JP6767350B2 - Solenoid valve stator and solenoid valve - Google Patents

Description

The present invention relates to a stator for an electric valve used in a refrigeration cycle system such as an air conditioner, and an electric valve provided with the stator.

Conventionally, as an electric valve of this type, there is one that operates a valve member in a valve body by rotation of a magnet rotor of a motor portion such as a stepping motor. In such an electric valve, it is necessary to seal the fluid flow path, and the magnet rotor of the motor portion is housed in a cylindrical can that forms a sealed structure together with the valve body. The stator of the motor unit is arranged on the outer circumference of the can. For example, Japanese Patent Application Laid-Open No. 2006-20479 (Patent Document 1) and Japanese Patent Application Laid-Open No. 2012-124987 (Patent Document 2) disclose similar motorized valves.

Japanese Unexamined Patent Publication No. 2006-20479 Japanese Unexamined Patent Publication No. 2012-124987

In recent years, space saving of outdoor units of air conditioners has been actively promoted, and improvement of energy saving is also regarded as important, and the shape of piping inside the outdoor units has become diversified and complicated. Since the space inside the outdoor unit that is complicatedly piped in this way is small, the shape of the valve device is restricted. In Patent Document 1, a bracket for fixing the stator is provided on the upper side of the stator, and the bracket and the can protrude upward from the stator. Therefore, there is room for improvement in terms of space saving. On the other hand, in Patent Document 2, the bracket is provided on the lower side of the stator, and the length of the can protruding upward can be suppressed. However, in Patent Document 2, since the bracket and the stator are fixed by welding, there is a problem that the fixing is uncertain and the fixed portion is easily loosened.

INDUSTRIAL APPLICABILITY The present invention can improve the attachment structure of an elastic member for fixing to a cylindrical portion such as a can of a valve device in a stator for an electric valve that constitutes a motor portion together with a magnet rotor of the valve device, and can firmly fix the elastic member. An object of the present invention is to provide a stator for an electric valve and an electric valve.

The electric valve stator according to claim 1 is an electric valve stator that is attached to a valve device that is operated by driving a motor unit and constitutes the motor unit together with a magnet rotor on the valve device side. together with the insertion hole fitting, it engaged with the valve device comprising a elastic member for fixing the said valve device and a stator for the motor-operated valve, the outer periphery of the opening of the insertion hole, the fitted A fixed block having a wall surface orthogonal to the radial direction of the hole is formed, and the elastic member has an elastic piece that engages with the valve device and a base portion that is fixed to the fixed block. The base portion is fixed to the fixing block in a state where a part of the base portion is in contact with the wall surface from the axis side of the fitting / insertion hole.

The motor valve stator according to claim 2 is the motor valve stator according to claim 1, wherein the base portion of the elastic member is two side plates extending in parallel with the axis and arranged in the radial direction. The side plate on the inner side in the radial direction is brought into contact with the wall surface, and the base portion sandwiches the fixing block between the two side plates.

The electric valve stator according to claim 3 is the electric valve stator according to claim 1, wherein the base portion of the elastic member is a side plate extending in parallel with the axis, and the side plate and the elastic piece. The fixed block has a wall surface on the connecting plate side, and the connecting plate is bent toward the fixed block side. A locking claw having an end portion on the opposite side to the elastic piece is formed, the end portion of the front locking claw is brought into contact with the wall surface, and the base portion sandwiches the fixing block. To do.

The motor valve stator according to claim 4 is the motor valve stator according to claim 1, wherein the elastic piece of the elastic member is bent parallel to the axis around the axis of the fitting hole. It is characterized in that it extends in a direction intersecting the axis through the portion.

The electric valve stator according to claim 5 is the electric valve stator according to any one of claims 1 to 4, and the elastic piece that engages with the valve device of the elastic member is on the axis side. The first engaging portion of the elastic piece is engaged with the second engaging portion formed on the outer periphery of the valve device. It is characterized by being done.

The motorized valve stator according to claim 6 is the motorized valve stator according to claim 5, wherein the first engaging portion of the elastic piece projects toward the axis line, and the second engaging portion on the valve device side. It is characterized by being a convex portion that engages with a concave portion as an engaging portion.

The motor-operated valve according to claim 7 is characterized in that the valve device is provided with the stator for electric valve according to any one of claims 1 to 6.

