KR20200140573A - Regenerative battery test device with zero volt complete discharge, Discharge method of that equipment - Google Patents

Abstract

The present invention relates to a regenerative battery test device and a method for discharging a battery using the same. The device comprises: a battery to be charged or discharged; a charging/discharging unit for charging or discharging the battery; and an auxiliary discharging unit for auxiliarily discharging the battery at a predetermined voltage, at which the charging/discharging unit cannot discharge the battery, thereby solving the problem in which a switch burns out due to inrush current caused by a residual voltage remaining on the battery in the process of discharging the battery.

Description

Regenerative battery test device with zero volt complete discharge, Discharge method of that equipment

The present invention relates to a regenerative battery testing apparatus capable of solving the problem that residual current remains in a battery when a battery is discharged by a regenerative switching method, and a discharge method using the same.

Secondary batteries include hydrogen-ion batteries, lithium-ion batteries and lithium polymer batteries, and secondary batteries are increasingly in demand as electronic devices are developed. Such a secondary battery is manufactured through an electrode process, an assembly process, and a charge/discharge process, and in particular, a single secondary battery having a designated arbitrary capacity is produced by repeating the charge/discharge process several times.

Test devices for charging and discharging secondary batteries are divided into regenerative type and linear type devices. Conventionally, among these two methods, there has been an attempt to use a charge/discharge test apparatus using a regenerative method that consumes less energy, but the charge/discharge test apparatus using such a regenerative method has a problem in that the battery cannot be completely discharged. There is a problem in that the switch is burned due to the inrush current generated by the voltage, and recently, a charge/discharge test apparatus using a linear method is used.

However, the battery charging/discharging test apparatus using the linear method, as shown in FIG. 1, connects the positive and negative electrodes of the battery 20 to the positive terminal of the power supply 10, and then uses the power supply 10. When current is applied, power is converted into thermal energy in the switch 30 and the battery is discharged, so there is a problem in that energy consumption is large, as well as a problem that a large cooling device is required due to severe heat generation of the power supply device. .

Accordingly, there is a need for a new battery charge/discharge test apparatus capable of solving such conventional problems.

Patent Document 1) Korean Patent Publication No. 2016-1604419 (Name: Charge/Discharge Tester, Announcement Date: 2016.03.17)

The present invention was conceived to solve the above-described problems, and an object of the present invention is to use a regenerative method that not only can completely discharge the battery, but also prevent burnout of the switch that occurs during the battery discharge process. It is to provide a regenerative battery test apparatus and a battery discharge method using the same.

In detail, when the battery testing device is formed in the regenerative method, the voltage below a certain level is not transmitted to the DC/DC converter, and the battery is not completely discharged due to the line impedance. It solves the conventional problem that was not suitable for battery test.

A regenerative battery testing apparatus according to the present invention for achieving the above object includes, in a regenerative battery testing apparatus for testing a battery by charging or discharging a battery, comprising: a battery 100 to be charged or discharged; A charging/discharging unit 200 for charging or discharging the battery 100; An auxiliary discharge unit 300 connected to the charging/discharging unit 200 and discharging the battery; And a controller (C) for controlling the auxiliary discharge unit 300 based on the battery terminal voltage Vout of the charging/discharging unit. Including, the controller, when the battery terminal voltage (Vout) of the charging and discharging unit is within a predetermined voltage range in which the charging and discharging unit 200 does not discharge the battery 100, the auxiliary discharge unit 300 ) Is characterized in that the control to discharge the battery (100).

