CN107017777A - Constant current mode inverse excitation type converter based on primary side feedback - Google Patents
Constant current mode inverse excitation type converter based on primary side feedback Download PDFInfo
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- CN107017777A CN107017777A CN201710291303.7A CN201710291303A CN107017777A CN 107017777 A CN107017777 A CN 107017777A CN 201710291303 A CN201710291303 A CN 201710291303A CN 107017777 A CN107017777 A CN 107017777A
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- H—ELECTRICITY
- H02—GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
- H02M—APPARATUS FOR CONVERSION BETWEEN AC AND AC, BETWEEN AC AND DC, OR BETWEEN DC AND DC, AND FOR USE WITH MAINS OR SIMILAR POWER SUPPLY SYSTEMS; CONVERSION OF DC OR AC INPUT POWER INTO SURGE OUTPUT POWER; CONTROL OR REGULATION THEREOF
- H02M3/00—Conversion of dc power input into dc power output
- H02M3/22—Conversion of dc power input into dc power output with intermediate conversion into ac
- H02M3/24—Conversion of dc power input into dc power output with intermediate conversion into ac by static converters
- H02M3/28—Conversion of dc power input into dc power output with intermediate conversion into ac by static converters using discharge tubes with control electrode or semiconductor devices with control electrode to produce the intermediate ac
- H02M3/325—Conversion of dc power input into dc power output with intermediate conversion into ac by static converters using discharge tubes with control electrode or semiconductor devices with control electrode to produce the intermediate ac using devices of a triode or a transistor type requiring continuous application of a control signal
- H02M3/335—Conversion of dc power input into dc power output with intermediate conversion into ac by static converters using discharge tubes with control electrode or semiconductor devices with control electrode to produce the intermediate ac using devices of a triode or a transistor type requiring continuous application of a control signal using semiconductor devices only
- H02M3/33507—Conversion of dc power input into dc power output with intermediate conversion into ac by static converters using discharge tubes with control electrode or semiconductor devices with control electrode to produce the intermediate ac using devices of a triode or a transistor type requiring continuous application of a control signal using semiconductor devices only with automatic control of the output voltage or current, e.g. flyback converters
- H02M3/33523—Conversion of dc power input into dc power output with intermediate conversion into ac by static converters using discharge tubes with control electrode or semiconductor devices with control electrode to produce the intermediate ac using devices of a triode or a transistor type requiring continuous application of a control signal using semiconductor devices only with automatic control of the output voltage or current, e.g. flyback converters with galvanic isolation between input and output of both the power stage and the feedback loop
-
- H—ELECTRICITY
- H02—GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
- H02M—APPARATUS FOR CONVERSION BETWEEN AC AND AC, BETWEEN AC AND DC, OR BETWEEN DC AND DC, AND FOR USE WITH MAINS OR SIMILAR POWER SUPPLY SYSTEMS; CONVERSION OF DC OR AC INPUT POWER INTO SURGE OUTPUT POWER; CONTROL OR REGULATION THEREOF
- H02M1/00—Details of apparatus for conversion
- H02M1/08—Circuits specially adapted for the generation of control voltages for semiconductor devices incorporated in static converters
-
- 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
- Y02B—CLIMATE CHANGE MITIGATION TECHNOLOGIES RELATED TO BUILDINGS, e.g. HOUSING, HOUSE APPLIANCES OR RELATED END-USER APPLICATIONS
- Y02B70/00—Technologies for an efficient end-user side electric power management and consumption
- Y02B70/10—Technologies improving the efficiency by using switched-mode power supplies [SMPS], i.e. efficient power electronics conversion e.g. power factor correction or reduction of losses in power supplies or efficient standby modes
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- Engineering & Computer Science (AREA)
- Power Engineering (AREA)
- Dc-Dc Converters (AREA)
- Rectifiers (AREA)
Abstract
The invention discloses a kind of constant current mode inverse excitation type converter based on primary side feedback, including rectifier bridge, wave filter, absorbing circuit, transformer, secondary output circuit, auxiliary circuit and constant-current controller.The present invention can not only be operated in non-continuous mode, moreover it is possible to be operated in continuous mode.
Description
Technical field
The present invention relates to integrated circuit fields, the constant current mode inverse excitation type converter more particularly to based on primary side feedback.
Background technology
Hand-held personal telecommunication terminal (such as mobile phone) product, quickly grows in recent years.Its related charger market is therewith
Development.Inverse excitation type converter is widely used in this field due to its own cost, performance advantage.And various use primary sides
The constant-current controller of feedback, it is with low cost because its peripheral structure is simple, it is widely accepted and applies.
