KR20180091852A - Two-stage electronic expansion valve - Google Patents

Abstract

The present invention provides a two-stage electronic expansion valve comprising a motor (1) and a speed reducer (2) connected to an output end of the motor (1), the bellows (11) being covered on the outer surface of the valve rod Wherein the bellows (11) is extended or contracted by reciprocating movement of the valve rod (15), the first valve hole (13) is opened or closed according to the valve rod (15) In the two-stage electronic expansion valve provided in the present invention, the lower end portion of the valve core 12 and the first valve hole 13 are formed in the valve- It is possible to solve the problem of abnormal noise which occurs when the initial volume of the existing electronic expansion valve is controlled by the contact state and the fluid passes through the mesh-like noise member and the vortices and bubbles therein are largely removed and dispersed. At the same time, since the volume control is mainly performed through the second valve hole 125 provided in the valve core, the flow control range is wider and the precision is higher under the condition of the same pulse quantity.

Description

Two-stage electronic expansion valve

The present application claims the priority of Chinese patent application filed on Dec. 9, 2015 with the application number of 201510908144.1, the name of which is "2-stage electronic expansion valve", and all contents disclosed in the application .

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to refrigeration equipment technology, and more particularly to an electronic expansion valve used in an inverter air conditioner.

The electronic expansion valve is mainly used in the inverter air conditioning system. It drives the motor by the high pulse frequency current and rotates it, operates the direct speed reducer, and is also screw thread pair. It is transferred by the valve rod to lift the valve needle, The flow rate of the refrigerant is automatically adjusted so that the refrigerant circuit system always maintains the highest state.

Referring to FIG. 1, FIG. 1 illustrates a structure of an electronic expansion valve in the prior art.

As shown in Fig. 1, this electronic expansion valve mainly comprises a valve body portion for regulating the flow rate and a coil portion used for driving. Here, the coil portion includes a motor 1 ', a speed reducer 2', a screw coupling structure 5 'for converting rotational motion of the motor 1' into vertical movement of the screw rod 3 ' And the motor case 6 'are riveted to the outside of the gear box 9' outside the speed reducer 2 '. The valve body portion includes key components such as a valve seat 14 ', a valve rod 15', and a bellows 11 'for controlling the elevation of the valve needle 12'. The working principle is that the rotor of the motor 1 'rotates to rotate the reducer 2' and is transmitted by the threaded structure 5 'so that the screw rod 3' moves downward and the valve needle 12 ' Pushes the force transmitting component bush 16 'and the valve rod 15' downwardly. At this time, the bellows 11 'is continuously extended. Applying a reverse pulse will cause the screw rod 3 'to move up and the valve needle 12' will move up constantly under the action of restoring resilience of the bellows 11 'and system pressure to change the degree of opening of the valve hole 13' Thereby realizing the purpose of changing the passage area, controlling the flow rate, and adjusting the system.

In the structure of such an electronic expansion valve, in the period from the fully closed state to the initial control of the propylene content, that is, the valve needle 12 'gradually comes into contact with the valve hole 13' The degree of opening of the valve hole 13 'is small so that the flow rate can be definitely limited, the velocity of the fluid passing through the valve hole portion is greatly increased, and the abnormal noise due to the vortex of the specified frequency is generated, Which affects the feeling of the user. Further, according to the electronic expansion valve of this structure, the valve hole 13 'is large, so that the control range in the amount of ownership is narrow and it is disadvantageous in adjustment of higher precision.

Therefore, designing an electronic expansion valve capable of reducing abnormal noise within the range of the initial amount of ownership adjustment and improving the controllability and precision of the amount of ownership has become a problem to be solved by those skilled in the art.

A second object of the present invention is to provide a two-stage electronic expansion valve for an inverter air conditioner capable of improving the accuracy of adjustment in the amount of oil while reducing abnormal noise within the controllable range. do

A two-stage electronic expansion valve comprising a motor and a speed reducer connected to an output end of the motor, wherein a bellows is covered on the outer surface of the valve rod and the bellows is extended or contracted by reciprocating movement of the valve rod, And a valve core in which a first valve hole is opened or closed and a second valve hole provided in a lower portion of the valve rod and a second valve hole is provided inside the valve core.

