FI83453C - FOERFARANDE FOER BYGGANDE AV UNDERBYGGNAD FOER KONSTIS. - Google Patents

Description

83453 METHOD OF CONSTRUCTION OF ARTIFICIAL ICE STRUCTURE 1 The invention relates to a method of constructing artificial ice substructure, in which the form plates act as a mounting base for cooling pipes and as a casting or spreading base for a casting component such as concrete or the like.

As can be seen from the above, the present invention relates to a method of constructing an artificial ice structure, in which shaped plates made of steel sheet, other metal sheet or other material such as corrugated sheets, corrugated sheets, cassettes and the like serve as an ice as a casting or spreading medium for the required casting component such as concrete, asphalt, asphalt concrete, sand, gravel, rock ash or the like, whereby a suitably profiled form plate gives its pipes and casting component a reliable lower support and a suitably selected profile height, or in conjunction with cooling pipe mounting spacers, etc., determines a suitable height position, mutual distance for the pipes, eliminates mechanical and other stresses, makes it possible In addition to steel pipes, the use of cooling pipes made of plastic is also used, whereby the use of spacers or the like can also eliminate, if necessary, the risk of corrosion due to contact between the form plate and the cooling pipes. The anchoring of the pipes to the form plate can also be realized by stamping, cutting, etc. from the material of the form plate itself, making protrusions, tongues or other protrusions between which the pipes are installed and also using separate fastening means such as hooks, loops, glue, adhesive, etc.

It is preferable to provide the mold plate with a suitable gripping mechanism, whereby the mold plate acts simultaneously as a casting or application base (mold) and a reinforcement (reinforcement) of the casting component. Under certain conditions, it is advantageous to provide the shaped plates with routing so that water or moisture is passed through the plate to the moisture-permeable and / or absorbent layers below it. In addition, it is preferred that the material of the plate 30 be moisture and corrosion resistant or that the plate be coated with an anti-corrosion coating. It is further preferred that the material of the sheet is thermally conductive and / or reflective or that the sheet is coated with a layer reflecting heat radiation.

As an application example of the present invention, a solution is described in more detail in which the cooling pipes are supported on a corrugated sheet made of steel sheet with a gripping mechanism and the casting component is concrete, whereby the corrugated sheet simultaneously acts as a mold and reinforcement. Some embodiments of such corrugated sheets are known from Finnish patent No. 54006, but this is not limited to the said 2 83453 1 corrugated sheet, but in addition to the corrugated sheet it can be corrugated sheets, cassettes, etc. In addition, it can only be a shaped sheet without a gripping mechanism. in which the form plate acts with its own rigidity as a structure carrying concrete and loads or as a mere concrete casting mold.

5

The shaped plates can be provided with a lower thermal insulation, as described, for example, in Finnish Patent No. 61067, Finnish Patent Publication No. 61066 and in a separate application No. 841743. However, this is not limited to the solutions defined in said patents, but the heat-10 insulator may be free-form, made of any material and may be plate-like, fibrous, granular, crumbly, foamy, liquid, etc., and the insulation need not be attached to the form plate or is pre-attached to the form plate or, if necessary, is attached at a construction site, factory, etc.

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It should be emphasized in this connection that, although concrete is discussed above, the casting component may also be asphalt, asphalt concrete, sand, gravel, rock ash or the like, or some freezing liquid material which can be cast, applied or otherwise installed using molded plates as a casting substrate.

20 The installation direction of the cooling pipes can be chosen arbitrarily, as long as they are either directly or indirectly supported on the form plates.

Although the following will focus on the method of constructing an artificial ice rink, it is by no means limited to artificial ice rinks, but the method can be used in the construction of artificial ice rafts, ice roads, etc., and generally in locations where the use of artificial ice is justified.

In the base structure of the artificial ice rink, either J0f25 mm PEL plastic pipe or 017 mm -023 mm steel pipe is currently used as 30 cooling pipes cast in concrete.

The slab is normally cast to a thickness of about 120 mm in a single casting for the entire ice rink (for example, in the case of a hockey rink, the surface area of the slab is about 31 m x 61 m). If steel pipes are used on the track, a separate support structure will be built for them.

