CN202633176U

CN202633176U - Energy-saving device of electromagnetic system and electromagnetic system comprising same

Info

Publication number: CN202633176U
Application number: CN 201220338137
Authority: CN
Inventors: 黄世泽; 朱谅; 杨佰传; 屠瑜权
Original assignee: ZHEJIANG ZHONGKAI ELECTRIC EQUIPMENT CO Ltd
Current assignee: ZHEJIANG ZHONGKAI ELECTRIC EQUIPMENT CO Ltd
Priority date: 2012-07-12
Filing date: 2012-07-12
Publication date: 2012-12-26
Anticipated expiration: 2022-07-12

Abstract

The utility model relates to an energy-saving device of an electromagnetic system and the electromagnetic system comprising the same. The energy-saving device comprises a silicon-controlled rectifier (SCR) control unit, wherein an input end of the silicon-controlled rectifier control unit is connected with an alternating-current power supply and comprises at least one second variable resistor VR2 and a seventh capacitor C7, the second variable resistor VR2 and the seventh capacitor C7 are connected in series mutually, the resistance value of the second variable resistor VR2 is regulated to control the seventh capacitor C7 to achieve different charge/discharge time, different charge/discharge time of the capacitor changes the magnitude of the phase-shift angle of trigger impulse of a SCR so as to further change the magnitude of a conduction angle of the SCR. By means of regulating the resistance value of the second variable resistor VR2, different pull-in voltage and different sustaining voltage can be acquired, and the energy-saving device is suitable for different electromagnetic systems and is greatly enhanced in universality.

Description

The energy saver of electromagnetic system and comprise the electromagnetic system of this energy saver

Technical field

The utility model relates to the contactor technical field, specifically is a kind of energy saver of electromagnetic system and the electromagnetic system that comprises this energy saver.

Background technology

A.C. contactor be widely used as electric power cut-off with control circuit in, it utilizes main contact to open and close circuit, carries out control command with auxiliary contact.Main contact generally has only normal opened contact, and auxiliary contact often has two pairs of contacts with Chang Kai and normally closed function, and A.C. contactor mainly contains four parts and forms: (1) electromagnetic system comprises sucking coil, moving iron core and static iron core; (2) contact system comprises that three groups of main contacts and one to two group are often opened, normally closed auxiliary contact, it and the interlock mutually that connects together of moving iron core; (3) arc-control device, the general bigger A.C. contactor of capacity all is provided with arc-control device, so that rapid breaking arc avoids burning out main contact; (4) insulation crust and annex, various springs, transmission mechanism, short-circuited conducting sleeve, binding post etc.When coil electricity, static iron core produces electromagnetic attraction, will move the iron core adhesive, because contact system links with moving iron core, therefore moving iron core drives three movable contact springs and moves the closing of contact, thereby energized simultaneously.When coil blackout, suction disappears, and moving iron core interlock part relies on the reaction force of spring and separates, and main contact is broken off, and cuts off the electricity supply.

It is that the energising of closing brake cable circle produces electromagnetic force and overcomes tripping spring and realize that the combined floodgate of tradition contactor keeps; The electromagnetic force that makes generation is not enough to overcome the reaction force of spring in case electric current diminishes; Contactor just can not keep "on" position; So the combined floodgate of conventional AC contactor keeps leaning on the continual energising of coil to keep, this electric current is milliampere from tens of to thousands of.And permanent magnet AC contactor combined floodgate maintenance dependence is permanent magnetism power; And do not need coil to produce the electromagnetic force maintenance of closing a floodgate through electric current, have only the operating current of the 0.8mA-1.5mA of electronic module, thereby; Saves energy to greatest extent, power saving rate is up to more than 99.8%.

