JP5730630B2 - Expansion valve - Google Patents

Description

  The present invention relates to an expansion valve with a built-in temperature sensing mechanism used in a refrigeration cycle.

Conventionally, for a refrigeration cycle used in an air conditioner or the like mounted in an automobile, a temperature expansion valve with a built-in temperature sensing mechanism that adjusts the passage of refrigerant according to the temperature is used to omit installation space and wiring. The
Patent document 1 shows this kind of expansion valve concerning the present applicant.
The valve body of the expansion valve has an inlet port into which high-pressure refrigerant is introduced and a valve chamber communicating with the inlet port. A spherical valve member disposed in the valve chamber is opposed to the valve seat in the valve hole that opens to the valve chamber, and is operated by a valve rod driven by a power element to open a throttle passage between the valve seat and the valve seat. Control the degree.
The refrigerant passing through the valve hole is sent from the outlet port to the evaporator side. The refrigerant returning from the evaporator to the compressor side passes through a return passage provided in the valve body.
A valve member drive mechanism called a power element is provided on the top of the valve body.
The power element is composed of an upper lid member that forms a pressure working chamber, a thin diaphragm that is elastically deformed under pressure, and a disk-shaped receiving member. The three members are overlapped and the circumference is joined by TIG welding means, etc. Formed.
A working gas is enclosed in a pressure working chamber formed by the upper lid member and the diaphragm. In order to enclose the working gas in the pressure working chamber, a hole is provided in the top portion of the upper lid member, and after filling the working gas from this hole, the hole is closed with a steel ball or the like and the pressure working chamber is sealed by a projection welding means or the like.

JP 2008-180475 A

The temperature expansion valve with a built-in temperature sensing mechanism as described above has an advantage that the outer dimensions can be reduced, but since a large number of parts are arranged in close proximity to each other, further downsizing is required. ing. There is also an advantage that the manufacturing cost can be reduced by downsizing.
This invention is made | formed in view of this situation, The objective is to provide the expansion valve which aimed at size reduction by reducing the diameter of a power element.

In order to achieve the above object, an expansion valve of the present invention is formed at an inlet port into which a high-pressure refrigerant is introduced, a valve chamber communicating with the inlet port, a valve hole opening in the valve chamber, and an inlet of the valve hole. A valve main body having an outlet port through which the refrigerant that has passed through the valve hole is sent out, a valve member disposed opposite to the valve seat, and a working gas that drives a valve rod that operates the valve member An expansion valve comprising a power element having a sealed pressure working chamber,
Said power element, and the upper cover member pressure chamber is formed, receiving member and said a diaphragm is sandwiched between the upper lid member and the receiving member, the outer peripheral portion of the receiving member and the upper lid member and the diaphragm 0.2mm~1.0mm, together are joined in a molten portion formed by laser welding, the fulcrum position location of the diaphragm is sandwiched by the upper cover member and the receiving member, the deepest penetration position of the molten portion Set to a distant position .
Further, the valve body has a cylindrical portion in which the power element is inserted, the power element by caulking the upper portion of the cylindrical portion is intended to be fixed.

  By providing the above means, the expansion valve of the present invention can be reduced in size by reducing the diameter of the power element.

Sectional drawing and the right view of one Example of the expansion valve of this invention. The principal part enlarged view of FIG. Explanatory drawing which shows the welding structure of the power element of this invention. Explanatory drawing which shows the heat influence range to the diaphragm by the welding structure of FIG. Explanatory drawing which shows the difference in the welding structure of the power element of this invention and a prior art. Sectional drawing and the right view of the other Example of the expansion valve of this invention.

FIG. 1 shows a sectional view (a) and a right side view (b) of an expansion valve of the present invention.
The valve body 10 of the expansion valve of the present invention is produced by machining a material made by extruding an aluminum alloy, and has an inlet port 20 into which a high-pressure refrigerant is introduced.
A small-diameter hole 22 is provided in the back wall of the inlet port 20 and communicates with a valve chamber 24 having a central axis in the longitudinal direction of the valve body 10. The valve chamber 24 communicates with the refrigerant outlet port 28 through a valve hole 26 formed coaxially.