Fig. 1 is a kind of constant current mode inverse-excitation type variator based on primary side feedback of the prior art, including rectifier bridge 101,
∏ mode filters 102, absorbing circuit 103, the transformer being made up of armature winding Np, secondary windings Ns and assists winding Naux
104th, secondary output circuit 105, auxiliary circuit 106, constant-current controller 107 and metal oxide semiconductor field effect tube Q1, secondary
Level winding Ns is also associated with commutation diode D6, output capacitance C4, dummy resistance R2, and assists winding Naux is also associated with rectification
Diode D7, output capacitance C5, feedback resistance R3 and R4, metal oxide semiconductor field effect tube Q1 grid and current constant control
The output end connection of device 107, metal oxide semiconductor field effect tube Q1 drain electrode is connected with armature winding Np, metal oxide
Semiconductor field Q1 source electrode is grounded by primary current sampling resistor R119, and constant-current controller 107 includes removing Magnetic testi
Module 108, phase inverter 110, current source 113 and 114, transmitting switch 115 and 116, electric capacity C131, comparator 118, rest-set flip-flop
121st, drive module 123, comparator 128 etc..
The input of degaussing detection module 108 is connected with assists winding Vaux voltage division signal, degaussing detection module 108
Output end connects the input of phase inverter 110 and the control end of switch 116, the output end connecting valve 115 of phase inverter 110 respectively
Control end, switch 115 one end connecting valve 116 one end, switch 116 the other end be grounded by current source 114, switch
115 other end connects supply voltage by current source 113, and one end of switch 115 is grounded by electric capacity C131, and the one of switch 115
End is also connected with the in-phase input end of comparator 118, the inverting input of the first reference voltage input comparator 118, comparator 118
Output end connect the S ends of rest-set flip-flop 121, the output end of rest-set flip-flop 121 passes through drive module 123 and connects metal oxide
The grid of semiconductor field 118, the source electrode of metal oxide semiconductor field effect tube 118 connects the same phase of comparator 128
Input, the inverting input of comparator 128 inputs the second reference voltage, the output end connection rest-set flip-flop 121 of comparator 128
R ends.
Constant-current controller 107 needs to extract the degaussing time of the current signal and transformer that flow through armature winding Np
Tdemag, by exporting the conducting and cut-off of modulated signal controlling switch, to stablize output current.In the system shown in figure 1,
The current signal for flowing through armature winding Np is the electric current of metal oxide semiconductor field effect tube Q1 source electrodes outflow, and transformer is gone
Magnetic time Tdemag can be obtained by the node in the middle of feedback resistance R3 and R4.
Assuming that secondary windings Ns is I by the commutation diode D6 and output capacitance C4 electric currents exportedout, metal oxide
Semiconductor field Q1 source voltage is Vcs, current sampling resistor R119 resistance value is Rcs, the armature winding Np number of turn
For Npri, the secondary windings Ns number of turn is Nsec, the cycle of the output signal of constant-current controller 107 is T.
When converter is operated in non-continuous mode:
As can be seen that can be by simultaneously constant from formula (1)And Vcs-peakMethod carry out constant output current.
With reference to Fig. 1 and Fig. 2, if metal oxide semiconductor field effect tube Q1 is turned on, current sampling resistor is flowed through
R119 electric current linearly increases.It is assumed that the magnitude of voltage of the second reference voltage is Vref2, metal oxide semiconductor field effect tube Q1
Source voltage together with the second reference voltage enter comparator 128.When metal oxide semiconductor field effect tube Q1 source electrode
When voltage is more than the second reference voltage, then the output voltage of comparator 128 is high level.
So metal oxide semiconductor field effect tube Q1 source voltage values VcsFor:
Vcs=Vref2 (2)
When metal oxide semiconductor field effect tube Q1 ends, the energy being stored in transformer 104 is released to defeated
Go out end, demagnetization process starts.In demagnetization process, degaussing detection module 108 is carried out to the signal in the middle of feedback resistance R3 and R4
Processing, exports degaussing time signal, that is, Tdemag.The output signal controlling transmission of degaussing detection module 108 switch 116, instead
The output signal controlling transmission switch 115 of phase device 110, by current source 113 and 114, discharge and recharge is carried out to electric capacity C131.Assuming that
The magnitude of voltage of first reference voltage is Vref1, electric capacity C131 voltage signal and the first reference voltage signal enter comparator together
118.When electric capacity C131 voltage signal is more than the first reference voltage signal, the output signal of comparator 118 for high level simultaneously
Into rest-set flip-flop 121, the output signal of rest-set flip-flop 121 enters drive module 123, finally produces modulated signal, control gold
Belong to the open-minded of oxide semiconductor field effect pipe Q1.Assuming that the electric current of current source 113 and 114 is I respectively1And I2, now draw:
By formula (1), (2) and (3) simultaneous, with reference to Fig. 1 and Fig. 2, it can be seen that the constant-current controller 107 of primary side feedback leads to
Cross constantAnd Vcs-peakTo realize the course of work of constant output current.
But existing primary side feedback constant current technology, converter can only operate in non-continuous mode, and the mode converter is worked as
Power output is more than 20 watt-hours, and it is not high to there is transformer utilization factor, the problems such as switching tube current stress is excessive.