The valve core is cylindrical and has a first cavity and a second cavity at both ends thereof, respectively, and a second valve hole is opened between the first cavity and the second cavity.

A further obstruction is provided in the first cavity and the lower end of the valve rod penetrates the obstruction and extends into the first cavity to achieve a mutually movable connection between the valve rod and the obstruction by the position limiting element.

The position restricting part is a washer, an annular groove is formed in the valve rod, and a washer is inserted into the annular groove.

The disturbance part and the valve core are fixed through welding or crimping.

The valve core includes a large diameter section and a small diameter section, and a flow section is formed on an outer wall of the large diameter section.

A flow port is formed in the valve core, and the flow path communicates the first cavity and the outer space of the valve core.

A first noise absorbing member is provided in the first cavity so that fluid introduced from the flow passage is subjected to noise treatment of the first noise absorbing member and then discharged from the second valve hole.

And a second noise member is installed in the second cavity.

And fixes the second noise insulating member in the second cavity in such a manner that the bottom of the valve core is crimped and deformed.

A pressing member is provided at the bottom of the valve core, and the pressing member is forcedly engaged with the valve core to fix the second noise insulating member in the second cavity.

The second noise member includes an upper noise member and a lower noise member.

A normally open type device is provided between the first cavity and the second cavity to maintain a constant flow rate between the first cavity and the second cavity at all times.

The washer has an opening and a contact portion, and the contact portion contacts the circumferential wall of the annular groove.

According to the two-stage electronic expansion valve provided in the present invention, the lower end of the valve core and the first valve hole are always in contact with each other at the time of controlling the proprietary amount, and the fluid passes through the mesh-like noise member, Thus, it is possible to solve the problem of abnormal noise that occurs when the initial amount of the electronic expansion valve is controlled. At the same time, since the volume control is mainly made through the second valve hole provided inside the valve core, the flow control range is wider and the precision is higher under the condition of the same pulse quantity.

1 is a view showing a structure of an electronic expansion valve in the prior art.
2 is a view showing the structure of a first embodiment of a two-stage electronic expansion valve provided in the present invention.
3 is a cross-sectional view showing a partial structure of the first embodiment of the present invention.
4 is a view showing a washer structure according to the first embodiment of the present invention.
5 is a cross-sectional view showing a partial structure of a second embodiment of a two-stage electronic expansion valve provided in the present invention.
6 is a cross-sectional view showing a partial structure of a third embodiment of a two-stage electronic expansion valve provided by the present invention.
7 is a cross-sectional view showing a partial structure of a fourth embodiment of a two-stage electronic expansion valve provided in the present invention.

BRIEF DESCRIPTION OF THE DRAWINGS The present invention will be described in more detail in connection with the following drawings and specific embodiments in order that those skilled in the art will be better able to understand the technical solution of the present invention.

First Embodiment:

2 and 3, FIG. 2 is a view showing the structure of a first embodiment of a two-stage electronic expansion valve provided in the present invention. 3 is a view showing a structure of a valve core according to a first embodiment of the present invention.

As shown in FIG. 2, the two-stage electronic expansion valve provided in the present invention mainly comprises a valve body portion for controlling the flow rate and a coil portion for driving the valve body portion. The coil portion includes a motor 1 and a speed reducer 2 connected to an output end of the motor 1 and a screw rod 3 is connected to a lower end of the speed reducer 2 via a screw coupling structure 5 The screw coupling structure 5 converts the rotational motion of the motor 1 into the reciprocating motion of the screw rod 3. [ The nut 4 is connected between the screw rod 3 and the gear box 9 and the gear box 9 is covered on the outer surface of the reducer 2 and the motor case 6 of the motor 1 is connected to the gear box 9, As shown in Fig.

