SE420784B - DEVICE FOR FIRE SEALING FOR A ATMINSTONE A WIRE THROUGH A BUILDING ELEMENT - Google Patents

Description

x -§oo2o4s-6 10 15 20 25 30 sar. At least some of these blocks are divided and have mutually facing semicircular recesses for a cable. The cylindrical space between these ball halves is filled with a cylindrical sealing body, which can thus be removed to make room for a cable. The clamping frame offers through employment the desired tight abutment between the blocks and the cables. The disadvantage of such a clamping frame, however, is that the provided blocks only offer sealing for certain cable dimensions and a certain number of cables. This in turn has meant that when supplementing the cable through such a clamping frame, an entire block is simply removed so that the seal between the cable and the adjacent blocks is destroyed. Furthermore, it has often been observed that in connection with the handling work, blocks have been lost which have not been replaced, which is why the fire penetration has continuous openings which nullify the device's fire-retardant function.

Furthermore, it is previously known to use rubber bushings to seal a cable gland (cf. British Patent Specification 953 869) in which a tubular rubber plug is clamped in a bushing, after which a cable group is penetrated through the hole of the plug. However, such a technique is not particularly useful for fire sealing purposes, as the cables usually have to be routed a long distance through the plug, and a new bushing must be provided and a new plug provided if an additional cable group is to be routed through the wall.

They have therefore switched to a plastic casting technique which means that the cables or wires are laid in the bushing, and then the bushing is temporarily sealed by means of dams, whereupon a fire-retardant silicon rubber is foamed in place in the bushing. This technology is offered by Studsvik Energiteknik AB under the designation "Fire sealing system FC-225", using a silicone foam that is commercially available under the designation Dow Corning 3-6548 RTV. However, if you subsequently wish to run a cable through, for example, a wall, you should take up a further penetration for this, for example in an existing wall and seal the bushing with the FC-225 technology. This is difficult, especially if the wall consists of concrete, and costly, not least considering that wall coverings such as panels and wallpaper are often damaged and must be replaced.

Alternatively, a hole can be drilled through a fire seal in an existing bushing to seal the annular gap between the hole and the cable after the wiring.

DISCLOSURE OF THE INVENTION The present invention relates to a special device for fire sealing of lead-through for conduit through a building part such as a cast wall, roof or floor or cast part thereof, for example lightweight concrete blocks or wall modules or so-called concrete or lightweight concrete floorboards, whereby by means of the invention the above-mentioned disadvantages are considerably reduced or eliminated and in addition special advantages are achieved with regard to simplicity and economy in manufacture, economic storage and simple and reliable application. In addition, the invention enables a safe fire seal even during ongoing construction.

The device according to the invention here comprises a prefabricated body with a tubular jacket and elastically refractory foam material arranged in the jacket, which is compressed by the jacket across the longitudinal axis of the jacket, whereby the conduit is tightly clamped in the foam material by its compression. It is characteristic of the invention that the jacket has an external helical thread.

In addition to the above-mentioned inconveniences of previously known devices for fire sealing a bushing being significantly reduced or eliminated, the invention gains the advantage of using bodies which can be manufactured in the factory under conditions which can be easily and well controlled with respect to the foaming conditions. Through the external thread, the advantage is obtained of a form-bonded casting of the fire-sealing body in the building element and a good seal around the body by the casting mass (concrete) lying in the threads. Preferably, the jacket is formed to form, in addition to the external thread, also an internal thread, whereby a molded arrangement is also obtained of the foam material expanded during the production of the body into the threads and a good seal between the jacket and the foam material. The external thread also has the advantage that it enables a simple and secure anchoring of the fire-sealing body during its casting in by screwing one end of the jacket into a fastening element fastened to one of the mold walls.

By screwing in the casing adapted length, an adjustment to the correct length in relation to the thickness of the cast building element is also made possible in a simple manner. A secure attachment of the opposite end of the fire seal body can in a preferred embodiment be obtained simply by the foam material at this end projecting a small distance outside the jacket and thereby being pressed against friction against the mold wall.

