CN211601219U

CN211601219U - Electromagnetic thermal expansion valve

Info

Publication number: CN211601219U
Application number: CN201922237737.6U
Authority: CN
Inventors: 张凯
Original assignee: Shanghai Fu Filter Enterprise Development Co ltd
Current assignee: Shanghai Fu Filter Enterprise Development Co ltd
Priority date: 2019-12-13
Filing date: 2019-12-13
Publication date: 2020-09-29
Anticipated expiration: 2029-12-13

Abstract

The utility model discloses an electromagnetic thermal expansion valve, which can flexibly adjust the opening between a valve needle and a valve hole on the premise of not influencing the adjustment flexibility of the valve needle; the valve comprises a valve hole, a valve needle, a valve rod and an adjusting cylinder, wherein the valve rod and an adjusting rod are respectively fixed at two ends of the adjusting cylinder; adjust the pole bottom and pack into the detection intracavity and with adjust a section of thick bamboo assembly fixed, adjust a section of thick bamboo inside and be hollow regulation inner tube, block in the regulation inner tube, slidable is equipped with electrically conductive main aspects, electrically conductive main aspects one end is electrically conductive with first wire and is connected, electrically conductive main aspects are fixed on leading electrical pillar, it passes and adjusts a section of thick bamboo to lead electrical pillar, be connected with the conducting block is electrically conductive behind the insulating spring, conducting pillar one end is electrically conductive with the second wire and is connected, first wire is electrically conductive with DC power supply's positive pole and is connected, the second wire is electrically conductive with DC power supply's negative pole, the second wire, first wire respectively with the negative pole of voltmeter, anodal electrically conductive connection, the signal terminal of voltmeter and the signal terminal communication of PLC are connected, DC.

Description

Electromagnetic thermal expansion valve

Technical Field

The utility model relates to an expansion valve especially relates to an electromagnetism thermal expansion valve.

Background

The thermostatic expansion valve controls the opening degree of the expansion valve through the superheat degree of gaseous refrigerant at the outlet of the evaporator. The valve hole of the conventional thermostatic expansion valve is adjusted by screwing a valve needle with an external device through threads, and the valve needle is driven to move through the threads to adjust the opening degree between the valve needle and the valve hole. The biggest defect of the method is that larger resistance is caused to the valve needle, so that the elastic metal film needs larger force to drive the valve needle to move, the flexibility of the valve needle is greatly reduced, the thermostatic expansion valve is not timely in reaction, and the performance of the thermostatic expansion valve is seriously affected.

SUMMERY OF THE UTILITY MODEL

In view of the above-mentioned defects in the prior art, the technical problem to be solved in the utility model is to provide an electromagnetic thermal expansion valve, its aperture that can survey needle and valve opening.

To achieve the above object, the present invention provides

An electromagnetic thermal expansion valve comprises a valve shell, wherein a hollow valve cavity and a detection cavity are respectively arranged in the valve shell, a valve body is installed in the valve cavity, an input port, a valve hole, an output port, a pressure relief channel, a communicating cavity and a thermal driving cavity are respectively arranged on the valve body, the communicating cavity and the thermal driving cavity are hermetically divided by an elastic metal film, the communicating cavity is communicated with the input port, the thermal driving cavity is communicated with the interior of a thermal bulb through a thermal pipe, the thermal bulb is filled with a second refrigerant for driving the elastic metal film, the thermal bulb is tightly attached to an output pipe, and the output pipe is communicated with the output port;

two ends of the valve hole are respectively communicated with the input port and the output port, a valve needle is axially and slidably arranged in the valve hole, the valve needle is fixed on a valve rod, one end of the valve rod is tightly attached or fixedly connected with an elastic metal film, and the other end of the valve rod penetrates through the valve body and then is arranged in the adjusting cavity and is assembled and fixed with the big end of the valve rod; the large end of the valve rod is clamped with the adjusting cavity and can be assembled in an axial sliding mode, and an adjusting spring is arranged between the large end of the valve rod and the closed end of the adjusting cavity; the adjusting cavity is arranged in the adjusting cylinder, and one end of the adjusting cylinder, which is far away from the valve rod, is fixedly assembled with the adjusting rod;

the utility model discloses a detection device, including regulation pole, conductive piece, insulating spring, conductive piece, first wire, second wire, signal end and PLC's signal terminal communication connection, DC power supply is used for exporting invariable electric current.

