CN205017091U - A alternating current -direct current conversion control circuit and double current method EMUs for double current method EMUs - Google Patents

A alternating current -direct current conversion control circuit and double current method EMUs for double current method EMUs Download PDF

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Publication number
CN205017091U
CN205017091U CN201520639064.6U CN201520639064U CN205017091U CN 205017091 U CN205017091 U CN 205017091U CN 201520639064 U CN201520639064 U CN 201520639064U CN 205017091 U CN205017091 U CN 205017091U
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relay
connects
direct current
normally
normally opened
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王延翠
邓桂美
孙传铭
梁君海
唐兆祥
焦京海
梁建英
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CRRC Qingdao Sifang Co Ltd
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CSR Qingdao Sifang Locomotive and Rolling Stock Co Ltd
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Abstract

The utility model relates to an alternating current -direct current conversion control circuit and double current method EMUs for double current method EMUs. This circuit includes: sensor unit is pressed to the net for detect the net suppression formula of current electric wire netting and net the data signal that suppression formula formed conversion alternating current -direct current change over switch according to this, the complete non -loaded judgement unit of car for output indicates the non -loaded control signal of EMUs when full car uninstallation relay operation, alternating current -direct current change over switch the control unit for be transformed into corresponding alternating current circuit or direct current return circuit according to data signal with alternating current -direct current change over switch when the complete non -loaded judgement unit of car judgement is non -loaded, pantograph the control unit for, alternating current -direct current change over switch carries out a liter bow operation when arranging alternating current circuit in. These double current method EMUs include above -mentioned alternating current -direct current conversion control circuit. The utility model discloses can satisfy EMUs automatic switch -over between AC25kV and DC1500V, the reliability is high, and the suitability is strong.

Description

For AC-DC conversion control circuit and the double-current system motor train unit of double-current system motor train unit
Technical field
The utility model relates to automatic control technology field, particularly relates to a kind of AC-DC conversion control circuit for double-current system motor train unit and double-current system motor train unit.
Background technology
Multithread motor train unit in current use needs manual switching or utilizes network control to automatically switch.Wherein, when utilizing network control to automatically switch, need fixed line or driving route are provided with signalling, know to make motor train unit the net pressing type parameter running front electrical network in time.But, there is no multithread motor train unit at home at present and use, and also there is no corresponding line condition.
Along with future market is to the demand of the motor train unit of AC25kV and DC1500V two kinds of standards, need a kind of AC-DC conversion control circuit of exploitation badly, enable motor train unit on the line without electrical network net pressure signal supervisory instrument when, the same circuit of manual switchover ac/dc power supply system or on independently ac/dc power supply system circuit alternating current-direct current realize switching controls, and reliability service.
Utility model content
One of them object of the present utility model is to provide a kind of AC-DC conversion control circuit for double-current system motor train unit and double-current system motor train unit, when reaching without the need to installing net pressure signal supervisory instrument, motor train unit electrical network can be automatically switched between direct current network and AC network.
First aspect, the utility model embodiment provides a kind of AC-DC conversion control circuit for double-current system motor train unit, comprise: net pressure sensor unit, AC-DC conversion switch control unit, pantograph control unit, the complete non-loaded judging unit of car and switch positions determining unit, wherein:
Described net pressure sensor unit, for detecting the net pressing type of current electric grid and forming the digital signal changing AC-DC conversion switch according to this net pressing type;
The non-loaded judging unit of described full car, carries for judging whether motor train unit is with;
Described AC-DC conversion switch control unit, for being transformed into corresponding ac circuit or DC loop according to described digital signal by AC-DC conversion switch when the non-loaded judging unit of described full car judges non-loaded;
Described pantograph control unit, for carrying out the operation of lifting bow when AC-DC conversion switch is placed in ac circuit, or keeps pantograph state constant when the conversion of described AC-DC conversion switch switches between ac circuit and DC loop.
Alternatively, described AC-DC conversion switch control unit comprise exchange control subelement, for be placed in DC side at AC-DC conversion switch and pantograph is non-bent time formed switching signal be converted to AC to make this AC-DC conversion switch from DC side.
Alternatively, described interchange controls that subelement comprises full car unloading relay, bow order relay, AC-DC conversion change over switch combined floodgate auxiliary relay, AC relay and alternating current electromagnetic valve and direct current relay fall in direct current net potential relay, pantograph, wherein:
First normally opened contact of described full car unloading relay connects the first voltage input end, and the second normally opened contact connects the first normally-closed contact of described direct current net potential relay, and connects the first normally-closed contact that bow order relay falls in described pantograph;
First normally-closed contact of described AC-DC conversion change over switch combined floodgate auxiliary relay connects the second normally-closed contact of described direct current net potential relay, and the second normally-closed contact of bow order relay falls in described pantograph, the second normally-closed contact connects the first end of the coil of described AC relay; Second end of the coil of described AC relay connects the second voltage input end;
The first normally-closed contact that bow order relay falls in described pantograph connects the first voltage input end, and the second normally-closed contact connects the first normally opened contact of described AC relay;
First normally opened contact of described direct current relay connects the first voltage input end, and the second normally opened contact connects the first normally opened contact of described AC relay;
Second normally opened contact of described AC relay connects the first end of the coil of described alternating current electromagnetic valve; Second end of the coil of described alternating current electromagnetic valve connects the second voltage input end.
Alternatively, described AC-DC conversion switch control unit also comprises DC control subelement, for only detect at net pressure sensor direct current net pressure, the unloading of full car and pantograph rising bow time conducting direct current electromagnetically operated valve be converted to DC side to make this AC-DC conversion switch from AC.
