CN110094519B - Electric valve - Google Patents

Abstract

Provided is an electrically operated valve capable of reducing the wear of a stopper body and a collision sound (initialization sound) at the time of initialization (positioning of a base point of the electrically operated valve). In a stopper presser (48) that prevents relative movement of a lower stopper (25) with respect to a guide bush (20), a support claw (49d) that supports the lower stopper (25) in the circumferential direction is elastically deformable in the circumferential direction.

Description

Electric valve

Technical Field

The present invention relates to an electrically operated valve incorporated in a refrigeration cycle such as an air conditioner or a refrigerator as a flow rate control valve.

Background

As such an electrically operated valve, for example, a valve having the following components is known: a valve shaft provided with a valve element at a lower end portion thereof; a guide bush having a cylindrical portion into which the valve shaft is inserted in a state of being relatively movable in an axial direction and relatively rotatable; a valve main body having a valve seat portion (valve seat) that is in contact with and separated from the valve body, and to which the guide bush is attached and fixed; a valve shaft holder having a cylindrical portion into which the guide bush is inserted and a top portion through which an insertion hole through which an upper end portion of the valve shaft is inserted is formed, and coupled and fixed to the valve shaft; a biasing member interposed between the valve shaft and the valve shaft holder to bias the valve body in a valve closing direction; a motor having a rotor and a stator for rotating the valve shaft holder with respect to the guide bush; a screw feed mechanism including a fixed screw portion formed on an outer periphery of the guide bush and a movable screw portion formed on an inner periphery of the valve shaft holder, the screw feed mechanism being configured to raise and lower the valve body of the valve shaft with respect to the valve seat portion (valve seat) based on rotational driving of the rotor; and a lower stopper mechanism configured by a fixed stopper provided to a lower stopper having a female screw portion screwed with the fixed screw portion of the guide bush, and a movable stopper provided to the valve shaft holder, the lower stopper mechanism being configured by a fixed stopper body provided to the lower stopper having a female screw portion screwed with the fixed screw portion of the guide bush, and a gap having a predetermined size being formed between the valve body and the valve seat portion (valve seat) when the valve body is located at the lowermost position (for example, see patent document 1).

In the air conditioner using the valve-opening-less type electric valve as described above, since a predetermined gap is formed between the valve element and the valve seat even when the valve element is at the lowermost position (normally, in the fully closed state), for example, when the dehumidification operation is performed in late night, the electric valve can be operated in a state in which the amount of refrigerant is throttled instead of the fully closed state, and generation of operating noise due to turning on/off of the electric valve can be suppressed. In addition, the motor-operated valve as described above has the following advantages as compared with a normal valve-closing type motor-operated valve: the valve element can be reliably prevented from biting into the valve seat.

Documents of the prior art

Patent document

Patent document 1: japanese patent laid-open publication No. 2016-217451

Problems to be solved by the invention

However, in the conventional motor-operated valve as described above, since a gap of a predetermined size is formed between the valve element and the valve seat, the lower stopper may be non-rotatably coupled and positioned with respect to the guide bush by using a stopper presser (pressing member) that engages with the lower stopper having a fixed stopper body constituting the stopper mechanism to prevent the lower stopper from rotating relative to the guide bush.

However, the stopper presser (pressing member) is generally formed of a metal member (a rigid plate made of metal) having high rigidity. Therefore, for example, when the movable stopper body provided in the valve shaft holder collides with the fixed stopper body provided in the lower stopper at the time of initialization (base point positioning of the motor-operated valve), the stopper presser hardly bends (does not deform), and there is a possibility that a force (impact force) applied to the movable stopper body, the fixed stopper body, and the stopper presser becomes large, a collision sound (initialization sound) thereof becomes large, and abrasion between the stopper bodies becomes large.

Disclosure of Invention

The present invention has been made in view of the above problems, and an object of the present invention is to provide an electrically operated valve capable of reducing a collision sound (initialization sound) and wear of a stopper body at the time of initialization (positioning of a base point of the electrically operated valve).

Means for solving the problems

In order to solve the above problems, the motor-operated valve of the present invention basically includes: a valve shaft provided with a valve core; a guide bush in which the valve shaft is inserted so as to be relatively movable in the axial direction and relatively rotatable; a valve main body having a valve port with a valve seat, and to which the guide bush is attached and fixed; a valve shaft holder coupled to the valve shaft; a motor having a rotor and a stator for rotating the valve shaft holder relative to the guide bushing; a screw feed mechanism for raising and lowering the valve body relative to the valve seat based on rotational driving of the rotor, the screw feed mechanism being provided between the guide bush and the valve shaft holder; a lower stopper mechanism for restricting a rotational downward movement of the valve shaft holder, the lower stopper mechanism having a movable stopper body provided to the valve shaft holder and a fixed stopper body provided to a lower stopper attached to the guide bush; and a pressing member that prevents relative movement of the lower stopper with respect to the guide bush, wherein a support portion that supports the lower stopper in the circumferential direction and is elastically deformable in the circumferential direction is provided upright on the pressing member.

In a preferred aspect, the support portion is provided with a curved portion formed to have a predetermined radius when viewed in a radial direction.

In another preferred aspect, the support portion supports the lower stopper in a circumferential direction so as to face a side surface of the lower stopper on a valve closing direction side.

In another preferred aspect, the support portion is embedded in the lower stopper to support the lower stopper in the circumferential direction.

In another preferred aspect, a support leg is disposed on the support portion, and the support leg extends from the support portion in the normal direction.

