KR20230032849A - Electronic expansion valve and refrigeration system thereof - Google Patents

Abstract

The present invention relates to a refrigeration technology field and, more specifically, to an electronic expansion valve and a refrigeration system thereof. The electronic expansion valve includes a valve seat and a nut assembly. At least one portion of the nut assembly is installed to penetrate the valve seat. The nut assembly includes a nut seat and a connecting sleeve. The connecting sleeve covers the outer circumferential portion of the nut seat and is connected to the nut seat. A rotation stopping unit is installed on the connecting sleeve. The rotation stopping unit is matched with the valve seat to restrict circumferential rotation of the nut seat and the connecting sleeve. Accordingly, the present invention has an advantage of preventing the rotation of the connecting sleeve as the rotation stopping unit is matched with the valve seat to restrict its location. In addition, the present invention can prevent the nut seat from rotating which could affect the functionality of the electronic expansion valve by restricting the location of the nut seat in a circumferential direction through connection of the connecting sleeve and the nut seat.

Description

Electronic expansion valve and its refrigeration system {ELECTRONIC EXPANSION VALVE AND REFRIGERATION SYSTEM THEREOF}

The present invention relates to the field of refrigeration technology, and more particularly to an electronic expansion valve and a refrigeration system thereof.

An electronic expansion valve is a major part of an inverter air conditioner, and can control the liquid supply amount of a heat exchanger according to a predetermined program. This is an important part of refrigeration system intelligence, and an important means and guarantee to truly realize refrigeration system optimization.

Conventional electronic expansion valves typically include a valve seat and nut assembly. The nut assembly is installed through the valve seat, and the nut assembly includes the nut seat. In the process of operation, the nut seat often causes rotational motion, which may affect the implementation of the electronic expansion valve function.

Based on this, the present invention provides an electronic expansion valve to solve the problem of easy rotation of the nut seat described above. The technical solution is as follows.

An electronic expansion valve comprising a valve seat and a nut assembly. At least a portion of the nut assembly is installed through the valve seat. The nut assembly includes a nut seat and a connecting sleeve. The connection sleeve surrounds an outer circumferential side of the nut seat and is connected to the nut seat. A rotation stop is installed on the connecting sleeve. The rotation stop portion may be matched with the valve seat to limit rotation of the connection sleeve and the nut seat in a circumferential direction.

Through this installation, the rotation stop can be matched with the valve seat to limit its position, thereby preventing the connecting sleeve from rotating. Again, through the connection of the connecting sleeve and the nut seat, the circumferential position is limited relative to the nut seat, thereby avoiding the problem that the nut seat rotates and affects the implementation of the electronic expansion valve function.

In one embodiment, the hardness of the valve seat is smaller than the hardness of the connecting sleeve. The valve seat is press-fitted with the connecting sleeve.

Through this installation, when the nut seat and the connecting sleeve are pressed into the valve seat in an interference fit, the valve seat is deformed according to the shape of the connecting sleeve. Therefore, it is possible to form a shape that is matched with the rotation stop and performs the rotation stop function.

In one embodiment, the rotation stop includes a first rotation stop. An outer surface of the connecting sleeve includes a first surface and a second surface. The first surface is a plane. The first surface is connected to the second surface, and a joining point between the first surface and the second surface forms the first rotation stop.

Through this installation, an edge-like structure can be formed between the flat surface and the arc surface. After the inner wall of the valve seat is slightly deformed, the edge-like structure is likely to form a rotation stop fit between it and the valve seat.

In one embodiment, the rotation stop includes a first rotation stop. An outer surface of the connecting sleeve includes a first surface and a second surface. Both the first surface and the second surface are circular arc surfaces. The first surface and the second surface are not concentric. The first surface and the second surface are connected, and a joining point of the first surface and the second surface forms the first rotation stop.

