DE29813171U1 - Radiant heater - Google Patents

Description

se, 98207-DEU 23 July 1998

Jürgen Bretschneider 09465 Neudorf

"Radiator heaters"

The invention relates to a radiant heater, in particular a ceiling radiant panel, consisting of a large-area radiant plate provided with recesses, of a system of interconnected tube-like elements for supplying and discharging a medium for heat transport, wherein the tubes have contact surfaces to the radiant plate for heat transfer in a peripheral section, and of a thermal insulation plate on the side facing away from the radiant surface of the radiant heater.

Radiant heaters of the type mentioned are known in many different forms,
(e.g. DE 93 04 900.5 LM, EP 500 778 Al, EP 501 443 A1)
Trough-shaped recesses are made in the large-surface radiant plate, into which the pipes are inserted that carry the medium for heat transport. The contact surfaces between the peripheral sections of the pipes and the troughs in the radiant plate usually form an angle of 180°.
It has been shown that the radiant plate radiates its heat very strongly in the immediate area of the contact surface with the pipe and that the radiation effect decreases significantly even at a small distance from the pipe. This circumstance has previously been taken into account by placing the pipes closer together to guide the medium.

This makes the ceiling radiator heavy. It is difficult to handle during installation. The heat distribution in the pipe system becomes less favorable. This uneven heat distribution had to be counteracted by a more complicated distribution system for the medium. However, a second distribution system, which is often used, is expensive to manufacture and maintain.

The object of the present invention is to propose a radiant heater that enables uniform heat radiation over the entire surface of the radiant plate with the smallest possible number of tubes. The radiant heater should be inexpensive to manufacture.

According to the invention, this object is achieved in a surprisingly simple manner by the elements defined in claim 1. By assigning so-called distribution plates, additional heat is removed from a previously free peripheral section of the pipes via a contact surface, passed between the radiation plate and the insulation plate above it to a second contact surface remote from the pipe and transferred there to the radiation plate.

The heat losses in the section between the pipe and the second contact surface in the distribution plate are significantly lower than the heat losses on the radiation plate in this section.

The embodiment according to claim 2, which provides a distance between the distributor plate and the radiation plate between the contact surfaces, leads to a higher radiation intensity in the area of the contact surfaces remote from the pipes.

It has proven advantageous to profile the distributor plate for the purpose of creating a distance from the radiant plate and for the purpose of stabilization and to leave the radiant plate predominantly in one plane (claim 3).

With the design of the contact surfaces of the radiant plate to the pipe according to claim 4, the radiant plate can also be made largely flat in this area. The visible surface of the radiant plate then only has a minimum of functional profiling.

The production of radiant panels and distribution panels from a drawn aluminum extruded profile according to claim 5 allows both panels to be produced with one and the same device and to create flat radiant or visible surfaces on both sides. This design is also suitable for radiant heaters that are installed in vertical walls. In this case, the insulation panel can be interrupted in limited areas distributed over the surface of the wall. The heat then radiated into the wall there helps to keep the wall dry. The dry outer wall enables low heat losses.

The embodiment according to claim 6 makes it possible to keep the total mass of the radiant heater low or to reduce it.

With the embodiment according to claim 7, the thickness of the distributor plate can be reduced without impairing the desired heat transport to the positions remote from the pipes.

The invention will be explained in more detail below using exemplary embodiments.

The accompanying drawings show:

Fig. 1 is a partial perspective view of a radiant heater according to the invention,

Fig. 2 is an enlarged partial view of the sectional view shown in Fig. 1,

Fig. 3 a second variant of the radiant heater in a representation

according to Fig. 2,

Fig. 4 a third variant with a reduced distributor plate in a representation according to Fig. 2,

Fig. 5 a cross section through a part of the radiant heater from

drawn aluminium profiles and

Fig. 6 a radiant heater with an almost flat radiant surface

of the radiant panel.

The radiant heating element consists in the conventional manner of a radiant plate 2, into which trough-shaped recesses for the pipes 1 are made. The pipes 1 are fixed in the troughs of the radiant plate 2 either with weld seams or resistance welding points 41, so that an unhindered heat transfer is possible over a large area at the contact surfaces A. The distribution plates 3 are also equipped with recesses. These recesses surround the pipes 1 from above and absorb the heat from the pipes 1 via the contact surface B.

The distribution plates 3 can be welded to the radiant plates in the immediate vicinity of the pipes 1. This connection ensures that the heat transfer from the pipe 1 to the radiant plate 2 and to the distribution plate 3 is optimal. The distribution plate 3 then extends between the radiant plate 2 and the insulation mat 5 arranged above the distribution plate 3 to the next pipe 1.

In the middle section between the pipes 1, the distributor plate 3 is then brought closer to the radiant plate 2 and connected to it either via a contact rail 40 or via a corresponding profile. The heat from the distributor plate 3, which has been conducted almost without loss up to that point, is transferred to the radiant plate 2 via the contact surface C, D thus created.
This measure makes it possible to ensure an approximately equal radiation level over the entire surface of the radiant plate 2, even if the tubes 1 are spaced apart from one another.

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The principle described here can be modified with regard to the requirements for the appearance of the underside of the radiant panel, from the point of view of reducing the mass of the radiator or other aspects.

