CN203660887U - Emergency starting power supply circuit - Google Patents

Abstract

The utility model discloses an emergency starting power supply circuit, which comprises an input protection circuit, a first-stage tandem switch power supply circuit, a second-stage switch power supply circuit, a power supply protection and output control circuit. The input protection circuit is used for acquiring the power supply voltage of a subway power supply network. The first-stage tandem switch power supply circuit is used for dividing the power supply voltage to obtain partial power supply voltages, and then converting the partial power supply voltages into a parallel-connection type output power supply voltage. The second-stage switch power supply circuit is used for reducing the parallel-connection type output power supply voltage to obtain a working power supply voltage. The power supply protection and output control circuit is used for protecting and controlling the parallel-connection type output power supply voltage and the working power supply voltage. According to the technical scheme of the utility model, the power supply voltage of the subway power supply network is acquired and directly reduced to be served as an emergency starting power supply for the auxiliary power box of a subway traction system by means of switching power supplies, instead of conventional built-in batteries adopted in the prior art. In this way, the service life of the entire power supply is prolonged, and the damage of the leaked electrolyte to the mechanical structure of the power box body is reduced. Meanwhile, the influence of scrapped products on the environment is lowered. Compared with a conventional technical scheme based on built-in storage batteries, the emergency starting power supply with high-frequency switching power supplies is lower in cost and lighter in weight.

Description

A kind of emergency start power circuit

Technical field

The utility model relates to railcar traction technique field, in particular, relates to a kind of emergency start power circuit.

Background technology

The normal startup of railcar trailer system need to be powered to control system by controlling storage battery, then starts accessory power supply (comprising subordinate inverter and battery charger) by control system.After battery charger starts normally, controlling electricity is powered by battery charger.In the time there is power shortage in control storage battery, whole railcar trailer system just cannot start, therefore, generally all is furnished with emergency start power supply at railcar trailer system, can in the situation that controlling discharged or defective battery, the alternative storage battery of controlling of short time be secondary power system power supply, after auxiliary power start is normal, cut off emergency start power supply.

At present, emergency start power supply is mainly at the built-in small battery of secondary power system, and when accessory power supply is normally worked, small battery, always in floating charge state, is manually cut built-in small battery in the time needing emergency start.Because metro traction system control power supply is 110VDC, thisly need more piece storage battery series connection at the built-in small battery of secondary power system, cause the cost of built-in small battery high, weight is large; Railcar designed life is 30 years, but storage battery ordinary life is 5-10, therefore, because the useful life of storage battery is short, need to change storage battery; In addition, storage battery may have leakage risk, and because battery electrolyte generally has corrosivity, leakage easily causes damage to casing mechanical structure, and then causes whole casing to be scrapped; Due to the generation manufacture of storage battery and follow-up to scrap processing all larger to environmental impact, use not environmental protection of storage battery, and easy contaminated environment.

Therefore, providing a kind of emergency start power circuit, extend whole service life, and after scrapping, reduce the impact on environment, is those skilled in the art's problem demanding prompt solutions.

Utility model content

In view of this, the utility model provides a kind of emergency start power circuit, short and leakage risk may occur to overcome in prior art useful life due to storage battery, causes bulk life time short and scrap the problem larger to environmental impact.

For achieving the above object, the utility model provides following technical scheme:

A kind of emergency start power circuit, comprising:

Get the input protection circuit of the supply voltage of subway power supply network;

Be connected with described input protection circuit, described supply voltage carried out to dividing potential drop and obtain dividing voltage supply voltage, and described dividing voltage supply voltage transitions is become to the first order tandem tap power circuit of output supply voltage in parallel;

Be connected with described first order tandem tap power circuit, described output supply voltage in parallel carried out step-down and obtained the second level switching power circuit of working power voltage;

Be connected with described second level switching power circuit with described first order tandem tap power circuit respectively; power protection and output control circuit that described output supply voltage in parallel and described working power voltage are protected and controlled; after in emergency start, emergency start power circuit output a period of time enough chargers start, output control circuit is closed described emergency start power supply automatically.

