CN109378889A - A kind of adjustable DC power supply circuit of fuel oil variable-frequency power generation unit output voltage - Google Patents
A kind of adjustable DC power supply circuit of fuel oil variable-frequency power generation unit output voltage Download PDFInfo
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- CN109378889A CN109378889A CN201811488261.7A CN201811488261A CN109378889A CN 109378889 A CN109378889 A CN 109378889A CN 201811488261 A CN201811488261 A CN 201811488261A CN 109378889 A CN109378889 A CN 109378889A
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- 238000010248 power generation Methods 0.000 title claims abstract description 17
- 239000000295 fuel oil Substances 0.000 title claims abstract description 16
- 238000006243 chemical reaction Methods 0.000 claims abstract description 23
- 238000005070 sampling Methods 0.000 claims abstract description 20
- 239000003990 capacitor Substances 0.000 claims description 37
- 239000003381 stabilizer Substances 0.000 claims description 26
- 239000004065 semiconductor Substances 0.000 claims description 23
- 230000005611 electricity Effects 0.000 claims description 10
- 238000000034 method Methods 0.000 abstract description 4
- 230000008569 process Effects 0.000 abstract description 3
- XUIMIQQOPSSXEZ-UHFFFAOYSA-N Silicon Chemical compound [Si] XUIMIQQOPSSXEZ-UHFFFAOYSA-N 0.000 description 8
- 229910052710 silicon Inorganic materials 0.000 description 8
- 239000010703 silicon Substances 0.000 description 8
- WHXSMMKQMYFTQS-UHFFFAOYSA-N Lithium Chemical compound [Li] WHXSMMKQMYFTQS-UHFFFAOYSA-N 0.000 description 5
- 229910052744 lithium Inorganic materials 0.000 description 5
- 230000008901 benefit Effects 0.000 description 3
- 238000001914 filtration Methods 0.000 description 3
- 238000010586 diagram Methods 0.000 description 2
- 238000004804 winding Methods 0.000 description 2
- 208000033999 Device damage Diseases 0.000 description 1
- 239000002253 acid Substances 0.000 description 1
- 230000003321 amplification Effects 0.000 description 1
- 230000005540 biological transmission Effects 0.000 description 1
- 230000015572 biosynthetic process Effects 0.000 description 1
- 230000001413 cellular effect Effects 0.000 description 1
- 230000008859 change Effects 0.000 description 1
- 238000004891 communication Methods 0.000 description 1
- 230000006837 decompression Effects 0.000 description 1
- 230000007812 deficiency Effects 0.000 description 1
- 238000001514 detection method Methods 0.000 description 1
- 238000005265 energy consumption Methods 0.000 description 1
- 238000005516 engineering process Methods 0.000 description 1
- 239000000446 fuel Substances 0.000 description 1
- 230000006872 improvement Effects 0.000 description 1
- 230000002045 lasting effect Effects 0.000 description 1
- 239000007788 liquid Substances 0.000 description 1
- 238000003199 nucleic acid amplification method Methods 0.000 description 1
Classifications
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- H02J7/1461—
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- H02J7/008—
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- H02J7/0088—
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- H—ELECTRICITY
- H02—GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
- H02J—CIRCUIT ARRANGEMENTS OR SYSTEMS FOR SUPPLYING OR DISTRIBUTING ELECTRIC POWER; SYSTEMS FOR STORING ELECTRIC ENERGY
- H02J7/00—Circuit arrangements for charging or depolarising batteries or for supplying loads from batteries
- H02J7/14—Circuit arrangements for charging or depolarising batteries or for supplying loads from batteries for charging batteries from dynamo-electric generators driven at varying speed, e.g. on vehicle
- H02J7/1469—Regulation of the charging current or voltage otherwise than by variation of field
- H02J7/1492—Regulation of the charging current or voltage otherwise than by variation of field by means of controlling devices between the generator output and the battery
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- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y02—TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
- Y02T—CLIMATE CHANGE MITIGATION TECHNOLOGIES RELATED TO TRANSPORTATION
- Y02T10/00—Road transport of goods or passengers
- Y02T10/80—Technologies aiming to reduce greenhouse gasses emissions common to all road transportation technologies
- Y02T10/92—Energy efficient charging or discharging systems for batteries, ultracapacitors, supercapacitors or double-layer capacitors specially adapted for vehicles
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Abstract
A kind of adjustable DC power supply circuit of fuel oil variable-frequency power generation unit output voltage, including three-phase half-controlled full-bridge rectification filter circuit, DC-DC conversion module circuit, PWM drive control module and sampling module;The input terminal of the three-phase half-controlled full-bridge rectification filter circuit is connected with the end three-phase AC;The output end of the three-phase half-controlled full-bridge rectification filter circuit is connected with DC-DC conversion module circuit input end;The sampling module is used to acquire the input electrical signal, output electric signal and temperature of DC-DC conversion module circuit;The output port of the sampling module is connected with the input terminal of PWM drive control module;The output end of the PWM drive control module is connected with the control terminal of DC-DC conversion module circuit.Simplify unit energy conversion process, with AC-DC-DC topology instead of AC-DC-AC-DC-DC topology, greatly improves the load capacity of unit.