According to the stators for electric valves of claims 1 to 6, the base portion of the elastic member is fixed to the fixing block on the outer periphery of the opening of the fitting hole, and a part of the base portion is radially from the axial side of the fitting hole. Since the valve device is in contact with the orthogonal wall surfaces, the wall surface can receive the radial load received by the elastic piece when the valve device is fitted into the fitting hole, and the elastic member and the stator can be fixed. Loosening can be prevented and this elastic member can be firmly fixed.

According to the motorized valve of claim 7, the same effect as that of claims 1 to 6 can be obtained.

It is a partial cross-sectional side view of the electric valve of the 1st Embodiment of this invention. FIG. 1 is a cross-sectional view taken along the line BB of FIG. It is a figure which shows the bracket and the fixing block in 1st Embodiment. It is a vertical cross-sectional view and bottom view of the stator for motor-operated valve of 1st Embodiment. It is a vertical cross-sectional view and bottom view of the stator for electric valve of 2nd Embodiment. It is a vertical cross-sectional view and bottom view of the stator for the motor-operated valve of the third embodiment. It is a figure explaining the exposed part of the joint iron with respect to a bobbin in an embodiment. It is a figure which shows the refrigeration cycle system of an embodiment.

Next, the stator for the motor-operated valve and the embodiment of the motor-operated valve of the present invention will be described with reference to the drawings. 1 is a partial cross-sectional side view of the motor-operated valve of the embodiment, FIG. 2 is a cross-sectional view taken along the line BB of FIG. 1, FIG. 3 is a view showing a bracket and a fixing block in the first embodiment, and FIG. 4 is a first. It is a vertical sectional view and a bottom view of the stator for electric valve of an embodiment, and FIG. 4A is a sectional view taken along the line AA of FIG. 4B. The concept of "up and down" in the following description corresponds to the top and bottom in the drawing of FIG.

As shown in FIGS. 1 and 4, this solenoid valve is a cylindrical can composed of a bracket 1 as an "elastic member", a stepping motor 20 as an "motor portion", a valve body 30, and a non-magnetic material. It has 40 and. The stepping motor 20 is composed of a stator 21 as an "motor valve stator" described later, which is attached to the outer periphery of the can 40, and a magnet rotor 22 rotatably arranged inside the can 40. A predetermined gap is provided between the outer peripheral surface of the magnet rotor 22 and the inner peripheral surface of the can 40.

The valve body 30 has a housing 310 made of stainless steel or the like, and a valve member or the like is built in the housing 310. Then, the valve body 30 is operated by driving the stepping motor 20 (rotation of the magnet rotor 22), and the flow rate of the fluid flowing from the first joint pipe 31 to the second joint pipe 32, or the flow rate of the fluid flowing from the second joint pipe 32 to the first joint. The flow rate of the fluid flowing to the pipe 31 is controlled.

A can 40 is airtightly assembled to the upper end of the housing 310 of the valve body 30 by welding or the like, whereby the valve body 30 and the can 40 form a “valve device”.

The stator 21 is configured by winding coils 21b and 21b around a resin bobbin 21a so that a pair of coil portions are laminated in the axis L direction. Further, a joint iron (yoke) 21c having magnetic pole teeth 21d is integrally assembled to the bobbin 21a by molding. Further, the stator 21 has a cylindrical fitting hole 21H centered on the axis L in the center, and the magnetic pole teeth 21d of the joint iron 21c are arranged on a part of the inner peripheral surface of the fitting insertion hole 21H. ing. The magnetic pole teeth 21d are arranged to face the outer peripheral surface of the can 40.

With the above configuration, in the stepping motor 20, the coil 21b generates a magnetic field line by applying the pulse output to the coil 21b. As a result, the magnetic poles (N, S poles) change alternately in the magnetic pole teeth 21d, a magnetic attraction force and a magnetic repulsion force are generated with respect to the magnet rotor 22, and the magnet rotor 22 rotates. As a result, the valve member inside the valve body 30 operates and the opening degree of the valve opening is variably controlled, so that the first joint pipe 31 to the second joint pipe 32 or from the second joint pipe 32 as described above. The flow rate of the refrigerant flowing to the first joint pipe 31 is controlled.