In combination with projecting foam material (possibly alternatively to projecting foam material), the retention can be further ensured by attaching a retaining member in engagement with the foam material in the mold wall. In an embodiment of the invention, the jacket is filled with foam material along its entire length. In an alternative embodiment, the jacket is filled with foam material from its one end up to a piece from the opposite end of the jacket, the length of the foam material being adapted to correspond to the set safety requirements for the current fire seal and said piece with unfilled foam material having a length for adapting the entire length of the body to the thickness of the building element in question. By this alternative embodiment an advantageous limitation of the amount of foam material is obtained. the desired adaptation of the length of the body to the actual thickness of the building element can, if not already the length is correct; easily obtained by cutting the sheath of the non-foamed part of the body. This can be economically advantageous in that the nantehukan is made of a cheap material compared to the foam material; preferably thermoplastic materials such as poly- Gtên- THROUGH this process no material is lost. Furthermore, after mounting the body, the jacket ends can be used for easy screwing in of any suitable detail, for example a decorative flange suitable from an appearance point of view.

Preferred embodiments of the invention are described in more detail below with reference to the accompanying drawings. FIGURE DESCRIPTION Fig. 1 shows in section along the line I-I in Fig. 2 an embodiment of a fire-sealing body.

Fig. 2 shows an end view of the fire seal body seen from the Left in Fig. 1.

Fig. 3 illustrates in side view and exploded view the installation of a fire sealing body between two mold walls.

Fig. 4 shows in section corresponding to Fig. 1 the fire sealing body in mounted position between the mold walls and after the mold has been filled with concrete.

Fig. 5 shows on a larger scale a plan view of a fastening element suitably designed for the fire sealing body according to Figs. 1 and 2 for fastening the fire sealing body during casting, for example a casting as shown in Fig. 4.

Fig. 6 shows a section taken along the line VI-VI in Fig. 5.

Fig. 7 shows a section taken along the line VII-VII in Fig. S.

Figs. 8-11 show sections corresponding to Fig. 4 but after tearing the mold walls and illustrate in different working steps the drawing of a pipe through the fire sealing body by means of a tool specially designed for the drawing.

Fig. 12 shows in perspective view and on a larger scale the head of a handle included in the tool. V 8002045-6 Figs. 13 and 14 illustrate in perspective view two different examples of attachment of a fire sealing body to a pre-occupied hole in, for example, a cast wall or building element.

Fig. 15 illustrates in perspective view the fastening of a fire sealing body in a hole in a thin wall of fire-resistant material such as steel.

PREFERRED EMBODIMENTS Figs. 1 and 2 show in principle the construction of a fire sealing body; generally denoted by 1. This consists of a jacket 2 which is axially formed with thread 3. In the embodiment shown, the jacket 2 is so shaped that both external and internal threads are present.

The sheath can consist of, for example, thermoplastic such as polyethylene.

The interior of the jacket is from one end along a part 3a of its length filled with an elastic fire-resistant foam material 4 which is foamed in place in the jacket so that the hardened foam is kept compressed by the jacket. The foam material is suitably a silicone foam which is commercially available under the designation Dow Corning 3-6548 RTV, which foam is suitably produced in place in the jacket 2. As the material expands during manufacture, assuming a foam-rubbery consistency, the jacket is also filled in. internal threads, which, in addition to the jacket being compressed, holds the foam material across the axial direction of the jacket, contributes to the foam material being retained and also provides a decidedly better seal than if the inside of the jacket were smooth. Although not shown, one or more reinforcing meshes may be included in the foam material, partly to prevent the material from breaking loose during later wiring (see Figs. 8-11), and partly to enable a tight arranging a plurality of conduits through the fire seal body without breaking the material and cracking therein. The length Safilled with the foam material is adapted to the regulations applicable to the fire seal in question in the form of fire classification involving a certain minimum gap fl and electrical safety regulations involving a certain maximum length.

The fire sealing body 1 is manufactured with an unfilled part 5 which suitably has a length which enables the use of the same fire sealing body for different current wall thicknesses. The part 5 can easily be cut, suitably with a saw, to the correct length, for example as shown in Fig. 1 after a dotted line 6.

Figs. 3 and 4 illustrate the casting of a fire-sealing body between two mold walls 7 and 8, the fire-sealing body having the design shown in Figs. 1 and 2 in principle.

