JP6951579B2 - Electronic expansion valve - Google Patents

Description

The present invention relates to the technical field of refrigeration control, and specifically to an electronic expansion valve.
This application was filed with the China Patent Office on March 23, 2018, claiming the priority of the Chinese patent application with the application number 201810246495.4 and the invention name "Electronic Expansion Valve". All the contents described in the above are incorporated into this application by reference.

In the current electronic expansion valve, the drive part (coil, rotor) and the flow control part (nut, screw rod, housing, valve needle, valve seat, valve seat core, connecting pipe, etc.) are used to open and close the valve. The driving force for this is formed by driving the rotor with a coil, and the driving force output by the standard rotor and coil is constant, and the system refrigerant upgrades as the diameter of the valve opening increases. After that, since the pressure formed inside the valve body is large, the demand for the driving force required for the product is large when switching from the valve closed state to the valve open state, which affects the smoothness of the valve opening. On the other hand, the improvement of the driving force required for the product is realized by a method such as expanding the coil, which leads to an increase in cost.

An object of the present invention is to provide an electronic expansion valve that reduces the differential pressure formed inside the valve body, reduces the driving force required for the product, and reduces the manufacturing cost of the product.

In order to realize the above object, the present invention opens a valve seat having a valve chamber and a valve opening communicating with the valve chamber, and a closing position and a valve opening that are movably provided in the valve chamber to close the valve opening. A valve needle having an open position, a housing fixed to the valve seat and having a cavity inside, a screw rod located in the cavity, and a screw rod located in the cavity and connected to the valve needle. In an electronic expansion valve including a nut to be used and a drive mechanism having a rotor located in the cavity and a coil provided around the outside of the housing in the circumferential direction, the rotor is connected to a screw rod and the screw is driven by the coil. Driven to rotate the rod, the transmission of the screw rod moves the nut along the axial direction, and the drive of the nut switches the valve needle between the open position and the closed position, and the valve needle and valve seat There is a flow passage between them, which seals the flow passage so that the valve chamber and the cavity do not communicate with each other when the valve needle is in the closed position, and through the circulation passage when the valve needle is in the open position. It is equipped with a sealing component that allows the valve chamber and cavity to communicate with each other.

According to the application of the present invention, when the electronic expansion valve is in the closed state, that is, when the core unit is in contact with the valve port and the refrigerant enters from the valve port, the body pressure inside the valve body increases and the refrigerant pressures. Since it is not in time for release, there is a possibility that the core unit is not in contact with the valve opening, and the pressure between the valve chamber and the rotor chamber is balanced by the action of the sealed engagement between the sealed part and the complete part, and the electronic When the expansion valve is left closed and the electronic expansion valve is open, that is, when the core unit is relatively far from the valve port, pressure is quickly introduced when the refrigerant enters the rotor chamber through the valve port. Since the pressure release is slow, it is easy to form a buildup of pressure, and the engaging action between the sealed part and the notch causes the refrigerant to flow out through the gap between the sealed part and the notch, gradually releasing the pressure. Therefore, the differential pressure formed inside the valve body is relatively small in both the valve open state and the valve closed state, and when the valve opening or closing is required, the need for the driving force by the coil is small. It is not necessary to realize it by a method such as expanding the coil, and the manufacturing cost is reduced.

The present specification and drawings are used to further understand the present invention, and examples and description thereof of the present invention do not constitute an unreasonable limitation on the present invention and are used for interpreting the present invention.
FIG. 3 is a vertical cross-sectional view of an electronic expansion valve in which the core unit is closed in the first embodiment of the present invention. FIG. 5 is an enlarged view of a portion A in the electronic expansion valve shown in FIG. FIG. 3 is a vertical cross-sectional view of an electronic expansion valve in which the core unit is in the valve open state in the first embodiment of the present invention. FIG. 3 is an enlarged view of a portion B in the electronic expansion valve shown in FIG. 3D view of the core unit in the electronic expansion valve shown in FIG. FIG. 5 is a vertical cross-sectional view of the core unit in FIG. FIG. 5 is a cross-sectional view showing sizes D1, D2, D3 and D4 of the electronic expansion valve shown in FIG. FIG. 3 is a vertical cross-sectional view of an electronic expansion valve in which the core unit is closed in the second embodiment of the present invention. FIG. 8 is an enlarged view of a portion C in the electronic expansion valve shown in FIG. FIG. 3 is a vertical cross-sectional view of an electronic expansion valve in which the core unit is in the valve open state in the second embodiment of the present invention. FIG. 10 is an enlarged view of a portion D in the electronic expansion valve shown in FIG. 3D view of the core unit in the electronic expansion valve shown in FIG. The vertical sectional view of the core unit shown in FIG.

