JPH066934A - Power-supply changeover circuit - Google Patents

Abstract

PURPOSE:To avoid that the life of a primary battery is shortened by a method wherein the voltage of a capacitor is compared with the voltage of the primary battery and, when both voltages are approximately the same, the primary battery is connected to a parallel circuit which is composed of a load and the capacitor. CONSTITUTION:In a comparator CO, its power supply is supplied from a DC power supply PS when the voltage of the DC power supply PS exists, and its power supply is supplied from a capacitor C when the DC power supply PS does not exist. The comparator compares the voltage of the capacitor C with the voltage of a primary battery; it is operated according to the result of the comparison. When the voltage of the capacitor C and the voltage of the primary battery B are approximately the same, the primary battery B is connected to a parallel circuit which is composed of a load L and the capacitor C. Thereby, there exists no possibility that the primary battery B is charged undesirably, and it is possible to avoid that the life of the primary battery B is shortened.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a power supply switching circuit for switching a power supply for a semiconductor memory or the like used in an electronic device or the like to a backup battery for maintaining a direct current power supply based on a commercial power supply or the like in the absence. Regarding the improvement of. In particular, it relates to improvement of a power supply switching circuit when a primary battery that does not allow charging current is used as a battery.

[0002]

2. Description of the Related Art One example of a conventional power supply switching circuit will be described with reference to the conceptual configuration diagram shown in FIG.

In FIG. 5, PS is a DC power source based on a commercial power source, SW ₁ is a first opening / closing means which is closed only when the DC power source PS is present, and C is a capacitor,
L is a load, and the DC power supply PS is connected to the parallel circuit of the load L and the capacitor C and supplies power to the load L only when the DC power supply PS is present. B is a non-rechargeable primary battery such as a dry battery, SW ₂ is a second opening / closing means that is closed only when the DC power source PS is not present, and the primary battery B is a load only when the DC power source PS is not present. It is connected to the parallel circuit of L and the capacitor C. Capacitor C
The function of is to prevent the fluctuation of the voltage supplied to the load L even if the voltage of the power supply or the load L fluctuates.

By the way, since this power supply switching circuit is a circuit intended to hold the semiconductor memory or the like which is the load L even when the DC power supply PS is not present, the voltage of the primary battery B is 60% of DC power supply PS voltage
The degree is selected.

The operation of the power supply switching circuit according to this conventional technique will be described with reference to FIG. 6 showing an operation waveform diagram. See FIG. 6. When the DC power supply PS is present, the first opening / closing means SW ₁
And N-channel enhancement type field effect transistor Q ₂ to which constitutes turns on the first switching means SW ₁
The gate of the P-channel enhancement-type field effect transistor Q ₁ constituting the above is at a low voltage and is also on, and power is supplied from the DC power supply PS to the load L. Here, when the DC power supply PS is not present, the P-channel enhancement type field effect transistor Q ₁ forming the _first switching means SW ₁ is turned off. At the same time, the P-channel enhancement type field effect transistor Q ₃ forming the _second switching means SW ₂ is immediately turned on.

On the other hand, since the capacitor C exists, the load L is supplied with current from the capacitor C, and the input voltage of the load L does not immediately drop. However, as mentioned above,
Since the P-channel enhancement type field effect transistor Q ₃ forming the second opening / closing means SW ₂ is on, if the voltage of the capacitor C decreases and becomes equal to the output voltage of the primary battery B, the primary battery Power is supplied from B to the load L, and the power supply is switched.

[0007]

By the way, as described above, when the direct-current power supply PS is not present, the P-channel enhancement type field effect transistor Q ₃ forming the _second switching means SW ₂ is immediately turned on. During the period until the voltage of C drops to the output voltage of the primary battery B (generally about 1 second), a reverse current is supplied to the primary battery B such as a dry battery to shorten the life of the primary battery B. There are drawbacks.

An object of the present invention is to eliminate this drawback, and in a power supply switching circuit in which a DC power supply and a primary battery having a voltage lower than the voltage value of the DC power supply are used by switching, a DC power supply is used. If no longer exists, the switching from the DC power supply to the primary battery is improved so as to be performed when the capacitor voltage (the voltage at which the load is continuously supplied with power) drops to the voltage of the primary battery, It is to provide a power supply switching circuit in which reverse current to the primary battery is prevented.

[0009]

SUMMARY OF THE INVENTION The above object is to provide a first switching means (SW ₁ ) which is connected to a direct current power source (PS) and is closed when the voltage of the direct current power source (PS) is present and is opened when it is not present. ) Via load (L) and capacitor (C)
A power supply circuit connected to a parallel circuit of the DC power supply and the DC power supply (P) when the voltage of the DC power supply (PS) is present.
S), power is supplied, and when the voltage of the DC power supply (PS) does not exist, power is supplied from the capacitor (C), and the voltage of the capacitor (C) and the primary battery (B) The voltage of the capacitor (C) is compared with the voltage of the capacitor (C) by comparing the voltage with the voltage of the comparator (CO) that operates in response to the voltage change.
When the voltage of the secondary battery (B) is almost the same, the above 1
Second switching means (SW ₂ ) for connecting the secondary battery (B) to the parallel circuit of the load (L) and the capacitor (C)
Is achieved by a power supply switching circuit having

In the above-mentioned structure, the primary battery B keeps the comparator CO while the primary battery B is supplying power to the load L.
Therefore, the power is still supplied, and the primary battery B is wastefully used. Therefore, as shown in FIGS. 3 and 4, the third switching means SW ₃ is operated on condition that the comparator CO detects that the voltage of the capacitor C has dropped to the voltage of the primary battery B. Therefore, if the power supply to the comparator CO is stopped and the restart of the comparator CO is conditioned on the recovery of the DC power supply PS, the primary battery B will not be wasted.