In addition, one side is connected to the battery terminal of the charging/discharging unit 200 and the other side is connected to the battery 100, corresponding to the discharge voltage of the battery 100 to be discharged by the charging/discharging unit 200, the Further comprising a switching unit 400 for changing the polarity of the battery 100 connected to the battery terminal of the charging and discharging unit 200, the charging and discharging unit 200, one end of the system power source 211 and directly or a transformer ( It is connected indirectly through 212), and both directions that convert AC voltage to DC or DC voltage to AC voltage?? An AC/DC converter 220, a bidirectional DC/DC converter 230 having one end connected to the other end of the AC/DC converter 220 and converting an input voltage into a designated arbitrary voltage, and one end of the DC It is characterized in that it includes a smoothing capacitor 240 that is connected to the /DC converter 230 and the other end is connected to the switching unit 400 and stabilizes unstable power.

In addition, the auxiliary discharge unit 300 is characterized in that it includes a resistor and a switch.

In addition, the auxiliary discharge unit 300 is characterized in that it includes a semiconductor switch.

In addition, the controller controls to operate the semiconductor switch of the auxiliary discharge unit 300 when the voltage of the battery 100 reaches a certain level or less, so that the residual energy of the battery is consumed in the semiconductor switch and the battery is discharged. Characterized in that.

In addition, the switching unit 400 has a first switch 410 having one end connected to the positive electrode of the smoothing capacitor 240, the other end connected to the positive electrode of the battery, and one end connected to the negative electrode of the smoothing capacitor 240 A second switch 420 having the other end connected to the positive electrode of the battery, a third switch 430 having one end connected to the negative electrode of the smoothing capacitor 240 and the other end connected to the negative electrode of the battery, and one end of the battery It characterized in that it comprises a fourth switch 440 connected to the positive electrode of the smoothing capacitor 240 and the other end connected to the negative electrode of the battery.

The battery discharge method using the regenerative battery test apparatus of the present invention for achieving the above object is such that the voltage difference between the battery terminal voltage Vout of the charging/discharging unit 200 and the battery voltage Vbat is less than a certain level. An initial charging step of charging the smoothing capacitor 240; A primary discharging step of discharging the battery 100 using the charging/discharging unit 200 until the battery terminal voltage Vout of the charging/discharging unit 200 falls below a predetermined voltage threshold; A secondary discharging step of discharging the battery 100 by using the auxiliary discharging unit 300 when the battery terminal voltage Vout of the charging/discharging unit 200 is less than a predetermined voltage threshold; It characterized in that it comprises a.

In addition, the initial charging step may include a voltage comparison step (S110) of comparing the battery voltage (Vout) of the charging/discharging unit 200 with the battery voltage (Vbat); Voltage for controlling the charging/discharging unit so that the battery terminal voltage Vout of the charging/discharging unit increases when the battery terminal voltage Vout of the charging/discharging unit 200 in the voltage comparing step S110 is smaller than the battery voltage Vbat Adjusting step (S120); When the two voltages compared in the voltage comparison step (S110) coincide with each other, some of the switches constituting the switching unit 400 are operated to provide an electrode of the battery 100 at the battery terminal of the charging/discharging unit 200. A forward switch operation step (S130) connecting the forward direction; It characterized in that it comprises a.

In addition, it is located between the first discharge step (S210) and the second discharge step (S230), the voltage (Vout) measured at the battery terminal of the charging and discharging unit 200 and the line impedance 510 A first discharge check step (S220) of performing the second discharge step (S230) when the voltage difference is greater than 0V after checking whether the difference between the voltage (V _RL ) is less than 0V; When it is confirmed that the voltage difference identified in the first discharge check step (S220) is 0V or less, a second discharge check step of checking whether the voltage (V _RL ) difference between the voltage of the battery 100 and the line impedance 510 is less than 0V (S240); When the voltage difference is greater than or equal to 0V in the second discharge check step (S240), a first discharge re-execution step (S250) of lowering the battery terminal voltage (Vout) of the charging/discharging unit 200 and then re-executing the first discharge step (S210) (S250). ; And a reverse direction in which the electrode of the battery 100 is connected to the battery terminal of the charging/discharging unit 200 in a reverse direction when it is confirmed that the voltage difference is less than 0V in the second discharge checking step (S240). Switch operation step (S260); It characterized in that it comprises a.

