KR102591649B1 - A system for regenerative discharge of a secondary battery and the control method therefor - Google Patents

Abstract

The present invention relates to a discharge system for secondary batteries. More specifically, in the discharge process preceding the recycling or disposal of waste batteries, regenerative discharge of the battery is basically performed, and resistance discharge is performed according to the remaining voltage of the battery. It relates to a secondary battery regenerative discharge system and its control method.
The conventional secondary battery discharge system is designed to perform a regeneration process by determining whether regenerative discharge is possible, and must further include unnecessary control configurations to configure this, and also include a history of the state value of the battery unit at the time of shipment or a battery module of the same type. By comparing the status value of the new battery to determine whether to discharge or not, if the information is incorrect, problems may occur due to unnecessary or incorrect operation.
The present invention basically performs regenerative discharge in the initial battery discharge, monitors the remaining voltage of the battery requiring resistance discharge, and automatically switches from regenerative discharge to resistance discharge, thereby enabling stable battery discharge and making it more economical. The aim is to provide a secondary battery regenerative discharge system that can be configured with a control unit.

Description

Secondary battery regenerative discharge system and its control method {A SYSTEM FOR REGENERATIVE DISCHARGE OF A SECONDARY BATTERY AND THE CONTROL METHOD THEREFOR}

The present invention relates to a discharge system for secondary batteries. More specifically, in the discharge process preceding the recycling or disposal of waste batteries, regenerative discharge of the battery is basically performed, and resistance discharge is performed according to the remaining voltage of the battery. It relates to a secondary battery regenerative discharge system and its control method.

Typically, a secondary battery refers to a battery that converts chemical energy into electrical energy to supply power to an external load, and when discharged, receives external power and converts electrical energy into chemical energy to store electricity.

As mentioned above, this type of secondary battery refers to a battery that can be reused through a charging process, unlike primary batteries, which are disposable. It converts electrical energy into chemical energy, stores it, and then converts it back into electrical energy when needed. Because it can be used repeatedly, it is considered a key material in various industries.

With the development of secondary battery technology, various types of secondary batteries have been used, and lithium-ion batteries are currently used in mobile devices and auxiliary batteries.

Such lithium-ion batteries can be charged using an external power source, and have the advantages of high energy density, excellent preservation, and long lifespan, leading to miniaturization, weight reduction, and high capacity of batteries, and have become the mainstream of secondary batteries.

Demand for such secondary batteries is expected to increase in various fields, and interest is bound to grow, especially in fields such as new and renewable energy and electric vehicles for carbon neutrality.

Recently, in response to the severity of environmental pollution caused by exhaust gases from automobiles, most automobile manufacturers are manufacturing and selling electric vehicles and hybrid vehicles, and many countries are mandating the manufacture of electric vehicles, making the use of eco-friendly electric vehicles more popular than ever. This is rapidly increasing.

Moreover, since electric vehicles and hybrid vehicles require large electric capacity, the use of batteries is increasing as battery packs containing multiple electric battery modules are used. As such, demand for secondary batteries continues to increase. As the number of waste batteries increases, the problem of how to dispose of used waste batteries has emerged.

When recycling or disposing of such waste batteries, a discharge process before dismantling is essential to remove the residual voltage of the waste batteries.

In order to recycle/reuse a waste battery, a discharge process for fire prevention must be performed before dismantling the waste battery, and a chemical discharge process must be performed again after the dismantling of the waste battery.

This chemical discharge process discharges waste batteries by immersing them in salt water and leaving them for a certain period of time. However, in this method of discharging the battery in salt water through which current flows, the amount of discharge (according to the amount of charge) is inevitably different depending on the type of battery, so there is no way to accurately check whether the battery is discharged. At this time, waste batteries that are not properly discharged may cause a large explosion or fire.

Accordingly, in the previously registered patent publication No. 10-2308374, a secondary battery discharge system and method are proposed that track and diagnose the state of the battery and enable discharge through power conversion or resistance.

However, such a conventional secondary battery discharge system is designed to perform a regeneration process by determining whether regenerative discharge is possible, and must further include unnecessary control configurations to configure this. In addition, the state value history of the battery unit at the time of shipment or the same By comparing the status value of the type of battery module to determine whether to discharge or not, if the information of the new battery is incorrect, problems may occur due to unnecessary or incorrect operation.