Further, in the above structure, the DC power source P
If the operation of the comparator CO is delayed when S is restored,
The current flows backward to the primary battery B during the period. There
Then, as shown in FIG. 4, it is necessary to recover the voltage of the DC power supply PS.
As the second opening / closing means (SW ₂) That make up
Nel enhancement type field effect transistor Q₃Open
If the DC power supply PS is restored, the comparator
Backflow to the primary battery B until CO operates
Disappear.

[0012]

The above-mentioned drawback is that the second switching means SW ₂ is closed when the voltage of the capacitor C is higher than the voltage of the primary battery B. In order to eliminate this drawback, until the voltage of the capacitor C becomes the same as the voltage of the primary battery B,
It suffices if the primary battery B is not connected to the open circuit of the capacitor C. In order to embody this idea, in the present invention, power is supplied from the DC power supply PS when the voltage of the DC power supply PS exists, and power is supplied from the capacitor C when the voltage of the DC power supply PS does not exist. (Since a field effect transistor generally has a parasitic diode that connects the source and drain in the forward direction, a DC power source P
When the voltage of S or the voltage of the primary battery B exists, any power source and the comparator CO can be connected without positive connection.
Is connected to the power supply circuit of), and a comparator CO that compares the voltage of the capacitor C and the voltage of the primary battery B and operates in response to the high and low is provided, and opens and closes in response to the operation of the comparator CO. When the voltage of the capacitor C and the voltage of the primary battery B are approximately the same, the primary battery B is connected to the load L and the capacitor C.
And a second opening / closing means SW ₂ connected to a parallel circuit of

In the second embodiment, the DC power source P
In order to avoid that the power source of the comparator CO is supplied from the primary battery B and the primary battery B is unnecessarily consumed while S is not present, the comparison is performed on the condition that the comparator CO operates. The power supply to the container CO is stopped.

In the third embodiment, the DC power source P
When S is restored, in order to prevent backflow to the primary battery B, when the DC power supply PS is restored, the connection with the primary battery B is immediately opened with the voltage of the DC power supply PS. .

[0015]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS A power supply switching circuit according to three embodiments of the present invention will be described below with reference to the drawings.

First Embodiment See FIGS. 1 and 2 FIG. 1 is a conceptual block diagram. In the figure, PS is a DC power source based on a commercial power source, SW ₁ is a first switching means that is closed only when the DC power source PS is present, C is a capacitor, L is a load, The DC power supply PS is connected to the parallel circuit of the load L and the capacitor C and supplies the power to the load L only when the DC power supply PS is present. B is a primary battery, SW ₂ is a second opening / closing means, and the primary battery B is connected to the parallel circuit of the load L and the capacitor C only when the DC power source PS does not exist, and the load L is supplied with electric power. To supply. The function of the capacitor C is to prevent the fluctuation of the voltage supplied to the load L even if the voltage of the power supply or the load L changes. CO is a comparator, which is supplied with power from the DC power supply PS when the voltage of the DC power supply PS is present, and is supplied with power from the capacitor C when the DC power supply PS is not present. Since there is generally a parasitic diode that connects the source and drain in the forward direction, when the voltage of the DC power supply PS or the voltage of the primary battery B exists, even if the connection is not positively made, Either power source and the power circuit of the comparator CO are connected, and the voltage of the capacitor C and the primary battery B
And a comparator CO that operates in response to the high and low is a second opening / closing means that is closed only when it is determined that the voltage of the capacitor C is lower than the voltage of the primary battery B.
The primary battery B is connected to the parallel circuit of the load L and the capacitor C only when the DC power source PS is not present, and the power is supplied to the load L.

The operation of the power supply switching circuit according to the first embodiment will be described with reference to FIG. 2 showing an operation waveform diagram. See FIG. 2. When the DC power source PS is present, the first opening / closing means SW ₁
And N-channel enhancement type field effect transistor Q ₂ to which constitutes turns on the first switching means SW ₁
The gate of the P-channel enhancement-type field effect transistor Q ₁ constituting the above is at a low voltage and is also on, and power is supplied from the DC power supply PS to the load L. Here, when the DC power supply PS is not present, the P-channel enhancement type field effect transistor Q ₁ forming the _first switching means SW ₁ is turned off. Then, the power is supplied from the capacitor C to the load L. However, since the energy is not supplied, the voltage of the capacitor C gradually decreases. When the voltage of the capacitor C becomes lower than the voltage of the primary battery B, the comparator CO outputs "0", which is applied to the resistor 4 forming the _second switching means SW2, and the P-channel enhancement type field effect transistor Q. ₃ , the primary battery B is connected to the parallel circuit of the load L and the capacitor C, and the power supply is switched.

