DE3730419A1 - Rotary valve - Google Patents

Abstract

The proposal is for a rotary valve which is arranged in a housing, having a cylindrical or spherical rotary plug with a through hole for connecting the desired connecting lines. In order to achieve reliable sealing of the connecting lines (2 to 4) with respect to one another and with respect to the housing, an annular gap is provided in the region of the inlet openings of the feed lines (2 to 4) and this gap serves to accommodate a ring seal (25 to 27) which surrounds the connecting line, the ring seal surrounding an annular shoulder formed by the connecting lines. Provided between the ring seals (25 to 27) and the rotary plug is a plastic plate matched to the circumferential surface of the rotary plug (6), and, to effect sealing, this plastic plate is pressed against the rotary plug by the ring seal. <IMAGE>

Description

The invention relates to a rotary valve according to the Preamble of claim 1 and in particular one Sealing arrangement for a rotary valve or the like.

Taps or rotary valves are known as shut-off devices become. The final part is the cock chick or Rotary chick, which is conical, cylindrical or spherical can be trained. Depending on the type it has Rooster chicks or rotary chicks passages in I-, L-, T- or X- Shape by turning the chick into the desired one Operating position. With the three-way valve or Three-way rotary valves are generally three rectangular Connections to each other are provided, the chick with L or T-shaped passages when turning two each Connects connections with each other. The route will be only released when the previously opened one is already closed.

The problem of sealing such rotary vane after outside and the connecting lines play with each other a significant role. So with the so-called Patent cock between the cylindrical chick and the Housing inserted an elastic sealing sleeve that the Enables re-sealing as with a cloth can. (see Lueger, Lexikon der Technik, Volume 1, pp. 199, 192).

In bulk material technology with pneumatic conveying Bulk goods often have the problem of flowing Medium, preferably a gas-solid mixture of one incoming pipeline optionally with at least two to connect draining pipes. Conversely, it can be required at least two, the flowing medium leading, incoming pipelines optionally with a to connect further pipeline.  

The transport of dusty, powdery or coarse-grained Solids with the help of a flowing gas through a pneumatic delivery line becomes problematic when within the branching device or the rotary valve no gas or solid transfer from the through flowing pipeline into the non-flowing Pipeline may take place. In contrast to that of pure liquids or gases or merging facilities are subject to the moving parts and especially such Branch devices or rotary valve when used in pneumatic or hydraulic delivery lines with Solid content a considerable wear.

Various devices are available to solve this problem known. First, the branch lines always V-shaped at the most acute angle possible Supply line arranged to keep flow losses small hold. The V-shaped lines can be used to shut off one shut-off valve, flaps, ball valves, pinch valves or the like. Although these taps can be complete run tightly, but a dead forms Space in the branch line in front of the shut-off valve. Farther such taps have a high pressure drop.

Another option is the so-called tongue or flap switches with a lower V- shaped area of the branch arranged pivot point and swivel here and one direction of flow freely give. The disadvantage of this arrangement is that a complete seal especially for high pressures not possible.  

So-called bobbin turnouts are also known a rotatable in the V-shaped crossing point and swiveling clapper, which in the respective too closing pipeline is swung in. Disadvantageous the dead space is also in front of it Bobbin turnout, the high pressure drop and the linkage in the Funding area.

Also known for the branch are so-called Drum switches, built like a rotary valve are. The connection of the V-shaped branches from one The supply line is done using a rotary plug oblique through hole, each one of the branching lines by rotation, for example 180 ° connects. Such arrangements are large and heavy and therefore complex to manufacture.

Another known possibility for producing a V-shaped branch of a feed line is shown in FIG. 1. This is a kind of three-way rotary valve as explained at the beginning. The rotary plug is provided with an eccentric through hole that connects the respective lines to be acted on. In order to isolate the individual lines from each other in a pressure-tight manner, O-rings are inserted in the inner circumferential surface of the housing around the feed openings of the connecting lines as a sealing means, which seals the respective connecting line against the rotary plug and thus against the next connecting line. The O-rings are embedded in ring grooves in the housing wall and are supported between the housing and the rotary plug.

This sealing arrangement has the disadvantage that the Seals with every rotation of the rotary plug from the  Opening edge of the through hole of the rotary plug be painted over so that it pops out and excessive stress on the annular seal can come. There are possibilities from the literature known to have contact seals on sliding surfaces an additional ring on the sliding surface provided with a direct contact with the O-ring avoids the sliding surface. this happens especially when sealing pistons and rods in Working cylinders. The additional rings are in the recessed and supported ring grooves intended for the O-ring always between the O-ring and the moving part.