Wherein, described first order tandem tap power circuit comprises:

The supply voltage of subway power supply network is carried out to dividing potential drop and obtains the input bleeder circuit of dividing voltage supply voltage;

At least three that be connected in series and be connected and described dividing voltage supply voltage carried out to the power conversion circuit of power conversion with described input bleeder circuit;

Be connected and carry out the current rectifying and wave filtering circuit of rectifying and wave-filtering with described power conversion circuit respectively, the output of described current rectifying and wave filtering circuit is output in parallel;

Be connected with described power conversion circuit respectively and drive three drive circuits of corresponding power translation circuit;

And the pwm control circuit being connected with described drive circuit, described power conversion circuit, described input bleeder circuit and described output in parallel respectively.

Wherein, between described power conversion circuit and described pwm control circuit, also comprise:

Be connected and carry out current sample with described power conversion circuit, and the electric current of sampling is sent to the current sampling circuit of described pwm control circuit;

Be connected with described power conversion circuit and carry out the control power circuit of system power supply control.

Wherein, between described input bleeder circuit and described pwm control circuit, also comprise:

The overvoltage/undervoltage testing circuit that is connected and carries out overvoltage/undervoltage detection and testing result is passed to described pwm control circuit with described input bleeder circuit;

Be connected to system and carry out the auxiliary power supply circuit of auxiliary power supply with described input bleeder circuit.

Wherein, between described output in parallel and described pwm control circuit, also comprise:

The voltage sampling circuit that carries out electric current and voltage sampling and sampled result is passed to described pwm control circuit is connected with described output circuit in parallel;

Be connected and carry out the over-voltage detection circuit of overvoltage detection with described output in parallel.

Wherein, described input bleeder circuit comprises the resistor capacitor circuit that at least three groups are connected in series, described resistor capacitor circuit comprises the resistance and the electric capacity that are connected in parallel, described in one end ground connection of the resistor capacitor circuit that is connected in series, the supply voltage of subway power supply network described in another termination.

Wherein, described power conversion circuit comprises: filter capacitor (C2, C5, C8), with described filter capacitor (C2, C5, C8) the connected resistor capacitor circuit in one end, single-phase switch pipe (the D1 that negative electrode is connected with the described resistor capacitor circuit other end, D3, and drain electrode and described single-phase switch pipe (D1 D5), D3, D5) the connected switching tube (Q1 of anode, Q2, Q3), described resistor capacitor circuit comprises the resistance (R1 being connected in parallel, R4, and electric capacity (C1 R7), C4, C7), described switching tube (Q1, Q2, Q3) source electrode and filter capacitor (C2, C5, C8) the other end is connected, the source electrode of described switching tube Q3 is through resistance R 10 ground connection, described switching tube (Q1, Q2, Q3) drain electrode and the other end of described resistor capacitor circuit respectively with transformer (TR1, TR2, TR3) former limit is connected, described transformer (TR1, TR2, TR3) secondary is the output of described power conversion circuit.

Wherein, described current rectifying and wave filtering circuit comprises: the single-phase switch pipe (D2, D4, D6), resistance (R2, R5, R8) and the electric capacity (C3, C6, C9) that are connected in series, the anode of described single-phase switch pipe (D2, D4, D6) is connected with an output of described power conversion circuit, the other end of another output of described power conversion circuit and described electric capacity (C3, C6, C9) is connected and ground connection, and the ungrounded end of described electric capacity (C3, C6, C9) is the output of described current rectifying and wave filtering circuit.

Wherein, described first order switching power circuit and/or described second level switching power circuit are flyback power circuit.

Preferably, described second level switching power circuit comprises: the first power conversion circuit, the first current rectifying and wave filtering circuit and the first external output circuit that connect successively, the first pwm control circuit being connected with described the first current rectifying and wave filtering circuit with described the first power conversion circuit respectively and the first order control circuit being connected with the described first external output circuit with described the first current rectifying and wave filtering circuit respectively, wherein

Between described the first power conversion circuit and described the first pwm control circuit, be provided with drive circuit, current sampling circuit and control power circuit, between described the first current rectifying and wave filtering circuit and described the first pwm control circuit, be provided with voltage sampling circuit, between the described first external output circuit and described first order control circuit, be provided with output control circuit, between described the first current rectifying and wave filtering circuit and described first order control circuit, be provided with over-voltage detection circuit, described output control circuit is connected with enabling signal circuit, described drive circuit is connected with auxiliary power supply circuit.