In another preferred aspect, the pressing member and the lower stopper are formed as one member.

In a more preferred aspect, the pressing member and the lower stopper are integrated by welding, bonding, caulking, or insert molding.

In another preferred aspect, the lower stopper is biased upward with respect to the guide bush by the pressing member.

In a more preferred aspect, the pressing member is provided with an upper urging portion that abuts against a lower surface of the lower stopper to push up the lower stopper.

In another preferred aspect, the lower stopper is biased downward with respect to the guide bush by the pressing member.

In a more preferred aspect, the pressing member is provided with a lower urging portion that abuts against an upper surface of the lower stopper to press down the lower stopper.

In another preferred aspect, the stator is disposed outside a cylindrical housing joined to the valve body, and the rotor is disposed inside the housing and connected to the valve shaft holder so as to be rotatable integrally therewith.

Effects of the invention

According to the present invention, since the support portion of the pressing member that supports the lower stopper in the circumferential direction is elastically deformable in the circumferential direction, when the movable stopper body provided to the valve shaft holder collides with the fixed stopper body provided to the lower stopper at the time of initialization (base point positioning of the electric valve), for example, the support portion is elastically deformed (flexed) in the circumferential direction, whereby the impact (in the circumferential direction) is alleviated, and therefore, the impact sound (initialization sound) at the time of initialization (base point positioning of the electric valve) and the abrasion between the stopper bodies can be effectively reduced.

After the collision, the lower stopper supported by the support portion can be returned to the original position or posture by the elastic force (repulsive force) of the support portion, and therefore controllability of the flow rate can be ensured.

Further, since the pressing member and the lower stopper are formed as one member, the number of parts and the number of assembling steps can be reduced, and the assembling process can be simplified.

Drawings

Fig. 1 is a longitudinal sectional view showing a first embodiment of an electric valve according to the present invention.

Fig. 2 shows the valve shaft holder shown in fig. 1, where fig. 2 (a) is a perspective view and fig. 2 (B) is a plan view.

Fig. 3 shows the stopper presser shown in fig. 1, where fig. 3 (a) is a perspective view and fig. 3 (B) is a plan view.

Fig. 4 is a perspective view showing an internal structure (a state where a lower stopper and a stopper presser are attached) of the motor-operated valve shown in fig. 1.

Fig. 5 is a side view of fig. 4.

Fig. 6 is a top view of fig. 4.

Fig. 7 is a perspective view showing an internal structure (a state in which a lower stopper and a stopper presser are attached) of a second embodiment of an electric valve according to the present invention.

Fig. 8 is a side view of fig. 7.

Fig. 9 is a top view of fig. 7.

Fig. 10 is a perspective view illustrating the stopper presser shown in fig. 7.

Fig. 11 is a six-side view showing the stopper presser shown in fig. 7.

Fig. 12 is a perspective view showing an internal structure (a state in which a lower stopper and a stopper presser are attached) of a third embodiment of an electric valve according to the present invention.

Fig. 13 is a side view of fig. 12.

Fig. 14 is a top view of fig. 12.

Fig. 15 is a perspective view illustrating the stopper presser shown in fig. 12.

Fig. 16 is a six-side view showing the stopper presser shown in fig. 12.

Fig. 17 is a perspective view showing an internal structure (a state in which a lower stopper and a stopper presser are attached) of a fourth embodiment of an electric valve according to the present invention.

Fig. 18 is a side view of fig. 17.

Fig. 19 is a top view of fig. 17.

Fig. 20 is a perspective view illustrating the lower stopper with the stopper presser shown in fig. 17.

Fig. 21 is a six-side view showing the lower stopper with the stopper presser shown in fig. 17.

Fig. 22 is a perspective view separately showing the stopper presser shown in fig. 17.

Fig. 23 is a six-side view separately showing the stopper presser shown in fig. 17.

Description of the symbols

1 electric valve (first embodiment)

2 electric valve (second embodiment)

3 electric valve (third embodiment)

4 electric valve (fourth embodiment)

10 valve shaft

14 valve core

20 guide bush

21 cylindrical part

23 fixed thread part (external thread part)

24 fixed stop body

25 lower stop

28 screw thread feeding mechanism

29 lower stop mechanism

30 valve shaft holder

31 cylindrical part

32 top part

33 Movable screw part (internal screw part)

34 Movable stop body

35 convex part

40 valve body

40a valve chamber

41 first opening

41a first conduit

42 second opening

42a second conduit

43 insertion hole

44 fitting hole

45 bottom wall

46 valve port

46a valve seat

47 Flange plate

47a annular groove

48 stop presser (pressing component)

48a mounting support

48b mounting and fixing part

48c step part

48d inserting hole

48e fan-shaped part

49d supporting claw (supporting part)

49e bend

49f supporting leg

49g flange part

49h step part

49u upper force applying claw (upper force applying part)

49v lower force applying claw (lower force applying part)

50 stepping motor

51 rotor

52 stator

55 casing

60 compression coil spring

70 fixing part

71 fixed part

72 flange part

O axis

Detailed Description

Hereinafter, embodiments of the present invention will be described with reference to the drawings.

In the drawings, gaps formed between the members, a distance between the members, and the like may be exaggerated for the purpose of facilitating understanding of the invention and facilitating drawing. In the present specification, the description of the positions and directions such as up and down, left and right is based on the directional arrows in fig. 1, and does not refer to the positions and directions in the actual usage state.

[ first embodiment ]

Fig. 1 is a longitudinal sectional view showing a first embodiment of an electric valve according to the present invention.

