CN208522662U - A kind of power circuit - Google Patents

Abstract

The utility model embodiment discloses a kind of power circuit, comprising: AC to DC converter circuit, for exporting electric signal to the control circuit, the electric signal includes AC compounent and DC component；Control circuit, it is connect with the AC to DC converter circuit, subcomponent is exchanged with second for the AC compounent to be divided into the first exchange subcomponent, and controls the AC to DC converter circuit and exports the first exchange subcomponent and the second exchange the sum of the subcomponent and the DC component respectively to condenser network and DC-DC circuit；The condenser network is connect with the AC to DC converter circuit, for filtering out the first exchange subcomponent；The DC-DC circuit is connect with the AC to DC converter circuit, for exporting after the second exchange the sum of the subcomponent and the DC component are carried out boost or depressurization processing.Power circuit can be reduced to the dependence of electrolytic capacitor, thus the adverse effect for preventing the aging of electrolytic capacitor from generating to power circuit.

Description

A kind of power circuit

Technical field

The utility model relates to electronic technology field more particularly to a kind of power circuits.

Background technique

Direct current (AC/DC) converter is turned for the exchange of isolated form two-stage and generally includes AC/DC, electrolytic capacitor (such as BULK electricity Hold) and DC to DC (DC/DC) three-level circuit.Wherein, after the processing of AC/DC grades of circuits, alternating current becomes with friendship Flow the electric signal of ingredient and flip-flop.In order to achieve the purpose that direct current output, electrolytic capacitor is needed to filter out wherein all friendships Flow ingredient.Therefore the configuration biggish electrolytic capacitor of capacitance is usually required that conventional isolated form two-stage AC/DC converter, this not only makes Volume at the capacitor needed to configure is excessive, and when alternating component accounting is larger, will lead to electrolytic capacitor and seriously generate heat, more For it is important that electrolytic capacitor influence of the aging characteristics to capacitance and heat sinking function, become and restrict AC/DC converter and make With the key factor in service life.

Utility model content

The utility model embodiment provides a kind of power circuit.Power circuit can be reduced to the dependence of electrolytic capacitor, Adverse effect to prevent the aging of electrolytic capacitor from generating to power circuit.

The utility model embodiment provides a kind of power circuit, and the power circuit includes AC to DC converter circuit, control Circuit, condenser network and DC-DC circuit processed, in which:

The AC to DC converter circuit, for exporting electric signal to the control circuit, the electric signal includes exchange point Amount and DC component；

The control circuit is connect with the AC to DC converter circuit, for the AC compounent to be divided into the first friendship It flows subcomponent and exchanges subcomponent with second, and control the AC to DC converter circuit and handed over to condenser network output described first It flows subcomponent and exchanges subcomponent and the DC component to DC-DC circuit output described second；

The condenser network is connect with the AC to DC converter circuit, for filtering out the first exchange subcomponent；

The DC-DC circuit is connect with the AC to DC converter circuit, for the second exchange subcomponent Boost or depressurization processing is carried out with the sum of the DC component, and output is by boost or depressurization treated the second exchange The sum of component and the DC component.

Wherein, the first exchange subcomponent is the product of the AC compounent and distribution coefficient, and the distribution coefficient is Number more than or equal to 0 and less than or equal to 1.

Wherein, the calculation formula of the AC compounent is

It is described first exchange subcomponent calculation formula be

Wherein, I is the current peak of the DC component, t is the time and k is the distribution coefficient.

Wherein, the second exchange subcomponent is the difference that the AC compounent subtracts the first exchange subcomponent.

Wherein, the calculation formula of the second exchange subcomponent is

Wherein, I is the current peak of the DC component, t is the time and k is the distribution coefficient.

Wherein, the control circuit is also connect with the DC-DC circuit, for obtaining the amplitude of the electric signal And phase, and according to the amplitude and the phase, the input for adjusting the DC-DC circuit is the second exchange The sum of component and the DC component.