A valve seat 25 is formed between the valve chamber 24 and the valve hole 26, and a spherical valve member 40 disposed in the valve chamber 24 faces the valve seat 25.
The valve member 40 is supported by a support member 42, and the support member 42 is supported by a plug 50 that seals the opening of the valve chamber 24 via a coil spring 44. The plug 50 is screwed into the opening of the valve chamber 24 of the valve body 10 by a screw portion 52. Since the plug 50 can be rotated by inserting a wrench into the bottomed hexagonal hole 53, the spring force of the coil spring 44 that supports the valve member 40 can be adjusted by adjusting the screwing amount of the plug 50. it can.
A seal member 54 is provided on the outer peripheral portion of the plug 50, thereby sealing the valve chamber 24.

The refrigerant sent out from the outlet port 28 is sent to the evaporator and exchanges heat with the outside air to evaporate. The refrigerant returning from the evaporator to the compressor side passes through a return passage 30 provided in the valve body 10.
The power element 100 is attached to the top of the valve body 10 by a crimping portion 12 a formed by caulking the upper portion of the cylindrical portion 12 formed on the upper portion of the valve body 10. A seal member 64 is disposed between the power element 100 and the valve body 10.

The power element 100 is manufactured in a manner described later, and includes an upper lid member 110, a ring-shaped receiving member 120, and a diaphragm 130 sandwiched between the upper lid member 110 and the receiving member 120.
A working gas is sealed in a pressure working chamber 112 composed of the upper lid member 110 and the diaphragm 130 and sealed with a plug 114. A stopper member 62 is disposed on the lower surface of the diaphragm 130, and the movement of the stopper member 62 is transmitted to the valve member 40 via the valve rod 60. A spring member 66 is disposed on the outer periphery of the valve stem 60, and a sliding resistance is added to the valve stem 60 to prevent vibration of the valve member 40.
The valve body 10 is provided with two through holes 70 penetrating the valve body 10 and used as bolt insertion holes for attaching the valve body 10 to other members. In addition, one bottomed screw hole 80 is also formed in the center of the valve body 10.

FIG. 2 is a cross-sectional view of the power element 100.
In the power element 100, the upper lid member 110, the diaphragm 130, and the receiving member 120 are overlapped, and a welded portion W is formed on the outer peripheral portion by welding means to form a unit. The upper lid member 110 has a convex portion at the center, and a hole 116 is provided at the top. A working gas is injected into the pressure working chamber 112 defined between the hole 116 and the diaphragm 130, and the hole 116 is closed with a plug 114 and sealed by welding or the like.
In order to reduce the size of the expansion valve, it is necessary to reduce the outer diameter D of the power element 100.

(A) of FIG. 3 shows the case of forming the welded portion _{W 1} by TIG welding. Due to the length L ₁ of the welded portion W ₁ formed by TIG welding, a heat affected range H ₁ is generated in the overlapping portion of the upper lid member 110, the diaphragm 130, and the receiving member 120. Since TIG welding often heat is turned in forming the molten portion W _1, the heat-affected area H ₁ also increases. In this range, the diaphragm 130 is also annealed and the characteristics as a diaphragm are deteriorated.
To power element 100 exerts a predetermined performance, it is necessary to ensure the effective diameter D ₅ of the inner diaphragm fulcrum P _1.
In the configuration of forming the welded portion W ₁ by TIG welding shown in FIG. 3 (a), in order to ensure the effective diameter D ₅ of the diaphragm 130, the outer diameter D ₁ of the power element 100 is increased There is a need.

(B) of FIG. 3 shows the case where the melting section W ₂ by laser welding. In the laser melting, the melted portion W ₂ is formed as a length dimension L ₂ inside the end surfaces of the upper lid member 110 and the receiving member 120.
Further, it requires only a heat requires less to form a molten portion W _2. Therefore, the thermal influence range _{H 2} is also reduced.
Utilizing characteristics of the laser melting, while ensuring the effective diameter D ₅ of the diaphragm 130, it is possible to reduce the outer diameter D ₂ of the power element 100.

FIG. 4 is an explanatory diagram showing a range in which a thermal effect is exerted on the diaphragm 130 when the outer peripheral portion of the power element 100 is TIG welded and when laser welding is performed.
In TIG welding, the diaphragm 130 is affected by annealing from the length dimension due to the melting of the melted portion W to about 1.0 mm, but in laser welding, it is 1.0 mm or less, and up to about 0.2 mm. Experiments have confirmed that it can be made smaller.

