CN203617902U - Integrated buck-flyback type high power factor constant current circuit and device - Google Patents

Integrated buck-flyback type high power factor constant current circuit and device Download PDF

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Publication number
CN203617902U
CN203617902U CN201320804625.4U CN201320804625U CN203617902U CN 203617902 U CN203617902 U CN 203617902U CN 201320804625 U CN201320804625 U CN 201320804625U CN 203617902 U CN203617902 U CN 203617902U
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China
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connects
diode
circuit
winding
switching tube
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CN201320804625.4U
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谢小高
叶美盼
汪丞辉
蔡拥军
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Hangzhou Silan Microelectronics Co Ltd
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Hangzhou Silan Microelectronics Co Ltd
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    • YGENERAL 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
    • Y02TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
    • Y02BCLIMATE CHANGE MITIGATION TECHNOLOGIES RELATED TO BUILDINGS, e.g. HOUSING, HOUSE APPLIANCES OR RELATED END-USER APPLICATIONS
    • Y02B70/00Technologies for an efficient end-user side electric power management and consumption
    • Y02B70/10Technologies 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
    • YGENERAL 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
    • Y02TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
    • Y02PCLIMATE CHANGE MITIGATION TECHNOLOGIES IN THE PRODUCTION OR PROCESSING OF GOODS
    • Y02P80/00Climate change mitigation technologies for sector-wide applications
    • Y02P80/10Efficient use of energy, e.g. using compressed air or pressurized fluid as energy carrier

Abstract

The utility model provides an integrated buck-flyback type high power factor constant current circuit and an integrated buck-flyback type high power factor constant current device. The circuit comprises a pre-stage circuit and a post-stage circuit which are coupled with each other, wherein the pre-stage circuit is a buck circuit used for realizing power factor correction; the post-stage circuit is a flyback type converting circuit used for realizing DC-to-DC conversion; and the pre-stage circuit and the post-stage circuit share a same switching tube and a bus capacitor. The device comprises the integrated buck-flyback type high power factor constant current circuit and a constant current control driving circuit, wherein a current sampling end of the constant current control driving circuit acquires the current information of a sampling resistor, the constant current control driving circuit generates driving signals according to the current information of the sampling resistor, and the driving signals are transmitted to a control end of the switching tube. According to the integrated buck-flyback type high power factor constant current circuit and the integrated buck-flyback type high power factor constant current device, the output ripple current can be reduced, and the circuit cost can be decreased.

Description

Integrated step-down-inverse-excitation type constant current circuit with high power factor and device
Technical field
The utility model relates to switch power technology, relates in particular to a kind of integrated step-down-inverse-excitation type constant current circuit with high power factor and device.
Background technology
At present, most of power consumption equipments are in the time of access electrical network, and input AC electric current cannot be sinusoidal variations with input voltage waveform, thereby current waveform distortion is serious, exist power factor (PF) very low, harmonic wave serious interference, even the impact problem of the normal work of other power consumption equipment around.International Electrotechnical Commission (IEC) has formulated the standard of IEC61000-3-2 harmonic current restriction, the adverse effect that may cause in order to limit humorous wave interference.Meanwhile, for the fail safe of guarantor in the time using power consumption equipment, most of A.C.-D.C. converter all requires to adopt isolated power stage design, thereby needs to adopt optocoupler or other isolating device to realize the isolation of control circuit, will inevitably increase like this cost and the complexity of control circuit.
In order to solve the problem of low power factor, single-stage or two stage power factor correcting (PFC) circuit engineering have been widely used in AC-DC power inverter.
With respect to single-level power factor correction technology, it is little that two stage power factor correcting technology has output ripple, and the feature that power factor is high is widely used in circuit of power factor correction, and its basic theory diagram as shown in Figure 1.Input ac voltage is input to first order power factor correcting converter 101 after rectifier bridge rectification, first order power factor correcting converter 101 is conventional to realize Active Power Factor Correction, common topology is boosted (Boost), buck (Buck-boost) and step-down (Buck) structure.Because input current will be followed the wave form varies of input voltage, thereby input power is the power of pulsation, therefore conventionally there is a jumbo storage capacitor C between first order power factor correcting converter 101 and second level DC-DC converter 102 bulk, the ac input power of pulsing in order to balance and stably DC output power.Second level DC-DC converter 102 can realize effectively adjustment to the voltage of output or electric current.
But because the scheme shown in Fig. 1 exists two stage power circuit, control circuit also needs corresponding two parts, thereby has increased the complexity of circuit, and cost is relatively high, and loss is larger.
The single-stage power factor correcting circuit of another kind of prior art as shown in Figure 2.Wherein, interchange input source connects two inputs of rectifier bridge 201, the positive output termination capacitor C of rectifier bridge 201 infirst end and the former limit winding W of transformer T psame Name of Ends, the former limit winding W of transformer T pdifferent name termination switching tube Q 1drain electrode, switching tube Q 1source electrode meet sampling resistor R senfirst end, sampling resistor R senthe second ground, the former limit of termination, the negative output termination capacitor C of rectifier bridge 201 inthe second end and receive ground, former limit simultaneously, the first input end of secondary current analog module 202 meets sampling resistor R senfirst end, the auxiliary winding W of the second input termination transformer T of secondary current analog module 202 adifferent name end, the output termination PFC of secondary current analog module 202 controls and the first input end of driver module 203, PFC controls and second the inputting termination transformer and assist winding W of driver module 203 adifferent name end, PFC controls and the output termination switching tube Q of driver module 203 1grid.In Fig. 2, secondary current analog module 202 is by sampling resistor R senobtain former limit switching current information, and simulate secondary current information, then send into PFC and control and driver module 203, carry out control switch pipe Q with the driving signal that produces adjustable output constant current and PFC control 1thereby, in single-stage translation circuit, realized input power factor correction and output constant current.
Adopt single-stage power factor correcting circuit technology, need in guaranteeing stable output DC signal, realize High Power Factor.Adopt in this way, simplified the complexity of power circuit structure and control circuit, transducer effciency density is high, and cost is low, but has the shortcomings such as output current ripple is larger.
Utility model content
The technical problems to be solved in the utility model is to provide a kind of integrated step-down-inverse-excitation type constant current circuit with high power factor and device, prime is reduction voltage circuit, rear class is inverse-excitation type translation circuit, two stage power circuit shares a power tube and bus capacitor, can realize the constant current control to output current by Direct Sampling primary current, be conducive to reduce circuit cost.
For solving the problems of the technologies described above, the utility model provides a kind of integrated step-down-inverse-excitation type constant current circuit with high power factor, comprises the front stage circuits and the late-class circuit that intercouple, wherein,
This front stage circuits is the reduction voltage circuit for realizing power factor correction;
This late-class circuit is the inverse-excitation type translation circuit for realizing DC-dc conversion;
Wherein, this front stage circuits and late-class circuit share same switching tube and bus capacitor.
According to an embodiment of the present utility model, described front stage circuits comprises:
Input capacitance, its first end connects positive input terminal, and its second end connects negative input end;
Described switching tube, its first power end connects the first end of described input capacitance, and its control end receives outside driving signal;
The second diode, the second end of input capacitance described in its anodic bonding;
The 3rd diode, the second power end coupling of its anode and described switching tube, its negative electrode connects the negative electrode of described the second diode;
Described bus capacitor, its first end connects the negative electrode of described the 3rd diode and the negative electrode of the second diode;
Inductance, its first end connects the second end of described input capacitance, and its second end connects the second end of described bus capacitor;
Described late-class circuit comprises:
Described bus capacitor;
Described switching tube;
The first diode, its negative electrode connects the first power end of described switching tube, the first end of bus capacitor described in its anodic bonding;
Sampling resistor, the second power end coupling of its first end and described switching tube;
Transformer, the different name end of its former limit winding connects the second end of described sampling resistor, and the Same Name of Ends of its former limit winding connects the second end of described bus capacitor;
Output diode, the Same Name of Ends of the secondary winding of transformer described in its anodic bonding, the different name end of its negative electrode and this secondary winding is as load access interface.
According to an embodiment of the present utility model, described late-class circuit also comprises:
Output loading, its first end connects the negative electrode of described output diode, and its second end connects the different name end of the secondary winding of described transformer, and described output loading is output capacitance, load or output capacitance and any one in load in parallel.
According to an embodiment of the present utility model, when described switching tube conducting, the signal circuit of described front stage circuits is: the signal of described positive input terminal is via described switching tube, the 3rd diode, bus capacitor and inductive transmission to described negative input end, and the signal circuit of described late-class circuit is: the signal of the first end of described bus capacitor transfers to the second end of described bus capacitor via described the first diode, switching tube, sampling resistor, former limit winding; When described switching tube turn-offs, the signal circuit of described front stage circuits is: the electric current of the described inductance of flowing through is back to described inductance via described the second diode and bus capacitor afterflow; The signal circuit of described late-class circuit is: the electric current of the described secondary winding of flowing through is back to described secondary winding via described output diode and output loading afterflow.