The bottom of the bobbin 21a of the stator 21 on the valve body 30 side has a hakama portion 21K whose diameter is expanded from the opening 21H1 of the fitting hole 21H to the valve body 30 side. Further, the can 40 is composed of a small diameter portion 40A facing the outer circumference of the magnet rotor 22 with the axis L as the central axis, and a large diameter portion 40B whose diameter is expanded from the small diameter portion 40A to the valve body 30 side. Then, the small diameter portion 40A of the can 40 is fitted into the fitting insertion hole 21H of the stator 21, and the large diameter portion 40B of the can 40 is located on the valve body 30 side of the opening 21H1, and the hakama portion of the stator 21 is located. A part of it is housed in 21K. As a result, the stator 21 is attached to the valve device. A bracket 1 as an "elastic member" is attached to the bottom of the stator 21.

As shown in FIG. 3, the bracket 1 is formed by pressing a metal plate or the like, and extends from a side portion of the base portion 11 integrally with the base portion 11 having a groove structure composed of three plate-shaped portions. It has an elastic piece 12 and the like. The base portion 11 is composed of a side plate 11a, a short side plate 11b facing the side plate 11a, and a connecting plate 11c connecting the side plates 11a and 11b. Further, the side plates 11a and 11b each have claws 11a and 11b1 cut out inside the base 11. The claws 11a1 and 11b1 are bent in a direction intersecting the axis L, and are arranged so that the edge line of the tip end portion thereof is parallel to each other in the direction intersecting the axis L. The elastic piece 12 is pressed by bending a convex portion 12a as a "first engaging portion" formed integrally with the elastic piece 12 and a part of the elastic piece 12 on the opposite side to the base portion 11. It has a portion 12b, a fulcrum portion 12c, and a protrusion 12d formed at one location on the side side of the elastic piece 12.

A rectangular parallelepiped fixed block 21B is formed by a bobbin 21a in a part of the hakama portion 21K of the stator 21, and the bracket 1 is attached to the fixed block 21B. That is, as shown in FIG. 3, a slit 21a1 is formed on the outside of the fixed block 21B in the bobbin 21a. Then, when the bracket 1 is attached, the side plate 11a and the claw 11a1 of the bracket 1 are fitted into the slit 21a1, the side plate 11b is fitted inside the fixing block 21B, and the claw 11a1 of the side plate 11a is fitted to the end of the fixing block 21B. Lock. In the natural state of the bracket 1, the inner dimension W1 on the connecting portion 11c side of the side plates 11a and 11b and the distance W2 between the ends of the side plates 11a and 11b are
W2 <W1
It is set in the relationship of. As a result, in the attached state of the bracket 1, the side plates 11a and 11b act so as to sandwich the fixing block 21B by the elastic force thereof. The bobbin 21a is made of resin, and the fixing block 21B has a wall surface 21B1 on the L side of the axis line that is orthogonal to the radial direction of the fitting hole 21H. Then, in the mounted state of the bracket 1, the claw 11b1 of the side plate 11b bites into the wall surface 21B1 of the fixing block 21B. As a result, the bracket 1 is prevented from coming off from the fixed block 21B in the axis L direction, and is firmly fixed to the fixed block 21B.

As described above, with the bracket 1 attached to the stator 21, the elastic piece 12 faces the opening 21H1 in the hakama 21K outside the periphery of the opening 21H1 of the fitting hole 21H of the stator 21. Placed in. Further, as shown in FIG. 2, the convex portion 12a of the elastic piece 12 projects toward the center side (axis line L side) of the hakama portion 21K of the stator 21. Further, the can 40 has a plurality of recesses 40a formed on the outer periphery of the large diameter portion 40B so as to engage with the convex portions 12a of the bracket 1. In this embodiment, five are formed. Then, as shown in FIG. 1, the convex portion 12a of the bracket 1 and the concave portion 40a of the can 40 are engaged with each other in a state where the stator 21 is assembled to the valve device. As a result, the stator 21 is positioned around the axis L of the stator 21 with respect to the can 40, and the stator 21 is attached to the can 40 in a state where it is prevented from coming off in the axis L direction. Further, as shown in FIG. 2, the elastic piece 12 abuts the fulcrum portion 12c on the inner circumference of the hakama portion 21K in a state where the pressing portion 12b is in contact with the outer circumference of the can 40. As a result, the elastic piece 12 presses the can 40 with the fulcrum portion 12c as a fulcrum by the elastic force of the elastic piece 12. As a result, the can 40 is sandwiched between the elastic piece 12 and the opposite inner wall of the opening 21H1 on the opposite side of the elastic piece 12.