The valve body portion includes a valve seat 14 and a valve rod 15, and the bellows 11 is covered on the outer surface of the valve rod 15. The bellows 11 is extended or contracted in accordance with the reciprocating movement of the valve rod 15 and the valve core 12 and the valve rod 15 are mutually movably connected to each other, So that the first valve hole 13 provided in the valve seat 14 can be opened or closed.

&Quot; Coupled together " as used in the present invention means that the valve core and valve rod can move relative to each other but can not be released.

The outer surface of the valve core 12 is formed in a generally cylindrical shape and has a large-diameter section 121 and a small-diameter section 122. The first cavity 123 is formed at one end near the large diameter section 121 and the second cavity 124 is formed at one end near the small diameter section 122. The first cavity 123 and the second cavity 124 The second valve hole 125 is opened.

Diameter portion 121 is formed in the outer wall of the large diameter section 121 so that the fluid is allowed to flow through the large diameter section 121 from the outer wall of the large diameter section 121. In this embodiment, ≪ / RTI > However, a person skilled in the art can design the shape of the circulation part 1211 in the spherical shape of the present invention by a groove forming method, a hole opening method or the like, and it is sufficient that the fluid can pass between the upper end and the lower end of the large-

The lower end 152 of the valve rod 15 extends into the interior of the first cavity 123 and cooperates with and opens or closes the second valve hole 125 to open or close the second valve hole 125 to adjust the flow rate do. The obstacle 126 is further installed in the first cavity 123 so that the valve rod 15 and the valve core 12 are connected to each other and the obstacle 126 is fixedly connected to the inner wall of the large diameter section 121. The two may be welded, crimped or otherwise secured.

An annular groove 151 is formed near the end of the valve rod 15 and a position restricting part is provided in the annular groove 151. The positional restricting part can maintain the connection state in which the valve rod 15 and the interruption part 126 are relatively movable. In the present embodiment, the position restricting part is specifically a washer 127. Specifically, the washer 127 is held in the annular groove 151 so that the valve rod 15 can not be released from the restriction of the obstruction 126. [ Specifically, after the valve rod 15 is inserted into the interference portion 126, the washer 127 is disposed in the annular groove 151, and then the interference portion 126 is inserted into the large- And restricting the maximum position at which the valve rod 15 moves upward by the interference portion 126 and the washer 127.

4 is a view showing a structure of a washer according to a first embodiment of the present invention. The washer 127 is generally "C" shaped and has an opening 1272 for insertion into the annular groove 151 of the valve rod. After the three contacts 1271 are installed and assembled in the inside of the washer 127, a notch is formed between the abutting portions 1271 which are in close contact with the circumferential wall of the annular groove 151. Here, FIG. 4 is a specific embodiment, and a person skilled in the art will be able to obtain other variations upon such technical suggestions. For example, the notch portion may be eliminated and the contact portion 1271 may be integrally connected to realize the object of the present invention. The shape of the annular groove 151 is not limited to the shape using the washer or the holding or fixing degree of the annular groove 151. For example, the annular groove 151 may be formed with a through- (126). ≪ / RTI > The above positioning method is also included in the protection scope of the present invention.

The flow port 1221 may be formed on the outer wall of the small diameter section 122 of the valve core 12 and the number of the flow ports 1221 may be one or more. The flow port 1221 allows the first cavity 123 to communicate with the outer space of the valve core 12 and the fluid can flow from the flow port 1221 into the first cavity 123. A first noise member 128 is provided in the first cavity 123 between the flow port 1221 and the valve hole 125 so that the fluid introduced from the flow port 1221 is discharged by the first noise member 128, And then discharged from the second valve hole 125. [ As shown in FIG. 3, the first noise absorbing member 128 may be designed in an annular shape that fills the first cavity 123.

The second cavity 124 is provided at the lower end of the small diameter section 122 and the second noise member 129 is installed at the second cavity 124. The lower end portion of the small-diameter section 122 may be deformed to fix the second noise absorbing member 129 in the second cavity 124 in a compressed manner.

