CN204967417U - Incessant DC power supply system - Google Patents

Abstract

The utility model provides an incessant DC power supply system belongs to the continuous current plant field, including the charger, the AC -DC module, the battery, thyristor and trigger circuit, the battery is connected to alternating current power supply through the charger, it is connected to DC output through the thyristor to hold the battery output end, the input of AC -DC module is connected to alternating current power supply, the output of AC -DC module is connected to DC output, trigger circuit's input is connected to the output of charger, trigger circuit's output is connected to the gate electrode of trigger circuit thyristor, trigger circuit includes the triode, base resistance and zener diode, the collecting electrode of triode is connected to the positive pole of battery, the projecting pole of triode is connected to the gate electrode of thyristor, the base of triode is connected to the cathode output of AC -DC module through zener diode, base resistor parallel with is between base and collecting electrode, can realize that the stable of DC power supply switches, maintain and save the cost more.

Description

Uninterrupted DC power system

Technical field

The utility model provides a kind of uninterrupted DC power system, belongs to continuous-current plant field.

Background technology

Industrial a lot of field needs the uninterrupted supply of DC power supply, for power consumption equipment provides lasting, stable power supply, to ensure normally carrying out of production.Existing uninterrupted DC power system, make use of intelligent controller to control switching device, by compiled burning program is realized various logic to intelligent controller, but this control mode stability by intelligent controller is very bad, and is applied in and high-tension apparatus is easily hit and damages, existing uninterrupted DC power system simultaneously, the switching time of main power supply is long, run into frequently stop power transmission time, cannot tackle, must occur be interrupted.

Utility model content

The utility model object is to provide a kind of uninterrupted DC power system, can realize the stable switching of DC power supply, safeguard and more save cost.

Uninterrupted DC power system described in the utility model, comprises charger, AC-DC module, storage battery, thyristor and circuits for triggering.Storage battery is connected to AC power by charger, the output of storage battery is connected to DC output end by thyristor, the input of AC-DC module is connected to AC power, the output of AC-DC module is connected to DC output end, the input of circuits for triggering is connected to the output of charger, the output of circuits for triggering is connected to the gate electrode of circuits for triggering thyristor, circuits for triggering comprise triode, base resistance and voltage stabilizing didoe, the collector electrode of triode is connected to the positive pole of storage battery, the emitter of triode is connected to the gate electrode of thyristor, the base stage of triode is connected to the cathode output end of AC-DC module by voltage stabilizing didoe, base resistance is connected in parallel between base stage and collector electrode.

Described uninterrupted DC power system, on the basis of existing uninterrupted DC power supply, the hardware capability combination of application voltage stabilizing didoe and triode instead of controller and relies on the mode of software simulating, more stable, and safeguards, changes and more save cost.

Described uninterrupted DC power system, the number of thyristor is two, be respectively thyristor A and thyristor B, the anode of thyristor A and thyristor B is connected to battery positive voltage respectively by contactor A and contactor B, and two thyristor negative electrodes are all connected to AC-DC module positive pole.

Described uninterrupted DC power system, the initial position of contactor A is closed, and the initial position of contactor B is off.

Described uninterrupted DC power system, be provided with relay A, relay B, relay C and relay D, relay A, relay B, the time delay coil of relay C and relay D is connected in parallel between two outputs of AC-DC module, relay A, relay B, the normally opened contact of relay C and relay D respectively with the closing coil of contactor A, the disconnection coil of contactor A, the closing coil of contactor B and the disconnection coils connected in series of contactor B, and relay coil after series connection and between the contactor coil positive pole that is connected in parallel on storage battery and AC-DC module and the negative pole of AC-DC module.

Described uninterrupted DC power system, by four relays after AC-DC module restores electricity, according to the order action successively of its time delay, the thyristor just converting conducting state can be replaced by another thyristor, cut out again, realized exiting of stand-by power supply.Again by the switching recovering state initial position of two thyristors, ensure that in the recovery process of a thyristor, having another thyristor replaces it to complete the action recovered in gap, drop into disposable Switching power only relative to existing uninterrupted DC power supply, the utility model is that thyristor recovers to occur that the problem again switched has made guarantee in gap.

