SE528794C2 - Snow trap for preventing thawing snow from falling off e.g. roof, designed to melt snow and ice so that it then drains away or evaporates - Google Patents

Abstract

The trap is designed to catch snow and ice and then melt it so that the water drains away or evaporates.

Description

25 30 528 794 The main object of the present invention is therefore primarily to solve said problems simply, economically, safely and efficiently.

Said object is achieved by means of a device according to the present invention, which is mainly characterized in that the construction in question is provided with an insulating surface such as ice etc. is intended to form a coating on and that said insulating surface has elements extending at an angle from the construction. which increases the surface of ice to form a coating on but which, seen from the surface of the construction in question, divides it into smaller surface portions and thereby reduces the risk of falling larger portions of formed ice, etc.

The invention is described below as a number of preferred embodiments, with reference to the accompanying drawings in which Fig. 1 shows a cross-sectional view of a bridge cable with enclosing ice fall protection, Fig. 2 shows said protection schematically, Fig. 3 shows a side view of said protection, Figs. Fig. 4 shows protection with barbs, Fig. 5-6 shows gutter protection, Figs. 7-10 show different examples of spacers with associated grid-shaped cover protection, Fig. 7 showing examples of application of extra insulation between a structure and a surface-mounted device, and Figs. 11-12 show a cross-sectional view and a perspective view, respectively, of a wire-enclosed icefall protection.

A device 1 for increasing safety against falling larger pieces of ice from raised structures 2, such as e.g. bridge cables 21, walls, roofs, bridges, and gutters 102 or other objects such as e.g. vehicles and parts thereof, e.g. vehicle canopies, trailers, cabins, etc. are according to the present invention arranged and intended to cover and surround the surface 10 of the structure 2 or the object which it is desired to be protected against coating and precipitation of frozen ice and / or snow, with a superimposed attachable insulating surface 3 of thermally insulating suitable material is arranged between the structure 2 and said surface A and / or device 1. The function of said insulating surface 3 / material 31 is to substantially delay the formation of ice coating. on surface A at temperatures around 0 ° C but at a lower temperature instead. When the temperature then drops below 0 ° C, a coating of ice is now obtained which freezes on the covering insulated surface 3, as ice would have done at a higher temperature directly on the structure 2 previously if it had not been covered or surrounded of an insulating surface. Ice should also mean hard-packed, hard-frozen snow or a combination of ice and snow.

You can then have the surfaces coated with e.g. foil to change the adhesion to the ice or to de-icing, e.g. metal foil, Teflon, paint, etc. and it is also possible to heat said surface in a known manner.

Said insulating surface 3 may have elements 4 extending at an angle from the construction 2, which are intended to increase the surface of the ice to adhere to and form a coating but which, seen against the surface of the construction in question, divide it into smaller surface portions, similar to ice-freezer compartments and thereby reduce the risk of falling larger batches of formed ice. These ice-freezer compartments form cells 5 whose walls can be inclined so that the opening 6 decreases in extent as far as its bottom 7. The ice is thereby retained effectively. Said element 4 can also have a plurality of angled barbs 8 extending from the elements 4. Said element 4 and barbs 8 increase the surface which ice can cause to freeze along. When said ice melts, the barbs 8 contribute to further increasing the ability to retain this ice at said element 4 without falling down. Outside and / or around the element 4 there is preferably one or more nets 9 or a similar fine-mesh grid which covers said construction 2 at least in the direction downwards 10 facing portions 11, and which is kept at a distance from the construction by means of suitable spacers. Said distances can, in addition to said fixed cell walls, be in the form of loose or in the construction 2, the element 4 and / or the net 9 fixed distances in the form of e.g. drops. These spacers with or without barbs and which are either loose or attached to the element 4 and / or the net 9 have, in addition to the ability to keep the said parts separate from each other through their height, also the ability to contribute to increasing the surface that ice freezes. while also holding the ice, not least thanks to the barbs 8.

The height of the distances from the surface insulation 3 of the structure should be at least 1/3 of the thickness of the expected ice coating. In this case, the distance between the insulation 3 and the net 9 also becomes 1/3 of the expected coating of ice. When or if the space between the insulation 3 and the net 9 is completely filled with ice somewhere, the coating of ice can continue to grow through the net 9 and further outside the net 9. In this case the net 9 forms a reinforcement for the ice which in addition to being frozen at the insulation ring and at the spacers 4 and / or cells 5 frozen in ice provided with or without barbs 8, also frozen in the net 9. Dimensioning and material in the net 9 as well as distance and mutual placement between the wires included in the net 9 are adapted so that the net 9 is strong enough to retain all the ice that is formed between the structure 2 and the net 9 and outside the net 9 without being deformed even if ice has released the tag from the insulation cells 5 or spacers 4, and not let through any ice without melted into water or water vapor. When, after a weather that has meant that the plant is covered with ice, the weather becomes milder with temperatures around 10 ° C or above, ice begins to melt from the outside and towards first the net 9 and then further towards the insulation 3. Because the insulation 3 is of some insulating material and / or coated between the intended surface to be protected and the insulation 3 with some insulating material, ice will release from the insulation 3 later than ice would have done if it had been frozen directly against the structure 2 and if this emitted, conducted or reflected heat. In addition, ice is frozen in cells 5 and / or spacers 4 or is held by barbs 8 emanating from cells 5 and / or spacers 4. If or when ice detaches from the insulation 3, cells 5 and / or spacers 4 or the barbs 8 which may starting from these, ice is still reinforced in the net 9 or surrounded by the net 9 and can therefore not fall down but melt into water and water vapor between the insulation 3 and the net 9.