Alternatively, described DC control subelement comprises the first direct current transfer delay relay, bow order relay, full car unloading relay, AC network potential relay, AC-DC conversion switch direct current combined floodgate auxiliary relay, direct current relay, AC relay and DC electromagnetic valve fall in the second direct current transfer delay relay, direct current net potential relay, pantograph, wherein:
First normally opened contact of described first direct current transfer delay relay connects the first voltage input end, and the second normally opened contact connects the first normally opened contact of described second direct current transfer delay relay;
The first end of the coil of described direct current net potential relay connects the second normally opened contact of described second direct current transfer delay relay, and the second end connects the second voltage input end;
The first normally opened contact that bow order relay falls in described pantograph connects the first voltage input end, and the second normally opened contact connects the first normally opened contact of described full car unloading relay;
First normally-closed contact of described AC network potential relay connects the second normally opened contact of described full car unloading relay, and the second normally-closed contact connects the first normally-closed contact of described AC-DC conversion switch direct current combined floodgate auxiliary relay; Second normally-closed contact of described AC-DC conversion switch direct current combined floodgate auxiliary relay connects the first end of the coil of described direct current relay;
First normally opened contact of described direct current net potential relay connects the second end of the coil of described direct current relay, and the second normally opened contact connects the second voltage input end;
First normally closed normally opened contact of described AC relay connects the first voltage input end, and the second end connects the first normally opened contact of described direct current relay; Second normally opened contact of described direct current relay connects the first end of the coil of described DC electromagnetic valve; Second end of the coil of described DC electromagnetic valve connects the second voltage input end.
Alternatively, the non-loaded judging unit of described full car comprises multiple unloading detection module, each unloading detection module is for detecting the loading condition in two joint compartments in a power unit, each unloading detection module comprises DC loop main circuit breaker relay in first segment compartment, DC loop earthed switch relay and the first full car unloading relay, and ac circuit earthed switch relay in second section compartment and ac circuit main circuit breaker relay; Wherein,
The first end of the coil of the described first full car unloading relay connects the second voltage input end, and the second end connects the first normally-closed contact of described DC loop earthed switch relay;
First normally-closed contact of described DC loop main circuit breaker relay connects the second normally-closed contact of described DC loop earthed switch relay, and the second normally-closed contact of described DC loop main circuit breaker relay connects the first normally-closed contact of described ac circuit earthed switch relay;
First normally-closed contact of ac circuit main circuit breaker relay connects the second normally-closed contact of described ac circuit earthed switch relay, and the second normally-closed contact connects the first normally opened contact of the described first full car unloading relay;
Second normally opened contact of the described first full car unloading relay connects the first voltage input end.
Alternatively, described pantograph control unit comprise four with door and one or, wherein:
First be connected ac circuit main circuit breaker auxiliary relay signal with the first input end of door, the second input connects ac circuit earthed switch relay signal and connect with the 3rd input and exchange auxiliary relay signal;
The second master controller relay being connected the first compartment with the first input end of door, the second input connect the display pantograph climb command end in the first compartment;
3rd to be connected the display pantograph climb command end that the master controller relay in the first compartment and the second input connect the first compartment with the first input end of door;
Or the first input end of door connects the output of second and door, the second input connects the output of the 3rd and door;
4th to be connected with the first input end of door first with the output of door, the second input connects or the output of door, and output exports pantograph rising control signal.
Alternatively, also comprise interlocking unit, for running through signal accordingly and carry out alternating current-direct current loop switch to make traction convertor detecting that ac circuit or DC loop are formed when connecting.
The utility model embodiment is by this control circuit identification and the action controlling AC-DC conversion switch, thus correct connection ac main circuit or direct current major loop.The utility model can meet intercity motor train unit and be applicable to AC25kV and DC1500V power supply mode, and according to net pressing type automatic switchover major loop, reliability is high, and applicability is strong.
Accompanying drawing explanation
Can understanding feature and advantage of the present utility model clearly by reference to accompanying drawing, accompanying drawing is schematic and should not be construed as and carry out any restriction to the utility model, in the accompanying drawings:
Fig. 1 is a kind of double-current system motor train unit traction system major loop block diagram that the utility model embodiment provides;
Fig. 2 is the AC-DC conversion control circuit block diagram of a kind of double-current system motor train unit that the utility model embodiment provides;
Fig. 3 is the control circuit schematic diagram of net pressure sensor unit in the control circuit of AC-DC conversion shown in Fig. 2;
Fig. 4 is the control circuit schematic diagram of AC-DC conversion switch control unit in the control circuit of AC-DC conversion shown in Fig. 2;
Fig. 5 is the control loop schematic diagram of pantograph control unit in the control circuit of AC-DC conversion shown in Fig. 2;
Fig. 6 is the control logic schematic diagram of the control unit of pantograph shown in Fig. 5;
Fig. 7 is DC control subelement control loop schematic diagram in the control unit of AC-DC conversion switch shown in Fig. 2;
Fig. 8 exchanges in the control unit of AC-DC conversion switch shown in Fig. 2 to control subelement control loop schematic diagram;
Fig. 9 is the control loop schematic diagram of the complete non-loaded judging unit of car in the control circuit of AC-DC conversion shown in Fig. 2;
Figure 10 unloads detection module control loop schematic diagram in the complete non-loaded judging unit of car shown in Fig. 9;
Figure 11 is the alternating current-direct current interlock circuit schematic diagram of the AC-DC conversion control circuit that the utility model embodiment provides;
Part description of reference numerals: 1, AEVTR-AC network potential relay; 2, ALEVTR-exchanges interlocking relay; 3, ATSCR-change over switch exchanges combined floodgate auxiliary relay; 4, ATSCRR-exchanges auxiliary relay; 5, ATSCV-alternating current electromagnetic valve; 6, ATSOR-change over switch exchanges separating brake auxiliary relay; 7, DEVTD1-direct current transfer delay relay; 8, DLEVTR-direct current interlocking relay; 9, DS-DC loop earthed switch; 10, DSR-DS relay; 11, DTSCV-DC electromagnetic valve; 12, DTSCR-change over switch direct current combined floodgate auxiliary relay; 13, DTSOR-change over switch direct current separating brake auxiliary relay; 14, EGS-ac circuit earthed switch; 15, EGSR-EGS relay; 16, MCR-master controller relay; 17, PanDCCR-pantograph isolating switch relay; 18, bow order relay falls in PanDR1-pantograph; 19, PanUS: pantograph raise switch; 20, PanCGS-pantograph diverter switch; 21, PanUR1-pantograph rising bow relay; 22, HSCB-DC loop main circuit breaker; 23, HSCBR-HSCB relay; 24, VCB-ac circuit main circuit breaker; 25, VCBRR-VCB auxiliary relay.
