JPH077870A - Power supply circuit apparatus - Google Patents

Abstract

PURPOSE:To provide reliable switching from a battery output to converter output and to raise the voltage stability of a first output supplied to a load. CONSTITUTION:A voltage stabilization detection circuit 8 uses a single output feedback only with output 1 during AC input, and thus high voltage stability can be obtained. Also, a voltage higher than 2.5V is always given to a point 'b' by the partial voltage of an output 2 of resistors R4 and R5 thereby preventing the pull-in of a current from point 'a'. At the time of disconnection of an AC input, if switching to the output of a battery 4 occurs, then the voltage of the output 2 becomes 0V and the voltage at point 'b' drops to 0V. At this time, the voltage by the output of the battery 4 is applied but the voltage at point 'a' is higher than that of point 'b' so that a current is pulled into the point 'b' through a diode D4. By doing this, the voltage at the point 'b' does not exceed the reference voltage of a shunt regulator IC1 so that a signal for restricting the output of a DC-DC converter 3 is not transmitted.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a power supply circuit which supplies a DC output to a load from a DC-DC converter using an AC power supply as a power supply in a normal state and switches the DC output from a battery to a load in an abnormal state. It relates to the device.

[0002]

2. Description of the Related Art FIG. 2 shows a block circuit diagram of a power supply circuit device of this type. First, the AC input from the AC power supply AC passes through the low-pass filter 1 and the diode bridge D
B and a smoothing capacitor C ₀ are input to the rectifying / smoothing circuit 2, and the DC voltage from the rectifying / smoothing circuit 2 is DC-DC.
It is supplied as a power source for the converter 3. DC-
The DC output (output 1) of the DC converter 3 is adapted to be supplied to the load _RL , and the voltage stabilization detection circuit 8 uses the DC-D to stabilize the voltage of the output 1.
It controls the switching elements of the C converter 3.

An output 2 is output as a second output from the DC-DC converter 3 as a charging voltage for the battery 4. Output 2 from this DC-DC converter 3
Output voltage charges the battery 4 via the charging circuit 5. A fuse F is provided between the charging circuit 5 and the battery 4.
Has been inserted.

A battery voltage drop detection circuit 6 is provided in parallel with the battery 4, and a signal from the battery voltage drop detection circuit 6 is input to a drive circuit 7. Further, between the battery 4 and the load R _L , a transistor SW ₁ is connected as a switch element for switching the power supply source to the load R _L. Here, the battery voltage drop detection circuit 6 detects the voltage of the battery 4 and
If the voltage is insufficient, a signal for turning off the transistor SW ₁ is sent to the drive circuit 7 in order to prevent the battery 4 from being over-discharged.

In addition, the input voltage of the AC power supply AC is lowered,
At the time of interruption, the output of the DC-DC converter 3 changes to the battery 4
An AC input drop detection circuit 10 is provided for detecting a drop or interruption of the input voltage when the power is switched to the load R _L and supplied to the output of the above. Then, when the AC input is normal, the output 1 is supplied from the DC-DC converter 3 to the load _RL , but when the AC input decreases, the AC input decrease detection circuit 10 detects this and the drive circuit 7 When the voltage of the battery 4 is equal to or higher than a predetermined value, the transistor SW ₁ is turned on. As a result, power is supplied from the battery 4 to the load R _L.

Next, the operation of FIG. 2 will be described. When the normal AC power supply AC is input, the DC-DC converter 3 outputs the output 1 (for example, 7.2 V). The DC-DC converter 3 is controlled by the voltage stabilization detection circuit 8 so that the output voltage of the output 1 becomes stable. The charging voltage (for example, 15V) of the battery 4 is output to the output 2 of the DC-DC converter 3, and the battery 4 is charged through the charging circuit 5.

In this state, if the AC input is normal, the AC input drop detection circuit 10 causes the transistor SW to pass.
A signal for turning off ₁ is sent to the drive circuit 7. As a result, the transistor SW ₁ is off. Therefore, the DC voltage from the DC-DC converter 3, that is, the output 1 is supplied to the load _RL .

