CN204517684U - Isolated voltage conversion circuit and control circuit - Google Patents
Isolated voltage conversion circuit and control circuit Download PDFInfo
- Publication number
- CN204517684U CN204517684U CN201520126388.XU CN201520126388U CN204517684U CN 204517684 U CN204517684 U CN 204517684U CN 201520126388 U CN201520126388 U CN 201520126388U CN 204517684 U CN204517684 U CN 204517684U
- Authority
- CN
- China
- Prior art keywords
- voltage
- circuit
- signal
- output
- input
- Prior art date
- Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
- Withdrawn - After Issue
Links
- 238000006243 chemical reaction Methods 0.000 title claims abstract description 136
- 238000004804 winding Methods 0.000 claims abstract description 75
- 238000004146 energy storage Methods 0.000 claims abstract description 8
- 238000001514 detection method Methods 0.000 claims description 33
- 238000012360 testing method Methods 0.000 claims description 12
- 238000005070 sampling Methods 0.000 claims description 10
- 230000003111 delayed effect Effects 0.000 claims description 8
- 230000000052 comparative effect Effects 0.000 claims description 2
- 230000001681 protective effect Effects 0.000 claims description 2
- 238000002955 isolation Methods 0.000 abstract description 4
- 238000010586 diagram Methods 0.000 description 9
- 230000003321 amplification Effects 0.000 description 7
- 238000003199 nucleic acid amplification method Methods 0.000 description 7
- 238000013519 translation Methods 0.000 description 6
- 238000001914 filtration Methods 0.000 description 3
- 238000000034 method Methods 0.000 description 3
- 230000033228 biological regulation Effects 0.000 description 2
- 239000003990 capacitor Substances 0.000 description 2
- 238000005516 engineering process Methods 0.000 description 2
- 230000004044 response Effects 0.000 description 2
- 230000009471 action Effects 0.000 description 1
- 230000000903 blocking effect Effects 0.000 description 1
- 230000008859 change Effects 0.000 description 1
- 239000013256 coordination polymer Substances 0.000 description 1
- 238000013461 design Methods 0.000 description 1
- 238000011161 development Methods 0.000 description 1
- 230000007613 environmental effect Effects 0.000 description 1
- 230000009123 feedback regulation Effects 0.000 description 1
- 230000005669 field effect Effects 0.000 description 1
- 229910044991 metal oxide Inorganic materials 0.000 description 1
- 150000004706 metal oxides Chemical class 0.000 description 1
- 238000012986 modification Methods 0.000 description 1
- 230000004048 modification Effects 0.000 description 1
- 230000008569 process Effects 0.000 description 1
- 239000004065 semiconductor Substances 0.000 description 1
Landscapes
- Dc-Dc Converters (AREA)
Abstract
An isolated voltage conversion circuit and a control circuit are disclosed. The isolated voltage conversion circuit comprises an energy storage element, a controllable switch, a feedback circuit, a control module and a voltage ripple control circuit. The energy storage element is provided with a third winding used for sensing the output voltage of the isolation type voltage conversion circuit, the feedback circuit generates a feedback signal representing an output voltage signal according to the sensing voltage of the third winding, and the control module controls the on-off switching of the controllable switch according to the feedback signal. When the voltage conversion circuit is in light load, the voltage ripple control circuit detects the ripple of the output voltage, compares a voltage ripple signal with a threshold signal, and switches on the controllable switch when the ripple signal is greater than the threshold signal. The isolated voltage conversion circuit has good dynamic performance and low power consumption.
Description
Technical field
The utility model relates to isolated voltage conversion circuit, is specifically related to isolated voltage conversion circuit and the control circuit of the control of former limit.
Background technology
Along with the development of electronic technology and the raising of environmental requirement, efficiency and stability become the vital design factor of voltage conversion circuit.
Isolated voltage conversion circuit can be used for the high adapter of security requirement and charger, and it comprises former limit circuit and secondary circuit, passes through transformer isolation.In the isolated form translation circuit that traditional secondary end regulates, in order to realize constant voltage and/or current constant control, often need voltage and/or the current signal of sampling secondary, and carry out feedback regulation according to the voltage of secondary and/or current signal, control the turn-on and turn-off of former limit switching tube, and then regulate voltage and/or the electric current of secondary.The isolated voltage conversion circuit that traditional secondary end regulates can provide accurate voltage, Current Control, but its component count is more, sampling resistor increases power consumption, simultaneously due to the buffer action of transformer, usually, when sampling secondary current and/or voltage signal, secondary current and/or voltage signal carry out sampling and export former limit control circuit to by the normal optocoupler of costliness that needs.Therefore the isolated voltage conversion circuit that traditional secondary end regulates is with high costs, complex structure.
Nowadays, in order to reduce component count, avoiding using optocoupler, reducing cost and the complexity of circuit, and then raising the efficiency, usually obtained the size of isolated voltage conversion circuit output voltage and/or output current by the sampling of former limit.
Particularly, calculated the size of secondary output current by former limit peak current of sampling, and by the size of the tertiary winding of transformer sensing output voltage, and the output current signal of acquisition and output voltage signal are delivered to control circuit carry out FEEDBACK CONTROL.
Figure 1 shows that the isolated voltage conversion circuit 50 that a former limit controls.As shown in the figure, ac voltage signal V
aCby being converted to a d. c. voltage signal V after a rectifier bridge and capacitance
dC.
D. c. voltage signal V
dCthrough an inverse-excitation converting circuit and then be converted to an output voltage signal V
oUT.Inverse-excitation converting circuit comprises a transformer T and controlled tr tube 4.Transformer T comprises former limit winding 1, vice-side winding 2 and the tertiary winding 3.When gate-controlled switch 4 conducting, former limit winding 1 flows through electric current I
p, and stored energy; When gate-controlled switch 4 turns off, the energy that former limit winding stores is passed to load by a diode by vice-side winding 2, and now this diode flows through electric current I
s, the voltage V now on the tertiary winding 3
twith output voltage V
oUTbe directly proportional.When flowing through the electric current I of the diode be connected with vice-side winding 2
safter being reduced to zero, the voltage V on the tertiary winding 3
tbe zero.
Isolated voltage conversion circuit 50 comprises a feedback circuit 5 further, feedback circuit 5 couple transformer T the tertiary winding 3, as output voltage signal V
oUTraise, the induced voltage V on the tertiary winding
talso raise.Induced voltage V
tthrough divider resistance dividing potential drop, obtain an output voltage feedback signal V
fB.
