KR20210139292A - expansion valve - Google Patents

Abstract

The invention relates to an expansion valve (10) for controlling fluid flow, said expansion valve (10) comprising a valve means housing (12), at least one valve means movably arranged in said valve means housing (12). (16) and an actuator housing (14) in which the electric drive of the expansion valve (10) is arranged, said valve means housing (12) being formed substantially at least in part from metal, in particular from aluminum, said actuator housing 14 is substantially at least partially formed of plastic, said actuator housing 14 being secured to said valve means housing 12 by at least one connecting element 40 . According to the invention, the connecting element 40 is formed, at least in part, as a latching element and/or a clip element.

Description

expansion valve

The invention relates to an expansion valve having the features of the independent claims.

In expansion valves, it is already known to mount the actuator housing to the valve means housing via screwing. However, this combination has many installation space-related limitations.

The present invention relates to an expansion valve for controlling fluid flow, said expansion valve having a valve means housing, at least one valve means movably arranged within said valve means housing, and an electric drive of said expansion valve. It comprises an actuator housing, wherein the valve means housing is formed substantially at least partly of metal, in particular of aluminum, the actuator housing being substantially at least partly formed of plastic, the actuator housing being valved by at least one connecting element is attached to the means housing. According to the invention, the connecting element is designed, at least in part, as a latching element and in addition or alternatively as a clip element.

An expansion valve according to the invention with the features of the independent claims has the advantage that a simple and inexpensive connection can be provided between the actuator housing and the valve means housing. The actuator housing can be mounted particularly easily on the valve means housing by means of the connection element according to the invention. Also, the space required for the connection can be reduced. The connection element according to the invention allows different expansion valve variants to be connected without further adjustment. The connecting element according to the invention can provide a simple and secure connection between two parts, preferably made of different materials.

In an expansion valve of the type under discussion here the fluid is at least partially in the gaseous state in the flow region of the valve means housing, given a high pressure in the range of 1-30 bar and up to 100 bar as short as possible. Because of these thermodynamic boundary conditions, the valve means block is formed of a metal, preferably of aluminum or an aluminum alloy. However, it is also possible for at least one housing part of the valve means housing to have a plastic body with a diffusion barrier layer containing metal. This valve means housing can be manufactured simply and inexpensively compared to an aluminum block housing. At the same time, due to the tightness of the expansion valve according to the invention, it can be used in fluid circuits in which the fluid is at least partially in the gaseous state. The actuator housing, in which the electric drive is arranged, is at least partially formed of plastic, as it obeys different boundary conditions in terms of sealability and functionality.

A fluid of the type discussed herein is a heat transfer medium circulating within a fluid circuit. In particular, the fluid is a natural refrigerant such as hydrocarbon, carbon dioxide, ammonia, propane, butane, propene, water or a synthetic refrigerant such as a chlorofluorocarbon or partially halogenated fluorocarbon.

The measures set forth in the dependent claims bring about a desirable improvement of the features of the independent claim.

In a preferred development of the invention, the connecting element has at least one first section and at least one second section, said first section being at least partially engaged into the valve means housing, said second section being at least partially with the actuator housing and the second section has fir-shaped teeth on its outer peripheral surface.

In the context of the present invention, fir-shaped teeth can be understood as meaning the outer contour of a connecting element having a number of teeth. The teeth or protrusions of the fir-shaped teeth are preferably latched or clawed with a receptacle on the actuator housing, whereby a particularly simple and secure connection of the housing can be provided. Since the actuator housing is formed of plastic, the actuator housing can be deformed to provide a fixed connection when the fir-shaped teeth are pushed in.

According to a preferred development of the invention, the first section of the connecting element is formed elastically in the circumferential direction. This circumferentially elastic connecting element can be inserted particularly simply into the valve means housing under preload, so that the connecting element remains in the housing due to the restoring force. A particularly simple and robust solution can be provided, since the first section is designed at least partially as a slotted sleeve. According to a preferred development of the invention, the second section extends substantially axially, the second section is formed substantially flat and has an insertion bevel at its free end opposite the first section. This insertion slope allows the second section to be inserted into the actuator housing in a particularly simple manner. In the context of the present invention, the axial direction of such an expansion valve can be understood to mean in particular the direction of extension of the valve stem in which the valve means is arranged.