Examples of the present invention and features in the examples can be combined with each other.
The present invention will be described in detail below with reference to the drawings.

As shown in FIGS. 1 to 6, the electronic expansion valve of this embodiment includes a valve seat 10, a screw rod 30, a nut 40, a core unit 20, a drive mechanism 50, a sealing component 70, and a housing 60.
The valve seat 10 has a valve chamber 1 and a valve opening 13 communicating with the valve chamber 1.
The screw rod 30 and the nut 40 are engaged with each other via a screw.
The core unit 20 is fixedly connected to the nut 40, at least a part of the core unit 20 is movably provided in the valve chamber 1, and the core unit 20 has a complete portion and a notch portion, and at least a complete portion is provided. Part of it is located above the notch.
The drive mechanism 50 has a rotor 51 and a coil 52. The rotor 51 is connected to the screw rod 30, the screw rod 30 is rotated via the coil 52, and the nut 40 is screwed with the screw rod 30. The core unit 20 moves closer to or away from the valve opening 13 by the nut 40.
The sealing component 70 is provided between the valve seat 10 and the core unit 20 and may engage a complete or notched portion.
The housing 60 is fixedly connected to the valve seat 10 and has a rotor chamber 2. When the sealing component 70 and the complete portion engage with each other, the rotor chamber 2 and the valve chamber 1 are closed to each other by the sealing action of the sealing component 70. When the sealed part 70 and the notch are engaged without communicating, there is a gap between the sealed part 70 and the notch, and the rotor chamber 2 communicates with the valve chamber 1 through the gap.

According to the first embodiment, when the electronic expansion valve is in the closed state, that is, when the core unit 20 is in contact with the valve port 13 and the refrigerant enters from the valve port 13, the body pressure inside the valve body is large and the refrigerant Is not in time for pressure release, so there is a possibility that the core unit 20 is not in contact with the valve port 13, and the pressure between the valve chamber 1 and the rotor chamber 2 is due to the action of the closed engagement between the sealed part 70 and the complete part. Keeps the balance, the electronic expansion valve remains closed, and the refrigerant is released from the valve port 13 when the electronic expansion valve is in the open state, that is, when the core unit 20 is relatively far from the valve port 13. Since the pressure is introduced quickly and the pressure is released slowly when entering the rotor chamber 2, it is easy to form a stack of pressure, and the refrigerant moves between the sealed part 70 and the notch by the cooperative action between the sealed part 70 and the notch. Since the pressure is gradually released through the gap between the valves, the differential pressure formed inside the valve body is relatively small in both the valve open state and the valve closed state, and the valve needs to be opened or closed. In addition, the need for the driving force of the coil is small, and it is not necessary to realize it by a method such as expanding the coil, which reduces the manufacturing cost.

It should be explained that when the "complete part" and the sealing part 70 are engaged, there is no gap between the part of the sealing part 70 and the engaging complete part, so that the valve chamber 1 and the rotor chamber 1 and the rotor chamber are not separated. 2 cannot communicate with each other through the gap.
The shape of the "perfect portion" is not limited (for example, a cylinder, a prism, etc.), and it may be ensured that there is no gap between the sealing component 70 and a part of the perfect portion engaged with the sealing component 70.
When the "notch" and the sealing part are engaged, there is a gap between the sealing part 70 and a part of the complete part that engages, so that the valve chamber 1 and the rotor chamber 2 have the gap. Can communicate through.
The shape of the "notch" is not limited (for example, a polygonal column or an irregular shape), and there is a gap between a part of the "notch" that engages the sealing part 70. You can guarantee it.

