JPH0632785Y2 - Switching power supply - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION <Industrial field of application> The present invention relates to a switching power supply having a protection function of cutting off the DC output when the DC output is in an abnormal state such as overvoltage or overcurrent. By connecting a relay in parallel with the control circuit to the power supply circuit for operation from the circuit to the control circuit, it does not respond directly to an output short circuit and responds to normal and abnormal conditions detected by the protection circuit. It is possible to provide a switching power supply that can output relay signals corresponding to each of them to the outside without error.

<Prior art> When the DC output from the output rectifying / smoothing circuit has an abnormal condition such as overvoltage or overcurrent, the switching power supply has a protection function that shuts off the DC output. In order to make it known from the outside, conventionally, a relay is connected to the output side of the output rectifying / smoothing circuit so that normality or abnormality can be discriminated by the relay signal. FIG. 3 is a block diagram of a conventional switching power supply of this type. In the figure, 1 and 2
Is a DC input terminal, 3 and 4 are output terminals, 5 is a switch for turning on a power source, 6 is a switching conversion circuit, 7 is an output rectifying / smoothing circuit, 8 is a control circuit, 9 is an auxiliary power supply circuit, 10 is a protection circuit, 11 Is a relay and 12 is a protective resistor.

Switching converter circuit 6 switches the DC input V _in, obtained by, for example, rectifying and smoothing the commercial AC output rectifying and smoothing circuit 7 converts the switching output which is output from the switching converter circuit 6 into a DC output DC output V ₀ is output from terminals 3 and 4.

The control circuit 8 monitors the DC output V _0, as DC output V ₀ is constant, and the pulse width control the switching operation of the switching converter circuit 6. The auxiliary power supply circuit 9 supplies operating power to the control circuit 8.

The protection circuit 10 operates to shut off the operating power supply circuits (a) and (b) from the auxiliary power supply circuit 9 to the control circuit 8 when the DC output V ₀ is abnormal. Abnormalities in the DC output V ₀ are overvoltage and overcurrent, which are input to the protection circuit 10 through a detection circuit (not shown).

The relay 11 connects the coil 111 to the output side of the output rectifying / smoothing circuit 7, and outputs the normal and abnormal DC output V ₀ as an opening / closing signal of the contact 112 driven by the coil 111.

In the above-mentioned conventional example, when the DC output V ₀ is normal, the coil 111 of the relay 11 is excited by the DC output V ₀ , the contact 112 is closed, and a relay signal corresponding to normal operation is output. Has been done.

However, when the DC output V ₀ is in an abnormal state such as overvoltage or overcurrent, the protection circuit 10 causes the auxiliary power supply circuit 9 to operate.
Power supply circuit for operation from control circuit 8 to control circuit 8
Is cut off, and the control circuit 8 stops operating. Therefore, the switching operation of the switching conversion circuit 6 stops and the DC output V ₀ disappears. Therefore, the coil 11 of the relay 11
When 1 is in a non-excitation state, its contact 112 opens and a relay signal corresponding to the abnormal state is output.

<Problems to be Solved by the Invention> However, the conventional switching power supply described above has the following problems.

(A) When an output short circuit occurs in which the output terminals 3-4 are substantially short-circuited, the DC output V ₀ is significantly reduced.
In the event of an output short circuit, the protection circuit 10 will eventually operate, but since the protection circuit 10 has a delay time element, the relay 11 responds to the output short circuit before the protection circuit 10 operates. Then
The coil 111 is in a non-excited state, and a relay signal corresponding thereto is output. At this time, the relay signal is the protection circuit.
It is the same as the relay signal after 10 protection operations. For this reason,
Whether the coil 111 of the relay 11 is de-excited and the corresponding relay signal is output due to the output short circuit,
It cannot be discriminated whether it is based on the protection operation by the protection circuit 10. A large short-circuit current flows when the output is short-circuited, but no current flows after the protection operation by the protection circuit 10, and even with the same relay signal, the current state is completely different, so it is necessary to distinguish between the two. However, the conventional circuit cannot make the determination.

(B) Even when a momentary output short circuit that cannot be regarded as an abnormal state occurs, the relay 11 responds and the contact 112 turns on,
There is the inconvenience of repeatedly turning off.

Therefore, the problem to be solved by the present invention is to solve the above-mentioned conventional problems and not directly respond to an output short circuit, and to correspond to the relay signals corresponding to only the normal state and the abnormal state detected by the protection circuit. It is to provide a switching power supply that can output to the outside without error.

