to a battery pack simulation apparatus and method having a calibration function for enabling the function verification of the battery pack to be performed more conveniently and accurately.

In recent years, demand for portable electronic products such as notebook computers, video cameras, and portable telephones has been rapidly increased, and development of batteries, robots, and satellites for energy storage has been accelerated. Thus, a high performance rechargeable battery Researches are being actively conducted.

The secondary rechargeable batteries are nickel-cadmium batteries, nickel-hydrogen batteries, nickel-zinc batteries, and lithium secondary batteries. Among them, lithium secondary batteries have almost no memory effect compared to nickel- The self-discharge rate is very low and the energy density is high.

In recent years, with the depletion of carbon energy and the growing interest in the environment, demand for hybrid cars and electric vehicles is increasing worldwide, including in the United States, Europe, Japan, and Korea. Since such hybrid vehicles and electric vehicles use the charge / discharge energy of the battery pack to obtain the vehicle driving power, they are more fuel-efficient than the vehicles using only the engine and can not discharge or reduce pollutants. . Therefore, more attention and research are focused on automotive batteries, which are key components of hybrid cars and electric vehicles.

Such a battery is generally used in the form of a battery pack rather than a single battery. The battery pack includes a cell cluster including at least one battery cell and a battery pack management device for managing the overall state of the battery cell or the battery pack. The battery pack management device may be referred to as a battery management system (BMS), a battery management unit (BMU), or the like.

The battery pack management apparatus may further include a power supply control unit for controlling power supply to a load connected to the battery pack, measuring electrical parameters such as current or voltage, charge / discharge control, equalization control of voltage, state of charge estimation, And the state of health (SOH) estimation of the secondary battery.

On the other hand, such a battery pack management device is one of the most important components of the battery pack because it has a configuration for controlling the battery pack as a whole. However, if the battery pack management device does not operate properly in the battery pack, the state of the secondary battery can not be properly monitored, and proper power supply to the external device may not be performed. In addition, if the protection function of the battery pack management device is not properly performed, a safety accident may occur.

Therefore, functional verification of whether the battery pack management apparatus is operating properly is required. However, currently, there is insufficient research on a technology for verifying whether the battery pack management apparatus is operating properly. Research on the battery pack management device itself has been actively conducted, but research on the function verification of the battery pack management device has not been conducted.

Since the function verification determines whether the device to be verified is operating correctly, the verification accuracy is a key factor. In this respect, research on a battery pack simulation apparatus capable of accurately testing the function of the battery pack management apparatus is required.

It is an object of the present invention to provide a battery pack simulation apparatus and method that can accurately verify the function of a battery pack management apparatus provided in a battery pack.

Other objects and advantages of the present invention can be understood by the following description, and will be more clearly understood by the embodiments of the present invention. It is also to be understood that the objects and advantages of the invention may be realized and attained by means of the instrumentalities and combinations thereof.

According to an aspect of the present invention, there is provided a battery pack simulation apparatus for verifying a function of a battery pack management apparatus provided in a battery pack, the apparatus comprising: Output module; A read module that reads the received data from the battery pack management device when the battery pack management device receives data corresponding to the set value output from the output module; A comparison module for comparing the received data with a target value; And a calibration module for calibrating the set value output by the output module using the comparison result performed by the comparison module and transmitting the calibrated set value to the output module.

The output module may output the calibrated set value to the battery pack management device when receiving the calibrated set value from the calibrating module.

The calibration module may calibrate the set value by adding or subtracting a difference value corresponding to a difference between the target value and the received data to or from the set value.

The battery pack simulation apparatus may further include an initial setting module that receives the target value and determines an initial set value using the input target value.

The initial setting module may assign the target value to the initial set value as it is, or may assign a result value obtained by adding or subtracting an estimated error value, which is an estimated error value, to or from the target value.

The calibration module may not perform the calibration operation when the difference between the target value and the received data is equal to or less than a preset reference error value as a result of the comparison of the comparison module.

The calibration module may store a difference value between the target value and the last calibration value when the difference between the target value and the received data is less than or equal to a predetermined reference error value as a result of the comparison module.

The battery pack simulation apparatus may further include a storage module for storing a difference value between the target value and the last calibration value.

The difference value between the target value and the last correction value stored in the storage module may be used to determine an initial set value when the target value is changed.

