NO313717B1 - Device for closable fluid flow valve, special use of the valve and method in connection with valve closure and opening - Google Patents

Description

The invention relates to devices for closable fluid flow-through valves comprising a tubular housing in which a valve seat with a through-hole for the flowing fluid is fitted, and a valve body that interacts periodically with this, displaceably arranged with at least one axial through-hole for the flow of the fluid, where the seat and valve body cooperate in at least shaped with each other in the valve's closed position, where opposite surface parts on adjacent parts of the seat and valve body are in sealing contact with each other, and where there are means to partly bring the valve body into hole-covering, sealing contact with the seat, corresponding to the closed valve position, partly to move the valve body in the opposite direction, away from the seat, to another position, corresponding to the open valve position.

The invention relates to at least one particular application of a closable/openable fluid flow valve designed in accordance with the present invention, namely as a modulating valve, designed for continuous regulation of the fluid flow that passes through the valve at any time.

In a method which is also covered by the present invention, measures are taken to dampen the closing movement of the valve body towards the seat by creating a closed valve position and its opening movement away from the seat, where at the end of the valve body opposite the seat there is arranged a ring/sleeve-shaped stopper body, and where the latter end of the valve body is internally designed with a conical surface: for cooperation with a complementary abutment surface on the stopper body.

Fluid as in. due to the internal special design of the valve construction has been guided between cooperating conical surfaces at one or the other end of the valve body and the seat or stopper, acts as a damping medium for the last part of the relative movement of the conical surfaces in the direction towards each other.

An annulus enclosing the end portion of the valve body closest to the seat may contain a helical pressure spring and will be in fluid communication with fluid residing between cooperating conical surfaces at one or the other end of the valve body, depending on whether the valve is in the process of being closed or whether the opening bias is about to end.

Said annulus is delimited in the axial direction between an outwardly directed flange; of a guide sleeve which constitutes a piece of the valve housing, farthest from the seat, and a stepped part of the valve body, so that the spring in the annulus is compressed axially when the valve body is pulled away from the seat. This annulus acts as a damping chamber during regulation.

In a preferred embodiment, the valve body can have at least one reaction surface facing away from the intended direction of fluid flow, so that the flowing fluid attacks said reaction surface and drives the valve body towards the seat to create a closed valve position, provided that other forces acting on the valve body and has a direction opposite to the fluid flow direction, falls short of the fluid's impact force on the valve body's reaction surface. Mentioned other forces can advantageously be developed by an electromagnetic coil which surrounds the valve housing and a part of the sleeve-shaped valve body which acts as a magnetic armature.

The valve may belong to a valve type known as "coaxial valves" where the tubular valve body, a central through-hole, circular disc-shaped seat body and a linear reciprocating, sleeve-shaped valve body are positioned coaxially with each other and thus have one common straight-line longitudinal axis.

In one known embodiment of such a coaxial valve which is designed for concentric installation in a pipeline in which a fluid flows, which may consist of a gaseous or liquid medium or a gelatinous medium, and where the fluid/medium may also be abrasive, aggressive and/or contaminated, the gable surface of the sleeve-shaped valve body forms at its end closest to the seat a planar abutment surface which is parallel to the opposing circular surface of the seat body, that is to say that the abutment surface of the valve body and the opposite surface of the seat-forming circular disk are essentially perpendicular to said joint rectilinear longitudinal axis.

The fluid/medium to be controlled/controlled flows through the valve body and is led past the valve disc with significant changes in direction in relation to its intended axial flow direction.

Such coaxial valves are very versatile and applicable and thus have a very wide range of applications. They are known to be reliable in function and ensure good performance. They are further distinguished in an advantageous respect by being essentially completely balanced with regard to pressure, so that any inlet pressure has no effect on the opening/closing properties of the valve. Coaxial valves are very simple in construction, and the function is based on the simplest forms of operation.

