FI80670C - UPPVAERMANDE BELAEGGNINGSTRUKTUR OCH -ELEMENT. - Google Patents

Description

1 80670 Heated cladding structure and element

The invention relates to a heating coating structure for construction, the heating layer of which comprises a binder, a aggregate and possibly other additives, including an electric heating resistor. The invention also relates to a heating element having such a structure and its use e.g. as a chassis structure for heavy and light traffic.

As construction increasingly shifts to internal or backward heating of the structure surface, a new type of construction material is also needed that receives the heat given off by the heating equipment and stores or passes it on as desired. Previous heating main construction structures have not taken these problems into account too much, but the mechanical properties, tightness and thermal insulation of these products have been considered the most important properties.

Thus, the building information foundation publication RT 30-10342 discloses stone-paved subfloor structures, one layer of which contains heating cables. The structure consists, starting from the top surface, of a stone pavement with joint mortars, a layer of adhesive mortar, a layer of fixing mortar, a sliding surface or moisture insulation, and a thick reinforced concrete slab placed before thermal insulation, into which any heating cables are embedded. However, such a structure is unsuitable for underfloor heating because the thermal conductivity of the concrete used in it is only about 0.9 W / mK, which is not sufficient for efficient heat transfer from the resistor to the floor or substrate surface.

Our previous FI patent application 874 461 discloses a heat-storing screed and a floor structure made of it, the essential part of which consists of soapstone powder.

Our FI patent application 880 058 discloses a heat-storing 2,80670 and leveling stone, slab, element or screed for construction, the aggregate part of which consists on the one hand of soapstone and / or magnesite material and on the other hand of a material substantially harder than these stones.

We have now found that the magnesite material mentioned in these previous applications is perfectly suited for a heating, building cladding structure, the heating layer of which has an electric heating advantage. The invention is thus essentially characterized by what is stated in the preamble of the claims. Thus, it has been realized that the heating efficiency of a coating structure with a heating resistor increases decisively if the heating material of the heating layer contains a well-heat-equalizing and heat-storing magnetite. In addition to a heat-equalizing and charge-accumulating aggregate, a substantially harder aggregate, such as, for example, quartz sand, may also be included in said aggregate in order to improve the workability and strength of the structural material.

Depending on the desired properties, the heating layer of the heating coating structure may contain about 5-50, preferably 5-30% by weight of a binder, which is preferably cement. The amount of magnesite is 10-90, preferably 20-70% by weight of the total amount of material in the heating layer. A substantially harder aggregate, such as sand, which retains its mechanical properties, may be present in an amount of 10 to 90% by weight, preferably 30 to 80% by weight, of the total amount of material in the heating layer. If the binder is cement, about 2-60, preferably 2-40% by weight of water may be added.

A suitable type of magnesite is, for example, magnesite I and magnesite II (both MgCOg) based on the by-product of talc production. Such magnesite is obtained e.g. As a by-product of Myllykoski Oy's <Luikonlahti) talc production. The poor properties of magnesite are its softness and the effect of slowing down the hardening and hardening of concrete, which makes it difficult to use them as aggregate.

Important properties for the invention are the density, specific heat and thermal conductivity of the magnesite. Magnesite has approximately the same properties as soapstone, with a specific heat range of 0.9 to 1.1 kJ / kg C, when conventionally

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rocks usually have about 0.84 kJ / kg C. When the volumetric weight of soapstone, 2.98 kg / dm, is also greater than the volumetric weight of other rock types (2.4-2.9 kg / dm), its heat capacity per unit volume is up to about 30% higher than for other stone materials. The thermal conductivity is about 6.4 W / mK, which is about twice that of other stone materials.

The product according to a preferred embodiment of the invention contains magnesite and a substantially harder aggregate such as quartz sand in such a ratio that the thermal conductivity of said layer is at least between 1-5 W / mK, preferably between at least 2-4 W / mK.

