DE1940855B2 - Support for pipe passing through hole in wall - absorbs shock loads and seals gap between pipe and hole using two rows of circular segments - Google Patents

Abstract

The support (300) consists of two rows of circular segments (301) made of an elastomeric material in the form of links of a chain. These links are fastened together with bolts (312) in such a way that the links of one row overlap the links of the other row. The end load of the bolt (312) is spread over the end surface of the links by the plates (310). The segments are wrapped round the pipes and the ends connected by a bolt (312). All the bolts are then tightened so that the elastomeric segments are compressed axially, causing them to expand radially and grip the outer surface of the pipe of the inner surface of the hole in the wall.

Description

The invention relates to a sealing, shock-absorbing wall duct for pipes or the like. according to the generic term of claim 1.

There are numerous applications in which a liquid-tight seal for an electrical Line, pipe or other line is necessary, which runs through a wall. Typical examples this includes underground electrical shafts, pits, tunnels, bridges and the like Wall through which the pipe runs against ingress or egress of water or other liquids, it is often necessary to provide shock absorption. For example, in a cable duct, the electrical cables must be dampened against shocks, especially if the Manhole or canal runs alongside a road. In addition, the seal can be made of electrical or thermal reasons.

There are already a large number of seal designs for sealing pipes and others Lines that run through walls in cellars, shafts and other underground rooms. For example conical stoppers made of a relatively flexible material have been used. One also knows Sealing ring combinations made of sealing fibers and lead, which are similar to those seals which are described in Installation systems for overflow pipes are used. However, these usual seals are very susceptible to damage. In addition, they are not cheap and take a significant amount of time to install as well as a lot of skill in assembly.

Use a different type of seal (OE-PS 2 33 227).

del a cylindrical sealing body made of rubber or another elastomeric material on which opposite revenges pressure rings are attached. The two pressure rings are through a series of Screws connected to one another, which engage in threads of the other ring from one ring and to press the rings together when screwing tight. Because of this axial compression of the cylindrical Rubber body expands this in the circumferential direction and seals the space between a line that runs axially through the rubber body, and the surrounding hole wall.

This latter construction is already a significant improvement over some of the more well-known Embodiments are, but it also has some disadvantages. For example, the seal must be in the Wall can be inserted before the tube or line is pushed through, or it must be on the tube be brought into the correct position and possibly a fairly large piece on the tube κ » be postponed. A far greater disadvantage, however, is that this known seal only suitable for a certain pipe diameter of a pipe that passes through a wall opening certain size is to be passed through, and there are no significant changes in the outer diameter the pipe can be adjusted to the inside diameter of the wall opening.

The sealing wall duct known from US Pat. No. 19 14 343 corresponds to that described above Wall bushing with the only difference that in this case the sealing ring in two pieces is divided so that it can be attached to the side of a line or cable and not over the Pipe or cable must be pushed in the axial direction. But even with this arrangement, the Seal only for a certain pipe or cable diameter and only for a certain one Wall bushing diameter are used, so that here too the disadvantages already mentioned above appear.

From US-PS 27 68 036 and FR-PS 6 41 088 sealing wall bushings are known in which the sealing ring is composed of individual sealing segments. However, these sealing rings are not securely, firmly and thus tightly connected to one another, so that liquid penetrate between them can. There is also no radial seal or a sealing pressure in the radial direction, around a Ensure sealing between the segments and the pipe penetration or the pipe. These Seals can be adapted to pipes, cables and pistons of various diameters, but not but different radial dimensions between the tube, the cable or the piston and the Wall duct or the cylinder. This represents a further disadvantage of these known arrangements.

The invention is therefore based on the object of providing a sealing wall duct for pipes or the like the way to train that the seal with easy handling not only for a narrowly limited Diameter range \ on wall penetration and pipe can be formed, but that such a sealing wall duct also for very different duct diameter ranges, d. H. especially used for very different circumferential lengths of the area to be sealed can be.

This object is achieved according to the invention by what is stated in the characterizing part of claim 1 Measures resolved.

Advantageous configurations of the wall duct according to the invention are set out in the subclaims specified.

The sealing and shock-absorbing wall duct according to the invention can therefore be over a large Diameter range for different pipe or cable diameters and different wall opening diameters adjust, achieving a secure seal and shock-absorbing effect.