However, one serious disadvantage of valve constructions of the kind indicated at the outset is that the liquid flow through the valve, as it flows out of the valve body and passes the circular disc-shaped seat, is subjected to at least one significant change in direction of flow. Another serious disadvantage of this known type of valve construction is that it is necessary to provide the sleeve-shaped valve body with external sliding seals. The design of the valve requires a planar annular abutment surface portion on the adjacent end of the valve body to provide sealing at the seat when the valve is closed. The outer circumferential edge of the valve body's aforementioned sealing abutment surface portion must extend a considerable distance beyond the valve body's hole-delimiting, circular, inner circumferential edge in order to be able to ensure the desired sealing effect with a high degree of reliability.

These requirements for the valve's closing properties inevitably result in the sleeve-shaped valve body having to be dimensioned so that the wall thickness is large and the bore diameter is reduced, which is very unfortunate and undesirable in a fluid re-

flow valve of this general nature.

Another disadvantage of the aforementioned valve construction of coaxial type is that the very simplified design of the valve seat and body makes it difficult (without significant modifying interventions in the constructive valve structure) to provide differentiated throttling with a high degree of accuracy. The large deviation in flow direction at the seat gives rise to unwanted turbulence phenomena and thereby affects the fluid flow in the seat area in a negative direction.

A main purpose of the present invention has therefore been to remedy shortcomings, disadvantages and limitations of use that are inherent in known techniques, and also to bring about technical advantages in other, related respects.

Said purpose is essentially realized in that a device for a closable fluid flow-through valve designed in accordance with the introductory part of patent claim 1 also exhibits the special features indicated in the characterizing part of patent claim 1.

The application and the method associated with such a valve construction are distinguished by features which are specified in separate patent claims.

Advantageous, albeit subordinate, features of the valve construction appear from the non-independent patent claims whose content has a real connection to the invention according to the independent apparatus claim, patent claim 1.

The seat body is designed as a hollow body with a conically tapered outer surface facing the valve body in which at least two through holes open out either directly or via a transition cavity. The conical surface parts that enclose the outer mouth of each through hole must be substantially covered during sealing by a complementary conical surface part formed internally in the adjacent end part of the valve body, which is continuous and unperforated.

When this end of the valve body together with the seat is to effect closing of the valve, it is controlled due to the cooperating, mutually sliding conical surface parts towards an end position where the surface parts now sealing against each other displace fluid while dampening the closure's conclusion.

In a longitudinal plane of symmetry through the valve construction, the outer contour of the seat body will be represented by two diametrically opposed generatrices. The same will of course apply to an inner contour of the valve body's complementary conical cavity in the end part.

The internal conical cavity at the end of the valve body closest to the seat is delimited in said axial symmetry plane by two diametrically opposed generatrices.

Such a generatrix can be thought of as constituting the hypotenuse of a right-angled triangle where a leg is assumed to extend perpendicular to said plane. It is obvious that the hypotenuse will have a superior longitudinal extent when it comes to covering under "overlapping" holes formed in a complementary inclined/conical face. The valve body's internal, effective contact surface has a significantly smaller dimension in a plane perpendicular to said common longitudinal axis.

The sleeve-shaped valve body thus has a large covering area with regard to sealing the holes in the seat and in this closed valve position including with a good margin to project outside the hole mouths at the conical seat surface to ensure the sealing function. At the same time, the sleeve wall at the valve body can be reduced in relation to interacting contact surfaces on the seat and on the valve body, where the contact surfaces run more or less perpendicular to the longitudinal axis of the sleeve-shaped valve body. A reduction in the wall thickness of the valve body makes it possible to increase its through bore through which the fluid flows.

In a practical embodiment, the angle at the apex of the cone that forms the conical surface portion of the seat body can be, for example, 60°. Due to the risk of the valve body wedging and becoming stuck on the outside of the seat body, the taper should not be chosen too low. In an alternative embodiment, the seat floats themselves can be placed radially, perpendicularly to the central axis of the valve in order to completely avoid frictional forces arising between the seat and the valve body.

Conical contact surfaces on the outside of the seat body and inside the cooperating end of the valve body have been shown to reduce the pulling force that the electromagnet must provide in order to influence the valve body acting as a magnetic armature and pull it away from the closed position towards the open valve position. The reason for this favorable feature is that only a proportion of the closing force caused by the differential pressure across the valve multiplied by the valve's opening area acts in the valve's axial direction. The construction of the valve thus means that a relatively large opening area can be uncovered with the help of a relatively small axial force.

