JP2014190494A - Cover structure of motor - Google Patents

Abstract

PROBLEM TO BE SOLVED: To prevent moisture from entering inside.SOLUTION: In a cover structure of a motor, a coil terminal 56 extending outward in a radial direction from a stator assembly 40 through an opening provided on a peripheral wall 92 of an upper cover member 90 is connected to a connector terminal 61 in the peripheral wall surrounding the opening, and the opening is sealed by a cap 96 having a fitting wall fitted with outside of the peripheral wall. The peripheral wall is constituted by an upper wall 951 along an upper side of the opening, side walls 952 extending downward along a side of the opening from both ends of the upper wall 951, and a terminal support part for connecting lower parts of the side walls 952. Step parts 954 in contact with a contact part of the fitting wall are provided on outer peripheries of the side walls 952, and positions of the step parts 954 are offset from positions of outer peripheral parts 953 of the side walls 952 in a fitting direction of the cap 96 to the side walls 952.

Description

  The present invention relates to a cover structure in a motor.

  Patent Document 1 discloses an electric valve that drives a valve element by a motor.

JP 2008-292003 A

In this electric valve, the rotor of the motor is rotatably provided in a bottomed cylindrical case. A stator portion is attached by extrapolation to a peripheral wall portion surrounding the outer periphery of the rotor in the case, and the stator portion is disposed on the radially outer side of the rotor.
The stator portion has a lead terminal extending radially outward. The lead terminal protrudes radially outward from the main body cover covering the outer periphery and the upper surface of the stator portion, and is connected to the connector portion outside the main body cover. ing.

  Here, a connector cover for protecting the connector portion exposed to the outside of the main body cover is assembled to the outer periphery of the main body cover, and the outer periphery and the upper surface of the connector portion are covered with the connector cover.

  In the electric valve of Patent Document 1, the connector cover is simply locked to the main body cover, and when moisture or the like adheres to the main body cover, the moisture passes through the assembly portion of the connector cover and the main body cover. There is a risk of entering the inside of the connector cover.

  Therefore, it is required to prevent moisture from entering the connector cover.

The present invention
A cover structure in a valve element driving motor of a valve device that opens and closes a refrigerant flow path of a refrigerator,
A stator having a drive coil is disposed in a main body cover having a peripheral wall covering the outer periphery of the stator,
A coil terminal to which an end of the drive coil is connected extends radially outward from the stator through an opening provided in the peripheral wall, and is connected to a connector terminal in the peripheral wall surrounding the opening,
In the motor that is configured to seal the opening of the peripheral wall portion with a sealing member having a fitting wall that is fitted on the peripheral wall portion,
On the outer periphery of the peripheral wall portion, a step portion is provided for contacting the tip of the fitting wall,
A cover structure for a motor, wherein a position of the stepped portion is offset from a position of a distal end portion of the peripheral wall portion in a fitting direction of the fitting wall with respect to the peripheral wall portion.

According to the present invention, the position of the step where the tip of the fitting wall contacts and the position of the tip of the peripheral wall where the fitting wall is fitted are offset in the fitting direction of the fitting wall with respect to the peripheral wall. Therefore, even if moisture enters from the contact surface between the tip of the fitting wall and the stepped portion toward the inside of the peripheral wall, the moisture that has entered passes between the peripheral wall and the fitting wall. If it does not move in the fitting direction, it cannot enter the peripheral wall.
Therefore, it is possible to prevent moisture from entering the peripheral wall portion (main body cover) without separately providing a sealing member such as an O-ring.

It is sectional drawing of the valve drive device concerning embodiment. It is X1-X1 sectional drawing in FIG. It is a perspective view which decomposes | disassembles and shows the principal part of a valve drive device. It is a figure explaining the connector cover part of an upper cover member. It is a figure explaining an upper cover member. It is a figure explaining the connector cover part of an upper cover member. It is a figure explaining a connector part. It is a figure explaining the cap of a connector cover part. It is principal part sectional drawing of a connector cover part. It is a perspective view which decomposes | disassembles and shows the motor side of a valve drive device. It is a perspective view which decomposes | disassembles and shows the valve part in a valve drive device. It is a figure explaining operation | movement of a valve drive device.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings as appropriate, taking as an example the case where the present invention is applied to a valve drive device (gear unit) of a valve device that opens and closes a refrigerant flow path of a refrigerator. explain.
In each figure, common portions are denoted by the same reference numerals, and redundant description is omitted.
In the following description, the positional relationship of each component of the valve drive device will be described as appropriate with reference to the upper and lower portions in the valve drive device 1 shown in FIG.

FIG. 1 is a cross-sectional view of a valve drive device 1 according to an embodiment. 2 is a cross-sectional view taken along line X1-X1 in FIG. FIG. 3 is an exploded perspective view of the valve drive device 1 on the motor M side.
In FIG. 3, a portion of the stator assembly 40 formed of resin is hatched.

As shown in FIGS. 1 to 3, the valve drive device 1 according to the embodiment of the present invention is a flow path through which fluid (here, refrigerant) can circulate between a refrigerator (not shown) that is an external device. , And is a valve device that guides the fluid introduced from the refrigerator into the fluid chamber S through the fluid introduction pipe 2 to the refrigerator through the fluid outlet pipes 3 and 4.
In this valve drive device 1, the valve portion 70 is driven by the motor M, and the fluid introduced into the fluid chamber S is led out from the fluid outlet pipes 3 and 4 to the refrigerator side. As the motor M of the apparatus 1, a claw pole type stepping motor in which a pair of stator sets 50 </ b> A and 50 </ b> B (A phase coil and B phase coil) are arranged in the axial direction of the rotor 30 is employed.

In the valve driving device 1, a fluid chamber S is formed between the bottom plate portion 10 and the partition wall 20 by a bottomed cylindrical partition wall 20 fixed to the upper surface of the bottom plate portion 10.
In the valve drive device 1, the partition wall 20 is provided with the bottom portion 20 a facing upward on the opposite side to the bottom plate portion 10. The partition wall 20 has an outer shape expanded in two steps in a direction away from the bottom portion 20a, and includes a small diameter portion 201 on the bottom portion 20a side and a large diameter portion 202 on the bottom plate portion 10 side.
On the outer peripheral edge of the bottom plate portion 10, a stepped portion 11 is provided over the entire periphery to which the tip end 202 a of the large diameter portion 202 is fitted, and the partition wall 20 has the tip end 202 a of the large diameter portion 202 on the stepped portion 11. And is fixed to the bottom plate portion 10.
Further, the valve drive device 1 is used in an arrangement (see FIG. 1) in which the rotor 30 of the motor M is directed upward and the fluid chamber S is directed downward.

Inside the small diameter portion 201, the rotor 30 of the motor M is provided in a state of being extrapolated to the shaft member 21.
In the valve driving device 1, the shaft member 21 is provided along the axis X, and one end 21 a of the shaft member 21 is supported by the recess 20 b of the bottom portion 20 a, and the other end 21 b is a hole in the bottom plate portion 10. The shaft member 21 is brazed by the portion 10a, and is provided in a state of being prevented from rotating.
In the shaft member 21, the rotor 30 is rotatably supported, and rotates around the axis X when the motor M is driven.

The rotor 30 includes a base portion 31 having a bearing portion 31 a that is extrapolated to the shaft member 21, and magnets 32 in which N and S phases are alternately arranged in the circumferential direction around the axis X.
The magnet 32 is formed integrally with the rotor 30 by insert molding when the rotor 30 is resin-molded. In the base portion 31, the magnet 32 is provided over the entire circumference in the circumferential direction around the axis X.

  A transmission shaft 33 that transmits rotation of the rotor 30 to a valve unit 70 described later is inserted and fixed between the bearing portion 31 a and the base portion 31 at a lower portion of the base portion 31 on the bottom plate portion 10 side. Like the rotor 30, the transmission shaft 33 is rotatably supported by the shaft member 21, and rotates around the axis line X integrally with the rotor 30.

The transmission shaft 33 extends downward along the axis X on the side of the bottom plate portion 10, and the tip end portion 33 a is in contact with the upper surface 10 b of the bottom plate portion 10.
In the embodiment, the rotor 30 is urged downward on the bottom plate portion 10 side by a spring Sp extrapolated to the one end 21a side of the shaft member 21, and the tip portion of the transmission shaft 33 is urged by the urging force of the spring Sp. 33a is always brought into contact with the upper surface 10b of the bottom plate portion 10, and the axial line X of the rotor 30 is positioned in the axial direction.