Embodiment
Below in conjunction with drawings and Examples, embodiment of the present utility model is described in further detail.Following examples for illustration of the utility model, but are not used for limiting scope of the present utility model.
Fig. 1 shows the utility model embodiment and provides a kind of double-current system motor train unit traction system, and wherein the major loop of this trailer system comprises pantograph, AC-DC conversion switch, ac high-voltage equipment, traction transformer, HVDC Equipment, traction convertor and hauling machine.Wherein pantograph shares, and can be operated under exchanging standard or direct current standard.AC-DC conversion switch connects transmission line by pantograph, and this transmission line can provide the voltage exchanging 25kV or direct current 1500V.AC-DC conversion switch action under the control of control circuit is switched to AC or DC side, connects ac circuit when AC-DC conversion switch TS is positioned at AC, connects DC loop when AC-DC conversion switch TS is positioned at DC side.
For realizing switching ac main circuit and direct current major loop not installing under line voltage standard signal checkout gear scene, the utility model embodiment provides a kind of AC-DC conversion control circuit for double-current system motor train unit, as shown in Figure 2, comprise: net pressure sensor unit, AC-DC conversion switch control unit, the complete non-loaded judging unit of car and switch positions determining unit, wherein:
Net pressure sensor unit, for detecting the net pressing type of current electric grid and forming the digital signal changing AC-DC conversion switch according to this net pressing type;
Full car is non-loaded judging unit, carries for judging whether full car is with;
AC-DC conversion switch control unit, for being transformed into corresponding ac circuit or DC loop according to digital signal by AC-DC conversion switch when the non-loaded judging unit of described full car judges non-loaded;
Pantograph control unit, for carrying out rising bow operation when AC-DC conversion switch is placed in ac circuit.
The utility model embodiment is by the net pressing type of net pressure sensor identification electrical network, and the working state signal (comprising control signal and auxiliary contact signal) combining ac circuit main circuit breaker, DC loop main circuit breaker and AC-DC conversion switch in the major loop that gathers controls AC-DC conversion switch action, thus realize motor train unit and reliably switch in different electrical network.With need signalization checkout gear in prior art and arrange compared with network control system, the utility model without the need to signal supervisory instrument, need not manual operation, applicability stronger, and effectively can improve fail safe and abnormal disposal efficiency.
In practical application, as shown in Figure 3, when after motor train unit rising bow, now rising bow relay PanUR1 obtains electric, and normally opened contact closes, and thus in net pressure sensor unit, net pressure sensor powers on.After the net pressing type of this net pressure sensor detection of grid (exchanging 25kV or direct current 1500V), output AC and DC analogue quantity signal and digital quantity signal.Analog signals shows and synchronizing signal, with conducting as pantograph rising bow relay PanUR1 in Fig. 3 for netting pressure.Digital quantity signal is used for the conducting of circuit identification net pressing type as the coil of the first direct current transfer delay relay DEVTD1, the second direct current transfer delay relay DEVTD2 or AC network potential relay AEVTR in Fig. 3.
In practical application, the relay that the utility model embodiment adopts comprises one group of voltage input end (connecting positive source and power cathode), one group of normally opened contact (comprising the first normally opened contact and the second normally opened contact) and one group of normally-closed contact (comprising the first normally-closed contact and the second normally-closed contact), those skilled in the art can according to circumstances select, and the utility model is not construed as limiting.
Alternatively, in the utility model embodiment, AC-DC conversion switch TS is electric-controlled pneumatic type, control circuit as shown in Figure 4, AC-DC conversion switch TS is converted to the operating principle of DC side from AC: when AC-DC conversion switch TS is in AC state, change over switch direct current combined floodgate auxiliary relay DTSCR obtains electric, makes DC electromagnetic valve DTSCV energized action to open gas circuit; Compressed air enters pressure cylinder through DC electromagnetic valve DTSCV, and the rotating shaft promoting joystick rotates 60 °, makes AC-DC conversion switch TS action to DC side.When promoting the axis of rotation of joystick, the actuated by cams switch elements be fixed on main shaft changes state and exports one group of (one often open one normally closed) status signal by relay.Turn to the operating principle of AC identical from DC side, the utility model embodiment repeats no more.