Known via above-mentioned technical scheme, compared with prior art, the utility model discloses a kind of emergency start power circuit, comprise the input protection circuit of the supply voltage of getting subway power supply network; Be connected with input protection circuit, supply voltage carried out to dividing potential drop and obtain dividing voltage supply voltage, and dividing voltage supply voltage transitions is become to the first order tandem tap power circuit of output supply voltage in parallel; Be connected with first order tandem tap power circuit, out-put supply in parallel carried out step-down and obtained the second level switching power circuit of working power voltage; Be connected with second level switching power circuit with first order tandem tap power circuit respectively, power protection and output control circuit that out-put supply in parallel and working power voltage are protected and controlled.The utility model is used as the emergency start power supply of metro traction system supplymentary power supply box by the direct step-down of supply voltage that uses Switching Power Supply to get subway power supply network, ban original internal battery, extend whole service life, there is no leakage risk, reduce damage casing mechanical structure being caused due to electrolyte leakage, and reduced and scrapped the rear impact on environment, cost is lower compared with existing internal battery scheme, weight is lighter for the emergency start power supply of employing high frequency switch power.

Brief description of the drawings

In order to be illustrated more clearly in the utility model embodiment or technical scheme of the prior art, to the accompanying drawing of required use in embodiment or description of the Prior Art be briefly described below, apparently, accompanying drawing in the following describes is only embodiment of the present utility model, for those of ordinary skill in the art, do not paying under the prerequisite of creative work, other accompanying drawing can also be provided according to the accompanying drawing providing.

Fig. 1 is the disclosed a kind of emergency start circuit construction of electric power schematic diagram of the utility model embodiment;

Fig. 2 is the disclosed first order tandem tap of the utility model embodiment circuit construction of electric power schematic diagram;

Fig. 3 is the main circuit diagram of the disclosed first order tandem tap of the utility model embodiment power circuit;

Fig. 4 is the disclosed second level of the utility model embodiment switching power circuit structural representation;

Fig. 5 is the main circuit diagram of the disclosed second level of the utility model embodiment switching power circuit.

Embodiment

Below in conjunction with the accompanying drawing in the utility model embodiment, the technical scheme in the utility model embodiment is clearly and completely described, obviously, described embodiment is only the utility model part embodiment, instead of whole embodiment.Based on the embodiment in the utility model, those of ordinary skill in the art are not making the every other embodiment obtaining under creative work prerequisite, all belong to the scope of the utility model protection.

The utility model discloses a kind of emergency start power circuit, comprise the input protection circuit of the supply voltage of getting subway power supply network; Be connected with input protection circuit, supply voltage carried out to dividing potential drop and obtain dividing voltage supply voltage, and dividing voltage supply voltage transitions is become to the first order tandem tap power circuit of output supply voltage in parallel; Be connected with first order tandem tap power circuit, output supply voltage in parallel carried out step-down and obtained the second level switching power circuit of working power voltage; Be connected with second level switching power circuit with first order tandem tap power circuit respectively, power protection and output control circuit that output supply voltage in parallel and working power voltage are protected and controlled.The utility model is used as the emergency start power supply of metro traction system supplymentary power supply box by the direct step-down of supply voltage that uses Switching Power Supply to get subway power supply network, ban original internal battery, extend whole service life, there is no leakage risk, reduce damage casing mechanical structure being caused due to electrolyte leakage, and reduced and scrapped the rear impact on environment, cost is lower compared with existing internal battery scheme, weight is lighter for the emergency start power supply of employing high frequency switch power.

