DE19625050A1 - Lightweight, and stable heat transfer sandwich board material - Google Patents

Abstract

The heat transfer board material comprises two plates (4,6) with a space between them, of a material with high thermal conductivity. The space between them is filled with a heat insulation material (8). The heat transfer pipes (10) are at least partially embedded in the insulation material (8), and are in heat transfer contact with the plate(s) (4,6). The plates (4, 6) are of metal e.g. zinc-plated and bake-painted steel sheet. The insulating material (8) is a polyurethane foam or a polyisocyanurate foam. The outer surface of the heated plate (4) is clad (12) with natural stone e.g. granite or marble, artificial bricks, ceramics, tiles, plastics or metal.

Description

The invention relates to a plate-shaped heat transfer support element.

The object of the present invention is a light, stable, simple in construction, easy to manufacture hard and versatile, self-supporting heat transfer to create a load-bearing element with minimized heat loss.

This object is achieved by the invention according to claim 1 solved.

Advantageous and expedient further developments of the inventions Appropriate task solution are in the subclaims give.

The plate-shaped heat according to the invention Transmission element is very simple in construction and therefore knockout inexpensive and easy to manufacture and thanks to the sandwich construction very stable and self-supporting. Through direct contact the heat transfer tubes with at least one of the two Highly arranged heat-conducting plates generate high heat transmission via this front or face Plate reached. On these preferably made of metal The plate can be clad with an adhesive for example made of natural stone, such as granite or marble Artificial stone, ceramics, tiles, plastic, metal etc., open are brought so that the heat transfer practically without Losses can occur through this cladding. By the heat insulation between the two panels will be effective  rear insulation to prevent heat loss enough. The plate-shaped heat transfer according to the invention support element is particularly suitable for use in Wall, floor and ceiling area as a cladding element and also as a separate radiator or heat sink. The heat transfer Support element can be practically any size you want getting produced. Multiple heat transfer elements can to form larger flat structures or complete cells be set. The heat transfer element according to the invention is stable and light in weight. It is easy processable and can be high at germicidal temperatures be heated.

The invention is based on in the case of attached drawing illustrated embodiments are explained.

It shows

Fig. 1 shows a first embodiment of a plate-shaped heat transfer element and

Fig. 2 shows a second embodiment of a plate-shaped heat transfer element.

Fig. 1 of the drawing shows a section through a plate-shaped heat transfer element 2 , the two spaced metal plates, for example sheet metal plates 4 and 6 , such as galvanized and stove-enamelled steel sheet plates, between which a thermal insulation 8 , for example made of polyurethane (PU) - or Polyisocyanorate (PIR) foam that is ordered.

In this heat insulation 8 heat transfer pipes 10 , for example hot water heating pipes or cooling pipes, are embedded so that they are essentially flush with the top of the pipe with the surface of the heat insulation and with the one, front or face arranged metal plate 4 are in heat transfer contact, for example by direct contact, and abge ben to the metal plate 4 , from which the heat is radiated into the room, or absorb heat via the metal plate 4 , dissipated via the heat from the room and thus the room is cooled. The thermal insulation serves as rear thermal insulation.

The visible or front side of the heat transfer element 2 can be provided with a cladding 12 , for example from a thin plate of natural stone, such as granite or marble, of artificial stone, ceramic, tiles, plastic, metal, etc. . The cladding is preferably connected by means of a heat transfer to the cladding non-adhesive 14 with the metal plates 4 , so that the heat radiation or heat absorption can take place practically without loss via the cladding 12 , which also allows a certain amount of heat storage depending on the material .

Such a panel 12 can also be provided on the back side gene metal plate 6 (not shown). Fer ner, it is possible to provide further in contact with the metal plate 6 , embedded in the heat insulation 8 heat transfer tubes (not shown) in order to obtain a heat-radiating element or a heat-absorbing element on both sides.

Fig. 2 shows a section through a plate-shaped heat transfer element 20 , which - like the heat transfer element 2 of FIG. 1 - has a self-supporting, plate-shaped sandwich element 22 which has a preferably high-pressure foamed, arranged between two metal sheets 24 , 26 core 28th made of foam material. The foam material is preferably polyurethane (PU) - or Polyi socyanorat (PIR) foam, the density of the foam preferably in the range from 420 to 450 N / m³, that is to say in the range from 42 to 45 kg / m³.

The metal sheet is preferably a galvanized and a stove-enamelled sheet steel.

The sandwich element 22 has, on the inside, in the sheet metal 24 and the foam core 28, for example, channels 30 machined by milling, into which heat transfer tubes 32 are inserted. The channels 30 are preferably only deep enough that the pipe crowns of the heat transfer pipes 32 to be embedded are flush with the outside of the plate 24 . On this side of the sandwich element 22 provided with the inserted tubes, a glass fiber fabric 34 is glued by means of temperature-resistant adhesive in order to restore the original stability of the sandwich element 22 reduced by the incorporation of the channels 30 .