Fig. 3 here illustrates how first against one mold wall 7 is fastened by means of nail 9 a fastening frame generally designated 10, which may have a design as described in more detail below with reference to Figs. 5-7, i.e. among other things, have an internal thread adapted to the thread 3 of the jacket 2. After cutting off the fire-sealing body 1 to at least approximately the correct length, the body is relatively fixed to the mold wall 7 by screwing into the fastening frame 10.

Through different lengths of screwing in, the possibility of adjustment with regard to the thickness of the wall is offered -Then the mold wall 8 is mounted and the mold is pulled together, whereby the fire-sealing body is clamped between the mold walls. An adjustment within a certain tolerance for the length of the fire seal body is also obtained by the longitudinal elasticity of the body due to its threaded design. As can be seen from Fig. 3 (and also Fig. 1), the foam material projects a small piece (a few mm) outside the jacket 2. This projecting part is denoted by 11. As a result, friction between the foam material and the mold wall is obtained by holding it end of the fire seal body against the mold wall. An additional security for holding this end can be obtained by nailing to the mold wall 8 a suitable relatively flat device (not shown) provided with insertion means, for example in the form of concentric rings, which after mounting the mold wall will to engage with the foam material. In this case, the protruding foam material 11 could alternatively be dispensed with. By using a fastening frame, the requirement for a perfect cutting of the fire-sealing body with respect to the flatness of the cut as well as the perpendicularity to the longitudinal axis of the body is eliminated.

Fig. 4 illustrates the fire sealing body 1 with fastening frame 10 after the filling of concrete 12 between the mold walls 7 and 8.

By also filling the external threads with concrete, a form-retained holding of the fire-sealing body in the concrete is obtained. The fire seal body forms a gas, fire, water and sound tight penetration during the entire construction period, both before and after wiring through the fire seal body.

With reference to Figs. 5-7, an advantageous design of the fastening frame 10 shown in Figs. 3 and 4 will now be described. This consists of an annular wall 13, along the inside of which a thread is formed. In the exemplary embodiment shown, this consists of two straight, almost semicircular strips 14 and 15, the free ends of which, seen in plan view, do not meet. On the outside of the wall 13, four diametrically opposite nail holes 16 are arranged for nailing the fastening frame to the mold wall (the mold wall 7 in Figs. 3 and 4). The nail holes 16 widen in ßon2n4s-6 10 15 20 25 30 35 10 towards the edge side of the mounting frame wall 13 which is to abut against the mold wall. When tearing down the mold wall 8, the nails follow, but the flange frame remains in the concrete.

From the opposite edge side of the flange frame wall 13, perpendicularly the wall projects four diametrically opposite corner portions 17 and 17, respectively. 18. In the corner portions 17, outwardly open grooves 19 are formed and the corner portions 18 are provided with buttons 20, which can be snapped into the grooves 19 in a nearby fastening frame to form the desired number of fastened frames 10 in a row. To ensure a fixed such snapping together adjacent fastening frames, each fastening frame is provided with locking means consisting of a salmon tail-shaped lug 21 projecting from the outside of the fastening frame wall located between the buttons 20 and a diametrically opposite groove 22 formed in a corresponding manner.

Figs. 8 ~ 11 illustrate in different working steps the laying of a pipe through a fire-sealing body after the mold walls have been torn down. The exemplary fire sealing body shown corresponds to the body according to Fig. 4 and is shown cast in concrete wall 23. In order to obtain a tight penetration of the pipe, a special penetration tool is used, which consists of three parts, a conical tip 24, a sleeve 25 and a handle 26 with head 27, which cooperate in the manner shown in the following description.