Preferably, the conductive block, the conductive sheet, the conductive column and the conductive big end are all conductors, the conductive sheet is fixed in the insulating base, and the insulating base is fixed in the detection cavity.

Preferably, the adjusting cylinder can slide axially, the adjusting rod is clamped in a guide inner hole of the guide block and can be assembled with the guide inner hole in an axially sliding mode, a driving pin is arranged on the outer wall of the adjusting cylinder, the driving pin is arranged in a driving chute and can be assembled with the driving chute in a sliding mode, the driving chute is arranged on the adjusting plate, the adjusting plate is clamped and slidably arranged in the adjusting chute, and the adjusting chute is arranged between the adjusting supporting plate and the valve body.

Preferably, the adjusting chute is provided with a first travel switch and a second travel switch at the maximum displacement positions at two ends of the adjusting plate, the triggering ends of the first travel switch and the second travel switch are just opposite to the adjusting plate, the signal ends of the first travel switch and the second travel switch are in communication connection with the signal end of the PLC, and the PLC is arranged in the valve cavity.

Preferably, the adjusting plate is further provided with a rack portion, the rack portion is formed by a plurality of tooth grooves formed in the adjusting plate and the adjusting plate, the rack portion is in meshing transmission with the first gear, the first gear is in meshing transmission with the second gear, the second gear is fixed to a first output shaft of the first motor, and the first motor is fixed in the valve cavity.

Preferably, the interior of the adjusting rod is a hollow adjusting shaft hole, a damping adjusting rod is circumferentially and slidably mounted in the adjusting shaft hole, one end of the damping adjusting rod penetrates through the adjusting rod and then is fixedly assembled with the damping big end, the damping big end is slidably mounted in the adjusting cavity, and two ends of the adjusting spring are respectively fixed on the damping big end and the valve rod big end;

a plurality of oblique tooth grooves are formed in the damping adjusting rod along the axial direction of the damping adjusting rod, the oblique tooth grooves are in meshing transmission with oblique clamping teeth, the oblique clamping teeth are fixed on a second output shaft, and one end of the second output shaft is installed in a second motor; the second motor is fixed on the motor supporting plate, the motor supporting plate is fixed on the outer wall of the adjusting rod, a rotating shaft hole is formed in the position, corresponding to the second output shaft, of the adjusting rod, and the second output shaft and the rotating shaft hole can be assembled in a circumferential rotating mode.

Preferably, a third travel switch and a fourth travel switch are respectively installed on the adjusting support plate and the guide block, the third travel switch and the fourth travel switch are respectively located at two maximum displacement ends of the motor support plate, signal ends of the third travel switch and the fourth travel switch are in communication connection with a signal end of the PLC, and the motor support plate can respectively trigger the third travel switch and the fourth travel switch.

Preferably, the valve body is still installed through sealed screw thread closure and is adjusted the stopper, adjusts stopper one end and stretches out the valve casing, the other end and packs into the thermal drive intracavity, install the tube head in adjusting the stopper, the tube head lies in one of thermal drive intracavity and serves and be provided with the lead-out groove, and the lead-out groove is with heating power pipe and thermal drive chamber intercommunication, and the tube head packs into and installs the pressure spring between one end terminal surface in thermal drive chamber and the elastic metal membrane.

Preferably, still include the pressure release subassembly, the pressure release subassembly includes the pressure release chamber, and the pressure release chamber communicates with the input port, and the block in the pressure release chamber, slidable, seal installation have the pressure release piston, and the pressure release chamber communicates with pressure release channel one end, and the pressure release channel other end communicates with the delivery outlet.