The motor-operated valve 1 of the illustrated embodiment is incorporated in a refrigeration cycle such as an air conditioner or a refrigerator as a flow rate control valve, and mainly includes: the valve shaft 10 provided with the valve element 14, the guide bush 20, the valve shaft holder 30, the valve body 40, the housing 55, the stepping motor 50 including the rotor 51 and the stator 52, the compression coil spring (urging member) 60, the fixing member 70 serving as the stopper, the screw feed mechanism 28, and the lower stopper mechanism 29.

The valve shaft 10 includes an upper small diameter portion 11, an intermediate large diameter portion 12, and a lower small diameter portion 13 from the upper side, and an inverted conical valve element 14 having a step is integrally formed at the lower end of the lower small diameter portion 13, and the valve element 14 controls the flow rate of the fluid (refrigerant) flowing through the valve port 46.

The guide bush 20 has a cylindrical portion 21 and an extended portion 22, and (the intermediate large diameter portion 12 of) the valve shaft 10 is inserted into the cylindrical portion 21 so as to be relatively movable (slidable) in the direction of the axis O and relatively rotatable about the axis O; the extension portion 22 extends upward from the upper end of the cylindrical portion 21 and has an inner diameter larger than that of the cylindrical portion 21, and the upper end of the intermediate large diameter portion 12 and the lower end of the upper small diameter portion 11 of the valve shaft 10 are inserted into the extension portion 22. A fixed screw portion (male screw portion) 23 is formed on the outer periphery of the cylindrical portion 21 of the guide bush 20, and the fixed screw portion 23 constitutes one side of a screw feed mechanism 28 that moves up and down the valve body 14 of the valve shaft 10 with respect to the valve seat 46a of the valve body 40 by the rotational drive of the rotor 51. The lower portion (portion located below the fixed screw portion 23) of the cylindrical portion 21 has a large diameter, and constitutes a fitting portion 27 that fits into the fitting hole 44 of the valve main body 40. The lower stopper 25 is screwed into the fixed screw portion 23 (below the valve shaft holder 30) and a fixed stopper 24 is integrally provided on the outer periphery of the lower stopper 25 in a projecting manner, and the fixed stopper 24 constitutes one side of a lower stopper mechanism 29 that restricts the downward movement of the rotation of the valve shaft holder 30. In this example, the upper surface 27a of the fitting portion 27 constitutes a stopper portion that restricts downward movement of the lower stopper 25 (in other words, that defines the position of the lower stopper 25 in a seated state described later).

In this example, a stopper presser (pressing member) 48 is attached (externally fitted) to the lower stopper 25 attached to (the fixed threaded portion 23 of) the guide bush 20, and the lower stopper 25 is coupled to (the fixed threaded portion 23 of) the guide bush 20 by the stopper presser 48 so as not to be rotatable (described later in detail).

The valve shaft holder 30 is made of, for example, a resin (preferably, a resin reinforced with SUS or carbon fiber having high wear resistance in consideration of contact with the fixing member 70), and has a cylindrical portion 31 into which the guide bush 20 is inserted and a top portion 32, and the top portion 32 has a through hole 32a through which an upper end portion (in a state of being relatively movable in the direction of the axis O and relatively rotatable about the axis O) of the valve shaft 10 is inserted, the through hole being formed so as to penetrate the top portion 32. A movable screw portion (female screw portion) 33 is formed at a lower portion of an inner periphery of the cylindrical portion 31 of the valve shaft holder 30, the movable screw portion 33 is screwed with the fixed screw portion 23 of the guide bush 20 to constitute the screw feeding mechanism 28, and an upper portion of the inner periphery of the cylindrical portion 31 is in contact with (sliding contact with) an outer periphery of the cylindrical extension portion 22 of the guide bush 20. The other movable stopper 34 constituting the lower stopper mechanism 29 is integrally provided to protrude from the outer peripheral lower end of the cylindrical portion 31.

As is apparent from fig. 1 and 2, two convex portions 35 having a substantially fan shape (here, a fan shape having a central angle of about 90 degrees) in a plan view (when viewed in the direction of the axis O) are integrally formed on the upper surface (the opposing surface opposing the flange portion 72 of the fixing member 70 described later) of the top portion 32 of the valve shaft holder 30. More specifically, the two protrusions 35 are provided so as to protrude upward on the opposite side of the axis O (in other words, at positions symmetrical with respect to the rotation axis O of the valve shaft holder 30) around the insertion hole 32a on the upper surface of the top portion 32 (in other words, around the rotation axis O of the valve shaft holder 30), and have a shape in which a notch (a notch 36 having a substantially fan shape in plan view (a fan shape having a center angle of about 90 degrees here)) is formed between the two protrusions 35 (in this example, an upper portion of one end surface 34a in the circumferential direction of the movable stopper 34, that is, a portion including the same position as the one end surface 34a in the circumferential direction of the movable stopper 34).

Since the contact area of the valve shaft holder 30 with respect to the fixed member 70 is reduced by the convex portion 35, for example, contact resistance (rotational sliding resistance) when the valve shaft holder 30 abuts against the fixed member 70 is reduced.

Further, for example, when the valve shaft holder 30 is made of a molded product such as resin, the contact resistance (rotational sliding resistance) can be further reduced by providing the notch 36 at a position where the weld line or parting line formed during molding is aligned with the position of the notch 36, that is, at a position where the weld line or parting line is formed during molding, and the flatness of the sliding surface of the valve shaft holder 30 can be increased, thereby further suppressing the shaft misalignment of the valve shaft 10.