In addition, the conventional secondary battery discharge system uses a DC-DC converter to control the regenerative voltage level when performing the power conversion discharge process. At this time, the regenerative discharge is performed using a constant current method that requires voltage boosting through the converter. , auxiliary power must be used for smooth operation of the converter.

In the present invention, taking this into consideration, the initial battery discharge is basically performed through regenerative discharge, and the residual voltage of the battery requiring resistance discharge is monitored to automatically switch from regenerative discharge to resistance discharge, thereby ensuring stable battery discharge. The goal is to provide a secondary battery regenerative discharge system that allows the construction of a more economically efficient control unit while enabling this.

The present invention basically consists of a large-capacity inverter with a converter inside, performs a power conversion process without a separate boosting process by auxiliary power, transmits it to the system, and regenerative discharge is performed, so that auxiliary power is unnecessary. The goal is to provide a regenerative discharge system.

The present invention basically allows regenerative discharge to be performed, and monitors the battery voltage to switch from regenerative discharge to resistance discharge when it reaches a predetermined voltage (voltage requiring resistance discharge). This is a more efficient secondary battery regenerative discharge. The purpose of providing a system has its technical characteristics.

The regenerative discharge system of the secondary battery of the present invention is,

In the regenerative discharge system for a secondary battery that performs regenerative discharge by supplying the voltage of the electrically connected battery unit to the power system,

A breaker for controlling the supply of power from the battery unit to the discharge unit, a switch unit set to supply power supplied through the breaker to the power conversion unit, and controlled to switch to the resistance discharge unit according to the control of the control unit;

When the breaker operates and regenerative discharge begins, a comparison process is performed between the remaining voltage information of the battery section provided by the voltage detection unit and the set reference voltage. When the remaining voltage of the battery section falls below the set reference voltage, the switch section is controlled to control the battery section power. Battery information including a control unit that supplies power to the resistance discharge unit and controls it to cause resistance discharge, a temperature detection unit to detect the temperature of the battery unit and the resistance discharge unit, and the type, capacity, or product name of the battery unit to be discharged. It includes an input means for inputting and a storage means for storing reference voltage information for switching from power system discharge to resistance discharge according to battery information, and a display means for displaying the reference voltage information, and the control unit inputs the input through the input means. A process is configured to display the reference voltage information stored in the storage means through the display means according to the requested request information, and set the reference voltage stored in the storage means according to the battery information input from the input means, and the temperature detection unit If the temperature of the resistance discharge unit is above a predetermined temperature, a secondary battery regenerative discharge system may be provided, which provides a signal to the circuit breaker to operate the circuit breaker to cut off the voltage of the battery unit.

In the system of the present invention, the control unit monitors the temperature of the resistance discharge unit detected by the temperature sensing unit, determines whether the resistance discharge unit is overheated by comparing it with the reference temperature information, and operates the circuit breaker according to the judgment result to prevent the battery unit from being transferred to the discharge unit. It is characterized in that it further includes a process for controlling the supply voltage.

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In addition, the system of the present invention further includes means for detecting the temperature of the resistance discharge unit, and a temperature detection unit that provides a signal to the circuit breaker to operate the circuit breaker and cut off the voltage of the battery unit when the detected temperature increases above the predetermined temperature. It is characterized by being

And the present invention system,

A voltage detection unit for detecting the voltage and current of the battery unit, a current detection unit, and the remaining voltage information of the battery unit are provided from the voltage detection unit, and the voltage and current values of the battery unit provided from the voltage detection unit 70 and the current detection unit are received. It is characterized by further comprising a control unit that monitors and determines overvoltage and overcurrent and controls the supply voltage of the battery unit 10 to the discharging unit by controlling the circuit breaker to be turned off according to the results.

In addition, the system of the present invention,

It further includes an input means for inputting battery information including the type, capacity, or product name of the battery unit to be discharged, and a storage means for storing reference voltage information according to the battery information, wherein the control unit stores the battery information input from the input means. Therefore, a process of reading the reference voltage stored in the storage means and setting a reference voltage for switching from regenerative discharge (power system discharge) to resistance discharge is further configured.