As shown in Fig. 8, preferably only the tip 24 is pressed into the foam material 4, or if several lines are to be drawn, a tip is pressed for each line, whereby by means of the tips it is possible to plan how the different lines are best placed. The front end 28 of the sleeve is inserted into the tip and by means of the handle the tip and the sleeve are pushed through the foam material and when the tip has passed the foam material it falls off by itself. For this push-through, the handle can be allowed to press against the rear end 29 of the sleeve with the handle in position as shown in Fig. 8, whereby in the head 27 of the handle an annular bottom groove is accommodated (see Fig. 12) in which the sleeve end is inserted during the push-through. By special design of the head 27 (shown in more detail in Fig. 12) with recesses 30 for hooking on two of four lugs 31 evenly distributed around the circumference of the sleeve 25 located near the rear end of the sleeve, alternatively after such hooking the piercing of the tip 24 and the sleeve 25 be made with a relatively inclined position of the handle 26 for the handle 26, which can be valuable in more inaccessible places.

Fig. 9 shows the position of the sleeve 25 after it has been pressed through the fire sealing body and a line 32 has been pulled through the sleeve. Because the hole made through the fire seal body is shot with and thus protected by the sleeve, the cable can be pulled through the fire seal body without damaging it. As shown, the sleeve is slotted at the ends 28 and 29 and thereby forms "funnel" -shaped openings, thereby preventing the conduit from being locked in place during the drawing thereof.

Fig. 10 illustrates pulling the sleeve 25 out of the foam material after the wiring is completed. Especially for this extraction, the sleeve is provided with said lugs 31 and the main part 27 of the handle with said recess 30. Through the four lugs 31, which are arranged around the circumference of the sleeve, a versatile engagement between two lugs and the recesses is allowed for good accessibility. In addition, rotation of the sleeve during extraction to the most comfortable position is permitted. Furthermore, the recesses 30 are widened outwards so that the lugs 31 are guided into the bottoms of the recesses even at an angle between the center axis of the handle and the center axis of the sleeve lying within a relatively large angular range, thereby also allowing a similar large angular range between handle and sleeve during extraction. After extraction, the sleeve must be removed from the cable. To easily accomplish this, the sleeve is formed with a perforation or other instruction (not shown) extending between two opposite bottoms of the slotted ends 28, 29.

After cutting this perforation, the sleeve can be widened and the cable removed. The head 27 of the handle is specially designed for use in this cutting.

On the back of the head 27 relative to the recesses 30, the head is provided with a slitting part (see further Fig. 12) consisting of cutting edge 33 located inside an outwardly rounded sliding lug 34. In the slots at the sleeve ends 28, 29, between which the perforation extends, a secure engagement of the slit 27 of the head 27 is obtained, whereby in addition the slit part is designed so that the handle can be held within a large angular range relative to the sleeve (eg 15-559) for convenient access. The accessibility is also increased by the fact that the head 27 is designed with two slit parts; one behind each recess 30; and thereby also increases the life of the handle. The rounded sliding lug 34 is arranged to prevent the cutting edge 33 from being damaged during the slitting.

Fig. 11 shows the line 32 inserted in the bushing after the sleeve 25 has been removed. By not removing any foam material but only compressing the material, the resilient material 4 is elastically obtained and a sealing enclosure of the foam material around the line is obtained.

As stated above, the head 27 of the handle is more clearly shown in Fig. 12 with the design of recesses 30, cutting edge 33 and sliding lug 34. Furthermore, the figure shows the annular groove, into which the end 29 of the sleeve 25 is inserted during printing. of the tip 24 and the sleeve 25 through the foam material 4 of the fire seal body 1. This groove is indicated in the figure by 35. In addition, a groove 36 is delimited by the sliding coupling 34 against the side of the recess 30 and a bottom wall, the lower edge of which is shown in the figure. the cutting edge 33. In this groove 36, during the slitting of the sleeve 25, one of the slotted edges is successively guided.

With reference to Figs. 1-12, a fire-filled body with a circular cross-section and a threaded jacket has been partially filled with foam material. Many of the advantages stated in this specification, as initially introduced under the heading DESCRIPTION OF THE INVENTION, can be obtained with a fire seal body of a cross-sectional shape other than circular, such as, for example, square, rectangular or oval, the jacket of such a body being may have external threads or other corrugation or other protruding portions or be smooth but instead of being threaded into the fastening frame can be fastened in another way, for example snapping into a suitably designed fastening frame.

Another alternative is to use a fire-filled body completely filled with foam material with a circular cross-section and a threaded jacket. Such a fire sealing body has all the above-mentioned advantages except those obtained by having the jacket of the fire sealing body only partially filled with foam material.

