JP2019158154A - Electric operated valve - Google Patents

Abstract

To suppress a friction resistance between a needle valve 3 and guide holes 14, 21c in an electric operated valve when a foreign matter is bitten in a valve port 13 to prevent restraint of the needle valve 3 and smooth advancing and retreating movement.SOLUTION: A valve chamber 1A and a valve port 13 are provided inside a valve body 1. A needle part 31 at the tip of a rod-shaped needle valve 3 is inserted in the valve port 13. A cylinder part 33 of the needle valve 3 is inserted through a body guide hole 14 of the valve body 1 and a drive part guide hole 21c of a support member 2 to be guided. The needle valve 3 is driven by a stepping motor 5, and the needle valve 3 is advanced and retreated through a screw feed mechanism of a male screw part 21a and a female screw part 521a. A clearance between the body guide hole 14 and the drive part guide hole 21c, and the cylinder part 33 of the needle valve 3 is set larger than a clearance between the valve port 13 and the needle part 31 of the needle valve 3.SELECTED DRAWING: Figure 1

Description

  The present invention relates to an electric valve that controls a flow rate of a fluid such as a refrigerant such as an expansion valve of a refrigeration circuit such as an air conditioner or a refrigerator.

  Conventionally, as motor-operated valves used in refrigeration circuits such as air conditioners and refrigerators, for example, disclosed in JP2013-204613A (Patent Document 1) and JP2011-174487A (Patent Document 2). There is something.

  In the electric valve of Patent Document 1, a magnet rotor is disposed in a case of a stepping motor, and a needle valve having a needle portion (valve body portion) at the lower portion is fitted into the center of a male screw shaft fixed to the magnet rotor. ing. The male screw shaft forms a screw feed mechanism together with the female screw of the support member on the valve body side. Then, the rotation of the magnet rotor and the screw feed mechanism drive the needle valve back and forth to control the opening of the valve port (valve port). In the electric valve of Patent Document 2, the valve body is not a needle valve, but is configured to advance and retract the valve body by rotation of a magnet rotor and a screw feed mechanism.

JP 2013-204613 A JP 2011-174487 A

  In recent years, improvement in energy saving performance has been actively studied for air conditioners and refrigerators, and the same performance is required for motor-operated valves used in the refrigeration circuit. For example, in order to improve energy saving performance, the compressor is operated at a low frequency to reduce the circulation amount of the refrigerant in the refrigeration cycle. In this case, it is necessary to reduce the flow rate by making the valve opening of the motor-operated valve extremely small in accordance with the circulation amount, and the motor-operated valve is required to have high controllability in this minute flow rate region.

  However, if the valve opening is extremely small, foreign matter may be caught between the valve opening and the tip of the needle valve (needle part), and the frictional resistance against the guide part (hole etc.) that guides the needle valve There is a problem that the movement of the needle valve becomes worse, or the needle valve is restrained, leading to malfunction. In particular, when the flow rate is low, the gap between the straight part (or needle part) of the needle valve and the valve port is finely controlled, so that the influence of foreign matter is increased.

  It is an object of the present invention to suppress frictional resistance between a needle valve and a guide hole when a foreign object is caught in a valve port in a motor-operated valve, to prevent the needle valve from being restrained and to smoothly advance and retreat. To do.

  The motor-driven valve according to claim 1 is provided inside the valve body and has a valve chamber having a valve port, a rod-shaped needle valve into which a needle portion at the tip is inserted into the valve port, and an intermediate portion of the needle valve A motor-driven valve including a guide hole that guides the needle valve and a drive unit that drives the needle valve to advance and retreat, the guide hole being more than the clearance between the valve port and the needle part of the needle valve. And a clearance between the intermediate portion of the needle valve is set large. There may be a case where the intermediate portion or guide hole of the needle valve is somewhat tapered, but the clearance between the guide hole and the intermediate portion of the needle valve is the minimum between the guide hole and the intermediate portion. It is clearance.

  The motor-driven valve according to claim 2 is the motor-operated valve according to claim 1, wherein the guide hole is formed in a main body guide hole provided in a part of the valve main body and in a part of the drive unit. And a clearance between the drive portion guide hole and the intermediate portion of the needle valve is set larger than a clearance between the main body guide hole and the intermediate portion of the needle valve. It is characterized by.

