JP3397031B2 - Overdischarge prevention device - Google Patents

Description

Description: BACKGROUND OF THE INVENTION [0001] 1. Field of the Invention [0002] The present invention relates to a device for preventing overdischarge of a secondary battery, and more particularly, to eliminating leakage current after detecting overdischarge and improving the life of the battery. The present invention relates to an overdischarge prevention device. 2. Description of the Related Art In general, in a secondary battery, battery performance often deteriorates rapidly when excessive discharge is repeated. For this reason, a battery pack or the like using a secondary battery is particularly provided with an overdischarge prevention mechanism. FIG. 6 shows a voltage monitor 14 for monitoring the voltage of the secondary battery 11, a switch circuit 12 connected in series to the secondary battery 11, and a drive circuit 13 for driving the switch circuit 12. 1 is an example of a conventionally known overdischarge prevention device. In such a configuration, when the discharge proceeds and the battery voltage falls below a predetermined voltage (discharge lower limit voltage), the voltage monitoring unit 4 operates, and the switch circuit 12 is turned off via the drive circuit 13 to flow into the load Z. By interrupting the discharge current I, overdischarge of the secondary battery 11 is prevented. However, in the above configuration, even if the overdischarge prevention mechanism operates and the power supply to the load Z is stopped, as shown by the broken line in FIG.
There is a current path to No. 4, and even after disconnection of the load, the battery discharge due to the leakage current I0 is continued, and there is a possibility that overdischarge may occur. FIG. 7 shows an overdischarge prevention device improved in view of the above disadvantages. The present device is provided with a second switch circuit 15 operated by a second drive circuit 16 in a power supply path to the voltage monitoring unit 14, and when the overdischarge is detected, the second switch circuit 15 is turned off to set the voltage This is to interrupt the discharge path of the secondary battery formed through the monitoring unit 14. However, in such a configuration, at the moment when the power supply of the voltage monitoring unit 14 is stopped, the operation of the voltage monitoring unit 14 itself becomes unstable, and the battery output is temporarily reduced. Oscillation occurs and a computer or the like connected thereto malfunctions (for example, data to be stored is destroyed). More specifically, the operation when the battery output is cut off will be described with reference to the sequence shown in FIG. 5. Discharge proceeds and the battery voltage falls below a predetermined voltage value (discharge lower limit voltage VL). When Dout changes from "H" to "L", the first drive circuit 13 is turned off and the first switch circuit 1 is turned off.
2 is turned off, and the discharge current I is cut off. As a result, the output voltage decreases toward 0 V, and when the output voltage falls below the threshold level Vth of the second drive circuit 16, the second drive circuit 16 turns off. Therefore, the second switch circuit 15 turns off to monitor the voltage. The power supply to the unit 14 is cut off. As a result, the voltage monitor 14 becomes uncontrollable and an "H" level is generated at the output Dout (part), whereby the first drive circuit 13 is turned on again and the output voltage is restored (part). ). The battery voltage with the load released increases (part of) and is discharged again.
When the discharge proceeds and the battery voltage reaches the discharge lower limit voltage VL again, the voltage monitor 14 detects overdischarge again and shuts off the battery output. The above phenomenon is repeated until the battery output drops below the minimum operating voltage of the circuit element, so that the battery output enters an oscillating state during the transition to 0V. An object of the present invention is to provide a highly reliable overdischarge prevention device which has solved the above-mentioned disadvantages after overdischarge detection. That is, according to the present invention, there is provided an overdischarge prevention device for preventing overdischarge of a secondary battery (1), which is connected in series with the secondary battery (1). A first switch circuit connected to turn on / off a discharge current (I) (2)
A first drive circuit (3) for controlling ON / OFF of the first switch circuit (2); and a voltage of the secondary battery (1) is monitored, and the first voltage is detected when a predetermined voltage is detected. A voltage monitoring unit (4) for controlling the driving circuit (3) to be in an off state; and a second voltage monitoring unit (4) connected in series with the voltage monitoring unit (4) to turn on / off the power supply of the voltage monitoring unit (4). Switch circuit (5), a second drive circuit (6) for driving the second switch circuit (5), and between the output (Dout) of the voltage monitoring unit (4) and the power supply output terminal (T1). To form a current path for driving the first drive circuit (3), and to turn off the first switch circuit (2).
When the output voltage (V) decreases, the second switch
Turning off the first drive circuit before the path (5) turns off;
A constant voltage element (7) for fixing (3) to off . DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of an overdischarge prevention device according to the present invention will be described below with reference to the drawings. FIG. 1 is a block diagram showing the basic configuration. In the figure, reference numeral 1 denotes a rechargeable battery (rechargeable battery) whose positive (+) and negative (-) sides have output terminals T1 and T2 via a first switch circuit 2 for turning on / off a discharge current I. And a load Z is connected between the output terminals so that the secondary battery 1 (+) to the first switch circuit 2
-The output terminal T1-the load device Z-the ground terminal T2-the discharge path of the secondary battery 1 (-) is formed. T1 is a power supply terminal, and T2 is a ground terminal. Reference numeral 3 denotes a first drive circuit for driving the first switch circuit 2, the output of which is connected to the first switch circuit 2. A voltage monitor 4 for monitoring the voltage of the secondary battery 1 is provided to the input of the first drive circuit 3.
Output Dout of the first switch circuit 2
The drive current path of the first drive circuit 3 composed of the constant voltage element 7 is connected to the output of the first drive circuit 3 by OR (OR). A power supply line Vcc of the voltage monitor 4 connected to the positive electrode of the secondary battery 1 is connected to a second switch circuit 5 for turning on / off the power supply of the voltage monitor 4. The second drive circuit 6 is connected to its input. FIG. 2 shows a specific electronic circuit corresponding to the block configuration shown in FIG. According to FIG. 1, the first switch circuit 2 is connected to the MOS-FET Qu, and the second switch circuit 5 is connected to the M-FET Qu.
The first driving circuit 3 corresponds to the transistor (Qt), and the second driving circuit 6 corresponds to the transistor Q
Each corresponds to S. The constant voltage element 7 is a Zener diode D1 whose Zener voltage is set higher than a threshold level of a second drive circuit 6, which will be described later. The voltage monitoring unit 4 uses, for example, a comparator. Vcc is a driving power supply, and Vdd is a monitoring power supply. In the present embodiment, the circuit configuration is such that the drive power supply voltage of the power supply monitoring unit 4 is monitored as it is. The above is the configuration of the secondary battery pack to which the overdischarge prevention device of the present invention is added. Next, the operation and control of the secondary battery pack will be described in detail with reference to the sequence diagram of FIG.
In the drawing, the operation timing indicated by a broken line is the case of the conventional type described above, and the timing of the present application is a solid line portion. When a desired load Z is connected between the output power terminal T1 and the ground terminal T2, the discharge of the secondary battery 1 starts. At this time, since the first drive circuit 3 is on, the first drive circuit 3 is turned on.
Is turned on, the discharge current I from the secondary battery 1 flows into the load Z through the first switch circuit 2. In this state, the second drive circuit 6 maintains the ON state, so that the second-stage second switch circuit 5 is also turned ON, and the power supply Vcc and Vdd are supplied to the power supply monitoring unit 4. At this time, the power supply Vdd voltage is a predetermined value (discharge lower limit voltage VL).
), The output DOUT maintains the "H" state. As the discharge progresses, the battery voltage gradually decreases, and when Vdd falls below the predetermined voltage value VL, the power supply monitoring unit 4 detects this and the output Dout changes from "H" to "L". Then, the first drive circuit 3 is turned off, and the "H" of the output turns off the first switch circuit 2 to cut off the current supply to the load Z. When the discharge current I is cut off, the output voltage V decreases toward 0 V. At this time, when the output voltage V falls below the Zener voltage VZ of the constant voltage element 6 (Zener diode D1), the output voltage V decreases. Since the voltage element 6 is turned off and the drive current of the first drive circuit 3 is cut off, the first drive circuit 3 is fixed at off and the off state of the first switch circuit 2 at the next stage is established. . When the output voltage V further decreases and the input potential of the second drive circuit 6 (base potential of the transistor Qs) falls below the threshold level, the second drive circuit 6
Is turned off and the second switch circuit 5 in the next stage is turned off.
Overdischarge of the battery after overdischarge detection is completely prevented. In this configuration, the power supply to the voltage monitoring unit 4 is stopped by turning off the second switch circuit 5, and even if the level of the output Dout becomes unstable, the constant voltage element 6 is already turned off. Since the first drive circuit 3 is fixed off, it is possible to prevent a trouble that the second drive circuit is turned on again and the battery output oscillates temporarily as in the conventional circuit. FIG. 3 shows an overcharge prevention mechanism by adding a switch circuit (MOS-FET Qv) that is turned on / off by the overcharge detection output Cout of the voltage monitoring unit 4 to the circuit configuration of FIG. FIG. 4 shows an embodiment in which a plurality of secondary batteries B1 to Bn are connected in series in FIG. Either case is an application example of the overdischarge prevention device, and the present invention is of course applicable. The over-discharge prevention device of the present invention has been described above. Table 1 shows the current consumption of the over-discharge prevention device of this configuration and the over-discharge prevention device of the conventional configuration shown in FIG. The respective overdischarge prevention effects were compared. [Table 1] According to Table 1, in the case of the conventional example, when the remaining capacity of the secondary battery reaches the overdischarge lower limit voltage VL, the remaining capacity is 75 mAh.
If it is less than one year, the battery will be completely discharged after one year, causing battery deterioration. However, in this configuration, since the power consumption after the detection of overdischarge is 0, such a problem of such deterioration is completely avoided. Does not occur. As described above, according to the present invention, the second switch circuit is provided in the power supply path of the voltage monitoring unit, and is turned off when an overvoltage is detected, so that the power supply of the power monitoring unit is stopped. Is cut off, leakage current after overvoltage detection is eliminated, overdischarge of the battery is prevented, and the life of the battery is improved. Further, when an overvoltage is detected, the first drive circuit for driving the first switch circuit using the constant voltage element is fixed to off, so that the battery output is temporarily turned off when the power is cut off as in the conventional circuit. This eliminates troubles such as oscillating, and prevents malfunctions of a computer or the like connected to this.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a block diagram showing a basic configuration of an overvoltage protection device according to the present invention. FIG. 2 is an electronic circuit diagram of the overvoltage protection device corresponding to the block diagram of FIG. FIG. 3 is an electronic circuit diagram of another overvoltage protection device different from FIG. 2; FIG. 4 is an electronic circuit diagram of an overvoltage protection device different from FIG. 3; FIG. 5 is a diagram showing a sequence of the overvoltage protection device. FIG. 6 is a block diagram showing a basic configuration of a conventional overvoltage protection device. FIG. 7 is a block diagram showing a basic configuration of an overvoltage protection device different from FIG. 6; [Description of Signs] 1 Secondary battery 2, Qu first switch circuit 3, Qt first drive circuit 4 Voltage monitor 5, Q1 second switch circuit 6, Qs second drive circuit 7, D1 constant voltage Element Dout Output I of voltage monitoring unit Discharge current T1, T2 Power supply output terminal