The first noise absorbing member 128 and the second noise absorbing member 129 may be formed by a porous filter net, wire winding, powder sintering or the like. In the present invention, the material or the shape of the noise member is not limited.

A certain flow rate must be ensured even after the first valve hole 13 is closed by the valve core 12 so that the two-stage electronic expansion valve has a dehumidifying function. In order to realize the above object, a normally open type device is provided between the first cavity 123 and the second cavity 124 in the present embodiment. In the present embodiment, the normally open type device is a normally open type hole 130, whereby a part of the flow rate can always flow between the two connection pipes of the two-stage electronic expansion valve. However, it is not limited to providing the normal open hole 130 as a means for securing a constant flow rate after the first valve hole 13 is closed, and it can be replaced by various technical means. The inner circumferential surface of the first valve hole 13 is formed in such a manner that an inclined hole is formed in the small diameter section 122 to directly communicate the second cavity 124 to the outside of the valve core 12 or to form a groove, Even when a large number of flow grooves are formed in the wall, a constant flow rate can be ensured after the valve body is closed. Those skilled in the art will appreciate that the use of a number of alternative means within the contemplation of the invention is also within the scope of protection of the present invention.

Thereby, a proprietary adjustment mechanism is formed between the lower end 152 of the valve rod 15 and the second valve hole 125 in the valve core 12.

When the valve rod 15 moves from the top to the bottom, the bellows 11 is in the extended state and the valve core 12 is in the state in which the lower end face of the obstruction portion 126 always acts on the upper face Respectively. The valve rod 15 continues to move downward after the valve core 12 has moved down to the maximum position and contacted the first valve hole 13. At this time, And then the lower end portion 152 of the valve rod 15 comes into contact with the second valve hole 125 to be sealed. At this time, the two-stage electronic expansion valve is closed It is closed.

The bellows 11 is contracted and the valve rod 15 is moved from below to above and the valve core 12 is subjected to the action of the differential pressure so that the lower end of the valve core 12 The surface still maintains contact with the first valve hole 13. The valve rod 15 continues to move upward and eventually the upper end surface of the washer 127 comes into contact with the lower end surface of the obstacle 126. [ As the valve rod 15 continues to move upward, the disturbing portion 126 also moves upward, and at this time the entire valve core starts to move upward. When the motor 1 is opened with a fully open pulse, the entirety of the two-stage electronic expansion valve is brought into a fully opened state.

In the above process, in the adjustment distance before the upper end surface of the washer 127 contacts the lower end surface of the obstacle 126, the flow rate is mainly controlled by the lower end 152 of the valve rod 15 and the second valve Is controlled by the degree of opening between the holes 125, that is, the volume control period. As the valve hole is reduced, the control range of the flow rate is further widened under the same pulse quantity condition. When the entire valve core 12 is moved upward by the valve rod 15, the flow rate is mainly controlled by the degree of opening between the valve core 12 and the first valve hole 13, that is, the large flow control period.

As described above, the lower end portion of the valve core 12 and the first valve hole 13 are always in contact with each other in the propulsion control section. At this time, the fluid flows from the flow port 1221 and is subjected to noise treatment by the first noise member 128, and then passes through the second valve hole 125. Then, the noise is processed again by the second noise member 129, and when the fluid passes through the noise member, the vortex that is sufficiently dispersed due to the action of the multi-layer network can be removed and noise can be reduced.

In other words, according to the two-stage electronic expansion valve provided in the present invention, since the fluid passes through the noise member of the mesh-like shape and the vortex and other gasses are greatly removed and dispersed, the abnormal noise problem Can be solved. At the same time, since the volume control is mainly performed through the second valve hole 125 formed in the valve core 12, the range of the flow rate can be further controlled and the accuracy is further enhanced under the same pulse quantity condition.

