KR20220028024A - Valve core assembly and electronic expansion valve having same - Google Patents

Abstract

In the valve core assembly, it includes a screw rod (10) and an annular structure (20). Here, the annular structure 20 is a bush or bearing. The screw rod 10 is an integrally formed structure, and the screw rod 10 includes a first rod section 11 and a flanging structure 12 installed at one end of the first rod section 11 . The radial dimension of the flanging structure 12 is larger than the radial dimension of the first rod section 11 . The first rod section 11 is installed through the annular structure 20 . A gap is provided between the circumferential surface of the first rod section 11 and the inner wall of the annular structure 20 , and the flanging structure 12 is matched with one end of the annular structure 20 in a position limit.

Description

Valve core assembly and electronic expansion valve having same

The present application relates to the field of valve technology, and more particularly, to a valve core assembly and an electronic expansion valve having the same.

In the valve core assembly of a conventional electromagnetic expansion valve, a bush or bearing is assembled on a screw rod with an interference fit. Among them, the bush and the screw rod are fixed integrally again by laser welding. The coaxiality of the screw rod and the valve needle is greatly affected by the installation location, and the coaxiality error of the electromagnetic expansion valve is easy to occur in the structure of the nut and valve port after assembly. This may cause jamming between the valve needle and the valve port during use, and at the same time have a relatively large frictional force, which may affect the valve opening performance.

The present application provides a valve core assembly and an electronic expansion valve having the same, thereby solving the problem that the electronic expansion valve is easily clogged during use in the prior art.

In order to solve the above problem, in one aspect of the present application, the present application provides a valve core assembly. Here, a screw rod having an integrally formed structure and including a first rod section and a flanging structure installed at one end of the first rod section, wherein a radial dimension of the flanging structure is greater than a radial dimension of the first rod section; and annular structure - the first rod section is installed through the annular structure, a gap is provided between the circumferential surface of the first rod section and the inner wall of the annular structure, and one end of the flanging structure and the annular structure is position-limited and matched, The structure is a bush or bearing.

Also, the flanging structure is shaped like a trumpet.

In addition, the first rod section has a process hole, and the process hole communicates with the hole of the flanging structure.

Also, the flanging structure is a stamping forming structure.

In addition, the screw rod further includes a second rod section. The second load section is connected to the other end of the first load section. The diameter of the second rod section is greater than the diameter of the first rod section. The cross section of the second rod section is matched with the other end of the annular structure in a position limit. The distance between the cross section of the second rod section and the flanging structure is greater than the axial dimension of the annular structure.

The valve core assembly also includes a first pressure sleeve. The second rod section is installed through the first pressure sleeve. A gap is provided between the circumferential surface of the second rod section and the inner wall of the first pressure sleeve. An end of the first pressure sleeve is positionally matched with an end of the annular structure.

Also, the annular structure is a bush. A second position limiting step is provided on the outer wall of the bush. The valve core assembly includes an elastic member having one end installed to cover the bush and in contact with the second position limiting step; and a valve needle in contact with the other end of the elastic member.

Also, the annular structure is a bearing. The valve core assembly includes: a second pressure sleeve, the end of which abuts against the bearing, and having a third position limiting step on an outer wall thereof; an elastic member having one end installed to cover the second pressure sleeve and in contact with the third position limiting step; and a valve needle in contact with the other end of the elastic member.

Also, one end of the second pressure sleeve facing the flanging structure has a conical hole, and the conical hole is used to avoid the flanging structure.

Another aspect of the present application provides an electronic expansion valve, which includes the above-described valve core assembly.

In applying the technical solution of the present application, a screw rod and an annular structure are installed in the valve core assembly. Here, the annular structure is a bush or bearing. The screw rod has an integrally formed structure, and the screw rod includes a first rod section and a flanging structure installed at one end of the first rod section. A radial dimension of the flanging structure is greater than a radial dimension of the first rod section. The first rod section is installed through the annular structure. A gap is provided between the circumferential surface of the first rod section and the inner wall of the annular structure, and the flanging structure is matched with one end of the annular structure by position restriction. A gap is provided between the screw rod and the annular structure, the screw rod being movable with respect to the annular structure. Therefore, in use, some structures of the valve core assembly can automatically perform adaptive position adjustment according to the coaxiality error of the structure, such as the nut and valve port of the electromagnetic expansion valve. This prevents the electronic expansion valve from clogging easily and reduces friction between some structures to improve valve opening performance.