  The motor-driven valve according to claim 3 is the motor-operated valve according to claim 1, wherein the guide hole is formed in a main body guide hole provided in a part of the valve main body and a part of the drive unit. And a clearance between the main body guide hole and the intermediate portion of the needle valve is set larger than a clearance between the drive portion guide hole and the intermediate portion of the needle valve. It is characterized by.

  The motor-operated valve according to claim 4 is the motor-operated valve according to any one of claims 1 to 3, wherein the needle portion of the needle valve has a clearance from the valve port at an end portion on the intermediate portion side. It is characterized by having a straight part that minimizes.

  According to the electric valve of the first aspect, even when foreign matter is caught between the valve port and the needle portion, the friction resistance between the intermediate portion of the needle valve and the guide hole is suppressed to restrain the needle valve. The needle valve can be smoothly moved forward and backward. That is, if the clearance between the valve port and the needle portion is larger than the clearance between the guide hole and the intermediate portion of the needle valve, the needle valve will be inserted into the guide hole when foreign matter is caught between the valve port and the needle portion. In the present invention, this can be prevented.

  According to the electric valve of claim 2, in addition to the effect of claim 1, the clearance between the drive portion guide hole and the intermediate portion of the needle valve is greater than the clearance between the main body guide hole and the intermediate portion of the needle valve. Since it is set large, the sliding resistance between the intermediate portion and the drive portion guide hole can be suppressed while enhancing the sealing performance at the main body guide hole.

  According to the electric valve of claim 3, in addition to the effect of claim 1, the clearance between the main body guide hole and the intermediate portion of the needle valve 3 is more than the clearance between the drive portion guide hole and the intermediate portion of the needle valve. Therefore, even if a concentric variation occurs when, for example, the support member is pressed into the valve body during assembly, the concentric variation can be absorbed.

  According to the fourth aspect of the present invention, in addition to the effect of any one of the first to third aspects, even if the advance / retreat position of the needle valve fluctuates in the range where the straight portion is within the valve opening, the minimum minute A constant flow range can be secured.

It is a longitudinal cross-sectional view of the motor operated valve of embodiment of this invention. It is an enlarged view of the vicinity of a needle part and a valve mouth in an embodiment. It is an enlarged view of the part of the cylindrical part and guide hole in embodiment.

  Next, an embodiment of the motor-operated valve of the present invention will be described with reference to the drawings. FIG. 1 is a longitudinal sectional view of an electric valve according to an embodiment. Note that the concept of “upper and lower” in the following description corresponds to the upper and lower sides in the drawing of FIG.

  This electric valve has a valve body 1 formed by cutting a metal member with stainless steel, brass, or the like, and the valve body 1 has a valve chamber 1A therein. A first joint pipe 11 connected to the valve chamber 1 </ b> A is connected to one outer peripheral side of the valve body 1. A second joint pipe 12 is connected to the lower end of the valve body 1, and a valve port 13 is formed on the inner bottom surface of the valve body 1, and the second joint pipe 12 is connected to the valve port 13 via the valve port 13. Conducted to chamber 1A. The first joint pipe 11 and the second joint pipe 12 are fixed to the valve body 1 by brazing or the like. A main body guide hole 14 as a part of a “guide hole” opened at the upper end and a mounting hole 15 are formed on the opposite side of the valve body 1 from the valve port 13, and the support member 2 is press-fitted into the mounting hole 15. It is attached by.

  The support member 2 constitutes a part of the “driving portion”, and includes a substantially cylindrical holder portion 21, a flange portion 22 formed near the valve body 1 of the holder portion 21, a fixed-side stopper portion 23, and the like. have. A male screw portion 21a is formed on the outer periphery of the holder portion 21, and a cylindrical rotor guide 21b for guiding a magnet rotor 52 described later is formed above the male screw portion 21a. Furthermore, a drive portion guide hole 21c as a part of a “guide hole” coaxial with the axis X of the valve port 13 is formed at the center of the support member 2, and the needle valve 3 is formed in the drive portion guide hole 21c. Is inserted.

