JP3226051U - Power supply - Google Patents

Abstract

PROBLEM TO BE SOLVED: To simplify the configuration of a power supply device in which an output terminal is connected to an output side of an oscillation circuit. A power supply device includes a switching element (17) that opens and closes an inrush prevention circuit (5) connected to an output side of a noise filter (4) with an oscillation circuit (7) or an output terminal (9) or a signal from a load connected to the output terminal. , The fuse 18 and the first resistance element 19 are connected in series, and the second resistance element 20 is connected in parallel, and the resistance value of the second resistance element is set to that of the first resistance element. Make it larger than the resistance value. Then, when the fuse is cut off, the electric charge of the capacitor element 11 of the noise filter is discharged through the second resistance element. [Selection diagram] Figure 1

Description

The present invention relates to a power supply device in which an output terminal is connected to an output side of an oscillation circuit.

This type of conventional power supply device has an input terminal, a noise filter connected to the output side of the input terminal, a full-wave rectification circuit connected to the output side of the noise filter through an inrush prevention circuit, and The configuration includes an oscillator circuit connected to the output side of the full-wave rectifier circuit and an output terminal connected to the output side of the oscillator circuit.
In addition, when the power supply to the input terminal is cut off, specifically, when the plug is unplugged from the outlet, the discharge control circuit consisting of the semiconductor control element causes the charge of the capacitor element that constitutes the noise filter. Is configured to be discharged (the following Patent Document 1 is similar to this document).

JP, 2019-47655, A

In the above conventional example, when the plug is unplugged from the outlet, the discharge control circuit composed of the semiconductor control element discharges the electric charge of the capacitor element that constitutes the noise filter. If the discharge control circuit including the semiconductor control element is provided, the configuration becomes complicated.
Then, this invention aims at simplification of a structure.

  In order to achieve this object, the power supply device of the present invention is connected to an input terminal, a noise filter connected to the output side of this input terminal, and an output side of this noise filter through an inrush prevention circuit. A full-wave rectifier circuit, an oscillating circuit connected to the output side of the full-wave rectifying circuit, and an output terminal connected to the output side of the oscillating circuit. The full-wave rectifier circuit has a capacitor element, and at least the first, second, third, and fourth rectifier elements are connected in a bridge shape, and the second capacitor element is connected to the output side thereof. The inrush prevention circuit includes a switching element that opens and closes according to a signal from the oscillation circuit, the output terminal, or a load connected to the output terminal, and the direct connection between the fuse and the first resistance element. A connecting member, a second resistor element is constituted by the parallel connection of the resistance value of said second resistor element is made larger than the resistance value of the first resistor element.

As described above, the power supply device of the present invention includes a switching element that opens and closes the inrush prevention circuit connected to the output side of the noise filter with an oscillation circuit, an output terminal, or a signal from a load connected to the output terminal, The fuse and the first resistance element are connected in series and the second resistance element is connected in parallel, and the resistance value of the second resistance element is greater than the resistance value of the first resistance element. Since the size is increased, the structure can be simplified.
That is, in the present invention, a resistance value larger than the resistance value of the first resistance element is set in the parallel connection body of the switching element forming the inrush prevention circuit and the series connection body of the fuse and the first resistance element. Since the second resistance element that is included is simply connected in parallel, the configuration can be greatly simplified.

1 is a circuit diagram of a power supply device according to an embodiment of the present invention.

An embodiment of the present invention will be described below with reference to the accompanying drawings.
(Embodiment 1)
In FIG. 1, reference numeral 1 denotes an input terminal, which is detachably connected to a commercial AC power source 2 through an outlet 3.
A noise filter 4 is connected to the output side of the input terminal 1, and a full-wave rectifier circuit 6 is connected to the output side of the noise filter 4 via an inrush prevention circuit 5. The oscillator circuit 7 is connected to the output side of the oscillator circuit 7, and the output terminal 9 is connected to the output side of the oscillator circuit 7 via the rectifier circuit 8.

The noise filter 4 is a general one having an inductance element 10 and a first capacitor element 11.

The full-wave rectifier circuit 6 connects at least four rectifier elements (first, second, third, fourth rectifier elements 12, 13, 14, 15) in a bridge shape, and has a second rectifier element on the output side thereof. This is a general type in which a capacitor element 16 is connected.

The rush prevention circuit 5 includes a switching element 17 that opens and closes according to a signal from the oscillation circuit 7, the output terminal 9, or a load (not shown, for example, a printing device) connected to the output terminal 9, and a fuse 18. And a first resistor element 19 connected in series, and a second resistor element 20 connected in parallel. The second resistor element 20 has a resistance value of that of the first resistor element 19. It is larger than the resistance value.

The oscillating circuit 7 is a general one including a control element 21, a transformer 22, a control element 23, etc., and a normal driving power source for the control element 23 is supplied via a transformer 22, a rectifying element 24, and a capacitor element 25. It is supposed to be done.
The control element 21 and the control element 23 are connected via a resistance element 26.

Further, the rectifying circuit 8 is a general one that is composed of a rectifying element 27 and a capacitor element 28.

Next, one end side of the first capacitor element 11 that constitutes the noise filter 4 is connected to the control element 21 of the oscillation circuit 7 via the fifth rectifying element 29 and the resistance elements 30 and 31.
Further, the other end side of the first capacitor element 11 constituting the noise filter 4 is connected to the control element 21 of the oscillation circuit 7 via the sixth rectifying element 32 and the resistance elements 33 and 31.

