CN101577493B - Power supply circuit - Google Patents
Power supply circuit Download PDFInfo
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- CN101577493B CN101577493B CN2008100671000A CN200810067100A CN101577493B CN 101577493 B CN101577493 B CN 101577493B CN 2008100671000 A CN2008100671000 A CN 2008100671000A CN 200810067100 A CN200810067100 A CN 200810067100A CN 101577493 B CN101577493 B CN 101577493B
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Abstract
The invention provides a power supply circuit which comprises an AC-DC converting circuit, a pulse width modulating controller, a switching transistor, a transformer, a rectifying and filtering circuit and a slow start circuit, wherein under the control of the pulse width modulating controller and the switching transistor, exterior AC voltage is converted into DC voltage sequentially through the AC-DC converting circuit, the transformer and the rectifying and filtering circuit; and the slow start circuit is arranged between the rectifying and filtering circuit and a load. The power supply circuit still can normally work under the condition that the load is arranged firstly and then is electrified.
Description
Technical field
The present invention relates to a kind of power circuit.
Background technology
See also Fig. 1, it is a kind of circuit diagram of power circuit of prior art.This power circuit 10 mainly comprises an AC-DC (AC-DC) change-over circuit 11, a PDM keyer 12, a switching transistor 13, a transformer 14, a current rectifying and wave filtering circuit 15, a feedback circuit 16 and a current-limiting resistance 19.This current rectifying and wave filtering circuit 15 comprises one first output 151 and one second output 152.This AC-DC change-over circuit 11 is converted to direct voltage with extraneous alternating voltage, this feedback circuit 16 feeds back to this PDM keyer 12 with the output voltage of this current rectifying and wave filtering circuit 15, and this switching transistor 13 is opened or closed to this PDM keyer 12 according to the feedback signal of its reception.Under the control of this PDM keyer 12 and this switching transistor 13, extraneous alternating voltage changes a 5V direct voltage and a 16V direct voltage into by this AC-DC change-over circuit 11, this transformer 14 and this current rectifying and wave filtering circuit 15 successively, and respectively from this first output 151 and 152 outputs of this second output.When the electric current in this power circuit 10 surpasses a set point (i.e. the mistake flow point of this power circuit 10); the corresponding voltage reference value that surpasses this PDM keyer 12 of the voltage of this current-limiting resistance 19; this PDM keyer 12 just quits work, and this process is called overcurrent protection.Can change the mistake flow point of this power circuit 10 by the resistance value of setting this current-limiting resistance 19.
But, set higherly if will cross flow point, when these power circuit 10 output abnormalities, do not have the effect of overcurrent protection so, very big potential safety hazard is arranged.If will cross flow point sets lower; when starting under the situation that this power circuit 10 is formerly switched on behind the bringing onto load; electric capacity in this load and this current rectifying and wave filtering circuit 15 (indicating) is relation in parallel; therefore the all-in resistance of these power circuit 10 outlet sides is very little; electric current in this power circuit 10 can be very big; this electric current is crossed flow point in case surpass it, and this power circuit 10 promptly enters the overcurrent protection state.The problem that therefore can occur cisco unity malfunction under the situation that this power circuit 10 is formerly switched on behind the bringing onto load.
Summary of the invention
Electric current can be very big, this electric current is crossed flow point in case surpass it, this power circuit 10 promptly enters the overcurrent protection state.The problem that therefore can occur cisco unity malfunction under the situation that this power circuit 10 is formerly switched on behind the bringing onto load.
In order to solve the problem of cisco unity malfunction under the situation that power circuit in the prior art formerly switches on behind the bringing onto load, the invention provides under a kind of situation that has low flow point and formerly switch on behind the bringing onto load can operate as normal power circuit.
