KR20230016797A - Methed for managing life of battery pack using temperature sensor - Google Patents

Abstract

The purpose of the present invention is to provide a method for managing the life of a battery pack which calculates the i^th charge/discharge cycle number for discharge after the i^th charge by checking the i^th charge amount and i^th discharge amount of the battery pack, and updates effective charge/discharge cycle number information corresponding to the remaining life of the battery pack by subtracting the i^th charge/discharge cycle number calculated from the effective charge/discharge cycle number information of the battery pack stored in a management DB such that when the battery pack is recovered and regenerated after being used in an eco-friendly vehicle or when the battery pack is used in an application field other than an intended purpose, the lifespan of the battery pack can be predicted through condition management and the battery pack capable of guaranteeing safety can be provided by eliminating the risk of fire or explosion which may occur in the future therethrough, wherein i is greater than or equal to 1. The present invention as described above has the advantage of predicting the lifespan of the battery pack through condition management when the battery pack is recovered and recycled after being used in the eco-friendly vehicle or when the battery pack is used in the application field other than the intended purpose and has the advantage of providing the battery pack capable of guaranteeing safety by eliminating the risk of fire or explosion which may occur in the future therethrough.

Description

Battery pack life management method using temperature sensor {METHED FOR MANAGING LIFE OF BATTERY PACK USING TEMPERATURE SENSOR}

The present invention relates to a method for managing the lifespan of a battery pack.

Recently, eco-friendly vehicles such as electric vehicles and hydrogen vehicles are gradually becoming popular, and considering the replacement cycle of these eco-friendly vehicles, it is predicted that about 10,000 electric vehicles will collect waste batteries for vehicles annually in 2024, and by 2031 In 2018, it is predicted that about 100,000 electric vehicles will collect waste batteries for vehicles each year (Refer to the study on the recycling method and standards for electric vehicle waste batteries (Ministry of Environment, 2018. 10)).

However, in the case of a vehicle battery mounted on an eco-friendly vehicle, the battery manufacturer tests and guarantees the safety of the vehicle battery for a certain period of time (or a certain mileage) after manufacturing, but after such a vehicle battery is recovered from an eco-friendly vehicle and regenerated and/or Or, when the vehicle battery is used in applications other than eco-friendly vehicles (e.g., use other than intended use), there is no basis for guaranteeing the safety of the vehicle battery, and there is a risk of fire or explosion at any time. has a problem with

Accordingly, in the case of regenerating and using waste batteries for vehicles recovered after being used in eco-friendly vehicles and/or using vehicle batteries used in applications other than eco-friendly vehicles, accurate charge/discharge information of the vehicle batteries must be secured. The method proposed up to has a problem in that it is difficult to easily check the charge/discharge information in the vehicle battery.

Korean Registered Patent No. 10-0897062 (registered on May 4, 2009)

Accordingly, the present invention has been made from the foregoing background, and the ith (i≥1)th charge amount and the ith discharge amount of a battery pack are checked, and the ithth charge/discharge cycle number for discharge after the ith charge is determined. and by subtracting the i-th charge/discharge cycle number calculated from information on the number of effective charge/discharge cycles of the battery pack stored in the management DB to update the information on the number of effective charge/discharge cycles corresponding to the remaining life of the battery pack. When used in an eco-friendly vehicle and then recovered and recycled, or when used in an application field other than the designated purpose, the lifespan of the battery pack can be predicted through condition management, and through this, the risk of fire or explosion that may occur later can be predicted in advance. An object of the present invention is to provide a battery pack lifespan management method capable of providing a battery pack capable of ensuring safety by removing the present invention.

The object of the present invention is not limited thereto, and other objects not mentioned will be clearly understood by those skilled in the art from the description below.

In order to achieve this object, one embodiment of the present invention is a method executed through a management module and an operation server of a battery pack, wherein the operation server is applied to each battery module separated from a vehicle battery pack used in an eco-friendly vehicle. Unique identification information given to the regenerated battery pack including M (M ≥ 1) battery modules including battery cells of the same quality after a predetermined quality test on the provided n (n ≥ 2) battery cells and the above A first step of linking and storing information on the number of effective charge/discharge cycles corresponding to the lifespan of the battery pack determined based on the quality inspection in a designated management DB; The voltage value of the battery pack, through which the management module of the battery pack can check the amount of charge and discharge of the battery pack, and N values of the N (N≥n, N=M*n) number of battery cells provided in the battery pack. Voltage values for each battery cell, T temperature values sensed through T (T≥1) temperature sensors provided at designated locations of the battery pack, battery pack charging state using the power terminal of the battery pack, battery pack A second step of constructing state information including a battery pack state value identifying at least one state of a discharge state and a battery pack terminal open state and transmitting the procedure to an operation server through a communication module of the battery pack; A third step of receiving, by the operation server, status information transmitted through a management module of a designated battery pack and accumulatively storing it in a designated management DB; The operation server reads the state information of the designated battery pack stored in the management DB, confirms the i-th charge amount corresponding to the ith (i≥1)-th charge of the battery pack, and after the i-th charge, the ith-th charge a fourth step of checking an i-th discharge amount corresponding to the discharge; When the ith-th charge amount and the ith-th discharge amount are confirmed, the operation server conducts the ith-th charge/discharge for discharge after the ith-th charge using the difference between the ith-th charge amount and the ith-th discharge amount. a fifth step of calculating the number of cycles; and the operation server subtracts the calculated i-th charge/discharge cycle number from information on the number of effective charge/discharge cycles of the battery pack stored in the management DB to obtain information on the number of valid charge/discharge cycles corresponding to the remaining life of the battery pack. A sixth step of updating; provides a battery pack life management method using a temperature sensor, characterized in that it includes.

In addition, the charge/discharge cycle includes a cycle in which a state in which the battery pack is fully charged up to a set full charge amount and then completely discharged up to a set full discharge amount in the battery pack is set as one cycle. A method for managing the lifespan of a battery pack using the present invention is provided.

In addition, the quality inspection includes an optical inspection for determining whether at least one of damage, swelling, and discoloration of the battery module is within a predetermined effective range. to provide.

In addition, in the quality inspection, the temperature value sensed through at least one temperature sensor provided in the battery module while charging the battery module to the fully charged voltage according to the specification through the power terminal of the battery module is within a preset effective range. It provides a battery pack life management method using a temperature sensor, characterized in that it includes a temperature inspection for determining whether the

In addition, in the quality inspection, the temperature value sensed through at least one temperature sensor provided in the battery module while discharging the battery module to the full discharge voltage according to the specification through the power terminal of the battery module is within a preset effective range. It provides a battery pack life management method using a temperature sensor, characterized in that it includes a temperature inspection for determining whether the

In addition, the battery pack management module determines whether the state of the battery pack is switched from a battery pack charging state or a battery pack terminal open state to a battery pack discharging state, and when the state is switched to the battery pack discharging state, the battery pack Provided is a battery pack life management method using a temperature sensor, characterized in that state information corresponding to the pack discharge state is configured and transmitted to the operation server.

In addition, the battery pack management module determines whether the state of the battery pack is switched from a battery pack discharge state or a battery pack terminal open state to a battery pack charge state, and when the state is converted to the battery pack charge state, the battery pack Provided is a battery pack life management method using a temperature sensor, characterized in that state information corresponding to the charge state of the pack is configured and transmitted to the operation server.

In addition, the operation server reads T temperature values included in at least one state information corresponding to a recent period among a plurality of state information accumulated and stored in the management DB for the battery pack to determine a predetermined effective temperature range. It provides a battery pack life management method using a temperature sensor, further comprising: checking a temperature-related abnormal state corresponding to at least one deviating temperature value.

According to an embodiment of the present invention, the ith (i≥1)th charge amount and the ith discharge amount of the battery pack are checked to calculate the ithth charge/discharge cycle number for discharge after the ithth charge; By subtracting the i-th charge/discharge cycle number calculated from the number of effective charge/discharge cycles of the battery pack stored in the management DB, the number of effective charge/discharge cycles corresponding to the remaining life of the battery pack is updated, so that the battery pack is an eco-friendly vehicle. The advantage of being able to predict the lifespan of a battery pack through state management when it is used for recovery and regeneration or when it is used for applications other than the designated purpose, and through this, the risk of fire or explosion that may occur later is eliminated in advance. Thus, there is an advantage in providing a battery pack capable of ensuring safety.

1 is a diagram showing the configuration of a system for managing the lifespan of a battery pack according to an embodiment of the present invention.
2 is a diagram illustrating a process of checking the amount of charge and discharge of a battery pack through state information received from the battery pack according to the method of the present invention.
3 is a diagram illustrating a process of calculating the number of charge/discharge cycles of a battery pack and updating information on the number of effective charge/discharge cycles corresponding to the remaining service life according to the method of the present invention.