  An upper side of the distal end portion 33a of the transmission shaft 33 is a large diameter portion 33b having a diameter larger than that of the distal end portion 33a. A tooth portion provided on an outer periphery of a gear 71 described later is provided on the outer periphery of the large diameter portion 33b. The tooth part 33c which meshes with 71g is provided (refer FIG. 2).

As shown in FIG. 1, the small-diameter portion 201 of the partition wall 20 that accommodates the rotor 30 is formed in a cylindrical shape that surrounds the magnet 32 of the rotor 30 at a predetermined interval, and the stator assembly 40 is disposed on the outer periphery of the small-diameter portion 201. Is attached by extrapolation.
In the embodiment, the disk portion 203 that connects the small diameter portion 201 and the large diameter portion 202 is provided orthogonal to the axis X, and the stator assembly 40 extrapolated to the small diameter portion 201 by the disk portion 203. The two stator sets 50A and 50B are arranged on the radially outer side of the rotor 30 (magnet 32).
Since the magnet 32 of the rotor 30 is driven by a magnetic force from a stator assembly 40 described later via the partition wall 20, the partition wall 20 is made of a nonmagnetic material. Further, the partition wall 20 is made of metal so as to withstand the pressure of the fluid chamber S. For this reason, the partition 20 is comprised with the stainless steel which is a nonmagnetic metal.

As shown in FIG. 2, the stator assembly 40 includes two stator sets 50A and 50B arranged so as to overlap each other in the axial direction of the axis X, and the stator assembly 40 has outer peripheries of the stator sets 50A and 50B. A surrounding outer stator core 59 is attached by extrapolation.
The outer stator core 59 is formed by pressing a magnetic plate like the inner stator cores 51 and 52 to be described later. When the outer stator core 59 is attached to the stator assemblies 50A and 50B, the outer stator core 59 and The inner stator cores 51 and 52 are provided in contact with each other, and the outer stator core 59 and the inner stator cores 51 and 52 constitute a magnetic path.

Each of the stator sets 50A and 50B has a basic configuration in which a coil 54 wound around the outer periphery of a bobbin 53 is disposed between a pair of inner stator cores 51 and 52 that are spaced apart in the axial direction. .
In the stator assembly 40, the bobbin 53 is a resin molded body (insulator) in which the inner stator cores 51 and 52 of the stator assemblies 50A and 50B are embedded by insert molding, and is formed integrally with a terminal holding portion 55 described later. ing.

4A is an enlarged cross-sectional view of the main part in FIG. 1, and FIG. 4B is an enlarged view of a region A in FIG.
As shown in FIG. 4, the inner stator cores 51 and 52 are formed to stand in the axis X direction from the inner periphery of the ring-shaped flange portions 510 and 520 arranged in a direction orthogonal to the axis X and the flange portions 510 and 520. The pole teeth 511 and 521 are provided at equal intervals in the circumferential direction around the axis X on the inner diameter side of the flange portions 510 and 520.
The pair of inner stator cores 51 and 52 of the stator sets 50A and 50B are arranged such that the pole teeth 511 of one inner stator core 51 and the pole teeth 521 of the other inner stator core 52 are alternately arranged in the circumferential direction around the axis X. As shown in the figure, the pole teeth 511 and 521 are arranged to face each other.

  A cylindrical base portion 530 of a bobbin 53 around which a coil is wound is located on the outer side in the radial direction of the pole teeth 511 and 521, and the outer side in the radial direction is located at both ends of the base portion 530 in the axial direction of the axis X. The flanges 531 and 532 extending in the circumferential direction are provided over the entire circumference in the circumferential direction around the axis X.

As shown in FIG. 2, in the stator assembly 40, the inner stator core 51 of the stator assembly 50A and the inner stator core 52 of the stator assembly 50B are in contact with the flange portions 510 and 520 (see FIG. 4) in the axial direction of the axis X. It is provided in a state of letting it.
And these flange parts 510 and 520 are hold | maintained in resin in the state joined without gap.

In the stator assembly 40 in which the inner stator cores 51 and 52 are embedded, the pole teeth 511 and 521 are exposed on the inner diameter side of the base portion 530 of the bobbin 53, and the surface of the flange portions 510 and 520 on the coil 54 side is the flange portion 531. 532 is covered with a resin constituting 532.
Here, the pole teeth 511 and 521 are exposed on the inner diameter side of the base portion 530 of the bobbin 53 when the bobbin 53 in which the inner stator cores 51 and 52 are embedded is formed by insert molding. This is because the inner diameter sides of 511 and 521 are used as positioning portions with the mold.

In the stator assembly 40, a ring-shaped attachment portion 57 (see FIGS. 2 and 3) is formed of a resin material that covers the upper surface on the inner diameter side of the flange portion 510 of the stator assembly 50B. Are fitted with a fitting wall 91c of an upper cover member 90 to be described later.
Further, a ring-shaped contact portion 58 (see FIG. 2) is formed of a resin material that covers the lower surface on the inner diameter side of the flange portion 520 of the stator assembly 50A. In this contact portion 58, the stator assembly 40 is a partition wall. When the 20 small-diameter portions 201 are extrapolated, they come into contact with the disk portion 203 at the boundary between the small-diameter portions 201 and the large-diameter portions 202 from the direction of the axis X, and positioning of the stator assembly 40 in the axial direction is performed. The contact portion 58 is in contact with the disc portion 203.

  As shown in FIG. 4, in the flange portions 510 and 520 of each stator core, notches 510b and 520b that are recessed toward the axis X side are formed in a part of the outer peripheral portion, and the notches of the flange portions 510 and 520 are formed. The notches 510b and 520b are provided at positions overlapping when viewed from the axial direction of the axis X. In the embodiment, the terminal holding portion 55 is provided by using the notches 510b and 520b.

The terminal holding portion 55B of the stator assembly 50B is provided across the notches 510b and 520b of the flange portions 510 and 520.
The terminal holding portion 55B is formed integrally with the flange portions 532 and 531 of the bobbin 53 located on both sides of the flange portions 510 and 520, and has a predetermined thickness in the axial direction of the axis X.

The terminal holding portion 55 </ b> A of the stator set 50 </ b> A is provided in the notch portion 520 b of the flange portion 520 of the inner stator core 52.
The terminal holding portion 55A is formed integrally with the flange portion 532 of the bobbin 53 of the stator assembly 50A, and has a predetermined thickness in the axial direction of the axis X.

The terminal holding portion 55A of the stator set 50A and the terminal holding portion 55B of the stator set 50B are provided with an interval in the axis X direction.
A plurality of coil terminals 56 are press-fitted and supported by the terminal holding portions 55A and 55B of the stator assemblies 50A and 50B, and the plurality of coil terminals 56 are provided so as to protrude radially outward from the stator assembly 40. At the same time, the base end of the coil terminal 56 is located in the notches 510b and 520b.

Therefore, in the outer stator core 59 that is attached by being fitted to the stator assembly 40, a notch 593 (see FIG. 3) for avoiding interference with the coil terminal 56 is provided in the peripheral wall portion 592 surrounding the outer periphery of the stator assemblies 50A and 50B. In addition, an opening 92a for avoiding interference with the coil terminal 56 is also provided in a peripheral wall portion 592 of the upper cover member 90 described later (see FIG. 2).
Here, in the embodiment, since the coil terminal 56 of the stator set 50A and the coil terminal 56 of the stator set 50B are arranged close to each other in the axial direction of the axis X, the notch 593 in the outer stator core 59 is formed. The size of the range to be formed and the range in which the opening 92a is provided in the peripheral wall portion 592 can be reduced.

  As shown in FIG. 3, the outer stator core 59 has a bottomed cylindrical shape, and an opening 591 a through which the bottom 20 a side of the partition wall 20 can be inserted is provided at the center of the bottom 591. And the surrounding wall part 592 provided over the perimeter of the bottom part 591 has comprised the cylindrical shape which surrounds the flange parts 510 and 520 of stator assembly 50A, 50B over a perimeter.