The sealing elements according to the invention can be used to form a large number of different line seals simply put together by adding more or less sealing elements to an annular one Seal united. This creates a great deal of flexibility with regard to differences between the Outer diameter of the tube and the inner diameter of the wall openings in which the seal should be provided. With the same pressure plates and bolts can also be sealing or Use insulating blocks of different thicknesses, so that very different radial distances between the pipe and wall opening can be bridged.

Since the seal according to the invention is composed of individual elements, the pressure plates, the sealing blocks and the bolts are completely standardized, and the tooling costs can be minimal keep. Furthermore, the cost of assembly is very low, especially because of the assembly of a Sealing element for a 2> / 2-inch pipe requires exactly the same steps, albeit more often must be carried out like the assembly of a complete gasket for a 1 'Azollig pipe. Because the element structure of the seal according to the invention is both in the manufacture and in Assembly achieved an exceptional economy.

At the place of use of the seal it is very easy to simply pulling out a bolt and thereby opening the annular seal so that it is attached to a Place immediately next to the wall opening around the pipe. It is not necessary to do this Insert the seal into the wall in the desired position before inserting the pipe, and the On the other hand, the seal does not have to be pushed over the pipe in large pieces. Another The advantage is that in the event of an error regarding the determination of the pipe diameter in the highest an element can be easily added to or removed from the seal when the Seal is used in place so that there is no loss of time due to such errors.

In the following, embodiments are dei Invention described with reference to the drawings. E: shows

1 shows a partially broken away plan view of a seal according to the invention, which at a position is open and lying flat,

F i g. FIG. 2 is a side view of the FIG. 1 shown: seal,

F i g. Figure 3 is a partially sectioned end view of the i: the F i g. 1 and 2 shown seal between a pipe and a wall opening in still nicri tightened state,

F i g. 4 shows a section along the line 4-4 in FIG. 3 bc not tightened bolt,

F i g. 5 shows a section along the line 5-5 in FIG. 3 with the bolt tightened,

6 shows a partial plan view corresponding to FIG. 1, but with the bolt tightened,

Fig. 7 is a plan view of a modified embodiment with slightly different printing plates and Printing blocks,

F i g. 8 is a partial end view of the FIG. 7 illustrated embodiment,

9 and 10 partial views of further variants of the Shapes of sealing blocks,

FIGS. 11 to 14 are perspective views of further embodiments of the invention.

An embodiment of the shock absorbing seal 20 according to the invention is shown in FIGS. 1 to 6 shown. It consists of a plurality of individual sealing elements 21, 22, 23, 24, 25 and 26, which are designed according to the invention and joined together so that they form an annular shock-absorbing seal, as shown in FIG. 3 shows.

A sealing element 21 contains a sealing block 31 of approximately Z-shape (see FIG. 1), which consists of a resilient, compressible elastomer material, such as rubber, neoprene or the like, and has a certain density T (FIG. 2) Has. The plan view of Fig. 1 shows that the opposite ends 32 and 33 are offset from one another, so that the approximately Z-shaped shape of the block is formed. A first bolt opening 34 extends through one end 32 of the sealing block 31, and a second bolt opening 35 protrudes through the opposite end 33 of the sealing block.

At the top of the sealing block 35 is shown in FIG. 1, a first pressure plate 36 is arranged as part of the sealing unit 21. The pressure plate 36 is articulated and contains a first plate element 37 which extends on the side of an end section 32 of the sealing block 31. The pressure plate element 37 is hingedly attached to a second pressure plate element 38 with the aid of a rivet or a connecting pin 39. The pressure plate element 38 extends the pressure plate 36 so that the total length of the pressure plate is approximately equal to the total length L of the sealing block 31. At one end of the pressure plate 36 there is a bolt opening 42 in the element 37, which is aligned with the opening 34 of the sealing block. At the other end of the pressure plate 36 there is another opening 43 in the element 38, which is aligned with the opening 35 of the sealing block

On the opposite side of the sealing element 21 so in FIG. 1 on the lower side, there is a second pressure plate 46, which is similar in structure to the pressure plate 36. The pressure plate 46 consists of two individual pressure plate elements 47 and 48 which are pivotably connected to one another by a pin 49 or a similar part The plate element 47 is aligned with the opening 34 of the sealing block. In the same way, an opening 53 of the plate element 48 is aligned with the sealing block opening 35

The sealing element 21 also contains a bolt 54 which has a short, square or otherwise non-circular shaft part which protrudes into the correspondingly shaped opening 53 of the plate element 48 so that the bolt cannot rotate. The bolt 54 protrudes through the opening 35 of the sealing block and through the opening 43 of the plate element and is held by a nut 56.

