FI125992B - Fire protection duct for electrical cables - Google Patents

Description

FIRE PROTECTION DUCT FOR ELECTRIC CABLES

The present invention relates to a fire protection duct for electrical cables, the fire protection duct having a base member and a cover member having both an outer casing and an insulating layer arranged against the inner surface of the outer casing to insulate , and the fire protection duct includes a support plate attached thereto, comprising a plurality of support points for attaching electrical cables.

Electric cables are usually covered with plastic, which in the event of a fire is easily melted or ignited. The fire spreads easily through electrical cables to various parts of the building. It is therefore important to protect the electric cables with a separate fire protection duct. According to general fire safety regulations, the internal temperature of the fire duct in the event of a fire must not exceed 180 * Ό after 30 minutes and the maximum outside temperature of the fire duct is 850 * 0.

One solution known in the art is disclosed in Utility Model Publication DE 20023142 U1, where electrical cables are placed in an insulated fire protection duct over ridges. Another known solution is the fire protection duct, known as Rauthermo, manufactured by Rehau AG, where electrical cables are placed on insulated fire protection ducts on shelves. The problem with both of the above solutions is that the electrical cables overlap in the fire protection duct as bundles of electrical cables. In this case, the electric cables are exposed to heat caused by the current flowing through them. In addition, the electric cables are loose in the fire protection enclosures without any attachment. This is also a space-functionally poor solution.

US 5,391,840 is also known in the art where the fire protection duct includes a support iron to which electrical cables are attached. However, this solution is otherwise of poor thermal insulation.

It is an object of the invention to provide a prior art fire protection duct for electric cables, in which the electrical cables can be secured to the fire duct offset from one another and can be advantageously implemented while still providing sufficient insulation. Characteristic features of the present invention are apparent from the appended claim 1.

This object can be achieved by a fire protection duct for electrical cables, which fire protection duct includes a base part and a cover part. The base member and the carrier member both include an outer casing and an insulating layer arranged against the inner surface of the outer casing to insulate the electrical cables installed inside the fire duct from the heat caused by a fire. At least the base member includes a plane member and side members, and the fire protection duct includes a support plate attached thereto, comprising a plurality of support points for attaching electrical cables. The fire duct further includes a second insulating layer adapted to be mounted on the junction between the base member and the cover member to insulate the junction duct.

Thanks to the second insulating layer, heat transfer from the outside of the fire duct to the junction between the base and the cover portion is effectively prevented. With this solution, the electrical cables can be secured to each other in a fire protection duct so that the temperature of the electrical cables remains low. The fire protection duct can be mounted on a wall or ceiling, as the electric cables always remain attached to the brackets.

Preferably, the outer shell of both the base portion and the lid portion is arranged to extend at least the intersection of the fire protection duct e to the inner surface of the layer. Thus, the outer shell effectively protects the dielectric layer and prevents heat from entering the fire duct.

Preferably, at least one of the dielectric layers is gypsum to absorb heat. The gypsum is non-combustible and absorbs heat.

The fire protection duct may include at least one longitudinal support wall partition for the fire protection duct, comprising support points for increasing electrical cable support points. The support partition wall can be used to extend the power cable support points inside the fire protection duct if needed.

Preferably, the carrier plate is superimposed on both the edge portions and the planar portion and is adapted to be U-shaped to accommodate the insulating layer to support the fire duct. In this way, the carrier plate is firmly secured to the base member and supports the base members and the plane member to one another and presses the insulating layer or layers on the outer casing.

According to one embodiment, the ends of the outer casings of both the base portion and the cover portion are bent substantially parallel to the side insulating layer inside the insulating layer. The bending allows the heat transfer between the base and the lid section to be effectively stopped.

An open space for the ends of the outer casing may be left between the second layer of the junction and the junction layer of the cover member. This allows the outer shells to be folded inside the fire duct.

Preferably, the second dielectric layer is adapted to cover the junction of the base member and the cover member over a longitudinal length of the entire fire protection duct. Thus, the second dielectric layer prevents heat leaking into the fire duct from the junction.

The second insulation layer may include a third insulation layer and a second insulation layer mounted on the base insulation layer for additional insulation of electrical cables. The third insulating layer stops heat propagation from the junction between the base member and the cover member toward the electrical cables. At least one layer of insulation may be wool to lighten the fire protection duct.