According to an embodiment of the present utility model, described front stage circuits comprises:
Input capacitance, its first end connects positive input terminal, and its second end connects negative input end;
Described switching tube, its first power end connects the first end of described input capacitance, and its control end receives outside driving signal;
The second diode, the second end of input capacitance described in its anodic bonding;
The 3rd diode, the second power end coupling of its anode and described switching tube, its negative electrode connects the negative electrode of described the second diode;
Described bus capacitor, its first end connects the negative electrode of described the 3rd diode and the negative electrode of the second diode;
Inductance, its first end connects the second end of described input capacitance, and its second end connects the second end of described bus capacitor;
Described late-class circuit comprises:
Described bus capacitor;
Described switching tube;
The first diode, its negative electrode connects the first power end of described switching tube, the first end of bus capacitor described in its anodic bonding;
Sampling resistor, the second power end coupling of its first end and described switching tube;
Transformer, the different name end of its former limit winding connects the second end of described sampling resistor, and the Same Name of Ends of its former limit winding connects the second end of described bus capacitor;
Output diode, the Same Name of Ends of the former limit winding of transformer described in its anodic bonding, the different name end of its negative electrode and this former limit winding is as load access interface.
According to an embodiment of the present utility model, described late-class circuit also comprises:
Output loading, its first end connects the different name end of the former limit winding of described transformer, and its second end connects the negative electrode of described output diode, and described output loading is output capacitance, load or output capacitance and any one in load in parallel.
According to an embodiment of the present utility model, when described switching tube conducting, the signal circuit of described front stage circuits is: the signal of described positive input terminal is via described switching tube, the 3rd diode, bus capacitor and inductive transmission to described negative input end, and the signal circuit of described late-class circuit is: the signal of the first end of described bus capacitor transfers to the second end of described bus capacitor via described the first diode, switching tube, sampling resistor, former limit winding; When described switching tube turn-offs, the signal circuit of described front stage circuits is: the electric current of the described inductance of flowing through is back to described inductance via described the second diode and bus capacitor afterflow; The signal circuit of described late-class circuit is: the electric current of the described former limit winding of flowing through is back to described former limit winding via described output diode and output loading afterflow.
According to an embodiment of the present utility model, described front stage circuits comprises:
Input capacitance, its first end connects positive input terminal, and its second end connects negative input end;
Described switching tube, its first power end connects the first end of described input capacitance, and its control end receives outside driving signal;
The 3rd diode, the second power end coupling of its anode and described switching tube;
The second diode, its negative electrode connects the negative electrode of described the 3rd diode;
Inductance, comprise the first winding and second winding of coupling, the different name end of this first winding connects the second end of described input capacitance, and the Same Name of Ends of this second winding connects the Same Name of Ends of described the first winding, and the different name end of this second winding connects the anode of described the second diode;
Described bus capacitor, its first end connects the negative electrode of described the 3rd diode and the negative electrode of the second diode, and its second end connects the Same Name of Ends of described the first winding and the second winding;
Described late-class circuit comprises:
Described bus capacitor;
Described switching tube;
The first diode, its negative electrode connects the first power end of described switching tube, the first end of bus capacitor described in its anodic bonding;
Sampling resistor, the second power end coupling of its first end and described switching tube;
Transformer, the different name end of its former limit winding connects the second end of described sampling resistor, and the Same Name of Ends of its former limit winding connects the second end of described bus capacitor;
Output diode, the Same Name of Ends of the secondary winding of transformer described in its anodic bonding, the different name end of its negative electrode and this secondary winding is as load access interface.
According to an embodiment of the present utility model, described late-class circuit also comprises:
Output loading, its first end connects the negative electrode of described output diode, and its second end connects the different name end of described secondary winding, and described output loading is output capacitance, load or output capacitance and any one in load in parallel.
According to an embodiment of the present utility model, when described switching tube conducting, the signal circuit of described front stage circuits is: the signal of described positive input terminal transfers to described negative input end via the first winding of described switching tube, the 3rd diode, bus capacitor and inductance, and the signal circuit of described late-class circuit is: the signal of the first end of described bus capacitor transfers to the second end of described bus capacitor via described the first diode, switching tube, sampling resistor, former limit winding; When described switching tube turn-offs, the signal circuit of described front stage circuits is: the electric current of the second winding of the described inductance of flowing through is back to described the second winding via described the second diode and bus capacitor afterflow; The signal circuit of described late-class circuit is: the electric current of the secondary winding of the described transformer of flowing through is back to described secondary winding via described output diode and output loading afterflow.
According to an embodiment of the present utility model, described front stage circuits comprises:
Input capacitance, its first end connects positive input terminal, and its second end connects negative input end;
Described switching tube, its first power end connects the first end of described input capacitance, and its control end receives outside driving signal;
The 3rd diode, the second power end coupling of its anode and described switching tube;
The second diode, its negative electrode connects the negative electrode of described the 3rd diode;
Inductance, comprise the first winding and second winding of coupling, the different name end of this first winding connects the second end of described input capacitance, and the Same Name of Ends of this second winding connects the Same Name of Ends of described the first winding, and the different name end of this second winding connects the anode of described the second diode;
Described bus capacitor, its first end connects the negative electrode of described the 3rd diode and the negative electrode of the second diode, and its second end connects the Same Name of Ends of described the first winding and the second winding;
Described late-class circuit comprises:
Described bus capacitor;
Described switching tube;
The first diode, its negative electrode connects the first power end of described switching tube, the first end of bus capacitor described in its anodic bonding;
Sampling resistor, the second power end coupling of its first end and described switching tube;
Transformer, the different name end of its former limit winding connects the second end of described sampling resistor, and the Same Name of Ends of its former limit winding connects the second end of described bus capacitor;
Output diode, the Same Name of Ends of the former limit winding of transformer described in its anodic bonding, the different name end of its negative electrode and this former limit winding is as load access interface.
According to an embodiment of the present utility model, described late-class circuit also comprises:
Output loading, its first end connects the different name end of described former limit winding, and its second end connects the negative electrode of described output diode, and described output loading is output capacitance, load or output capacitance and any one in load in parallel.
According to an embodiment of the present utility model, when described switching tube conducting, the signal circuit of described front stage circuits is: the signal of described positive input terminal transfers to described negative input end via the first winding of described switching tube, the 3rd diode, bus capacitor and inductance, and the signal circuit of described late-class circuit is: the signal of the first end of described bus capacitor transfers to the second end of described bus capacitor via described the first diode, switching tube, sampling resistor, former limit winding; When described switching tube turn-offs, the signal circuit of described front stage circuits is: the electric current of the second winding of the described inductance of flowing through is back to described the second winding via described the second diode and bus capacitor afterflow; The signal circuit of described late-class circuit is: the electric current of the former limit winding of the described transformer of flowing through is back to described former limit winding via described output diode and output loading afterflow.
According to an embodiment of the present utility model, described front stage circuits and late-class circuit also comprise peak value current-limiting resistance, described the 3rd anode of diode and the first end of described sampling resistor are connected with the second power end of described switching tube via described peak value current-limiting resistance, the first end of this peak value current-limiting resistance connects the second power end of described switching tube, and the second end of this peak value current-limiting resistance connects the anode of described the 3rd diode.
According to an embodiment of the present utility model, described front stage circuits comprises:
Input capacitance, its first end connects positive input terminal, and its second end connects negative input end;
The first diode, its negative electrode connects the first end of described input capacitance;
The 3rd diode, the anode of the first diode described in its anodic bonding;
Inductance, its first end connects the first end of described input capacitance;
Described bus capacitor, its first end connects the second end of described inductance, and its second end connects the anode of described the first diode and the 3rd diode;
Described switching tube, its first power end connects the negative electrode of described the 3rd diode, the second end coupling of its second power end and described input capacitance, its control end receives outside driving signal;
Described late-class circuit comprises:
Described bus capacitor;
Described switching tube;
The second diode, its negative electrode connects the second end of described bus capacitor;
Sampling resistor, the anode of its first end and described the second diode, the second power end coupling of its second end and described switching tube;
Transformer, the different name end of its former limit winding connects the first end of described bus capacitor, and the Same Name of Ends of its former limit winding connects the first power end of described switching tube;
Output diode, the Same Name of Ends of the secondary winding of transformer described in its anodic bonding, the different name end of its negative electrode and this secondary winding is as load access interface.
According to an embodiment of the present utility model, described late-class circuit also comprises:
Output loading, its first end connects the negative electrode of described output diode, and its second end connects the different name end of described secondary winding, and described output loading is output capacitance, load or output capacitance and any one in load in parallel.
According to an embodiment of the present utility model, when described switching tube conducting, the signal circuit of described front stage circuits is: the signal of described positive input terminal transfers to described negative input end via described inductance, bus capacitor, the 3rd diode and switching tube, and the signal circuit of described late-class circuit is: the signal of the first end of described bus capacitor transfers to the second end of described bus capacitor via described former limit winding, switching tube, sampling resistor and the second diode; When described switching tube turn-offs, the signal circuit of described front stage circuits is: the electric current of the described inductance of flowing through is back to described inductance via described the first diode and bus capacitor afterflow; The signal circuit of described late-class circuit is: the electric current of the secondary winding of the described transformer of flowing through is back to described former limit winding via described output diode and output loading afterflow.
According to an embodiment of the present utility model, described front stage circuits comprises:
Input capacitance, its first end connects positive input terminal, and its second end connects negative input end;
The first diode, its negative electrode connects the first end of described input capacitance;
The 3rd diode, the anode of the first diode described in its anodic bonding;
Inductance, its first end connects the first end of described input capacitance;
Described bus capacitor, its first end connects the second end of described inductance, and its second end connects the anode of described the first diode and the 3rd diode;
Described switching tube, its first power end connects the negative electrode of described the 3rd diode, the second end coupling of its second power end and described input capacitance, its control end receives outside driving signal;
Described late-class circuit comprises:
Described bus capacitor;
Described switching tube;
The second diode, its negative electrode connects the second end of described bus capacitor;
Sampling resistor, the anode of its first end and described the second diode, the second power end coupling of its second end and described switching tube;
Transformer, the different name end of its former limit winding connects the first end of described bus capacitor, and the Same Name of Ends of its former limit winding connects the first power end of described switching tube;
Output diode, the Same Name of Ends of the former limit winding of transformer described in its anodic bonding, the different name end of its negative electrode and this former limit winding is as load access interface.
