JP2021121761A - Motor operated valve and refrigeration cycle system - Google Patents

Abstract

To provide a motor operated valve capable of appropriately maintaining quietness, and a refrigeration cycle system using the motor operated valve.SOLUTION: A motor operated valve 2 converts a rotating motion of a rotor housed in an inner periphery of a case into a linear motion by screw engagement between a male screw member and a female screw member and moves a valve body 17 housed in a valve main body 30 in an axial direction on the basis of the linear motion, and includes: a first pipe joint 12 fitted on a side surface of the valve main body; a valve seat member 16 having a valve port 16a where the valve body can approach or alienate; and a second pipe joint 15 communicating with the first pipe joint via the valve port. A position of a top surface 16b of the valve seat member in the axial direction is located nearer on the rotor side than a central axis of the first pipe joint. A valve chamber 11 in the valve main body includes a first space 11a formed nearer on the rotor side than the first pipe joint in the axial direction and a second space 11b formed nearer on the second pipe joint side than the first pipe joint in the axial direction.SELECTED DRAWING: Figure 2

Description

The present invention relates to an electric valve and a refrigeration cycle system using the electric valve.

Conventionally, an electric valve having a structure as shown in FIG. 5 has been known (see, for example, Patent Document 1). That is, when the stepping motor is driven and the rotor 103 is rotated, the valve body 114 moves in the central axis L direction due to the screw feeding action of the female screw 131a and the male screw 121a. As a result, the opening degree of the valve port 130b is adjusted, and the flow rate of the fluid flowing in from the pipe joint 111 and flowing out from the pipe joint 112 or the flow rate of the fluid flowing in from the pipe joint 112 and flowing out from the pipe joint 111 is controlled. Will be done.

Here, when controlling the flow rate of various fluids, there is a problem that fluid passing noise is generated, so that noise reduction is required. Further, in the indoor unit of the refrigeration cycle of a household air conditioner or a commercial air conditioner using a refrigerant, when the refrigerant flow rate is controlled by the electric valve 100, the liquid refrigerant is a gas-liquid mixed two-phase before and after passing through the valve port 130b. Since it becomes a flow, it is required to exhibit quietness even in various refrigerant states and operating conditions.

Japanese Unexamined Patent Publication No. 2016-0898770

By the way, the above-mentioned electric valve 100 is fixed to a fluid pipe (not shown) via a pipe joint 111 and a pipe joint 112, and the valve body 114 and the valve port 130b of the valve seat 130 are exposed in the flow path. Therefore, in the electric valve 100, when a high pressure difference occurs between the inlet side and the outlet side of the valve port 130b, particularly when the fluid flows from the pipe joint 111 to the pipe joint 112, as shown in FIG. , A fluid such as a refrigerant flowing from the pipe joint 111 may hit the valve body 114, and the valve body 114 may vibrate in the radial direction (C) due to the collision force. When the sound generated by this vibration is generated, the quietness of the electric valve 100 may not be maintained.

Here, as shown in FIG. 7, it is conceivable to raise the position of the top surface 130a of the valve seat 130 so that the fluid flowing from the pipe joint 111 into the valve chamber 121 does not directly hit the valve body 114. Be done. However, in this case, since most of the fluid that hits the valve body 114 flows upward, an upward force is applied to the valve body 114, and the valve body 114 vibrates in the vertical direction (E). Therefore, in this case as well, it becomes difficult to maintain quietness.

An object of the present invention is to provide an electric valve capable of accurately maintaining quietness, and a refrigeration cycle system using the electric valve.

The electric valve of the present invention
The rotary motion of the rotor housed in the inner circumference of the case is converted into a linear motion by screwing the male screw member and the female screw member, and based on this linear motion, the valve body housed in the valve body is used as an axis. An electric valve that moves in the direction
The first pipe joint mounted on the side surface of the valve body and
A valve seat member having a valve port on which the valve body can be brought close to or separated from each other.
A second pipe joint that communicates with the first pipe joint via the valve port is provided.
The position of the top surface of the valve seat member in the axial direction is located on the rotor side of the central axis of the first pipe joint.
In the valve chamber in the valve body, a first space formed on the rotor side of the first pipe joint in the axial direction and the second pipe joint side of the first pipe joint in the axial direction. It is characterized in that it includes a second space formed in.