The structure according to the invention may be in the form of a filler, stones or tiles, but preferably it consists of prefabricated elements inside which one or more heating elements pass. The elements preferably have, in addition to the heating layer, a surface layer on the heating side and possibly a thermal insulation layer on the non-heating side. The surface layer is preferably a natural stone or ceramic tile, which e.g. consists of several flat tiles sealed to each other with a waterproof sealant. The thermal insulation layer is, for example, foam, preferably polystyrene.

It is a good idea to provide the elements with plugs that can be connected to the power supply line for heating and removed from it when replacing or removing the elements.

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The elements can be used for both indoor and outdoor paving and upholstery. Indoor applications include heating floors, thermal walls, thermal ceilings and thermal stairs. However, it is most advantageous to use elements for the tile tiling of self-supporting outdoor spaces. In this case, they can be placed in a row substantially parallel to the power supply line and connected to the power supply line, preferably in parallel.

When a self-melting pavement, pedestrian street, car or train stop, etc. is formed, melt water is easily formed. The problem caused by this can be solved by placing the rows of heated elements with the power supply lines substantially parallel to planes which tilt so that the melt water flows into the gutters and / or sewer pipes embedded in the intersections of the heating surfaces, which are preferably heated by electrically connected resistors. The dimensions of the elements serving as the base structure for light traffic are, for example, of the order of about 600x1200x200 mm.

The structural elements according to the invention can also be used for the production of self-melting stairs, so that the heating elements form the steps of the stairs, whereby they are connected to the power supply lines running parallel to the stairs and next to the stairs. Such thermal steps are attached to a pre-cast concrete scaffold with a mortar. The dimensions of the thermal step stages are, for example, in the order of 300x600x200 mm.

The invention will now be described in more detail with reference to the figures, in which Figure 1 shows a heating building structure according to an embodiment of the invention, Figure 2 shows the manufacture of a natural stone element and a ceramic tile element according to the invention in a prefabricated factory, Fig. 5 shows the elements installed in a light traffic substructure. installing the structural elements according to the invention so that the melt water or rainwater is directed to the sewer, Fig. 5 shows a step assembled from thermal step elements.

According to an embodiment of the heating construction structure according to the invention, shown in Figure 1, the surface of the structure has tiles 1, which are preferably of natural stone or ceramic tile. The tiles are sealed to each other with a waterproof sealant 2. Under the tiles there is a heating layer 3 acting as a heating layer, which is a material consisting of a binder, aggregate and possibly other additives, a substantial part of In addition to a heat-equalizing and charge-accumulating aggregate, the thermal paving 3 preferably also contains a substantially harder aggregate, such as, for example, quartz sand. An electric heating resistor 4 is embedded in the thermal filler 3, which is preferably connected to a steel mesh or reinforcement reinforcing the element about 2 cm from the insulation. Below the thermal leveler 3 there is still an insulating layer 5, which is e.g. cellular plastic, preferably cellular polystyrene with a density of at least 25 kg / m 2. Such an insulating layer prevents heat conduction into the structures below the element, acts as a dampener and stabilizer for dynamic vibration, shock and load caused by traffic, and acts as a protective and reinforcing part of the element.

Figure 2 shows two different methods of manufacturing the elements. The left shows the production of a natural stone element in which natural stones 1 are placed on the bottom of the mold and waterproof sealant 2 is added between them. The mold is then filled to a level corresponding to the desired thickness of the leveling compound 3 with a wet leveling compound reinforcement is arranged substantially horizontally in the middle of the heat screed layer. Finally, a thermal insulation layer 5 is placed on the thermal filler 3, which is preferably a cellular polystyrene-like foam.

The right side of Figure 2 shows the factory manufacture of the ceramic tile element. In it, the thermal insulation layer 5 is placed on the bottom of the mold, after which the thermal filler 3 with thermal resistors 4 and possibly steel mesh or reinforcements is introduced into the mold and finally ceramic tiles 1 are placed on the thermal filler 3 so that a waterproof sealant 2 is placed between the tiles.

In the elements shown in Fig. 2, the heating resistor 4 is connected to a plug 6, through which electricity can be conducted from the power supply line to the heating resistor 4.