  As shown in FIG. 4, the coil terminal 56 is a conductive pin having a linearly extending rod shape, penetrates through an opening 92 a provided in the upper cover member 90, and the tip side thereof is connected to the connector cover portion. 93 (accommodating portion 95).

  In the stator assembly 40 of the embodiment, since the terminal holding portions 55A and 55B are provided in the notches 510b and 520b of the flange portions 510 and 520 of the inner stator cores 51 and 52, the terminals are compared with the case where no notches are provided. The holding portions 55A and 55B are preferably prevented from projecting radially outward, and the motor M is prevented from being enlarged in the radial direction.

  Further, in the stator assembly 50A, the terminal holding portion 55A is provided using the thickness of the flange portion 520, and in the stator assembly 50B, the terminal holding portion 55B is provided using the thickness of the flange portions 510 and 520, respectively. 55B can be increased in thickness. Thereby, the support strength of the coil terminal 56 in the terminal holding | maintenance part 55A, 55B is raised.

  In the terminal holding portion 55A of the stator set 50A, the plurality of coil terminals 56 that are press-fitted and supported are positioned within the thickness range of the flange portion 520 of the inner stator core 52 of the stator set 50A. In the terminal holding portion 55B of the stator set 50B, the plurality of press-fitted and supported coil terminals 56 are positioned within the thickness range of the overlapping portions of the flange portions 510 and 520 of the stator core that are overlapped in the axial direction.

In the embodiment, on the terminal holding portion 55A side of the coil terminal 56 held by the terminal holding portion 55A, an end portion of a winding wire (not shown) drawn from the coil 54 (A phase coil) of the stator assembly 50A. ) And the end of the winding wire drawn from the coil 54 (B phase coil) of the stator assembly 50B on the terminal holding portion 55B side of the coil terminal 56 held by the terminal holding portion 55B (not shown). Z)) is entangled.
Each of the coil terminals 56 supported by the terminal holding portions 55A and 55B is connected to a corresponding connector terminal 61 via a flexible common printed board 60 (hereinafter referred to as a board 60). It is connected. Note that each of the coil terminals 56 is connected to a corresponding wiring among the wirings provided on the substrate 60 on the surface of the substrate 60 opposite to the coil 54 by soldering.
Note that each of the coil terminals 56 is connected to the substrate 60 at a radially outer side than a portion where ends (not shown) of windings drawn from the coil 54 are entangled, and the terminal holding portion 55A. , 50B and the substrate 60, a space is secured for winding an end portion (not shown) of the winding drawn from the coil 54.

  As shown in FIGS. 1 to 3, the upper cover member 90 is a member that accommodates the stator assembly 40 and the outer stator core 59 of the motor M. The upper cover member 90 covers the upper surface of the stator assembly 40, and the outer periphery of the outer stator core 59. And a peripheral wall portion 92 that surrounds the connector wall portion 92, and a connector cover portion 93 is formed integrally with the peripheral wall portion 92.

A ring-shaped bulging portion 91a is provided at the center of the cover portion 91 as viewed from the axial direction, and the partition wall 20 located in the bulging portion 91a can be visually recognized at the center of the bulging portion 91a. An opening 91b is provided.
A ring-shaped fitting wall 91c (see FIG. 2) is formed on the opposite side of the cover portion 91 from the bulging portion 91a. The fitting wall 91c is formed on the upper portion of the stator assembly 40. It is fitted in a stepped portion 57a (see FIG. 2) of the provided substantially ring-shaped mounting portion 57.

FIG. 5 is a view for explaining the connector cover portion 93 of the upper cover member 90, and FIG. 5A is a perspective view of the connector portion 94 and the housing portion 95 of the connector cover portion 93 as viewed from diagonally upward to the right. (B) is the perspective view which looked at the connector part 94 and the accommodating part 95 from diagonally downward, (c) is the top view which looked at the accommodating part 95 from radial direction.
6A and 6B are views for explaining the connector cover portion 93. FIG. 6A is a plan view seen from the upper side in the axis X direction, and FIG. 6B is a perspective view.
7A and 7B are diagrams illustrating the connector portion 94, where FIG. 7A is a plan view seen from the lower side in the axis X direction, and FIG. 7B is a perspective view seen from the lower oblique side in the axis X direction. .

As shown in FIG. 5, the peripheral wall portion 92 of the upper cover member 90 has an annular shape when viewed from the axial direction. In the valve drive device 1, the peripheral wall portion 92 is provided so as to surround the outer periphery of the outer stator core 59. ing.
The lower end 92b (see FIG. 3) of the peripheral wall portion 92 is located below the coil terminal 56 and the drive coil 54 disposed inside the upper cover member 90 and the connector cover portion 93 in the axis X direction. The water applied to the peripheral wall portion 92 is preferably prevented from reaching the conductive portions such as the coil terminal 56 and the drive coil 54.

In the peripheral wall portion 92, a region that interferes with the coil terminal 56 is cut out when viewed from the radial direction, and the cutout region is an opening through which the coil terminal 56 that extends in the radial direction from the stator assembly 40 passes. The portion 92a is formed.
In the peripheral wall portion 92, the opening 92a is formed in a height range from the lower end of the peripheral wall portion 92 to the vicinity of the cover portion 91 (see FIG. 5B), and the upper side 92a1 of the opening 92a is A position offset downward from the cover portion 91 extends parallel to the cover portion 91.
Both sides 92a2 and 92a2 of the opening 92a in the circumferential direction of the peripheral wall 92 extend linearly along the axis X, and the opening 92a has a substantially rectangular shape when viewed from the radial direction (see FIG. 5 (c)).

  In the opening 92a, protruding portions 921 are provided on both sides of the upper side 92a1 so as to protrude radially outward. The substrate 92 is in contact with the protruding portion 921 from the outside in the radial direction (see FIG. 1), and the positioning of the substrate 60 in the radial direction is performed by the protruding portion 921.

In the peripheral wall portion 92 of the upper cover member 90, an engaged portion 922 to be engaged with an engaging arm 84 of the lower cover member 80 to be described later is provided at a position on the opposite side of the opening portion 92 a across the axis X. Yes.
The upper cover member 90 is formed integrally with the connector portion 94 and the housing portion 95 of the connector cover portion 93.

As shown in FIG. 3, in the peripheral wall portion 92 of the upper cover member 90, a connector cover portion 93 that covers the opening 92a is provided outside the opening 92a in the radial direction.
The connector cover portion 93 extends downward from the outer side in the radial direction of the peripheral wall portion 92, the connector portion 94 positioned below the opening 92 a, and the connector terminal 61 provided in the connector portion 94 as described above. A housing portion 95 that houses the substrate 60 that connects the coil terminal 56 and a cap 96 that seals the opening 930 of the housing portion 95 are provided.
In the embodiment, the upper cover member 90 and the connector portion 94 (accommodating portion 95, cap 96) are made of boribylene terephthalate (PBT), and the upper cover member 90 in which the accommodating portion 95 is integrally formed is In FIG. 5A, it is molded by a mold that is divided into two in the vertical direction.

As shown in FIG. 4, in the connector portion 94, a terminal support portion 940 is provided at a position on the radially outer side of the large diameter portion 202. In the terminal support portion 940, the connector terminal 61 described above is provided. A plurality of them are provided at intervals in the circumferential direction around the axis X (see FIG. 3).
Each of the connector terminals 61 is provided so as to penetrate the terminal support portion 940 in the thickness direction (axis X direction), and each of the connector terminals 61 is positioned below the above-described coil terminal 56 as viewed from the radial direction. In addition, it is provided in a direction substantially orthogonal to the coil terminal 56.

  Each of the connector terminals 61 is connected to a corresponding coil terminal 56 via the substrate 60, and a connection portion (soldering portion) between the connector terminal 61 and the substrate 60 is a connection between the coil terminal 56 and the substrate 60. It is provided at a position offset from the portion (soldering portion) by a predetermined height h downward in the axis X direction. And the board | substrate 60 which connects the coil terminal 56 and the connector terminal 61 makes the other end (lower end part 60b) side the other end (lower end part 60b) side in the direction in alignment with the axis line X on the curved part 60c as a boundary. It is directed in a direction along the direction orthogonal to the axis X, and is curved so as to be substantially L-shaped in a sectional view.