The other sealing elements 22 to 26 are of the same construction as the sealing element 21 and are therefore not described in more detail. The manner in which the sealing elements are connected to one another to form the complete seal 20 is evident from FIGS. 1 to 3 stand out without further ado. From Fig. 1 it can be seen that the bolt 54 of the sealing element 21 through

An opening in the sealing block of the adjacent element 22 and through openings in the two pressure plates for the sealing element 22 protrudes and holds the elements 21 and 22 together. The remaining bolts ensure the same cohesion of the other sealing elements. At the point of use, a bolt is withdrawn and the gasket 20 is wrapped around the pipe 61 or other conduit. The bolt is then reinserted through the adjacent overlapping ends of the two end units and the gasket is ready for installation to seal the outer surface of a conduit 61 against the inner surface 62 of a hole in a wall 63 through which the conduit passes .

When the seal 21 is initially placed in position, it can be relatively loose on the line 61 and in the surface 62 of the hole, as shown in FIGS. 3 and 4 is shown. For final sealing the nut 56 is tightened on each bolt 54.

The two pressure plates of each sealing element are moved towards each other, so that the ring of the Sealing blocks compressed between the two rings of the plate elements in the axial direction and thereby expands in the radial direction. The radial expansion can be inwards and outwards take place so that when all bolts in the in the F i g. 5 and 6 are screwed tight, a complete Sealing between the outer surface of the conduit 61 and the inner surface 62 of the wall opening is achieved, as shown in FIG. 5 shows. F i g. 6 is a partial plan view for illustrating the effect the tightening of the bolts of the seal and the restraining effect of the pressure plates, which the Press most of the rubber material outwards in a radial direction so that the desired tight fit arises.

Regarding the most common pipe sizes in electrical shafts. Pits or other areas of application for the seal € 2

so one advantageously chooses the length of the Plattenelemen te or links such as the elements 37,38,47 and 48 about; greater than 1 inch The center distance D between the pivot points of the articulated pressure plates is preferably somewhat smaller than 1 inch

SS held a

This results in a sufficient number of pivot points on the circumference of the seal, so that there are also pipes of relatively small diameter. wi (1/4 inch tubes, well enclosed. Simultaneously

the sealing elements are sufficiently large when used in front of pressure plate elements of this size so that only a limited number of Drchtungsele elements is required to produce a seal for relatively thick tubes, for example 2 1/2 inch tubes zt . With a distance D of about 1/2 inch, four sealing elements encompass a pipe with an outside diameter of 1 < U.sub.oI, five sealing elements a tube with an outside diameter of ½ inch. six sealing elements

assemble a two-line pipe and seven sealing clips a 2 '/.'/ 0IMgCs pipe, etc.

The sealing units 21 to 26 also allow a similar flexibility with regard to different radial distances / between the outer surface of the pipe 61 and the inner surface 62 of the edge opening. Thus, cooling blocks with a thickness T of Vk inches can provide a suitable fit if the radial opening to be sealed lies within a first predetermined range. On the other hand, a block with a thickness of ⁷ / κ inches results in an adaptation to significantly larger radial distances / between the pipe and the wall opening. Finally, VU inch thick sealing blocks can also be used with the same pressure plates if even larger edge openings are intended for a particular pipe size.

The I i g. Figures 7 and 8 illustrate a shock absorption Seal 120 in a modified embodiment of the Frfindiing. The seal 120 includes a A plurality of a sealing element 121, 122, 123 etc .. which are constructed according to the invention and with The desired seal is found adjacent to each other form. The seal 120 is typical for the sealing elements according to FIGS. 7 and 8. It contains a sealing block 131 made of rubber. Neoprene or any other elastomeric material shown in the Example is approximately U-shaped and has a protrusion 133 on one hand that points to an opening of the adjacent U-shaped block of the sealing element 122 too. The two legs 132 of the sealing block 131, one end of the sealing block each have a bolt receiving opening 134. The opposite and offset end 133 of the sealing block 131 is with a corresponding Bol / .en receiving opening 135 provided.