By connecting the magnetic coil to a suitable control unit, the valve can be used as a modulating valve.

In what follows, a non-limiting example of a currently selected, preferred embodiment of a closable fluid flow-through valve where the device according to the invention is realized is described.

Reference is made to the attached drawings where:

Fig. 1 is an axial section through a mounted valve construction according to the invention, shown in the closed valve position; Fig. 2 shows the same, but with the valve in an intermediate position between closed and fully open position; Fig. 3 shows the same, with the valve in a fully open position; Fig. 4 shows a side view of an embodiment of a seat body separately; Fig. 5 shows a side view of a seat body in an alternative embodiment; and Fig. 6 shows a side view of a seat body in a further alternative embodiment where a section of the valve body is also shown.

An essentially straight, cylindrical/tubular valve body, generally denoted by the reference number 10, is made up of several screwed/soldered/glued individual parts with a common longitudinal axis 12.

These individual parts consist of an outlet piece 10a, an annular intermediate piece 10b with an outwardly directed, hexagonal nut-shaped end flange 10b', a guide sleeve 10c firmly connected to the latter and an inlet piece 10d.

At the axial outer end of the inlet piece 10d, which is designed with threads, a nut 14 is screwed on, which via a support piece 16 rests against one end surface of an electromagnetic coil 18, whose other end surface rests against the opposite annular end surface of the hexagonal nut-shaped end flange. end 10b' on the annular intermediate piece 10b which is functionally one with the guide sleeve 10c.

The outlet piece 10a of the valve housing has, at a certain distance from its outer end, an internal, ring-shaped shoulder surface 10a' which faces away from said outer end and serves as a bearing surface for a specially shaped seat body 20 which, with the outer surface of a radially protruding flange portion 20a, abuts against the bearing surface -ten 10a' and with an annular part 20b engages in the bore 22 of the outlet piece 10a.

The seat body 20 has a central, massive front piece part 20c and a conically tapered outward surface part 20C formed between this and the ring-shaped part 20b, fig. 3, which is important to the intended function of the present invention.

The conical part 20c' of the hollow seat body 20, see fig. 4, is designed with through holes 24, which are designed with the desired opening area and number, preferably equidistantly distributed along an imaginary circle perpendicular to the longitudinal axis 12 and positioned approximately in the middle of the length of the cone between the end surface

20d and one with its circumference parallel, outer limiting line 20e which terminates the extent of the conical surface portion in

direction towards the outer, free end of the outlet piece 10a.

The fluid flow holes 24 of the seat 20 can be designed with a rather significant individual opening area, because the mouths of the holes are located at an inclined/conical surface. In order to cover these through-holes 24 in the closed valve position so that a circular, ring-shaped, hole mouth civ-bounding surface part of the conical surface around each hole 24 is simultaneously covered sealingly, an internal, complementary conical contact surface part 26a is used in the nearby end part of a reciprocating valve body 26 which form the magnetic armature for the electromagnetic coil 18.

The complementary conical, internal abutment surface 26a of the valve body 26 is designed and dimensioned to be able to be brought into shaped, tight-fitting abutment contact with the conical side surface 20c' of the seat body 20, thereby closing the valve. The inclined/conical contact surfaces 26a, 20c<1> exert a certain control effect when the closed valve position is to be established.

It should be mentioned that the actual contact surfaces, i.e. a circular hole edge part around each hole 24 for the seat body 20 and corresponding contact surface inside the end part of the valve body 26, which contact surfaces in the closed valve position really come into contact with each other, surface to surface, not necessarily need to follow the conical course of the conical outer surface 20c' and the cooperating inner, complementary conical surface 26a, but can have a different slant (in the case of a different conicity) or a straight course in relation to the longitudinal axis 12. The surface parts of said conical surfaces which enclose said actual contact surfaces that actively participate in building up tight surface contact will, however, normally follow the original conical course of the seat body 20

or the valve body 26.