Hereinafter, the operating principle 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 description below relate to preferred implementation methods among various methods for effectively explaining the features of the present invention, and the present invention is not limited to only the drawings and description below.

That is, the following embodiments correspond to examples of a preferred combination form among numerous embodiments of the present invention, and examples in which specific configurations (or steps) are omitted in the following embodiments, or specific configurations (or steps) Embodiments in which implemented functions are divided into specific components (or steps), or embodiments in which functions implemented in two or more components (or steps) are integrated into any one component (or steps), and specific configurations (or steps) It is clearly stated that the embodiments in which the operation sequence is replaced are all within the scope of the present invention, even if not separately mentioned in the following embodiments. Therefore, it is clearly stated that various examples corresponding to subsets or complements 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 known function or configuration may unnecessarily obscure the subject matter of the present invention, the detailed description will be omitted. In addition, 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 a user or operator. Therefore, the definition should be made based on the contents throughout the present invention.

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

Figure 1 is a diagram showing the configuration of a system for managing the lifespan of a battery pack according to an embodiment of the present invention.

In more detail, this drawing 1 shows after a predetermined quality test for n (n≥2) battery cells 140 provided in each battery module 135 separated from a vehicle battery pack 130 used in an eco-friendly vehicle. After the unique identification information assigned to the regenerated battery pack 130 and information on the number of effective charge/discharge cycles corresponding to the lifespan of the battery pack 130 determined based on the quality inspection are linked and stored in a designated management DB, the battery pack The voltage value of the battery pack 130 capable of checking the amount of charge and discharge of the battery pack 130 received from the management module 170 in (130) and N (N≥n, State information including voltage values for each of the N battery cells for the N=M*n battery cells 140 is read, and the ith (i≥1)th charge amount and the ith order of the battery pack 130 are read. The i-th charge/discharge cycle number for discharging after the i-th charge is checked by checking the discharge amount, and the calculated i-th charge/discharge cycle number of the battery pack 130 is stored in the management DB. It relates to a system for updating effective charge/discharge cycle number information corresponding to the remaining life of the battery pack 130 by subtracting the number of charge/discharge cycles. Various implementation methods for the configuration of the system (eg, implementation methods in which some components are omitted, subdivided, or combined) may be inferred by referring to and/or modifying FIG. It is made including an implementation method, and its technical characteristics are not limited only to the implementation method shown in FIG. 1.

Referring to Figure 1, the system of the present invention, a predetermined quality of n (n≥2) battery cells 140 provided in each battery module 135 separated from a vehicle battery pack used in an eco-friendly vehicle. After inspection, M (M≥1) number of battery modules 135 including battery cells 140 of equal quality are reproduced, and the voltage value of the battery pack 130 and the battery pack 130 capable of checking the amount of charge and discharge and the battery pack The communication module of the battery pack 130 ( 195), the battery pack 130 transmitted to the operation server 100, and the lifespan of the battery pack 130 determined based on the unique identification information assigned to the battery pack 130 and the quality inspection corresponding to After storing information on the number of effective charge and discharge cycles in connection with a designated management DB, the amount of charge and discharge of the battery pack 130 received from the management module 170 of the battery pack 130 can be checked. State information including voltage values and voltage values for each of the N battery cells of the N (N≥n, N=M*n) battery cells 140 provided in the battery pack 130 is read, The ith (i≥1)th charge amount and the ith discharge amount of the pack 130 are checked, the ithth charge/discharge cycle number for the discharge after the ith charge is calculated, and the battery stored in the management DB. An operation server configured to subtract the calculated i-th charge/discharge cycle number from the effective charge/discharge cycle count information of the pack 130 to update the effective charge/discharge cycle count information corresponding to the remaining life of the battery pack 130 ( 100) may be configured.

The battery pack 130 includes M (M ≥ 1) number of battery modules 135 having N (N ≥ 2) number of battery cells 140, and each battery module 135 has N number of It may include M number of battery module management modules 155 connected to the battery cell 140 to measure the voltage value of each N number of battery cells 140, and + for charging or discharging the battery pack 130. /- It is connected to at least one power terminal of the pack power terminal 165 and is communicatively connected to the M number of battery module management modules 155 to collect voltage values for each (M * N) number of battery cells 140 and The management module 170 that calculates the voltage value of the battery pack 130 using the collected voltage values for each (M*N) number of battery cells 140 may be hierarchically provided.

According to the implementation method of the present invention, the battery pack 130 may include a regenerated battery pack that is regenerated after a predetermined quality test for each battery module by separating a battery module from a vehicle battery pack used in an eco-friendly vehicle. For example, in the case of the battery pack 130 of the present invention, it does not necessarily have to be a regenerated battery pack, but when it includes a regenerated battery pack, the unbalance of the voltage value for each N battery cell is higher than that of a new battery pack just shipped from the factory. Since the probability of occurrence is inevitably high, it is necessary to monitor the unbalance of the voltage values of each N number of battery cells.

In addition, according to the embodiment of the present invention, when the battery pack 130 includes a plurality of battery modules, after a predetermined quality test on the battery modules separated from the vehicle battery pack, battery modules of the same quality are combined and reproduced. Renewable battery packs may be included.

The battery module 135 may include N battery cells 140 connected in a designated cell connection structure, and may include a frame 155 for arranging and fixing the N battery cells 140 in a designated arrangement structure. Meanwhile, the battery module 135 may include N cell terminals 145 connected to the N battery cells 140, and a battery module having N battery cells 140 connected by a designated cell connection structure ( 135) may include a +/- module power supply terminal 150 for charging or discharging.

According to the implementation method of the present invention, the battery module 135 measures the voltage value of each n number of battery cells provided in the battery module 135 and provides it to the management module 170 of the battery pack, a management module for a battery module. (155) may be included.

The battery cell 130 is a minimum unit that charges power within a battery, and the battery module 135 includes a plurality (=N) of battery cells 140 . The N number of battery cells 140 may maintain a fixed arrangement in a designated arrangement structure through the frame 155 while being connected in a designated cell connection structure.

According to the implementation method of the present invention, the cell connection structure for connecting the N battery cells 140 includes a structure for connecting the N battery cells 140 in series, a structure for connecting the N battery cells 140 in parallel, and a structure for connecting the N battery cells 140 in parallel. A structure in which some of the battery cells 140 are connected in series and a combination of battery cells 140 connected in series is connected in parallel, some of the N battery cells 140 are connected in parallel, and a combination of battery cells 140 connected in parallel is connected in series. At least one of a structure, a structure in which some of the N battery cells 140 are connected in series and the other parts are connected in parallel, and a structure in which some of the N battery cells 140 are connected in parallel and the remaining parts are connected in series. can include

Meanwhile, according to the embodiment of the present invention, the battery module 135 may further include a ground terminal corresponding to the ground (GND) of the N cell terminals 120 .

The battery module management module 155 is connected to the N battery cells 140 provided in the battery module 135 through the N cell terminals 145 provided in the battery module 135, and the N It includes a cell voltage measurement function for measuring voltage values of each N number of battery cells 140 through the number of cell terminals 145, and the management module 170 of the battery pack includes the M number of battery module management modules 155 and It includes a cell voltage collection unit 175 that is communicatively connected and collects voltage values for each (M*N) number of battery cells 140 .

The cell voltage collection unit 175 collects voltage values for each of the N battery cells 140 for each designated period from the designated management module 155 for battery modules, so as to collect voltage values for each of the M battery module management modules 155 for a designated period. Voltage values for each (M*N) number of battery cells 140 may be collected. For example, the cell voltage collecting unit 175 is configured to perform N cycles of at least one of 1 second, 1.5 second, 2 second, 2.5 second, and 3 second intervals from the designated battery module management module 155, respectively. By collecting voltage values for each number of battery cells 140 , voltage values for each (M*N) number of battery cells 140 may be collected for each designated period from the management module 155 for M number of battery modules.

According to the embodiment of the present invention, in the case of including a plurality of battery modules 135, the module connection structure connecting the M number of battery modules 135 is a structure connecting the M number of battery modules 135 in series, the M number of battery modules 135 A structure for connecting battery modules 135 in parallel, a structure for connecting some of the M number of battery modules 135 in series and connecting a combination of series-connected battery modules 135 in parallel, a structure for connecting some of the M number of battery modules 135 in parallel A structure in which a combination of battery modules 135 connected in parallel is serially connected, a structure in which some of the M battery modules 135 are connected in series and the remaining parts are connected in parallel, some of the M battery modules 135 are connected in parallel, and the remaining It may include at least one structure among structures connecting parts in series.

