CN102005945A - Method for designing photoelectric isolation type alternating-direct current voltage conversion circuit - Google Patents

Abstract

The invention relates to a direct current power supply, in particular to a method for designing a photoelectric isolation type alternating-direct current voltage conversion circuit for converting 220V alternating current into direct current without using a transformer. The method is characterized in that a rectifier circuit and DC/DC conversion circuits are arranged in a shell, a load circuit of the rectifier circuit is serially connected with a current-limiting resistor R0 and a light-emitting diode string, multiple silicon photocell units are arranged in a light-emitting direction of the light-emitting diode string, the voltage output ends of the silicon photocell units are electrically connected with the input ends of the DC/DC conversion circuits, and the output ends of the DC/DC conversion circuits are electrically connected with DC/DC voltage output ends of the shell; the silicon photocell units are respectively and electrically connected with the input ends of a plurality of DC/DC conversion circuits; and the output ends of the DC/DC conversion circuits are electrically connected with the DC/DC voltage output ends of the shell. The invention provides the method for designing the photoelectric isolation type alternating-direct voltage current conversion circuit for converting 220V alternating current into direct current without using the transformer.

Description

A kind of photoelectricity isolated form combined-voltage design of switching circuit method

Technical field

The present invention relates to a kind of DC power supply, particularly a kind ofly convert the 220V alternating current to galvanic a kind of photoelectricity isolated form combined-voltage design of switching circuit method without transformer.

Background technology

In electronic equipment, the required power supply of electronic device is many to be to convert to galvanicly by the 220V alternating current, and this transfer process has by transformer finishes the conversion of high pressure to low pressure, converts into low-voltage alternating-current to stream again.The switching power circuit of employing pattern is also arranged, and is that its volume of which kind of form all is must be bigger.It all needs transformer, and the transformer of Switching Power Supply is smaller.

Summary of the invention

The purpose of this invention is to provide a kind of transformer that do not need and convert the 220V alternating current to galvanic a kind of photoelectricity isolated form combined-voltage design of switching circuit method.

The object of the present invention is achieved like this, a kind of photoelectricity isolated form combined-voltage design of switching circuit method, it is characterized in that: rectification circuit and DC/DC change-over circuit are arranged in housing, the load circuit of rectification circuit is serially connected with current-limiting resistance R0 and light emitting diode string, the silicon photocell group is arranged on the light emission direction of light emitting diode string, the voltage output end of silicon photocell group is electrically connected with the input of DC/DC change-over circuit, and the output of DC/DC change-over circuit is electrically connected with the DC/DC voltage output end of housing; The silicon photocell component becomes many groups, is divided into many group silicon photocell groups and is electrically connected with the input of a plurality of DC/DC change-over circuits respectively; The output of a plurality of DC/DC change-over circuits is electrically connected with a plurality of DC/DC voltage output ends of housing.

The light emitting diode string number of the load circuit serial connection of described rectification circuit is according to the output current and the voltage parameter decision of DC/DC change-over circuit.

The rectifier diode of described rectification circuit is a light-emitting diode.

Described rectification circuit is bridge rectifier or semibridge system rectification circuit.

Advantage of the present invention is: owing to constitute the AC/DC change-over circuit by photoelectricity coupling circuit, a DC/DC change-over circuit, the diode of the rectification circuit of the input of photoelectricity coupling circuit is a light-emitting diode, the output circuit of photoelectricity coupling circuit is a silicon photocell, that is to say by the 220V alternating current is changeed the driven for emitting lights diode, by silicon photocell transform light energy is become electric energy, by the DC/DC change-over circuit voltage of silicon photocell is being changed into the direct current of needs at last.Direct current is to isolate fully with the 220V alternating current, therefore has the advantage that body is slight, reliability is high, anti-interference is good.

Description of drawings

The invention will be further described below in conjunction with the embodiment accompanying drawing:

Fig. 1 is principle of the invention figure;

Fig. 2 is the embodiment of the invention 1 structural representation;

Fig. 3 is the embodiment of the invention 2 structural representations.

Among the figure, 1, bridge rectifier; 2, DC/DC change-over circuit; 3, rectification circuit; 4, silicon photocell group; 5, housing; 6, light emitting diode string; 7, DC/DC voltage output end; 8, load circuit.

Embodiment

Embodiment 1

As shown in Figure 1, a kind of photoelectricity isolated form combined-voltage design of switching circuit method, rectification circuit 3 and DC/DC change-over circuit 2 are arranged in housing 5, the rectifier diode of rectification circuit 3 is light-emitting diodes, the load circuit 8 of rectification circuit 3 is serially connected with current-limiting resistance R0 and light emitting diode string 6, silicon photocell group 4 is arranged on the light emission direction of light emitting diode string 6, the voltage output end of silicon photocell group 4 is electrically connected with the input of DC/DC change-over circuit 2, and the output of DC/DC change-over circuit 2 is electrically connected with the DC/DC voltage output end 7 of housing 5.Rectification circuit 3 is bridge rectifiers 1, and light emitting diode string 6 numbers of load circuit 8 serial connections of bridge rectifier 1 are according to the output current and the voltage parameter decision of DC/DC change-over circuit 2.