Preferably, a limiting protrusion is further fixed in the pressure relief cavity and used for limiting the maximum displacement of the pressure relief piston moving towards the microswitch.

The utility model has the advantages that: the utility model discloses simple structure can adjust the aperture between needle and the valve opening in a flexible way through first motor, can not influence normal regulation, the switching of needle after the adjustment moreover to not influencing the normal function and the flexibility of needle, accord with present high accuracy control's demand.

The utility model discloses still realize the detection to needle, the initial aperture of valve opening through conducting block and conducting strip, it detects the high and real durable of skin of precision.

Drawings

Fig. 1 is a schematic structural diagram of the present invention.

Fig. 2 is an enlarged view of fig. 1 at F1.

Fig. 3 is an enlarged view of fig. 1 at F2.

Fig. 4 is an enlarged view of fig. 1 at F3.

Fig. 5 is an enlarged view at F4 in fig. 1.

Fig. 6 is a schematic view of the structure of the adjusting cylinder of the present invention.

Detailed Description

The technical solution in the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention.

In the description of the present invention, it is to be understood that the terms "upper", "lower", "front", "rear", "left", "right", "top", "bottom", "inner", "outer", and the like indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience of description and simplicity of description, and do not indicate or imply that the device or element being referred to must have a particular orientation, be constructed and operated in a particular orientation, and therefore, should not be construed as limiting the present invention.

Referring to fig. 1 to 6, an electromagnetic thermal expansion valve includes a valve housing 110, a hollow valve cavity 111 and a detection cavity 112 are respectively disposed inside the valve housing 110, a valve body 120 is installed inside the valve cavity 111, an input port 121, a valve hole 122, an output port 123, a pressure relief channel 124, a communicating cavity 125, and a thermal driving cavity 126 are respectively disposed on the valve body 120, the communicating cavity 125 and the thermal driving cavity 126 are sealed and divided by an elastic metal film 210, the communicating cavity 125 is communicated with the input port 121, the thermal driving cavity 126 is communicated with the interior of a thermal bulb 920 through a thermal pipe 930, a second refrigerant for driving the elastic metal film 210 is filled in the thermal bulb 920, the thermal bulb 920 is attached to an output pipe 910, and the output pipe 910 is communicated with the output port;

two ends of the valve hole 122 are respectively communicated with the input port 121 and the output port 123, a valve needle 311 is axially slidably mounted in the valve hole 122, the valve needle 311 is fixed on a valve rod 310, one end of the valve rod 310 is tightly attached or fixedly connected with the elastic metal film 210, the other end of the valve rod 310 penetrates through the valve body 120 and then is mounted in the adjusting cavity 323 and is fixedly assembled with the large end 312 of the valve rod, the large end 312 of the valve rod is clamped with the adjusting cavity 323 and is axially slidably assembled, an adjusting spring 370 is mounted between the large end 312 of the valve rod and the closed end of the adjusting cavity 323, and the adjusting spring 370 is used for generating elastic force for blocking the large end 312 of the valve. The valve rod and the valve needle form a valve core.

The adjusting cavity 323 is arranged in the adjusting cylinder 320, one end of the adjusting cylinder 320, which is far away from the valve rod 310, is assembled and fixed with the adjusting rod 330, the adjusting cylinder 320 can slide axially, the adjusting rod 330 is clamped and assembled in the guide inner hole 511 of the guide block 510 and can slide axially, the outer wall of the adjusting cylinder 320 is provided with a driving pin 321, the driving pin 321 is arranged in the driving chute 131 and can slide slidably assembled therewith, the driving chute 131 is arranged on the adjusting plate 130, the adjusting plate 130 is clamped and slidably installed in the adjusting chute 141, the adjusting chute 141 is arranged between the adjusting support plate 140 and the valve body 330, the adjusting chute 141 is provided with a first stroke switch 231 and a second stroke switch 232 at the maximum displacement positions at the two ends of the adjusting plate 130, the triggering ends of the first stroke switch 231 and the second stroke switch 232 are respectively over against the adjusting plate 130, and the adjusting plate 130 can trigger the first stroke switch 231, the signal ends of the first travel switch 231 and the second travel switch 232 are in communication connection with the signal end of the PLC, and the PLC is installed in the valve cavity 111;

