KR20210109093A - Method for Regenerating Battery Module - Google Patents

Abstract

A method for regenerating a battery module of the present invention, executed through a battery regeneration device for regenerating a vehicle waste battery recovered after being used in an eco-friendly vehicle, includes the steps of: preparing a battery module of a waste battery including the N number of battery cells, wherein N >= 2 is satisfied; performing an internal resistance test of the battery module; charging the battery module to a designated maximum charging voltage; discharging the charged battery module to a designated minimum discharge voltage; and charging and regenerating the N number of battery cells included in the battery module to a designated rated voltage.

Description

Method for Regenerating Battery Module

The present invention is to regenerate a regenerative battery capable of guaranteeing safety against fire or explosion risk for a certain period or longer by using a vehicle waste battery recovered after being used in an eco-friendly vehicle.

Recently, eco-friendly vehicles such as electric vehicles and hydrogen vehicles are gradually being distributed. Considering the replacement cycle of such eco-friendly vehicles, it is predicted that waste batteries for vehicles will be collected from about 10,000 electric vehicles per year in 2024, 2031 It is predicted that the vehicle waste batteries will be recovered from about 100,000 electric vehicles per year in 2018 (refer to the study on recycling methods and standards for electric vehicle waste batteries (Ministry of Environment, 2018. 10)).

However, in the case of a vehicle battery mounted in an eco-friendly vehicle, the battery manufacturer tests and guarantees the safety of the vehicle battery for a certain period (or a certain mileage) after manufacturing, but after such vehicle battery is recovered from the eco-friendly vehicle, the recovered There is no basis for correcting the stability of vehicle batteries.

On the other hand, if waste batteries for vehicles recovered after being used in eco-friendly vehicles are immediately disposed of (e.g., resource recovery, etc.), a huge amount of disposal costs will be incurred every year from 2024, and the disposal cost is expected to increase explosively from 2031 . In order to solve some of these problems, it is necessary to recycle the used vehicle batteries for other applications. It has a very socially dangerous problem.

An object of the present invention is to prepare a battery module of a waste battery including N (N≥2) battery cells in a method implemented through a battery regeneration device for regenerating a waste battery for a vehicle recovered after being used in an eco-friendly vehicle. A first step, a second step of performing an internal resistance test of the battery module, a third step of charging the battery module to a specified maximum charging voltage, a fourth step of discharging the charged battery module to a specified lowest discharging voltage, and the An object of the present invention is to provide a battery module regeneration method including a fifth step of charging and regenerating N battery cells included in the battery module to a specified rated voltage.

The battery module regeneration method according to the present invention is a method that is executed through a battery regeneration apparatus for regenerating a vehicle waste battery recovered after being used in an eco-friendly vehicle, the battery of the waste battery including N (N≥2) battery cells A first step of preparing the module, a second step of performing an internal resistance test of the battery module, a third step of charging the battery module to a specified maximum charging voltage, and a third step of discharging the charged battery module to a specified lowest discharge voltage Step 4 and a fifth step of charging and regenerating the N battery cells included in the battery module to a specified rated voltage.

In the battery module regeneration method according to the present invention, the battery module is characterized in that it comprises a state in which a battery management system (BMS) of a battery manufacturer and a vehicle case are separated from the waste battery.

In the battery module regeneration method according to the present invention, the first step is to perform a specified procedure of an optical balance check to determine whether at least one of the damage, expansion, and discoloration of the battery module is included within a preset effective range It is characterized in that it further comprises a step.

In the battery module regeneration method according to the present invention, the first step may further include sensing at least one of damage, expansion, and discoloration of the battery module through a camera unit or an optical sensor unit.

In the battery module regeneration method according to the present invention, the first step further comprises the step of receiving an inspection result visually inspected by an inspector or an inspection result measured and inspected through a measuring instrument through an input unit. .

In the battery module regeneration method according to the present invention, the first step is to convert the battery module into a resource recovery target battery module when at least one of damage, expansion, and discoloration of the battery module is out of a preset effective range. It is characterized in that it further comprises the step of determining.

In the battery module regeneration method according to the present invention, in the first step, a power terminal of the battery module is connected to a module connection terminal of the battery regeneration device, and cells corresponding to N battery cells provided in the battery module and connecting a terminal to a cell connection terminal of the battery regeneration device.

In the battery module regeneration method according to the present invention, the second step is to measure the resistance value of the battery module through a module connection terminal connected to the power terminal of the battery module to determine whether it matches a preset effective resistance range It characterized in that it comprises the step of performing a resistance test.

In the battery module regeneration method according to the present invention, the second step further comprises the step of determining the battery module as a resource recovery target battery module when the measured resistance value is out of a preset effective resistance range characterized in that

In the battery module regeneration method according to the present invention, the third step comprises charging the battery module to a specified maximum charging voltage through a module connection terminal connected to a power terminal of the battery module. do.

In the battery module regeneration method according to the present invention, in the third step, a preset initial voltage difference between the N battery cells through a cell connection terminal connected to a cell terminal of the battery module before charging the battery module It characterized in that it further comprises the step of initializing within the voltage balance range.

In the battery module regeneration method according to the present invention, the third step is characterized in that it comprises the step of charging the battery module according to a specified current ratio through the module connection terminal.

In the battery module regeneration method according to the present invention, the third step is characterized in that it comprises the step of charging the battery module through the module connection terminal at a current ratio of 0.5C (C-rate).

In the battery module regeneration method according to the present invention, the third step is characterized in that it comprises the step of charging by applying a specified constant voltage to the battery module through the module connection terminal.

In the battery module regeneration method according to the present invention, the third step is characterized in that it comprises the step of charging by applying a voltage pattern that is changed within a specified voltage range to the battery module through the module connection terminal.

In the battery module regeneration method according to the present invention, the third step may include charging by applying a constant current matching a specified current ratio to the battery module through the module connection terminal.

In the battery module regeneration method according to the present invention, the third step comprises charging by applying a current pattern that is changed within a specified current ratio range to the battery module through the module connection terminal. .

In the battery module regeneration method according to the present invention, the third step includes charging between N battery cells provided in the battery module through a cell connection terminal connected to a cell terminal of the battery module when the battery module is charged. a step 3a of checking balance information including a voltage difference, and a step 3b of performing a balance check for determining whether a difference in charging voltage between the N battery cells included in the balance information matches a preset charging voltage effective balance range It is characterized in that it further comprises.

In the battery module regeneration method according to the present invention, the step 3a includes a balance including a charging voltage difference during charging between N battery cells provided in the battery module through the cell connection terminal while the battery module is being charged and checking information, wherein step 3b includes performing a balance check to determine whether a difference in charging voltage during charging between the N battery cells included in the balance information matches a preset charging voltage effective balance range It is characterized in that it comprises a.

In the battery module regeneration method according to the present invention, in step 3b, when the charging voltage difference during charging between the N battery cells is out of a preset charging voltage effective balance range, the battery module is converted to a resource recovery target battery module. It is characterized in that it further comprises the step of determining.

In the battery module regeneration method according to the present invention, in step 3a, when the battery module is charged up to a specified maximum charging voltage, the maximum charging voltage difference between the N battery cells provided in the battery module through the cell connection terminal Including the step of checking the balance information that includes, the step 3b is a balance check to determine whether the maximum charging voltage difference between the N battery cells included in the balance information matches a preset charging voltage effective balance range It is characterized in that it comprises the step of performing.

In the battery module regeneration method according to the present invention, in step 3b, when the maximum charging voltage difference between the N battery cells is out of a preset charging voltage effective balance range, determining the battery module as a resource recovery target battery module It is characterized in that it further comprises the step of

In the battery module regeneration method according to the present invention, the fourth step comprises discharging the battery module to a specified minimum discharge voltage through a module connection terminal connected to a power terminal of the battery module. do.

In the battery module regeneration method according to the present invention, in the fourth step, before discharging the battery module, a preset initial voltage difference between the N battery cells is performed through a cell connection terminal connected to a cell terminal of the battery module. It characterized in that it comprises the step of initializing within the voltage balance range.

In the battery module regeneration method according to the present invention, the fourth step is characterized in that it comprises the step of discharging the battery module according to a specified current ratio through the module connection terminal.

In the battery module regeneration method according to the present invention, the fourth step comprises discharging the battery module at a current ratio of 0.5C (C-rate) through the module connection terminal.

In the battery module regeneration method according to the present invention, the fourth step is characterized in that it comprises the step of discharging the battery module according to a specified constant voltage through the module connection terminal.

In the battery module regeneration method according to the present invention, the fourth step may include discharging the battery module according to a voltage pattern that is changed within a voltage range specified through the module connection terminal.

In the method for regenerating a battery module according to the present invention, the fourth step may include discharging the battery module according to a constant current matching a specified current ratio through the module connection terminal.

In the battery module regeneration method according to the present invention, the fourth step may include discharging the battery module according to a current pattern changed within a current ratio range specified through the module connection terminal.

In the battery module regeneration method according to the present invention, in the fourth step, when the battery module is discharged, discharging between N battery cells provided in the battery module through a cell connection terminal connected to a cell terminal of the battery module A step 4a of checking balance information including a voltage difference and a step 4b of performing a balance check for determining whether a discharge voltage difference between the N battery cells included in the balance information matches a preset discharge voltage effective balance range It is characterized in that it further comprises.

In the battery module regeneration method according to the present invention, the step 4a includes a balance including a discharge voltage difference during discharging between N battery cells provided in the battery module through the cell connection terminal while discharging the battery module and checking information, wherein step 4b includes performing a balance check to determine whether a discharge voltage difference during discharge between the N battery cells included in the balance information matches a preset discharge voltage effective balance range It is characterized in that it comprises a.

In the battery module regeneration method according to the present invention, in the step 4b, when the discharge voltage difference during discharging between the N battery cells is out of a preset discharge voltage effective balance range, the battery module is converted into a resource recovery target battery module. It is characterized in that it further comprises the step of determining.

In the battery module regeneration method according to the present invention, in step 4a, when the battery module is discharged to a specified minimum discharge voltage, the minimum discharge voltage difference between the N battery cells provided in the battery module through the cell connection terminal and checking balance information including, wherein the step 4b is a balance check for determining whether a minimum discharge voltage difference between the N battery cells included in the balance information matches a preset discharge voltage effective balance range. It is characterized in that it comprises the step of performing.

In the battery module regeneration method according to the present invention, in the step 4b, when the minimum discharge voltage difference between the N battery cells is out of a preset discharge voltage effective balance range, determining the battery module as a resource recovery target battery module It is characterized in that it further comprises the step of

In the battery module regeneration method according to the present invention, in the fourth step, when the battery module is discharged to a specified minimum discharge voltage, the discharge time required for discharging the battery module to the specified minimum discharge voltage is checked; The method may further include calculating the remaining ratio of the battery module based on a proportional relationship between the confirmed discharging time and a reference discharging time corresponding to the reciprocal of the current ratio.

In the battery module regeneration method according to the present invention, the fourth step may further include determining whether the calculated remaining ratio matches a preset remaining ratio effective range.

In the battery module regeneration method according to the present invention, the fourth step further comprises the step of determining the battery module as a resource recovery target battery module when the calculated remaining ratio is out of a preset effective remaining ratio range, characterized by being made.

In the battery module regeneration method according to the present invention, step 5-1 of charging and regenerating the battery module up to a specified ratio range of a specified module rated voltage through a module connection terminal connected to a power terminal of the battery module and the battery 5 - to simultaneously charge and reproduce the N battery cells up to the rated voltage for each cell specified through the cell connection terminal connected to the cell terminal of the battery module when the voltage of the module reaches the specified ratio range of the specified module rated voltage It is characterized in that it comprises two steps.

In the battery module regeneration method according to the present invention, the step 5-1 is characterized in that it comprises the step of charging the battery module according to a specified current ratio through a module connection terminal.

In the battery module regeneration method according to the present invention, the step 5-1 is characterized in that it comprises the step of charging the battery module at a current ratio of 0.5C (C-rate) through a module connection terminal.

In the battery module regeneration method according to the present invention, the step 5-1 is characterized in that it comprises the step of charging by applying a specified constant voltage to the battery module through a module connection terminal.

In the battery module regeneration method according to the present invention, the step 5-1 is characterized in that it comprises the step of charging by applying a constant current matching a specified current ratio to the battery module through a module connection terminal.

In the battery module regeneration method according to the present invention, in step 5-1, when the battery module is reproduced, balance information including a difference in regeneration voltage between N battery cells provided in the battery module through a cell connection terminal a step 5-1a of confirming and a step 5-1b of performing a balance check for determining whether a difference in reproduction voltage between the N battery cells included in the balance information matches a preset module reproduction voltage effective balance range; characterized by being made.

In the battery module regeneration method according to the present invention, in step 5-1a, the N batteries provided in the battery module through a cell connection terminal during regeneration by charging the battery module up to a specified ratio range of the specified module rated voltage and checking balance information including a reproduction voltage difference during module reproduction between battery cells, wherein the step 5-1b includes a preset reproduction voltage difference between the N battery cells included in the balance information during module reproduction. and performing a balance check to determine whether the module regeneration voltage matches an effective balance range.