The set value may include at least one of a current, a voltage, and a temperature.

According to another aspect of the present invention, there is provided a battery pack simulation method for verifying a function of a battery pack management device provided in a battery pack, the method comprising: An output step; A reading step of reading the received data from the battery pack management device when the battery pack management device receives data corresponding to the set value output in the output step; A comparison step of comparing the received data with a target value; And a calibration step of calibrating the set value output in the output step using the comparison result performed in the comparison step.

If the set value is calibrated in the calibration step, the output step may output the calibrated set value to the battery pack management device, and perform the reading step, the comparison step, and the calibration step.

The calibration step may correct the set value by adding or subtracting a difference value corresponding to a difference between the target value and the received data to or from the set value.

The battery pack simulation method may further include an initial setting step of receiving the target value before the output step and determining an initial set value using the input target value.

In the initial setting step, the target value may be directly allocated to the initial set value, or a result value obtained by adding or subtracting an estimated error value, which is an estimated error value, to or from the target value may be allocated.

The calibration step may not perform the calibration operation when the difference between the target value and the received data is less than or equal to a predetermined reference error value as a result of the comparison performed in the comparison step.

The battery pack simulation method further includes a storing step of storing a difference value between the target value and the last calibration value when the difference between the target value and the received data is less than or equal to a predetermined reference error value as a result of the comparison performed in the comparing step .

The difference value between the target value and the last correction value stored in the storing step may be used to determine an initial set value when the target value is changed.

The set value may include at least one of a current, a voltage, and a temperature.

According to the present invention, the function of the battery pack management apparatus can be verified more accurately.

Particularly, according to the present invention, even if the battery pack management device can not accurately receive the set value output from the battery pack simulation device, the battery pack simulation device reads the data received by the battery pack management device, So that the target set value can be transmitted to the battery pack management apparatus. As a result, more accurate function verification can be achieved.

According to an aspect of the present invention, the battery pack simulation apparatus can perform more accurate donation verification by repeating the calibration operation several times.

According to another aspect of the present invention, by making the calibration degree database for the same parameter, the calibration work can be performed quickly.

In addition, the present invention can have various other effects, and other effects of the present invention can be understood by the following description, and can be more clearly understood by the embodiments of the present invention.

BRIEF DESCRIPTION OF THE DRAWINGS The accompanying drawings, which are incorporated in and constitute a part of the specification, illustrate preferred embodiments of the invention and, together with the description of the invention given below, serve to further the understanding of the technical idea of the invention. And should not be construed as limiting.
FIG. 1 is a view illustrating a function verification system of a battery pack management apparatus according to an embodiment of the present invention.
2 is a flowchart illustrating an example of a calibration operation of the battery pack simulation apparatus according to an embodiment of the present invention.
3 is a flowchart illustrating a battery pack simulation method according to an embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. Prior to this, terms and words used in the present specification and claims should not be construed as limited to ordinary or dictionary terms, and the inventor should appropriately interpret the concepts of the terms appropriately It should be construed as meaning and concept consistent with the technical idea of the present invention based on the principle that it can be defined.

Therefore, the embodiments described in this specification and the configurations shown in the drawings are merely the most preferred embodiments of the present invention and do not represent all the technical ideas of the present invention. Therefore, It is to be understood that equivalents and modifications are possible.

In the following description, well-known functions or constructions are not described in detail since they would obscure the invention in unnecessary detail.

FIG. 1 is a view illustrating a function verification system of a battery pack management apparatus according to an embodiment of the present invention.

Referring to FIG. 1, a function verification system for a battery pack management apparatus 110 according to an embodiment of the present invention includes a battery pack 100 and a battery pack simulation apparatus 200.

The battery pack 100 includes at least one battery cell B and a battery pack management device 110. The battery pack 100 includes a charge / discharge terminal, and can supply power (discharge) to an external load (load) L through the charging / discharging terminal or receive power from an external charging apparatus (charge).

The battery pack management device 110 is configured to control power supply to the load L connected to the battery pack 100 and to measure and control electrical parameters such as current or voltage (charge / discharge current, voltage control) And monitors and controls the state of the secondary battery such as measurement and control of the usage environment of the battery pack 100, equalization control of voltage, state of charge (SOC) estimation, state of health (SOH) .