It should be further explained that the notch and the sealing part 70 are engaged, and the meaning of "engagement" does not necessarily indicate contact engagement, and the notch corresponds to (not in contact with) the sealing part 70. ), There may be a gap between the outer wall of the notch and the inside of the sealing component 70.

As shown in FIGS. 1 to 6, in the first embodiment, the outer wall of the core unit 20 is provided with a flow groove 24, and the shaft stage of the core unit 20 where the flow groove 24 is located forms a notch. However, the other shaft step portion of the core unit 20 forms a complete portion.
Specifically, when the core unit 20 moves downward before the valve is closed, the sealing component 70 is located above the circulation groove 24, and the inner surface of the sealing component 70 is on the outer wall of the core unit 20. The outer surface of the sealed component 70 is bonded to the inner wall of the valve seat 10, and thus the sealed component 70 acts as a closed seal and does not allow the valve chamber 1 and the rotor chamber 2 to communicate with each other.
When the core unit 20 is moved upward before the valve is opened, the sealing component 70 corresponds to the flow recessed groove 24, and thus between the inner surface of the sealing component 70 and the groove bottom of the circulation recessed groove 24. Has a gap, the refrigerant in the valve chamber 1 enters the rotor chamber 2 through the gap, the refrigerant in the rotor chamber 2 also enters the valve chamber 1 through the gap, and the valve chamber 1 and the rotor chamber 2 and 2 quickly realize the purpose of balancing the pressure per unit area.
In addition, the arrangement of the concave grooves makes the configuration simple, convenient for processing, and low cost.

As shown in FIGS. 1, 3, 5 and 6, in the first embodiment, the flow groove 24 is a long groove extending along the axial direction of the core unit 20.
The configuration is simple and makes processing convenient.
In the first embodiment, the flow groove 24 is a long groove extending along the axial direction of the core unit 20.
The configuration is simple and makes processing convenient.

As shown in FIGS. 5 and 6, in the first embodiment, the end of the flow groove 24, one end of the core unit 20 close to the valve port 13 and one end of the core unit 20 away from the valve port 13 , Both have a distance.

As shown in FIGS. 5 and 6, in the first embodiment, the core unit 20 includes a first core stage 21 fixedly connected to the nut 40 and a second core stage 22 located below the first core stage 21. The outer diameter of the second core stage 22 is larger than the outer diameter of the first core stage 21, and the sealing component 70 is located between the first core stage 21 and the valve seat 10.
The configuration is simple, and since the outer diameter of the second core stage 22 is larger than the through diameter of the valve port 13, the core unit 20 closes the valve port 13.

As shown in FIGS. 1 to 4, in the first embodiment, a stepped surface 25 is formed at the connection point between the first core stage 21 and the second core stage 22, and the valve seat 10 has a first stopper member. 90 is provided, and the lower surface of the first stopper member 90 is abutted and engaged with the stepped surface 25.
In the above configuration, the position is restricted with respect to the moving position of the core unit 20, the ascending stroke of the core unit 20 is fixed, and the opening and closing of the electronic expansion valve are more effective (high efficiency). Guarantee to.
The first stopper member 90 is a lower retaining ring.

As shown in FIGS. 1 to 4, in the first embodiment, the nut 40 is provided with a protrusion 41, and the valve seat 10 is provided with a second stopper member 100 located above the first stopper member 90. Then, the upper surface of the second stopper member 100 is abutted and engaged with the lower surface of the protrusion 41.
In the above configuration, the position is restricted with respect to the moving position of the core unit 20 to fix the downward stroke of the core unit 20.
In the first embodiment, when the second stopper member 100 is abutted and engaged with the nut 40, the core unit 20 is located at the bottom dead center.
The stopper member prevents the contact force between the core unit 20 of the electronic expansion valve and the valve port 13 from being too large, and guarantees the life of the core unit 20.