A kind of power circuit, it comprises an AC-DC change-over circuit, one PDM keyer, one switching transistor, one transformer, one current rectifying and wave filtering circuit and a soft-start circuit, under the control of this PDM keyer and this switching transistor, extraneous alternating voltage is successively by this AC-DC change-over circuit, this transformer and this current rectifying and wave filtering circuit change direct voltage into, this soft-start circuit is arranged between this current rectifying and wave filtering circuit and the load, this current rectifying and wave filtering circuit comprises one first output and one second output, this soft-start circuit comprises one first resistance, one second resistance, one the 3rd resistance, one electric capacity, one the first transistor, one transistor seconds, one the 3rd transistor, one first output and one second output, this first resistance and this second resistance string are connected between first output and ground of this current rectifying and wave filtering circuit, this electric capacity is in parallel with this first resistance, the control utmost point of this first transistor is by this first grounding through resistance, the first conduction utmost point ground connection of this first transistor, the second conduction utmost point of this first transistor is connected with the control utmost point of this transistor seconds, the control utmost point of this transistor seconds is connected with first output of this current rectifying and wave filtering circuit by the 3rd resistance, the first conduction utmost point of this transistor seconds is connected with first output of this current rectifying and wave filtering circuit, the second conduction utmost point of this transistor seconds is connected with first output of this soft-start circuit, the 3rd transistorized control utmost point is connected with the control utmost point of this transistor seconds, the 3rd transistorized first conduction utmost point is connected with second output of this current rectifying and wave filtering circuit, and the 3rd transistorized second conduction utmost point is connected with second output of this soft-start circuit.
Description of drawings
Compared with prior art, power circuit of the present invention is because adopted this soft-start circuit, this soft-start circuit to be arranged between the current rectifying and wave filtering circuit and load of this power circuit.When this power circuit have low flow point and the situation of formerly switching on behind the bringing onto load under when starting, this soft-start circuit is equivalent to a switch.This soft-start circuit at first is in closed condition, at this moment, but this power circuit operate as normal.This soft-start circuit conducting then, this power circuit begins to power to the load by this soft-start circuit.Therefore still can operate as normal under this power circuit situation of formerly switching on behind the bringing onto load.
Fig. 1 is a kind of circuit diagram of power circuit of prior art.
Fig. 2 is the circuit diagram of first execution mode of power circuit of the present invention.
Fig. 3 is the circuit diagram of soft-start circuit shown in Figure 2.
Embodiment
Fig. 4 is the circuit diagram of soft-start circuit of second execution mode of power circuit of the present invention.
See also Fig. 2, it is the circuit diagram of first execution mode of power circuit of the present invention.This power circuit 20 mainly comprises an AC-DC change-over circuit 21, a PDM keyer 22, a switching transistor 23, a transformer 24, a current rectifying and wave filtering circuit 25, a feedback circuit 26 and a soft-start circuit 27.This current rectifying and wave filtering circuit 25 comprises one first output 251 and one second output 252.This AC-DC change-over circuit 21 is converted to direct voltage with extraneous alternating voltage, this feedback circuit 26 feeds back to this PDM keyer 22 with the output voltage of this current rectifying and wave filtering circuit 25, and this switching transistor 23 is opened or closed to this PDM keyer 22 according to the feedback signal of its reception.Under the control of this PDM keyer 22 and this switching transistor 23, extraneous alternating voltage changes a 5V direct voltage and a 16V direct voltage into by this AC-DC change-over circuit 21, this transformer 24 and this current rectifying and wave filtering circuit 25 successively, and respectively from this first output 251 and 252 outputs of this second output.
See also Fig. 3, it is the circuit diagram of soft-start circuit shown in Figure 2.This soft-start circuit 27 comprises one first resistance R 1, one second resistance R 2, one the 3rd resistance R 3, an electric capacity 270, a first transistor T1, a transistor seconds T2, one the 3rd transistor T 3, one first output 271 and one second output 272.This first transistor T1 is a npn type bipolar transistor, and this transistor seconds T2 and the 3rd transistor T 3 are the P-channel metal-oxide-semiconductor field-effect transistor.
This first resistance R 1 and this second resistance R 2 are serially connected between first output 251 and ground of this current rectifying and wave filtering circuit 25.This electric capacity 270 is in parallel with this first resistance R 1.The base stage of this first transistor T1 is passed through this first resistance R, 1 ground connection, its grounded emitter, and its collector electrode is connected with the grid of this transistor seconds T2.The grid of this transistor seconds T2 is connected with first output 251 of this current rectifying and wave filtering circuit 25 by the 3rd resistance R 3, its source electrode is connected with first output 251 of this current rectifying and wave filtering circuit 25, and its drain electrode is connected with second output 271 of this soft-start circuit 27.The grid of the 3rd transistor T 3 is connected with the grid of this transistor seconds T2, and its source electrode is connected with second output 252 of this current rectifying and wave filtering circuit 25, and its drain electrode is connected with second output 272 of this soft-start circuit 27 by a fuse 28.