The element 121 has a first pressure plate 136 with two bolt openings 142 and 143 on their opposing ones End up. One end 138 of plate 136 is opposite the other end 137 by a distance offset, which is approximately equal to the thickness of the printing plate. so that the assembled panels are each overlap like F i g. 7 shows.

The sealing element 121 also includes a bolt 154 that extends through the opening 134 in the split end 133 of the sealing block 131 extends. The bolt 154 also protrudes through a opening 142 in the pressure plate 136 and through one of the bolt openings 152 in a second pressure plate 146, those on the opposite side of the sealing element located. As shown by bolts 154a and 1546 in FIG. the bolt protrudes each Sealing element through the openings of the pressure plates and through one end of the sealing block of a adjacent sealing element, so that all sealing elements / u a complete seal be united.

The in the F i g. The structure shown in FIGS. 7 and 8 has the same basic advantages as that according to FIGS. 1 to 6 on. The undivided pressure plates of the sealing elements according to FIGS. 7 and 8 avoid the need for rivets or other articulated connections, as is the case with the divided plates according to FIGS. 1 to 6 is the case. However, the individual pressure plates of the gasket 120 must be short enough to accommodate relatively small changes in pipe size so that the overall lengths of the gasket blocks and pressure plates are smaller than is the case with the hinge construction of the first embodiment. Accordingly, the embodiment of FIGS. 7 and 8 may be somewhat more expensive for a given application, depending on the number of different pipe sizes for which the fittings are intended.

F i g. 9 shows yet another training that is available for the Sealing block of each of the two seals 20 and 120 is usable. The remote blocks 161 and 162 are approximately V-shaped. In which the two legs of the V

The comprehensive end of the block 161 is a transverse opening 163 provided for the bolt, which runs through both legs. Also in the pointed end 164 of the Block 161 is a bolt opening 165 is provided which mn the two openings 166 of the adjacent block 162 is aligned. The V-shaped or herringbone shape the blocks according to I-i g. 9 results in the same clamping and sealing arrangement as in the other shaped blocks according to FIGS. 1 and 7.

Fig. 10 illustrates another relatively simple one Block shape, which is also suitable for the seal according to the invention. The two sealing blocks 171 and 172 have a parallelogram shape with two acute angles. The block 171 has two bolt holes 173 and 174. which run perpendicular to the side edges of the block and about the middle of the others both block edges go. The adjacent sealing block 172 has like bolt openings 175 and 176 on. the opening 175 with the opening 174 of the Block 171 is aligned. With this arrangement, the bolts of the sealing unit hold the one sealing block together and press the blocks together so that that a continuous shock-absorbing sealing element is created.

Another preferred embodiment of the invention is shown in FIGS. Il to 14 shown. the Seal 300 has resilient, compressible sealing blocks 301 in fragment form, the opposite Ends have grooves of circular cross-section, so that concave surfaces 301 are remote.

as Fig. 13 shows. The other edge parts protrude in addition, and represent convex projections 301 Λ. The projections of a block fit complementarily into the grooves of a second block and form a joint in the assembled state, the stepped Ends of each block are held together by means of a bolt 312 as shown in FIG.

For this purpose, the convex ends or projections 301 X of each block are formed with a through opening 305, as can be seen in FIGS. 13 and 14, and this through opening is aligned with the corresponding through opening of the neighboring block when the two parts are put together. For installation, the seal is provided with individual pressure plates and bolts, with the help of which the blocks are pressed apart in the radial direction and form a tight seal.

The individual relatively short pressure plates 310 are attached to opposite surfaces of the individual blocks and a bolt 312 is inserted through their openings 311. The pressure plates are arcuate and conform to the radius of curvature of the associated sealing blocks; their length is so great that at least the mated ends of the blocks are overlapped. The pressure plates are placed on opposite sides of the block, their opening 311 being aligned with the openings 305 of the assembled sealing blocks, so that a bolt 312 through each

609535/4 «

aligned openings can graze. The openings in the pressure plates are with Provided threads into which the bolts are screwed with their corresponding thread. in the In the non-tensioned state, the seal 300 according to FIG Parts are arranged, and the bolts produce the desired expansion and when tightening «Jen seal fit. Of course, the seal 300 can just as easily be unfolded, as shown in Fig. 14 put the inner part to be sealed around and then with its loose ends again with the help of the bolt put together.