As shown in FIGS. 1 to 4, in the first embodiment, the first stopper member 90 is a lower retaining ring, the second stopper member 100 is an upper retaining ring, and the sealing component 70 is a sealing ring. A sealing ring is interposed between the first stopper member 90 and the second stopper member 100, and the core unit 20 is bored in the upper retaining ring, the lower retaining ring, and the sealing ring.
The stopper member is simple and makes it convenient to fix the sealing ring.

As shown in FIGS. 1 to 4, in the first embodiment, the nut 40 is provided with a protrusion 41, and the electronic expansion valve includes a support component 80 fixedly arranged on the valve seat 10, and the support component 80 is provided with a support component 80. Is provided with a position limiting groove 81 that can engage with the protrusion 41.
When the nut 40 has a tendency to rotate along the circumferential direction, the side wall of the protrusion 41 cannot be rotated along the circumferential direction due to the stopper of the position limiting groove 81.
The configuration is simple and easily realized.
Further, when the lower surface of the protrusion 41 is in contact with the upper surface of the upper retaining ring, the core unit 20 is located at the bottom dead center (it cannot continue to move downward), and the core unit 20 continues to move. Restrict movement down.
Since the protrusion 41 has two functions at the same time, the utilization of the configuration can be maximized, the design of a new configuration can be avoided, and the manufacturing cost can be reduced.

It should be explained that when the core unit 20 is located at the bottom dead center, the end portion of the core unit may be in direct contact with the valve port 13.

As shown in FIG. 1, in the first embodiment, the support component 80 has a cup shape, and the bottom of the support component 80 is provided with an opening extending upward to form a position limiting groove 81.
Specifically, when the nut 40 has a tendency to rotate along its axis, the side wall of the position limiting groove 81 is provided with a protrusion 41 so that the nut 40 cannot rotate along its axis. Lock the side wall of the.
The configuration is simple, easily realized, and low in cost.

When the upper surface of the protrusion 41 is in contact with the ceiling surface of the position limiting groove 81, the core unit 20 is located at the top dead center (it cannot continue to move upward).

As shown in FIGS. 1 to 4, in the first embodiment, the screw rod 30 is fixed to the rotor 51, the rotor 51 and the screw rod 30 are supported by the support component 80, and the support component 80 and the nut 40 are connected to each other. An elastic component 110 is provided between them, and the elastic component 110 applies a downward force to the nut 40 to prevent the nut 40 from escaping upward.

As shown in FIGS. 1 to 4, in the first embodiment, the valve seat 10 has a valve seat main body 11 and a connecting seat 12 fixed to the valve seat main body 11, and the connecting seat 12 and the valve seat main body 11 The inside of the valve chamber 1 is formed, the valve port 13 is provided in the valve seat main body 11, the connection seat 12 is provided with a mounting hole 121, and the mounting hole 121 is mounted in the mounting stage and the hole diameter. It has a guide step that is larger than the step and is located below the mounting step, the outer wall of the core unit 20 and the guide step are engaged, and the sealing component 70 is between the hole wall of the mounting step and the outer wall of the core unit 20. Located in.

As shown in FIGS. 1 to 4, in the first embodiment, the outer wall of the core unit 20 is provided with the circulation concave groove 24, and the shaft step of the core unit 20 in which the circulation concave groove 24 is located forms a notch. However, the other shaft step portion of the core unit 20 forms a complete portion, and the lower end of the flow groove 24 is lower than the lower end of the hole wall of the mounting hole 121.
With the above configuration, the refrigerant in the valve chamber 1 more easily enters the flow groove 24, and the pressure per unit area in the valve chamber 1 and the rotor chamber 2 is more quickly balanced.

As shown in FIGS. 1 to 4, in the first embodiment, the mounting hole 121 is a stepped hole, and the sealing component 70 is fixed to the stepped surface 122 of the stepped hole.
The configuration is simple and easy to install.
The sealing component 70 is fixed to the stepped surface 122 by a method such as adhesion, connection with fasteners, or tightening connection.