Isolated voltage conversion circuit 50 comprises a control module 6 further, receives output voltage feedback signal V
fB, and according to reception output voltage feedback signal V
fBexport a control signal C
sto the grid of gate-controlled switch 4, control the turn-on and turn-off of gate-controlled switch 4, and then regulation output voltage V
oUT, make output voltage V
oUTconstant in a desired value.
Fig. 2 shows the work wave Figure 60 according to isolated voltage conversion circuit 50 1 embodiments.In the embodiment illustrated in figure 2, the load of isolated voltage conversion circuit 50 will experience nominal load, underloading and heavy duty three working stages.Wherein, when the load of isolated voltage conversion circuit 50 be the normal band such as nominal load and heavy duty carry the stage time, it is operated in the first mode of operation.When the load of isolated voltage conversion circuit 50 is the underloading stage, it is operated in the second mode of operation, and wherein, the underloading stage also comprises zero load.In the illustrated example shown in fig. 2, first mode of operation of isolated voltage conversion circuit 50 is pulse width modulation (PulseWidth Modulation, PWM) pattern, the second mode of operation is skip cycle mode, namely controls gate-controlled switch 4 in some cycle and stops turn-on and turn-off switching.In some other example, first mode of operation of isolated voltage conversion circuit 50 is PWM mode, second mode of operation is pulse frequency modulated (Pulse FrequencyModulation, PFM) pattern, i.e. gate-controlled switch 4 turn-on and turn-off frequencies go lower.In some other example, the first mode of operation of isolated voltage conversion circuit 50 can be PFM pattern, and the second mode of operation can be skip cycle mode.
As shown in the figure, the switch periods of isolated voltage conversion circuit 50 is T, and at the working stage of nominal load, it is operated in the first mode of operation, and the value of duty ratio D is d1.In the t0 moment, gate-controlled switch 4 conducting, primary current I
prise, the induced voltage V of the tertiary winding 3
tequal
output voltage feedback signal V
fBequal zero, wherein N
pthe number of turn of the first winding 1, N
tit is the number of turn of the tertiary winding 3.In the t1 moment, gate-controlled switch 4 turns off, secondary current I
sdecline, and the diode through being connected with vice-side winding 2 flows to load, now, the induced voltage V of the tertiary winding 3
tequal
output voltage feedback signal V
fBequal
wherein N
sbe the number of turn of the second winding 2, k is a proportionality coefficient, is determined by the divider resistance value in feedback circuit 5.During t2-t3, due to secondary current I
sbe zero, output voltage feedback signal V
fBequal zero.Meanwhile, during t2-t3, the load of isolated voltage conversion circuit 50 becomes underloading from nominal load, output voltage V
oUTraise.Next gate-controlled switch 4 blocking interval (t4-t5), output voltage feedback signal V
fBuprise, isolated for adjustment voltage conversion circuit 50 is entered the second mode of operation by control module 6, i.e. skip cycle mode.Gate-controlled switch 4 stops turn-on and turn-off switching, and the tertiary winding 3 can not respond to output voltage V
oUTsize, output voltage feedback signal V
fBbe zero.In the embodiment depicted in figure 2, two blank cycles (Blank time) just schematically, in real work, can need the quantity of sets itself blank cycle according to load.If during blank cycle, load changes, and load becomes heavy duty from underloading during t6-t7 as shown in FIG., output voltage V
oUTdragged down, and now output voltage feedback signal V
fBbe still zero, control module 6 can not return to the first mode of operation from the second mode of operation timely, thus can not according to the change of load in time to output voltage V
oUTadjust.Only have after blank cycle terminates, the tertiary winding 3 senses output voltage V
oUTvalue after, control module 6 could according to output voltage feedback signal V
fBto output voltage V
oUTregulate.As shown in the figure, in the t8-t9 moment, output voltage feedback signal V
fBdiminish, control module 6 draws high output voltage V by the value (becoming d2 from d1) increasing duty ratio D in next cycle
oUTvalue.
In other words, when isolated voltage conversion circuit 50 returns to the stage of being normally with and carrying from the underloading stage, due to the output voltage feedback signal V that the tertiary winding 3 senses
fBdelay, isolated voltage conversion circuit 50 can not return to the first mode of operation from the second mode of operation in time, and thus dynamic response is slow, and efficiency is low.
In some other example, isolated voltage conversion circuit 50 only has a mode of operation in normal band year stage and underloading stage.When isolated voltage conversion circuit 50 enters the underloading stage, the turn-on and turn-off time of gate-controlled switch 4 is very limited, and the tertiary winding 3 as above thus also can be caused can not to sense output voltage signal V timely
oUT.Isolated voltage conversion circuit 50 still can cause the consequences such as dynamic response is slow, inefficiency.
Meanwhile, to it will be appreciated by those skilled in the art that the inverse-excitation converting circuit illustrated is signal type here, in other isolated topological structure, such as forward conversion circuit, isolation bridge conversion circuit etc., adopt the former limit control method of the tertiary winding and circuit to there is identical problem too.Therefore, need to consider in the sampling control circuit of former limit, how to improve dynamic responding speed and the efficiency of translation circuit.
Utility model content
For one or more problem of the prior art, propose a kind of isolated voltage conversion circuit and control circuit of former limit control.
The utility model provides a kind of isolated voltage conversion circuit on the one hand, comprise: energy-storage travelling wave tube, for storage power, there is former limit winding, vice-side winding and the tertiary winding, the wherein said tertiary winding for responding to an output voltage of described voltage conversion circuit, and produces an output voltage induced signal; Gate-controlled switch, is electrically coupled to described energy-storage travelling wave tube, is switched in described energy-storage travelling wave tube and stores and release energy, and then an input voltage is converted to described output voltage by the turn-on and turn-off of described gate-controlled switch; Feedback circuit, comprise voltage feedback circuit and there is input and output, the input of described voltage feedback circuit receives described output voltage induced signal, and provides an output voltage feedback signal to characterize described output voltage at the output of described voltage feedback circuit; Control module, receive described output voltage feedback signal, and produce the first control signal according to described output voltage feedback signal, and judge that described voltage conversion circuit is that underloading or normal band carry according to described output voltage feedback signal, wherein, when described output voltage feedback signal is less than desired value, described first control signal is effective; Voltage ripple control circuit, when described voltage conversion circuit underloading, described voltage ripple control circuit detects the ripple of output voltage, and voltage ripple signals and first threshold signal is compared, and produces second control signal; Wherein, when described ripple signal is greater than described first threshold signal, described second control signal is effective; And logical circuit, there is first input end, the second input and output, described first input end receives described first control signal, described second input receives described second control signal, described logical circuit carries out logical operation to described first control signal and described second control signal, and provides the 3rd control signal to switch for the turn-on and turn-off controlling described gate-controlled switch at output; Wherein, when described first control signal and described any one signal of second control signal effective time, gate-controlled switch described in described 3rd control signal conducting.