According to an embodiment of the present utility model, described late-class circuit also comprises:
Output loading, its first end connects the negative electrode of described output diode, and its second end connects the different name end of described secondary winding, and described output loading is output capacitance, load or output capacitance and any one in load in parallel.
According to an embodiment of the present utility model, when described switching tube conducting, the signal circuit of described front stage circuits is: the signal of described positive input terminal transfers to described negative input end via described inductance, bus capacitor, the 3rd diode and switching tube, and the signal circuit of described late-class circuit is: the signal of the first end of described bus capacitor transfers to the second end of described bus capacitor via described former limit winding, switching tube, sampling resistor and the second diode; When described switching tube turn-offs, the signal circuit of described front stage circuits is: the electric current of the described inductance of flowing through is back to described inductance via described the first diode and bus capacitor afterflow; The signal circuit of described late-class circuit is: the electric current of the former limit winding of the described transformer of flowing through is back to described former limit winding via described output diode and output loading afterflow.
According to an embodiment of the present utility model, described front stage circuits and late-class circuit also comprise peak value current-limiting resistance, the second end of described sampling resistor and the second end of described input capacitance are connected with the second power end of described switching tube via this peak value current-limiting resistance, the first end of this peak value current-limiting resistance connects the second end of described input capacitance and the second end of described sampling resistor, and the second end of this peak value current-limiting resistance connects the second power end of described switching tube.
According to an embodiment of the present utility model, described front stage circuits at least also comprises input capacitance and inductance, and described late-class circuit at least also comprises transformer and output loading, and this output loading is output capacitance, load or output capacitance and any one in load in parallel, wherein
Described switching tube conduction period, described input capacitance, inductance and switching tube form the first loop, and the former limit winding of described bus capacitor, switching tube, transformer forms second servo loop;
Described switching tube blocking interval, described inductance, bus capacitor form tertiary circuit, and the former limit winding of described transformer or secondary winding and this output loading form the 4th loop.
According to an embodiment of the present utility model, described switching tube conduction period, the voltage that the voltage at described inductance two ends equals described input capacitance two ends deducts the voltage at described bus capacitor two ends, the flow through Current rise of described inductance, the voltage at the winding two ends, former limit of described transformer equals the voltage at described bus capacitor two ends, the Current rise of the described transformer primary side winding of flowing through; Described switching tube blocking interval, the voltage at the described bus capacitor two ends that the voltage at described inductance two ends equals to bear, flow through described inductance electric current decline, the voltage at the described output loading two ends that the voltage at the former limit winding of described transformer or secondary winding two ends equals to bear, the electric current of described the second inductance of flowing through declines.
According to an embodiment of the present utility model, this circuit also comprises: rectifier bridge, and to the ac supply signal rectification of input, its positive output end connects described positive input terminal, and its negative output terminal connects described negative input end.
According to an embodiment of the present utility model, described switching tube is power MOSFET, the drain electrode that described the first power end is described mosfet transistor, the source electrode that described the second power end is described mosfet transistor, the grid that described control end is described mosfet transistor.
According to an embodiment of the present utility model, described switching tube is pliotron, the collector electrode that described the first power end is described pliotron, the emitter that described the second power end is described pliotron, the base stage that described control end is described pliotron.
According to an embodiment of the present utility model, described switching tube is unit switch.
The utility model also provides a kind of integrated step-down-inverse-excitation type high power factor constant current device, comprising:
Integrated step-down-inverse-excitation type constant current circuit with high power factor described in above-mentioned any one;
Constant-current control drive circuit, its current sample end sampling obtains the current information of described sampling resistor, and described in it, constant-current control drive circuit produces and drives signal according to the current information of described sampling resistor, and described driving signal transfers to the control end of described switching tube.
According to an embodiment of the present utility model, the current sample end of described constant-current control drive circuit connects the first end of described sampling resistor, the second ground, the former limit of termination of described sampling resistor; Or the current sample end of described constant-current control drive circuit connects the second end of described sampling resistor, the first ground, the former limit of termination of described sampling resistor.
According to an embodiment of the present utility model, described constant-current control drive circuit also has zero passage detection end, this zero passage detection end obtains the ON time information of described output diode, and described constant-current control drive circuit produces this driving signal according to described current information and ON time information.
According to an embodiment of the present utility model, described transformer also comprises auxiliary winding, the ground, the former limit of different name termination of the auxiliary winding of described transformer, and the Same Name of Ends of the auxiliary winding of described transformer connects the zero passage detection end of described constant-current control drive circuit.
According to an embodiment of the present utility model, described integrated step-down-inverse-excitation type constant current circuit with high power factor is the circuit described in claim 10 or 15, described constant-current control drive circuit also has peak current current limliting end, this peak current current limliting end is connected to obtain peak current information with the first end of described peak value current-limiting resistance, described constant-current control drive circuit produces described driving signal according to described current information and peak current information.
Compared with prior art, the utlity model has following advantage:
Integrated step-down-inverse-excitation type high power factor circuit of the utility model embodiment single step arrangement that is as the criterion, compares two-stage type structure, and circuit structure is simpler, is conducive to circuit cost; Compare single stage type structure, greatly reduce the ripple current of output loading, without stroboscopic.
In addition, the front stage circuits of integrated step-down-inverse-excitation type high power factor circuit of the utility model embodiment is to realize the reduction voltage circuit of power factor emendation function, compare other topologys and can obtain more high power, late-class circuit is the inverse-excitation type translation circuit of realizing DC-dc conversion, two stage power circuit shares a power switch pipe and a set of control circuit, can only realize the constant current control (former limit FEEDBACK CONTROL) to output current by the primary current of sampling transformer, be conducive to further reduce circuit arrangement cost.
Accompanying drawing explanation
Fig. 1 is the theory diagram of a kind of AC-DC power inverter that adopts two stage power factor correcting technology in prior art;
Fig. 2 is the theory diagram of a kind of single-stage power factor correcting circuit of former limit constant current in prior art;
Fig. 3 is the theory diagram of integrated step-down-inverse-excitation type high power factor constant current device of the present utility model the first embodiment;
Fig. 4 is the schematic equivalent circuit of integrated step-down-inverse-excitation type high power factor constant current device shown in Fig. 3 under the first operating state;
Fig. 5 is the schematic equivalent circuit of integrated step-down-inverse-excitation type high power factor constant current device shown in Fig. 3 under the second operating state;
Fig. 6 is the theory diagram of integrated step-down-inverse-excitation type high power factor constant current device of the present utility model the second embodiment;
Fig. 7 is the schematic equivalent circuit of integrated step-down-inverse-excitation type high power factor constant current device shown in Fig. 6 under the first operating state;
Fig. 8 is the schematic equivalent circuit of integrated step-down-inverse-excitation type high power factor constant current device shown in Fig. 6 under the second operating state;
Fig. 9 is the theory diagram of integrated step-down-inverse-excitation type high power factor constant current device of the present utility model the 3rd embodiment;
Figure 10 is the schematic equivalent circuit of integrated step-down-inverse-excitation type high power factor constant current device shown in Fig. 9 under the first operating state;
Figure 11 is the schematic equivalent circuit of integrated step-down-inverse-excitation type high power factor constant current device shown in Fig. 9 under the second operating state;
Figure 12 is the theory diagram of integrated step-down-inverse-excitation type high power factor constant current device of the present utility model the 4th embodiment;
Figure 13 is the schematic equivalent circuit of integrated step-down-inverse-excitation type high power factor constant current device shown in Figure 12 under the first operating state;
Figure 14 is the schematic equivalent circuit of integrated step-down-inverse-excitation type high power factor constant current device shown in Figure 12 under the second operating state;
Figure 15 is the theory diagram of integrated step-down-inverse-excitation type high power factor constant current device of the present utility model the 5th embodiment;
Figure 16 is the schematic equivalent circuit of integrated step-down-inverse-excitation type high power factor constant current device shown in Figure 15 under the first operating state;
Figure 17 is the schematic equivalent circuit of integrated step-down-inverse-excitation type high power factor constant current device shown in Figure 15 under the second operating state;
Figure 18 is the theory diagram of integrated step-down-inverse-excitation type high power factor constant current device of the present utility model the 6th embodiment;
Figure 19 is the schematic equivalent circuit of integrated step-down-inverse-excitation type high power factor constant current device shown in Figure 18 under the first operating state;
Figure 20 is the schematic equivalent circuit of integrated step-down-inverse-excitation type high power factor constant current device shown in Figure 18 under the second operating state.
Embodiment
Integrated step-down-inverse-excitation type constant current circuit with high power factor of the present utility model comprises the front stage circuits and the late-class circuit that intercouple, this front stage circuits is the reduction voltage circuit for realizing power factor correction, this late-class circuit is the inverse-excitation type translation circuit for realizing DC-dc conversion, and this front stage circuits and late-class circuit share same switching tube and bus capacitor.Compare two-stage type structure, circuit structure is simpler, is conducive to circuit cost; Compare single stage type structure, greatly reduce the ripple current of output loading, without stroboscopic.
