JPH03164034A - Charger for battery - Google Patents

Abstract

PURPOSE:To charge plural secondary batteries in ideal conditions with simple circuit constitution by performing trickle-charge so as to charge the plural secondary batteries after quickly charging the secondary batteries. CONSTITUTION:A power source 6 for charge is equipped with a transformers and a diode. A current control switching means 5 changes over the charge currents of secondary batteries 1A-1C by on-off operation. Battery changeover switching means 4A-4C select the secondary batteries 1A-1C to be charged, and are also used as the switches for stopping trickle charge. A control means 3 changes over the on-off conditions of the current control means 5 and the three sets of battery changeover switching means 4. The control means 3 controls a voltage detecting means 2 and, with a timer, the current control switching means and the battery changeover switching means.

Description

[Detailed description of the invention] [Industrial application field]

The present invention relates to a charging device that sequentially charges a plurality of secondary batteries, and particularly to a charging device that quickly charges the batteries and then charges them with a minute current to more completely charge the batteries.

[Conventional technology]

There are roughly two types of methods for charging a plurality of secondary batteries. There are two methods: a method in which all secondary batteries are connected directly, and a method in which they are connected in parallel. When multiple secondary batteries are connected in series and charged, all 2
The next battery cannot be fully charged, resulting in overcharged batteries and undercharged batteries. This is because the charging current of each secondary battery is equal even though the discharge state of each secondary battery is not uniform. Furthermore, in the method of charging secondary batteries by connecting them in parallel, it is necessary to provide each secondary battery with a circuit for controlling the charging current, which results in a complicated circuit configuration. As a charging device that solves this drawback, a charging device in which a switching element is connected to secondary batteries connected in parallel has been developed (for example, Japanese Patent Application Laid-Open No. 56-107744 and Japanese Patent Application Laid-Open No. 61-52117). . The charging devices disclosed in these publications connect a switch in series with a plurality of secondary batteries, and charge the secondary batteries in order via the switches. This charging device can adjust the amount of charge according to the amount of electricity remaining in each secondary battery. Therefore, a plurality of batteries can be charged almost every time. Additionally, a charging device has been developed that connects multiple secondary batteries in parallel and controls the charging time with a timer (Japanese Patent Application Laid-open No.
8-33942). This charging device charges a secondary battery using a constant current power source. Therefore, 2. When W secondary batteries are connected in parallel, both secondary batteries are charged by controlling the charging time to twice the charging time of one secondary battery.

[Problem to be solved by the invention]

However, these charging devices have a drawback that they cannot charge all the secondary batteries to an ideal state. This is caused by the charging characteristics of the secondary battery. That is,
Secondary batteries cannot be fully charged by rapid charging alone. Secondary batteries such as Ni-Cd batteries cannot be fully charged by rapid charging;
After quick charging, it is necessary to trickle charge the battery by applying a small current for a long time. A charging device that performs trickle charging of a secondary battery after rapid charging has been developed (Japanese Unexamined Patent Publication No. 58-33939). The charging device disclosed in this publication charges a secondary battery to a fully charged state under the following conditions. ■ Apply rapid charging current to the secondary battery. As the battery is rapidly charged, the voltage of the secondary battery gradually increases. - As the battery approaches full charge, the voltage of the secondary battery once rises to a peak and then gradually drops, as shown in FIG. When the voltage of the secondary battery drops from the maximum value to a constant voltage,
Stop quick charging. ■Then, the secondary battery is trickle charged with a minute current. By charging the battery in this state, the secondary battery will
The battery can be sufficiently charged to a state that cannot be achieved with fast charging. By the way, in trickle charging, the charging current is extremely small compared to quick charging, so unlike the quick charging circuit, there is no switch provided to stop the energization after a certain period of time. However,
A secondary battery that has been rapidly charged and is almost fully charged generates heat due to the subsequent trickle charging current, which causes deterioration of the secondary battery. This drawback can be overcome by specifying the trickle charging time with a timer. However, in order to realize this, a switch for stopping trickle charging is required in the charging circuit, which further complicates the circuit configuration. This invention was developed with the aim of solving these conventional drawbacks, and an important purpose of this invention is to use a switch for changing the charging state of each secondary battery as an on/off switch for trickle charging. By doing so, it is an object of the present invention to provide a charging device that can charge a plurality of secondary batteries to an ideal state with a simple circuit configuration.

