JP2007303684A - Electric flow control valve - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an electric flow control valve with a connector protruding sidewise which is compact as a whole, by solving a problem in which an electric flow control valve requires a large space because of its structure for wiring an electric wire at right angles to the electric flow control valve. <P>SOLUTION: The electric flow control valve has a can fixed to a valve main body part, a mold body attached on an outer circumference face of the can in which a stator yoke and a magnet wire are molded with resin, a rotor provided in the can and electromagnetically rotated by the mold body and a valve element for opening and closing a fluid in/out port formed in a valve chamber in the valve main body part by moving up and down by the rotation of the rotor. A connector housing with a motor connector and a connector pin in it and a connector of the electric wire side connected with the motor connector and the connector pin are provided at a side part of the mold body. A sidewise connection part is formed for the connector and an electric wire draw-out part is formed downward at approximately right angles to the sidewise connection part. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to an electric flow control valve used by being incorporated in a refrigeration cycle such as a heat pump air conditioner or a freezer.

  FIG. 7 shows a conventional electric flow control valve 100. The electric flow control valve 100 includes a stepping motor 2, a valve body 3, and a valve body 5, and the stepping motor 2 is attached to the outer periphery of a cylindrical can 7. A flange member 6 that is expanded outward is provided at the upper portion of the valve body 3, and the flange 7 a of the can 7 is connected and fixed to the flange 6 a of the flange member 6. A stator yoke 8 is integrally inserted into the outer periphery of the can 7. A bobbin 9 is disposed in the stator yoke 8, and a magnet wire 10 that is energized from the outside is wound around the bobbin 9.

The outer circumferences of the stator yoke 8, bobbin 9 and magnet wire 10 are sealed with a mold 11. A rotor 12 made of a magnet fixed to a sleeve 29 described later is disposed inside the can 7.
On the upper part of the mold 11, a press locking tool 14 having a locking projection 15 is provided. A concave portion 16 is formed on the outer periphery of the can 7, and the locking convex portion 15 is fitted into the concave portion 16 so that the mold 11, the stator yoke 8, the bobbin 9 and the magnet wire 10 can be positioned and retained. It has become.
A motor connector 39 having connector pins 39 a is provided on one side of the mold 11. A connector 56 is inserted into the motor connector 39 and the stepping motor 2 is energized via the electric wire 62.

  The valve main body 3 has a valve chamber 17, a fluid inlet / outlet 19 is opened at a side of the valve chamber 17, and a conduit 18 communicating with the valve chamber 17 is connected to the fluid inlet / outlet 19. Yes. A fluid inlet / outlet 21 opened and closed by the valve body 5 is opened at the lower part of the valve chamber 17, and a conduit 20 communicating with the valve chamber 17 through the fluid inlet / outlet 21 is connected. A resin lid 33 is fixed in the valve portion 3 above the valve chamber 17, and a guide bush 23 is fitted and fixed to the resin lid 33 so as to hang down in the valve chamber 17. A female screw portion 22 is threaded on the inner peripheral portion of the guide bush 23. The resin lid 33 is provided with a stopper 31 so as to come into contact with a movable side stopper 28 at a lower end of a sleeve 29 described later.

A male threaded portion 25 threaded on the outer periphery of the holder 24 is screwed into the female threaded portion 22 of the guide bush 23, and a valve body 5 with a flange 5a is slidably fitted into the inner peripheral lower portion of the holder 24. ing. A collar 26 that receives the flange 5 a of the valve body 5 is press-fitted and fixed to the lower part of the holder 24, and the valve body 5 is always urged downward by a compression coil spring 27 that is mounted in the holder 24.
The holder 24 is fixed to a sleeve 29 fitted inside the cylindrical rotor 12. A return coil spring 70 is provided between the upper end portion of the sleeve 29 and the can 7.

Since the conventional electric flow control valve 1 is configured as described above, when the fluid inlet / outlet 21 is closed, the magnet wire 10 is energized and excited in one direction, and the rotor 12, sleeve 29, valve shaft 4 and holder 24 are energized. Rotate together. As a result, the valve body 5 is lowered by screw feed by screwing between the female screw portion 22 and the male screw portion 25, and the fluid inlet / outlet 21 is closed by the valve body 5.
When the fluid inlet / outlet 21 is closed, the movable side stopper 28 is not in contact with the fixed side stopper 31, and the holder 24 further rotates and descends while the valve body 5 closes the fluid inlet / outlet 21. At this time, the lowering amount of the holder 24 with respect to the valve body 5 is absorbed by the compression coil spring 27 compressing, and when the holder 24 is further rotated down, the movable side stopper 28 comes into contact with the fixed side stopper 31. Thereby, even if energization excitation to the rotor 12 is continued, the rotational lowering motion of the sleeve 29, the valve shaft 4, and the holder 24 is forcibly stopped.
When opening the fluid inlet / outlet 21, the magnet wire 10 is energized and excited in the other direction, and the rotor 12, the sleeve 29, the valve shaft 4, and the holder 24 are reversely rotated, whereby the female screw portion 22 and the male screw portion 25 are screwed together. The valve body 5 is raised by the screw feed according to, and the fluid inlet / outlet 21 is opened.