  The needle valve 3 is formed of a metal member such as stainless steel or brass, and has a needle portion 31 at the lower end and a tapered portion 32 having a truncated cone shape. The needle valve 3 includes a cylindrical portion 33 as an “intermediate portion” inserted through the main body guide hole 14 of the valve main body 1 and the drive portion guide hole 21 c of the support member 2, and a rod-like shape having a smaller diameter than the cylindrical portion 33. Rod part 34. The urging spring 4 is disposed around the rod portion 34 between the step portion 33a of the cylindrical portion 33 and the magnet rotor 52 in a compressed state. Thereby, the needle valve 3 is always biased toward the valve port 13 with respect to the magnet rotor 52.

  A lid 16 is attached to the upper end of the valve body 1, and a case 51 of the stepping motor 5 constituting a part of the “driving unit” is airtightly fixed to the lid 16 by welding or the like. In the case 51, a magnet rotor 52 having an outer peripheral portion magnetized in multiple poles is rotatably provided. A stator coil 53 is disposed on the outer periphery of the case 51. The stepping motor 5 rotates the magnet rotor 52 according to the number of pulses when a pulse signal is given to the stator coil 53. The magnet rotor 52 includes a rotor body 521 and a magnet 522 fixed to the outer periphery thereof.

  A female screw portion 521a coaxial with the axis X of the valve port 13 and a screw hole thereof are formed below the center of the rotor main body 521, and at the center of the rotor main body 521 from the inner periphery of the screw hole of the female screw portion 521a. A cylindrical slide hole 521b having a small diameter is also formed. Further, a needle valve insertion hole 521c is formed at the upper center of the slide hole 521b. In addition, a movable side stopper 52a that protrudes downward is formed at one lower portion of the magnet 522.

  The cylindrical portion 33 of the needle valve 3 is inserted into the main body guide hole 14 of the valve body 1 and the drive portion guide hole 21c of the support member 2, and the end portion of the needle valve 3 is inserted into the needle valve insertion hole 521c of the rotor body 521. 3a (end part of the rod part 34) is penetrated. The magnet rotor 52 is inserted into the slide hole 521b through the rotor guide 21b of the support member 2, and the female screw portion 521a on the magnet rotor 52 side is screwed to the male screw portion 21a on the support member 2 side. . Then, the fixing member 6 is press-fitted into the end portion 3a of the needle valve 3, and is integrally fixed by welding (the needle valve 3 and the fixing member 6).

  The male screw portion 21a and the female screw portion 521a are screw feeding mechanisms, but in this embodiment, the male screw portion 21a and the female screw portion 521a are right-hand screws. A compression spring 54 is provided between the case 51 and the magnet rotor 52 to urge the magnet rotor 52 in the valve closing direction. However, backlash between the male screw portion 21a and the female screw portion 521a occurs. By removing it, it plays a role of reducing the operating noise of the magnet rotor 52.

  With the above configuration, when the magnet rotor 52 rotates, the magnet rotor 52 moves in the axis X direction (up and down) by the screw feeding action of the female screw portion 521a and the male screw portion 21a. Further, the fixing member 6 at the upper end of the needle valve 3 is in contact with the magnet rotor 52 by the biasing force of the biasing spring 4, the needle valve 3 moves together with the magnet rotor 52, and the needle portion 31 of the needle valve 3 is the valve port. Advances and retreats against 13. Thereby, the opening degree of the valve port 13 is changed, and the flow rate of the refrigerant flowing from the first joint pipe 11 to the second joint pipe 12 or the flow rate of the refrigerant flowing from the second joint pipe 12 to the first joint pipe 11 is controlled. The

  Further, the needle portion 31 has a cylindrical straight portion 31a at the end on the taper portion 32 side, and the clearance between the straight portion 31a and the valve port 13 is very small, and the straight portion 31a is the valve port. When it is located within 13, the control is performed in the minute flow rate region. Note that the lower end position of the magnet rotor 52 is regulated by the fixed-side stopper portion 23. That is, when the magnet rotor 52 rotates and descends, the movable side stopper 52a passes over the fixed side stopper portion 23, and the rotation is restricted when the movable side stopper 52a contacts the fixed side stopper portion 23. .

2 is an enlarged view of the vicinity of the needle portion 31 and the valve port 13, and FIG. 3 is an enlarged view of a cylindrical portion 33 and a guide hole portion. As shown in FIG. 2, when the diameter of the valve port 13 is D1, and the diameter of the straight part 31a of the needle part 31 is D2, the diameter D2 is slightly smaller than the diameter D1,
D1-D2 = CL1
However, this is the clearance between the valve port 13 and the needle portion 31 (straight portion 31a).