According to a preferred development of the invention, the connecting element axially surrounds the valve means housing and the actuator housing. In this case, the connecting element is preferably designed as a clamp element. By means of such a clamp element attached under preload, a particularly simple and space-saving connection between the actuator housing and the valve means housing can be provided.

A particularly simple and space-saving connecting element can be provided, in particular, in that the connecting element is formed substantially u-shaped and has at least two legs, the legs being arranged substantially parallel to each other. The legs of the connecting element preferably each have a free end, and a clamping projection is arranged at each free end of the connecting element. In the assembled state, the clamping projections can engage into the valve means housing and corresponding undercuts arranged in the actuator housing as an alternative or in addition thereto.

In particular, a particularly cost-effective connecting element can be provided by designing the connecting element as one piece, in particular as a stamping bending part.

In the drawings embodiments of the expansion valve or connection element are shown and are described in more detail in the following description.

1 is an exploded perspective view of an expansion valve according to a first embodiment;
2 is a perspective view of a connecting element designed as a clamp element;
3 is a perspective view of a valve means housing and a connecting element arranged in the valve means housing;
4 is a perspective view of a connecting element according to the embodiment shown in FIG. 3 ;

In various variant embodiments, like parts are denoted by like reference numerals.

1 shows a first embodiment of an expansion valve 10 in an exploded view. The expansion valve 10 has an actuator housing 14 and a valve means housing 12 , as is clearly shown in FIG. 1 . At least one valve means 16 is arranged inside the valve means housing 12 . The valve means 16 is designed to be movable, in particular to be rotatable with respect to the valve means housing 12 . In addition, the first valve means housing 12 has a flow area through which the fluid flows. A fluid of the type discussed herein is a heat transfer medium circulating within a fluid circuit. In particular, the fluid is a natural refrigerant such as hydrocarbon, carbon dioxide, ammonia, propane, butane, propene, water or a synthetic refrigerant such as a chlorofluorocarbon or partially halogenated fluorocarbon.

The valve means housing 12 has at least two first openings 20 , 22 defining an inlet and an outlet of the fluid to the valve means housing 12 . Due to the selected view, only one of the two first openings 20 , 22 is visible in FIG. 1 . The two openings 20 , 22 are arranged perpendicular to the axial direction 18 of the expansion valve 10 in the valve means housing 12 according to the embodiment of the invention shown in FIG. 1 . The valve means housing 10 can be designed in particular as a valve means block, which is designed to be substantially hermetic under the thermodynamic conditions given to the expansion valve 10 .

In an expansion valve 10 of the type discussed herein, the fluid in the flow region of the valve means housing 12 is at least partially gaseous, given a high pressure in the range of 1-30 bar and up to 100 bar as short as possible. Due to these thermodynamic boundary conditions, this valve means block 12 is formed of a metal, preferably of aluminum or an aluminum alloy. However, it is also possible for at least one housing part of the valve means housing 12 to comprise a plastic body with a diffusion barrier layer containing metal. This valve means housing 12 can be manufactured simply and inexpensively compared to an aluminum block housing. At the same time, due to the tightness of the expansion valve 10 according to the invention, it can be used in fluid circuits in which the fluid is at least partially in the gaseous state.

As can be seen in FIG. 1 , an actuator housing 14 is arranged on the valve means housing 12 . According to the embodiment of the invention shown in FIG. 1 , the actuator housing 14 has two actuator housing parts 24 , 26 in which an electric drive device (not shown here) is arranged. Such an electric drive can in particular be designed as a stepper motor, a brushless motor or a brush motor. The actuator housing 14 is formed substantially at least in part from plastic. In particular, the actuator housing 14 is manufactured by an injection molding process.

According to a preferred embodiment of the invention, in addition to the electric drive, a gear arrangement is arranged in the actuator housing 14 which transmits the movement of the electric drive to the corresponding valve stem 30 . Motor electronics for controlling the electric drive are also arranged in the actuator housing 14 . Corresponding valve means are arranged on the valve stem 30 . The valve stem 30 passes through the opening 32 of the valve means housing 12 and extends substantially in the axial direction 18 .