Then, the base 11 of the bracket 1 is fixed to the fixing block 21B on the outer periphery of the opening 21H1 of the fitting hole 21H, and the side plate 11b of the base 11 is attached to the wall surface 21B1 orthogonal to the radial direction from the axis L side of the fitting hole 21H. It is in a state of being in contact. Therefore, the wall surface 21B1 can receive the radial load received by the elastic piece 12 when the can 40 is fitted into the fitting hole 21H, the looseness of the fixing between the bracket 1 and the stator 21 can be prevented, and the bracket 1 is fixed by the fixing block. It can be firmly fixed to 21B. In this embodiment, since the base 11 of the bracket 1 is fixed to the fixing block 21B on the outer periphery of the opening 21H1 of the fitting hole 21H, the base 11 and the can 40 fitted into the fitting hole 21H are engaged with each other. The distance from the matching elastic piece 12 becomes shorter, and the elastic piece 12 has a structure that is less likely to bend in the L direction of the axis. Further, in the bracket 1, the elastic piece 12 has a bent portion 1A on the base 11 side. With the bracket 1 attached to the stator 21, the bent portion 1A is parallel to the axis L. That is, the elastic piece 12 extends in a direction orthogonal to (intersects) the axis L via the bent portion 1A. Therefore, even if a load is applied to the stator 21 in the axis L direction, the elastic piece 12 has a structure that is unlikely to bend in the axis L direction. As a result, the stator 21 can be reliably held in an engaged state with the can 40 of the valve device, and can be firmly fixed to the valve device without being displaced.

FIG. 7 is a diagram illustrating an exposed portion of the joint iron 21c with respect to the bobbin 21a in the embodiment, and the shaded portion is a portion of the mold resin of the bobbin 21a. In this embodiment, the joint iron 21c is partially exposed on the outer periphery of the opening 21H1 of the fitting hole 21H by assembling the joint iron 21c by molding. Then, the bracket 1 is electrically grounded to the can 40 via the convex portion 12a and the concave portion 40a of the can 40 as described above, and is electrically connected to the joint iron 21c via the protrusion 12d formed on the elastic piece 12. Is grounded to. The protrusion 12d is formed on the joint iron 21c side of the elastic piece 12, but the protrusion 12d is shown by a solid line in FIG. 7 for the sake of clarity. In this way, the joint iron 21c and the can 40 are surely grounded via the elastic piece 12, and electrical noise between the joint iron 21c and the can 40 can be prevented.

5A is a vertical sectional view and a bottom view of the stator for an electric valve of the second embodiment, and FIG. 5A is a sectional view taken along the line AA of FIG. 5B. In addition, in the following 2nd embodiment and 3rd embodiment, the same elements as those in the 1st embodiment have the same action and effect, and the same reference numerals as those in FIGS. Omitted as appropriate. In this second embodiment, a bracket 1'as an "elastic member" is attached to the bottom of the stator 21.

The bracket 1'is formed by pressing a metal plate or the like, and has a base portion 11 similar to that of the first embodiment, and a first elastic piece 13 extending from the side portion of the base portion 11 integrally with the base portion 11. It has a second elastic piece 14 extending on the side opposite to the first elastic piece 13 with respect to the base 11. The first elastic piece 13 includes a convex portion 13a as a "first engaging portion" formed integrally with the first elastic piece 13, and a protrusion 13d formed at one side piece of the elastic piece 13. have. Further, the second elastic piece 14 has a convex portion 14a formed integrally with the second elastic piece 14. As in the first embodiment, the base portion 11 of the bracket 1'has the side plates 11a and 11b sandwiching the fixed block 21B, and the claw 11b1 bites into the wall surface 21B1 of the fixed block 21B due to its elastic force. As a result, the bracket 1'is firmly fixed to the fixing block 21B.