As shown in FIG. 3, when the diameter of the main body guide hole 14 is D3, the diameter of the drive portion guide hole 21c is D4, and the diameter of the cylindrical portion 33 of the needle valve 3 is D5, D3 and D4 are slightly smaller than D5. Big and
D3 <D4
It has become. And
D3-D5 = CL2
Is the clearance between the main body guide hole 14 and the cylindrical portion 33,
D4-D5 = CL3
However, this is the clearance between the drive portion guide hole 21 c and the cylindrical portion 33. Therefore,
CL2 <CL3
It has become.

Furthermore, in this embodiment,
CL1 <CL2 <CL3
It has become. That is, the clearance between the main body guide hole 14 and the drive portion guide hole 21c (guide hole) and the cylindrical portion 33 (intermediate portion) rather than the clearance (CL1) between the valve port 13 and the needle portion 31 at the tip of the needle valve 3 ( CL2 and CL3) are set large.

  This suppresses frictional resistance between the cylindrical portion 33 of the needle valve 3, the main body guide hole 14, and the drive portion guide hole 21c even when foreign matter is caught between the valve port 13 and the needle portion 31. Therefore, the needle valve 3 can be prevented from being restrained, and the needle valve 3 can be smoothly moved forward and backward. That is, when the clearance between the valve port 13 and the needle portion is larger than the clearance between the guide hole and the columnar portion 33 of the needle valve 3, when foreign matter is caught between the valve port 13 and the needle portion 3, The needle valve 3 is restrained by the guide hole, but this can be prevented.

  Further, the clearance (CL3) between the drive portion guide hole 21c and the cylindrical portion 33 (intermediate portion) of the needle valve 3 is larger than the clearance (CL2) between the main body guide hole 14 and the cylindrical portion 33 (intermediate portion) of the needle valve 3. Is set larger. Therefore, the sliding resistance between the cylindrical portion 33 and the drive portion guide hole 21c can be suppressed while enhancing the sealing performance in the main body guide hole 14.

  Contrary to the above embodiment, the main body guide hole 14 and the cylindrical portion 33 (intermediate portion) of the needle valve 3 are more than the clearance (CL3) between the drive portion guide hole 21c and the cylindrical portion 33 (intermediate portion) of the needle valve 3. ) And the clearance (CL2) may be set larger. In this case, since the cylindrical portion 33 does not substantially contact the main body guide hole 14, even if the concentric variation occurs when the support member 2 is pressed into the valve main body 1 during assembly, the concentric variation can be absorbed.

  In the electric valve of the above embodiment, the male screw portion 21a and the female screw portion 521a constituting the screw feeding mechanism are related to the male screw portion 21a fixed to the valve body 1 side, and the female screw portion 521a is the magnet rotor 52. Although fixed to the side, the reverse configuration may be used. That is, according to the present invention, a screw feed mechanism is configured by screwing a male screw portion fixed to the magnet rotor with a female screw portion fixed to the valve body, as in Patent Document 1, for example. Thus, it can be applied to a motor-operated valve.

  In the above embodiment, the drive unit drives the needle valve forward and backward by a screw feed function, but the drive unit may have other configurations as long as it drives the needle valve to advance and retract.

  As described above, the embodiments of the present invention have been described in detail with reference to the drawings. However, the specific configuration is not limited to these embodiments, and the design can be changed without departing from the scope of the present invention. Is included in the present invention.

1 Valve Body 1A Valve Chamber 11 First Joint Pipe 12 Second Joint Pipe 13 Valve Port 14 Body Guide Hole (Guide Hole)
2 Support member (drive unit)
21 Holder part 21a Male thread part 21b Rotor guide 21c Drive part guide hole (guide hole)
3 Needle valve 31 Needle part 31a Straight part 32 Taper part 33 Cylindrical part (intermediate part)
34 Rod part 4 Biasing spring 5 Stepping motor (drive part)
51 Case 52 Magnet rotor 521a Female thread part 53 Stator coil X Axis