In addition, a reverse battery discharging step of discharging the battery 100 for a third time after changing the electrode of the battery 100 connected to the battery terminal of the charging/discharging unit 200 using the switching unit 400 (S300) It characterized in that it further includes;

In addition, a reverse battery discharging step of discharging the battery 100 for a third time after changing the electrode of the battery 100 connected to the battery terminal of the charging/discharging unit 200 using the switching unit 400 (S300) It characterized in that it further includes;

In addition, the reverse battery discharging step includes a third discharging step (S310) of discharging the battery 100 through CC (constant current) control while increasing the voltage of the charging/discharging unit 200; A third discharge check step (S320) of checking whether the voltage (Vbat) of the battery 100 is less than 0V; A second discharge re-execution step (S330) of re-executing the third discharge step (S310) when the voltage is 0V or more in the third discharge check step (S320); A terminating step (S340) of terminating discharging when the voltage measured in the third discharge checking step (S320) is less than 0V; It characterized in that it comprises a.

In the battery testing apparatus of the present invention, after first discharging the battery by using the charging/discharging unit, a low voltage that is difficult to discharge by the charging/discharging unit can be secondarily discharged by the auxiliary discharge unit. Therefore, if residual voltage remains in the battery, the power supply unit and the There is an advantage of solving the problem that switch burnout may occur due to inrush current due to a potential difference of the battery and constant current discharge is impossible.

In addition, since it is possible to apply a reverse voltage to the battery by using the switching unit, the voltage difference between the charging/discharging unit and the battery is increased and the battery is discharged for the third time, thereby more completely discharging the residual voltage of the battery.

In addition, when the battery voltage direction is changed, a section in which the voltage difference between the output voltage of the power supply device and the voltage of the battery rapidly increases is solved by using the auxiliary discharge unit to apply a reverse voltage to discharge the battery. There is an advantage of solving the problem that the voltage difference is increased and the load is applied to the battery testing device.

1 is a conceptual diagram showing a battery charging and discharging test apparatus using a conventional linear method.
2 is a circuit diagram showing a regenerative battery test apparatus according to a first embodiment of the present invention.
3 to 5 are graphs showing the battery voltage, the voltage at the anode end of the battery, and the voltage at the battery end of the charging/discharging unit in a discharge situation.
6 is a circuit diagram showing a regenerative battery test apparatus according to a second embodiment of the present invention.
7 is a circuit diagram showing a regenerative battery test apparatus according to a third embodiment of the present invention.
Figure 8 is a block diagram showing a battery discharge method using the present inventors regenerative battery testing apparatus.

Advantages and features of the embodiments of the present invention, and a method of achieving them will become apparent with reference to the embodiments described later in detail together with the accompanying drawings. However, the present invention is not limited to the embodiments disclosed below, but may be implemented in a variety of different forms, and only these embodiments make the disclosure of the present invention complete, and common knowledge in the technical field to which the present invention pertains. It is provided to completely inform the scope of the invention to those who have, and the invention is only defined by the scope of the claims. The same reference numerals refer to the same elements throughout the specification.

In describing the embodiments of the present invention, if it is determined that a detailed description of a known function or configuration may unnecessarily obscure the subject matter of the present invention, a detailed description thereof will be omitted. In addition, terms to be described later are terms defined in consideration of functions in an embodiment of the present invention, which may vary according to the intention or custom of users or operators. Therefore, the definition should be made based on the contents throughout this specification.

Hereinafter, with reference to the accompanying drawings will be described with respect to the expansion joint device 1000 according to the present invention.

2 is a circuit diagram showing a regenerative battery testing apparatus 1000 according to a first embodiment of the present invention, and FIGS. 3 to 5 are diagrams showing changes in the battery voltage Vbat and the voltage at the positive end of the battery Vab appearing in a discharge situation. It is a graph.