The utility model provides a kind of former limit control circuit for isolated voltage conversion circuit on the other hand, wherein, described isolated voltage conversion circuit comprises a gate-controlled switch and transformer, described transformer has former limit winding, vice-side winding and the tertiary winding, the wherein said tertiary winding for responding to an output voltage of described voltage conversion circuit, and produces an output voltage induced signal as output voltage feedback signal; Wherein, described control circuit comprises: control module, receive described output voltage feedback signal, and produce the first control signal and light condition detection signal according to described output voltage feedback signal, wherein, when described light condition detection signal is effective, described isolated voltage conversion circuit enters light condition, when described output voltage feedback signal is less than desired value, described first control signal is effective; Voltage ripple control circuit, receive described light condition detection signal, when described light condition signal is effective, described voltage ripple control circuit detects the ripple of output voltage, and voltage ripple signals and first threshold signal are compared, produce second control signal, wherein, when described ripple signal is greater than described first threshold signal, described second control signal is effective; And logical circuit, receive described first control signal and described second control signal, described logical circuit carries out logical operation to described first control signal and described second control signal, and provide one the 3rd to control signal to described gate-controlled switch for controlling the turn-on and turn-off switching of described gate-controlled switch, when described first control signal and described second control signal any one effective time, gate-controlled switch described in described 3rd control signal conducting.
Accompanying drawing explanation
Below in institute's drawings attached, identical label represents to have identical, similar or corresponding feature or function.
Fig. 1 shows the rough schematic view of a kind of existing former limit control voltage translation circuit 50;
Fig. 2 shows waveform correlation 60 schematic diagram in the control voltage translation circuit of former limit shown in Fig. 1 50;
Fig. 3 shows isolated voltage conversion circuit 100 schematic diagram according to the utility model one embodiment;
Fig. 4 shows control circuit 200 schematic diagram of the isolated voltage conversion circuit according to the utility model one embodiment;
Fig. 5 shows another control circuit 300 schematic diagram of the isolated voltage conversion circuit according to the utility model one embodiment;
Fig. 6 shows the schematic diagram of the isolated voltage conversion circuit 400 according to the utility model one embodiment.
Embodiment
Specific embodiment of the present disclosure being described in detail below, it should be noted that the embodiments described herein is only for illustrating, is not limited to the disclosure.On the contrary, the disclosure is intended to contain the various alternatives, modification and the equivalent that define in the disclosure spirit and scope that defined by claims.In the following description, in order to provide thorough understanding of the present disclosure, a large amount of specific detail has been set forth.But do not have these details for it should be understood by one skilled in the art that, the disclosure can be implemented equally.In some other embodiment, for the ease of highlighting purport of the present disclosure, well-known scheme, flow process, components and parts and circuit are not explained in detail.
Fig. 3 shows the simplified block diagram of the isolated voltage conversion circuit 100 according to the utility model one embodiment.As shown in Figure 3, isolated voltage conversion circuit 100 comprises rectification circuit 10, receives ac voltage signal V
aC, and by ac voltage signal V
aCrectification, simultaneously after capacitance 11 filtering, provides a d. c. voltage signal V
dC.
Isolated voltage conversion circuit 100 comprises a conversion switch further, and as shown in the figure, conversion switch is illustrated as an inverse-excitation type translation circuit, comprises transformer T, controlled tr tube 26, diode 24 and filter capacitor 25.Conversion switch passes through the turn-on and turn-off of gate-controlled switch 26, by d. c. voltage signal V
dCbe converted to an output voltage signal V
oUT.It is N that transformer T comprises the number of turn
pformer limit winding 21, the number of turn is N
svice-side winding 22, the number of turn is N
tthe tertiary winding 23.When gate-controlled switch 26 conducting, former limit winding 21 flows through electric current I
p, and stored energy; When gate-controlled switch 26 turns off, what former limit winding stored by vice-side winding 22 can pass to load, and diode 24 flows through electric current I
s.Vice-side winding voltage 22 after electric capacity 25 filtering as output voltage V
oUT.The tertiary winding 23 is for sensing output voltage V
oUT, when gate-controlled switch 26 conducting, the induced voltage on the tertiary winding 23 is V
tequal
when gate-controlled switch 26 turns off, the voltage on the tertiary winding 23 is
it will be appreciated by those skilled in the art that here, it is an embodiment that conversion switch is illustrated as inverse-excitation converting circuit, and conversion switch can also comprise other isolated topological structure, such as forward conversion circuit, isolation bridge conversion circuit etc.In addition, in isolated voltage conversion circuit 100, gate-controlled switch 26 in conversion switch is illustrated as metal oxide semiconductor field effect tube (MOSFET), in other embodiments, gate-controlled switch 26 comprises other suitable power switch pipes, such as technotron (JFET) constant power switching tube.
Isolated voltage conversion circuit 100 comprises a feedback circuit further.Feedback circuit comprises voltage feedback circuit, this voltage feedback circuit couple transformer T the tertiary winding 23, receive induced voltage signal V
t, and by induced voltage V
tbe converted to an output voltage feedback signal V
fB, characterize output voltage V
oUTvalue.In one embodiment, output voltage feedback signal V
fBequal
itself and output voltage V
oUTwith the number of turn N of the tertiary winding
tbe directly proportional, with the number of turn N of vice-side winding
sbe inversely proportional to.In one embodiment, such as, in the control loop of a voltage, double current loop modulation, feedback circuit also comprises current feedback circuit, and the electric current I of gate-controlled switch 26 is flow through in the sampling of this current feedback circuit
sW, electric current I
sWpeak value can characterize the value of secondary output current, therefore an output current feedback signal I can be provided
fB.