Wherein, the AC to DC converter circuit includes rectification unit Q1, inductance L1, switch S1, diode D5, in which:

The first output port of the rectification unit Q1 is connect with one end of the inductance L1, and the rectification unit Q1's is another One output port is connect with one end of the switch S1, the other end of the other end of the inductance L1 and the switch S1 respectively at The anode connection of the diode D5, the cathode of the diode D5 are connect with the first input port of the condenser network.

Wherein, the condenser network includes capacitor C1, in which:

One end of the capacitor C1 is connect with the first output port of the AC to DC converter circuit, and the capacitor C1's is another One end is connect with the second output terminal mouth of the AC to DC converter circuit.

Wherein, the capacitor C1 is electrolytic capacitor.

Wherein, the DC-DC circuit includes switch S2, transformer T1, diode D6, capacitor C2 and resistance R1, In:

One end of the switch S2 is connect with the first output port of the AC to DC converter circuit, and the switch S2's is another One end is connect with the first input port of the transformer T1, and the second input port of the transformer T1 turns straight with described exchange The second output terminal mouth of current circuit connects, and the first output port of the transformer T1 is connect with the anode of the diode D6, One end of the cathode of the diode D6 and the capacitor C2 are connect with one end of the resistance R1 respectively, the transformer T1's The other end of second output terminal mouth and the capacitor C2 are connect with the other end of the resistance R1 respectively.

Implement the utility model embodiment, AC to DC converter circuit first exports electric signal to the control circuit, described Electric signal includes AC compounent and DC component；Then the AC compounent is divided into the first exchange point by the control circuit Amount with second exchange subcomponent, and control the AC to DC converter circuit to condenser network export described first exchange subcomponent, And subcomponent and the DC component are exchanged to DC-DC circuit output described second；Then the condenser network filters out The first exchange subcomponent；The last DC-DC circuit to the second exchange subcomponent and the DC component it With carry out boost or depressurization processing, output is by boost or depressurization treated the second exchange subcomponent and the direct current point The sum of amount.By the AC compounent of reduction input capacitance circuit, power circuit can be reduced to the dependence of electrolytic capacitor, thus The adverse effect for preventing the aging of electrolytic capacitor from generating to power circuit.

Detailed description of the invention

It, below will be to required in embodiment description in order to illustrate more clearly of the technical solution of the utility model embodiment The attached drawing used is briefly described, it should be apparent that, the accompanying drawings in the following description is some embodiments of the utility model, right For those of ordinary skill in the art, without creative efforts, it can also be obtained according to these attached drawings His attached drawing.

Fig. 1 be the utility model proposes a kind of power circuit first embodiment structural schematic diagram；

Fig. 2 is a kind of structural schematic diagram for AC to DC converter circuit that the utility model embodiment proposes；

Fig. 3 (a) is a kind of waveform diagram of the electric current of alternating current provided by the embodiment of the utility model；

Fig. 3 (b) is a kind of waveform diagram of the electric current of electric signal provided by the embodiment of the utility model；

Fig. 4 (a) is a kind of waveform diagram of AC compounent provided by the embodiment of the utility model；

Fig. 4 (b) is a kind of waveform diagram of DC component provided by the embodiment of the utility model；

Fig. 5 is that the waveform of the sum of a kind of second exchange subcomponent and DC component provided by the embodiment of the utility model is illustrated Figure；

Fig. 6 be the utility model proposes a kind of power circuit second embodiment structural schematic diagram；

Fig. 7 be the utility model proposes a kind of two-stage independent control in the prior art electrical block diagram；

Fig. 8 be the utility model proposes a kind of two-stage merge control electrical block diagram.

Specific embodiment

The following will be combined with the drawings in the embodiments of the present invention, carries out the technical scheme in the embodiment of the utility model It clearly and completely describes, it is clear that the embodiments are a part of the embodiments of the present invention, rather than whole implementation Example.Based on the embodiments of the present invention, those of ordinary skill in the art are obtained without creative efforts The every other embodiment obtained, fall within the protection scope of the utility model.