Therefore, in the urgent need to a kind of appearance of the technology for the primary side constant current for being adaptive to continuous and non-continuous mode.
The content of the invention
Goal of the invention:It is an object of the invention to provide it is a kind of be adaptive to continuous and non-continuous mode based on primary side feedback
Constant current mode inverse excitation type converter.
Technical scheme:Constant current mode inverse excitation type converter of the present invention based on primary side feedback, including rectifier bridge, rectification
The direct-flow output signal of bridge is filtered by wave filter, filter output connection first resistor R11 and the first electric capacity C31 groups
Into parallel circuit one end, one end of parallel circuit of first resistor R11 and the first electric capacity C31 compositions is also connected with armature winding
Np non-same polarity, first resistor R11 is connected the first diode D51 with the other end of the first electric capacity C31 parallel circuits constituted
Negative electrode, the first diode D51 anode connects armature winding Np Same Name of Ends and metal oxide semiconductor field-effect respectively
Pipe Q11 drain electrode, secondary windings Ns Same Name of Ends connects the second diode D61 anode, the second diode D61 negative electrode connection
The one end for the parallel circuit that second electric capacity C41 and second resistance R21 are constituted, it is that the second electric capacity C41 and second resistance R21 is constituted and
Join the other end connection secondary windings Ns of circuit non-same polarity, assists winding Naux Same Name of Ends connection 3rd resistor R31's
One end, 3rd resistor R31 one end is also connected with the 3rd diode D71 anode, the 3rd diode D71 electricity of negative electrode connection the 3rd
Hold C51 one end, the 3rd electric capacity C51 other end ground connection, assists winding Naux non-same polarity is also grounded, 3rd resistor R31
The other end be grounded by the 4th resistance R41, armature winding Np, secondary windings Ns and assists winding Naux composition transformer, gold
The source electrode for belonging to oxide semiconductor field effect pipe Q11 connects the 5th resistance Rcs1 one end, the 5th resistance Rcs1 another termination
Ground, in addition to oscillator, the output end of oscillator connect the S ends of rest-set flip-flop, and the output end of rest-set flip-flop passes through drive module
Connect metal oxide semiconductor field effect tube Q1 grid, the R ends of rest-set flip-flop connect the output end of the first OR gate, first or
One input of door connects the output end of first comparator, and the in-phase input end of first comparator connects the 5th resistance respectively
Rcs1 one end and one end of first switch, the inverting input of first comparator input the first reference voltage, first switch
The other end connects the 4th electric capacity C243 one end, and the 4th electric capacity C243 other end is grounded, and the 4th electric capacity C243 one end also connects
An input of output current computing module is connect, the output end of output current computing module connects the anti-of the first operational amplifier
Phase input, the in-phase input end of the first operational amplifier inputs the second reference voltage, and the output end of the first operational amplifier connects
The input opened with sampling time module is connect, the output end opened with sampling time module connects the another of the first OR gate
Individual input, opens the control end with sampling time module another output end connection first switch, 3rd resistor R31's is another
End is also connected with the input of degaussing detection module, the output end connection output current computing module of degaussing detection module another
Input.
Further, described open includes triangular-wave generator, the output end point of triangular-wave generator with sampling time module
Do not connect the in-phase input end of the second comparator and the in-phase input end of the 3rd comparator, the output end of the second comparator is as opening
One output end of logical and sampling time module, the inverting input of the second comparator connects the 6th resistance R101 one end, the
The inverting input of two comparators is also as the input opened with sampling time module, and the 6th resistance R101 other end is connected
7th resistance R111 one end, the 7th resistance R111 other end ground connection, the 7th resistance R111 one end is also connected with the 3rd and compared
The inverting input of device, the output end of the 3rd comparator connects the input of monostable module, and the output end of monostable module is made
To open another output end with sampling time module.
Further, described open includes the 4th comparator with sampling time module, and the in-phase input end of the 4th comparator connects
The 5th resistance Rcs1 one end is connect, the inverting input of the 4th comparator is used as the input opened with sampling time module,
The output end of four comparators is used as the output end opened with sampling time module, the output end connection latch of rest-set flip-flop
Clock end, the data input pin connection latch of latchEnd, latchEnd be also connected with first with one of door it is defeated
Enter end, first with another input of door be also respectively connected with rest-set flip-flop output end and second with an input of door,
The Q ends connection second of latch and another input of door, first is connected the control of second switch with the output end of door respectively
End and the control end of the 3rd switch, one end of second switch are grounded by the first current source, and the other end of second switch connects respectively
The inverting input of the 5th comparator and one end of the 4th switch are connect, the inverting input of the 5th comparator also passes through the second electric capacity
C731 is grounded, and the in-phase input end of the 5th comparator inputs the 3rd reference voltage, the output end connection the 3rd of the 5th comparator with
One input of door, the 3rd be connected the output end of first and door with another input of door, the 3rd and door output end company
An input of the second OR gate is connect, the other end of the 4th switch connects supply voltage by the second current source, the 4th switch
Control end connection second and the output end of door, second is also connected with the control end of the 5th switch with the output end of door, the 5th switch
One end is grounded by the 3rd current source, and the inverting input and the 3rd that the 5th other end switched connects the 6th comparator respectively is opened
One end of pass, the other end of the 3rd switch connects supply voltage by the 4th current source, and the inverting input of the 6th comparator is also
It is grounded by the 3rd electric capacity C732, the in-phase input end of the 6th comparator inputs the 4th reference voltage, the output of the 6th comparator
End connection the 4th and an input of door, the 4th is connected the output end of second and door with another input of door, the 4th and
The output end of door connects another input of the second OR gate, the output end connection the 5th of the second OR gate and an input of door
End, the 5th is connected the output end of rest-set flip-flop with another input of door, the 5th and door output end as opening and
Another output end of sampling time module.