Documents CN102347166A discloses a kind of method of work of silent power-saving formula A.C. contactor; Comprise the steps; Bridge rectifier gets when electric; Open late oscillator starting and with higher hunting of frequency, the pulse signal of opening second base stage output of the double-basis pipe diode in the oscillator late export and is loaded into silicon controlled and controls and extremely go up on the 6th resistance, and makes the silicon controlled angle of flow be in maximum rating; Loop, sucking coil place direct current is in maximum, makes the armature and the iron core moment adhesive of A.C. contactor; When said armature and iron core adhesive; Resistance moment of resistance strain gage becomes big, thereby has strengthened the time constant that discharges and recharges of the RC circuit opened late in the oscillator, has reduced the charging current of electric capacity; Impel and open oscillator reduction frequency of oscillation late; And make silicon controlled conducting angle be in minimum state, and the direct current that obtains on the sucking coil is in minimum value, and this direct current that is in minimum value is suitable for making A.C. contactor to be stabilized in the sticking state.

But since the electromagnetic system parameter determining adhesive characteristic of electrical equipment, and according to different product, the electromagnetic system parameter all needs change, therefore the battery saving arrangement versatility of disclosed fixedly pick-up voltage and sustaining voltage is poor in the above-mentioned patent documentation.

The utility model content

For this reason, the utility model is to be solved to be the technical problem of the versatility difference fixedly brought of existing electromagnetic relay battery saving arrangement pick-up voltage and sustaining voltage, a kind of energy saver of electromagnetic system is provided and comprises the electromagnetic system of this energy saver.

For solving the problems of the technologies described above, the technical scheme that the utility model adopts is following:

A kind of energy saver of electromagnetic system comprises:

The SCR control unit, it imports termination AC power, comprises at least one the second adjustable resistance VR2 and one the 7th capacitor C 7 of mutual series connection;

Rectification unit, the output of its input termination SCR control unit is used for alternating current is adjusted into the direct current and the output of pulsation, and the output of said rectification unit constitutes the output of energy saver, output DC stream;

The AC/DC converter unit, its input is parallelly connected with the input of said SCR control unit, connects AC power jointly, is used for alternating current is become direct current output;

Delay unit, its input links to each other with the output of AC/DC converter unit, conducting when accumulation voltage arrives predetermined value;

Relay drive unit, its input links to each other with the output of delay unit, and signal is sent in the conversion of control relay contact when the delay unit conducting; Its output links to each other with SCR control circuit control end.

Said delay unit comprises first resistance R 1, the first variable resistor VR1, the 6th capacitor C 6, the first voltage-stabiliser tube Z1; First resistance R 1, the first variable resistor VR1 and the 6th capacitor C 6 are in sequential series, and first resistance R 1 does not constitute the input of said delay unit with the end that the first variable resistor VR1 directly links to each other; The positive pole of the 6th capacitor C 6 links to each other with the first variable resistor VR1 and their tie point links to each other with the anode of the first voltage-stabiliser tube Z1, and the negative electrode of the first voltage-stabiliser tube Z1 constitutes the output of said delay unit; The minus earth of said the 6th capacitor C 6.

The SCR control unit also comprises second resistance R 2, the 3rd resistance R 3, the 3rd variable resistor VR3, the second voltage-stabiliser tube Z2, controllable silicon SCR; Wherein, Second resistance R 2, the second adjustable resistance VR2, the 3rd resistance R 3, the 3rd variable resistor VR3 and the 7th capacitor C 7 are connected successively, and the end that second resistance R 2 does not directly link to each other with the second adjustable resistance VR2 links to each other with the controllable silicon SCR anode and their tie point constitutes the output of SCR control unit; The negative electrode of controllable silicon SCR links to each other with the negative pole of the 7th capacitor C 7 and ground connection; The said second voltage-stabiliser tube Z2, one end extremely links to each other with the control of controllable silicon SCR, on the positive pole that the other end is connected the 7th capacitor C 7 and the tie point that the 3rd variable resistor VR3 links to each other; The tie point of said the 3rd resistance R 3 and the second adjustable resistance VR2 constitutes the input of SCR control unit.

