DE1475998B1 - Check valve with a hose membrane - Google Patents

Description

The invention relates to a check valve for arrangement in a Pipeline, with an axially fixed, aerodynamically designed, with a tip directed against the fluid flow insert body and with a likewise axially arranged, a tubular wall having membrane made of elastic Material that is in the closed position of the valve due to its material-related Resetting striving with its one surface on a counter surface of the insert body sealing and preventing a backflow of the fluid and from the forward flowing Flud is lifted from the opposite surface.

A check valve of this type is already known. It is on arranged at an enlarged point of the pipeline and has an insert body, which is sleeve-shaped at its end pointing in the direction of flow. The wall of the sleeve has perforations, the inner openings of which are separated from the cuff to be covered. The cuff is generally pot-shaped and is in its closed position with the free end of its annular wall on the inside of the sleeve. While During normal operation, the fluid flows from the tip of the insert body to the openings in the sleeve-shaped part, passes through it, presses the cuff wall and leaves the insert body. In the event of a backflow, the cuff will pressed by the fluid from the inside against the sleeve wall, and the openings are thus closed against the passage of fluid.

In another known check valve, a basket-shaped, perforated insert body clamped between the joints of two pipe sockets, and a frustoconical diaphragm made of rubber is on the downstream side tightly fitting over the insert body. The edge of their larger mouth will come together detected with the edge of the insert body from the pipe socket. During normal In operation, the fluid enters the basket-shaped or funnel-shaped part of the insert body a, penetrates its wall, pushes the membrane while expanding outwards and flows off. In the case of backflow or when a minimum pressure has dropped to the intended level In the direction of flow, the membrane tightens due to its tendency to restore finally around the insert body together.

Also known is a toilet flushing device with a self-closing, Flushing valve secured against sucking back of the flushing water, whereby the sucking back safety consists of a tubular sleeve closed at the end, which has holes that by a sleeve made of rubber or other elastic sleeve surrounding the sleeve Material are covered.

The known check valves have up to a certain flow pressure proven to be fully operational. However, at higher pressures they show the Disadvantage that the cuffs in the case of backflow with sections in the openings the insert body are pushed in. This can go as far as punching out wall parts, which lie in the projection of the openings, lead out of the cuffs, whereby the backflow protection becomes obsolete. Even if the cuffs are so strong that they cannot burst, difficulties arise due to plastic deformation at the points in question and the resulting slowdown in response.

The object of the invention is to provide a check valve create, which has both the proven properties of the known valves as well as at high pressures can be used without showing the disadvantages described.

Based on a check valve of the type described above this object is achieved according to the invention in that the membrane, as per se known, open at both ends and its end opposite to the direction of flow is clamped that also in a known manner, the clamping point in the Pipeline is longitudinally movable between limits that the restraint of the Membrane in a rigid sliding ring that can be moved lengthways inside the pipeline is made and that the sliding ring in the closed position of the valve on a the end face that limits the longitudinal mobility of the clamping point in the pipeline a centering ring rests sealingly. This type of training offers the possibility to use a massive insert body as a sealing counter element for the Membrane, d. H. an insert body without perforations into which sections could press into the membrane. The passage of the fluid through the valve is namely not only caused by deformation of the membrane, but by removal of the whole membrane from its opposite surface, so that basically no deformation work needs to be expended. To achieve a sufficient flow cross-section However, the training can be made so that the membrane is in the connection to their displacement or to the initiation of their displacement. This has the advantage that the valve during normal operation the has known favorable flow conditions, with high throughput has a low dynamic pressure and for the locking device with little effort gets by. In addition, when a backflow occurs, there is a complete rigid closure that can withstand comparatively higher pressures Es a design is also known in which the valve body is axially displaceable, however, the valve body is the normal, tubular rubber diaphragm, which here has only been reinforced in a bead shape at certain points. Closure element is only the rubber of the membrane, which is supposed to cover an annular space.