Further, the output current computing module include the second operational amplifier, the second operational amplifier it is same mutually defeated
Enter end as an input of output current computing module, the inverting input of the second operational amplifier connects the second computing and put
The output end of big device, the output end of the second operational amplifier is also connected with one end of the 6th switch, the other end difference of the 6th switch
The 8th resistance R305 one end and one end of the 7th switch are connected, the 8th resistance R305 other end is connect by the 9th electric capacity C306
Ground, the 8th resistance R305 other end is also as the output end of output current computing module, and the control end connection of the 6th switch is anti-
The input of phase device, the control end of the switch of output end connection the 7th of phase inverter, the input of phase inverter is also as output current
Another input of computing module.
Beneficial effect:The invention discloses a kind of constant current mode inverse excitation type converter based on primary side feedback, it can not only work
In non-continuous mode, moreover it is possible to be operated in continuous mode.In addition, transformer utilization factor is high in the present invention, compared to can only operate in
For the variator of non-continuous mode, power can do more.
Brief description of the drawings
Fig. 1 is the circuit diagram of the constant current mode inverse excitation type converter of primary side feedback of the prior art;
Simplified timing diagram when Fig. 2 works for constant current mode inverse excitation type converter in Fig. 1;
Fig. 3 be the specific embodiment of the invention in constant current mode inverse excitation type converter circuit diagram;
Fig. 4 is to open circuit diagram with one embodiment of sampling time module in the specific embodiment of the invention;
Fig. 5 be open with sampling time module use one embodiment circuit when constant current mode inverse excitation type converter non-
The output current formula of continuous and continuous mode;
Fig. 6 be open with sampling time module use one embodiment circuit when constant current mode inverse excitation type converter non-
Simplified timing diagram during continuous mode;
Fig. 7 is to open constant current mode inverse excitation type converter when using the circuit of one embodiment with sampling time module connecting
Simplified timing diagram during Discontinuous Conduction mode;
Fig. 8 be the specific embodiment of the invention in output current computing module circuit diagram;
Fig. 9 is to open circuit diagram with second embodiment of sampling time module in the specific embodiment of the invention;
Figure 10 be open with sampling time module using second embodiment circuit when constant current mode inverse excitation type converter exist
Simplified timing diagram during non-continuous mode;
Figure 11 be open with sampling time module using second embodiment circuit when constant current mode inverse excitation type converter exist
Simplified timing diagram during continuous mode.
Embodiment
With reference to the accompanying drawings and detailed description, technical scheme is further introduced.
Present embodiment discloses a kind of constant current mode inverse excitation type converter based on primary side feedback, as shown in figure 3, bag
Rectifier bridge 201 is included, rectifier bridge 201 includes the 4th diode D11, the 5th diode D21, the 6th diode D31 and the seven or two pole
Pipe D41, the 4th diode D11 anode connect the 6th diode D31 negative electrode, the 4th diode D11 negative electrode connection the 5th
Diode D21 negative electrode, the 5th diode D21 anode connects the 7th diode D41 negative electrode, the 7th diode D41 sun
Pole connects the 6th diode D31 anode.The direct-flow output signal of rectifier bridge 201 is filtered by wave filter 202.Wave filter
202 include inductance L11, and inductance L11 one end connects the 7th electric capacity C11 one end and the 5th diode D21 negative electrode, inductance respectively
The L11 other end connects the 8th electric capacity C21 one end and first resistor R11 one end respectively, the 8th electric capacity C21 other end and
The 7th electric capacity C11 other end is grounded.First resistor R11 one end is also connected with the first electric capacity C31 one end, first resistor
The R11 other end connects the first electric capacity C31 other end.First electric capacity C31 one end is also connected with the non-of the same name of armature winding Np
End, the first electric capacity C31 other end is also connected with the first diode D51 negative electrode, and the first diode D51 anode is connected just respectively