Description
Technical field
The present invention relates to general gasoline engines and field of switch power, and in particular to a kind of fuel oil variable-frequency power generation unit output
The adjustable DC power supply circuit of voltage.
Background technique
With new energy technology development and improvement of living standard, people in field to all kinds of DC loads, such as it is various
Battery pack, direct current generator and motor, cellular base station emergency system etc., the demand of application is more and more, therefore to various types of battery
Application demand is also more and more.But no matter that battery pack, electricity is limited, it is therefore desirable to carry out in time to battery pack
Charging, to meet the increasingly vigorous use demand of user.
Currently, there is not yet the collecting system control and inversion direct current output of complete set in general fuel unit industry
Comprehensive mould group.User otherwise be using gas-liquid-liquid three-phase flow output alternating current or can only be supplied electricity to by city battery pack charge.
But be that no alternating current is available in field, user can only select generating set to charge the battery.Common generator
Group is because its overall efficiency is low, volume big weight weight, noise is big, energy consumption is high, the big many disadvantages such as not environmentally of pollution are by frequency conversion
Generating set replaces.And the topology to be charged with variable-frequency power generation unit to battery are as follows: AC-DC-AC-DC-DC.This process will be undergone
Multiple energy conversion, system is not only at high cost, and overall efficiency is also low.
Summary of the invention
In view of the deficiencies of the prior art, the present invention proposes a kind of adjustable direct currents of fuel oil variable-frequency power generation unit output voltage
Source circuit, specific technical solution are as follows:
A kind of adjustable DC power supply circuit of fuel oil variable-frequency power generation unit output voltage, it is characterised in that:
Including three-phase half-controlled full-bridge rectification filter circuit, DC-DC conversion module circuit, PWM drive control module and sampling
Module;
The input terminal of the three-phase half-controlled full-bridge rectification filter circuit is connected with the end three-phase AC;
The output end of the three-phase half-controlled full-bridge rectification filter circuit is connected with DC-DC conversion module circuit input end;
The sampling module is used to acquire the input electrical signal, output electric signal and temperature of DC-DC conversion module circuit;
The output port of the sampling module is connected with the input terminal of PWM drive control module;
The output end of the PWM drive control module is connected with the control terminal of DC-DC conversion module circuit.
Further: the DC-DC conversion module circuit includes battery pack reverse-connection protection circuit, the battery pack reverse connecting protection
Circuit includes driving circuit U8 and metal-oxide-semiconductor Q14, first interface end P15 and second interface end P16, the first interface end P15 and
Two interface end P16;
The first interface end P15 is connected with secondary one end of transformer, and the first interface end P15 is for connecting battery just
Pole;
First interface end P15 is also connected with the cathode of diode D39, and the anode of diode D39 is successively through resistance
R18, resistance R86 and resistance R85 are connected with diode cathode in optocoupler U15, the diode anode and metal-oxide-semiconductor in optocoupler U15
The drain of Q14 is connected, and the source level of metal-oxide-semiconductor Q14 is connected with the secondary ground end of transformer;
The grid of metal-oxide-semiconductor Q14 is connected with diode D33 anode, the cathode of diode D33 and the driving circuit U8
Output end be connected, be parallel with resistance R71 between the anode and cathode of diode D33;
The input port of the driving circuit U8 is connected with the output port of controller, and the driving circuit U8 is integrated mould
Block, model UCC27517;
The output end of the optocoupler U15 is connected with the input terminal of driving circuit U8;
The second interface end P16 is also connected with the drain of metal-oxide-semiconductor Q14 with the common end of optocoupler U15, the second interface end
For connecting the cathode of battery.
Further: the sampling module circuit includes output current collection circuit, the output current collection circuit packet
Amplifier U1B, amplifier U1A are included, the end in the same direction of amplifier U1B is grounded through resistance R8, and the backward end of amplifier U1B is through electricity
Resistance R4 is current acquisition port, transboundary has resistance R3 between the output end and backward end of the amplifier U1B;
The output end of the amplifier U1B is successively held through resistance R7 with the amplifier U1A of resistance R6 in the same direction to be connected;
One branch of backward end of the amplifier U1A is connected through controllable resistor R1 with power end, and another branch is through controllable electric
R2 ground connection is hindered, is connected to capacitor C3 in the both ends span of the controllable resistor R1;
The output end of the amplifier U1A is connected with the anode of diode D3, and the cathode of diode D3 is with resistance R23's
One end is connected, and the other end of resistance R23 is over-current signal output port.
Further: further including revolving speed Acquisition Circuit, which includes acquisition port P9, port P9 mono-
Road is connected with diode D18 anode, the diode D18 cathode successively base through resistance R35 and resistance R36 and triode Q12
Extremely it is connected, the emitter ground connection of triode Q12;
The collector of the triode Q12 is connected with optocoupler U2 input terminal, one branch of optocoupler U2 output end and resistance
The one end R29 is connected, and the second end of resistance R29 is revolving speed output end PRM;
It has also been arranged in parallel resistance R38 and capacitor respectively between the resistance R35 and the common end and ground of resistance R36
C9;
It has also been arranged in parallel capacitor respectively between ground GND between the resistance R36 and the common end of triode Q12
C51 and resistance R92.