In the battery module regeneration method according to the present invention, in the step 5-1b, if the regeneration voltage difference during module regeneration among the N battery cells is out of a preset module regeneration voltage effective balance range, the battery module is recovered as resources It characterized in that it further comprises the step of determining the target battery module.

In the battery module regeneration method according to the present invention, in step 5-2, when the voltage of the battery module reaches a specified ratio range of the specified module rated voltage, the voltage difference between the N battery cells through the cell connection terminal and initializing to within a preset cell regeneration voltage effective balance range.

In the battery module regeneration method according to the present invention, the step 5-2 is characterized in that it comprises the step of simultaneously charging the N battery cells according to a specified current ratio through the cell connection terminal.

In the battery module regeneration method according to the present invention, the step 5-2 includes simultaneously charging the N battery cells at a current ratio of 0.5C (C-rate) through the cell connection terminal. characterized.

In the battery module regeneration method according to the present invention, the step 5-2 is characterized in that it comprises charging by simultaneously applying a specified constant voltage to the N battery cells through the cell connection terminals.

In the battery module regeneration method according to the present invention, the step 5-2 includes charging by simultaneously applying a constant current matching a specified current ratio to the N battery cells through the cell connection terminal. characterized.

In the battery module regeneration method according to the present invention, in step 5-2, a cell to which a cell regeneration voltage reproduced for each of the N battery cells is designated while simultaneously charging and regenerating the N battery cells through the cell connection terminal. It is characterized in that it comprises the step of regenerating while fine balancing by reducing the amount of current of the cell regeneration power applied to the N battery cells to a specified fine current range according to a specified reduction pattern as it approaches the rated voltage of each.

In the battery module regeneration method according to the present invention, the step 5-2 includes a difference in regeneration voltage between the N battery cells provided in the battery module through the cell connection terminal when the N battery cells are reproduced. a step 5-2a of checking the balance information to It is characterized in that it comprises a.

In the battery module regeneration method according to the present invention, in the step 5-2a, the cell regeneration voltage difference between the N battery cells provided in the battery module is measured through the cell connection terminal while the N battery cells are being reproduced. and determining the balance information including It is characterized in that it comprises the step of performing the inspection.

In the battery module regeneration method according to the present invention, in the step 5-2b, when the cell regeneration voltage difference between the N battery cells is out of a preset cell regeneration voltage effective balance range, the battery module is used as a resource recovery target battery. It characterized in that it further comprises the step of determining the module.

In the battery module regeneration method according to the present invention, the cell regeneration voltage effective balance range includes a fine voltage balance range of a specified ratio or less than the module regeneration voltage effective balance range related to the regeneration of the battery module through the module connection unit. characterized in that

In the battery module regeneration method according to the present invention, the effective balance range of the cell regeneration voltage is matched to the effective balance range of the module regeneration voltage related to the regeneration of the battery module when the process of regenerating the N battery cells is started. It is characterized in that, as the cell regeneration voltage reproduced for each N battery cells approaches the rated voltage for each designated cell, a balance range in which the cell regeneration voltage is reduced to a specified fine voltage balance range according to a specified reduction pattern is included.

In the battery module regeneration method according to the present invention, it is characterized in that it further comprises the step of mounting a BMS for a regenerative battery having a balance management function on the regenerated battery module.

In the battery module regeneration method according to the present invention, the BMS for the regeneration battery is electrically connected to at least one side of a power terminal of the battery module, and includes a cell terminal corresponding to N battery cells provided in the battery module; It is characterized in that it is electrically connected.

In the battery module regeneration method according to the present invention, the balance management function includes a function of generating balance information including voltage values for each N battery cells during charging of the battery module, and N battery cells during discharging of the battery module A function of generating balance information including each voltage value, a function of transmitting the generated balance information through a designated communication unit, and a function of analyzing the balance information including the voltage value of each N battery cells during charging of the battery module to determine the N A function of determining whether a voltage difference during charging between the N battery cells matches a preset effective voltage balance range during charging, and when the voltage difference during charging between the N battery cells does not match a preset effective voltage balance range during charging, the battery The function of blocking the charging of the module, the function of transmitting the balance warning information of the battery module through a designated communication unit when the voltage difference during charging between the N battery cells does not match the preset effective voltage balance range during charging, the battery A function of analyzing balance information including voltage values for each N battery cells during discharging of a module to determine whether a voltage difference during discharging between the N battery cells matches a preset effective voltage balance range during discharging, the N battery cells The function to block the discharge of the battery module when the voltage difference during discharging does not match the preset effective voltage balance range during discharging, and the voltage difference during discharging between the N battery cells matches the preset effective voltage balance range during discharging If not, it characterized in that it comprises at least one or two or more functions of the function of transmitting the balance warning information of the battery module through a designated communication unit.

In the battery module regeneration method according to the present invention, the BMS for the regenerative battery includes a contact-type communication unit communicating through a communication terminal among the terminal units of the case, a short-range wireless communication unit communicating through a designated short-range wireless communication, and a designated wireless network. It characterized in that it comprises at least one communication unit among the wireless network communication unit for communicating through.

According to the present invention, among waste batteries for vehicles recovered after being used in an eco-friendly vehicle, an internal resistance test of a battery module is passed, and a balance test between N battery cells provided in the battery module while charging or discharging the battery module is performed. By repeatedly performing and recycling only the safe battery module that has passed, there is a risk of fire or explosion of the battery even when reusing and recycling waste batteries for vehicles recovered after being used in eco-friendly vehicles (for example, batteries whose warranty period has expired) There is an advantage of providing a regenerative battery that can guarantee safety for a certain period of time or longer.

1 is a diagram showing the configuration of a battery reproducing apparatus 100 according to an embodiment of the present invention.
2 is a diagram illustrating an optical balance test and a resistance test process for battery regeneration according to an embodiment of the present invention.
3 is a diagram illustrating a charging or charging balance inspection process of the battery module 188 for battery regeneration according to an embodiment of the present invention.
4 is a diagram illustrating a discharge or discharge balance test and a residual ratio test process of the battery module 188 for battery regeneration according to an embodiment of the present invention.
5 is a diagram illustrating a process of charging and regenerating the battery module 188 according to an embodiment of the present invention.
6 is a diagram illustrating a process of regenerating the battery module 188 by charging the battery cell 192 according to the embodiment of the present invention and loading the BMS for the regenerative battery.

Hereinafter, the principle of operation of the preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings and description. However, the drawings shown below and the following description are for preferred implementation methods among various methods for effectively explaining the features of the present invention, and the present invention is not limited only to the following drawings and description.

That is, the following embodiment corresponds to an embodiment of a preferred union type among numerous embodiments of the present invention, and an embodiment in which a specific configuration (or step) is omitted in the following embodiment, or a specific configuration (or step) An embodiment in which the implemented function is divided into a specific configuration (or step), or an embodiment in which the function implemented in two or more configurations (or step) is integrated into any one configuration (or step), of a specific configuration (or step) Embodiments in which the order of operation is replaced, etc. are clearly stated to be within the scope of the present invention, even if not separately mentioned in the following embodiments. Therefore, it is clearly specified that various embodiments corresponding to a subset or a complement can be divided retroactively from the filing date of the present invention based on the following examples.

In addition, in the following description of the present invention, if it is determined that a detailed description of a related well-known function or configuration may unnecessarily obscure the gist of the present invention, the detailed description thereof will be omitted. And the terms to be described later are terms defined in consideration of functions in the present invention, which may vary according to the intention or custom of the user or operator. Therefore, the definition should be made based on the content throughout the present invention.

As a result, the technical spirit of the present invention is determined by the claims, and the following examples are one means for efficiently explaining the technical spirit of the present invention to those of ordinary skill in the art to which the present invention belongs. only

1 is a diagram showing the configuration of a battery regeneration apparatus 100 according to an embodiment of the present invention.

In more detail, FIG. 1 is a battery regeneration device 100 that regenerates a regenerative battery capable of guaranteeing safety against fire or explosion risk for a certain period or longer using a vehicle waste battery recovered after being used in an eco-friendly vehicle, and the present invention For those of ordinary skill in the art, various implementation methods for the configuration of the battery regeneration apparatus 100 (eg, some components are omitted or subdivided, or combined implementation methods) may be inferred, but the present invention includes all of the inferred implementation methods, and the technical characteristics are not limited to only the implementation method illustrated in FIG. 1 .

The waste battery of the present invention includes a waste battery for a vehicle that is used in an eco-friendly vehicle (eg, an electric vehicle, a hydrogen vehicle, etc.) and is recovered for each reason (eg, inspection, repair, expiration of period, accident, scrap car, etc.).

According to the embodiment of the present invention, the waste battery includes N (N≥2) battery cells 192 and a battery management system (BMS) of a battery manufacturer mounted by the battery manufacturer at the time of manufacturing the vehicle battery, and the It includes a vehicle case (however, it can be omitted if it is mounted in a vehicle without a separate case) provided at the time of manufacturing the battery or at the time of mounting the battery in the vehicle. Meanwhile, the waste battery may include different specifications for each battery manufacturer and/or each vehicle manufacturer and/or each vehicle.

The battery cell 192 is a unit of a minimum unit for charging power in the battery, and the battery of the present invention includes a plurality of (=N) battery cells 192 . According to the embodiment of the present invention, the N battery cells 192 may be connected in a series connection structure and/or in a parallel connection structure within the battery.

The BMS of the battery manufacturer is a BMS mounted by the battery manufacturer at the time of manufacturing the vehicle battery, and includes functions such as overcharge prevention or overdischarge prevention, and all N battery cells 192 connected by a specified connection structure (eg, batteries). Includes voltage or current sensing function for Some BMSs may further include a temperature sensing function.

On the other hand, in the present invention, when the waste battery is recovered from the eco-friendly vehicle, the battery module 188 including N battery cells 192 by separating the BMS of the battery manufacturer and the vehicle case (which can be omitted) from the waste battery. Prepare (or wear)

According to the embodiment of the present invention, the battery module 188 includes a power terminal (eg, a +/- terminal) for charging or discharging power, and N battery cells included in the battery module 188 ( 192) and a corresponding cell terminal. Preferably, the cell terminal may include at least (N+1) contact points (eg, N contact points for each cell and ground contact points, etc.).

1, the battery regeneration device 100 includes a module connection unit 180 including a module connection terminal connected to the power terminal of a battery module 188 of a waste battery including N battery cells 192, A cell connection unit 184 including a cell connection terminal connected to cell terminals corresponding to the N battery cells 192 provided in the battery module 188, and the module connection unit 180 and the cell connection unit 184 are connected to each other. and a control module 104 for controlling to regenerate the battery module 188 that has passed the balance check by performing a specified balance check in conjunction with the battery module 188 through the.

The module connection terminal of the module connection part 180 is electrically connected to the power terminal of the battery module 188, and the module connection part 180 is the voltage value or current of the battery module 188 through the module connection terminal. An electrical circuit is provided for measuring at least one of a value or a resistance value or for charging, discharging, or regenerating the battery module 188 .

The cell connection terminal of the cell connection part 184 is electrically connected to the cell terminals corresponding to the N battery cells 192 provided in the battery module 188, and the cell connection part 184 connects the cell connection terminal. An electrical circuit for measuring at least one of a voltage value, a current value, or a resistance value for each of the N battery cells 192 provided in the battery module 188 or regenerating the N battery cells 192 is provided.

According to the embodiment of the present invention, the battery regeneration apparatus 100 includes the module connection unit 180 and the cell connection unit 184 in a set unit. For example, the battery regeneration apparatus 100 may include one set of the module connection unit 180 and the cell connection unit 184 , or a plurality of sets.

Referring to FIG. 1 , the control module 104 includes an information management unit 108 that stores and manages management information for managing an inspection process or a regeneration process for the regeneration of the battery module 188 .

The information management unit 108 is a specification of the reproduction target battery module 188 (eg, a specification for each battery provided by a battery manufacturer, and/or a specification including information calculated or derived through a specification for each battery provided by the battery manufacturer) , and/or management information corresponding to specifications measured or defined based on specifications for each battery provided by the battery manufacturer) is input/registered, and stored and managed in a designated storage area.