Wherein, front stage circuits can comprise switching tube, bus capacitor, input capacitance and inductance, late-class circuit can comprise switching tube, bus capacitor, transformer and output loading, this output loading is output capacitance, load or output capacitance and any one in load in parallel, wherein, switching tube conduction period, input capacitance, inductance and switching tube form the first loop, and the former limit winding of bus capacitor, switching tube, transformer forms second servo loop; Switching tube blocking interval, inductance, bus capacitor form tertiary circuit, and the former limit winding of transformer or secondary winding and this output loading form the 4th loop.
Furthermore, switching tube conduction period, the voltage that the voltage at inductance two ends equals input capacitance two ends deducts the voltage at bus capacitor two ends, the flow through Current rise of inductance, the voltage at the winding two ends, former limit of transformer equals the voltage at bus capacitor two ends, the Current rise of the transformer primary side winding of flowing through; Switching tube blocking interval, the voltage at inductance two ends equals the voltage at negative bus capacitor two ends, the electric current of inductance of flowing through declines, and the voltage at the former limit winding of transformer or secondary winding two ends equals the voltage at negative output loading two ends, and the electric current of second inductance of flowing through declines.
Below in conjunction with specific embodiments and the drawings, the utility model is described in further detail, but should not limit protection range of the present utility model with this.
The first embodiment
With reference to figure 3, Fig. 3 shows integrated step-down-inverse-excitation type high power factor constant current device of the first embodiment, comprises integrated step-down-inverse-excitation type constant current circuit with high power factor and coupled constant current Drive and Control Circuit 301.
Wherein, integrated step-down-inverse-excitation type constant current circuit with high power factor comprises rectifier bridge BR, input capacitance C in, the first diode D 1, the second diode D 2, the 3rd diode D 3, inductance L b, transformer T, switching tube Q 1, peak value current-limiting resistance R lim, sampling resistor R s, bus capacitor C bulk, output diode D 4and output capacitance C o.Wherein, rectifier bridge BR, input capacitance C in, switching tube Q 1, resistance R lim, the second diode D 2, the 3rd diode D 3, inductance L bwith bus capacitor C bulkform front stage circuits, bus capacitor C bulk, the first diode D 1, switching tube Q 1, resistance R lim, sampling resistor R s, transformer T, output diode D 4and output capacitance C oform late-class circuit.Bus capacitor C bulk, switching tube Q 1and peak value current-limiting resistance R limfor the multiplex element of two-stage circuit.
Furthermore, the input termination ac supply signal Vac of rectifier bridge BR it is carried out to rectification, input capacitance C infirst end connect the positive output end of rectifier bridge BR, input capacitance C inthe second end connect the negative output terminal of rectifier bridge BR, the first diode D 1negative electrode connect input capacitance C infirst end, the second diode D 2negative electrode meet the first diode D 1anode, the second diode D 2anode and input capacitance C inthe second end coupling, switching tube Q 1the first power end connect the first diode D 1negative electrode, its control end receives outside driving signal, peak value current-limiting resistance R limfirst end connecting valve pipe Q 1the second power end, resistance R limthe second end connect sampling resistor R sfirst end; The 3rd diode D 3anodic bonding switching tube Q 1the second power end, bus capacitor C bulkthe first termination the 3rd diode D 3negative electrode and the first diode D 1anode, inductance L bfirst end connect input capacitance C inthe second end; The former limit winding W of transformer T pdifferent name end and sampling resistor R sthe second end be connected, the former limit winding W of transformer T psame Name of Ends and inductance L bthe second end and bus capacitor C bulkthe second end be connected, the secondary winding W of transformer T stermination output diode D of the same name 4anode, output diode D 4negative electrode meet output capacitance C ofirst end, the secondary winding W of transformer T sdifferent name termination output capacitance C othe second end, load and output capacitance C oparallel connection, load and output capacitance C ocan be collectively referred to as output loading.Certainly, output loading also can only comprise load or output capacitance C o.
In the first embodiment, the peak current current limliting end I of constant-current control drive circuit 301 limconnecting resistance R limfirst end, the current sample end CS of constant-current control drive circuit 301 connects sampling resistor R sfirst end, the ground end SGND of constant-current control drive circuit 301 meets sampling resistor R sthe second end and receive ground, former limit, the zero passage detection end ZCD of constant-current control drive circuit 301 meets the auxiliary winding W of transformer T asame Name of Ends, the auxiliary winding W of transformer T aground, the former limit of different name termination, the output PWM of constant-current control drive circuit 301 meets switching tube Q 1control end.
The sampling resistor R that constant-current control drive circuit 301 samples according to current sample end CS scurrent information and the output diode D that detects of zero passage detection end ZCD 4oN time information (or perhaps current over-zero information) produce and drive signal, this driving signal is for control switch pipe Q 1periodically conducting and cut-off are to realize output load current constant current.In the time that integrated step-down-inverse-excitation type constant current circuit with high power factor powers on, due to bus capacitor C bulkboth end voltage is not yet set up, bus capacitor C bulkbe approximately short circuit, the peak current current limliting I of constant-current control drive circuit 301 limpeak value current-limiting resistance R is flow through in detection limpeak current information, the current-limiting circuit by constant-current control drive circuit 301 inside realizes the restriction of the input current to integrated step-down-inverse-excitation type constant current circuit with high power factor while powering on.
Wherein, switching tube Q 1can be power MOSFET, the drain electrode that its first power end is mosfet transistor, the source electrode that its second power end is mosfet transistor, the grid that its control end is described mosfet transistor.Or, switching tube Q 1also can be pliotron, the collector electrode that its first power end is pliotron, the emitter that its second power end is pliotron, the base stage that its control end is pliotron.Or, switching tube Q 1can also be unit switch or well known to a person skilled in the art other switching tube structures.
With reference to figure 4, Fig. 4 is the equivalent circuit diagram of integrated step-down-inverse-excitation type high power factor constant current device shown in Fig. 3 in the time of the first operating state, and in figure, dotted portion represents that line related and device do not participate in work.In the first operating state, switching tube Q 1conducting, input ac power signal V achalf-sinusoid voltage after rectifier bridge BR rectification is through switching tube Q 1, peak value current-limiting resistance R lim, the 3rd diode D 3, bus capacitor C bulkand inductance L bthe loop forming is to inductance L bcharging, inductance L bboth end voltage equals input capacitance C inboth end voltage deducts busbar voltage C bulkboth end voltage, the inductance L of flowing through bcurrent i brise; Meanwhile, bus capacitor C bulkthrough switching tube Q 1, peak value current-limiting resistance R lim, sampling resistor R s, transformer T former limit winding W pthe loop forming is to the former limit magnetizing inductance charging of transformer T, the former limit winding W of transformer T pboth end voltage equals bus capacitor C bulkboth end voltage, the primary current i of transformer T frise.The secondary winding Ws of transformer T is to output capacitance C oload current is provided.
Fig. 5 is the equivalent circuit diagram of the integrated step-down-inverse-excitation type high power factor constant current device shown in Fig. 3 in the time of the second operating state, and in figure, dotted portion represents that corresponding circuit and device do not participate in work.In the second operating state, switching tube Q 1disconnect the inductance L of flowing through bcurrent i bthrough the second diode D 2, bus capacitor C bulkand inductance L bthe loop afterflow forming, inductance L bboth end voltage equals negative bus capacitor C bulkboth end voltage, current i l1decline; Meanwhile, the flow through former limit winding W of transformer T pcurrent i ftransfer to transformer secondary, the secondary winding W of transformer T s, output diode D 4with output capacitance C othe loop afterflow forming, the secondary winding W of transformer T sboth end voltage equals negative output voltage, the secondary winding W of transformer T selectric current decline.
The second embodiment
Fig. 6 shows integrated step-down-inverse-excitation type high power factor constant current device of the second embodiment, comprises integrated step-down-inverse-excitation type constant current circuit with high power factor and coupled constant current Drive and Control Circuit 301.The second embodiment is the non-isolated form of the first embodiment.
In the second embodiment, integrated step-down-inverse-excitation type constant current circuit with high power factor comprises rectifier bridge BR, input capacitance C in, the first diode D 1, the second diode D 2, the 3rd diode D 3, inductance L b, transformer L f, switching tube Q 1, peak value current-limiting resistance R lim, sampling resistor R s, bus capacitor C bulk, output diode D 4and output capacitance C o.Wherein, rectifier bridge BR, input capacitance C in, switching tube Q 1, peak value current-limiting resistance R lim, the second diode D 2, the 3rd diode D 3, inductance L bwith bus capacitor C bulkform front stage circuits; Bus capacitor C bulk, the first diode D 1, switching tube Q 1, peak value current-limiting resistance R lim, sampling resistor R s, transformer L f, output diode D 4and output capacitance C oform late-class circuit.Bus capacitor C bulk, switching tube Q 1and peak value current-limiting resistance R limfor the multiplex element of two-stage circuit.
Furthermore, the input termination ac supply signal Vac of rectifier bridge BR it is carried out to rectification, input capacitance C infirst end connect the positive output end of rectifier bridge BR, input capacitance C inthe second end connect the negative output terminal of rectifier bridge BR, the first diode D 1negative electrode connect input capacitance C infirst end, the second diode D 2negative electrode meet the first diode D 1anode, the second diode D 2anode meet input capacitance C inthe second end, switching tube Q 1the first power end connect the first diode D 1negative electrode, its control end receives outside driving signal; Peak value current-limiting resistance R limfirst end connecting valve pipe Q 1the second power end, peak value current-limiting resistance R limthe second end connect sampling resistor R sfirst end; The 3rd diode D 3anodic bonding switching tube Q 1the second power end, bus capacitor C bulkthe first termination the 3rd diode D 3negative electrode and the first diode D 1anode, inductance L bfirst end connect input capacitance C inthe second end; Transformer L fmain winding W pdifferent name end and sampling resistor R sthe second end be connected, transformer L fmain winding W psame Name of Ends and inductance L bthe second end and bus capacitor C bulkthe second end be connected, transformer L fmain winding W psame Name of Ends also connect output diode D 4anode, output diode D 4negative electrode meet output capacitance C ofirst end, output capacitance C othe second termination transformer L fmain winding W pdifferent name end, load is in parallel with output capacitance, load and output capacitance C ocan be collectively referred to as output loading.Certainly, output loading also can only comprise load or output capacitance C o.