Such additional, low-wear rings can also not solve the problem of a heavily stressed circumferential seal in a known device according to FIG. 1, since the opening area of the plug passage bore that sweeps over the seal and the inner pull of the seal along a circular chord easily pop out or loosen Seal especially in the case of the flowing media with solid contents cannot be excluded.

The invention has for its object a Rotary vane especially for use with pneumatic or hydraulic conveying lines with bulk material create the seal of the rotary plug compared to the housing and thus the connecting lines done satisfactorily with each other. The task is still a seal for similar cases to propose.

This task is based on a rotary valve introductory significant type according to the invention by the characterizing features of claim 1 solved, and generally solved by claim 4.  

In the further subclaims are advantageous Developments and improvements to the main claim and subclaim 4 specified rotary valve or Sealing arrangement possible.

The invention is based on the knowledge that it is always important in a seal designed as an O-ring to use this sealing element as possible as a stationary seal, ie as a contact seal on resting surfaces. In the known type of seal shown in FIG. 1, the O-ring must therefore be placed in an area which is not covered by moving or sliding surfaces. However, it is not sufficient to provide the O-ring with an overlying protective ring, as is known in the prior art.

To achieve this, an annular gap is inventively created between rotary valve housing and rotary plug, which is used to hold the connecting cables enclosing ring seals or O-rings. Here an additional plastic plate, especially one slidable Teflon plate between the rotating Rotary plug and the seal arranged, the Teflon plate as circular ring pieces at least in the area of Ring seals are arranged.

Characterized in that the connecting line ends formed in the The ring seal can protrude into the housing completely enclose these connection ends, so that by means of the cover by the Teflon plate slipping off Seal when crossing the through hole of the Rotary plug is excluded.

Due to the tight fit of the seal around the connection end the connecting line pulls the O-ring in a radial direction Direction together and widens in its axial Direction up and thus results in a pressure on the  Teflon plate behind, which thereby against the Rotary plug is pressed.

This effect can still be in an embodiment of the invention by applying additional pressure to the annular gap Compressed air improved especially in the area of the O-rings will. The O-ring is pressurized compressed radially further, d. H. into the through housing, Ring shoulder and chick formed groove pressed. Through the flexible Teflon plate movable against the chick can then axially widen the O-ring and thereby the Press the Teflon plate against the rotary plug. Here A slight system overpressure is sufficient for complete Sealing of the connecting lines with each other.

The Teflon plate can partially or twist the rotary plug completely enclose. The arrangement is decisive this plastic plate immediately in front of the annular Gasket to form an intermediate layer between Seal and moving rotary plug. The Teflon plate in general as an washer around the in the Annular gap protruding connecting ends of the Connection lines laid.

In training the invention according to subclaim 4, the inventive idea also on other machine components be applied.

An advantageous and convenient embodiment of the Invention is shown in the drawing and in the following description explained in more detail. Show it

Fig. 1 is a three-way rotary valve according to a conventional design,

Fig. 2 shows a three-way rotary valve according to the invention in plan view and

Fig. 3 is a section along section line II in Fig. 2.

In the known rotary valve ( 1 ) shown in Fig. 1, the transport of a gas-solid mixture from an incoming pipeline ( 2 ) optionally in two exhaust pipes ( 3 and 4 ) which for flow reasons V-shaped with an angle of z. B. α = 30 ° and a common axis intersection ( 5 ) are arranged. In order to determine the direction of flow, a rotary plug ( 6 ) is provided which has a through hole ( 7 ). In Fig. 1, the connecting lines ( 2 and 3 ) are connected to each other via the through hole ( 7 ) in the rotary plug ( 6 ). If you want to connect the connecting line ( 2 ) to the connecting line ( 4 ), then the rotary plug must be rotated by the angle β = 180 ° C α so that the matching connection openings of the connecting lines and the rotary plug are adjacent.

In order to seal the connecting lines ( 2 to 4 ) against each other in such a way that no flowing medium can get into a line not intended for this purpose, ring grooves ( 9 ) are milled into the rotary valve housing ( 8 ) around the inlet openings of the connecting lines ( 2 to 4 ) the ring-shaped seals, in particular O-rings ( 10 to 12 ) are embedded. The O-ring ( 10 ) seals the connecting line ( 2 ), the O-ring ( 11 ) the connecting line ( 3 ) and the O-ring ( 12 ) the connecting line ( 4 ) between the housing ( 8 ) and the rotary plug ( 6 ) from. The medium to be pumped can therefore not pass through the gap ( 13 ) between the housing ( 8 ) and the rotary plug ( 6 ) to a supply line which is not provided.

