CN204578189U - Oxyhydrogen machine energy-saving current voltage stabilizing auxiliary system - Google Patents

Abstract

The utility model discloses a kind of oxyhydrogen machine energy-saving current voltage stabilizing auxiliary system, it comprises reserve battery, charging and voltage stabilizing circuit, detects commutation circuit and output voltage stabilizing circuit.Topology layout of the present utility model is reasonable, can discharge and recharge simultaneously, namely utilizes the providing auxiliary power amount of traveling apparatus generator with a stable current/voltage supply oxyhydrogen generator and is supplemented to backup battery, backup battery can be automatically switched to when energy output is not enough and be continuously the working power that oxyhydrogen generator provides stable, the job stability of effective guarantee oxyhydrogen generator, engine for traveling apparatus provides the hydrogen of constant flow rate, carrier of oxygen, reliability is high, the power of effective lifting engine and saving fuel oil, energy-conserving and environment-protective, greatly extend traveling apparatus to carry battery and ensure the normal operation of traveling apparatus simultaneously, applied widely, may be used for fuel oil, on the traveling apparatus of the fuel such as natural gas, as at car, bus, the equipment such as lorry and steamer uses.

Description

Oxyhydrogen machine energy-saving current voltage stabilizing auxiliary system

Technical field

The utility model relates to a kind of management of charging and discharging technical field, specifically a kind of oxyhydrogen machine energy-saving current voltage stabilizing auxiliary system.

Background technology

Along with the consumption of the energy is increasing, also more and more higher to the power conservation requirement of traveling apparatus.

Engine is the power part of the traveling apparatus such as automobile, and the fuel that the cylinder combustion of traditional engine is burnt is simple gasoline or diesel oil, relies on the burning of simple fuel to be kinetic energy by chemical energy.But existing engine also exists the burning phenomenon not fully of fuel, and thus the chemical transformation of energy of fuel is insufficient, and the gross power of engine is not high enough, finally shows as burnup high.

For promoting fuel oil effect, Chinese invention patent application number " 201310159042.5 ", publication number " CN 103233830 A ", name is called " Oxy-hydrogen hybrid power device ", comprise the engine with air intake branch, also comprise: by be provided with air inlet and gas outlet container, be contained in the filtered fluid in this container and be immersed in the filter that the air permeable plate in filtered fluid forms, under described air inlet is positioned at the liquid level of filtered fluid, described gas outlet is positioned on the liquid level of filtered fluid, and is communicated with described air intake branch; By positive and negative electrolysis electrode be contained in the water-splitting case that the electrolyte in electrolysis tank forms, for generation of hydrogen, carrier of oxygen, and be communicated with described air inlet; The automatic controller be electrically connected with described positive and negative electrolysis electrode, for controlling the flow of produced hydrogen, carrier of oxygen; And the vehicular power-bottle to be electrically connected with described automatic controller.Under the effect of vehicular power-bottle, automatic controller can control the flow that water-splitting case generates hydrogen, carrier of oxygen, and hydrogen, carrier of oxygen are sent into the cylinder of engine through filter from air intake branch, participate in the burning in cylinder, adding of hydrogen, carrier of oxygen makes the burning of cylinder fuel more abundant.

But in actual use, because it is without special oxyhydrogen machine energy-saving current voltage stabilizing auxiliary system, cause the current/voltage supplying water-splitting case unstable, have influence on the flow of hydrogen, carrier of oxygen, be difficult to the normal work ensureing engine, reliability reduces.Meanwhile, owing to being supply water-splitting case working power by vehicular power-bottle, cause vehicular power-bottle load excessive, easily occur, because electricity deficiency affects normal vehicle operation problem, also substantially reducing the life-span of vehicular power-bottle in addition.

Summary of the invention

For above-mentioned deficiency, the utility model object is, a kind of topology layout is reasonable, can simultaneously discharge and recharge, the unnecessary electricity that traveling apparatus work can be utilized to travel generator is supplemented to the electricity of backup battery, and can provide stable working power for oxyhydrogen generator, good operating stability, reliability is high, and the normal operation of effective guarantee traveling apparatus and prolongation carry the oxyhydrogen machine energy-saving current voltage stabilizing auxiliary system of battery.