In the second embodiment, the peak current current limliting end I of constant-current control drive circuit 301 limmeet peak value current-limiting resistance R limfirst end, the current sample end CS of constant-current control drive circuit 301 connects sampling resistor R sfirst end, the ground end SGND of constant-current control drive circuit 301 meets sampling resistor R sthe second end and receive ground, former limit, constant-current control drive circuit 301 zero passage detection end ZCD meet transformer L fauxiliary winding W asame Name of Ends, the auxiliary winding W of transformer T aground, the former limit of different name termination, the output PWM of constant-current control drive circuit 301 meets switching tube Q 1control end.
In the second embodiment, the sampling resistor R that constant-current control drive circuit 301 samples according to current sample end CS scurrent information and the output diode D that detects of zero passage detection end ZCD 4oN time information (or perhaps current over-zero information) produce and drive signal, this driving signal is for control switch pipe Q 1periodically conducting and cut-off are to realize output load current constant current.Identical with the first embodiment, the impulse current of the interchange input while powering in order to limit, switching tube Q flows through 1peak current information through peak value current-limiting resistance R limbe transferred to the peak current current limliting end I of constant-current control drive circuit 301 lim.
Wherein, switching tube Q 1can be power MOSFET, the drain electrode that its first power end is mosfet transistor, the source electrode that its second power end is mosfet transistor, the grid that its control end is described mosfet transistor.Or, switching tube Q 1also can be pliotron, the collector electrode that its first power end is pliotron, the emitter that its second power end is pliotron, the base stage that its control end is pliotron.Or, switching tube Q 1can also be unit switch or well known to a person skilled in the art other switching tube structures.
With reference to figure 7, Fig. 7 is the equivalent circuit diagram of integrated step-down-inverse-excitation type high power factor constant current device shown in Fig. 6 in the time of the first operating state, and in figure, dotted portion represents that line related and device do not participate in work.In the first operating state, switching tube Q 1conducting, input ac power signal V achalf-sinusoid voltage after rectifier bridge BR rectification is through switching tube Q 1, peak value current-limiting resistance R lim, the 3rd diode D 3, bus capacitor C bulkand inductance L bthe loop forming is to inductance L bcharging, inductance L bboth end voltage equals input capacitance C inboth end voltage deducts busbar voltage C bulkboth end voltage, the inductance L of flowing through bcurrent i brise; Meanwhile, bus capacitor C bulkthrough switching tube Q 1, peak value current-limiting resistance R lim, sampling resistor R s, transformer L fformer limit winding W pthe loop forming is to transformer L fmagnetizing inductance charging, transformer L fformer limit winding W pthe voltage at two ends equals bus capacitor C bulkboth end voltage, transformer L fformer limit winding current i frise.At transformer secondary, output capacitance C oload current is provided.
Fig. 8 is the equivalent circuit diagram of the integrated step-down-inverse-excitation type high power factor constant current device shown in Fig. 6 in the time of the second operating state, and in figure, dotted portion represents that corresponding circuit and device do not participate in work.In the second operating state, switching tube Q 1disconnect the inductance L of flowing through bcurrent i bthrough the second diode D 2, bus capacitor C bulkand inductance L bthe loop afterflow forming, inductance L bboth end voltage equals negative bus capacitor C bulkboth end voltage, current i bdecline; Meanwhile, transformer L fformer limit winding current i fthrough transformer L fformer limit winding W p, output diode D 4with output capacitance C othe loop afterflow forming, transformer L fformer limit winding both end voltage equal negative output voltage, transformer L fformer limit winding current i fdecline.
The 3rd embodiment
The circuit structure of the first embodiment shown in Fig. 3 is under high voltage input condition, and circuit duty is smaller, causes circuit efficiency not high.
With reference to figure 9, Fig. 9 shows integrated step-down-inverse-excitation type high power factor constant current device of the 3rd embodiment, comprises integrated step-down-inverse-excitation type constant current circuit with high power factor and coupled constant current Drive and Control Circuit 301.The 3rd embodiment adopts coupling inductance T 1replace the inductance L in the first embodiment shown in Fig. 3 b, this coupling inductance T 1comprise the first winding and second winding of coupling, can expand the duty ratio of circuit, thus raising efficiency.
Particularly, integrated step-down-inverse-excitation type constant current circuit with high power factor of the 3rd embodiment comprises rectifier bridge BR, input capacitance C in, the first diode D 1, the second diode D 2, the 3rd diode D 3, coupling inductance T 1, transformer T 2, switching tube Q 1, peak value current-limiting resistance R lim, sampling resistor R s, bus capacitor C bulk, output diode D 4and output capacitance C o.Wherein, rectifier bridge BR, input capacitance C in, switching tube Q 1, peak value current-limiting resistance R lim, the second diode D 2, the 3rd diode D 3, coupling inductance T 1with bus capacitor C bulkform front stage circuits; Bus capacitor C bulk, the first diode D 1, switching tube Q 1, peak value current-limiting resistance R lim, sampling resistor R s, transformer T 2, output diode D 4and output capacitance C oform late-class circuit.Bus capacitor C bulk, switching tube Q 1and peak value current-limiting resistance R limfor the multiplex element of two-stage circuit.
Furthermore, the input termination ac supply signal Vac of rectifier bridge BR it is carried out to rectification, input capacitance C infirst end connect the positive output end of rectifier bridge BR, input capacitance C inthe second end connect the negative output terminal of rectifier bridge BR, the first diode D 1negative electrode connect input capacitance C infirst end, the second diode D 2negative electrode meet the first diode D 1anode, the second diode D 2anode meet coupling inductance T 1the second winding N b2different name end, coupling inductance T 1the second winding N b2termination coupling inductance T of the same name 1the first winding N b1same Name of Ends, coupling inductance T 1the first winding N b1different name termination input capacitance C inthe second end, switching tube Q 1the first power end connect the first diode D 1negative electrode, its control end receives outside driving signal; Peak value current-limiting resistance R limfirst end connecting valve pipe Q 1the second power end, peak value current-limiting resistance R limthe second end connect sampling resistor R sfirst end; The 3rd diode D 3anodic bonding switching tube Q 1the second power end, bus capacitor C bulkthe first termination the 3rd diode D 3negative electrode and the first diode D 1anode, bus capacitor C bulksecond termination the first winding N b1same Name of Ends and the second winding N b2same Name of Ends; Transformer T 2former limit winding L pdifferent name end and sampling resistor R sthe second end be connected, transformer T 2former limit winding L psame Name of Ends and coupling inductance T 1the second winding N b2same Name of Ends and bus capacitor C bulkthe second end be connected, transformer T 2secondary winding L stermination output diode D of the same name 4anode, output diode D 4negative electrode meet output capacitance C ofirst end, transformer T 2secondary winding L sdifferent name termination output capacitance C othe second end, load and output capacitance C oparallel connection, load and output capacitance C ocan be collectively referred to as output loading.Certainly, output loading also can only comprise load or output capacitance C o.
In the 3rd embodiment, the peak current current limliting end I of constant-current control drive circuit 301 limmeet peak value current-limiting resistance R limfirst end, the current sample end CS of constant-current control drive circuit 301 connects sampling resistor R sfirst end, the ground end SGND of constant-current control drive circuit 301 meets sampling resistor R sthe second end and receive ground, former limit, the zero passage detection end ZCD of constant-current control drive circuit 301 meets transformer T 2auxiliary winding L asame Name of Ends, the auxiliary winding L of transformer T aground, the former limit of different name termination, the output PWM of constant-current control drive circuit 301 meets switching tube Q 1control end.
In the 3rd embodiment, the sampling resistor R that constant-current control drive circuit 301 samples according to current sample end CS scurrent information and the output diode D that detects of zero passage detection end ZCD 4oN time information (or perhaps current over-zero information) produce drive signal, this driving Signal-controlled switch pipe Q 1periodically conducting and cut-off are to realize output load current constant current.
Similarly, switching tube Q 1can be power MOSFET, the drain electrode that its first power end is mosfet transistor, the source electrode that its second power end is mosfet transistor, the grid that its control end is described mosfet transistor.Or, switching tube Q 1also can be pliotron, the collector electrode that its first power end is pliotron, the emitter that its second power end is pliotron, the base stage that its control end is pliotron.Or, switching tube Q 1can also be unit switch or well known to a person skilled in the art other switching tube structures.