It cannot be left to the discretion of the specialist whether that Closure piece can be clamped in a special, longitudinally displaceable ring target. If one waives such a restraint, then under the action the backflow pressure inevitably pushes the membrane into the annular space to be sealed, deformed and tired in the long run. Especially when high pressures are used, a such, consisting only of rubber, albeit longitudinally movable closure body highly unstable and unreliable. It depends on the rubber membrane from the intake to relieve the backflow pressure in that the closure, as in the case of the invention Check valve is the case, when backflow is not through rubber, but through solid Parts is effected.

Although a check valve is known, its axial displaceable valve body in the closed position a rigid shut-off of the line ensures while at the same time the membrane from absorbing the backflow pressure is relieved.

The main difference between the subject of the application and This check valve, however, consists in the fact that here on the possibility of laminar Flow as well as the creation of the lowest possible flow resistance no attention was wasted. When the check valve of the known Type of construction necessarily occur considerable turbulence, which is at most flowing at the transition from the annular space around the membrane into the window of the outlet cylinder to make noticable. The construction here is so flow-resistant that it is necessary considerable pressure resistance must occur. These disadvantageous flow conditions in the known design can also not be easily modified by making changes remedy. The use appears as a result of the disadvantageous flow conditions the known design for separable liquids, for example fluids, which contain suspended matter as completely excluded.

According to a further feature of the invention, this is characterized in that the sliding ring can be acted upon by the medium in both directions of flow Has end faces.

Another feature of the invention is that the inner diameter of the slip ring the outer diameter of the insert body on the back of known per se, the insert body supporting webs corresponds and that the back of webs and centering ring is adapted in terms of shape to the front of the sliding ring. With this training method there is a check valve, which in his The closed position can also be subjected to the highest pressures, as the seal caused exclusively by rigid parts.

The insert body advantageously settles in the direction of flow continues with a cylindrical extension, the diameter of which is equal to the diameter of the opening of the membrane located in the direction of flow is in its closed position. This creates an additional guide for the membrane on its displacement path educated.

As for the displaceability of the membrane in detail, so is proposed according to the invention that in the wall of the pipeline in the Area where the movable membrane is located, a known slideway is worked out for the sliding ring, the opposite to the direction of flow Stop for the sliding ring is formed by the centering ring of the insert body. This ensures that the membrane can be displaced in a reliable manner.

In the drawing, the invention is illustrated using an exemplary embodiment. F i.g 1 shows an axial longitudinal section through the check valve in the closed position, F i g. 2 in the working position, F i g. 3 in the working position with under the influence of the flowing flux of the widened cuff.

The valve is essentially made up of two pipe sockets 1 and 2, a bomb-shaped insert body 3, also called a torpedo, and a sleeve 4 made of elastic material, e.g. B. rubber, composed. The pipe sockets 1 and 2 are provided at their ends with external threads 5 for screwing into a pipeline and have flanges 6 and 7, respectively, at the point where they are connected, which are held together by a union nut 8 by means of corresponding threads. The pipe socket 2 is provided near its flange 7 with a section 9 of enlarged diameter. The intended direction of flow through the pipe is indicated by arrow 10 .

In the interior of the line formed by the pipe socket 1 and 2, the torpedo 3 is arranged so that its tip is directed in the opposite direction to the normal flow. The torpedo is made of solid material and has a smooth surface. Following its tip, it has a cylindrical section 11, which is in turn adjoined by a frustoconical part 12 which ends in a cylindrical extension 13. On the circumference of the cylindrical section 11 , four wing-like webs 14 are arranged, which are surrounded on the outside by a centering ring 15 with which the torpedo is clamped in the pipeline. For this purpose, there are corresponding annular recesses on the inside of the flanges 6 and 7, into which the centering ring fits exactly when the pipe socket is screwed together.