Refer to accompanying drawing 1, for the utility model embodiment discloses a kind of emergency start circuit construction of electric power schematic diagram.The utility model embodiment discloses a kind of emergency start power circuit, comprising: the input protection circuit 101 of getting the supply voltage of subway power supply network; Be connected with described input protection circuit 101, described supply voltage carried out to dividing potential drop and obtain dividing voltage supply voltage, and described dividing voltage supply voltage transitions is become to the first order tandem tap power circuit 102 of output supply voltage in parallel; Be connected with described first order tandem tap power circuit 102, described out-put supply in parallel carried out step-down and obtained the second level switching power circuit 103 of working power voltage; Be connected with described second level switching power circuit 103 with described first order tandem tap power circuit 103 respectively; power protection and output control circuit 104 that described out-put supply in parallel and described working power voltage are protected and controlled; after in emergency start, emergency start power circuit output a period of time enough chargers start, output control circuit is closed described emergency start power supply automatically.In the present embodiment, the supply voltage of subway power supply network described above is 1500VDC, can also adopt the supply voltage of other grades for subway power supply network.

As shown in Figure 1, emergency start power circuit is mainly made up of four parts, after two-stage transformation, obtain working power voltage from the supply voltage of subway power supply network to realize whole emergency start system, wherein first order transformation is realized by first order tandem tap power circuit, because the supply voltage of subway power supply network is too high, therefore it is first divided into obtain dividing voltage supply voltage, again dividing voltage supply voltage power is converted and then obtains output supply voltage in parallel, second level transformation is realized by second level switching power circuit, every one-level switching power circuit all forms negative feedback closed loop control to its output voltage monitoring, in addition, the work of output supply voltage in parallel is also subject to the control of output control circuit and input overvoltage undervoltage detection circuit, and in the time that input power exceeds normal range (NR), emergency start power supply quits work, in the time of emergency start, output circuit output a period of time in parallel, after enough chargers start, output control circuit is closed emergency start power supply automatically.

Above-mentioned the utility model is used as the emergency start power supply of metro traction system supplymentary power supply box by the direct step-down of supply voltage that uses Switching Power Supply to get subway power supply network, ban original internal battery, extend whole service life, there is no leakage risk, reduce damage casing mechanical structure being caused due to electrolyte leakage, and reduced and scrapped the rear impact on environment, cost is lower compared with existing internal battery scheme, weight is lighter for the emergency start power supply of employing high frequency switch power.

Referring to accompanying drawing 2, is the disclosed first order tandem tap of the utility model embodiment circuit construction of electric power schematic diagram.Concrete, as shown in Figure 2, first order tandem tap power circuit 102 described above comprises: the input bleeder circuit 201 that the supply voltage of subway power supply network is carried out to dividing potential drop and obtains dividing voltage supply voltage, at least three that be connected in series and be connected and described dividing voltage supply voltage carried out to the power conversion circuit 202 of power conversion with described input bleeder circuit 201, be connected and carry out the current rectifying and wave filtering circuit 203 of rectifying and wave-filtering with described power conversion circuit 202 respectively, the output of described current rectifying and wave filtering circuit is output in parallel, be connected with described power conversion circuit 202 respectively and drive three drive circuits 204 of corresponding described power conversion circuit and respectively with drive circuit 204 described in a group wherein, described power conversion circuit 202, described input bleeder circuit 201 and the connected pwm control circuit 205 of described output in parallel.

Concrete, as shown in Figure 2, between described power conversion circuit 202 and described pwm control circuit 205, also comprise: be connected and carry out current sample with described power conversion circuit 202, and the electric current of sampling is sent to the current sampling circuit 206 of described pwm control circuit 205 and is connected and carries out the control power circuit 207 of system power supply control with described power conversion circuit 202; Between described input bleeder circuit 201 and described pwm control circuit 205, also comprise: be connected with described input bleeder circuit 201 and carry out overvoltage/undervoltage detection and testing result is passed to the overvoltage/undervoltage testing circuit 208 of described pwm control circuit 205 and is connected to system and carries out the auxiliary power supply circuit 209 of auxiliary power supply with described input bleeder circuit 201; Between described output in parallel and described pwm control circuit 205, also comprise: be connected with described output in parallel and carry out electric current and voltage sampling and sampled result is passed to the voltage sampling circuit 210 of described pwm control circuit 205 and is connected and carries out the over-voltage detection circuit 211 of overvoltage detection with described output in parallel.