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The construction method of an artificial ice rink is usually as follows: A thermal insulation is installed on top of the leveled gravel or sand layer, on top of which a 30 mm thick non-reinforced concrete slab is poured, on which a so-called tukiterästapit. Thereafter, the reinforcement of the lower surface of the above-mentioned plate 120, about 120 mm thick, which is usually j6 8 k 100/150 mm, is installed. After reinforcement of the lower surface 3 83453 1, the so-called Π -shaped steel brackets for pipes welded to the above-mentioned support steel pins. Piping brackets are dimensioned to withstand the weight of the pipes and the stresses during casting. After the installation of the piping, a surface reinforcement of 0.8 k 100 / 150mm is installed on the pipes. Finally, 5 uniform concrete slabs of about 120 mm are cast, on which ice is formed.

When using plastic pipes, their tying and maintaining the height position has been proven e.g. very difficult during casting work. For this reason, a steel pipe is most often used in a concrete slab. The advantage of a steel pipe is better cold conductivity and 10 the disadvantage is the high cost of material and installation work. The most common is steel pipe material

Fe 35.8 and diameter 20 mm.

The object of the invention is to solve many of the problems currently encountered in the construction of a substructure. As can be seen from the above, the current methods of constructing an artificial ice rink sub-15 course are multi-stage, laborious and expensive. Two concrete castings have to be carried out, the installation of pipes requires a lot of man-hours, a lot of rebar is used, etc.

U.S. Patent No. 3,485,057 discloses a method of constructing artificial ice in which cooling pipes are supported on rails notched for the pipes. The method of constructing an ice rink substructure disclosed in the U.S. Patent Publication is essentially similar to that described above. The difference from the usual is that the notched rails replace the steel pins embedded in the base concrete and the steel profiles welded to them.

When the base structure of the artificial ice rink is made by the method according to the invention, the level of the upper surface of the profile of the shaped plates determines the height position of the cooling pipes, which e.g. the form plate-based spacers or similar fasteners can be easily adjusted. If the form plate stiffeners are about 100..300 mm apart, a plastic pipe can also be used as the cooling pipe due to dense support, or the inventive distance of the form plate stiffeners adjusts the distance between the pipes to suit, for example when the pipes are parallel to the plate stiffener. There is only one casting because no base slab is needed, so less concrete is used. If the form plate is sufficiently rigid or the form plate has an adhesion mechanism, the reinforcement of the lower surface may be omitted. When steel pipes are used, the pipes also act as reinforcement, in which case the surface reinforcement can be reduced or, in certain circumstances, it can be omitted altogether.

In order to achieve the above and later objects, the invention is mainly characterized in that in the method of building the artificial ice substructure 40, the cooling pipes are supported on form plates, which form plates serve as a casting or application base for the casting component. In addition, the invention is characterized in that the method is used e.g. for the construction of artificial ice rinks, artificial ice rafts and ice roads, and for the construction of heated outdoor tracks, such as sports fields or the like, as well as sports halls or similar subfloors, by replacing 5 cooling pipes with heating pipes.

In the following detailed description of the invention, the use of the invention in the construction of artificial ice rinks is shown by way of example with reference to some embodiments of the invention shown in the figures of the accompanying drawings, to which the invention is not intended to be narrowly limited.

The method can also be used in the construction of heated outdoor tracks such as sports fields or the like and indoor fields such as sports halls or the like by exchanging cooling pipes for heating pipes in which water or the like flows as a heating liquid.

Figure 1 shows a cross-sectional view of an application example of the invention in the construction of artificial ice rinks, in which the form plate is a corrugated plate disclosed in Finnish Patent No. 45006.

Figure 2 shows a cross-sectional view of an embodiment 20 of the invention for the construction of artificial ice rinks, where there is thermal insulation under the corrugated plate, on which the corrugated plate rests on a plane formed by the lower surface of the corrugated sheets.

Figure 3 shows a cross-sectional view of an application example of the invention in the construction of artificial ice rinks, where the upper surface 25 of the thermal insulation under the corrugated sheet is arranged in the form of corrugations.