By the way, since the electric flow control valve 100 as proposed above has a structure in which the can 7 is connected by the flange 6a via the flange member 6 expanded in the outward direction, the outer diameter of the can 7 is necessarily increased. There were drawbacks. In addition, the electric flow control valve 100 with the connector 56 projecting laterally has a structure in which the electric wire 62 is wired in a direction perpendicular to the electric flow control valve 100, so that the space of the electric flow control valve 100 increases as a whole. There was a problem.
The present invention has been made in view of the above-described problems, and an object of the present invention is to provide an electric flow control valve that has a can having the same diameter as that of the valve main body and is miniaturized as a whole.

  In order to achieve the above object, an electric flow control valve according to the present invention is a mold in which a can fixed to a valve main body, an outer peripheral surface of the can, and a stator yoke and a magnet wire are molded with a resin. A body, a rotor disposed in the can and electromagnetically rotated by the mold body, and a valve body that moves up and down by the rotation of the rotor and opens and closes a fluid inlet / outlet formed in a valve chamber in the valve main body. And a connector housing having a motor connector and a connector pin therein, and a connector on the electric wire side connected to the motor connector and the connector pin are provided on the side of the mold body, and the connector Is characterized in that a lateral connection portion is formed and a wire lead-out portion is formed in a downward direction substantially perpendicular to the lateral connection portion.

  In the electric flow control valve according to the present invention, a box-shaped cover having one side surface and a lower surface opened is attached to the outside of the connector housing and the connector, and the cover of the cover on the connector housing side is mounted. The inner surface is integrally provided with ribs formed with locking claws at both lower ends locked in the grooves of the connector housing, and the inner space of the cover is sealed with resin. Yes.

  Furthermore, in the electric flow control valve according to the present invention, the connector housing is integrated with the mold body and accommodates the connector inside, and a lower portion is opened and a lid is formed on the front surface. Is sealed with resin.

Since the electric flow control valve of the present invention has the same diameter as that of the valve main body, no mounting flange is required, and there is no protrusion to the side of the can and the valve main body. In addition, an electric flow control valve having an excellent appearance can be obtained.
In addition, since the connector having a structure in which the connection portion to the motor connector and the wire lead-out portion form a substantially right angle, the wire can be arranged in parallel with the can, and the wiring space can be reduced.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.
In the description of the embodiments, the same reference numerals are given to those having the same functions as the conventional example.
An electric flow control valve 1 shown in FIG. 1 includes a stepping motor 2, a valve body 3, and a valve body 5, and the stepping motor 2 is attached to the outer periphery of a cylindrical can 7. The can 7 has the same outer diameter as the valve body 3, and the can 7 is formed by fitting the lower end of the can 7 to a step 3 a formed on the upper edge of the valve body 3 and welding the can 7. The main body 3 is connected and fixed.

  A stator yoke 8 of the stepping motor 2 is fitted on the outer periphery of the can 7. A bobbin 9 is disposed in the stator yoke 8, and a magnet wire 10 that is energized from the outside is wound around the bobbin 9. The stator yoke 8, bobbin 9 and magnet wire 10 are sealed with resin mold to form a molded body 11. Inside the can 7, a rotor 12 made of a bond magnet fixed to a sleeve 29 described later is provided. Has been placed. A connector housing 38 is provided at one side of the mold body 11, and a motor connector 39 and a connector pin 39a are provided therein.

The rotor 12 is preferably composed of a rare earth bonded magnet, that is, a bonded magnet in which neodymium / iron / boron (Nd—Fe—B) powder is bonded with a resin. Thereby, since the magnetic characteristics of the rotor 12 can be improved, the diameter of the rotor 12 can be reduced.
A valve chamber 17 is provided in the valve body 3, a fluid inlet / outlet 19 is opened at a side of the valve chamber 17, and a conduit 18 communicating with the valve chamber 17 is connected to the fluid inlet / outlet 19. Yes. A fluid inlet / outlet 21 opened and closed by the valve body 5 is opened at the lower portion of the valve chamber 17, and a conduit 20 communicating with the valve chamber 17 through the fluid inlet / outlet 21 is connected.