Meanwhile, the regenerative discharge control method of the secondary battery of the present invention is,

When the circuit breaker is turned 'on' and the voltage of the battery unit is supplied along the switch unit where the battery voltage supply path is set for regenerative discharge, regenerative discharge is performed through the power conversion unit; the voltage of the battery unit provided from the voltage detection unit is monitored; , a step of controlling the switching part so that the battery voltage path is set to the resistance discharge part when the voltage of the battery part falls below the standard voltage through comparison with the reference voltage, a step of controlling the breaker by determining battery overvoltage and overcurrent, and temperature detection. It is characterized by comprising the step of monitoring the temperature of the resistance discharge unit from the unit and controlling the circuit breaker when the temperature of the resistance discharge unit rises above a predetermined temperature.

In addition, the regenerative discharge control method of the secondary battery of the present invention is,

Characterized by further comprising the step of reading the reference voltage information for controlling the changeover from regenerative discharge to resistance discharge stored according to the battery information input through the input means and setting the reference voltage for controlling the changeover from regenerative discharge to resistance discharge. do.

According to the present invention, an efficient secondary battery regeneration system can be formed by performing regenerative discharge through the initial power system and converting it to resistance discharge according to the remaining voltage of the battery unit.

And according to the present invention, power system regenerative discharge can be achieved through power conversion using a large-capacity inverter, making it possible to construct a secondary battery regeneration system without a separate voltage boosting process.

1 is a block diagram showing the configuration of the secondary battery regenerative discharge system of the present invention.
Figure 2 is a flow chart showing the execution process of the secondary battery regenerative discharge control method of the present invention.

First, the terms used in the specification and claims are general terms selected in consideration of their functions in various embodiments of the present invention. However, these terms may vary depending on the intention of technicians working in the field, legal or technical interpretation, and the emergence of new technologies. Additionally, some terms may be terms arbitrarily selected by the applicant. These terms may be interpreted as defined in this specification, and if there is no specific term definition, they may be interpreted based on the overall content of this specification and common technical knowledge in the relevant technical field.

In addition, the same reference numerals or symbols in each drawing attached to this specification indicate parts or components that perform substantially the same function. For convenience of explanation and understanding, different embodiments will be described using the same reference numbers or symbols. That is, even if all components having the same reference number are shown in multiple drawings, the multiple drawings do not represent one embodiment.

In this specification, singular expressions include plural expressions, unless the context clearly dictates otherwise. In the present application, terms such as 'comprise' or 'constitute' are intended to designate the presence of features, numbers, steps, operations, components, parts, or combinations thereof described in the specification, but are intended to indicate the presence of one or more other It should be understood that this does not exclude in advance the possibility of the presence or addition of features, numbers, steps, operations, components, parts, or combinations thereof.

Additionally, in an embodiment of the present invention, when a part is connected to another part, this includes not only direct connection but also indirect connection through other media. Additionally, the fact that a part includes a certain component does not mean that other components are excluded, but that it may further include other components, unless specifically stated to the contrary.

Hereinafter, the present invention system will be described in more detail with reference to the attached drawings.

Figure 1 is a block diagram showing the configuration of the secondary battery regenerative discharge system of the present invention.

A circuit breaker (MCCB) 20 for managing the supply of power from the battery unit 10 to the discharge unit, and supplying power supplied from the circuit breaker 20 to the power conversion unit 40 or the resistance discharge unit 50. a switch unit 30 for detecting the temperature of the resistance discharge unit 50, a temperature detection unit 60 for detecting the temperature of the battery unit 10, a voltage detection unit 70 for detecting the voltage and current of the battery unit 10, and a current detection unit. Remaining voltage information of the battery unit 10 is provided from the unit 80 and the voltage detection unit 70, and a comparison process is performed between the remaining voltage of the battery unit 10 and the set reference voltage to determine the battery unit 10. When the remaining voltage of ) is lowered below the set reference voltage, the switch unit 30 is controlled to supply power from the battery unit 10 to the resistance discharge unit 50 so that resistance discharge occurs, and the voltage detection unit ( 70), the voltage and current values of the battery unit 10 provided from the current detection unit 80 are monitored to determine overvoltage and overcurrent, and the breaker 20 is controlled to turn off according to the results, and the temperature detection unit ( 60) monitors the temperature of the resistance discharge unit 50, compares it with the reference temperature information, determines whether the resistance discharge unit 50 is overheated, and operates the circuit breaker 20 according to the determination result to transfer the battery to the discharge unit. It is configured to include a control unit 90 that regulates the supply voltage of the unit 10.