Further: including voltage gear number according to Acquisition Circuit, which includes the port P1, institute according to Acquisition Circuit
It states the port P1 to be connected with GSS Gear Select Switch, four gears pair of first to fourth branch and gear selection in the port P1
It answers;
The port the P1 first branch is connected through swept resistance R12 with the cathode of voltage-stabiliser tube D43, the sun of voltage-stabiliser tube D43
Pole ground connection;
The port P1 second branch is connected through swept resistance R11 with the cathode of voltage-stabiliser tube D43, the port the P1 third branch
Road is connected through swept resistance R14 with the cathode of voltage-stabiliser tube D43;
The 4th branch of the port P1 is connected through swept resistance R17 with voltage-stabiliser tube D43 cathode;
The first acquisition port OV1 is connected through resistance R1 and resistance R81 with the cathode of voltage-stabiliser tube D43, the resistance R1
It is connected through resistance R8 with power vd C with the common end of resistance R81;
The second acquisition port OV2 is successively connected through capacitor C3 and resistance R10 with the cathode of voltage-stabiliser tube D43;
It is connected with optocoupler between the first acquisition port OV1 and the second acquisition port OV2, the output end of the optocoupler
For signal output end;
Also it is connected with the cathode of integrated regulator source U1 in the second acquisition port OV2, the sun of integrated circuit U1
Pole ground connection, the reference end of integrated circuit U1 is connected with the cathode of voltage-stabiliser tube D43.
Further: further include the temperature acquisition processing circuit including amplifier U1C, power port, the power port
One branch is grounded through resistance R11 and capacitor C6, and another branch is grounded through resistance R10 and resistance R14;
The end in the same direction of the amplifier U1C is connected between the resistance R10 and the common end of resistance R14;
The backward end of the amplifier U1C is connected between resistance R11 and the common end of capacitor C6, resistance R11 and electricity
The common end for holding C6 is temperature acquisition port;
The output port of the amplifier U1C is connected with diode D4 anode, and the cathode of diode D4 is with resistance R24's
First end is connected, and the second end of resistance R24 is overtemperature signal output port;
It has also been arranged in parallel resistance R26 and capacitor C14 respectively between the cathode and ground of the diode D4.
Further: the control module circuit includes unit flameout control circuit, which includes
The base stage of relay K1 and triode Q9, triode Q9 are connected with control port DOWN OFF, the emitter of triode Q9
Ground connection, the collector of triode Q9 are connected with the electromagnetic coil of relay K1;
The control port of relay K1 is connected with unit port P5.
Further: diode cathode and anode both ends in the optocoupler U15 are parallel with capacitor C48.
Further: bridging has resistance R68 between the drain and grid of the metal-oxide-semiconductor Q14.
The invention has the benefit that the mould group has several advantages that
First, simplify unit energy conversion process, with AC-DC-DC topology instead of AC-DC-AC-DC-DC topology, substantially
Improve the load capacity of unit.
Second, realize that the revolving speed to complete machine, band carry the various controls such as situation, fault cues, data transmission, emergency shutdown and protect
Shield.
Third, user can select multiple voltage gears to adapt to different direct current systems by switch.
4th, user can the electrodeless maximum output current from main modulation system: 0~100%.
5th, it, only need to be external straight instead of frequency converter sets original (AC-DC-AC) inverter and group charger
Current load or battery pack can be achieved with driving DC load or charge to battery pack, reduce system structure and cost.
Detailed description of the invention
Fig. 1 is circuit structure block diagram of the invention;
Fig. 2 is system general diagram of the invention;
Fig. 3 is voltage gear number according to Acquisition Circuit structure chart;
Fig. 4 is output current collection circuit and temperature sampling processing circuit figure;
Fig. 5 is revolving speed Acquisition Circuit figure;
Fig. 6 is unit flameout control circuit figure;
Fig. 7 is stepper motor driving figure;
Fig. 8 is single-chip microcontroller sampling control circuit figure;
Fig. 9 is PWM drive circuit structure chart;
Figure 10 is battery pack reverse-connection protection circuit.
Specific embodiment
The preferred embodiments of the present invention will be described in detail with reference to the accompanying drawing, so that advantages and features of the invention energy
It is easier to be readily appreciated by one skilled in the art, so as to make a clearer definition of the protection scope of the present invention.
It is as shown in Figures 1 to 10:
A kind of adjustable DC power supply circuit of fuel oil variable-frequency power generation unit output voltage, including three-phase AC input port, three
Phase half control full-bridge rectification filter circuit, DC-DC conversion module circuit, sampling module circuit and control module circuit, three-phase AC
Input port is connected with the input terminal of three-phase half-controlled full-bridge rectification filter circuit, the three-phase half-controlled full-bridge rectification filter circuit it is defeated
Outlet is connected with DC-DC conversion module circuit input end;
The sampling module is used to acquire the input electrical signal, output electric signal and temperature of DC-DC conversion module circuit;
The output port of sampling module circuit is connected with the input terminal of PWM drive control module;
The output end of PWM drive control module is connected with the control terminal of DC-DC conversion module circuit.