Referring to FIG. 1, Fig. 1 be the utility model proposes a kind of power circuit first embodiment structural schematic diagram. As shown, the circuit in the utility model embodiment includes:

AC to DC converter circuit 101, for exporting electric signal to the control circuit, the electric signal includes AC compounent And DC component.

Specifically, as shown in Fig. 2, AC to DC converter circuit 101 may include rectification unit Q1, inductance L1, switch S1 and Diode D5, wherein the first output port of the rectification unit Q1 is connect with one end of the inductance L1, the rectification unit Another output port of Q1 is connect with one end of switch S1, the other end difference of the other end of the inductance L1 and the switch S1 It is connect with the anode of the diode D5, the first input port of the cathode of the diode D5 and the condenser network 103 connects It connects.Wherein, rectification unit Q1 is made of diode D1, diode D2, diode D3 and diode D4, can be carried out to alternating current Rectification, and the cathode of diode D1 is connect with the cathode of diode D2, and the anode of diode D2 connects with the cathode of diode D4 It connects, the anode of diode D4 is connect with the anode of diode D3 and the cathode of diode D3 is connect with the anode of diode D1. Inductance L1 is used to inhibit the kurtosis of current/voltage, and switch S1 can be on-load switch, for protecting circuit.Diode D5 is used In carrying out secondary rectification, so as to the AC compounent being further reduced in the electric signal.The AC to DC converter circuit 101 can be with Alternating current is rectified using rectification unit Q1 and diode D5, obtains the electric signal, which includes electric current and electricity Pressure.Because alternating current can not be thoroughly converted into direct current by rectification unit Q1 and diode D5, which both included DC component also includes AC compounent.Wherein, DC component is the average value of electric signal, it is not changed with time, Such as the average value of electric current, the AC compounent is the amount changed with time in the electric signal.

Such as: as shown in Fig. 3 (a), the electric current of the alternating current of AC power source output is 3sin (t), wherein t is the time, electricity The unit of stream is that the unit of ampere (A) and t are the second (s).After AC to DC converter circuit 101 rectifies the alternating current, Shown in the waveform of the electric current of obtained electric signal such as Fig. 3 (b).Because the electric current of the presence of AC compounent, the electric signal is unstable, It but is same direction current.

It should be noted that AC to DC converter circuit 101 can with but be not limited to topological structure shown in Fig. 2.

Control circuit 102 is connect with the AC to DC converter circuit 101, for the AC compounent to be divided into first It exchanges subcomponent and exchanges subcomponent with second, and control the AC to DC converter circuit 101 and export institute to the condenser network 103 It states the first exchange subcomponent and exports the second exchange subcomponent and the direct current to the DC-DC circuit 104 Component.

Specifically, control circuit 102 can be the integrated circuit with operation, storage and control function.Control circuit 102 The electric signal can be sampled first, according to amplitude, the phase of the electric signal that sampling obtains, determine the electric signal Waveform and its mathematic(al) representation；The AC compounent and DC component of the electric signal are calculated then according to mathematic(al) representation；Then The AC compounent is divided into the first exchange subcomponent and exchanges subcomponent with second, wherein described first, which exchanges subcomponent, is The product of the AC compounent and distribution coefficient, the distribution coefficient are the number (such as 0.6) more than or equal to 0 and less than or equal to 1, institute Stating the second exchange subcomponent is the difference that the AC compounent subtracts the first exchange subcomponent；The exchange is finally controlled to turn DC circuit 101 to the condenser network 103 exports the first exchange subcomponent and to the DC-DC circuit The 104 connection output second exchange subcomponents and the DC component.