As shown in FIGS. 1 and 3, in the first embodiment, the valve seat main body 11 is provided with the first connection port 14 and the second connection port 15 at intervals, and the horizontal pipe is the first connection port 14. The second connection port 15 communicates with the valve port 13, and the vertical pipe is inserted into the second connection port 15.

As shown in FIGS. 1 to 4, in the first embodiment, the core unit 20 has a communication chamber 4, the nut 40 is located in the communication chamber 4, and is fixed to the core unit 20 with the nut 40. By providing a distribution configuration between the core unit 20 and the core unit 20, the communication chamber 4 and the rotor chamber 2 communicate with each other via the distribution configuration.
According to the above configuration, when the core unit is in the closed position and the refrigerant flows into the communication chamber 4 from the valve port 13, the refrigerant continues to enter the rotor chamber 2 through the distribution configuration, and the communication chamber 4 and the rotor chamber 2 The purpose is to balance the pressure with and to reduce the downward resistance received by the nut 40 when the core unit 20 moves upward in this way, and finally to make the opening of the core unit 20 smoother. To realize.

In the first embodiment, the nut is provided with a flow hole forming the flow structure.
The configuration is simple and easy to process.

As shown in FIGS. 8 to 13, the difference between the electronic expansion valve of the second embodiment and the electronic expansion valve of the first embodiment lies in the specific shape of the core unit 20.
Specifically, in the second embodiment, the core unit 20 is located between the first core stage 21 fixedly connected to the nut 40, the second core stage 22, and the first core stage 21 and the second core stage 22. It has a contraction stage 23 located, and the outer diameter of the contraction stage 23 is gradually reduced from the first core stage 21 to the second core stage 22.
The contraction stage 23 forms a notch, and the first core stage 21 forms a complete portion.
When the core unit 20 is in the valve closed state, the sealed component 70 is in close contact with the outer wall of the first core stage 21 and the inner wall of the valve seat 10, and when the core unit 20 is in the valve open state, the sealed component is a sealed component. There is a distance between the 70 and the outer wall of the contraction stage 23.
Specifically, when the core unit 20 moves downward before the valve is closed, the sealing component 70 corresponds to the first core stage 21, and the inner surface of the sealing component 70 is the first core stage 21. It is attached to the outer wall, and the outer surface of the sealing component 70 is attached to the inner wall of the valve seat 10 (preferably the hole wall of the mounting hole 121). The valve chamber 1 and the rotor chamber 2 do not communicate with each other.
When the core unit 20 moves upward before the valve is opened, the sealing component 70 corresponds to the contraction stage 23, and the outer diameter of the contraction stage 23 is small. Therefore, the inner surface of the sealing component 70 and the contraction stage 23 A gap is formed between the refrigerant chamber 1 and the outer surface of the rotor chamber 1, and the refrigerant in the valve chamber 1 enters the rotor chamber 2 through the gap, and the refrigerant in the rotor chamber 2 also enters the valve chamber 1 through the gap. As described above, the valve chamber 1 and the rotor chamber 2 quickly realize the purpose of balancing the pressure per unit area.
The configuration is simple and easy to process.

As shown in FIGS. 8 to 13, in the second embodiment, a stepped surface 25 is formed at the connection point between the second core stage 22 and the contraction stage 23.
The configuration is simple and does not require other stepped surfaces to be placed independently, making processing and manufacturing convenient.