Isolated voltage conversion circuit 100 comprises a control module 40 further.In one embodiment, control module 40 receives output voltage feedback signal V
fB, and according to reception output voltage feedback signal V
fBfirst control signal CS and light condition detection signal UL is provided.In another embodiment, control module 40 receives output voltage feedback signal V
fBwith output current feedback signal I
fB, and according to reception output voltage feedback signal V
fBwith output current feedback signal I
fBfirst control signal CS and light condition detection signal UL is provided.First control signal CS is a logic low and high level signal, and representative controls the state of gate-controlled switch 26 turn-on and turn-off.In one embodiment, high level represents conducting gate-controlled switch 26, and low level representative turns off gate-controlled switch 26.In another embodiment, also can on the contrary for it.When output voltage feedback signal VFB is less than a preset value, the first control signal CS is effective.In one embodiment, being high level when the second control signal CV is effective, in another embodiment, is low level when the second control signal CV is effective.
Isolated voltage conversion circuit 100 comprises a voltage ripple control circuit 70 further and has first input end, the second input and output, wherein, the first input end of voltage ripple control circuit 70 couples the output of isolated voltage conversion circuit 100, receives output voltage V
oUT; Second input couples control module and receives light condition detection signal UL; Voltage ripple control circuit 70, after isolated voltage conversion circuit 100 enters underloading working stage, detects output voltage V
oUTripple and produce a ripple signal Δ V
oUT.Voltage ripple control circuit 70 is by ripple signal Δ V
oUTgeneration second control signal CV is compared with a threshold signal.Second control signal CV is a logic low and high level signal, as ripple signal Δ V
oUTwhen being greater than threshold signal, the second control signal CV is effective, gate-controlled switch 26 conducting.In one embodiment, being high level when the second control signal CV is effective, in another embodiment, is low level when the second control signal CV is effective.Voltage ripple control circuit 70 comprises voltage ripple detection circuit 701 and voltage ripple comparison circuit 702, and voltage ripple detection circuit 701 detects output voltage V
oUTripple and produce ripple signal Δ V
oUT, voltage ripple comparison circuit 702 receives ripple signal Δ V
oUT, by ripple signal Δ V
oUTgeneration second control signal CV is compared with a threshold signal.
Isolated voltage conversion circuit 100 comprises a logical circuit 80 further and has first input end, the second input and output, the first input end of logical circuit 80 receives the first control signal CS, second input of logical circuit 80 receives the second control signal CV, first control signal CS and the second control signal CV is done logical operation and exports the grid of the 3rd control signal CTRL to gate-controlled switch 26 at output by logical circuit 80, the turn-on and turn-off controlling gate-controlled switch 26 switch, and then regulation output voltage V
oUT, make output voltage V
oUTconstant in a desired value.Wherein, when the first control signal CS and any one signal of the second control signal CV effective time, conducting gate-controlled switch 26.
In voltage conversion circuit 100 isolated shown in Fig. 3, control module 40, logical circuit 80 and voltage ripple comparison circuit 702 are illustrated as a power management chip, this power management chip has voltage feedback signal input pin receiver voltage feedback signal V
fB, current feedback signal input pin receives output current feedback signal I
fB, ripple signal input pin receives ripple signal Δ V
oUT, drive pin to export the 3rd control signal CTRL, power pin receives supply power voltage V
cC, ground pin is electrically connected to logically and compensation pins receives loop compensation signal CP.In other some examples, the gate-controlled switch 26 in conversion switch can also be integrated into chip internal by power management chip.Now, power management chip increases a gate-controlled switch drain electrode and draws pin, and previous current feedback signal input pin, driving pin all can omit.Can comprise different control methods in control module 40, such as in one embodiment, control module 40 only comprises voltage control loop, controls output voltage; In yet another embodiment, control module 40 only comprises current controlled circuit, controls output current; In yet another embodiment, control circuit comprises 40 voltages, double current loop modulation loop, controls output current and output voltage.Equally, control module 40 comprises multiple-working mode, and in one embodiment, control module 40 controls isolated voltage conversion circuit 100 and is operated in PWM mode; In yet another embodiment, control module 40 controls isolated voltage conversion circuit 100 and is operated in PFM pattern.In yet another embodiment, control module 40 controls isolated voltage conversion circuit 100 and works in multiple modes, such as, work in a PWM mode under the condition of work that normal band carries, PFM pattern is operated in, again or under the condition of work of underloading, be operated in the pattern of hop cycle under underloading condition of work.
Fig. 4 shows control circuit 200 schematic diagram of the isolated voltage conversion circuit according to the utility model one embodiment.Control circuit 200 comprises feedback circuit, control module 40, voltage ripple control circuit 70 and logical circuit 80.
In one embodiment, feedback circuit comprises voltage feedback circuit 30, has input and output.The input of voltage feedback circuit 30 couples the tertiary winding 23 of transformer T, receives induced voltage V
tand provide output voltage feedback signal V at output
fB.
In one embodiment, control module 40 comprises voltage control circuit 401 and light condition testing circuit 402.Voltage control circuit 401 has input and output, and its input receives output voltage feedback signal V
fB, and according to output voltage feedback signal V
fBfirst control signal CS.In one embodiment, voltage control circuit 401 comprises voltage error amplifying circuit and voltage comparator circuit, and voltage error amplifying circuit is by output voltage feedback signal V
fBcompare with a reference voltage signal, export an error amplification signal; Error amplification signal and a ramp signal compare by voltage comparator circuit, the first control signal CS.In another embodiment, voltage control circuit 401 comprises all modules of constant on-time control circuit, such as constant on-time generation module, voltage comparator circuit and logical circuit.Time constant conduction module produces a constant on-time signal; Output voltage feedback signal VFB is compared generation comparison signal with a reference voltage signal by voltage comparison module; Constant on-time signal and comparison signal are done logical operation by logic module, and then produce the first control signal CS.In a word, voltage control circuit 401 can comprise the circuit module needed for any voltage control mode.
Control module 40 comprises light condition testing circuit 402 further, has input and output.The input of light condition testing circuit 402 receives output voltage feedback signal V
fB, and according to output voltage feedback signal V
fBexport a light condition detection signal UL, for judging whether isolated voltage conversion circuit 100 enters light-load mode.In one embodiment, light condition testing circuit is by output voltage feedback signal V
fBcompare with a threshold signal, as output voltage feedback signal V
fBwhen being greater than this threshold signal, representing isolated voltage conversion circuit and enter light-load mode.
In one embodiment, logical circuit 80 receives the first control signal CS and the second control signal CV, and the first control signal CS and the second control signal CV is done logical operation, export the 3rd control signal CTRL at output and then control the turn-on and turn-off switching of gate-controlled switch 26.
