JP3095892B2 - Multi-stage solenoid valve - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an improvement of a solenoid valve used for an electric expansion valve or the like of a refrigeration system.

[0002]

2. Description of the Related Art FIG. 8 is a sectional view of a conventional motor-operated valve. That is, a needle valve c which comes into contact with and separates from the valve seat b of the valve body 1 is slidably provided in a male screw pipe d provided in the valve body 1, and a rotor e having a permanent magnet is provided at the center thereof. A screw tube f is screwed to the male screw tube d so as to be rotatable and axially movable, and an end of the needle valve c is connected to an axially intermediate portion of the rotor e. The configuration is such that a stator h having a coil g inside is disposed coaxially on the outer periphery of e.

In the conventional example, the rotor e is rotated when the coil g of the stator h is energized, and the slider j moves along the spiral guide ring k in accordance with the rotation of the rotor e during operation. The rotation of the rotor e and the movement of the needle valve c are stopped at a position where they abut against the upper and lower ends m and n.

Therefore, it is necessary to accurately excite the rotor e while counting pulses in the form of a stepping motor to apply a rotating magnetic field, and inevitably require control by a microcomputer, and a relatively large system is required. Disadvantages. In addition, it is necessary to arrange a rotor coaxially on the outer periphery of the valve body and further provide a coil coaxially on the outer periphery thereof.

[0005]

SUMMARY OF THE INVENTION In view of the foregoing, it is an object of the present invention to provide an electromagnetic valve used for an expansion valve or the like of a refrigeration system by selectively energizing a plurality of coils to perform multi-stage operation. It is an object of the present invention to provide a multi-stage solenoid valve capable of setting a valve lift at a time.

[0006]

SUMMARY OF THE INVENTION In order to achieve the above object, the present invention provides a valve body having a plunger tube coupled thereto.
At the end of the plunger tube is provided a suction element,
A multi-stage solenoid valve having a hollow first plunger inserted in the plunger tube on the valve body side and a hollow second plunger inserted on the suction element side in a slidable manner. The valve body which comes into contact with and separates from the valve seat provided between the primary port and the secondary port is fixed to the first plunger, and a spring for urging the valve body in the valve closing direction is provided. The engaging step having the enlarged diameter is loosely fitted to the engaging step formed on the second plunger, and a stopper for restricting the sliding of the second plunger in the first plunger direction is provided. In the valve state, a first gap is formed between the first plunger and the second plunger, and a second gap larger than the first gap is provided between the suction element and the second plunger. The plunger tube has a first
A first coil corresponding to the plunger and the second plunger and a second coil corresponding to the second plunger and the attraction element are provided, and when the first coil is energized, the valve corresponds to the first gap. When the second coil is energized, a second lift corresponding to the second gap is formed in the valve body.
A lift occurs, and when the first and second coils are energized,
A configuration was employed in which a third lift corresponding to the sum of the first lift and the second lift was generated in the valve element.

Further, a mortar-shaped recess is formed at one end of each of the ends facing the second plunger and the suction element, and the other end is a protrusion corresponding to the recess. Was adopted. Also,
A plunger tube is coupled to the valve body, a suction element is provided at an end of the plunger tube, and a hollow first plunger is provided in the plunger tube on the valve body side and a hollow first plunger is provided on the suction element side. A multi-stage solenoid valve, each of which is slidably inserted with the second plunger, wherein the valve body that comes into contact with and separates from a valve seat provided between a primary port and a secondary port of the valve body is the first plunger. The first plunger is fixed to the first plunger, the first plunger is provided with a first spring for urging the valve body in a valve closing direction, and the first plunger is provided with a first locking step in a hollow portion thereof. One end of the first connecting rod provided with a retaining ring in the locking step is loosely fitted, and the other end of the first connecting rod provided with the retaining ring is formed at the lower end of the hollow portion of the second plunger. One end of the second connecting rod, which is loosely fitted to the engaging portion and provided with a retaining ring, is formed in the hollow portion of the second plunger. A second spring that loosely fits into the second locking step portion, locks the other end of the second connecting rod to the suction element, and biases the valve body in the valve closing direction on the second plunger; In the valve closed state, a first gap is provided between the first plunger and the second plunger, and a second gap larger than the first gap is provided between the second plunger and the suction element. A first coil corresponding to the first plunger and the second plunger;
A second coil corresponding to the plunger and the suction element is provided, and when the first coil is energized, a first lift corresponding to the first gap is generated in the valve body, and when the second coil is energized, The valve body has a second gap corresponding to the second gap.
A lift occurs, and when the first and second coils are energized,
The third lift corresponding to the sum of the first lift and the second lift is formed on the valve body.