For realizing reliable rising bow, the pantograph control unit that the utility model embodiment provides controls to carry out the operation of lifting bow when AC-DC conversion switch is placed in ac circuit, or makes pantograph hold mode constant when AC-DC conversion switch conversion switches between ac circuit and DC loop.That is, in initial rising bow or when falling bow, AC-DC conversion switch TS must be placed in AC, otherwise can not rising bow;
As shown in Figure 5, when master controller relay MCR is excited, VCB auxiliary relay VCBRR is excited, ac circuit earthed switch relay EGSR is excited and exchange auxiliary relay ATSCRR and be excited, and after operating pantograph raise switch PanUS, according to pantograph diverter switch PanCGS set situation, by corresponding rising bow order line pressurization.
As shown in Figure 6, rising bow control logic circuit comprises: first with door the 1 ~ four and door 4 and or door 5.First be connected ac circuit main circuit breaker auxiliary relay VCBRR signal with the first input end of door, the second input connects ac circuit earthed switch relay EGSR signal and connect with the 3rd input and exchange auxiliary relay ATSCRR signal.Second to be connected the display pantograph climb command M1-UP that the master controller relay MCR (M1) in the first compartment and the second input connect the first compartment with the first input end of door 2.3rd to be connected the display pantograph climb command M2-UP that the master controller relay MCR (M2) in the first compartment and the second input connect the first compartment with the first input end of door 3.Or the first input end of door 5 connects the output of second and door 2, the second input connects the output of the 3rd and door 3.4th to be connected with the first input end of door 4 first with the output of door 1, the second input connects or the output of door 4, and output exports pantograph rising control signal.
DC loop is loaded in order to prevent AC network pressure, be broken down by high-voltage scaling loss or direct current net pressure of DC loop parts is caused to be loaded into ac circuit and to cause traction transformer short circuit, AC-DC conversion control circuit reliable recognition also correctly must connect interchange or DC loop, alternatively, the AC-DC conversion switch control unit that the utility model embodiment provides comprises interchange and controls subelement and DC control subelement.Wherein, this interchange control subelement be used for AC-DC conversion switch be placed in DC side and pantograph non-rising bow time form switching signal and be converted to AC to make this AC-DC conversion switch from DC side.
As shown in Figure 7, interchange control subelement comprises full car unloading relay VHNR, direct current net potential relay DEVTRR1, bow order relay PanDR1, AC-DC conversion change over switch combined floodgate auxiliary relay, AC relay ATSCVR, alternating current electromagnetic valve and direct current relay DTSCVR fall in pantograph, wherein:
First normally opened contact of full car unloading relay VHNR connects the first voltage input end, and the second normally opened contact connects first normally-closed contact of direct current net potential relay DEVTRR1, and connects the first normally-closed contact that bow order relay PanDR1 falls in pantograph; First normally-closed contact of AC-DC conversion change over switch combined floodgate auxiliary relay connects second normally-closed contact of direct current net potential relay DEVTRR1, and connecting the second normally-closed contact that bow order relay PanDR1 falls in pantograph, the second normally-closed contact connects the first end of the coil of AC relay ATSCVR; Second end of the coil of AC relay ATSCVR connects the second voltage input end; The first normally-closed contact that bow order relay PanDR1 falls in pantograph connects the first voltage input end, and the second normally-closed contact connects first normally opened contact of AC relay ATSCVR; First normally opened contact of direct current relay DTSCVR connects the first voltage input end, and the second normally opened contact connects first normally opened contact of AC relay ATSCVR; Second normally opened contact of AC relay ATSCVR connects the first end of the coil of alternating current electromagnetic valve; Second end of the coil of alternating current electromagnetic valve connects the second voltage input end.
AC-DC conversion switch TS needs to be transformed into AC, as shown in Figure 7, need the non-conducting of direct current net potential relay, namely line voltage is that AC network pressure or electrical network are not energized, now alternating current electromagnetic valve ATSCV obtains electric, and AC-DC conversion switch rotating shaft is placed in AC.And when falling bow (the non-conducting of bow order relay PanDR1 falls in pantograph), now alternating current electromagnetic valve ATSCV obtains electric, and AC-DC conversion switch TS action is to AC.
As shown in Figure 7, when full car unloading relay VHNR obtains electric, now when the first normally opened contact and the second normally opened contact conducting, the coil of AC relay ATSCVR obtains electric the first normally opened contact and the second normally opened contact conducting that make AC relay ATSCVR, thus alternating current electromagnetic valve ATSCV obtains electric, AC-DC conversion switch TS by action to AC.
Control logic is shown below:
< condition > 1. ∧ (2. ∨ 3.) ∧ 4. ∧ (3. ∨ 5.) ∧ 6.,
Wherein, 1. full car unloads relay VHNR excitation: entirely arrange unloading;
2. the non-excitation of direct current net potential relay DEVTRR1: net pressure sensor does not detect direct current net pressure;
3. the non-excitation of bow order relay PanDR1 falls in pantograph: non-rising bow state;
4. AC-DC conversion switch exchanges the non-excitation of combined floodgate auxiliary relay ATSCR: AC-DC conversion switch TS is not at AC;
5. the non-excitation of direct current relay DTSCVR;
6. AC relay ATSCVR excitation: 1. ∧ 4. for ∧ (2. ∨ 3.).
Alternatively, this DC control subelement, for only detect at net pressure sensor direct current net pressure, the unloading of full car and pantograph rising bow time conducting direct current electromagnetically operated valve DTSCV be converted to DC side to make this AC-DC conversion switch from AC.