In particular, the battery pack management device 110 may be connected to the battery pack simulation device 200 to receive data corresponding to the set values output by the battery pack simulation device 200. Thus, the battery pack management apparatus 110 may be set according to a set value output from the battery pack simulation apparatus 200. [

Here, the set value may be various parameter values for which the battery pack simulation apparatus 200 desires to set the battery pack management apparatus 110. The parameter value mainly corresponds to an electric parameter value such as a current, a voltage, and the like, but is not limited thereto. For example, the cooling temperature of the battery pack management device 110 to the battery pack 100 may correspond to the above parameters.

And the set value is an output power that the battery pack 100 outputs to the outside. The battery pack simulation apparatus 200 may be configured to output an output power of, for example, 100 W to the external load L in order to verify whether or not the battery pack management apparatus 110 operates correctly. To this end, the battery pack simulation apparatus 200 may set the output power corresponding to 100 W to a set value and output it to the battery pack management apparatus 110. Then, the battery pack management apparatus 110 receives 100 W data from the battery pack simulation apparatus 200, and controls the battery pack 100 so that the battery pack 100 outputs 100 W of output power to the outside.

However, there may be a difference between the set values output from the battery pack simulation apparatus 200 to the battery pack management apparatus 110 and the received data received by the battery pack management apparatus 110. That is, for example, if the error occurs in the communication line C connecting the battery pack simulation apparatus 200 and the battery pack management apparatus 110, or the setting value of the battery pack simulation apparatus 200 And the data received by the battery pack management device 110 may be different.

That is, in the above example, the battery pack simulation apparatus 200 outputs a set value of 100 W, but the battery pack management apparatus 110 can receive data in which an error has occurred. For example, an error of 3 W occurs, and the battery pack management apparatus 110 can receive data of 97 W. In this case, since the battery pack management device 110 controls the battery pack 100 to output the output power of 97 W instead of the target 100 W, accurate function verification of the battery pack management device 110 is performed There is a possibility that it will not.

The battery pack simulation apparatus 200 according to the present invention reduces the difference between the set value output from the battery pack simulation apparatus 200 and the received data recognized by the battery pack management apparatus 110, So that the functions of the battery pack management apparatus 110 can be more accurately tested.

The battery pack simulation apparatus 200 is connected to a battery pack management apparatus 110 provided in the battery pack 100 and outputs a set value to the battery pack management apparatus 110 to control the battery pack management apparatus 110 The function of the battery pack managing apparatus 110 can be verified while changing the set value.

To this end, the battery pack simulation apparatus 200 may output a set value to the battery pack management apparatus 110. The battery pack simulation apparatus 200 can read received data received from the battery pack management apparatus 110 from the battery pack management apparatus 110 as data corresponding to the set values. Then, the battery pack managing apparatus 110 can be set to a target value through an appropriate calibration process so as to reach a target set value (hereinafter referred to as a target value). The specific configuration and operation of the battery pack simulation apparatus 200 will be described with reference to FIG.

Referring again to FIG. 1, the battery pack simulation apparatus 200 includes an output module 220, a read module 230, a comparison module 240, and a calibration module 250.

The output module 220 may output a set value to the battery pack management device 110. [ At this time, the output module 220 may output a set value to the battery pack management device 110 through the communication line C as shown in FIG. Here, the set value output from the output module 220 to the battery pack management device 110 may be an initial set value initially output, or may be a calibrated set value after a calibration process. As described above, when the set value is output from the output module 220 to the battery pack management device 110, the battery pack management device 110 receives data corresponding to the output set value.

The reading module 230 can read received data received from the battery pack management device 110 by the battery pack management device 110. [ That is, when the battery pack management device 110 receives data corresponding to the set value output from the output module 220, the reading module 230 reads the data from the battery pack management device 110, Data can be read.

At this time, it is preferable that the reading module 230 reads the received data via a path separate from the communication line C. For this purpose, a separate communication channel may be provided between the battery pack management device 110 and the read module 230, which is different from the communication line C. The communication channel may be a wired communication channel or a wireless communication channel, and various known communication technologies may be applied.

Preferably, the communication channel is a digital communication channel. By adopting the digital communication channel, the reading module 230 can read the received data from the battery pack management device 110 without error or minimize the error.