In one embodiment, the rotation stop portion includes a second rotation stop portion. A first concave groove is formed on the side of the connecting sleeve. The second rotation stop portion is formed at a junction between an inner wall of the first concave groove and an outer wall of the connection sleeve. and/or a second concave groove is opened on the end face of the connecting sleeve remote from the valve seat. A junction between the inner wall of the second concave groove and the outer wall of the connecting sleeve forms the second rotation stop. Through this installation, the single concave groove can form a plurality of edge-like structures with the outer wall of the connecting sleeve, thereby enhancing the rotation stopping function of the connecting sleeve.

In one embodiment, the electronic expansion valve further includes a sleeve. The sleeve is mounted on the valve seat. A valve cavity is provided within the sleeve. The nut assembly further includes a screw rod. The screw rod is installed through the nut seat and is threadedly connected to the nut seat. A balance hole is installed on the nut seat. A second concave groove is opened on the end face of the connecting sleeve remote from the valve seat. The balance hole is installed through the second concave groove. An inside of the valve seat communicates with the valve cavity through the balance hole and the second concave groove.

Through this installation, the concave groove and the balance hole penetrate and communicate. Thus, the purpose of balancing the pressure inside and outside the nut seat is achieved.

In one embodiment, the electronic expansion valve further includes a sleeve. The sleeve is mounted on the valve seat. A valve cavity is provided within the sleeve. The nut assembly further includes a screw rod. The screw rod is installed through the nut seat and is threadedly connected to the nut seat. A balance hole is opened in the outer wall of the nut seat. The balance hole is located on one side far from the valve seat of the connecting sleeve. The connecting sleeve does not shield the balance hole. An inside of the nut seat communicates with the valve cavity through the balance hole.

Through this installation, the balance hole directly communicates with the outer cavity of the nut seat, and there is no need to provide a concave groove installed through the balance hole on the connecting sleeve again, simplifying the structure.

In one embodiment, a convex portion is installed on the connecting sleeve. The convex portion is installed perpendicularly to the connecting sleeve. The convex portion is embedded in the nut seat.

Through this installation, the bonding strength between the connecting sleeve and the nut seat is improved.

In one embodiment, the connecting sleeve is made of stainless steel or powder metallurgical material.

This installation guarantees the strength of the connecting sleeve and lowers its cost.

The present invention further provides the following technical solutions.

The refrigeration system includes the aforementioned stop valve.

Compared with the prior art, the stop valve provided by the present invention can prevent the connecting sleeve from rotating by limiting the position of the rotation stop matched with the valve seat. Again, through the connection of the connecting sleeve and the nut seat, the position of the nut seat in the circumferential direction is limited, preventing the nut seat from rotating and affecting the implementation of the electronic expansion valve function.

1 is a cross-sectional view of an electronic expansion valve according to the present invention.
2 is a perspective view of one embodiment of a nut assembly according to the present invention.
3 is a perspective view of another embodiment of a nut assembly according to the present invention.
4 is a perspective view of a connecting sleeve according to the present invention.
5 is a perspective view 1 of Example 3 of a connecting sleeve according to the present invention.
6 is a perspective view 2 of Example 3 of a connecting sleeve according to the present invention.
7 is a perspective view of Example 1 of a connecting sleeve according to the present invention.
The meaning of each symbol in the drawing is as follows.
Reference numeral 100 is an electromagnetic expansion valve, 10 is a valve seat, 11 is a first opening, 12 is a second opening, 13 is a first communication tube, 14 is a second communication tube, 15 is a valve port, 20 is a valve core assembly, and 21 is a valve core. , 22 is an elastic member, 24 is a magnetic rotor, 25 is a first connecting rod, 30 is a nut assembly, 31 is a nut seat, 311 is a balance hole, 32 is a connecting sleeve, 321 is a first rotation stop, and 322 is a first rotation stop. 2 rotation stop, 323 convex portion, 324 first concave groove, 325 second concave groove, 326 first surface, 327 second surface, 33 screw rod, 40 stop assembly, 41 second A connecting rod, 42 is a guide member, 43 is a first position limiting block, 44 is a second position limiting block, 50 is a sleeve, 51 is an end cover, and 52 is a valve cavity.