According to another embodiment, the outer casing is arranged to form on said free side a longitudinal groove of the fire protection channel for locking the cover portion of the cover portion. The purpose of the groove is to prevent the "screwing" of the fixing screw between the base and the cover part.

According to one embodiment, the plane portion and the edge portions are arranged in a U-shape.

Preferably, the fire protection duct comprises at least two separate support plates which are 5-50 cm long, preferably 10-25 cm long in the longitudinal length of the fire protection duct. Thus, the support plate can be discontinuous and the support points can be located only in parts of the fire protection duct.

The support points may be bulges made on the support plate. The bulges allow the electrical cables to be disconnected from one another on the carrier plate e without reducing the thickness of the layer. Preferably, the support points are overlapping with respect to each other and longitudinally along the fire protection duct, leaving an air space between the electric cables through which the heat generated by the electric cables can be dissipated.

The fire protection duct according to the invention can be used mounted on a ceiling or wall and the fire protection duct fulfills the requirements for fire safety with respect to insulation. The support plate allows the electrical cables to be secured to the flat and edge sections of the fire protection housing and to separate the electrical cables. This ensures that the electric cables are securely attached, which results in better room utilization and efficient cooling of the electric cables.

The invention will now be described in detail with reference to the accompanying drawings, in which:

Figure 1 shows a fragmentary axonometric view of a fire protection duct according to an embodiment of the invention,

Fig. 2 is an exploded and opened axonometric view of a fire protection duct according to an embodiment of the invention,

Figure 3 is a sectional view of a fire protection duct according to an embodiment of the invention,

Figure 4 shows a sectional view of a fire protection duct according to an embodiment of the invention, when the fire protection duct has a carrier partition,

Fig. 5 shows axonometric details of a fire protection duct carrier plate according to an embodiment of the invention,

Figure 6 is a sectional view of a fire protection duct according to another embodiment of the invention,

Figure 7 shows an open axonometric view of a fire protection duct according to another embodiment of the invention,

Figure 8 is a fragmentary enlarged view of an embodiment of the fire protection duct of Figure 7.

Figures 1-5 illustrate a fire protection duct according to one embodiment of the invention, while Figures 6-8 illustrate another embodiment. As shown in Figure 1, the fire protection duct 10 consists of a base member 12 and a cover member 14 adapted to be attached thereto. The fire protection duct 10 is preferably rectangular and is fixed in use to a planar member 32 of the base member 12 on a wall, ceiling or floor. In shaft structures, attachment can be made to, for example, step planes. The fastening can be made through the fastening holes 54 (shown in Figure 5) of the base part 12, for example with screws or bolts.

According to one embodiment, the fire protection duct may be 400 mm wide, 120 mm high and 2000 mm long. The dimensions of the fire duct may vary considerably depending on the application.

Fig. 2 shows an open fire protection duct 10 according to an embodiment of the invention, with the lid portion 14 lifted off the base portion 12. The lid portion 14 can be secured to the base portion 12 parallel to the lid portions 34 by fastening means 44 . The fastening means 44 may be, for example, wood screws which are covered by the cover pins 46 because of the visual appearance of the fire protection duct. The outer shell 16 has holes 48 for fastening means 44. For carrying the electric cables, at least one support plate 24 having a support point 26 is superimposed on the bottom part 12 of the fire protection duct 10 at least on the plane part 32.

In the embodiment shown in Fig. 2, the base portion 12 has a plurality of separate support plates 24. In the long fire protection channels 10, the support plates 24 should be fastened at even intervals, e.g. 30-50 cm, depending on how firmly the electrical cables are to be secured. The carrier plates 24 may be, for example, 5-50 cm, preferably 10-25 cm long in length, but the length of the carrier plates may vary from application to application. Separate bracket plates allow electrical cables to be secured to the fire duct without a single shelf or support plane throughout the fire duct. In the embodiments of the fire protection duct shown in Figures 2, 4 and 5, the base part 12 further includes support partitions 40.