For achieving the above object, the technical scheme provided is the utility model: a kind of oxyhydrogen machine energy-saving current voltage stabilizing auxiliary system, and it comprises reserve battery, charging and voltage stabilizing circuit, detects commutation circuit and output voltage stabilizing circuit.Wherein, reserve battery, for providing power supply for oxyhydrogen generator; Charging and voltage stabilizing circuit, for charging the unnecessary electricity of traveling apparatus to reserve battery with a stable current/voltage; Detecting commutation circuit, for detecting the electrical voltage point of traveling apparatus from charged pool, reserve battery, when traveling apparatus generator has providing auxiliary power amount, this energy output can be utilized to provide stable working power for oxyhydrogen generator and/or charge to reserve battery; When the energy output of traveling apparatus generator is not enough, switches to reserve battery and be continuously the working power that oxyhydrogen generator provides stable; When energy output when traveling apparatus generator and the electricity from charged pool are all not enough, suspend and provide power supply to oxyhydrogen generator, until the electricity of reserve battery returns to preset value just for oxyhydrogen generator provides stable working power; Output voltage stabilizing circuit, for by traveling apparatus generator, traveling apparatus from the electricity of charged pool and reserve battery with a stable current/voltage supply oxyhydrogen generator.

Improve as one of the present utility model, described charging and voltage stabilizing circuit comprises P-MOS type field-effect transistor Q1, N-MOS type field-effect transistor Q2, integrated package U1, integrated package U2, inductance L 1, diode D1, diode D2, resistance R1, resistance R2, resistance R3, resistance R4, resistance R5 and resistance R6, the drain electrode of described P-MOS type field-effect transistor Q1 connects the positive source of traveling apparatus, grid connects the 1st end pin of integrated package U1, drain electrode is connected with one end of inductance L 1 with diode D1 respectively, the other end ground connection of this diode D1, the other end of this inductance L 1 is connected with the source electrode of N-MOS type field-effect transistor Q2 diode D2 one end respectively, the other end of diode D2 is connected with the positive pole of reserve battery, and series resistance R4 and resistance R5 successively, the other end of this resistance R4 is connected with the 1st end pin of integrated package U2, and by resistance R6 ground connection, the grounded drain of N-MOS type field-effect transistor Q2, grid is connected with the 5th end pin of integrated package U2, and the 4th end pin of integrated package U1 is by resistance R1 ground connection, and series resistance R3 successively, resistance R2, and be connected with the other end of diode D2.

During charging, U1 and U2 monitors cell voltage by resistance R2, resistance R3, resistance R1, resistance R4, resistance R5, resistance R6, and with the ON time of this control P-MOS type field-effect transistor Q1 and N-MOS type field-effect transistor Q2, finally realize the charging to battery, diode D1, diode D2 and inductance L 1 form rectification circuit.

Improve as one of the present utility model, described detection commutation circuit comprises P-MOS type field-effect transistor Q3, P-MOS type field-effect transistor Q4, P-MOS type field-effect transistor Q5, P-MOS type field-effect transistor Q6 and micro-control unit U3, the source electrode of P-MOS type field-effect transistor Q3 is connected with the positive pole of reserve battery, drain electrode is connected with the drain electrode of P-MOS type field-effect transistor Q4, the grid of this P-MOS type field-effect transistor Q3 is connected with the 3rd end pin of micro-control unit U3 with the grid of P-MOS type field-effect transistor Q4, the 1st end pin ground connection of this micro-control unit U3, 2nd end pin is connected with the grid of P-MOS type field-effect transistor Q6 with P-MOS type field-effect transistor Q5, the source electrode of this P-MOS type field-effect transistor Q6 is connected with the source electrode of P-MOS type field-effect transistor Q4, the drain electrode of this P-MOS type field-effect transistor Q6 is connected with the drain electrode of P-MOS type field-effect transistor Q5, the source electrode of this P-MOS type field-effect transistor Q5 connects the positive source of traveling apparatus.

When traveling apparatus carries (as 13.7V) when cell voltage is greater than predetermined voltage, micro-control unit U3 control P-MOS type field-effect transistor Q5, P-MOS type field-effect transistor Q6 conducting, P-MOS type field-effect transistor Q3, P-MOS type field-effect transistor Q4 ends, and at this moment powers to output circuit from charged pool primarily of traveling apparatus.When traveling apparatus carries cell voltage lower than (as 13.7V) during predetermined voltage, micro-control unit U3 control P-MOS type field-effect transistor Q3, P-MOS type field-effect transistor Q4 conducting, P-MOS type field-effect transistor Q5, P-MOS type field-effect transistor Q6 ends, and at this moment powers primarily of reserve battery.