Hereinafter, the technical solutions of the embodiments of the present application will be clearly and completely described with reference to the accompanying drawings of the embodiments of the present application. The described embodiments are only some rather than all of the present application. All other embodiments obtained by a person skilled in the art without creative work based on the embodiments of the present application fall within the protection scope of the present application.

Note that when a component is described as being “mounted” on another component, it may be directly mounted on the other component or there may be an intervening component. When a component is described as being “installed” on another component, it may be directly installed on the other component or intervening components may exist simultaneously. When one component is described as being "fixed" to another component, it may be directly fixed to the other component or intervening components may exist simultaneously.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this application belongs. Terms used herein in the specification of the present application are for describing specific embodiments, and are not intended to limit the present application. As used herein, the term “or/and” includes any and all combinations of one or more of the related listed items.

Referring to FIGS. 1 to 3 , the electronic expansion valve 100 is mounted in a refrigeration system and is used to communicate and block pipes.

The electronic expansion valve 100 includes a valve seat 10, a sleeve 50, a valve core assembly 20 and a nut assembly 30. The sleeve 50 is connected to the valve seat 10 to provide a closed space for the electronic expansion valve 100 . A valve cavity 52 is provided within the sleeve 50 . One end of the valve core assembly 20 is inserted into the valve seat 10 and used to control the opening of the electronic expansion valve 100 . At least a portion of the nut assembly 30 is positioned within the valve cavity 52 and can move axially along the sleeve 50 with the valve core assembly 20 .

Specifically, the first opening 11, the second opening 12 and the valve port 15 are installed on the valve seat 10. The second opening 12 and the valve port 15 communicate with each other. In this embodiment, the electronic expansion valve 100 is mounted vertically as shown in the accompanying drawings (when terms indicating directions such as up, down, left, right, etc. are mentioned, all electronic expansion valves 100 are basically is mounted vertically, which will not be described again below).

A first communication pipe 13 is connected to one side of the first opening 11 far from the valve core assembly 20 . The first opening 11 communicates with the pipeline of the refrigeration system through the first communication pipe 13 . A second communication pipe 14 is connected to one side of the second opening 12 far from the valve core assembly 20 . The second opening 12 communicates with the pipeline of the refrigeration system through the second communication pipe 14 . The first communication tube 13 and the second communication tube 14 are used as an inlet or outlet of the medium, respectively.

When the first communication tube 13 is used as the inlet of the medium, the medium flows into the electromagnetic expansion valve 100 from the first communication tube 13 and flows into the valve seat 10 through the first opening 11. do. When the electromagnetic expansion valve 100 is open, the medium passes through the valve port 15 and flows out of the electromagnetic expansion valve 100 through the second communication pipe 14 . Likewise, the medium flows into the valve seat 10 from the second communication pipe 14 through the second opening 12, and then passes through the valve port 15 and the first communication pipe 13 to the electronic expansion valve. can flow out of (100).

Optionally, the positions of the first opening 11 and the second opening 12 are not limited to being opened on the lower side and left side of the valve seat 10 in this embodiment. In another embodiment, the first opening 11 and the second opening 12 may be installed on the lower side and the right side of the valve seat 10.

An end cover 51 is installed at one end of the sleeve 50 far from the valve seat 10 . The end cover 51 is connected to the sleeve 50 to seal the port of the sleeve 50, thereby matching the sleeve 50 and sealing the entire electromagnetic expansion valve 100. Optionally, the end cover 51 may be installed to cover the outer circumferential side of the end far from the valve seat 10 of the sleeve 50 to realize sealing. This may be installed inside the end of the sleeve 50 far from the valve seat 10 so that the outer circumferential side of the end cover 51 comes into contact with the inner wall of the sleeve 50 to achieve sealing. The connection method of the end cover 51 and the sleeve 50 is not limited to the above-described individual solutions. It is only necessary to implement the sealing function of the electronic expansion valve 100.