As shown in Figure 8, DC control subelement comprises the first direct current transfer delay relay DEVTD1, bow order relay PanDR1 falls in the second direct current transfer delay relay DEVTD2, direct current net potential relay DEVTRR1, pantograph, full car unloading relay VHNR, AC network potential relay AEVTR, AC-DC conversion switch direct current combined floodgate auxiliary relay DTSCR, direct current relay DTSCVR, AC relay ATSCVR and DC electromagnetic valve DTSCV, wherein:
First normally opened contact of the first direct current transfer delay relay DEVTD1 connects the first voltage input end, and the second normally opened contact connects the first normally opened contact of the second direct current transfer delay relay; The first end of the coil of direct current net potential relay DEVTRR1 connects the second normally opened contact of the second direct current transfer delay relay, and the second end connects the second voltage input end; The first normally opened contact that bow order relay PanDR1 falls in pantograph connects the first voltage input end, and the second normally opened contact connects first normally opened contact of full car unloading relay VHNR; First normally-closed contact of AC network potential relay AEVTR connects second normally opened contact of full car unloading relay VHNR, and the second normally-closed contact connects first normally-closed contact of AC-DC conversion switch direct current combined floodgate auxiliary relay DTSCR; Second normally-closed contact of AC-DC conversion switch direct current combined floodgate auxiliary relay DTSCR connects the first end of the coil of direct current relay DTSCVR; First normally opened contact of direct current net potential relay DEVTRR1 connects the second end of the coil of direct current relay DTSCVR, and the second normally opened contact connects the second voltage input end; The first normally closed normally opened contact of AC relay ATSCVR connects the first voltage input end, and the second end connects first normally opened contact of direct current relay DTSCVR; Second normally opened contact of direct current relay DTSCVR connects the first end of the coil of DC electromagnetic valve DTSCV; Second end of the coil of DC electromagnetic valve DTSCV connects the second voltage input end.
As shown in Figure 8, when direct current net pressure being detected, when namely direct current net potential relay DEVTRR1 is excited, DC electromagnetic valve DTSCV obtains electric thus makes its first normally opened contact and the second normally opened contact conducting; When its first normally opened contact and the second normally opened contact conducting when bow order relay PanDR1 obtains electric fall in pantograph, and when full car unloading relay VHNR obtains its first normally opened contact electric and the second normally opened contact conducting, direct current relay DTSCVR coil obtains electric, first normally opened contact of this direct current relay DTSCVR and the second normally opened contact conducting, thus AC-DC conversion switch TS is transformed into DC side.
Control logic is shown below:
< condition >
first direct current transfer delay relay DEVTD1: net pressure sensor detects direct current net pressure (time delay 1S closes);
second direct current transfer delay relay DEVTD2: net pressure sensor detects direct current net pressure (time delay 1S closes);
direct current net potential relay DEVTRR1 excitation:
bow order relay PanDR1 excitation falls in pantograph: rising bow state;
full car unloading relay VHNR excitation: entirely arrange unloading;
the non-excitation of AC network potential relay AEVTR: net pressure sensor does not detect AC network pressure;
the non-excitation of AC-DC conversion switch direct current combined floodgate auxiliary relay DTSCR: AC-DC conversion switch TS is not in direct current position;
direct current relay DTSCVR excitation:
the non-excitation of AC relay ATSCVR.
In practical application, AC-DC conversion switch TS or netting twine scaling loss when AC-DC conversion switch band TS carries action, can be caused.For preventing above-mentioned phenomenon, alternatively, as shown in Figure 9, the AC-DC conversion switch control unit that the utility model embodiment provides also comprises the non-loaded judging unit of full car, and the non-loaded judging unit of this full car is used for the conducting full car unloading electromagnetically operated valve when full car ac circuit earthed switch, full car DC loop earthed switch, ac circuit main circuit breaker and DC loop main circuit breaker disconnect.
Alternatively, full car is non-loaded, and judging unit comprises multiple unloading detection module, as shown in Figure 10, each unloading detection module is for detecting the loading condition in two joint compartments in a power unit, each unloading detection module comprises DC loop main circuit breaker relay HSCBR, DC loop earthed switch relay DSR and first in first segment compartment full car unloading relay VHNR, and ac circuit earthed switch relay EGS in second section compartment and ac circuit main circuit breaker relay VCBR; Wherein,
The first end of the coil of the first full car unloading relay VHNR connects the second voltage input end, and the second end connects first normally-closed contact of DC loop earthed switch relay DSR;
First normally-closed contact of DC loop main circuit breaker relay HSCBR connects second normally-closed contact of DC loop earthed switch relay DSR, and second normally-closed contact of DC loop main circuit breaker relay HSCBR connects first normally-closed contact of ac circuit earthed switch relay EGS;
First normally-closed contact of ac circuit main circuit breaker relay VCBR connects second normally-closed contact of ac circuit earthed switch relay EGS, and the second normally-closed contact connects first normally opened contact of the first full car unloading relay VHNR;
Second normally opened contact of the first full car unloading relay VHNR connects the first voltage input end.
In practical application, a power unit generally includes two adjacent joint compartment, i.e. first segment compartment and second section compartments.Certainly, the compartment that those skilled in the art also can arrange varying number realizes, and the utility model is not construed as limiting.
As shown in Figures 9 and 10, multiple unloading detection module is mutually connected thus can be formed the non-loaded judging unit of full car, by detecting the loading condition of full car, thus the situation of AC-DC conversion switch TS or the netting twine scaling loss caused when AC-DC conversion switch band TS carries action can be prevented.