For example, when a gate for injecting a resin for molding is provided on the valve shaft holder 30 on the side opposite to the movable stopper 34, the notch 36 is provided above the movable stopper 34 (more specifically, above the circumferential end surface 34a of the movable stopper 34) as described above, so that the projection 35 of the valve shaft holder 30 does not have a weld line or parting line formed during molding, and therefore the contact resistance (rotational sliding resistance) can be further reduced, the flatness of the sliding surface of the valve shaft holder 30 can be increased, and the axial displacement of the valve shaft 10 can be further suppressed.

Further, by arranging the projections 35 symmetrically with respect to the rotation axis O of the valve shaft holder 30 on the upper surface of the top portion 32 of the valve shaft holder 30, the axial displacement of the valve shaft 10 can be more effectively suppressed, and by arranging the projections 35 in a distributed manner at a plurality of positions around the rotation axis O of the valve shaft holder 30, the contact area of (the projections 35 of) the valve shaft holder 30 with respect to the fixing member 70 can be further reduced.

The shape, number, position, and the like of the projections 35 provided on the upper surface of the top portion 32 of the valve shaft holder 30 are not limited to the illustrated example, and the projections 35 may be omitted.

Further, a cylindrical compression coil spring (urging member) 60 is compression-mounted between a stepped surface (stepped portion) 15 formed between the upper small diameter portion 11 and the intermediate large diameter portion 12 of the valve shaft 10 and a lower surface of the top portion 32 of the valve shaft holder 30 via a disk-shaped pressing plate (washer) 61 disposed on a lower surface side of the top portion 32 of the valve shaft holder 30 so as to be fitted over the upper small diameter portion 11 of the valve shaft 10, and the compression coil spring 60 urges the valve shaft 10 and the valve shaft holder 30 in a direction in which the valve shaft 10 and the valve shaft holder 30 are separated in the vertical direction (axis O direction), in other words, the valve shaft 10 (valve body 14) downward at all times (valve closing direction).

The valve main body 40 is formed of a cylindrical body made of metal such as brass or SUS. The valve body 40 includes a valve chamber 40a into and from which a fluid is introduced and discharged, a first pipe 41a is connected and fixed by brazing or the like to a first opening 41 provided in a side portion of the valve chamber 40a in a lateral direction, an insertion hole 43 and a fitting hole 44 are formed in a top portion of the valve chamber 40a, the insertion hole 43 is inserted with (the middle large diameter portion 12 of) the valve shaft 10 in a state of being relatively movable (slidable) in the axis O direction and relatively rotatable about the axis O, a lower portion (a fitting portion 27) of the guide bush 20 is fitted and fixed to the fitting hole 44, and a second pipe 42a is connected and fixed by brazing or the like to a second opening 42 provided in a lower portion of the valve chamber 40a in a longitudinal direction. Further, a stepped valve port 46 is formed in the bottom wall 45 between the valve chamber 40a and the second opening 42, and the valve port 46 has a valve seat 46a that is in contact with and separated from (close to and separated from) the valve body 14.

An annular flange-shaped plate 47 is fixed to the outer periphery of the upper end portion of the valve body 40 (outside the guide bush 20 of the valve body 40) by caulking, brazing, or the like, and the lower end portion of the topped cylindrical housing 55 is sealingly joined to a step portion provided on the outer periphery of the flange-shaped plate 47 by butt welding or the like.

In this example, a stopper presser (pressing member) 48 formed of a substantially disc-shaped member with a step is disposed and fixed on the upper surface (the surface on the housing 55 side) of the flange-shaped plate 47, and the stopper presser 48 engages with the lower stopper 25 to prevent the relative rotation of the lower stopper 25 with respect to the guide bush 20.

The stopper presser 48 is made of a metal member such as brass or SUS by press working or the like, and is engaged with the lower stopper 25 in a state of being separated (floated) from (the upper surface of) the valve main body 40 and (the upper surface of) the flange-shaped plate 47 provided to the valve main body 40, and an outer peripheral portion (a portion located outside the annular stepped portion 48 c) of the stopper presser 48 is brought into contact with (the upper surface of) the flange-shaped plate 47, and is joined and fixed by welding, adhesion, or the like.

Specifically, as is apparent from fig. 1 and 3 to 6, the stopper presser 48 is attached (externally attached) to the lower stopper 25, and includes: a disc-shaped mounting support portion 48a disposed apart from (the upper surface of) the valve main body 40; and an annular attachment fixing portion 48b, the attachment fixing portion 48b being provided on the outer periphery of the attachment supporting portion 48a via a stepped portion 48c, and the attachment fixing portion 48b being attached and fixed to a flange-like plate 47 provided on the outer periphery of the valve main body 40.

An insertion hole 48d having a size through which the lower stopper 25 is inserted is formed in the mounting support portion 48a, and three support claws 49a, 49b, and 49c having a rectangular shape in side view sandwiching (the outer surface of) the lower stopper 25 are provided so as to stand adjacent to the insertion hole 48d (in other words, at the outer peripheral portion of the insertion hole 48 d). The three support claws 49a, 49b, and 49c stand so as to face the outer surface of the lower stopper 25, and among them, the relatively small support claw 49c (having a relatively small width and height in the circumferential direction) is disposed adjacent to the fan-shaped portion 48e of the insertion hole 48d into which the fixed stopper 24 is inserted, which is fan-shaped in a plan view (specifically, adjacent to the side surface on the valve opening direction side of the fixed stopper 24 inserted into the fan-shaped portion 48 e). Further, in an outer peripheral portion of the fan-shaped portion 48e (specifically, a portion adjacent to a side surface on the valve closing direction side opposite to the side surface on the valve opening direction side of the fixed stopper 24 inserted into the fan-shaped portion 48 e), a support claw (support portion) 49d having a rectangular shape in a circumferential direction is provided so as to face an outer surface (side surface on the valve closing direction side) of the fixed stopper 24, and the support claw 49d sandwiches both side surfaces of the fixed stopper 24 in the circumferential direction together with the support claw 49 c.