A stop assembly 40 is connected to the inner wall of the end cover 51 and is used to stop the valve core assembly 20 from rising unrestrictedly and at the same time stop the unrestricted descending of the valve core assembly 20 . That is, it shows upper and lower limit actions for the valve core assembly 20 .

Specifically, the stop assembly 40 includes a guide member 42, a second connecting rod 41, a first position limiting block 43 and a second position limiting block 44. One end of the second connecting rod 41 comes into contact with the nut assembly 30, and the other end is embedded in the guide member 42. The outer wall of the guide member 42 has a spiral shape, and the first position limit block 43 and the second position limit block 44 are located at both ends of the guide member 42, respectively.

During the operation process, when the electronic expansion valve 100 is in a valve opening operation state, the nut assembly 30 may rotate and ascend. Since the second connecting rod 41 comes into contact with the nut assembly 30, the nut assembly 30 can also drive the second connecting rod 41 to rotate and rise. The rotation axis of the second connecting rod 41 is coaxial with the guide member 42 . When the second connecting rod 41 rises to the top end of the guide member 42, the position is limited by the first position limiting block 43 and cannot continue to rise, so the nut assembly 30 also rotates and rises. movement is stopped When the second connecting rod 41 descends to the bottom end of the guide member 42, the position is restricted by the second position limit block 44 and cannot continue to descend, so the nut assembly 30 also rotates and descends. this is stopped

The nut assembly 30 includes a nut seat 31, a screw rod 33 and a connecting sleeve 32. The nut seat 31 is installed to at least partially cover the outer circumferential side of the valve core assembly 20 . The screw rod 33 is installed in the nut seat 31 and is threadedly connected with the nut seat 31, and the screw rod 33 is connected with the valve core assembly 20. One end far from the end cover 51 of the nut seat 31 is inserted into the valve seat 10. The connection sleeve 32 surrounds the nut seat 31 and is connected to the nut seat 31 . The assembly formed by the nut seat 31 and the connecting sleeve 32 is press fit with the valve seat 10 .

The nut seat 31 is made of engineering plastic. The connecting sleeve 32 is made of metal or powder metallurgy material. The connecting sleeve 32 serves to protect the nut seat 31 . The nut seat 31 is made of engineering plastic and can be molded using an injection molding process. The quality of the thread in the nut seat 31 can be guaranteed during the injection molding process. The connecting sleeve 32 is made of metal or powder metallurgy material. The metal or powder metallurgy material is relatively hard, so when press-fitting with the valve seat 10, the connecting sleeve 32 can protect the nut seat 31 from being damaged, ensuring the integrity of the nut seat 31. The nut seat 31 and the connecting sleeve 32 are fixedly connected by injection molding.

Specifically, a balance hole 311 is opened on the nut seat 31, and is used to balance the pressure inside the nut seat 31 and the valve cavity 52.

Referring to FIG. 3 , in one embodiment, the balance hole 311 is installed on the outer wall of the nut seat 31 . The balance hole 311 is located on one side far from the valve seat 10 of the connecting sleeve 32 . That is, the connection sleeve 32 implements communication between the inside and outside of the nut seat 31 without shielding the balance hole 311 . Therefore, by balancing the upper and lower pressures of the screw rod 33, the downward movement of the screw rod 33 is prevented from being impossible or difficult because the pressure at the bottom of the screw rod 33 is too great.

Referring to FIG. 2 , in another embodiment, the balance hole 311 is opened within the inner wall covering range of the connecting sleeve 32 . On the cross section of the connecting sleeve 32 far from the valve seat 10, a second concave groove 325 is opened. The second concave groove 325 is installed through the balance hole 311 . The inside of the nut seat 31 communicates with the valve cavity 52 through the balance hole 311 and the second concave groove 325 .

A first connecting rod 25 is installed on the screw rod 33. The first connecting rod 25 is connected to one end far from the valve seat 10 of the screw rod 33, and is matched with the second connecting rod 41 to limit the axial motion path of the screw rod 33. used

The hardness of the connecting sleeve 32 is greater than that of the valve seat 10 . Thus, when the connecting sleeve 32 is pressed into the valve seat 10 with an interference fit, it is ensured that the deformation of the connecting sleeve 32 is very small or basically not deformed.