After that, the comparator CO is operated by the DC power supply PS.
Until it recovers, "0" will be output, but DC power supply PS
"1" is output and the second opening / closing means
SW ₂P-channel enhancement type electric field
Effect transistor Q₃Turn off.

As a result, during the period when the voltage of the capacitor C is higher than the voltage of the primary battery B, the voltage of the primary battery B is not connected to the voltage of the capacitor C, and the primary battery B is never charged. Absent.

Second Embodiment In the above-described embodiment, the power source of the comparator CO is substantially 1 when the DC power source PS is not present.
Since it is supplied from the secondary battery B, the primary battery B will be uselessly consumed.

Therefore, in this embodiment, the comparator CO
However, on condition that it has detected that the voltage of the capacitor C has dropped to the voltage of the primary battery B, the third opening / closing means S
It is to beゝW ₃ is operated to stop the power supply of the comparator CO to. Even when the DC power source PS is not present, the comparator CO outputs "1" while the voltage of the capacitor C is higher than the voltage of the primary battery B, and the third switching means SW ₃
, The N-channel enhancement type field effect transistor Q ₅ is turned on, and the P-channel enhancement type field effect transistor Q ₄ is also turned on. Power is supplied from the capacitor C as the power source of the comparator CO. When the voltage of C is reduced to the voltage of the primary battery B, the comparator CO outputs "0", the N-channel enhancement type field effect transistor Q ₅ constituting the third switching means SW ₃ is turned off, P-channel The enhancement-type field effect transistor Q ₄ is also turned off and the power supply circuit of the comparator CO is cut off. However, during this period, P which constitutes the _second opening / closing means SW ₂
Since the channel enhancement type field effect transistor is never turned off, there is no problem. When the DC power supply PS is restored, the voltage of the DC power supply PS is directly applied to the power supply circuit of the comparator CO to start normal operation.

[0022]Third embodiment In the above embodiment, when the DC power supply PS is restored
Is the first opening / closing means SW ₁Works immediately and capacitors
The voltage of C rises immediately, but the operation of the comparator CO is
The second opening / closing means SW requires a small amount of time.₂Cycle of
However, a slight time delay is inevitable. So that period
In the meantime, it is desirable that the reverse current flows into the primary battery B.
Absent.

Therefore, in this embodiment, the DC power source P
When S is restored, the second switching means SW ₂ is opened immediately with the voltage of the DC power supply PS.
There is no opportunity for the reverse current to flow in the secondary battery B.

[0024]

As described above, in the power supply switching circuit according to the present invention, in the power supply switching circuit, the DC power supply and the primary battery having a voltage lower than the voltage value thereof are switched and used. , When the voltage of the DC power supply is present, the power is supplied from the DC power supply, and when the DC power supply is not present, the power is supplied from the capacitor, and the voltage of the capacitor is compared with the voltage of the primary battery, and it responds to the level And a parallel circuit of a load and a capacitor when the voltage of the capacitor and the voltage of the primary battery are approximately the same when the comparator opens and closes in response to the operation of the comparator. Since the second opening / closing means connected to the primary battery is provided, there is no chance that the primary battery is undesirably charged, and it is possible to avoid shortening the life of the primary battery.

[Brief description of drawings]

FIG. 1 is a conceptual configuration diagram of a power supply switching circuit according to a first embodiment of the present invention.

FIG. 2 is an operation waveform diagram of the power supply switching circuit according to the first embodiment of the present invention.

FIG. 3 is a conceptual configuration diagram of a power supply switching circuit according to a second embodiment of the present invention.

FIG. 4 is a conceptual configuration diagram of a power supply switching circuit according to a third embodiment of the present invention.

FIG. 5 is a conceptual configuration diagram of a power supply switching circuit according to a conventional technique.

FIG. 6 is an operation waveform diagram of a power supply switching circuit according to a conventional technique.

[Explanation of symbols]

PS DC power supply B Primary battery C Capacitor L Load SW ₁ First opening / closing means SW ₂ Second opening / closing means SW ₃ Third opening / closing means CO Comparator

Claims (1)

[Claims] 1. A direct current power supply (PS) is connected to the direct current power supply.
When the voltage of the power source (PS) exists
First opening / closing means (SW₁) Through the load
(L) and a capacitor (C) connected to a parallel circuit
Source circuit and the direct current when the voltage of the direct current power source (PS) is present.
Power is supplied from the power source (PS), and the DC power source (P
If the voltage of S) does not exist, the capacitor (C)
Is supplied with power, and the voltage of the capacitor (C) and the primary
Operates in response to high and low by comparing with the voltage of the battery (B)
And a comparator (CO) that opens and closes in response to the operation of the comparator (CO).
The voltage of the capacitor (C) and the voltage of the primary battery (B) are different.
When it is almost the same, load the primary battery (B) with the load
(L) and the capacitor (C) connected in parallel
2 opening / closing means (SW ₂) And having a
Source switching circuit.