The drain electrode of level winding Np Same Name of Ends and metal oxide semiconductor field effect tube Q11, secondary windings Ns Same Name of Ends connection the
Two diode D61 anode, the second diode D61 negative electrode connects the electricity in parallel that the second electric capacity C41 is constituted with second resistance R21
The one end on road, the second electric capacity C41 is connected the non-of the same name of secondary windings Ns with the other end of the second resistance R21 parallel circuits constituted
End, assists winding Naux Same Name of Ends connection 3rd resistor R31 one end, 3rd resistor R31 one end is also connected with the three or two pole
Pipe D71 anode, the 3rd diode D71 negative electrode connects the 3rd electric capacity C51 one end, and the 3rd electric capacity C51 other end is grounded,
Assists winding Naux non-same polarity is also grounded, and the 3rd resistor R31 other end is grounded by the 4th resistance R41, armature winding
Np, secondary windings Ns and assists winding Naux composition transformers 204, metal oxide semiconductor field effect tube Q11 source electrode connect
Connect the 5th resistance Rcs1 one end 224, the 5th resistance Rcs1 other end ground connection.Wherein, first resistor R11, the first electric capacity C31
Absorbing circuit 203 is collectively constituted with the first diode D51.Second diode D61, the second electric capacity C41 and second resistance R21 are common
The secondary output circuit 205 of composition.3rd diode D71, the 3rd electric capacity C51,3rd resistor R31 and common group of the 4th resistance R41
Into auxiliary circuit 206.Constant current mode inverse excitation type converter also includes constant-current controller 2071, and constant-current controller 2071 includes oscillator
212, the output end of oscillator 212 connects the S ends of rest-set flip-flop 214, and the output end 215 of rest-set flip-flop 214 passes through drive module
217 connection metal oxide semiconductor field effect tube Q1 grid, the R ends of rest-set flip-flop 214 connect the output of the first OR gate 220
End a, input of the first OR gate 220 connects the output end of first comparator 223, the in-phase input end of first comparator 223
The 5th resistance Rcs1 one end 224 and one end of first switch 236 are connected respectively, and the inverting input of first comparator 223 is defeated
Enter the first reference voltage, the other end of first switch 236 connects the 4th electric capacity C243 one end, the 4th electric capacity C243 other end
Ground connection, the 4th electric capacity C243 one end is also connected with an input 237 of output current computing module 225, and output current is calculated
The output end 226 of module 225 connects the inverting input of the first operational amplifier 227, the first operational amplifier 227 it is same mutually defeated
Enter the second reference voltage of end input, the input with sampling time module 407 is opened in the output end connection of the first operational amplifier 227
End 228, the output end 221 opened with sampling time module 407 connects another input of the first OR gate 220, open-minded
With the control end of another output end 235 connection first switch 236 of sampling time module 407, the 3rd resistor R31 other end is also
The input of degaussing detection module 210 is connected, the output end connection output current computing module 225 of degaussing detection module 210
Another input 211.
One embodiment with sampling time module 407 is opened as shown in figure 4, including triangular-wave generator 230, triangle
The output end of wave producer 230 connects the in-phase input end of the second comparator 242 and the homophase input of the 3rd comparator 240 respectively
End, the output end of the second comparator 242 is used as the output end 221 opened with sampling time module 407, the second comparator
242 inverting input connects the 6th resistance R101 one end, and the inverting input of the second comparator 242, which is also used as, to be opened and adopt
The input 228 of sample time module 407, the 6th resistance R101 other end connects the 7th resistance R111 one end, the 7th resistance
R111 other end ground connection, the 7th resistance R111 one end is also connected with the inverting input of the 3rd comparator 240, the 3rd comparator
The input of 240 output end connection monostable module 234, the output end of monostable module 234 is as opening and the sampling time
Another output end 235 of module 407.6th resistance R101 and the 7th resistance R111 resistance is equal.