According to this, by raising the position of the top surface of the valve seat member, it is possible to prevent the fluid flowing in from the first pipe joint from directly colliding with the valve body, and suppress the vibration in the radial direction of the valve body. can do. Further, by providing the second space in addition to the first space in the valve body, all the fluid flowing in from the first pipe joint flows upward and an upward force is applied to the valve body, so that the valve body moves in the axial direction. It is possible to suppress the vibration. By reducing the load on the valve body in this way, it is possible to reduce the vibration in the radial axis direction of the valve body and accurately maintain the quietness of the electric valve.

Further, the electric valve of the present invention is
The inner diameter of the valve body is larger than the inner diameter of the first pipe joint.
As a result, it is possible to accurately secure an escape place for the fluid.

Further, the electric valve of the present invention is
The lowermost end of the outer diameter of the first pipe joint is arranged on the rotor side of the inner bottom surface of the valve body.
As a result, the upward flow of the fluid flowing in from the first pipe joint can be suppressed more accurately.

Further, the electric valve of the present invention is
The position of the top surface of the valve seat member in the axial direction does not exceed the uppermost end of the inner diameter of the first pipe joint in the axial direction.
As a result, the fluid flowing in from the first pipe joint can be accurately distributed up and down and guided to the first space and the second space.

Further, the refrigeration cycle system of the present invention is
A refrigeration cycle system including a compressor, a condenser, an expansion valve, and an evaporator, characterized in that the above-mentioned electric valve is used as the expansion valve.

According to the invention according to the present invention, it is possible to provide an electric valve capable of accurately maintaining quietness and a refrigeration cycle system using the electric valve.

It is the schematic sectional drawing of the electric valve which concerns on embodiment. It is an enlarged view of the main part of the electric valve which concerns on embodiment. It is a side view of the main part of the electric valve which concerns on embodiment. It is a figure which shows the top surface of the valve seat member which is visible from the inside of the 1st pipe joint connected to the electric valve which concerns on embodiment. It is the schematic sectional drawing of the conventional electric valve. It is an enlarged view of the main part of a conventional electric valve. It is an enlarged view of the main part of the electric valve as a comparative example.

Hereinafter, the electric valve according to the embodiment of the present invention will be described with reference to the drawings. FIG. 1 is a schematic cross-sectional view showing the electric valve 2 according to the embodiment. In addition, in this specification, "upper" or "lower" is defined in the state of FIG. That is, the rotor 4 is located above the valve body 17.

In the electric valve 2, the valve body 30 is integrally connected to the lower side of the opening side of the case 60 having a tubular cup shape made of metal by welding or the like.
Here, the valve body 30 is made of a metal such as stainless steel, and has a valve chamber 11 inside. Further, the valve body 30 is fixedly fitted with a first pipe joint 12 made of, for example, stainless steel or copper, which directly communicates with the valve chamber 11. Further, a valve seat member 16 having a valve port 16a having a circular cross section is incorporated in the bottom surface of the valve body 30. A second pipe joint 15 made of, for example, stainless steel or copper, which communicates with the first pipe joint 12 via the valve port 16a and the valve chamber 11, is fixedly mounted on the valve seat member 16.

A rotatable rotor 4 is housed in the inner circumference of the case 60, and a valve shaft 41 is arranged at a shaft core portion of the rotor 4 via a bush member 33. The rotor 4 is made of a magnetic material such as a resin material containing magnetic powder or a ferrite magnet. Both the bush member 33 and the valve shaft 41 are made of a metal such as stainless steel, and the valve shaft 41 and the rotor 4 connected by the bush member 33 move integrally in the vertical direction while rotating. A male screw 41a is formed on the outer peripheral surface of the valve shaft 41 near the middle portion. In this embodiment, the valve shaft 41 functions as a male screw member. Further, the valve body 17 can be brought close to or separated from the valve port 16a.

A stator composed of a yoke, a bobbin, a coil, and the like (not shown) is arranged on the outer periphery of the case 60, and a stepping motor is configured by the rotor 4 and the stator.
Below the bush member 33 of the valve shaft 41, a valve shaft holder 6 having a function of forming a screw feed mechanism A with the valve shaft 41 and suppressing the inclination of the valve shaft 41 is provided as a valve body. It is fixed so that it cannot rotate relative to 30.

The valve shaft holder 6 includes a tubular small diameter portion 6a on the upper side, a tubular large diameter portion 6b on the lower side, a fitting portion 6c accommodated on the inner peripheral portion side of the valve body 30, and a ring-shaped flange portion 6f. Consists of. The flange portion 6f of the valve shaft holder 6 is fixed to the upper end of the valve body 30 by welding or the like. Further, inside the valve shaft holder 6, a storage chamber 6h for accommodating a valve guide 18 described later is formed. The valve shaft holder 6 is made of a resin material except for the metal flange portion 6f.