BRIEF DESCRIPTION OF THE DRAWINGS The accompanying drawings, which form a part of the present application, are provided to provide a further understanding of the present application. Exemplary embodiments of the present application and descriptions thereof are provided to interpret the present application, and do not limit the present application. The description of the accompanying drawings is as follows.
1 is a structural diagram of a valve core assembly according to Example 1 of the present application.
FIG. 2 is a partially enlarged view of FIG. 1 .
3 is a structural diagram in which the valve core assembly of FIG. 1 is applied to the electromagnetic expansion valve.
4 is a structural diagram in which the valve core assembly according to Embodiment 2 of the present application is applied to an electromagnetic expansion valve.
FIG. 5 is a partially enlarged view of FIG. 4 .
Herein, the following reference numbers are included in the accompanying drawings.
10 is a screw rod, 11 is a first rod section, 12 is a flange structure, 13 is a process hole, 14 is a second rod section, 20 is an annular structure, 30 is a first pressure sleeve, 40 is a valve sleeve, 50 is elastic Member, 60 is a valve needle, 70 is a second pressure sleeve, 71 is a conical hole.

Hereinafter, the technical solutions of the embodiments of the present application will be clearly and completely described with reference to the drawings of the embodiments of the present application. Of course, the described embodiments are only some, not all of the embodiments of the present application. One or more exemplary embodiments below are for illustrative purposes only and do not limit the present application and its application or use. All other embodiments obtained by those skilled in the art without creative work based on the embodiments of the present application fall within the protection scope of the present application.

As shown in the drawings, an embodiment of the present application provides a valve core assembly. Here, it is an integrally formed structure, and the first rod section 11 and the screw rod 10 including the flanging structure 12 installed at one end of the first rod section 11 - the radial direction of the flanging structure 12 . The dimension is greater than the radial dimension of the first rod section 11 ; And the annular structure 20 - the first rod section 11 is installed through the annular structure 20, a gap is provided between the circumferential surface of the first rod section 11 and the inner wall of the annular structure 20, One end of the flanging structure 12 and the annular structure 20 is position-limited matched, and the annular structure 20 is a bush or a bearing.

In applying the technical solution of the present application, the screw rod 10 and the annular structure 20 are installed in the valve core assembly. Here, the annular structure 20 is a bush or bearing. The screw rod 10 is an integrally molded structure, and the screw rod 10 includes a first rod section 11 and a flanging structure installed at one end of the first rod section 11 . The radial dimension of the flanging structure is larger than the radial dimension of the first rod section 11 . The first rod section 11 is installed through the annular structure 20 . A gap is provided between the circumferential surface of the first rod section 11 and the inner wall of the annular structure 20 , and the flanging structure is matched with one end of the annular structure 20 in a position limit. A gap is provided between the screw rod 10 and the annular structure 20 , the screw rod 10 being movable relative to the annular structure 20 . Therefore, in use, some structures of the valve core assembly can automatically perform adaptive position adjustment according to the coaxiality error of the structure, such as the nut and valve port of the electromagnetic expansion valve. This prevents the electronic expansion valve from clogging easily and reduces friction between some structures to improve valve opening performance.

In this embodiment, the flanging structure 12 is shaped like a trumpet ball. When the flanging structure 12 is installed in the shape of a flare, the annular structure 20 can be easily assembled and disassembled, and the flanging structure 12 can be easily processed and molded. Optionally, the included angle between the sidewall of the flanging structure 12 and the axial direction of the first rod section 11 is between 40 degrees and 50 degrees.

In this embodiment, the flanging structure 12 is a stamping forming structure. By adopting the stamping forming method, the flanging structure 12 can be easily processed and formed, and the process is simple and the cost is low.

In addition, the first rod section 11 has a process hole 13 , and the process hole 13 communicates with the hole of the flanging structure 12 . When the process hole 13 is installed, the flanging structure 12 can be easily formed. The process hole 13 is used for tools that avoid stamping forming.