Figure 3 is a sectional view of a fire protection duct according to an embodiment of the invention. Both the base part 12 and the cover part 14 have a similar construction. Both include, for example, a galvanized sheet metal outer shell 16, which is substantially U-shaped. Insulating layer 20 is mounted inside outer casing 16 against its inner surface 18, which can be a uniform U-shaped structure or it can be made of separate planar parts 32 and edge parts 34 which are attached, for example, glued to each other. The insulating layer 20 can be glued to the outer shell and further fastened by means of props. The outer shell 16 is adapted to fold over the free side 36 of the edge portion 34 of the layer 20 in both the bottom portion 12 and the lid portion 14 and extend all the way to the inner surface 58 of the layer 20. Advantageously, the outer shells can be bent parallel to the body portion according to the second embodiment of Figure 6, whereby the heat propagation from the outside of the fire protection duct towards the interior of the fire protection duct is considerably hampered.

According to the invention, a second insulating layer 28 extending along the longitudinal direction of the fire protection duct 10 is arranged at the junctions 30 of the bottom part 12 and the cover part 14 to prevent heat leakage from the junctions 30 into the fire protection duct 10. The second insulating layers 28 are preferably secured to the edge portions 34 of the base 12, for example by means of gluing and screws. A second insulating layer 28 is arranged to cover the junction 30 of the base member 12 and the cover member over a longitudinal length of the entire fire protection duct 10. The insulating layers 20 and 28 are preferably non-flammable asbestos-free hard gypsum board. The insulating layer may also be made of other equivalent material which meets the fire safety regulations. The gypsum board may be 15 mm thick at the intersection of layer 20 and 13 mm at the other e intersection of layer 28. The thickness of the gypsum board may vary depending on the required fire protection performance. The water in the gypsum board absorbs heat and does not burn.

In addition to the second insulating layer 28, the junctions 30 may be protected by a separate fire seal, which may be mounted at the junctions 30 in the longitudinal direction, for example a refractory ceramic sealing strip. Such a sealing tape may be, for example, a sealing tape known as Keraband, which is a rubber adhesive and can withstand temperatures up to 1200Ό.

For the support of electrical cables, a U-shaped support plate 24 is also attached to the base portion, which is secured to the second insulating layers 28 in the direction of the peripheral parts 34. The carrier plate 24 can be secured to the insulating layers 20 and 28, for example by screws. The carrier plate 24 also partially supports the overall structure of the fire protection duct by pressing the second insulating layers 28 against the outer casing 16. The support plate 24 preferably comprises a plurality of cutting support points 26, to which the electrical cables 22 can be fastened, for example, by means of cable ties or similar fastening means. The support points 26 are preferably bulges in which the heels are raised above the level of the support carrier plate 24. Thus, the anchor points can be made without recesses in the insulating layer.

As illustrated, electrical cables may be attached to the carrier plate 24 with both the carrier portion 24 parallel to the planar portion 32 and the carrier portion 24 with the portions 34 thus providing a large amount of carrier so that the electrical cables 22 can be spaced apart. This allows the internal heat of the electric cables to dissipate effectively from the surfaces of the electric cables, making the electric cables less susceptible to overheating. The support plate can also be used to bundle electric cables, provided that their heating is not a problem. This will further enhance the space utilization of the fire protection duct. Preferably, the support points may be in the support plate, for example, in two transverse rows of the fire protection duct, as shown in Figure 8. The support positions of the rows alternate with each other so that adjacent electrical cables are preferably secured to support points on different rows.

Fig. 4 shows an embodiment of a fire protection duct with a carrier partition 40 in addition to the carrier plate 24. The carrier partition 40 may be e.g. a plate mounted in the middle of the planar part 32 of the fire protection channel 10, with additional carrier points 26. By this solution solution. The carrier partition may also be more than one in parallel, whereby the number of carrier points can be further increased. The carrier partitions 40 can also be secured to the insulating layer 20 by means of screws.

Figure 5 shows a fire protection duct according to an embodiment. The figure shows how the outer shell 16 turns the intersection over the free side 36 of the edge portion 34 of the layer 20. Preferably, the base portion 12 has an outer casing 16 bent over the free side 36, having fastening holes 50 for securing the cover portion, and a longitudinal groove 38 in the fire protection duct to prevent "topping" of the upper fastening members by a curved planar surface. The outer shell of the corresponding free side 36 of the lid portion may have oval openings for fastening means.

Fig. 6 shows a fire protection duct 10 according to another embodiment of the invention. The figure shows how the outer shell 16 of both the base portion 12 and the cover portion 14 extends all the way to the inner surface 58 of the housing portion 34. Preferably, the ends 64 of the outer casing 16 are bent in the direction of the side members 34, whereby the connection of the cover member 14 and the base member 12 from the point 30 is prevented from entering the fire protection duct 10. For bending the outer sheaths 16, the second insulating layers 28 preferably extend a distance from the cover portion 14, leaving an open space 62 for the ends 64 of the outer shell 16 between the cover portion 14 and the second insulating layer 28.

