JPH05326026A - Battery discharge device - Google Patents

Abstract

PURPOSE:To eliminate a memory effect into an ideal condition by detecting the actual capacity of a battery, and starting memory effect eliminating discharge. CONSTITUTION:A microcomputer 4A operates a signal from a current detecting means 3 so as to integrate discharge amount, when the microcomputer 4A detects the discharge of a battery 1 by means of the signal from the current detecting means 3. After an integration processing, the microcomputer 4A compares the signal from a voltage detecting circuit 2 with the final voltage VEND, and loops the signal in a fixed order so as to integrated battery capacity when the battery voltage is higher than the voltage VEND. When the battery voltage becomes lower than the voltage VEND, the microcomputer 4A compares the integrated battery capacity with the set capacity of the battery. When the battery capacity is smaller than the set capacity, a discharge means 5 starts the discharge of the battery. When the discharge means 5 performs memory effect eliminating discharge, an indicating means 6 indicates that the battery is in its process of memory effect eliminating discharge. No memory effect eliminating discharge is allowed during the discharge to a load.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a battery discharge device,
In particular, it relates to a device for deeply discharging a battery whose capacity is substantially reduced by the memory effect.

[0002]

2. Description of the Related Art Generally, when a secondary battery such as a nickel-cadmium battery or a nickel-hydrogen battery is deeply discharged after repeating a shallow charge / discharge cycle, the voltage at the time of discharge is 2%.
It is known that a phenomenon called a so-called memory effect called a drop occurs. A chain line A in FIG. 1 shows the discharge characteristic of the battery having the memory effect, and a solid line B shows the discharge characteristic of the normal battery having no memory effect.
As shown in this figure, the voltage of the battery having the memory effect drops at an early time as the discharge progresses. Therefore, when the battery having the memory effect is used in a device that is cut off at the final voltage, the actual capacity is reduced.

As described above, when a memory effect occurs in a secondary battery used as a power source for various battery devices, the operating voltage of the secondary battery drops during operation of the device and suddenly falls below the drive voltage of the device. Problems such as the operation of the device stop. On the other hand, in a battery-driven device such as an 8 mm video camera, when the battery voltage falls below the drive voltage of the device, the battery is electrically disconnected from the device and the operation of the device is stopped. This is to prevent the device from being driven and malfunctioning due to the lowered battery voltage.

The drive voltage of such devices is often set to a voltage at which the battery is not completely discharged and there is a reserve capacity. Therefore, when the charge / discharge cycle is repeated in this manner, the memory effect is likely to occur in the battery.

In order to eliminate the memory effect, a technique has been developed in which an appropriately deep discharge is performed at the time of charging / discharging (Japanese Patent Laid-Open Publication No. 6-242242).
2-193516). The discharge device described in this publication has a built-in discharge means that discharges deeply when the voltage of the secondary battery falls below a set value. The discharging means discharges the battery deeply for a certain period of time by a timer, or detects the battery voltage and deeply discharges it until a constant voltage is reached.

[0006]

The discharge device described in this publication has a feature that it is possible to recover the decrease in the actual capacity due to the memory effect by deeply discharging the battery, that is, by performing discharge for eliminating the memory effect. In this way, the memory effect elimination discharge is performed in order to recover the substantial capacity of the battery which is lowered by the memory effect. Memory effect elimination discharge
For example, this is done when the actual capacity of the battery drops below 80% of the normal capacity. Even if a battery whose actual capacity has not decreased due to the memory effect is deeply discharged, the capacity of the battery does not recover. Discharging a battery with no memory effect to eliminate the memory effect not only wastes power but also shortens the discharge cycle life of the battery. Also,
Even if the memory effect elimination discharge is performed every time the battery voltage decreases, the actual capacity does not recover to the initial capacity.

Therefore, a discharge device that automatically performs memory effect elimination discharge each time the battery voltage drops to a set value is
Since the memory effect elimination discharge is performed every time the battery voltage decreases, it takes time to deeply discharge the battery, and it takes time to charge the deeply discharged battery. Furthermore, the terminal voltage of the battery is affected by the load current. When the load current is large, the voltage drop due to the internal resistance of the battery is large and the terminal voltage of the battery is low. Therefore, the device that detects the battery voltage and performs the memory effect elimination discharge has a drawback that the memory effect elimination discharge starts early when the load current is large and the memory effect elimination discharge starts slowly when the load current is small. is there. That is, this device has a drawback that the actual capacity of the battery varies when the discharge for eliminating the memory effect is started.

The present invention was developed with the object of resolving this drawback. An important object of the present invention is to detect the substantial capacity of the battery and initiate discharge for eliminating the memory effect. Disclosed is a battery discharge device that can eliminate the memory effect in various states.