Referring to FIG. 2, the regenerative battery testing apparatus 1000 according to the present invention includes a battery 100 to be charged or discharged, a charging/discharging unit 200 for charging or discharging the battery 100, and the charging/discharging unit ( The auxiliary discharge unit 300 is connected to 200 and discharges the battery, and a controller C that controls the auxiliary discharge unit 300 based on the battery end voltage Vout of the charging/discharging unit. , The controller C, when the battery terminal voltage Vout of the charging/discharging unit 200 is within a predetermined voltage range in which the charging/discharging unit 200 does not discharge the battery 100, the auxiliary room All 300 are controlled to discharge the voltage Vab of both ends of the battery 100.

가 배터리(100)와 배터리(100)의 양단전압(Vab) 차만큼 크게 흐르게 된다.When described with reference to FIG. 3. When the charging/discharging unit 200 applies a voltage to the battery 100 in a positive direction to discharge the battery 100, as shown in FIG. 3, the battery voltage Vbat remains without falling below a certain value. The voltage at both ends (Vab) of (100) also does not drop to 0V. Therefore, in order to completely discharge the battery, the battery 100 must be discharged by applying a voltage in the reverse direction to the battery again. However, since the magnitude of the reverse voltage applied to discharge the battery 100 is determined by a value corresponding to the voltage at both ends (Vab) of the battery 100, the voltage at both ends (Vab) of the battery 100 is not 0V. When applying a reverse voltage to the battery 100 in the state, the difference between the battery voltage Vbat and the voltage at both ends (Vab) of the battery 100 is determined by the following Equation 1), and thus increases rapidly,

Is flowed as large as the difference between the voltages Vab at both ends of the battery 100 and the battery 100.

Equation 1)

Therefore, when applying a reverse voltage while not lowering the voltage at both ends (Vab) of the battery 100 to 0V, as shown in FIG. 4, the first discharge section (t1) and the reverse voltage to which a constant voltage is applied to the battery are applied. Since there is a problem that the inrush current (r) is generated between the third discharge section (t3) that is used, in the present invention, as shown in FIG. 5, between the first discharge section (t1) and the third discharge section (t3). A second discharge section (t2) for discharging the residual current is formed using the auxiliary discharge unit 300 to make the voltage at both ends of the battery (Vab) to 0V, and then apply a reverse voltage to the battery 100 for the third discharge. By doing so, when the reverse voltage is applied, the difference between the voltage across the battery 100 (Vab) and the voltage (Vbat) of the battery 100 becomes greater than a specified value and prevents instantaneous transient current from occurring.

In detail, in the present invention, since the discharge of the battery 100 is performed in a CC (constant current) method that gradually lowers the discharge voltage while maintaining a constant current, the voltage of the battery is the first discharge section. As shown in (t1), since it has a linear function shape and is stably lowered, the accurate discharge time of the battery is also predictable based on this linear voltage change, so that the battery discharge current is constant in the constant current discharge. It is very important to keep it. However, as described with reference to FIG. 4 above, when the difference between the voltage Vbat of the battery 100 and the voltage Vab at both ends of the battery 100 increases, and an inrush current occurs, the voltage increases over time if the discharge current is kept constant. Since it deviates from the basic mechanism of constant current discharge that decreases in the form of a linear function in proportion, there is a problem that the charging time of the constant current discharge battery cannot be predicted. There is also a problem that the driving cannot be performed. Accordingly, in the present invention, as shown in FIG. 5, the second discharge section (t2) discharges the residual current by using the auxiliary discharge unit 300 between the first discharge section (t1) and the third discharge section (t3). ), and after making the voltage at both ends of the battery (Vab) to 0V, a reverse voltage is applied to the battery 100 to discharge it for the third time. When the reverse voltage is applied, the voltage at both ends of the battery 100 (Vab) and the battery 100 The difference in voltage (Vbat) increases beyond a specified value and prevents instantaneous transient current from occurring.