According to the implementation method of the present invention, the battery module 135 may further include T number of temperature sensors 160 provided at designated locations. In this case, the battery module management module 155 is the battery module. 135 further includes a temperature measuring function for measuring T temperature values through T temperature sensors 160, and the management module 170 is connected to the M sub management modules 150 by communication ( The temperature collection unit 180 for collecting temperature values for each of the (M*T) number of sensors measured through the M*T) number of sensors is further included.

Here, the T number of temperature sensors 160 may include t (1≤t≤T) number of temperature sensors 160 for each battery module provided at a designated location of each battery module 130, and the t number of temperature sensors 160 The sensor 160 may include a battery cell 140 provided in each battery module 135 and a temperature sensor 160 provided between the battery cells 140 .

In addition, the T number of temperature sensors 160 may include a battery module 135 provided in the battery pack 130 and a temperature sensor 160 provided between the battery modules 135 .

In addition, the T number of temperature sensors 160 may include temperature sensors provided at positions within the battery pack where a temperature change may occur in a charged state or a discharged state of the battery pack.

The temperature collection unit 180 collects temperature values for each of the T sensors for each designated period from the designated battery module management module 150, and for each designated period from the M battery module management module 150 (M*T ) temperature values for each sensor can be collected. For example, the temperature collection unit 180 controls the temperature of each T sensor for each period of at least one of 1 second, 1.5 second, 2 second, 2.5 second, and 3 second units from the designated management module 150. By collecting the values, it is possible to collect temperature values for each (M*T) sensor for each designated period from the M management modules 150 for battery modules.

Meanwhile, the management module 170 is a voltage value of the battery pack 130 capable of checking the amount of charge and discharge of the battery pack 130 checked through the M number of battery modules 135 provided in the battery pack 130. and a state information configuring unit 185 configuring state information including voltage values for each of the N battery cells for the N (N≥n, N=M*n) battery cells provided in the battery pack 130. can include more.

According to the implementation method of the present invention, the state information may further include unique identification information of the battery pack 130 .

According to the implementation method of the present invention, the state information may further include at least one of a voltage value of the battery pack 130 and a current value of the battery pack. For example, the voltage value of the battery pack 130 and the current value of the battery pack 130 are not included in the data block, but may be included in a separate area.

According to the implementation method of the present invention, the state information further includes a battery pack state value identifying at least one of a battery pack charging state using the terminal of the battery pack 130, a battery pack discharging state, and a battery pack terminal open state. can include

According to the implementation method of the present invention, the state information configuration unit 185 checks whether the state of the battery pack 130 is switched from a battery pack charging state or a battery pack terminal open state to a battery pack discharging state, and When the state is converted to the pack discharge state, state information corresponding to the battery pack discharge state may be configured.

In addition, according to the embodiment of the present invention, the state information configuration unit 185 checks whether the state of the battery pack 130 is switched from a battery pack discharge state or a battery pack terminal open state to a battery pack charge state, When the state is switched to the battery pack charging state, state information corresponding to the battery pack charging state may be configured.

In addition, according to the implementation method of the present invention, the state information configuration unit 185 may configure the state information simultaneously with the state transition or within a certain period of time after the state transition.

Referring to Figure 1, the battery pack 130 can be connected to a designated communication network, and may include a communication module 195 for communicating with a designated operation server 100 via a designated communication path. Meanwhile, the management module 170 determines the amount of charge and discharge of the battery pack 130 and the voltage value of the battery pack 130 and N (N≥n, N=M) provided in the battery pack 130. * Includes a communication processing unit 190 that performs a procedure for transmitting the configured state information to a designated operation server 100 when state information including voltage values for each N battery cell for n) battery cells is configured can do.

According to the embodiment of the present invention, the management module 170 of the battery pack 130 checks whether the state of the battery pack 130 is switched from a battery pack charging state or a battery pack terminal open state to a battery pack discharging state. And, when the state is converted to the battery pack discharge state, a procedure of constructing state information corresponding to the battery pack discharge state and transmitting it to the operation server 100 through the communication module 195 may be performed.

In addition, according to the embodiment of the present invention, the management module 170 of the battery pack 130 converts the state of the battery pack 130 from a battery pack discharge state or a battery pack terminal open state to a battery pack charge state. and, when the state is converted to the battery pack charging state, a procedure of configuring and transmitting state information corresponding to the battery pack charging state through the communication module 195 may be performed. Here, the management module 170 of the battery pack 130 performs a procedure of configuring and transmitting the status information simultaneously with the state transition, or performing a procedure of configuring and transmitting the status information within a certain time after the state transition. can do.

Meanwhile, according to the implementation method of the present invention, the state information of the battery pack 130 may further include location information of the battery pack determined through a location positioning unit (not shown).

Here, the location positioning unit is provided in the communication module 195 of the battery pack 130, is provided in the management module 170 of the battery pack 130, or is provided in the management module 170 of the battery pack 130. Alternatively, it is possible to be provided in the form of a separate positioning module that interworks with the communication module 195. For example, the communication module 195 is LTE Cat. In the case of a communication module communicating through the M1 network, a GPS positioning function may be basically provided in the communication module.

The communication module 195 is a general term for a configuration that connects communication via a designated communication path between the management module 170 and the designated operation server 100, and is provided as an internal component of the management module 170 or And / or may be provided in the form of a separate module that works with the management module 170.

According to the first embodiment of the communication module 195, the communication module 195 is a wireless communication module 195 for communicating with the designated operation server 100 via a designated wireless communication network (eg, mobile communication network, etc.) can include In this case, the management module 170 may communicate with the operation server 100 via a wireless communication network designated through the wireless communication module 195 .

Meanwhile, according to the second embodiment of the communication module 195, the communication module 195 is a wired communication module 195 for communicating with a designated management server 195 via a designated wired communication network (eg, wired Internet, etc.) ) may be included. In this case, the management module 170 may communicate with the operation server 100 via a wired communication network designated through the wired communication module 195 .

Meanwhile, according to the third embodiment of the communication module 195, the communication module 195 is short-range for communicating with the designated operation server 100 via designated short-range wireless communication (eg, Wi-Fi, Bluetooth, ZigBee, etc.) A wireless communication module 195 may be included. In this case, the management module 170 passes through a designated communication network through designated short-range wireless communication (eg, via wired Internet through a wireless LAN between the Wi-Fi-based short-distance wireless communication module 195 and a Wi-Fi-based wireless AP, or Bluetooth Through Bluetooth communication between the based short-range wireless communication module 195 and a short-range Bluetooth-enabled device, it is possible to communicate with the management server 195 via a wireless communication network or a wireless communication network to which the Bluetooth-enabled device is connected.

Meanwhile, according to the fourth embodiment of the communication module 195, when a communication terminal for data communication is included in the battery pack terminal unit including the pack power supply terminal 165, the communication module 195 operates on the battery pack. Through a communication terminal included in the terminal unit, the device having the battery pack 130 may communicate with the operation server 100 via a wireless communication network or a wireless communication network connected thereto.

Meanwhile, according to the fifth embodiment of the communication module 195, the communication module 195 may be implemented in the form of at least partially combining at least two or more of the first to fourth embodiments, and the present invention It is clearly stated that these embodiments are also included in the scope of rights.

Referring to FIG. 1, the battery pack 130 includes a housing for housing a battery pack configuration including the M battery modules 135, M battery module management modules 150, and management modules 170. can include

The housing unit has a housing structure that can be mounted on a device equipped with or equipped with the battery pack 130 (e.g., a motorized mobile device using the power of the battery pack 130 as a power source and/or an energy storage system (ESS)) can include Meanwhile, the housing unit may further include a structure for discharging (or discharging) heat generated from the inside to the outside. Alternatively, the housing unit circulates air between the inside and outside of the battery pack 130 when the waterproof function of the battery pack 130 is not considered (eg, when the battery pack 130 is mounted in an ESS) It may further include a structure to do so.

Meanwhile, referring to FIG. 1, the operation server 100 determines an effective charge/discharge cycle corresponding to the lifespan of the battery pack 130 determined on the basis of unique identification information assigned to the regenerated battery pack 130 and quality inspection. An information management unit 105 that links and stores count information, an information storage unit 110 that receives and stores status information from the battery pack 130, and reads status information of a designated battery pack stored in the management DB to The information checking unit 115 that checks the ith-th charge amount and the ith-th discharge amount of the battery pack, and the difference between the ith-th charge amount and the ith-th discharge amount are used to determine the discharge after the ith charge. It may include an information calculation unit 120 that calculates the number of i-th charge/discharge cycles for the battery pack, and an information processor 125 that updates information on the number of effective charge/discharge cycles corresponding to the remaining life of the battery pack. On the other hand, the embodiment of this drawing 1 shows the operation server 100 as one server for convenience, but the embodiment implementing the operation server 100 is not limited thereto, and the operation server 100 has two It may be implemented in the form of a combination of the above servers or a server system, or may be implemented in the form of software mounted on a pre-built server, and the present invention includes all such embodiments.