Optionally, the calculation formula of the AC compounent of electric signal can be

It is described first exchange subcomponent calculation formula can be

It is described second exchange subcomponent calculation formula can be

Wherein, I is the current peak of the DC component, t is the time and k is the distribution coefficient.

Such as: as shown in figure 3, carrying out sampling the available electric signal being 3sin by the electric current to electric signal first (t).Further, as shown in Fig. 4 (a), the AC compounent for the electric current that the electric signal can be calculated by Fourier transformation is 3* | sin (t) | -2*3/ π, and as shown in Fig. 4 (b), DC component is 2*3/ π；Then by AC compounent 3* | sin (t) | -2* 3/ π be divided into the first exchange subcomponent 0.6* (3* | sin (t) | -2*3/ π) with second exchange subcomponent 0.4* (3* | sin (t) | - 2*3/π)。

Condenser network 103 is connect with the AC to DC converter circuit 101, for filtering out the first exchange subcomponent.

Specifically, condenser network 103 may include at least one electrolytic capacitor, the first exchange subcomponent is flowing through electrolysis electricity Rong Shi will dissipate on electrolytic capacitor, and when the peak value of the first exchange subcomponent is in the permissible range of the electrolytic capacitor It is interior, and the sum of capacity of at least one electrolytic capacitor can accommodate the first exchange subcomponent and dissipate completely discharged charge When, the first exchange subcomponent will dissipate completely, achieve the purpose that filter out the first exchange subcomponent.Wherein, the first exchange Component is a part in AC compounent, compared to whole AC compounents is filtered out, filters out the first exchange subcomponent to electrolysis electricity The capacity requirement of appearance is reduced, and when distribution coefficient is 0, and the first exchange subcomponent is 0, then can be to avoid to electrolysis The use of capacitor.

DC-DC circuit 104 is connect with the AC to DC converter circuit 101, for the second exchange son point Amount and the sum of the DC component carry out boost or depressurization processing, and output is by boost or depressurization treated second exchange The sum of subcomponent and the DC component.

Specifically, in order to adapt to the requirement to voltage or electric current of electrical equipment, DC-DC circuit 104 can be by Two exchange subcomponents and DC component are overlapped after electric signal obtained does boost or depressurization processing and export to electrical equipment.

Such as: as shown in figure 5, by the second of the electric current of electric signal the exchange subcomponent 0.4* (3* | sin (t) | -2*3/ π) and DC component 2*3/ π is overlapped to obtain the current signal in figure, and DC-DC circuit 104, which flows through the current signal, to be produced Raw voltage exports after carrying out decompression processing to electrical equipment.

In the utility model embodiment, AC to DC converter circuit exports electric signal to the control circuit first, described Electric signal includes AC compounent and DC component；Then the AC compounent is divided into the first exchange point by the control circuit Amount with second exchange subcomponent, and control the AC to DC converter circuit to condenser network export described first exchange subcomponent, And subcomponent and the DC component are exchanged to DC-DC circuit output described second；Then the condenser network filters out The first exchange subcomponent；The last DC-DC circuit to the second exchange subcomponent and the DC component it With progress boost or depressurization processing.By reducing the AC compounent of input capacitance circuit, power circuit can be reduced to electrolysis electricity The dependence of appearance, thus the adverse effect for preventing the aging of electrolytic capacitor from generating to power circuit.

Referring to FIG. 6, Fig. 6 be the utility model proposes a kind of power circuit second embodiment structural schematic diagram. As shown, the circuit in the utility model embodiment includes:

AC to DC converter circuit 601, for exporting electric signal to the control circuit, the electric signal includes AC compounent And DC component.