A guide bush 23 is fitted and fixed in the valve body 3 above the valve chamber 17 so as to hang down into the valve chamber 17. A female screw portion 22 is threaded on the inner peripheral portion of the guide bush 23.
A stopper 31 is provided at the upper end of the guide bush 23 and comes into contact with a movable side stopper 28 at the lower end of a sleeve 29 described later. A male threaded portion 25 threaded on the outer periphery of the holder 24 is screwed into the female threaded portion 22 of the guide bush 23, and a valve body 5 with a flange 5a is slidably fitted into the inner peripheral lower portion of the holder 24. ing. A collar 26 that receives the flange 5 a of the valve body 5 is press-fitted and fixed to the lower portion of the holder 24. A spiral fluid passage 65 is formed on the outer periphery of the guide bush 23 to make the valve chamber 17 and the inside of the can 7 have a uniform pressure (see FIG. 6).

  The holder 24 is fixed to a sleeve 29 fitted inside the cylindrical rotor 12. A refrigerator oil return hole 40 is formed in the sleeve 29. The valve shaft 4 is slidably inserted into the holder 24, and the upper end of the valve shaft 4 is guided into a guide hole 43 of a stopper member 42 that is fitted into a convex portion 41 formed at the upper end portion of the can 7. To invade. A compression coil spring 27 is provided between the flange portion 4a at the lower end of the valve shaft 4 and the flange portion 5a of the valve body 5. The valve body 5 is always kept downward by the compression coil spring 27, and the valve shaft 4 is always in contact. It is biased upward.

  2 to 4, the upper end of the can 7 protrudes from the opening 2 a of the stepping motor 2. A locking cap 44 is attached to the convex portion 41 of the can 7. The locking cap 44 has four locking pieces 46 that are bent in the horizontal direction at the lower end of the cylindrical portion 45, and ribs 46 a are formed on the locking pieces 46. It fits into the part 41 and is fixed by caulking 71. As shown in FIG. 1, the shoulder 7 a of the can 7 has a downward slope facing outward, so that a gap G is formed between the locking piece 46 and the shoulder 7 a.

On the flat upper surface portion 11 a of the mold 11 of the stepping motor 2, a locking projection 47 and a pair of engagement pieces 48 positioned on the opposite side of the locking projection 47 are formed.
The upper end portion of the can 7 is inserted into the fixed band 50 as shown in FIG. The fixing band 50 is made of an elastic metal member of a substantially ring-shaped ring portion 51b in which linear portions 51a are integrally connected to both ends, and an inverted L-shaped locking piece 51 is formed on the upper edge of the ring portion 51b. ing. A cutout groove 52 and a raised tongue piece 53 are formed on the upper side 51 a of the locking piece 51. A stop piece 54 that is bent horizontally is formed at the lower edge of the ring portion, and a stop hole 55 is formed in the stop piece 54 (see FIG. 4).

The locking hole 55 of the fixed band 50 is locked to the locking projection 47, and the linear portion 50a is pulled in the approaching direction to engage with the engagement piece 48. Thereby, the fixing band 50 is fixed to the upper surface part 11a.
Next, after inserting the can 7 in which the locking cap 44 is fitted into the convex portion 41 into the opening 2a of the mold 11 and positioning it inside the fixed band 50, the stepping motor 2 is moved around the can 7 for positioning. Rotate. As a result, the fixing band 50 also rotates together, and the locking piece 46 of the locking cap 44 enters between the upper side portion 51 a of the locking piece 51 of the fixing band 50 and the tongue piece 53. The rib 46 a snaps into the notch groove 52 and the fixing band 50 is locked to the locking cap 44. Thereby, the position of the rotor and coil of the stepping motor 2 is set to the optimum position.

An example of the connection structure between the motor connector 39 and the wire-side connector 56 is shown in FIG.
In FIG. 4, a connector 56 is formed with a connecting portion 56a in the lateral direction, and a wire lead-out portion 56b is formed in a downward direction substantially perpendicular to the connecting portion 56a. After inserting the connecting portion 56a into the motor connector 39 with the electric wire lead-out portion 56b facing downward, a box-shaped cover 57 having one side and a lower surface opened as shown in FIG. . Ribs 58 are formed on the inner surface of the cover 57, and locking claws 59 are formed at both lower ends of the ribs 58. The locking claw 59 is slid and inserted along the groove 60 of the connector housing 38 and is locked to the lower end of the connector housing 38. Finally, sealing 61 is performed on the inner space of the cover 57 with resin (see FIG. 1). As a result, the lead wire 62 is wired downward.

Further, as shown in another embodiment of FIG. 5A, a connector housing 38 having a lower opening and a lid portion 38a formed on the front surface is integrated with the mold 11 of the stepping motor 2, and the connector 56 is After the insertion, the lid portion 38a can be closed and the sealing 61 can be performed with resin as shown in FIG. 5B.
The electric flow control valve 1 configured as described above energizes and magnetizes the magnet wire 10 in one direction when the fluid inlet / outlet 21 is closed, and rotates the rotor 12, sleeve 29, valve shaft 4 and holder 24 integrally. . As a result, the holder 24 is lowered by screw feed by screwing of the female screw portion 22 and the male screw portion 25, the valve body 5 is lowered accordingly, and the fluid inlet / outlet 21 is closed by the valve body 5.