According to the implementation method of the present invention, the management information is a specified maximum charging voltage capable of charging the battery module 188 (eg, a full charging voltage in the specification of the battery module 188, or charging or balance of the battery module 188) The maximum charging voltage set/defined for inspection), the specified minimum discharge voltage capable of discharging the battery module 188 (eg, the full discharge voltage in the specifications of the battery module 188, or the discharge of the battery module 188 or The minimum discharge voltage set/defined for balance check), the specified rated voltage of the battery module 188 (eg, the rated voltage in the specifications of the battery module 188, or the safe use of the regenerated battery module 188) The rated voltage set/defined for the purpose, the rated voltage set/defined in the application field of the battery module 188 to be reproduced, etc.), the specified standard charging current of the battery module 188 (eg, on the specification of the battery module 188) Standard charging current, or standard charging current set/defined for charging of the battery module 188, etc.), the specified standard charging time of the battery module 188 (eg, the standard charging time on the specification of the battery module 188, or a standard charging time set/defined for charging of the battery module 188, etc.), a specified standard current rate of the battery module 188 (eg, a standard current ratio on the specification of the battery module 188, Or the standard current ratio separately set/defined in the battery module 188, etc.), the standard current ratio during specified charging of the battery module 188 (eg, the standard current ratio when charging according to the specifications of the battery module 188, or the battery The standard current ratio set/defined for charging of the module 188, etc.), the standard current ratio when the battery module 188 is discharged (eg, the standard current ratio when the battery module 188 is discharged according to the specifications, or the battery A specified maximum charge for each of the N battery cells 192 capable of charging the N battery cells 192 provided in the battery module 188, etc.) Voltage (eg, a full charge voltage according to the specifications for each N battery cells 192 , or a maximum charging voltage set/defined for charging or balance check for each N battery cells 192 ), the N battery cells 192 ) specified for each of the N battery cells 192 capable of discharging (for example, the full discharge voltage according to the specifications of the N battery cells 192, or set/ defined minimum discharge voltage, etc.), the specified rated voltage for each of the N battery cells 192 (eg, the rated voltage according to the specifications for each of the N battery cells 192, or the safe use of each of the N battery cells 192 to be reproduced). The rated voltage set/defined for the purpose, the rated voltage set/defined in the application field for each of the N battery cells 192 to be reproduced, etc.), the specified standard charging current for each of the N battery cells 192 (eg, N battery cells) (192) standard charging current according to each specification, or standard charging current set/defined for charging each N battery cells 192, etc.), specified standard charging time for each N battery cells 192 (eg, N The standard charging time according to the specifications for each battery cell 192, or the standard charging time set/defined for charging each N battery cells 192, etc.), the specified standard current ratio for each of the N battery cells 192 (Current Rate) ) (e.g., the standard current ratio in the specifications for each N battery cells 192, or the standard current ratio separately set/defined for the N battery cells 192, etc.), when charging specified for each N battery cells 192 The standard current ratio (eg, the standard current ratio when charging according to the specifications of the N battery cells 192, or the standard current ratio set/defined for charging each N battery cells 192, etc.), the N battery cells ( 192) Among the specified discharge standard current ratio (for example, the standard current ratio for discharging according to the specifications for each N battery cells 192, or the standard current ratio set/defined for discharging for each N battery cells 192) contains more than one piece of information can do.

On the other hand, according to the implementation method of the present invention, the management information is confirmed through the specification of the battery module 188 for the optical balance test for the battery module 188, or the battery module 188 confirmed by measuring a designated part Geometry specification information corresponding to the geometric structure of Specification information corresponding to a combination of two or more of the curvatures of the vertex region), and the color of the battery module 188 confirmed through the specification or measurement of the battery module 188 (or the designated angle of the battery module 188) The color specification information of the battery module 188 corresponding to the color of each part) It may further include pattern specification information of the battery module 188 .

Meanwhile, according to the study of the applicant, when the balance state including the voltage difference between the N battery cells 192 provided in the battery module 188 during the charging and discharging process of the battery module 188 is out of a specific effective balance range, It was confirmed that the heat generation of the battery cell 192 rapidly increased, so that the probability of a fire or explosion was increased exponentially. Although the effective balance range in which the heat generation rapidly increases is slightly different for each battery manufacturer and/or each battery module 188, in general, the voltage difference between the N battery cells 192 is different for each battery cell 192. ) It was confirmed that the heat generation of the battery cell 192 rapidly increases when it is out of the range of about 1% of the rated voltage of each star, and it is predicted that there is a risk of fire or explosion at any time thereafter. Therefore, the risk of fire or explosion can be offset only by maintaining the balance state between the N battery cells 192 within a preset effective balance range, and the present invention provides a charging process corresponding to the specified charging situation of the battery module 188 . It is preferable to select and reproduce the battery module 188 capable of guaranteeing stability through a balance test during a discharge process and/or a balance test during a discharge process corresponding to a specified discharge situation.

Referring to Figure 1, the control module 104, the specified procedure of the optical balance test to determine whether at least one of the damage, swelling, and discoloration of the battery module 188 is included within a preset effective range It includes an optical inspection unit 112 to perform. Meanwhile, the optical inspection unit 112 may be included in the battery regeneration device 100 in the form of a separate device (or module) separated from the control module 104 , and the present invention also includes such an embodiment within the scope of its rights.

The optical inspection unit 112, when the battery module 188 including the N number of battery cells 192 is prepared (or stocked), for a designated part of each part of the prepared (or stocked) battery module 188 A specified procedure of the optical balance test is performed to determine whether at least one of breakage, expansion, and discoloration is within a preset effective range or out of a preset effective range.

According to the first optical balance inspection embodiment of the present invention, the optical inspection unit 112 may include a camera unit or an optical sensor unit for sensing at least one of damage, expansion, and discoloration of the battery module 188 . In this case, the optical inspection unit 112 senses a designated part of the battery module 188 through the camera unit or the optical sensor unit to check the geometrical structure information of the battery module 188, and the management information corresponding to the A procedure of comparing and analyzing the geometrical structure standard information and the confirmed geometrical structure information may be performed, and the geometrical structure deformation state such as a broken state or an expanded state of the battery module 188 is a preset validity of the geometrical structure standard information. A procedure for determining whether the information is included within the range or out of a preset effective range of the geometric structure standard information may be performed. On the other hand, the optical inspection unit 112 corresponds to the procedure of detecting the color information or pattern information of the battery module 188 by sensing a designated part of the battery module 188 through the camera unit or the optical sensor unit, and the management information. A procedure of comparing and analyzing the color standard information or pattern standard information and the confirmed color information or pattern information can be performed, and the discoloration state of the battery module 188 determines the preset validity of the color standard information or pattern standard information. A procedure may be performed to determine whether it is within the range or out of a preset effective range of the color standard information or the pattern standard information.

According to the second optical balance test embodiment of the present invention, the inspector can inspect a change in at least one of a broken state, an expanded state, and a discoloration state for a designated part of each part of the battery module 188 through a visual inspection. In this case, the optical inspection unit 112 may include an input unit for receiving an inspection result visually inspected by the inspector. Preferably, the optical inspection unit 112 may perform a procedure of receiving the inspection result of the visual inspection from the inspector through the input unit, and read the inspection result to be designated among each part of the battery module 188 . A procedure for determining whether at least one of breakage, expansion, and discoloration of the part is within a preset effective range or out of a preset effective range may be performed.

According to the third optical balance inspection embodiment of the present invention, the inspector inspects a change in at least one of a broken state, an expanded state, and a discoloration state for a designated part of each part of the battery module 188 through measurement through a measuring instrument. In this case, the optical inspection unit 112 may include an input unit for receiving an inspection result measured and inspected by the inspector. Preferably, the optical inspection unit 112 may perform a procedure of receiving an inspection result of the measurement inspection from the inspector through the input unit, and read the inspection result to be designated among each part of the battery module 188 . A procedure for determining whether at least one of breakage, expansion, and discoloration of the part is within a preset effective range or out of a preset effective range may be performed.

On the other hand, when the state of at least one of damage, expansion, and discoloration of a designated part of the battery module 188 is out of a preset effective range, the optical inspection unit 112 recovers the battery module 188 as resources. It can be determined as the target battery module 188, and the battery module 188 is resource recovered through a designated output unit (eg, at least one output unit among a screen output unit, an LED output unit, and a sound output unit (not shown)). Disposal of notifying the battery module 188 to the target battery module 188 and/or the battery module 188 to the target battery module 188 for resource recovery to a designated terminal or server through a designated communication unit (not shown) Notification information can be sent.

On the other hand, according to the fourth optical balance inspection embodiment of the present invention, the inspector through a visual inspection or measurement inspection of at least one state of damage, expansion, discoloration of a designated part of each part of the battery module 188 is preset After determining whether it is within the effective range or out of the preset effective range, the battery module ( 188) is connected to the module connection unit 180 and the cell connection unit 184, the optical inspection unit 112 may be omitted, and the present invention is not limited thereto.

Referring to FIG. 1 , the control module 104 measures the resistance value of the battery module 188 through the module connection unit 180 and performs a resistance test to determine whether it matches a preset effective resistance range. and an inspection unit 116 .

When the power terminal of the battery module 188 is connected to the module connection terminal of the module connection unit 180 and the cell terminal of the battery module 188 is connected to the cell connection terminal of the cell connection unit 184, the resistance test unit Reference numeral 116 measures the internal resistance value of the battery module 188 through the module connection unit 180, and determines whether the measured internal resistance value of the battery module 188 matches a preset effective resistance range.

If the measured internal resistance value of the battery module 188 matches a preset effective resistance range, the resistance test unit 116 includes the battery module 188 in the regeneration target battery module 188 or reproduces it. The state included in the target battery module 188 is maintained. On the other hand, when the measured internal resistance value of the battery module 188 is out of a preset effective resistance range (eg, the amount of active material in the N battery cells 192 is reduced below a specified reference amount, so that the internal resistance value is a preset effective resistance value) out of the resistance range, etc.), the resistance test unit 116 may determine the battery module 188 as the resource recovery target battery module 188, and a designated output unit (eg, a screen output unit, an LED output unit, a sound Through at least one output unit (not shown) of the output units, discard notification information for notifying the battery module 188 to the resource recovery target battery module 188 is outputted and/or through a designated communication unit (not shown) Disposal notification information for notifying the battery module 188 to the resource recovery target battery module 188 may be transmitted to a designated terminal or server.

Referring to FIG. 1 , the control module 104 includes a module charging unit 120 for charging the battery module 188 to a specified maximum charging voltage through the module connection unit 180 , and the battery module 188 ) when charging, a charge balance check unit 124 that checks balance information including a charge voltage difference between the N battery cells 192 provided in the battery module 188 through the cell connection unit 184, and the and a charge balance checker 128 that performs a balance check to determine whether a difference in charge voltage between the N battery cells 192 included in the balance information matches a preset charge voltage effective balance range.

The module charging unit 120 applies a specified module charging power to the power terminal of the battery module 188 through the module connection unit 180 to charge the battery module 188 to a specified maximum charging voltage. do. For example, eight battery cells 192 are provided in series in the battery module 188, the rated voltage for each battery cell 192 is 3.7V, and the maximum charging voltage for each battery cell 192 is 4.2V and when the amount of current is 30A, the module charging unit 120 applies power for charging the module of 33.6V (=8*4.2V) to the power terminal of the battery module 188 through the module connection unit 180, The battery module 188 can be charged up to 33.6V.

According to the embodiment of the present invention, the module charging unit 120 checks the voltage value for each of the N battery cells 192 through the cell connection unit 184 before charging the battery module 188, and the confirmation A balance check procedure may be performed to determine whether the voltage difference for each of the N battery cells 192 is within a preset initial voltage balance range based on the voltage values for each of the N battery cells 192 . Here, the balance check procedure does not consider whether the voltage value charged in the N battery cells 192 is large or small, and the voltage value charged in the N battery cells 192 is determined for each battery cell 192 . ) between the specified maximum charging voltage and the specified minimum discharge voltage (or the voltage value in the state of being charged or discharged through the BMS of the battery manufacturer before being removed from the waste battery) is sufficient. That is, the balance check procedure checks whether the voltage difference between the N battery cells 192 is within a preset initial voltage balance range, regardless of the magnitude of the voltage value charged in the N battery cells 192 . It is desirable to include a procedure. If the voltage difference for each of the N battery cells 192 is out of a preset initial voltage balance range, the module charging unit 120 performs the N through the cell connection unit 184 before charging the battery module 188 . Among the number of battery cells 192, a specified cell charging power is selectively applied to some cell terminals corresponding to some battery cells 192 having a lower voltage value than that of other battery cells 192, and/or the N battery cells ( 192) of the N battery cells ( 192) may be initialized within a preset initial voltage balance range. For example, when the rated voltage for each battery cell 192 is 3.7V and the amount of current is 30A, the module charging unit 120 performs the N through the cell connection unit 184 before charging the battery module 188 . The voltage difference between the battery cells 192 may be initialized within 3 mV.

According to the embodiment of the present invention, the module charging unit 120 includes a function of charging the battery module 188 according to a specified current ratio through the module connection unit 180 . For example, the module charging unit 120 may charge the battery module 188 through the module connection unit 180 at a current ratio of 0.5C (C-rate). However, the current ratio for charging the battery module 188 is not limited to a specific value, and the current ratio may include various ratios within a specified range (eg, a current ratio of 0.3C or a current ratio of 1.0C, etc.). .

In the case of one voltage embodiment for charging the battery module 188 in the present invention, the module charging unit 120 may be charged by applying a specified constant voltage to the battery module 188 through the module connection unit 180 .

On the other hand, in the case of another voltage embodiment for charging the battery module 188 in the present invention, the module charging unit 120 is a voltage pattern that is changed within the voltage range specified in the battery module 188 through the module connection unit 180. It can be charged by applying a matching voltage. That is, when the battery module 188 is regenerated as a regenerative battery and then charged in a designated application field, different voltages may be applied and charged according to a charging method for charging the regenerative battery. In order to check whether the module 188 is charged while maintaining the balance, the battery module 188 may be charged by applying a voltage matching a voltage pattern of various situations changing within a specified voltage range.

