JPH10220616A - Electric operated valve - Google Patents

Abstract

PROBLEM TO BE SOLVED: To improve lubrication performance of a drive screw of an electric operated valve used for a refrigeration cycle. SOLUTION: An electric operated valve 1 has a can 10 and a motor mold 20 is mounted on the outside of the can 10. The motor mold 20 has a stator yoke 21 and a magnet wire 22 is jointed to an outside control device via a lead wire 36. A valve holder 70 integrated with a rotor 61, 60 has hollow part 71 and slidably supports a valve body 80 inserted into the hollow part 71. A bush 90 fixed to a valve body 40 has a female thread 92 and a male thread 74 of the valve holder 70 is screwed thereon. A coil spring 72 is inserted into the hollow part 71 of the valve holder 70 and a disc-shaped washer 100 is interposed between the coil spring 72 and the valve holder 70 functions as a thrust bearing to smoothly slide the valve holder to the valve body 80. Sliding resistance can be reduced by shaping the contact part of the coil spring with the waste 100 into a big tail end.

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 A motor-operated valve used in a refrigeration cycle converts, for example, a rotary motion of a stepping motor into a linear motion of a valve body by a screw mechanism, and controls a flow passage area between the valve body and an orifice of the valve body. The configuration has In particular,
A bush having a female screw portion is attached to the valve body, and a male screw portion is provided on a valve body integral with the rotor of the stepping motor or a valve holder supporting the valve body, and the two screw portions are screwed together.

[0003]

In such a motor-operated valve, the tip of the valve body contacts the orifice while the valve body rotates together with the rotor. The electric valve is closed by this contact, but the valve element is pressed against the orifice by receiving the axial force of the screw. However, when the needle-shaped valve is pressed against the orifice, the valve comes into close contact with the orifice,
There is a possibility that a problem of poor valve opening that the valve opening becomes difficult may occur. Therefore, in the conventional electric valve, a stopper is provided, and the rotation of the rotor is stopped by the stopper at the same time as the valve is closed. However, it is difficult to accurately manage the synchronization between the stop of rotation and the closing of the valve due to the contact of the stopper due to the variation in the dimensions of assembling parts such as the rotor and the valve element. In order to solve this problem, a hollow portion is provided in the valve holder, and a slidable valve body is provided via a coil spring. There is a structure in which the valve body is compressed to generate a predetermined spring load and press the valve body against the orifice. However, after the valve body contacts the orifice, the rotor further rotates in the valve closing direction until it comes into contact with the stopper. As a result, as the number of repeated operations due to the contact of the valve body with the orifice increases,
Wear may occur on the orifice surface, causing a problem such as a change in flow rate characteristics. In view of the above, an object of the present invention is to provide a motor-operated valve that can prevent orifice wear and suppress fluctuations in flow characteristics.

[0004]

A motor-operated valve according to the present invention comprises, as basic means, a valve body having a valve chamber and an orifice, a cylindrical can attached to the valve body, and an outer side of the can. A stator member, a rotor member disposed inside the can, a valve holder integrated with the rotor member, a valve body slidably inserted into a hollow portion of the valve holder to open and close an orifice of a valve body, and a valve. A bush fixed to the main body and having a threaded portion to be screwed with a threaded portion of the valve holder; a coil spring disposed between the valve holder and the valve body; and a coil spring disposed between the coil spring and the valve holder. Equipped with a disk-shaped washer. Further, the motor-operated valve of the present invention has a disk-shaped washer provided between the coil spring and the valve body. Since such a disk-shaped washer acts as a thrust bearing, the sliding phenomenon that occurs between the fixed end and the rotating end due to the load of the coil spring generated after the valve body contacts the orifice is moved to a position other than the valve and the orifice. It is possible to transfer.

Further, the motor-operated valve of the present invention is provided with a coil spring having a coil spring whose end has a pigtail shape or a so-called one-sided pig tail end. By using a coil spring having such a terminal shape as a pigtail, or a pigtail end on one side, the contact area is greater than that when a coil spring having a closed end is used as a coil spring provided in the electric valve of the present invention. Is reduced, it is possible to more reliably transfer the sliding phenomenon to a position other than the valve element and the orifice.