[Means to solve conventional problems]

In order to achieve the above object, the battery charging device of the present invention has the following configuration. (a) A charging power supply that outputs a voltage for charging a secondary battery, a current control switching means that switches a charging current between a quick charging current and a trickle charging current, and a charging state of a plurality of secondary batteries that is switched and charged. A battery switching means for selecting the secondary battery and stopping trickle charging, a control means for controlling the current control switching means and the battery switching switching means, and a voltage detection means for detecting the voltage of the secondary battery. There is. (b) There are a plurality of battery switching means,
Each battery switching means is configured to charge a secondary battery,
It is connected in series with the secondary battery so that it can be switched between non-charging and non-charging. (c) The plurality of battery changeover switching means are current control switching means with one side connected to each other so that any one of the plurality of battery changeover switching means can be turned on to charge the secondary battery connected to the battery changeover switching means in the on state. It is connected to. (d) The battery changeover switching means and the current control switching means connected in parallel are connected in series so that the state of charge of each secondary battery is controlled via the current control switching means and the battery changeover switching means. has been done. (e) The control means is controlled by the voltage detection means to switch the on/off state of the battery switching means so as to switch from quick charging to trickle charging according to the voltage of the secondary battery. (f) the control means comprises a timer for controlling the battery changeover switching means in the trickle charge state;
The timer controls the on-time of each battery switching means to control trickle charging of the secondary battery.

[Effect]

The battery charging device of the present invention rapidly charges a secondary battery and then performs trickle charging to charge a plurality of secondary batteries. Hereinafter, the operation of the battery charging device shown in FIG. 1 will be explained based on the drawings. (2) After the voltage detection means 2 detects that the secondary battery before charging is not fully charged, charging of each secondary battery is started. (2) In FIG. 1, the control means turns on the battery switching means 4A connected to the secondary battery IA and turns off the other battery switching means 4B and 4C. (2) Voltage detection means 2 detects the voltage of secondary battery IA, and turns on current control switching means 5. In this state, the secondary battery IA is rapidly charged. (2) When the secondary battery IA is charged to the set voltage, the voltage detection means 2 detects the voltage of the secondary battery IA and controls the control means 3. The set voltage of the secondary battery is set to a voltage that is slightly lower than the maximum voltage as the voltage of the secondary battery increases. At this time, the control means 3 turns off the battery changeover switching means 4A and turns on the battery changeover switching means 4B. The battery switching means 4C maintains the off state. ■ When the secondary battery IB is rapidly charged and charged to the set voltage, the control means 3 causes the battery switching means 4 to
B is turned off, and the battery switching means 4C is turned on. At this time, the battery switching means 4A is kept in the off state. ■ When the secondary battery IC is rapidly charged and charged to the set voltage, the control means 3 activates the battery changeover switching means 4C.
is off. (2) The control means 3 turns off the current control switching stage 5 and reduces the charging current to create a trickle charging state. ■ The control means 3 includes battery switching means 4A, 4.
B and 4C are turned on in order at a certain period, for example, at a period of 0.5 to 5 seconds, and the secondary batteries IA, IB, and I are turned on for a certain period of time.
Trickle charge c. In this trickle charging, one of the battery switching means is on and the other one is off. - After trickle charging the secondary battery l for a certain period of time, the control means 3 controls all the battery switching means 4A, 4B.
4C is considered to be OFF-state deaf. This method of repeating trickle charging to each secondary battery at regular intervals allows all secondary batteries to be fully charged at the same time, and since trickle charging is performed intermittently, most of the heat generated by the secondary battery is reduced. It can be eliminated. However, the present invention does not specify the state in which a plurality of secondary batteries are trickle charged to this state. For example, after charging the secondary batteries 1A, IB, and IC to a full state in order, the battery switching means 4A, 4B
, 4C can also be switched in order. In this case, after the secondary battery IA is completely charged by trickle charging the lightning cell switching means 4A for a fixed period of time, the battery switching means 4A is turned off, and then the battery switching means 4B is turned on for a fixed period of time. Secondary battery I
Trickle charge B to fully charge it, and then
It is also possible to fully charge the secondary battery IC.