Specifically, as shown in Fig. 2, AC to DC converter circuit 601 may include rectification unit Q1, inductance L1, switch S1 and Diode D5, wherein the first output port of the rectification unit Q1 is connect with one end of the inductance L1, the rectification unit Another output port of Q1 is connect with one end of switch S1, the other end difference of the other end of the inductance L1 and the switch S1 It is connect with the anode of the diode D5, the first input port of the cathode of the diode D5 and the condenser network 603 connects It connects.Wherein, rectification unit Q1 is made of diode D1, diode D2, diode D3 and diode D4, can be carried out to alternating current Rectification, and the cathode of diode D1 is connect with the cathode of diode D2, and the anode of diode D2 connects with the cathode of diode D4 It connects, the anode of diode D4 is connect with the anode of diode D3 and the cathode of diode D3 is connect with the anode of diode D1. Inductance L1 is used to inhibit the kurtosis of current/voltage.Switch S1 can be on-load switch, for protecting circuit.Diode D5 is used In carrying out secondary rectification, so as to the AC compounent being further reduced in the electric signal.The AC to DC converter circuit 601 can be with Alternating current is rectified using rectification unit Q1 and diode D5, obtains the electric signal, which includes electric current and electricity Pressure.Because alternating current can not be thoroughly converted into direct current by rectification unit Q1 and diode D5, which both included DC component also includes AC compounent.Wherein, DC component is the average value of electric signal, it is not changed with time, Such as the average value of electric current, the AC compounent is the amount changed with time in the electric signal.

It should be noted that AC to DC converter circuit 601 can with but be not limited to topological structure shown in Fig. 2.

Control circuit 602 is connect with the AC to DC converter circuit, for the AC compounent to be divided into the first exchange Subcomponent exchanges subcomponent with second, and controls the AC to DC converter circuit 601 and export described to the condenser network 603 One exchanges subcomponent and exports the second exchange subcomponent and the DC component to the DC-DC circuit 604.

Specifically, control circuit 602 can be the integrated circuit with operation, storage and control function.Control circuit 602 The electric signal can be sampled first, according to amplitude, the phase of the electric signal that sampling obtains, determine the electric signal Waveform and its mathematic(al) representation；The AC compounent and DC component of the electric signal are calculated then according to mathematic(al) representation；Then The AC compounent is divided into the first exchange subcomponent and exchanges subcomponent with second, wherein described first, which exchanges subcomponent, is The product of the AC compounent and distribution coefficient, the distribution coefficient are the number (such as 0.6) more than or equal to 0 and less than or equal to 1, institute Stating the second exchange subcomponent is the difference that the AC compounent subtracts the first exchange subcomponent；The exchange is finally controlled to turn DC circuit 601 to the condenser network 603 exports the first exchange subcomponent and to the DC-DC circuit The 604 connection output second exchange subcomponents and the DC component.

Optionally, the calculation formula of the AC compounent of electric signal can be

It is described first exchange subcomponent calculation formula can be

It is described second exchange subcomponent calculation formula can be

Wherein, I is the current peak of the DC component, t is the time and k is the distribution coefficient.

Optionally, the control circuit 602 can also be connect with the DC-DC circuit 604, for according to The amplitude and phase of electric signal, the input for adjusting DC-DC circuit 604 is the second exchange subcomponent and the direct current The sum of component.Wherein, the amplitude and phase for the electric signal that control circuit 602 can be obtained according to sampling first, determining should The waveform and its mathematic(al) representation of electric signal, so that the second exchange subcomponent and the DC component and sum of the two are calculated, Then the input of DC-DC circuit 604 is controlled, to ensure that the input of DC-DC circuit 604 is handed over second It is identical to flow the sum of subcomponent and the DC component.

It should be noted that including AC compounent in DC-DC circuit in the utility model embodiment, therefore, such as Shown in Fig. 7, independent control circuit is used according to AC to DC converter circuit in the prior art and DC-DC circuit Scheme, then in order to which the electric signal that actually enters for controlling DC-DC circuit is the second exchange the sum of subcomponent and DC component, The control circuit of DC-DC circuit needs again to sample the amplitude of electric signal and phase, such in order to avoid occurring Situation, in the utility model embodiment AC to DC converter circuit and DC-DC circuit can share control circuit to input/ Output is controlled, and concrete condition is as shown in Figure 8, wherein includes AC compounent division module and control mould in control circuit Block increases AC compounent division module compared with the prior art.