Then, with the bracket 1'attached to the stator 21, the elastic pieces 13 and 14 face the opening 21H1 in the hakama portion 21K outside the periphery of the opening 21H1 of the fitting hole 21H of the stator 21. Placed in position. Further, the convex portion 13a of the first elastic piece 13 projects toward the center side (axis L side) of the hakama portion 21K of the stator 21, and the concave portion 40a of the large diameter portion 40B of the can 40 is the same as in the first embodiment. The stator 21 is positioned around the axis L of the stator 21 with respect to the can 40, and the stator 21 is attached to the can 40 in a state where it is prevented from coming off in the axis L direction. Further, the convex portion 14a of the second elastic piece 14 is in contact with the outer circumference of the can 40. Then, the first elastic piece 13 and the second elastic piece 14 press the can 40 by their own elastic force. As a result, the can 40 is sandwiched between the elastic pieces 13 and 14 and the opposite inner wall of the opening 21H1 opposite to the elastic pieces 13 and 14.

Then, as in the first embodiment, the side plate 11b of the base portion 11 is in contact with the wall surface 21B1 orthogonal to the radial direction from the axis L side of the fitting hole 21H, and the can 40 is fitted into the fitting hole 21H. The wall surface 21B1 can receive the radial load received by the elastic pieces 13 and 14 when the elastic pieces 13 and 14 are inserted, the base portion 11 of the bracket 1'can be prevented from bending, and the bracket 1'can be firmly fixed to the fixing block 21B. it can.

Further, since the base 11 of the bracket 1'is fixed to the fixing block 21B on the outer periphery of the opening 21H1 of the fitting hole 21H, the distance between the base 11 and the elastic pieces 13 and 14 becomes short, and the elastic pieces 13 Reference numeral 14 denotes a structure that does not easily bend in the L direction of the axis. Further, in the bracket 1', the elastic pieces 13 and 14 have bent portions 1A and 1A on the base 11 side. With the bracket 1'attached to the stator 21, the bent portions 1A and 1A are parallel to the axis L. That is, the elastic pieces 13 and 14 extend in the direction orthogonal to (intersect) the axis L via the bent portions 1A and 1A, respectively. Therefore, even if a load is applied to the stator 21 in the axis L direction, the elastic pieces 13 and 14 have a structure that is unlikely to bend in the axis L direction. As a result, the stator 21 can be reliably held in an engaged state with the can 40 of the valve device, and can be firmly fixed to the valve device without being displaced.

FIG. 6 is a vertical sectional view and a bottom view of the stator for an electric valve according to the third embodiment, and FIG. 6A is a sectional view taken along the line AA of FIG. 6B. In this third embodiment, a bracket 1 "as an" elastic member "is attached to the bottom of the stator 21.

The bracket 1 ″ has a base portion 15 having a groove structure formed by pressing a metal plate or the like, and an elastic piece 16 extending integrally with the base portion 15. Is composed of a side plate 15a and a connecting plate 15b that connects the side plate 15a and the elastic piece 16. The side plate 15a has a claw 15a1 cut out inside the base 15, and the connecting plate 15b is a base. It has a claw 15b1 as a "locking claw" cut out inside the fifteen. Further, the claws 15a1 and 15b1 are bent in a direction intersecting the axis L, and are arranged so that the edge line of the tip end portion thereof is parallel to each other in the direction intersecting the axis L. The elastic piece 16 has a convex portion 16a as a "first engaging portion" formed integrally with the elastic piece 16.

A rectangular parallelepiped fixed block 21B'is formed by a bobbin 21a in a part of the hakama portion 21K of the stator 21, and a bracket 1 "is attached to the fixed block 21B'. Similar to the first embodiment. A slit 21a2 is formed on the outside of the fixing block 21B'. When the bracket 1 "is attached, the side plate 15a and the claw 15a1 of the bracket 1" are fitted into the slit 21a2, and the claw 15a1 of the side plate 15a is fixed to the fixing block 21B'. An engaging recess 21B2'is formed on the surface of the fixing block 21B'on the connecting plate 15b side, and the surface of the engaging recess 21B2' facing the axis L has a diameter. The wall surface 21B1'is orthogonal to the direction. Then, by fitting the claw 15b1 of the connecting plate 15b into the engaging recess 21B2', the end portion of the claw 15b1 is in contact with the wall surface 21B1'. As a result, the claws 15a1 of the side plate 15a and the claws 15b1 of the connecting plate 15b act so as to sandwich the fixing block 21B'by the elastic force of the bracket 1 ″. As a result, the bracket 1 ″ is firmly fixed to the fixing block 21B ′.