Embodiment 2

As shown in Figure 2, rectification circuit 3 and DC/DC change-over circuit 2 are arranged in housing 5, the load circuit 8 of rectification circuit is serially connected with current-limiting resistance and light emitting diode string 6, silicon photocell group 4 is arranged on the light emission direction of light emitting diode string 6, the voltage output end of silicon photocell group 4 is electrically connected with the input of DC/DC change-over circuit 2, and the output of DC/DC change-over circuit 2 is electrically connected with the DC/DC voltage output end 7 of housing 5.Rectification circuit 3 is bridge rectifiers 1, the number of the light emitting diode string 6 of load circuit 8 serial connections of bridge rectifier 1 is to determine according to DC/DC output current and voltage, embodiment 2 is common rectification two utmost points with the rectifier diode that is not both rectification circuit 3 of embodiment 1, as 1N4001,1N4007 or the like.

Embodiment 3

Rectification circuit 3 and DC/DC change-over circuit 2 are arranged in housing 5, the load circuit 8 of rectification circuit is serially connected with current-limiting resistance and light emitting diode string 6, silicon photocell group 4 is arranged on the light emission direction of light emitting diode string 6, the voltage output end of silicon photocell group 4 is electrically connected with the input of DC/DC change-over circuit 2, and the output of DC/DC change-over circuit 2 is electrically connected with the DC/DC voltage output end 7 of housing 5.Rectification circuit 3 is semibridge system rectification circuits, and the light-emitting diode number of load circuit 8 serial connections of semibridge system rectification circuit is determined according to DC/DC output current and voltage.

Embodiment 4

As shown in Figure 3, rectification circuit 3 and DC/DC change-over circuit 2 are arranged in housing 5, the load circuit 8 of rectification circuit is serially connected with current-limiting resistance and light emitting diode string 6, silicon photocell group 4 is arranged on the light emission direction of light emitting diode string 6, silicon photocell group 4 is divided into many groups, being divided into many group silicon photocell groups 4 is electrically connected with the input of a plurality of DC/DC change-over circuits 2 respectively, the output of a plurality of DC/DC change-over circuits 2 is electrically connected with a plurality of DC/DC voltage output ends of housing 5, and a plurality of DC/DC voltage output end electricity altogether.Rectification circuit 3 is bridge rectifiers, and the light-emitting diode number of load circuit 8 serial connections of bridge rectifier is determined according to DC/DC output current and voltage.

Embodiment 5

As shown in Figure 3, rectification circuit 3 and DC/DC change-over circuit 2 are arranged in housing 5, the load circuit 8 of rectification circuit is serially connected with current-limiting resistance and light emitting diode string 6, silicon photocell group 4 is arranged on the light emission direction of light emitting diode string 6, silicon photocell group 4 is divided into many groups, being divided into many group silicon photocell groups 4 is electrically connected with the input of a plurality of DC/DC change-over circuits 2 respectively, the output of a plurality of DC/DC change-over circuits 2 is electrically connected with a plurality of DC/DC voltage output ends of housing 5, and a plurality of DC/DC voltage output end electricity are not altogether.Rectification circuit 3 is bridge rectifiers, and the light-emitting diode number of load circuit 8 serial connections of bridge rectifier is determined according to DC/DC output current and voltage.

Claims (4)

1. photoelectricity isolated form combined-voltage design of switching circuit method, it is characterized in that: rectification circuit and DC/DC change-over circuit are arranged in housing, the load circuit of rectification circuit is serially connected with current-limiting resistance R0 and light emitting diode string, the silicon photocell group is arranged on the light emission direction of light emitting diode string, the voltage output end of silicon photocell group is electrically connected with the input of DC/DC change-over circuit, and the output of DC/DC change-over circuit is electrically connected with the DC/DC voltage output end of housing; The silicon photocell component becomes many groups, is divided into many group silicon photocell groups and is electrically connected with the input of a plurality of DC/DC change-over circuits respectively; The output of a plurality of DC/DC change-over circuits is electrically connected with a plurality of DC/DC voltage output ends of housing.

2. a kind of photoelectricity isolated form combined-voltage design of switching circuit method according to claim 1 is characterized in that: the light emitting diode string number of the load circuit serial connection of described rectification circuit is according to the output current and the voltage parameter decision of DC/DC change-over circuit.

3. a kind of photoelectricity isolated form combined-voltage design of switching circuit method according to claim 1, it is characterized in that: the rectifier diode of described rectification circuit is a light-emitting diode.

4. a kind of photoelectricity isolated form combined-voltage design of switching circuit method according to claim 1, it is characterized in that: described rectification circuit is bridge rectifier or semibridge system rectification circuit.

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