JP2000120885A - Motor operated valve - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a motor operated valve used for refrigerating cycle etc., with full close function. SOLUTION: A motor operated valve 100 has a can 110, while a motor mold 120 is attached to the outside of the can 110. The motor mold 120 has a stator yoke 121. A magnet wire 122 is connected to an external control device through a lead wire. A valve holder 150 integrated with rotors 170, 160 slidably supports a valve element 230. A bush 250 fixed to a valve main body 200 has an internal thread 252 with which an external thread 152 of the valve holder 150 is threadedly engaged. Fluororesin coating is performed on the surface, and a seat member 300 is made of fluororesin material, to bring about a full close state of the valve.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a motor-operated valve used for controlling a flow rate of a fluid such as a refrigerant used in a refrigeration cycle.

[0002]

2. Description of the Related Art As shown in FIG. 5, a refrigeration cycle constituting a conventional heat pump type air conditioner or the like is divided into an indoor unit A and an outdoor unit B, and an indoor heat exchanger 1 is provided in the indoor unit A. In addition to being equipped, the outdoor unit B includes a compressor 2, an outdoor heat exchanger 3, a four-way switching valve 4, an electric valve 5, two strainers 6, 6, and two manual opening / closing valves 7, 7, etc. The components are equipped and the components are connected such that the fluid refrigerant is moved by conduits.

[0003] Both the indoor unit A and the outdoor unit B,
It is assembled at a production site such as a factory and carried to an installation location, where an indoor unit A and an outdoor unit B are installed at a predetermined location. To complete the refrigeration cycle so that the refrigerant can circulate in the cycle.

FIG. 6 shows the structure of the motor-operated valve 5, two strainers 6, and the manual opening / closing valve 7 among the respective components of the outdoor unit B, and a plurality of conduits 9,. FIG. 2 shows a state in which the devices are connected via a USB cable. The motor-operated valve 5 includes a valve main body 5a and an electric motor 5 disposed above the valve main body 5a.
b, and the electric motor 5b is provided with a closed case 5c.
And a rotor 5e disposed inside the closed case 5c. One end of a conduit 9 is connected to the side of the valve body 5a of the electric valve 5 by brazing or the like, and a strainer 6 is similarly connected to the other end of the conduit 9 by brazing. ing. Further, one end of the conduit 9 is also connected to the lower portion of the valve body 5a by brazing, and another strainer 6 is connected to the other end of the conduit 9 by brazing.

[0005] The manual opening / closing valve 7 is turned sideways T
The valve body 7a is provided with refrigerant inlet / outlet connecting portions 7b and 7c which are orthogonal to each other, and a male threaded spool type valve element 7d is turned around an axis. It is arranged in a movable state. The one connecting portion 7
One end of a conduit 9 is connected and fixed to b by brazing or the like, and the strainer 6 is similarly connected and fixed to the other end of the conduit 9 by brazing. The other connecting portion 7c has a conduit 8 serving as a refrigerant circulation passage connecting the indoor unit A and the outdoor unit B.
Are connected and fixed by an appropriate pipe joint 7e.

[0006] The manual on-off valve 7, the front air-conditioning installation (factory), closing said valve element 7d closes shut off the connecting portions 7b that the tip conical surface portion 7d ₁ is seated on the valve seat 7f Position (lowest position). On the other hand, when the air conditioner is installed, the valve element 7d is rotated to move upward from the closed position so that the connection portion 7c and the connection portion 7b located on the indoor unit A side communicate as a refrigerant circulation passage. and, moving said from the valve seat 7f the tip conical surface portion 7d ₁ leaves the open position (uppermost position). This allows circulation of the refrigerant.

[0007]

Incidentally, the above-described air conditioner needs to be provided with a manual on-off valve 7 in addition to the motor-operated valve 5. The manual on-off valve 7 is used only when the air conditioner is transported from the factory to the installation location or when the air conditioner is relocated, and does not need to be opened and closed when the air conditioner is operating.

[0008] In addition, the motor-operated valve provided in the air conditioner is:
The valve body having the tapered portion is separated from and brought into contact with the annular valve seat, and has a function of controlling the flow rate of the refrigerant. It is necessary to press against the sheet. However, when the tapered portion of the valve body is pressed against the valve seat, the valve body and the valve seat are fixed by frictional force. There is a problem that a malfunction may occur. The present invention has been made in view of such a problem, and its purpose is to control the flow rate of the refrigerant,
An object of the present invention is to provide a motor-operated valve having a fully closed function.