In this example, a bent portion (also referred to as an R-shaped portion) 49e is provided at a lower end portion (root portion) of the support claw 49d, the bent portion 49e is formed to have a predetermined radius as viewed in a radial direction (lateral direction), and the support claw 49d is elastically deformable in a circumferential direction.

For example, at the time of initialization (base point positioning of the motor-operated valve 1), when the movable stopper 34 provided on the valve shaft holder 30 collides with the fixed stopper 24 provided on the lower stopper 25, the support claws 49d elastically deform (flex) in the circumferential direction, so that the impact (in the circumferential direction) is alleviated, and after the collision, the (fixed stopper 24 of the) lower stopper 25 supported by the support claws 49d is pushed back to the original position or posture by the elastic force (repulsive force) of the support claws 49 d.

Further, since the movable stopper 34 and the fixed stopper 24 are made of resin reinforced with SUS, carbon fiber, or the like, for example, abrasion due to impact can be suppressed, and displacement of the base point at the time of initialization can be prevented.

Here, the lower stopper 25 and the stopper presser 48 are configured as separate members, but the lower stopper 25 and the stopper presser 48 may be configured integrally (as one member) by joining (fixedly attaching) the support claws 49a, 49b, 49c, and 49d to the lower stopper 25 by welding, bonding, caulking, or the like, for example.

On the other hand, the attachment fixing portion 48b of the stopper presser 48 is joined and fixed to a substantially central portion (joint portion K) of (the upper surface of) the flange-like plate 47 by welding, adhesion, or the like, whereby the lower stopper 25 and (the fixed threaded portion 23 of) the guide bush 20 are coupled so as not to be relatively rotatable.

When the stopper presser 48 is joined and fixed to the flange-like plate 47 by welding, these members are preferably made of a homogeneous material (or a material having a melting point equivalent thereto), and in this example, brass or SUS may be used, for example.

An annular recessed groove 47a is provided on the upper surface of the flange-shaped plate 47 (specifically, on the inner side of the portion in contact with the attachment fixing portion 48b), and the annular recessed groove 47a prevents the flow of the brazing material when the flange-shaped plate 47 is brazed to the valve body 40.

A rotor 51 is rotatably disposed inside the housing 55 and outside the guide bush 20 and the valve shaft holder 30, and a stator 52 including a yoke 52a, a bobbin 52b, a stator coil 52c, a resin mold cover 52d, and the like is disposed outside the housing 55 to rotationally drive the rotor 51. A plurality of lead terminals 52e are connected to the stator coil 52c, a plurality of lead wires 52g are connected to the lead terminals 52e via a base plate 52f, and the rotor 51 disposed in the housing 55 is rotated about the axis O by energization and excitation of the stator coil 52 c.

The rotor 51 disposed in the housing 55 is engaged with and supported by the valve shaft holder 30, and the valve shaft holder 30 rotates together with (integrally with) the rotor 51.

More specifically, the rotor 51 has a double-tube structure including an inner tube 51a, an outer tube 51b, and a connecting portion 51c, the connecting portion 51c connects the inner tube 51a and the outer tube 51b at a predetermined angular position about the axis O, and a vertical groove 51d extending in the axis O direction (vertical direction) is formed in the inner circumference of the inner tube 51a (for example, at an angular interval of 120 degrees about the axis O).

On the other hand, as is apparent from fig. 2, a tapered surface portion 30c formed of a conical surface is provided at the upper end of the outer periphery (upper half portion) of the valve shaft holder 30, a protrusion 30a extending in the vertical direction (for example, at an angular interval of 120 degrees around the axis O) is provided so as to protrude below the tapered surface portion 30c, and upward engaging surfaces 30b for supporting the rotor 51 are formed on both lower sides of the protrusion 30 a.

As described above, the vertical groove 51d of the inner cylinder 51a of the rotor 51 engages with the protrusion 30a of the valve shaft holder 30, and the lower surface of the inner cylinder 51a of the rotor 51 abuts against the locking surface 30b of the valve shaft holder 30, whereby the rotor 51 is supported and fixed to the outer periphery of the valve shaft holder 30 in a state of being aligned with the valve shaft holder 30, and the valve shaft holder 30 rotates together with the rotor 51 while supporting the rotor 51 in the housing 55.

In this example, the rotor 51 is engaged with and supported by the valve shaft holder 30 such that the upper surface of the valve shaft holder 30 is flush with the upper surface of the inner cylinder 51a of the rotor 51, or the upper surface of the valve shaft holder 30 is positioned slightly above the upper surface of the inner cylinder 51a of the rotor 51.

In order to prevent the relative movement between the valve shaft holder 30 and the rotor 51 in the vertical direction (in other words, to press the rotor 51 downward relative to the valve shaft holder 30 to be locked in a retaining manner) and to connect the valve shaft 10 and the valve shaft holder 30, a fixing member 70 is disposed above the rotor 51 and the valve shaft holder 30, and the fixing member 70 is fitted and fixed to (the upper small diameter portion 11 of) the upper end portion of the valve shaft 10.