Rectification unit is the full-wave rectification unit, and it comprises the 3rd diode D3, the 4th diode D4, the 5th diode D5, the 6th diode D6; The anode of described the 3rd diode D3 links to each other with the negative electrode of the 5th diode D5, and is connected in the output of said AC power jointly; The negative electrode of the anode of said the 4th diode D4 and the 6th diode D6 links to each other and their tie point constitutes the input of said rectification unit; The negative electrode of the 3rd diode D 3 links to each other with the negative electrode of the 4th diode D4 and their tie point constitutes an output of rectification unit; The anode of said the 5th diode D5 links to each other with the anode of the 6th diode D6 and their tie point constitutes another output of rectification unit.

The AC/DC converter unit comprises: transformer T1, bridge type rectifier DB1, capacitor C 2, capacitor C 3, three terminal regulator IC1, capacitor C 4, capacitor C 5; The primary side of described transformer T1 constitutes the input of AC/DC converter unit; Secondary side links to each other with the AC side of bridge type rectifier DB1, the positive pole of the positive pole of the outlet side of bridge type rectifier DB1 and second capacitor C 2, the 3rd capacitor C 3 links to each other and their tie point links to each other with the input of three terminal regulator IC1, and the positive pole of the 5th capacitor C 5 links to each other the positive pole of the output of said three terminal regulator IC1 and the 4th capacitor C 4 and their tie point constitutes the output of AC/DC converter unit; The negative pole of the negative pole of the negative pole of the negative pole of said second capacitor C 2, the 3rd capacitor C 3, the 4th capacitor C 4 and the 5th capacitor C 5 links to each other and ground connection.

Relay drive unit comprises: the first triode Q1, the second triode Q2, the first diode D1 and relay R L1; The base stage of the described first triode Q1 constitutes the input of relay drive unit, and the emitter of the first triode Q1 links to each other with the base stage of the second triode Q2, and the emitter of the second triode Q2 links to each other with the output negative pole of AC/DC converter unit and ground connection; The collector electrode of the first triode Q1 links to each other with the collector electrode of the second triode Q2; The negative electrode of the first diode D1 links to each other with the positive pole of the output of AC/DC converter unit, and the anode of the first diode D1 links to each other with the collector electrode of the first triode Q1; Control end one end of relay R L1 links to each other with the positive pole of AC/DC converter unit, and the other end of the control end of relay R L1 links to each other with the collector electrode of the second triode Q2; The output circuit of relay R L1 constitutes the output of relay drive unit.

The AC/DC converter unit comprises the modular power source AC/DC and first capacitor C 1, and wherein, the input of said modular power source constitutes the input of AC/DC converter unit; First capacitor C 1 is parallel between the output of modular power source, and the two ends of first capacitor C 1 constitute the output of AC/DC converter unit.

Simultaneously, a kind of electromagnetic system is provided, it uses arbitrary above-mentioned energy saver.

The technique scheme of the utility model is compared prior art and is had the following advantages:

The SCR control unit of the utility model; Its input termination AC power; At least one the second adjustable resistance VR2 and one the 7th capacitor C 7 of comprising mutual series connection; The resistance of regulating the second adjustable resistance VR2 is controlled the 7th capacitor C 7 and is had different discharging and recharging the time, the difference of the electric capacity time that discharges and recharges change controllable silicon SCR trigger impulse phase shift angle size so that change the angle of flow size of controllable silicon SCR.Resistance through adjustment the second adjustable resistance VR2 can obtain different pick-up voltages and different sustaining voltages, is applicable to different electromagnetic systems, and versatility strengthens greatly.

Its input of the delay unit of the utility model links to each other with the output of AC/DC converter unit; Conducting when accumulation voltage arrives predetermined value obtains the different time delay time, and the control electromagnetic system transfers hold mode to by attracting state; Applicable to Different control electrical equipment, versatility strengthens greatly.