In one embodiment, feedback circuit comprises output current feedback circuit 31 further, has input and output.The input receiving key current signal I of current feedback circuit 31
sW, and provide output current feedback signal I at output
fB.In this embodiment, the voltage control circuit 401 in control module 40 is also by this output current of reception feedback signal I
fB, and according to output voltage feedback signal V
fBwith output current feedback signal I
fB, provide the first control signal CS at output.Now voltage control circuit 401 is a voltage, double current loop modulation circuit, can comprise any voltage, circuit module needed for double current loop modulation mode.
In one embodiment; control circuit 200 also comprises protective circuit 90; receive the one or more voltage and/or the signal that need overvoltage and/or overcurrent protection; and this one or more voltage and/or signal are compared with respective threshold value, and provide one or more control signal PRO to logical circuit 80 according to comparative result.In this embodiment, this one or more control signal and the first control signal CS and the second control signal CV are carried out logical operation by logical circuit 80, produce described 3rd control signal CTRL, and then the turn-on and turn-off controlling gate-controlled switch 26 switch.
Fig. 5 shows control circuit 300 schematic diagram of the isolated voltage conversion circuit according to another embodiment of the utility model.As shown in the figure, control circuit 200 comprises feedback circuit, control module 40, voltage ripple control circuit 70 and logical circuit 80.
Compared with the control circuit 200 shown in Fig. 4, the maximum difference of control circuit 300 is control module 40.Control module 40 comprises a mode control circuit 403 further, is operated in the first mode of operation and the second mode of operation for setting isolated voltage conversion circuit 100.Wherein, when the load of isolated voltage conversion circuit 100 is that when normally band carries the stage, it is operated in the first mode of operation.When the load of isolated voltage conversion circuit 100 is the underloading stage, it is operated in the second mode of operation, and wherein, the underloading stage also comprises zero load.In one embodiment, the first mode of operation is PWM mode, and the second mode of operation is skip cycle mode, and namely in some cycle, switch stops turn-on and turn-off switching.In another embodiment, the first mode of operation is PWM mode, and the second mode of operation is PFM pattern, i.e. switch conduction and shutoff frequencies go lower.In some other embodiment, the first mode of operation can be PFM pattern, and the second mode of operation is skip cycle mode.
In embodiment illustrated in fig. 5 300, voltage control circuit 401 no longer directly exports the first control signal CS, but delivers to mode control circuit 403 as the 4th control signal CA.Mode control circuit 403 has first input end, the second input and output.Its first input end couples the input of voltage control circuit 401, receives the 4th control signal CA; Its second end couples the output of light condition testing circuit 402, receives light condition detection signal UL; Mode control circuit 403 sets the first mode of operation and second mode of operation of isolated voltage conversion circuit 100 according to light condition detection signal UL and the 4th control signal CA, and exports the first control signal CS at output.Wherein, when isolated voltage conversion circuit 100 is operated in the first mode of operation when normally band carries, the second mode of operation is operated in when underloading.In one embodiment, when isolated voltage conversion circuit 100 is operated in the first mode of operation, the first control signal CS is identical with the 4th control signal CA.
Fig. 6 shows the circuit theory diagrams of the isolated voltage conversion circuit 400 according to the utility model one embodiment.
Isolated voltage conversion circuit 400 comprises a conversion switch, and as shown in Figure 6, conversion switch is illustrated as an inverse-excitation type translation circuit, comprises transformer T, controlled tr tube 26, diode 24 and filter capacitor 25.Conversion switch passes through the turn-on and turn-off of gate-controlled switch 26, by d. c. voltage signal V
dCbe converted to an output voltage signal V
oUT.It is N that transformer T comprises the number of turn
pformer limit winding 21, the number of turn is N
svice-side winding 22, the number of turn is N
tthe tertiary winding 23.When gate-controlled switch 26 conducting, former limit winding 21 flows through electric current I
p, and stored energy; When gate-controlled switch 26 turns off, the energy transferring that former limit winding stores by vice-side winding 22 is to load, and diode 24 flows through electric current I
s.Vice-side winding voltage 22 after electric capacity 25 filtering as output voltage V
oUT.The tertiary winding 23 is for sensing output voltage V
oUT, when gate-controlled switch 26 conducting, the induced voltage on the tertiary winding 23 is V
tequal
when gate-controlled switch 26 turns off, the induced voltage on the tertiary winding 23 is V
tvoltage is
Isolated voltage conversion circuit 400 comprises a voltage feedback circuit 30 further, voltage feedback circuit 30 couple transformer T the tertiary winding 23, the tertiary winding 23 senses vice-side winding voltage, as output voltage signal V
oUTraise, the induced voltage V on the tertiary winding
talso raise.Induced voltage V
tthrough diode 34 and divider resistance 32,33 dividing potential drop, obtain an output voltage feedback signal V
fB.Output voltage feedback signal V
fBequal
itself and output voltage V
oUTwith the number of turn N of the tertiary winding
tbe directly proportional, with the number of turn N of vice-side winding
sbe inversely proportional to.Meanwhile, the tertiary winding 23 is also for the control circuit of isolated voltage conversion circuit 400 provides a supply power voltage V
cC.
Isolated voltage conversion circuit 400 comprises a voltage control circuit 401 further.Voltage control circuit 401 comprises a voltage error amplifying circuit 41 and the first voltage comparator circuit 42.Voltage error amplifying circuit 41 has first input end, the second input and output.The first input end of voltage error amplifying circuit 41 receives output voltage feedback signal V
fB; Second input of voltage error amplifying circuit 41 receives a reference voltage signal V
rEF; Voltage error amplifying circuit 41 is by output voltage feedback signal V
fBwith reference voltage signal V
rEFerror amplify, and export an error amplification signal COMP at output.First voltage comparator circuit 42 has first input end, the second input and output.The first input end of the first voltage comparator circuit 42 receives error amplification signal COMP; Second input of the first voltage comparator circuit 42 receives a ramp signal V
rAMP; First voltage comparator circuit 42 is by error amplification signal COMP and ramp signal V
rAMPcompare, and export the 4th control signal CA at output.
Isolated voltage conversion circuit 400 comprises a light condition testing circuit 402 further.Light condition testing circuit 402 comprises the voltage error amplifying circuit 41 shared with voltage control circuit 401.Light condition testing circuit 402 comprises the second voltage comparator circuit 43 further, has first input end, the second input and output.The first input end of the second voltage comparator circuit 43 receives error amplification signal COMP; Second input of the second voltage comparator circuit 43 receives a threshold signal V
tH; First voltage comparator circuit 42 is by error amplification signal COMP and threshold signal V
tHcompare, and export light condition detection signal UL at output.