With reference to Figure 10, Figure 10 is the equivalent circuit diagram of integrated step-down-inverse-excitation type high power factor constant current device shown in Fig. 9 in the time of the first operating state, and in figure, dotted portion represents that line related and device do not participate in work.In the first operating state, switching tube Q 1conducting, input ac power signal V achalf-sinusoid voltage after rectifier bridge BR rectification is through switching tube Q 1, peak value current-limiting resistance R lim, the 3rd diode D 3, bus capacitor C bulkwith coupling inductance T 1the first winding N b1the loop forming is to coupling inductance T 1charging, coupling inductance T 1the first winding N b1both end voltage equals input capacitance C inboth end voltage deducts busbar voltage C bulkboth end voltage, the coupling inductance of flowing through T 1the first winding N b1current i brise; Meanwhile, bus capacitor C bulkthrough switching tube Q 1, resistance R lim, sampling resistor R s, transformer T 2former limit winding W pthe loop forming is to transformer T 2magnetizing inductance charging, transformer T 2former limit winding W pboth end voltage equals bus capacitor C bulkboth end voltage, transformer T 2former limit winding current i frise.At transformer secondary, output capacitance C oload current is provided.
Figure 11 is the equivalent circuit diagram of the integrated step-down-inverse-excitation type high power factor constant current device shown in Fig. 9 in the time of the second operating state, and in figure, dotted portion represents that corresponding circuit and device do not participate in work.In the second operating state, switching tube Q 1disconnect the coupling inductance of flowing through T 1the first winding N b1current i btransfer to coupling inductance T 1the second winding N b2in, and through the second diode D 2, bus capacitor C bulkthe loop afterflow forming, coupling inductance T 1the second winding N b2both end voltage equals negative bus capacitor C bulkboth end voltage; Meanwhile, the transformer T that flows through 2former limit winding W pcurrent i ftransfer to transformer secondary, transformer T 2secondary winding W s, output diode D 4with output capacitance C othe loop afterflow forming, transformer T 2secondary winding W sboth end voltage equals negative output voltage, transformer T 2secondary winding current decline.
The 4th embodiment
With reference to Figure 12, Figure 12 shows integrated step-down-inverse-excitation type high power factor constant current device of the 4th embodiment, comprises integrated step-down-inverse-excitation type constant current circuit with high power factor and coupled constant current Drive and Control Circuit 301.The 4th embodiment is the non-isolated form of the 3rd embodiment, and the main distinction is between transformer and load to be non-isolated form.
Particularly, integrated step-down-inverse-excitation type constant current circuit with high power factor of the 4th embodiment comprises rectifier bridge BR, input capacitance C in, the first diode D 1, the second diode D 2, the 3rd diode D 3, coupling inductance T 1, transformer L f, switching tube Q 1, peak value current-limiting resistance R lim, sampling resistor R s, bus capacitor C bulk, output diode D 4and output capacitance C o.Wherein, rectifier bridge BR, input capacitance C in, switching tube Q 1, resistance R lim, the second diode D 2, the 3rd diode D 3, coupling inductance T 1with bus capacitor C bulkform front stage circuits, bus capacitor C bulk, the first diode D 1, switching tube Q 1, peak value current-limiting resistance R lim, sampling resistor R s, transformer L f, output diode D 4and output capacitance C oform rear class inverse-excitation type DC-DC transfer circuit.Bus capacitor C bulk, switching tube Q 1and resistance R limfor Two-level multiplexing element.
Figure 13 and Figure 14 are the two kinds of operating states of the 4th embodiment shown in Figure 12, can describe to evolution process and the operating state of the second embodiment with reference to the first embodiment, are not described in detail here.
The 5th embodiment
With reference to Figure 15, Figure 15 shows integrated step-down-inverse-excitation type high power factor constant current device of the 5th embodiment, comprises integrated step-down-inverse-excitation type constant current circuit with high power factor and coupled constant current Drive and Control Circuit 401.
Integrated step-down-inverse-excitation type constant current circuit with high power factor of the 5th embodiment comprises rectifier bridge BR, input capacitance C in, the first diode D 1, the second diode D 2, the 3rd diode D 3, inductance L b, transformer T, switching tube Q 1, peak value current-limiting resistance R lim, sampling resistor R s, bus capacitor C bulk, output diode D 4and output capacitance C o.Wherein, rectifier bridge BR, input capacitance C in, switching tube Q 1, peak value current-limiting resistance R lim, the first diode D 1, the 3rd diode D 3, inductance L bwith bus capacitor C bulkform front stage circuits, bus capacitor C bulk, the second diode D 2, switching tube Q 1, peak value current-limiting resistance R lim, sampling resistor R s, transformer T, output diode D 4and output capacitance C oform rear class inverse-excitation type DC-DC transfer circuit.Bus capacitor C bulk, switching tube Q 1and peak value current-limiting resistance R limfor the multiplexing element of two-stage circuit.
Wherein, exchange input source V acconnect two inputs of rectifier bridge BR, the positive output termination input capacitance C of rectifier bridge BR infirst end and inductance L bfirst end, inductance L bthe former limit winding W of the second termination transformer T pdifferent name end, the former limit winding W of transformer T ptermination switching tube Q of the same name sdrain electrode and the 3rd diode D 3negative electrode, switching tube Q ssource electrode meet peak value current-limiting resistance R limfirst end, peak value current-limiting resistance R limthe second end connect sampling resistor R sfirst end, capacitor C innegative output terminal and the ground, former limit of the second end, rectifier bridge BR, sampling resistor R ssecond termination the second diode D 2anode, the second diode D 2negative electrode meet the first diode D 1anode, the 3rd diode D 3anode and bus capacitor C bulkthe second end, bus capacitor C bulkfirst end connect inductance L bthe second end, the negative electrode of the first diode D1 connects inductance L bfirst end, the secondary winding W of transformer T stermination output diode D of the same name 4anode, output diode D 4negative electrode meet output capacitance C ofirst end, the secondary winding W of transformer T sdifferent name termination output capacitance C othe second end, output capacitance C obe configured in parallel with load, load and output capacitance C ocan be collectively referred to as output loading.Certainly, output loading also can only comprise load or output capacitance C o.
In the 5th embodiment, the peak current current limliting end I of constant-current control drive circuit 401 limmeet peak value current-limiting resistance R limfirst end, the current sample end CS of constant-current control drive circuit 401 connects sampling resistor R sfirst end, the ground end SGND of constant-current control drive circuit 401 connects ground, former limit, the zero passage detection end ZCD of constant-current control drive circuit 701 meets the auxiliary winding W of transformer T asame Name of Ends, the auxiliary winding W of transformer T aground, the former limit of different name termination, the output PWM of constant-current control drive circuit 401 meets switching tube Q 1control end.
In the 5th embodiment, the sampling resistor R that constant-current control drive circuit 401 samples according to current sample end CS scurrent information and the output diode D that detects of zero passage detection end ZCD 4oN time information (or perhaps current over-zero information) produce drive signal, this driving Signal-controlled switch pipe Q 1periodically conducting and cut-off are to realize output load current constant current.
It should be noted that in the 5th embodiment the sampling resistor R that current sample end CS samples scurrent information be the primary current information of negative circuit of reversed excitation, therefore, in constant-current control drive circuit 401, this current information also needs through one-level negater circuit.In addition,, at the impulse current in order to limit the interchange input while powering on, switching tube Q flows through 1peak current information through peak value current-limiting resistance R limdeliver to the peak current current limliting end I of constant-current control drive circuit 401 lim.
With reference to Figure 16, Figure 16 is the equivalent circuit diagram of integrated step-down-inverse-excitation type high power factor constant current device shown in Figure 15 in the time of the first operating state, and in figure, dotted portion represents that line related and device do not participate in work.In the first operating state, switching tube Q 1conducting, input ac power signal V achalf-sinusoid voltage after rectifier bridge BR rectification is through inductance L b, bus capacitor C bulk, the 3rd diode D 3, switching tube Q 1with peak value current-limiting resistance R limthe loop forming is to inductance L bcharging, inductance L bboth end voltage equals input capacitance C inboth end voltage deducts busbar voltage C bulkboth end voltage, the inductance L of flowing through bthe first winding N b1current i brise; Meanwhile, bus capacitor C bulkthrough the former limit winding W of transformer T p, switching tube Q 1, peak value current-limiting resistance R limwith sampling resistor R sthe loop forming is to the former limit magnetizing inductance charging of transformer T, the former limit winding W of transformer T pboth end voltage equals bus capacitor C bulkboth end voltage, the former limit winding current i of transformer T frise.At transformer secondary, output capacitance C oload current is provided.
Figure 17 is the equivalent circuit diagram of the integrated step-down-inverse-excitation type high power factor constant current device shown in Figure 16 in the time of the second operating state, and in figure, dotted portion represents that corresponding circuit and device do not participate in work.In the second operating state, switching tube Q 1disconnect the inductance L of flowing through bcurrent i bthrough the first diode D 1, bus capacitor C bulkthe loop afterflow forming, inductance L bboth end voltage equal negative bus capacitor C bulkboth end voltage; Meanwhile, the flow through former limit winding W of transformer T pcurrent i ftransfer to transformer secondary, through the secondary winding W of transformer T s, output diode D 4with output capacitance C othe loop afterflow forming, the secondary winding both end voltage of transformer T equals negative output voltage, and the secondary winding current of transformer T declines.
The 6th embodiment
With reference to Figure 18, Figure 18 shows that the structured flowchart of integrated step-down-inverse-excitation type high power factor constant current device of the 6th embodiment.The 6th embodiment is compared with the 5th embodiment, and the main distinction is that in the 6th embodiment, the coupled modes of transformer and load are non-isolated form.