The information management unit 105 performs a predetermined quality test on n (n≥2) battery cells 140 provided in each battery module 135 separated from a vehicle battery pack used in an eco-friendly vehicle, and then obtains the same quality. The battery pack 130 determined based on the unique identification information assigned to the regenerated battery pack 130 including M (M≥1) number of battery modules 135 including the battery cells 140 and the quality inspection Information on the number of effective charge/discharge cycles corresponding to the lifespan of may be linked and stored in a designated management DB.

According to the implementation method of the present invention, the quality inspection may include a quality inspection of n battery cells 140 provided in each battery module 135 . Here, the battery pack 130 may include the same quality as the N number of battery cells 140 .

In addition, according to the implementation method of the present invention, the quality inspection may include an optical inspection for determining whether at least one state of damage, swelling, and discoloration of the battery module 135 is within a predetermined effective range.

In addition, according to the implementation method of the present invention, the quality test is a resistance test for determining whether the resistance value of the battery module 135 is matched to a preset effective resistance range by measuring the resistance value of the battery module 135 through the power terminal of the battery module 135. can include

In addition, according to the implementation method of the present invention, the quality inspection is to determine whether the battery module 135 is matched to the effective charging range according to the specification while charging the battery module 135 to the full charge voltage according to the specification through the power terminal of the battery module 135. May include filling inspection.

On the other hand, according to the implementation method of the present invention, the quality inspection is performed while charging the battery module 135 through the power terminal of the battery module 135 according to a specified current ratio (C-rate) to a fully charged voltage according to the specification. A charging test may be performed to determine whether the battery is charged in a matched manner within an allowable range of the current ratio.

In addition, according to the implementation method of the present invention, the quality inspection is performed while charging the battery module 135 to a fully charged voltage according to the specification through the power terminal of the battery module 135, and the cell provided in the battery module 135 A balance test may be performed to determine whether a difference in voltage between battery cells included in the battery module 135 through a connection terminal is within a predetermined effective range.

In addition, according to the implementation method of the present invention, the quality inspection is performed while charging the battery module 135 to a fully charged voltage according to the specification through the power terminal of the battery module 135, and the cell provided in the battery module 135 A temperature test for determining whether a temperature value sensed through at least one temperature sensor provided in the battery module 135 through a connection terminal is within a predetermined effective range may be included.

In addition, according to the implementation method of the present invention, the quality inspection is to determine whether the battery module 135 is matched to the effective discharge range according to the specification while discharging the battery module 135 to the full discharge voltage through the power terminal of the battery module 135. Discharge inspection may be included.

In addition, according to the implementation method of the present invention, the quality inspection is performed while discharging the battery module 135 through the power terminal of the battery module 135 according to a specified current ratio (C-rate) until the fully discharged voltage according to the specification. A discharge inspection may be performed to determine whether discharge is matched within an allowable range of the current ratio.

In addition, according to the implementation method of the present invention, the quality inspection is performed while discharging the battery module 135 to the full discharge voltage according to the specification through the power terminal of the battery module 135, and the cells provided in the battery module 135 A balance test may be performed to determine whether a difference in voltage between battery cells included in the battery module 135 through a connection terminal is within a predetermined effective range.

In addition, according to the implementation method of the present invention, the quality inspection is performed while discharging the battery module 135 to the full discharge voltage according to the specification through the power terminal of the battery module 135, and the cells provided in the battery module 135 A temperature test may be performed to determine whether a temperature value sensed through at least one temperature sensor provided in the battery module 135 through a connection terminal is within a predetermined effective range.

On the other hand, according to the method of the present invention, the battery pack 130 discharges M number of battery modules 135 including battery cells 140 of the same quality to the full discharge voltage according to the specification, and then the M battery modules It can be regenerated by charging the N battery cells provided in 135 up to the rated voltage according to specifications.

According to the implementation method of the present invention, the charge/discharge cycle is a cycle in which a state in which the battery pack 130 is completely charged up to the set full charge amount and then fully discharged up to the set full discharge amount is set as one cycle. can include For example, in the case of charging 100% (= fully charged) in the i-th charge/discharge and then discharging using up to 0% (= fully discharged), the i-th charge/discharge cycle is calculated as (100 - 0)/100 = 1 cycle If it is 100% charged (= fully charged) in the ith charge and discharge and then discharged by using up to 50%, the ith charge and discharge cycle can be calculated as (100-50)/100 = 0.5 cycle. there is. In addition, when only about 80% is rapidly charged in the i-th charge and discharge and then discharged by using up to 20%, the i-th charge and discharge cycle can be calculated as (80-20)/100 = 0.6 cycles.

Here, the fully charged amount is set based on the charge capacity of N battery cells 140 included in the regenerated battery pack 130, or M battery modules included in the regenerated battery pack 130 ( 135) can be set based on the charging capacity.

In addition, the complete discharge amount is set within a predetermined range based on the charging capacities of the N battery cells 140 included in the regenerated battery pack 130, or provided in the regenerated battery pack 130. It may be set within a preset range based on the charging capacity of the M number of battery modules 135.

On the other hand, according to the implementation method of the present invention, the information management unit 105 provides information on the quality level corresponding to the quality inspection result of the battery module 135 and the number of effective charge/discharge cycles corresponding to the lifespan of the battery pack 130. It is possible to store a quality-cycle table matching , check quality levels corresponding to quality inspection results of the M battery modules 135 included in the battery pack 130, and determine the quality-cycle table based on the quality-cycle table. Information on the number of effective charge/discharge cycles corresponding to the identified quality level may be checked.

The information storage unit 110 may receive state information transmitted through the management module 170 of the designated battery pack 130 and accumulate and store it in a designated management DB.

According to the implementation method of the present invention, the information storage unit 110 uniquely identifies the unique identification information of the designated battery pack 130 and the M number of battery modules 135 included in the battery pack 130. M modules for uniquely identifying them. Identification information can be linked and stored in a designated management DB. Here, the status information may include M data blocks that do not include the M module identification information and include n battery cell voltage values for each battery module.

In addition, the M number of battery modules 135 are provided in the battery pack 130 in a designated number order, and the M number of module identification information is provided in the M number of battery modules 135 included in the battery pack 130. The M data blocks may be concatenated to match the number order assigned to the M number of battery modules 135 included in the battery pack 130 and included in the status information.

Also, when each battery module 135 includes a temperature sensor, the M data blocks may further include at least one temperature value sensed through a temperature sensor included in each battery module.

The information checking unit (115) reads the status information of the designated battery pack stored in the management DB, checks the ith order charge amount corresponding to the ith (i≥1) order charge of the battery pack, and checks the ith order charge amount. After charging, it is possible to check the i-th discharge amount corresponding to the ith-th discharge.

According to the implementation method of the present invention, the i-th charge amount is the i-th charge amount of the battery pack 130 in the (i-1)th discharge state of the battery pack 130 or the terminal open state of the battery pack 130. It may be calculated by integrating the electric power charged in the battery pack 130 based on state information stored until just before the transition to the i-th discharge state of the battery pack 130 after switching to the primary charged state.

In addition, according to the method of the present invention, the i-th charge amount of the battery pack 130 is the (i−1)th discharge state of the battery pack 130 or the terminal open state of the battery pack 130. of the battery pack voltage value (or a combination of voltage values for each N number of battery cells) immediately before switching to the ith discharge state of the battery pack 130 after switching to the ith charge state and the battery pack 130 It can be calculated through the relationship between the specified full charge voltages.

Meanwhile, according to the method of the present invention, the ith order discharge amount is the ith order discharge amount of the battery pack 130 in the ith order charging state or the terminal open state of the battery pack 130. It can be calculated by integrating the power discharged from the battery pack 130 based on state information stored until just before the transition to the (i+1)th charged state of the battery pack 130 after the conversion to the discharge state. .

In addition, according to the method of the present invention, the ithth discharge amount is the ithth discharge amount of the battery pack 130 in the ithth state of charge of the battery pack 130 or the terminal open state of the battery pack 130. of the battery pack voltage value (or a combination of voltage values for each N number of battery cells) immediately before being converted to the (i+1) th state of charge of the battery pack 130 after being converted to state, and the battery pack 130 It can be calculated through the relationship between the specified full discharge voltages.