The comparison module 240 may compare the received data with a target value. Here, the received data is the data read from the battery pack management device 110 by the read module 230 and corresponds to the set value output by the output module 220 as described above. Here, the target value may be an ultimate setting value for the battery pack simulator 200 to set the battery pack manager 110.

The target value can be easily understood by referring to the example described above. That is, in the above-described example, the battery pack simulation apparatus 200 has the battery pack management apparatus 110 so that the battery pack 100 outputs the output power of 100 W to the outside in order to verify the function of the battery pack management apparatus 110, Respectively. Here, the ultimate set value of 100 W, which the battery pack simulation apparatus 200 intends to set the battery pack management apparatus 110, may be a target value.

The comparison module 240 may compare the target value with the received data read from the battery pack management device 110 by the read module 230. [ Here, the comparison performed by the comparison module 240 may simply compare the target value with the received data. In addition to comparing the target value with the received data, the comparison module 240 may compare not only the target value with the received data, And calculating the difference. Preferably, the comparison module 240 may calculate a difference between any one of the target value and the received data.

The calibration module 250 may calibrate the set values output by the output module 220. [ At this time, the calibration module 250 can calibrate the set value using the comparison result performed by the comparison module 240. The calibration module 250 may calibrate the set values output by the output module 220 and then transmit the calibrated set values to the output module 220. Through this process, the output module 220 can output the calibrated set value to the battery pack management device 110. An example of a specific calibration method is as follows.

For example, the calibration module 250 may use the comparison result performed by the comparison module 240, but may simply calibrate the set value using the magnitude of the target value and the received data. That is, when the target value is larger than the received data, a predetermined reference value is added to the set value to correct the set value. If the target value is smaller than the received data, the predetermined value is subtracted from the set value, Can be calibrated.

As another example, the calibration module 250 may correct the set value by adding or subtracting the difference value corresponding to the difference between the target value and the received data to or from the set value.

As one example of the above-described specific calibration method, the calibration module 250 can calibrate the set values using various other calibration methods.

If the difference between the target value and the received data is less than or equal to a preset reference error value, the calibration module 250 may not perform the calibration operation. In addition, if the difference between the target value and the received data is less than or equal to a predetermined reference error value as a result of the comparison by the comparison module 240, the calibration module 250 stores the difference value between the target value and the last calibration value . Here, the last correction value corresponds to a set value corresponding to the received data when the difference between the target value and the received data is equal to or less than a preset reference error value. In other words, the last calibration value may be a setting value output by the output module 220 at the time when the calibration operation is terminated.

Meanwhile, the battery pack simulation apparatus 200 according to the present invention may further include a storage module for storing the difference value, i.e., the difference between the target value and the last calibration value. The difference between the target value and the last calibration value may be stored in the storage module. The difference value, that is, the difference between the target value and the last calibration value, can be used to determine the initial setting value when the target value is changed or reset. This will be described in detail through an embodiment of the calibration operation.

Preferably, the battery pack simulation apparatus 200 according to an embodiment of the present invention may further include an initial setting module 210. The initial setting module 210 is a component for determining an initial set value of the set values. The output module 220 outputs a set value to the battery pack management device 110. The set value may be largely divided into an initial set value and a calibrated set value. It can be said that the initial setting value corresponds to the setting value that the output module 220 first outputs for a specific target value. The calibrated set value may be a set value calibrated at least once by the calibration module 250 after the initial set value is output, and may be a set value other than the initial set value.

The initial setting module 210 may use the target value in determining the initial set value. For this purpose, the initial setting module 210 can receive a target value from a user of the battery pack simulation apparatus 200. [ Upon receiving the target value, the initial setting module 210 may determine the initial set value using the input target value. At this time, the initial setting module 210 can directly determine the input target value as an initial setting value, or can modify the input target value to determine an initial setting value.

For example, the initial setting module 210 assigns the target value to the initial setting value as it is, or adds or subtracts an estimated error value (hereinafter referred to as an estimated error value) To the initial set value. For example, the difference between the target value and the last calibration value may be used as the initial setting value.

Hereinafter, the calibration operation of the battery pack simulation apparatus 200 according to an embodiment of the present invention will be described in detail with reference to FIG.