In one embodiment, the connecting sleeve 32 is annular, and the annular connecting sleeve 32 surrounds the outside of the nut seat 31 .

In another embodiment, the connecting sleeve 32 is strip-shaped, and the connecting sleeve 32 is plural. A plurality of connecting sleeves 32 surround the outer side of the nut seat 31 .

Specifically, a rotation stop is installed on the connecting sleeve 32 . The rotation stop can be matched with the valve seat 10 to limit the circumferential rotation of the connecting sleeve 32 and subsequently the nut seat 31 in the circumferential direction. The hardness of the connecting sleeve 32 is greater than that of the valve seat 10 . By this installation, after the connecting sleeve 32 is inserted into the valve seat 10, the valve seat 10 and the connecting sleeve 32 are press-fitted. In addition, it can be deformed according to the shape of the connection sleeve 32 and closely matched with the connection sleeve 32 . The hardness of the connecting sleeve 32 is likewise greater than that of the nut seat 31 . Therefore, the nut seat 31 and the connecting sleeve 32 are tightly fitted and the coupling becomes more tight.

Referring also to FIG. 7 , in the first embodiment, the rotation stop portion includes a first rotation stop portion 321 . On the outer surface of the connecting sleeve 32, a first surface 326 and a second surface 327 are included. The first surface 326 is installed as a plane, and the first surface 326 and the second surface 327 are connected. Also, the junction of the first surface 326 and the second surface 327 forms a first rotation stop 321 . After the connecting sleeve 32 is inserted into the valve seat 10, the connecting sleeve 32 and the valve seat 10 are press fit. The valve seat 10 causes a corresponding deformation according to the above-described edge-like shape of the junction of the first surface 326 and the second surface 327. Through this, it is matched with the first rotation stop 321 to limit the rotational position of the connection sleeve 32 .

It is understood that the outer surface of the connecting sleeve 32 may further include a third surface and a fourth surface, wherein the third surface is a flat surface and the fourth surface is an arc surface. That is, on the outside of the connection sleeve 32, two planes are spaced apart from each other. Two arc surfaces are installed between the two planes. The combination of the outer plane and arc surface of the connecting sleeve 32 is not limited to the combination of one arc surface and one plane surface according to the present embodiment, or two arc surfaces and two plane surfaces.

In Embodiment 2, both the first surface 326 and the second surface 327 on the connecting sleeve 32 are installed as circular arc surfaces. The arc surfaces of the first surface 326 and the second surface 327 are not concentric. The first surface 326 and the second surface 327 are connected, and the junction of the two forms a first rotational stop 321 .

Optionally, a third surface may be further installed outside the connecting sleeve 32 . The third surface is also an arc surface, and the arc surface combination outside the connecting sleeve 32 is not limited to the combination of two arc surfaces according to the present embodiment.

In Example 3, referring to FIGS. 5 and 6 , a first concave groove 324 is formed on the connecting sleeve 32 . The junction between the inner wall of the first concave groove 324 on the connecting sleeve 32 and the outer wall of the connecting sleeve 32 forms a second rotational stop 322 . As described above, when the connecting sleeve 32 is inserted into the valve seat 10, the second rotation stop 322 is matched with the valve seat 10 like the first rotation stop 321 to connect the sleeve 32 ) can be limited. Alternatively, the junction between the inner wall of the second concave groove 325 and the outer wall of the connecting sleeve 32 forms the second rotation stop 322 . Alternatively, the first concave groove 324 and the second concave groove 325 are installed on the connecting sleeve 32 at the same time, and the first concave groove 324, the second concave groove 325 and the connecting sleeve 32 The junction points between the outer walls each form a second rotation stop 322 .