Now, when the AC input is lost due to a power failure or the like, the output of the DC-DC converter 3 decreases. The AC input drop detection circuit 10 detects this AC input drop, and sends a signal to the drive circuit 7 so that the transistor SW ₁ is turned on. At this time, if the battery 4 is charged and there is a certain set value, for example, a voltage of 6.6 V or higher,
The drive circuit 7 turns on the transistor SW ₁ in response to a signal from the low battery voltage detection circuit 6. When the transistor SW ₁ is turned on, the voltage from the battery 4 is supplied to the load R _L.

[0009]

Here, in the switching regulator which detects the AC input disconnection and supplies the power from the output of the battery 4 to the load R _L as described above,
The output of the battery 4 and the output of the DC-DC converter 3 are switched as follows. That is, the presence or absence of an AC input is detected by the AC input drop detection circuit 10, and if the AC input is cut off, the transistor SW ₁ is turned on as described above, and the output from the battery 4 is produced. When the AC input is restored, the transistor SW ₁ is turned on. It turns off and switches to the output of the DC-DC converter 3.

Conventionally, the output from the DC-DC converter 3 has been stabilized as follows. FIG. 3 shows a specific circuit diagram of the conventional voltage stabilization detecting circuit 8 and will be described with reference to FIG. First, output 1 (7.2V) and output 2 (15V)
Control is applied through the voltage stabilization detection circuit 8 (double feedback). Outputs 1 and 2 are divided at points a by resistors R ₁ , R ₂ and R ₃ , respectively, and the divided voltage is compared with a reference voltage (2.5V) of the shunt regulator IC ₁ .

When the voltage at the point a exceeds the reference voltage, the shunt regulator IC ₁ draws a current from the cathode to the anode, so that the light emitting portion of the photocoupler PC ₁ emits light and the light received by the DC-DC converter 3 side. Send a signal to the department. Since the DC-DC converter 3 suppresses the output while this signal is being sent, the power to the load _RL can be controlled.

Here, it will be explained that it is necessary to apply the detection points of the voltage stabilization detection circuit 8 at two points of output 1 and output 2 (double feedback). While the DC-DC converter 3 is operating (outputting), the battery 4 is constantly charged by the charging circuit 5. When the output from the battery 4 is reached when this charge is sufficient, DC- is applied to the output 1.
The output voltage of the DC converter 3, that is, a voltage higher than the control voltage is applied.

In this state, when the detection point of the voltage stabilization detection circuit 8 is only the output 1 (single output feedback), the voltage at the point a becomes higher than the reference voltage of the shunt regulator IC ₁ , so that DC- The signal for stopping the DC converter 3 is continuously sent. When the AC input is restored while the voltage of the battery 4 is higher than the control voltage of the output 1, the DC-DC converter 3 starts to operate, but the signal from the voltage stabilization detection circuit 8 continues to be sent, Can not do it.

In order for the DC-DC converter 3 to operate, it is necessary to wait until the voltage of the battery 4 becomes lower than the control voltage of the output 1, or the voltage stabilization detecting circuit 8 operates even if the voltage of the battery 4 is high. You have to turn off the signal. If the signal from the voltage stabilization detection circuit 8 can be stopped only when the battery 4 is output, the DC-DC converter 3 can operate.

Therefore, if the detection points of the voltage stabilization detecting circuit 8 are two points of output 1 and output 2 and double feedback is performed, even when the voltage of the output 1 is high when the battery 4 is outputting,
Output 2 when the DC-DC converter 3 is not operating
Is 0V, the voltage at point a is the shunt regulator IC
The reference voltage of ₁ will not be exceeded, and no signal will be sent from the voltage stabilization detection circuit 8 to the DC-DC converter 3. This double feedback ensures that the output of the DC-DC converter 3 and the output of the battery 4 are switched when the AC input is disconnected and restored.

However, the double feedback has a problem that the voltage stability of the output 1 is worse than that of the single output feedback of only the output 1. This is because the output 2 is charging the battery 4. That is, when the battery 4 is being charged, the voltage of the battery 4 is about 6.5 to 9.0 V, which changes depending on the charging time and the ambient temperature. When the voltage of the battery 4 is low, the charging current is large, and when the voltage of the battery 4 is high, the charging current is small.

As described above, the charging current is opposite to the voltage of the battery 4, so that the battery 4 is charged in the range of about 45 to 115 mA. This difference in charging current affects the voltage stability of the output 1. In this power supply circuit device (switching regulator), switching between the output of the battery 4 and the output of the DC-DC converter 3 and the voltage stability of the output 1 are contradictory problems.