  As shown in FIG. 7B, the terminal support portion 940 has a peripheral wall portion 941 surrounding the outer periphery of the connector terminal 61 protruding downward from the terminal support portion 940. The peripheral wall portion 941 is a terminal support portion. Side wall portions 942 and 942 provided on both sides in the longitudinal direction of the portion 940, an outer wall portion 943 provided along a radially outer side edge of the terminal support portion 940, and a radially inner side edge And an inner wall portion 944 formed.

An inner diameter side of the inner wall portion 944 (the diagonally upper right side in FIG. 7B) is cut away leaving two connection beams 945 and 945 with the terminal support portion 940. The notch 944a has a width L3 larger than the width L2 of the substrate 60, and an engaging protrusion (not shown) of the mating connector is locked at the center of the notch 944a in the width direction. A locking portion 944b is provided.
The connecting beams 945 and 945 have a substantially rectangular shape when viewed from the axis X side (inner diameter side), and are provided along the direction in which the mating connector is attached to and detached from the connector portion 94.
The connecting beams 945 and 945 are provided on the inner side of the inner wall portion 944 and the terminal support portion 940 on the inner side in order to reinforce the inner wall portion 944 against the force applied to the locking portion 944b when the mating connector is pulled out. The inner wall portion 944 and the side wall portion are connected and provided by transmitting (releasing) a force acting on the locking portion 944b (inner wall portion 944) to the terminal support portion 940 when the mating connector is pulled out. The stress is concentrated on the connection portion with 942 to prevent breakage from the connection portion.
In the connector portion 94 according to the embodiment, the connection beams 945 and 945 are provided, so that sufficient strength can be secured even if the side wall portions 942 and 942 are separated from each other. The width L3 (see FIG. 5B) can be made larger than the width L2 of the substrate 60 (see FIG. 3).

In the connection portion of the connection beam 945 with the terminal support portion 940, an inclined surface 945a in which the thickness of the connection beam 945 decreases toward the support surface 940b side of the substrate 60 of the terminal support portion 940 (upper side in FIG. 4) is provided. ing.
Further, an inclined surface 940 a that is inclined in the same direction as the inclined surface 945 a is also provided on the side surface exposed in the notch 944 a of the terminal support portion 940.
Therefore, as shown in FIG. 4, a gap W1 between the connecting beam 945 and a reinforcing wall 82 of the mounting portion 85, which will be described later, and a gap W2 between the terminal support portion 940 and the reinforcing wall 82 are provided in the upper cover. It becomes wider toward the upper side of the member 90.

  In the embodiment, the outer stator core 59 and the upper cover member 90 are assembled in order to the stator assembly 40 (see FIG. 3) in which the board 60 is soldered to the coil terminal 56, and the connector cover portion 93. Then, a clearance Sa for avoiding interference with the coil terminal 56 and the substrate 60 is secured on the inner diameter side of the terminal support portion 940 (see FIG. 4).

  Here, immediately after the upper cover member 90 is assembled, the lower end portion 60b of the substrate 60 is in a position indicated by a dotted line in FIG. 4, so the lower end portion 60b side is bent radially outward from this state (in the drawing). It is necessary to engage the terminal hole 601 (see FIG. 3) provided in the lower end 60b with the connector terminal 61 protruding upward from the upper surface (support surface 940b) of the terminal support 940.

However, since the reinforcing wall 82 of the mounting portion 85 to be described later is located on the inner diameter side of the terminal support portion 940, if the gap between the reinforcing wall 82 is small, the lower end portion 60b side of the substrate 60 is curved. At this time, the entire substrate 60 needs to be largely curved, and at this time, the bending radius of the substrate 60 becomes small.
Therefore, it becomes necessary to lengthen the length L1 (see FIG. 3) of the substrate 60 in the longitudinal direction so that the length L1 of the substrate 60 has a margin.
In the embodiment, the terminal support portion 940 side of the inner wall portion 944 is notched, the inner diameter side of the terminal support portion 940 is exposed in the notch portion 944a, and the gap Sa on the inner diameter side of the terminal support portion 940 is formed. It is spreading.
Further, inclined surfaces 945a and 940a are provided in the connection beam 945 and the terminal support portion 940, respectively, to widen the gap between the reinforcing wall 82 and the inclined surfaces 945a of the support surface 940b of the terminal support portion 940. , 940a, the connector terminal 61 is positioned.

Therefore, the length L1 in the longitudinal direction of the substrate 60 can be shortened and the bending radius of the substrate 60 when the substrate 60 is bent can be increased as compared with the case where the notch 944a is not provided. ing.
Since the inclined surfaces 940a and 945a are provided, the gap is widened by the inclined surfaces 940a and 945a. Therefore, the inclined surfaces 940a and 945a function as a guide when the substrate 60 is curved, and the substrate 60 This contributes to an increase in the bending radius of the substrate 60 when the substrate is bent.

  Since the length L1 of the substrate 60 can be shortened by providing the notch portion 944a in the inner wall portion 944, in a state where the lower end portion 60b side of the substrate 60 is bent approximately 90 degrees with respect to the upper end portion 60a side, The curved portion 60c of the substrate 60 can be arranged at a position away from the metal reinforcing wall 82.

When the length L1 of the substrate 60 is increased, the curved portion 60c may come into contact with the metal reinforcing wall 82. Here, wiring that connects the coil terminal 56 and the connector terminal 61 is provided (printed) in the substrate 60, and when the substrate 60 and the reinforcing wall 82 are in contact with each other, There is a possibility that the substrate 60 is scraped from the reinforcing wall 822 by vibration due to driving, and the wirings provided on the substrate 60 are connected to each other via the metal reinforcing wall 82 and short-circuited.
As described above, by providing the inclined surfaces 940a and 945a and suppressing the length L1 in the longitudinal direction of the substrate 60, the curved portion 60c in the substrate 60 can be disposed at a position away from the reinforcing wall 82. The possibility of occurrence of a short circuit due to contact between the portion 60c and the reinforcing wall 82 is reduced.
Further, since the bending radius of the substrate 60 can be increased, problems that may occur when the bending radius is small, such as the problem that the substrate 60 or a wiring pattern (copper pattern) provided in the substrate 60 breaks, are preferably prevented. it can.

As shown in FIG. 5, the housing portion 95 of the connector cover portion 93 is provided adjacent to the upper side of the connector portion 94, and is an upper wall portion provided along the upper side 92 a 1 of the opening 92 a of the peripheral wall portion 92. 951 and side wall portions 952 and 952 provided along the side 92a2 of the opening 92a.
The upper wall portion 951 and the side wall portions 952 and 952 protrude radially outward from the outer peripheral surface of the peripheral wall portion 92, and when viewed from the radial direction of the axis X, the upper side and both sides of the opening portion 92a provided in the peripheral wall portion 92. Is provided so as to surround.

The side wall portions 952 and 952 are provided over the entire length of the side 92a2 of the opening 92a, and the upper end portions thereof are connected to both end portions in the longitudinal direction of the upper wall portion 951.
As shown in FIG. 6B, the lower end side of the side wall portion 952 bulges away from the peripheral wall portion 92 toward the lower side, and this bulged portion (bulged portion 952c). The terminal support portion 940 described above is integrally connected to the lower end of the.

Therefore, the connector portion 94 having the terminal support portion 940 is held by the side wall portions 952 and 952 at a position spaced radially outward from the outer periphery of the peripheral wall portion 92, and the lower end side of the side wall portions 952 and 952 is bulged. The portion 952c functions as a rib that secures the support strength of the terminal support portion 940. Thereby, the strength against the force acting on the terminal support portion 940 when the mating connector is removed from the connector portion 94 is ensured.
When the portion where the terminal support portion 940 is provided is seen from the radial direction of the axis X, the opening 92a of the peripheral wall portion 92 is formed by the terminal support portion 940, the upper wall portion 951, and the side wall portions 952 and 952. A surrounding wall (go wall) is formed.