[0009]

SUMMARY OF THE INVENTION In order to achieve the above object, an electric valve according to the present invention comprises a stepping motor and a seat member forming an orifice provided in a valve body by rotation of a rotor of the stepping motor. A valve actuating mechanism for connecting the valve body and the valve member, wherein the surfaces of the valve body and the seat member are formed of a material having low friction characteristics due to elasticity and self-lubrication. In the motor-operated valve of the present invention configured as described above, it is possible to control the flow rate of the refrigerant and to provide a fully-closed function of fully closing the valve opening degree by using elasticity, thereby sealing the refrigerant. In addition, since it has low friction characteristics due to self-lubricating properties, the valve opening operation of the valve body can be smoothly performed.

A preferred specific embodiment of the motor-operated valve of the present invention is as follows.
A valve body having a valve chamber and an orifice, a cylindrical can attached to the valve body, a stator member disposed outside the can, a rotor member disposed inside the can, and an integral part of the rotor member. A valve holder, a valve body having a tapered portion at a tip attached to the valve holder, a bush fixed to the valve body and screwed to the valve holder, and a seat member fixed to an inlet of an orifice of the valve body, The valve body is formed by forming the surface of the seat member from a material having elasticity and self-lubricating properties. The material having elasticity and self-lubricating property is a fluorine resin or a polyamideimide resin.

Further, the electric valve according to the present invention includes a stepping motor, and a valve operating mechanism for bringing the valve body into and out of contact with a seat member forming an orifice provided in the valve body by rotation of a rotor of the stepping motor, The valve body includes an elastic member that abuts on the valve seat member to completely close the orifice.

Further, a preferred embodiment of the motor-operated valve according to the present invention includes a valve body having a valve chamber and an orifice, a cylindrical can attached to the valve body, and a stator member disposed outside the can. A rotor member disposed inside the can, a valve holder integrated with the rotor member, a valve body having a tapered portion at a tip attached to the valve holder, and a bush fixed to the valve body and screwed to the valve holder. A seat member fixed to the entrance of the orifice of the valve body, and an elastic member for fully closing the orifice at the tip of the valve body. The elastic member is made of any one of rubber, fluorine resin, and polyamideimide resin.

[0013]

DESCRIPTION OF THE PREFERRED EMBODIMENTS One embodiment of the present invention will be described below with reference to the drawings. FIG. 1 is a sectional view showing an embodiment of the motor-operated valve of the present invention. The motor-operated valve generally denoted by reference numeral 100 has a cylindrical can 110 and a stator member 120 fitted around the outer periphery of the can 110. The stator member 120 is formed by molding resin, and the stator yoke 12
1 has a stator coil 122.

The opening of the can 110 has a plate-like lid member 13.
0 is welded, the inner peripheral portion of the lid member 130 is fitted into the cylindrical portion 226 of the valve body 200, and the edge of the cylindrical portion is expanded outward and caulked, so that the can 110 is fixed to the valve body 200. . The lid member may, of course, have a cup shape as in FIG. Since the valve body 200 is made of, for example, a material such as a copper alloy, it can be easily caulked. The valve body 200 has a valve chamber 210 and an orifice 2
20 to which pipes 215 and 225 are connected, respectively. A guide bush 250 made of stainless steel is inserted into an opening communicating with the valve chamber 210. Guide bush 25
0 is fixed to the valve body 200 by bending or crimping the edge portion 224 of the valve body 200 inward.

The rotating body provided in the can 110 includes a metal valve holder 150, a plastic sleeve 160 formed integrally with the outer periphery of the valve holder, and a bonded magnet formed integrally with the outer periphery of the plastic sleeve. 170. The bond magnet 170 on the outer periphery functions as a rotor of the motor, and rotates the entire rotating body. Note that 180
Is a stopper portion made of resin, and is formed integrally with the guide bush 250. Guide bush 250
Is provided with a female screw 252, and the male screw 152 of the valve holder 150 is screwed into the guide bush 250 and the valve holder 15.
0 constitutes a valve operating mechanism. The rotating body including the valve holder 150 is guided by the valve operating mechanism in accordance with the amount of rotation and moves in the axial direction. As a result, the valve element 230 comes into contact with or separates from the orifice 220.

The center of the bearing member 140 fixed to the inside of the can 110 projects deeply into the can 110. The shaft 260 is inserted through the bearing member 140 and the center hole of the valve holder 150. Shaft 260
Is loosely fitted to the bearing member 140 and the valve holder 150, and abuts on the head of the valve element 230 supported by the valve holder 150.
A snap ring 262 is attached to the tip of the shaft 260, and a coil spring 280 disposed between the snap ring 262 and the valve holder 150
To the orifice 220 side.

The valve element 230 is inserted into the valve holder 150, and the collar ring 290 is press-fitted to prevent the valve element 230 from coming off. The outer peripheral portion of the valve body 230 has a clearance with respect to the inner peripheral portion of the collar ring 290, and can move freely with respect to the valve holder 150. A coil spring 270 is provided on the outer periphery of the shaft 260. The coil spring 270 presses the rotating body against the threaded portion even when the rotating body including the valve holder 150 overruns upward and the threaded portion is unscrewed, thereby ensuring the threaded engagement. .