The fixing member 70 is manufactured by press working, cutting, or the like using a metal member such as brass, SUS, or the like, and includes: a stepped cylindrical fixing portion 71 composed of a small-diameter upper portion 71a and a large-diameter lower portion 71b fitted around (the upper small-diameter portion 11 of) the valve shaft 10 and fixed to (the upper small-diameter portion 11 of) the valve shaft 10 by press fitting, welding, adhesion, or the like; and a disk-shaped flange portion 72 extending outward from the lower end portion of (the large-diameter lower portion 71b of) the fixing portion 71 to the vicinity of the inner cylinder 51a of the rotor 51.

The lower surface of the flange portion 72 is opposed to the upper surface of the valve shaft holder 30 and the upper surface of (the inner cylinder 51a of) the rotor 51, and is abutted against (the upper surface of) the projection 35 provided on the upper surface of the valve shaft holder 30 and the upper surface of (the inner cylinder 51a of) the rotor 51.

As described above, the rotor 51 is clamped between the valve shaft holder 30 biased upward by the biasing force of the compression coil spring 60 and (the outer peripheral portion of the flange portion 72 of) the fixing member 70 and is locked so as to be prevented from coming off.

Further, a return spring 75 formed of a coil spring for biasing the valve shaft holder 30 toward the guide bush 20 is externally attached to the fixed member 70 (the large diameter lower portion 71b of the fixed portion 71) fixed to the upper end portion of the valve shaft 10, so that the valve shaft holder 30 is prevented from excessively moving upward relative to the guide bush 20 and the fixed screw portion 23 of the guide bush 20 and the movable screw portion 33 of the valve shaft holder 30 are not screwed together when operating.

In the motor-operated valve 1, for example, in order to prevent the valve element 14 from biting into the valve seat 46a and to ensure controllability in a low flow rate region, a gap of a predetermined size is formed between the valve element 14 and the valve seat 46a when the valve element 14 is located at the lowermost position (origin position).

To describe the assembly process of the motor-operated valve 1, in particular, the process of positioning the origin position (the lowermost position) of the valve element 14 in detail, first, the valve shaft 10, the guide bush 20, the lower stopper 25, the stopper presser 48, the compression coil spring 60, the valve shaft holder 30, the rotor 51, the valve body 40, the flange-like plate 47, and the like are assembled. For example, the flange-shaped plate 47 is brazed to the valve main body 40, the guide bush 20 is press-fitted and fixed to the valve main body 40, then the lower stopper 25 is screwed into (the fixing screw portion 23 of) the guide bush 20, and the stopper presser 48 is attached to the lower stopper 25 and placed on the valve main body 40 and the flange-shaped plate 47, or the like, to assemble them. At this time, (the attachment fixing portion 48b of) the stopper presser 48 is not fixed to the flange-like plate 47 of the valve body 40, and the lower stopper 25 is first screwed to the guide bush 20 so as to be relatively rotatable. In this stage, the lower stopper 25 may be disposed so as to abut against the stopper 27a of the guide bush 20, or may be disposed at a distance from the stopper 27 a. Next, the valve shaft holder 30, the rotor 51, and the valve shaft 10 are lowered while being rotated by the screw feeding mechanism 28 including the fixed screw portion 23 of the guide bush 20 and the movable screw portion 33 of the valve shaft holder 30, until the following states are reached: the valve body 14 provided at the lower end portion of the valve shaft 10 abuts (is seated on) the valve seat 46a, and the compression coil spring 60 is slightly compressed, so that the movable stopper body 34 of the valve shaft holder 30 abuts the fixed stopper body 24 of the lower stopper 25, and (the lower surface of) the lower stopper 25 abuts the stopper portion 27a of the guide bush 20. Then, in a state where the valve shaft holder 30 is disposed at the lowermost position in this way, the fixing member 70 is fitted and fixed to the upper end portion of the valve shaft 10 (seated state) by press fitting, welding, adhesion, or the like.

Next, after the lower stopper 25 and the stopper presser 48 are rotated together by a predetermined rotation angle in the valve opening direction (e.g., counterclockwise in plan view) with respect to the guide bush 20 from the seated state, the (attachment fixing portion 48b of the stopper presser 48) is fixedly joined to the flange-like plate 47 of the valve body 40 by welding, adhesion, or the like, and the (fixing screw portion 23 of the) lower stopper 25 and the (guide bush 20) are fixedly joined to each other so as not to be rotatable (see fig. 4 ·

Fig. 6). Accordingly, since the position of the fixed stopper 24 of the lower stopper 25 with respect to the guide bush 20 changes, a gap of a predetermined size is formed between the valve element 14 and the valve seat 46a even when the movable stopper 34 of the valve shaft holder 30 abuts against the fixed stopper 24 of the lower stopper 25 and the valve shaft holder 30 is located at the lowermost position.

In the motor-operated valve 1 having this configuration, when the rotor 51 is rotated by energization and excitation of (the stator coil 52c of) the stator 52, the valve shaft holder 30 and the valve shaft 10 rotate integrally with the rotor 51. At this time, the screw feed mechanism 28 including the fixed screw portion 23 of the guide bush 20 and the movable screw portion 33 of the valve shaft holder 30 moves up and down along with the valve element 14, and thereby the clearance (lift amount, valve opening degree) between the valve element 14 and the valve seat 46a increases and decreases, and the flow rate of the fluid such as the refrigerant is adjusted. Further, even when the movable stopper 34 of the valve shaft holder 30 abuts against the fixed stopper 24 of the lower stopper 25 fixed to the guide bush 20 and the valve element 14 is located at the lowermost position, a gap is formed between the valve element 14 and the valve seat 46a, and therefore a predetermined amount of flow rate is secured.