Because the input voltage of the supply voltage of subway power supply network is too high, be not suitable for directly turning 250V, thereby the utility model first adopts bleeder circuit that 1500V is divided into three sections, every section of magnitude of voltage is 500V.The power supply that 1500V voltage is turned to 250V voltage becomes three groups of 500V voltages and turns the power supply of the input series connection of 250V voltage.According to above-mentioned concrete description, refer to accompanying drawing 3, be the main circuit diagram of the disclosed first order tandem tap of the utility model embodiment power circuit.

As shown in Figure 3: described input bleeder circuit 201 comprises the resistor capacitor circuit that at least three groups are connected in series, described resistor capacitor circuit comprises the resistance R and the capacitor C that are connected in parallel, one end ground connection of the described resistor capacitor circuit being connected in series, the supply voltage of subway power supply network described in another termination, as shown in Figure 3, on described input bleeder circuit 201, draw two outputs, DR11-and DR12-, described power conversion circuit 202 comprises: one end respectively with the supply voltage of subway power supply network, filter capacitor (the C2 that the output DR11-of input bleeder circuit is connected with DR12-, C5, C8), with described filter capacitor (C2, C5, C8) the connected resistor capacitor circuit in one end, single-phase switch pipe (the D1 that negative electrode is connected with the described resistor capacitor circuit other end, D3, and drain electrode and described single-phase switch pipe (D1 D5), D3, D5) the connected switching tube (Q1 of anode, Q2, Q3), described resistor capacitor circuit comprises the resistance (R1 being connected in parallel, R4, and electric capacity (C1 R7), C4, C7), described switching tube (Q1, Q2, Q3) source electrode and filter capacitor (C2, C5, C8) the other end is connected, and the source electrode of described switching tube Q3 is through resistance R 10 ground connection, described switching tube (Q1, Q2, Q3) drain electrode and the other end of described resistor capacitor circuit respectively with transformer (TR1, TR2, TR3) former limit is connected, described transformer (TR1, TR2, TR3) secondary is the output of described power conversion circuit, described switching tube (Q1, Q2, Q3) grid and driving voltage (DR11+, DR12+, DR13+) being connected, is described switching tube (Q1, Q2, Q3) provide driving power.Described resistance R 10 is the sampling resistor in current sampling circuit 206, and the voltage signal ISIN of resistance R 10 is sent to pwm control circuit 205.The additional winding of described transformer (TR1, TR2) is vacant, and transformer (TR1, TR2) one end is connected with DR12-with DR11-respectively in the present embodiment, and the other end is unsettled; The output VCC5V voltage of the additional winding of described transformer TR3, is the control circuit power supply on the former limit of described transformer TR3, and the secondary of described transformer (TR1, TR2, TR3) is the output of described power conversion circuit.Described current rectifying and wave filtering circuit 203 comprises: the single-phase switch pipe (D2, D4, D6), resistance (R2, R5, R8) and the electric capacity (C3, C6, C9) that are connected in series, the anode of described single-phase switch pipe (D2, D4, D6) is connected with an output of described power conversion circuit, the other end of another output of described power conversion circuit and described electric capacity (C3, C6, C9) is connected and ground connection, and the ungrounded end of described electric capacity (C3, C6, C9) is the output of current rectifying and wave filtering circuit.By above-mentioned input bleeder circuit, the supply voltage of subway power supply network (as 1500V) is divided into 3 sections of dividing voltage supply voltages (as 500V) that magnitude of voltage is equal, then by conversion and the last output-parallel output supply voltage of rectifying and wave-filtering effect (as 250V) of power conversion circuit and current rectifying and wave filtering circuit.

Preferably, for protection switch pipe (Q1, Q2, Q3), the source electrode of described switching tube (Q1, Q2, Q3) and grid are connected with resistance (R3, R6, R9); The source electrode of described switching tube (Q1, Q2, Q3) and grid can also be connected with voltage-stabiliser tube (Z1, Z2, Z3), the anode of described voltage-stabiliser tube (Z1, Z2, Z3) is connected with the source electrode of switching tube (Q1, Q2, Q3), and negative electrode is connected with the grid of switching tube (Q1, Q2, Q3).