Second embodiment with sampling time module 407 is opened as shown in figure 9, including the 4th comparator 781, the 4th ratio
In-phase input end compared with device 781 connects the 5th resistance Rcs1 one end 224, and the inverting input of the 4th comparator 781 is as opening
The input 228 of logical and sampling time module 407, the output end of the 4th comparator 781 is as opening and sampling time module 407
An output end 221, the output end 215 of rest-set flip-flop 214 connects the clock end of latch 701, and the data of latch 701 are defeated
Enter end connection latch 701End, latch 701End is also connected with first and an input of door 704, and first and door
704 another input is also respectively connected with the output end 215 and second of rest-set flip-flop 214 and an input of door 703, lock
The Q ends connection second of storage 701 and another input of door 703, first is connected second switch respectively with the output end of door 704
The control end of 722 control end and the 3rd switch 723, one end of second switch 722 is grounded by the first current source 711, and second
The other end of switch 722 connects the inverting input of the 5th comparator 741 and one end of the 4th switch 721 respectively, and the 5th compares
The inverting input of device 741 is also grounded by the second electric capacity C731, and the in-phase input end of the 5th comparator 741 inputs the 3rd benchmark
Voltage, output end connection the 3rd and the input of door 751 of the 5th comparator 741, the 3rd with another input of door 751
End connection first and the output end of door 704, the 3rd is connected an input of the second OR gate 761, the 4th with the output end of door 751
The other end of switch 721 connects supply voltage, the control end connection second of the 4th switch 721 and door by the second current source 710
703 output end, second is also connected with the control end of the 5th switch 714 with the output end of door 703, and one end of the 5th switch 714 leads to
Cross the 3rd current source 724 to be grounded, the other end of the 5th switch 714 connects the inverting input and the of the 6th comparator 742 respectively
One end of three switches 723, the other end of the 3rd switch 723 connects supply voltage, the 6th comparator by the 4th current source 713
742 inverting input is also grounded by the 3rd electric capacity C732, and the in-phase input end of the 6th comparator 742 inputs the 4th benchmark electricity
Pressure, output end connection the 4th and the input of door 752 of the 6th comparator 742, the 4th with another input of door 752
Connection second and the output end of door 703, the 4th is connected another input of the second OR gate 761, second with the output end of door 752
The output end connection the 5th of OR gate 761 and an input of door 771, the 5th, which is connected RS with another input of door 771, touches
Send out the output end 215 of device 214, the 5th with the output end of door 771 as open with sampling time module 407 another is defeated
Go out end 235.
Wherein, output current computing module 225 is as shown in figure 8, including the second operational amplifier 301, the second operation amplifier
The in-phase input end of device 301 as output current computing module 225 an input, the second operational amplifier 301 it is anti-phase
Input connects the output end of the second operational amplifier 301, and the output end of the second operational amplifier 301 is also connected with the 6th switch
302 one end, the other end of the 6th switch 302 connects the 8th resistance R305 one end and one end of the 7th switch 303 respectively, the
The eight resistance R305 other end is grounded by the 9th electric capacity C306, and the 8th resistance R305 other end is also calculated as output current
The output end of module 225, the control end of the 6th switch 302 connects the input of phase inverter 304, and the output end of phase inverter 304 connects
The control end of the 7th switch 303 is connect, the input of phase inverter 304 is also as another input of output current computing module 225
End.
When opening the circuit with the use first embodiment of sampling time module 407, constant current mode inverse excitation type converter is operated in
Output current formula and simplified timing diagram difference during non-continuous mode are as shown in Figure 5 and Figure 6.The signal that oscillator 212 is produced
So that the output voltage of rest-set flip-flop 214 is changed into high level from low level, the output signal of drive module 217 is high level, that
Metal oxide semiconductor field effect tube Q11 enters conducting state, and armature winding Np electric current is by zero linear increase, the 5th electricity
Voltage on resistance Rcs1 also linearly increases.When second reference voltage is equal with the output voltage of the first operational amplifier 227, second
The output voltage of comparator 242 begins to upset so that the output voltage of rest-set flip-flop 214 is changed into low level from high level, drives
The output signal of dynamic model block 217 is low level, then metal oxide semiconductor field effect tube Q11 enters cut-off state.In gold
Belong in oxide semiconductor field effect pipe Q11 turn on process, when the output voltage of the first operational amplifier 227 passes through the 6th resistance
After R101 and the 7th resistance R111 partial pressure, because the 6th resistance R101 and the 7th resistance R111 resistance is equal, the 6th resistance
The magnitude of voltage of R101 and the 7th resistance R111 intermediate node is equal to the half of the output voltage values of the first operational amplifier 227.
So when the second reference voltage is equal with the magnitude of voltage of the 6th resistance R101 and the 7th resistance R111 intermediate node, the 3rd compares
The output signal of device 240 is begun turning, from the inference of the proportional theorem of parallel lines separated time section, and flip-flop transition is exactly that RS is touched
Send out the half of the high level time of the output voltage of device 214.
In Fig. 5, if the high level time of the output voltage of rest-set flip-flop 214 is Ton, then the 3rd comparator 240 is exported
Voltage is by the low time uprisedIf the peak value of the 5th resistance Rcs1 voltage is Vcs-peak, then the 4th electric capacity
C243 voltage is
In output current computing module 225, the 8th resistance R305 resistance is R0, output current computing module 225 it is defeated
Go out voltage V0, because the 9th electric capacity C306 is in a cycle, the electric charge of charging and discharging is equal, combined circuit connection, can obtain
Go out:
So,
V0Equal to the second reference voltage, it is assumed that be Vref, then:
Output current formula is during non-continuous mode:
Formula (3) and (4) simultaneous can be obtained:
It can be seen that, constant output current.