In order to seal the flow area of the fluid, a housing element 34 designed as a cover is arranged in the second opening 32 . In this case, the housing element 34 has an axially concentric bore 18 , through which the valve stem 30 projects into the valve means housing 12 .

According to the invention, the actuator housing 14 is now attached to the valve means housing 14 by means of at least one connecting element 40 designed at least in part as a latching element and alternatively or additionally as a clip element. 1 and 2 respectively show a first embodiment of such a latching or clip element.

As can be seen in FIG. 1 , the connection element 40 according to the embodiment of the invention shown here encloses the valve means housing 12 and the actuator housing 14 in the axial direction 18 and as a clamp element. is designed The clamp element 40 has a clamping projection 44 at one of its free ends 42b , a further clamping projection 45 being formed by the curved segment 60 . The curved segment is preferably part of the free end 42a, in particular the leg 58 . The clamping projections 44 , 45 engage into corresponding undercuts 46 , 47 of the valve means housing 12 and the actuator housing 14 , respectively.

According to the embodiment of the invention shown in FIG. 1 , the undercut 46 of the valve means housing 12 is designed as a recess extending substantially radially in the valve means housing 12 . The side 48 of the undercut 46 facing the actuator housing 14 in this case preferably extends substantially perpendicular to the axial direction 18 . This side 48 acts as an axial stop for the connecting element 40 in the assembled state.

According to the embodiment of the present invention shown in FIG. 1 , at least one radially extending projection 50 is arranged on the actuator housing 14 , and an undercut 47 of the actuator housing 14 is formed on the projection 50 . ) at least partially. When assembling the connecting element 40 , generally first a first clamping protrusion 44 is hooked into the undercut 46 of the valve means housing 12 , followed by a second clamping protrusion 45 of the actuator housing 14 . It is inserted into the corresponding undercut 47 . To facilitate insertion or pressing of the second clamping projection 45 into the undercut 47 on the actuator housing 14 , the projection 50 of the actuator housing 14 preferably has an insertion slope 52 .

According to the embodiment of the invention shown in FIG. 1 , the expansion valve 10 has two connecting elements 40 which are respectively arranged on opposite sides of the expansion valve 10 . Of course, the number and arrangement of the connecting elements 40 may vary.

2 shows an enlarged view of the connecting element 40 of FIG. 1 . According to the embodiment of the present invention shown in FIG. 2 , the clamp element 40 is formed in a substantially u-shape, with a first central portion 56, and legs disposed respectively on opposite sides of the central portion 56 ( 58 , 59 , the legs 58 , 59 forming the free ends 42a and 42b of the connecting element 40 , respectively. According to the embodiment of the invention shown in FIG. 2 , the legs 58 , 59 of the clamp element 40 are arranged substantially parallel to one another and extend substantially radially in the assembled state. The central portion 56 of the clamp element 40 is formed at least partially flat in accordance with the embodiment shown in FIG. 2 and extends substantially in the axial direction 18 in the assembled state.

The clamp element 40 surrounds the edge region between the adjacent valve means housing 12 and the actuator housing 14 with legs 58 , 59 . As already explained, the clamp element has clamping projections 44 , 45 which, in the assembled state, engage into respective undercuts 46 , 47 on the valve means housing 12 or the actuator housing 14 . The clamping protrusion 45 , which in the assembled state engages into the actuator housing 14 , is bent at an acute angle β with respect to the direction of extension of the associated leg 58 . The clamping projection 45 preferably has a curved segment 60 extending in the axial direction 18 and sliding over the insertion bevel 52 before engaging the corresponding undercut 47 during assembly. The legs 59 that engage into the valve means housing 12 in the assembled state are formed substantially arcuate, and the free ends 42b of the arcuate legs 59, in the assembled state, are provided with an undercut of the valve means housing 12 ( 46) on the side wall 48. In this way, a sufficient preload can be applied to the clamp element 40 during assembly.

The connecting element 40 shown in FIG. 2 is formed integrally. Such a connecting element 40 can be manufactured in a particularly simple manner by means of a stamping bending process.