Then, with the bracket 1 ″ attached to the stator 21, the elastic piece 16 is positioned so as to face the opening 21H1 in the hakama portion 21K outside the periphery of the opening 21H1 of the fitting hole 21H of the stator 21. Further, the convex portion 16a of the elastic piece 16 projects toward the center side (axis line L side) of the hakama portion 21K of the stator 21, and is a concave portion of the large diameter portion 40B of the can 40 as in the first embodiment. It engages with 40a, positions the stator 21 around the axis L of the can 40, and the stator 21 is attached to the can 40 in a state where it is prevented from coming off in the axis L direction.

As described above, in the third embodiment, the end portion of the claw 15b1 of the connecting plate 15b of the bracket 1 ″ is in contact with the wall surface 21B1 ′ orthogonal to the radial direction from the axis L side of the fitting hole 21H. Therefore, the wall surface 21B1'can receive the radial load received by the elastic piece 16 when the can 40 is fitted into the fitting hole 21H, and the base 15 of the bracket 1 "can be prevented from bending. It can be firmly fixed to the fixing block 21B'. Also in this embodiment, since the base portion 15 of the bracket 1 ″ is fixed to the fixing block 21B'on the outer periphery of the opening 21H1 of the fitting hole 21H, this The distance between the base portion 15 and the elastic piece 16 that engages with the can 40 fitted in the fitting hole 21H becomes short, and the elastic piece 16 has a structure that is hard to bend in the axis L direction. As a result, the stator 21 can be reliably held in an engaged state with the can 40 of the valve device, and can be firmly fixed to the valve device without being displaced.

FIG. 8 is a diagram showing a refrigeration cycle system of the embodiment. In the figure, reference numeral 100 is an electric valve of the embodiment of the present invention constituting an expansion valve, 200 is an outdoor heat exchanger mounted on an outdoor unit, 300 is an indoor heat exchanger mounted on an indoor unit, and 400 is a four-way valve. The flow path switching valve 500 constituting the above is a compressor. The motorized valve 100, the outdoor heat exchanger 200, the indoor heat exchanger 300, the flow path switching valve 400, and the compressor 500 are each connected as shown by a conduit to form a heat pump type refrigeration cycle. The accumulator, pressure sensor, temperature sensor, etc. are not shown.

The flow path of the refrigeration cycle is switched between the flow path during the cooling operation and the flow path during the heating operation by the flow path switching valve 400. During the cooling operation, as shown by the solid line arrow in the figure, the refrigerant compressed by the compressor 500 flows into the outdoor heat exchanger 200 from the flow path switching valve 400, and the outdoor heat exchanger 200 functions as a condenser. Then, the refrigerant liquid flowing out from the outdoor heat exchanger 200 flows into the indoor heat exchanger 300 via the electric valve 100, and the indoor heat exchanger 300 functions as an evaporator.

On the other hand, during the heating operation, as shown by the broken arrow in the figure, the refrigerant compressed by the compressor 500 is transferred from the flow path switching valve 400 to the indoor heat exchanger 300, the electric valve 100, the outdoor heat exchanger 200, and the flow path. The switching valve 400 and the compressor 500 are circulated in this order, the indoor heat exchanger 300 functions as a condenser, and the outdoor indoor heat exchanger 200 functions as an evaporator. The electric valve 100 depressurizes and expands the refrigerant liquid flowing from the outdoor heat exchanger 200 during the cooling operation and the refrigerant liquid flowing from the indoor heat exchanger 300 during the heating operation, and further controls the flow rate of the refrigerant.

In each embodiment, the elastic piece of the elastic member is arranged at a position facing the opening of the fitting hole, but the elastic piece of the elastic member is at least this cylinder so as to be engaged with the cylindrical part of the valve device. It suffices if it is arranged at a position facing the portion.