When the ith-th charge amount and the ith-th discharge amount are confirmed, the information calculation unit 120 calculates the discharge after the ith charge using the difference between the ith-th charge amount and the ith-th discharge amount. The i-th charge/discharge cycle number can be calculated.

The information processing unit 125 corresponds to the remaining life of the battery pack 130 by subtracting the calculated i-th charge/discharge cycle number from information on the number of effective charge/discharge cycles of the battery pack 130 stored in the management DB. It is possible to update information on the number of effective charge and discharge cycles.

According to the implementation method of the present invention, the i-th charge/discharge cycle number is determined based on the i-th charge amount based on one cycle corresponding to the difference between the fully charged amount and the completely discharged amount set in the battery pack 130 and A value corresponding to the ratio of the difference between the i-th discharge amounts may be included. For example, in the case of charging 100% (= fully charged) in the i-th charge/discharge and then discharging using up to 0% (= fully discharged), the i-th charge/discharge cycle is calculated as (100 - 0)/100 = 1 cycle If it is 100% charged (= fully charged) in the ith charge and discharge and then discharged by using up to 50%, the ith charge and discharge cycle can be calculated as (100-50)/100 = 0.5 cycle. If, in the ith charge and discharge, only about 80% is rapidly charged and then discharged by using up to 20%, the ith charge and discharge cycle can be calculated as (80-20)/100 = 0.6 cycle.

On the other hand, according to the implementation method of the present invention, the information processing unit 125 is included in at least one cell-based state information corresponding to a recent predetermined period among cell-based state information stored in the management DB for the designated battery pack 130 Voltage values of each N number of battery cells are mutually compared to determine an abnormal cell balance state corresponding to a voltage value of at least one battery cell outside a predetermined effective balance range, and when the cell balance abnormal state is confirmed, the battery pack 130 ) may be deducted or initialized by a predetermined ratio (or number of times) of effective charge/discharge cycle number information corresponding to the remaining lifespan of ). For example, regardless of the current voltage value of each N battery cell, the voltage values of each N battery cell must be the same within 0.001V. If the voltage value of one of the N battery cells differs If a difference of more than 0.001V is shown compared to the voltage values of (N-1) battery cells, a certain percentage (or number) of the information on the number of effective charge and discharge cycles corresponding to the remaining life of the battery pack 130 is subtracted The battery pack 130 is no longer charged and discharged (=cannot be used) and immediately recovered by reducing the life remaining for charging and discharging the battery pack 130 or by initializing the information on the number of effective charge and discharge cycles (eg, initialized to '0'). can be made

In addition, according to the implementation method of the present invention, the information processing unit 125 includes T included in at least one state information corresponding to a recent certain period among a plurality of state information accumulated and stored in the management DB for the designated battery pack 130. When a temperature-related abnormal state corresponding to at least one temperature value outside a preset effective temperature range is identified by reading the number of temperature values, information on the number of effective charge/discharge cycles corresponding to the remaining lifespan of the battery pack 130 is set to a predetermined value. The rate (or number of times) can be deducted or reset. For example, when there is a risk of fire or explosion due to a rise in temperature, the battery pack 130 is replaced by deducting a certain percentage (or number) of the information on the number of effective charge/discharge cycles corresponding to the remaining life of the battery pack 130. The remaining charge/discharge lifespan may be reduced or the effective charge/discharge cycle number information may be initialized (eg, initialized to '0') so that the battery is immediately recovered without further charge/discharge (=cannot be used).

In addition, according to the implementation method of the present invention, the information processing unit 125 includes T number of status information included in a plurality of status information accumulated during a recent period among a plurality of status information accumulated and stored in a management DB for a designated battery pack 130. A temperature corresponding to at least one temperature value that includes a preset effective temperature change trend (or pattern) and a temperature change trend (or pattern) that is not matched within a preset allowable range by sorting and reading the temperature values for each temperature sensor. When the related abnormal state is confirmed and the temperature related abnormal state is confirmed, information on the number of effective charge/discharge cycles corresponding to the remaining life of the battery pack 130 may be deducted at a predetermined rate (or number of times) or initialized. For example, regardless of battery charge/discharge, temperature values are sorted by temperature sensor and trend (or pattern) is analyzed to identify temperature-related anomalies that deviate from the effective temperature change. (or pattern), or in the case of a trend (or pattern) in which the temperature continuously rises, a predetermined ratio (or number) of the information on the number of effective charge/discharge cycles corresponding to the remaining life of the battery pack 130 is subtracted to the battery pack. Reducing the remaining life for charging and discharging the 130 or initializing the effective charge and discharge cycle number information (eg, initializing to '0') so that it can no longer be charged and discharged (= cannot be used) and is immediately recovered. can

In addition, according to the implementation method of the present invention, the information processing unit 125 includes T number of status information included in a plurality of status information accumulated during a recent period among a plurality of status information accumulated and stored in a management DB for a designated battery pack 130. Temperature values corresponding to at least one temperature value including a temperature change trend (or pattern) that is matched with a preset dangerous temperature change trend (or pattern) by reading after sorting the temperature values for each temperature sensor within a preset allowable range When the abnormal state is confirmed and the temperature-related abnormal state is confirmed, information on the number of effective charge/discharge cycles corresponding to the remaining life of the battery pack 130 may be deducted by a predetermined ratio (or number of times) or initialized. For example, it is possible to identify a temperature-related anomaly corresponding to a dangerous temperature change by arranging the temperature values by temperature sensor and analyzing the trend (or pattern) regardless of battery charging/discharging. In the case of an increasing trend (or pattern) or a continuous temperature rising trend (or pattern), a certain percentage (or number) of the information on the number of effective charge/discharge cycles corresponding to the remaining life of the battery pack 130 is subtracted. to reduce the life remaining for charging and discharging the battery pack 130 or initialize the information on the number of effective charge and discharge cycles (eg, initialized to '0') so that the battery pack 130 can no longer be charged and discharged (= cannot be used) and immediately can be recovered.

In addition, according to the implementation method of the present invention, the information processing unit 125 includes T number of status information included in a plurality of status information accumulated during a recent period among a plurality of status information accumulated and stored in a management DB for a designated battery pack 130. At least one temperature value including a predetermined effective temperature change trend (or pattern) and a temperature change trend (or pattern) that is not matched within a predetermined allowable range by reading after sorting the temperature values for each temperature sensor, in the same type of battery pack state of charge A temperature-related abnormal state corresponding to the temperature value of is checked, and when the temperature-related abnormal state is confirmed, a predetermined ratio (or number of times) is subtracted from information on the number of effective charge/discharge cycles corresponding to the remaining life of the battery pack 130, or can be initialized. For example, it is possible to identify temperature-related anomalies that deviate from the effective temperature change by arranging the temperature values in a state where a certain time has elapsed after switching to the battery charging state for each temperature sensor and analyzing the trend (or pattern). In the case of a trend (or pattern) in which the temperature rises or a trend (or pattern) in which the temperature continuously rises, a certain ratio (or number of times) of the information on the number of effective charge and discharge cycles corresponding to the remaining life of the battery pack 130 By deducting , the remaining life for charging and discharging the battery pack 130 is reduced, or the effective charge and discharge cycle count information is initialized (eg, initialized to '0') so that the battery pack 130 can no longer be charged and discharged (= cannot be used). ) can be retrieved immediately.

In addition, according to the implementation method of the present invention, the information processing unit 125 includes T number of status information included in a plurality of status information accumulated during a recent period among a plurality of status information accumulated and stored in a management DB for a designated battery pack 130. After arranging the temperature values for each temperature sensor, read them, and at least one temperature change trend (or pattern) that is matched within the preset allowable range with the preset dangerous temperature change trend (or pattern) in the same type of battery pack charging state. A temperature-related abnormal state corresponding to the temperature value is checked, and when the temperature-related abnormal state is confirmed, the information on the number of effective charge/discharge cycles corresponding to the remaining life of the battery pack 130 is deducted at a predetermined rate (or the number of times) or initialized. can do. For example, it is possible to identify a temperature-related anomaly corresponding to a dangerous temperature change by arranging the temperature values in a state where a certain time elapsed after switching to the battery charging state for each temperature sensor and analyzing the trend (or pattern). In the case of a trend (or pattern) in which the temperature rises rapidly or a trend (or pattern) in which the temperature continuously rises, a certain ratio (or number of times) of the information on the number of effective charge and discharge cycles corresponding to the remaining life of the battery pack ) to reduce the remaining charge/discharge lifespan of the battery pack, or the effective charge/discharge cycle number information is initialized (eg, initialized to '0') so that the battery pack can no longer be charged and discharged (= cannot be used) and immediately can be recovered.