Further, a female screw 6d is formed downward from the upper opening 6g of the tubular small diameter portion 6a of the valve shaft holder 6 to a predetermined depth. Therefore, in the present embodiment, the valve shaft holder 6 functions as a female screw member. The screw feed mechanism A is composed of a male screw 41a formed on the outer circumference of the valve shaft 41 and a female screw 6d formed on the inner circumference of the tubular small diameter portion 6a of the valve shaft holder 6.

Further, a pressure equalizing hole 51 is formed on the side surface of the tubular large diameter portion 6b of the valve shaft holder 6, and the pressure equalizing hole 51 allows the valve shaft holder chamber 83 in the tubular large diameter portion 6b and the rotor. It communicates with the containment chamber 67 (second back pressure chamber). By providing the pressure equalizing hole 51 in this way, the space for accommodating the rotor 4 of the case 60 and the space inside the valve shaft holder 6 are communicated with each other, so that the valve body 17 can be smoothly moved. ..

Further, below the valve shaft 41, a tubular valve guide 18 is slidably arranged with respect to the accommodating chamber 6h of the valve shaft holder 6. The ceiling portion 21 side of the valve guide 18 is bent at a substantially right angle by press molding. A through hole 18a is formed in the ceiling portion 21. Further, a flange portion 41b is further formed below the valve shaft 41.

Here, the valve shaft 41 is inserted into the through hole 18a of the valve guide 18 in a loose state so as to be rotatable with respect to the valve guide 18 and displaceable in the radial direction, and the flange portion 41b is a valve. It is arranged in the valve guide 18 so as to be rotatable with respect to the guide 18 and displaceable in the radial direction. Further, the valve shaft 41 is arranged so that the through hole 18a is inserted and the upper surface of the flange portion 41b faces the ceiling portion 21 of the valve guide 18. Since the flange portion 41b has a diameter larger than that of the through hole 18a of the valve guide 18, the valve shaft 41 is prevented from coming off.

Since the valve shaft 41 and the valve guide 18 can be moved in the radial direction to each other, the valve guide 18 and the valve guide 18 and the valve guide 18 and the valve guide 18 are not required to have a high degree of concentric mounting accuracy with respect to the arrangement positions of the valve shaft holder 6 and the valve shaft 41. Concentricity with the valve body 17 can be obtained.
A washer 70 having a through hole formed in the central portion is installed between the ceiling portion 21 of the valve guide 18 and the flange portion 41b of the valve shaft 41.

Next, a main part of the electric valve 2 according to the embodiment will be described. FIG. 2 is an enlarged view of a main part of the electric valve 2 according to the embodiment. As shown in FIG. 2, a valve chamber 11 is formed in the valve body 30. In the present embodiment, the valve chamber 11 is divided into three spaces described below. That is, in the valve chamber 11, the first space 11a formed at a position above the first pipe joint 12 (rotor 4 side) in the axis M direction and below the first pipe joint 12 (second pipe). The second space 11b formed at the position (on the joint 15 side) and the third space 11c formed at the same level as the first pipe joint 12 are included. Here, the upper side of the first pipe joint 12 more specifically means the upper side of the uppermost end X1 of the outer diameter of the first pipe joint 12. Similarly, the lower side of the first pipe joint 12 refers to the lower side of the lowermost end X2 of the outer diameter of the first pipe joint 12.

Further, the first space 11a is a substantially cylindrical space, and the upper portion thereof is in contact with the lower portion of the valve shaft holder 6 and the valve body 17.
The second space 11b is a substantially annular space, and is formed around the valve seat member 16. The second space 11b is formed by attaching the outermost lower end X2 of the first pipe joint 12 to the upper side of the bottom surface 30a of the valve body 30. More preferably, the first pipe joint 12 is attached so that the depth (L) of the second space 11b is deeper than the radius (D / 2) of the inner diameter of the first pipe joint (L> D /). 2).

Further, in the electric valve 2 according to the embodiment, a valve seat member 16 having a high height is used. Specifically, as the valve seat member 16, the position of the top surface 16b in the axis M direction is located above the position of the central axis N of the first pipe joint 12 in a state of being fixedly mounted to the second pipe joint 15. Is used.