The operation process of the electronic expansion valve is specifically introduced below. As shown in FIG. 7, D1 is the outer diameter of the first core stage 21, D2 is the through diameter D2 of the valve port 13, and D3 is the second core stage. The outer diameter of 22, D4 is the inner diameter of the core unit 20, SD1 is the cross-sectional area of the first core stage 21, SD2 is the area of the valve port 13, SD3 is the area of the second core stage 22, and SD4 is the inner hole of the core unit 20. As the cross-sectional area of
(1) When the core unit is in the valve closed state and pressure is introduced into the lateral pipe, the sealing component 70 makes a closed contact with the outer wall of the core unit 20 and the inner wall of the valve seat 10 above the notch. As a result, sealing (circumferential sealing) is realized, the valve chamber 1 and the rotor chamber 2 are separated from each other at the top and bottom via the sealing component 70, and the rotor chamber 2 and the communication chamber 4 penetrate at the top and bottom, and the valve chamber 1 Is isolated from the communication chamber 4 by the closed contact between the closed pair and the valve port 13.
The pressure per unit area of the refrigerant in the horizontal pipe is acted on the core unit 20, and the action of the area difference (SD3-SD2) and the pressure P per unit area forms an upward differential pressure on the core unit 20. Further, due to the action of the area difference (SD3-SD1) and the pressure P per unit area, a downward differential pressure is formed in the core unit 20.
In this embodiment, the size of D1 is designed to be substantially equal to D2 in order to bring the upper and lower resultant forces of the core unit 20 close to zero.
in this way,
F = (SD3-SD2) * P- (SD3-SD1) * P
= (SD3-SD2-SD3 + SD1) * P
= (SD1-SD2) * P
Since it becomes ≒ 0
With the above configuration, the demand for the driving force of the core unit 20 becomes extremely small during the open operation.
In this embodiment, (SD2-SD1) ≦ 40 mm ² .

(2) When the core unit is in the valve open state and pressure is introduced into the lateral pipe, the core unit 20 moves upward so that the sealing component 70 and the core unit 20 are partially sealed. It is formed, and the valve chamber 1 and the rotor chamber 2 penetrate through the gap between the sealing component 70 and the notch, and the pressures per unit area are close to the same.
The rotor chamber 2 and the communication chamber 4 penetrate vertically, and the pressure per unit area approaches the same.
The transverse pipe pressure is acted on the core unit 20, and the action of the area difference (SD3-SD4) and the pressure P per unit area forms an upward differential pressure on the core unit 20.
Due to the action of the area difference (SD3-SD1) of the stepped surface 25 of the core unit 20 and the pressure P per unit area, a downward differential pressure is formed in the core unit 20, and the area difference of the ceiling portion of the core unit 20. Due to the action of (SD1-SD4) and the pressure P per unit area, a downward differential pressure is formed in the core unit 20, and the area difference between the upper and lower receiving forces is zero. And the pressure per unit area of each part of the communication chamber 4 is close to the coincidence.
Therefore, the vertical resultant force of the core unit 20 approaches zero.
When the core unit is opened and closed, the demand for driving force is reduced.

(3) When the core unit is in the valve closed state and pressure is introduced into the vertical pipe, the sealing component 70 makes a closed contact with the outer wall of the core unit 20 and the inner wall of the valve seat 10 above the notch. As a result, sealing (circumferential sealing) is realized, the valve chamber 1 and the rotor chamber 2 are separated from each other at the top and bottom via the sealing component 70, and the rotor chamber 2 and the communication chamber 4 penetrate at the top and bottom, and the valve chamber 1 Is isolated from the communication chamber 4 by the closed contact between the closed pair and the valve port 13.
The pressure per unit area of the vertical pipe is applied to the core unit 20, and the action of the area difference (SD2-SD4) and the pressure P per unit area forms an upward differential pressure on the core unit 20. Due to the action of the area difference (SD1-SD4) and the pressure P per unit area, a downward differential pressure is formed in the core unit 20, and D1≈D2.
F = (SD2-SD4) * P- (SD1-SD4) * P
= (SD2-SD4-SD1 + SD4) * P
= (SD2-SD1) * P
≒ 0,
Therefore, the upper and lower resultant forces of the core unit 20 are close to zero, and when the core unit 20 is opened, the demand for the driving force becomes extremely small.