<Means for Solving the Problems> In order to solve the above problems, the present invention, as shown in FIG. 1, outputs a switching conversion circuit 6 for switching a DC input V _in and an output from the switching conversion circuit 6. Output rectifying / smoothing circuit 7 for converting a switching output into a direct current and outputting the same, a control circuit 8 for controlling the switching operation of the switching conversion circuit 7, and an auxiliary power supply circuit for supplying an operating power supply to the control circuit 8. 9 is a switching power supply having a protection circuit 10 for interrupting the power supply for operation from the auxiliary power supply circuit 9 to the control circuit 8 when the DC output V ₀ is abnormal. In the operation power supply circuits (a) and (b) to the circuit 8, in parallel with the control circuit 8,
The coil 131 of the relay 13 is connected, and the relay 13 outputs relay signals respectively corresponding to a normal time and an abnormal time.

<Operation> FIG. 1 is a block diagram of a switching power supply according to the present invention. In the figure, the same reference numerals as those in FIG. 3 denote the same components. As shown in the figure, an operation power supply circuit (a) from the auxiliary power supply circuit 9 to the control circuit 8
In (b), the coil 131 of the relay 13 is provided in parallel with the control circuit 8.
Since the relay 13 outputs the relay signals corresponding to the normal time and the abnormal time respectively, the protection circuit 10 causes the auxiliary power supply circuit 9 to transfer to the control circuit 8 when the abnormal voltage such as overvoltage or overcurrent occurs. Power supply circuit for operation of (a),
Only when (B) is cut off, the relay contact 132 is switched. Including a momentary output short circuit that cannot be considered abnormal,
The relay 13 does not directly respond to the output short circuit.
Therefore, the switching power supply according to the present invention includes the protection circuit 10
Only for normal and abnormal conditions detected by
The relay signal corresponding to each will be output to the outside without error.

After the above-mentioned abnormal state is repaired, the reset switch attached to the protection circuit 10 is operated to release the short circuit of the auxiliary power supply circuit 9 by the protection circuit 10. As a result, the normal state is restored.

<Embodiment> FIG. 2 is a more specific circuit diagram of a switching power supply according to the present invention. In the figure, the same reference numerals as those in FIG. 1 denote the same components. The switching conversion circuit 6 includes a transformer 61 and a switching element 62. The transformer 61 has an input winding 611, an output winding 612 and an auxiliary winding 613. The input winding 611 is connected to the input terminals 1 and 2 via the switching element 62, and the output winding 612 is connected to the output rectifying / smoothing circuit 7.

The switching element 62 is composed of a bipolar transistor, a field effect transistor, or the like, and its main electrode is connected to the input winding 611 in series.

The output rectifying / smoothing circuit 7 has a circuit configuration of a forward rectifying system or a flyback rectifying system. Since these circuit configurations are obvious to those skilled in the art, details thereof will be omitted.

A part of the DC output V ₀ is fed back to the control circuit 8, and the control circuit 8 controls the switching element 62 so that the DC output V ₀ (voltage) becomes constant based on the feedback input signal. Add pulse width modulation control to the control electrodes.

The auxiliary power supply circuit 9 converts the voltage generated in the winding 613 provided in the transformer 61 into a direct current by the diode 91 and the capacitor 92, and this direct current voltage is stabilized by the transistor 93, the zener diode 94 and the resistor 95. The power supply for operation is supplied to the control circuit 8 after being stabilized by the digitalization circuit. For the control circuit 8, a transistor 93
The emitter side and the anode side of the Zener diode 94 are the operation power supply terminals (a) and (b), respectively.

The output side of the protection circuit 10 is connected to both ends of the Zener diode 94 of the auxiliary power supply circuit 9. When the overcurrent detection signal or the overvoltage detection signal is input to the protection circuit 10, the protection circuit 10 operates so as to short-circuit both ends of the Zener diode 94. As a result, the auxiliary power supply circuit 9 to the control circuit 8
Since the operation power supply circuit leading to the
Then, the switching operation of the switching element 62 is stopped.

In the relay 13, both ends of the coil 131 are connected to the emitter side of the transistor 93 and the anode side of the Zener diode 94 via the resistor 14. This allows
The relay 13 is connected to the auxiliary power supply circuit 9 in parallel with the control circuit 8. 96 is a resistor for starting.