Improve as one of the present utility model, described output voltage stabilizing circuit comprises P-MOS type field-effect transistor Q7, N-MOS type field-effect transistor Q8, inductance L 2, diode D3, diode D4, integrated package U4, integrated package U5, resistance R7, resistance R8, resistance R9, resistance R10, resistance R11 and resistance R12, the drain electrode of described P-MOS type field-effect transistor Q7 is connected with the 2nd end pin of integrated package U4 with the source electrode of P-MOS type field-effect transistor Q4, the grid of this P-MOS type field-effect transistor Q7 is connected with the 1st end pin of integrated package U4, source electrode is connected with one end of inductance L 2 with diode D3 respectively, the other end ground connection of this diode D3, the other end of this inductance L 2 is connected with the source electrode of N-MOS type field-effect transistor Q8 with one end of this diode D4 respectively, the grounded drain of this N-MOS type field-effect transistor Q8, grid is connected with the 5th end pin of integrated package U5, the other end of diode D4 connects the positive pole of oxyhydrogen generator, and series resistance R9 successively, the other end of resistance R8, this resistance R8 is connected with the 4th end pin of integrated package U4, and by resistance R7 ground connection, one end of resistance R10 is connected with the other end of diode D4, and the other end is connected with one end of resistance R11, and this resistance R11 other end is connected with the 1st end pin of integrated package U5, and by resistance R12 ground connection.

During output, integrated package U4 and integrated package U5 monitors output voltage by resistance R9, resistance R8, resistance R7, resistance R10, resistance R11, resistance R12, and with the ON time of this control P-MOS type field-effect transistor Q7 and N-MOS type field-effect transistor Q8, finally realize the current/voltage of stable output, diode D3, diode D4 and inductance L 2 form rectification circuit.

The beneficial effects of the utility model are: topology layout of the present utility model is reasonable, include reserve battery, charging and voltage stabilizing circuit, detect commutation circuit and output voltage stabilizing circuit, can simultaneously discharge and recharge, namely utilize the providing auxiliary power amount of traveling apparatus generator with a stable current/voltage supply oxyhydrogen generator, simultaneously when detect still have providing auxiliary power amount time, the unnecessary energy output automatic makeup of this part can be utilized to be charged to backup battery simultaneously, backup battery can be automatically switched to when energy output is not enough and be continuously the working power that oxyhydrogen generator provides stable, when energy output when traveling apparatus generator and the electricity from charged pool are all not enough, suspend and provide power supply to oxyhydrogen generator, the i.e. use of temporary transient oxyhydrogen generator, can also automatic decision traveling apparatus whether be whether the corresponding decision of starting state powers to oxyhydrogen generator simultaneously, and the current/voltage of power supply is stablized, the job stability of effective guarantee oxyhydrogen generator, the hydrogen of constant flow rate can be provided for the engine of traveling apparatus, carrier of oxygen, and then ensure the normal work of engine, reliability is high, the power of effective lifting engine and saving fuel oil 5 ~ 30%, energy-conserving and environment-protective, greatly extend traveling apparatus to carry battery and ensure the normal operation of traveling apparatus simultaneously, applied widely, may be used for fuel oil, on the traveling apparatus of the fuel such as natural gas, as at car, bus, the equipment such as lorry and steamer uses.

Below in conjunction with drawings and Examples, the utility model is described in further detail.

Accompanying drawing explanation

The block diagram of Fig. 1 the utility model oxyhydrogen machine energy-saving current voltage stabilizing auxiliary system.

Fig. 2 is the utility model oxyhydrogen machine energy-saving current voltage stabilizing auxiliary system figure.