Described uninterrupted DC power system, the timing duration of relay A, relay B, relay C and relay D is respectively 3s, 2s, 1s and 4s.The action of control two contactors of each relay can be made mutually to stagger, and no matter four relays how control contactor action, all at least having a thyristor can guarantee of work reliability of the present utility model.

The utility model compared with prior art beneficial effect is:

On the basis of existing uninterrupted DC power supply, the hardware capability combination of application voltage stabilizing didoe and triode instead of controller and relies on the mode of software simulating, more stable, and safeguards, changes and more save cost, is applicable to multiple voltage grade.More reliable to the switching between main power supply, overcoming the problem having between thyristor twice action and recover gap, ensure that, when frequently stopping power transmission, the utility model still can accomplish continual direct current supply.

Accompanying drawing explanation

Fig. 1 is the utility model embodiment electric diagram.

In figure: 1, AC-DC module; 2, charger; 3, storage battery; 4, triode; 5, voltage stabilizing didoe; 6, thyristor A; 7, contactor A; 8, contactor B; 9, the normally opened contact of relay A; 10, the normally opened contact of relay B; 11, the normally opened contact of relay C; 12, the normally opened contact of relay D; 13, the disconnection coil of contactor B; 14, the closing coil of contactor B; 15, the disconnection coil of contactor A; 16, the closing coil of contactor A; 17, thyristor B; 18, the time delay coil of relay D; 19, the time delay coil of relay C; 20, the time delay coil of relay B; 21, the time delay coil of relay A.

Embodiment

Below in conjunction with the utility model, the utility model embodiment is described further:

As shown in Figure 1, described uninterrupted DC power system, comprises charger 2, AC-DC module 1, storage battery 3, thyristor and circuits for triggering.Storage battery 3 is connected to AC power by charger 2, the output of storage battery 3 is connected to DC output end by thyristor, the input of AC-DC module 1 is connected to AC power, the output of AC-DC module 1 is connected to DC output end, the input of circuits for triggering is connected to the output of charger 2, the output of circuits for triggering is connected to the gate electrode of circuits for triggering thyristor, it is characterized in that, circuits for triggering comprise triode 4, base resistance and voltage stabilizing didoe 5, the collector electrode of triode 4 is connected to the positive pole of storage battery 3, the emitter of triode 4 is connected to the gate electrode of thyristor, the base stage of triode 4 is connected to the cathode output end of AC-DC module 1 by voltage stabilizing didoe 5, base resistance is connected in parallel between base stage and collector electrode.The number of thyristor is two, is respectively thyristor A6 and thyristor B17; The anode of thyristor A6 and thyristor B17 is connected to storage battery 3 positive pole respectively by contactor A7 and contactor B8, and two thyristor negative electrodes are all connected to AC-DC module 1 positive pole.Be provided with relay A, relay B, relay C and relay D, the time delay coil 18 of relay A, relay B, relay C and relay D is connected in parallel between two outputs of AC-DC module 1, the normally opened contact of relay A, relay B, relay C and relay D is connected with the disconnection coil 13 of the closing coil 16 of contactor A, the disconnection coil 15 of contactor A, the closing coil 14 of contactor B and contactor B respectively, and relay coil after series connection and contactor coil are connected in parallel between the positive pole of storage battery 3 and AC-DC module 1 and the negative pole of AC-DC module 1.

In uninterrupted DC power system, AC-DC module 1 is as the conventional power supply of using electricity system, and charger 2 and storage battery 3 are as the stand-by power supply of using electricity system.Break down in AC-DC module 1, can not for using electricity system power time, charger 2 and storage battery 3 can be automatically switched into jointly for using electricity system is powered.In civil power AC220V power-off, charger 2 and AC-DC module 1 all cisco unity malfunction time, switch to storage battery 3 to power for using electricity system.

The base voltage of triode 4 is stabilized in 80% of rated voltage by the voltage stabilizing didoe 5 in circuits for triggering, and the emitter of triode 4 is used for providing gate trigger current for thyristor A6 and thyristor B17.When AC-DC module 1 normally works, the anode potential of thyristor A6 and thyristor B17 is lower than cathode potential, and thyristor A6 and thyristor B17 is not triggered.When conventional power supply and AC-DC module 1 power-off, the electromotive force of thyristor A6 gate pole is higher than cathode potential, and the emitter of triode 4 triggers thyristor A6 conducting immediately, now switches to charger 2 and storage battery 3 to power for using electricity system.When civil power AC220V power-off, when AC-DC module 1 and charger 2 do not work simultaneously, in like manner can realize storage battery 3 for using electricity system powers.When thyristor is triggered, ON time only has several microsecond, ensures the seamless switching of stand-by power supply and conventional power supply.Thyristor can bear voltage difference very large between negative electrode and anode, so be applicable to multiple voltage grade.