When opening the circuit with the use first embodiment of sampling time module 407, constant current mode inverse excitation type converter is operated in
Output current formula and simplified timing diagram difference during continuous mode are as shown in figure 5 and figure 7.The output voltage production of oscillator 212
Raw signal causes the output voltage of rest-set flip-flop 214 to be changed into high level from low level, and the output signal of drive module 217 is height
Level, then metal oxide semiconductor field effect tube Q11 enters conducting state, armature winding Np electric current is not zero and linear
Voltage on increase, the 5th resistance Rcs1 also linearly increases.Assuming that the initial value of the voltage on the 5th resistance Rcs1 is Vcs-min,
When second reference voltage is equal with the output voltage of the first operational amplifier 227, the output voltage of the second comparator 242 is begun to
Upset so that the output voltage of rest-set flip-flop 214 is changed into low level from high level, and the output signal of drive module 217 is low electricity
It is flat, then metal oxide semiconductor field effect tube Q11 enters cut-off state.In metal oxide semiconductor field effect tube Q11
In turn on process, when the output voltage of the first operational amplifier 227 passes through the 6th resistance R101 and the 7th resistance R111 partial pressure
Afterwards, because the 6th resistance R101 and the 7th resistance R111 resistance is equal, the 6th resistance R101 and the 7th resistance R111 segmentum intercalaris
The magnitude of voltage of point is equal to the half of the output voltage values of the first operational amplifier 227.So when the second reference voltage and the 6th
When the magnitude of voltage of resistance R101 and the 7th resistance R111 intermediate node is equal, the output signal of the 3rd comparator 240 is begun turning,
From the inference of the proportional theorem of parallel lines separated time section, flip-flop transition is exactly the height electricity of the output voltage of rest-set flip-flop 214
Half between usually.
In Fig. 5, if the high level time of the output voltage of rest-set flip-flop 214 is Ton, then the 3rd comparator 240 is exported
Voltage is by the low time uprisedIf the peak value of the 5th resistance Rcs1 voltage is Vcs-peak, then the 4th electric capacity
C243 voltage is
The input voltage of another input 211 of output current computing module 225 is Tdemag, and the cycle is T, similarly
Go out:
The voltage of the output end 226 of output current computing module 225 is:
The voltage of the output end 226 of output current computing module 225 is equal to the second reference voltage V ref, namely:
Output current formula is during continuous mode:
Formula (8) and (9) simultaneous can be obtained:
It can be seen that, constant output current.
Claims (4)
1. the constant current mode inverse excitation type converter based on primary side feedback, including rectifier bridge (201), the direct current output of rectifier bridge (201)
Signal is filtered by wave filter (202), and wave filter (202) output end connection first resistor R11 and the first electric capacity C31 is constituted
Parallel circuit one end, one end of parallel circuit of first resistor R11 and the first electric capacity C31 compositions is also connected with armature winding Np
Non-same polarity, first resistor R11 is connected the first diode D51's with the other end of the first electric capacity C31 parallel circuits constituted
Negative electrode, the first diode D51 anode connects armature winding Np Same Name of Ends and metal oxide semiconductor field effect tube respectively
Q11 drain electrode, secondary windings Ns Same Name of Ends connects the second diode D61 anode, the second diode D61 negative electrode connection the
The one end for the parallel circuit that two electric capacity C41 and second resistance R21 are constituted, it is in parallel that the second electric capacity C41 and second resistance R21 are constituted
The other end connection secondary windings Ns of circuit non-same polarity, the one of assists winding Naux Same Name of Ends connection 3rd resistor R31
End, 3rd resistor R31 one end is also connected with the 3rd diode D71 anode, and the 3rd diode D71 negative electrode connects the 3rd electric capacity
C51 one end, the 3rd electric capacity C51 other end ground connection, assists winding Naux non-same polarity is also grounded, 3rd resistor R31's
The other end is grounded by the 4th resistance R41, armature winding Np, secondary windings Ns and assists winding Naux composition transformers (204),
Metal oxide semiconductor field effect tube Q11 source electrode connects the 5th resistance Rcs1 one end, the 5th resistance Rcs1 other end
Ground connection, it is characterised in that:Also include oscillator (212), the output end of oscillator (212) connects the S ends of rest-set flip-flop (214),
The output end of rest-set flip-flop (214) connects metal oxide semiconductor field effect tube Q1 grid, RS by drive module (217)
The R ends of trigger (214) connect the output end of the first OR gate (220), and the input connection first of the first OR gate (220) is compared
Compared with the output end of device (223), the in-phase input end of first comparator (223) connects the 5th resistance Rcs1 one end and first respectively
Switch the one end of (236), the inverting input of first comparator (223) inputs the first reference voltage, first switch (236) it is another
One end connects the 4th electric capacity C243 one end, and the 4th electric capacity C243 other end is grounded, and the 4th electric capacity C243 one end is also connected with
One input of output current computing module (225), the output end of output current computing module (225) connects the first computing and put
The inverting input of big device (227), the in-phase input end of the first operational amplifier (227) inputs the second reference voltage, the first fortune
The output end for calculating amplifier (227) connects the input opened with sampling time module, opens one with sampling time module
Output end connects another input of the first OR gate (220), opens and another output end of sampling time module connection first
The control end of (236) is switched, the 3rd resistor R31 other end is also connected with the input of degaussing detection module (210), removes Magnetic testi
Another input of the output end connection output current computing module (225) of module (210).