The regenerative discharge system of the present invention discharges the remaining energy charged in the electrically connected battery unit to the power system, and when the remaining energy (voltage) charged in the battery unit reaches a certain value or less, it switches to resistance discharge and discharges the battery unit. There are technical features that allow this to be performed.

A circuit breaker 20 and a switch unit 30 are configured as switching means for managing the electrical connection with the battery unit 10.

The circuit breaker 20 is composed of a MCCB (molded circuit breaker).

The switch unit 30 is a means for managing the connection between the battery unit 10 and the power conversion unit 40 or the battery unit 10 and the resistance discharge unit 50.

The switch unit 30 includes a battery unit 10, a first switch having a contact point for connecting the input terminal of the circuit breaker 20 and the power conversion unit 40, a battery unit 10, a circuit breaker 20, and a resistance room. It includes a second switch having a contact point for connecting the input terminal of the front 50, and is composed of an electromagnetic contactor (MG) in which the first switch and the second switch are mutually switched on/off.

The power conversion unit 40 supplies the voltage of the battery unit 10 supplied through the switch unit 30 to the power system (GRID) to regenerate the power system to discharge the remaining energy charged in the battery unit 10. It is a means of discharging.

The power conversion unit 40 is composed of a large-capacity inverter so that the voltage of the battery unit 10 can be supplied to the grid through an inverter without a separate voltage boosting process during the regenerative discharge process.

This power conversion unit 40 is composed of a 30kw large capacity inverter for regenerative discharge of a battery pack, such as a solar inverter including a DC-DC converter.

The resistance discharge unit 50 is a means for resistively discharging the battery voltage supplied through the switch unit 30, and is composed of parallel resistance heating elements such as a sheath heater.

At this time, a switch means is configured to perform a switching operation by the control unit 90 for the resistance heating element, and the control unit 90 may be configured to include a process of controlling the resistance value of the resistance discharge unit 50 by controlling the operation of the switch means. there is.

The temperature sensing unit 60 is attached to the resistance discharge unit 50 and is a means of detecting the temperature of the resistance discharge unit 50 and providing the temperature to the control unit 90.

The temperature sensing unit 60 is a means for detecting the temperature of the resistance discharge unit 50, and when the detected temperature increases above a predetermined temperature, it provides a signal to the circuit breaker 20 to operate the circuit breaker 20 to disconnect the battery unit. It can be configured to include means for blocking the voltage at (10). In this case, the control unit 90 does not include a process for monitoring the temperature and controlling the temperature of the circuit breaker 20 according to the monitoring results, and the temperature sensing unit 60 monitors the temperature according to the temperature of the resistance discharge unit 50. The operation of the circuit breaker 20 is controlled independently.

The operation process of the secondary battery regenerative discharge system of the present invention configured as described above will be described as follows.

The initial operation begins with regenerative discharge through the power system through the power conversion unit 40, and when the voltage of the battery unit 10 falls below a certain voltage, it switches to resistance discharge and discharge is performed.

In the initial setting, the breaker 20 is in the 'Off' state, and the switch unit 30 makes contact with the power conversion unit 40.

The user switches the breaker 20 to the 'ON' state to start the regenerative discharge operation.

As described above, when the circuit breaker 20 is switched to the 'on' state, the remaining energy charged in the battery unit 10 is supplied to the power conversion unit 40 through the circuit breaker 20 and the switch unit 30, and power conversion is performed. The voltage of the battery unit 10 supplied to the unit 40 is converted through the power conversion unit 40 and supplied to the power system (GRID), thereby causing regenerative discharge of the battery unit 10.

In the process of discharging the power system through the power conversion unit 40, the control unit 90 receives the voltage of the battery unit 10 from the voltage detection unit 20 and uses the remaining power of the battery unit 10. monitor.