As described above, in the motor-operated valve 1 of the present embodiment, since the support claws 49d that support the lower stopper 25 in the circumferential direction in the stopper presser 48 are elastically deformable in the circumferential direction, when the movable stopper 34 provided in the valve shaft holder 30 collides with the fixed stopper 24 provided in the lower stopper 25 at the time of initialization (base point positioning of the motor-operated valve), for example, the support claws 49d are elastically deformed (flexed) in the circumferential direction, whereby the impact (in the circumferential direction) is alleviated, and therefore, the impact sound (initialization sound) at the time of initialization (base point positioning of the motor-operated valve) and the abrasion between the stopper bodies can be effectively reduced.

After the collision, the (fixed stopper 24 of the) lower stopper 25 supported by the supporting claws 49d can be returned to the original position or posture by the elastic force (repulsive force) of the supporting claws 49d, and therefore controllability of the flow rate can be ensured.

[ second embodiment ]

Fig. 7 to 11 show a motor-operated valve according to a second embodiment of the present invention.

The motor-operated valve 2 according to the second embodiment is different from the motor-operated valve 1 according to the first embodiment mainly in the configuration of the stopper presser 48, and the other configurations are substantially the same. Therefore, common reference numerals are assigned to portions corresponding to the respective portions of the first embodiment, and redundant description is omitted, and the following description focuses on differences.

In addition to the structure of the first embodiment, the motor-operated valve 2 of the present embodiment is provided with an upper biasing claw (upper biasing portion) 49u protruding from the stopper presser 48, and the upper biasing claw 49u biases the lower stopper 25 upward (upward in the vertical direction) with respect to the guide bush 20.

In this example, the upper urging claws 49u are provided in two positions (i.e., at equal angular intervals in the circumferential direction) which are symmetrical with respect to the axis O between the supporting claws 49a and 49c and between the supporting claws 49b and 49c, so as to be adjacent to the insertion hole 48d formed in the outer supporting portion 48a of the stopper presser 48 (in other words, in the outer peripheral portion of the insertion hole 48 d). The upper end of each upper urging claw 49u abuts (elastically) the lower surface of the lower stopper 25, and the lower stopper 25 is pushed up against the guide bush 20 by the elastic force of each upper urging claw 49 u.

As described above, in the motor-operated valve 2 of the present embodiment, in addition to the same operational effects as those of the motor-operated valve 1 of the first embodiment, the upper urging claws 49u provided in the stopper presser 48 urge the lower stopper 25 upward relative to the guide bush 20, so that the backlash between (the fixed threaded portion (male threaded portion) 23 of) the guide bush 20 and (the female threaded portion of) the lower stopper 25 can be eliminated, and the controllability of the flow rate can be improved.

[ third embodiment ]

Fig. 12 to 16 show a motor-operated valve according to a third embodiment of the present invention.

The motor-operated valve 3 according to the third embodiment is different from the motor-operated valve 1 according to the first embodiment mainly in the configuration of the stopper presser 48, and the other configurations are substantially the same. Therefore, common reference numerals are assigned to portions corresponding to the respective portions of the first embodiment, and redundant description is omitted, and the following description focuses on differences.

In addition to the structure of the first embodiment, the motor-operated valve 3 of the present embodiment is provided with a lower biasing claw (lower biasing portion) 49v protruding from the stopper presser 48, and the lower biasing claw 49v biases the lower stopper 25 downward (downward in the vertical direction) with respect to the guide bush 20.

In this example, two lower urging claws 49v are provided adjacent to the insertion hole 48d formed in the outer support portion 48a of the stopper presser 48 (in other words, in the outer peripheral portion of the insertion hole 48 d), at positions symmetrical with respect to the axis O (that is, at equal angular intervals in the circumferential direction) between the support claws 49a and 49c and between the support claws 49b and 49 c. Each lower urging claw 49v has a rectangular shape when viewed from the side surface (radial direction) and an inverted L-shape when viewed in the circumferential direction, each lower urging claw 49v linearly extends from below to above (along the axis O) on the outer side of the lower stopper 25, the upper end portion of each lower urging claw 49v is bent inward to abut against the upper surface of the lower stopper 25 (elastically), and the lower stopper 25 is pressed down against the guide bush 20 by the elastic force of each lower urging claw 49 v.

As described above, in the motor-operated valve 3 of the present embodiment, in addition to the same operational effects as those of the motor-operated valve 1 of the first embodiment, since the lower stopper 25 is biased downward with respect to the guide bush 20 by the lower biasing claw 49v provided in the stopper presser 48, it is possible to eliminate the thread gap between (the fixed thread portion (male thread portion) 23 of) the guide bush 20 and (the female thread portion of) the lower stopper 25, and to improve the controllability of the flow rate.

[ fourth embodiment ]

Fig. 17 to 23 show a fourth embodiment of an electrically operated valve according to the present invention.

The motor-operated valve 4 according to the fourth embodiment is different from the motor-operated valve 1 according to the first embodiment mainly in the configuration of the stopper presser 48 and the lower stopper 25, and the other configurations are substantially the same. Therefore, common reference numerals are assigned to portions corresponding to the respective portions of the first embodiment, and redundant description is omitted, and the following description focuses on differences.