Further, as shown in FIG. 3, the top surface 16b is preferably located at a height that can be visually recognized when the inside of the first pipe joint 12 is viewed from the direction of the arrow (B) in FIG. That is, it is preferable that the valve seat member 16 is arranged at a position where the top surface 16b does not exceed the uppermost end of the inner diameter of the first pipe joint 12 in the axis M direction. In this case, as shown in FIG. 4, when the lowermost end of the inner diameter of the first pipe joint 12 is used as the upper and lower reference, the position (H) of the top surface 16b is the position (D) of the central axis N of the first pipe joint 12. It is located above the / 2) and below the uppermost end (D) of the inner diameter of the first pipe joint 12 (D / 2 <H <D).

Here, as shown in FIG. 2, the velocity of the fluid flowing into the valve chamber 11 from the first pipe joint 12 is the fastest at the center and becomes slower as it approaches the inner circumference of the first pipe joint 12. Therefore, if the top surface 16b is positioned below the central axis N of the first pipe joint 12, a high-speed fluid directly hits the valve body 17, and a large radial load is applied to the valve body 17. Will cause the valve body 17 to vibrate in the radial direction.

On the other hand, when the top surface 16b is located at the position (D / 2 <H <D) described with reference to FIG. 4, as in the electric valve 2 according to the embodiment, as shown in FIG. In addition, the earliest part of the fluid once collides with the outer circumference of the valve seat member 16 to reduce the speed and branches in the vertical direction. The fluid branched upward is introduced into the first space 11a, and the fluid branched downward is introduced into the second space 11b.

Here, in the electric valve 2 according to the embodiment, since the height of the top surface 16b is not located too high, the force applied upward to the valve body 17 by the fluid branched upward (see FIG. 7) is also present. It will be reduced.

Further, since the second space 11b is provided below the valve chamber 11, an escape route for the fluid branched downward is secured. As a result, it is suppressed that the fluid branched downward loses the escape place and flows upward, and applies an upward force to the valve body 17.

Further, in the electric valve 2 according to the embodiment, the inner diameter Y (see FIG. 2) of the valve body 30 is formed to be larger than the inner diameter (D) of the first pipe joint 12 (Y> D). .. Therefore, it is possible to accurately secure an escape place for the fluid that has flowed into the valve chamber 11.

According to the electric valve 2 in this embodiment, the position of the top surface 16b of the valve seat member 16 is raised so that the fluid flowing in from the first pipe joint 12 does not directly collide with the valve body 17. It is possible to suppress the radial vibration of the valve body 17. Further, by providing the second space 11b in addition to the first space 11a in the valve body 30, all the fluid flowing in from the first pipe joint 12 flows upward and an upward force is applied to the valve body 17. It is possible to suppress the valve body 17 from vibrating in the axis M direction. By reducing the load on the valve body 17 in this way, it is possible to reduce the radial and axial vibrations of the valve body 17, and even in various fluid controls, various refrigerant states and operating conditions in the refrigeration cycle can be reduced. Even in the above case, the quietness of the electric valve 2 can be accurately maintained.

Further, since the quietness of the electric valve 2 is maintained only by raising the position of the top surface 16b of the valve seat member 16, the structure of the electric valve 2 is not complicated, and a sound absorbing member, a sound deadening device, and the like can be used. Since it is not used, the quietness of the electric valve 2 can be maintained at low cost.

Further, the electric valve 2 of the above-described embodiment is used as an expansion valve provided between the condenser and the evaporator in, for example, a refrigeration cycle system including a compressor, a condenser, an expansion valve, an evaporator and the like. Be done.

2 Electric valve 6d Female screw 11 Valve chamber 11a 1st space 11b 2nd space 11c 3rd space 12 1st pipe joint 15 2nd pipe joint 16 Valve seat member 16a Valve port 16b Top surface 17 Valve body 18 Valve guide 30 Valve body 30a Bottom surface 41a Male screw M Shaft of electric valve 2 N Central axis of first pipe joint 12 X1 Uppermost end of outer diameter of first pipe joint 12 X2 Lowermost end of outer diameter of first pipe joint 12 Y Inner diameter of valve body 30