The control unit 90 compares the set reference voltage with the remaining voltage of the battery unit 90, and when the voltage of the battery unit 90 falls below the set reference voltage, it controls the switch unit 30 to create a resistance discharge unit. Switch the contact point to the (50) side.

Therefore, the voltage of the battery unit 10 that was supplied to the power conversion unit 40 is supplied to the resistance discharge unit 50, and resistance discharge occurs through the resistance discharge unit 50.

That is, when the remaining voltage of the battery unit 90 falls below the reference voltage, the control unit 90 applies a switching control voltage to the switch unit 30, activates the magnet of the switch unit 30, and turns the contact point into a resistance discharge unit ( By converting to the 50 side, the voltage path of the battery unit 10 supplied through the breaker 20 is set to the resistance discharge unit 50 side.

At this time, display means can be further configured to provide to the outside the voltage and current information of the battery unit 10 detected through the voltage detection unit 70 and the current detection unit 80, and the control unit 90 displays the battery unit 10. The voltage and current information of the battery unit 10 are displayed through the display means, and information on the overvoltage and overcurrent status of the battery unit 10 during the discharging process can also be displayed.

The control unit 90 monitors the voltage and current information of the battery unit 10 provided from the voltage detection unit 70 and the current detection unit 80 to determine the overvoltage and overcurrent status of the battery unit 10, and monitors the overvoltage and overcurrent conditions of the battery unit 10. In the case of an overcurrent state, the circuit breaker 20 is turned 'off' to cut off the voltage of the battery unit 10, and the overvoltage and overcurrent status information of the battery unit 10 can be displayed through the display unit as described above.

In addition, the control unit 90 monitors the temperature of the resistance discharge unit 50 provided through the temperature detection unit 60 attached to the resistance discharge unit 50, and if the temperature of the resistance discharge unit 50 increases above the set temperature, In this case, the circuit breaker 20 is turned 'off' to block the voltage output of the battery unit 10, and the temperature of the resistance discharge unit 50 and overheating information of the resistance discharge unit 50 can be displayed through the display means. .

Here, the temperature sensing unit 60 may be configured as a means for supplying a switching control voltage to the blocking unit 20 when the temperature of the resistance discharge unit 50 increases above a predetermined temperature.

And an input means for inputting battery information including the type, capacity, or product name of the battery unit 10 to be discharged, and a storage where reference voltage information for converting from regenerative discharge (power system discharge) to resistance discharge according to the battery information is stored. It further includes a means, and the control unit 90 displays the reference voltage information stored in the storage means according to the request information input through the input means through the display means and displays the reference voltage information stored in the storage means according to the battery information input from the input means. The process for setting the reference voltage can be further configured.

According to this configuration, the user (manager) inputs the type and product name of the battery through an input means, and the control unit 90 sets the reference voltage according to this information and adjusts the voltage of the battery unit 10 as described above. Therefore, the switch unit 30 is controlled to enable a transition from regenerative discharge to resistance discharge.

Figure 2 is a flow chart showing the execution process of the secondary battery regenerative discharge control method of the present invention.

Meanwhile, the regenerative discharge control method of the secondary battery of the present invention performed in the control unit 90 is:

When the breaker 20 is turned 'on' and the voltage of the battery unit 10 is supplied along the switch unit 30 where the battery voltage supply path is set for regenerative discharge, regenerative discharge is performed through the power conversion unit 40. Step (S1), the voltage of the battery unit 10 provided from the voltage detection unit 70 is monitored, and when the voltage of the battery unit 10 falls below the reference voltage through comparison with the reference voltage, the battery voltage A step of performing a resistance discharge process by switching and controlling the switch unit 30 so that the path is set to the resistance discharge unit 50 (S2), a step of determining battery overvoltage and overcurrent and controlling the circuit breaker 20, and a temperature sensing unit. It includes the step of monitoring the temperature of the resistance discharge unit 50 from (60) and controlling the circuit breaker 20 when the temperature of the resistance discharge unit 50 rises above a predetermined temperature.

The method may further include setting a reference voltage by reading reference voltage information for controlling the switch from regenerative discharge to resistance discharge stored according to battery information input through an input means.