In the above switching power supply, when the switch 5 is turned on, the startup power is supplied to the control circuit 8 via the startup resistor 96, the control circuit 8 starts operating, and the startup pulse is supplied to the switching element 62. . When the switching element 62 starts operating in response to the supply of the startup pulse, the input voltage supplied to the input winding 611 of the transformer 61 is intermittent,
A voltage is induced in the output winding 612 and the auxiliary winding 613.

The voltage induced in the auxiliary winding 613 is converted into a direct current by the diode 91 and the capacitor 92 that form the auxiliary power supply circuit 9, and is further stabilized by the voltage stabilizing circuit that is formed by the transistor 93 and the Zener diode 94. , The control circuit 8 and the relay 13 connected in parallel therewith
Is supplied to the coil 131. As a result, the control circuit 8 receives the power supply from the auxiliary power supply circuit 9 and continues its operation, the coil 131 of the relay 13 is excited, the contact 132 is closed, and the relay signal corresponding to the normal state is output.

Due to the continuous operation of the control circuit 8 and the accompanying switching operation of the switching conversion circuit 6, the voltage induced in the output winding 612 is converted into direct current by the output rectifying / smoothing circuit 7, and is output from the output terminals 3 and 4. The DC output V ₀ is supplied to a load (not shown).

Now, an abnormal condition such as overcurrent or overvoltage occurs, and the protection circuit
When 10 operates, the output of the protection circuit 10 short-circuits both ends of the Zener diode 94. Therefore, the operating power supply circuit from the auxiliary power supply circuit 9 to the control circuit 8 is cut off,
The control circuit 8 stops operating. When the control circuit 8 stops operating, the switching operation of the switching conversion circuit 6 also stops, and the DC output V ₀ of the output terminals 3 and 4 disappears.

When the operating power supply circuit from the auxiliary power supply circuit 9 to the control circuit 8 is cut off, the control circuit 8 stops operating, and at the same time, the coil 131 of the relay 13 is not supplied with power, so that the contact 132 is switched. Instead, a relay signal corresponding to the abnormal state is output.

The above-described operation of the relay 13 accurately corresponds to whether or not the protection circuit 10 is performing the protection operation, and the relay signals corresponding to each of the normal state and the abnormal state can be output to the outside without error. .

Further, the protection circuit 10 does not detect an instantaneous output short circuit due to its own time element. Therefore, the protection operation by the protection circuit 10 is not performed, and the Zener diode 94 is not short-circuited. Therefore, the relay 13 remains excited, the relay signal does not switch, and the contact 132
Does not turn on and off repeatedly.

<Effect of the device> As described above, a relay is connected in parallel to the control circuit to the operating power supply circuit from the auxiliary power circuit to the control circuit, and relay signals corresponding to normal and abnormal conditions are provided. Since it is designed to output, it does not respond directly to an output short circuit and can output relay signals corresponding to each of the normal and abnormal states detected by the protection circuit to the outside without error. A power supply can be provided.

[Brief description of drawings]

FIG. 1 is a block diagram of a switching power supply according to the present invention,
FIG. 2 is also a more specific circuit diagram, and FIG. 3 is a block diagram of a conventional switching power supply. 6 ... Switching conversion circuit 7 ... Output rectifying / smoothing circuit 8 ... Control circuit, 9 ... Auxiliary power supply circuit 10 ... Protection circuit, 13 ... Relay

 ─────────────────────────────────────────────────── ─── Continuation of front page (72) Masanori Nakayasu 1 Toyota-cho, Toyota-shi, Aichi Toyota Motor Co., Ltd. (72) Hiroyoshi Nakamura 1-1 1-1 Asahi-cho, Kariya-shi, Aichi Toyota Koki Co., Ltd. Inside the company (72) Inventor Kazuo Maki 1-13-1 Nihonbashi, Chuo-ku, Tokyo Inside TDC Corporation (56) Reference JP-A-63-64566 (JP, A) JP-A-1-174271 (JP, A)

Claims (1)

[Scope of utility model registration request] 1. A switching conversion circuit for switching a direct current input, an output rectifying / smoothing circuit for converting a switching output output from the switching conversion circuit into a direct current and outputting the direct current, and a control for controlling a switching operation of the switching conversion circuit. Circuit, an auxiliary power supply circuit for supplying operating power to the control circuit, and in the event of an abnormal DC output,
A switching power supply having a protection circuit for shutting off an operation power supply circuit from the auxiliary power supply circuit to the control circuit, wherein the operation power supply circuit from the auxiliary power supply circuit to the control circuit is provided with the control circuit. A switching power supply characterized in that relays are connected in parallel, and the relays output relay signals corresponding to normal times and abnormal times respectively.