In this embodiment, the screw rod 10 further includes a second rod section 14 . The second load section 14 is connected to the other end of the first load section 11 . The diameter of the second rod section 14 is larger than the diameter of the first rod section 11 . The cross-section of the second rod section 14 is matched with the other end of the annular structure 20 by position limitation. The distance between the cross section of the second rod section 14 and the flanging structure 12 is greater than the axial dimension of the annular structure 20 . In this way, it is possible to limit the positions of both ends of the annular structure 20 through the second rod section 14 and the flanging structure 12, respectively. Also, the distance between the cross section of the second rod section 14 and the flanging structure 12 is greater than the axial dimension of the annular structure 20 . Therefore, the annular structure 20 and the screw rod 10 can cause a constant relative displacement in the axial direction to adjust the position and adapt to the assembly error.

In this embodiment, the valve core assembly further includes a first pressure sleeve 30 . The second rod section 14 is installed through the first pressure sleeve 30 . A gap is provided between the circumferential surface of the second rod section 14 and the inner wall of the first pressure sleeve 30 . The end of the first pressure sleeve 30 is positionally matched with the end of the annular structure 20 . The first pressure sleeve 30 may serve as a position limiting relative to the annular structure 20 . Optionally, a first position limiting step is provided on the outer wall of the first pressure sleeve 30 . The valve core assembly further includes a valve sleeve 40 . A part of the first pressure sleeve 30 is installed through the valve sleeve 40 , and the first position limiting step comes into contact with the end face of the valve sleeve 40 to perform positioning and position limiting roles. In this embodiment, the annular structure 20 is a bush.

In this embodiment, the annular structure 20 is a bush. A second position limiting step is provided on the outer wall of the bush. The valve core assembly includes an elastic member 50 having one end installed to cover the bush and in contact with the second position limiting step; And it further includes a valve needle 60 in contact with the other end of the elastic member (50). The valve needle 60 is used to block the valve port of the electromagnetic expansion valve, and the elastic member 50 may serve to pre-tighten the valve needle 60 .

In the second embodiment, the difference from the above-described embodiment is as follows. That is, the annular structure 20 is a bearing, and the valve core assembly includes: a second pressure sleeve 70 whose end abuts against the bearing and has a third position limiting step on its outer wall; an elastic member 50 whose one end is installed to cover the second pressure sleeve 70 and is in contact with the third position limiting step; And it further includes a valve needle 60 in contact with the other end of the elastic member (50). By installing the second pressure sleeve 70, the elastic member 50 and the bearing can be spaced apart, thereby protecting the bearing and improving reliability. Specifically, the second pressure sleeve 70 is in contact with the outer ring of the bearing.

Optionally, the valve core assembly further includes a valve sleeve 40 . The screw rod 10 is installed through the valve sleeve 40 . The bearing is located within the valve sleeve 40 . One end of the valve sleeve 40 has an annular position limiting structure, and the annular position limiting structure is matched with the outer ring of the bearing for position limiting. The cross section of the second rod section 14 of the screw rod 10 is matched with the inner ring of the bearing and the position limit.

In this embodiment, one end of the second pressure sleeve 70 facing the flanging structure 12 is provided with a conical hole 71 , and the conical hole 71 is used to avoid the flanging structure 12 . do. Through the above-described installation, it is possible to prevent the flanging structure 12 from interfering with the second pressure sleeve 70 .

Another embodiment of the present application provides an electronic expansion valve, which includes the above-described valve core assembly. In applying the technical solution of this embodiment, the screw rod 10 and the annular structure 20 are installed in the valve core assembly. Here, the annular structure 20 is a bush or bearing. The screw rod 10 is an integrally molded structure, and the screw rod 10 includes a first rod section 11 and a flanging structure installed at one end of the first rod section 11 . The radial dimension of the flanging structure is larger than the radial dimension of the first rod section 11 . The first rod section 11 is installed through the annular structure 20 . A gap is provided between the circumferential surface of the first rod section 11 and the inner wall of the annular structure 20 , and the flanging structure is matched with one end of the annular structure 20 in a position limit. A gap is provided between the screw rod 10 and the annular structure 20 , the screw rod 10 being movable relative to the annular structure 20 . Therefore, in use, some structures of the valve core assembly can automatically perform adaptive position adjustment according to the coaxiality error of the structure, such as the nut and valve port of the electromagnetic expansion valve. This prevents the electronic expansion valve from clogging easily and reduces friction between some structures to improve valve opening performance.