In addition, according to the implementation method of the present invention, the information processing unit 125 includes T number of status information included in a plurality of status information accumulated during a recent period among a plurality of status information accumulated and stored in a management DB for a designated battery pack 130. At least one temperature value including a predetermined effective temperature change trend (or pattern) and a temperature change trend (or pattern) that is not matched within a predetermined allowable range by sorting and reading the temperature values for each temperature sensor, in the discharge state of the same type of battery pack A temperature-related abnormal state corresponding to the temperature value of is checked, and when the temperature-related abnormal state is confirmed, a predetermined ratio (or number of times) is subtracted from information on the number of effective charge/discharge cycles corresponding to the remaining life of the battery pack 130, or can be initialized. For example, it is possible to identify temperature-related anomalies that deviate from the effective temperature change by arranging the temperature values in a state where a certain amount of time has elapsed after switching to a battery discharge state for each temperature sensor and analyzing the trend (or pattern). In the case of a trend (or pattern) in which the temperature rises or a trend (or pattern) in which the temperature continuously rises, a certain ratio (or number of times) of the information on the number of effective charge and discharge cycles corresponding to the remaining life of the battery pack 130 By deducting , the remaining life for charging and discharging the battery pack 130 is reduced, or the effective charge and discharge cycle count information is initialized (eg, initialized to '0') so that the battery pack 130 can no longer be charged and discharged (= cannot be used). ) can be retrieved immediately.

In addition, according to the implementation method of the present invention, the information processing unit 125 includes T number of status information included in a plurality of status information accumulated during a recent period among a plurality of status information accumulated and stored in a management DB for a designated battery pack 130. At least one temperature value including a temperature change trend (or pattern) that is matched within a predetermined allowable range with a preset dangerous temperature change trend (or pattern) in the same type of battery pack discharge state by aligning and reading the temperature values for each temperature sensor. A temperature-related abnormal state corresponding to the temperature value is checked, and when the temperature-related abnormal state is confirmed, the information on the number of effective charge/discharge cycles corresponding to the remaining life of the battery pack 130 is deducted at a predetermined rate (or the number of times) or initialized. can do. For example, it is possible to identify a temperature-related anomaly corresponding to a dangerous temperature change by arranging the temperature values in a state where a certain time has elapsed after the battery discharge state is sorted by temperature sensor and analyzing the trend (or pattern), which is matched to a preset risk slope In the case of a trend (or pattern) in which the temperature rises rapidly or a trend (or pattern) in which the temperature continuously rises, a certain ratio (or number of times) of the information on the number of effective charge and discharge cycles corresponding to the remaining life of the battery pack By deducting , the remaining life span for charging and discharging the battery pack is reduced, or the number of effective charge and discharge cycles is initialized (eg, initialized to '0') so that the battery pack can no longer be charged and discharged (= cannot be used) and immediately recovered. can be made

On the other hand, here, the information processing unit 125 checks the battery pack 130 for which information on the number of effective charge/discharge cycles is less than a preset reference value in conjunction with the management DB, and identifies a battery whose information on the number of effective charge/discharge cycles is less than a preset reference value. A charging device that configures battery pack information corresponding to the pack 130 to charge the battery pack 130, a terminal device that manages the battery pack 130, and a user's wireless terminal using the battery pack 130 A procedure for transmitting to at least one of the designated target devices may be performed.

2 is a diagram illustrating a process of checking the amount of charge and discharge of a battery pack through state information received from the battery pack according to the method of the present invention.

In more detail, this drawing 2 shows a battery regenerated after a predetermined quality test for n (n≥2) battery cells provided in each battery module separated from a vehicle battery pack used in an eco-friendly vehicle in the operation server 100. The management module 170 of the battery pack 130 after linking and storing the unique identification information assigned to the pack and information on the number of effective charge/discharge cycles corresponding to the lifespan of the battery pack determined based on the quality inspection in a designated management DB The voltage value of the battery pack 130 capable of checking the amount of charge and discharge of the battery pack 130 received from the voltage value of the battery pack 130 and N (N≥n, N=M*n) number of battery cells provided in the battery pack 130 It shows a process of checking the ith (i≥1)th charge amount and ithth discharge amount of the battery pack 130 by reading state information including voltage values of each N number of battery cells for Those of ordinary skill in the art to which the invention pertains may infer various implementation methods for the process (eg, an implementation method in which some steps are omitted or the order is changed) by referring to and/or modifying this Figure 2. Although it may be possible, the present invention is made including all the implementation methods inferred above, and its technical characteristics are not limited only to the implementation method shown in FIG. 2.

Referring to FIG. 2, the operation server 100 sets a preset value for n (n≥2) battery cells 140 provided in each battery module 135 separated from a vehicle battery pack used in an eco-friendly vehicle. After the quality inspection, the unique identification information given to the regenerated battery pack 130 including M (M≥1) battery modules 135 including battery cells 140 of equivalent quality and the quality inspection determined based on Information on the number of effective charge/discharge cycles corresponding to the lifespan of the battery pack 130 is linked and stored in a designated management DB (200).

According to the implementation method of the present invention, the quality inspection may include a quality inspection of n battery cells 140 provided in each battery module 135 . Here, the battery pack 130 may include the same quality as the N number of battery cells 140 .

In addition, according to the implementation method of the present invention, the quality inspection may include an optical inspection for determining whether at least one state of damage, swelling, and discoloration of the battery module 135 is within a predetermined effective range.

In addition, according to the implementation method of the present invention, the quality test is a resistance test for determining whether the resistance value of the battery module 135 is matched to a preset effective resistance range by measuring the resistance value of the battery module 135 through the power terminal of the battery module 135. can include

In addition, according to the implementation method of the present invention, the quality inspection is to determine whether the battery module 135 is matched to the effective charging range according to the specification while charging the battery module 135 to the full charge voltage according to the specification through the power terminal of the battery module 135. May include filling inspection.

On the other hand, according to the implementation method of the present invention, the quality inspection is performed while charging the battery module 135 through the power terminal of the battery module 135 according to a specified current ratio (C-rate) to a fully charged voltage according to the specification. A charging test may be performed to determine whether the battery is charged in a matched manner within an allowable range of the current ratio.

In addition, according to the implementation method of the present invention, the quality inspection is performed while charging the battery module 135 to a fully charged voltage according to the specification through the power terminal of the battery module 135, and the cell provided in the battery module 135 A balance test may be performed to determine whether a difference in voltage between battery cells included in the battery module 135 through a connection terminal is within a predetermined effective range.

In addition, according to the implementation method of the present invention, the quality inspection is performed while charging the battery module 135 to a fully charged voltage according to the specification through the power terminal of the battery module 135, and the cell provided in the battery module 135 A temperature test for determining whether a temperature value sensed through at least one temperature sensor provided in the battery module 135 through a connection terminal is within a predetermined effective range may be included.

In addition, according to the implementation method of the present invention, the quality inspection is to determine whether the battery module 135 is matched to the effective discharge range according to the specification while discharging the battery module 135 to the full discharge voltage through the power terminal of the battery module 135. Discharge inspection may be included.

In addition, according to the implementation method of the present invention, the quality inspection is performed while discharging the battery module 135 through the power terminal of the battery module 135 according to a specified current ratio (C-rate) until the fully discharged voltage according to the specification. A discharge inspection may be performed to determine whether discharge is matched within an allowable range of the current ratio.

In addition, according to the implementation method of the present invention, the quality inspection is performed while discharging the battery module 135 to the full discharge voltage according to the specification through the power terminal of the battery module 135, and the cells provided in the battery module 135 A balance test may be performed to determine whether a difference in voltage between battery cells included in the battery module 135 through a connection terminal is within a predetermined effective range.

In addition, according to the implementation method of the present invention, the quality inspection is performed while discharging the battery module 135 to the full discharge voltage according to the specification through the power terminal of the battery module 135, and the cells provided in the battery module 135 A temperature test may be performed to determine whether a temperature value sensed through at least one temperature sensor provided in the battery module 135 through a connection terminal is within a predetermined effective range.

On the other hand, according to the method of the present invention, the battery pack 130 discharges M number of battery modules 135 including battery cells 140 of the same quality to the full discharge voltage according to the specification, and then the M battery modules It can be regenerated by charging the N battery cells provided in 135 up to the rated voltage according to specifications.