6 is a circuit diagram showing a regenerative battery testing apparatus 1000 according to a second embodiment of the present invention. 2 and 6, the auxiliary discharge unit 300 includes a resistor 310 and a discharge switch connected to a wire connecting the charging/discharging unit 200 and the battery 100 as shown in FIG. 2. 320, or may include a semiconductor switch 330 passing only a current having a voltage of a predetermined or higher voltage as shown in FIG. 6.

In detail, the auxiliary discharge unit 300 first discharges the battery 100 through CC (constant current) control, and then performs the second discharge to adjust the voltage at both ends (Vab) of the battery 100. By making it to 0V, it is a device for preventing the difference between the voltage at both ends (Vab) and the battery voltage (Vbat) of the battery 100 from increasing when the third discharge through the reverse current is performed.The voltage of the battery is lowered and the charging/discharging unit ( Since it is sufficient if it is possible to remove the residual voltage remaining without moving to 200), the auxiliary discharge unit 300 is composed of a resistor 310 and a discharge switch 320, as shown in FIG. At this point, the discharge switch 320 is turned on by the control of the controller C so that the residual voltage is discharged at the resistor 310, or the auxiliary discharge unit 300 is turned to the semiconductor switch 330 as shown in FIG. After configuration, the controller C controls the semiconductor switch 330 to operate in the linear region, so that the residual voltage at both ends of the battery is consumed by the semiconductor switch 330 so that the voltage at both ends of the battery (Vab) is close to 0V. I did it.

7 shows a regenerative battery testing apparatus according to a third embodiment of the present invention.

5, the regenerative battery testing apparatus 1000 according to the present invention has one end connected to the battery end of the charging/discharging unit 200, and the other end connected to the positive electrode of the battery 100, so that the charging/discharging unit 200 In response to the discharge voltage of the battery 100 to be discharged at, a switching unit 400 for changing the polarity of the battery 100 connected to the battery terminal of the charging/discharging unit 200 may be further included, and the The switching unit 400 has a first switch 410 having one end connected to the positive electrode of the smoothing capacitor 240 located at the battery end of the charging/discharging unit 200, the other end connected to the positive electrode of the battery, and A second switch 420 connected to the negative electrode of the smoothing capacitor 240, the other end connected to the positive electrode of the battery, and one end connected to the negative electrode of the smoothing capacitor 240 and the other end connected to the negative electrode of the battery. A third switch 430 and a fourth switch 440 having one end connected to the positive electrode of the smoothing capacitor 240 and the other end connected to the negative electrode of the battery may be included.

In detail, as described above, the smoothing capacitor 240 positioned at the battery terminal of the charging/discharging unit 200 and the positive and negative terminals of the battery 100 are connected to each other. At this time, the primary discharge of the battery 100 is performed by gradually lowering the voltage of the charging/discharging unit 200 through CC (Constant Current) control after connecting the charging/discharging unit 200 to the positive electrode of the battery 100, The secondary discharge is performed by the operation of the auxiliary discharge unit 300, and the third discharge is performed by changing the polarity of the battery 100 and then controlling the voltage of the charging/discharging unit 200 through CC (constant current) control. It progresses gradually increasing it. In this case, since the voltage of the battery 100 needs to be changed from the forward direction to the reverse direction in the process of performing the third discharge after the second discharge, in the present invention, the switching unit 400 is connected to the positive electrode of the battery 100. It consists of a switch 410 and a second switch 420, a third switch 430 connected to the negative electrode of the battery 100, and a fourth switch, and the first switch 410 and the third switch are When the switch 430 is turned on, the voltage of the battery 100 is positioned in the forward direction, and when the second switch 420 and the fourth switch 440 are operated in the third discharge, the voltage of the battery 100 is positioned in the reverse direction. I did it. At this time, since current flows from the negative electrode of the battery to the positive electrode during the third discharge, if the battery terminal voltage of the charging/discharging unit 200 is gradually increased through CC (constant current) control, the battery voltage becomes negative It goes without saying that the battery can be discharged more completely because the difference from the battery voltage becomes larger.