In the present application, the gap fit is both between the screw rod and the pressure sleeve and between the screw rod and the bush (or bearing). The bush is locked in the screw rod through flanging, and by controlling the flanging position after assembly, it is possible to freely rotate between the screw rod and the bush while securing the connection strength between the bush and the screw rod. The bush abuts against the pressure sleeve, and the gap allows the screw rod to move within a certain range. Through the design of the flanging wall thickness and flanging amount, the connection strength between the screw rod and the bush is ensured. The above method prevents clogging during product assembly due to a coaxiality error between the nut and the valve port. It also reduces the friction between the screw rod bush assembly and the pressure sleeve, which helps to improve the product's valve opening performance.

Since the above content is only a preferred embodiment of the present application, it does not limit the present application. Those skilled in the art to which this application pertains can variously modify and change the present invention. All modifications, equivalent substitutions, improvements, etc. made within the spirit and principle of the present application shall be included within the protection scope of the present application.

Claims (10)

A valve core assembly comprising:
A screw rod 10 having an integrally molded structure and including a first rod section 11 and a flanging structure 12 installed at one end of the first rod section 11; and
and an annular structure 20 through which the first rod section 11 is installed therein,
The radial dimension of the flanging structure 12 is larger than the radial dimension of the first rod section 11,
A gap is provided between the circumferential surface of the first rod section 11 and the inner wall of the annular structure 20, and one end of the flanging structure 12 and the annular structure 20 is position-limited matching,
The valve core assembly, characterized in that the annular structure (20) is a bush or bearing. The method of claim 1,
The valve core assembly, characterized in that the flanging structure (12) is in the shape of a flare. 3. The method of claim 2,
The first rod section (11) includes a process hole (13), and the process hole (13) communicates with the hole of the flanging structure (12). 3. The method of claim 2,
The valve core assembly, characterized in that the flanging structure (12) is a stamping forming structure. The method of claim 1,
The screw rod 10 further includes a second rod section 14,
The second load section 14 is connected to the other end of the first load section 11 , and the diameter of the second load section 14 is larger than the diameter of the first load section 11 , and the second The cross-section of the rod section 14 is matched with the other end of the annular structure 20 by position limitation, and the distance between the cross section of the second rod section 14 and the flanging structure 12 is that of the annular structure 20 . A valve core assembly, characterized in that it is larger than the axial dimension. 6. The method of claim 5,
The valve core assembly further comprises a first pressure sleeve (30),
The second rod section 14 is installed through the first pressure sleeve 30 , and a gap is provided between the circumferential surface of the second rod section 14 and the inner wall of the first pressure sleeve 30 , , the end of the first pressure sleeve (30) is a valve core assembly, characterized in that the position limit matching with the end of the annular structure (20). The method of claim 1,
The annular structure 20 is a bush, and a second position limiting step is provided on the outer wall of the bush,
The valve core assembly,
an elastic member 50 in contact with the second position limiting step; and
Further comprising a valve needle (60) in contact with the other end of the elastic member (50),
The valve core assembly, characterized in that one end of the elastic member (50) is installed to cover the bush. The method of claim 1,
The annular structure 20 is a bearing,
The valve core assembly further comprises a second pressure sleeve (70), an elastic member (50) and a valve needle (60),
The end of the second pressure sleeve 70 abuts against the bearing and has a third position limiting step on the outer wall of the second pressure sleeve 70,
One end of the elastic member 50 is installed to cover the second pressure sleeve 70, and comes into contact with the third position limiting step,
The valve needle (60) is a valve core assembly, characterized in that in contact with the other end of the elastic member (50). 9. The method of claim 8,
One end of the second pressure sleeve (70) facing the flanging structure (12) has a conical hole (71), the conical hole (71) being used to avoid the flanging structure (12) Features a valve core assembly. An electronic expansion valve comprising the valve core assembly according to claim 1 .

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