In the motor-operated valve 4 of the present embodiment, the lower stopper 25 and the stopper presser 48 are integrally molded by, for example, insert molding.

Specifically, the attachment support portion 48a of the stopper presser 48 of the first embodiment is omitted, the support leg 49f with the stepped portion 49h is disposed so as to extend from (the inner periphery of) the attachment fixing portion 48b of the stopper presser 48 toward the substantially normal direction of the lower stopper 25, the support claw (support portion) 49d having substantially the same width as the support leg 49f is provided upright (via the bent portion 49e) at the tip (inner end) of the support leg 49f, and the upper portion of the support claw 49d is embedded in the lower surface of the lower stopper 25, whereby the lower stopper 25 and the stopper presser 48 are integrated (constituted as one member). A flange portion 49g having a slightly wider width is formed at an upper end portion of the support claw 49d embedded in the lower stopper 25.

In this example, three support legs 49f and three support claws 49d are provided at equal angular intervals around the axis O (circumferential direction).

In other words, in the present embodiment, the support claw 49d with the bent portion 49e embedded in the lower stopper 25 and supporting the lower stopper 25 in the circumferential direction is fixed to the flange-like plate 47 of the valve main body 40 via the support leg 49f (having substantially the same width as the support claw 49d) extending from the lower end portion of the support claw 49d in the substantially normal direction (of the lower stopper 25).

As described above, in the motor-operated valve 4 of the present embodiment, the lower stopper 25 and the stopper presser 48 are formed as one component, and thus the number of components and the number of assembly steps can be reduced, and the assembly process can be simplified, in addition to obtaining the same operational effects as the motor-operated valve 1 of the first embodiment.

In addition, the motor-operated valve 4 of the present embodiment has the following advantages: by appropriately setting the elastic force (spring force) of (the support leg 49f of, etc.) the stopper presser 48, the dimensions of the respective components, and the like, the lower stopper 25 can be biased upward (upward in the lifting direction) or downward (downward in the lifting direction) with respect to the guide bush 20 by the stopper presser 48, and therefore, as in the second and third embodiments described above, the thread clearance between (the fixed thread portion (male thread portion) 23 of) the guide bush 20 and (the female thread portion of) the lower stopper 25 can be eliminated, and the controllability of the flow rate can be improved.

In the above-described embodiment, the description has been made with respect to the valve-opening-less type electric valve in which a predetermined gap is formed between the valve element 14 and the valve seat 46a (that is, the valve element 14 is not seated on the valve seat 46a) when the valve element 14 is at the lowermost position (normally, in the fully closed state), but for example, in the case of the electric valve in which the valve element is seated on the valve seat (for example, see japanese patent application laid-open publication No. 2011-208716 and the like), the same operational effects as described above can be obtained even when the lower stopper and (the fixed threaded portion of) the guide bush are coupled so as not to be relatively rotatable using the same stopper presser (presser member), and it is needless to say that detailed description is not necessary.

Claims (10)

1. An electrically operated valve having:

a valve shaft provided with a valve core;

a guide bush in which the valve shaft is inserted so as to be relatively movable in the axial direction and relatively rotatable;

a valve main body having a valve port with a valve seat, and to which the guide bush is attached and fixed;

a valve shaft holder coupled to the valve shaft;

a motor having a rotor and a stator for rotating the valve shaft holder relative to the guide bush;

a screw feed mechanism for raising and lowering the valve body relative to the valve seat based on rotational driving of the rotor, the screw feed mechanism being provided between the guide bush and the valve shaft holder;

a lower stopper mechanism for restricting a rotational downward movement of the valve shaft holder, the lower stopper mechanism having a movable stopper body provided to the valve shaft holder and a fixed stopper body provided to a lower stopper attached to the guide bush; and

a pressing member that prevents relative movement of the lower stopper with respect to the guide bush,

a support portion that supports the lower stopper in the circumferential direction and is elastically deformable in the circumferential direction is provided upright on the pressing member,

the lower stopper is biased upward or downward with respect to the guide bush by the pressing member.

2. Electrically operated valve according to claim 1,

the support portion is provided with a curved portion formed to have a predetermined radius when viewed in a radial direction.

3. Electrically operated valve according to claim 1 or 2,

the support portion supports the lower stopper in a circumferential direction so as to be opposed to a side surface of the lower stopper on a valve closing direction side.

4. Electrically operated valve according to claim 1 or 2,

the support portion is embedded in the lower stopper and supports the lower stopper in the circumferential direction.

5. Electrically operated valve according to claim 1 or 2,

a support leg is disposed on the support portion, and the support leg extends from the support portion in the normal direction.

6. Electrically operated valve according to claim 1 or 2,

the pressing member and the lower stopper are formed as one member.

7. Electrically operated valve according to claim 6,

the pressing member and the lower stopper are integrated by welding, bonding, caulking, or insert molding.

8. Electrically operated valve according to claim 1 or 2,

the lower stopper is biased upward with respect to the guide bush by the pressing member,

the pressing member is provided with an upper urging portion that abuts against a lower surface of the lower stopper to push the lower stopper upward.

9. Electrically operated valve according to claim 1 or 2,

the lower stopper is biased downward with respect to the guide bush by the pressing member,

the pressing member is provided with a lower urging portion that abuts against an upper surface of the lower stopper to press down the lower stopper.

10. Electrically operated valve according to claim 1 or 2,

the stator is disposed outside a cylindrical housing joined to the valve body, and the rotor is disposed inside the housing and connected to the valve shaft holder so as to be integrally rotatable.

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