Condenser network 603 is connect with the AC to DC converter circuit 601, for filtering out the first exchange subcomponent.

Specifically, the condenser network may include capacitor C1, wherein capacitor C1 can be electrolytic capacitor, such as bus (BULK) capacitor.Wherein, one end of the capacitor C1 is connect with the first output port of AC to DC converter circuit 601, the other end With the second output terminal mouth in AC to DC converter circuit 601.First exchange subcomponent, will be in capacitor C1 when flowing through capacitor C1 It dissipates, in the permissible range of the peak value capacitor C1 of the first exchange subcomponent, and the capacity of capacitor C1 can accommodate the first friendship Stream subcomponent dissipate completely discharged charge when, first exchange subcomponent will dissipate completely, reach filter out it is described first exchange The purpose of subcomponent.

DC-DC circuit 604 is connect with the AC to DC converter circuit 601, for the second exchange son point Amount and the sum of the DC component carry out boost or depressurization processing, and output is by boost or depressurization treated second exchange The sum of subcomponent and the DC component.

Specifically, the DC-DC circuit 604 may include switch S2, transformer T1, diode D6, capacitor C2 and Resistance R1, wherein one end of the switch S2 is connect with the first output port of the AC to DC converter circuit 601, described to open Close S2 the other end connect with the first input port of the transformer T1, the second input port of the transformer T1 with it is described The second output terminal mouth of AC to DC converter circuit 601 connects, the first output port of the transformer T1 and the diode D6 Anode connection, one end of the cathode of the diode D6 and the capacitor C2 connect with one end of the resistance R1 respectively, institute The other end of the second output terminal mouth and the capacitor C2 of stating transformer T1 is connect with the other end of the resistance R1 respectively.Its In, switch S2 can be on-load switch, and for carrying out overload and short-circuit protection to transformer T1, diode D6 is for carrying out convection current The electric signal of warp is rectified, and resistance R1 prevents the output excessive damage electrical equipment of electric current, transformer T1 is used for carrying out current limliting In to electric signal progress boost or depressurization.

It should be noted that DC-DC circuit 604 can with but be not limited to the topological structure that Fig. 6 provides.

In order to adapt to the requirement to voltage or electric current of electrical equipment, DC-DC circuit 604 can be by the second exchange Subcomponent and DC component are overlapped after electric signal obtained does boost or depressurization processing and export to electrical equipment.

Such as: as shown in figure 5, by the second of the electric current of electric signal the exchange subcomponent 0.4* (3* | sin (t) | -2*3/ π) and DC component 2*3/ π is overlapped to obtain the current signal in figure, and DC-DC circuit 604, which flows through the current signal, to be produced Raw voltage exports after carrying out decompression processing to electrical equipment.

In the utility model embodiment, AC to DC converter circuit exports electric signal to the control circuit first, described Electric signal includes AC compounent and DC component；Then the AC compounent is divided into the first exchange point by the control circuit Amount with second exchange subcomponent, and control the AC to DC converter circuit to condenser network export described first exchange subcomponent, And subcomponent and the DC component are exchanged to DC-DC circuit output described second；Then the condenser network filters out The first exchange subcomponent；The last DC-DC circuit to the second exchange subcomponent and the DC component it With progress boost or depressurization processing.By reducing the AC compounent of input capacitance circuit, power circuit can be reduced to electrolysis electricity The dependence of appearance, thus the adverse effect for preventing the aging of electrolytic capacitor from generating to power circuit.

It should be noted that for simple description, therefore, it is stated as a systems for each embodiment of the method above-mentioned The combination of actions of column, but those skilled in the art should understand that, the utility model is not by the limit of described sequence of movement System, because certain some step can be performed in other orders or simultaneously according to the utility model.Secondly, art technology Personnel also should be aware of, and the embodiments described in the specification are all preferred embodiments, and related actions and modules is not It must be necessary to the utility model.

