SK283570B6 - Controllable ball valve - Google Patents

Abstract

The ball valve has shutter-type throttle element inserts (40,41). The first element is located on one side of the shut-off device (20) in the opening area of the passage (21), the second one is located on the other side of the device within the flow path (14') of a first housing part (12'). Both elements have parallel teeth defining flow gaps and projecting into the flow path in rotary direction of the shut-off device. In partially open position of the device up to approx. 60 degrees, the teeth form flow dividers.

Description

The object of the invention is a controllable ball valve with a housing consisting of at least two housing parts having a through hole, with a spherical closing mechanism located inside the housing between the annular seal in which a through bore is formed and movably mounted about a pivot axis perpendicular to the through hole. a fully open position in which the through-holes in the housing portions and the through-hole of the closure member are flush with each other to the closed position separating the through-holes in the housing portions as well as any throttling position between the open and closed positions and first and second throttling elements; reducing the noise of the locking mechanism set to the throttling position.

BACKGROUND OF THE INVENTION

An adjustable ball valve of this type is already known from WO 94/07063, in which a shut-off member is provided on the inlet and outlet side with a throttle element and these throttle elements have teeth projecting into the through-hole of the shut-off member. Likewise, throttling elements are disposed in the housing at the inlet and outlet sides immediately adjacent to the shut-off member with teeth equally projecting into the through-hole, which in the throttle position cooperate with the shut-off members of the shut-off member. One half of the closure member is also provided with bores formed obliquely to its through opening which, in the throttling position, bypassing the throttling point, allow the medium to flow from the through opening in the closing organ to the outlet side of the through opening of the housing.

In the known ball valves, their complicated construction is unsatisfactory, especially in relation to the shut-off member, in which the throttle elements are formed on the inlet and outlet side in one piece with the shut-off member in the form of sawtooth-shaped protrusions projecting into the through hole of the shut-off member. In addition, the interaction of the throttle elements of the shutter members with the throttle elements on the housing side creates turbulence, which is intensified by the outlet of the medium from the through-hole of the shutter member to the through-hole on the outlet side of the jacket.

SUMMARY OF THE INVENTION

SUMMARY OF THE INVENTION The object of the invention is to provide a controllable ball valve which is characterized in comparison with the ball valve known according to WO 94/07063 by a simple construction, but which in the throttling position produces less noise immissions than in the prior art.

This object is achieved by the fact that in an adjustable ball valve according to the preamble of claim 1, the throttle elements are designed as inserts in the form of an orifice, the first throttle element being located on the side of the closure mechanism in the mouth opening area and the second throttle element a spherical closing mechanism adjacent to it in the through hole of one part of the housing, the throttle elements having teeth protruding in the direction of flow from the edge of the insert in the form of an orifice to create through spaces spaced parallel to each other in the direction of rotation of the closing mechanism in the partially open position of the closure mechanism up to the open position, a flow divider at an angle of 60 ° C.

It is an object of the invention that in the area of the opening of the borehole passing through the closure member, an annular insert is provided as the first throttle element, which ensures a simple construction of the closure member. The second throttle body is also an annular insert which is disposed on the side of the closure member facing away from the first throttle element immediately adjacent it in the through hole in the housing.

The invention is characterized by the existence of only one first and second throttle element without further assembly or additional through holes passing through the shut-off member, so that only in the region of the inlet and outlet of the shut-off member low noise.

Particularly in the open position of the closure member, flow in the region of the insert in the form of a diaphragm in which its teeth do not reach inwardly is obstructed so that a high flow passage is ensured even with the throttling elements. In the closed position, on the other hand, the protruding teeth of the orifice-shaped insert act as a flow divider, which creates spaced gaps parallel to one another.

According to a preferred embodiment of the invention, the first throttle element located in the through hole in the closure body is located on the inlet side and the second throttle element located in the through hole of the housing part is then located on the outlet side of the closure member.

According to a further embodiment of the invention, the arrangement is designed such that the teeth of the first throttle projecting into the through hole in the closing body protrude from its edge in the closing direction of the closure member and the teeth of the second throttle projecting into the through hole of the housing part protrude against authority. The teeth of the two throttle elements thus project from the region extending above the half-circumference of the aperture-shaped inserts in the same directions both to the through-hole of the closure member and to the through-hole of the housing part.