Embodiment

Embodiment: see figures.1.and.2, a kind of oxyhydrogen machine energy-saving current voltage stabilizing auxiliary system that the utility model provides, it comprises reserve battery, charging and voltage stabilizing circuit, detects commutation circuit and output voltage stabilizing circuit.Wherein reserve battery is used for providing power supply for oxyhydrogen generator; Charging and voltage stabilizing circuit is used for the unnecessary electricity of traveling apparatus to charge to reserve battery with a stable current/voltage; Detecting commutation circuit for detecting the electrical voltage point of traveling apparatus from charged pool, reserve battery, when traveling apparatus generator has providing auxiliary power amount, this energy output can be utilized to provide stable working power for oxyhydrogen generator and/or charge to reserve battery; When the energy output of traveling apparatus generator is not enough, switches to reserve battery and be continuously the working power that oxyhydrogen generator provides stable; When energy output when traveling apparatus generator and the electricity from charged pool are all not enough, suspend and provide power supply to oxyhydrogen generator, until the electricity of reserve battery returns to preset value just for oxyhydrogen generator provides stable working power; Output voltage stabilizing circuit to be used for traveling apparatus generator, traveling apparatus from the electricity of charged pool and reserve battery with a stable current/voltage supply oxyhydrogen generator.

Concrete, described charging and voltage stabilizing circuit comprises P-MOS type field-effect transistor Q1, N-MOS type field-effect transistor Q2, integrated package U1, integrated package U2, inductance L 1, diode D1, diode D2, resistance R1, resistance R2, resistance R3, resistance R4, resistance R5 and resistance R6, the drain electrode of described P-MOS type field-effect transistor Q1 connects the positive source of traveling apparatus, grid connects the 1st end pin of integrated package U1, drain electrode is connected with one end of inductance L 1 with diode D1 respectively, the other end ground connection of this diode D1, the other end of this inductance L 1 is connected with the source electrode of N-MOS type field-effect transistor Q2 diode D2 one end respectively, the other end of diode D2 is connected with the positive pole of reserve battery, and series resistance R4 and resistance R5 successively, the other end of this resistance R4 is connected with the 1st end pin of integrated package U2, and by resistance R6 ground connection, the grounded drain of N-MOS type field-effect transistor Q2, grid is connected with the 5th end pin of integrated package U2, and the 4th end pin of integrated package U1 is by resistance R1 ground connection, and series resistance R3 successively, resistance R2, and be connected with the other end of diode D2.In the present embodiment, described integrated package U1 is preferably the IC that model is FP5003.Described integrated package U2 is preferably the IC that model is FP5139.

Described detection commutation circuit comprises P-MOS type field-effect transistor Q3, P-MOS type field-effect transistor Q4, P-MOS type field-effect transistor Q5, P-MOS type field-effect transistor Q6 and micro-control unit U3, the source electrode of P-MOS type field-effect transistor Q3 is connected with the positive pole of reserve battery, drain electrode is connected with the drain electrode of P-MOS type field-effect transistor Q4, the grid of this P-MOS type field-effect transistor Q3 is connected with the 3rd end pin of micro-control unit U3 with the grid of P-MOS type field-effect transistor Q4, the 1st end pin ground connection of this micro-control unit U3, 2nd end pin is connected with the grid of P-MOS type field-effect transistor Q6 with P-MOS type field-effect transistor Q5, the source electrode of this P-MOS type field-effect transistor Q6 is connected with the source electrode of P-MOS type field-effect transistor Q4, the drain electrode of this P-MOS type field-effect transistor Q6 is connected with the drain electrode of P-MOS type field-effect transistor Q5, the source electrode of this P-MOS type field-effect transistor Q5 connects the positive source of traveling apparatus.In the present embodiment, described integrated package U3 is preferably the MCU that model is 7P167.

Described output voltage stabilizing circuit comprises P-MOS type field-effect transistor Q7, N-MOS type field-effect transistor Q8, inductance L 2, diode D3, diode D4, integrated package U4, integrated package U5, resistance R7, resistance R8, resistance R9, resistance R10, resistance R11 and resistance R12, the drain electrode of described P-MOS type field-effect transistor Q7 is connected with the 2nd end pin of integrated package U4 with the source electrode of P-MOS type field-effect transistor Q4, the grid of this P-MOS type field-effect transistor Q7 is connected with the 1st end pin of integrated package U4, source electrode is connected with one end of inductance L 2 with diode D3 respectively, the other end ground connection of this diode D3, the other end of this inductance L 2 is connected with the source electrode of N-MOS type field-effect transistor Q8 with one end of this diode D4 respectively, the grounded drain of this N-MOS type field-effect transistor Q8, grid is connected with the 5th end pin of integrated package U5, the other end of diode D4 connects the positive pole of oxyhydrogen generator, and series resistance R9 successively, the other end of resistance R8, this resistance R8 is connected with the 4th end pin of integrated package U4, and by resistance R7 ground connection, one end of resistance R10 is connected with the other end of diode D4, and the other end is connected with one end of resistance R11, and this resistance R11 other end is connected with the 1st end pin of integrated package U5, and by resistance R12 ground connection.In the present embodiment, described integrated package U4 is the IC that model is preferably FP5003.Described integrated package U4 is preferably the IC that model is FP5139.