When carrying out the rotary movement of the rotary plug ( 6 ) by the angle β for connecting the connecting line ( 2 ) to the connecting line ( 4 ) ( FIG. 1), the edges ( 14 ) of the outlet openings ( 15 , 16 ) pass over the through bore ( 7 ). of the rotary plug ( 6 ), the sealing rings ( 10 to 12 ), wherein there is no radial pressure on the seals in the area of the openings ( 15 , 16 ), so that these can be released from the grooves ( 9 ) under certain circumstances. This is particularly because the tension of the prestressed O-rings lies in a sectional plane which is represented by the chord ( 17 ). Without the radial pressure of the plug ( 6 ) in the area of the openings ( 15 , 16 ), the seals can slide out of the grooves ( 9 ), especially in the case of worn and older seals.

This process is reinforced by the behavior of the dusty, powdery or coarse-grained solids in the Transport lines.

The device according to the invention is shown in FIG. 2. If the same parts are provided with the same functionality as in Fig. 1, they are provided with the same reference numerals.

In order to solve the sealing problem of the device according to FIG. 1, in the device according to the invention according to FIG. 2 the inside diameter ( D ₁ ) of the rotary valve housing ( 18 ) for forming an annular gap ( 19 ) is larger than the diameter ( D ₂ ) of the Cylindrical swivel plug ( 6 ). The diameters are, for example, D ₁ ∼ 250 mm, D ₂ ∼ 230 mm. The branch angle of the V-shaped arrangement of the branch lines ( 3 , 4 ) is α = 30 ° in the exemplary embodiment. The eccentric arrangement of the aligned pipe axes ( 20 , 21 ) including the aligned central axis ( 22 ) of the through hole ( 7 ) from the parallel central axis ( 23 ) of the rotary plug ( 6 ) is e ∼ 27 mm.

The inner diameter of the connecting pipes ( 2 to 4 ) is designated by d . In the exemplary embodiment, it is d ∼ 80 mm.

The ends of the connecting lines ( 2 , 3 , 4 ) protrude into the annular gap ( 19 ) and thus form an annular shoulder ( 24 ) which is non-positively enclosed by the respective ring seal or the O-ring ( 25 to 27 ). A separate puncture groove in the housing ( 18 ) is therefore not provided. The ring seal ( 25 ) accordingly surrounds the ring shoulder ( 24 ) of the connecting end of the connecting line ( 2 ) projecting into the annular gap ( 19 ). The same applies to the annular seal ( 26 ) for the connecting line ( 3 ) and the ring seal ( 27 ) for the connecting line ( 4 ).

Between the annular seals (25 to 27) and the rotary plug (6) respectively flexibly disposed in the radial direction of the plastic plates (28), in particular Teflon plates (28) are arranged mm with a thickness of approx. 2 These stationary Teflon plates ( 28 ) partially enclose the rotary plug as partial lateral surfaces and have corresponding cutouts for the flow openings ( 15 , 16 ) of the connecting lines ( 2 to 4 ). The Teflon plates lie on the outer surface of the rotary plug ( 6 ) and are pressed against this outer surface by the seals ( 25 , 26 , 27 ) due to their axial expansion. This is symbolically represented by the force arrow ( 29 ) in FIG. 2. Since the ring-shaped seals (O-rings 25 to 27 ) widen axially due to the positive locking of the ring shoulders ( 24 ) of the connecting ends of the lines ( 2 to 4 ), there is a radial force with respect to the rotary plug ( 6 ) (arrow 29 , 30 ) on the Teflon plate ( 28 ), which leads to the sealing of the connecting lines ( 2 to 4 ) against the housing ( 18 ).

This seal can be reinforced by introducing compressed air (arrow 32 ) into the ring channel ( 19 ) via a feed line ( 31 ), which presses the ring seals ( 25 , 26 , 27 ) even more against the ring shoulder ( 24 ) of the connecting ends of the pipelines ( 2 to 4 ) presses (force arrow 33 ), which leads to a further axial expansion (arrow 29 , 30 ) of the seals ( 25 to 27 ) and thus to an increase in the sealing effect.

The Teflon plate ( 28 ) can be designed as a partial outer surface or as a peripheral outer surface. The latter is indicated by the dashed line ( 34 ) in Fig. 2.