2 is a flowchart illustrating an example of a calibration operation of the battery pack simulation apparatus according to an embodiment of the present invention.

Hereinafter, the set value is the charge current of the battery pack 100, and the target value is 3000 mA, for example.

First, the user inputs a target value of 3000 mA to the battery pack simulation apparatus 200 to verify whether the battery pack management apparatus 110 properly controls the amount of charge current. The initial setting module 210 receives a target value of 3000 mA (S201) and determines an initial set value using the input target value (S203). In the present embodiment, the initial setting module 210 assumes that the target value is used as an initial setting value as it is. Then, the initial setting value is 3000mA.

The output module 220 outputs the set value corresponding to the initial setting value of 3000 mA to the battery pack management device 110 (S205). The output module 220 outputs a set value corresponding to 3000 mA but the battery pack management device 110 receives data corresponding to 3012 mA due to an error of the communication line C or the like do. Therefore, the reading module 230 reads the received data of 3012 mA from the battery pack management device 110 (S209).

Then, the comparison module 240 compares the received data of 3012 mA with the target value of 3000 mA. In this embodiment, it is assumed that the comparison module 240 calculates the difference between the target value and the received data. Therefore, the comparison module 240 calculates -12 mA by subtracting 3012 mA, which is the reception data, from the target value of 3000 mA (S211).

Next, the calibration module 250 adds 12 mA, which is a difference between the target value and the received data, to the set value according to the comparison result performed by the comparison module 240 (S213). That is, since the target value is smaller than the received data, 12 mA is subtracted from the initial setting value of 3000 mA. Then, 2988mA (3000mA - 12mA = 2988mA) becomes the calibrated set value. The calibration module 250 transmits the calibrated set values to the output module 220. Through this process, one calibration is completed.

The output module 220 receives the calibrated set value from the calibrating module 250, and outputs the calibrated set value to the battery pack managing device 110 (S215). That is, the output module 220 outputs the initial set value at first, and then outputs the calibrated set value. The set value output by the output module 220 after the calibration once is set is 2988 mA as a calibrated set value.

When the output module 220 outputs a set value of 2988 mA to the battery pack management device 110, the battery pack management device 110 receives data corresponding to 2988 mA (S217). It is expected that the battery pack management apparatus 110 will receive data corresponding to 3000 mA when outputting 2988 mA because an error of 12 mA has occurred in the immediately previous current set value output, It can not be guaranteed that the device 110 receives data corresponding to 3000 mA. Therefore, in this embodiment, when the output module 220 outputs 2988 mA, it is assumed that the battery pack management device 110 receives 2997 mA. Although the error is reduced through the first calibration, there is still an error of 3 mA. Therefore, further calibration work needs to be performed.

Since the received data received by the battery pack management device 110 is 2997 mA, the read module 230 reads the received data of 2997 mA from the battery pack management device 110 (S219).

Then, the comparison module 240 compares the received data of 2997 mA with the target value of 3000 mA. In this embodiment, since the difference between the target value and the received data is calculated, the comparison module 240 calculates + 3 mA minus the received data of 2997 mA at the target value of 3000 mA (S221).

Next, the calibration module 250 adds or subtracts 3 mA, which is the difference between the target value and the received data according to the comparison result performed by the comparison module 240, to the set value. That is, since the target value is larger than the received data, 3 mA is added to the first calibrated set value of 2988 mA. Then, 2991 mA (2988 mA + 3 mA = 2991 mA) becomes a calibrated set value (S223). The calibration module 250 transmits the calibrated set values to the output module 220. Through this process, two calibrations are completed.

Such a calibration operation is repeatedly performed so that the received data received by the battery pack managing apparatus 110 can reach the target value. Preferably, the target value and the received data received by the battery pack management device 110 are perfectly matched, but it is impossible for them to be perfectly matched, and an excessive amount of time and resources may be consumed in the calibration operation . Accordingly, when the difference between the target value of the comparison result of the comparison module 240 and the received data is equal to or less than a preset reference error value, the calibration module 250 is preferably configured not to perform the calibration operation any more.

The output module 220 receives 2991 mA, which is a set value calibrated in accordance with the twice calibration, from the calibration module 250, and outputs 2991 mA, which is the calibrated set value, to the battery pack management device 110 (S225).