As shown in figure 11, when detecting after motor train unit rising bow that AC-DC conversion switch TS is placed in ac circuit, namely AC network potential relay AEVTR excitation, the non-excitation of direct current net potential relay DEVTRR1, change over switch exchange combined floodgate auxiliary relay ATSCR excitation and pantograph isolating switch relay PanDCCR excitation.During AC network potential relay AEVTR excitation, interchange interlocking runs through line LAC and pressurizes; The AC network potential relay ALEVTR excitation of rising bow vehicle, interchange interlocking runs through line LAC and pressurizes; Ac circuit main circuit breaker VCB place vehicle ALEVTR2 excitation makes its normally opened contact be concatenated into ac circuit main circuit breaker VCB closed-loop path, thus it is closed to control ac circuit main circuit breaker VCB.
Detect after motor train unit rising bow that AC-DC conversion switch TS is connected to DC loop, namely the non-excitation of direct current net potential relay DEVTRR1, change over switch exchange separating brake auxiliary relay ATSOR excitation, AC-DC conversion switch direct current combined floodgate auxiliary relay DTSCR excitation.During the direct current net potential relay DLEVTR excitation of rising bow vehicle, direct current interlocking runs through line LDC and pressurize, after traction convertor obtains this signal, controls DC loop main circuit breaker relay HSCB closed.Interchange interlocking and direct current interlocking run through line LDC signal and are input to traction convertor, and traction convertor controls inner alternating current-direct current loop switch accordingly.
Below, the working condition of the AC-DC conversion control circuit that the utility model embodiment provides is described in detail.
The first situation: when electrical network is AC25kV, circuit operation process is as follows:
(1) confirm that AC-DC conversion switch TS is positioned at AC by TCMS (TrainControlandManagementSystem, Train Control and management system) display, and full row are non-loaded.
(2) operate driving position rising bow knob or TCMS display rising bow button, pantograph rises, and high voltage isolator closes.
(3) AC network pressure detected, AC-DC conversion switch TS keeps AC.Exchange interlocking and run through line pressurization, allow ac circuit main circuit breaker VCB to drop into.
(4), when operation pantograph is fallen, ac circuit main circuit breaker VCB disconnects, and AC-DC conversion switch TS keeps AC.
The second situation: when the net pressing type of electrical network is direct current DC1500V, circuit operation process is as follows:
(1) confirm that AC-DC conversion switch TS is positioned at AC by TCMS display, and full row are non-loaded.
(2) operate driving position rising bow knob or TCMS display rising bow button, pantograph rises, and high voltage isolator closes.
(3) direct current net pressure detected, AC-DC conversion switch TS is transformed into DC side.Direct current interlocking runs through line pressurization, allows DC loop main circuit breaker HSCB to drop into.
(4), when operation pantograph is fallen, DC loop main circuit breaker HSCB disconnects, and AC-DC conversion switch TS is transformed into AC.
The third situation: when the voltage of electrical network is from AC25kV → without electricity → DC1500V, circuit operation process is as follows:
(1) confirm that AC-DC conversion switch TS is positioned at AC by TCMS display, and full row are non-loaded.
(2) operate driving position rising bow knob or TCMS display rising bow button, pantograph rises, and high voltage isolator closes.
(3) AC network pressure detected, AC-DC conversion switch TS keeps AC.Exchange interlocking and run through line pressurization, allow ac circuit main circuit breaker VCB to drop into.
(4) when contact line is without electricity, TS keeps AC.Exchange interlocking and run through line without electricity, ac circuit main circuit breaker VCB disconnects.
(5) when contact line is DC1500V, AC-DC conversion switch TS is transformed into DC side.Direct current interlocking runs through line pressurization, allows DC loop main circuit breaker HSCB to drop into.
(6), when operation pantograph is fallen, DC loop main circuit breaker HSCB disconnects, and AC-DC conversion switch TS is transformed into AC.
4th kind of situation: when contact line is DC1500V → without electricity → AC25kV, circuit operation process is as follows:
(1) confirm that full row TS is positioned at AC by TCMS display, and full row are non-loaded.
(2) operate driving position rising bow knob or TCMS display rising bow button, pantograph rises, and high voltage isolator closes.
(3) direct current net pressure detected, TS is transformed into DC side.Direct current interlocking runs through line pressurization, allows HSCB to drop into.
(4) when contact line is without electricity, TS is transformed into AC.Exchange interlocking and run through line without electricity, VCB remains open.
(5) when contact line is AC25kV, AC-DC conversion switch TS keeps AC.Exchange interlocking and run through line pressurization, allow ac circuit main circuit breaker VCB to drop into.
(6), when operation pantograph is fallen, ac circuit main circuit breaker VCB disconnects, and AC-DC conversion switch TS keeps AC.
Alternatively, the control loop that the utility model provides also comprises interlocking unit, for running through signal accordingly and carry out alternating current-direct current loop switch to make traction convertor detecting that ac circuit or DC loop are formed when connecting.
On the other hand, the utility model embodiment further provides a kind of double-current system motor train unit, comprises above-mentioned AC-DC conversion control circuit.The double-current system motor train unit that the utility model embodiment provides is owing to comprising control circuit mentioned above, thus identical technical problem can be solved, realize identical technique effect, specific embodiment can with reference to embodiment above, and the utility model embodiment repeats no longer one by one.
In sum, the AC-DC conversion control circuit for double-current system motor train unit that the utility model embodiment provides and double-current system motor train unit, intercity motor train unit can be met and be applicable to AC25kV and DC1500V power supply mode, automatically the action of AC-DC conversion switch is identified by this control circuit, thus correct connection ac main circuit or direct current major loop, the utility model is according to net pressing type automatic switchover major loop, and reliability is high, and applicability is strong.