When starting working under the situation that this power circuit 20 is formerly switched on behind the bringing onto load, first output, 251 outputs, the one 16V direct voltage of this current rectifying and wave filtering circuit 25, its second output, 252 outputs, one 5V direct voltage.This 16V direct voltage charges to this electric capacity 270 by this second resistance R 2.This moment, the base stage of this first transistor T1 was a low level, and this first transistor T1 is in cut-off state.The grid of this transistor seconds T2 and the 3rd transistor T 3 is high level, and this transistor seconds T2 and the 3rd transistor T 3 are in cut-off state.When these electric capacity 270 chargings finished, the base stage of this first transistor T1 was a high level, this first transistor T1 conducting.The grid of this transistor seconds T2 and the 3rd transistor T 3 all by drop-down be low level, this transistor seconds T2 and the 3rd transistor T 3 are in conducting state, first output, 271 beginnings of this soft-start circuit 27 are to load (figure does not show) output 16V direct voltage, and its second output, 272 beginnings are to load output 5V direct voltage.
Compared with prior art, power circuit 20 of the present invention is because adopted this soft-start circuit 27, this soft-start circuit 27 to be arranged between the current rectifying and wave filtering circuit 25 and load of this power circuit 20.When this power circuit 20 have low flow point and the situation of formerly switching on behind the bringing onto load under when starting, this soft-start circuit 27 is equivalent to a switch.This soft-start circuit 27 at first is in closed condition, at this moment, but these power circuit 20 operate as normal.These soft-start circuit 27 conductings then, this power circuit 20 begins to power to the load by this soft-start circuit 27.Therefore still can operate as normal under this power circuit 20 situation of formerly switching on behind the bringing onto load.
See also Fig. 4, it is the circuit diagram of soft-start circuit of second execution mode of power circuit of the present invention.This soft-start circuit 37 is roughly the same with the circuit structure of this soft-start circuit 27, its difference is: this first transistor M1 is a N NMOS N-channel MOS N field-effect transistor, its grid is by these first resistance R, 11 ground connection, its source ground, its drain electrode is connected with the grid of this transistor seconds M2.
In first and second execution mode of this power circuit 20, this transistor seconds T2, M2 and the 3rd transistor T 3, M3 also can be the positive-negative-positive bipolar transistors.In this manual, the base stage of bipolar transistor or the grid of metal oxide semiconductcor field effect transistor are referred to as the control utmost point, the emitter of bipolar transistor or the source electrode of metal oxide semiconductcor field effect transistor are referred to as the first conduction utmost point, and the collector electrode of bipolar transistor or the drain electrode of metal oxide semiconductcor field effect transistor are referred to as the second conduction utmost point.
Claims (9)
1. power circuit, it comprises an AC-DC change-over circuit, one PDM keyer, one switching transistor, one transformer and a current rectifying and wave filtering circuit, under the control of this PDM keyer and this switching transistor, extraneous alternating voltage is successively by this AC-DC change-over circuit, this transformer and this current rectifying and wave filtering circuit change direct voltage into, it is characterized in that: this power circuit also comprises a soft-start circuit, this soft-start circuit is arranged between this current rectifying and wave filtering circuit and the load, this current rectifying and wave filtering circuit comprises one first output and one second output, this soft-start circuit comprises one first resistance, one second resistance, one the 3rd resistance, one electric capacity, one the first transistor, one transistor seconds, one the 3rd transistor, one first output and one second output, this first resistance and this second resistance string are connected between first output and ground of this current rectifying and wave filtering circuit, this electric capacity is in parallel with this first resistance, the control utmost point of this first transistor is by this first grounding through resistance, the first conduction utmost point ground connection of this first transistor, the second conduction utmost point of this first transistor is connected with the control utmost point of this transistor seconds, the control utmost point of this transistor seconds is connected with first output of this current rectifying and wave filtering circuit by the 3rd resistance, the first conduction utmost point of this transistor seconds is connected with first output of this current rectifying and wave filtering circuit, the second conduction utmost point of this transistor seconds is connected with first output of this soft-start circuit, the 3rd transistorized control utmost point is connected with the control utmost point of this transistor seconds, the 3rd transistorized first conduction utmost point is connected with second output of this current rectifying and wave filtering circuit, and the 3rd transistorized second conduction utmost point is connected with second output of this soft-start circuit.
2. power circuit as claimed in claim 1, it is characterized in that: this first transistor is a bipolar transistor, its control utmost point i.e. the base stage of this bipolar transistor, and its first conduction utmost point i.e. the emitter of this bipolar transistor, and its second conduction utmost point i.e. the collector electrode of this bipolar transistor.
