JPS59130075A - Battery discharge detecting circuit - Google Patents

Abstract

PURPOSE:To detect the timing of discharge to be done in an accurate manner, by making full use of a fact that internal resistance grows large in a battery simultaneously with the discharge, while checking the terminal voltage at that time in a way of making a large current into a flow a moment. CONSTITUTION:In order to operate a device 35, when a key 34 is pressed, this device 35 is set in motion and simultaneously a pulse is outputted out of an input P of a central processing unit 33 whereby the first portion flows into a condenser 31 (a so-called rush current) as a collector current for a transistor 28 and then those from the second one downward flow into a resistor 30. While operating the device 35, if the quantity of discharge reaches a point 14 shown in this discharge characteristic drawing, internal resistance inside a battery 1 rises as the rush current flows so that output voltage of the battery 1 drops to some extent. So, finally no current flows into a Zener diode 16, stopping the conduction of transistors 17 and 21, and the S input of an RS flip-flop circuit 24 is turned to ''H''. With this rush current, when a Q output is turned to ''H'', the lighting of an LED25 goes out, informing an operator of the discharge start timing immediately.

Description

DETAILED DESCRIPTION OF THE INVENTION Field of the Invention The present invention relates to a battery discharge detection circuit that can be used in a circuit that indicates when to charge a rechargeable battery.

Conventional configuration and its problems FIG. 1 shows a conventional battery discharge detection circuit.

In FIG. 1, reference numeral 1 indicates a rechargeable battery such as a Ninocur Calbenium battery. 2 is a zener diode, which is the sum of the zener voltage of the zener diode 2 and the heath-emitter voltage of the transistor 3, or the charging start voltage of the battery. 3 (P N J) type L-Lanmes, this transformer 7 star 3 is connected to the emitter or the positive side of the battery 1, connected to the Hess or Zener tie auto 20 cup-1- side, and the collector or the no. It is connected to the bias resistor 5. 4 is the negative resistance of the Zener tie auto 2, and this negative resistance /I is connected on one side to the positive side of the battery 1, and on the other hand to the cathode 1 of the Zener diode 2. 51j, l is a bias resistor connected to the collector of the run/screw transistor 3. 6fd, l' is a bias resistor connected between the collector of the run/screw 3 and the base of the transformer 7 star 7. In Trump Stuff, the collector is L I'3 D 8 cuttoy rule and the emitter is connected to ground. 8 is No. 51 and bias resistor 9
is connected to the anode side.

9 is a bias resistor, one of which is connected to the positive side of the battery 1 and the other to the anode side of the LED 8.

Next, the operation of the conventional battery discharge detection circuit will be explained.

First, when the battery J has a sufficient charging source, the Zener voltage of the Zener diode 2 is exceeded, so the Zener diode becomes conductive, and the l-run/metal 3 also becomes conductive. The voltage of the battery 1 is applied to the base of the transistor 7 via the emitter and collector of the transistor 3 and the bias resistor 6, thereby making the transistor 7 conductive. When the transistor 7 becomes conductive, the voltage of the battery 1 becomes L through the bias resistor 9.
Apply voltage to ED8 to light LED8. User is L
When I see E D 8 lit, I know that battery J is sufficiently charged.

However, if battery J is used for a long time, the output voltage of battery 1 will become lower. The Zener voltage (V2) of Zener diode 2 and the base-emitter voltage (V2) of transistor 3
When the voltage of battery 1 (■,) is lower than the sum of BE),
Zener diode 2 no longer conducts. At the same time, no current flows between the base and emitter of the transistor 3, and the transistor 3 is no longer conductive. As a result, the conduction of transistor 7 ceased and the light was on.
disappears to notify the user when it is time to start charging.

Next, the relationship between the discharge amount of the battery 1 and the output voltage will be explained using FIG. 2. In FIG. 2, the vertical axis shows the output voltage of the battery i, and the horizontal axis shows the discharge amount of the battery 1. Discharge amount 11.
When discharging at -j, the output voltage drops rapidly and discharging of the battery 1 is stopped.

However, in the conventional example above, the output voltage at the initial stage of discharge is
The difference 12 in the output voltage of the discharge amount 11 is much smaller than the large field of the output voltage (in this conventional example, the difference 2 when the output voltage is 5) is Oi'V). Therefore, the voltage setting for discharge detection is also done by transistor 3 and Zener diode 2.
This has been a problem since it is easily affected by temperature fluctuations and changes in temperature, making it impossible to accurately display the charging start time.