Below is an overall picture of the invention.

The surface to be protected against ice coating is surrounded by and covered with a new to some extent insulating surface on which ice can form a coating. Said surface is coated with an insulating layer between the structure 2 and the insulation 3.

On the insulation 3 there are attached cells of the honeycomb type or other shape, e.g. angles, triangles, squares, pentagons, longitudinal and / or transverse rulers, etc. extending from the insulation 3 and thus increasing the surface at which ice can freeze.

The above-mentioned cells may be smooth or provided with barbs, which when ice or hard-frozen snow or a combination thereof melts help to retain ice against the surface of the insulation 3 and / or against the surfaces of cells without letting go and falling down.

A net 9 can be arranged on the outside and / or around these cells 5, and these cells 5 thereby keep the net 9 separate from the insulation 3 by the distance indicated by the height of the cells.

Loose distances of varying shape can be applied between the insulation 3 and the net 9, for example angles, triangles, squares, pentagons, etc. along and / or transverse rulers, cylinders, cones, pyramids, cubes, etc. to keep the insulation 3 and the net 9 separate at the desired distance.

On the insulation 3, distances of the above shape and appearance can be attached and / or molded in, which keep the insulation 3 and the net 9 separated at the desired distance.

The net 9 can be attached and / or cast-in spacers of the above shape and appearance which keep the insulation 3 and the net 9 separated at the desired distance.

The net 9 can surround or cover the insulation 3, alternatively the net 9 with its spacers can be used independently to in some cases directly surround or cover the structure 2.

The components insulation 3, the net 9 and the cells 5 and / or spacers 4 can also form a homogeneous unit which is specially designed to surround or cover the structure 2 and / or be composed of a number of homogeneous units which interconnect surround or cover the structure. 2.

It can also be designed as a soft homogeneous unit which can be formed directly against or around the construction 2 in question and cover it.

The task of cells 5 and spacers 4 is to increase the surface that ice can freeze against and to keep the insulation 3 and the net 9 separate at the previously determined distance, which should be about 1/3 of the thickness of the expected coating of ice.

When any part of the space between the net 9 and the insulation 3 has been completely filled with ice, the coating of ice can continue to grow through the net 9 and further outside the net 9.

In this case, the net 9 forms a root attachment and a reinforcement for ice which, in addition to being frozen in the insulation 3 and / or cells 5 and / or spacers 4, is now also frozen in the net 9 and reinforced by the net 9. .

Dimensioning and material in the net 9 are calculated so that the net 9 can withstand the expected amount of ice between the insulation 3 and the net 9 and coating outside the net 9 without breaking or deforming even if ice would completely release from the insulation 3 the cells 5 or the distances 4 and the barbs 8.

The distances between the tubes-strands-strands-bands included in the net 9 and the mutual placement between them must be designed so that they form a pattern of grids and / or nets, through which wet snow, snow, sub-cooled rain, rain, melt water, cold water can easily reach the surface of the insulation 3 and / or the cells 5 and / or the distances 4 and in the area between the insulation 3 and the net 9 the ice forms a coating which can fill this space but also grow through the net 9 and outside the net 9, the net 9 reinforces and retains ice even if it is released at the insulation 3 and / or the cells 5 and / or the spacers 4. Said nets or fine-mesh grids may be arranged to be formed by a plurality of smaller sections, which are assembled together into a continuous larger net or GRID.

When ice melts, the net 9 is designed so that only very small fractions of ice could pass through the net 9 without first melting into water or water vapor.

Because the insulation 3 is of a partially insulating nature or coated with an insulating layer between the structure 2 and the insulation 3, ice melts from outside and into first the net 9 and then the insulation 3 and does not release the grip from the insulation 3 as easily as it could from the structure 2 if the structure 2 emits, conducts or reflects heat from below against ice. Therefore, ice does not detach as easily from the insulation ring and falls down. In addition, this is hindered by the surrounding or covering network 9 and / or barbs 8 on the cells 5 and / or the spacers 4.

In addition to being frozen on the insulation 3, ice is frozen on cells and / or spacers and / or is held by cells and / or spacers from barbs which hold ice firmly and prevent it from falling down and can be surrounded by the net 9 as extra security.