the adjusting plate 130 is further provided with a rack portion 132, the rack portion 132 is formed by a plurality of tooth grooves formed in the adjusting plate 130 and the adjusting plate, the rack portion 132 is in meshing transmission with the first gear 410, the first gear 410 is in meshing transmission with the second gear 420, the second gear 420 is fixed on a first output shaft of the first motor 260, the first motor is fixed in the valve cavity 111, and the first motor has a power-off automatic braking function. In this embodiment, the first motor is a stepping motor or a servo motor, and is driven by a first motor driver, and a control end of the first motor driver is in communication connection with a signal end of the PLC.

When the valve needle needs to be adjusted axially, namely the opening between the valve needle and the valve hole is adjusted, the first motor is started, the first motor drives the adjusting plate to move, so that the driving pin 321 is driven to move up and down through the driving chute 131 to drive the valve rod, the adjusting rod and the adjusting cylinder to move axially synchronously, the movement amount of the adjusting rod is fed back to the resistance change between the conducting strip and the conducting block in real time, the adjusting amount can be calculated in real time, the design obviously can obtain higher adjusting precision, and the adjusting sensitivity is also higher. And no matter how the axial direction of the adjusting cylinder is adjusted, the initial acting force between the adjusting spring and the valve rod is hardly influenced, so that the valve needle can be flexibly driven by the elastic metal film and the first refrigerant liquid. In use, a first refrigerant fluid enters the inlet port, then passes through the valve opening to vaporize, and finally exits through outlet tube 910.

The interior of the adjusting rod 330 is a hollow adjusting shaft hole 331, the damping adjusting rod 340 is circumferentially slidably mounted in the adjusting shaft hole 331, one end of the damping adjusting rod 340 penetrates through the adjusting rod 330 and then is fixedly assembled with the damping big end 350, the damping big end 350 is slidably mounted in the adjusting cavity 323, and two ends of the adjusting spring 370 are respectively fixed on the damping big end 350 and the valve rod big end 360;

a plurality of oblique tooth grooves 341 are formed in the damping adjusting rod 340 along the axial direction thereof, the oblique tooth grooves 341 are engaged with the oblique latch teeth 252 for transmission, so as to form a gear rack transmission mechanism, the oblique latch teeth 252 are fixed on the second output shaft 251, one end of the second output shaft 251 is installed in the second motor 250, and the second motor 250 can drive the second output shaft 251 to rotate circumferentially after being electrified;

the second motor 250 is fixed on the motor support plate 332, the motor support plate 332 is fixed on the outer wall of the adjusting rod 330, a rotating shaft hole 333 is arranged at the position of the adjusting rod 330 corresponding to the second output shaft 251, and the second output shaft and the rotating shaft hole can be assembled in a circumferential rotating mode.

When the damping of the valve rod needs to be adjusted, the second motor is started, so that the damping adjusting rod is driven to move axially, the distance between the damping large end 350 and the valve rod large end 360 is also adjusted, the initial compression degree of the adjusting spring 370 is adjusted, and the compression degree of the adjusting spring 370 is directly converted into the resistance of the valve needle to move. The design can adjust the resistance of the valve needle according to the first refrigerants with different pressures, so that the valve needle can adapt to different working conditions.