The electric valve of the present invention
The rotary motion of the rotor housed in the inner circumference of the case is converted into a linear motion by screwing the male screw member and the female screw member, and based on this linear motion, the valve body housed in the valve body is used as an axis. An electric valve that moves in the direction
The first pipe joint mounted on the side surface of the valve body and
A valve seat member having a flat top surface with an open valve port from which the valve body can be brought close to or separated from each other.
A second pipe joint that communicates with the first pipe joint via the valve port is provided.
To branch a fluid flowing into the valve chamber of the valve body from said first fitting into the second fitting side direction as the rotor side direction of the valve body, the said top surface of said valve seat member position in the axial direction, Oite the rotor side from the central axis of the first pipe joint, located at a height not exceeding the top end of the inner diameter of the first fitting,
The valve chamber of the valve body has a first space formed in the rotor side of the first fitting in the axial direction, the second fitting than the first fitting in the axial direction It is characterized by including a second space formed on the side.
Further, the electric valve of the present invention is
The rotary motion of the rotor housed in the inner circumference of the case is converted into a linear motion by screwing the male screw member and the female screw member, and based on this linear motion, the valve body housed in the valve body is used as an axis. An electric valve that moves in the direction
The first pipe joint mounted on the side surface of the valve body and
A valve seat member having a flat top surface with an open valve port from which the valve body can be brought close to or separated from each other.
A second pipe joint that communicates with the first pipe joint via the valve port is provided.
The position of the top surface of the valve seat member in the axial direction is on the rotor side of the central axis of the first pipe joint, and the extension line of the central axis of the first pipe joint and the valve seat member. The outer peripheral surfaces intersect, and the position of the top surface of the valve seat member in the axial direction is located at a height not exceeding the uppermost end of the inner diameter of the first pipe joint.
In the valve chamber in the valve body, a first space formed on the rotor side of the first pipe joint in the axial direction and a second pipe joint side of the first pipe joint in the axial direction. Includes a second space formed in
The axial position of the seating tapered surface of the valve body is on the rotor side from the uppermost end of the outer diameter of the first pipe joint when the valve is fully opened.

According to this, by raising the position of the top surface of the valve seat member, it is possible to prevent the fluid flowing in from the first pipe joint from directly colliding with the valve body, and suppress the vibration in the radial direction of the valve body. can do. Further, by providing the second space in addition to the first space in the valve body, all the fluid flowing in from the first pipe joint flows upward and an upward force is applied to the valve body, so that the valve body moves in the axial direction. It is possible to suppress the vibration. By reducing the load on the valve body in this way, it is possible to reduce the vibration in the radial axis direction of the valve body and accurately maintain the quietness of the electric valve.
In addition, the fluid flowing in from the first pipe joint can be accurately distributed up and down and guided to the first space and the second space.

Further, the electric valve of the present invention is
The first pipe joint is characterized in that the depth of the second space is deeper than the radius of the inner diameter of the first pipe joint.
Further, the electric valve of the present invention is
The valve body is characterized in that its outer diameter portion is larger than that of the valve port, and an annular flat surface is formed between the tip portion thereof and the outer diameter portion.
Further, the electric valve of the present invention is
The lower end of the female thread member is closer to the rotor side than the uppermost end of the outer diameter of the first pipe joint.
Further, the electric valve of the present invention is
The dimension between the lower surface of the overhanging portion of the female screw member and the uppermost end of the outer diameter of the first pipe joint is larger than the inner diameter of the first pipe joint.

Claims (5)

The rotary motion of the rotor housed in the inner circumference of the case is converted into a linear motion by screwing the male screw member and the female screw member, and based on this linear motion, the valve body housed in the valve body is used as an axis. An electric valve that moves in the direction
The first pipe joint mounted on the side surface of the valve body and
A valve seat member having a valve port on which the valve body can be brought close to or separated from each other.
A second pipe joint that communicates with the first pipe joint via the valve port is provided.
The position of the top surface of the valve seat member in the axial direction is located on the rotor side of the central axis of the first pipe joint.
In the valve chamber in the valve body, a first space formed on the rotor side of the first pipe joint in the axial direction and the second pipe joint side of the first pipe joint in the axial direction. An electric valve characterized in that it includes a second space formed in. The electric valve according to claim 1, wherein the inner diameter of the valve body is larger than the inner diameter of the first pipe joint. The electric valve according to claim 1 or 2, wherein the lowermost outer diameter of the first pipe joint is arranged on the rotor side of the inner bottom surface of the valve body. The aspect according to any one of claims 1 to 3, wherein the position of the top surface of the valve seat member in the axial direction does not exceed the uppermost end of the inner diameter of the first pipe joint in the axial direction. Electric valve. A refrigeration cycle system including a compressor, a condenser, an expansion valve, and an evaporator, wherein the electric valve according to any one of claims 1 to 4 is used as the expansion valve. ..

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