JPH0312030Y2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION This invention relates to a power supply device, and in particular to switching the output voltage of a switching power supply and overvoltage protection thereof.

In order to accommodate the rated voltages of various loads, switching power supplies are sometimes required to be able to change their output voltage values. In such a case, protection of the load against overvoltage is required when switching the output.

The object of this invention is to provide a power supply device that is compatible with output switching and provides overvoltage protection.

This idea is based on a power supply device that compares a reference voltage and a detection voltage using an error amplifier and controls the output voltage using the error voltage obtained from the comparison. an output switching circuit that applies the obtained detection voltage to the error amplifier to switch the output voltage value to 2 or more; and an output switching circuit that responds to the output switching of this output switching circuit and sets an overvoltage value corresponding to each output voltage value, and The present invention is characterized in that it is comprised of an overvoltage detection circuit that detects the occurrence of the overvoltage detection circuit, and a switching circuit that short-circuits the output terminals in response to the detection output of the overvoltage detection circuit.

This invention will be described in detail below with reference to embodiments shown in the drawings.

FIG. 1 shows an embodiment of the power supply device of this invention. In the figure, the input terminal 2A is set to the positive side, and the input terminal 2B is set to the negative side or zero potential side, and a DC voltage to be stabilized or voltage adjusted is applied between these input terminals 2A and 2B. A switching transistor 4 (hereinafter referred to as transistor 4) and a rectification/smoothing circuit 6 are installed on the positive power supply line where the input terminal 2A is formed, and an output terminal 8A is formed. An output terminal 8B is formed on the reference potential line on which the input terminal 2B is formed.

A drive circuit 10 for controlling the base current of the transistor 4 is installed on the base side of the transistor 4, and the error voltage output of the error amplifier 12 is applied to this drive circuit 10 as a control input. error amplifier 1
A switching input from the output switching circuit 14 and a reference voltage from the reference voltage source 16 are applied to the output switching circuit 2 as comparison inputs.

The output switching circuit 14 includes a switch 18 and a resistor 2.
0, 22, and 24, and the resistance values of the resistors 22 and 24 are made different, and the detected voltage division ratio between the output terminals 8A and 8B is changed by selecting the switch 18.

An overvoltage protection circuit 26 is installed between the output terminals 8A and 8B.
are overvoltage detection circuit 28 and switching circuit 30
It is made up of. The overvoltage detection circuit 28 is composed of constant voltage diodes 32, 34 and a resistor 36, and has an overvoltage set corresponding to the output voltage set by the output switching circuit 14, and detects the occurrence of the overvoltage. Switching circuit 3
0, a controlled rectifying element 38 (hereinafter referred to as thyristor 38) is installed between output terminals 8A and 8B, and an overvoltage detection output is given to its gate.

The operation will be explained based on the above configuration. The reference voltage and the detection output of the output switching circuit 14 are compared by the error amplifier 12, and the control output thereof is given to the drive circuit 10. In the drive circuit 10, a switching pulse current having an ON-OFF duty is generated in response to the output thereof, and the transistor 4 is switched by this current. As a result,
The DC voltage is converted into an intermittent voltage (AC), passed through a rectifier/smoothing circuit 6, converted to DC again, and sent to an output terminal 8.
It is taken out from A and 8B and supplied to a load (not shown). In such switching control, fluctuations in the output are detected by the error amplifier 12, and a stabilized output is obtained by changing the ON-OFF duty of the transistor 4.

Now, the reference voltage from the reference voltage source 16 is V _REF , and the resistance values of the resistors 20, 22, 24, and 36 are R ₁ , R ₂ ,
Assuming R ₃ and R ₄ , the output voltage V _pa when the switch 18 is closed to the a side is V _pa =V _REF (R ₁ +R ₃ )/R ₃ (1). Further, the output voltage V _pb when the switch 18 is closed to the b side is V _pb =V _REF (R ₂ +R ₃ )/R ₃ (2).

Here, the breakdown voltages of the constant voltage diodes 32 and 34 are assumed to be V _Z1 and V _Z2 .

In this case, when the switch 18 is closed to the a side, if a voltage exceeding the breakdown voltage V _Z1 of the voltage regulator diode 32 is generated or applied between the output terminals 8A and 8B, the voltage regulator diode 32 A trigger current flows through the gate of thyristor 38, and thyristor 38 is turned on. As a result, the output terminals 8A and 8B are short-circuited and the output thereof is released, so that the load or the power supply device can be protected from application of a voltage other than the predetermined voltage or an abnormally high voltage.