Most of the above-mentioned configurations are well-known configurations, and will be briefly described in order to complicate the description.
That is, when the input terminal 1 is connected to the outlet 3 of the commercial AC power supply 2, the fifth rectifying element 29, the resistance elements 30, 31, or the sixth rectifying element is applied to the control element 21 of the oscillation circuit 7 depending on the polarity. Initial power is supplied through the element 32 and the resistance elements 33 and 31.
In other words, it becomes a standby state.

At the same time, power is supplied to the full-wave rectifier circuit 6 via the series connection body of the fuse 18 and the first resistance element 19. At this time, the presence of the first resistance element 19 causes Rapid current flow into the second capacitor element 16 is suppressed. That is, rush prevention is achieved.
At this time, the switching element 17 is in the off state, but when the standby state is completed, the oscillation circuit 7, the output terminal 9, or a load connected to the output terminal 9 (not shown, for example, printing When the switching element 17 is turned on by a signal from the device, full-scale power supply to the output terminal 9 is performed.

When the input terminal 1 is pulled out from the outlet 3 of the commercial AC power supply 2, the control element 21 of the oscillation circuit 7 confirms that the power supply via the fifth rectifying element 29 or the sixth rectifying element 32 is cut off. The switching element 17 is turned off by a signal from the oscillation circuit 7 or the output terminal 9 or a load (not shown, for example, a printing device) connected to the output terminal 9 which is detected.

Therefore, in this state, the charge accumulated in the first capacitor element 11 forming the noise filter 4 is changed from the one end side of the first capacitor element 11 to the fifth rectifying element 29 and the resistor element 30 depending on the polarity. , 31, the control element 21, and the second rectifying element 13 of the full-wave rectifying circuit 6, reach the other end side of the capacitor element 11 and are discharged.

When the polarities are opposite, the sixth rectifying element 32, the resistance elements 33 and 31, the control element 21, and the fourth rectifying element of the full-wave rectifying circuit 6 are arranged from the other end side of the first capacitor element 11. 15. Through the first resistance element 19 and the fuse 18 of the rush prevention circuit 5, the first capacitor element 11 is discharged to one end side.

However, since the fuse 18 may be cut off as a safety measure due to overcurrent, at that time, if the polarities are opposite, from the other end side of the first capacitor element 11 to the sixth rectifying element 32 and the resistor. Through the elements 33 and 31, the control element 21, the rectifying element 15 of the full-wave rectifying circuit 6, and the second resistance element 20 of the inrush prevention circuit 5, the first capacitor element 11 reaches one end side and is discharged. .

Since the resistance value of the second resistance element 20 is larger than that of the first resistance element 19, almost no current flows in the normal state, but when the fuse 18 is interrupted abnormally, the second resistance element 20 does not flow. It is possible to surely discharge the electric charge of the first capacitor element 11 via 20.

As described above, in the present embodiment, the first resistor is connected to the parallel connection body of the switching element 17 forming the inrush prevention circuit 5 and the series connection body of the fuse 18 and the first resistance element 19. Since the second resistance element 20 having a resistance value larger than that of the element 19 is simply connected in parallel, the configuration can be greatly simplified.

The present invention is used as a power supply device for various electronic devices.

1 Input Terminal 2 Commercial AC Power Supply 3 Outlet 4 Noise Filter 5 Inrush Prevention Circuit 6 Full Wave Rectifier Circuit 7 Oscillation Circuit 8 Rectifier Circuit 9 Output Terminal 10 Inductance Element 11 First Capacitor Element 12 First Rectifier Element 13 Second Rectification Element 14 Third rectifying element 15 Fourth rectifying element 16 Second capacitor element 17 Switching element 18 Fuse 19 First resistance element 20 Second resistance element 21 Control element 22 Transformer 23 Control element 24 Rectification element 25 Capacitor element 26 resistance element 27 rectification element 28 capacitor element 29 fifth rectification element 30 resistance element 31 resistance element 32 sixth rectification element 33 resistance element

Claims (3)

Input terminal, noise filter connected to the output side of this input terminal, full-wave rectifier circuit connected to the output side of this noise filter through the inrush prevention circuit, and connected to the output side of this full-wave rectifier circuit And an output terminal connected to the output side of the oscillation circuit,
The noise filter has an inductance element and a first capacitor element,
The full-wave rectifier circuit has a structure in which at least first, second, third, and fourth rectifying elements are connected in a bridge shape, and a second capacitor element is connected to the output side thereof,
The inrush prevention circuit includes a switching element that is opened and closed by a signal from the oscillation circuit, the output terminal, or a load connected to the output terminal, a serial connection body of a fuse and a first resistance element, and a second connection element. And a resistance element of the first resistance element, the resistance value of the second resistance element being larger than the resistance value of the first resistance element. One end side of the first capacitor element forming the noise filter is connected to the oscillation circuit through a fifth rectifying element, and the other end side of the first capacitor element forming the noise filter is connected. The power supply device according to claim 1, wherein the power supply device is connected to the oscillation circuit via a sixth rectifying element. The switching element forming the rush prevention circuit is turned off by stopping the power supply to the input terminal, and the electric charge accumulated in the first capacitor element forming the noise filter is stored in the first capacitor element. A first discharge circuit extending from one end side of the first capacitor element to the other end side of the first capacitor element via the fifth rectifying element, the oscillating circuit, and the full-wave rectifying circuit, and the first capacitor element. Is discharged from the other end side of the second rectifying element, the oscillation circuit, the full-wave rectifying circuit, and the second discharging circuit reaching the one end side of the first capacitor element through the rush prevention circuit. The power supply device according to claim 2, which is configured as follows.

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