According to the implementation method of the present invention, the charge/discharge cycle is a cycle in which a state in which the battery pack 130 is completely charged up to the set full charge amount and then fully discharged up to the set full discharge amount is set as one cycle. can include For example, in the case of charging 100% (= fully charged) in the i-th charge/discharge and then discharging using up to 0% (= fully discharged), the i-th charge/discharge cycle is calculated as (100 - 0)/100 = 1 cycle If it is 100% charged (= fully charged) in the ith charge and discharge and then discharged by using up to 50%, the ith charge and discharge cycle can be calculated as (100-50)/100 = 0.5 cycle. there is. In addition, when only about 80% is rapidly charged in the i-th charge and discharge and then discharged by using up to 20%, the i-th charge and discharge cycle can be calculated as (80-20)/100 = 0.6 cycles.

Here, the fully charged amount is set based on the charge capacity of N battery cells 140 included in the regenerated battery pack 130, or M battery modules included in the regenerated battery pack 130 ( 135) can be set based on the charging capacity.

In addition, the complete discharge amount is set within a predetermined range based on the charging capacities of the N battery cells 140 included in the regenerated battery pack 130, or provided in the regenerated battery pack 130. It may be set within a preset range based on the charging capacity of the M number of battery modules 135.

On the other hand, according to the implementation method of the present invention, the information management unit 105 provides information on the quality level corresponding to the quality inspection result of the battery module 135 and the number of effective charge/discharge cycles corresponding to the lifespan of the battery pack 130. It is possible to store a quality-cycle table matching , check quality levels corresponding to quality inspection results of the M battery modules 135 included in the battery pack 130, and determine the quality-cycle table based on the quality-cycle table. Information on the number of effective charge/discharge cycles corresponding to the identified quality level may be checked.

In the operation server 100, a unique identification given to the battery pack regenerated after a predetermined quality test for n (n≥2) battery cells provided in each battery module separated from the vehicle battery pack used in the eco-friendly vehicle After linking and storing the information and information on the number of effective charge/discharge cycles corresponding to the lifespan of the battery pack determined on the basis of the quality inspection in a designated management DB, the management module 170 of the battery pack 130 determines the quality of the battery pack. The voltage value of the battery pack 130, which can check the amount of charge and discharge, is checked (205), and the N number of battery cells for the N (N≥n, N=M*n) number of battery cells provided in the battery pack 130 After checking the voltage value of each battery cell (210), the communication module 195 of the battery pack 130 configures state information including the checked voltage value of the battery pack 130 and the voltage value of each N number of battery cells. It is transmitted to the operation server 100 through (215).

Then, the operation server 100 receives the state information transmitted through the management module 170 of the battery pack 130 and accumulates and stores it in a designated management DB (220).

According to the implementation method of the present invention, the operation server 100 identifies the unique identification information of the designated battery pack 130 and the M number of modules for uniquely identifying the M number of battery modules 135 provided in the battery pack 130. Information can be linked and stored in a designated management DB. Here, the status information may include M data blocks that do not include the M module identification information and include n battery cell voltage values for each battery module.

In addition, the M number of battery modules 135 are provided in the battery pack 130 in a designated number order, and the M number of module identification information is provided in the M number of battery modules 135 included in the battery pack 130. The M data blocks may be concatenated to match the number order assigned to the M number of battery modules 135 included in the battery pack 130 and included in the status information.

Also, when each battery module 135 includes a temperature sensor, the M data blocks may further include at least one temperature value sensed through a temperature sensor included in each battery module.

After the status information is accumulated and stored in the designated management DB, the operation server 100 reads the status information of the designated battery pack stored in the management DB to perform the ith (i≥1)th charging of the battery pack 130. The corresponding ith-th charge amount is checked (225), and the ith-th discharge amount corresponding to the ith-th discharge after the ith-th charge is checked (230).

According to the implementation method of the present invention, the i-th charge amount is the i-th charge amount of the battery pack 130 in the (i-1)th discharge state of the battery pack 130 or the terminal open state of the battery pack 130. It may be calculated by integrating the electric power charged in the battery pack 130 based on state information stored until just before the transition to the i-th discharge state of the battery pack 130 after switching to the primary charged state.

In addition, according to the method of the present invention, the i-th charge amount of the battery pack 130 is the (i−1)th discharge state of the battery pack 130 or the terminal open state of the battery pack 130. of the battery pack voltage value (or a combination of voltage values for each N number of battery cells) immediately before switching to the ith discharge state of the battery pack 130 after switching to the ith charge state and the battery pack 130 It can be calculated through the relationship between the specified full charge voltages.

Meanwhile, according to the method of the present invention, the ith order discharge amount is the ith order discharge amount of the battery pack 130 in the ith order charging state or the terminal open state of the battery pack 130. It can be calculated by integrating the power discharged from the battery pack 130 based on state information stored until just before the transition to the (i+1)th charged state of the battery pack 130 after the conversion to the discharge state. .

In addition, according to the method of the present invention, the ithth discharge amount is the ithth discharge amount of the battery pack 130 in the ithth state of charge of the battery pack 130 or the terminal open state of the battery pack 130. of the battery pack voltage value (or a combination of voltage values for each N number of battery cells) immediately before being converted to the (i+1) th state of charge of the battery pack 130 after being converted to state, and the battery pack 130 It can be calculated through the relationship between the specified full discharge voltages.

3 is a diagram illustrating a process of calculating the number of charge/discharge cycles of a battery pack and updating information on the number of effective charge/discharge cycles corresponding to the remaining service life according to the method of the present invention.

In more detail, FIG. 3 shows after the ith (i≥1)th charging amount and ithth discharging amount of the battery pack 130 are confirmed in the operation server 100 through the process of FIG. 2, and after the ithth charging. The i-th charge/discharge cycle number for discharge is calculated, and the calculated i-th charge/discharge cycle number is subtracted from information on the number of effective charge/discharge cycles of the battery pack 130 stored in the management DB to obtain the battery pack 130 ), and shows a process of updating the number of effective charge and discharge cycles corresponding to the remaining lifespan of ), and those skilled in the art to which the present invention belongs refer to and / or modify this figure 3 to perform the above process Various implementation methods (eg, implementation methods in which some steps are omitted or the order is changed) may be inferred, but the present invention includes all implementation methods inferred above, and the implementation shown in FIG. The technical characteristics are not limited only by the method.

Referring to Figure 3, after the process of Figure 2, the operation server 100, when the operation server 100 confirms the i-th charge amount and ith-th discharge amount (300), the confirmed i-th The i-th charge/discharge cycle number for discharge after the i-th charge is calculated using the difference between the i-th charge amount and the ith-th discharge amount (305).

Further, the operation server 100 subtracts the calculated i-th charge/discharge cycle number from information on the number of effective charge/discharge cycles of the battery pack 130 stored in the management DB (310), and the battery pack 130 ) is updated (315).

According to the implementation method of the present invention, the i-th charge/discharge cycle number is determined based on the i-th charge amount based on one cycle corresponding to the difference between the fully charged amount and the completely discharged amount set in the battery pack 130 and A value corresponding to the ratio of the difference between the i-th discharge amounts may be included.

On the other hand, according to the implementation method of the present invention, the operation server 100 is included in at least one cell-based state information corresponding to a recent certain period among the cell-based state information stored in the management DB for the designated battery pack 130 After comparing the voltage values of each N number of battery cells (320), the cell balance abnormal state corresponding to the voltage value of at least one battery cell outside the preset effective balance range is checked (325), and the cell balance abnormal state is determined. If confirmed, the information on the number of effective charge/discharge cycles corresponding to the remaining life of the battery pack 130 is deducted by a predetermined ratio (or number of times) or initialized (330).

According to the implementation method of the present invention, the operation server 100 includes T temperatures included in at least one state information corresponding to a recent certain period among a plurality of state information accumulated and stored in a management DB for a designated battery pack 130. When a temperature-related abnormal state corresponding to at least one temperature value outside a predetermined effective temperature range is confirmed by reading the value, information on the number of effective charge/discharge cycles corresponding to the remaining life of the battery pack 130 is set at a predetermined rate ( or count) can be deducted or initialized.

In addition, according to the implementation method of the present invention, the operation server 100 includes T number of states included in a plurality of state information accumulated during a recent period among a plurality of state information accumulated and stored in a management DB for a designated battery pack 130. A temperature corresponding to at least one temperature value that includes a preset effective temperature change trend (or pattern) and a temperature change trend (or pattern) that is not matched within a preset allowable range by sorting and reading the temperature values for each temperature sensor. When the related abnormal state is confirmed and the temperature related abnormal state is confirmed, information on the number of effective charge/discharge cycles corresponding to the remaining life of the battery pack 130 may be deducted at a predetermined rate (or number of times) or initialized.