Sampling module circuit includes input current acquisition module, output current collection circuit, voltage gear number according to acquisition electricity
Road, temperature acquisition processing circuit;
Input current acquisition module be existing conventional current acquisition module, the output end of the input current acquisition module with
The input terminal of PWM drive control module is connected;
Export current collection circuit are as follows:
Output current collection circuit includes amplifier U1B, amplifier U1A, and the end in the same direction of amplifier U1B connects through resistance R8
Ground, the backward end of amplifier U1B is current acquisition port through resistance R4, between the output end and backward end of amplifier U1B
Transboundary there is resistance R3;
The output end of amplifier U1B is successively held through resistance R7 with the amplifier U1A of resistance R6 in the same direction to be connected;
One branch of backward end of amplifier U1A is connected through controllable resistor R1 with power end, and another branch is through controllable resistor R2
Ground connection, is connected to capacitor C3 in the both ends span of controllable resistor R1;
The output end of amplifier U1A is connected with the anode of diode D3, the cathode of diode D3 and one end of resistance R23
It is connected, the other end of resistance R23 is over-current signal output port.
It further include revolving speed Acquisition Circuit, which includes acquisition port P9, mono- branch of port P9 and two poles
Pipe D18 anode is connected, and diode D18 cathode is successively connected through resistance R35 and resistance R36 with the base stage of triode Q12, three pole
The emitter of pipe Q12 is grounded;
The collector of triode Q12 is connected with optocoupler U2 input terminal, one branch of optocoupler U2 output end and the one end resistance R29 phase
Even, the second end of resistance R29 is revolving speed output end PRM;
It has also been arranged in parallel resistance R38 and capacitor C9 respectively between resistance R35 and the common end and ground of resistance R36;
Also be arranged in parallel respectively between ground GND between resistance R36 and the common end of triode Q12 capacitor C51 and
Resistance R92.
Voltage gear number is according to Acquisition Circuit are as follows:
The voltage gear number includes the port P1 according to Acquisition Circuit, and the port P1 is connected with GSS Gear Select Switch, in the port P1
First to fourth branch is corresponding with four gears of gear selection;
The port the P1 first branch is connected through swept resistance R12 with the cathode of voltage-stabiliser tube D43, and the anode of voltage-stabiliser tube D43 connects
Ground;
The port P1 second branch is connected through swept resistance R11 with the cathode of voltage-stabiliser tube D43, and the port P1 third branch is through sliding
Resistance R14 is connected with the cathode of voltage-stabiliser tube D43;
The 4th branch of the port P1 is connected through swept resistance R17 with voltage-stabiliser tube D43 cathode;
First acquisition port OV1 is connected through resistance R1 and resistance R81 with the cathode of voltage-stabiliser tube D43, resistance R1 and resistance R81
Common end be connected through resistance R8 with power vd C;
Second acquisition port OV2 is successively connected through capacitor C3 and resistance R10 with the cathode of voltage-stabiliser tube D43;
It is connected with optocoupler between first acquisition port OV1 and the second acquisition port OV2, the output end of the optocoupler is that signal is defeated
Outlet;
Also it is connected with the cathode of integrated regulator source U1 in the second acquisition port OV2, the anode of integrated circuit U1 connects
The reference end on ground, integrated circuit U1 is connected with the cathode of voltage-stabiliser tube D43.
Temperature acquisition processing circuit are as follows:
Temperature acquisition processing circuit includes amplifier U1C, and power port, one branch of power port is through resistance R11 and electricity
Hold C6 ground connection, another branch is grounded through resistance R10 and resistance R14;
The end in the same direction of amplifier U1C is connected between resistance R10 and the common end of resistance R14;
The backward end of amplifier U1C is connected between resistance R11 and the common end of capacitor C6, resistance R11 and capacitor C6
Common end be temperature acquisition port;
The output port of amplifier U1C is connected with diode D4 anode, the cathode of diode D4 and the first of resistance R24
End is connected, and the second end of resistance R24 is overtemperature signal output port;
It has also been arranged in parallel resistance R26 and capacitor C14 respectively between the cathode and ground of diode D4.
Control module circuit includes unit flameout control circuit and stepper motor driving circuit, the unit flameout control circuit
Including relay K1 and triode Q9, the base stage of triode Q9 is connected with control port DOWN OFF, the hair of triode Q9
The collector of emitter grounding, triode Q9 is connected with the electromagnetic coil of relay K1, the control port and machine of relay K1
Group port P5 is connected.