The present invention has been provided in view of the above-mentioned points, and aims at voltage stability of the first output, and even when the battery voltage is higher than the set voltage of the first output, A power supply circuit device for reliably switching to a converter output.

[0019]

According to the present invention, a DC voltage obtained by rectifying and smoothing an AC input is converted into a predetermined voltage value by a converter and supplied to a load, and when the AC input is normal, the battery described above is used. When charging by the output of the converter and the AC input is abnormally low or cut off and normal DC output from the converter cannot be supplied to the load, the DC output is supplied to the load from the above battery via the switch element that was turned on at the time of abnormality. In the power supply circuit device configured to supply the load, the converter has a first output that supplies power to the load when the AC input is normal, and a second output that charges the battery, and outputs the output voltage on the load side. A voltage stabilization detection circuit that detects and feeds back a signal corresponding to the detected voltage to the converter to stabilize the output voltage, and a voltage stabilization detection circuit when the AC input is abnormal. It is obtained by a control means for prohibiting the transmission of the voltage feedback signal from the regulated detection circuit to the converter when powering the load from Teri.

[0020]

According to the present invention, the first output is supplied to the load, the voltage on the load side is detected, and a signal corresponding to the detected voltage is fed back to the converter to stabilize the output voltage. Since it is controlled by the stabilization detection circuit,
The so-called single output feedback can be achieved, and the voltage stability of the first output can be made very high. In addition, by prohibiting the feedback signal from being sent from the voltage stabilization detection circuit to the converter when power is being supplied from the battery to the load when the AC input is abnormal, the battery voltage is lower than the set voltage of the first output. However, the converter is still operable even when the battery is output, so that the battery output can be reliably switched to the converter output when the AC input is restored. Therefore, it is possible to reliably switch from the battery output to the converter output and to increase the voltage stability of the first output supplied to the load.

[0021]

Embodiments of the present invention will be described below with reference to the drawings. Power supply circuit device (switching regulator)
Since the block configuration of the device itself is the same as the conventional one, the elements having the same function are denoted by the same reference numerals, and the description thereof will be omitted.

FIG. 1 shows a specific circuit diagram of the voltage stabilization detection circuit 8 of the present invention. In the figure, T is an output transformer forming the DC-DC converter 3. From the first output winding N ₂ of the output transformer T of the DC-DC converter 3 to the output 1 (first
Output). And DC-D
The output 1 from the C converter 3 is rectified by the diode D ₁ and smoothed by the capacitor C _1, and the load R _L is supplied with electric power of, for example, 7.2V.

In parallel with the load R _L , a series circuit of the light emitting section of the photocoupler PC ₁ and the shunt regulator IC ₁ and a series circuit of the resistors R ₁ and R ₃ are respectively connected. The voltage divided by the resistors R ₁ and R ₃ is applied to the shunt regulator IC ₁ . Here, the point a, which is the connection point between the resistors R ₁ and R ₃ , is the detection point.

The output 2 (second output) from the second output winding N ₃ of the output transformer T of the DC-DC converter 3
To supply. The output 2 from the DC-DC converter 3 is rectified by the diode D ₂ and smoothed by the capacitor C ₂ , and the battery 4 is charged through the charging circuit 5 composed of the diode D ₃ and the resistor R _6. There is. Further, a transistor SW ₁ which is on / off controlled by the drive circuit 7 is interposed between the battery 4 and the load R _L.

[0025] Here, the output 2 is detected by the resistor R ₄ and R _5, the point b which is a connection point of the resistors R ₄ and R ₅ are the detection point. The point a and the point b are connected by a diode D ₄ . Although a capacitor C ₃ is connected in parallel to both ends of the diode D ₄ as a measure against noise, it does not affect the present invention even if the capacitor C ₃ is not particularly connected. Further, the resistors R ₄ , R ₅ and the diode D ₄ form a control means.

Next, the operation will be described. AC input, DC
Output 1 and output 2 are obtained from the output of the DC converter 3. Since the voltage stabilization detection circuit 8 is the single output feedback of only the output 1, high voltage stability is obtained. Further, a voltage of 2.5 V or more is constantly applied to the point b by the voltage division of the output 2 of the resistors R ₄ and R ₅ to prevent the current from being drawn from the point a.