Isolated voltage conversion circuit 400 comprises a mode control circuit 403 further.Mode control circuit 403 has first input end, the second input and output.Its first input end couples the input of voltage control circuit 401, receives the 4th control signal CA; Its second end couples the output of light condition testing circuit 402, receives light condition detection signal UL; Mode control circuit 403 sets the first mode of operation and second mode of operation of isolated voltage conversion circuit 400 according to light condition detection signal UL and the 4th control signal CA, and exports the first control signal CS at output.
Isolated voltage conversion circuit 400 comprises a voltage ripple control circuit 70 further.Voltage ripple control circuit 70 comprises the first electric capacity 72, second electric capacity 73, comparison circuit 77 and reference voltage source 76.Wherein, comparison circuit 77 has first input end, the second input and output; Reference voltage source 76 has first end and the second end.When normally band carries isolated voltage conversion circuit 400, the first electric capacity 72 is connected electrically in the first logic ground potential GND
1with the second logic ground potential GND
2between; Second electric capacity 73 is connected electrically in output voltage signal V
oUTwith the second logic ground potential GND
2between.When normally band carries isolated voltage conversion circuit 400 during underloading, the first electric capacity 72 is connected electrically in the first logic ground potential GND
1with the first input end of comparison circuit 77; Second electric capacity 73 is connected electrically in output voltage signal V
oUTwith the first end of reference voltage source 76; Second end of reference voltage source is electrically connected to the second input of comparison circuit 77; The output of comparison circuit 77 exports the second control signal CV.
In one embodiment, voltage ripple control circuit 70 comprises voltage time delay module 71, first switch 74 and second switch 75 further.Time delay module 71 has input and output, its input receives light condition detection signal UL, time delay module 71 couples of light condition detection signal UL carry out time delay and export a time delayed signal UL ', and wherein time delayed signal UL is effective after isolated voltage conversion circuit 400 enters underloading.First switch 74, has first end a, the second end b, the 3rd end c and control end.Second switch 75, has first end a, the second end b, the 3rd end c and control end.First electric capacity 72 one end is electrically connected the first logic ground potential GND
1, the other end is electrically connected the first end a of the first switch 74; Second end b of the first switch 74 is electrically connected the first input end of comparison circuit 77, and the 3rd end c of the first switch 74 is electrically connected the second logic ground potential GND
2, the control end of the first switch 74 receives described time delayed signal UL '; Second electric capacity 73 one end electrical connection output voltage V
oUT, the first end a of other end electrical connection second switch 75.Second end b of second switch 75 is electrically connected the second input of comparison circuit 77, and the 3rd end c of second switch 75 is electrically connected the second logic ground potential GND
2, the control reception delay signal UL ' of second switch.When normally band carries isolated voltage conversion circuit 400, the first switch 74 first end a respective with second switch 75 is connected with the 3rd end c; When time delayed signal UL ' effectively time, the first switch 74 and second switch 75 respective first end a be connected with the second end b; The output of comparison circuit 77 exports the second control signal CV.
Isolated voltage conversion circuit 400 comprises a logical circuit 80 further.In one embodiment, logical circuit 80 comprise further one or, there is first input end, the second input and output, or the first input end of door receives the first control signal CS, or the second input of door receives the second control signal CV, or goalkeeper first control signal CS and the second control signal CV does logic OR computing and exports the grid of the 3rd control signal CTRL to gate-controlled switch 26 at output, the turn-on and turn-off controlling gate-controlled switch 26 switch.Wherein, when the first control signal CS and any one signal of the second control signal CV are high level, conducting gate-controlled switch 26.
Above-mentioned specification of the present utility model and execution mode are only only exemplary to the isolated voltage conversion circuit of the utility model embodiment and the description of control circuit in an exemplary fashion, and are not used in restriction scope of the present utility model.It is all possible for carrying out changing and revising for disclosed embodiment, other feasible selectivity embodiments and to the equivalent variations of element in embodiment can understand by those skilled in the art.Other changes of embodiment disclosed in the utility model and amendment do not exceed spirit of the present utility model and protection range.
Claims (13)
1. an isolated voltage conversion circuit, comprising:
Energy-storage travelling wave tube, for storage power, have former limit winding, vice-side winding and the tertiary winding, is characterized in that, the described tertiary winding for responding to an output voltage of described voltage conversion circuit, and produces an output voltage induced signal;
Gate-controlled switch, is electrically coupled to described energy-storage travelling wave tube, is switched in described energy-storage travelling wave tube and stores and release energy, and then an input voltage is converted to described output voltage by the turn-on and turn-off of described gate-controlled switch;
Feedback circuit, comprise voltage feedback circuit and there is input and output, the input of described voltage feedback circuit receives described output voltage induced signal, and provides an output voltage feedback signal to characterize described output voltage at the output of described voltage feedback circuit;
Control module, receive described output voltage feedback signal, and produce the first control signal according to described output voltage feedback signal, and judge that described voltage conversion circuit is that underloading or normal band carry according to described output voltage feedback signal, wherein, when described output voltage feedback signal is less than desired value, described first control signal is effective;
Voltage ripple control circuit, when described voltage conversion circuit underloading, described voltage ripple control circuit detects the ripple of output voltage, and voltage ripple signals and first threshold signal is compared, and produces second control signal; Wherein, when described ripple signal is greater than described first threshold signal, described second control signal is effective; And
Logical circuit, there is first input end, the second input and output, described first input end receives described first control signal, described second input receives described second control signal, described logical circuit carries out logical operation to described first control signal and described second control signal, and provides the 3rd control signal to switch for the turn-on and turn-off controlling described gate-controlled switch at output; Wherein, when described first control signal and described any one signal of second control signal effective time, gate-controlled switch described in described 3rd control signal conducting.
2. isolated voltage conversion circuit as claimed in claim 1, it is characterized in that, described voltage conversion circuit at least comprises the first mode of operation and the second mode of operation, wherein, described voltage conversion circuit is normally with when carrying and is operated in the first mode of operation, is operated in the second mode of operation during described voltage conversion circuit underloading; Wherein, when described ripple signal is greater than described first threshold signal, described voltage conversion circuit is jumped out the second mode of operation and is entered the first mode of operation.