Preferably, the adjusting support plate 140 and the guide block 510 are respectively provided with a third travel switch 241 and a fourth travel switch 242, the third travel switch 241 and the fourth travel switch 242 are respectively located at two maximum displacement ends of the motor support plate 332, signal ends of the third travel switch 241 and the fourth travel switch 242 are in communication connection with a signal end of the PLC, and the motor support plate 332 can respectively trigger the third travel switch 241 and the fourth travel switch 242. When the adjustment lever is used, the maximum displacement point at which the adjustment lever moves in the axial direction is detected by the third and

fourth stroke switches

241 and 242.

Preferably, referring to fig. 2, since in a part of the refrigeration system, the elastic metal film cannot be driven by the second refrigerant alone, so that the adjustment of the valve needle is not flexible, for this, the applicant installs an adjusting plug 01 on the valve body by screwing through a sealing thread, one end of the adjusting plug 01 extends out of the valve housing 110, and the other end of the adjusting plug is installed in the thermal driving cavity 126, a pipe head 02 is installed in the adjusting plug 01, an outlet groove 021 is provided on one end of the pipe head 02 located in the thermal driving cavity 126, the outlet groove 021 communicates the thermal pipe 930 with the thermal driving cavity 126, and a pressure spring 03 is installed between one end face of the pipe head 02 installed in the thermal driving cavity 126 and the elastic metal film 210. When the pressure regulator is used, the pressure between the pipe head 02 and the pressure spring 03 can be regulated by rotating the regulating plug 01, so that the prestress for pushing the valve rod downwards is generated on the elastic metal film 210. The design is mainly suitable for the conditions that the adjusting spring is too hard, and the initial opening degree of the valve needle and the valve hole has strict requirements.

Preferably, the bottom of the adjusting rod 330 is installed in the detection cavity 112 and assembled and fixed with the adjusting cylinder 670, the adjusting cylinder 670 is internally provided with a hollow adjusting inner cylinder 671, the adjusting inner cylinder 671 is internally engaged and slidably assembled with a conductive big end 651, one end of the conductive big end 651 is electrically connected with the first conducting wire 631, the conductive big end 651 is fixed on the conductive post 650, the conductive post 650 penetrates through the adjusting cylinder 670 and the insulating spring 730 and is electrically connected with the conductive block 640, the insulating spring 730 is used for generating an elastic force for pushing the conductive block 640 to the conductive sheet 620, so that the conductive block 640 always keeps being pressed and electrically conducted with the conductive sheet 620, one end of the conductive sheet 620 is electrically connected with the second conducting wire 632, the first conducting wire 631 is electrically connected with the positive electrode of the dc power supply, the second conducting wire 632 is electrically connected with the negative electrode of the dc power supply, the second conducting wire 632 and the first conducting wire 631 are electrically connected with the negative, therefore, the voltmeter detects the voltage value between the second lead 632 and the first lead 631 in real time, and the signal end of the voltmeter is in communication connection with the signal end of the PLC. The DC power supply is used to output a constant current, and in this embodiment, the DC power supply is an AC-DC converter. When the valve is used, the sliding rheostat is formed between the conducting plate and the conducting block, the conducting block is in contact conduction with the conducting plates at different parts, so that the resistance between the conducting block and the conducting block is changed, the voltage is changed accordingly, the resistance between the conducting plate and the conducting block can be calculated through the change of the voltage, however, only the resistance at the conducting plate is changed, the contact position between the conducting plate and the conducting block can be deduced according to the size, the conductivity and the like of the conducting plate, the position of the conducting block on the conducting plate is converted, and the displacement and the relative position of the adjusting rod are calculated (when the valve needle is in the uppermost state, the state of sealing the valve hole is an initial state, and the. The design structure is very simple, the accuracy rate is high, and the device is more real and durable. And the opening degree between the valve needle and the valve hole can be deduced, thereby facilitating accurate control.

The conductive block 640, the conductive sheet 620, the conductive column 650 and the conductive big end 651 are all conductors, the conductive sheet 620 is fixed in the insulating base 610, and the insulating base 610 is fixed in the detection cavity 112.