According to another embodiment, the teeth of the throttle elements protrude into the through hole as a flow divider on a circle whose center is on the side facing away from the teeth. The radii of these circles are at most identical to the diameter of the flow path.

Because of this design of the protruding teeth of the throttle elements, the protruding-tooth-free area permitting flow is prevented, formed lens-shaped and decreasing as the closure member turns to the throttling position and after this region of the tooth-free flow passage. of the element located in the passage bore of the closure member pass through the adjacent seal, or through the edge of the closure member bounding the through bore, the free ends of the tongues of the second throttle member pass. Also in this operating position, a flow-free, turbulent and noise-free flow is provided through the interstices located parallel to each other.

According to another embodiment of the invention, the through holes formed by teeth projecting as flow dividers into the through hole have equal widths to each other. The passage gaps between the protruding teeth of the first throttle element may, however, also have a different, in particular smaller, width than the passage gaps of the second throttle element.

An important further embodiment is that the second throttle element located in the through hole of the housing part is formed in one piece with a seal mounted axially movably and by means of elastic force pressed against the sealing member by the sealing surfaces. Thus, in this further embodiment, no additional sealing is required on the side of the closing member, but a second sealing element designed as an annular diaphragm simultaneously performs the function of the sealing.

BRIEF DESCRIPTION OF THE DRAWINGS

The invention is further elucidated in the following examples by means of the accompanying drawings. In schematic views, it shows:

Fig. 1 shows a longitudinal section along the section line I-I shown in FIG. 1 with an adjustable ball valve according to the invention with throttle elements in the form of orifice-shaped inserts on the inlet and outlet side of the ball closure mechanism in the open position; 2 is a longitudinal section through an adjustable ball valve along section line II - II in FIG. 2, FIG. 3 is a front view of the adjustable ball valve according to arrow III in FIG. 1, FIG. 4 shows the insert forming the throttle element on the supply side as seen in FIG. 1, FIG. 5 shows the insert for the inlet side in the view according to the arrow V in FIG. 4, FIG. 6 shows an insert forming a throttling element on the outlet side as seen in FIG. 1, FIG. 7 shows an insert for the outlet side as seen in arrow VII in FIG. 6, FIG. 8 shows a controllable ball valve in longitudinal section as in FIG. 2 with the spherical closing mechanism in a throttling position rotated about an axis of rotation relative to the open position by 45 [deg.] And FIG. 9 shows a controllable ball valve in a front view as in FIG. 3, but with a spherical closing mechanism in a throttling position rotated about an axis of rotation relative to the open position by 30 °.

DETAILED DESCRIPTION OF THE INVENTION

The ball valve 10 shown in longitudinal section in FIG. 1, consists of a housing 11 which consists of two parts 12, 12 'of the housing 11 complementing each other in an approximately spherical shape. The two housing parts 12, 12 'are connected to each other by means of screws 13. The housing parts 12, 12' have mating through holes 14, 14 '. On the mutually opposite sides of the casing 11, tubular sections 15, 15 'with connecting flanges 16, 16' are welded to the casing parts 12, 12 ', which secure the installation of the ball valve 10 into a pipe guide (not shown).

Inside the housing 11, a spherical closing mechanism 20 with a through bore 21 is disposed between the seals housed in the housing parts 12, 12 'of the housing 11 by means of a through bore 21. By means of the switching shaft 22 the spherical locking mechanism 20 is adjustable about each axis 23 to each intermediate position Fig. 1 and 2, in which the through bore 21 aligns the through holes 14, 14 'in the housing parts 12, 12' with the closed position rotated relative to the open position by 90 °, in which the through holes 14, 14 'are separated from each other. The pivot axis 23 is formed perpendicular to the through bore 21 in the spherical locking mechanism 20.

Fig. 8 and 9 show schematically the intermediate positions of the ball closure mechanism 20 when such a ball valve 10 is made from an open position to a closed position, or vice versa, in which the longitudinal axis of the through bore 21 is clamped relative to the through hole 14, 14 'of the housing part 12, 12'. 11 or 45 °.