The drawings show in Figs. 11 and 12 examples of application of a device 1 to a suspended bridge cable 2 with an enclosing mains basket 9 and spacers 4 in the form of longitudinal ridges and / or triangles distributed along the surface extension of said cable 2a in longitudinal direction and / or transversely. Said spacers may be cone-shaped and have a plurality of barbs 8 along their sides. Ice and / or hard-frozen snow is effectively retained with said embodiments and functions according to the principle of the invention is retained in the air formed in as stated above, where the ice etc. the cells 5. The insulation can then consist of e.g. said distances 4.

At e.g. application of the net 9 with fixed cells and / or spacers around a gutter, part of the net 9 can be without cells and / or spacers and continue over the gutter further up under the roof covering and fastened there. Then, in addition to preventing leaves and foreign objects from ending up in the gutter, it also constitutes an extra security against the construction 2, the insulation 3 and the net 9 together with the ice coating would loosen from their mounts by their own weight or the mounts would come loose from the attachment points and fall down.

A device 1 for preventing precipitation of larger portions of ice and the like from raised constructions 2, as stated above, comprises a protection 9 lying on the surface of said construction 2 which is applied by fastening with e.g. screw, glue, fasteners or by enclosing the construction 2 in question. Said protection is formed by a net 9, grid or some similar permeable surface and that said protection 9 is arranged to be kept at a distance from said construction 2 by means of spacers 4 which also form insulation against the construction 2. Said protection 9 is arranged to retain larger portions of ice formed but allow melt water to pass through when the ice melts at higher temperatures.

In Fig. 5 it is shown that spacers 104 and nets 109 are arranged externally about the underside 150 of a gutter, the net 109 being arranged to be attached to the roof 151 of the housing and extending along the upper part 152 of the gutter and preferably formed into an upwardly formed snow cover, and attached to the roof batten 153 under the roof tiles 154.

Fig. 6 shows hanging nets 209 which are attached to the gutter 202 and which are arranged to form reinforcement for ice which is formed at the gutter 202.

Finally, Fig. 1 shows how a two-part to the circumferential shape of the construction in question, e.g. bridging wires fitting insulating parts with enclosing nets 9 are arranged connectable and by means of screws or other fastening means are arranged to form an enclosing insulating cage, and an insulating covering layer 3 of insulating material is arranged to form a core for the protection.

Claims (9)

10 15 20 25 30 528 7ø4 10O Patent claims 1. l. Device (l) for increasing safety against falling larger pieces of ice or frozen snow or a combination thereof from elevated structures (2), such as t-eX bridge cables, walls, roofs, bridges and gutters or other objects such as for example vehicles and parts thereof, characterized in that the construction (2) in question is provided with an insulating surface (3) such as ice, etc. is intended to form a coating on and that said insulating surface (3) has an angle from the construction (2). stretching elements (4) which increase the surface of ice to form a coating on but which, seen from the surface of the construction in question, divide it into smaller surface portions and thereby reduce the risk of falling larger portions of formed ice, etc. Device according to claim 1, characterized in that said protection (1) is surface-divided into cells (5) with a circumferential circumferential shape. Device according to claim 2, characterized in that the shape of said cells (5) is similar to honeycomb shape with from triangular circumferential shape to polygonal circumferential shape. Device according to one of Claims 2 to 3, characterized in that said cells (5) have a reduced circumferential shape seen in the direction of said construction (2) and / or in that at least outer portions of the cells have angled barbs (8). . 10 15 20 25 30 528 794 ll Device according to one of the preceding claims, characterized in that a net or similar fine-mesh grid covers said construction at least inwardly facing (10) directions. Device (1) for preventing the fall of large portions of ice or frozen snow or a combination thereof and the like from raised structures (2) Such as t-eX bridge cables, walls, roofs, bridges and gutters, or other objects such as e.g. vehicles and parts thereof, characterized in that a surface protection (9) is applied to the surface in question which larger portions of ice etc. are intended to prevent from falling off, said protection (9) being formed by a net, grid or similar permeable surface , that said protection (9) is arranged to be kept at a distance from said construction (2) by means of elements (4) extending at an angle from the construction (2) which form insulation, and that said protection (9) is arranged to retain larger batches of ice formed etc. but allow melt water to pass through when the ice etc. melts. Device according to claim 6, characterized in that spacers (104) and nets (109) are arranged externally if the underside of a gutter is attached (150), the net (109) to the roof (151) extending along the upper part (152) of the gutter. and is preferably formed into an upright formed snow cover. 528 ÉIÉ / Uš- 12 Device according to claim 6, characterized in that a two-part to the circumferential shape of the construction in question, e.g. bridge wires fitting insulating parts with enclosing nets are arranged connectable to form an enclosing insulating cage. Device according to one of Claims 6 to 8, characterized in that an insulating covering layer (3) of insulating material is arranged to form a core for the cover (1).