[0008]

According to the first aspect of the present invention, as described above, the first invention
When the coil is energized, the first plunger between the first plunger and the second plunger in a valve-closed state is closed.
A first lift corresponding to the gap is generated, and when the second coil is energized, a second lift corresponding to a second gap between the suction element and the second plunger in the valve closed state is generated in the valve body, and the first lift is generated.
When the second coil is energized, a third lift corresponding to the sum of the first lift and the second lift is generated in the valve body.

Further, at each end of the second plunger and the suction element facing each other, a mortar-shaped recess is formed at one end, and the other end is formed at a protrusion corresponding to the recess. Formed, the first lift,
A new lift can be set by controlling the current of each coil separately from the second lift and the third lift.

[0010] Since the second invention is configured as described above,
When the first coil is energized, a first lift corresponding to a first gap between the first plunger and the second plunger in a valve closed state is generated in the valve body, and when the second coil is energized, A second lift corresponding to a second gap between the suction element and the second plunger in the valve closed state is generated in the valve body, and the first lift and the second lift are applied to the valve body when the first and second coils are energized. A third lift corresponding to the sum of the two lifts results.

[0011]

FIG. 1A is a sectional view of a first embodiment of a multistage solenoid valve A according to the first invention. That is, the multi-stage solenoid valve A
The plunger tube 2 is coupled to the valve body 1, a suction element 3 is provided at an end of the plunger tube 2, and the first plunger 4 is further connected to the valve body 1 of the plunger tube 2. A second plunger 5 is slidably provided on the suction element 3 side.

The valve seat 10 is formed between a primary port 7 to which the joint 6 of the valve body 1 is connected and a secondary port 9 to which the joint 8 is connected. Valve body 11
The first plunger 4 and the snap ring 12 are fixed at a position where the upper end of the first plunger 4 contacts the jaw 11b of the head 11a.

The head 11a of the valve element 11 has an engaging step 11c formed by expanding the diameter of the upper part, and the head 11a is formed by a locking step formed at the lower end of the hollow portion 13 of the second plunger 5. 14 is slidably and loosely fitted to 14. In the hollow portion 13 of the second plunger 5, a spring 15 has one end thereof connected to the valve body 1.
1 and the other end thereof contacts the lower surface of the suction element 3 to urge the valve body 11 in the valve closing direction.

A stopper rod 16 as stopper means of the second plunger 5 penetrates a notch 4a formed in the first plunger 4, and one end of the stopper rod 16 is a stepped portion of the valve body 1. 17 and the other end thereof abuts against the lower surface of the second plunger 5 in the valve closed state, and contacts the upper surface of the first plunger 4 in the valve closed state.
Forming a first gap L ₁ between the lower surface of the plunger 5 (see FIG. 1 (B)).

[0015] The distance in the closed state from the upper surface of the stopper rod 16 to the lower surface of the suction element 3, a second gap L ₂ is formed by being slightly greater than the height of the second plunger 5, further wherein than the first gap L ₁ second gap L ₂ is set larger.

A first coil 19 is wound around the bobbin 18 from the valve seat 10 on the plunger tube 2 and corresponds to the first plunger 4 and the second plunger 5, and is attached to the bobbin 18 from the suction element 3. The second coil 20 is wound and corresponds to the second plunger 5 and the suction element 3.

Reference numeral 21 denotes a spacer made of a non-magnetic material.
The magnetic flux generated in the first coil 19 and the second coil 20 is mutually cut off. A lid 22 also serves as a magnetic flux passage, and is screwed to the suction element 3 with a nut 23. Reference numerals 24, 25, 26, and 27 denote yokes made of a magnetic material serving as a magnetic flux passage.

Since the multi-stage solenoid valve A of the first embodiment according to the first invention is constructed as described above, the first coil 1
9, the first plunger 4 and the second plunger 5 are attracted and the valve body 11 is turned on, as shown in FIG.
'S engagement step 11c by compressing the spring 15, the first plunger 4 and the valve body 11 together displaced upwards by an amount corresponding to the first gap L _1, the leading end of the valve seat 10 and the valve element 11 resulting in first lift L ₁ between the parts 11d.