(4) When the core unit is in the valve open state and pressure is introduced into the vertical pipe, the core unit 20 moves upward so that the sealing component 70 and the core unit 20 are partially sealed. The valve chamber 1 and the rotor chamber 2 penetrate through the gap between the sealing part 70 and the notch, and the pressure formed in the rotor chamber 2 is accumulated in the process of introducing the pressure of the vertical pipe. Avoid (because the pressure value is clearly larger than the pressure value per unit area at the 13 valve openings, an extra downward differential pressure is generated), and the pressure per unit area is close to the coincidence.
The rotor chamber 2 and the communication chamber 4 penetrate vertically, and the pressure per unit area approaches the same.
The pressure per unit area of the vertical pipe is applied to the core unit 20, and the action of the area difference (SD3-SD4) and the pressure P per unit area forms an upward differential pressure on the core unit 20. Due to the action of the area difference (SD3-SD1) of the stepped surface 25 of the core unit 20 and the pressure P per unit area, a downward differential pressure is formed in the core unit 20, and the area difference of the ceiling portion of the core unit 20. Due to the action of (SD1-SD4) and the pressure P per unit area, a downward differential pressure is formed in the core unit 20.
The area difference between the upper and lower receiving forces is zero, that is,
[(SD3-SD4)-(SD3-SD1)-(SD1-SD4)] = 0.
The pressures per unit area of each of the valve chamber 1, the rotor chamber 2, and the communication chamber 4 are close to the same.
Therefore, the vertical resultant force of the core unit 20 approaches zero.
When the core unit is opened and closed, the demand for driving force is reduced.

The above description is an embodiment of the present invention which does not limit the present invention, and for those skilled in the art, the present invention may have various changes and changes.
All amendments, equivalent substitutions, improvements, etc. made within the spirit and principles of the invention should fall within the scope of the invention.

1 ・ ・ ・ Valve room 2 ・ ・ ・ Rotor room 4 ・ ・ ・ Communication room 10 ・ ・ ・ Valve seat 11 ・ ・ ・ Valve seat body 12 ・ ・ ・ Connection seat 121 ・ ・ ・ Mounting hole 122 ・ ・ ・ Step surface 13・ ・ ・ Valve port 14 ・ ・ ・ 1st connection port 15 ・ ・ ・ 2nd connection port 20 ・ ・ ・ Core unit 21 ・ ・ ・ 1st core stage 22 ・ ・ ・ 2nd core stage 23 ・ ・ ・ Shrink stage 24・ ・ ・ Distribution concave groove 25 ・ ・ ・ Step surface 30 ・ ・ ・ Screw rod 40 ・ ・ ・ Nut 41 ・ ・ ・ Protrusion 50 ・ ・ ・ Drive mechanism 51 ・ ・ ・ Rotor 52 ・ ・ ・ Coil 60 ・ ・ ・ Housing 70 ・ ・ ・ Sealed parts 80 ・ ・ ・ Support parts 81 ・ ・ ・ Position limiting groove 90 ・ ・ ・ First stopper member 100 ・ ・ ・ Second stopper member 110 ・ ・ ・ Elastic parts

Claims (14)