Optionally, referring to FIG. 4, in Embodiment 1 and Embodiment 2, or in a combination of Embodiments 1 and 2, one or more first recesses 324 are provided on the side of the connecting sleeve 32. can also be installed. The opening of the first concave groove 324 does not affect the installation of the flat and arcuate surfaces in the above-described embodiments. Alternatively, one or more second concave grooves 325 are formed on the cross section of the connecting sleeve 32 far from the valve seat 10 . The second concave groove 325 and the balance hole 311 are installed through, and the balance hole 311 can communicate with the valve cavity 52 .

A convex portion 323 is installed on the connecting sleeve 32 . The convex portion 323 is embedded in the nut seat 31 and is used to strengthen the connection between the connecting sleeve 32 and the nut seat 31.

Preferably, in this embodiment, an included angle between the connecting sleeve 32 and the convex portion 323 is a right angle. In another embodiment, an included angle between the connecting sleeve 32 and the convex portion 323 may be an obtuse angle or an acute angle.

The valve core assembly 20 includes a valve core 21 and an elastic member 22 . The valve core 21 is used to insert into the valve port 15 to realize flow control of the electronic expansion valve 100. The screw rod 33 and the valve core 21 are rotationally connected. The elastic member 22 is installed in the screw rod 33. One end of the elastic member 22 abuts on the valve core 21 and the other end abuts on the screw rod 33 . When the valve core 21 is inserted into the valve port 15, the elastic member 22 may exert a buffer action on the screw rod 33 and the valve core 21.

The electronic expansion valve 100 further includes a magnetic rotor 24 . The magnetic rotor 24 is connected to the outer wall of the top end far from the valve seat 10 of the screw rod 33. When an electromagnetic coil (not shown) is energized and a magnetic field is generated, the magnetic rotor 24 is driven to rotate and the screw rod 33 is driven to rotate. Since the nut seat 31 does not rotate after the position is limited by the stop portion, the screw rod 33 drives the valve core 21 to realize the lifting movement. Optionally, the valve core assembly 20 may select other actuating members. It is only necessary to drive the valve core assembly 20 to rotate.

The present invention further provides a refrigeration system including the electronic expansion valve 100 described above. The electronic expansion valve 100 is mounted in the medium passage of the refrigeration system to control the flow rate of the passage.

During operation of the electromagnetic expansion valve 100, when the electromagnetic expansion valve 100 needs to be opened wide, the magnetic rotor 24 is rotated through an external electromagnetic coil to drive the screw rod 33 to rotate. The screw rod 33 drives the valve core 21 to rise through thread matching with the nut seat 31 . The first connecting rod 25 on the screw rod 33 may abut against the second connecting rod 41 . The second connecting rod 41 rises along the guide path on the guide member 42 . Since the upward movement is stopped when the top end is reached, the upward movement of the valve core 21 is also stopped. When the electromagnetic expansion valve 100 needs to be closed slightly, the electromagnetic coil is energized in the reverse direction to rotate the magnetic rotor 24 in the reverse direction, and finally the valve core 21 is lowered. Since the valve core 21 is inserted into the valve port 15, the gap between the valve core 21 and the inner wall of the valve port 15 is reduced and the flow rate of the medium is reduced.

Compared with the prior art, the rotation stop provided in the present invention is matched with the valve seat 10 to limit its position, thereby preventing the connection sleeve 32 from rotating. Again, by limiting the position of the nut seat 31 in the circumferential direction through the connection of the connection sleeve 32 and the nut seat 31, the nut seat 31 rotates to affect the implementation of the electronic expansion valve 100 function. prevent problems from

The technical features of the foregoing embodiments may be arbitrarily combined. For concise description, all possible combinations of technical features according to the foregoing embodiments have not been described, but as long as there is no contradiction in the combinations of technical features, they should all be considered within the scope described in the present invention.

The foregoing embodiments represent various embodiments of the present application, and the description is relatively specific and detailed, but should not be construed as limiting the scope of the patent of the present application. It should be noted that a person skilled in the art to which this application pertains may make modifications and improvements without departing from the spirit of the present invention, all of which fall within the protection scope of this application. Therefore, the scope of protection of the patent of this application is based on the appended claims.