At this time, since the second coil 20 is not energized, the second gap L between the second plunger 5 and the attraction element 3 is not changed.
₂ is kept as is. When the second coil 20 is energized, as shown in FIG. 3, the second plunger 5 and the suction element 3 come into close contact with each other, and the locking step 1 of the second plunger 5
4 engages the engaging step portion 11c of the valve body 11, displaced upward by the amount corresponding to the second gap L _2, the second between the tip portion 11d of the valve seat 10 and the valve element 11 produce the lift L _2.

At this time, since the first coil 19 is not energized, the first gap L ₁ between the second plunger 5 and the first plunger 4 is maintained. First coil 19
When the second coil 20 and the second coil 20 are energized simultaneously, the first plunger 4 comes into close contact with the second plunger 5 as shown in FIG.
The engaging step 11 c of the valve body 11 compresses the spring 15. Therefore, the second plunger 5 is displaced to a separating upward corresponding to the second gap L _2, the first plunger 4 is an amount corresponding to the first gap L _1, displaced upward. As a result, a third lift corresponding to the sum of the first lift L ₁ and the second lift L ₂ is generated in the gap between the distal end portion 11 d of the valve body 11 and the valve seat 10.

FIG. 5 is a sectional view of a second embodiment of the multi-stage solenoid valve A 'according to the first invention. That is, a mortar-shaped concave portion 5a 'is formed at the upper end edge of the second plunger 5', and a convex portion 3a 'corresponding to the concave portion 5a' is formed at the lower end of the suction element 3 '.

The rest of the configuration is the same as that of the first embodiment of the first aspect of the present invention, and will not be described. Therefore,
In operation, as in the first embodiment, a first lift L ₁ is generated in the valve body 11 by energizing the first coil 19, and a second lift L ₂ is generated in the valve body 11 by energizing the second coil 20. the first coil 19 and the valve body 11 by energizing the second coil 20 produces a third lift the first lift L ₁ and corresponds to the sum of the second lift.

The difference is that by setting the current value of each selected coil to a current value of an arbitrary percentage of the rated current of the coil, for example, by performing the fourth lift, 50% of the first lift L ₁ To set a new
The fifth lift can be newly set to 50% of the second lift, and the sixth lift can be newly set to 50% of the third lift.

FIG. 6 is a sectional view of a third embodiment of the multistage solenoid valve A "according to the first invention. That is, a plunger tube 29 is connected to a valve body 28, and the plunger tube 29 is connected to the valve body 28.
Is provided at the end of the plunger tube 29.
The first plunger 31 is slidably provided on the valve body 28, and the second plunger 32 is slidably provided on the suction element 30 side.

The valve seat 10 is formed between a primary port 7 connected to the joint 6 of the valve body 28 and a secondary port 9 connected to the joint 8. The first plunger 31 is attached to the jaw 33b of the head 33a of the valve body 33.
Plunger 31 and retaining ring 3 at a position where the upper end of
It is fixed at 4.

The head 33a of the valve element 33 has an engagement step 33c formed by expanding the diameter of the upper part, and the head 33a has a locking step formed at the lower end of the hollow portion 35 of the second plunger 32. 36
Is slidably loosely fitted to A spring 37 contacts one end of the hollow portion 35 of the second plunger 32 with the valve element 33, and the other end of the suction element 3
The valve body 33 is urged in the valve closing direction by contacting the lower surface of the valve body 0.

The second plunger 32 has an engaging step 32a formed by expanding the diameter of the suction element 30 side, and a locking step 29a provided by the suction element 30 of the plunger tube 29. The plunger 32 constitutes stopper means for the direction of the valve seat 10. In the closed state, the upper end of the first plunger 31 is provided between the second plunger 32 are set to have a first gap L _1, the engaging step portion 33c of the second plunger 32 the valve body 33 Is pushed downward by a spring 37 through the engaging step 32a,
The second gap L is locked between the upper end of the second plunger 32 and the lower end of the suction element 30 by being locked by the locking step 29a of the plunger tube 29 which is a stopper means of the second plunger 32.
Has _two . The second gap L ₂ is set larger than the first gap L _1.