In the case of a current embodiment for charging the battery module 188 in the present invention, the module charging unit 120 is charged by applying a constant current matching the specified current ratio to the battery module 188 through the module connection unit 180 . can do.

On the other hand, in the case of another current embodiment for charging the battery module 188 in the present invention, the module charging unit 120 is a current pattern that is changed within the current ratio range specified in the battery module 188 through the module connection unit 180. It can be charged by applying a current matching the . That is, when the battery module 188 is regenerated as a regenerative battery and then charged in a designated application field, different amounts of current may be applied and charged according to a charging method for charging the regenerative battery. In order to check whether the module 188 is charged while maintaining the balance, the battery module 188 may be charged by applying a current matching the current pattern of various situations changing within a specified current ratio range.

When the battery module 188 is charged through the module charging unit 120 , the charge balance checking unit 124 is provided with the N battery cells 192 provided in the battery module 188 through the cell connection unit 184 . ) is checked, and balance information including a charging voltage difference between the N battery cells 192 is checked based on the checked voltage values for each of the N battery cells 192 .

Meanwhile, when the balance information including the charging voltage difference between the N battery cells 192 is checked through the charge balance check unit 124 , the charge balance check unit 128 determines the N number of battery cells included in the balance information. A balance check is performed to determine whether the charging voltage difference between 192 matches the preset charging voltage effective balance range. For example, when the rated voltage for each battery cell 192 is 3.7V and the amount of current is 30A, the charge balance checker 128 determines whether the charging voltage difference between the N battery cells 192 is within 30mV. inspection can be performed.

According to the embodiment of the present invention, the charge balance check unit 124 is charged to the battery module 188 through the cell connection unit 184 while the battery module 188 is charged through the module charging unit 120 . It is possible to check the balance information including the charging voltage difference during charging between the N battery cells 192 provided, and in this case, the charge balance checker 128 is charged between the N battery cells 192 included in the balance information. A balance check may be performed to determine whether the difference between the charging voltages matches a preset charging voltage effective balance range.

If the charging voltage difference during charging between the N battery cells 192 matches the preset charging voltage effective balance range, the charging balance checker 128 converts the battery module 188 to the regenerated target battery module 188 . It is included in or maintained in the state included in the regeneration target battery module 188 . On the other hand, when the charging voltage difference during charging between the N battery cells 192 is out of a preset charging voltage effective balance range, the charging balance checking unit 128 sets the battery module 188 to the resource recovery target battery module 188. It can be determined as, and through a designated output unit (eg, at least one output unit (not shown) of a screen output unit, an LED output unit, and a sound output unit), the battery module 188 is a resource recovery target battery module 188. Disposal notification information for notifying the battery module 188 to the resource recovery target battery module 188 may be output and/or to a designated terminal or server through a designated communication unit (not shown). .

On the other hand, according to the embodiment of the present invention, when the battery module 188 is charged up to a specified maximum charging voltage through the module charging unit 120, the charge balance check unit 124 is configured to use the cell connection unit 184 through the cell connection unit 184 The balance information including the maximum charging voltage difference between the N battery cells 192 provided in the battery module 188 can be checked. A balance check may be performed to determine whether the maximum charging voltage difference between the cells 192 matches a preset charging voltage effective balance range.

If the maximum charge voltage difference between the N battery cells 192 matches the preset charge voltage effective balance range, the charge balance check unit 128 sets the battery module 188 to the regeneration target battery module 188. It is included or maintained in the state included in the reproduction target battery module 188 . On the other hand, when the maximum charging voltage difference between the N battery cells 192 is out of a preset charging voltage effective balance range, the charging balance checker 128 converts the battery module 188 to the resource recovery target battery module 188. It can be determined, and the battery module 188 is transferred to the resource recovery target battery module 188 through a designated output unit (eg, at least one output unit (not shown) among a screen output unit, an LED output unit, and a sound output unit). Disposal notification information for notifying may be output and/or disposal notification information for notifying the battery module 188 to the resource recovery target battery module 188 may be transmitted to a designated terminal or server through a designated communication unit (not shown).

According to the embodiment of the present invention, the module charging unit 120 may perform a charging procedure for charging the battery module 188 to a specified maximum charging voltage one or more times. Preferably, the module charging unit 120 may perform a charging procedure for a standard charging situation, as well as a charging procedure for various charging situations that may occur in an application field using a regenerative battery including the battery module 188. have. The charge balance check unit 124 may check the balance information including the maximum charge voltage difference between the N battery cells 192 provided in the battery module 188 one or more times in the process of performing the charging procedure. In addition, the charge balance check unit 128 may perform a balance check to determine whether the maximum charge voltage difference between the N battery cells 192 included in the balance information matches a preset charge voltage effective balance range one or more times. have.

1, the control module 104 includes a module discharge unit 132 for discharging the battery module 188 to a specified lowest discharge voltage through the module connection unit 180, and the battery module ( When discharging 188), a discharge balance checking unit 136 that checks balance information including a discharge voltage difference between the N battery cells 192 provided in the battery module 188 through the cell connection unit 184; and a discharge balance checker 140 that performs a balance check for determining whether a discharge voltage difference between the N battery cells 192 included in the balance information matches a preset discharge voltage effective balance range.

The module discharging unit 132 performs a procedure of discharging the battery module 188 to a specified lowest discharge voltage through the module connection unit 180 . For example, eight battery cells 192 are provided in the battery module 188, the rated voltage for each battery cell 192 is 3.7V, the lowest discharge voltage for each battery cell 192 is 3.0V, and the amount of current In the case of 30A, the module discharge unit 132 may discharge the battery module 188 to 24V through the module connection unit 180 .

According to the implementation method of the present invention, the module discharging unit 132 discharges the battery module 188 to a specified minimum discharge in a state in which the battery module 188 is charged to a specified maximum charging voltage through the module charging unit 120 . Discharge to voltage can be performed. Meanwhile, according to another embodiment of the present invention, the module discharging unit 132 converts the current charged voltage to the specified lowest discharging voltage before the battery module 188 is charged to the specified maximum charging voltage through the module charging unit 120 . The discharging procedure may be performed first, and the present invention is not limited thereto.

According to the embodiment of the present invention, the module discharging unit 132 checks the voltage value for each of the N battery cells 192 through the cell connection unit 184 before discharging the battery module 188, and the A balance check procedure may be performed to determine whether a voltage difference for each of the N battery cells 192 is within a preset initial voltage balance range based on the checked voltage values for each of the N battery cells 192 . Here, in the balance check procedure, it is not considered that the voltage values charged in the N battery cells 192 are large or small, and the voltage values charged in the N battery cells 192 are determined for each battery cell 192 . ), any voltage value between the specified minimum discharge voltage and the specified minimum discharge voltage (or a voltage value in a state charged through the module charging unit 120) is sufficient. That is, the balance check procedure checks whether the voltage difference between the N battery cells 192 is within a preset initial voltage balance range, regardless of the magnitude of the voltage value charged in the N battery cells 192 . It is desirable to include a procedure. If the voltage difference for each of the N battery cells 192 is out of a preset initial voltage balance range, the module discharging unit 132 operates through the cell connection unit 184 before discharging the battery module 188 . Among the N battery cells 192 , a specified cell charging power is selectively applied to some cell terminals corresponding to some battery cells 192 having a lower voltage value than other battery cells 192 , and/or the N battery cells The N battery cells by selectively discharging the power charged in the some battery cells 192 through some cell terminals corresponding to some battery cells 192 having a higher voltage value than the other battery cells 192 among (192). The voltage difference between 192 may be initialized within a preset initial voltage balance range. For example, when the rated voltage for each battery cell 192 is 3.7V and the amount of current is 30A, the module discharging unit 132 passes through the cell connection unit 184 before discharging the battery module 188 . The voltage difference between the N battery cells 192 may be initialized within 3 mV.

According to the embodiment of the present invention, the module discharging unit 132 includes a function of discharging the battery module 188 according to a specified current ratio through the module connection unit 180 . For example, the module discharging unit 132 may discharge the battery module 188 through the module connection unit 180 at a current ratio of 0.5C (C-rate). However, the current ratio for discharging the battery module 188 is not limited to a specific value, and the current ratio may include various ratios within a specified range (eg, a current ratio of 0.3C or a current ratio of 1.0C, etc.). .

In the case of one voltage embodiment for discharging the battery module 188 in the present invention, the module discharging unit 132 may discharge the battery module 188 according to a specified constant voltage through the module connection unit 180 .

Meanwhile, in the case of another voltage embodiment for discharging the battery module 188 in the present invention, the module discharging unit 132 is configured to change the battery module 188 according to a voltage pattern that is changed within a voltage range specified through the module connection unit 180 . ) can be discharged. That is, the battery module 188 may be discharged to different voltages according to a discharging method for discharging the regenerative battery when discharging in a designated application field after reproducing the battery module 188 as a regenerative battery. In order to check whether the battery module 188 is discharged while maintaining the balance of 188 , the battery module 188 may be discharged to match the voltage pattern of various situations changed within a specified voltage range.

In the case of a current embodiment in which the battery module 188 is discharged in the present invention, the module discharge unit 132 discharges the battery module 188 according to a constant current matching a specified current ratio through the module connection unit 180 . can do.

On the other hand, in the case of another current embodiment for discharging the battery module 188 in the present invention, the module discharging unit 132 is the battery module ( 188) can be discharged. That is, after the battery module 188 is regenerated as a regenerative battery, when discharging in a designated application field, different current amounts may be discharged according to a discharging method for discharging the regenerative battery. In order to check whether the battery module 188 is discharged while maintaining the balance of the battery module 188, the battery module 188 may be discharged to match the current pattern of various situations changed within a specified current ratio range.

When discharging the battery module 188 through the module discharging unit 132 , the discharge balance checking unit 136 generates N battery cells ( 192) Check each voltage value, and check balance information including a discharge voltage difference between the N battery cells 192 based on the checked voltage value for each N battery cells 192 .

Meanwhile, when the balance information including the discharge voltage difference between the N battery cells 192 is checked through the discharge balance check unit 136 , the discharge balance check unit 140 determines the N number of battery cells included in the balance information. A balance check is performed to determine whether the discharge voltage difference between 192 is matched to a preset discharge voltage effective balance range. For example, when the rated voltage for each battery cell 192 is 3.7V and the amount of current is 30A, the discharge balance checker 140 determines whether the discharge voltage difference between the N battery cells 192 is within 30mV. inspection can be performed.

According to the implementation method of the present invention, the discharge balance checking unit 136 is configured to discharge the battery module 188 through the module discharge unit 132 while discharging the battery module 188 through the cell connection unit 184. It is possible to check the balance information including the discharge voltage difference during discharging between the N battery cells 192 provided in the A balance check may be performed to determine whether a discharge voltage difference during discharge matches a preset discharge voltage effective balance range.

If the discharging voltage difference during discharging between the N battery cells 192 matches a preset discharging voltage effective balance range, the discharging balance check unit 140 sets the battery module 188 to the regenerated target battery module 188 . It is included in or maintained in the state included in the regeneration target battery module 188 . On the other hand, when the discharge voltage difference during discharging between the N battery cells 192 is out of a preset discharge voltage effective balance range, the discharge balance inspection unit 140 sets the battery module 188 to the resource recovery target battery module 188. It can be determined as, and through a designated output unit (eg, at least one output unit (not shown) of a screen output unit, an LED output unit, and a sound output unit), the battery module 188 is a resource recovery target battery module 188. Disposal notification information for notifying the battery module 188 to the resource recovery target battery module 188 may be output and/or to a designated terminal or server through a designated communication unit (not shown). .

Meanwhile, according to the embodiment of the present invention, when the battery module 188 is discharged to a specified minimum discharge voltage through the module discharge unit 132 , the discharge balance check unit 136 connects the cell connection unit 184 to the cell connection unit 184 . The balance information including the minimum discharge voltage difference between the N battery cells 192 provided in the battery module 188 can be checked through the A balance check may be performed to determine whether the minimum discharge voltage difference between the battery cells 192 matches a preset discharge voltage effective balance range.

If the minimum discharge voltage difference between the N battery cells 192 matches the preset discharge voltage effective balance range, the discharge balance checker 140 sets the battery module 188 to the regeneration target battery module 188. It is included or maintained in the state included in the reproduction target battery module 188 . On the other hand, when the minimum discharge voltage difference between the N battery cells 192 is out of a preset discharge voltage effective balance range, the discharge balance inspection unit 140 sets the battery module 188 to the resource recovery target battery module 188 . It can be determined, and the battery module 188 is transferred to the resource recovery target battery module 188 through a designated output unit (eg, at least one output unit (not shown) among a screen output unit, an LED output unit, and a sound output unit). Disposal notification information for notifying may be output and/or disposal notification information for notifying the battery module 188 to the resource recovery target battery module 188 may be transmitted to a designated terminal or server through a designated communication unit (not shown).