[0009]

The device of the present invention has the following constitution in order to achieve the above-mentioned object. That is,
The battery discharging device of the present invention, a discharging means for discharging the battery, a current detecting means for determining the presence or absence of the energized state of the battery,
And a capacity detecting means for detecting the capacity of the battery. The discharge device determines by the current detection means that the battery is not in the energized state, and also detects by the capacity detection means that the capacity of the battery has become equal to or less than the predetermined value, and the discharge means detects the memory effect of the battery. Dissolve discharge starts.

[0010]

The battery discharging apparatus of the present invention discharges the battery by eliminating the memory effect only when the following conditions are satisfied. The battery is not energized. That is, the battery is not in use. This is detected by the current detecting means. The actual capacity of the battery has decreased below the specified value. This is detected by the capacity detecting means.

That is, the discharge device of the present invention discharges the memory effect by deeply discharging the battery when the capacity of the battery is reduced for a certain period of time due to the memory effect.
When the battery is used, if the memory effect eliminating discharge is performed, the battery cannot be used. Therefore, the memory effect eliminating discharge is not performed during the discharging.

[0012]

Embodiments of the present invention will be described below with reference to the drawings. However, the examples shown below exemplify discharge devices for embodying the technical idea of the present invention,
The discharge device of the present invention does not specify the circuit configuration, parts used, discharge conditions, etc. as described below. The discharge device of the present invention can be modified in various ways within the scope of the claims.

FIG. 2 is a block diagram of the discharge device. The discharge device shown in this figure is built in a battery pack. That is, the battery pack of this figure has a battery group 1 in which a plurality of nickel-cadmium batteries are connected in series, and a discharge device.

The discharging device comprises a voltage detecting means 2, a current detecting means 3, a capacity detecting means 4, a discharging means 5 and a display means 6.

The voltage detecting means 2 is connected to both ends of the battery group 1 and detects the voltage of the battery group 1. The current detection means 3 is
It is connected in series with the battery group 1 and detects the energization state of the batteries. The current detection means 3 is composed of, for example, a current detection resistor 3A connected in series with a battery, and an amplifier 3B that amplifies the voltage across the current detection resistor 3A. A voltage proportional to the current of the battery group 1 is generated in the current detection resistor 3A. Therefore, when a load current or a charging current flows in the battery group 1, the current detecting means 3 outputs a signal having a level proportional to the current. The amplifier 3B is used to reduce the current detection resistor 3A to reduce the measurement loss.

The capacity detecting means 4 calculates the output signal of the current detecting means 3 and calculates the actual capacity of the battery by a microcomputer 4A.
Equipped with. The microcomputer 4A receives signals from both the current detecting means 3 and the voltage detecting means 2. The microcomputer 4A is
A / D that converts the input analog signal into a digital value
Built-in converter (not shown).

The microcomputer 4A calculates the actual capacity of the battery by calculating the input signals of both the voltage detecting means 2 and the current detecting means 3. The microcomputer 4A determines that the battery voltage is the final voltage VEN.
Calculate the actual capacity until it drops to D. The capacity of the battery can be calculated from the integrated value of the load current until the fully charged battery drops to the final voltage VEND. Nickel cadmium battery, for example, the final voltage VEND per battery cell,
Set to 1.16V. However, the final voltage VEND for calculating the capacity of the battery is set equal to or slightly higher than the stop voltage of the electric device. For example, the stop voltage of the electric device is set to 1.14 to 1.15 V per cell of the battery. The voltage is set in this manner because the battery capacity is calculated while the battery is used in an electric device and discharged.
When the final voltage VEND for calculating the capacity of the battery is lower than the stop voltage of the electric device, the discharge of the battery is stopped before the calculation of the capacity of the battery is completed, so that the capacity cannot be calculated.

The discharging means 5 is connected in parallel with the battery group 1 and performs the memory effect eliminating discharge for deeply discharging the battery whose capacity has been reduced by the memory effect. The discharge means 5 is a discharge resistor 5A.
And a switching element 5B connected in series with this. The switching element 5B is controlled by the signal from the capacitance detecting means 4. When the switching element 5B is turned on, the battery is discharged through the discharge resistor 5A to eliminate the memory effect. When the switching element 5B is turned off, the memory effect elimination discharge is stopped.

The display means 6 displays the capacity of the battery during normal use, and indicates that the memory effect eliminating discharge is in progress when performing the memory effect eliminating discharge.

The above discharge device operates as follows in the flow chart shown in FIG. Determine if the battery is charging. When the battery pack is connected to the charger and is being charged, the current detection means 3 detects the charging current and inputs it to the microcomputer 4A. The microcomputer 4A determines whether to charge the battery group 1 and discharges the battery 5
The switching element 5B is turned off. Therefore, when the battery group 1 is being discharged, the discharging by the discharging means 5 does not cause the memory effect elimination discharge. Further, the display means 6 does not display during discharging.