Claims (10)

In the electronic expansion valve,
It includes a valve seat 10 and a nut assembly 30, and at least a portion of the nut assembly 30 is installed through the valve seat 10,
The nut assembly 30 includes a nut seat 31 and a connection sleeve 32, and the connection sleeve 32 surrounds an outer circumferential side of the nut seat 31 and is connected to the nut seat 31, A rotation stop is installed on the connection sleeve 32, and the rotation stop is matched with the valve seat 10 to limit rotation of the connection sleeve 32 and the nut seat 31 in the circumferential direction. Characterized by an electronic expansion valve. According to claim 1,
The electromagnetic expansion valve, characterized in that the hardness of the valve seat (10) is smaller than the hardness of the connecting sleeve (32), and the valve seat (10) is press-fitted with the connecting sleeve (32). According to claim 2,
The rotation stop portion includes a first rotation stop portion 321, the outer surface of the connection sleeve 32 includes a first face 326 and a second face 327, the first face 326 is a plane, the first surface 326 is connected to the second surface 327, and the junction between the first surface 326 and the second surface 327 is the first rotation stop 321 ) Electronic expansion valve, characterized in that to form. According to claim 2,
The rotation stop portion includes a first rotation stop portion 321, the outer surface of the connection sleeve 32 includes a first face 326 and a second face 327, the first face 326 and the second surface 327 is a circular arc surface, the first surface 326 and the second surface 327 are not concentric, and the first surface 326 and the second surface 327 are The electronic expansion valve, characterized in that connected and the junction of the first surface (326) and the second surface (327) form the first rotation stop (321). The method of claim 2, 3 or 4,
The rotation stop portion includes a second rotation stop portion 322, a first concave groove 324 is opened on the side of the connection sleeve 32, and an inner wall of the first concave groove 324 and the connection sleeve ( The joining point between the outer walls of 32) forms the second rotation stop 322, and/or a second concave groove 325 is formed on the cross section of the connecting sleeve 32 away from the valve seat, An electromagnetic expansion valve, characterized in that a junction between the inner wall of the second concave groove (325) and the outer wall of the connecting sleeve (32) forms the second rotation stop (322). According to claim 1,
The electromagnetic expansion valve further includes a sleeve 50, the sleeve 50 is mounted on the valve seat 10, a valve cavity 52 is provided in the sleeve 50, and the nut assembly 30 further includes a screw rod 33, the screw rod 33 is installed through the nut seat 31 and is threadedly connected with the nut seat 31, and a balance on the nut seat 31 A hole 311 is installed, and a second concave groove 325 is opened on an end surface of the connecting sleeve 32 far from the valve seat, and the balance hole 311 and the second concave groove 325 are penetrated. and the inside of the nut seat 31 communicates with the valve cavity 52 through the balance hole 311 and the second concave groove 325. According to claim 1,
The electromagnetic expansion valve further includes a sleeve 50, the sleeve 50 is mounted on the valve seat 10, a valve cavity 52 is provided in the sleeve 50, and the nut assembly 30 further includes a screw rod 33, the screw rod 33 is installed through the nut seat 31 and is threadedly connected with the nut seat 31, and the outer wall of the nut seat 31 A balance hole 311 is installed, and the balance hole 311 is located on one side far from the valve seat of the connection sleeve 32, and the connection sleeve 32 does not shield the balance hole 311. , The electronic expansion valve, characterized in that the inside of the nut seat (31) communicates with the valve cavity (52) through the balance hole (311). According to claim 1,
A convex portion 323 is installed on the connecting sleeve 32, the convex portion 323 is installed vertically with the connecting sleeve 32, and the convex portion 323 is embedded in the nut seat 31. Electronic expansion valve, characterized in that being. According to claim 1,
The electronic expansion valve, characterized in that the connecting sleeve (32) is made of stainless steel or powder metallurgy material. A refrigeration system comprising the electronic expansion valve according to any one of claims 1 to 4 and 6 to 9.

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