The ball closure mechanism 20 is rotatably mounted by means of bearing pins 24, 24 'disposed on opposite sides in the bearing bushes 25, 25' located in the housing 11. The switching shaft 22 extends through the extension 26 of the housing 11 and is rotatably mounted therein. it is also sealed by a gland 27 with respect to the inner space of the housing 11 in which the ball closure mechanism 20 is mounted and is non-rotatably connected to the ball closure mechanism 20. The control of the ball valve 10 between the open position and the closed position of the ball closure mechanism 20 on the contrary, it occurs by means of a displacement motor (not shown) which is non-rotatably coupled to the switching shaft 22 or equally by means of a hand wheel (not shown) mounted on the switching shaft 22 at the end opposite to the ball closure mechanism 20.

In the first part 12 of the casing 11 on the inlet side, a seal 30 is disposed in the first annular chamber 29 extending radially with respect to the first through hole 14 by this first part 12. This seal 30 is a known metal seal adjacent to the sealing surface 31 On the side facing away from the spherical closure mechanism 20, the seal 30 is supported on a disc spring 32 ensuring it is pressed against the spherical closure mechanism 20.

Also in the second part 12 'of the downstream side casing 11, a further seal 35, formed in one piece with the throttle element 41 described below, is disposed in the second through hole 14' of the radially expanded second annular chamber 34. This further seal 35 abuts the sealing surface 36 a further spherical-shaped seal 35 to the spherical closing mechanism 20 and is also pressed against the spherical closing mechanism 20 by means of a further disc spring 37 which is supported on the shoulder axially delimited by the second annular chamber 34.

The regulating ball valve 10 is provided with a throttle element 40, 41 on the inlet and outlet sides. These throttle elements 40, 41 are designed as inserts in the form of an aperture and have teeth 44, 45 extending parallel to each other from the edge of the annular body. 42, 43. These teeth 44, 45 extend above half of the flow cross section and terminate on an imaginary circle 46, 47 whose center 48, 49 lies on the side of the aperture area 51, 52 without teeth 44,45.

The first inlet-side throttle element 40 is mounted in a radial extension in the region of the borehole 21 of the borehole 21 in the spherical closure mechanism 20 and has an outer shape adapted to the spherical shape. The teeth 44 on the outlet side protrude perpendicularly to the axis of rotation 23 of the ball closure mechanism 20 into its through bore 21, in the direction of rotation of the ball closure mechanism 20 as it rotates in the direction of the closure position.

The second outlet side throttle element 41, which is formed in one piece with the other seal 35, is received in the second through hole 14 'of the second side 12' of the jacket side part 11 'immediately on the ball closure com mechanism 20. From the peripheral annular body, FIG. 7, projecting teeth 45 on the exit side located in the second through hole 14 ' located to create exit gaps 43 on the exit side equally parallel to each other while facing the direction of rotation of the ball closure mechanism 20 when manipulated into the closed position. The outlet-side teeth 45 terminate on a second circle 47 whose center 49 lies on the side of the orifice area 52 at the outlet without the outlet-side teeth 45. On the side facing the ball closure mechanism 20, the second throttle element 41 has a contour adapted to the shape of the ball closure mechanism 20.

Fig. 1 to 3 show the controllable ball valve 10 with the ball shut-off mechanism 20 in the fully open position. In this working position, there is only insignificant influence on the free flow cross section. This is shown in particular in FIG. 3. When the ball closure mechanism 20 is rotated about the pivot axis 23 in the direction of the arrow 53 to the closed position, it decreases with the closing of the area between the teeth 44 on the inlet side of the first throttle element 40 and the seal 30 on the inlet side. an outlet side protruding into the second through hole 14 'of the second housing part 12' of the outlet side 11 and by delimiting the through bore 21 passing through the ball closure mechanism 20.

In FIG. 8 shows the operating position of the spherical closure mechanism 20 in which the orifice area 51 at the inlet without teeth 44 on the inlet side of the first throttle element 40 is in a position rotated from the first through hole 14 of the first inlet housing 12; 45 on the outlet side of the second throttle element 41 on the outlet side is outside the through bore 21 of the spherical closing mechanism 20.