When the output of the DC-DC converter 3 is switched to the output of the battery 4 when the AC input is cut off, the voltage of the output 2 becomes 0V and the voltage at the point b also drops to 0V. At this time, the voltage due to the output of the battery 4 is applied to the point a of the voltage stabilization detection circuit 8. And the resistance R ₄ ,
Synthesis parallel resistance value of R _5, R ₃ is lower than that of the resistor R _3, and towards the voltage of the point a, since higher than the voltage at point b, point b via the diode D ₄ Draws current.

As a result, the voltage stabilization detection circuit 8 is able to operate even if the voltage of the battery 4 is higher than the set voltage of the output 1.
Since the voltage at the point does not exceed the reference voltage of the shunt regulator IC ₁ , a signal for suppressing the output of the DC-DC converter 3 is not output. Therefore, the DC-DC converter 3 is always ready to operate when the battery 4 outputs. As a result, when the AC input is restored, the output of the battery 4 becomes DC-
It is possible to reliably switch to the output of the DC converter 3.

With the circuit configuration of FIG. 1, the following experimental results were obtained. The load current was 0.3 to 1.3 A, and the voltage stability was 5.9% in the related art (including the change amount of the charging current of the battery 4 of 45 to 115 mA). No change), a high voltage stability of output 1 of 0.1% could be obtained. Further, even when the voltage of the battery 4 is higher than the set voltage of the output 1, the output of the battery 4 can be reliably switched to the output of the DC-DC converter 3.

[0030]

According to the present invention, a DC voltage obtained by rectifying and smoothing an AC input is converted into a predetermined voltage value by a converter and supplied to a load, and when the AC input is normal, the battery is connected to the converter. When the battery is charged by the output and the AC input is abnormally low or is cut off and the converter cannot supply the normal DC output to the load, the battery supplies the DC output to the load via the switch element that was turned on in the abnormal condition. In the above power supply circuit device, the converter has a first output for supplying power to the load when the AC input is normal, and a second output for charging the battery, and detects the output voltage on the load side. A voltage stabilization detection circuit that stabilizes the output voltage by feeding back a signal corresponding to the detected voltage to the converter, and a battery Since the control means for prohibiting the feedback signal from being sent from the voltage stabilization detection circuit to the converter while the power is being supplied to the load is provided, the first output is supplied to the load and Since the voltage stabilization detection circuit controls the voltage detection circuit to feed back a signal corresponding to the detection voltage to the converter to stabilize the output voltage, so-called single output feedback is performed and the first output The voltage stability of can be very high. Further, by prohibiting the feedback signal from being sent from the voltage stabilization detection circuit to the converter when the power is being supplied from the battery to the load when the AC input is abnormal, the battery voltage is higher than the set voltage of the first output. However, the converter is ready to operate even when the battery is output, so when the AC input is restored,
It is possible to reliably switch from the battery output to the converter output. Therefore, it is possible to reliably switch the battery output to the converter output and to increase the voltage stability of the first output supplied to the load.

[Brief description of drawings]

FIG. 1 is a specific circuit diagram of a voltage stabilization detection circuit according to an embodiment of the present invention.

FIG. 2 is an overall block diagram of a power supply circuit device.

FIG. 3 is a specific circuit diagram of a conventional voltage stabilization detection circuit.

[Explanation of symbols]

1 Low pass filter 2 Rectifier circuit 3 DC-DC converter 4 Battery 5 Charging circuit 6 Battery voltage drop detection circuit 7 Drive circuit 8 Voltage stabilization detection circuit 10 AC input drop detection circuit _RL load D ₄ Diode SW ₁ transistor (switch element)

Claims (1)

[Claims] 1. A converter converts a direct current voltage obtained by rectifying and smoothing an alternating current input into a predetermined voltage value and supplies it to a load, and when the alternating current input is normal, a battery is charged by the output of the converter to generate an alternating current. When the input is abnormally low or cut off and the converter cannot supply the normal DC output to the load, the power supply circuit device is designed to supply the DC output to the load from the battery through the switch element that is turned on when the error occurs. In, the converter has a first output for supplying power to the load when the AC input is normal, and a second output for charging the battery, and detects an output voltage on the load side and responds to the detected voltage. Voltage detection circuit that feeds back the generated signal to the converter to stabilize the output voltage, and supplies power from the battery to the load when the AC input is abnormal And a control means for prohibiting the feedback signal from being sent from the voltage stabilization detection circuit to the converter during operation.