[0006]

FIG. 1 is a sectional view showing the overall structure of a motor-operated valve according to an embodiment of the present invention, and FIG. The motor-operated valve indicated by reference numeral 1 has a cylindrical can 10 and a motor mold 20 fitted around the outer periphery of the can 10. The motor mold 20 is formed by molding a resin, and includes a stator yoke 21, a bobbin 24, and a magnet wire 22 wound around the bobbin 24 inside. This magnet wire 22 is a lead wire 23
Is connected to a connector 34 inside the housing 30 attached to the motor mold 20. Connector 3
4 is connected to a control device via a lead wire 36. The bobbin 30 is filled with an epoxy resin 32.

The motor mold 20 is removably fitted to the outer periphery of the can 10 in the axial direction, and is fixed to the motor mold 20 by a stopper 28 attached with a screw 26. A recess 11 for receiving the stopper 28 is formed on the outer periphery of the can 10. The lid member 12 is attached to the opening of the can 10 by means such as welding, and the valve body 40 is attached to the opening of the lid member 12. The valve body 40 is made of, for example, a copper alloy and has a valve chamber 42, an inlet 43, and an outlet 44. Exit 4
4 forms an orifice for controlling the flow rate of the valve.

An inlet pipe 50 communicates with the inlet 43 of the valve body 40, and an outlet pipe 52 communicates with the orifice outlet 44. A guide bush 90 is inserted into the inner diameter of the valve body 40. Guide bush 90
Has a female screw portion 92 in the inner diameter portion, and a valve holder 70 having a male screw portion 74 screwed to the female screw portion 92 is attached. The valve holder 70 has a cylindrical shape having a hollow portion 71, and a valve body 80 is slidably inserted into a lower portion thereof. A disc-shaped washer 10 is provided at the bottom of the hollow portion 71 of the valve holder 70.
0 is equipped. Through the washer 100, the hollow portion 7
The valve body 8 is moved by the coil spring 72 inserted into the valve body 8.
0 is constantly urged in the direction of being pushed outward, and the protruding position of the valve body is regulated by the collar 82 which is press-fitted into the inlet of the valve holder.

A shaft 64 is provided above the valve holder 70. A plastic sleeve 60 is integrally formed on the outer periphery of the shaft 64 and the valve holder 70, and a bond magnet 62 is formed on the outer periphery of the plastic sleeve 60. The bond magnet 62 functions as a motor rotor. The upper end of the shaft 64 is supported by a bearing member 14 disposed on the back surface of the top of the can 10. A coil spring 66 provided on the shaft 64 is for pressing the valve holder 70 toward the bush 90 when the rotor rotates and rises together with the valve holder 70 to unscrew the screw portion. It is. The stopper member 77 attached to the upper part of the bush 90 regulates the lower end position of the rotor, is formed of a resin material, and comes into contact with the stopper portion 78 of the sleeve 60.

The valve chamber 42 of the valve body 40 communicates with the inside of the can 10 through a passage 46, and the inside of the can 10 communicates with the hollow portion of the valve holder through a hole 73. Therefore, the refrigerant flowing into the valve chamber 42 is filled into the can 10, and the screw portion between the female screw portion 92 of the bush 90 and the male screw portion 74 of the valve holder 70, the coil spring 72, and the washer 1.
The refrigerant flows in between 00 and 00. Refrigerant has a strong cleaning action,
Therefore, the lubricating component of the sliding portion is also easily removed.

Rotational sliding occurs between the washer 100 and the coil spring 72 when the valve body 80 is seated on the orifice 44 and stops rotating. In order to press the valve body against the orifice with a predetermined force, the valve body 80 is
Even after the contact with the coil 4, the rotor is rotated by a predetermined rotation angle to compress the coil spring 72 to generate a spring force. Due to this action, the portion between the washer 100 and the coil spring 72 slides while receiving thrust by the spring. That is, the sliding phenomenon between the valve element and the orifice is transferred to a position between the washer and the coil spring.