The other configuration is the same as that of the first embodiment, and the description is omitted. The operation is the same as that of the first embodiment, and the description is omitted. FIG.
FIG. 5 is a sectional view of an embodiment of the multi-stage solenoid valve B according to the second invention. That is, a plunger tube 39 is coupled to the valve body 38, a suction element 40 is provided at an end of the plunger tube 39, and the first plunger 41 is further connected to the valve body 38 of the plunger tube 39. A second plunger 42 is slidably provided on the suction element 40 side.

The valve seat 10 is formed between a primary port 7 to which the joint 6 of the valve body 38 is connected and a secondary port 9 to which the joint 8 is connected. The head 43a of the valve body 43 is provided with the hollow portion 4 of the first plunger 41.
4 is fitted and fixed at the lower part.

One end of the first connecting rod 45 provided with the retaining ring 46 is slidable on a first locking step 47 formed at an intermediate portion of the hollow portion 44 of the first plunger 41. It is loosely fitted. A retaining ring 48 is provided at the other end of the first connecting rod 45, and is loosely fitted to a lower end of the hollow portion 49 of the second plunger 42 by a washer 50 as an engaging portion.

A second locking step 51 is formed in the middle of the hollow portion 49 of the second plunger 42.
One end of a second connecting rod 52 provided with a retaining ring 53 is loosely fitted, and the other end of the second connecting rod 52 is inserted into the suction element 40. Constitutes stopper means for closing the second plunger 41 in the valve closing direction.

A first spring 54 is provided in the hollow portion 44 of the first plunger 41 to urge the valve body 43 in the valve closing direction, and a second spring 55 is also provided in the hollow portion 49 of the second plunger 42. And urges the second plunger 42 in the valve closing direction. Therefore, the first locking step 47 of the first plunger 41 comes into contact with the retaining ring 46 of the first connecting rod 45 to constitute a stopper means in the valve closing direction, and the second plunger 42 is the second plunger 42. The locking step portion 51 contacts the retaining ring 53 of the second connecting rod 52 to constitute a stopper means in the valve closing direction.

In the closed state, the first plunger 41
Top and between the lower end of the second plunger 42 are set to have a first gap L ₁ via the first spring 54, the lower end of the upper end and the attractor 40 of the second plunger 42 of the It is set to have a second gap L ₂ via the second spring 55 is provided between, the second gap L ₂ is set larger than the first gap L _1.

The other configuration is the same as that of the first embodiment of the first invention, and the description is omitted. When the first coil 19 is energized, the upper end of the first plunger 41 and the second plunger 4
With 2 the lower end is in close contact, the first spring 54 is compressed, the first plunger 41 is displaced upward by the amount corresponding to the first gap L _1, a needle portion 4 of the valve body 43
Gap between 3b and the valve seat 10 results in a first lift L _1.

[0035] Upon energizing the second coil 20, the second plunger 42 is in close contact with the suction element 40, the second spring 55 is compressed, the second plunger 42 by the amount corresponding to the second gap L ₂ Displaced upward, the valve element 43
The gap between the needle portion 43b and the valve seat 10 of the results of the second lift L _1.

When the first coil 19 and the second coil 20 are energized simultaneously, the second plunger 42 comes into close contact with the suction element 40, the first plunger 41 comes into close contact with the second plunger 42, and the first spring 54 and the second spring 55 is compressed, respectively, the second plunger 42 is displaced upward by the amount corresponding to the second gap L _2, first
The plunger 41 is displaced upward by the amount corresponding to the first gap L _1.

[0037] As a result, the gap between the needle portion 43b and the valve seat 10 of the valve body 43, produces a third lift corresponding to the sum of the first lift L ₁ and the second lift L _2.

[0038]

Since the present invention is constructed as described above, in a solenoid valve used for the purpose of an expansion valve or the like of a refrigeration system, by selectively energizing a plurality of coils, a simple multi-step operation is possible. This has the effect that the valve lift can be set.

[Brief description of the drawings]

FIG. 1A is a sectional view of a first embodiment of a multistage solenoid valve according to the first invention. (B) is a sectional view of the stopper means.

FIG. 2 is a sectional view when a first coil is energized.

FIG. 3 is a sectional view when the second coil is energized.

FIG. 4 is a cross-sectional view when a first coil and a second coil are energized.

FIG. 5 is a sectional view of a second embodiment of the multistage solenoid valve according to the first invention;

FIG. 6 is a sectional view of a third embodiment of the multistage solenoid valve according to the first invention;

FIG. 7 is a sectional view of an embodiment of a multi-stage solenoid valve according to the second invention.