At the outer end of the outlet piece 10a opposite its free outer end, a radially protruding hexagonal nut-shaped flange 10a", which rests against the corresponding flange 10b' on the annular piece 10b, which is firmly connected to the guide sleeve 10c, is formed.

Between (a) the downstream end 10b" of the annular piece/portion 10b" (arrow 28 in Fig. 1 shows the direction of fluid flow) and (b) an opposing annular shoulder surface 26b at a stepped portion formed externally on the valve body 26 at its closing end with the internal complementary conical contact surface 26a, and between (c) the outer surface of the valve body 26 and the opposite (d) inner surface of the longitudinal section of the outlet piece 10a with reduced wall thickness, a longitudinal chamber 30 with an annular cross-section (annular space) is formed in which a helical compression spring 32 is clamped, which is pressed together and tensioned in the axial direction when the valve body/magnet armature 26 of the electromagnet coil 18 is pulled away from its closed position, Fig. 1, towards the open valve position, where Fig. 2 shows an intermediate position.

The chamber 30 is supplied with fluid and acts as a damping device during regulation operations.

When closing the valve, the fluid-filled conical space 34 also acts, see fig. 2, between the conical surface

20c' on the seat body 20 and the complementary conical surface 26a inside the downstream end of the valve body 26, as a damping direction. A corresponding, but mirrored space 36 with damping properties due to trapped fluid with the possibility of escape is found at the upstream end of the valve body 26 where

during the opening process of the valve, it will eventually cooperate with a downstream stopper part 10d'. The cooperating ends of the valve body 26 and inlet piece 10d with stop part 10d' likewise engage with each other with mutually complementary conical end parts which, in the fully open valve position, lie tightly against each other. This end position is shown in fig. 3.

With a valve design of the kind illustrated in the drawings, the valve body 26 will be able to be brought from a position corresponding to the open valve position, fig. 2, against the one in fig. 1 showed a position that corresponds to the closed valve position by utilizing the fluid that flows in the direction of the arrow 28. When moving the valve body 26 in the opposite direction, the electromagnet coil 18 is used.

By ensuring that the two radially protruding hexagon nut-like flanges 10a" and 10b' have the same external dimensions and are located in close proximity to each other, they can be advantageously operated with one common tool whenever the need arises.

In an alternative embodiment, see fig. 5, the seat body 20 is provided with a transitional cavity 20f and an undercut seat surface portion 20g. The transition cavity 20f causes the fluid flow into the through holes 24 to become less turbulent. Reduction of the seat surface 20c<1> by means of the undercut area 2 And reduces the area that can be exposed to sticking when the valve is used for certain types of sticky substances.

In a further embodiment, see fig. 6, the sealing rafts 20c<1> are designed radially perpendicular relative to the valve's central axis 12. The design prevents wedging between the seat body 20 and the valve body 26.

With regard to material selection, it is of course - in the case of the selected withdrawal device for the valve body 26 in the form of an electromagnetic coil 18 - a prerequisite that the sleeve-shaped valve body 26 consists of magnetic material such as a material with ferromagnetic properties.

In the aforementioned embodiment, the guide sleeve 10c should be made of a sintered metal or brass (non-magnetic).

Claims (13)