The valve body 200 includes a valve chamber 210 and a can 11.
0 has a refrigerant passage 202 communicating therewith. Valve body 2
The valve seat member 30 is located at the entrance of the orifice 220
0 is fitted and fixed by bending or crimping the edge 222 of the valve body 200 inward. As a result, the valve element 230 is moved by the valve operating mechanism to the valve seat member 3.
00 comes and goes.

The valve seat member 300 is made of, for example, a fluorine resin or a polyamideimide resin. Since these resins have low friction characteristics due to elasticity and self-lubricating properties, when the valve element 230 is pressed, it is easy to form a fully closed state due to elasticity. In addition, the valve body 230 has low friction characteristics.
Can be smoothly performed. The valve seat member 300 can be entirely made of a fluororesin or a polyamideimide resin. If necessary, for example, a metal member using brass is used, and the surface of the fluororesin or the polyamideimide resin is used. May be coated or baked.

Similarly, the valve element 230 is made of, for example, brass. The surface of the valve element 230 is coated with a fluorine-based resin or a polyamide-imide resin or baked to form a layer 230a.
Has been given. The valve element 230 has a small-diameter portion 232 at the distal end.
And a tapered portion 236. The tapered portion 236 is separated from and connected to the valve seat member 300 to adjust the valve opening.
The tapered portion 236 is pressed against the valve seat member 300 to form a fully closed state.

The motorized valve is set to the fully closed state only when the air conditioner is shipped or relocated, and it is not necessary to form the fully closed state when the air conditioner is operating. Therefore, the flow from the minimum flow rate to the maximum flow rate is always controlled. The straight portion 234 provided between the small diameter portion 232 and the tapered portion 236 of the valve element 230 has a function of raising the valve element 230 and securing a minimum flow rate between the valve element 230 and the inner peripheral surface of the valve seat member 300. Have.

FIG. 2 is a sectional view showing another embodiment of the motor-operated valve according to the present invention, and FIGS. 3 and 4 are explanatory views of the main part thereof. FIG. 2 is a cross-sectional view similar to FIG. 1 and shows a state in which a stator member of the motor-operated valve is removed, and portions common to FIG. 1 are denoted by the same reference numerals. In these figures, a motor-operated valve 100a is provided inside a can 110 with a plastic sleeve 160 and a bonded magnet 1 constituting a rotor.
70. The shaft 260 pressed into the upper center of the plastic sleeve 160 is supported by a bearing member 140 provided inside the top of the can 110.

A holder member (a member corresponding to the valve holder in FIG. 1) 1 formed integrally with the plastic sleeve 160
Reference numeral 50 has a threaded portion 152 on the outer peripheral portion, and is screwed to the inner threaded portion 252 of the guide bush 250 fixed to the valve body 200. The can 110 is welded to the lid member 130, and the lid member 130 is fixed to the valve body 200 as in FIG.
With this configuration, when the rotor including the plastic sleeve 160 and the bonded magnet 170 rotates, the holder member 1 is rotated.
50 moves up and down according to the pitch of the screw which was screwed. The pin 154, which is press-fitted into the lower end of the holder member 150 and whose head is in contact with the shaft 260, opens and closes a valve mechanism composed of the needle valve body 450 and the valve member 400 in accordance with this vertical movement.

The valve member 400 fixed to the valve body 200 has a cylindrical shape. The valve member 400 is fixed to the tip of the valve body 200 by caulking, and a valve seat 430 is formed at the lower end thereof. A polygonal, for example, hexagonal column-shaped guide 410 is slidably inserted into the valve member 400, and a spring member 4.
Due to 40, the guide 410 is constantly urged in a direction in which it comes into contact with the pin 154. The guide 410 has a needle valve 4
50 is press-fitted, and the head of the needle valve body 450 is
A tapered portion 454 formed in a lower portion of the needle valve body 450 and in contact with the tip of the needle valve body 4 opposes the valve seat 430 to adjust the valve opening.

A packing member 470, which is a fully-closed valve, is inserted into the small-diameter portion 452 formed at the tip of the tapered portion 454 of the needle valve 450. The packing member 470 is made of an elastic body made of a resin material such as a fluororesin or a polyamideimide resin or a rubber material. Small diameter part 452
And a cap member 46 on the outer periphery of the packing member 470.
0 is fitted, and the needle valve body 450 is crimped or the like.
To be fixed.

FIG. 4 shows a plan view of the guide 410 that slides in the valve holder 400. A fluid passage 420 is formed between the hexagonal column guide 410 and the valve holder 400.