Particularly, integrated step-down-inverse-excitation type constant current circuit with high power factor of the 6th embodiment comprises rectifier bridge BR, input capacitance C in, the first diode D 1, the second diode D 2, the 3rd diode D 3, inductance L b, transformer L f, switching tube Q 1, peak value current-limiting resistance R lim, sampling resistor R s, bus capacitor C bulk, output diode D 4and output capacitance C o.Wherein, rectifier bridge BR, input capacitance C in, switching tube Q 1, peak value current-limiting resistance R lim, the first diode D 1, the 3rd diode D 3, inductance L bwith bus capacitor C bulkform front stage circuits; Bus capacitor C bulk, the second diode D 2, switching tube Q 1, peak value current-limiting resistance R lim, sampling resistor R s, transformer L f, output diode D 4and output capacitance C oform late-class circuit.Bus capacitor C bulk, switching tube Q 1and peak value current-limiting resistance R limfor the multiplex element of two-stage circuit.
Integrated step-down-inverse-excitation type high power factor constant current device of the 6th embodiment comprises integrated step-down-inverse-excitation type constant current circuit with high power factor and coupled constant current Drive and Control Circuit 401.Figure 19 and Figure 20 are two kinds of operating states that Figure 18 shows that the 6th embodiment, can describe to evolution process and the operating state of the second embodiment with reference to the first embodiment, are not described in detail here.
In above-mentioned multiple embodiment, the current sample end CS of constant-current control drive circuit connects the first end of sampling resistor Rs, sampling resistor R sthe second ground, the former limit of termination.It should be known that the current sample end CS of constant-current control drive circuit is connected to sampling resistor R as the technical staff of this professional domain sthe second end, and sampling resistor R sthe first ground, the former limit of termination, then the current signal of sampling is carried out oppositely, can obtaining the function same with above-mentioned each embodiment in constant-current control drive circuit.
In addition, it should be noted that, although in above six embodiment, be all to there is zero passage detection end by constant-current control drive circuit, for obtaining the ON time information of output diode.But, it will be appreciated by those skilled in the art that and be operated in as determined the mode of operations such as frequency time when integrated step-down-inverse-excitation type high power factor constant current device, constant-current control drive circuit also can not need to possess zero passage detection end.
In addition, although the constant-current control drive circuit in above-mentioned six embodiment all has peak current current limliting end, for obtaining peak current information.But, it will be appreciated by those skilled in the art that this peak current current limliting end and corresponding peak value current-limiting resistance are optional.
To sum up, integrated step-down-inverse-excitation type constant current circuit with high power factor of the present utility model and device tool have the following advantages:
(1) constant current circuit with high power factor of the utility model embodiment single step arrangement that is as the criterion, compares two-stage type structure, and circuit structure is simpler, is conducive to reduce circuit cost; Compare single stage type structure, greatly reduce the ripple current of output loading, without stroboscopic;
(2) in the constant current circuit with high power factor of the utility model embodiment, front stage circuits is step-down circuit, compares other topology and can obtain greater efficiency;
(3) constant current circuit with high power factor of the utility model embodiment and device adopt the constant current control of former limit, can only can realize the constant current control to output load current by the former limit winding current signal of sampling transformer, be conducive to further reduce circuit cost.
Although the utility model with preferred embodiment openly as above; but it is not for limiting the utility model; any those skilled in the art are not departing from spirit and scope of the present utility model; can make possible variation and modification, the scope that therefore protection range of the present utility model should be defined with the utility model claim is as the criterion.

Claims (24)

1. integrated step-down-inverse-excitation type constant current circuit with high power factor, is characterized in that, comprises the front stage circuits and the late-class circuit that intercouple, wherein,
This front stage circuits is the reduction voltage circuit for realizing power factor correction;
This late-class circuit is the inverse-excitation type translation circuit for realizing DC-dc conversion;
Wherein, this front stage circuits and late-class circuit share same switching tube and bus capacitor.
2. integrated step-down-inverse-excitation type constant current circuit with high power factor according to claim 1, is characterized in that, described front stage circuits comprises:
Input capacitance, its first end connects positive input terminal, and its second end connects negative input end;
Described switching tube, its first power end connects the first end of described input capacitance, and its control end receives outside driving signal;
The second diode, the second end of input capacitance described in its anodic bonding;
The 3rd diode, the second power end coupling of its anode and described switching tube, its negative electrode connects the negative electrode of described the second diode;
Described bus capacitor, its first end connects the negative electrode of described the 3rd diode and the negative electrode of the second diode;
Inductance, its first end connects the second end of described input capacitance, and its second end connects the second end of described bus capacitor;
Described late-class circuit comprises:
Described bus capacitor;
Described switching tube;
The first diode, its negative electrode connects the first power end of described switching tube, the first end of bus capacitor described in its anodic bonding;
Sampling resistor, the second power end coupling of its first end and described switching tube;
Transformer, the different name end of its former limit winding connects the second end of described sampling resistor, and the Same Name of Ends of its former limit winding connects the second end of described bus capacitor;
Output diode, the Same Name of Ends of the secondary winding of transformer described in its anodic bonding, the different name end of its negative electrode and this secondary winding is as load access interface.
3. integrated step-down-inverse-excitation type constant current circuit with high power factor according to claim 2, is characterized in that, described late-class circuit also comprises:
Output loading, its first end connects the negative electrode of described output diode, and its second end connects the different name end of the secondary winding of described transformer, and described output loading is output capacitance, load or output capacitance and any one in load in parallel.
4. integrated step-down-inverse-excitation type constant current circuit with high power factor according to claim 1, is characterized in that, described front stage circuits comprises:
Input capacitance, its first end connects positive input terminal, and its second end connects negative input end;
Described switching tube, its first power end connects the first end of described input capacitance, and its control end receives outside driving signal;
The second diode, the second end of input capacitance described in its anodic bonding;
The 3rd diode, the second power end coupling of its anode and described switching tube, its negative electrode connects the negative electrode of described the second diode;
Described bus capacitor, its first end connects the negative electrode of described the 3rd diode and the negative electrode of the second diode;
Inductance, its first end connects the second end of described input capacitance, and its second end connects the second end of described bus capacitor;
Described late-class circuit comprises:
Described bus capacitor;
Described switching tube;
The first diode, its negative electrode connects the first power end of described switching tube, the first end of bus capacitor described in its anodic bonding;
Sampling resistor, the second power end coupling of its first end and described switching tube;
Transformer, the different name end of its former limit winding connects the second end of described sampling resistor, and the Same Name of Ends of its former limit winding connects the second end of described bus capacitor;
Output diode, the Same Name of Ends of the former limit winding of transformer described in its anodic bonding, the different name end of its negative electrode and this former limit winding is as load access interface.
5. integrated step-down-inverse-excitation type constant current circuit with high power factor according to claim 4, is characterized in that, described late-class circuit also comprises:
Output loading, its first end connects the different name end of the former limit winding of described transformer, and its second end connects the negative electrode of described output diode, and described output loading is output capacitance, load or output capacitance and any one in load in parallel.
6. integrated step-down-inverse-excitation type constant current circuit with high power factor according to claim 1, is characterized in that, described front stage circuits comprises:
Input capacitance, its first end connects positive input terminal, and its second end connects negative input end;
Described switching tube, its first power end connects the first end of described input capacitance, and its control end receives outside driving signal;
The 3rd diode, the second power end coupling of its anode and described switching tube;
The second diode, its negative electrode connects the negative electrode of described the 3rd diode;
Inductance, comprise the first winding and second winding of coupling, the different name end of this first winding connects the second end of described input capacitance, and the Same Name of Ends of this second winding connects the Same Name of Ends of described the first winding, and the different name end of this second winding connects the anode of described the second diode;
Described bus capacitor, its first end connects the negative electrode of described the 3rd diode and the negative electrode of the second diode, and its second end connects the Same Name of Ends of described the first winding and the second winding;
Described late-class circuit comprises:
Described bus capacitor;
Described switching tube;
The first diode, its negative electrode connects the first power end of described switching tube, the first end of bus capacitor described in its anodic bonding;
Sampling resistor, the second power end coupling of its first end and described switching tube;
Transformer, the different name end of its former limit winding connects the second end of described sampling resistor, and the Same Name of Ends of its former limit winding connects the second end of described bus capacitor;
Output diode, the Same Name of Ends of the secondary winding of transformer described in its anodic bonding, the different name end of its negative electrode and this secondary winding is as load access interface.
7. integrated step-down-inverse-excitation type constant current circuit with high power factor according to claim 6, is characterized in that, described late-class circuit also comprises:
Output loading, its first end connects the negative electrode of described output diode, and its second end connects the different name end of described secondary winding, and described output loading is output capacitance, load or output capacitance and any one in load in parallel.
8. integrated step-down-inverse-excitation type constant current circuit with high power factor according to claim 1, is characterized in that, described front stage circuits comprises:
Input capacitance, its first end connects positive input terminal, and its second end connects negative input end;
Described switching tube, its first power end connects the first end of described input capacitance, and its control end receives outside driving signal;
The 3rd diode, the second power end coupling of its anode and described switching tube;
The second diode, its negative electrode connects the negative electrode of described the 3rd diode;
Inductance, comprise the first winding and second winding of coupling, the different name end of this first winding connects the second end of described input capacitance, and the Same Name of Ends of this second winding connects the Same Name of Ends of described the first winding, and the different name end of this second winding connects the anode of described the second diode;
Described bus capacitor, its first end connects the negative electrode of described the 3rd diode and the negative electrode of the second diode, and its second end connects the Same Name of Ends of described the first winding and the second winding;
Described late-class circuit comprises:
Described bus capacitor;
Described switching tube;
The first diode, its negative electrode connects the first power end of described switching tube, the first end of bus capacitor described in its anodic bonding;
Sampling resistor, the second power end coupling of its first end and described switching tube;
Transformer, the different name end of its former limit winding connects the second end of described sampling resistor, and the Same Name of Ends of its former limit winding connects the second end of described bus capacitor;
Output diode, the Same Name of Ends of the former limit winding of transformer described in its anodic bonding, the different name end of its negative electrode and this former limit winding is as load access interface.