It is an electronic expansion valve
A valve seat (10) having a valve chamber (1) and a valve opening (13) communicating with the valve chamber (1),
With screw rods (30) and nuts (40) that engage via screws,
It is fixedly connected to the nut (40) and at least a part is movably provided in the valve chamber (1) to have a complete portion and a notch portion, and at least a part of the complete portion is located above the notch portion. Core unit (20) and
A drive mechanism (50) having a rotor (51) and a coil (52), the rotor (51) is connected to the screw rod (30), and the coil (52) connects the screw rod (30) to the screw rod (30). Rotated, the nut (40) moves along the axial direction by the screwing action with the screw rod (30), and the nut (40) causes the core unit (20) to move to the valve port (13). With a drive mechanism (50) that is close to or away from the valve port (13),
A sealing component (70) provided between the valve seat (10) and the core unit (20) and engaged with the complete portion or the notch portion.
In a housing (60) having a rotor chamber (2) fixedly connected to the valve seat (10), when the sealed component (70) and the complete portion of the core unit (20) are engaged with each other. The rotor chamber (2) and the valve chamber (1) are not communicated with each other by the sealing action of the sealing component (70), and the sealing component (70) and the notch portion of the core unit (20) are engaged with each other. In this case, there is a gap between the sealed part (70) and the notch of the core unit (20), and the housing that communicates the rotor chamber (2) with the valve chamber (1) through the gap. An electronic expansion valve comprising (60). A distribution recess (24) is provided on the outer wall of the core unit (20).
The shaft step of the core unit (20) in which the flow groove (24) is located forms the notch.
The electronic expansion valve according to claim 1, wherein the other shaft step portion of the core unit (20) forms the complete portion. The electronic expansion valve according to claim 2, wherein the flow groove (24) is a long groove extending along the axial direction of the core unit (20). The end of the circulation groove (24), one end of the core unit (20) near the valve port (13), and one end of the core unit (20) away from the valve port (13). The electronic expansion valve according to claim 2, wherein all of them have a distance. The core unit (20) has a first core stage (21) fixedly connected to the nut (40) and a second core stage (22) located below the first core stage (21). ,
The outer diameter of the second core stage (22) is larger than the outer diameter of the first core stage (21).
The electronic expansion valve according to claim 1, wherein the sealed component (70) is located between the first core stage (21) and the valve seat (10). A stepped surface (25) is formed at the connection point between the first core stage (21) and the second core stage (22).
The valve seat (10) is provided with a first stopper member (90).
The electronic expansion valve according to claim 5, wherein the lower surface of the first stopper member (90) is abutted and engaged with the stepped surface (25). The nut (40) is provided with a protrusion (41), and the nut (40) is provided with a protrusion (41).
The valve seat (10) is provided with a second stopper member (100) located above the first stopper member (90).
The electronic expansion valve according to claim 6, wherein the upper surface of the second stopper member (100) is abutted and engaged with the lower surface of the protrusion (41). The first stopper member (90) is a lower retaining ring.
The second stopper member (100) is an upper retaining ring.
The sealing component (70) is a sealing ring.
The sealing ring is interposed between the first stopper member (90) and the second stopper member (100).
The electronic expansion valve according to claim 7, wherein the core unit (20) is bored in the upper retaining ring, the lower retaining ring, and the sealing ring. The nut (40) is provided with a protrusion (41), and the nut (40) is provided with a protrusion (41).
It has a support component (80) that is fixedly arranged on the valve seat (10).
The electronic expansion valve according to claim 1, wherein the support component (80) is provided with a position limiting groove (81) that engages with the protrusion (41). The support component (80) has a cup shape and has a cup shape.
The electronic expansion valve according to claim 9, wherein the bottom of the support component (80) is provided with an opening extending upward to form the position limiting groove (81). The first core stage (21), the second core stage (22), the first core stage (21), and the second core stage in which the core unit (20) is fixedly connected to the nut (40). It has a contraction stage (23) located between (22) and
The outer diameter of the contraction stage (23) gradually decreases from the first core stage (21) toward the second core stage (22).
The contraction stage (23) forms the notch,
The electronic expansion valve according to claim 1, wherein the first core stage (21) forms the complete portion. 5. A claim 5 is characterized in that if the cross-sectional area of the first core stage (21) is SD1 and the cross-sectional area of the valve port (13) is SD2, ^{the relational expression (SD2-SD1) ≤ 40 mm 2 is satisfied.} Alternatively, the electronic expansion valve according to claim 11. The valve seat (10) has a valve seat body (11) and a connecting seat (12) fixed to the valve seat body (11).
The valve chamber (1) is formed inside the connecting seat (12) and the valve seat main body (11).
The valve port (13) is provided on the valve seat main body (11).
The connection seat (12) is provided with a mounting hole (121).
The mounting hole (121) has a mounting step and a guide step having a hole diameter larger than that of the mounting step and located below the mounting step, and the outer wall of the core unit (20) and the guide step are engaged with each other. death,
The electronic expansion valve according to claim 2, wherein the sealed component (70) is located between the hole wall of the mounting stage and the outer wall of the core unit (20). A distribution recess (24) is provided on the outer wall of the core unit (20).
The shaft step of the core unit (20) in which the flow groove (24) is located forms the notch.
The other shaft step portion of the core unit (20) forms the complete portion.
The electronic expansion valve according to claim 13, wherein the lower end of the flow groove (24) is lower than the lower end of the hole wall of the mounting hole (121).

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