In addition, the charging/discharging unit 200 has one end connected directly to the system power source 211 or indirectly through a transformer 212, and a bidirectional AC/DC that converts AC voltage to DC or converts DC voltage to AC voltage. A converter 220, a bidirectional DC/DC converter 230 having one end connected to the other end of the AC/DC converter 220 and converting an input voltage into a designated arbitrary voltage, and one end of the DC/DC converter It goes without saying that it is connected to 230 and the other end is connected to the switching unit 400 and may include a smoothing capacitor 240 to stabilize unstable power.

8 is a block diagram of a battery discharge method using the regenerative battery test apparatus described above.

7 and 8, the battery discharging method is the initial charging of the smoothing capacitor 240 so that the voltage difference between the battery terminal voltage Vout of the charging/discharging unit 200 and the battery voltage Vbat is less than a certain level. A charging step and a primary discharging step of discharging the battery 100 using the charging/discharging unit 200 until the battery terminal voltage Vout of the charging/discharging unit 200 falls below a predetermined voltage threshold ( S210 and, when the battery terminal voltage Vout of the charging/discharging unit 200 is less than or equal to a predetermined voltage threshold, a secondary discharging step of discharging the battery 100 using the auxiliary discharging unit 300 (S230) ), and a reverse battery discharging step (S300) of third-discharging the battery 100 after changing the electrode of the battery 100 connected to the battery terminal of the charging/discharging unit 200 using the switching unit 400 It may include.

In detail, by minimizing the difference between the voltage of the battery and the voltage of the battery end of the smoothing capacitor 240 in the initial charging step (S100), when the voltage difference between the voltage of the smoothing capacitor 240 and the battery is more than a certain amount, the battery is discharged. After solving the problem that does not proceed stably, and discharging the voltage at the anode end of the battery to close to 0V through the first discharging step (S210) and the second discharging step (S230), in the reverse battery discharging step (S300) By applying a reverse voltage to the battery 100 using the switching unit 400, the battery is completely discharged through the third discharge.

At this time, the initial charging step (S100) includes a voltage comparing step (S110) comparing the battery end voltage (Vout) of the charging/discharging unit 200 with the voltage (Vbat) of the battery (1), and the voltage comparing step ( In S110), when the battery terminal voltage Vout of the charging/discharging unit 200 is smaller than the battery voltage Vbat, a voltage adjusting step of controlling the charging/discharging unit to increase the battery terminal voltage Vout of the charging/discharging unit (S120) And, when the two voltages compared in the voltage comparison step (S110) coincide with each other, some of the switches constituting the switching unit 400 are operated so that the battery 100 is placed at the battery terminal of the charging/discharging unit 200. It may include a forward switch operating step (S130) connecting the electrodes of the forward direction.

And, after operating the first switch 410 and the third switch 430 in the forward switch operation step (S130), the first discharge step (S210) and the third discharge step (S230) are executed. , Between the first discharge step (S210) and the second discharge step (S230), the voltage (Vout) measured at the battery terminal of the charging/discharging unit 200 and the switching unit 400 and the smoothing capacitor 240 After checking whether the difference between the voltage (V _RL ) measured in the line 510 is less than 0V, when the voltage difference is greater than 0V, a first discharge check step (S220) of executing the second discharge step (S230) may be located. Then, when it is confirmed that the voltage difference identified in the first discharge check step (S220) is 0V or less, the voltage of the battery 100 and the line 510 located between the switching unit 400 and the smoothing capacitor 240 The second discharge check step (S240) of checking whether the voltage difference of is less than 0V, and the battery end voltage (Vout) of the smoothing capacitor 240 when the voltage difference is determined to be 0V or more in the second discharge check step (S240) The switching unit 400 when the voltage difference is less than 0V in the first discharge re-execution step (S250) and the second discharge check step (S240) to re-execute the first discharge step (S210) after lowering. ) To connect the electrode of the battery 100 to the battery terminal of the charging/discharging unit 200 in a reverse direction (S260).