3. isolated voltage conversion circuit as claimed in claim 2, is characterized in that, under described second mode of operation, described gate-controlled switch stops turn-on and turn-off switching.
4. isolated voltage conversion circuit as claimed in claim 2, is characterized in that, under described second mode of operation, and described gate-controlled switch turn-on and turn-off switching frequency step-down.
5. isolated voltage conversion circuit as claimed in claim 1, it is characterized in that, described control module comprises:
Voltage control circuit, has first input end and output, and wherein, the first input end of described voltage control circuit is coupled to the output of described voltage feedback circuit, receives described output voltage feedback signal, and provides described first control signal at output; And
Light condition testing circuit, there is input and output, wherein, described input is coupled to described voltage feedback circuit, receive described output voltage feedback signal, judge described voltage conversion circuit whether underloading according to output voltage feedback signal, and provide a light condition detection signal at output; Wherein, when described voltage conversion circuit underloading, described light condition detection signal is effective.
6. isolated voltage conversion circuit as claimed in claim 2, it is characterized in that, described control module comprises:
Voltage control circuit, has input and output, and wherein, described input is coupled to described voltage feedback circuit, receives described output voltage feedback signal, and provides the 4th control signal according to described output voltage feedback signal at output;
Light condition testing circuit, there is input and output, wherein, described input is coupled to described voltage feedback circuit, receive described output voltage feedback signal, and judge described voltage conversion circuit whether underloading according to output voltage feedback signal, and provide a light condition detection signal at output; Wherein, when described voltage conversion circuit underloading, described light condition detection signal is effective; And
Mode control circuit, there is first input end, second input and output, the output that described first input end couples voltage control circuit receives described 4th control signal, the output that described second input couples light condition testing circuit receives described light condition detection signal, described mode control circuit sets described voltage conversion circuit according to described 4th control signal and described light condition detection signal and works in the first mode of operation or the second mode of operation, and provides described first control signal at output.
7. isolated voltage conversion circuit as described in claim 5 or 6, it is characterized in that, described feedback circuit comprises current feedback circuit further, described current feedback circuit has input and output, wherein, the input of described current feedback circuit receives a current sampling signal, and provides a current feedback signal to characterize described current sampling signal at the output of described current feedback circuit;
Wherein, described voltage control circuit comprises the second input further, and the second input of described voltage control circuit is coupled to the output of described current feedback circuit, receives described current feedback signal.
8. isolated voltage conversion circuit as claimed in claim 1, it is characterized in that, described isolated voltage conversion circuit also comprises:
Protective circuit, receives the one or more voltage and/or the current signal that need overvoltage and/or overcurrent protection, and described one or more voltage and/or current signal is compared with respective threshold value, and provide one or more control signal according to comparative result;
Wherein, described one or more control signal and described first control signal and the second control signal are carried out logical operation by described logical circuit, produce described 3rd control signal, and then the turn-on and turn-off controlling described gate-controlled switch switch.
9. isolated voltage conversion circuit as described in claim 5 or 6, is characterized in that, described voltage ripple control circuit comprises:
Voltage ripple detection circuit has first input end, the second input and output, and the first input end of described voltage ripple detection circuit receives described output voltage signal; Second input of described voltage ripple detection circuit receives described light condition detection signal; Described voltage ripple detection circuit, in the described light condition detection signal valid period, provides described voltage ripple signals at output; And
Voltage ripple comparison circuit has first input end, the second input and output, and the first input end of described voltage ripple comparison circuit receives described voltage ripple signals; Second input of described voltage ripple comparison circuit receives described first threshold signal; Described voltage ripple signals and described first threshold signal compare by described voltage ripple comparison circuit, and provide the second control signal at output.
10. isolated voltage conversion circuit as described in claim 5 or 6, is characterized in that, comprises at described voltage ripple control circuit:
Time delay module, there is input and output, its input receives light condition detection signal, and described time delay module carries out time delay to light condition detection signal and exports a time delayed signal, and wherein said time delayed signal is effective after described voltage conversion circuit enters underloading;
Comparison circuit, has first input end, the second input and output;
Reference voltage source, has anode and negative terminal;
First switch, has first end, the second end, the 3rd end and control end;
Second switch, has first end, the second end, the 3rd end and control end;
First electric capacity; And
Second electric capacity;
Wherein, first electric capacity one end electrical connection first logically current potential, the other end is electrically connected the first end of the first switch; The first input end of the second end electrical connection comparison circuit of the first switch, the 3rd end electrical connection second logically current potential of the first switch, the control end of the first switch receives described time delayed signal; Second electric capacity one end electrical connection output voltage, the first end of other end electrical connection second switch; Second input of the second end electrical connection comparison circuit of second switch, the 3rd end electrical connection second logically current potential of second switch, the control end of second switch receives described time delayed signal; When described voltage conversion circuit be normally with carry time, the first switch and second switch first end is separately connected with the 3rd respective end; When described voltage conversion circuit underloading, the first switch and second switch separately first end be connected with the second respective end; The output of described comparison circuit exports described second control signal.
11. isolated voltage conversion circuits as claimed in claim 1, it is characterized in that, described voltage ripple control circuit comprises:
Comparison circuit, has first input end, the second input and output;
Reference voltage source, as first threshold signal, has first end and the second end;
First electric capacity, has first end and the second end, when described voltage conversion circuit be normally with carry time, be connected electrically in the first logically current potential and second logically between current potential; When described voltage conversion circuit underloading, between the first input end being connected electrically in the described first logically current potential and described comparison circuit; And
Second electric capacity, when described voltage conversion circuit be normally with carry time, be connected electrically in the output and described second of described voltage conversion circuit logically between current potential; When described voltage conversion circuit underloading, be connected electrically between the output of described voltage conversion circuit and the first end of described reference voltage source, the second end of described reference voltage source is electrically connected to the second input of described comparison circuit; Wherein, the difference between the first input end of described comparison circuit and the second input is described voltage ripple signals, and the output of described comparison circuit exports described second control signal.
12. isolated voltage conversion circuits as claimed in claim 1, is characterized in that, when described gate-controlled switch conducting, described former limit winding stored energy, the energy that described former limit winding stores when described gate-controlled switch turns off is transferred into load by vice-side winding.