As shown in FIG. 6, a concave groove 951 a is provided between the upper wall portion 951 and the peripheral wall portion 92 on the inner diameter side, and the concave groove 951 a is formed on the peripheral wall portion 92 as viewed from above. It forms an arc along the outer periphery.
In the circumferential direction around the axis X, both end portions 951a1 in the longitudinal direction of the concave groove 951a are located on the diameter line Lm1 side passing through the axis X from both end portions 951b in the longitudinal direction of the upper wall portion 951. For this reason, the circumferential length of the concave groove 951a is shorter than the circumferential length of the upper wall portion 951, and both end portions in the width direction of the upper wall portion 951 engage with a locking portion 971b of the cap 96 described later. It becomes the latching | locking part 951c to stop.

  Further, a step portion 954 is formed on the outer surface of the side wall portion 952 in the circumferential direction around the axis X at a position offset inward from the outer peripheral portion 953 of the side wall portion 952, and more than the step portion 954 in the side wall portion 952. On the outer peripheral portion 953 side, a fitting wall portion 98 of a cap 96 which will be described later is an inner fitting wall portion 955 that fits in an inlay shape.

  Here, an outer fitting wall portion 990 of the cap 96 to be described later comes into contact with the step portion 954 from the axial direction of the axis X, and this step portion 954 is formed from the upper edge portion 953a of the outer peripheral portion 953. Also, the lower portion is parallel to the upper edge portion 953a in the direction orthogonal to the axis X, and the peripheral wall portion 92 side of the outer peripheral portion 953 is parallel to the edge portion 953b. A step portion 954b extending in the axis X direction, a step portion 954c extending below the edge portion 953c of the outer peripheral portion 953 in parallel with the edge portion 953c, and between the step portion 954c and the step portion 954b. And a step portion 954d extending downward.

The terminal support portion 940 connected to the lower end of the side wall portion 952 is disposed with its upper surface (support surface 940b) orthogonal to the axis X, and the support surface 940b of the terminal support portion 940 is a connector. The upper end 943a of the outer wall portion 943 of the portion 94 is positioned above the cover portion 91 by a predetermined height h2 (see FIG. 6).
A side edge 940c on the outer diameter side of the terminal support portion 940 is located on the radially inner side with respect to the outer wall portion 943 on the outer diameter side of the connector portion 94, and a contact portion 974 of the cap 96 to be described later contacts. It is a contact surface.

FIG. 8 is a diagram illustrating the cap 96.
The cap 96 seals the opening 930 of the connector cover portion 93. In the connector cover portion 93, the opening 930 is surrounded by the upper wall portion 951, the side wall portions 952 and 952, and the terminal support portion 940. (See FIG. 6A).
The cap 96 has a wall portion 97 that closes the opening 930 of the connector cover portion 93, and fitting wall portions 98 that are externally fitted to the side wall portions 952 and 952 are formed on both sides in the width direction of the wall portion 97. Is provided.

As shown in FIG. 4, the wall portion 97 includes an engaging portion 971 that is engaged with the upper wall portion 951 from above, an inclined portion 972 that extends obliquely downward from the engaging portion 971, and a lower end of the inclined portion 972. And a cover portion 973 extending linearly downward.
In the wall portion 97, the locking portion 971 extends linearly in a direction perpendicular to the axis X, and the upper surface 971 c of the locking portion 971 is lower than the upper surface 91 d of the cover portion 91 of the upper cover member 90. positioned. At the tip of the locking portion 971, a locking portion 971a that is locked in the groove 951a of the upper wall portion 951 is provided over the entire length in the width direction of the locking portion 971. 971a extends downward along the axis X direction.

As shown in FIGS. 8B and 8C, on both sides of the locking portion 971a in the longitudinal direction, locking portions 971b locked to the locking portions 951c of the upper wall portion 951 are provided. The cap 96 is provided by locking the locking portion 971b and the locking portion 971a to the upper wall portion 951.
Therefore, the cap 96 is prevented from falling off (disconnecting in the radial direction) from the connector cover 93 by the locking portion 971b and the locking portion 971a locked to the upper wall portion 951. .

  At the lower end of the cover portion 973, a thin contact portion 974 is provided over the entire length in the width direction. This contact portion 974 is formed when the cap 96 is assembled to the connector cover portion 93. The lower end surface 974a is brought into contact with the upper end 943a of the outer wall portion 943 of the connector portion 94 from the axial direction of the axis X, and the inner side surface 974b is brought into contact with the side edge 940c on the outer diameter side of the terminal support portion 940. (See FIG. 4B).

The fitting wall portions 98 are provided on both sides of the wall portion 97 in the width direction, and are provided in a range from the contact portion 974 to the locking portion 971 along the longitudinal direction of the wall portion 97.
In the side view, the front end side of the fitting wall portion 98 has a shape (see FIG. 6B) that matches the side surface shape of the step portion 954 provided on the outer periphery of the side wall portion 952. A contact portion 981a that contacts the step portion 954a from the axial direction of the axis X, a contact portion 981b that contacts the step portion 954b, a contact portion 981c that contacts the step portion 954c from the axial direction of the axis X, and a step portion A contact portion 981d that contacts 954d.

  On the inner side surface of the fitting wall portion 98, a step portion 99 is provided at a position offset inward from the outer peripheral portion 981 of the fitting wall portion 98. The step portion 99 has a shape that matches the side shape of the inner fitting wall portion 955 of the side wall portion 952, and the outer peripheral portion 981 side of the fitting wall portion 98 is closer to the inner side of the side wall portion 952 than the step portion 99. It becomes the outer fitting wall part 990 which fits the fitting wall part 955 in an inlay shape.

  FIG. 9 is a view for explaining a fitting structure between the outer fitting wall portion 990 on the cap 96 side and the inner fitting wall portion 955 on the housing portion 95 side in the connector cover portion 93. The perspective view of the connector cover part 93, (b) is CC sectional drawing in (a), (c) is BB sectional drawing in (a), (d) is AA in (a). It is sectional drawing. 9B, 9C, and 9D show a state in which each step surface is viewed from the right side (the outside in the radial direction of the axis X) in FIG.

As described above, when the cap 96 is assembled to the accommodating portion 95 of the connector cover portion 93, the outer fitting wall portion 990 on the cap 96 side is fitted on the outer periphery of the inner fitting wall portion 955 on the accommodating portion 95 side. It is supposed to be.
Here, when water or the like is applied from the outside to the connector cover portion 93, water or the like enters the cap 96 and the housing portion 95 exposed from the outer periphery of the connector cover portion 93 and the joint portion.
Here, since the valve drive device 1 according to the embodiment is a valve drive device of a valve device that opens and closes the refrigerant flow path of the refrigerator, the water used for the connector cover 93 is used, for example, in a kitchen. Water that has been removed and water excreted by pets kept indoors can be considered.

When such moisture enters the cap 96 exposed from the outer periphery of the connector cover portion 93, the accommodating portion 95, and the joint portion, as shown in FIGS. 9B and 9D, the step portion 954a of the side wall portion 952 is provided. , 954c, the contact portions 981a and 981c of the outer fitting wall portion 990 of the fitting wall portion 98 are in contact with each other from the axial direction of the axis X, and are indicated by arrows in the figure due to capillary action or the like. Moisture may move in the direction (the direction toward the inside of the connector cover portion 93).
However, an inner fitting wall portion 955 is erected on the inner side of the joint portion, and the movement of moisture in the direction indicated by the arrow in the figure is blocked by the inner fitting wall portion 955. Moisture that has entered from the joint between the step portions 954 a and 954 c and the contact portions 981 a and 981 c of the outer fitting wall portion 990 does not enter the inside of the connector cover portion 93 as it is.

Here, since the step portion 954c of the side wall portion 952 is inclined with respect to the axis X (see FIG. 6B), the step portion 954c and the contact portion 981c of the outer fitting wall portion 990 are in contact with each other. Moisture that has entered the joint moves in the direction indicated by arrow A1 in FIG. 9A, and is finally discharged from the space between the cap 96 and the housing portion 95 to the outer wall portion 943 side of the connector portion 94. Will be.
Here, since the support surface 940b of the terminal support portion 940 disposed adjacent to the outer wall portion 943 is located above the upper end 943a of the outer wall portion 943 (see FIG. 6B), this discharge Thus, the water portion is prevented from contacting the connector terminal 61 supported by the terminal support portion 940.
Note that between the outer peripheral portion 981 and the step portion 954 (between the step portion 954a and the contact portion 981a, between the step portion 954b and the contact portion 981b, between the step portion 954c and the contact portion 981c, and between the step portion 954d and the step portion 954d. If moisture exists (wet) between the contact portions 981d), the moisture may move downward along the periphery 981 and the step portion 954.

