DE1459733B2 - Electric underfloor storage heater - Google Patents

Description

The invention relates to an electric floor storage heating device that can be assembled from prefabricated components, consisting of layers arranged one above the other, namely a thermal insulation layer, a heating layer, a storage layer and a top layer forming the floor.

Electric underfloor storage heating devices of the type mentioned (magazine Elektrowärme 1963, Booklet 4, p. 181), gradually indicate the stored heat generated by the heat conductors below the room. Underfloor storage heating comes closest to ideal heating. The memory of this Heaters can be made of concrete or other solid materials that are used for heat storage suitable. With all materials, the storage temperature drops after a certain period of heat emission off, concrete reaches this point in time after about 6 hours. With all such memories must therefore need to be reheated in good time, otherwise their heat emission will not be sufficient for a daily routine. These storage heaters require additional heating if they are not reheated in time, they are therefore only imperfect and can be described as half storage heaters. Join it These storage heaters also generate room temperatures that are too high when the outside temperature rises. In particular in the event of unforeseen exposure to the sun, the room temperature rises due to the additional Heat emission of the underfloor storage heating is unbearable, so that staying in the room is only possible is when windows and doors are opened to cool off. The heat output of the storage heater cannot be throttled. As a result, the efficiency is reduced and electrical energy is insufficient exploited.

Also known is an electric heat storage furnace (Austrian patent 162 505), the one provides a heat-storing layer and a heat-conducting layer facing the room to be heated. The two layers are separated from one another by a heat-insulating separating layer. Included the layers contain channels through which air flows in such a way that heat is emitted from the storage layer is removed and released to the top layer, the air being circulated. The disadvantages the individual furnace heating are known. Apart from the space required, which affects the living space, it has the property that it is cold on the ground on the feet and warm on the top of the head. Close to the furnace the room is overheated while the window is cold. With a room height of 2.7 m with individual stove heating the temperature is 16 ° C on the floor and 25 ° C on the ceiling. With underfloor heating on the other hand Bottom 24 ° C and above 17 ° C. Due to the required high heating of the storage tank in such a case electric heat storage furnace gives this even with closed closing organs, no longer adjustable, its heat because the thermal insulation is insufficient or is too large would have to. Disadvantages such as overheating, unnecessary power consumption and high electricity costs are then the Episode.

The invention is based on the object of an electric floor storage heater of the aforementioned To train the species so that the heat on the one hand, without noticeably decreasing, longer Time saved and, on the other hand, can be given to the room to be heated if required, whereby In addition, the heating device can be used for direct heating. '>

According to the invention, this object is to be achieved in that the cover layer is thermally conductive is formed and a heat-impermeable separating layer is formed between the storage layer and the cover layer is arranged and that both in the storage layer and in the cover layer channels for a flowing heat transfer medium are admitted and connected to one another in such a way that the heat transfer medium by a conveyor device from the channels of the storage layer to the channels of the cover layer and can be funded back again.

The invention is explained in more detail using an exemplary embodiment in the drawings. It shows F i g. 1 an artificial stone slab with channels for air as a heat transfer medium and the heating panel underneath with heating conductor,

Fig. 2 is one provided with lower channels Layer of artificial stone seen from below,

F i g. 3 a layer of the artificial stone slab provided with high channels seen from below,

F i g. 4 a light metal intermediate foil to be folded down sideways as a separating layer, also seen from below,

F i g. 5 the joint of two artificial stone slabs, with lower channels meeting high channels,

3 4

F i g. 6 how at the joint of two artificial stone slabs serving as a conveyor 5 fan or Components a nozzle-like section for the air cross-flow fan generated air flow in the art mix forms, stone slabs is possible in different ways:

F i g. 7 four plate shapes of artificial stone plates Either it flows, supported by the suction

and 5 the conveyor 5, upper air over the part

8 shows a laying arrangement with the four platform area m back to the lower air, with transverse

ten forms according to FIG. 7 and a fan as lowering ducts allow air to circulate next to each other.

Conveyor. distribute the artificial stone slabs,

In the case of the in FIG. 1 are artificial stone slab or upper air flows in the same direction as

the following individual layers exist: io lower air over the sub-area m further and the

a top layer α made of artificial stone with lower | ^an ^ ^{e air} moves in a circle to the sucking air

Channels k conveyor 5 back. Transverse canals

a storage layer b made of artificial stone with high effect the air circulation even with meandering

Channels / laid artificial stone slabs.

a light metal foil as a separating layer c with ¹⁵ _T , ⁱⁿ some systems you can also let liquid circulate in a tight, heat-impermeable layer, channels. If, behind the heating conductor, the artificial stone plates lying on top of each other, a rolled light metal ^foil e ^{butted together, would have slightly high layers} , then there would be a light metal foil glued on it /, S ^? ^Γ · L / ^{uf the} overlying a Bodenisolierfolie g ^ S ^50111111 and ^{20 Flat no} heat discharge takes,
the grooved with the light metal film e and g ^heaters for floor heating Instant-Bodenisolierfolie connected dazwischenlie- removal of heat is heater boards, "h end rigid foam layer." on both ■ ^en heat conductor d enclosing Leichtmetallfolieri e ° 'and /, z. B. by plastic stone, against mechanical According to FIG. 5 meet at the joint of two artificial stone 25 damage are protected. The connection lightweight panels each lower channels k to high channels /. metal-plastic stone is by a suitable binding-The left plate according to FIG. 5 is made of the panel according to medium, such as PVC. The same as on the lower Fig. 1. In the right plate according to FIG. 5 light metal foil, ie the floor insulation g, the artificial stone plate part with lower channels k glued plastic stone can be used for thermal insulation below as a storage layer and the artificial stone plate 30 z. B. fireclay powder and asbestos fibers (if used outdoors with high channels / as a top layer) or z. B. Rigid foam in pearls, form (when used in closed spaces) The in F i g. 7 shown four plate shapes 1, 2 are added. Allow the on the upper light metal 3, 4 of artificial stone plates, the plates also foil, ie the separating layer c, to put glued plastic over a corner so that the hot air stone can stream to improve the thermal conductivity, for. B. can be performed in a meander shape. Light metal can be added. Use outdoors. Quarry tile finished radiator shown 1 and 5, for the protection against the Einhaben in two superimposed layers α penetration of foreign bodies in the latticed heating conductor and b, which are pasted through the intervening separating manner with plastic stone,
layer c made of light metal with heat-impermeable 40 ■. ., ".._". , ",". ,,.
Edition are separated, lengthways and crossways in both examples for underfloor full storage heating

