JPH06205540A - Charger and discharger - Google Patents

Abstract

(57) [Abstract] [Object] The present invention relates to a charging device and a discharging device for charging and discharging a battery, and a charging switch for each battery,
An object of the present invention is to provide a discharging switch and a measuring switch, and switch them to connect to a charging loop or a discharging loop to enable charging and discharging independently for each battery with a simple configuration. [Configuration] A charging switch 2 provided for each battery 1 is switched to be serially connected to a charging loop, and when the measurement switch 4 is switched to full charge, the charging switch 2 is switched to be removed from the charging loop. Constitute. Further, the discharging switch 3 provided for each battery is switched to be connected in series to the discharging loop, and when the measuring switch 4 is switched to finish discharging, the discharging switch 3 is switched to be removed from the discharging loop. Further, both are integrated to manufacture a charging / discharging device.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a charging device and a discharging device for charging and discharging a battery.

[0002]

2. Description of the Related Art Conventionally, when individual batteries are independently charged under different charging conditions or discharged under discharging conditions,
A power source (load) for charging and discharging, a voltmeter, and a controller are provided for one battery.

Further, instead of providing the above-mentioned power source (load) or the like for each battery, the power source (load) is shared and the connected battery groups are collectively charged (discharged).

[0004]

If the power source (load), the voltmeter, and the controller are provided for each battery as in the former case, the equipment becomes large and expensive. There was a problem that it would end up.

Further, when the power source (load) for connecting the batteries is shared as in the latter case described above, there is a problem in that the batteries cannot be charged or discharged independently. In order to solve these problems, the present invention provides a charging switch, a discharging switch, and a measuring switch for each battery, and connects the batteries in series with the charging switch in the charging loop to charge the batteries independently. The battery can be independently charged, discharged and measured by connecting the battery in series to the discharge loop with a discharge switch to discharge the battery independently or by switching the measurement switch to measure the voltage independently of the battery. The purpose is to have a simple structure and be inexpensive.

[0006]

[Means for Solving the Problems] Means for solving the problems will be described with reference to FIG. In FIG. 1, a charging switch 2 is for connecting the batteries 1 in series in a charging loop.

The discharge switch 3 connects the batteries 1 in series in the discharge loop. The measuring switch 4 connects the battery 1 to the measuring device 12 individually. The charging power source 5 generates a charging loop.

The load 6 creates a discharge loop.

[0009]

According to the present invention, as shown in FIG. 1, a charging switch 2 and a measuring switch 4 are provided for each battery 1, and
A charging power source 5 is provided, the measurement switch 4 is switched, the battery 1 is connected to the measuring device 12, and measurement is performed. When the battery is not fully charged (or when a charging instruction is issued), the charging switch 2
, And connect the battery 1 in series in the charging loop,
On the other hand, switching of the charging switch 2 to remove the battery 1 from the charging loop at the time of full charge is sequentially repeated for all the batteries 1 so that each battery 1 is independently charged.

At this time, the charging power source 5 for generating a plurality of charging loops is provided, and the charging switch 2 is switched to the charging loop designated for each battery 1 and connected in series to perform charging.

Further, a discharging switch 3 and a load 6 are provided, and when the battery 1 is fully charged (or when a discharging instruction is issued), the discharging switch 3 is switched to switch the battery 1 concerned.
Are connected in series in the discharge loop to start discharging, the measurement switch 4 is switched to connect the battery 1 to the measuring device 12, and measurement is performed. When the discharge is completed, the discharge switch 3 is switched to discharge the battery 1. The removal from the loop is sequentially repeated for all the batteries 1 so that each battery 1 is independently discharged.

At this time, a load 6 for generating a plurality of discharge loops is provided, and the discharge switch 3 is switched to the discharge loop designated for each battery 1 and connected in series to discharge.