DC-DC conversion module circuit includes battery pack reverse-connection protection circuit, which includes driving
Circuit U 8 and metal-oxide-semiconductor Q14, first interface end P15 and second interface end P16, the first interface end P15 and second interface end P16;
First interface end P15 is connected with secondary one end of transformer, and the first interface end P15 is for connecting anode;
First interface end P15 is also connected with the cathode of diode D39, and the anode of diode D39 is successively through resistance
R18, resistance R86 and resistance R85 are connected with diode cathode in optocoupler U15, the diode anode and metal-oxide-semiconductor in optocoupler U15
The drain of Q14 is connected, and the source level of metal-oxide-semiconductor Q14 is connected with the secondary ground end of transformer;
The grid of metal-oxide-semiconductor Q14 is connected with diode D33 anode, and the cathode of diode D33 is defeated with driving circuit U8's
Outlet is connected, and is parallel with resistance R71 between the anode and cathode of diode D33, the diode cathode in optocoupler U15 and sun
Pole both ends are parallel with capacitor C48, and bridging has resistance R68 between the drain and grid of metal-oxide-semiconductor Q14.
The input port of driving circuit U8 is connected with the output port of controller;
The output end of optocoupler U15 is connected with the input terminal of driving circuit U8;
Second interface end P16 is also connected with the drain of metal-oxide-semiconductor Q14 with the common end of optocoupler U15, which is used for
Connect the cathode of battery.
PWM drive control module circuit, hardware current-limiting circuit, on/off circuit, output overcurrent are protected circuit and were inputted
Stream protection circuit;
Hardware current-limiting circuit includes hardware restrictor port, which is connected with diode D45 anode, two pole
Pipe D45 cathode is grounded through resistance R111, the input terminal phase of common end and drive module between diode D45 and resistance R111
Even;
On/off circuit includes triode Q18, silicon-controlled Q19, and the collector of triode Q18 is through resistance R110 and two poles
The cathode of pipe D45 is connected with the common end of resistance R111;
The emitter of triode Q18 is connected with the first power end;
The base stage of triode Q18 is connected through resistance R113 with the anode of thyristor Q19, the yin of thyristor Q19
Pole ground connection, the control terminal of thyristor Q19 are connected with the end control port SHUTD;
The output end of output overcurrent protection circuit is connected through resistance R116 with diode anode D46, the yin of diode D46
Pole is connected with the control terminal of silicon-controlled Q19;
The output end of input overcurrent protection circuit is connected through resistance R115 with the anode of diode D44, diode D44's
Cathode is connected with the control terminal of silicon-controlled Q19.
Output overcurrent protection circuit includes amplifier U17B, and the end in the same direction of amplifier U17B is temperature signal input,
The backward end of amplifier U17B is grounded through resistance R118, and the backward end of amplifier U17B is also through resistance R117 and the first power supply
It is connected, is parallel with capacitor C67 at the both ends resistance R118, the output end of amplifier U17B is the output that output overcurrent protects circuit
End.
Input overcurrent protection circuit includes amplifier U17A, and the end in the same direction of amplifier U17A is current signal input,
One branch of backward end of amplifier U17A is grounded through resistance R120, and another branch is connected through resistance R119 with the first power end;
It is parallel with capacitor C65 at the both ends resistance R120, is also parallel with respectively between the end and ground in the same direction of amplifier U17A
Capacitor C65 and resistance R121.
Working principle: after startup of unit, the three-phase AC power source that three-phase motor generates is converted into directly through module A C-DC-DC
D/C voltage needed for current load.Another low pressure winding of the motor provides low-tension supply and tach signal to mould group simultaneously.
Mould group does not stop to detect revolving speed, module temperature, the voltage/current/temperature of load etc. of unit, and according to payload size
Constantly adjust the aperture of throttle.When unloaded, mould group, which adjusts throttle, reduces revolving speed, and unit is made to enter standby mode.When voltage gear
It changes or when current knob is rotated, when being no more than peak power output, mould group adjusts output voltage in due course
Or electric current reaches corresponding value.And the signals such as revolving speed, voltage, electric current, power, temperature are sent to display module by serial ports,
So that user checks in time.When system jam, mould group output misfire signals stop igniter light a fire to close unit,
It prevents from causing system bigger damage.
In sampling module circuit and control module circuit, it is whole system that the core of sampling and control module, which is single-chip microcontroller,
Control core, single-chip microcontroller can use different brands and model.
It realizes the acquisition to the voltage of mould group direct current output, electric current, temperature, and calculates power.It also needs to judge to use simultaneously
The voltage gear selection at family, maximum output current limit grade, Throttle Opening Control, revolving speed acquisition, unit, which stop working, to be controlled, is aobvious with unit
Show the functions such as section communication.Multisection type pipe can be carried out according to the charged state for requiring to complete to lead-acid battery or lithium battery group
Reason.
In voltage gear number according in Acquisition Circuit, the external gear rotary dip switch in the port P1 can also be opened using dial-up
It closes, 1 to 4 gear is corresponding from different output voltage levels respectively.
Voltage gear number is according to acquisition module same 79.8V (19 section serial lithium battery group of 78.5V), 67.2V (66V 16 respectively
Save serial lithium battery group), 54.6V (13 section serial lithium battery group of 53.5V), 42V (10 section serial lithium battery group of 41V) it is corresponding.
