CZ20033421A3 - Cable sealing - Google Patents

Abstract

The present invention relates to a cable gland comprising a pair of gaskets elements placed in a protective tube around the sealed cables and compressed in the axial direction by flanges. Essence in that at least the outer flanges consist of two area parts (1,2). Each of these planar portions (1,2) is divided into at least two segments adapted for side paneling already installed cables (10), always out of these overlapping at least 65% of its outer the inner diameter of the protective tube (21).

Description

Cable gland

Technical field

FIELD OF THE INVENTION The present invention relates to glands for sealing points where cables pass through a wall or partition, while avoiding the passage of vapors, gases or liquids, even at relatively high pressures. Furthermore, it is an area where an element to ensure the fire resistance of such a passage is incorporated into the seals.

BACKGROUND OF THE INVENTION

At present various types of cable glands are known, in some cases resistant only to splashing water, but also to liquids, most often again to water, which may be under a certain overpressure. Seals preventing the ingress of splashing water are often used for cable passages or harnesses in motor vehicles. These are plugs with orifices and where contact of the seal with the cable surface is ensured by the elasticity of the seal material. Such seals, respectively. The grommets have a relatively low contact force between the cable and the gland and this also corresponds to the relatively low sealing capability. Seals used to seal cables at the inlet of electrical circuit breakers exhibit a higher sealing capability, where a rubber ring is threaded onto the cable, which is axially compressed by a hollow screw at the passageway thereby generating a radial expansion of the seal material and thus sealed cable and housing surfaces. Larger cable glands also work on this principle, also adapted to seal multiple cables. Here, however, it is necessary to solve the problem of resistance to relatively high axial forces, if the seal has a relatively larger area and seals relatively high pressures, and the problem of a suitable assembly of the seal for cases where it is not possible to count on it. threading the gland, and its flange-type accessories, etc., over the ends of the cable or cables, but where it is necessary to install the gland laterally. In such cases, split bodies are used, both the split seal body and the split flange body. Such an embodiment is known, for example, from EP 0899493, where a sealing ring with a separating plane is used, here in particular running at an angle to the radial plane. Regarding the blockage against the squeezing of the gland by the protective tube, it is known to support the pressure flanges or discs on some part of the through protective tube. It is also known to form circumferential protrusions within the protective tube, which are to prevent, among other things, the displacement of the sealing element in the protective tube. Such solutions meet the desired purpose quite well, but under high stresses, the inner protrusion in the protective tube is no longer an obstacle to displacement of the sealing element when it is small, or, on the contrary, undesirable deformation of the sealing element body, if it is too large. As for supporting the outer pressure flange on the edges of the protective tube, there are two types of problems at higher pressures. On the one hand, due to the split design of such a flange, it may have greater deformation just in the vicinity of the dividing line, which either requires an extremely strong design of such a flange, or it may cause undesirable deformation of this flange and thereby inadmissible deformation Whole cable glands.

SUMMARY OF THE INVENTION

These disadvantages are solved to a considerable extent and the formation of a cable gland of relatively light but durable and reliable construction is achieved by a cable gland according to the present invention comprising a pair of sealing elements disposed in a protective tube around sealed cables and compressed axially by flanges, consists in that at least the outer flanges consist of two planar portions, each of said planar portions being divided into at least two segments, adapted for lateral lining of the cables already installed, each of them being The outer of these planar portions exceeds the inner diameter of the protective tube by at least 65% of its outer circumference. Preferably, the dividing line between the segments of the inner surface and the outer surface of each, at least the outer flanges, are mutually parallel to each other. It is particularly advantageous if the dividing line between the segments of the inner surface and the outer surface of each, at least the outer flange, forms an angle of between 30 and 90 degrees. It may also be advantageous if the number of segments of the outer surface of each outer flange is greater than the number of segments of the respective inner surface of the outer flange. Advantageously, the outer and inner flanges are each pulled together by at least four tightening bolts over the respective sealing element, and at the same time the two outer flanges, supported from outside on the ends of the protective tube, are pulled together by at least one through-bolt. It is also advantageous if the cable gland system also contains a fire-resistant gland of non-combustible material between the sealing elements. Alternatively, it may be advantageous if, in the cable seal system, a pipe or tunnel is provided on the outside of the sealing elements containing a fire seal of a non-combustible material. Finally, it may be advantageous if at least one tightening screw has a through axial bore in which a valve adapted to connect the tightness monitoring device of the interior of the cable gland is provided.

This results in a lightweight and relatively inexpensive cable gland that is both highly reliable and easy to manufacture and assemble. The pleated flanges can be easily manufactured from a flat material without turning and yet exhibit high strength and deformation resistance even at high sealing pressures in the configuration of the present invention, thereby maintaining the unchanged shape of the sealing elements for longer and thereby maintaining their full sealing ability. . In this connection, the mounting of the cable gland system in the protective tube, with anchoring against axial displacement or extension due to the pressure difference by means of overlapping outer surface portions of the outer flanges, also has the prerequisites for bearing higher axial forces. the surface portions of the outer flange transferred to the inner surface portion of the outer flange causing premature undesirable deformation of the respective sealing element, resulting in premature loss of its sealing ability.

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BRIEF DESCRIPTION OF THE DRAWINGS

BRIEF DESCRIPTION OF THE DRAWINGS The invention is described in more detail with reference to the accompanying drawings, in which: Fig. 1 shows a cable gland in an exemplary embodiment in longitudinal vertical section; Fig. 2 shows a plan view of an inner planar part consisting of two segments Fig. 3 shows the shape of the sealing element in plan view with its dividing line, and finally, Fig. 4 shows, again in plan view, from inside the sealing system, the outer flange assembly with the peripheral surface of the outer flange, with the inner surface of the outer flange visible and the relative positions of the dividing lines of the respective segments of the respective outer flange portions shown.