OBJECTS OF THE INVENTION It is an object of the present invention to eliminate the above-mentioned problems of the prior art, and to accurately detect when to charge the battery.

Structure of the Invention The present invention attempts to accurately detect when to charge by passing an instantaneous current and checking the terminal voltage at that time, taking advantage of the fact that the internal resistance of a battery increases as it discharges. It is something to do.

DESCRIPTION OF EMBODIMENTS The configuration of an embodiment of the present invention will be described below with reference to the drawings. In FIG. 3, the vertical axis shows the output voltage of the battery i1, and the horizontal axis shows the discharge amount of the battery 1.

13 is a curve showing the discharge amount and output voltage when current is supplied to the device 35. 14 shows a situation in which the output voltage drops when a rush current is passed through a capacitor of a constant capacity at a certain discharge amount. 16 is an envelope of the output voltage drop when the above rush current is applied at each discharge amount. 15 indicates the difference between the output voltage at the initial stage of discharging and the output voltage that dropped when a rush current was applied at the start of charging. The voltage difference] 5 in FIG. 3 shows a much larger value (about several times) than the voltage difference 12 in FIG.

The configuration of an embodiment of the present invention will be described below with reference to the drawings. In FIG. 4, 16 is a Zener diode, which allows the sum of the Zener voltage of Zener diode 2 and the base-emitter voltage of transistor 7, or the inrush current at the charging start time shown in 14 in FIG. 3, to flow. The above Zener voltage is set so that the output voltage is the same as when the sensor is in use. 17b) N I) type transistor, this transistor] 7 is connected to the emitter or to the bias resistor of the battery 1, the base to the canot side of the Zener diode 16, and the collector to the bias resistor 9. . The bias resistor 20 is connected between the collector of the transistor 17 and the base of the transistor 21. Reference numeral 21 denotes an NPN type Torano Duster, and this transistor 21 has a collector connected to a bias resistor 22, an emitter connected to earth, and a base connected to a bias resistor 20. 22 is a bias resistor, and this bias resistor 22 is connected to the positive side of the battery 1 and the collector of the transistor 21. 24 is I(,S
This RS flip-flop 24 is a flip-flop, and the S (set) input is connected to the collector R (
A bias resistor 23 is connected to the (reset) input.

The cathode of the LED 25 is connected to the output Q. S
When the input is rr, ", -j, that is, the transistor 21 is conductive, the voltage of the battery 1 flows to the LJcJ] 25 via the bias resistor 26, so that the LED 25 lights up. If the S input is [(J, the Q output will also be ■1, and LEI) 25 will not light up. This Q output becomes /ζ [(once it becomes J, regardless of the S input]). To convert this Q output to rLJ, it is necessary to make It a large input rHJ. 27 is a bias resistor. in,
A pulse signal from the bias resistor 27ViCPU 33 is applied to the base of the transistor 28. 28baN
I) An N-type transistor, the base is connected to the bias resistor 27, the emitter is connected to the ground, and the collector is connected to the speaker 3.
2 is connected. 29 is a diode, and the cathode of this diode 29 is connected to the collector of the transistor 28,
The anode is disconnected from the bias resistor 30. 31 is a capacitor, and this capacitor 3J is connected between the positive terminal of the battery ↑ and the anode of the diode 29.

Reference numeral 32 denotes a speaker, which is connected between the positive side of battery 1 and the collectors of 1 to 28, and generates sound by turning off transistor 28 in response to a pulse from CPO 33. 33 is a control unit (CPU) of a microcomputer that controls the device 35 and outputs a pulse from the output P when the key 34 is pressed. 35
This device 35 is, for example, a portable storage device that has a built-in battery 1 and stores input information from the keys 34. For example, a salesperson carries this device 35 and uses the keypad 35 to temporarily store information such as the number of products ordered and sales proceeds.
The case where this device 35 is used is determined by inputting the contents into 4.

36Ul/Se, Tosuinochi, this) Nosetsuinochi 36 is used as the R input of the RS flip-flop 24, and once the Q output becomes rI-IJ, when you want to return it to "L", use the above 7/ This can be achieved by pressing Toisochi. Then LJ3D25 lights up again.