Layers of concurrent channels k and I with air as a radiator with a total of 20 kWh of connection ^ _- heat transfer medium. The upper layer is thermally conductive, the one with a covering of 60X30 cm, at the same time ^ the lower one stores heat. Both layers change the screed-forming artificial stone slabs with 140 mm 'in the height of their channels k and / at the collision 45 total conversion height, covers the concrete floor, on slab components lying one behind the other, and one which is a prefabricated house with a basement artificially created ^{with 100 m 2} here there is a dividing air flow in living space. The prefabricated inner walls with doors and the channels k and / ensures that they are attached to supports and stand on the artificial stone upper and lower layers of air mix and the panels without air channels.

The temperature of one equals that of the other. 5 ° Under the floor intended for furniture - Without the artificially generated air flow, the surface forms the storage layer of the artificial stone lower layer from the heat emission, because the plates form a closed ceiling and prevent the overall cross-section of the ducts as a result of the under-heat discharge on these surfaces. A in the difference current altitude of the layers and the built of lightweight cellar wall fan with small motor metal - except one, in amount of from to 55 generates weak air circulating in the channels of overlapping air ducts portion formed m lining to which it is connected with air ducts slot installed for air circulation - is entirely. A heat-storing layer surrounded by artificial stone slabs and walls. Air shafts, to be opened if necessary, lead to a smaller amount of the slabs and stored ventilators to air systems in the rooms.
Therefore only a small amount of warm air enters the 60s.
Channels can arrive. Example of underfloor heating for immediate heating

The fact that the artificial stone plates are placed together on the upper plastic stone layer of the radiator

sticks, the heat of the upper layer can persist is a known fabric made of artificial

Do not spread to the sides, neither fabric tubes nor sisal hemp can be glued on. It educates

Air from ducts k and / escape, nor from 65 a heatable carpet that covers the whole cold,

penetrate outside. Minor leaks of the damp, covered floor, is elastic and self

Channels k and / do not harm, wear on the contrary to adapt to the unevenness of the floor,

their dehumidification. The mixing of the heating panels of the heating

body can be switched individually and spread the generated heat over the entire surface of the radiator. They serve as full or replacement underfloor heating. The flexible plastic tubes of the Carpets protect against the ingress of foreign bodies, while the plastic stone prevents penetration from Z. B. prevents pointed heels. With the help of the "heatable carpet" sound, Insulates heat and cold and insulates moisture.

Floor heating systems for immediate heating are also suitable for subsequent heating because of their flat design Suitable for outdoor installation and heats large areas controllably, according to the outside temperature.

The radiator consists of large heating panels and non-heatable, cut-up, otherwise identical connection panels, which cover the floor of the object to be heated and form a closed, evenly heat-emitting surface. In the glued-together of two light metal (. As aluminum z) e sheets and / existing heater boards is a - known per se ■ - moisture resistant, insulated heating conductor d as a closed circuit on or laid multiphase. The heating panel completely encloses the heating conductor d and is connected to the earth of the supply cable. Insulated from the heating conductor, the foils are not under tension and protect them from heat build-up. Since only temperatures up to 80 ° C can be set, the heatsealing band d has a practically unlimited shelf life; it can also be regulated. For storage heaters, the radiator consists of heating and connection panels, which are also permanently attached to the underside, and an intermediate layer of sound and heat insulating, moisture-insulating plastic (e.g. PVC) foam for the floor.

1 sheet of drawings

Claims (4)

Patent claims: 1. Electric floor storage heating device that can be assembled from prefabricated components, consisting of layers arranged one above the other, namely a thermal insulation layer, a heating layer, a storage layer and a cover layer forming the floor, characterized in that the cover layer (α) is designed to be thermally conductive and between the storage layer ( ö) and the cover layer (α) a heat-impermeable separating layer (c) is arranged and that both in the storage layer (b) and in the cover layer (α) channels for a flowing heat carrier are let in and connected to one another in such a way that the heat carrier is through a Conveyor device (5) can be conveyed from the channels of the storage layer to the channels of the cover layer and back again. 2. Floor storage heating device according to claim 1, characterized in that the channels (k, Z) on the one hand in superimposed layers each of a component and on the other hand in layers of adjacent components lying at the same height have different heights, such that at the butt joint of two adjacent components the high duct parts lying in layers of different heights overlap in a partial area (m) of their cross-section. 3. Floor storage heating device according to claim 1 or 2, characterized in that the Separating layer (c) consists of light metal foil provided with a heat-impermeable layer. 4. Floor storage heating device according to one of claims 1 to 3, characterized in that that the heat carrier is air.