DETAILED DESCRIPTION OF THE INVENTION

The cable 10 is sealed in the wall 20 by means of a cable gland assembly comprising rubber sealing elements 3 inserted into the protective tube 21, consisting of two portions 31, 32, each of which portions 31, 32 with axial openings 311 and 32, respectively. 321 for the clamping screws 6 and for the through screws 7. The sealing elements 3 are compressed by the clamping screws 6, over each other the outer surface 1 and the inner surface 2, respectively, corresponding to the outer flange and the inner surface 4 and outer the flat parts 5 belonging to the inner flange. Here, each surface part 1, 2, 4, 5, and also the sealing elements 3, are here divided into two segments. This makes it possible to mount the surface parts 1, 2, 4, 5 and the sealing elements 3 from the side onto the cables 10 already installed in the protective tube 21. The through bolts 7 are supported so that they extend over both the outer and inner flanges and over the two sealing elements 3 and over the entire interior space in the sealing system, the outer flanges or the outer flanges respectively tightened to each other by the through bolts 7; the outer planar portions 1 of these outer flanges are supported by their edges on the face of the protective tube 21, which is made possible by overlapping the outer periphery of the outer planar portion 1 of the outer flange, here along the entire periphery, over the inner periphery of the protective tube 21. but also due to the deformation of the sealing elements 3 due to the relatively high axial force on these sealing elements 3 at larger pressure differences.

between spaces separated by pressure. Thus, the sealing elements 3 are pressed against the inner walls of the protective tube 21 at symmetrical pressure of the flanges on both sides, and likewise they are pressed on the clamping screws 6 and the through screws 7, thereby ensuring tightness against relatively high pressures with very high reliability. In the exemplary embodiment, there is still a fire seal 8 disposed between the sealing elements 3. An alternative embodiment with two fire seals disposed on the outside of the sealing elements 3 is not shown here, but its technical design is quite analogous, and neither any sealing function of such a fire stopper 8 is not anticipated, so as a rule, it is sufficient to simply press such fire stopper 8, here made of a non-combustible fibrous material, into the protective tube 21 when installing. relative to the inner part 2, respectively. 3, the flanges, then the dividing lines between the pairs of segments of these parts are always rotated by 90 angle degrees to each other. This achieves a uniform transmission of forces from the compressed sealing elements 3 to the flanges as a whole, even though these flanges are formed from planar parts divided into individual segments. In some cases, not shown, the manufacturing and assembly advantage may be that the number of segments forming the outer flange portion 1 of the outer flange is greater than the number of segments forming the inner flange portion 2 of the outer flange. The most common embodiment of such a flange type will then have an outer planar portion 1 composed of three segments divided in the manner of longitudinal parallel strips. In at least one clamping screw 6, a through axial bore, not shown here, may be formed, in which a valve adapted to connect the tightness monitoring device of the interior of the cable gland is provided. Such a monitoring device may be, for example, a pressure gauge or a pressure sensor for the remote transmission of the measured absolute pressure value, or for transmitting a fixed exceeded signal, i.e. essentially a pressure switch.

The assembly of the sealing assembly is apparent from the description of the exemplary embodiment. The function of the whole device is mainly sealing, eventually also fire-fighting.

Economic usability

The cable gland according to the present invention is mainly used for sealing the spaces between which the cables are to pass, and where these spaces are to have a highly durable and reliable seal that exhibits a long service life without at the same time the cost of the seal being extremely high and production and assembly was disproportionately complicated. The use of this cable gland is likewise possible for the formation of a sealed passage of other shapes than cables, for example pipes or earthing strips. The types of sealed passages described will generally occur between deep spaces where there is, or may be, a situation with a high pressure difference.

Claims (8)

PROTECTION REQUIREMENTS? 44 99 4994 4 4 4 4 9 4 4 4 4 4 4 4 9 · · · · · ··· · * · « A cable gland comprising a pair of sealing elements mounted in a protective tube around sealed cables and compressed axially by flanges, characterized in that at least the outer flanges consist of two planar portions (1,2), each of said planar portions (1). 2) is divided into at least two segments, adapted for lateral lining of already installed cables (10), each of the outer parts of which at least 65% of its outer circumference exceeds the inner diameter of the protective tube (21). Cable gland according to claim 1, characterized in that the dividing line between the segments of the inner surface (2,4) and the outer surface (1,5) of each, at least the outer flange, is mutually parallel. Cable gland according to Claim 1 and 2, characterized in that the dividing line between the segments of the inner surface (2,4) and the outer surface (1,5) of each, at least the outer flange, forms an angle of between 30 and 90 degrees. Cable gland according to claims 1 to 3, characterized in that the number of segments of the outer surface portion (1) of each outer flange is greater than the number of segments of the respective inner surface portion (2) of the outer flange. Cable gland according to one of Claims 1 to 4, characterized in that the outer and inner flanges are each pulled together by means of at least four clamping screws (6) over the respective sealing element (3) and at the same time the two outer flanges supported from the outside. the ends of the protective tube (21) are tightened to each other by at least one through screw (7). Cable gland according to one of Claims 1 to 5, characterized in that the cable gland system comprises, in addition to the sealing elements (3), a fire gland (8) made of a non-combustible material. 44 4444 4 4 4 4 4 4 4 4 4 4 4 4 4 44 44 Cable gland according to one of Claims 1 to 5, characterized in that in the cable gland system a protective tube (21) or a tunnel comprising a fire-resistant gland (8) of non-combustible material is provided on the outside of the sealing elements (3). Cable gland according to one of Claims 1 to 7, characterized in that a through axial bore is provided in at least one clamping screw (6) in which a valve adapted to connect the leak monitoring device of the interior of the cable gland is provided.