Description of drawings

For the content that makes the utility model is more clearly understood,, the utility model is done further detailed explanation, wherein below according to the specific embodiment of the utility model and combine accompanying drawing

Fig. 1 is the structured flowchart of an embodiment energy saver of the utility model;

Fig. 2 is the circuit structure diagram of the energy saver of first embodiment of the utility model;

The circuit structure diagram of the AC/DC converter unit of first embodiment of Fig. 3 the utility model;

Fig. 4 is the delay unit of first embodiment of the utility model and the circuit structure diagram of relay drive unit;

Fig. 5 is the circuit structure diagram of the SCR control unit of first embodiment of the utility model;

Fig. 6 is the circuit structure diagram of the full-wave rectification unit of first embodiment of the utility model;

Fig. 7 is the circuit structure diagram of the AC/DC converter unit of second embodiment of the utility model;

Fig. 8 is the delay unit of second embodiment of the utility model and the circuit structure diagram of relay drive unit;

Fig. 9 is the circuit structure diagram of second embodiment halfwave rectifier unit of the utility model.

Embodiment

Referring to shown in Figure 1 be the structured flowchart of energy saver of the electromagnetic system of an embodiment of the utility model; Energy saver as an embodiment of the utility model; It comprises: the SCR control unit, and its input termination AC power is used to adjust the silicon controlled angle of flow; Rectification unit, the output of its input termination SCR control unit is used for alternating current is adjusted into the direct current and the output of pulsation, and the output of said rectification unit constitutes the output of energy saver, output DC stream; The AC/DC converter unit, its input is parallelly connected with the input of said SCR control unit, connects AC power jointly, is used for alternating current is become direct current output; Delay unit, its input links to each other with the output of AC/DC converter unit, conducting when accumulation voltage arrives predetermined value; Relay drive unit, its input links to each other with the output of delay unit, and signal is sent in the conversion of control relay contact when the delay unit conducting; Its output links to each other with SCR control circuit control end.

Referring to Fig. 2-shown in Figure 6, be the circuit structure diagram of the energy saver of an embodiment of the utility model, wherein, said delay unit comprises first resistance R 1, the first variable resistor VR1, the 6th capacitor C 6, the first voltage-stabiliser tube Z1; First resistance R 1, the first variable resistor VR1 and the 6th capacitor C 6 are in sequential series, and first resistance R 1 does not constitute the input of said delay unit with the end that the first variable resistor VR1 directly links to each other; The positive pole of the 6th capacitor C 6 links to each other with the first variable resistor VR1 and their tie point links to each other with the anode of the first voltage-stabiliser tube Z1, and the negative electrode of the first voltage-stabiliser tube Z1 constitutes the output of said delay unit; The minus earth of said the 6th capacitor C 6.

Relay drive unit as an embodiment of the utility model comprises: the first triode Q1, the second triode Q2, the first diode D1 and relay R L1; The base stage of the described first triode Q1 constitutes the input of relay drive unit, and the emitter of first triode (Q1) links to each other with the base stage of the second triode Q2, and the emitter of the second triode Q2 links to each other with the direct current negative pole of AC/DC converter unit and ground connection; The collector electrode of the first triode Q1 links to each other with the collector electrode of the second triode Q2; The negative electrode of the first diode D1 links to each other with the positive pole of the output of AC/DC converter unit, and the anode of the first diode D1 links to each other with the collector electrode of the first triode Q1; Control end one end of relay R L1 links to each other with the positive pole of AC/DC converter unit, and the other end of the control end of relay R L1 links to each other with the collector electrode of the second triode Q2; The output circuit of relay R L1 constitutes the output of relay drive unit, and the break-make of the output circuit of relay R L1 is by the control end control of relay R L1.