By utilizing the characteristics of laser welding as described above, as shown in (b) of FIG. 3, the melting unit distance dimension S ₁ from the support position P ₁ of the diaphragm 130 to the outer periphery of the power element 100 is formed by laser melting It was set to a distance obtained by adding 0.2mm~1.0mm the length dimension _{L 2} of W _2. The distance S ₁ is half of the difference between the outer diameter D ₂ of the power element 100 and the effective diameter D ₅ of the diaphragm 130. In order to minimize the outer diameter of the power element 100 while avoiding the thermal effect, the distance added to the L ₂ is preferably about 0.5 ± 0.2 mm.
As described above, in the present invention, the outer diameter dimension of the power element 100 can be reduced while ensuring the effective diameter dimension of the diaphragm 130.

(A) of FIG. 5 shows the case of forming the molten portion _{W 1} by TIG welding by torch _{T 1.}
As described in (a) of FIG. 3, the outer diameter D ₁ of the power element 100 needed to ensure the effective diameter D ₅ of the diaphragm 130 increases.

FIG. 5B shows a case where the melted portion W ₂ is formed by the laser beam B ₁ irradiated from the laser torch T ₂ .
As described in (b) of FIG. 3, the outer diameter D ₂ of the power element 100 needed to ensure the effective diameter D ₅ of the diaphragm 130 can be reduced.

A small expansion valve can be obtained by inserting the power element 100 into a cylindrical portion 12 formed on the upper portion of the valve body 10 and fixing the power element 100 with a caulking portion 12a.
In the case of such a caulking structure expansion valve, the outer diameter of the upper portion of the expansion valve is a dimension obtained by adding twice the thickness of the caulking portion 12 a to the outer diameter of the power element 100. In the case of the conventional power element by TIG welding, since the outer diameter is large, there is a problem that it is difficult to adopt such a caulking structure. However, according to the present invention, the power element 100 can be made to have a small diameter. It becomes easy to adopt. This eliminates the need for screw processing for screwing the power element 100 to the valve body 10, thereby reducing the manufacturing cost.

In this embodiment, the valve stem 60 is in contact with the diaphragm 130 via the stopper member 62, and the receiving member 120 has a ring shape, and a gap is formed between the inner peripheral portion and the outer peripheral portion of the stopper member 62. The stopper member 62 is in contact with the valve main body 10 so that movement in the valve opening direction is restricted.
In the conventional expansion valve, as shown in FIG. 6, the stopper member 62 comes into contact with the receiving member 120 so that the movement in the valve opening direction is limited. In contrast, in this embodiment, The height dimension of the expansion valve can be shortened.
Further, since the receiving member 120 is not interposed between the stopper member 62 and the valve body 10, the vertical position of the stopper member 62 is not affected by the thickness of the receiving member 120, so the position of the diaphragm 130 is stabilized, There is less variation in individual performance.

  In the present invention, as shown in FIG. 6, an expansion valve having a structure in which the power element 100 is screwed to the valve body 10 by the screw part 120 a formed on the receiving member 120 and the screw part 10 a formed on the valve body 10. It is also applicable to.

  In addition, various modifications can be made to the above embodiment without departing from the gist of the present invention.

DESCRIPTION OF SYMBOLS 10 Valve main body 12 Cylindrical part 12a Caulking part 20 Inlet port 22 Small diameter hole 24 Valve chamber 25 Valve seat 26 Valve hole 28 Outlet port 30 Return path 40 Valve member 42 Support member 44 Coil spring 50 Plug 52 Screw part 53 Hexagon hole 54 Seal member 60 Valve Rod 62 Stopper Member 64 Seal Member 66 Spring Member 70 Through Hole 80 Screw Hole 100 Power Element 110 Upper Cover Member 120 Receiving Member 130 Diaphragm

Claims (2)

An inlet port into which a high-pressure refrigerant is introduced, a valve chamber communicating with the inlet port, a valve hole opening in the valve chamber, a valve seat formed at the inlet of the valve hole, and a refrigerant passing through the valve hole are sent out An expansion valve comprising: a valve body having an outlet port; a valve member disposed to face the valve seat; and a power element having a pressure working chamber enclosing a working gas for driving a valve rod for operating the valve member. There,
The power element is provided with a lid member which pressure chamber is formed, and the receiving member, and a diaphragm sandwiched between the upper lid member and the receiving member,
The outer peripheral portion of the upper cover member and said diaphragm and said receiving member, while being bonded in the molten portion formed by laser welding, the fulcrum position location of the diaphragm is sandwiched by the receiving member and the upper lid member, the molten portion The expansion valve which is a position 0.2 mm to 1.0 mm away from the deepest penetration position . The valve body has a cylindrical portion in which the power element is inserted, the expansion valve according to claim 1, wherein the power element is fixed by caulking the upper part of the cylindrical portion.

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