3. power circuit as claimed in claim 2 is characterized in that: this first transistor is a npn type bipolar transistor.
4. power circuit as claimed in claim 1, it is characterized in that: this first transistor is a metal oxide semiconductcor field effect transistor, its control utmost point i.e. the grid of this metal oxide semiconductcor field effect transistor, its first conduction utmost point i.e. the source electrode of this metal oxide semiconductcor field effect transistor, its i.e. drain electrode of this metal oxide semiconductcor field effect transistor of second conduction utmost point.
5. power circuit as claimed in claim 4 is characterized in that: this first transistor is a N NMOS N-channel MOS N field-effect transistor.
6. power circuit as claimed in claim 1, it is characterized in that: this transistor seconds is a metal oxide semiconductcor field effect transistor, its control utmost point i.e. the grid of this metal oxide semiconductcor field effect transistor, its first conduction utmost point i.e. the source electrode of this metal oxide semiconductcor field effect transistor, its i.e. drain electrode of this metal oxide semiconductcor field effect transistor of second conduction utmost point.
7. power circuit as claimed in claim 6 is characterized in that: this transistor seconds is the P-channel metal-oxide-semiconductor field-effect transistor.
8. power circuit as claimed in claim 1, it is characterized in that: the 3rd transistor is a metal oxide semiconductcor field effect transistor, its control utmost point i.e. the grid of this metal oxide semiconductcor field effect transistor, its first conduction utmost point i.e. the source electrode of this metal oxide semiconductcor field effect transistor, its i.e. drain electrode of this metal oxide semiconductcor field effect transistor of second conduction utmost point.
9. power circuit as claimed in claim 8 is characterized in that: the 3rd transistor is the P-channel metal-oxide-semiconductor field-effect transistor.
Priority Applications (1)
Application Number | Priority Date | Filing Date | Title |
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CN2008100671000A CN101577493B (en) | 2008-05-07 | 2008-05-07 | Power supply circuit |
Applications Claiming Priority (1)
Application Number | Priority Date | Filing Date | Title |
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CN2008100671000A CN101577493B (en) | 2008-05-07 | 2008-05-07 | Power supply circuit |
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CN101577493A CN101577493A (en) | 2009-11-11 |
CN101577493B true CN101577493B (en) | 2011-06-15 |
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CN2008100671000A Expired - Fee Related CN101577493B (en) | 2008-05-07 | 2008-05-07 | Power supply circuit |
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Families Citing this family (1)
Publication number | Priority date | Publication date | Assignee | Title |
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CN103973093A (en) * | 2014-05-22 | 2014-08-06 | 深圳东科半导体有限公司 | Nondestructive starting circuit of switching converter |
Citations (5)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US4794508A (en) * | 1987-12-23 | 1988-12-27 | Dci Technology | PWM control circuit for a non-symmetrical switching power supply |
US5267133A (en) * | 1990-12-10 | 1993-11-30 | Nec Corporation | Switching power source |
CN2240226Y (en) * | 1995-02-18 | 1996-11-13 | 严波 | Electronic dimming ballast for fluorescent lamp |
US5946200A (en) * | 1995-12-02 | 1999-08-31 | Korea Electrotechnology Research Institute | Circulating current free type high frequency soft switching pulsewidth modulated full bridge DC/DC converter |
CN101154881A (en) * | 2006-09-29 | 2008-04-02 | 群康科技(深圳)有限公司 | Switch power circuit |
-
2008
- 2008-05-07 CN CN2008100671000A patent/CN101577493B/en not_active Expired - Fee Related
Patent Citations (5)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US4794508A (en) * | 1987-12-23 | 1988-12-27 | Dci Technology | PWM control circuit for a non-symmetrical switching power supply |
US5267133A (en) * | 1990-12-10 | 1993-11-30 | Nec Corporation | Switching power source |
CN2240226Y (en) * | 1995-02-18 | 1996-11-13 | 严波 | Electronic dimming ballast for fluorescent lamp |
US5946200A (en) * | 1995-12-02 | 1999-08-31 | Korea Electrotechnology Research Institute | Circulating current free type high frequency soft switching pulsewidth modulated full bridge DC/DC converter |
CN101154881A (en) * | 2006-09-29 | 2008-04-02 | 群康科技(深圳)有限公司 | Switch power circuit |
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CN101577493A (en) | 2009-11-11 |
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Granted publication date: 20110615 Termination date: 20210507 |