In addition, according to the implementation method of the present invention, the operation server 100 includes T number of states included in a plurality of state information accumulated during a recent period among a plurality of state information accumulated and stored in a management DB for a designated battery pack 130. Temperature values corresponding to at least one temperature value including a temperature change trend (or pattern) that is matched with a preset dangerous temperature change trend (or pattern) by reading after sorting the temperature values for each temperature sensor within a preset allowable range When the abnormal state is confirmed and the temperature-related abnormal state is confirmed, information on the number of effective charge/discharge cycles corresponding to the remaining life of the battery pack 130 may be deducted by a predetermined ratio (or number of times) or initialized.

In addition, according to the implementation method of the present invention, the operation server 100 includes T number of states included in a plurality of state information accumulated during a recent period among a plurality of state information accumulated and stored in a management DB for a designated battery pack 130. At least one temperature value including a predetermined effective temperature change trend (or pattern) and a temperature change trend (or pattern) that is not matched within a predetermined allowable range by reading after sorting the temperature values for each temperature sensor, in the same type of battery pack state of charge A temperature-related abnormal state corresponding to the temperature value of is checked, and when the temperature-related abnormal state is confirmed, a predetermined ratio (or number of times) is subtracted from information on the number of effective charge/discharge cycles corresponding to the remaining life of the battery pack 130, or can be initialized.

In addition, according to the implementation method of the present invention, the operation server 100 includes T number of status information included in a plurality of status information accumulated during a recent period among a plurality of status information accumulated and stored in a management DB for a designated battery pack 130. At least one temperature change trend (or pattern) that includes a preset dangerous temperature change trend (or pattern) and a temperature change trend (or pattern) matching within a preset allowable range in the charging state of the same type of battery pack by sorting and reading the temperature values for each temperature sensor. A temperature-related abnormal state corresponding to the temperature value is checked, and when the temperature-related abnormal state is confirmed, the information on the number of effective charge/discharge cycles corresponding to the remaining life of the battery pack 130 is deducted at a predetermined rate (or the number of times) or initialized. can do.

In addition, according to the implementation method of the present invention, the operation server 100 includes T number of states included in a plurality of state information accumulated during a recent period among a plurality of state information accumulated and stored in a management DB for a designated battery pack 130. At least one temperature value including a predetermined effective temperature change trend (or pattern) and a temperature change trend (or pattern) that is not matched within a predetermined allowable range by sorting and reading the temperature values for each temperature sensor and in the discharge state of the same type of battery pack A temperature-related abnormal state corresponding to the temperature value of , and when the temperature-related abnormal state is confirmed, a predetermined ratio (or number) of information on the number of effective charge/discharge cycles corresponding to the remaining life of the battery pack 130 is subtracted, or can be initialized.

In addition, according to the implementation method of the present invention, the operation server 100 includes T number of states included in a plurality of state information accumulated during a recent period among a plurality of state information accumulated and stored in a management DB for a designated battery pack 130. At least one temperature value including a temperature change trend (or pattern) that is matched within a predetermined allowable range with a preset dangerous temperature change trend (or pattern) in the same type of battery pack discharge state by aligning and reading the temperature values for each temperature sensor. A temperature-related abnormal state corresponding to the temperature value is checked, and when the temperature-related abnormal state is confirmed, the information on the number of effective charge/discharge cycles corresponding to the remaining life of the battery pack 130 is deducted at a predetermined rate (or the number of times) or initialized. can do.

On the other hand, here, when the operation server 100 interworks with the management DB and confirms the battery pack 130 whose effective charge/discharge cycle count information is less than a preset reference value (335), the effective charge/discharge cycle count information is preset. A charging device for charging the battery pack 130, a terminal device for managing the battery pack 130, and the battery pack 130 by configuring battery pack information corresponding to the battery pack 130 having a value less than the reference value (340) is transmitted to at least one designated target device among the user's wireless terminals using (345).

In the above, even though all the components constituting the embodiment of the present invention have been described as being combined or operated as one, the present invention is not necessarily limited to these embodiments. That is, within the scope of the object of the present invention, all of the components may be selectively combined with one or more to operate.

The above description is merely an example of the technical idea of the present invention, and various modifications and variations can be made to those skilled in the art without departing from the essential characteristics of the present invention. Therefore, the embodiments disclosed in the present invention are not intended to limit the technical spirit of the present invention, but to explain, and the scope of the technical spirit of the present invention is not limited by these embodiments. The protection scope of the present invention should be construed according to the following claims, and all technical ideas within the equivalent range should be construed as being included in the scope of the present invention.

100: operation server 105: information management unit
110: information storage unit 115: information confirmation unit
120: information calculation unit 125: information processing unit
130: battery pack 135: battery module
140: battery cell 145: cell terminal
150: module power terminal 155: management module for battery module
160: temperature sensor 165: pack power terminal
170: management module 175: cell voltage collection unit
180: temperature collection unit 185: state information component
190: communication processing unit 195: communication module

Claims (8)

In the method executed through the management module and operation server of the battery pack,
The operation server performs a predetermined quality test on n (n ≥ 2) battery cells provided in each battery module separated from a vehicle battery pack used in an eco-friendly vehicle, and then M (M ≥ 1) A first method for linking and storing unique identification information assigned to a regenerated battery pack including two battery modules and valid charge/discharge cycle number information corresponding to the lifespan of the battery pack determined on the basis of the quality inspection in a designated management DB. step;
The voltage value of the battery pack, through which the management module of the battery pack can check the amount of charge and discharge of the battery pack, and N values of the N (N≥n, N=M*n) number of battery cells provided in the battery pack. Voltage values for each battery cell, T temperature values sensed through T (T≥1) temperature sensors provided at designated locations of the battery pack, battery pack charging state using the power terminal of the battery pack, battery pack A second step of constructing state information including a battery pack state value identifying at least one state of a discharge state and a battery pack terminal open state and transmitting the procedure to an operation server through a communication module of the battery pack;
A third step of receiving, by the operation server, status information transmitted through a management module of a designated battery pack and accumulatively storing it in a designated management DB;
The operation server reads the state information of the designated battery pack stored in the management DB, confirms the i-th charge amount corresponding to the ith (i≥1)-th charge of the battery pack, and after the i-th charge, the ith-th charge a fourth step of checking an i-th discharge amount corresponding to the discharge;
When the ith-th charge amount and the ith-th discharge amount are confirmed, the operation server conducts the ith-th charge/discharge for discharge after the ith-th charge using the difference between the ith-th charge amount and the ith-th discharge amount. a fifth step of calculating the number of cycles; and
The operation server subtracts the calculated i-th charge/discharge cycle number from information on the number of effective charge/discharge cycles of the battery pack stored in the management DB to update information on the number of valid charge/discharge cycles corresponding to the remaining life of the battery pack. The sixth step of doing;
Battery pack life management method using a temperature sensor comprising a. According to claim 1,
The charge/discharge cycle is
A battery pack life management method using a temperature sensor, characterized in that it comprises a cycle in which a state in which the battery pack is fully charged up to the set full charge amount and then completely discharged up to the set complete discharge amount is set as one cycle. According to claim 1,
The quality check is
A battery pack life management method using a temperature sensor, comprising an optical inspection for determining whether at least one of damage, swelling, and discoloration of the battery module is within a predetermined effective range. According to claim 1,
The quality check is
A temperature test is performed to determine whether a temperature value sensed through at least one temperature sensor included in the battery module is within a predetermined effective range while charging the battery module to a fully charged voltage according to specifications through a power terminal of the battery module. Battery pack life management method using a temperature sensor, characterized in that for doing. According to claim 1,
The quality check is
A temperature test is performed to determine whether a temperature value sensed through at least one temperature sensor provided in the battery module is within a predetermined effective range while discharging the battery module to a fully discharged voltage according to specifications through a power terminal of the battery module. Battery pack life management method using a temperature sensor, characterized in that for doing. According to claim 1,
The management module of the battery pack,
Checking whether the state of the battery pack is converted from a battery pack charging state or a battery pack terminal open state to a battery pack discharging state;
The battery pack life management method using a temperature sensor, characterized in that when the state is converted to the battery pack discharge state, the state information corresponding to the battery pack discharge state is configured and transmitted to the operation server. According to claim 1,
The management module of the battery pack,
Checking whether the state of the battery pack is switched from a battery pack discharge state or a battery pack terminal open state to a battery pack charge state;
and configuring and transmitting state information corresponding to the battery pack charging state to the operating server when the state is switched to the battery pack charging state. According to claim 1,
The operation server,
Regarding the battery pack, T temperature values included in at least one state information corresponding to a recent period among a plurality of state information accumulated and stored in the management DB are read, and at least one temperature value outside a predetermined effective temperature range is determined. A method for managing lifespan of a battery pack using a temperature sensor, further comprising: checking a corresponding temperature-related abnormal state.

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