2. the constant current mode inverse excitation type converter according to claim 1 based on primary side feedback, it is characterised in that:It is described open-minded
Include triangular-wave generator (230) with sampling time module, the output end of triangular-wave generator (230) connects second and compared respectively
The in-phase input end of the in-phase input end of device (242) and the 3rd comparator (240), the output end conduct of the second comparator (242)
An output end with sampling time module is opened, the inverting input of the second comparator (242) connects the 6th resistance R101's
One end, the inverting input of the second comparator (242) is also as the input opened with sampling time module, the 6th resistance R101
The other end connect the 7th resistance R111 one end, the 7th resistance R111 the other end ground connection, the 7th resistance R111 one end is also
The inverting input of the 3rd comparator (240) is connected, the output end connection monostable module (234) of the 3rd comparator (240)
Input, the output end of monostable module (234) is used as another output end opened with sampling time module.
3. the constant current mode inverse excitation type converter according to claim 1 based on primary side feedback, it is characterised in that:It is described open-minded
Include the 4th comparator (781) with sampling time module, the in-phase input end of the 4th comparator (781) connects the 5th resistance Rcs1
One end, the inverting input of the 4th comparator (781) is used as the input opened with sampling time module, the 4th comparator
(781) output end is latched as the output end opened with sampling time module, the output end connection of rest-set flip-flop (214)
The clock end of device (701), the data input pin connection latch (701) of latch (701)End, latch (701)End
It is also connected with an input for first and door (704), first is also respectively connected with rest-set flip-flop with another input of door (704)
(214) output end and second with an input of door (703), Q ends connection second and the door (703) of latch (701)
Another input, first is connected the control end and the 3rd switch of second switch (722) with the output end of door (704) respectively
(723) control end, one end of second switch (722) is grounded by the first current source (711), second switch (722) it is another
End connects the inverting input of the 5th comparator (741) and one end of the 4th switch (721) respectively, the 5th comparator (741)
Inverting input is also grounded by the second electric capacity C731, and the in-phase input end of the 5th comparator (741) inputs the 3rd reference voltage,
Output end connection the 3rd and an input of door (751) for 5th comparator (741), the 3rd with door (751) another is defeated
Enter end connection first and the output end of door (704), the 3rd be connected with the output end of door (751) one of the second OR gate (761) it is defeated
Enter end, the other end of the 4th switch (721) connects supply voltage, the control of the 4th switch (721) by the second current source (710)
End connection second and the output end of door (703), second is also connected with the control end of the 5th switch (714) with the output end of door (703),
One end of 5th switch (714) is grounded by the 3rd current source (724), and the other end of the 5th switch (714) connects the 6th respectively
One end of the inverting input of comparator (742) and the 3rd switch (723), the other end of the 3rd switch (723) passes through the 4th electricity
Stream source (713) connects supply voltage, and the inverting input of the 6th comparator (742) is also grounded by the 3rd electric capacity C732, and the 6th
The in-phase input end of comparator (742) inputs the 4th reference voltage, the output end connection the 4th of the 6th comparator (742) and door
(752) a input, the 4th is connected the output end of second and door (703) with another input of door (752), the 4th with
The output end of door (752) connects another input of the second OR gate (761), the output end connection the 5th of the second OR gate (761)
The output end of rest-set flip-flop (214) is connected with another input of door (771) with an input of door (771), the 5th, the
Five with the output end of door (771) as being used as another output end opened with sampling time module.
4. the constant current mode inverse excitation type converter according to claim 1 based on primary side feedback, it is characterised in that:The output
Current calculation module (225) includes the second operational amplifier (301), the in-phase input end conduct of the second operational amplifier (301)
One input of output current computing module (225), the inverting input of the second operational amplifier (301) connects the second computing
The output end of amplifier (301), the output end of the second operational amplifier (301) is also connected with one end of the 6th switch (302), the 6th
The other end of switch (302) connects the 8th resistance R305 one end and one end of the 7th switch (303), the 8th resistance R305 respectively
The other end be grounded by the 9th electric capacity C306, the 8th resistance R305 other end is also as output current computing module (225)
Output end, the 6th switch (302) control end connection phase inverter (304) input, phase inverter (304) output end connection
The control end of 7th switch (303), the input of phase inverter (304) also as output current computing module (225) another
Input.
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CN112636600A (en) * | 2019-10-09 | 2021-04-09 | 杭州必易微电子有限公司 | Constant current control circuit and control method and flyback circuit |
CN112886823A (en) * | 2021-02-20 | 2021-06-01 | 深圳市必易微电子股份有限公司 | Primary side control circuit, control method and isolated switching power supply |
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CN112886823B (en) * | 2021-02-20 | 2024-05-31 | 深圳市必易微电子股份有限公司 | Primary side control circuit, control method and isolated switching power supply |
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