Second embodiment:

A second embodiment of the present invention will be described below by combining Fig. 5 is a diagram showing the structure of a second embodiment of a two-stage electronic expansion valve provided in the present invention. In order to explain the difference between the present embodiment and the first embodiment, the same reference numerals are applied to components having the same structure and function.

The two-stage electronic expansion valve includes a motor 1 and a speed reducer 2 connected to an output end of the motor 1. A screw rod 3 is connected to the lower end of the speed reducer 2 via a screw- And the screw coupling structure 5 converts the rotational motion of the motor 1 into the reciprocating motion of the screw rod 3. [ The nut 4 is connected between the screw rod 3 and the gear box 9 and the gear box 9 is covered on the outer surface of the reducer 2 and the motor case 6 of the motor 1 is connected to the gear box 9, Is riveted to the outside of

The valve body portion includes a valve seat 14 and a valve rod 15, and the bellows 11 is covered on the outer surface of the valve rod 15. The bellows 11 is extended or contracted in accordance with the reciprocating motion of the valve rod 15 and the valve core 12A and the valve rod 15 are mutually movably connected to each other, So that the first valve hole 13 provided in the valve seat 14 can be opened or closed.

Other than the structure of the valve core 12 among the above components, all other components are the same as those of the first embodiment and can be understood with reference to FIG. 2, and detailed description thereof is omitted here.

In the present embodiment, the outer surface of the valve core 12A is generally formed in a two-step cylindrical shape and has a large-diameter section 121A and a small-diameter section 122A. In the upper and lower ends of the valve core 12A, The first cavity 123A and the second cavity 124A are formed and the second valve hole 125A is formed between the first cavity 123A and the second cavity 124A.

The flow portion 1211A is provided on the outer wall of the large diameter section 121A and in this embodiment the flow section 1211A is a plurality of planes machined from the outer wall of the large diameter section 121A to allow fluid to pass therethrough. However, a person skilled in the art can design the shape of the circulating portion 1211A in the spherical shape of the present invention by a groove forming method, a hole opening method or the like, and it is sufficient that the fluid can pass between the upper end and the lower end of the large-

The lower end portion 152A of the valve rod 15 extends to the inside of the first cavity 123A and forms a flow rate adjusting mechanism between the second valve holes 125A and the lower end portion 152A of the valve rod 15 is provided between the lower end portion 152A and the second valve hole 125A The second valve hole 125A is opened or closed to adjust the flow rate. The obstacle 126A is further installed in the first cavity 123A so that the valve rod 15 and the valve core 12A are connected to each other and the obstacle 126A is fixedly connected to the inner wall of the large diameter section 121A. The two may be welded, crimped or otherwise secured.

An annular groove 151A is formed near the end of the valve rod 15 and a position restricting part is provided in the annular groove 151A. The positional restricting part can maintain the connection state in which the valve rod 15 and the interruption part 126A can move relative to each other. Similar to the first embodiment, the position restricting part of the present embodiment may also be a washer 127A, and its structure is the same as that of the washer 127 in the first embodiment. 4, detailed description thereof will be omitted here. And restricts the maximum position at which the valve rod 15 moves upward by the interference portion 126A and the washer 127A.

Similar to the first embodiment, a person skilled in the art can obtain other deformation of the position-restricting part by taking such a technical suggestion, and the present invention is not limited to the use of the holding or fixing degree washer of the annular groove 151, The limiting connection between the valve rod 15 and the obstruction portion 126 can be realized by a method of using the positioning pin by forming a through hole in the through hole. The above positioning method is also included in the protection scope of the present invention.

The flow port 1212A may be formed on the outer wall of the large diameter section 121A of the valve core 12A and the number of the flow port 1212A may be one or a plurality of the flow port 1212A, and the first cavity 123A may be formed by the flow port 1212A. And the outer space of the valve core 12A to allow the fluid to flow from the outside of the valve core 12A to the first cavity 123A through the flow port 1212A.