Wherein, the first acquisition port OV1 and the second acquisition port port OV2 connect optocoupler, and optocoupler feeds back output voltage
PWM drive control module is returned, integrated circuit source U1 is TL431, and voltage-stabiliser tube D43 is 3.3V or 5.1V zener diode.Voltage gear
Position data acquisition module default output 79.8VDC, when user's turning knob, corresponding gear voltage can be pulled to ground, pass through
Single-chip microcontroller can be immediately detected the suddenly change of voltage, and adjust the charge mode of module immediately, and adjust the maximum electricity of restriction
Flow valuve.
Particularly, zener diode D43 is extremely important, if there is no voltage-stabiliser tube D43, user's on-line tuning gear knob
When, the voltage of node 1 can be equally high with output voltage, this will lead to integrated circuit source U1 damage, results even in single-chip microcontroller damage
It is bad.
Export current collection circuit, resistance R4, resistance R3, resistance R7, capacitor C4, resistance R5, capacitor C1, resistance R8 and fortune
The sign-changing amplifier amplification of U1B composition is put, U1A and UIC and its accessory circuit constitute comparator.
After system output current passes through current acquisition port processing, which is " OA_OUT acquisition ", even
It is connected to the 6th foot of operational amplifier U1B, amplified signal is exported through the 7th foot of U1B, constituted using resistance R7 and capacitor C4
Low-pass filter filtering.Later, be on the one hand connected to the 3rd foot of operational amplifier U1A, so as to the 2nd foot reference voltage into
Row compares, and when the voltage is more than reference voltage, 1 foot of U1A exports high level;On the other hand, which passes through capacitor C1
After the low-pass filter filtering constituted with resistance R5, exported by the port " ADC " to Chip Microcomputer A/port D, single-chip microcontroller acquisition should
Voltage simultaneously calculates corresponding current value.
In temperature sampling processing circuit, overheat protection function is similar with its, temperature acquisition port, which is
" TEMPER ", the 9th foot of collected temperature voltage signal input amplifier U1C, the reference voltage with the 10th foot are compared,
When being more than reference voltage, the 8th foot of U1C exports high level.
Meanwhile the 1st of U1C the, high level of 8 feet output is connected to single-chip microcontroller, and single-chip microcontroller is allowed to know specific failure cause, and
Make corresponding control measure and prompt.The port " OC/OT " is connected to control module by optocoupler, which is PWM driving
Control module.When output overcurrent or overtemperature occurs, which exports high level, realizes overheat protection function.
In PWM drive control module circuit, use integrated circuit SG2525AP for core, it is possible to use other driving chips
It realizes the driving of the metal-oxide-semiconductor or triode or IGBT pipe to switch primary, and there is primary overcurrent protection, secondary mistake
Flow Cycle by Cycle protection, secondary lasting overcurrent protection, mould group overheat protection function.
Particularly, in addition to basic two-way complementation PWM output, module also achieves hardware current limliting, overtemperature/output overcurrent and protects
The functions such as shield, input overcurrent protection, the control of system machine open/close.
Specifically in the following way: port " 10PIN " is the output enable port of SG2525AP, when 10PIN low level
SG2525AP exports PWM, otherwise stops output.
The circuit also can control the output enable port of other chips, if logic is on the contrary, need to only do tiny variation.
The realization of hardware current-limiting function: when system needs hardware current limliting, " hardware current limliting " port is high level, passes through two
Pole pipe D45 is applied to port 10PIN, and SG2525AP is made to stop output PWM waveform.When " hardware current limliting " port becomes bottom level
When, SG2525AP exports PWM waveform immediately.
The realization of system machine open/close function: resistance R110, resistance R112, resistance R113, triode Q18, silicon-controlled Q19,
Capacitor C63, resistance R114 are the devices for realizing this function.When the end " SHUTD " becomes high level, the grid of silicon-controlled Q19 becomes
It is then connected for high level, and the base stage of triode Q18 is dragged down, triode Q18 is PNP, therefore triode Q18 works, will
5VDC high level voltage, is applied to 10PIN, and SG2525AP is made to stop output PWM wave.It should be pointed out that because silicon-controlled
Characteristic, once even if the end conducting SHUTD " becomes low level again, silicon-controlled Q19 is still in the conductive state, again except nonsystematic
Cut-off could be restored by powering on, and SG252AP could export PWM again.
Diode D44 and diode D46 and its circuit on right side are overtemperature/output overcurrent protection, the port OC/OT, OA_
The port IN connects input overcurrent protection circuit.
The work realization principle of the two is similar, for inputting overcurrent protection: the collected voltage warp of port " OA_IN "
The 3rd foot of in-phase end of comparator U17A, resistance R119, electricity are input to after resistance R122, resistance R121, capacitor C16 divider filter
5V divider filter formation reference voltage is input to the 2nd foot of backward end of comparator U17A by resistance R120, capacitor C65.
When " OA_IN " voltage be the 3rd foot, lower than the 2nd foot reference voltage when, comparator export low level, diode
D44 does not work, and SG252AP is worked normally.Conversely, silicon-controlled Q19 is connected in diode D44 output high level, and make triode
Q18 work, triode Q18 are that 5VDC voltage is herein high level, is applied to 10PIN, makes by PNP
SG2525AP stops output PWM wave.Likewise, cut-off, SG252AP ability could be restored except nonsystematic re-powers
Again PWM is exported.