Thereafter, the reverse battery discharging step (S300) is performed, and in the reverse battery discharging step (S300), the first switch 410 and the third switch 430 are turned off in the reverse switch operation step (S260), After the second switch 420 and the fourth switch 440 are turned on, the voltage of the charging/discharging unit 200 is increased through CC (constant current) control, and the battery 100 is discharged. Discharge step (S310) and a second discharge check step (S320) of re-executing the third discharge step (S310) when the voltage to be checked after checking whether the voltage (Vbat) of the battery 100 is less than 0V is 0V or more, and If the voltage measured in the second discharge check step (S320) is less than 0V, a completion step (S330) of turning off all switches constituting the switching unit 400 and turning off the bidirectional DC/DC converter 230 is performed. Can include.

The present invention is not limited to the above-described embodiments, and the scope of application thereof is diverse, as well as anyone with ordinary knowledge in the field to which the present invention belongs without departing from the gist of the present invention claimed in the claims. Of course, various modifications are possible.

100: battery
200: charging and discharging unit 210: rectified power
220: AC/DC converter 230: DC/DC converter
240: smoothing capacitor
300: auxiliary discharge unit
400: switching unit 410: first switch
420: second switch 430: third switch
440: fourth switch
S100: Initial charging step S110: Voltage comparison step
S120: voltage control step S130: forward switch operation step
S200: forward battery discharge step S210: primary discharge step
S220: first discharge check step S230: second discharge step
S240: second discharge confirmation step S250: first discharge re-execution step
S260: Reverse switch operation step
S300: reverse battery discharge step S310: third discharge step
S320: second discharge confirmation step S330: completion step

Claims (10)