The second cavity 124A is formed at the lower end of the small diameter section 122A and the second noise member 128A is installed at the second cavity 124A and the second noise member 128A is provided at the lower end of the second cavity 124A A pressing member 129A is provided to fix the pressing member 129A and the pressing member 129A is brought into close contact with the inner wall at the lower end of the small diameter section 122A to fix the second noise insulating member 128A in the second cavity 124A.

The second noise absorbing member 128A may be constructed by a porous filter net, wire winding, powder sintering, or the like. In the present invention, the material or the shape of the noise member is not limited.

It is necessary to maintain a constant flow rate even after the first valve hole 13 is closed by the valve core 12A so that the two-stage electronic expansion valve has a dehumidifying function, as in the first embodiment. (Not shown) is provided between the first cavity 123 and the second cavity 124 so that the flow rate between the two connection pipes of the two-stage electronic expansion valve is always constant Can flow. However, the means for ensuring a constant flow rate after the first valve hole 13 is closed is not limited to the provision of the normally open type hole, and can be replaced by various technical means. The inner circumferential surface of the first valve hole 13 is formed in such a manner that an inclined hole is formed in the small diameter section 122A to directly communicate the second cavity 124A to the outside of the valve core 12A or to form a groove, Even when a large number of flow grooves are formed in the wall, a constant flow rate can be ensured after the valve body is closed. Those skilled in the art will appreciate that the use of a number of alternative means within the contemplation of the invention is also within the scope of protection of the present invention.

Thereby, a proprietary adjustment mechanism is formed between the lower end 152A of the valve rod 15 and the second valve hole 125A in the valve core 12A.

When the valve rod 15 moves from the top to the bottom, the bellows 11 is in the extended state and the valve core 12 is in the state in which the lower end face of the interference part 126 always acts under the action of the differential pressure, As shown in FIG. The valve rod 15 is continuously moved downward after the valve core 12A moves down to the maximum position and contacts the first valve hole 13. At this time, And the second end 152A of the valve rod 15 comes into contact with the second valve hole 125A to be sealed. At this time, the two-stage electronic expansion valve is closed It is closed.

The bellows 11 is contracted and the valve rod 15 is moved from the bottom to the top while the valve core 12A is moved under the action of the differential pressure and the lower end of the valve core 12A The surface still maintains contact with the first valve hole 13. The valve rod 15 continues to move upward and finally the upper end surface of the washer 127A comes into contact with the lower end surface of the obstacle 126A. As the valve rod 15 continues to move upward, the disturbing portion 126A also moves upward, and at this time, the entire valve core starts to move upward. When the motor 1 is opened with a fully open pulse, the entirety of the two-stage electronic expansion valve is brought into a fully opened state.

In the above process, in the adjustment distance before the upper end surface of the position restricting part (washer 127) comes into contact with the lower end surface of the obstacle 126A, the flow rate mainly depends on the lower end 152A of the valve rod 15, Is controlled by the degree of opening between the second valve holes 125A, that is, the volume control period. As the valve hole is reduced, the control range of the flow rate is further widened under the same pulse quantity condition. When the entire valve core 12A is moved upward by the valve rod 15, the flow rate is mainly controlled by the degree of opening between the valve core 12A and the first valve hole 13, that is, the large flow control period.

As described above, the bottom end of the valve core 12 and the first valve hole 13 are always in contact with each other at the time of controlling the volume of the fluid. At this time, the fluid flows from the flow port 1212A into the first cavity 123A Through the second valve hole 125A while being subjected to the noise treatment of the next noise member 128A and to remove the vortex that is sufficiently dispersed by the action of the multiple layer mesh when the fluid passes through the noise member And noise can be reduced.

In other words, according to the two-stage electronic expansion valve provided in the present invention, since the fluid passes through the noise member of the mesh-like shape and the vortex and other gasses are greatly removed and dispersed, the abnormal noise problem Can be solved. At the same time, since the volume control is mainly performed through the second valve hole 125A formed in the valve core 12A, the range of the flow rate can be further controlled and the accuracy is further enhanced under the same pulse quantity condition.