In revolving speed Acquisition Circuit, port P9 connects the low pressure winding of oneself magneto, takes half-wave signa with diode D18,
Two-stage decompression filtering is constituted through resistance R35, resistance R38, capacitor C9, resistance R36, capacitor C51, resistance R92, triode Q12, most
Tach signal is transmitted to by the port " RPM " by triode Q12 and optocoupler U2 afterwards, is supplied to the I/O mouth acquisition of single-chip microcontroller.
Single-chip microcontroller adjusts unit by revolving speed, voltage, current value and the calculated module output power of acquisition in real time
Revolving speed, it is ensured that best match of the generating unit speed with output power.Wherein, U9 is drive integrated circult, port P19 connection unit
The stepper motor of carburetor.Stepper motor can be mutually wireless according to unit actual conditions selection four line of two-phase or four.
In unit flameout control circuit, once there is above-mentioned failure in system, and single-chip microcontroller will control the port " DOWN OFF "
Relay K1 is acted, 1 foot and the short circuit of 2 feet of port P5 are made.
Port P5 both can connect the trigger signal of igniter, also can connect other controls of misfire signals or igniter
Interface processed, therefore the scope of application of circuit is very wide.
The realization of battery pack reversal connection protection function:
When battery pack normally connects, i.e. first interface end P15 connect battery+, second interface end P16 connect battery-when because
Diode in diode D39 and optocoupler U15 is in reverse-biased, therefore diode D39, resistance R18, resistance R85, resistance R86
And the circuit optocoupler U15 no current passes through, optocoupler U15 does not work, therefore control driving circuit U8 will not be gone to remove driving metal-oxide-semiconductor
Q14, system worked well.
When battery reversal connection, i.e. first interface end port P15 connects battery-, second interface end P16 connect battery+when, diode
The body diode of D39 and optocoupler U15 are in positively biased, diode D39, resistance R18, resistance R85, resistance R86 and optocoupler U15
Circuit has electric current to pass through, and optocoupler U15 work drags down the 3rd foot of integrated circuit U8, causes the 5th foot of integrated circuit U8 defeated always
Low level out, metal-oxide-semiconductor Q14 is without driving signal, and module is without output.It is achieved that battery reverse connecting protection, avoids mould group device
Damage.
The realization of battery pack Charge Management function:
After system electrification, metal-oxide-semiconductor Q14 is in long-time on state, and the SCM system of mould group can not stop detection
Between one interface end P15, second interface end P16, i.e., battery pack+,-between voltage, electric current and read battery pack and feed back
Temperature information, and judge according to these information the charge mode of battery pack, such as constant pressure, constant current, trickle.Pass through single-chip processor i/o
Output PWM wave makes the 3rd foot control metal-oxide-semiconductor Q14 of driving circuit U8, the final Charge Management function of realizing battery pack.
Claims (9)
1. a kind of adjustable DC power supply circuit of fuel oil variable-frequency power generation unit output voltage, it is characterised in that:
Including three-phase half-controlled full-bridge rectification filter circuit, DC-DC conversion module circuit, PWM drive control module and sampling module;
The input terminal of the three-phase half-controlled full-bridge rectification filter circuit is connected with the end three-phase AC;
The output end of the three-phase half-controlled full-bridge rectification filter circuit is connected with DC-DC conversion module circuit input end;
The sampling module is used to acquire the input electrical signal, output electric signal and temperature of DC-DC conversion module circuit;
The output port of the sampling module is connected with the input terminal of PWM drive control module;
The output end of the PWM drive control module is connected with the control terminal of DC-DC conversion module circuit.
2. the adjustable DC power supply circuit of a kind of fuel oil variable-frequency power generation unit output voltage according to claim 1, feature
Be: the DC-DC conversion module circuit includes battery pack reverse-connection protection circuit, which includes driving
Circuit U 8 and metal-oxide-semiconductor Q14, first interface end P15 and second interface end P16, the first interface end P15 and second interface end P16;
The first interface end P15 is connected with secondary one end of transformer, and the first interface end P15 is for connecting anode;
First interface end P15 is also connected with the cathode of diode D39, and the anode of diode D39 is successively through resistance R18, electricity
Resistance R86 and resistance R85 is connected with diode cathode in optocoupler U15, the leakage of the diode anode in optocoupler U15 and metal-oxide-semiconductor Q14
Grade is connected, and the source level of metal-oxide-semiconductor Q14 is connected with the secondary ground end of transformer;
The grid of metal-oxide-semiconductor Q14 is connected with diode D33 anode, and the cathode of diode D33 is defeated with the driving circuit U8's
Outlet is connected, and is parallel with resistance R71 between the anode and cathode of diode D33;
The input port of the driving circuit U8 is connected with the output port of controller;
The output end of the optocoupler U15 is connected with the input terminal of driving circuit U8;
The second interface end P16 is also connected with the drain of metal-oxide-semiconductor Q14 with the common end of optocoupler U15, which is used for
Connect the cathode of battery.