1. Device for a closable fluid flow-through valve comprising a tubular valve housing (10a-10d) in which a valve seat (20) with flow-through hole (24) for the flowing fluid is fitted, and a valve seat (20) periodically interacting with the tubular valve housing (10a- d) displaceably arranged valve body (26) with at least one axially through bore for the flow of the fluid, where the seat (20) and the valve body (26) cooperate at least in a form-determined manner with each other in the closed position of the valve, where opposite contact surface parts (20C, 26a) on adjacent parts of the seat (20) and the valve body (26) are in sealing contact with each other, and where there are means ("28", 18) to partly lead the valve body (26) to a seat hole-covering, sealing arrangement against the seat, corresponding to closed valve position, partly to move the valve body (26) in the opposite direction, away from the seat (20), to another position, corresponding to the open valve position, characterized in that the seat body (20) is designed as a hollow body with a surface portion (20c') facing the valve body (26), conically tapering in this direction, with at least one through hole (24) opening out on the outside of the hole body, while the seat surface parts that enclose the mouth of each through hole (24) are designed as contact surface parts for in the closed valve position to co-operate sealingly with complementary surface parts formed in an internal, essentially complementary installation surface part (26a). 2.. Device according to claim 1, characterized in that the sleeve-shaped valve body (26) at its upstream end, connected to the flow direction (28) of the fluid through the valve, is designed with at least one reaction surface (26c) facing the direction of fluid flow (28), in order to be affected by the flowing fluid in the direction of the seat (20), and that a preferably elongated longitudinal part (10c, 10d) of the valve housing (10a-10d) is enclosed concentrically by an electromagnetic coil (18) which in the current-carrying state is aligned to be able to pull a magnetic valve body (26) which likewise acts as a magnetic armature away from its engaging position with the seat (20), corresponding to the closed valve position, towards the open position. 3. Device according to claim 1 or 2, characterized in that the seat body (20) in the form of a symmetrical hole body in the essentially external conical continuous surface part (20C) is designed with one or more through holes (24) which are distributed preferably equidistantly along an imaginary circular line which is essentially perpendicular to the valve's common longitudinal axis (12). 4. Device according to claim 2, characterized in that the aforementioned reaction surface (26c) of the valve body (26) at its upstream end is designed to engage in a predetermined way into and interact, limiting movement and finally stopping, with a correspondingly designed downstream part (10d') on a inlet piece (10d) which forms a longitudinal part of the valve housing (10). 5. Device according to any one of the preceding claims, characterized in that the actual ring-shaped contact surfaces which enclose each of the through holes (24) of the seat body (20) and interact sealingly with the corresponding contact surface parts of the valve body (26) in the closed valve position by direct contact , flat to flat, lie in a plane that forms an angle with generatrices at the seat cone. 6. Device according to any one of the preceding claims, characterized in that the actual ring-shaped contact surfaces which enclose each of the through holes (24) of the seat body (20) and interact sealingly with the corresponding contact surface parts of the valve body (26) in the closed valve position by direct contact ., face to face, lie in radial planes that form a right angle with the longitudinal axis (12). 7. Device according to any one of the preceding claims, characterized in that between a longitudinal part of the inner surface of the valve housing (10a-10d) and the outer surface of the valve body (26) as well as opposite radial annular surfaces (10b) located at a distance from each other in the longitudinal direction of the valve '', 26b) in the valve housing and valve body, a longitudinal annular space (30) is delimited, in which a concentric compression spring (32) is clamped which is pressed together and tensioned when the valve body (26) is moved from the closed to the open valve position. 8. Device according to any one of the preceding claims, characterized in that said seat body (20) in the form of a hollow cone exhibits an angle (a) of the order of 40-60° at the apex of the cone between diametrically opposed generatrices. 9. Device according to any one of the preceding claims, characterized in that said seat body (20) is provided with a transition cavity (20f) in the form of an encircling groove in the seat surface (20C). 10. Device according to any one of the preceding claims, characterized in that the seat surface (20C) of the seat body (20) is provided with an undercut part (20g). 11. Use of a fluid flow valve designed in accordance with claim 1 as a modulating valve, designed for continuous regulation of the fluid flow (28) that passes through the valve at any time. 12. Method for dampening the valve body's axial movement immediately before it assumes the shut-off position, respectively an end position that corresponds to a fully open valve position, characterized in that fluid communication is ensured between the valve housing's continuous run/bore and the spaces (34; 36) that are delimited of the contact surfaces (20c, 26a; 26c, 10d') which interact in pairs when the valve is closed or in the fully open position of the valve. 13. Method according to claim 12, characterized in that fluid communication is provided between the valve housing's continuous run/bore and an annular space (30) which is delimited between the valve housing and the valve body in such a way that the fluid-filled annular space (30) is reduced in length and thus in volume during fluid displacement when the valve body (26) is pulled away from the seat (20), which annulus (30) thereby forms a damping chamber during regulation.