Other examples of fire seal bodies, completely or partially filled with foam material, are shown in Figs. 13-15, Figs. 13 and 14 showing fire seal bodies for attachment to a pre-occupied hole in a wall or building element and Fig. 15 showing a fire seal body in a hole in a relatively thin wall of fire-resistant material, such as a ship shot.

Fig. 13 shows a part of a wall or a building element 37 with a hole 38. An outer sleeve 39 of foam material is cast on a slotted pipe 40, which in addition to the inner thread 41 shown may have an outer thread and which tapered suitably. towards the wear edges.

The tube 40 with the sleeve 39 is inserted into the hole 38. Thereafter, shafts 46, 47 ha '14 are threaded into the tube 40 with a sheath 42 provided with an external thread 42 and preferably also with an internal thread for a bushing body. 43, which is completely or partially filled 7 with foam material 4. At the entrance, the slotted tube 40 is pressed by expansion against the outer sleeve 39, which in turn is pressed against the walls of the hole 38.

Fig. 14 shows a wall or a building element 44 in section through a hole provided in the wall with thread 45. The thread 45 can in this case be formed in a cast-in sleeve or in certain wall materials the thread can be formed in the material itself.

A bushing body consists of two cross-section semicircular halves 46 and 47 with jacket with external thread 48 and as shown preferably also internal thread and with cross-section semicircular hole 49. The halves 46 and '47 as shown are filled with their entire length with foam material 4, is pressed on a line 50 and clamped against each other, after which the assembled halves are inserted into the hole provided with the thread 45. This design of a fire seal body is intended for a single pipe, especially of a coarser dimension, and is especially useful for pipe which is not channeled through the foam material of a fire seal body by, for example, being provided with a projecting connection. Alternatively, it is possible to cast the fire seal body in the usual manner and then unscrew it to connect the line and re-screw it into the threaded hole. This has the advantage that even during construction you can have a tight penetration.

Another alternative is to instead of two separate a slotted bushing body.

Finally, Fig. 15 shows a bushing body 51 with a jacket provided with an external thread 52 and preferably also an internal thread, the jacket usually enclosing a foam material 4. The bushing body is threaded in by means of fastening flanges 54 provided with internal threads 53, which previously attached to opposite sides of a wall S5 with the collars 56 of the mounting flanges sealingly surrounding a hole received through the wall 55.

If in the embodiments according to Figs. 13 and 15 only one line is to be arranged through the bushing body, this can, similarly to what is shown and described with reference to the embodiment according to Fig. 14, be divided into half-ear or slit.

Claims (7)

8002045-6 16 PATàNn A device for fire-sealing a bushing for at least one conduit through a building element, comprising a prefabricated body with a tubular jacket with a circular cross-section and arranged in the jacket an elastically fire-resistant foam material, which is compressed by the jacket along the longitudinal axis of the jacket, wherein the conduit is sealingly clamped in the foam material by its compression, characterized in that the jacket (2) has an external helical thread (3). Device according to claim 1, characterized in that the jacket (2) is formed to form, in addition to the external thread (3), also an internal thread. Device according to claim 1 or 2, characterized in that the jacket (2) is filled with foam material (4) along its entire length. Device according to claim 1 or 2, characterized in that the jacket (2) is filled with foam material (4) from its one end to a distance from the powered end of the jacket, the length (3a) for the foam material is adapted to correspond to the set safety requirements for the current fire seal and said piece (5) with unfilled foam material has a length for adapting the entire length of the body (1) to the thickness of the relevant building element (23). Device according to one of the preceding claims, characterized in that one end of the jacket (2) is screwed into a fastening element (10), which during casting of the building element (23) between mold walls (7, 8) is attached to one mold wall / 7), Device according to claim 5, characterized in that the foam material (4) projects a small piece (11) outside the jacket (2) at the end opposite said one end for abutment during casting of the building element (23) towards the other. fqrmväggen (8). Device according to claim S or 6, characterized in that the foam material (4) at the end opposite said one end is in engagement with one end holding means attached to the other_§9: m wall (8).