Here, as shown in FIGS. 9B to 9D, in the portion where the inner fitting wall portion 955 and the outer fitting wall portion 990 are fitted, the inner fitting wall portion 955 and the outer fitting wall are provided. Capillary force also acts on the gap Sx extending in the vertical direction along the joint surface of the portion 990.
Therefore, when moisture that has entered from the joints between the step portions 954a, 954c, and 954d of the inner fitting wall portion 955 and the contact portions 981a, 981c, and 981d of the outer fitting wall portion 990 reaches the gap Sx, Possibility of moving to the upper side in the drawing in the gap Sx and reaching the gap Sy at the portion where the step portion 99 of the outer fitting wall portion 990 and the edges 953a, 953b, and 953c of the inner fitting wall portion 955 face each other There is.

In the embodiment, the inner peripheral side surface 98a of the stepped portion 99 (the inner peripheral surface of the fitting wall portion 98) and the inner peripheral surface 955d of the inner fitting wall portion 955 are flush with each other. Therefore, even if the moisture that has reached the gap Sy enters the right side (inside of the connector cover portion 93) in the drawing, the surface tension acts and is retained in the gap Sy. Intrusion of moisture is prevented.
Incidentally, when the side surface 98a and the inner peripheral surface 955d are not flush with each other, a step for forming a water pool is formed at the boundary portion, and after the water accumulated in the step grows, the connector cover is formed. There is a risk of dropping (penetrating) into the inside of the portion 93.

Further, as shown in FIG. 9 (c), gravity acts on the moisture that has entered the joint portion between the step portion 954b and the outer fitting wall portion 990 at the portion along the step portion 954b in the inner fitting wall portion 955. Thus, the infiltrated moisture may move downward in the direction of gravity (in the direction of arrow A2 in the figure).
Then, when the moisture moves in the direction indicated by the arrow A2 in the figure, the moved moisture contacts the stepped portion 954d of the side wall portion 952 with the contact portion 981d of the outer fitting wall portion 990 from the axial direction of the axis X. It will be discharged | emitted from the junction part which has contact | connected to the outer peripheral surface of the side wall part 952 (refer Fig.9 (a) and arrow A3).

In addition, moisture (see arrow A4 in the figure) that has entered the gap between the locking portion 971 of the cap 96 and the peripheral wall portion 92 of the upper cover member 90 is caused by the concave groove 951a (see FIG. Through a) see), the groove 951a is discharged laterally from both end portions 951a1 in the longitudinal direction.
Here, since both end portions 951a1 of the recessed groove 951a communicate with the above-described upper edge portion 953a, the moisture discharged from the recessed groove 951a is in contact with the contact portion 981a of the outer fitting wall portion 990 and the inner fitting. The joint wall portion 955 is discharged to the outside through a joint portion with the step portion 954a.

Returning to the description of the cap 96, as shown in FIG. 8, on the outer surface of the contact portion 982 of the fitting wall portion 98 with the side surface of the locking portion 971, 985 is provided.
The engaging portion 985 is a plate-like member that protrudes downward from the abutting portion 982, and an opening 986 is formed in the center portion along the longitudinal direction.
Both side portions of the opening 986 are arm portions 985a and 985a, and the end portions of the arm portions 985a and 985a are connected by an engaging portion 985b.
When the cap 96 is assembled to the housing portion 95 of the connector cover portion 93, the engaging portion 985 b is locked to the locking projection 956 (see FIG. 3) provided on the side wall portion 952, thereby The drop-off from 95 is prevented.

Next, the valve unit 70 driven by the motor M will be described.
FIG. 10 is an exploded perspective view of the lower cover member 80, the valve unit 70, the base member 86, and the motor M in the valve drive device 1. FIG. 11 is an exploded perspective view showing the gear 71 and the valve body 72 of the valve unit 70.

The valve unit 70 of the valve driving device 1 is a member that is rotationally driven around the axis X2 (see FIG. 10) by the motor M, and includes a gear 71 and a valve body 72.
The gear 71 is an external gear that meshes with a tooth portion 33 c provided on the outer periphery of the transmission shaft 33 of the motor M. As shown in FIG. 11, a circular hole 71a is formed at the center of the gear 71. On the bottom surface of the gear 71, there are a central protrusion 71b and a plurality of (around the central protrusion 71b). In this embodiment, three) projections 71c are formed.

The valve body 72 is a member having a substantially disk shape. A circular hole 72a is formed in the center of the valve body 72, and the upper surface of the valve body 72 is arranged around the hole 72a. One hole 72b and two recesses 72c are formed.
A cutout 72 d is formed on the bottom surface of the valve body 72. A portion of the bottom surface of the valve body 72 where the notch 72d is not formed is configured to be able to close the openings 3a and 4a (see FIG. 10) of the fluid outlet tubes 3 and 4.

The gear 71 and the valve body 72 are fixed to each other by inserting the center protrusion 71b and the three protrusions 71c of the gear 71 into the hole 72a, the one hole 72b, and the two recesses 72c of the valve body 72, respectively. ing.
The gear 71 and the valve body 72 are rotatably supported by a shaft member 73 (see FIG. 10) through which the hole 71a and the hole 72a are inserted, and as shown in FIG. The lower end 73b is held in a state in which the lower end 73b is prevented from rotating by the support hole 89a of the base member 86 and the hole portion 15a of the connection member 15 fixed to the bottom plate portion 10.

The connecting member 15 is provided by being inserted into a through hole 10 c provided in the bottom plate portion 10 from the lower side opposite to the motor M.
A hole 15a for supporting the shaft member 73 is formed at the center of the connection member 15 so as to open to the fluid chamber S side. In the connection member 15, a position on the radially outer side of the hole 15a. In FIG. 10, the opening 3a of the fluid outlet tube 3 and the opening 4a of the fluid outlet tube 4 are located (see FIG. 10).
The fluid outlet pipes 3 and 4 are each provided so as to penetrate the connecting member 15 in the direction of the axis X, and communicate with a fluid chamber S formed above the bottom plate part 10.

  In the bottom plate portion 10, a through hole 10 d is provided at a position opposite to the through hole 10 c across the central hole portion 10 a, and the fluid introduction pipe 2 is fitted into the through hole 10 d. In this state, the opening 2 a of the fluid introduction pipe 2 is opened in the fluid chamber S, and the fluid introduction pipe 2 is communicated with the fluid chamber S.

As shown in FIG. 10, a base member 86 is placed on the upper surface 10 b (see FIG. 1) of the bottom plate portion 10, and the base member 86 is below the peripheral portion of the base portion 87 and the base portion 87. And a plurality of leg portions 88 (88a, 88b) extending to the side.
In the base portion 87, a hole portion 87a through which the transmission shaft 33 is inserted is formed in the central portion thereof, and an arm portion 89 including a support hole 89a is formed around the axis X on the radially outer side of the hole portion 87a. Are provided along the circumferential direction.

In the embodiment, when the partition wall 20 is fixed to the bottom plate portion 10, the bottom plate portion 10 reaches a position where the disk portion 203 of the partition wall 20 contacts the base portion 87 and the leg portion 88 a contacts the bottom plate portion 10. It is designed to push down on the side.
At this time, since the leg portion 88b is provided so as to protrude radially outward from the leg portion 88a, the base member 86 is in a state in which the leg portion 88b is pressed against the inner periphery of the large-diameter portion 202 of the partition wall 20. It is held in the partition wall 20.

  Moreover, the arm part 89 which supports the shaft member 73 of the valve part 70 can be deformed in the axial direction independently of the base part 87, and when the base member 86 is pushed downward on the bottom plate part 10 side. The valve body 72 is urged downward on the bottom plate 10 side. Therefore, the valve body 72 of the valve portion 70 is always brought into contact with the upper surface of the bottom plate portion 10 by the arm portion 89 and is positioned in the axial direction.