The present invention performs regenerative discharge through the initial power system and switches to resistance discharge when a set voltage is reached, making it possible to construct an efficient regenerative discharge system for secondary batteries.

10: Battery unit 20: Circuit breaker
30: switch unit 40: power conversion unit
50: Resistance discharge part 60: Temperature sensing part
70: voltage detection unit 80: current detection unit
90: control unit

Claims (6)

In the regenerative discharge system for a secondary battery that performs regenerative discharge by supplying the voltage of the electrically connected battery unit 10 to the power system,
A circuit breaker (20) for controlling the supply of power from the battery unit (10) to the discharge unit,
A switch unit 30 that is set to supply power supplied through the breaker 20 to the power conversion unit 40 and is controlled to switch to the resistance discharge unit 50 under the control of the control unit 90,
When the circuit breaker 20 operates and regenerative discharge begins, a comparison process is performed between the remaining voltage information of the battery unit 10 provided from the voltage detection unit 70 and the set reference voltage to determine the remaining voltage of the battery unit 10. A control unit 90 that controls the switch unit 30 to supply power from the battery unit 10 to the resistance discharge unit 50 to cause resistance discharge when the voltage drops below a set reference voltage;
A temperature sensing unit 60 for detecting the temperature of the battery unit 10 and the resistance discharge unit 50;
Input means for inputting battery information including the type, capacity, or product name of the battery unit 10 to be discharged; and
a storage means for storing reference voltage information for switching from power system discharge to resistance discharge according to battery information, and a display means for displaying the reference voltage information; Including,
The control unit 90 is
Configure a process to display the reference voltage information stored in the storage means through the display means according to the request information input through the input means, and to set the reference voltage stored in the storage means according to the battery information input from the input means; ,
The temperature sensing unit 60 is
If the temperature of the resistance discharge unit 50 is above a predetermined temperature, providing a signal to the circuit breaker 20 to operate the circuit breaker 20 to cut off the voltage of the battery unit 10; A secondary battery regenerative discharge system characterized by The method of claim 1, wherein the control unit 90 monitors the temperature of the resistance discharge unit 50 detected by the temperature detection unit 60 and determines whether the resistance discharge unit 50 is overheated by comparing it with reference temperature information. A secondary battery regenerative discharge system characterized by further comprising a process of controlling the supply voltage of the battery unit 10 to the discharge unit by operating the circuit breaker 20 according to the determination result. According to paragraph 1,
The circuit breaker 20 is composed of a MCCB (middle circuit breaker),
The switch unit 30 includes a switch contact for connecting the input terminal of the battery unit 10, the breaker 20, and the power conversion unit 40; and
An electromagnetic contactor (MG) having a switch contact point for connecting the battery unit 10, the circuit breaker 20, and the input terminal of the resistance discharge unit 50; A secondary battery regenerative discharge system comprising: According to claim 1, the power conversion unit 40 is comprised of a large-capacity inverter so that the voltage of the battery unit 10 can be supplied to the grid through an inverter without a separate voltage boosting process during the regenerative discharge process. Characterized by a secondary battery regenerative discharge system. delete Stores reference voltage information for switching from power system discharge to resistance discharge according to battery information including the type, capacity, or product name of the battery unit 10 to be discharged through an input means, and displays the stored reference voltage information through a display means. and setting a reference voltage for regenerative discharge according to the battery information input from the input means.
When the breaker 20 is turned 'on' and the voltage of the battery unit 10 is supplied along the switch unit 30 where the battery voltage supply path is set for regenerative discharge, regenerative discharge is performed through the power conversion unit 40. step;
The voltage of the battery unit 10 provided from the voltage detection unit 70 is monitored, and when the voltage of the battery unit 10 falls below the reference voltage through comparison with the reference voltage, the battery voltage path is connected to the resistance discharge unit ( 50) switching control of the switch unit 30 to be set to the side; and
Controlling the circuit breaker 20 by determining battery overvoltage and overcurrent; and
A temperature sensing unit (60) monitors the temperature of the resistance discharge unit (50) and controls the circuit breaker (20) when the temperature of the resistance discharge unit (50) rises above a predetermined temperature; A regenerative discharge control method for a secondary battery, comprising: