JPS6364136B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to a power supply device for stabilizing the power supply voltage from a battery power source with an automatic voltage adjustment circuit and supplying the stabilized output voltage of the automatic voltage adjustment circuit to a load as the power supply voltage. In particular, it is an object of the present invention to provide a power supply device that can prevent a battery as a power source from leaking due to overdischarge.

Generally, as shown in FIG. 1, a power supply device of a device supplies a power supply voltage V _BB from a plurality of batteries 11 to an automatic voltage adjustment circuit 12.
The stabilized output voltage V _DD was supplied to the load 13 as a power supply voltage. However, the above-described power supply device has a problem that leakage occurs when the battery 11 serving as a power source is over-discharged, and a countermeasure for this problem is desired. In particular, when a rechargeable nickel-cadmium battery is used as the battery 11, a large current flows from the plurality of batteries 11 connected in series, resulting in an overdischarge state. At this time, the capacities of the above-mentioned batteries are not completely equal, and in the above-mentioned over-discharge state, the battery with the lower capacity discharges first, and becomes a load on the batteries that are not yet fully discharged, which causes the battery to discharge. A dead battery is charged in the reverse direction. Batteries that are reverse-charged quickly deteriorate, causing leakage that can damage equipment, or lead to a state of insufficient capacity where the capacity is less than the original discharge capacity even after charging, resulting in a shortened battery life. I had a problem where I had to replace the battery.

The present invention eliminates such conventional drawbacks by providing means for detecting a drop in the power supply voltage from the battery power source and cutting off the comparison reference voltage of the automatic voltage adjustment circuit, thereby improving the automatic voltage adjustment. It is designed to cut off the output voltage from the circuit and prevent over-discharging of the battery.

Hereinafter, implementation of the power supply device of the present invention will be described. FIG. 2 shows an embodiment of the power supply device of the present invention. In FIG.
The voltage of the battery power supply 6 that can be charged by V _DC is taken out as the power supply voltage V _BB from the connection point of the diode D ₂ , the resistor R ₁ and the diode D ₁ , and this power supply voltage V _BB is stabilized to output the voltage V _DD . I'm starting to do that. This automatic voltage adjustment circuit 1 includes transistors Q ₂ ,
It consists of Q ₃ , diode D ₆ and resistors R ₆ and R ₇ . 2 is an automatic voltage adjustment circuit, and the above power supply voltage
V _BB is supplied, the automatic voltage adjustment circuit 1 operates with the output voltage V _DD as a reference voltage, and outputs a stabilized voltage V _CC . This automatic voltage adjustment circuit 2 is composed of transistors Q ₅ and Q ₆ , a diode D ₇ and resistors R ₈ and R ₁₀ . 3
4 is a load that operates using the output voltage V _DD of the automatic voltage adjustment circuit 1 as the power supply voltage, 4 is a load that operates using the output voltage V _CC of the automatic voltage adjustment circuit 2 as the power supply voltage, and 7 is an overdischarge prevention circuit that is connected to the power supply. The comparison reference voltage of the automatic voltage adjustment circuit 1 is cut off by detecting a drop in the voltage _VBB . This overdischarge prevention circuit 7 includes a transistor Q ₁ , a diode D ₃ , and resistors R ₂ and R ₃ . A circuit consisting of a transistor Q ₄ and a resistor R ₁₁ is configured to activate the automatic voltage adjustment circuit 2 using the output 3a of the load 3.

The load 3 consists of a minute current load such as a timer using a CMOS IC, a keyboard reception buffer IC, and a liquid crystal display driving IC, a memory element with a small standby current, a CMOS RAM, a liquid crystal display with a minute current consumption, etc. They consist of loads that need to be energized all the time and loads that consume only a small amount of current even when they are in operation.

The load 4 consists of a high-speed microprocessor made of an NMOS IC, a decoder made of TTL, etc., and a ROM that consumes a large amount of current but is required to operate only when the microprocessor is operated. Between loads 3 and 4, there are address lines, data lines (bidirectional), timing signals, and other control signals from the microprocessor of load 4, and the microprocessor outputs timer signals of load 3. It also receives the keyboard reception signal, processes it in the microprocessor, and then displays it on the liquid crystal display to the load 3, and updates the time data in the RAM.

Here, since the loads 3 and 4 use digital elements that require extremely stable voltages during operation, the output voltages V _DD and V _CC of the automatic voltage adjustment circuits 1 and 2 are both 5± Must be 0.25V. Therefore, the reference voltage input terminals of automatic voltage adjustment circuits 1 and 2 (bases of transistors Q ₃ and Q ₆ )
The configuration is such that approximately 5V is applied to the terminal.

As the battery power source 6, five Futatsukel cadmium batteries are connected in series, and the discharge characteristics are 6V to 6.8V in total.
I am getting . Then, by subtracting the voltage drop caused by the shot key barrier diode _D2 , the power supply voltage _VBB is obtained as 5.8 to 6.6V. Use regulated 9V as external power input. In this case, the power supply voltage V _BB is 8.2V, which is obtained by subtracting the voltage drop of the diode D ₁ from V _DC = 9V, and the current consumption from the battery power supply 6 disappears, and conversely, the battery power supply 6 is charged via the resistor R ₁ . Ru.

In this configuration, when there is no external power input and the battery power supply 6 is operating, when the voltage of the battery power supply 6 is sufficiently high, a Zener diode of about 4V is used as the diode _D3 , so the transistor _Q1 turns on and the base voltage of transistor Q ₃ is stabilized by Zener diode D ₅ of approximately 5V. Then _, the automatic voltage adjustment circuit 1 adjusts the _forward voltage (approximately
A voltage lower by 0.6 V) is applied to the emitter of transistor Q ₃ , and the value obtained by subtracting the forward voltage between the base and emitter of transistor Q ₃ (approximately 0.6 V) from the base voltage of transistor Q ₃ is compared. When the output voltage V _DD is too low, the transistor Q ₃
The base current of increases, and the collector current of transistor Q ₃ is amplified to the DC current amplification factor h _{FE 3} times, and the collector current of transistor Q ₂ is further multiplied by the DC current amplification h _{FE 2} of transistor Q ₂ by transistor Q ₂ . Therefore, it works to increase the output voltage V _DD . Conversely, when the output voltage V _DD is too high, the collector current of the transistor Q ₂ is limited, so the output voltage V _DD becomes approximately equal to the base potential of the transistor Q ₃ and is stabilized. On the other hand, the automatic voltage adjustment circuit 2 uses a timer included in the load 3.
Terminal 3a of load 3 is activated by an interrupt processing request signal from IC, keyboard reception IC, or external peripheral device
It sinks current at , causes the base current of transistor Q ₄ to flow, and turns transistor Q ₄ on.
That is, a signal is applied from the terminal 3a to turn on the transistor _Q4 . This makes transistor Q ₄
turns on, and the base of transistor Q ₆ becomes approximately equal to the emitter potential V _DD of transistor Q ₄ .
The circuit configuration of this automatic voltage adjustment circuit 2 is the same as that of the automatic voltage adjustment circuit 1, and therefore the transistor
The voltage approximately equal to the base voltage of Q ₆ is the transistor
Obtained as output voltage V _CC from the collector of Q ₅ .
If the base current of transistor _Q4 is cut off at terminal 3a of load 3, transistor _Q4 will be turned off.
The output voltage V _CC will be 0 volts.

Resistor _R10 of automatic voltage adjustment circuit 2 is a transistor
The resistor _R7 of the automatic voltage adjustment circuit 1 is set to a smaller value so as to increase the maximum emitter current of transistor _Q5 and increase the maximum collector current of transistor _Q5 . This means that the current flowing through resistors _R7 and _R10 is approximately equal to the emitter potential of transistors _Q3 and _Q6 .
Since it is always constant at 4.4V, it is almost constant, and the collector current of transistors Q ₂ and Q ₅ , that is, the load current, is small, and the corresponding transistors Q ₃ and Q ₆
Even if the emitter current of is small, the difference current is supplied through diodes _D6 and _D7 ,
The current flowing through the diodes _D6 and _D7 is considered to be a loss current. Therefore, from the viewpoint of extending battery life, the loss current of the automatic voltage adjustment circuit 1, which is always on, is suppressed as much as possible. In order to make this possible, the load on automatic voltage adjustment circuit 1 is kept as light as possible.On the other hand, automatic voltage adjustment circuit 2, which is turned on only when necessary, has a large load current, and the current flowing through resistor _R10 is also I'm trying to get bigger.
In this way, the load current of the automatic voltage adjustment circuit 2 is larger than the load current of the automatic voltage adjustment circuit 1, and since it is controlled on and off, the base current of the transistor Q ₆ is larger than the base current of the transistor Q ₃ .
Moreover, it is controlled to be turned on and off.

In this case, the base current of the transistor Q ₆ is supplied by the output V _DD of the automatic voltage adjustment circuit 1, so compared to the case where the base current of the transistor Q 6 is directly supplied from the reference voltage of the first automatic voltage adjustment circuit, the base current of the first automatic voltage adjustment circuit is Diode _D5 or
A great effect can be obtained in that a reduction in battery life due to increasing the current flowing through _D4 can be avoided.

Next, when the terminal voltage V _B of the battery power supply 6 decreases, the power supply voltage V _BB decreases, and the Zener diode
The current in D ₃ drops rapidly and transistor Q ₁ turns off. Then, transistor _Q3 is also turned off, and transistor _Q2 is also turned off. Since automatic voltage adjustment circuit 2 uses the output voltage V _DD of automatic voltage adjustment circuit 1 as a reference voltage, transistor Q ₆ is also turned off, transistor Q ₅ is also turned off, and the current consumption in loads 3 and 4 is completely cut off. can do. or,
Transistor Q ₁ is also off, and the current in diode D ₃ is also turned off. If we use a punch-through type Zener diode that works at high performance even at low voltages for diode D ₃ ,
Since it can be turned off quickly by a drop in the power supply voltage V _BB , if a Zener voltage of approximately 4 V is used for diode D ₃ , the entire load on the battery power supply 6 can be completely cut off when the power supply voltage V _BB reaches approximately 4.5 V. . Therefore, even if a nickel cadmium battery is used as the battery power source 6, over-discharge is prevented and there are no problems such as leakage or reverse charging. In addition, the resistance of the overdischarge prevention circuit 7
R ₃ is used to prevent excessive current loss from flowing through the Zener diode D ₃ when the power supply voltage V _BB is high, and the resistor R ₂ is used to prevent current loss from flowing through the Zener diode D ₃ when the power supply voltage V BB is high. _Q1 is used to completely turn off.

Also, the reason why an extra Zener diode _D4 is provided at the base of the transistor _Q3 via a resistor _R5 is because a Zener voltage of 6V is applied to the diode _D4 .
This is to suppress the increase in the reference voltage of the transistor _Q3 even if a large voltage is applied to the power supply voltage _VBB due to external power input. Note that in this example, two automatic voltage adjustment circuits were provided to control two loads, but even if three or more automatic voltage adjustment circuits are provided, the current consumption in the loads can be interrupted in the same way. This can prevent over-discharging of the battery power source.

As described above, according to the present invention, there is a means for detecting a drop in the power supply voltage from the battery power supply, and when this detection means detects the power supply voltage below the allowable voltage, the comparison reference voltage input to the automatic voltage adjustment circuit is adjusted. Since the overdischarge prevention circuit is provided with a means for cutting off, by cutting off the comparison reference voltage, the output voltage from the automatic voltage adjustment circuit can be cut off, and the output voltage from the detection means, the automatic voltage adjustment circuit, and the comparison reference voltage generation section can be It is possible to cut off all current and completely eliminate current consumption in the load. Therefore, it is possible to prevent over-discharge of the battery power source, eliminate liquid leakage, and prevent damage to equipment due to this liquid leakage. Furthermore, using a rechargeable nickel cadmium battery as a battery power source has the advantage of preventing overdischarge and eliminating the inconvenience of reverse charging. Further, a second load generator is activated by a signal output from the first load, and stabilizes the power supply voltage from the battery power supply using the output voltage of the first automatic voltage adjustment circuit as a reference voltage, and outputs the stabilized power supply voltage to the second load. Since it is equipped with two automatic voltage adjustment circuits, by cutting off the comparison reference voltage of the first automatic voltage adjustment circuit,
Current consumption in the second automatic voltage adjustment circuit and the second load can be completely cut off. the result,
The first and second loads can be easily controlled.

[Brief explanation of drawings]

FIG. 1 is a block diagram of a conventional power supply device, and FIG. 2 is a circuit connection diagram showing an embodiment of the power supply device of the present invention. 1, 2... automatic voltage adjustment circuit, 3, 4... load, 5... battery power supply, 7... over discharge prevention circuit,
_Q1 to _Q6 ...transistor, _D1 to _D7 ...diode, _R1 to _R10 ...resistance.

Claims (1)

[Scope of Claims] 1. A detection means for detecting a power supply voltage from a battery power supply, and when the detection means detects the power supply voltage below an allowable voltage, the power supply voltage is converted into a stabilized output voltage and supplied to the load. An over-discharge prevention circuit has means for cutting off current supply to a comparison reference voltage generation section input to an automatic voltage adjustment circuit, and when the voltage is below the permissible voltage, the detection means, the automatic voltage adjustment circuit, and the comparison reference voltage generation section are provided. A power supply device characterized by cutting off all current in the section. 2. The power supply device according to claim 1, wherein the overdischarge prevention circuit includes a Zener diode that turns off when the detection means detects a power supply voltage that is lower than an allowable voltage. 3. A first automatic voltage adjustment circuit that stabilizes the power supply voltage from the battery power source and supplies the output voltage to the first load as the power supply voltage, and is activated by a signal output from the first load. together with said first
a second automatic voltage adjustment circuit that stabilizes the power supply voltage from the battery power supply using the output voltage of the automatic voltage adjustment circuit as a reference voltage and outputs the stabilized power supply voltage to a second load; and means for detecting the power supply voltage from the battery power supply. and when the power supply voltage from the battery power supply becomes lower than the allowable voltage, the first and second A power supply device configured to cut off the output voltage from an automatic voltage regulation circuit.