Therefore, a charging switch 2, a discharging switch 3 and a measuring switch 4 are provided for each battery 1, and the charging switch 2 is switched to connect the battery 1 to the charging loop for independent charging or discharging. The charging switch 3 is switched to connect the battery 1 to the discharging loop to discharge independently, or the measuring switch 4 is switched to measure the voltage of the battery 1 and the like individually to charge and discharge the battery 1 independently. It becomes possible to measure. As a result, the structure of the charging device and the discharging device can be simplified and manufactured at low cost, and the charging and discharging device can be manufactured by integrating them.

[0014]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Next, the construction and operation of an embodiment of the present invention will be described in detail with reference to FIGS.

FIG. 1 shows a block diagram of an embodiment of the present invention.
In FIG. 1, a battery 1 is a battery to be charged or discharged. The charging switch 2 connects the battery 1 in series in the charging loop, takes out what was connected in series in the charging loop from the charging loop, etc., and is associated with the battery 1. It is provided for charging each battery 1 independently.

The discharge switch 3 is used to connect the battery 1 in series in the discharge loop or to take out what is connected in series in the discharge loop from the discharge loop. The battery 1 provided in association with
This is to discharge each independently.

The measuring switch 4 connects the battery 1 to the measuring device 1
It is intended to measure the voltage and the like separately connected to the battery 2, and is provided in association with the battery 1 to measure the voltage and the like independently for each battery 1.

The charging power source 5 generates a charging loop, and here, generates a charging loop that supplies, for example, a constant current to the batteries 1 connected in series.
The load 6 is for generating a discharge loop, and here is for generating a discharge loop, which is, for example, a constant current load, in the batteries 1 connected in series.

The microcomputer 7 performs various controls according to a program, and here, the charging control section 8-1,
Discharge control unit 8-2, charge / discharge determination 9, current state file 1
0, and the charge / discharge condition setting file 11 and the like.

The charging control section 8-1 sends a charging switch switching signal to turn on / off the charging switch 2 to charge the battery 1. The discharge control unit 8-2 sends a discharge switch switching signal to turn on the discharge switch 3.
/ OFF to discharge the battery 1.

For charge / discharge determination 9, the charging switch 2 is turned on.
To charge the battery 1 to determine whether it has reached the upper limit voltage and have completed charging, or to turn on the discharge switch 3 to discharge the battery 1 to determine if it has reached the final voltage and have completed discharging. (See FIG. 2).

The current status file 10 stores the current status (charging, discharging, stopping, etc.) of each channel of the battery 1 and the number of charge / discharge cycles.

The charge / discharge condition setting file 11 stores the charge upper limit voltage, charge end voltage, end cycle, etc. for each channel of the battery 1. The measuring device 12 turns on / off the measuring switch 4 to sequentially measure the voltage of the battery 1 and the like.

Next, the operation of the configuration of FIG. 1 will be described in detail in the order shown in the flowchart of FIG. In FIG. 2, S1 is initially set to CH = 1. For example, the initial setting is CH = 001 of the battery 1 in FIG.
The processes from S1 to S2 are executed.

In step S2, the contents of the current state file and charge / discharge condition setting file are read. For example, the contents shown in FIGS. 3 and 4 are read as the current state file 10 and the charge / discharge condition setting file 11. here, -Charging / discharging condition setting file Read the channel upper limit voltage, discharge end voltage, end cycle number 01 3.0 1.0 100 and its contents.

In step S3, it is determined whether or not it has ended. If yes, then continue with S10. If NO, the process proceeds to S4. S4
Turns on the measurement switch. As a result, for example, S001 of the measuring switch 4 in FIG. 1 is turned on, and CH001 of the battery 1 is connected to the measuring device 12.

In step S5, the voltage is fetched. In S4, the measuring switch 4 is turned on, and the voltage of the battery 1 is measured by the measuring device 1.
2 takes in. In S6, it is determined whether the battery is in a charged state. this is,
Whether the battery 1 that has received the voltage in S5 is in a charged state, that is, S2
For example, it is determined whether the current state of the current state file 10 shown in FIG. In the case of YES, the current state has been found to be the "charged state", and therefore the processing relating to charging in S7 to S9 is performed. On the other hand, in the case of NO in S6, the current state is found to be the "discharged state", so the flow proceeds to S12.