The free end 42b of the clamp element 40 forms a clamping projection 44 .

According to a preferred refinement, the clamp element 40 has a bend in the region 49 across its width. Optionally, a bend across the width is also formed in the central portion 56 . Selective bending in region 49 is preferably opposite to selective bending in region 56 .

The end faces 51 of the free ends 42a, 42b preferably have edges and/or corners that are not angled or rounded. In the end face 51 , free ends 42a , 42b with edges and/or corners are formed. There is no tapering towards the free ends 42a, 42b. The clamping projection 44 and the free end 42b do not taper in width. The clamping projection 44 and the free end 42b have edges and/or corners. The clamping projection 44 and the free end 42b preferably have no rounding.

The end faces 51 of the free ends 42a and 42b are formed in a rectangular shape. The edges are preferably angled and not rounded.

The width of the clamp element 40 is preferably substantially the same over its entire length.

According to a preferred refinement, the end face 51 of the free end 42b forming the clamping projection 44 has a concave profile over its width. The two opposite edges of the end face 51 of the free end 42b that are not aligned with the central portion 56 axially project beyond the middle therebetween. In the assembled state, the edges are preferably first engaged into the undercut 46 . This prevents displacement of the clamp element 40 relative to the actuator housing 14 , for example along the undercut 46 .

The central portion 56 is preferably free from kinking in the axial direction.

The free end 42b forms a clamping projection 44 . A further clamping projection 45 is formed by a leg 58 or a further free end 42a, in particular a curved segment 60 .

The normal vector of the end face 51 of the free end 42b points substantially in the axial direction 18 .

3 and 4 respectively show a second embodiment of the connecting element 40 . 3 shows a perspective view of the valve means housing 12 of the expansion valve 10 . As can be clearly seen in FIG. 3 , the valve block has at least two first openings 20 , 22 through which fluid can enter and exit. The valve means housing 12 also has a second opening 32 through which the valve stem 30 passes. The valve means housing 12 has a substantially flat support surface 35 , on which the actuator housing 14 is arranged in the assembled state.

As can be clearly seen in FIG. 3 , the connecting element 40 connects at least one first section 70 and a second section 72 for connecting the valve means housing 12 to the actuator housing 14 . have The first section 70 engages at least partially into a corresponding bore 80 of the valve means housing 12 . The second section 72 has fir-shaped teeth 74 on its outer circumferential surface. As can be clearly seen in FIG. 2 , the second section 72 of the connecting element 40 extends substantially in the axial direction 18 . The first section 70 of the connecting element 40 is formed resiliently in the circumferential direction and is held due to its spring force and friction in the valve means housing 12 . During assembly of the actuator housing 14 , the fir-shaped teeth 74 of the second section 72 engage into the actuator housing 14 , where it is latched or clawed, whereby the valve means housing 12 and the actuator A secure connection may be provided between the housings 14 .

According to the embodiment of the invention shown in FIG. 3 , two connecting elements 40 are provided for connecting the actuator housing 14 to the valve means housing 12 , said two connecting elements 40 being each They are rotated by 45° in the circumferential direction to each other.

Of course, the number and arrangement of the connecting elements 40 may vary.

FIG. 4 is an enlarged view of the connecting element according to the embodiment shown in FIG. 3 . As can be clearly seen in FIG. 4 , the connecting element 40 has a first section 70 and a second section 72 . The connecting element 40 extends substantially in the axial direction 18 . In the assembled state, the first section 70 engages at least partially into the valve means housing 12 , and fir-shaped teeth 74 arranged on the outer circumferential surface of the second section 72 latch onto the actuator housing 14 . do. As described above, the first section 70 is formed to be elastic in the circumferential direction. According to the embodiment of the invention shown in FIG. 4 , the second section 70 is formed for this purpose as a sleeve with slots.

As can be seen in FIG. 4 , in this case the slot 88 and the through hole 90 of the slotted sleeve 70 extend substantially in the axial direction 18 . Upon assembly, the slotted sleeve 70 is compressed and inserted into the axially extending bore 80 of the valve means housing 12 . Due to the restoring force of the elastic sleeve, it is pressed against the bore wall of the valve means housing 12 and held there.