The above-described design with the channels, heat transfer tubes and glass fiber fabric / adhesive coating 34 can be provided on both sides of the sandwich element 22 in order to obtain a heat transfer element on both sides.

The visible or front side of the heat transfer element 20 can be provided with a cladding 36 , for example from a thin plate of natural stone, such as gra nit or marble, of artificial stone, ceramic, tiles, plastic, metal, etc. . The panel 36 is preferably applied by means of a heat transfer to the panel non-obstructive adhesive 38 in the thin-bed adhesive process on the glass fiber fabric / adhesive layer 34 , so that the heat transfer can take place practically without loss via the panel. Depending on the material of the cladding, this can also allow a certain amount of heat to be stored.

If, as stated above, the formation with channels, heat transfer tubes and coating 34 is provided on both sides of the sandwich element 22 , such a cladding 36 can also be seen on the rear-side metal plate 26 (not shown).

The heat transfer elements 2 , 20 can be used to give off heat as heat radiation elements and heat absorbing as cold elements.

When used as a heat radiation element, the heat transmission tubes used as heating tubes and for example flowed through by heating water, and when used as cold element are the heat transfer tubes as cooling tubes from for example, cold water or a coolant flows.  

The heat transfer elements have a thickness of approx. 6 to 15 cm, depending on the requirement. You can, for example have a width of 35 or 70 cm and a height of 180 to Have 300 cm.

The heat transfer elements 2 , 20 can be assembled in a stable and self-supporting manner with the aid of foamed-in connecting elements, such as the eccentric hook closures known per se, into complete cells (heat or cold cells).

Claims (15)

1. Plate-shaped heat transfer element, characterized by

• - Two spaced plates ( 4 , 6 ; 24 , 26 ) made of a good heat-conducting material, between which a heat-insulating material ( 8 , 28 ) is arranged, and
• - Heat transfer tubes ( 10 , 32 ), which are at least partially embedded in the heat-insulating material ( 8 , 28 ) and are in heat transfer connection with at least one plate ( 4 , 24 ).

2. Plate-shaped heat transfer element according to claim 1, characterized in that the plates ( 4 , 6 ; 24 , 26 ) consist of metal. 3. Plate-shaped heat transfer element according to claim 1, characterized in that the heat insulating material ( 8 , 28 ) consists of a high pressure foamable material. 4. Plate-shaped heat transfer element according to claim 3, characterized in that the heat insulating material ( 8 , 28 ) consists of a polyurethane (PU) - or a polyisocyanorate (PIR) foam. 5. Plate-shaped heat transfer element according to claim 1, characterized in that the heat transfer tubes ( 10 ) are in direct contact with at least one of the plates ( 4 , 6 ). 6. Plate-shaped heat transfer element according to claim 1, characterized in that in the two plates ( 24 , 26 ) and the heat insulating material ( 28 ) arranged therebetween sandwich element ( 22 ) at least on one side channels ( 30 ) in the plate and heat isolate the material are formed, in which heat transfer tubes ( 32 ) are arranged. 7. Plate-shaped heat transfer element according to claim 6, characterized in that the heat transfer tubes ( 32 ) with their apex are flush with the outside of the plate ( 24 or 26 ). 8. Plate-shaped heat transfer element according to claim 6 or 7, characterized in that the sandwich element ( 22 ) on the side provided with the channels ( 30 ) and the heat transfer tubes ( 32 ) has a thin coating ( 34 ) made of a glued reinforcing fabric. 9. plate-shaped heat transfer element according to claim 8, characterized in that the reinforcing fabric glass fiber is weave. 10. Plate-shaped heat transfer element according to one of the preceding claims, characterized in that the heat transfer tubes ( 10 , 32 ) are flowed through by a heat-emitting medium heating tubes ( 10 ) or by a heat-absorbing medium flowing through cooling or cooling pipes ( 32 ). 11. Plate-shaped heat transfer element according to one of the preceding claims, characterized in that little least one of the sides of the heat transfer tubes ( 10 , 32 ) is provided on the outside or inside with a covering ( 12 , 36 ). 12. Plate-shaped heat transfer element according to claim 11, characterized in that the cladding ( 12 , 36 ) made of natural stone, such as granite or marble, made of artificial stone, ceramic, tiles, plastic or metal. 13. Plate-shaped heat transfer element according to claim 11 or 12, characterized in that the covering ( 12 ) on the plate ( 4 , 6 ) is glued. 14. Plate-shaped heat transfer element according to claim 11 or 12, characterized in that the covering ( 36 ) is glued to the existing coating ( 34 ) from the glued reinforcing fabric. 15. Use of several heat transfer elements ( 2 , 20 ) according to one of the preceding claims as wall, ceiling and floor panels for the production of complete heating or cooling rooms.