In the present invention, since the disk-shaped washer 100 is inserted, the washer 100 can achieve the function of a thrust bearing to achieve smooth rotational sliding.
Washer 100 is made of a material such as, for example, stainless steel. By forming the washer 100 into a disk shape, the washer can be accurately arranged at the bottom of the hollow portion of the valve holder at the time of assembly or the like by, for example, tweezers using a vacuum.

Further, according to the present invention, by applying (NI + PTFE) plating on both surfaces of the washer 100 to nickel containing polytetrafluoroethylene, lubricity can be improved and the function as a thrust bearing can be improved. . Further, the washer 100 may be provided between the spring 72 and the valve body 80 instead of being provided between the bottom of the hollow portion 71 of the valve holder 70 and the spring 72.

The plating means is the same as that of general electroless nickel plating. The NI + PTFE plating coating layer has high hardness, excellent slipperiness, and high abrasion resistance. Therefore, by forming this plating coating layer on the washer disposed between the valve holder and the spring, even in the case of an electric valve that controls a refrigerant having high cleaning performance and low lubricity, the valve holder can be used. And the valve body always functions normally and can exhibit predetermined performance.

In the above-described embodiment, the washer 100 is formed of a flat disk and is brought into contact with a mating member. For example, a projection is provided at the center of the washer to form a mating member. And a point contact may be made.

FIG. 3 is a longitudinal sectional view showing a main part of another embodiment of the motor-operated valve according to the present invention. In the figure, the configuration different from the embodiment shown in FIG. 1 is a coil spring,
Other configurations are the same as those in FIG.
1 denote the same or equivalent parts. In FIG. 3, reference numeral 721 denotes a so-called pig tail or a single-sided pig tail end coil spring in which the shape of the terminal is formed to be smaller by several turns, and the terminal side which is the pig tail end is in contact with the washer 100. With such a configuration, even after the valve element 80 is seated on the orifice 44 and the valve element is restrained by the orifice, the space between the valve holder 70 and the coil spring 721 is much more than in the embodiment of FIG. As a result, the orifice 44 can be more reliably prevented from being worn by the valve element 80.

[0017] In Thus, the slip torque T of one pigtail end of the coil spring 721, T = D / 2 · F B · μ where, D: number Volume fraction of terminals of the coil spring (side abutting the washer) The average coil diameter FB is represented by the following equation: F _B : Spring load μ: Massatsu coefficient
The slip torque T decreases.

FIG. 4 is a view showing a main part of another embodiment of the motor-operated valve according to the present invention. The shape of the coil spring and the shaft is different from that of the embodiment of FIG. 1, and the washer is omitted. The other configuration is the same as that of FIG. Therefore, in FIG. 4, the same reference numerals as those in FIG. 1 indicate the same or equivalent parts. In FIG. 4, reference numeral 722 denotes a coil spring of the same one-side pigtail end as in FIG.
The distal end portion 641R of the shaft 641 abutting on the coil spring 722 is formed in a spherical shape. By adopting this spherical shape, it is possible to perform the same operation as the washer of the embodiment shown in FIG. Can be omitted.

It is to be noted that the same effect can be obtained even when the distal end portion 641T of the shaft 641 is formed in a conical shape and the conical portion is brought into contact with the coil spring of the pigtail end on one side. An embodiment in this case is shown in FIG. In the motor-operated valve of the present invention,
The coil spring is not limited to the one-sided pigtail end, but may be a conical coil spring 723 having the shape shown in FIG.

[0020]

As described above, the present invention has a strong detergency,
Also, a valve holder for an electric valve of an air conditioner which needs to be operated in a state of being exposed to a refrigerant having low lubricity, which is integrally formed with a rotor of a stepping motor and performs a linear motion together with a rotary motion by a screw action. Is provided with a hollow portion, and a valve body is slidably inserted into the hollow portion. Therefore, the valve holder and the valve body are separated, and each can move independently.