In S7, since the charge state is found in S6,
It is determined whether or not the current voltage is the upper limit voltage (the charge upper limit voltage set in the charge / discharge condition setting file 11 (here, it indicates full charge)). In the case of YES, it is found that the charging voltage is equal to the upper limit voltage, so that the charging switch 2 is turned on in S8.
The FF and discharge switch 3 are turned on to switch from charging to discharging. Then, in S9, the current state “discharge” is stored in the current state file, and the process proceeds to S10.

In step S10, it is determined whether the channel is the final channel. YE
In the case of S, the process returns to S1 and is repeated from the beginning. On the other hand, in the case of NO, CH = CH + 1 is set in S11, and S2 and subsequent steps are repeatedly executed for the next channel.

Further, in S12, since the discharge state is determined by NO in S6, it is determined whether or not the cutoff voltage (representing the discharge completed state). In the case of YES, the discharge end voltage has been determined, so the discharge switch 3 is turned off in S13, and the battery 1 is removed from the charging loop. Then, the process proceeds to S14.

In step S14, it is determined whether it is the end cycle. This determines whether the number of cycles of the current state file 10 is equal to the number of end cycles of the charge / discharge condition setting file 11 read in S2. In the case of YES, since the charging / discharging cycle of the battery 1 has been repeated, the end flag is turned ON in S18, and the fact that the current state file 10 is completed is stored in S19. On the other hand, if NO in S14,
The number of cycles is incremented by 1 in S15, the charging switch is turned on in S16, and stored in the current state file 10 in S17. Then, the process proceeds to S10, it is determined whether it is the last channel, and Y
If ES, return to S1; if NO, S11 to CH
= CH + 1 and returns to S2.

As described above, the contents of the current state file 10 and the charge / discharge condition setting file 11 are read for each channel of the battery 1, the measurement switch 4 is turned on, and the battery 1 is read.
When the current state is "charging", it is determined whether it is the upper limit voltage, and when YES is determined that the charging is completed, the charging switch 2 is turned off and the discharging switch 3 is turned on.
And set the current state of the current state file to "discharged". On the other hand, when the current state is “discharge”, it is determined whether it is the end voltage, and when the result is YES, it is determined that the discharge is completed, the discharge switch 3 is turned off, the charging switch 2 is turned on, and the current state of the current state file is Set to “charge”. As a result, it becomes possible to perform voltage measurement, charge, and discharge independently for each battery 1.

FIG. 3 shows an example of the present state file of the present invention. The current state file 10 is a file that stores the current state of each battery 1, and stores the following information. Here, the channel represents the channel of the battery 1 in FIG. 1, the current state represents the current state of the battery 1, and the number of cycles represents the number of times of repeating charging / discharging up to the present.

FIG. 4 shows an example of the charge / discharge condition setting file of the present invention. The charge / discharge condition setting file 11 is a file that stores a charge / discharge state for each battery 1, and stores the following information.

Channel charge upper limit voltage Discharge end voltage Termination cycle 01 3.0 1.0 1.0 100 02 1.5 0.5 0.5 10 03 3.5 2.0 100 FIG. 5 shows an example of the switch of the present invention. This switch
An example of the charging switch 2 and the discharging switch 3 of FIG. 1 is shown.

In FIG. 5, the input is a portion connected in series with the charging loop generated by the charging power source 5 or the discharging loop generated by the load 6. The output is the part where the battery 1 is connected.

In the state described as short circuit, the input HI and LO are short-circuited, the charge loop or the discharge loop is short-circuited, and the battery 1 connected to the output is removed from the charge loop or the discharge loop. Indicates the status.

FIG. 6 shows an example of multiple loops of the present invention. In FIG. 6, the charging loop (1) and the charging loop (2)
Are different constant current loops generated by the charging power supply 5, respectively.