13. 1 kinds of former limit control circuits for isolated voltage conversion circuit, it is characterized in that, described isolated voltage conversion circuit comprises a gate-controlled switch and transformer, described transformer has former limit winding, vice-side winding and the tertiary winding, the wherein said tertiary winding for responding to an output voltage of described voltage conversion circuit, and produces an output voltage induced signal as output voltage feedback signal; Wherein, described control circuit comprises:
Control module, receive described output voltage feedback signal, and produce the first control signal and light condition detection signal according to described output voltage feedback signal, wherein, when described light condition detection signal is effective, described isolated voltage conversion circuit enters light condition, and when described output voltage feedback signal is less than desired value, described first control signal is effective;
Voltage ripple control circuit, receive described light condition detection signal, when described light condition signal is effective, described voltage ripple control circuit detects the ripple of output voltage, and voltage ripple signals and first threshold signal are compared, produce second control signal, wherein, when described ripple signal is greater than described first threshold signal, described second control signal is effective; And
Logical circuit, receive described first control signal and described second control signal, described logical circuit carries out logical operation to described first control signal and described second control signal, and provide one the 3rd to control signal to described gate-controlled switch for controlling the turn-on and turn-off switching of described gate-controlled switch, when described first control signal and described second control signal any one effective time, gate-controlled switch described in described 3rd control signal conducting.
Priority Applications (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
CN201520126388.XU CN204517684U (en) | 2015-03-05 | 2015-03-05 | Isolated voltage conversion circuit and control circuit |
Applications Claiming Priority (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
CN201520126388.XU CN204517684U (en) | 2015-03-05 | 2015-03-05 | Isolated voltage conversion circuit and control circuit |
Publications (1)
Publication Number | Publication Date |
---|---|
CN204517684U true CN204517684U (en) | 2015-07-29 |
Family
ID=53715612
Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
---|---|---|---|
CN201520126388.XU Withdrawn - After Issue CN204517684U (en) | 2015-03-05 | 2015-03-05 | Isolated voltage conversion circuit and control circuit |
Country Status (1)
Country | Link |
---|---|
CN (1) | CN204517684U (en) |
Cited By (4)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN104682745A (en) * | 2015-03-05 | 2015-06-03 | 成都芯源系统有限公司 | Isolated voltage conversion circuit, control circuit and control method thereof |
CN105591540A (en) * | 2015-11-16 | 2016-05-18 | 浙江凯耀照明股份有限公司 | Auxiliary direct current low-voltage power supply circuit applicable to switch power supply |
WO2017107267A1 (en) * | 2015-12-21 | 2017-06-29 | 深圳市华星光电技术有限公司 | Feedback control circuit and power management module |
CN107171533A (en) * | 2016-03-07 | 2017-09-15 | 精工半导体有限公司 | Switching regulaor |
-
2015
- 2015-03-05 CN CN201520126388.XU patent/CN204517684U/en not_active Withdrawn - After Issue
Cited By (7)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN104682745A (en) * | 2015-03-05 | 2015-06-03 | 成都芯源系统有限公司 | Isolated voltage conversion circuit, control circuit and control method thereof |
CN104682745B (en) * | 2015-03-05 | 2017-07-28 | 成都芯源系统有限公司 | Isolated voltage conversion circuit, control circuit and control method thereof |
CN105591540A (en) * | 2015-11-16 | 2016-05-18 | 浙江凯耀照明股份有限公司 | Auxiliary direct current low-voltage power supply circuit applicable to switch power supply |
WO2017107267A1 (en) * | 2015-12-21 | 2017-06-29 | 深圳市华星光电技术有限公司 | Feedback control circuit and power management module |
US10141840B2 (en) | 2015-12-21 | 2018-11-27 | Shenzhen China Star Optoelectronics Co., Ltd | Feedback control circuit and power management module shortening feedback response time |
CN107171533A (en) * | 2016-03-07 | 2017-09-15 | 精工半导体有限公司 | Switching regulaor |
CN107171533B (en) * | 2016-03-07 | 2020-03-27 | 艾普凌科有限公司 | Switching regulator |
Similar Documents
Publication | Publication Date | Title |
---|---|---|
CN104682745A (en) | Isolated voltage conversion circuit, control circuit and control method thereof | |
CN102957303B (en) | Control circuit, switch converter and control method thereof | |
Feng et al. | Optimal trajectory control of burst mode for LLC resonant converter | |
CN101925236B (en) | Isolated high-power factor flyback type primary-side constant-current control device of LED driver | |
CN101925237B (en) | Primary constant-current control device of isolated type flyback converter | |
CN104218806B (en) | Method and circuit for controlling fly-back switching power supplies of zero-voltageswitching | |
CN101877922B (en) | Non-isolated AC-DC (Alternating Current-Direct Current) LED driver current compensation circuit | |
CN202435294U (en) | Pulse width modulation switch power supply controller and switch power supply | |
CN109713889B (en) | Power factor correction circuit and control method thereof | |
CN101989818A (en) | Two-stage exchange type power switching circuit | |
CN204517684U (en) | Isolated voltage conversion circuit and control circuit | |
CN202652059U (en) | Power factor correction control circuit and power factor correction device comprising the same | |
CN202424552U (en) | Voltage reduction type voltage-stabilizing and rectifying circuit | |
CN103973138A (en) | Dynamic variable-frequency power conversion system | |
CN104702095A (en) | Switching power supply controller and switching power supply comprising switching power supply controller | |
CN202997938U (en) | A high power factor constant current drive circuit and a high power factor constant current device | |
Chuang et al. | A novel single-switch resonant power converter for renewable energy generation applications | |
CN101834527B (en) | Two-stage switching power supply conversion circuit | |
CN204442169U (en) | Switch power controller and comprise the Switching Power Supply of this switch power controller | |
CN104283420A (en) | Voltage conversion controller with voltage drop compensation function and voltage conversion circuit | |
CN202997942U (en) | Switching power supply controller and switching power supply containing same | |
CN201733501U (en) | Primary-side constant-current control device of LED driver | |
CN205490142U (en) | Switched inductor boost converter | |
CN204886731U (en) | Switching power supply controller and contain switching power supply of this switching power supply controller | |
CN204376711U (en) | Step-up and step-down switch power converter, control circuit and mode switching control unit |
Legal Events
Date | Code | Title | Description |
---|---|---|---|
C14 | Grant of patent or utility model | ||
GR01 | Patent grant | ||
AV01 | Patent right actively abandoned |
Granted publication date: 20150729 Effective date of abandoning: 20170728 |
|
AV01 | Patent right actively abandoned |