According to the embodiment of the present invention, the module discharging unit 132 may perform a discharging procedure for discharging the battery module 188 to a specified lowest discharging voltage one or more times. Preferably, the module discharging unit 132 performs a discharging procedure for various discharging situations that may occur in an application field using a regenerative battery including the battery module 188, as well as a discharging procedure for a reference discharging situation. can The discharge balance check unit 136 may check the balance information including the lowest discharge voltage difference between the N battery cells 192 provided in the battery module 188 one or more times in the process of performing the discharging procedure. In addition, the discharge balance checker 140 may perform a balance check to determine whether the minimum discharge voltage difference between the N battery cells 192 included in the balance information matches a preset discharge voltage effective balance range one or more times. have.

Referring to Figure 1, the control module 104, when the battery module 188 is discharged to the specified lowest discharge voltage, the discharge time required for discharging the battery module 188 to the specified lowest discharge voltage a remaining ratio calculating unit 144 for checking and calculating the remaining ratio of the battery module 188 based on a proportional relationship between the confirmed discharge time and a reference discharge time corresponding to the reciprocal of the current ratio; and a residual ratio checker 148 that determines whether the calculated residual ratio matches a preset residual ratio effective range.

When the battery module 188 is charged to a specified maximum charging voltage through the module charging unit 120 and then the battery module 188 is discharged to a specified lowest discharging voltage through the module discharging unit 132, the remaining The ratio calculator 144 checks the discharging time required for discharging the battery module 188 to the specified lowest discharge voltage (eg, discharging from the specified lowest discharging voltage to the specified lowest discharging voltage), and the module discharging unit ( After confirming the reference discharge time corresponding to the reciprocal of the current ratio (or the pattern of the current ratio) based on the current ratio (or the pattern of the current ratio) at which the 132) has discharged the battery touch module, the confirmed discharge time The remaining ratio of the battery module 188 is calculated on the basis of the proportional relationship between and the reference discharge time. For example, when the battery module 188 is discharged at a current ratio of 0.5C (C-rate) through the module discharging unit 132 , the reference discharge time corresponding to the reciprocal of the current ratio is 2 hours. If the discharging time required for discharging the battery module 188 to the specified lowest discharge voltage is 2 hours, the remaining ratio calculating unit 144 calculates the remaining ratio of the battery module 188 as 100%. can do. Alternatively, when it is confirmed that the discharge time of the battery module 188 is 1 hour, the remaining ratio calculating unit 144 may calculate the remaining ratio of the battery module 188 as 50%.

When the remaining ratio of the battery module 188 is calculated through the remaining ratio calculating unit 144, the remaining ratio checking unit 148 determines that the calculated remaining ratio of the battery module 188 is in the preset remaining ratio effective range. determine whether they match.

If the calculated remaining ratio matches the preset effective remaining ratio range, the remaining ratio checker 148 includes the battery module 188 in the reproduction target battery module 188 or the reproduction target battery module 188 ) remain included. On the other hand, when the calculated remaining ratio is out of a preset effective remaining ratio range, the charge balance check unit 128 may determine the battery module 188 as the resource recovery target battery module 188, and a designated output unit (eg, , through at least one output unit (not shown) among a screen output unit, an LED output unit, and a sound output unit) to output disposal notification information for notifying the battery module 188 to the resource recovery target battery module 188, or / Alternatively, the disposal notification information for notifying the battery module 188 to the resource recovery target battery module 188 may be transmitted to a designated terminal or server through a designated communication unit (not shown).

1, the control module 104 includes a module regeneration unit 152 for charging and regenerating the battery module 188 through the module connection unit 180 to a specified ratio range of a specified module rated voltage; When the voltage of the battery module 188 reaches a specified ratio range of the specified module rated voltage, the N battery cells 192 are simultaneously charged and regenerated through the cell connection unit 184 to the specified rated voltage for each cell. Balance including a regeneration voltage difference between the N battery cells 192 provided in the battery module 188 through the cell connection unit 184 when the battery module 188 is reproduced, and including a regeneration unit 164 A module regeneration balance check unit 156 for checking information, and a balance check for determining whether a difference in regeneration voltage between the N battery cells 192 included in the balance information matches a preset module regeneration voltage effective balance range It further includes a module regeneration balance check unit 168 and 160, and when the N battery cells 192 are reproduced, the N battery cells 192 provided in the battery module 188 through the cell connection unit 184. A cell regeneration balance check unit for checking balance information including a difference in regeneration voltage between the cells, and determining whether a difference in regeneration voltage between the N battery cells 192 included in the balance information matches a preset cell regeneration voltage effective balance range It further includes a cell regeneration balance checker 172 that performs a balance check.

The battery module 188 is inspected as a valid reproduction target battery module 188 by performing at least one charging procedure for the designated battery module 188 through the module charging unit 120 or at least one balance check linked thereto. If successful, the battery module 188 is tested as a valid regeneration target battery module 188 by performing at least one discharge procedure through the module discharging unit 132, a balance check and a residual ratio check linked thereto, at least once. If successful, the module regeneration unit 152 performs a regeneration procedure by charging the battery module 188 up to a specified ratio range of the specified module rated voltage through the module connection unit 180 . For example, eight battery cells 192 are provided in series in the battery module 188, the rated voltage for each battery cell 192 is 3.7V, and the maximum charging voltage for each battery cell 192 is 4.2V and when the amount of current is 30A, the module regeneration unit 152 applies power for charging the module of 33.6V (=8*4.2V) to the power terminal of the battery module 188 through the module connection unit 180, The battery module 188 can be charged up to 28V, which is within a specified ratio range of 29.6V, which is a specified module rated voltage.

According to the embodiment of the present invention, the module reproducing unit 152 checks the voltage value for each of the N battery cells 192 through the cell connection unit 184 before charging and regenerating the battery module 188, , a balance check procedure of confirming whether the voltage difference for each of the N battery cells 192 is within a preset initial voltage balance range may be performed based on the checked voltage value for each of the N battery cells 192 . Here, the balance check procedure does not consider whether the voltage value charged in the N battery cells 192 is large or small, and the voltage value charged in the N battery cells 192 is determined for each battery cell 192 . ), any voltage value between the specified maximum charge voltage and the specified minimum discharge voltage is sufficient. That is, the balance check procedure checks whether the voltage difference between the N battery cells 192 is within a preset initial voltage balance range, regardless of the magnitude of the voltage value charged in the N battery cells 192 . It is desirable to include a procedure. If the voltage difference for each of the N battery cells 192 is out of a preset initial voltage balance range, the module reproducing unit 152 connects the cell connection unit 184 before charging and regenerating the battery module 188 . Through the N battery cells 192, a specified cell charging power is selectively applied to some cell terminals corresponding to some battery cells 192 having a lower voltage value than other battery cells 192, and/or the N Among the battery cells 192, the power charged in the some battery cells 192 is selectively discharged through some cell terminals corresponding to some battery cells 192 having a higher voltage value than that of the other battery cells 192, so that the N The voltage difference between the battery cells 192 may be initialized within a preset initial voltage balance range. For example, when the rated voltage for each battery cell 192 is 3.7V and the amount of current is 30A, the module regeneration unit 152 connects the cell connection unit 184 before charging and regenerating the battery module 188 . Through this, the voltage difference between the N battery cells 192 may be initialized to within 3 mV.

According to the embodiment of the present invention, the module regeneration unit 152 includes a function of charging and regenerating the battery module 188 according to a specified current ratio through the module connection unit 180 . For example, the module regeneration unit 152 may regenerate the battery module 188 by charging it at a current ratio of 0.5C (C-rate) through the module connection unit 180 . However, the current ratio for charging and regenerating the battery module 188 is not limited to a specific value, and the current ratio may include various ratios within a specified range (eg, a current ratio of 0.3C or a current ratio of 1.0C, etc.). can

In the case of a voltage embodiment in which the battery module 188 is charged and reproduced in the present invention, the module regeneration unit 152 may be charged and reproduced by applying a specified constant voltage to the battery module 188 through the module connection unit 180 . have.

In the present invention, in the case of a current embodiment in which the battery module 188 is charged and regenerated, the module reproducing unit 152 applies a constant current matching the specified current ratio to the battery module 188 through the module connection unit 180 . It can be recharged and played.

When the battery module 188 is charged and reproduced through the module regeneration unit 152 , the module regeneration balance check unit 156 performs the N number of batteries provided in the battery module 188 through the cell connection unit 184 . A voltage value for each battery cell 192 is checked, and balance information including a reproduction voltage difference between the N battery cells 192 is checked based on the checked voltage value for each N battery cell 192 .

On the other hand, when the balance information including the regeneration voltage difference between the N battery cells 192 is checked through the module regeneration balance check unit 156, the module regeneration balance check unit 168, 160 is included in the balance information A balance check is performed to determine whether the difference in the regeneration voltage between the N battery cells 192 matches the preset module regeneration voltage effective balance range. For example, when the rated voltage for each battery cell 192 is 3.7V and the amount of current is 30A, the module regeneration balance checker 168, 160 determines that the difference in the regeneration voltage between the N battery cells 192 is within 30mV. A balance test to determine cognition may be performed.

According to the embodiment of the present invention, the module regeneration balance check unit 156 charges the battery module 188 through the module regeneration unit 152 and the battery module through the cell connection unit 184 while playing. Balance information including a regeneration voltage difference during module regeneration between the N battery cells 192 provided in 188 can be checked, and in this case, the module regeneration balance check unit 168, 160 includes the A balance check may be performed to determine whether a difference in a regeneration voltage during module regeneration between the N battery cells 192 matches a preset effective module regeneration voltage effective balance range.

If the regeneration voltage difference during module regeneration between the N battery cells 192 matches the preset module regeneration voltage effective balance range, the module regeneration balance check unit 168 , 160 reproduces the battery module 188 . It is included in the target battery module 188 or maintains the state included in the target battery module 188 to be reproduced. On the other hand, when the difference in the regeneration voltage during module regeneration among the N battery cells 192 is out of a preset module regeneration voltage effective balance range, the module regeneration balance check unit 168, 160 recovers the battery module 188 as resources. It can be determined as the target battery module 188, and the battery module 188 is resource recovered through a designated output unit (eg, at least one output unit among a screen output unit, an LED output unit, and a sound output unit (not shown)). Disposal of notifying the battery module 188 to the target battery module 188 and/or the battery module 188 to the target battery module 188 for resource recovery to a designated terminal or server through a designated communication unit (not shown) Notification information can be sent.

On the other hand, according to the implementation method of the present invention, when the module regeneration balance check unit 156 is regenerated by charging the battery module 188 through the module regeneration unit 152 to a specified ratio range of the specified module rated voltage, The balance information including the module regeneration voltage difference between the N battery cells 192 provided in the battery module 188 can be checked through the cell connection unit 184. In this case, the module regeneration balance check unit 168 ( 160) may perform a balance check to determine whether a module regeneration voltage difference between the N battery cells 192 included in the balance information matches a preset effective module regeneration voltage balance range.

If the module regeneration voltage difference between the N battery cells 192 matches a preset module regeneration voltage effective balance range, the module regeneration balance check unit 168, 160 selects the battery module 188 as a regeneration target battery. It is included in the module 188 or maintained in the state included in the regeneration target battery module 188 . On the other hand, when the module regeneration voltage difference between the N battery cells 192 is out of a preset module regeneration voltage effective balance range, the module regeneration balance check unit 168, 160 selects the battery module 188 as a resource recovery target battery. It can be determined as the module 188, and the battery module 188 is a resource recovery target battery through a designated output unit (eg, at least one output unit among a screen output unit, an LED output unit, and a sound output unit (not shown)). Disposal notification information for outputting disposal notification information to notify the module 188 and/or notifying the battery module 188 to a resource recovery target battery module 188 to a designated terminal or server through a designated communication unit (not shown) can be transmitted.

Meanwhile, according to another embodiment of the present invention, before the battery module 188 is reproduced through the module reproducing unit 152, a balance check is performed more than a specified number of times through the module charging unit 120 or the module discharging unit 132. In this case, the module regeneration balance check unit 156 and the module regeneration balance check unit can be omitted, and the present invention is not limited thereto.

When the voltage of the battery module 188 reaches a specified ratio range of the specified module rated voltage through the module reproducing unit 152, the cell reproducing unit 164 is connected to the N A procedure of simultaneously charging and regenerating the battery cells 192 up to the rated voltage for each designated cell is performed. For example, when eight battery cells 192 are provided in series in the battery module 188, the rated voltage for each battery cell 192 is 3.7V and the current is 30A, the module regeneration unit 152 When the voltage of the battery module 188 reaches 28V through .