Fig. 9 shows a view of the inlet side of the controllable ball valve 10 of an intermediate position of the ball closure mechanism 20, in which the central teeth 44 on the inlet side of the first throttle element 40 still leave a free lenticular region of the passage cross-section.

Naturally, in such an operating position of the spherical closure mechanism 20, the medium flows with considerable throttling through the through gap 42, 43 formed between the protruding teeth 44, 45, and there is more or less throttling depending on the spherical closure mechanism adjustment without attracting attention. The inlet-side teeth 44 projecting into the through bore 21 in the ball shut-off mechanism 20 of the second throttle element 41 form flow dividers for only a brief division into a plurality of flow directions which only reduce static pressure in the immediate throttling region. in ball valve 10.

PATENT CLAIMS

Claims (8)

A controllable ball valve with a housing (11) comprising at least two housing parts (12, 12 ') having a through hole (14, 14') with a spherical closing mechanism (20) located inside the housing (11) between an annular seal (30) in which the through bore (21) is formed and movably mounted about a pivot axis (23) positioned perpendicular to the through bore (21) from a fully open position in which the through holes (14) are aligned , 14 ') in the housing portions (12 12') and the through bore (21) of the spherical closing mechanism (20), to the closed position separating the through holes (14, 14 ') in the housing portions (12, 12') (11) as well as any throttling position between the open and closed positions, and with the first and second throttling elements (40, 41) for reducing the pressure and reducing the noise of the ball lock mechanism (20) set to the throttling position, characterized in that the throttle elements (40, 41) are formed as inserts in the form of an orifice, the first throttle element (40) being disposed on the side of the spherical closing mechanism (20) in the region of the borehole (21) and the second throttle element (41) on the other side of the spherical closing mechanism (20) adjacent to it, in the second through hole 14 ') of the second housing part (12') (11), the throttle elements (40, 41) having teeth (44, 45) projecting into direction of flow from the edge of the orifice in the form of an orifice to form through spaces (42, 43) formed spaced parallel to each other in the direction of rotation of the spherical closure mechanism (20) and reaching over half of their cross-section ) to the open position of the flow divider at 60 °. Adjustable ball valve according to claim 1, characterized in that the first throttle element (40) located in the through bore (21) in the ball closure mechanism (20) is located at the inlet side, and the second throttle element (41) is located in the a second through hole (14) of the second housing part (12) is located at the outlet side of the spherical closing mechanism (20). Adjustable ball valve according to claim 1 or 2, characterized in that the teeth (44) on the inlet side of the first throttle element (40) projecting into the through bore (21) of the ball closure mechanism (20) project from its edge in the direction the closure of the ball closure mechanism (20) and the teeth (45) on the outlet side of the second throttle element (41) extending into the second through-hole (14 ') of the second housing part (12') protrude against the closure direction of the ball closure mechanism 20). Adjustable ball valve according to one of Claims 1 to 3, characterized in that the teeth (44, 45) projecting as a flow divider in the flow direction are terminated on a circle (46, 47) whose center (48, 49) lies on the side facing away from the teeth (44,45). Adjustable ball valve according to claim 4, characterized in that the radii of the circles (46, 47) on which the teeth (44, 45) of the throttle elements (40, 41) are terminated are at most equal to the flow diameter. way. Adjustable ball valve according to one of Claims 1 to 5, characterized in that the through-holes (42, 43) formed by the teeth (44, 45) protruding as the flow divider of the throttle elements (40, 41) into the flow path have the same width . Adjustable ball valve according to one of Claims 1 to 5, characterized in that the inlet gaps (42) at the inlet side between the projecting teeth (44) at the inlet side of the first throttle element (40) have a smaller width than the corresponding through gap (43). at the outlet side of the second throttle element (41). Adjustable ball valve according to one of the preceding claims, characterized in that the second throttle element (41) located in the second through hole (14 ') of the second housing part (12') (11) is formed in one piece with another seal ( 35), mounted movably and compressed by elastic force through the sealing surfaces (36) of another seal (35) on the spherical closing mechanism (20).