The thickness of the elements is preferably 100-300 mm. Preferred elements have a width of the order of 600 mm and a length of either the same order of magnitude as the width or of the order of about 2,200 mm. Thus, a 600x600 mm element will weigh about 2,100 kg / piece and a 600x1200 mm element about 200 kg / piece.

It is advantageous to install the elements mechanically as shown in Fig. 3 as a light traffic base structure so that the heating elements are arranged in a line substantially parallel to the power supply line 7 and connected to these supply lines by short wires and plugs 6. It is advantageous to place the heating elements as shown in Figure 3. The planes can be tilted, for example, from the middle upwards so that the melt water flows into the troughs jotka, which are heated by an electrical resistor 9 connected in the same connection.

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Figure 4 shows the discharge of rainwater into the sewer pipe 8 by means of a tilted substructure formed of elements according to the invention. The figure also shows how the base structure can be connected to e.g. a lamp post 10 and equipped with a night-time electrical switch 11.

Figure 5 shows a top view of a thermal step element, a front view of an element of the same type and a side sectional view of the steps in which the steps consist of said thermal step elements. The elements are similar to other light traffic chassis structures, i.e. they consist of slab layer 1, thermal screed thermal resistance layer 3 and 4, and 1 thermal insulation layer 5. The elements are connected to the power supply line 7 via a single cable and plug 6.

The thermal step elements are attached to the step-shaped concrete base 13 by means of a fixing mortar 12. The power supply line 7 or lines run parallel to and next to the steps. The melt water either evaporates from the surface of the elements as indicated by the arrows or drains into a drain arranged below the stairs.

In particular, the present invention seeks to partially replace or facilitate winter snow work in difficult plowing areas. In winter, the heating can be arranged so that it only works, for example, during snowfall and / or using night electricity. In this case, the costs become relatively small compared to the high labor and equipment costs required by the winter maintenance readiness of both heavy and light traffic.

Claims (11)

1 · Heating coating structure intended for building, heat heating layer <3) (binder, bamboo material and possibly other type of material1) contains an electrically heated heating element (4), characterized in that a substantial portion of the bore material is extracted, accumulates warm. 2. A structure according to claim 1, characterized in that said base material, in addition to said attenuate material, which evenly equalizes and accumulates heat, furthermore contains a substantial hardener ethylene material such as e.g. kvarteaand. Structure according to claim 1 or 2, characterized in that the heat-resistant adhesive consists of cement, which is about 5-50, preferably about 5-30% of the total weight of said material. 4. A structure as claimed in any one of claims 1, 2 or 3, characterized in that it is in the form of a leveling element, ethylene, plate or representative sheet in the form of pre-produced elements. Structure according to claim 4, characterized in that it is in the form of pre-produced heating elements, except in addition to the heating layer <3> on the heating aid a surface layer (1, 2) and the non-heating aid have a heat-oiling layer if required. <5). 6. A structure as claimed in claim 5, characterized in that the surface layer of the heating elements is made of natural or ceramic plate coating, preferably of several plate plates (1), which is substantially smaller than the element and of a mating surface at each other. dense sealant material (2), and that heat insulation layer (5>, where appropriate, beetled by ecumplate, preferably of the polystyrene. II 11 80670 Structure according to claim 5 or 6, characterized in that the element is provided with wires and / or ethical contacts (6), which can be coupled to a β1β1111 (7) for heating and when switching or removing elements is also released. from this one. Structure according to claim 5, 6 or 7, characterized in that the elements dimene ions are of the order of approx. 600x1200x200 mm. Use of a structure as claimed in any one of claims 5-8, or in support, in that the heating elements are arranged in substantially parallel rows and provided with the element (7), preferably parallel to the heating element (7). Use according to Claim 9, characterized in that a non-paintworking driveway, pavement, gangway, car or tubular plate, etc. formed by arranging the heating element rows of the heating elements with associated til1 conductor lines <7) parallel to the pane, which is inclined, that the emelting water flows down into gutters or drains <8>, by heating the means connected to the electric eye end (9) . Use according to claim 9, characterized in that non-melting stairs are formed or that the heating elements form the stairs stsg, whereby they are coupled in the direction of the stairs and adjacent to the stairs running supply lines C 7>.