As shown in FIG. 2, a lower cover member 80 is externally fixed to the large diameter portion 202 of the partition wall 20 fixed to the upper surface of the bottom plate portion 10.
The lower cover member 80 is provided with an opening 81a into which the large-diameter portion 202 of the partition wall 20 is inserted at the center of the plate-like base portion 81. The inner periphery of the opening 81a faces upward in the axis X direction. A plurality of erected contact pieces 81b are provided in the circumferential direction around the axis X.
Each of the contact pieces 81b is provided so as to bulge from the opening 81a toward the axis X, and can be elastically deformed radially outward of the axis X.
Therefore, when the lower cover member 80 is attached to the large-diameter portion 202 of the partition wall 20 by being extrapolated, the large-diameter portion 202 is inserted into the opening 81a of the base 81 while spreading the contact piece 81b radially outward. The lower cover member 80 is fixed to the partition wall 20.

  As shown in FIG. 10, a mounting portion 85 formed by bending toward the lower side in the axis X direction is provided on one side of the base portion 81 in the width direction. The attachment portion 85 is provided to attach the valve driving device 1 to a refrigerator that is an external structure, and is provided over the entire length of the base portion 81 in the longitudinal direction. The attachment portion 85 is formed with a hole portion 85a through which a screw or the like is inserted. In order to avoid interference between the fluid introduction pipe 2 and the fluid outlet pipe 3, the hole 85a is formed in the radial direction of the axis X in FIG. It is located radially outside the fluid outlet tube 3.

As shown in FIG. 10, reinforcing walls 82 and 83 formed by bending toward the upper side in the axis X direction are provided on both sides in the longitudinal direction of the base 81. The reinforcing walls 82 and 83 are provided over the entire length of the base 81 in the width direction, and the upper cover member 90 (see FIG. 3) is placed on the upper ends 82a and 83a of the reinforcing walls. ing.
In the embodiment, as shown in FIGS. 1 and 3, the coil terminal 56 is positioned above the reinforcing wall 82 on one side, and the lower cover member 80 and the upper cover wall 83 are placed on the reinforcing wall 83 on the other side. An engagement arm 84 for holding the cover member 90 in an engaged state is provided.

In the reinforcing wall 82, the engaging arm 84 is provided so as to extend from a substantially central portion in the width direction in a direction away from the base 81 (upward), and at the upper end side of the engaging arm 84 swell toward the axis X side. An engaging portion 84a is provided.
The engaging portion 84a is adapted to engage with the engaged portion 922 of the upper cover member 90 when the upper cover member 90 is attached by being extrapolated to the outer stator core 59 of the motor M. The falling of the cover member 90 from the lower cover member 80 is prevented.

In the lower cover member 80 according to the embodiment, the reinforcing walls 82 and 83 are bent in the direction (upward) opposite to the bending direction (downward) of the attachment portion 85 in the axial direction of the axis X. The bending rigidity of the base portion 81 of 80 is increased.
This is because when the lower cover member 80 is attached to the large-diameter portion 202 of the partition wall 20 by extrapolation (press-fit), the large-diameter portion 202 pushes the contact piece 81b outward in the radial direction, and the opening 81a of the base 81 is opened. This is because the lower cover member 80 is inserted into the partition wall 20 and is fixed to the partition wall 20, so that the base 81 is not greatly deformed by the stress at this time.
Here, in the lower cover member 80 of the embodiment, since the reinforcing walls 82 and 83 on both sides in the longitudinal direction are bent in the same upward direction, the reinforcing walls 82 and 83 and the mounting portion 85 are connected by bending. The forming process can be performed more easily than when the reinforcing walls 82 and 83 are bent in different directions (vertical directions) in the axial direction of the axis X.

Hereinafter, an example of the operation of the valve driving device 1 will be described with reference to FIG.
FIG. 12 is a view for explaining the operation of the valve drive device 1, and shows the fluid outlet pipes 3 and 4 by phantom lines when the valve body 72 is viewed from the lower cover member 80 side. a) shows a closed state in which both of the fluid outlet pipes 3 and 4 are closed by the valve body 72, and (b) shows a first closed state in which the fluid outlet pipe 4 is closed by the valve body 72, (C) shows a second valve closed state in which both of the fluid outlet pipes 3 and 4 are opened, and (d) shows a third valve closed state in which the fluid outlet pipe 3 is closed by the valve body 72. FIG.

In the valve drive device 1, the coil 34 of the stator assemblies 50 </ b> A and 50 </ b> B is excited by energizing the coil 34 via the connector terminal 61 (61 a to 61 e), the substrate 60, and the coil terminal 56, and the rotor 30 is rotated by the magnetic force. Let
The rotation of the rotor 30 is transmitted to the valve body 72 via the tooth portion 33c of the transmission shaft 33, and the valve body 72 is rotationally driven around the axis X2.

<Valve closed state>
As shown in FIG. 12A, in a state where the notch 72d is at a position other than the fluid outlet pipes 3 and 4, the valve body 72 is in a closed state (fully closed) that closes the fluid outlet pipes 3 and 4. , The derivation of the fluid from the fluid chamber S to the fluid outlet pipes 3 and 4 is blocked.

<First valve open state>
As shown in FIG. 12B, when the gear 71 and the valve body 72 rotate clockwise from the valve-closed state and the notch 72d reaches the position of the fluid outlet pipe 3, the valve body 72 is connected to the fluid outlet pipe. 3 is opened, and the fluid outlet pipe 4 is closed (partially open). The fluid from the fluid chamber S to the fluid outlet pipe 3 is allowed to flow out, and the fluid outlet pipe 4 Fluid derivation is blocked.

<Second valve open state>
As shown in FIG. 12C, when the gear 71 and the valve body 72 further rotate clockwise from the first valve open state and the notch 72d reaches the position of the fluid outlet pipes 3 and 4, the valve body Reference numeral 72 denotes a second valve open state (fully opened) in which the fluid outlet pipes 3 and 4 are opened, and fluid discharge from the fluid chamber S to the fluid outlet pipes 3 and 4 is permitted.

<Third valve open state>
As shown in FIG. 12 (d), when the gear 71 and the valve body 72 further rotate clockwise from the second valve open state, and the notch 42 d passes the position of the fluid outlet pipe 3, the valve body 72. Is a third valve open state (partially open) in which the fluid outlet tube 3 is closed and the fluid outlet tube 4 is opened, and the fluid from the fluid chamber S to the fluid outlet tube 3 is blocked and fluid The fluid can be led out to the outlet pipe 4.

As described above, in the embodiment, the stator assembly 40 (stator) having the coil 54 (driving coil) has the peripheral wall portion 92 (peripheral wall) covering the outer periphery of the stator assembly 40 in the upper cover member 90 (main body cover). Are located in
A coil terminal 56 to which an end of the coil 54 is connected extends radially outward from the stator assembly 40 through an opening 92a provided in the peripheral wall 92, and is connected to the connector terminal 61 in the peripheral wall surrounding the opening 92a. In the motor M that is connected and sealed with the cap 96 (sealing member) having a fitting wall portion 98 that fits around the peripheral wall portion, the opening 92a is sealed.
The peripheral wall portion includes an upper wall portion 951 provided along the upper side 92a1 of the opening portion 92a, side wall portions 952 and 952 extending downward from both ends of the upper wall portion 951 along the side side 92a2 of the opening portion 92a, and side walls. A terminal support portion 940 for connecting the lower portions of the portions 952 and 952 to each other;
On the outer periphery of the side wall portions 952 and 952, a step portion 954 is provided for abutting the tip (abutting portion 981) of the fitting wall portion 98 of the cap 96;
In the fitting direction of the cap 96 with respect to the side wall portions 952 and 952, a cover structure in the motor having a configuration in which the position of the stepped portion 954 is offset from the position of the front end portion (outer peripheral portion 953) of the side wall portion 952 is adopted.

The position of the step portion 954 with which the contact portion 981 of the fitting wall portion 98 of the cap 96 abuts and the outer peripheral portion 953 of the side wall portion 952 with which the fitting wall portion 98 is fitted externally are caps for the side wall portions 952 and 952. Since the offset is 96 in the fitting direction, moisture enters from the contact surface between the contact portion 981 of the fitting wall portion 98 and the step portion 954 of the side wall portion 952 toward the inside of the side wall portion 952. However, the infiltrated moisture cannot enter the inside of the side wall portion 952 unless it moves between the side wall portion 952 and the fitting wall portion 98 in the fitting direction.
Therefore, it is possible to prevent moisture from entering the peripheral wall portion (upper cover member 90) without separately providing a sealing member such as an O-ring.