Referring to shown in Figure 5, be the SCR control unit of an embodiment of the utility model, it comprises second resistance R 2, the second adjustable resistance VR2, the 3rd resistance R 3, the 3rd variable resistor VR3, the 7th capacitor C 7, the second voltage-stabiliser tube Z2, controllable silicon SCR; Wherein, Second resistance R 2, the second adjustable resistance VR2, the 3rd resistance R 3, the 3rd variable resistor VR3 and the 7th capacitor C 7 are connected successively, and the end that second resistance R 2 does not directly link to each other with the second adjustable resistance VR2 links to each other with the controllable silicon SCR anode and their tie point constitutes the output of SCR control unit; The negative electrode of controllable silicon SCR links to each other with the negative pole of the 7th capacitor C 7 and ground connection; The said second voltage-stabiliser tube Z2, one end extremely links to each other with the control of controllable silicon SCR, on the positive pole that the other end is connected the 7th capacitor C 7 and the tie point that the 3rd variable resistor VR3 links to each other; The tie point of said the 3rd resistance R 3 and the second adjustable resistance VR2 constitutes the input of SCR control unit; The passive contact of said relay R L1 is parallel to the 3rd resistance R 3 and the 3rd variable resistor VR3 two ends; When the passive closing of contact of said relay R L1; Said the 3rd resistance R 3 and the 3rd variable resistor VR3 are by short circuit; When the passive contact of relay R L1 is broken off, said the 3rd resistance R 3 and the 3rd variable resistor VR3 access circuit, promptly second resistance R 2, the second adjustable resistance VR2, the 3rd resistance R 3, the 3rd variable resistor VR 3 and the 7th capacitor C 7 are connected successively.

As shown in the figure, the function of SCR control circuit is adjust the silicon controlled angle of flow, and then through rectification circuit, adjusting to be input to the current waveform of electromagnetic system coil, reaches hypotensive effect.This circuit realizes that through electric capacity is charged AC power is charged to electric capacity through variable resistor.When capacitance terminal voltage surpasses voltage-stabiliser tube conducting threshold values, will make the IGBT conducting; Adjustment variable resistor parameter, thus the scope of in the one-period angle of flow made, reach the effect of regulation voltage.

When circuit is in attracting state; The resistance value of getting variable resistance VR3 is smaller, like this charging interval of capacitor C 7 just very fast, the trigger impulse phase shift angle that causes being added on the controllable silicon SCR control utmost point SCR-G is less; Make thyristor operating angle become big, output voltage uprises; When circuit is in hold mode; Get the bigger variable resistance value of VR3, in the charging interval of capacitor C 7 because bigger resistance can slow down, the trigger impulse phase shift angle that SCR-G is extremely gone up in controllable silicon SCR control becomes big; Cause thyristor operating angle to diminish, make the output voltage step-down.Resistance R 3 and variable resistor VR3, the output of relay is in parallel, and when starting, by short circuit, what import capacitor loop into just has only R2 and VR2, the very fast conducting of IGBT, thus make pick-up voltage greater than sustaining voltage.

Rectification unit as an embodiment of the utility model is the full-wave rectification unit, and referring to shown in Figure 6, it comprises the 3rd diode D3, the 4th diode D4, the 5th diode D5, the 6th diode D6; The anode of described the 3rd diode D3 links to each other with the negative electrode of the 5th diode D5, and is connected in the output of said AC power jointly; The negative electrode of the anode of said the 4th diode D4 and the 6th diode D6 links to each other and their tie point constitutes the input of said rectification unit, links to each other with the anode of controllable silicon SCR; The negative electrode of the 3rd diode D 3 links to each other with the negative electrode of the 4th diode D4 and their tie point constitutes an output of rectification unit; The anode of said the 5th diode D5 links to each other with the anode of the 6th diode D6 and their tie point constitutes another output of rectification unit.

Referring to shown in Figure 3, as the AC/DC converter unit of an embodiment of the utility model, said AC/DC converter unit comprises: transformer T1, bridge type rectifier DB1, capacitor C 2, capacitor C 3, three terminal regulator IC1, capacitor C 4, capacitor C 5; The primary side of described transformer T1 constitutes the input of AC/DC converter unit; Secondary side links to each other with the AC side of bridge type rectifier DB1, the positive pole of the positive pole of the outlet side of bridge type rectifier DB1 and second capacitor C 2, the 3rd capacitor C 3 links to each other and their tie point links to each other with the input of three terminal regulator IC1, and the positive pole of the 5th capacitor C 5 links to each other the positive pole of the output of said three terminal regulator IC1 and the 4th capacitor C 4 and their tie point constitutes the output of AC/DC converter unit; The negative pole of the negative pole of the negative pole of the negative pole of said second capacitor C 2, the 3rd capacitor C 3, the 4th capacitor C 4 and the 5th capacitor C 5 links to each other and ground connection.