When the output module 220 outputs a set value of 2991 mA to the battery pack management device 110, the battery pack management device 110 receives data corresponding to 2991 mA (S227). In this embodiment, when the output module 220 outputs 2991 mA, it is assumed that the battery pack management device 110 receives 2999.9 mA.

Since the received data received by the battery pack management device 110 is 2999.9 mA, the read module 230 reads the received data of 2999.9 mA from the battery pack management device 110 (S229).

Then, the comparison module 240 compares the received data of 2999.9 mA with the target value of 3000 mA (S231). In this embodiment, since the difference between the target value and the received data is calculated, the comparison module 240 calculates 0.1 mA minus 2999.9 mA, which is the received data, at the target value of 3000 mA.

Although the error is reduced through the second calibration, there is still an error of 0.1 mA. However, an error of 0.1 mA can be considered to be a sufficiently small value. That is, in the present embodiment, assuming that the reference error value is 0.2 mA, 0.1 mA is 0.2 mA or less and corresponds to a value within the error range. Accordingly, the calibration module 250 may no longer perform the calibration operation (S233).

Since the difference (0.1 mA) between the target value (3000 mA) and the received data (2999.9 mA) is less than the predetermined reference error value (0.2 mA) (0.1 mA? 0.2 mA), the calibration module (250) 9mA (2991 mA - 3000 mA = -9 mA) which is a difference value between the value (2991 mA) and the target value (3000 mA) can be stored in the storage module (S235). At this time, it is preferable to simultaneously store the difference value and the parameter used as the set value as the output current.

On the other hand, this difference value can be used to determine the initial setting value when the target value is changed. That is, this difference value can be used as the above-described estimation error value. More specifically, the user can reset 2000 mA to the target value, not 3000 mA, to verify that the battery pack management device 110 properly controls the amount of charge current. At this time, if the new target value of 2000 mA is directly assigned to the initial setting value, the calibration operation will be performed several times. Therefore, it is preferable to assign a result of correcting the reset target value using the difference between the target value and the last correction value derived by the result of the previous calibration work as the initial setting value. In the above example, since the difference value is -9 mA, the initial setting module 210 can determine 1991mA which is -9 mA added to the reset 2000 mA as the initial setting value. Thus, by using the results of the previous calibration work, the number of times of calibration work can be reduced.

On the other hand, such a difference value is preferably distinguished by various parameters. That is, it is preferable to distinguish the current by current, by voltage by voltage, and by temperature by temperature.

3 is a flowchart illustrating a battery pack simulation method according to an embodiment of the present invention. In Fig. 3, the execution subject of each step may be each component of the battery pack simulation apparatus 200 described above.

As shown in FIG. 3, in the battery pack simulation method according to an embodiment of the present invention, the target value is input first and the initial set value is determined using the input target value (S310). At this time, the target value may be a value input by the user of the battery pack simulation apparatus 200. In the initial setting step S310, the input target value may be directly assigned to the initial setting value, or a result value obtained by adding or subtracting the estimated error value to or from the target value may be assigned to the initial setting value.

Then, the battery pack managing apparatus 110 outputs a set value (initial set value) (S320). Next, when the battery pack managing apparatus 110 receives data corresponding to the set value (initial setting value) output in the output step S320, it reads the received data from the battery pack managing apparatus 110 (S330 ). Next, the received data is compared with a target value (S340). Next, the setting value (initial setting value) output in the output step is calibrated using the comparison result performed in the comparing step S340 (S350). As an example of the specific calibration method, the set value (initial setting value) can be corrected by adding or subtracting the difference value corresponding to the difference between the target value and the received data to or from the set value (initial set value).

After the calibration process, the calibrated set value is output to the battery pack management device 110 (S320). When the battery pack management device 110 receives data corresponding to the set value output in the output step, the received data is read from the battery pack management device 110 (S330). Then, the received data is compared with the target value, and the set value output from the output step is calibrated using the comparison result performed in the comparison step.

By repeating the output step, the reading step, and the calibration step, the battery pack managing apparatus 110 can receive the set value close to the target value.

On the other hand, if the difference between the target value and the received data is less than or equal to a predetermined reference error value, the calibration step may not be performed any more (S360). Then, the difference value between the target value and the last calibration value can be stored (S370). The difference value between the target value and the last calibration value stored in the storing step S370 may be used to determine an initial setting value when the target value is changed.