The motor-driven valve according to claim 1 is provided inside the valve body and has a valve chamber having a valve port, and a needle part at the tip is inserted into the valve port, and an intermediate part is formed in a columnar shape or a tapered columnar shape. A rod-shaped needle valve, a guide hole for inserting and guiding the intermediate portion of the needle valve, and a drive portion for driving the needle valve forward and backward , the valve port and the needle portion of the needle valve than the clearance between, clearance scan is set larger is the minimum difference between the outer diameter of the intermediate portion of the inner diameter and the needle valve before outs id hole, the needle portion from said intermediate portion In addition, a cylindrical straight portion, and a needle intermediate taper portion that is adjacent to the straight portion and is tapered at the first taper angle toward the distal end side of the needle portion, the length of the straight portion is Serial and being shorter than the length of the needle intermediate tapered portion. There may be a case where the intermediate portion or guide hole of the needle valve is somewhat tapered, but the clearance between the guide hole and the intermediate portion of the needle valve is the minimum between the guide hole and the intermediate portion. It is clearance.
The motor-driven valve according to claim 2 is characterized in that, in the motor-operated valve according to claim 1, the length of the straight portion is smaller than the outer diameter of the straight portion.
The motor-operated valve according to claim 3 is the motor-operated valve according to claim 1, wherein a valve intermediate taper portion tapered toward the needle portion is provided between the needle portion and the intermediate portion of the needle valve. The straight portion of the needle portion is formed adjacent to the valve intermediate taper portion.
The motor-driven valve according to claim 4 is the motor-operated valve according to claim 1, wherein the intermediate portion of the needle valve is formed in a columnar shape, and the outer diameter of the intermediate portion is smaller than the inner diameter of the guide hole, In addition, the tip of the intermediate part on the needle part side protrudes into the valve chamber.
The motor-driven valve according to claim 5 is the motor-operated valve according to claim 1, wherein the needle portion is adjacent to the straight portion, the needle intermediate taper portion, and the needle intermediate taper portion from the intermediate portion side. In addition, a needle tip taper portion that is tapered toward the tip side at a second taper angle larger than the first taper angle is formed.
The motor-operated valve according to claim 6 is the motor-operated valve according to claim 1, wherein at least a part of the straight portion is inside the valve port when the needle valve is moved most toward the valve port side. It is characterized by being located.

The guide hole includes a main body guide hole provided in a part of the valve main body, and a drive part guide hole formed in a part of the drive part. The main body guide hole and the needle valve The clearance between the drive portion guide hole and the intermediate portion of the needle valve may be set larger than the clearance with the intermediate portion.

The guide hole includes a body guide hole provided in a part of the valve body, and a drive part guide hole formed in a part of the drive part. The drive part guide hole and the needle A clearance between the main body guide hole and the intermediate portion of the needle valve may be set larger than a clearance between the intermediate portion of the valve.

The needle portion of the needle valve may include a straight portion that minimizes a clearance from the valve port at an end portion on the intermediate portion side.

Moreover, than the clearance between the intermediate portion of the main body guide hole and the needle valve, the direction of the clearance between the intermediate portion of the driving portion guide hole and the needle valve is set to be larger, while enhancing the sealing performance of the in body guide hole And the sliding resistance of an intermediate part and a drive part guide hole can be suppressed.

Moreover, than the clearance between the intermediate portion of the driving portion guide hole and the needle valve, the main body guide hole and the direction of the clearance between the intermediate portion of the needle valve 3 is set to be larger, for example, the support member relative to the valve body during assembly Even if a concentric variation occurs during the press-fitting, the concentric variation can be absorbed.

Further , in the range where the straight portion is in the valve opening, even if the advance / retreat position of the needle valve varies, a minimum minute flow rate region can be secured constantly.

Claims (1)

A valve chamber that is provided inside the valve body and has a valve port; a needle-shaped needle valve in which an intermediate portion is formed in a columnar shape or a tapered column shape;
A guide hole for guiding and guiding the intermediate portion of the needle valve;
A drive unit for driving the needle valve forward and backward,
The guide hole is a motor-operated valve composed of a main body guide hole provided in a part of the valve main body and a drive part guide hole formed in a part of the drive part,
The clearance that is the smallest difference between the inner diameter of the main body guide hole and the outer diameter of the intermediate portion of the needle valve, and the inner diameter of the drive portion guide hole, rather than the clearance between the valve port and the needle portion of the needle valve And a clearance, which is a minimum difference between the outer diameter of the intermediate portion and the clearance, is set to be large.

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