Referring to shown in Figure 7, as the AC/DC converter unit of another embodiment of the utility model, said AC/DC converter unit comprises: modular power source AC/DC, first capacitor C 1, and the input of said modular power source constitutes the input of AC/DC converter unit; First capacitor C 1 is parallel between the output of modular power source, and the two ends of first capacitor C 1 constitute the output of AC/DC converter unit, as long as can realize the function of AC/DC conversion.

Referring to shown in Figure 8, as another embodiment of the utility model delay unit, said delay unit comprises time relay TR1 and the 4th resistance R 4.Described time relay TR1 input termination DC power supply is exported an end and is linked to each other with the positive pole of DC power supply, and the other end is connected in series the 4th resistance R 4 and links to each other with the ground of DC power supply, links to each other with the base stage of triode Q 3 simultaneously, and the delay time of the time relay is adjustable.When starting, delay time does not arrive, and output contact breaks off, and what triode Q3 received is low level signal.After delay time arrived, time relay TR1 output contact was closed, and what triode Q 3 received is high level, relay R L1 action.As other embodiment of the utility model relay drive unit, described relay drive unit comprises the 3rd triode Q3, diode D7, relay R L1.The base stage of described the 3rd triode Q3 constitutes the input of relay drive circuit; The emitter of the 3rd triode (Q1) links to each other with the ground of DC power supply; The negative electrode of the 7th diode D7 links to each other with the positive pole of the output of AC/DC converter unit, and the anode of the 7th diode D7 links to each other with the collector electrode of the 3rd triode Q3; Control end one end of relay R L1 links to each other with the positive pole of AC/DC converter unit, and the other end of the control end of relay R L1 links to each other with the collector electrode of the 3rd triode Q3.After delay time arrived, the base stage of the 3rd triode Q3 became high level, triode conducting, the control termination DC power supply of relay R L1, relay R L1 action.

Referring to shown in Figure 9, as other embodiment of the utility model rectification unit, described rectification unit is a half-wave rectifying circuit, comprises the 8th diode D8; Described the 8th diode D8 is serially connected between AC power and the electromagnetic system; The electric current that flows through electromagnetic system like this is a half-wave.

Obviously, the foregoing description only be for explanation clearly done for example, and be not qualification to execution mode.For the those of ordinary skill in affiliated field, on the basis of above-mentioned explanation, can also make other multi-form variation or change.Here need not also can't give exhaustive to all execution modes.And conspicuous variation of being extended out thus or change still are among the protection range of the utility model.

Claims

1. the energy saver of an electromagnetic system is characterized in that, comprising:

2. energy saver according to claim 1 is characterized in that: said delay unit comprises first resistance R 1, the first variable resistor VR1, the 6th capacitor C 6, the first voltage-stabiliser tube Z1; First resistance R 1, the first variable resistor VR1 and the 6th capacitor C 6 are in sequential series, and first resistance R 1 does not constitute the input of said delay unit with the end that the first variable resistor VR1 directly links to each other; The positive pole of the 6th capacitor C 6 links to each other with the first variable resistor VR1 and their tie point links to each other with the anode of the first voltage-stabiliser tube Z1, and the negative electrode of the first voltage-stabiliser tube Z1 constitutes the output of said delay unit; The minus earth of said the 6th capacitor C 6.