【Example】

Embodiments of the present invention will be described below based on the drawings. However, the embodiments shown below illustrate a battery charging device for embodying the technical idea of this invention, and the device of this invention specifies the circuit and charging process as follows. Not. Various modifications may be made to the device of the present invention within the scope of the claims. The battery charging device shown in FIG. 1 includes a charging power source 6, current control switching means 5, battery switching means 4A, 4B, 4C, control means 3, and voltage detection means 2. The charging power source 6 includes a transformer that drops 100 volts of alternating current to the voltage of the secondary battery, and a diode that rectifies the alternating current and converts it into direct current. The output voltage of this power supply is adjusted to a voltage that can charge the secondary battery. The current control switching means 5 operates on and off to
Switches the charging current of the next batteries IA, IB, and IC. In other words, if this is in the on state, the secondary batteries IA, IB,
Charge the IC quickly and trickle charge it in the off state. A transistor is used for the current control switching means 5 shown in the figure. The transistor should have its emitter connected to the output side of the charging power source 6, its collector connected to the battery switching means 4A, 4B, and 4C, and its base connected to the control means 3. Further, a resistor 7 is connected between the collector and the emitter. The resistance value of this resistor 7 adjusts the trickle charging voltage. When the resistance value of resistor 7 is large, the trickle charging current is small;
By decreasing the resistance value of the resistor 7, the trickle charging current can be increased. The current control switching means 5 can also perform trickle charging without connecting the resistor 7 in parallel. in this case,
The electric>g control switching means 5 includes a transistor and an F
Like ET, it uses a switching element that can control the passing current using a base signal. When a transistor is used as the current control switching means 5, the collector current, that is, the charging current can be controlled by the base current. Therefore, when performing rapid charging, a large current is passed through the base to turn the transistor into a low-resistance ON state, and when performing trickle charging, the base current is reduced to adjust the collector current to the trickle charging current. The base current of the current control switching means 5 can be controlled by the control means 3. The current control switching means 5 is switched on and off by a human power signal from the control means 3. The %i current control switching means 5 becomes an on state when an on current flows into the base from the control means 3, and becomes an off state when the base current is cut off. Although the battery charging device shown in this figure uses a transistor for the current control switching means 5, any switching element that can be turned on and off, such as an FET, can also be used for the current control switching means 5. Battery switching means 4A, 4B, and 4C select secondary batteries IA, IB, and IC to be charged. Further, battery switching means 4A, 4B,
4C is also used as a switch to stop trickle charging. Battery switching means 4A, 4B shown in the figure
, 4C are composed of transistors. The emitters of each transistor are connected to each other and to the collector of the current controlled switching means 5. The collectors of the transistors constituting the battery switching means 4A, 4B, 4C are connected to the positive sides of the secondary batteries IA, IB, IC, and the bases are connected to the control means 3. The plurality of battery switching means 4A, 4B, 4C are
Any one of the secondary batteries IA, IB, IC is charged by controlling one of them to be on and the others to be off, and all battery switching means 4A, 4B, and 4C are being controlled to be OFF and all Stop charging the secondary batteries IA, IB, and IC. Like the transistor of the current control switching means 5, this transistor is also switched on and off by the base current from the control means 3. That is, the transistor is turned on when the base current flows into it, and turned off when the base current is cut off. The battery changeover switching means 4A, 4B, and 4C can also use all switching elements that can be turned on and off similarly to the current control switching means 5. The control means 3 switches the current control switching means 5 and the three sets of battery changeover switching means 4 between on and off states. The control means 3 controls the current control switching means and the battery switching means using the voltage detection means 2 and the timer. That is, the control means 3 adjusts the base current of the current control switching means 5 and the battery switching means 4A, 4B, and 4C according to the signal supplied from the voltage detection means 2, and controls each switching element to an on-off state. . The voltage detection means 2 and the control means 3 rapidly charge the secondary batteries IA, IB, and IC in the process shown in FIG. Detect if connected. (2) With the current control switching stage 5 turned off and only the battery switching means 4A turned on, the secondary battery IA is trickle charged for a certain period of time, and the voltage detection means 2 measures the voltage. If the voltage of the secondary battery IA is abnormally low in this state, the 2
Since the next battery IA has an internal short circuit, charging is stopped. (2) When the voltage of the secondary battery IA is within the specified range, the current control switching means 5 is turned on to perform rapid charging. When rapidly charging, the voltage of the secondary battery IA increases. When the secondary battery IA approaches groove charging, the voltage gradually drops from its peak. Therefore, the voltage detection means 2 detects the voltage change of the secondary battery IA to detect whether groove charging is occurring. When the voltage of the secondary battery IA passes its peak and drops by a certain voltage, the secondary battery IA is almost fully charged. ■ Turn off the battery switching means 4A,
Stops rapid charging of the secondary battery IA. (2) Thereafter, the battery changeover switching means 4B is turned on, and the secondary batteries IB and IC are rapidly charged one after another in the same process. After all secondary batteries IA, IB, and IC are quickly charged,
The battery switching means 4A, 4 are in the state shown in FIG.
B, 4C are turned on and off, and each secondary battery IA, IB,
Trickle charge the IC. In the state shown in this figure, the battery switching means 4A,
By sequentially turning on 4B and 4C for T1 seconds each, the secondary batteries IA, IB, and IC are trickle charged in order. Then, the timer installed in the control means 3 counts T+, and each secondary battery receives 18000 counts (
After trickle charging (about 10 hours), all battery switching means 4A, 4B, and 4C are turned off. In this state, charging of all secondary batteries IA, IB, and IC is completely stopped. By the way, in the battery charging device of the present invention, the process of charging the secondary battery is not limited to the above-mentioned state. For example, after quickly charging the secondary battery IA, trickle charge it for a certain period of time to fully charge it, then quickly charge the secondary battery IB and trickle charge it for a set time, and then quickly charge the secondary battery IC. It is possible for children to trickle charge.