Preferably, the fire protection duct 10 according to the second embodiment of the invention further comprises a third dielectric layer 56 which is applied over the second dielectric layer 28 in parallel. The third insulating layer 56 extends from the base portion 12 to the cover portion 14, whereby it effectively insulates the electric cables from the heat coming from the junction 30. The third dielectric layer may be of the same material as the second dielectric layer 28. In addition, the dielectric layer 12 may have a second dielectric layer 28 'parallel to the planar portion 32, which in turn enhances the segregation of the siderel 12. Thus, wool which is lighter than gypsum board can be used as insulation in both the cover portion 14 and the planar portion 32 of the base portion 12. In addition, such a structure makes the fire duct as a whole more rigid, which facilitates their handling during transport and installation.

Figure 7 is an axonometric view of a fire protection duct 10 according to another embodiment. As shown, the carrier plates 24 of the fire protection duct 10 are preferably short pieces which are secured within the base portion 12 at even intervals over the entire dimension of the fire protection duct 10. One support plate 24 has a plurality of support points 26. Figure 8 shows a "det A" magnification of Figure 7. Preferably, both the third insulating layers 56 and the edge portions 34 extend to the same plane, whereby the cover portion to be mounted thereon rests firmly on them. The figure also shows the mounting holes 50 for piercing the outer shell 16 on the side parallel to the planar portion 32 of the mounting members 34, through which the cover member is screwed or secured to the base member 12. The mounting holes 50 are preferably made in the groove 38.

The fire protection duct according to the invention can be used in particular for different types of electric cables, but it is also suitable for water pipes or the like. The fire protection ducts between different spaces can be made modularly from different parts of the fire duct which are connected together. However, the basic construction of the fire duct is the same in all parts, only the dimensions and shapes can vary. The various shapes may be, for example, corner pieces and T-branches or the like. At the junctions of the individual parts of the fire duct, separate fire protection straps are added around the fire duct to protect the junctions. As an additional or alternative solution to the joints, an expandable fire protection agent may be used. In any case, the joints will be protected by at least one of the above alternatives.

The fire protection duct according to the invention is excellent in terms of space utilization for electrical cable installation. In addition, the fire protection duct is easy to open afterwards, making it easy to retrofit and repair electric cables. The fire duct is especially suited for indoor applications where a clean and intact exterior of the duct provides a first-class finish. Thus, the fire protection duct is also suitable for use in residential buildings. The fire protection duct according to the invention withstands a fire in which the outdoor temperature rises to 850 ° C for at least 30 minutes, during which time the internal temperature rise of the fire duct is less than 180 °.

Claims (6)

A fire protection conduit (10) for electrical cables (22) having a fire protection conduit (10) having a base portion (12) and a cover portion (14), the base portion (12) and cover portion (14) both having an outer shell (16) and said outer shell (16). 16) an insulating layer (20) arranged against the inner surface (18) for insulating the electrical cables (22) to be installed inside the fire protection duct (10), wherein at least the base part (12) comprises a plane part (32) 10) a retaining support plate (24) comprising a plurality of support points (26) for securing said electrical cables (22), characterized in that the fire protection channel (10) includes a second insulating layer (28) adapted to be mounted on the base (12) and cover part (14). ) at the junction (30) between the junction (30) to insulate the junction (30). A fire protection duct according to claim 1, wherein the outer shells of the base portion (12) and the cover portion (14) include inwardly flanged flanges (64) of the fire protection duct (10) at the junction (30). The fire protection duct according to any one of the preceding claims, wherein the at least one dielectric layer (20) is wool to lighten the fire duct (10). A fire protection duct according to any one of the preceding claims, wherein the flanges (64) are folded to terminate in a height direction of the fire protection duct (10). The fire protection duct according to claim 4, wherein an open space (62) for the ends (63) of the outer casings (16) remains open between said second insulating layer (28) and the insulating layer (14). A fire protection duct according to claim 4 or 5, wherein a second insulating layer (56) is provided on the second dielectric layer (28) for additional insulation of the electrical cables (22).