JPH03260482A - Structure of stopper of motor-driven valve - Google Patents

Abstract

PURPOSE:To lessen the number of parts constituting a valve stem and suppress the cost by splitting a stopper member into an appropriate number of pieces, wherein the stopper member is for loose fitting of a core rod fixed to a lid, and thereby permitting the resolution to remain at the necessary minimum for the hunting phenomenon not to occur. CONSTITUTION:If current is fed to a stator coil 10 so as to rotate in the direction of valve opening in the condition that a motor-driven valve is closed, the rotor 5 of motor makes one turn counterclockwise viewed from over irrespective of a stopper member 21, and a projection 5b on a rotor sleeve 5a collides with the opposite side of a protruding piece 21b below the stopper member 21. When thereafter the rotor sleeve 5a rotates, a protruding piece 21a over the stopper member 21 rotates leftwise being pushed by the projection 5b on the rotor sleeve 5a, and then protruding piece 21 over the stopper member 21 contacts the rear surface of the stopper piece 20, and the rotor 5 comes to standstill after two turns approximately.

Description

[Detailed Description of the Invention] [Industrial Application Field] The present invention relates to electronically controlled expansion valves used in the refrigeration cycle of room air conditioners, car air conditioners, etc., or proportional control that is used in combination with a microcomputer in the general industrial field. This invention relates to an electric valve used as a valve.

[Prior Art] Conventionally, various stopper structures have been devised for electric valves that combine a stepping motor and a valve and are controlled by a microcomputer.

Fig. 6 shows the method disclosed in Japanese Utility Model Application No. 62-93479 (hereinafter referred to as the stopper bolt method for convenience), and Fig. 7 shows the method disclosed in the Japanese Utility Model Application Publication No. 82-107174 (hereinafter referred to as the rotor sleeve method for convenience). This is a stopper structure for a conventional motor-operated valve disclosed in 2003, and its structure will be explained below.

As a common part between Fig. 6 and Fig. 7, the valve stem (1), which has a needle valve (3) and a needle valve (4) formed from its tip, is magnetized with multi-pole outer circumference through a rotor sleeve (5a). It is formed integrally with the motor rotor (5) made of a cylindrical permanent magnet, and the propulsion bearing (8) is fixed to the valve body (6).
) The male thread (4) is fitted into the female thread (7).

The outer periphery of the motor rotor (5) is covered with a thin cylindrical case (
9), and on the outside of this case (9) there is a stator coil (5) of the motor at a position corresponding to the rotor (5) of the motor.
10) is fixed.

The lower end of the case (9) has fluid inlets and outlets (11) and (12).
The upper end of the case (9) is also airtightly integrated with the valve body (6) having the valve seat (2) by plasma welding etc.
3) is sealed.

In addition, as a part of the stopper in the stopper bolt method shown in FIG. In addition to providing a screw, a through hole (15a) (15a) is provided near the circumference l#1WJ.
) is provided with a stopper nut (15), and a backing plate (16) is fixed to its tip, while two pins (15) fixed to the rear of the central recess of the rotor sleeve (5a) are
17) (17) into the through hole (15) of the stopper nut.
a) This is what was inserted in (15a).

Next, the operation of the stopper bolt type electric valve will be explained.

When the stator coil (10) is energized to rotate a certain amount in the valve closing direction, the motor rotor (5) and the valve shaft (1)
rotate integrally, and the valve shaft (1) moves forward in the valve closing direction by the action of the propelling screw.

On the other hand, the stopper bolt (14) fixed to the lid (13)
) is rotated by a pin (17) that rotates integrally with the rotor (5), so it moves forward in the same way as the valve shaft (1).

Then, the needle valve (3) is seated on the valve seat (2), and the stopper nut (15) is attached to the backing plate (16) just before the valve is completely closed.
At this point, the linear movement of the stopper nut (15) is stopped.

Therefore, the rotational and linear movement of the valve stem (1) also stops.

Subsequently, when the stator coil (10) is energized in the valve opening direction, the rotor (5) rotates in the opposite direction, and the stopper nut (15) separates from the backing plate (16) surface and closes the valve. It moves back together with the shaft (1), and after 6 predetermined rotations, the lid (
13), and the linear movement of the valve shaft (1) also stops.

Also, to explain the structure of a part of the stopper in the rotor sleeve method shown in FIG. On the other hand, on the inner surface of the lid (13), a retaining pin (18) is fixed by hanging down to a position that reaches the middle of the convex part, apart from the center part, and the motor is fixed. In the range of less than one revolution of the rotor (5),
The movement of the valve stem (1) is restricted by bringing the retaining pin (18) into contact with the side surface of the protrusion 1 (5b).

Next, the operation of the rotor sleeve type electric valve will be explained.