The cuff 4 is open at both ends and has a shape which exactly corresponds to the outer shape of the frustoconical part 12 of the torpedo 3. The edge 16 of the cuff pointing in the direction of flow is sharpened and rests on the surface of the extension 13, while the opposite edge is provided with an annular projection 17 which sits in a corresponding recess of a sliding ring 18 , whereby this and the cuff are connected . The cuff 4 can have a bias, that is, its opening at the edge 16 can be slightly smaller than the diameter of the extension 13. The sliding ring 18 moves on a path 19 which is formed in the interior of the enlarged part 9 of the pipe socket 2, namely within the limits of two stops, one of which is formed by the centering ring 5 and the other by the inner transition to the extension 9 in the pipe socket 2. The outer shape of the sliding ring 18 corresponds to the respective shape of the parts on which the ring rests in its end positions. The inner ring diameter is the same as the outer diameter of the central torpedo part 11.

During operation, the fluid pressure acts according to arrow 10, if the valve is closed (Fig. 1), on the opposite annular surface of the sliding ring 18 between the centering ring 15 and torpedo center part 11. Under the influence of the fluid pressure, the sliding ring 18 is along the Web 19 moved to the opposite stop in the connection piece 2. The sleeve 4 moves away from the frustoconical part 12, its edge 16 sliding on the extension 13 in a guiding manner. After the cuff 4 has reached the end of its displacement path (FIG. 2), the fluid makes it fully open according to FIG. 3 expanded.

If for any reason a back suction or a back flow occurs, that is, if the direction of the flow pressure is reversed, the cuff 4 initially closes again around the shoulder 13 (FIG. 2) due to its material-related tendency to return, and the back pressure acts both on the outer surface of the sleeve and on the annular rear side of the sliding ring 18. This has the consequence that the ring and the sleeve are shifted towards the centering ring 1 $ until the position shown in FIG. 1 is reached. In this position, the valve forms a rigid seal against the back pressure, which prevents the fluid from flowing back into the nozzle 1, largely independently of the sleeve 4, through the sliding ring 18 . The cuff only has a sealing function.

The insert body 3 with its parts 14 and 15 and the sliding ring 18 are preferably made of plastic. Liquid, gaseous and dusty media as well as mixtures of the same come into question as the fluid.

The in the above description, in the drawing and in the Features of the subject matter of the invention disclosed in the following claims individually as well as in any combination with each other for the realization be essential to the invention in its various embodiments.

Claims (5)

Claims: 1. Non-return valve for arrangement in a pipeline, with an axially fastened in the line, aerodynamically designed, with a tip directed against the fluid flow and with a likewise axially arranged, a tubular wall having membrane made of elastic material, which in the closed position of the valve due to its material-related tendency to return with its one surface on a mating surface of the insert body sealingly and preventing a backflow of the fluid and is lifted from the opposing surface by the forward flowing fluid, as characterized by the fact that the membrane (4), as known per se , is open at both ends and clamped at its end opposite to the direction of flow, that furthermore, in a manner known per se, the clamping point in the pipeline (1, 2) is longitudinally movable between limits, that the clamping of the membrane (4) continues to be rigid , inside the pipeline (1, 2) length gsverschieblichen sliding ring (18) is made and that the sliding ring (18) in the closed position of the valve on one of the longitudinal mobility of the clamping point in the pipeline (1, 2) limiting the end face of a centering ring (15) is sealing. 2. Check valve according to claim 1, characterized in that the sliding ring (18) has end faces which can be acted upon by the medium in both directions of flow. 3. Check valve according to claim 1 and 2, characterized in that the inner diameter of the sliding ring (18) corresponds to the outer diameter of the insert body (3) on the back of known, the insert body supporting webs (14) and that the back of The shape of the webs and centering ring (15) is adapted to the front of the sliding ring. 4. Check valve according to claim 1 to 3, characterized in that the insert body (3) continues in the flow direction (10) with a cylindrical extension (13), the diameter of which is equal to the diameter of the opening in the flow direction of the membrane (4) in its closed position. 5. Check valve according to claim 1 to 4, characterized in that in the wall of the pipeline (1, 2) in the area where the displaceable membrane (4) is located, a known slide (19) for the sliding ring (18 ) is worked out, with the stop for the sliding ring located against the direction of flow being formed by the centering ring (15) of the insert body (3).