The first engaging portion integrally formed with the elastic piece is not limited to the convex portion protruding toward the axis side, but is a concave portion recessed on the side opposite to the axis side with respect to the protrusion of the convex portion. There may be. Further, the second engaging portion of the can as a cylindrical portion is not limited to a plurality of recesses recessed on the axis side of the outer circumference of the can, and a plurality of recesses protruding outward from the outer diameter of the outer circumference of the can. It may be a convex portion. When the first engaging portion of the elastic piece is a concave portion, the second engaging portion on the can side becomes a convex portion, which is a combination of a relationship in which the first engaging portion and the second engaging portion are securely engaged. .. Further, the second engaging portion may be provided not only on the large diameter portion of the can but also on the small diameter portion, or may be provided on the valve body. Further, the bent portion of the elastic piece may have a crease as shown in the figure of each embodiment, or may be gently bent in an R shape, that is, one without a clear crease.

The method of fixing the base of the bracket to the fixing block may be another method such as caulking or welding.

Although the embodiments of the present invention have been described in detail with reference to the drawings, the specific configuration is not limited to these embodiments, and the design changes, etc. within the range not deviating from the gist of the present invention, etc. Even if there is, it is included in the present invention.

1 Bracket (elastic member)
11 Base 11a Side plate 11b Side plate 11c Connecting plate 11a1 Claw 11b1 Claw 12 Elastic piece 12a Convex part (first engaging part)
20 Stepping motor (motor section)
21 Stator (solenoid valve stator)
21a Bobbin 21a1 Slit 21b Coil 21H Fitting hole 21H1 Opening 21K Hakama 21B Fixed block 21B1 Wall surface 21B'Fixed block 21B1' Wall surface 22 Magnet rotor 30 Valve body (valve device)
40 can (valve gear)
40A Small diameter part 40B Large diameter part 1'Bracket 13 First elastic piece 14 Second elastic piece 13a Convex part (first engaging part)
1 ″ bracket (elastic member)
15 Base 15a Side plate 15b Connecting plate 15a1 Claw 15b1 Claw (locking claw)
16 Elastic piece 16a Convex part (first engaging part)
L-axis line 100 Electric valve 200 Outdoor heat exchanger 300 Indoor heat exchanger 400 Flow path switching valve 500 Compressor

Claims (7)

A stator for an electric valve that is attached to a valve device that is operated by driving a motor unit and constitutes the motor unit together with a magnet rotor on the valve device side, and has an insertion / insertion hole for fitting the valve device. An elastic member that engages with the valve device and fixes the electric valve stator and the valve device is provided.
The outer periphery of the opening of the insertion hole, together with the fixed block having a wall surface perpendicular to the radial direction of the insertion hole is formed, the elastic member includes an elastic piece that engages the valve device, the fixed Has a base that is fixed to the block
A stator for an electric valve, characterized in that the base portion of the elastic member is fixed to the fixing block in a state where a part of the base portion is in contact with the wall surface from the axis side of the fitting / insertion hole. The base portion of the elastic member has two side plates extending in parallel with the axis and arranged in the radial direction, and the side plates on the inner side in the radial direction are brought into contact with the wall surface to form the base portion. The stator for an electric valve according to claim 1, wherein the fixing block is sandwiched between the two side plates. The base portion of the elastic member has a side plate extending parallel to the axis and a connecting plate connecting the side plate and the elastic piece and arranged in parallel with the radial direction.
The fixed block has the wall surface on the connecting plate side.
A locking claw having an end portion on the side opposite to the elastic piece is formed on the connecting plate by being bent toward the fixed block side, and the end portion of the locking claw is brought into contact with the wall surface to obtain the above. The stator for an electric valve according to claim 1, wherein the base portion sandwiches the fixed block. Claim 1 or 2 is characterized in that the elastic piece of the elastic member extends in a direction intersecting the axis through a bent portion parallel to the axis around the axis of the fitting hole. The stator for the motorized valve described in. The elastic piece that engages with the valve device of the elastic member has a first engaging portion that protrudes on the axis side or is recessed on the side opposite to the protrusion.
The electric motor according to any one of claims 1 to 4, wherein the first engaging portion of the elastic piece is engaged with a second engaging portion formed on the outer periphery of the valve device. Valve stator. 5. The fifth aspect of the present invention, wherein the first engaging portion of the elastic piece is a convex portion that protrudes toward the axis and engages with a concave portion as the second engaging portion on the valve device side. Stator for electric valves. An electric valve comprising the stator for an electric valve according to any one of claims 1 to 6 provided in the valve device.

Images