When the stator filter (10) is energized to rotate a certain amount in the valve closing direction, the rotor sleeve (5a) fixed to the rotor (5) of the motor and the valve shaft (1) rotate integrally, The valve shaft (1) moves forward in the valve closing direction by the action of the propelling screw.

Then, before the needle valve (3) is seated on the valve seat and completely closed, the lid (13) is attached to the side of the protrusion (5b) of the rotor sleeve.
) hits the stop pin (18), the motor rotor (5) stops rotating less than one revolution, and the valve shaft (
1) The rotational/linear motion stops.

Subsequently, when the stator coil (10) is energized in the valve opening direction, the valve shaft (1) moves back in the valve opening direction, and eventually the side opposite to the protrusion (5b) of the rotor sleeve Stopper bottle (
18), the valve stem (1) stops after less than one revolution.

[Issues that the good idea aims to solve] Conventional stopper bolt type products have a large number of steps from fully closed to fully open, so they have excellent resolution and are characterized by highly accurate flow control. However, several types of parts such as a stopper bolt (14) and a stopper (without stopper) (15) are required to stop the valve stem, which increases the cost of the motorized valve. The problem was that I couldn't use it.

In addition, in the rotor sleeve type, the opening/closing operation of the valve stem (1) is performed within a range of less than one revolution of the rotor (5), so if the system is controlled by a microcomputer, the flow rate per pulse is The variation was too large, causing a hunting phenomenon (opening and closing operations were repeated between, for example, 1 and 20 to 21 pulses for a desired flow rate), which caused problems in durability.

An object of the present invention is to provide an electric valve that can reduce the resolution by keeping the resolution to the necessary minimum level without causing the hunting phenomenon, and by reducing the number of parts for stopping the valve shaft (1) from moving straight, thereby reducing costs.

[Means for Solving the Problems] The stopper structure of the electric valve of the present invention operates by energizing the stator coil (10) of the motor fixed to the outer periphery of the case (9) made of a non-magnetic material. The rotor (5) of the motor formed integrally with (1) is rotated, and this rotation is converted into linear movement of the valve shaft (1) by the propulsion bearing (8), thereby controlling the opening degree of the valve seat (2). In the electric valve to be controlled, a rotor sleeve (
A convex portion (5b) is formed on the inner circumferential surface of the lid (13) by protruding in the radial direction at only one place, while a flange (5b) is formed at the lower end of the inner surface center of the lid (13).
19a), and at the same time fix the upper end of the core rod (19) with
20) is suspended and fixed, and a stop member (21) protruding in the radial direction is loosely fitted, and the stopper piece (20) is brought into contact with the front or rear surface in the rotational direction of the upper protruding piece (21a). In addition, the convex portion (5b) of the rotor sleeve is positioned in contact with the rear or front surface in the rotational direction of the lower protruding piece (21b).

[Function] In the stopper structure of the electric valve of the present invention, during the first rotation of the rotor of the motor, the convex portion (5b) of the rotor sleeve moves away from the lower protruding piece (21b) of the stop member (21). During the second rotation, the protrusion (5b) of the rotor sleeve comes into contact with the opposite side of the protruding piece (21b), rotating the stop member (24) together with the rotor sleeve (5a), causing the upper part of the stop member to rotate. Projection piece (21a) and stopper piece (20
) comes into contact with the motor rotor (5), thereby stopping the rotation of the motor rotor (5).

Therefore, compared to the conventional rotor sleeve type, the number of revolutions of the motor during the period from fully closing to fully opening the valve can be increased (approximately 2 revolutions in the illustrated example), making it easier to control the system with a microcomputer. Since the change in flow rate per pulse can be reduced and there is no need to repeat frequent opening and closing operations of the valve, the durability of the motor-operated valve is improved.

[Embodiments of the invention] A first embodiment of the present invention will be described with reference to FIGS. 1-4.

The basic configuration is the same as the conventional product except for the parts for stopping the rotation of the valve stem (1), so the explanation will be omitted.

The rotor (5) of the motor is integrated with the valve shaft (1) via a rotor sleeve (5a), and above the inner surface of the rotor sleeve (5a) is a rotor that protrudes radially inward. A convex portion (5b) is provided.

In addition, a stopper piece (20) with a part of the outer edge of a disk protruding downward is fixed to the center of the inner surface of the lid (13), and a flange part (19a) is attached to the lower part of the stopper piece (20).
The upper end of the core rod (19) is fixed. In addition, although the said flange part (19a) is integrated with a core rod (19), this can also be replaced with a stop ring.

The stopper member (21) has an upper protruding piece (21a) and a lower protruding piece (21a) with a vertical difference as shown in FIGS. 3 and 4.
b) is provided to protrude in the radial direction, and when this stopper member (21) is loosely fitted to the core rod (22),
The stopper piece (20) is placed in contact with the rear surface of the upper protruding piece (21a) in the rotational direction, and the lower protruding piece (21a)
There is a convex part (5b) of the rotor sleeve on the front surface in the rotation direction of the rotor sleeve (5b)
) are arranged so that they are in contact with each other.