3. the adjustable DC power supply circuit of a kind of fuel oil variable-frequency power generation unit output voltage according to claim 1, feature
Be: the sampling module circuit include output current collection circuit, the output current collection circuit include amplifier U1B,
The end in the same direction of amplifier U1A, amplifier U1B are grounded through resistance R8, and the backward end of amplifier U1B is adopted through resistance R4 for electric current
Collect port, transboundary has resistance R3 between the output end and backward end of the amplifier U1B;
The output end of the amplifier U1B is successively held through resistance R7 with the amplifier U1A of resistance R6 in the same direction to be connected;
One branch of backward end of the amplifier U1A is connected through controllable resistor R1 with power end, and another branch is through controllable resistor R2
Ground connection, is connected to capacitor C3 in the both ends span of the controllable resistor R1;
The output end of the amplifier U1A is connected with the anode of diode D3, the cathode of diode D3 and one end of resistance R23
It is connected, the other end of resistance R23 is over-current signal output port.
4. the adjustable DC power supply circuit of a kind of fuel oil variable-frequency power generation unit output voltage according to claim 3, feature
It is: further includes revolving speed Acquisition Circuit, which includes acquisition port P9, mono- branch of port P9 and diode
D18 anode is connected, and the diode D18 cathode is successively connected through resistance R35 and resistance R36 with the base stage of triode Q12, this three
The emitter of pole pipe Q12 is grounded;
The collector of the triode Q12 is connected with optocoupler U2 input terminal, one branch of optocoupler U2 output end and resistance R29 mono-
End is connected, and the second end of resistance R29 is revolving speed output end PRM;
It has also been arranged in parallel resistance R38 and capacitor C9 respectively between the resistance R35 and the common end and ground of resistance R36;
Also be arranged in parallel respectively between ground GND between the resistance R36 and the common end of triode Q12 capacitor C51 and
Resistance R92.
5. the adjustable DC power supply circuit of a kind of fuel oil variable-frequency power generation unit output voltage according to claim 4, feature
Be: including voltage gear number according to Acquisition Circuit, which includes the port P1 according to Acquisition Circuit, the port P1 and shelves
Position selection switch is connected, and first to fourth branch in the port P1 is corresponding with four gears of gear selection;
The port the P1 first branch is connected through swept resistance R12 with the cathode of voltage-stabiliser tube D43, and the anode of voltage-stabiliser tube D43 connects
Ground;
The port P1 second branch is connected through swept resistance R11 with the cathode of voltage-stabiliser tube D43, the port the P1 third branch warp
Swept resistance R14 is connected with the cathode of voltage-stabiliser tube D43;
The 4th branch of the port P1 is connected through swept resistance R17 with voltage-stabiliser tube D43 cathode;
The first acquisition port OV1 is connected through resistance R1 and resistance R81 with the cathode of voltage-stabiliser tube D43, the resistance R1 and electricity
The common end of resistance R81 is connected through resistance R8 with power vd C;
The second acquisition port OV2 is successively connected through capacitor C3 and resistance R10 with the cathode of voltage-stabiliser tube D43;
It is connected with optocoupler between the first acquisition port OV1 and the second acquisition port OV2, the output end of the optocoupler is letter
Number output end;
Also it is connected with the cathode of integrated regulator source U1 in the second acquisition port OV2, the anode of integrated circuit U1 connects
The reference end on ground, integrated circuit U1 is connected with the cathode of voltage-stabiliser tube D43.
6. the adjustable DC power supply circuit of a kind of fuel oil variable-frequency power generation unit output voltage according to claim 1, feature
It is: further include the temperature acquisition processing circuit includes amplifier U1C, power port, one branch of power port is through resistance
R11 and capacitor C6 ground connection, another branch are grounded through resistance R10 and resistance R14;
The end in the same direction of the amplifier U1C is connected between the resistance R10 and the common end of resistance R14;
The backward end of the amplifier U1C is connected between resistance R11 and the common end of capacitor C6, resistance R11 and capacitor C6
Common end be temperature acquisition port;
The output port of the amplifier U1C is connected with diode D4 anode, the cathode of diode D4 and the first of resistance R24
End is connected, and the second end of resistance R24 is overtemperature signal output port;
It has also been arranged in parallel resistance R26 and capacitor C14 respectively between the cathode and ground of the diode D4.
7. the adjustable DC power supply circuit of a kind of fuel oil variable-frequency power generation unit output voltage according to claim 1, feature
Be: the control module circuit includes unit flameout control circuit, which includes relay K1 and three
The base stage of pole pipe Q9, triode Q9 are connected with control port DOWN OFF, the emitter ground connection of triode Q9, the triode
The collector of Q9 is connected with the electromagnetic coil of relay K1;
The control port of relay K1 is connected with unit port P5.
8. the adjustable DC power supply circuit of a kind of fuel oil variable-frequency power generation unit output voltage according to claim 1, feature
Be: diode cathode and anode both ends in the optocoupler U15 are parallel with capacitor C48.
9. the adjustable DC power supply circuit of a kind of fuel oil variable-frequency power generation unit output voltage according to claim 1, feature
Be: bridging has resistance R68 between the drain and grid of the metal-oxide-semiconductor Q14.
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