When the battery is not being charged, the microcomputer 4
A determines if the battery is discharging. When the battery is connected to the load and a current is supplied to the load, the current detecting means 3 detects the load current and inputs to the microcomputer 4A that the discharging is in progress. In this state, the switching element 5B of the discharging means 5 is turned off, and the battery is not discharged by eliminating the memory effect.

By the signal from the current detection means 3,
When the microcomputer 4A detects that the battery is discharged,
The microcomputer 4A calculates the signal from the current detecting means 3 and integrates the discharge amount. After the integration process, the microcomputer 4A compares the signal from the voltage detection circuit with the final voltage VEND. If the battery voltage is higher than the final voltage VEND, the following loop is performed to integrate the battery capacity.

When the battery voltage becomes lower than the final voltage VEND, the microcomputer 4A compares the integrated battery capacity with the battery set capacity. The set capacity of the battery is stored in advance in the microcomputer 4A. The set capacity of the battery is
For example, 60 to 90% of the rated capacity of the battery, preferably 70
It is set in the range of ~ 85%. When the capacity of the battery is smaller than the set capacity, the discharging means 5 starts discharging the battery. When the discharging means 5 discharges the battery to eliminate the memory effect, the display means 6 displays that the memory effect is being discharged.

The microcomputer 4A can also calculate the capacity from the remaining capacity of the battery and start the discharge for eliminating the memory effect. The remaining capacity of the battery can be calculated by subtracting the discharge capacity from the rated capacity. That is, the remaining capacity of the battery can be calculated by subtracting the capacity of the battery discharged to the final voltage VEND from the rated capacity of the battery. When the remaining capacity becomes larger than the storage capacity of the microcomputer 4A, that is, the discharge amount becomes smaller than a predetermined value, the microcomputer starts the memory effect elimination discharge.

The microcomputer 4A detects the voltage of the battery from the signal of the voltage detection circuit and determines whether the battery voltage has reached the discharge end voltage. Discharge the battery until the battery voltage reaches the discharge end voltage. This discharge is a memory effect elimination discharge that deeply discharges the battery. The end-of-discharge voltage is set to a voltage that deeply discharges the battery, for example, 1 V per cell in the case of nickel-cadmium battery.

When the operations of to are repeated and the capacity of the battery decreases due to the memory effect, the battery is discharged, and it is detected that the battery is not charged or discharged, and the memory effect eliminating discharge is performed. The operation of ~ is repeated to loop, so the memory effect is resolved and the discharging battery starts charging, or
When the discharge starts, the memory effect elimination discharge is stopped.

The discharge device shown in FIG. 2 is incorporated in a battery pack. The discharge device can be incorporated in an electric device or a charger.

[0028]

The battery discharge device of the present invention measures the capacity of the battery and performs discharge for eliminating the memory effect when the capacity becomes smaller than the set capacity due to the memory effect. The memory effect elimination discharge is for recovering the capacity of the battery whose capacity has been reduced by the memory effect. The capacity of the battery does not recover even if the battery whose capacity does not decrease is deeply discharged.
However, the conventional discharge device manually starts the memory effect elimination discharge, or starts the memory effect elimination discharge when the voltage of the battery drops to a certain value, or uses the discharged battery for a certain period of time. Since it is detected that the memory effect is not generated and the discharge for eliminating the memory effect is started, there is a disadvantage that the discharge cannot be performed deeply when the capacity is reduced due to the memory effect. Deep discharge of a battery whose capacity does not decrease has the drawbacks that it takes time to discharge and charge, and that the cycle life of the battery is shortened. However, the discharge device of the present invention is
When the capacity is reduced due to the memory effect, the battery is discharged by eliminating the memory effect, so that the battery can be deeply discharged in an ideal state without wasteful charging / discharging. Further, since the memory effect eliminating discharge is started by detecting that the battery is not in the energized state, the memory effect eliminating discharge is not started while the battery is in use. Therefore, by using the device of the present invention to discharge the battery to eliminate the memory effect, the original capacity of the battery can be secured when the battery is recharged, and the load can be stably driven.

[Brief description of drawings]

FIG. 1 is a graph showing a state where a battery voltage drops due to a memory effect.

FIG. 2 is a block diagram of a discharge device showing an embodiment of the present invention.

FIG. 3 is a flow chart for discharging the battery to eliminate the memory effect in the device shown in FIG.

[Explanation of symbols]

DESCRIPTION OF SYMBOLS 1 ... Battery group 2 ... Voltage detection means 3 ... Current detection means 3A ... Current detection resistance 3B ...
Amplifier 4 ... Capacitance detecting means 4A ... Microcomputer 5 ... Discharging means 5A ... Discharging resistance 5B ...
Switching element 6 ... Display means

Claims (1)

[Claims] 1. A battery discharging means, a current detecting means for determining whether or not the battery is energized, and a capacity detecting means for detecting the capacity of the battery are provided. A discharging device for a battery, wherein the discharging means starts discharging the battery when the capacity is detected by the capacity detecting means and when the capacity is detected by the capacity detecting means.