When traveling apparatus carries (as 13.7V) when cell voltage is greater than predetermined voltage, micro-control unit U3 control P-MOS type field-effect transistor Q5, P-MOS type field-effect transistor Q6 conducting, P-MOS type field-effect transistor Q3, P-MOS type field-effect transistor Q4 ends, and at this moment powers to output circuit from charged pool primarily of traveling apparatus.When traveling apparatus carries cell voltage lower than (as 13.7V) during predetermined voltage, micro-control unit U3 control P-MOS type field-effect transistor Q3, P-MOS type field-effect transistor Q4 conducting, P-MOS type field-effect transistor Q5, P-MOS type field-effect transistor Q6 ends, and at this moment powers primarily of reserve battery.

During output, integrated package U4 and integrated package U5 monitors output voltage by resistance R9, resistance R8, resistance R7, resistance R10, resistance R11, resistance R12, and with the ON time of this control P-MOS type field-effect transistor Q7 and N-MOS type field-effect transistor Q8, finally realize the current/voltage of stable output.

When the voltage of reserve battery is lower than (as 14.6V) during predetermined voltage, charging and voltage stabilizing circuit can enter charged state.During charging, U1 and U2 monitors cell voltage by resistance R2, resistance R3, resistance R1, resistance R4, resistance R5, resistance R6, and with the ON time of this control P-MOS type field-effect transistor Q1 and N-MOS type field-effect transistor Q2, finally realize the charging to battery.

The electric power loop of oxyhydrogen generator is controlled by the utility model oxyhydrogen machine energy-saving current voltage stabilizing auxiliary system, effectively can ensure the job stability of oxyhydrogen generator, think that the engine of traveling apparatus provides hydrogen, the carrier of oxygen of constant flow rate, and then ensure the normal work of engine, reliability is high, the power of effective lifting engine and saving fuel oil 5 ~ 30%, energy-conserving and environment-protective, greatly extend traveling apparatus simultaneously and carry battery and ensure the normal operation of traveling apparatus.The utility model oxyhydrogen machine energy-saving current voltage stabilizing auxiliary system is applicable to the upper use of traveling apparatus (as car, bus, lorry and steamer etc.) of various fuel (comprising fuel oil, natural gas).

Above-described embodiment is only the good execution mode of the utility model; the utility model can not enumerate out whole execution modes; the technical scheme of one of all employing above-described embodiments; or according to the equivalent variations that above-described embodiment does, as according to the corresponding increase of the power of load or reduce the current/voltage of discharge and recharge all in the utility model protection range.

The announcement of book and instruction according to the above description, the utility model those skilled in the art can also change above-mentioned execution mode and revise.Therefore, the utility model is not limited to embodiment disclosed and described above, also should fall in the protection range of claim of the present utility model modifications and changes more of the present utility model.In addition, although employ some specific terms in this specification, these terms just for convenience of description, do not form any restriction to the utility model, adopt other circuit same or analogous with it, all in the utility model protection range.

Claims (4)

1. an oxyhydrogen machine energy-saving current voltage stabilizing auxiliary system, is characterized in that: it comprises

Reserve battery, for providing power supply for oxyhydrogen generator;

Charging and voltage stabilizing circuit, for charging the unnecessary electricity of traveling apparatus to reserve battery with a stable current/voltage;

Detecting commutation circuit, for detecting the electrical voltage point of traveling apparatus from charged pool, reserve battery, when traveling apparatus generator has providing auxiliary power amount, this energy output can be utilized to provide stable working power for oxyhydrogen generator and/or charge to reserve battery; When the energy output of traveling apparatus generator is not enough, switches to reserve battery and be continuously the working power that oxyhydrogen generator provides stable; When energy output when traveling apparatus generator and the electricity from charged pool are all not enough, suspend and provide power supply to oxyhydrogen generator, until the electricity of reserve battery returns to preset value just for oxyhydrogen generator provides stable working power;

Output voltage stabilizing circuit, for by traveling apparatus generator, traveling apparatus from the electricity of charged pool and reserve battery with a stable current/voltage supply oxyhydrogen generator.