9. integrated step-down-inverse-excitation type constant current circuit with high power factor according to claim 8, is characterized in that, described late-class circuit also comprises:
Output loading, its first end connects the different name end of described former limit winding, and its second end connects the negative electrode of described output diode, and described output loading is output capacitance, load or output capacitance and any one in load in parallel.
10. according to the integrated step-down-inverse-excitation type constant current circuit with high power factor described in any one in claim 2 to 9, it is characterized in that, described front stage circuits and late-class circuit also comprise peak value current-limiting resistance, described the 3rd anode of diode and the first end of described sampling resistor are connected with the second power end of described switching tube via described peak value current-limiting resistance, the first end of this peak value current-limiting resistance connects the second power end of described switching tube, and the second end of this peak value current-limiting resistance connects the anode of described the 3rd diode.
11. integrated step-down-inverse-excitation type constant current circuit with high power factor according to claim 1, is characterized in that, described front stage circuits comprises:
Input capacitance, its first end connects positive input terminal, and its second end connects negative input end;
The first diode, its negative electrode connects the first end of described input capacitance;
The 3rd diode, the anode of the first diode described in its anodic bonding;
Inductance, its first end connects the first end of described input capacitance;
Described bus capacitor, its first end connects the second end of described inductance, and its second end connects the anode of described the first diode and the 3rd diode;
Described switching tube, its first power end connects the negative electrode of described the 3rd diode, the second end coupling of its second power end and described input capacitance, its control end receives outside driving signal;
Described late-class circuit comprises:
Described bus capacitor;
Described switching tube;
The second diode, its negative electrode connects the second end of described bus capacitor;
Sampling resistor, the anode of its first end and described the second diode, the second power end coupling of its second end and described switching tube;
Transformer, the different name end of its former limit winding connects the first end of described bus capacitor, and the Same Name of Ends of its former limit winding connects the first power end of described switching tube;
Output diode, the Same Name of Ends of the secondary winding of transformer described in its anodic bonding, the different name end of its negative electrode and this secondary winding is as load access interface.
12. integrated step-down-inverse-excitation type constant current circuit with high power factor according to claim 11, is characterized in that, described late-class circuit also comprises:
Output loading, its first end connects the negative electrode of described output diode, and its second end connects the different name end of described secondary winding, and described output loading is output capacitance, load or output capacitance and any one in load in parallel.
13. integrated step-down-inverse-excitation type constant current circuit with high power factor according to claim 1, is characterized in that, described front stage circuits comprises:
Input capacitance, its first end connects positive input terminal, and its second end connects negative input end;
The first diode, its negative electrode connects the first end of described input capacitance;
The 3rd diode, the anode of the first diode described in its anodic bonding;
Inductance, its first end connects the first end of described input capacitance;
Described bus capacitor, its first end connects the second end of described inductance, and its second end connects the anode of described the first diode and the 3rd diode;
Described switching tube, its first power end connects the negative electrode of described the 3rd diode, the second end coupling of its second power end and described input capacitance, its control end receives outside driving signal;
Described late-class circuit comprises:
Described bus capacitor;
Described switching tube;
The second diode, its negative electrode connects the second end of described bus capacitor;
Sampling resistor, the anode of its first end and described the second diode, the second power end coupling of its second end and described switching tube;
Transformer, the different name end of its former limit winding connects the first end of described bus capacitor, and the Same Name of Ends of its former limit winding connects the first power end of described switching tube;
Output diode, the Same Name of Ends of the former limit winding of transformer described in its anodic bonding, the different name end of its negative electrode and this former limit winding is as load access interface.
14. integrated step-down-inverse-excitation type constant current circuit with high power factor according to claim 13, is characterized in that, described late-class circuit also comprises:
Output loading, its first end connects the negative electrode of described output diode, and its second end connects the different name end of the secondary winding of described transformer, and described output loading is output capacitance, load or output capacitance and any one in load in parallel.
15. according to claim 11 to the integrated step-down-inverse-excitation type constant current circuit with high power factor described in any one in 14, it is characterized in that, described front stage circuits and late-class circuit also comprise peak value current-limiting resistance, the second end of described sampling resistor and the second end of described input capacitance are connected with the second power end of described switching tube via this peak value current-limiting resistance, the first end of this peak value current-limiting resistance connects the second end of described input capacitance and the second end of described sampling resistor, and the second end of this peak value current-limiting resistance connects the second power end of described switching tube.
16. according to the integrated step-down-inverse-excitation type constant current circuit with high power factor described in any one in claim 2 to 9,11 to 14, it is characterized in that, also comprises:
Rectifier bridge, to the ac supply signal rectification of input, its positive output end connects described positive input terminal, and its negative output terminal connects described negative input end.
17. according to the integrated step-down-inverse-excitation type constant current circuit with high power factor described in any one in claim 1 to 9,11 to 14, it is characterized in that, described switching tube is power MOSFET, the drain electrode that described the first power end is described mosfet transistor, the source electrode that described the second power end is described mosfet transistor, the grid that described control end is described mosfet transistor.
18. according to the integrated step-down-inverse-excitation type constant current circuit with high power factor described in any one in claim 1 to 9,11 to 14, it is characterized in that, described switching tube is pliotron, the collector electrode that described the first power end is described pliotron, the emitter that described the second power end is described pliotron, the base stage that described control end is described pliotron.
19. according to the integrated step-down-inverse-excitation type constant current circuit with high power factor described in any one in claim 1 to 9,11 to 14, it is characterized in that, described switching tube is unit switch.
20. 1 kinds of integrated step-down-inverse-excitation type high power factor constant current devices, is characterized in that, comprising:
Integrated step-down-inverse-excitation type constant current circuit with high power factor in claim 2 to 19 described in any one;
Constant-current control drive circuit, its current sample end sampling obtains the current information of described sampling resistor, and described in it, constant-current control drive circuit produces and drives signal according to the current information of described sampling resistor, and described driving signal transfers to the control end of described switching tube.
21. integrated step-down-inverse-excitation type high power factor constant current devices according to claim 20, is characterized in that, the current sample end of described constant-current control drive circuit connects the first end of described sampling resistor, the second ground, the former limit of termination of described sampling resistor; Or the current sample end of described constant-current control drive circuit connects the second end of described sampling resistor, the first ground, the former limit of termination of described sampling resistor.
22. integrated step-down-inverse-excitation type high power factor constant current devices according to claim 20, it is characterized in that, described constant-current control drive circuit also has zero passage detection end, this zero passage detection end obtains the ON time information of described output diode, and described constant-current control drive circuit produces this driving signal according to described current information and ON time information.
23. integrated step-down-inverse-excitation type high power factor constant current devices according to claim 22, it is characterized in that, described transformer also comprises auxiliary winding, the ground, the former limit of different name termination of the auxiliary winding of described transformer, the Same Name of Ends of the auxiliary winding of described transformer connects the zero passage detection end of described constant-current control drive circuit.
24. integrated step-down-inverse-excitation type high power factor constant current devices according to claim 20, it is characterized in that, described integrated step-down-inverse-excitation type constant current circuit with high power factor is the circuit described in claim 10 or 15, described constant-current control drive circuit also has peak current current limliting end, this peak current current limliting end is connected to obtain peak current information with the first end of described peak value current-limiting resistance, described constant-current control drive circuit produces described driving signal according to described current information and peak current information.
CN201320804625.4U 2013-12-09 2013-12-09 Integrated buck-flyback type high power factor constant current circuit and device Withdrawn - After Issue CN203617902U (en)

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Cited By (5)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN103647448A (en) * 2013-12-09 2014-03-19 杭州士兰微电子股份有限公司 Integrated step-down-flyback type high power factor constant current circuit and device
CN104466978A (en) * 2014-11-17 2015-03-25 浙江大学 Buck type power factor correction circuit
CN109194165A (en) * 2018-10-18 2019-01-11 矽力杰半导体技术(杭州)有限公司 AC-DC power converter
CN109256966A (en) * 2018-10-18 2019-01-22 矽力杰半导体技术(杭州)有限公司 AC-DC power converter
US11205966B2 (en) 2018-10-18 2021-12-21 Silergy Semiconductor Technology (Hangzhou) Ltd AC-DC power converter

Cited By (7)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN103647448A (en) * 2013-12-09 2014-03-19 杭州士兰微电子股份有限公司 Integrated step-down-flyback type high power factor constant current circuit and device
CN103647448B (en) * 2013-12-09 2016-01-06 杭州士兰微电子股份有限公司 Integrated step-down-flyback type high power factor constant current circuit and device
CN104466978A (en) * 2014-11-17 2015-03-25 浙江大学 Buck type power factor correction circuit
CN109194165A (en) * 2018-10-18 2019-01-11 矽力杰半导体技术(杭州)有限公司 AC-DC power converter
CN109256966A (en) * 2018-10-18 2019-01-22 矽力杰半导体技术(杭州)有限公司 AC-DC power converter
CN109194165B (en) * 2018-10-18 2021-05-14 矽力杰半导体技术(杭州)有限公司 AC-DC power converter
US11205966B2 (en) 2018-10-18 2021-12-21 Silergy Semiconductor Technology (Hangzhou) Ltd AC-DC power converter

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