After conventional power up is normal, thyristor A6 is in conducting state always, although the cathode potential of thyristor A6 is higher than gate pole electromotive force, but because thyristor self has the feature of " gate pole controls to trigger but do not control to end ", thyristor A6 can not automatic cut-off, the time delay coil 21 of relay A, the time delay coil 20 of relay B, the time delay coil 18 of the time delay coil 19 of relay C and relay D can simultaneously electric, time delay coil 19 time delay of relay C 1 second, obtain electric by the closed closing coil 14 of contactor B that makes of the normally opened contact 11 of relay C, carry out control contactor B8 to close, the cathode potential of thyristor B17 is higher than gate pole electromotive force, thyristor B17 not conducting.Time delay coil 20 time delay of relay B 2 seconds, obtain electric by the closed disconnection coil 15 of contactor A that makes of the normally opened contact 10 of relay B, control contactor A7 disconnects, and thyristor A6 deactivates.Time delay coil 21 time delay of relay A 3 seconds, by the normally opened contact of relay A 9 closed make the closing coil 16 of contactor A electric, control contactor A7 closes, the cathode potential of thyristor A6 higher than gate pole electromotive force, thyristor A6 not conducting.Time delay coil 18 time delay of relay D 4 seconds, obtain electric by the closed disconnection coil 13 of contactor B that makes of the normally opened contact 12 of relay D, the normally opened contact of contactor B8 disconnects.By relay A, relay B, relay C, relay D and contactor A7, contactor B8, realize after conventional power up is normal, stand-by power supply exits automatically.In whole handoff procedure, have at least a thyristor to be in the state that can be triggered, if conventional power supply breaks down again, still can switch seamlessly to stand-by power supply.

Claims (5)

1. a uninterrupted DC power system, comprises charger (2), AC-DC module (1), storage battery (3), thyristor and circuits for triggering, storage battery (3) is connected to AC power by charger (2), the output of storage battery (3) is connected to DC output end by thyristor, the input of AC-DC module (1) is connected to AC power, the output of AC-DC module (1) is connected to DC output end, the input of circuits for triggering is connected to the output of charger (2), the output of circuits for triggering is connected to the gate electrode of circuits for triggering thyristor, it is characterized in that, circuits for triggering comprise triode (4), base resistance and voltage stabilizing didoe (5), the collector electrode of triode (4) is connected to the positive pole of storage battery (3), the emitter of triode (4) is connected to the gate electrode of thyristor, the base stage of triode (4) is connected to the cathode output end of AC-DC module (1) by voltage stabilizing didoe (5), base resistance is connected in parallel between base stage and collector electrode.

2. uninterrupted DC power system according to claim 1, is characterized in that, the number of thyristor is two, is respectively thyristor A (6) and thyristor B (17); The anode of thyristor A (6) and thyristor B (17) is connected to storage battery (3) positive pole respectively by contactor A (7) and contactor B (8), and two thyristor negative electrodes are all connected to AC-DC module (1) positive pole.

3. uninterrupted DC power system according to claim 2, is characterized in that, the initial position of contactor A (7) is closed, and the initial position of contactor B (8) is off.

4. the uninterrupted DC power system according to Claims 2 or 3, it is characterized in that, be provided with relay A, relay B, relay C and relay D, relay A, relay B, the time delay coil of relay C and relay D is connected in parallel between two outputs of AC-DC module (1), relay A, relay B, the normally opened contact of relay C and relay D respectively with the closing coil (16) of contactor A, the disconnection coil (15) of contactor A, the closing coil (14) of contactor B and disconnection coil (13) series connection of contactor B, and series connection after relay coil and contactor coil be connected in parallel between the positive pole of storage battery (3) and AC-DC module (1) and the negative pole of AC-DC module (1).

5. uninterrupted DC power system according to claim 4, is characterized in that, the timing duration of relay A, relay B, relay C and relay D is respectively 3s, 2s, 1s and 4s.