In the above-described embodiments, it all emphasizes particularly on different fields to the description of each embodiment, is not described in some embodiment Part, reference can be made to the related descriptions of other embodiments.

Those of ordinary skill in the art will appreciate that all or part of the steps in the various methods of above-described embodiment is can It is completed with instructing relevant hardware by program, which can be stored in a computer readable storage medium, storage Medium may include: flash disk, read-only memory (English: Read-Only Memory, abbreviation: ROM), random access device (English Text: Random Access Memory, referred to as: RAM), disk or CD etc..

Detailed Jie has been carried out to content download method provided by the utility model embodiment and relevant device, system above It continues, specific case used herein is expounded the principles of the present invention and embodiment, and above embodiments are said The bright method and its core concept for being merely used to help understand the utility model；At the same time, for those skilled in the art, Based on the idea of the present invention, there will be changes in the specific implementation manner and application range, in conclusion this explanation Book content should not be construed as a limitation of the present invention.

Claims (6)

1. a kind of power circuit, which is characterized in that the power circuit includes AC to DC converter circuit, control circuit, capacitor electricity Road and DC-DC circuit, in which:

The AC to DC converter circuit, for the control circuit export electric signal, the electric signal include AC compounent and DC component；

The control circuit is connect with the AC to DC converter circuit, for the AC compounent to be divided into the first exchange Component and the second exchange subcomponent, and the AC to DC converter circuit is controlled to condenser network output the first exchange Component and to DC-DC circuit output the second exchange subcomponent and DC component；

The condenser network is connect with the AC to DC converter circuit, for filtering out the first exchange subcomponent；

The DC-DC circuit is connect with the AC to DC converter circuit, for the second exchange subcomponent and institute State the sum of DC component carry out boost or depressurization processing, output by boost or depressurization treated it is described second exchange subcomponent The sum of with the DC component.

2. power circuit as described in claim 1, which is characterized in that the control circuit, it is also electric with the DC to DC Road connection adjusts the direct current and turns for obtaining the amplitude and phase of the electric signal, and according to the amplitude and the phase The input of DC circuit is the second exchange the sum of the subcomponent and the DC component.

3. power circuit as described in claim 1, which is characterized in that the AC to DC converter circuit include rectification unit Q1, Inductance L1, switch S1, diode D5, in which:

The first output port of the rectification unit Q1 is connect with one end of the inductance L1, and the rectification unit Q1's is another defeated Exit port is connect with one end of the switch S1, the other end of the other end of the inductance L1 and the switch S1 respectively with it is described The anode connection of diode D5, the cathode of the diode D5 are connect with the first input port of the condenser network.

4. power circuit as described in claim 1, which is characterized in that the condenser network includes capacitor C1, in which:

One end of the capacitor C1 is connect with the first output port of the AC to DC converter circuit, the other end of the capacitor C1 It is connect with the second output terminal mouth of the AC to DC converter circuit.

5. power circuit as claimed in claim 4, which is characterized in that the capacitor C1 is electrolytic capacitor.

6. power circuit as described in claim 1, which is characterized in that the DC-DC circuit includes switch S2, transformation Device T1, diode D6, capacitor C2 and resistance R1, in which:

One end of the switch S2 is connect with the first output port of the AC to DC converter circuit, the other end of the switch S2 It is connect with the first input port of the transformer T1, the second input port of the transformer T1 turns direct current with described exchange The second output terminal mouth on road connects, and the first output port of the transformer T1 is connect with the anode of the diode D6, described One end of the cathode of diode D6 and the capacitor C2 are connect with one end of the resistance R1 respectively, and the second of the transformer T1 The other end of output port and the capacitor C2 are connect with the other end of the resistance R1 respectively.