Also it should be noted that, in this article, the such as relational terms of first and second grades and so on is only used for an entity or operation to separate with another entity or operating space, and not necessarily requires or imply the relation that there is any this reality between these entities or operation or sequentially.And, term " comprises ", " comprising " or its any other variant are intended to contain comprising of nonexcludability, thus make to comprise the process of a series of key element, method, article or equipment and not only comprise those key elements, but also comprise other key elements clearly do not listed, or also comprise by the intrinsic key element of this process, method, article or equipment.When not more restrictions, the key element limited by statement " comprising ... ", and be not precluded within process, method, article or the equipment comprising described key element and also there is other identical element.
Although describe execution mode of the present utility model by reference to the accompanying drawings, but those skilled in the art can make various modifications and variations when not departing from spirit and scope of the present utility model, such amendment and modification all fall into by within claims limited range.

Claims (9)

1. the AC-DC conversion control circuit for double-current system motor train unit, it is characterized in that, comprise: net pressure sensor unit, AC-DC conversion switch control unit, pantograph control unit, the complete non-loaded judging unit of car and switch positions determining unit, wherein:
Described net pressure sensor unit, for detecting the net pressing type of current electric grid and forming the digital signal changing AC-DC conversion switch according to this net pressing type;
The non-loaded judging unit of described full car, carries for judging whether motor train unit is with;
Described AC-DC conversion switch control unit, for being transformed into corresponding ac circuit or DC loop according to described digital signal by AC-DC conversion switch when the non-loaded judging unit of described full car judges non-loaded;
Described pantograph control unit, for carrying out the operation of lifting bow when AC-DC conversion switch is placed in ac circuit, or keeps pantograph state constant when the conversion of described AC-DC conversion switch switches between ac circuit and DC loop.
2. AC-DC conversion control circuit according to claim 1, it is characterized in that, described AC-DC conversion switch control unit comprises exchanging and controls subelement, for be placed in DC side at AC-DC conversion switch and pantograph non-rising bow time form switching signal and be converted to AC to make this AC-DC conversion switch from DC side.
3. AC-DC conversion control circuit according to claim 2, is characterized in that,
Described interchange controls that subelement comprises full car unloading relay, bow order relay, AC-DC conversion switch combined floodgate auxiliary relay, AC relay and alternating current electromagnetic valve and direct current relay fall in direct current net potential relay, pantograph, wherein:
First normally opened contact of described full car unloading relay connects the first voltage input end, and the second normally opened contact connects the first normally-closed contact of described direct current net potential relay, and connects the first normally-closed contact that bow order relay falls in described pantograph;
First normally-closed contact of described AC-DC conversion switch combined floodgate auxiliary relay connects the second normally-closed contact of described direct current net potential relay, and the second normally-closed contact of bow order relay falls in described pantograph, the second normally-closed contact connects the first end of the coil of described AC relay; Second end of the coil of described AC relay connects the second voltage input end;
The first normally-closed contact that bow order relay falls in described pantograph connects the first voltage input end, and the second normally-closed contact connects the first normally opened contact of described AC relay;
First normally opened contact of described direct current relay connects the first voltage input end, and the second normally opened contact connects the first normally opened contact of described AC relay;
Second normally opened contact of described AC relay connects the first end of the coil of described alternating current electromagnetic valve; Second end of the coil of described alternating current electromagnetic valve connects the second voltage input end.
4. AC-DC conversion control circuit according to claim 1, it is characterized in that, described AC-DC conversion switch control unit also comprises DC control subelement, for only detect at net pressure sensor direct current net pressure, the unloading of full car and pantograph rising bow time conducting direct current electromagnetically operated valve be converted to DC side to make this AC-DC conversion switch from AC.
5. AC-DC conversion control circuit according to claim 4, is characterized in that,
Described DC control subelement comprises the first direct current transfer delay relay, bow order relay, full car unloading relay, AC network potential relay, AC-DC conversion switch direct current combined floodgate auxiliary relay, direct current relay, AC relay and DC electromagnetic valve fall in the second direct current transfer delay relay, direct current net potential relay, pantograph, wherein:
First normally opened contact of described first direct current transfer delay relay connects the first voltage input end, and the second normally opened contact connects the first normally opened contact of described second direct current transfer delay relay;
The first end of the coil of described direct current net potential relay connects the second normally opened contact of described second direct current transfer delay relay, and the second end connects the second voltage input end;
The first normally opened contact that bow order relay falls in described pantograph connects the first voltage input end, and the second normally opened contact connects the first normally opened contact of described full car unloading relay;
First normally-closed contact of described AC network potential relay connects the second normally opened contact of described full car unloading relay, and the second normally-closed contact connects the first normally-closed contact of described AC-DC conversion switch direct current combined floodgate auxiliary relay; Second normally-closed contact of described AC-DC conversion switch direct current combined floodgate auxiliary relay connects the first end of the coil of described direct current relay;
First normally opened contact of described direct current net potential relay connects the second end of the coil of described direct current relay, and the second normally opened contact connects the second voltage input end;
First normally closed normally opened contact of described AC relay connects the first voltage input end, and the second end connects the first normally opened contact of described direct current relay; Second normally opened contact of described direct current relay connects the first end of the coil of described DC electromagnetic valve; Second end of the coil of described DC electromagnetic valve connects the second voltage input end.