Since a coil spring is inserted between the valve holder and the valve body and a disk-shaped washer is interposed between the coil spring and the valve holder, the washer functions as a thrust bearing, and Even after the body is constrained by the orifice, it can smoothly rotate and slide between the valve holder and the coil spring. Therefore, wear of the orifice can be prevented, and fluctuations in the flow characteristics can be suppressed. Thus, according to the present invention, the reliability of the motor-operated valve can be improved. Further, by forming a highly lubricious plating layer on the washer, the function as a thrust bearing can be further improved. Therefore, the present invention is effective for a motor-operated valve of an air conditioner that handles a low lubricating refrigerant or the like like an alternative refrigerant.

[Brief description of the drawings]

FIG. 1 is a longitudinal sectional view showing a configuration of an embodiment of a motor-operated valve according to the present invention.

FIG. 2 is an enlarged view of a main part of FIG.

FIG. 3 is a longitudinal sectional view of a main part showing a configuration of another embodiment of the motor-operated valve according to the present invention.

FIG. 4 is a longitudinal sectional view of a main part showing a configuration of another embodiment of the motor-operated valve according to the present invention.

FIG. 5 is a cross-sectional view showing another configuration of the distal end portion of the shaft of the present invention.

FIG. 6 is a sectional view showing another shape of the coil spring of the present invention.

[Explanation of symbols]

 Reference Signs List 1 motorized valve 10 can 12 lid member 14 bearing member 20 motor mold 21 stator yoke 24 bobbin 30 housing 40 valve body 42 valve chamber 44 orifice 60 plastic sleeve 62 bond magnet 70 valve holder 71 hollow portion 72,721,722 coil spring 74 male screw Part 80 Valve element 90 Bush 92 Female thread part 100 Washer

Claims (7)

[Claims] 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 integral with the rotor member; a valve body slidably inserted into the hollow portion of the valve holder to open and close the orifice of the valve body; and a screw portion fixed to the valve body and screwed with the screw portion of the valve holder. An electric valve, comprising: a bush having a coil spring disposed between a valve holder and a valve body; and a disk-shaped washer disposed between the coil spring and the valve holder. 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 integral with the rotor member; a valve body slidably inserted into the hollow portion of the valve holder to open and close the orifice of the valve body; and a screw portion fixed to the valve body and screwed with the screw portion of the valve holder. An electric valve comprising: a bush having: a coil spring disposed between a valve holder and a valve element; and a disk-shaped washer disposed between the coil spring and the valve element. 3. The motor-operated valve according to claim 1, wherein a plating coating layer made of a material containing polytetrafluoroethylene in nickel is formed on a surface of the disk-shaped washer. 4. 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 integral with the rotor member; a valve body slidably inserted into the hollow portion of the valve holder to open and close the orifice of the valve body; and a screw portion fixed to the valve body and screwed with the screw portion of the valve holder. A coil spring having a shape of a one-sided pigtail end disposed between the valve holder and the valve element, and a disk-shaped washer disposed between the coil spring and the valve holder. Electric valve. 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 integral with the rotor member; a valve body slidably inserted into the hollow portion of the valve holder to open and close the orifice of the valve body; and a screw portion fixed to the valve body and screwed with the screw portion of the valve holder. A coil spring having a shape of a one-sided pigtail end disposed between the valve holder and the valve element, and a disk-shaped washer disposed between the coil spring and the valve element. Electric valve. 6. The motor-operated valve according to claim 4, wherein a plating coating layer made of a material containing polytetrafluoroethylene in nickel is formed on a surface of the disk-shaped washer. 7. A rotor having 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 shaft disposed inside the can. Member, a valve holder integral with the rotor member, a valve body slidably inserted into the hollow portion of the valve holder to open and close the orifice of the valve body, and screwed to the screw portion of the valve holder fixed to the valve body. A bush having a threaded portion, and a coil spring having a shape of a one-sided pigtail end disposed between the valve holder and the valve body, wherein the end of the shaft is formed into a spherical shape or a conical shape, An electric valve, which is in contact with the coil spring.