Preferably, referring to fig. 2, in order to prevent the cooling system from being damaged or abnormally operated due to the excessive pressure in the input port 121, the applicant further designs a pressure relief assembly, where the pressure relief assembly includes a pressure relief cavity 101, the pressure relief cavity 101 is communicated with the input port 121, a pressure relief piston 220 is clamped, slidably and hermetically mounted in the pressure relief cavity 101, the pressure relief cavity 101 is communicated with one end of a pressure relief channel 124, and the other end of the pressure relief channel 124 is communicated with the output port 123.

The pressure relief cavity 101 is also internally fixed with a limiting protrusion 102, the limiting protrusion 102 is used for limiting the maximum displacement of the pressure relief piston moving towards the microswitch, so that the microswitch is prevented from being crushed, and the pressure relief cavity 101 is arranged in the valve body 120.

When the pressure is normal, the pressure relief channel 124 is sealed and isolated from the pressure relief cavity 101 by the pressure relief piston 220, a pressure relief spring 710 and a microswitch 810 are installed between the pressure relief piston 220 and the closed end of the pressure relief cavity 101, the pressure relief spring 710 is used for generating damping for the pressure relief piston to block the pressure relief piston from moving to the microswitch, the microswitch 810 is fixed on the closed end of the pressure relief cavity 101, a signal end of the microswitch is in communication connection with a signal end of a PLC, and the PLC is installed in the electrical box 130;

when the pressure is too big in the input port, this pressure can drive the pressure release piston to overcome pressure release spring's elasticity and remove to micro-gap switch, until triggering micro-gap switch, pressure release chamber and pressure release channel intercommunication this moment, and first refrigerant passes through pressure release channel discharge pressure release, and micro-gap switch is to PLC input signal, and PLC judges to be pressure too big, then switches on first motor for first motor drive adjusts the pole and moves down, with the initial aperture that increases needle and valve hole. The design is very flexible, and the opening degree of the valve hole and the valve needle can be automatically adjusted according to the first refrigerant pressure.

The details of the present invention are well known to those skilled in the art.

The foregoing has described in detail preferred embodiments of the present invention. It should be understood that numerous modifications and variations can be devised by those skilled in the art in light of the teachings of the present invention without undue experimentation. Therefore, the technical solutions that can be obtained by a person skilled in the art through logic analysis, reasoning or limited experiments based on the prior art according to the concepts of the present invention should be within the scope of protection defined by the claims.

Claims

1. An electromagnetic thermal expansion valve is characterized in that: the temperature sensing bag comprises a valve shell, wherein a hollow valve cavity and a detection cavity are respectively arranged in the valve shell, a valve body is installed in the valve cavity, an input port, a valve hole, an output port, a pressure relief channel, a communicating cavity and a thermal driving cavity are respectively arranged on the valve body, the communicating cavity and the thermal driving cavity are hermetically divided by an elastic metal film, the communicating cavity is communicated with the input port, the thermal driving cavity is communicated with the interior of the temperature sensing bag through a thermal pipe, a second refrigerant for driving the elastic metal film is filled in the temperature sensing bag, the temperature sensing bag is tightly attached to an output pipe, and the output pipe is communicated with the output port;

the utility model discloses a detection device, including regulation pole, conductive piece, insulating spring, conductive piece, insulating spring, regulation pole bottom is packed into and is detected the intracavity and fixed with regulation section of thick bamboo assembly, and regulation section of thick bamboo is inside to be hollow regulation inner tube, and block, slidable are equipped with the electrically conductive main aspects in the regulation inner tube, and electrically conductive main aspects one end is connected with first wire electrically conductive, and electrically conductive main aspects fixes on leading electrical pillar, leads electrical pillar and passes behind regulation section of thick bamboo, insulating spring and be connected with the conductive block is electrically conductive, and the conductive block compresses tightly electrically conductive with the conductive piece, conductive piece one end is electrically conductive with the second wire and is connected, first wire is electrically conductive with DC power supply's anodal electrically conductive connection, the second wire is electrically conductive with voltmeter's negative pole, anodal electrically conductive connection, voltmeter's signal terminal communication.