Above-mentioned description order in bracket is consistent with each other, and its corresponding relation is clearly according to order statement in bracket.

Preferably, first order switching power circuit described above and/or described second level switching power circuit are flyback power circuit.

Referring to accompanying drawing 4, is the disclosed second level of the utility model embodiment switching power circuit structural representation.Concrete, the second level described above switching power circuit 103 is flyback power circuit, as shown in Figure 4, concrete structure comprises: the first power conversion circuit 301 connecting successively, the first current rectifying and wave filtering circuit 302 and the first external output circuit 303, the first pwm control circuit 304 being connected with described the first current rectifying and wave filtering circuit 302 with described the first power conversion circuit 301 respectively and the first order control circuit 305 being connected with the described first external output circuit 303 with described the first current rectifying and wave filtering circuit 302 respectively, wherein, between described the first power conversion circuit 301 and described the first pwm control circuit 304, be provided with drive circuit 205, current sampling circuit 207 and control power circuit 208, between described the first current rectifying and wave filtering circuit 302 and described the first pwm control circuit 304, be provided with voltage sampling circuit 211, between the described first external output circuit 303 and described first order control circuit 305, be provided with output control circuit 306, between described the first current rectifying and wave filtering circuit 302 and described first order control circuit 305, be provided with over-voltage detection circuit 212, described output control circuit 306 is connected with enabling signal circuit 307, described drive circuit 205 is connected with auxiliary power supply circuit 210.

According to foregoing description, refer to accompanying drawing 5, be the main circuit diagram of the disclosed second level of the utility model embodiment switching power circuit.As shown in Figure 5; the first power conversion circuit 301 comprises: transformer TR4, peripheral hardware capacitor C 11; comprise the resistance R 11 that is connected in parallel and the resistor capacitor circuit of capacitor C 12; and the single-phase switch pipe D11 being connected with described resistor capacitor circuit; the negative electrode of described single-phase switch pipe D11 is connected with described resistor capacitor circuit; its anode is connected with one end, former limit of described transformer TR4; the other end on the former limit of described transformer TR4 is connected with described resistor capacitor circuit, described transformer TR4 is played to the effect of dividing potential drop protection.The first current rectifying and wave filtering circuit 302 comprises: single-phase switch pipe D12 and resistance R 12, the anode of described single-phase switch pipe D12 is connected with secondary one end of described transformer TR4, its negative electrode is connected with one end of described resistance R 12, the other end of described resistance R 12 is connected with one end of the parallel circuits of resistance R 13, capacitor C 13, and its other end is connected and ground connection with the secondary other end of described transformer TR4.The grid of described switching tube Q4 is connected with the output PWM of first order control circuit with resistance R 14 by single-phase switch pipe D13, and be connected with the output PWM of first order control circuit by resistance R 15, in the time of PWM input high level, by resistance R 15, control switch pipe Q4 opens, in the time of PWM input low level, described switching tube Q4 turn-offs, electric current, by single-phase switch pipe D13 and resistance R 14, accelerates the shutoff of described switching tube Q4, and resistance R 15 is in parallel with single-phase switch pipe D13 and resistance R 14; The grid of switching tube Q4 is connected with voltage-stabiliser tube Z4, switching tube Q4 is played to power protection and control signal input action, meanwhile, a described voltage-stabiliser tube Z4 resistance R 16 in parallel, described voltage-stabiliser tube Z4 is carried out to the protection of voltage dividing potential drop, and the source electrode of switching tube Q4 is connected with the positive pole of voltage-stabiliser tube Z4; The source electrode of described switching tube Q4 is through resistance R 18 ground connection, and described resistance R 18 two ends are parallel with the resistance R 17 and the capacitor C 14 that are connected in series, gathers the voltage signal ISIN2 at capacitor C 14 two ends and exports the first pwm control circuit 304 of second level switching power circuit to.First order control circuit 305 comprises: capacitor C 15, a single-phase switch pipe D14 and a resistance R 19, and resistance R 20, one end ground connection of the additional winding of described transformer TR4, the other end is connected with the anode of single-phase switch pipe D14 through resistance R 19, the negative electrode of described single-phase switch pipe D14 is through capacitor C 15 ground connection, the negative electrode of described single-phase switch pipe D14 also connects the output supply voltage in parallel (VCC250V voltage) of first order tandem tap power circuit through resistance R 20, the negative electrode output 15V voltage of described single-phase switch pipe D14 is the control circuit power supply on the former limit of transformer TR4.In the time that described emergency start power circuit has just started, the voltage of the control circuit on the former limit of described transformer TR4 is provided after resistance R 20 and capacitor C 15 by the output supply voltage in parallel of first order tandem tap power circuit, when after the normal work of transformer TR4, the voltage of the control circuit on the former limit of its transformer TR4 is provided after resistance R 19, single-phase switch pipe D14 and capacitor C 15 by the output voltage of the additional winding of transformer TR4.In the time that the control signal (pwm signal) of switching tube Q4 is high level, switching tube Q4 opens, transformer TR4 stored energy, and in the time that switching tube Q4 closes, transformer TR4 is to secondary output energy.