In Fig. 1, a corrugated sheet (4) provided with a gripping mechanism (4a) is mounted on a leveling layer (2) made of sand, stone ash or the like, which leveling layer (2) is based on a coarser soil layer such as gravel, somer, etc. The cooling pipes (6) are mounted in a transverse position relative to the stiffening direction of the corrugated sheets (4) on spacers or the like (7) made of plastic or other material, whereby 35 known e.g. spacers used in the installation of reinforcing bars, etc. However, it is preferable to design the spacers or similar fasteners (7) so that they can be easily attached to the form plate such as the upper surface of the corrugated plate (4) by screwing, hitting, gluing or the like. The casting component (5), such as concrete, asphalt, asphalt concrete, etc., is cast or applied using form plates (4) as a substrate. The function of the surface reinforcement (8, 9) 40, for example of reinforcing steel meshes or bonded loose steels, is to prevent the cracking of the casting component (S) in order to eliminate the risk of corrosion, for example when ordinary so-called cooling pipes (6) are used. black steel pipes. The ice layer (10) is formed on the upper surface of the casting component (5) by means of a refrigerant passing through the cooling pipes (6) or when the casting component (5) is a freezing liquid material, the ice layer may already be formed of the casting component (5).

In Fig. 2, a corrugated sheet (4) provided with a gripping mechanism (4a) is mounted via a planar surface formed by its lower flanges on a thermal insulation layer (3) made of polystyrene, polyurethane, mineral fibers, wood fibers or the like. , foamy, liquid or the like, which insulator (3) rests on the layer (1) via the leveling layer (2). The figure further shows the spacers and the like.

(7) a cooling pipe (6), surface steels (8,9), a casting component (5) and an ice layer (10) mounted on the corrugated sheets (4).

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In Fig. (3), the corrugated sheet (4) provided with the gripping mechanism (4a) is mounted on all its lower surfaces on an insulating layer (3) made of polyurethane, polystyrene, mineral fibers, wood fibers, etc., adapted to the corrugated sheet (4), where the insulating layer (3) when installed, be 20 plate-like, crumbly, fibrous, granular, foamy, liquid, etc. The insulating layer (3) rests on the layer (1) via the leveling layer (2). The figure also shows a cooling pipe (6), surface steels (8,9) and an ice layer (10) mounted on the corrugated plates (4) by means of spacers or the like (7).

Claims (15)

1. A construction method for a support structure for artifacts in which the cooling pipes are supported, characterized in that the cooling pipes (6) are supported against mold discs (4), which mold discs (4) act as casting or spreading support for the casting component (5). . Method according to Claim 1, characterized in that a molding mechanism (4a) for engaging the molding component (5) has been provided in the molding discs (4). 3. A method according to claim 1 or 2, characterized in that the molding discs (4) and / or the spacers supported thereon, the fastening means so attached to them, the fastening means (7) made of the disc material itself, determine and maintain the height position of the cooling pipes. (6). 4. A method according to any one of claims 1-3, characterized in that the cooling pipes (6) are mounted in any direction relative to the direction of stiffening of the molding plates (4) and parallel to one another. Method according to any of claims 1-4, characterized in that the spacers, separate fasteners or tubers, tongues or other such projections (7) formed by the disc material itself maintain the mutual spacing between the cooling tubes (6). . 30 6. A method according to any of claims 1-5, characterized in that the molding discs (4) act as heat transferors and equalizers between the adjacent cooling pipes (6). 35 Process according to any of claims 1-6, characterized in that the molding sheets (4) are made of heat reflective material and / or are coated with heat reflective coating. Method according to any one of claims 1-7, characterized in that the molding sheets (4) are made of corrosion-resistant material and / or are coated against corrosion. 9. A method according to any one of claims 1-8, characterized in that cracking in the casting component (5) is counteracted by an additional reinforcement (8,9). 10. A method according to any one of claims 1-9, characterized in that a thermal insulation layer (3) is mounted under the molding sheets (6). 15 11. A method according to any one of claims 1-10, characterized in that hAl (11) has been made in the molding discs (4) for passing water through the molding discs (4). Use of the method according to any one of claims 1-11 for the construction of art tracks. Use of the method according to any one of claims 1-11 for building art floats. 25 Use of the method according to any one of claims 1-11 for building ice roads. Use of the method according to any one of claims 1-11 for building heated outdoor courts such as sports planes or equivalent and indoors such as sports halls or the like by replacing the cooling pipes with suitable heating pipes.