2. a kind of oxyhydrogen machine energy-saving current voltage stabilizing auxiliary system according to claim 1, it is characterized in that, described charging and voltage stabilizing circuit comprises P-MOS type field-effect transistor Q1, N-MOS type field-effect transistor Q2, integrated package U1, integrated package U2, inductance L 1, diode D1, diode D2, resistance R1, resistance R2, resistance R3, resistance R4, resistance R5 and resistance R6, the drain electrode of described P-MOS type field-effect transistor Q1 connects the positive source of traveling apparatus, grid connects the 1st end pin of integrated package U1, drain electrode is connected with one end of inductance L 1 with diode D1 respectively, the other end ground connection of this diode D1, the other end of this inductance L 1 is connected with the source electrode of N-MOS type field-effect transistor Q2 diode D2 one end respectively, the other end of diode D2 is connected with the positive pole of reserve battery, and series resistance R4 and resistance R5 successively, the other end of this resistance R4 is connected with the 1st end pin of integrated package U2, and by resistance R6 ground connection, the grounded drain of N-MOS type field-effect transistor Q2, grid is connected with the 5th end pin of integrated package U2, and the 4th end pin of integrated package U1 is by resistance R1 ground connection, and series resistance R3 successively, resistance R2, and be connected with the other end of diode D2, the IC of described integrated package U1 to be model be FP5003, the IC of described integrated package U2 to be model be FP5139.

3. a kind of oxyhydrogen machine energy-saving current voltage stabilizing auxiliary system according to claim 2, it is characterized in that, described detection commutation circuit comprises P-MOS type field-effect transistor Q3, P-MOS type field-effect transistor Q4, P-MOS type field-effect transistor Q5, P-MOS type field-effect transistor Q6 and micro-control unit U3, the source electrode of P-MOS type field-effect transistor Q3 is connected with the positive pole of reserve battery, drain electrode is connected with the drain electrode of P-MOS type field-effect transistor Q4, the grid of this P-MOS type field-effect transistor Q3 is connected with the 3rd end pin of micro-control unit U3 with the grid of P-MOS type field-effect transistor Q4, the 1st end pin ground connection of this micro-control unit U3, 2nd end pin is connected with the grid of P-MOS type field-effect transistor Q6 with P-MOS type field-effect transistor Q5, the source electrode of this P-MOS type field-effect transistor Q6 is connected with the source electrode of P-MOS type field-effect transistor Q4, the drain electrode of this P-MOS type field-effect transistor Q6 is connected with the drain electrode of P-MOS type field-effect transistor Q5, the source electrode of this P-MOS type field-effect transistor Q5 connects the positive source of traveling apparatus, the MCU of described integrated package U3 to be model be 7P167.

4. a kind of oxyhydrogen machine energy-saving current voltage stabilizing auxiliary system according to claim 3, it is characterized in that, described output voltage stabilizing circuit comprises P-MOS type field-effect transistor Q7, N-MOS type field-effect transistor Q8, inductance L 2, diode D3, diode D4, integrated package U4, integrated package U5, resistance R7, resistance R8, resistance R9, resistance R10, resistance R11 and resistance R12, the drain electrode of described P-MOS type field-effect transistor Q7 is connected with the 2nd end pin of integrated package U4 with the source electrode of P-MOS type field-effect transistor Q4, the grid of this P-MOS type field-effect transistor Q7 is connected with the 1st end pin of integrated package U4, source electrode is connected with one end of inductance L 2 with diode D3 respectively, the other end ground connection of this diode D3, the other end of this inductance L 2 is connected with the source electrode of N-MOS type field-effect transistor Q8 with one end of this diode D4 respectively, the grounded drain of this N-MOS type field-effect transistor Q8, grid is connected with the 5th end pin of integrated package U5, the other end of diode D4 connects the positive pole of oxyhydrogen generator, and series resistance R9 successively, the other end of resistance R8, this resistance R8 is connected with the 4th end pin of integrated package U4, and by resistance R7 ground connection, one end of resistance R10 is connected with the other end of diode D4, and the other end is connected with one end of resistance R11, and this resistance R11 other end is connected with the 1st end pin of integrated package U5, and by resistance R12 ground connection, the IC of the IC of described integrated package U4 to be model be FP5003 or described integrated package U4 to be model be FP5139.