In sum: the utility model discloses a kind of emergency start power circuit, comprise the input protection circuit of the supply voltage of getting subway power supply network; Be connected with input protection circuit, supply voltage carried out to dividing potential drop and obtain dividing voltage supply voltage, and dividing voltage supply voltage transitions is become to the first order tandem tap power circuit of output supply voltage in parallel; Be connected with first order tandem tap power circuit, out-put supply in parallel carried out step-down and obtained the second level switching power circuit of working power voltage; Be connected with second level switching power circuit with first order tandem tap power circuit respectively, power protection and output control circuit that out-put supply in parallel and working power voltage are protected and controlled.The utility model is used as the emergency start power supply of metro traction system supplymentary power supply box by the direct step-down of supply voltage that uses Switching Power Supply to get subway power supply network, ban original internal battery, under subway operating mode, can reach 20 years useful life, extend whole service life, there is no leakage risk, reduce damage casing mechanical structure being caused due to electrolyte leakage, and reduced and scrapped the rear impact on environment, cost is lower compared with existing internal battery scheme, weight is lighter for the emergency start power supply of employing high frequency switch power.

To the above-mentioned explanation of the disclosed embodiments, make professional and technical personnel in the field can realize or use the utility model.To be apparent for those skilled in the art to the multiple amendment of these embodiment, General Principle as defined herein can, in the situation that not departing from spirit or scope of the present utility model, realize in other embodiments.Therefore, the utility model will can not be restricted to these embodiment shown in this article, but will meet the widest scope consistent with principle disclosed herein and features of novelty.

Claims (10)

1. an emergency start power circuit, is characterized in that, comprising:

Get the input protection circuit of the supply voltage of subway power supply network;

Be connected with described input protection circuit, described supply voltage carried out to dividing potential drop and obtain dividing voltage supply voltage, and described dividing voltage supply voltage transitions is become to the first order tandem tap power circuit of output supply voltage in parallel;

Be connected with described first order tandem tap power circuit, described output supply voltage in parallel carried out step-down and obtained the second level switching power circuit of working power voltage;

Be connected with described second level switching power circuit with described first order tandem tap power circuit respectively; power protection and output control circuit that described output supply voltage in parallel and described working power voltage are protected and controlled; after in emergency start, emergency start power circuit output a period of time enough chargers start, output control circuit is closed described emergency start power supply automatically.

2. emergency start power circuit according to claim 1, is characterized in that, described first order tandem tap power circuit comprises:

The supply voltage of subway power supply network is carried out to dividing potential drop and obtains the input bleeder circuit of dividing voltage supply voltage;

At least three that be connected in series and be connected and described dividing voltage supply voltage carried out to the power conversion circuit of power conversion with described input bleeder circuit;

Be connected and carry out the current rectifying and wave filtering circuit of rectifying and wave-filtering with described power conversion circuit respectively, the output of described current rectifying and wave filtering circuit is output in parallel;

Be connected with described power conversion circuit respectively and drive three drive circuits of corresponding power translation circuit;

And the pwm control circuit being connected with described drive circuit, described power conversion circuit, described input bleeder circuit and described output in parallel respectively.