FIG. 8 is a sectional view of a conventional example.

[Explanation of symbols]

 A, A ', A ", B Multi-stage solenoid valve 1, 28, 38 Valve body 2, 29, 39 Plunger tube 3, 30, 40 Suction element 4, 31, 41 First plunger 5, 32, 42 2 plunger 6,8 joint 7 primary opening 9 secondary opening 10 valve seat 11,33,43 valve body 11a, 33a head 11b, 33b jaw 11c, 33c ,, 51 engagement step 11d, 33d tip 12 , 34, 46, 48, 53, retaining ring 13, 35, 44, 49 hollow portion 14, 36, locking step 15, 37 spring 16 stopper rod 17 step 18 bobbin 19 first coil 20 second coil 21 spacer 22 Lid 23 Nut 24, 25, 26, 27 Yoke 45 First connection rod 47 First locking step 50 Washer 51 Second locking step 52 Second connection rod 54 First spring 55 2nd spring

Continuation of the front page (56) References JP-A-51-83220 (JP, A) JP-A-63-6284 (JP, A) JP-A-56-54372 (JP, U) JP-A-61-166283 (JP, A) , U) Shokai 55-177567 (JP, U) Shokai 55-176527 (JP, U) Shoko 59-39249 (JP, Y2) (58) Fields investigated (Int. Cl. ⁷ , DB Name) F16K 31/06-31/11

Claims (3)

(57) [Claims] 1. A plunger tube is coupled to a valve body, a suction element is provided at an end of the plunger tube, and a hollow first plunger is provided in the plunger tube on the valve body side. A multi-stage solenoid valve in which a hollow second plunger is slidably inserted on a suction element side, wherein the valve body comes into contact with and separates from a valve seat provided between a primary port and a secondary port of the valve body. A valve body is fixed to the first plunger, a spring for urging the valve body in a valve closing direction is provided, and an engagement step having an enlarged diameter formed on the valve body is formed on the second plunger. A stopper is provided for loosely fitting to the stop portion and for restricting the sliding of the second plunger in the direction of the first plunger. The stopper is provided between the first plunger and the second plunger in the valve closed state. Forming a gap, the suction element and a second plunger; And a second gap larger than the first gap is provided between the first plunger tube and the first coil corresponding to the first plunger and the second plunger; A corresponding second coil is provided, and when the first coil is energized, a first lift corresponding to the first gap is generated in the valve body, and when the second coil is energized, the valve body is provided with the second gap. A corresponding second lift occurs, and when the first and second coils are energized, the first
A multi-stage solenoid valve configured to generate a third lift corresponding to the sum of the lift and the second lift. 2. A mortar-shaped recess is formed at one end of each of the opposite ends of the second plunger and the suction element, and a protrusion corresponding to the recess is formed at the other end. 2. The multi-stage solenoid valve according to claim 1, wherein: 3. A plunger tube is coupled to the valve body, a suction element is provided at an end of the plunger tube, and a hollow first plunger is provided in the plunger tube on the valve body side. A multi-stage solenoid valve in which a hollow second plunger is slidably inserted on a suction element side, wherein the valve body comes into contact with and separates from a valve seat provided between a primary port and a secondary port of the valve body. Fixing a valve body to the first plunger;
A first spring for urging the valve body in the valve closing direction is provided on the plunger, a first locking step is provided in a hollow portion of the first plunger, and a retaining ring is provided in the first locking step. One end of the first connecting rod is loosely fitted, and the other end of the first connecting rod provided with a retaining ring is loosely fitted to an engaging portion formed at the lower end of the hollow portion of the second plunger; One end of the second connecting rod provided with a retaining ring is loosely fitted to a second locking step formed in the hollow portion of the second plunger, and the other end of the second connecting rod is connected to the suction element. Locking the second plunger to bias the valve body in the valve closing direction.
A spring is provided to provide a first gap between the first plunger and the second plunger in a valve-closed state, and a second gap larger than the first gap between the second plunger and the suction element. The plunger tube further includes a first coil corresponding to a first plunger and a second plunger, and a second coil corresponding to a second plunger and a suction element. At the time of energization, the first
A first lift corresponding to the gap is generated, and a second lift corresponding to the second gap is generated in the valve body when the second coil is energized, and a second lift is generated in the valve body when the first and second coils are energized. A multi-stage solenoid valve configured to generate a third lift corresponding to the sum of the first lift and the second lift.