Further, when the switch 18 is switched to the b side, if a voltage exceeding the breakdown voltage of the constant voltage diode 34 is generated or applied to the output side, the thyristor 38 similarly turns on, and the output terminals 8A, A similar effect can be obtained by short-circuiting between 8B and 8B.

Here, the values of the breakdown voltages V _Z1 and V _Z2 of the voltage regulator diodes 32 and 34 are V _Z1 = V _REF (R ₁ + R ₃ )/R ₃ + Vx = V _pa + Vx (3) V _Z2 = V _REF (R ₂ + R ₃ )/R ₃ + Vx = V _pb + Vx ...(4) In each formula (3) and (4), Vx is the voltage fluctuation range when the power supply is operating normally. Considering
Set to about several volts.

In this way, since the output voltage is switched and the overvoltage corresponding to the DC output voltage is switched at the same time to control the short circuit of the output, overvoltage protection corresponding to each output voltage can be obtained.

Further, when the switching circuit 30 is configured with a thyristor 38 as in the embodiment, the output terminal 8
Even if an appropriate output voltage is generated or the application is removed after overvoltage is generated or applied to A and 8B, the short-circuit condition is maintained, ensuring protection of the circuit and load. ing.

FIG. 2 shows another embodiment of the power supply device of this invention, in which the same parts as in the previous embodiment are given the same reference numerals. In this embodiment, the power supply device and the load 40 side are connected with connectors 8A, 8B, 8C, 9
A, 9B, 9C are the connector terminals, and the corresponding connector terminals 8A-9A, 8B-9B, 8C
-9C is connected. Connector terminal 8C, 9C
and the switch 19 sets the switch 18 to the load 4.
0 side, and the output voltage can be changed and the overvoltage can be changed on the circuit side of the load 40.

According to this configuration, if the output voltage when the switch 19 is open is _VH , this _VH is expressed as _VH = V _REF (R ₁ + R ₃ )/R ₃ as in equation (1). ...(5) becomes. Further, if the output voltage when the switch 19 is closed is _VL , then this _VL is as follows: _VL = V _REF (R _S + R ₃ )/R ₃ (6). However, R _S is a combined resistance value of the resistors 20 and 22, and is given by R _S =R ₁ ·R ₂ /(R ₁ +R ₂ ). Therefore, the output voltages V _H and V _L have a relationship of V _H > V _L.

The overvoltage can be similarly set using the constant voltage diodes 32 and 34, and the breakdown voltage
V _Z1 and V _Z2 are set as V _Z1 = V _H + VX ……(7) V _Z2 = V _L + VX ……(8), and _V Configure as in the example.

This embodiment eliminates the need to set the output voltage and overvoltage on the power supply side, and allows these to be switched on the load side. In this embodiment, a switch 19 is installed, but similar effects can be expected by using various switching means such as switching connector terminals or wiring in addition to this type of switch.

In addition, in the example, the output voltage and overvoltage settings are set to 2.
Although the circuit is configured to be switchable in stages, this invention can be implemented in the same way with a circuit that allows switching in three or more stages, and the same effects as in the previous embodiment can be expected.

As explained above, according to this invention, the overvoltage value can be set in response to the switching of the output voltage, and overvoltage protection can be obtained in response to the switching of the output voltage.

[Brief explanation of the drawing]

FIG. 1 is a circuit diagram showing an embodiment of the power supply device of this invention, and FIG. 2 is a circuit diagram showing another embodiment of the power supply device of this invention. 12...Error amplifier, 14...Output switching circuit,
26... Overvoltage protection circuit, 28... Overvoltage detection circuit, 30... Switching circuit.

Claims (1)

[Claims for Utility Model Registration] (1) In a power supply device that compares a reference voltage and a detection voltage using an error amplifier and controls the output voltage using the error voltage obtained from the comparison, the detection voltage division ratio of the output voltage is 2 or more. and an output switching circuit that switches the output voltage value to 2 or more by applying the detected voltage obtained by the switching to the error amplifier; A power supply device comprising: an overvoltage detection circuit that sets an overvoltage value and detects the occurrence of the overvoltage; and a switching circuit that shorts output terminals in response to the detection output of the overvoltage detection circuit. (2) The power supply device according to claim 1, wherein the switching circuit includes a controlled rectifying element that is controlled to be short-circuited by the output signal of the overvoltage detection circuit.