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 to be limited to the details thereof and that various changes and modifications will be apparent to those skilled in the art. And various modifications and variations are possible within the scope of the appended claims.

The features described in the individual embodiments herein may be combined and implemented in a single embodiment. Conversely, various features described herein in a single embodiment may be implemented in various embodiments individually or in a suitable subcombination.

In the present specification, the term 'module' such as 'comparison module', 'calibration module', etc. is used, but it is a logical constitutional unit, and not a component that can be physically separated. And will be apparent to those skilled in the art to which the invention pertains.

100: Battery pack
110: Battery pack management device
B: Battery cell
200: Battery pack simulation device
210: Initial setting module
220: Output module
230: read module
240: Comparison module
250: Calibration module

Claims (19)

A battery pack simulation apparatus for verifying a function of a battery pack management apparatus provided in a battery pack,
An output module for outputting a set value to the battery pack management device;
A read module that reads the received data from the battery pack management device when the battery pack management device receives data corresponding to the set value output from the output module;
A comparison module for comparing the received data with a target value; And
And a calibration module for calibrating the set value output by the output module using the comparison result performed by the comparison module, and transmitting the calibrated set value to the output module.
The method according to claim 1,
Wherein the output module outputs the calibrated set value to the battery pack management device when the calibrated set value is received from the calibration module.
The method according to claim 1,
Wherein the calibration module corrects the set value by adding or subtracting a difference value corresponding to a difference between the target value and the received data to or from the set value.
The method according to claim 1,
Further comprising an initial setting module that receives the target value and determines an initial set value using the input target value.
5. The method of claim 4,
Wherein the initial setting module assigns the target value to the initial set value as it is or assigns a result value obtained by adding or subtracting an estimated error value that is an estimated error value to or from the target value.
The method according to claim 1,
Wherein the calibration module does not perform a calibration operation when a difference between the target value and the received data is equal to or less than a predetermined reference error value as a result of comparison of the comparison module.
The method according to claim 6,
Wherein the calibration module stores a difference value between the target value and the last calibration value when the difference between the target value and the received data is equal to or less than a preset reference error value as a result of the comparison of the comparison module .
8. The method of claim 7,
Further comprising a storage module for storing a difference between the target value and the last calibration value.
9. The method of claim 8,
Wherein the difference value between the target value and the last correction value stored in the storage module is used to determine an initial set value when the target value is changed.
The method according to claim 1,
Wherein the set value comprises at least one of a current, a voltage, and a temperature.
A battery pack simulation method for verifying a function of a battery pack management device provided in a battery pack,
An output step of outputting a set value to the battery pack managing apparatus;
A reading step of reading the received data from the battery pack management device when the battery pack management device receives data corresponding to the set value output in the output step;
A comparison step of comparing the received data with a target value; And
And a calibration step of calibrating the set value output in the output step using the comparison result performed in the comparing step.
12. The method of claim 11,
Wherein the output step outputs the calibrated set value to the battery pack management device, and performs the reading step, the comparing step, and the calibrating step when the set value is calibrated in the calibrating step.
12. The method of claim 11,
Wherein the calibration step corrects the set value by adding or subtracting a difference value corresponding to a difference between the target value and the received data to or from the set value.
12. The method of claim 11,
Further comprising an initial setting step of receiving the target value before the output step and determining an initial set value using the input target value.
15. The method of claim 14,
Wherein the initial setting step allocates the target value to the initial set value as it is, or assigns a result value obtained by adding or subtracting an estimated error value, which is an estimated error value, to or from the target value.
12. The method of claim 11,
Wherein the correcting step does not perform the correcting operation when the difference between the target value and the received data is equal to or less than a predetermined reference error value as a result of the comparison performed in the comparing step.
17. The method of claim 16,
Further comprising a storing step of storing a difference value between the target value and the last calibration value when the difference between the target value and the received data is less than or equal to a predetermined reference error value as a result of the comparison performed in the comparing step Pack simulation method.
18. The method of claim 17,
Wherein the difference value between the target value and the last calibration value stored in the storing step is used to determine an initial setting value when the target value is changed.
12. The method of claim 11,
Wherein the set value includes at least one of a current, a voltage, and a temperature.

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