According to the embodiment of the present invention, the cell regeneration unit 164 determines the voltage values for each of the N battery cells 192 through the cell connection unit 184 before charging and regenerating the N battery cells 192 . Check and perform a balance check procedure to check whether the voltage difference for each of the N battery cells 192 is within a preset cell regeneration voltage effective balance range based on the checked voltage value for each of the N battery cells 192 have. Here, the balance check procedure does not consider whether the voltage value charged in the N battery cells 192 is large or small, and the voltage value charged in the N battery cells 192 is determined for each battery cell 192 . ), any voltage value between the specified maximum charge voltage and the specified minimum discharge voltage is sufficient. That is, the balance check procedure determines whether the voltage difference between the N battery cells 192 is within a preset effective cell regeneration voltage balance range regardless of the magnitude of the voltage value charged in the N battery cells 192 . It is desirable to include a procedure for verification. If the voltage difference for each of the N battery cells 192 is out of a preset cell regeneration voltage effective balance range, the cell regeneration unit 164 charges and reproduces the N battery cells 192 before the cell connection unit Through 184, a specified cell charging power is selectively applied to some cell terminals corresponding to some battery cells 192 having a lower voltage value than other battery cells 192 among the N battery cells 192 and/or Alternatively, the power charged in some of the battery cells 192 is selectively discharged through some cell terminals corresponding to some of the battery cells 192 having a higher voltage value than that of the other battery cells 192 among the N battery cells 192 . Thus, the voltage difference between the N battery cells 192 may be initialized within a preset cell regeneration voltage effective balance range. For example, when the rated voltage for each battery cell 192 is 3.7V and the amount of current is 30A, the cell regenerating unit 164 charges and regenerates the N battery cells 192 before regenerating the N battery cells 192 , the cell connection unit 184 . ), the voltage difference between the N battery cells 192 may be initialized to within 3 mV.

According to the embodiment of the present invention, the cell regeneration unit 164 includes a function of charging and regenerating the N battery cells 192 according to a specified current ratio through the cell connection unit 184 . For example, the cell regeneration unit 164 may regenerate the N battery cells 192 by charging them at a current ratio of 0.5C (C-rate) through the cell connection unit 184 . However, the current ratio for charging and regenerating the N battery cells 192 is not limited to a specific value, and the current ratio may vary within a specified range (eg, a current ratio of 0.3C or a current ratio of 1.0C). may include

In the present invention, in the case of a voltage embodiment in which the N battery cells 192 are charged and reproduced, the cell regeneration unit 164 applies a specified constant voltage to the N battery cells 192 through the cell connection unit 184 to It can be recharged and played.

In the present invention, in the case of the current embodiment in which the N battery cells 192 are charged and reproduced, the cell regeneration unit 164 matches the current ratio specified for the N battery cells 192 through the cell connection unit 184 . It can be regenerated by charging by applying a constant current.

On the other hand, according to the embodiment of the present invention, the cell regeneration unit 164 is reproduced for each of the N battery cells 192 while simultaneously charging and regenerating the N battery cells 192 through the cell connection unit 184 . As the cell regeneration voltage approaches the rated voltage for each specified cell, it is preferable to reduce the amount of current of the cell regeneration power applied to the N battery cells 192 to a specified fine current range according to a specified reduction pattern to perform reproduction while finely balancing. . For example, when the rated voltage for each battery cell 192 is 3.7V and the amount of current is 30A, the cell regeneration unit 164 charges and reproduces the N battery cells 192 in the initial stage of regenerating the N batteries. Cell regenerative power including a voltage of 3.7V and a current of 5A is applied to the cell 192 for regeneration, and as the cell regeneration voltage reproduced for each of the N battery cells 192 approaches the rated voltage for each designated cell, the N The amount of current of the cell regeneration power applied to the battery cells 192 can be reduced to 50 mA according to a specified current amount reduction pattern, so that it can be reproduced while finely balancing it.

Meanwhile, when the N battery cells 192 are charged and reproduced through the cell regeneration unit 164 , the cell regeneration balance check unit checks the voltage values for each of the N battery cells 192 through the cell connection unit 184 . check, and check balance information including a difference in reproduction voltage between the N battery cells 192 based on the checked voltage values for each of the N battery cells 192 .

On the other hand, when the balance information including the regeneration voltage difference between the N battery cells 192 is checked through the cell regeneration balance check unit, the cell regeneration balance check unit 172 is configured to check the N battery cells 192 included in the balance information. ), a balance check is performed to determine whether the difference between the regeneration voltages matches a preset cell regeneration voltage effective balance range. For example, when the rated voltage for each battery cell 192 is 3.7V and the amount of current is 30A, the cell regeneration balance checker 172 determines whether the regeneration voltage difference between the N battery cells 192 is within 30 to 3 mV. A balance check to judge can be performed.

According to an embodiment of the present invention, the cell regeneration voltage effective balance range is a fine voltage balance range of a specified ratio or less than the module regeneration voltage effective balance range related to the regeneration of the battery module 188 through the module connection unit 180 . may include

According to another embodiment of the present invention, the effective balance range of the cell regeneration voltage is in the effective balance range of the module regeneration voltage related to the regeneration of the battery module 188 when the process of regenerating the N battery cells 192 is started. As the cell regeneration voltage that is matched and reproduced for each of the N battery cells 192 approaches the rated voltage of each designated cell, a balance range in which the cell regeneration voltage is reduced to a specified fine voltage balance range according to a designated reduction pattern may be included.

According to the embodiment of the present invention, the cell regeneration balance check unit charges and reproduces the N battery cells 192 through the cell regeneration unit 164 while the N battery cells are charged and reproduced through the cell connection unit 184 . Balance information including a difference in the regeneration voltage during cell regeneration between cells 192 may be checked, and in this case, the cell regeneration balance checker 172 may check the regeneration voltage during cell regeneration among the N battery cells 192 included in the balance information. A balance check may be performed to determine whether the difference matches a preset cell regeneration voltage effective balance range.

If the regeneration voltage difference during cell regeneration among the N battery cells 192 matches a preset cell regeneration voltage effective balance range, the cell regeneration balance check unit 172 converts the battery module 188 to a regeneration target battery module. Included in (188) or maintained in the state included in the regeneration target battery module (188). On the other hand, when the regeneration voltage difference between the N battery cells 192 is out of a preset cell regeneration voltage effective balance range during cell regeneration, the cell regeneration balance check unit 172 sets the battery module 188 to a resource recovery target battery module. It can be determined as 188, and the battery module 188 is a resource recovery target battery module through a designated output unit (eg, at least one output unit among a screen output unit, an LED output unit, and a sound output unit (not shown)). Disposal notification information notifying the battery module 188 to the resource recovery target battery module 188 to a designated terminal or server through a designated terminal or server and/or a designated communication unit (not shown) can be transmitted

On the other hand, according to the embodiment of the present invention, when the cell regeneration balance check unit is regenerated by charging the N battery cells 192 through the cell regeneration unit 164 to a specified rated voltage for each cell, the cell connection unit 184 ), the balance information including the cell regeneration voltage difference between the N battery cells 192 can be checked. A balance check may be performed to determine whether the inter-cell regeneration voltage difference matches a preset cell regeneration voltage effective balance range. For example, when the rated voltage for each battery cell 192 is 3.7V and the N battery cells 192 are recharged to a specified rated voltage for each cell and reproduced, the cell regeneration balance check unit 172 may display the balance information A balance check may be performed to determine whether the cell regeneration voltage difference between the N battery cells 192 included in the ?

If the cell regeneration voltage difference between the N battery cells 192 matches a preset cell regeneration voltage effective balance range, the cell regeneration balance checker 172 converts the battery module 188 to the regeneration target battery module 188 ) or maintain the state included in the regeneration target battery module 188 . Meanwhile, when the cell regeneration voltage difference between the N battery cells 192 is out of a preset cell regeneration voltage effective balance range, the cell regeneration balance check unit 172 sets the battery module 188 to the resource recovery target battery module 188 . ), the battery module 188 through a designated output unit (eg, at least one output unit (not shown) among a screen output unit, an LED output unit, and a sound output unit) to be a resource recovery target battery module 188 ) to output the disposal notification information and/or to transmit the disposal notification information for notifying the battery module 188 to the resource recovery target battery module 188 to a designated terminal or server through a designated communication unit (not shown). have.

Meanwhile, according to another embodiment of the present invention, before reproducing the N cells through the cell reproducing unit 164, a balance check is performed more than a specified number of times through the module charging unit 120 or the module discharging unit 132. In this case, the cell regeneration balance check unit and the cell regeneration balance check unit 172 may be omitted, and the present invention is not limited thereto.

Referring to FIG. 1 , the control module 104 includes a battery regeneration unit 176 that regenerates the battery by mounting a BMS for a regenerative battery having a balance management function in the regenerated battery module 188 . On the other hand, the battery regeneration unit 176 may be included in the battery regeneration device 100 in the form of a separate device (or module) separated from the control module 104, and the present invention includes such an embodiment within the scope of its rights. .

When the battery module 188 is regenerated through the module reproducing unit 152 and the cell reproducing unit 164, the battery reproducing unit 176 provides a balance management function for the regenerated battery to the regenerated battery module 188. BMS for a regenerative battery equipped with a battery is regenerated.

According to the embodiment of the present invention, the BMS for the regenerative battery is electrically connected to at least one side of the power terminal of the battery module 188, and the N number of battery cells 192 provided in the battery module 188. It may be electrically connected to a corresponding cell terminal.

According to the implementation method of the present invention, the balance management function of the BMS for the regenerative battery is a function of generating balance information including voltage values for each N battery cells 192 during charging of the battery module 188, the battery module A function of generating balance information including voltage values for each N battery cells 192 during discharge of 188, a function of transmitting the generated balance information through a designated communication unit, N during charging of the battery module 188 A function of analyzing balance information including voltage values for each battery cell 192 to determine whether a voltage difference during charging between the N battery cells 192 matches a preset effective voltage balance range during charging, the N batteries When the voltage difference during charging between the cells 192 does not match the preset effective voltage balance range during charging, the function of blocking the charging of the battery module 188, the voltage difference between the N battery cells 192 during charging A function of transmitting the balance warning information of the battery module 188 through a designated communication unit when it does not match the preset effective voltage balance range during charging, the voltage for each N battery cells 192 during discharging of the battery module 188 A function of analyzing balance information including values to determine whether a voltage difference during discharging between the N battery cells 192 matches a preset effective voltage balance range during discharging, and a voltage during discharging between the N battery cells 192 A function of blocking the discharge of the battery module 188 when the difference does not match the effective voltage balance range during discharging, and the voltage difference during discharging between the N battery cells 192 is within a preset effective voltage balance range during discharging may include at least one or two or more functions among functions of transmitting balance warning information of the battery module 188 through a designated communication unit when it does not match.

According to the embodiment of the present invention, the BMS for the regenerative battery includes a contact communication unit that communicates through a communication terminal among the terminal units of the case, a short-range wireless communication unit that communicates through a designated short-range wireless communication, and a wireless communication unit that communicates through a specified wireless network. It may include at least one communication unit among the network communication units, and the balance management function of the BMS for the regenerative battery may transmit balance information and/or balance warning information using the communication unit.

On the other hand, when the BMS for the regenerative battery is mounted on the battery module 188, the battery regeneration unit 176 (or the battery regenerator) inserts the battery module 188 inside the case corresponding to the designated regenerative battery application field. By mounting and electrically connecting the power terminal of the battery module 188 and the terminal portion of the case, a regenerated battery including the battery module 188 can be reproduced and manufactured. Preferably, at least one of the power terminals of the battery module 188 is electrically connected to the terminal of the case via the BMS for the regenerative battery.

2 is a diagram illustrating an optical balance test and a resistance test process for battery regeneration according to an embodiment of the present invention.

In more detail, FIG. 2 shows that when a battery module 188 including N battery cells 192 is prepared (or stocked) through a waste battery for a vehicle recovered after being used in an eco-friendly vehicle, the battery module 188 is A process of performing an optical balance test to determine whether at least one of breakage, expansion, and discoloration is included within a preset effective range and a resistance test to determine whether the resistance value of the battery module 188 matches a preset effective resistance range As shown in the figure, those of ordinary skill in the art to which the present invention pertains, refer to and/or modify this figure 2 to see various implementation methods for the process (eg, some steps are omitted or the order is changed) implementation method) can be inferred, but the present invention includes all of the inferred implementation methods, and the technical characteristics are not limited only to the implementation method illustrated in FIG. 2 .

Referring to FIG. 2 , when a battery module 188 including N battery cells 192 is prepared (or stocked) through a vehicle waste battery recovered after being used in an eco-friendly vehicle (200), the battery regeneration device 100 ) performs a specified procedure of the optical balance test to determine whether at least one of the damage, expansion, and discoloration of the battery module 188 is included within a preset effective range ( 205 ).

If the state of at least one of damage, expansion, and discoloration of the battery module 188 is out of a preset effective range, the battery reproducing apparatus 100 sets the battery module 188 to a resource recovery target battery module 188. can be determined (220).

On the other hand, when the state of at least one of damage, expansion, and discoloration of the battery module 188 matches the preset effective range, the battery reproducing apparatus 100 connects the power terminal of the battery module 188 to the module connection unit 180 ) and connect the cell terminal of the battery module 188 to the cell connection terminal of the cell connection unit 184 (210). Meanwhile, the terminal connection process may be performed at any time before the resistance test or the charging process is started.

The battery regeneration apparatus 100 measures the resistance value of the battery module 188 through the module connection unit 180 and performs a resistance test to determine whether it matches a preset effective resistance range ( 215 ).

If the measured resistance value is out of a preset effective resistance range, the battery reproducing apparatus 100 may determine the battery module 188 as the resource recovery target battery module 188 (220).

3 is a diagram illustrating a charging or charging balance inspection process of the battery module 188 for battery regeneration according to an embodiment of the present invention.