Next, the operation of the present invention will be explained.

Figures 1 and 3.4 show the closed state of the electric valve, and in this state, when the stator coil (10) is energized to rotate in the valve opening direction, it has no relation to the stop member (21). , the rotor (5) of the motor rotates once in the left direction when viewed from the top, and the protrusion (5b) of the rotor sleeve engages the stop member (21).
It corresponds to the opposite side (rear surface) of the lower protruding piece (21b).

When the rotor sleeve subsequently rotates, the stop member (21)
The lower protruding piece (21b) of the rotor sleeve has a convex part (5).
b) and rotates to the left (at this time, the upper protruding piece (21a) rotates in a direction away from the front surface of the stopper piece (20), so there is no problem with the rotation of the rotor sleeve). The upper protruding piece (21a) of the stop member (21)
) comes into contact with the rear surface of the stopper piece (20), and the rotor (5) stops after approximately two revolutions as shown in FIG.

FIG. 5 shows another embodiment, in which the stop member loosely fitted onto the core rod (1 day) is divided into an upper stop member (22) and a lower stop member (23). ) The upper protruding piece (22a) provided on the stopper piece (20
), and the lower protruding piece (22b) is bent downward to come into contact with the rear face of the upper protruding piece (23a) provided on the lower stopper member (23).

In addition, the lower protruding piece (2) provided on the lower stopper member (23)
3b) is adapted to abut against the rear surface of the convex portion (5b) of the rotor sleeve.

By combining two stop members in this way,
The rotor (5) of the motor can be stopped after approximately three revolutions.

That is, the number of times the motor rotor (5) is stopped can be determined by the number of divisions of the stop member.

In the illustrated example, a coiled spring is used as the stopper member, but this is not limited to a spring, and it is sufficient to provide protruding pieces at appropriate positions above and below the cylinder.

Therefore, if the directions of the protruding pieces are set in approximately the same direction, the number of
It will rotate, and if it is installed at the 180'' position, it will rotate approximately half a rotation.

[Effects of the Invention] The present invention is capable of controlling the rotor (5) of the motor by dividing the stopper (21) loosely fitted into the core rod (19) fixed to the lid (13) into an appropriate number. It is possible to arbitrarily determine which addition is to be stopped at a certain time.

Additionally, since the number of parts is reduced compared to the conventional stopper bolt type, costs can be reduced.

In addition, compared to the conventional rotor sleeve type, the motor rotation speed can be increased during the period from fully closing to fully opening the valve, so when controlling the system with a microcomputer, the change in flow rate per pulse can be reduced. This is an effective invention that does not cause the hunting phenomenon.

[Brief explanation of drawings]

FIG. 1 is a longitudinal sectional view showing a valve closed state in an embodiment of the present invention. FIG. 2 is a longitudinal sectional view showing the valve in FIG. 1 in an open state. 3 is a partial perspective view showing the stop mechanism of FIG. 1; FIG. FIG. 4 is a sectional view taken along line AA in FIG. FIG. 5 is a partial perspective view showing another embodiment of the stopping mechanism. FIG. 6 is a longitudinal cross-sectional view of a conventional product. FIG. 7 is a longitudinal sectional view of another conventional product. (1) Valve shaft (2) Valve seat (3) Needle valve (4) Male wetting (5) Motor rotor (5a) Rotor sleeve (5b) Convex portion (6) Valve body (7) Female thread ( 8) Propulsion bearing (9) Case (10) Motor stator coil (11) (12) Entrance/exit (
13) Lid (14) Stopper bolt (15) Stopper nut (15a) Through hole (I6) Backing plate (17) Pin (I8) Stopping pin (19) Core rod (19a) Lower end (20) Stopper piece (21) Stopping member (21a) (2
1b) Projecting piece

Claims (1)

[Claims] 1) The valve shaft (
1) is rotated, and this rotation is converted into linear motion of the valve shaft (1) by the propulsion bearing (8) to control the opening degree of the valve seat (2). In the motor-operated valve, the rotor sleeve (5) integrated with the motor rotor (5)
A convex portion (5b) is formed on the inner circumferential surface of the lid (13) by protruding in the radial direction at only one place, while a core with a flange portion (19a) at the lower end is formed at the center of the inner surface of the lid (13). While fixing the upper end of the rod (19), a stopper piece (20) is placed at a position away from the center.
is hung down and fixed, and the upper protruding piece (19) is provided with a vertical difference on the core rod (19).
21a) and a lower protruding piece (21b) protruding in the radial direction.
A stopper piece (20
) are placed in contact with each other, and the lower protruding piece (21b
) on the rear or front surface of the rotor sleeve in the direction of rotation (
A stopper structure for an electric valve, characterized in that 5b) is positioned in an abutting manner.