In the regenerative battery testing apparatus for testing the battery by charging or discharging the battery,
A battery 100 to be charged or discharged;
A charging/discharging unit 200 for charging or discharging the battery 100;
An auxiliary discharge unit 300 connected to the charging/discharging unit 200 and discharging the battery; And
A controller (C) for controlling the auxiliary discharge unit 300 based on the battery terminal voltage Vout of the charging/discharging unit; Including,
The controller, when the battery terminal voltage (Vout) of the charging and discharging unit is within a predetermined voltage range in which the charging and discharging unit 200 does not discharge the battery 100, the auxiliary discharging unit 300 is Regenerative battery testing apparatus, characterized in that controlling to discharge (100).
The method of claim 1,
One side is connected to the battery terminal of the charging/discharging unit 200 and the other side is connected to the battery 100, corresponding to the discharge voltage of the battery 100 to be discharged by the charging/discharging unit 200, the charging/discharging unit Further comprising a switching unit 400 for changing the polarity of the battery 100 connected to the battery terminal of (200),
The charging and discharging unit 200,
One end is directly connected to the grid power 211 or indirectly through the transformer 212, and it is a bidirectional that converts AC voltage to DC or converts DC voltage to AC voltage?? An AC/DC converter 220,
A bidirectional DC/DC converter 230 having one end connected to the other end of the AC/DC converter 220 and converting an input voltage into a designated arbitrary voltage,
One end is connected to the DC / DC converter 230, the other end is connected to the switching unit 400, characterized in that it comprises a smoothing capacitor (240) for stabilizing unstable power, regenerative battery testing apparatus.
The method of claim 2,
The auxiliary discharge unit 300, characterized in that including a resistor and a switch, regenerative battery testing apparatus.
The method of claim 2,
The auxiliary discharge unit 300 is characterized in that it comprises a semiconductor switch, regenerative battery testing apparatus.
The method of claim 4,
The controller controls to operate the semiconductor switch of the auxiliary discharge unit 300 when the voltage of the battery 100 reaches a certain level or less, so that the residual energy of the battery is consumed in the semiconductor switch and the battery is discharged. Characterized in, regenerative battery test apparatus.
In the battery discharging method using the regenerative battery testing device of any one of claims 2 to 5,
An initial charging step of charging the smoothing capacitor 240 so that a voltage difference between the battery terminal voltage Vout of the charging/discharging unit 200 and the battery voltage Vbat is less than a predetermined value;
A primary discharging step of discharging the battery 100 using the charging/discharging unit 200 until the battery terminal voltage Vout of the charging/discharging unit 200 falls below a predetermined voltage threshold;
A secondary discharging step of discharging the battery 100 by using the auxiliary discharging unit 300 when the battery terminal voltage Vout of the charging/discharging unit 200 is less than a predetermined voltage threshold; It characterized in that it comprises a, battery discharge method.
The method of claim 6,
The initial charging step,
A voltage comparison step (S110) of comparing the battery end voltage (Vout) of the charging/discharging unit 200 with the voltage (Vbat) of the battery (1);
Voltage for controlling the charging/discharging unit so that the battery terminal voltage Vout of the charging/discharging unit increases when the battery terminal voltage Vout of the charging/discharging unit 200 in the voltage comparing step S110 is smaller than the battery voltage Vbat Adjusting step (S120);
When the two voltages compared in the voltage comparison step (S110) coincide with each other, some of the switches constituting the switching unit 400 are operated to provide an electrode of the battery 100 at the battery terminal of the charging/discharging unit 200 A forward switch operation step (S130) connecting the forward direction; It characterized in that it comprises a, battery discharge method.
The method of claim 7,
It is located between the first discharging step (S210) and the second discharging step (S230), the voltage (Vout) measured at the battery terminal of the charging and discharging unit 200, the switching unit 400 and the smoothing capacitor ( 240) a first discharge check step (S220) of executing the second discharge step (S230) when the voltage difference is greater than 0V after checking whether the difference between the voltage (V _RL ) measured in the line 510 located between it is less than 0V ;
When it is confirmed that the voltage difference identified in the first discharge confirmation step (S220) is 0V or less, the voltage Vbat of the battery 100 and the line located between the line switching unit 400 and the smoothing capacitor 240 ( A second discharge check step (S240) of checking whether the voltage (V _RL ) difference of 510) is less than 0V;
When the voltage difference is greater than or equal to 0V in the second discharge check step (S240), a first discharge re-execution step (S250) of lowering the battery terminal voltage (Vout) of the charging/discharging unit 200 and then re-executing the first discharge step (S210) (S250). ; And
A reverse switch for connecting the electrode of the battery 100 to the battery terminal of the charging/discharging unit 200 in the reverse direction by operating the switching unit 400 when it is confirmed that the voltage difference is less than 0V in the second discharge checking step (S240) Operation step (S260); It characterized in that it comprises a, battery discharge method.
The method of claim 6,
A reverse battery discharging step (S300) of third-discharging the battery 100 after changing an electrode of the battery 100 connected to the battery terminal of the charging/discharging unit 200 using the switching unit 400; Characterized in that it further comprises. How to discharge the battery.
The method of claim 9,
The reverse battery discharging step includes a third discharging step (S310) of discharging the battery 100 through constant current control while increasing the voltage of the charging/discharging unit 200;
A second discharge confirmation step (S320) of re-executing the third discharge step (S310) when the voltage (Vbat) of the battery 100 is less than 0V and then the checked voltage is 0V or more;
A completion step (S330) of turning off all switches constituting the switching unit 400 and the bidirectional DC/DC converter 230 when the voltage measured in the second discharge checking step (S320) is less than 0V; Characterized in that it comprises a. How to discharge the battery.

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