In more detail, FIG. 3 shows that while charging the battery module 188 to a specified maximum charging voltage, the charging voltage difference between the N battery cells 192 provided in the battery module 188 is in a preset charging voltage effective balance range. As an illustration of a process of performing a balance check to determine whether the present invention is matched, those skilled in the art to which the present invention pertains may refer to and/or modify this FIG. 3 to see various implementation methods for the process (eg, An implementation method in which some steps are omitted or the order is changed) may be inferred, but the present invention is made including all the implementation methods inferred above, and the technical characteristics are not limited only to the implementation method shown in FIG. 3 No.

3, the battery regeneration device 100 initializes the voltage difference between the N battery cells 192 through the cell connection unit 184 to within a preset initial voltage balance range (300), and the module connection unit ( 180), a procedure for charging the battery module 188 to a specified maximum charging voltage is performed (305).

On the other hand, the battery regeneration device 100 performs a procedure of charging the battery module 188 to a specified maximum charging voltage (305), and N provided in the battery module 188 through the cell connection unit 184 Check balance information including the charge voltage difference between the battery cells 192 (310), and determine whether the charge voltage difference between the N battery cells 192 included in the balance information matches a preset charge voltage effective balance range A balance check is performed (315).

If the charging voltage difference between the N battery cells 192 is out of a preset charging voltage effective balance range, the battery reproducing apparatus 100 determines the battery module 188 as the resource recovery target battery module 188. can (325).

On the other hand, when the charging voltage difference between the N battery cells 192 matches the preset charging voltage effective balance range, the battery reproducing apparatus 100 charges the battery module 188 to a specified maximum charging voltage. Confirm (320). If it fails to charge the battery module 188 to a specified maximum charging voltage, the battery reproducing apparatus 100 maintains a procedure for charging the battery module 188 to a specified maximum charging voltage and a procedure for checking the charge balance do.

4 is a diagram illustrating a discharge or discharge balance test and a residual ratio test process of the battery module 188 for battery regeneration according to an embodiment of the present invention.

In more detail, FIG. 4 shows that the discharge voltage difference between the N battery cells 192 provided in the battery module 188 is in a preset discharge voltage effective balance range while discharging the battery module 188 to a specified lowest discharge voltage. It shows a process of performing a balance check for determining whether matching and a residual ratio check for determining whether the remaining ratio of the battery module 188 matches a preset remaining ratio effective range, which is common knowledge in the technical field to which the present invention pertains. With reference to and/or modifying this figure 4, various implementation methods for the above process (eg, an implementation method in which some steps are omitted or the order is changed) will be inferred, but the present invention is based on the analogy It is made including all implementation methods that are used, and the technical characteristics are not limited only to the implementation method shown in FIG. 4 .

4, the battery regeneration device 100 initializes the voltage difference between the N battery cells 192 through the cell connection unit 184 to within a preset initial voltage balance range (400), and the module connection unit ( 180), a procedure for discharging the battery module 188 according to a specified current ratio up to a specified lowest discharge voltage is performed (405).

On the other hand, the battery regeneration device 100 performs a procedure of discharging the battery module 188 to a specified lowest discharge voltage (405), and N provided in the battery module 188 through the cell connection unit 184 Check balance information including the discharge voltage difference between the battery cells 192 (410), and determine whether the discharge voltage difference between the N battery cells 192 included in the balance information matches a preset discharge voltage effective balance range A balance check is performed (415).

If the discharge voltage difference between the N battery cells 192 is out of a preset discharge voltage effective balance range, the battery regeneration apparatus 100 determines the battery module 188 as the resource recovery target battery module 188. can (445).

On the other hand, when the discharge voltage difference between the N battery cells 192 matches a preset discharge voltage effective balance range, the battery reproducing apparatus 100 discharges the battery module 188 to a specified lowest discharge voltage. Confirm (440). If the battery module 188 fails to discharge to a specified lowest discharge voltage, the battery reproducing apparatus 100 maintains a procedure for discharging the battery module 188 to a specified lowest discharge voltage and a procedure for checking the discharge balance do.

If the battery module 188 is discharged to the specified lowest discharge voltage, the battery reproducing apparatus 100 checks the discharging time required for discharging the battery module 188 to the specified lowest discharge voltage (425) , after confirming the reference discharge time corresponding to the reciprocal of the current ratio (430), the battery module 188 based on the proportional relationship between the confirmed discharge time and the reference discharge time corresponding to the reciprocal of the current ratio. calculates a residual ratio of ( 435 ), and determines whether the calculated residual ratio matches a preset effective range of the residual ratio ( 440 ).

If the calculated remaining ratio is out of a preset effective remaining ratio range, the battery reproducing apparatus 100 may determine the battery module 188 as the resource recovery target battery module 188 (445).

Meanwhile, the process of FIG. 4 may be performed multiple times by matching various discharge conditions, and the present invention also includes such an embodiment within the scope of its rights.

5 is a diagram illustrating a process of charging and regenerating the battery module 188 according to an embodiment of the present invention.

In more detail, FIG. 5 shows a process of charging and regenerating the battery module 188 to a specified ratio range of a specified module rated voltage. 5, various implementation methods for the above process (eg, an implementation method in which some steps are omitted or the order is changed) may be inferred by referring and/or modifying 5, but the present invention includes all of the inferred implementation methods It is made, and the technical characteristics are not limited only to the implementation method shown in FIG. 5 .

5, the battery regeneration device 100 initializes the voltage difference between the N battery cells 192 through the cell connection unit 184 to within a preset initial voltage balance range (500), and the module connection unit ( 180), a procedure for regenerating the battery module 188 by charging up to a specified ratio range of the specified module rated voltage is performed (505).

On the other hand, the battery regenerating device 100 performs a procedure of charging and regenerating the battery module 188 up to a specified ratio range of the specified module rated voltage (505), and the battery module 188 through the cell connection unit 184 ), check the balance information including the difference in the regeneration voltage between the N battery cells 192 provided in (510), and the module regeneration voltage in which the difference in the regeneration voltage between the N battery cells 192 included in the balance information is preset A balance check is performed to determine whether it matches the valid balance range ( 515 ).

If the difference in the regeneration voltage between the N battery cells 192 is out of the preset module regeneration voltage effective balance range, the battery regeneration apparatus 100 converts the battery module 188 to the resource recovery target battery module 188. may be determined (525).

On the other hand, when the difference in the regeneration voltage between the N battery cells 192 matches the preset module regeneration voltage effective balance range, the battery regeneration apparatus 100 sets the voltage of the battery module 188 to the specified value of the module rated voltage. It is checked whether the ratio range is reached (520). If the voltage of the battery module 188 does not reach the specified ratio range of the specified module rated voltage, the battery regeneration device 100 allows the voltage of the battery module 188 to reach the specified ratio range of the specified module rated voltage. Maintain charging and regenerating procedures and checking module regeneration balance.

6 is a diagram illustrating a process of charging the battery cell 192 to regenerate the battery module 188 and mounting the BMS for the regenerated battery according to the embodiment of the present invention.

In more detail, FIG. 6 shows the N battery cells provided in the battery module 188 when the voltage of the battery module 188 is charged up to a specified ratio range of the specified module rated voltage through the process of FIG. 5 and reproduced. As showing the process of regenerating the battery module 188 by charging 192 to the rated voltage for each designated cell, those of ordinary skill in the art to which the present invention pertains, refer to FIG. 6 and/or Various implementation methods for the above process (eg, an implementation method in which some steps are omitted or the order is changed) may be inferred by modification, but the present invention is made including all the inferred implementation methods, and in Fig. 6 The technical characteristics are not limited only to the implementation method shown in .

Referring to FIG. 6 , the battery regeneration apparatus 100 initializes the voltage difference between the N battery cells 192 to be within a preset cell regeneration voltage effective balance range through the cell connection unit 184 ( 600 ), and the cell A procedure of regenerating the N battery cells 192 through the connection unit 184 is charged up to the rated voltage for each designated cell ( 605 ).

On the other hand, the battery regeneration apparatus 100 performs a procedure of charging and regenerating the N battery cells 192 to a rated voltage for each cell specified (605), and the N battery cells ( 192) check balance information including the difference in the regeneration voltage between them (610), and determine whether the difference in the regeneration voltage between the N battery cells 192 included in the balance information matches a preset cell regeneration voltage effective balance range A check is performed (615).

If the difference in the regeneration voltage between the N battery cells 192 is out of a preset cell regeneration voltage effective balance range, the battery regeneration apparatus 100 converts the battery module 188 to the resource recovery target battery module 188. A determination may be made (625).

On the other hand, when the difference in the regeneration voltage between the N battery cells 192 matches the preset cell regeneration voltage effective balance range, the battery regeneration apparatus 100 sets the voltage for each of the N battery cells 192 to the designated cell rating. It is checked whether the battery module 188 is regenerated after being charged to the voltage ( 620 ). If the voltage of each of the N battery cells 192 is not charged and regenerated up to the rated voltage of each specified cell, the battery playback apparatus 100 charges the voltage of each of the N battery cells 192 to the rated voltage of each specified cell. to maintain the regeneration procedure and the process of checking cell regeneration balance.

On the other hand, when the voltage for each of the N battery cells 192 is charged and regenerated up to the rated voltage for each designated cell, the battery reproducing apparatus 100 is stored in the battery module 188 including the regenerated N number of battery cells 192. By mounting the BMS for the regeneration battery, the battery is regenerated (630). According to the implementation method of the present invention, the balance management function of the BMS for the regenerative battery is a function of generating balance information including voltage values for each N battery cells 192 during charging of the battery module 188, the battery module A function of generating balance information including voltage values for each N battery cells 192 during discharge of 188, a function of transmitting the generated balance information through a designated communication unit, N during charging of the battery module 188 A function of analyzing balance information including voltage values for each battery cell 192 to determine whether a voltage difference during charging between the N battery cells 192 matches a preset effective voltage balance range during charging, the N batteries When the voltage difference during charging between the cells 192 does not match the preset effective voltage balance range during charging, the function of blocking the charging of the battery module 188, the voltage difference between the N battery cells 192 during charging A function of transmitting the balance warning information of the battery module 188 through a designated communication unit when it does not match the preset effective voltage balance range during charging, the voltage for each N battery cells 192 during discharging of the battery module 188 A function of analyzing balance information including values to determine whether a voltage difference during discharging between the N battery cells 192 matches a preset effective voltage balance range during discharging, and a voltage during discharging between the N battery cells 192 A function of blocking the discharge of the battery module 188 when the difference does not match the effective voltage balance range during discharging, and the voltage difference during discharging between the N battery cells 192 is within a preset effective voltage balance range during discharging may include at least one or two or more functions among functions of transmitting balance warning information of the battery module 188 through a designated communication unit when it does not match.

100: battery regeneration device 104: control module
108: information management unit 112: optical inspection unit
116: resistance test unit 120: module charging unit
124: charge balance check unit 128: charge balance check unit
132: module discharge unit 136: discharge balance check unit
140: discharge balance inspection unit 144: residual ratio calculation unit
148: residual ratio inspection unit 152: module regeneration unit
156: module regeneration balance check unit 160: module regeneration balance check unit
164: cell regeneration unit 168: module regeneration balance check unit
172: cell regeneration balance checking unit 176: battery regeneration unit
180: module connection unit 184: cell connection unit
188: battery module 192: battery cell

Claims (61)