6. AC-DC conversion control circuit according to claim 1, it is characterized in that, the non-loaded judging unit of described full car comprises multiple unloading detection module, each unloading detection module is for detecting the loading condition in two joint compartments in a power unit, each unloading detection module comprises DC loop main circuit breaker relay in first segment compartment, DC loop earthed switch relay and the first full car unloading relay, and ac circuit earthed switch relay in second section compartment and ac circuit main circuit breaker relay; Wherein,
The first end of the coil of the described first full car unloading relay connects the second voltage input end, and the second end connects the first normally-closed contact of described DC loop earthed switch relay;
First normally-closed contact of described DC loop main circuit breaker relay connects the second normally-closed contact of described DC loop earthed switch relay, and the second normally-closed contact of described DC loop main circuit breaker relay connects the first normally-closed contact of described ac circuit earthed switch relay;
First normally-closed contact of ac circuit main circuit breaker relay connects the second normally-closed contact of described ac circuit earthed switch relay, and the second normally-closed contact connects the first normally opened contact of the described first full car unloading relay;
Second normally opened contact of the described first full car unloading relay connects the first voltage input end.
7. AC-DC conversion control circuit according to claim 1, is characterized in that, described pantograph control unit comprise four with door and one or, wherein:
First be connected ac circuit main circuit breaker auxiliary relay signal with the first input end of door, the second input connects ac circuit earthed switch relay signal and connect with the 3rd input and exchange auxiliary relay signal;
The second master controller relay being connected the first compartment with the first input end of door, the second input connect the display pantograph climb command end in the first compartment;
3rd to be connected the display pantograph climb command end that the master controller relay in the first compartment and the second input connect the first compartment with the first input end of door;
Or the first input end of door connects the output of second and door, the second input connects the output of the 3rd and door;
4th to be connected with the first input end of door first with the output of door, the second input connects or the output of door, and output exports pantograph rising control signal.
8. the AC-DC conversion control circuit according to claim 1 ~ 7 any one, it is characterized in that, also comprise interlocking unit, for running through signal accordingly and carry out alternating current-direct current loop switch to make traction convertor detecting that ac circuit or DC loop are formed when connecting.
9. a double-current system motor train unit, is characterized in that, comprises the AC-DC conversion control circuit described in claim 1 ~ 8 any one.
CN201520639064.6U 2015-08-21 2015-08-21 A alternating current -direct current conversion control circuit and double current method EMUs for double current method EMUs Active CN205017091U (en)

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CN105141026A (en) * 2015-08-21 2015-12-09 南车青岛四方机车车辆股份有限公司 Alternating current-direct current conversion control circuit for double-current brake motor train unit
CN107046302A (en) * 2016-08-29 2017-08-15 中车青岛四方机车车辆股份有限公司 A kind of EMUs battery charge controller system and its control method
CN108790956A (en) * 2018-05-29 2018-11-13 中国铁道科学研究院集团有限公司 A kind of double-current system train crosses phase-separating section period control method
CN110525276A (en) * 2019-09-09 2019-12-03 中车株洲电力机车有限公司 A kind of EMU alternating current-direct current circuit on side of overhead contact line and its control method
CN110525274A (en) * 2019-09-09 2019-12-03 中车株洲电力机车有限公司 A kind of EMU alternating current-direct current circuit on side of overhead contact line and its control method
CN110674037A (en) * 2019-09-19 2020-01-10 深圳忆联信息系统有限公司 Automatic Microsoft power consumption testing method and device, computer equipment and storage medium
CN111907334A (en) * 2019-06-18 2020-11-10 中车大同电力机车有限公司 Pantograph, control method thereof and electric locomotive
WO2021047089A1 (en) * 2019-09-09 2021-03-18 中车株洲电力机车有限公司 Ac/dc network side circuit of motor train unit and control method therefor
WO2021046963A1 (en) * 2019-09-10 2021-03-18 中车南京浦镇车辆有限公司 Method for controlling automatic switching between vcb and hscb on basis of tcms of dual-current-system train

Cited By (10)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN105141026A (en) * 2015-08-21 2015-12-09 南车青岛四方机车车辆股份有限公司 Alternating current-direct current conversion control circuit for double-current brake motor train unit
CN107046302A (en) * 2016-08-29 2017-08-15 中车青岛四方机车车辆股份有限公司 A kind of EMUs battery charge controller system and its control method
CN107046302B (en) * 2016-08-29 2019-05-21 中车青岛四方机车车辆股份有限公司 A kind of EMU battery charge controller system and its control method
CN108790956A (en) * 2018-05-29 2018-11-13 中国铁道科学研究院集团有限公司 A kind of double-current system train crosses phase-separating section period control method
CN111907334A (en) * 2019-06-18 2020-11-10 中车大同电力机车有限公司 Pantograph, control method thereof and electric locomotive
CN110525276A (en) * 2019-09-09 2019-12-03 中车株洲电力机车有限公司 A kind of EMU alternating current-direct current circuit on side of overhead contact line and its control method
CN110525274A (en) * 2019-09-09 2019-12-03 中车株洲电力机车有限公司 A kind of EMU alternating current-direct current circuit on side of overhead contact line and its control method
WO2021047089A1 (en) * 2019-09-09 2021-03-18 中车株洲电力机车有限公司 Ac/dc network side circuit of motor train unit and control method therefor
WO2021046963A1 (en) * 2019-09-10 2021-03-18 中车南京浦镇车辆有限公司 Method for controlling automatic switching between vcb and hscb on basis of tcms of dual-current-system train
CN110674037A (en) * 2019-09-19 2020-01-10 深圳忆联信息系统有限公司 Automatic Microsoft power consumption testing method and device, computer equipment and storage medium

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Address after: Chengyang District of Shandong city of Qingdao province Jinhong road 266111 No. 88

Patentee after: CRRC QINGDAO SIFANG CO., LTD.

Address before: Chengyang District of Shandong city of Qingdao province Jinhong road 266111 No. 88

Patentee before: CSR Qingdao Sifang Locomotive and Rolling Stock Co., Ltd.