2. The electromagnetic thermostatic expansion valve of claim 1, wherein: the conductive block, the conductive sheet, the conductive column and the conductive big end are all conductors, the conductive sheet is fixed in the insulating base, and the insulating base is fixed in the detection cavity.

3. The electromagnetic thermostatic expansion valve of claim 1, wherein: the adjusting cylinder can axially slide, the adjusting rod is clamped in a guide inner hole of the guide block and can be axially slidably assembled with the guide inner hole, a driving pin is arranged on the outer wall of the adjusting cylinder, the driving pin is arranged in a driving chute and can be slidably assembled with the driving chute, the driving chute is arranged on an adjusting plate, the adjusting plate is clamped and slidably arranged in an adjusting chute, and the adjusting chute is arranged between the adjusting supporting plate and the valve body.

4. The electromagnetic thermostatic expansion valve of claim 3, wherein: the adjusting chute is located the maximum displacement punishment at adjusting plate both ends and installs first travel switch, second travel switch respectively, first travel switch, second travel switch's trigger end just right with the adjusting plate respectively, and first travel switch, second travel switch's signal end and PLC's signal end communication are connected, and PLC installs in the valve chamber.

5. The electromagnetic thermostatic expansion valve of claim 3, wherein: the adjusting plate is further provided with a rack portion, the rack portion is formed by a plurality of tooth grooves formed in the adjusting plate and the adjusting plate, the rack portion is in meshing transmission with a first gear, the first gear is in meshing transmission with a second gear, the second gear is fixed to a first output shaft of a first motor, and the first motor is fixed in the valve cavity.

6. The electromagnetic thermostatic expansion valve of claim 1, wherein: the damping adjusting rod is characterized in that a hollow adjusting shaft hole is formed in the adjusting rod, a damping adjusting rod is arranged in the adjusting shaft hole in a circumferential sliding mode, one end of the damping adjusting rod penetrates through the adjusting rod and then is assembled and fixed with a damping big end, the damping big end is arranged in the adjusting cavity in a sliding mode, and two ends of an adjusting spring are fixed to the damping big end and the valve rod big end respectively;

7. The electromagnetic thermostatic expansion valve of claim 3, wherein: and the third travel switch and the fourth travel switch are respectively arranged on the adjusting supporting plate and the guide block, the third travel switch and the fourth travel switch are respectively positioned at two maximum displacement ends of the motor supporting plate, the signal ends of the third travel switch and the fourth travel switch are in communication connection with the signal end of the PLC, and the motor supporting plate can respectively trigger the third travel switch and the fourth travel switch.

8. The electromagnetic thermostatic expansion valve of claim 3, wherein: the valve body still closes soon through sealed screw and installs the regulation stopper, adjusts stopper one end and stretches out the valve casing, the other end and packs into the thermal drive intracavity, install the tube head in the regulation stopper, the tube head lies in one of thermal drive intracavity and serves and is provided with the lead-out groove, and the lead-out groove is with thermal power pipe and thermal drive chamber intercommunication, and the tube head is packed into and is installed the pressure spring between the one end terminal surface in thermal drive chamber and the elastic metal membrane.

9. The electromagnetic thermostatic expansion valve of claim 1, wherein: still include the pressure release subassembly, the pressure release subassembly includes the pressure release chamber, and pressure release chamber and input port intercommunication, and the intracavity block of pressure release, slidable, sealing installation have the pressure release piston, pressure release chamber and pressure release channel one end intercommunication, the pressure release channel other end and delivery outlet intercommunication.

10. The electromagnetic thermostatic expansion valve of claim 9, wherein: and a limiting bulge is further fixed in the pressure relief cavity and used for limiting the maximum displacement of the pressure relief piston moving towards the microswitch.