──────────────────────────────────────────────────の Continued on the front page (72) Inventor Shoichi Wakao 5-36-11 Shimbashi, Minato-ku, Tokyo Inside Fuji Electric Chemical Co., Ltd. (72) Koji Oishi 5-36-11 Shimbashi, Minato-ku, Tokyo No. Fuji Electric Chemical Co., Ltd. (56) References JP-A-5-205782 (JP, A) JP-A-5-83868 (JP, A) JP-A-6-105458 (JP, A) JP-A-6 −105457 (JP, A) Jikken 63-41808 (JP, Y1) (58) Fields investigated (Int. Cl. ⁷ , DB name) H02H 7/18 H01M 10/44 H02J 7/00

Claims (1)

(1) An overdischarge prevention device for preventing an overdischarge of a secondary battery (1), wherein the device is connected in series to the secondary battery (1), and Current (I)
A first switch circuit (2) for turning on / off a power supply, a first drive circuit (3) for controlling on / off of the first switch circuit (2), and a voltage of the secondary battery (1). And a voltage monitoring unit (4) for controlling the first drive circuit (3) to be turned off when a predetermined voltage is detected; and a voltage monitoring unit (4) connected in series to the voltage monitoring unit (4). A second switch circuit (5) for turning on / off the power supply to (4), a second drive circuit (6) for driving the second switch circuit (5), and the voltage monitoring unit (4). output of) (Dout) and are power connection between the output terminal (T1), while constituting a current path for driving the first driving circuit (3), the first scan
The output voltage (V) is reduced by turning off the switch circuit (2).
Then, before the second switch circuit (5) is turned off,
And a constant voltage element (7) for fixing the first drive circuit (3) off .