3. emergency start power circuit according to claim 2, is characterized in that, between described power conversion circuit and described pwm control circuit, also comprises:

Be connected and carry out current sample with described power conversion circuit, and the electric current of sampling is sent to the current sampling circuit of described pwm control circuit;

Be connected with described power conversion circuit and carry out the control power circuit of system power supply control.

4. emergency start power circuit according to claim 2, is characterized in that, between described input bleeder circuit and described pwm control circuit, also comprises:

The overvoltage/undervoltage testing circuit that is connected and carries out overvoltage/undervoltage detection and testing result is passed to described pwm control circuit with described input bleeder circuit;

Be connected to system and carry out the auxiliary power supply circuit of auxiliary power supply with described input bleeder circuit.

5. emergency start power circuit according to claim 2, is characterized in that, between described output in parallel and described pwm control circuit, also comprises:

The voltage sampling circuit that carries out electric current and voltage sampling and sampled result is passed to described pwm control circuit is connected with described output circuit in parallel;

Be connected and carry out the over-voltage detection circuit of overvoltage detection with described output in parallel.

6. emergency start power circuit according to claim 2, it is characterized in that, described input bleeder circuit comprises the resistor capacitor circuit that at least three groups are connected in series, described resistor capacitor circuit comprises the resistance and the electric capacity that are connected in parallel, one end ground connection of the described resistor capacitor circuit being connected in series, the supply voltage of subway power supply network described in another termination.

7. emergency start power circuit according to claim 2, is characterized in that, described power conversion circuit comprises: filter capacitor (C2, C5, C8), with described filter capacitor (C2, C5, C8) the connected resistor capacitor circuit in one end, single-phase switch pipe (the D1 that negative electrode is connected with the described resistor capacitor circuit other end, D3, and drain electrode and described single-phase switch pipe (D1 D5), D3, D5) the connected switching tube (Q1 of anode, Q2, Q3), described resistor capacitor circuit comprises the resistance (R1 being connected in parallel, R4, and electric capacity (C1 R7), C4, C7), described switching tube (Q1, Q2, Q3) source electrode and filter capacitor (C2, C5, C8) the other end is connected, and the source electrode of described switching tube Q3 is through resistance R 10 ground connection, described switching tube (Q1, Q2, Q3) drain electrode and the other end of described resistor capacitor circuit respectively with transformer (TR1, TR2, TR3) former limit is connected, described transformer (TR1, TR2, TR3) secondary is the output of described power conversion circuit.

8. emergency start power circuit according to claim 2, it is characterized in that, described current rectifying and wave filtering circuit comprises: the single-phase switch pipe (D2 being connected in series, D4, D6), resistance (R2, R5, and electric capacity (C3 R8), C6, C9), described single-phase switch pipe (D2, D4, D6) anode is connected with an output of described power conversion circuit, another output of described power conversion circuit and described electric capacity (C3, C6, C9) the other end is connected and ground connection, described electric capacity (C3, C6, C9) ungrounded end is the output of described current rectifying and wave filtering circuit.

9. emergency start power circuit according to claim 1, is characterized in that, described first order switching power circuit and/or described second level switching power circuit are flyback power circuit.

10. emergency start power circuit according to claim 1, it is characterized in that, described second level switching power circuit comprises: the first power conversion circuit, the first current rectifying and wave filtering circuit and the first external output circuit that connect successively, the first pwm control circuit being connected with described the first current rectifying and wave filtering circuit with described the first power conversion circuit respectively and the first order control circuit being connected with the described first external output circuit with described the first current rectifying and wave filtering circuit respectively, wherein

Between described the first power conversion circuit and described the first pwm control circuit, be provided with drive circuit, current sampling circuit and control power circuit, between described the first current rectifying and wave filtering circuit and described the first pwm control circuit, be provided with voltage sampling circuit, between the described first external output circuit and described first order control circuit, be provided with output control circuit, between described the first current rectifying and wave filtering circuit and described first order control circuit, be provided with over-voltage detection circuit, described output control circuit is connected with enabling signal circuit, described drive circuit is connected with auxiliary power supply circuit.

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