As can be clearly seen in FIG. 4 , the second section 72 is arranged on the end face 29 of the sleeve 70 . Preferably, the second section 72 is radially opposite the slot 88 . The second section 72 extends substantially in the axial direction 18 and is formed substantially flat. The outer peripheral surface of the second section 72 has fir-shaped teeth 74 . According to the embodiment of the invention shown in FIG. 4 , the fir-shaped teeth are formed by three teeth 94 each arranged on either side of the second section. The tooth size of the teeth 94 preferably decreases with increasing distance from the first section 70 . As can be clearly seen in FIG. 4 , the second section 72 has an insertion bevel 96 at its free end opposite the first section, said insertion bevel surface being positioned on the valve means housing 12 on the actuator housing ( 14) to facilitate assembly. The connecting element 40 shown in FIG. 4 is formed integrally. Such a connecting element 40 can be manufactured in a particularly simple manner by means of a stamping bending process.

10: expansion valve
12: valve means housing
14: actuator housing
16: valve means
18: axial direction
20, 22: opening
40: connection element
42a, 42b: free end
44, 45: clamping projections
46, 47: undercut
58, 59: leg
70: first section
72: second section
96: insertion slope

Claims (10)

An expansion valve (10) for controlling fluid flow, said expansion valve (10) comprising: a valve means housing (12); at least one valve means (16) movably arranged in said valve means housing (12); and an actuator housing (14) in which the electric drive of the expansion valve (10) is arranged, the valve means housing (12) being formed substantially at least in part from metal, in particular from aluminum, the actuator housing (14) comprising: The expansion valve (10), wherein the expansion valve (10) is formed substantially at least partially of plastic, the actuator housing (14) being fixed to the valve means housing (12) by means of at least one connecting element (40),
The expansion valve (10), characterized in that the connecting element (40) is formed at least in part as a latching element and/or a clip element. 2. The connection element (40) according to claim 1, wherein said connecting element (40) comprises at least one first section (70) and a second section (72), said first section (70) being at least into said valve means housing (12). wherein said second section (72) is at least partially latched with said actuator housing (14), said second section (72) having fir-shaped teeth (74) on its outer circumferential surface. (10). 3. Expansion valve (10) according to claim 1 or 2, characterized in that the first section (70) of the connecting element (40) is formed in a circumferential direction elastically, in particular at least partially as a slotted sleeve. ). 4. The second section (72) according to any one of the preceding claims, wherein the second section (72) extends substantially in the axial direction (18), the second section (72) is formed substantially flat and the first section (72) is formed substantially flat. Expansion valve (10), characterized in that it has an insertion bevel (96) at its free end opposite section (70). 5. The connecting element (40) according to any one of the preceding claims, wherein the connecting element (40) encloses the valve means housing (12) and the actuator housing (41) in the axial direction (18), the connecting element (40) ) is preferably designed as a clamp element. 6. The connection element (40) according to any one of the preceding claims, wherein the connecting element (40) is formed substantially u-shaped and has at least two legs (58, 59), the legs (58, 59) are arranged substantially parallel to each other. 7. A method according to any one of the preceding claims, wherein the legs (58, 59) of the connecting element (40) each have a free end (42a, 42b), the free end of the connecting element (40) Expansion valve (10), characterized in that at the ends (42a, 42b) respectively clamping projections (44, 45) are arranged. 8. An undercut (46, 47) according to any one of the preceding claims, wherein an undercut (46, 47) is arranged in the valve means housing (12) and/or the actuator housing (14), and corresponding clamping projections of the connecting element (40). Expansion valve (10), characterized in that (44, 45) engages into said undercut (46, 47). 9. Expansion valve (10) according to any one of the preceding claims, characterized in that the connecting element (40) is formed in one piece, in particular as a stamping bending part. 10. The valve means housing (12) according to any one of the preceding claims, wherein the valve means housing (12) comprises at least two first openings (20, 22), and the valve means (16) comprises the valve means housing (12). ) which is movably arranged inside and capable of releasing and altering the flow of fluid through the openings 20 , 22 depending on the position of the valve means 16 relative to the openings 20 , 22 . Expansion valve (10) characterized.

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