  When the fluid inlet / outlet 21 is closed, the movable side stopper 28 is not in contact with the fixed side stopper 31, and the holder 24 further rotates and descends while the valve body 5 closes the fluid inlet / outlet 21. At this time, the lowering amount of the holder 24 relative to the valve body 5 is absorbed by the compression coil spring 27 being compressed, and when the holder 24 is further rotated down, the movable side stopper 28 comes into contact with the fixed side stopper 31 (FIG. 1). reference). Thereby, even if energization excitation to the rotor 12 is continued, the rotational lowering motion of the sleeve 29, the valve shaft 4, and the holder 24 is forcibly stopped.

  When opening the fluid inlet / outlet 21, the magnet wire 10 is energized and excited in the other direction, and the rotor 12, the sleeve 29, the valve shaft 4, and the holder 24 are reversely rotated, whereby the female screw portion 22 and the male screw portion 25 are screwed together. As a result, the holder 24 is raised by the screw feed, and the valve body 5 is raised to open the fluid inlet / outlet 21. When the holder 24 is raised, the valve shaft 4 is also raised, and the upper end of the valve shaft 4 enters the guide hole 43 of the stopper member 42 and stops by hitting the stopper member 42, but the holder 24 slightly rises while compressing the coil spring 27. . A downward force acts on the valve body 5 due to the compression force of the coil spring 27, and a downward force acts on the holder 24 via the collar 26. Therefore, even if the male screw 25 and the female screw 22 are unscrewed, The screwing operation at the time of lowering is performed smoothly.

As described above, according to the present embodiment, since the can 7 is configured to have the same diameter as the valve body 3, the conventional flange member 6 is not necessary, and the can 7 has a small diameter and a reduced electric flow rate. It can be a control valve. Further, since the connector 50 has a structure in which the connection portion 56a to the motor connector 39 and the wire lead-out portion 56b are substantially perpendicular to each other, the wire 62 can be disposed in parallel with the can 7 and the wiring space is reduced. be able to.
Furthermore, since the valve shaft 4 and the valve body 5 are slidably mounted on the upper and lower sides of the holder 24 and the compression coil spring 27 is provided between the valve shaft 4 and the valve body 5, conventionally, the valve shaft 4 and the valve body 5 are The number of the springs 27 and 42 required can be reduced to one, and the size can be reduced and the number of parts can be reduced.

Sectional drawing which shows one Embodiment of the electric flow control valve of this invention. The top view of the electric flow control valve of this invention. The perspective view of the electric flow control valve of this invention. The exploded perspective view of the electric flow control valve of the present invention. The other structural example of a connector part is shown, (a) is a perspective view before an assembly | attachment, (b) is a perspective view after completion. The perspective view of the guide bush used for the electric flow control valve of this invention. Sectional drawing of the conventional electric flow control valve.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Electric flow control valve 2 Stepping motor 3 Valve main-body part 4 Valve shaft 4a Flange 5 Valve body 5a Flange 7 Can 12 Rotor 17 Valve chamber 22 Female screw 23 Guide bush 24 Holder 25 Male screw 26 Collar 27 Compression coil spring 39 Motor connector 41 Convex part 44 Locking cap 50 Locking band 56 Connector 56a Connection part 56b Electric wire drawing part 65 Fluid passage

Claims (3)

A can fixed to the valve body, a molded body attached to the outer peripheral surface of the can and having a stator yoke and a magnet wire molded with resin, and disposed in the can and electromagnetically rotated by the molded body An electric flow control valve having a rotor that is moved up and down by a rotation of the rotor and that opens and closes a fluid inlet / outlet formed in a valve chamber in the valve main body,
In the side of the mold body, a connector housing provided with a motor connector and a connector pin inside, and a wire side connector connected to the motor connector and the connector pin are provided,
The electric flow control valve according to claim 1, wherein the connector is formed with a lateral connection portion and a wire lead-out portion is formed in a downward direction substantially perpendicular to the lateral connection portion.   A box-shaped cover having one open side and a lower surface is attached to the outside of the connector housing and the connector, and the inner surface of the cover on the connector housing side is engaged with a groove of the connector housing. The electric flow control valve according to claim 1, wherein ribs having locking claws formed at both lower ends to be stopped are integrally provided, and a space inside the cover is sealed with resin.   The connector housing is integrated with the mold body and houses the connector inside, and a lower part is opened, a lid part is formed on the front surface, and an inner space part is sealed with resin. The electric flow control valve according to claim 1.

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