  A peripheral wall 92 surrounding the opening 92a is open to the outside in the radial direction of the stator assembly 40, and the coil terminal 56 is connected to the connector terminal 61 via the flexible printed circuit board 60 in the peripheral wall 92. The coil terminal 56 and the connector terminal 61 are connected to the opening side surface of the peripheral wall portion 92 of the printed circuit board 60 by soldering.

If comprised in this way, in the surrounding wall part 92 opened to the radial direction outer side of the stator assembly 40, the connection part of the coil terminal 56 and the printed circuit board 60 of the connector terminal 61 becomes visible from the radial direction outer side, and a coil terminal The connection operation (soldering operation) between the connector terminal 61 and the printed circuit board 60 of the connector terminal 61 can be easily performed.
In this state, the upper wall portion 951 of the peripheral wall portion 92 is positioned above the soldering position. However, even if water is splashed above the upper wall portion 951 of the upper cover member 90, the cap 96 is not limited to the peripheral wall portion. Since it is provided so as to be fitted around 92, moisture does not enter the peripheral wall portion 92 and adhere to the connection portion between the coil terminal 56 and the printed circuit board 60 of the connector terminal 61.

  In the terminal support portion 940 located on the lower side in the installation direction of the valve driving device 1, the contact portion 974 of the cap 96 is below the support surface 940 b that is the upper surface of the terminal support portion 940. It was set as the structure contact | abutted to the side edge 94c.

  When moisture that has entered between the side wall portion 952 and the fitting wall portion 98 passes between the side wall portion 952 and the fitting wall portion 98 or between the outer peripheral portion 981 and the step portion 954. May move toward the terminal support portion 940 located on the lower side in the installation direction of the valve driving device 1 (motor M) along the joint portion between the outer peripheral portion 981 and the step portion 954. If comprised as mentioned above, it can prevent suitably that the moved water | moisture content permeates into the opening part 92a side from the part of the terminal support part 940. FIG.

The side wall portions 952 located on both sides in the installation direction of the valve driving device 1 (motor M) have a bulging portion 952c serving as a rib for supporting a terminal support portion 940 that is a support member of the connector terminal 61 on the lower side thereof. The step portion 954 extends to the portion of the bulging portion 952c in the side wall portion 952,
In the terminal support portion 940, the connector terminal 61 is connected to the coil terminal 56 via a flexible substrate 60 (printed substrate).
The bulging portion 952c is configured to have a height that extends upward from the connection position (soldering position) between the connector terminal 61 supported by the terminal support portion 940 and the substrate 60.

With this configuration, it is possible to prevent moisture from entering the terminal support portion 940 and preventing moisture from adhering to the connection portion between the connector terminal 61 and the substrate 60 and the substrate 60, so that a short circuit may occur. It can prevent suitably.
Since it is possible to prevent moisture from entering the terminal support portion 940, a gap is provided on the side of the substrate 60 placed on the terminal support portion 940 in preparation for the case where moisture enters as in the prior art. There is no need to prevent moisture from immediately contacting the substrate. Accordingly, the side wall portions 630 (ribs) are arranged in the vicinity of the connector terminals 61 in the circumferential direction around the rotation axis of the rotor 30, and the separation between the side wall portions 630 and 630 located at both ends in the longitudinal direction of the terminal support portion 940 Since the distance can be reduced, the size of the connector cover 93 that protects the connector terminal 61 in the circumferential direction can be suppressed.

  In the upper wall portion 951 located on the upper side in the installation direction of the valve driving device 1 (motor M), a concave groove along the outer periphery of the peripheral wall portion 92 is located between the upper wall portion 951 and the peripheral wall portion 92 on the inner diameter side. In the circumferential direction around the axis X, both end portions 951a1 in the longitudinal direction of the recessed groove 951a extend radially on both sides of the upper wall portion 951 among the step portions 954 provided in the side wall portion 952. It was set as the structure connected to the step part 954a.

Since the engaging portion 971 of the cap 96 is engaged with the recessed groove 951a of the upper wall portion 951, moisture enters the recessed groove 951a from between the upper wall portion 951 and the engaging portion 971 of the upper cover member 90. There are things to do.
Since both end portions 951a1 in the longitudinal direction of the concave groove 951a communicate with the step portion 954a provided in the side wall portion 952, the water accumulated in the concave groove 951a is finally provided in the step portion provided in the side wall portion 952. It will be discharged into 954a.
The moisture discharged into the step portion 954a of the side wall portion 952 is discharged downward through the interface between the side wall portion 952 and the fitting wall portion 98 fitted on the side wall portion 952.
Therefore, it is possible to suitably prevent moisture that has entered from between the upper wall portion 951 and the locking portion 971 from entering the inside.

  As mentioned above, although embodiment of this invention was described, this invention is not limited to the said embodiment, In the range which does not deviate from the summary of this invention, it can change suitably. For example, the valve drive device of the present invention can be applied to a flow path for fluid other than the refrigerant of the refrigerator, and the structure for opening / closing the valve by the valve body 72 can be changed as appropriate.

DESCRIPTION OF SYMBOLS 1 Valve drive device 2 Fluid introduction pipe 3, 4 Fluid lead-out pipe 40 Stator assembly 50A Stator assembly 50B Stator assembly 51, 52 Inner stator core 54 Coil 55 Terminal holding part 56a Coil terminal 59 Outer stator core 60 Printed circuit board (board)
61 connector terminal 65 coil terminal 90 upper cover member 91 cover portion 92 peripheral wall portion 92a opening 93 connector cover portion 94 connector portion 95 housing portion 96 cap 97 wall portion 98 fitting wall portion 940 terminal support portion 940a taper portion 940b support surface 940c Side edge 941 Peripheral wall portion 942 Side wall portion 943 Outer wall portion 943a Upper end 944 Inner wall portion 945 Connection beam 945a Inclined surface 955 Inner fitting wall portion 990 Outer fitting wall portion

Claims (5)

A cover structure in a valve element driving motor of a valve device that opens and closes a refrigerant flow path of a refrigerator,
A stator having a drive coil is disposed in a main body cover having a peripheral wall covering the outer periphery of the stator,
A coil terminal to which an end of the drive coil is connected extends radially outward from the stator through an opening provided in the peripheral wall, and is connected to a connector terminal in the peripheral wall surrounding the opening,
In the motor that is configured to seal the opening of the peripheral wall portion with a sealing member having a fitting wall that is fitted on the peripheral wall portion,
Provided on the outer periphery of the peripheral wall portion is a stepped portion that contacts the tip of the fitting wall portion;
A cover structure for a motor, wherein a position of the stepped portion is offset from a position of a distal end portion of the peripheral wall portion in a fitting direction of the fitting wall with respect to the peripheral wall portion. The peripheral wall portion surrounding the opening portion is open to the radially outer side of the stator,
In the peripheral wall portion, the coil terminal is connected to the connector terminal via a flexible substrate,
The cover structure in the motor according to claim 1, wherein the coil terminal and the connector terminal are connected to a surface of the substrate on the opening side of the peripheral wall portion by soldering.   3. The motor according to claim 1, wherein the fitting wall portion is fitted to a lower side surface of the peripheral wall portion in the lower peripheral wall portion in the installation direction of the motor. Cover structure. The peripheral wall portion located on both sides in the motor installation direction has a lower portion also serving as a rib for supporting the support member of the connector terminal, and the stepped portion extends to the rib portion of the peripheral wall portion. And
In the support member, the connector terminal is connected to the coil terminal via a connection member,
The said rib is formed in the height which extends above the connection position of the connector terminal supported by the said supporting member, and the said connection member, The any one of Claims 1-3 characterized by the above-mentioned. The cover structure in the motor according to one item. In the peripheral wall portion located on the upper side in the installation direction of the motor, a groove is provided along the peripheral wall on the peripheral wall side of the upper surface of the peripheral wall portion,
Either end in the longitudinal direction of the groove communicates with an upper end of a step portion of the circumferential wall portion located on both sides of the circumferential wall portion located on the upper side, respectively. The cover structure in the motor according to one item.

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