In the method performed through a battery regeneration device for regenerating a vehicle waste battery recovered after being used in an eco-friendly vehicle,
A first step of preparing a battery module of a waste battery including N (N≥2) battery cells;
a second step of performing an internal resistance test of the battery module;
a third step of charging the battery module to a specified maximum charging voltage;
a fourth step of discharging the charged battery module to a specified lowest discharge voltage; and
A battery module regeneration method comprising a; a fifth step of charging and regenerating the N battery cells included in the battery module to a specified rated voltage.
According to claim 1, wherein the battery module,
A battery module regeneration method, comprising a state in which a battery management system (BMS) of a battery manufacturer and a vehicle case are separated from the waste battery.
According to claim 1, wherein the first step,
The method for regenerating a battery module, characterized in that it further comprises the step of performing a specified procedure of the optical balance test to determine whether at least one of the state of damage, expansion, and discoloration of the battery module is included in a preset effective range.
According to claim 3, wherein the first step,
The battery module regeneration method, characterized in that it further comprises the step of sensing at least one of damage, expansion, and discoloration of the battery module through a camera unit or an optical sensor unit.
According to claim 3, wherein the first step,
The battery module regeneration method, characterized in that it further comprises the step of receiving the inspection result visually inspected by the inspector through the input unit or the inspection result measured and inspected through the measuring instrument.
According to claim 3, wherein the first step,
and determining the battery module as a resource recovery target battery module when at least one of damage, expansion, and discoloration of the battery module is out of a preset effective range.
According to claim 1, wherein the first step,
Connecting the power terminal of the battery module to the module connection terminal of the battery regeneration device,
and connecting cell terminals corresponding to N battery cells provided in the battery module to cell connection terminals of the battery reproducing apparatus.
According to claim 1, wherein the second step,
Regeneration of a battery module comprising the step of measuring the resistance value of the battery module through a module connection terminal connected to the power terminal of the battery module and performing a resistance test to determine whether it matches a preset effective resistance range Way.
The method of claim 8, wherein the second step comprises:
and determining the battery module as a resource recovery target battery module when the measured resistance value is out of a preset effective resistance range.
According to claim 1, wherein the third step,
and charging the battery module to a specified maximum charging voltage through a module connection terminal connected to the power terminal of the battery module.
11. The method of claim 10, wherein the third step,
The battery characterized in that it further comprises the step of initializing the voltage difference between the N battery cells to within a preset initial voltage balance range through a cell connection terminal connected to the cell terminal of the battery module before charging the battery module. How to play the module.
11. The method of claim 10, wherein the third step,
and charging the battery module according to a specified current ratio through the module connection terminal.
13. The method of claim 12, wherein the third step comprises:
and charging the battery module at a current ratio of 0.5C (C-rate) through the module connection terminal.
According to claim 10 or 12, wherein the third step,
and charging by applying a specified constant voltage to the battery module through the module connection terminal.
According to claim 10 or 12, wherein the third step,
and charging by applying a voltage pattern that is changed within a specified voltage range to the battery module through the module connection terminal.
According to claim 10 or 12, wherein the third step,
and charging by applying a constant current matching a specified current ratio to the battery module through the module connection terminal.
According to claim 10 or 12, wherein the third step,
and charging by applying a current pattern that is changed within a specified current ratio range to the battery module through the module connection terminal.
11. The method of claim 10, wherein the third step,
When charging the battery module,
a step 3a of checking balance information including a difference in charging voltage between N battery cells provided in the battery module through a cell connection terminal connected to a cell terminal of the battery module; and
and a (3b) step of performing a balance check for determining whether a difference in charging voltage between the N battery cells included in the balance information matches a preset effective balance range of a charging voltage.
19. The method of claim 18,
The step 3a includes checking balance information including a charging voltage difference during charging between N battery cells provided in the battery module through the cell connection terminal while charging the battery module,
The step 3b may include performing a balance test to determine whether a difference in charging voltage during charging between the N battery cells included in the balance information matches a preset charging voltage effective balance range. How to play the module.
The method of claim 19, wherein the step 3b comprises:
and determining the battery module as a resource recovery target battery module when the charging voltage difference during charging between the N battery cells is out of a preset charging voltage effective balance range.
19. The method of claim 18,
The step 3a includes, when the battery module is charged to a specified maximum charging voltage, checking balance information including a maximum charging voltage difference between N battery cells provided in the battery module through the cell connection terminal do,
The step 3b may include performing a balance check to determine whether the maximum charging voltage difference between the N battery cells included in the balance information matches a preset charging voltage effective balance range. How to play.
The method of claim 21, wherein the step 3b comprises:
and determining the battery module as a resource recovery target battery module when the maximum charging voltage difference between the N battery cells is out of a preset charging voltage effective balance range.
According to claim 1, wherein the fourth step,
and discharging the battery module to a specified minimum discharge voltage through a module connection terminal connected to a power terminal of the battery module.
The method of claim 23, wherein the fourth step comprises:
and initializing the voltage difference between the N battery cells to within a preset initial voltage balance range through a cell connection terminal connected to a cell terminal of the battery module before discharging the battery module. How to play.
The method of claim 23, wherein the fourth step comprises:
and discharging the battery module according to a specified current ratio through the module connection terminal.
The method of claim 25, wherein the fourth step comprises:
and discharging the battery module at a current ratio of 0.5C (C-rate) through the module connection terminal.
The method of claim 23 or 25, wherein the fourth step comprises:
and discharging the battery module according to a specified constant voltage through the module connection terminal.
The method of claim 23 or 25, wherein the fourth step comprises:
and discharging the battery module according to a voltage pattern changed within a specified voltage range through the module connection terminal.
The method of claim 23 or 25, wherein the fourth step comprises:
and discharging the battery module according to a constant current matching a specified current ratio through the module connection terminal.
The method of claim 23 or 25, wherein the fourth step comprises:
and discharging the battery module according to a current pattern that is changed within a current ratio range specified through the module connection terminal.
The method of claim 23, wherein the fourth step comprises:
When discharging the battery module,
a step 4a of checking balance information including a difference in discharge voltage between N battery cells provided in the battery module through a cell connection terminal connected to a cell terminal of the battery module; and
and a (4b) step of performing a balance check for determining whether a discharge voltage difference between the N battery cells included in the balance information matches a preset discharge voltage effective balance range.
32. The method of claim 31,
The step 4a includes checking balance information including a discharge voltage difference during discharging between N battery cells provided in the battery module through the cell connection terminal while discharging the battery module,
The step 4b includes performing a balance check to determine whether a discharge voltage difference during discharge between the N battery cells included in the balance information matches a preset discharge voltage effective balance range. How to play the module.
33. The method of claim 32, wherein the step 4b comprises:
and determining the battery module as a resource recovery target battery module when the discharge voltage difference during discharging among the N battery cells is out of a preset discharge voltage effective balance range.
32. The method of claim 31,
The step 4a includes, when the battery module is discharged to a specified minimum discharge voltage, checking balance information including a minimum discharge voltage difference between N battery cells provided in the battery module through the cell connection terminal do,
The step 4b may include performing a balance check to determine whether a minimum discharge voltage difference between the N battery cells included in the balance information matches a preset discharge voltage effective balance range. How to play.
The method of claim 34, wherein the step 4b comprises:
and determining the battery module as a resource recovery target battery module when the minimum discharge voltage difference between the N battery cells is out of a preset discharge voltage effective balance range.
The method of claim 25, wherein the fourth step comprises:
When the battery module is discharged to a specified minimum discharge voltage, a discharge time required for discharging the battery module to a specified minimum discharge voltage is checked, and a reference discharge corresponding to the reciprocal of the checked discharge time and the current ratio The method for regenerating a battery module, characterized in that it further comprises the step of calculating the remaining ratio of the battery module based on the proportional relationship between time.
37. The method of claim 36, wherein the fourth step comprises:
and determining whether the calculated remaining ratio matches a preset remaining ratio effective range.
38. The method of claim 37, wherein the fourth step comprises:
and determining the battery module as a resource recovery target battery module when the calculated remaining ratio is out of a preset effective remaining ratio range.
The method of claim 1,
a step 5-1 of charging and regenerating the battery module up to a specified ratio range of a specified module rated voltage through a module connection terminal connected to the power terminal of the battery module; and
When the voltage of the battery module reaches a specified ratio range of the specified module rated voltage, the N battery cells are simultaneously charged and regenerated to the rated voltage of each specified cell through the cell connection terminal connected to the cell terminal of the battery module. Step 5-2; battery module regeneration method comprising the.
40. The method of claim 39, wherein the step 5-1,
and charging the battery module according to a specified current ratio through a module connection terminal.
41. The method of claim 40, wherein the step 5-1,
and charging the battery module at a current ratio of 0.5C (C-rate) through a module connection terminal.
41. The method of claim 39 or 40, wherein the step 5-1,
and charging by applying a specified constant voltage to the battery module through a module connection terminal.
41. The method of claim 39 or 40, wherein the step 5-1,
and charging the battery module by applying a constant current matching a specified current ratio to the battery module through a module connection terminal.
40. The method of claim 39, wherein the step 5-1,
When playing the battery module,
a step 5-1a of checking balance information including a difference in reproduction voltage between N battery cells provided in the battery module through a cell connection terminal; and
a step 5-1b of performing a balance check to determine whether a difference in the regeneration voltage between the N battery cells included in the balance information matches a preset module regeneration voltage effective balance range; Way.
45. The method of claim 44,
The step 5-1a includes a difference in regeneration voltage during module regeneration between N battery cells provided in the battery module through a cell connection terminal while the battery module is charged and reproduced up to a specified ratio range of the specified module rated voltage Including the step of checking the balance information to
The step 5-1b includes performing a balance check to determine whether a difference in reproduction voltage during module reproduction between the N battery cells included in the balance information matches a preset module reproduction voltage effective balance range Battery module regeneration method characterized in that.
46. The method of claim 45, wherein the step 5-1b,
Regeneration of a battery module, characterized in that it further comprises the step of determining the battery module as a resource recovery target battery module when the difference in the regeneration voltage is out of a preset module regeneration voltage effective balance range during module regeneration between the N battery cells. Way.
40. The method of claim 39, wherein the step 5-2,
When the voltage of the battery module reaches a specified ratio range of the specified module rated voltage, the method further comprising the step of initializing the voltage difference between the N battery cells through a cell connection terminal to within a preset cell regeneration voltage effective balance range Battery module regeneration method characterized in that.
40. The method of claim 39, wherein the step 5-2,
and charging the N battery cells at the same time according to a specified current ratio through the cell connection terminal.
49. The method of claim 48, wherein the step 5-2,
and charging the N battery cells simultaneously at a current ratio of 0.5C (C-rate) through the cell connection terminal.
49. The method of claim 39 or 48, wherein the step 5-2,
and charging by simultaneously applying a specified constant voltage to the N battery cells through the cell connection terminals.
49. The method of claim 39 or 48, wherein the step 5-2,
and charging by simultaneously applying a constant current matching a specified current ratio to the N battery cells through the cell connection terminal.
40. The method of claim 39, wherein the step 5-2,
The cell regeneration power applied to the N battery cells as the cell regeneration voltage reproduced for each of the N battery cells approaches the rated voltage for each designated cell while simultaneously charging and regenerating the N battery cells through the cell connection terminal. Regenerating a battery module, characterized in that it comprises the step of reducing the amount of current according to a specified reduction pattern to a specified fine current range and regenerating the fine balancing.
40. The method of claim 39, wherein the step 5-2,
When the N battery cells are regenerated,
a step 5-2a of checking balance information including a difference in reproduction voltage between N battery cells provided in the battery module through the cell connection terminal; and
a step 5-2b of performing a balance check to determine whether a difference in reproduction voltage between the N battery cells included in the balance information matches a preset cell reproduction voltage effective balance range; Way.
54. The method of claim 53,
The step 5-2a includes checking balance information including a cell regeneration voltage difference between the N battery cells provided in the battery module through the cell connection terminal while the N battery cells are being reproduced, ,
The step 5-2b may include performing a balance check to determine whether a cell regeneration voltage difference between the N battery cells included in the balance information matches a preset cell regeneration voltage effective balance range. How to regenerate the battery module.
55. The method of claim 54, wherein the step 5-2b,
and determining the battery module as a resource recovery target battery module when the cell regeneration voltage difference between the N battery cells is out of a preset cell regeneration voltage effective balance range.
55. The method of claim 54, wherein the cell regeneration voltage effective balance range is:
The battery module regeneration method, characterized in that it comprises a fine voltage balance range less than a specified ratio than the module regeneration voltage effective balance range related to the regeneration of the battery module through the module connection unit.
57. The method of claim 56, wherein the cell regeneration voltage effective balance range is:
When the process of regenerating the N battery cells is started, the cell regeneration voltage that matches the effective balance range of the module regeneration voltage related to the regeneration of the battery module and is reproduced for each of the N battery cells approaches the rated voltage of each designated cell. Battery module regeneration method, characterized in that it comprises a balance range that is reduced to a specified fine voltage balance range according to the reduction pattern.
The method of claim 1,
The battery module regeneration method, characterized in that it further comprises the step of mounting a BMS for a regenerative battery having a balance management function on the regenerated battery module.
59. The method of claim 58, wherein the BMS for the regenerative battery,
The battery module regeneration method, characterized in that electrically connected to at least one side of the power terminal of the battery module, and electrically connected to cell terminals corresponding to the N battery cells provided in the battery module.
59. The method of claim 58, wherein the balance management function,
A function of generating balance information including voltage values for each N battery cells during charging of the battery module;
A function of generating balance information including voltage values for each N battery cells during discharging of the battery module;
A function of transmitting the generated balance information through a designated communication unit,
A function of analyzing balance information including voltage values for each N battery cells during charging of the battery module to determine whether a voltage difference between the N battery cells during charging matches a preset effective voltage balance range during charging;
a function of blocking charging of the battery module when the voltage difference during charging between the N battery cells does not match a preset effective voltage balance range during charging;
When the voltage difference during charging between the N battery cells does not match a preset effective voltage balance range during charging, a function of transmitting balance warning information of the battery module through a designated communication unit;
A function of analyzing balance information including voltage values for each N battery cells during discharging of the battery module to determine whether a voltage difference during discharging between the N battery cells matches a preset effective voltage balance range during discharging;
A function of blocking the discharging of the battery module when the voltage difference during discharging between the N battery cells does not match a preset effective voltage balance range during discharging;
When the voltage difference during discharging between the N battery cells does not match the effective voltage balance range during discharging, at least one or more functions of transmitting balance warning information of the battery module through a designated communication unit. Battery module regeneration method, characterized in that.
61. The method of claim 60, wherein the BMS for the regenerative battery,
A contact-type communication unit that communicates through a communication terminal among the terminal units of the case;
A short-distance wireless communication unit communicating through a designated short-distance wireless communication;
Battery module regeneration method, characterized in that it comprises at least one communication unit among the wireless network communication unit that communicates through a designated wireless network.

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