Discharge loop (1) and discharge loop (2)
Are different constant current loops respectively generated by the load 6, and discharge the battery 1. Here, R1 and R2 are provided as the charging switch 2 in order to connect the battery 1 in series to the charging loop (1). Similarly, R11 and R12 are provided as the charging switch 2 for connecting the battery 1 in series to the charging loop (2).

Further, T1 and T2 are provided as the discharge switch 3 for connecting the battery 1 in series to the discharge loop (1). Similarly, in order to connect the battery 1 in series to the discharge loop (2), T11 and T12 are used as the charging switch 2.
Is provided.

In this state of FIG. 6, R1, R2: short circuit, R11: battery 1 (CH001) is charged, R12: short circuit, T1, T2: short circuit, T11: short circuit, T12: battery 1 (CH002) is discharged. Is set.

[0042]

As described above, according to the present invention,
A charging switch 2, a discharging switch 3, and a measuring switch 4 are provided for each battery 1, and the charging switch 2 is switched to connect the battery 1 to a charging loop for independent charging,
Since the configuration is such that the discharge switch 3 is switched to connect the battery 1 to the discharge loop to discharge independently, or the measurement switch 4 is switched to measure the voltage of the battery 1 or the like, It can be charged, discharged and measured independently. As a result, the structure of the charging device and the discharging device can be simplified and manufactured at low cost, and the charging / discharging device can be manufactured at low cost by integrating the charging device and the discharging device.

[Brief description of drawings]

FIG. 1 is a configuration diagram of an embodiment of the present invention.

FIG. 2 is a flowchart explaining the operation of the present invention.

FIG. 3 is an example of a current state file of the present invention.

FIG. 4 is an example of a charge / discharge condition setting file of the present invention.

FIG. 5 is an example of a switch of the present invention.

FIG. 6 is an example of multiple loops of the present invention.

[Explanation of symbols]

 1: Battery 2: Charge switch 3: Discharge switch 4: Measurement switch 5: Charge power supply 6: Load 7: Microcomputer 8-1: Charge control unit 8-2: Discharge control unit 9: Charge / discharge determination 10: Current status file 11: Charge / discharge condition setting file 12: Measuring device

Claims (5)

[Claims] 1. A charging device for charging a battery, comprising a charging switch (2) for serially connecting a battery (1) in a charging loop, and a measuring switch for connecting the battery (1) to a measuring device (12). A switch (4) is provided for each battery (1), a charging power source (5) for generating the charging loop is provided, and the measurement switch (4) is switched to replace the battery (1) with the measurement device (12). ), And when the battery is not fully charged (or when a charging instruction is issued), the charging switch (2) is switched to connect the battery (1) in series in the charging loop. The charging switch (2) is sometimes switched to remove the battery (1) from the charging loop, which is sequentially repeated for all the batteries (1) so that each battery (1) is independently charged. Charging device characterized by . 2. A charging power source (5) for generating a plurality of charging loops is provided, and the charging switch (2) is switched to the charging loop designated for each battery (1) to be connected in series for charging. The charging device according to claim 1, wherein the charging device is configured as described above. 3. A discharge device for discharging a battery, comprising a discharge switch (3) for connecting the battery (1) in series in a discharge loop, and the measurement for connecting the battery (1) to a measuring device (12). A switch (4) for each battery (1) is provided, and a load (6) for generating the discharge loop is provided so that when the battery (1) is fully charged (or when a discharge instruction is issued). The discharging switch (3) is switched to connect the battery (1) in series in the discharging loop to start discharging, and the measuring switch (4) is switched to transfer the battery (1) to the measuring device (12). For all the batteries (1), connecting and measuring, and switching the discharging switch (3) to remove the battery (1) from the discharging loop when discharging is completed are sequentially repeated for all the batteries (1). Configured to discharge independently Discharge device characterized in that 4. A structure in which a load (6) for generating a plurality of discharge loops is provided, and the discharge switch (3) is switched to a discharge loop designated for each battery (1) and connected in series to discharge. The discharge device according to claim 3, wherein: 5. The charging device and the discharging device according to claim 1, wherein the charging device and the discharging device are integrated.