Next, the operation of the above embodiment will be explained. When the Zener battery J is sufficiently charged, the output voltage of the battery 1 is also high, so the voltage applied to the Zener diode 1G is also high and conductive. A current flows between the base and emitter of the transistor 17, the transistor 17 becomes conductive, and the transistor 17 also becomes conductive. The collector of Tran/Sufu 21 is rlL
Since it is J (earth potential), J (, S free,
Pfronop's man power S is also "L". Therefore, the output Q also becomes ILJ, and current flows through Ll D25,
LJUD25 lights up to indicate that battery 1 is fully charged.

When the key 34 is pressed to use the device 35, the CPU
The signal is processed at 33 and the device 35 is operated. At this time, a pulse is output from the output P of C1)U33. This pulse is passed through the bias resistor 27 to
It is input to the base of 8. Tran/Suf 28 bass
When a current flows between the emitters, a collector current that is multiplied by the current amplification factor flows. A portion of the collector current causes the speaker 32 to sound, and the rest flows through the diode 29.

The collector current flows through the capacitor 31 during the first pulse (so-called rush current), and through the resistor 30 during the second pulse. This situation will be explained using FIG. FIG. 5(a) shows the voltage waveform of the output P of the CPU 33. (1) in FIG. 5 is the collector current of the l-run/meta 28. This FIG. 5 shows that the collector current of the transformer/sub 28 flows in synchronization with the output waveform of the CPU: 33, and the first pulse (1) in FIG. 5 flows through the capacitor 31 in FIG. This is the inrush current that flows. Once the capacitor 31 is charged, this rush current becomes a normal current from the next pulse. In this example, the normal current is 50 m
For A, inrush current fd 1. A flows. CPU
When the output pulse from the output 33 stops, the electric charge stored in the capacitor 31 in FIG.
It is discharged via. In this case, when the key is pressed manually, there is a risk that an inrush current will flow with the first pulse and the amount of discharge will increase significantly, but in the case of this example, the time width of the J pulse is 200 μs, so the effect on the amount of discharge is There are almost no

As the device 35 is used, when the discharge amount reaches the point 14 in FIG. 3, the internal resistance of the battery increases when an inrush current is applied, and the output voltage of the battery 1 decreases. Therefore, the current no longer flows through the Zener diode [6], stopping the conduction between the transformer/springs J7 and 21, and causing the S input of the RS flip-flop 2/I to become rHJ. When the Q output becomes "■1" due to the rush current, the LED 25 turns off. The inrush current disappears and the S input changes to [Lj as well,
The Q output of the 11 flip-flop is rHJ it.

In order to return the Q output from "■]" to rLJ, the reset switch 36 must be pressed to set the R input to "11".

Effects of the Invention The present invention has the above configuration, and according to the present invention, the following effects can be obtained.

(1) Since an inrush current is applied and the charging timing is checked based on the resulting voltage drop, it is possible to accurately determine the charging timing by eliminating changes in the set voltage due to variations in semiconductors.

(2) Since the time width of the pulse used to flow an inrush current and check the charging timing is short, the amount of discharge of the battery due to the inrush current can be made negligibly small.

[Brief explanation of the drawing]

Fig. 1 is a diagram of a conventional battery discharge detection circuit, Fig. 2 is a diagram showing the discharge characteristics of a conventional battery, Fig. 3 is a diagram showing the discharge characteristics of a battery according to an embodiment of the present invention, and Fig. 4 is a diagram of the present invention. Battery discharge circuit diagram according to an embodiment of the invention, first rechargeable battery, 16
Zener diode 17, to 7/star, 24, ■7S flip-flop. 25-LED, 26・bias resistor, 27・bias resistor, 28 trans/splash, 3o bias resistor, 3
1-Capacitor. Name of agent: Patent attorney Toshio Nakao (1st person)
Figure 2 Discharge amount Figure 3 Discharge amount Figure 4 Figure 5

Claims (1)

[Scope of Claims] (1) A rechargeable battery, a voltage detection circuit that detects whether the terminal voltage of the above-mentioned battery is below a predetermined voltage, and (2) a voltage detection circuit connected in series between the terminals of the above-mentioned battery. A battery discharge detection device comprising a switch means upper stage and a capacitor, a resistor connected in parallel to a display condenser, and a display means that displays a charging instruction when the voltage detecting circuit detects a predetermined voltage or less when the switch means is conductive. circuit. (2) The battery discharge detection circuit according to claim 1, which is provided with a nulling means that conducts with the output of a pulse generation circuit that generates pulses when a key is operated.