10

From the above description of the ig. 11 to 14 it can be seen that the koniplementiirei projections of the convex linden 301A "in connection with the concave surfaces of the grooves 301C on the mating ends of the blocks result in a cylinder joint seal, which simultaneously effect a seal / wiper the plugged-together block ends allow the inner and outer curved surfaces .3OM and JOI B each block «

ίο very effective concentric or radial seals regarding the elements / wipe which clit Seal 300 according to Fig. 11 is arranged.

For this purpose 3 sheets of drawings

Claims (9)

Patent claims: 1. Sealing, shock-absorbing wall duct for pipes or the like with a ring compressible elastomer material of predetermined thickness, which is between a pipe sleeve and the pipe to be carried out or the like is arranged, and »η the axially having two pressure plates Clamping means are applied, which are provided by a number of axially tightenable clamping bolts that penetrate the ring are connected, which compress the elastomer ring in the axial direction so that it is in his Thickness expands and a seal between the pipe sleeve and pipe or the like. Forms, * obei the Elastomer ring is composed of several individual sealing blocks. characterized, that a plurality of more than two curved sealing blocks (21, 22, 23) so chained is provided that each sealing block (21, 22, 23) at least two axial Has bolt receiving openings (34, 35) which extend through the opposite ends of the block (21, 22, 23) at a circumferential distance from one another and in alignment with corresponding openings (35, 34) in the adjacent blocks (21, 22, 23) extend. each sealing block (21, 22, 23) having a Projection or the like at one end and a recess or the like at the opposite end has, and that the projection of each block (21, 22, 23) fits snugly into the receiving it Recess of the adjacent block (21, 22, 23) engages that the clamping means (36, 46) each consist of more than two pressure plates (37, 38 or 47, 48), with one pressure plate (37 or 38) forms a pair with a pressure plate (47 or 48) on the other side of the sealing blocks (21, 22, 23) and each pair of plates (37, 47, 38, 48) with an adjacent pair of sealing blocks on its opposite one Side ih is connected, and each plate (37, 47, 38, 48) with at least one Bolt receiving opening (42, 52 or 43, 53) is provided and the bolts (54) pass through them Pressure plate openings (42, 52 or 43, 53) and through the sealing blocks (21, 22, 23) extend to secure the pressure plates (37, 47; 38, 48) to the blocks (21, 22, 23) and around the Assemble sealing blocks (21, 22, 23) to form a linked arrangement. 2. Wall bushing according to claim 1, characterized in that each projection is circular is convex, and that each recess is circularly concave. 3. Wall bushing according to one of claims I and 2, characterized in that the Sealing blocks (21,22,23) offset connection ends each bolt (54) extending through the bolt receiving openings (43,53) in the two Pressure plates (37, 47 or 38, 48) and extends into the two adjacent sealing blocks (21,22). 4. Wall bushing according to one of claims I to 3, characterized in that each block (301 A) has a protruding part (301 *) at one end and a correspondingly recessed part (301 C) at the other end, the bolt holes at each sealing block are located in the protruding parts (301 X) of the blocks. 5. Wall bushing according to one of claims I to 4, characterized in that each Tensioning means (36, 46) is articulated like a chain. such that each a first flat Plate element (37,47) hinged to a second flat plate element (38,48) in an overlapping manner is. so that the opposite ends of the two connected pressure plates (37, 38 or 47, 48) are offset from one another by the thickness of a plate element. 6. Wall bushing according to one of claims 1 to 5, characterized in that a single sealing block (21,22,23) a right-angled Has a Z-shape, through the protruding legs of which the bolt receiving openings (34, 35) are performed (Fig. 1.6). 7. Wall bushing according to one of claims 1 to 5, characterized in that a single sealing block (121, 122, 123) has a U-shape with another end portion (133) protrudes from the arch of the U opposite the legs (132) of the U and into a recess of the central part of the adjacent block protrudes and that the bolt openings (134, 135) transversely through the legs (132) of the U or pass through the protruding end part (133) (FIG. 7). 8. Wall bushing according to one of claims 1 to 5, characterized in that the concatenated sealing blocks (161, 162) interlock in a V-shape (FIG. 9). 9. Wall bushing according to one of claims 1 to 5, characterized in that the chained sealing blocks (171, 172) each have the shape of an oblique prism (FIG. 10).