Third Embodiment

The third embodiment compresses the lower end portion 1222A of the small diameter section 122A at the point where the second noise insulating member 128A is fixed to the second cavity 124A in a compressed manner as shown in Fig. Which is different from the second embodiment in that the second noise absorbing member 128A is fixed. That is, the fixing method of the second noise insulating member of the first embodiment. The other parts of the present embodiment are the same as those of the second embodiment, and a detailed description thereof will be omitted.

Fourth Embodiment:

The fourth embodiment is different from the second embodiment in that the second noise member is divided into two layers of an upper noise insulating member 1281A and a lower noise insulating member 1282A and the noise member is fixed within the second cavity 124A And the pressing member 129A is brought into close contact with the inner wall of the lower end of the small diameter section 122A so that the upper noise insulating member 1281A and the lower noise insulating member 1282A are disposed in the second cavity 124A . Those skilled in the art can understand that the object of the present invention can be realized even when the noise member is not limited to two layers but two or more layers. The other parts of the present embodiment can be referred to corresponding descriptions of the second embodiment, and a detailed description thereof will be omitted here.

However, the terms of the upper, lower, left, and right positions described in the present invention are based on the structures shown in the drawings for the specification, and do not limit the scope of protection of the present invention.

The electronic expansion valve for an inverter air conditioner provided in the present invention has been described in detail above. Although the principles and embodiments of the present invention have been described in detail in the present application, the description of the embodiments above is intended to understand the method and core idea of the present invention. Those skilled in the art will be able to make various improvements or modifications of the invention without departing from the principles of the invention, and such improvements or modifications are within the scope of protection of the present invention.

Claims (14)

A two-stage electronic expansion valve comprising a motor and a speed reducer connected to an output end of the motor, wherein a bellows is covered on the outer surface of the valve rod and the bellows is extended or contracted by reciprocating motion of the valve rod,
Further comprising a valve core in which a volume adjusting mechanism is provided, the volume adjusting mechanism including a lower portion of the valve rod and a second valve hole provided in the valve rod, the valve core being opened or closed according to the valve rod. Electronic expansion valve. The method according to claim 1,
Wherein the valve core is cylindrical and has a first cavity and a second cavity at both ends thereof, and the second valve hole is opened between the first cavity and the second cavity. The method of claim 2,
Further comprising an obstruction in said first cavity and a lower end of said valve rod extending into said first cavity through said obstruction and providing a mutually movable connection between said valve rod and said obstruction by means of a position- Features a two-stage electronic expansion valve. The method of claim 3,
Wherein the position restricting part is a washer, and an annular groove is formed in the valve rod, and the washer is inserted into the annular groove. The method of claim 3,
And the intervening portion and the valve core are fixed through welding or compression. The method of claim 2,
Wherein the valve core includes a large diameter section and a small diameter section, and a flow section is formed on an outer wall of the large diameter section. The method of claim 2,
Wherein a flow port is formed in the valve core, and the flow passage communicates the first cavity and the outer space of the valve core. The method of claim 7,
Wherein the first noise absorbing member is installed in the first cavity and the fluid introduced from the flow passage is subjected to the noise treatment of the first noise member and then discharged from the second valve hole. The method of claim 7,
And a second noise member is installed in the second cavity. The method of claim 9,
And the second noise insulating member is fixed in the second cavity in such a manner that the bottom of the valve core is crimped and deformed. The method of claim 9,
Wherein a pressing member is provided at the bottom of the valve core, and the pressing member is forcedly engaged with the valve core to fix the second noise insulating member in the second cavity. 12. The method according to claim 10 or 11,
Wherein the second noise member includes an upper noise member and a lower noise member. The method according to claim 1 or 2,
Wherein a normal open type device is provided between the first cavity and the second cavity to maintain a constant flow rate between the first cavity and the second cavity at all times. The method of claim 4,
Wherein the washer has an opening and a contact portion, and the contact portion contacts the circumferential wall of the annular groove.

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