FIG. 2 shows that the guide 410 has a spring 440.
And the valve is fully opened. The fluid flows between one pipe 215 and the other pipe 225 through a flow path between the needle valve element 450 and the valve seat 430, a flow path 420 between the guide 410 and the valve holder 400.

When the rotor rotates in the valve closing direction, the pin 154 moves up together with the holder member 150 while rotating. Rotational sliding occurs between the tip of the pin 154 and the upper end of the guide 410, and the guide 410 is subjected to the counter-rotating torque of the pin 154. However, the friction torque between the spring 440 and the guide 410 is set so as to be larger, and the guide 410 slides in the axial direction without rotating.

FIG. 3 shows a state where the valve is fully closed. The guide 410 moves the spring 4 as the pin 154 rises.
It is pushed upward by 40. The needle valve body 450 together with the guide 410 rises to reduce the valve opening. Eventually, the packing member 470 comes into close contact with the valve seat 430 to form a fully closed state. The packing member 470 is
For example, the valve channel is closed because it is made of a resin material such as a fluorine-based resin or a polyamide-imide resin and an elastic material such as rubber.

When the pin 154 is moved in the valve opening direction, the packing member 470 of the needle valve body 450 is
Apart from the zero valve seat 430, a valve passage is formed.

[0031]

The motor-operated valve of the present invention has a function of fully closing the valve opening together with the flow control, so that the refrigerant can be sealed and the refrigerant can be held in the refrigeration cycle. By providing this fully closed function, it is possible to close the flow path of the refrigerant when the air conditioner is transported or the like, and to prevent the refrigerant from leaking outside the machine. Therefore, the structure of the entire apparatus is simplified without separately providing a manual on-off valve.

[Brief description of the drawings]

FIG. 1 is an explanatory diagram showing a configuration of a motor-operated valve according to an embodiment of the present invention.

FIG. 2 is an explanatory diagram showing a configuration of a motor-operated valve according to another embodiment of the present invention.

FIG. 3 is an explanatory view showing a main part of the electric valve shown in FIG. 2;

FIG. 4 is an explanatory view of a main part of the motor-operated valve shown in FIG. 2;

FIG. 5 is a piping diagram of a conventional air conditioner.

FIG. 6 is a configuration diagram of a conventional air conditioner.

[Explanation of symbols]

 REFERENCE SIGNS LIST 100 electric valve 110 can 120 stator member 130 lid member 140 bearing member 150 valve holder 160 plastic sleeve 170 bonded magnet 200 valve body 230 valve body 250 guide bush 260 shaft 300 seat member 400 holder 410 guide 420 flow path 430 sheet 440 spring 450 needle Valve body 460 Cap 470 Packing member

Continued on front page F term (reference) 3H052 AA01 BA02 BA35 CA22 CA33 CA34 CB22 CB33 CB34 DA06 EA04 EA11 3H062 AA02 AA15 BB28 CC02 DD01 EE06 EE08 EE09 FF39 FF40 FF41 HH04

Claims (6)

[Claims] 1. A stepping motor, and a valve operating mechanism for connecting a valve body to a seat member forming an orifice provided in a valve body by rotation of a rotor of the stepping motor, the valve body and a surface of the seat member. Characterized by comprising a material having elasticity and self-lubricating property. 2. A valve body having a valve chamber and an orifice, a cylindrical can attached to the valve body, a stator member disposed outside the can, and a rotor member disposed inside the can. A valve holder integrated with the rotor member, a valve body having a tapered portion at a tip attached to the valve holder, a bush fixed to the valve body and screwed to the valve holder, and a sheet fixed to an inlet of an orifice of the valve body. A motor-operated valve comprising: a member; and the surfaces of the valve body and the seat member are made of a material having elasticity and self-lubricating properties. 3. The method according to claim 1, wherein the material is a fluororesin or a polyamideimide resin.
The motor-operated valve according to claim 1. 4. A stepping motor, and a valve actuating mechanism for bringing a valve body into and out of contact with a seat member forming an orifice provided in a valve body by rotation of a rotor of the stepping motor, wherein the valve body is a valve seat member. A motor-operated valve provided with an elastic member that abuts on the orifice to fully close the orifice. 5. A valve body having a valve chamber and an orifice, a cylindrical can attached to the valve body, a stator member disposed outside the can, and a rotor member disposed inside the can. A valve holder integrated with the rotor member, a valve body having a tapered portion at a tip attached to the valve holder, a bush fixed to the valve body and screwed to the valve holder, and a sheet fixed to an inlet of an orifice of the valve body. And an elastic member for completely closing the orifice at the tip of the valve body. 6. The motor-operated valve according to claim 4, wherein the elastic member is made of any one of rubber, fluorine resin, and polyamide-imide resin.