The excess pressure which occurs in the annular gap ( 19 ) due to the compressed air supply need only be slightly above the system pressure. In addition to the additional axial widening of the seals ( 25 to 27 ), this has the additional advantage that a flow from the ring channel ( 19 ) into the connecting lines ( 2 to 4 ) and not vice versa can occur.

In Fig. 2, the connection of the connecting line ( 2 ) with the connecting line ( 4 ) is also shown in broken lines with reference numerals ( 7 '). To do this, the rotary plug must be rotated by more than β = 180 ° - α , ie by β = 150 °, to ensure that the connection openings match.

In the section shown in FIG. 3 along the section line II in FIG. 2, the same parts are shown with the same reference numerals. From Fig. 3 the enclosure of the respective annular shoulder ( 24 ), which is formed by the end of the respective connecting tube ( 2 , 3 ) projecting into the housing ( 18 ), can be seen through the respective O-ring ( 25 , 26 ). The non-positive encirclement of the ring shoulder ( 24 ) and the pneumatic pressure in the ring line ( 19 ) causes the O-ring to expand (force arrow 29 , 30 ) and thus exerts pressure against the Teflon plate ( 28 ). This reliably seals the inlet openings of the connecting lines ( 2 , 3 ) with respect to the housing ( 18 ) or the rotary plug ( 6 ).

In Fig. 3, the upper end plate ( 34 ) and the lower end plate ( 35 ) of the rotary valve housing ( 8 ) is also shown. The rotation of the rotary plug ( 6 ) is accomplished by means of the through shaft ( 36 ).

The invention is not based on that described and illustrated embodiment limited. It includes also rather all professional training and Improvements to the principle of the invention. In particular, the sealing arrangement can also be used for a rectilinear device are used at which is the problem of crossing over Through openings via ring seals occurs. This for example in a tubular body Connection holes axially movable control plunger with connection holes, such as in Valve controls are used. Equally can also different sealing rings from O-rings, like on known to be used.

Claims (6)

1. Rotary slide valve, with a cylindrical or spherical cock plug arranged in a housing with an I, L, T or X-shaped passage for connecting the desired connecting lines, an elastic seal being provided between the plug and the housing, characterized in that that the inner diameter (D ₁₎ is formed larger of the housing at least in the region of the inlet of the connecting lines (2, 3, 4) for forming an annular gap (19) than the diameter (D ₂₎ of the plug (6), wherein the lead ends protrude into the annular gap ( 19 ) to form an annular shoulder ( 24 ) that an annular seal (O-ring 25 , 26, 27) is arranged non-positively around the annular shoulder ( 24 ) of the line ends of the connecting lines ( 2 to 4 ) and that the ring seal ( 25 to 27 ) is supported by a flexible plate, in particular a plastic plate ( 28 ) against the plug ( 6 ) and the housing ( 18 ), sealing these parts. 2. Rotary valve according to claim 1, characterized in that for pressing the ring seal ( 25 , 26 , 27 ) of the annular gap ( 19 ) between the plug ( 6 ) and housing ( 18 ) with a pressure medium, in particular compressed air via a line ( 19 ) can be acted upon is. 3. rotary valve for the transport and distribution of dust, powder or coarse-grained solids in a pneumatic or hydraulic delivery line according to claim 1 or 2, characterized in that a rectilinear main line ( 2 , 3 ) and one at an angle of α ∼ 30 ° branching branch line ( 4 ) is provided. 4. Rotary valve according to claim 1 or 2, characterized in that the flexible plastic plate ( 28 ) consists of approx. 2 mm thick Teflon and the rotary plug ( 6 ) partially or completely (34) encloses a jacket. 5. contact seal on moving machine parts, in particular for use on a rotary valve according to one or more of claims 1 to 3, with a, a sealing first connecting line having a stationary housing and a moving on or in the housing machine part, which one, with the first Connecting line has aligned but displaceable through line, the first connecting line being provided with an annular seal (O-ring) in the stationary housing for sealing against the movable machine part, characterized in that at least in the area of the connecting line ( 2 , 3 , 4 ) between the A housing ( 18 ) and the movable machine part ( 6 ) are provided with a gap ( 19 ), the connecting line ( 2 , 3 , 4 ) protruding into the gap ( 19 ) to form an annular shoulder ( 24 ) and a ring seal ( 25 , 26 , 27 ) is non-positively enclosed and that between the ring seal ( 25 to 27 ) and the movable machine enteil (6) is represented by the ring seal (25 to 27) against the machine part (6) can be pressed plastic plate or disc provided (28). 6. Touch seal according to claim 4, characterized characterized in that the annular gap additionally with Compressed air can be applied.