【Effect of the invention】

The battery charging device of the present invention has a simple circuit configuration and has the advantage of being able to fully charge a plurality of secondary batteries with different amounts of remaining electricity to an ideal state. This feature is provided with a current control switching means for switching between quick charging and trickle charging, and a battery changeover switching means connected in series to each secondary battery, and a control means for controlling the current control switching means and the battery changeover switching means. This is achieved by controlling the state of charge of each secondary battery. The battery charging device with this configuration can quickly charge each secondary battery and then perform trickle charging and groove charging, and can also stop charging all the secondary batteries after trickle charging. A secondary battery that is charged in this state is trickle-charged for a certain period of time and then stops charging, so it has the advantage of being charged in an ideal state, preventing deterioration, and extending its life. Furthermore, since a plurality of secondary batteries can be trickle charged intermittently, it is possible to greatly reduce heat generation of the secondary batteries.

[Brief explanation of the drawing]

FIG. 1 is a circuit diagram of a battery charging device showing an embodiment of the present invention, FIG. 2 is a flowchart for rapidly charging a secondary battery, FIG. 3 is a graph showing the on/off state of the battery switching means, and FIG. The figure is a graph showing voltage changes in the charging state of the secondary battery. IA, IB, IC... Secondary battery, 2...
・Voltage detection means, 3...Control means, 4A, 4B, 4C...Battery switching means, 5...Current control switching means, 6...
...Charging power supply, 7...Resistor. Figure 2

Claims (1)

[Claims] A battery charging device having the following configuration. (a) A charging power source that outputs a voltage for charging a secondary battery, a current control switching device that switches the charging current between quick charging and trickle charging, and a battery switching device that switches the charging state of a plurality of secondary batteries. , a control means for controlling the current control switching means and the battery switching means, and a voltage detection means for detecting the voltage of the secondary battery. (b) There are a plurality of battery changeover switching means, and each battery changeover switching means is connected in series with the secondary battery. (c) The plurality of battery changeover switching means are connected to each other on one side and connected to the current control switching means. (d) Each battery changeover switching means is connected in series to a current control switching means. (e) In the current control switching means, when the voltage of the secondary battery reaches a set value, this is detected by the control means, and the switching is switched from the on state to the off state, thereby switching the secondary battery from quick charging to trickle charging. change. (f) The control means includes a timer for controlling the battery changeover switching means in the trickle charging state, and is configured to control trickle charging of the secondary battery by controlling the ON time of each battery changeover switching means by the timer. has been done.