3. energy saver according to claim 1 and 2 is characterized in that: the SCR control unit also comprises second resistance R 2, the 3rd resistance R 3, the 3rd variable resistor VR3, the second voltage-stabiliser tube Z2, controllable silicon SCR; Wherein, Second resistance R 2, the second adjustable resistance VR2, the 3rd resistance R 3, the 3rd variable resistor VR3 and the 7th capacitor C 7 are connected successively, and the end that second resistance R 2 does not directly link to each other with the second adjustable resistance VR2 links to each other with the controllable silicon SCR anode and their tie point constitutes the output of SCR control unit; The negative electrode of controllable silicon SCR links to each other with the negative pole of the 7th capacitor C 7 and ground connection; The said second voltage-stabiliser tube Z2, one end extremely links to each other with the control of controllable silicon SCR, on the positive pole that the other end is connected the 7th capacitor C 7 and the tie point that the 3rd variable resistor VR 3 links to each other; The tie point of said the 3rd resistance R 3 and the second adjustable resistance VR2 constitutes the input of SCR control unit.

4. energy saver according to claim 3 is characterized in that: rectification unit is the full-wave rectification unit, and it comprises the 3rd diode D3, the 4th diode D4, the 5th diode D5, the 6th diode D6; The anode of described the 3rd diode D3 links to each other with the negative electrode of the 5th diode D5, and is connected in the output of said AC power jointly; The negative electrode of the anode of said the 4th diode D4 and the 6th diode D6 links to each other and their tie point constitutes the input of said rectification unit; The negative electrode of the 3rd diode D3 links to each other with the negative electrode of the 4th diode D4 and their tie point constitutes an output of rectification unit; The anode of said the 5th diode D5 links to each other with the anode of the 6th diode D6 and their tie point constitutes another output of rectification unit.

5. energy saver according to claim 4 is characterized in that: the AC/DC converter unit comprises: transformer T1, bridge type rectifier DB1, capacitor C 2, capacitor C 3, three terminal regulator IC1, capacitor C 4, capacitor C 5; The primary side of described transformer T1 constitutes the input of AC/DC converter unit; Secondary side links to each other with the AC side of bridge type rectifier DB1, the positive pole of the positive pole of the outlet side of bridge type rectifier DB1 and second capacitor C 2, the 3rd capacitor C 3 links to each other and their tie point links to each other with the input of three terminal regulator IC1, and the positive pole of the 5th capacitor C 5 links to each other the positive pole of the output of said three terminal regulator IC1 and the 4th capacitor C 4 and their tie point constitutes the output of AC/DC converter unit; The negative pole of the negative pole of the negative pole of the negative pole of said second capacitor C 2, the 3rd capacitor C 3, the 4th capacitor C 4 and the 5th capacitor C 5 links to each other and ground connection.

6. according to claim 1 or 2 or 4 or 5 described energy savers, it is characterized in that: relay drive unit comprises: the first triode Q1, the second triode Q2, the first diode D1 and relay R L1; The base stage of the described first triode Q1 constitutes the input of relay drive unit, and the emitter of the first triode Q1 links to each other with the base stage of the second triode Q2, and the emitter of the second triode Q2 links to each other with the output negative pole of AC/DC converter unit and ground connection; The collector electrode of the first triode Q1 links to each other with the collector electrode of the second triode Q2; The negative electrode of the first diode D1 links to each other with the positive pole of the output of AC/DC converter unit, and the anode of the first diode D1 links to each other with the collector electrode of the first triode Q1; Control end one end of relay R L1 links to each other with the positive pole of AC/DC converter unit, and the other end of the control end of relay R L1 links to each other with the collector electrode of the second triode Q2; The output circuit of relay R L1 constitutes the output of relay drive unit.

7. energy saver according to claim 4 is characterized in that: the AC/DC converter unit comprises the modular power source AC/DC and first capacitor C 1, and wherein, the input of said modular power source constitutes the input of AC/DC converter unit; First capacitor C 1 is parallel between the output of modular power source, and the two ends of first capacitor C 1 constitute the output of AC/DC converter unit.

8. an electromagnetic system is characterized in that: use like the arbitrary described energy saver of claim 1-7.