The design shown in Fig. 2 makes it possible to design the radiant plate 22 and the distribution plate 32 (the number of appendixes refers to the respective figure) in the same way. Both plates 22, 32 are connected to one another by the weld seams 41, either close to the pipe 1 or at a greater distance from it, at C.

The majority of the heat from the distributor plate 32 is transferred here in the area C to the radiant plate 22. It is expedient (but not necessary) to insert a contact body 40 in an area in which the cross sections of the distributor plate 32 and the radiant plate 22 move away from each other. This contact body 40 can consist of a drawn aluminum rail.

It enables the residual heat of the distributor plate 32 remaining between two pipes to be transferred to the radiant plate 22.

Fig. 3 shows a design in which the distributor plate 33 is flat away from the trough. The radiant plate 23 is profiled here for mainly aesthetic reasons. The second contact surface is shown at J. One or two weld seams 41 ensure optimal heat transfer here.

In the design according to Fig. 4, the distributor plate 34 is initially guided at a very small distance from the radiant plate 24. The distributor plate 34 is connected to the radiant plate at a greater distance via a flat intermediate plate 43 made of a good heat conductor at F. Depending on the type of material used for the flat intermediate plate 43, the secure connection of both plates can be achieved either by screwing, riveting or welding connections.

The distributor plate 34 is not continued over the middle section of the radiant plate 24. This means that the heat energy still present there at the end is completely transferred into the radiant plate 24.

The design of a radiant heater shown in Fig. 5 shows the use of drawn aluminum profiles 25, 35 in conjunction with a pipe ¹¹ with a rectangular cross-section. The base surfaces (outside) of the radiant plate 25 and the distributor plate 35 are flat. The guide sections 25' and 35' projections in the area of the pipes 1' can be designed to be elastic in sections and can engage in a corresponding recess on the outer wall of the pipes 1' with a force fit.

Spacer sections 351 and 251 are provided at a distance from the pipes 1', which enable heat exchange at the contact surfaces G and H between the distributor plate 35 and the radiant plate 25. The secure, mutual connection can be achieved in this area either by welded connections or by known screw connections.

Because the radiant heater is flat on both sides, it is possible to install it on vertical walls or room dividers.

The design according to Fig. 6 is again based on the use of metal sheets. The contact surface A6 between the radiant plate 26 and the pipe 1 has been reduced here. The arc filled by the contact surface A6 extends approximately at an angle between 90° and 120°. The contact surface B6 between the pipe 1 and the distributor plate 36 is correspondingly larger.

Such an embodiment allows the radiant plate 26 to be made largely flat and the functional profiling in the area of the tubes 1 to be reduced to a minimum without reducing the radiation output of the radiant plate 26.

Radiant heaters of the type described here are used - as usual - in relatively large rooms as so-called ceiling radiators or radiant ceiling panels.

The use of such radiators in living spaces is currently still the exception. The radiant heaters described here can, however, also be used in living spaces - especially in the area of external walls - with particular advantages. In this case, the insulation panels, which are sensibly directed towards the external wall, can be reduced to a minimum in terms of their thickness. A certain amount of the heat can thus be introduced into the external wall, where it dries out.

The thermal insulation values of a wall dried in this way are significantly better than the insulation values of regularly damp walls, as is usual with conventional heating methods.

The dissipation of heat from the radiant heater into the wall can also be ensured via smaller, evenly distributed openings in the insulation panel 5.

se, 98207-DEU 23 July 1998

Jürgen Bretschneider 09465 Neudorf

"Radiator heater" List of references

1, V pipe

2 Radiant panel (applies to all variants) 22, 23, 24, 25, 26 Radiant panel (variants)

25' lead section

251 Distance section

3 Distribution plate (applies to all variants) 32, 33, 34, 35, 36 Distribution plate (variants)

35' leading section

351 Distance section

40 Contact rail

41 Weld seam (row of weld points) 43 Intermediate plate, welded

5 Insulation board

A, contact surface (tube - radiant plate)

B, contact surface (pipe - distributor plate)

C, D, E, F, G, H, J, K Contact surface (distribution plate - radiant plate)

Claims (7)

se, 98207-DEU 23 July 1998 Jürgen Bretschneider 09465 Neudorf "Radiator heaters" Claims 1. Radiant heater, in particular ceiling radiant panel, consisting of - a large-area jet plate with recesses (2), - a system of interconnected tube-like elements (1) for supplying and removing a medium for heat transport, wherein the tubes (1) have contact surfaces (A) to the radiant plate (2) for heat transfer in a peripheral section, and - a thermal insulation plate (5) on the side facing away from the radiant surface of the radiant heater, characterized, that the system of interconnected tubular elements (tubes 1) is assigned distributor plates (3) which - on a second circumferential section of the pipes (1) facing the insulation board (5), a first contact surface (B) for heat transfer and - at a distance of at least one pipe cross-section from the respective pipe (1) a second contact surface (C K) for heat transfer to the jet plate (2). 2. Radiant heater according to claim 1, characterized in that that the distributor plate (3) is guided in the area between the contact surface (B) to the pipe (1) and the second contact surface (C .... K) to the radiant plate (2) between the radiant plate (2) and the insulation plate (5) at a free distance from the radiant plate (2). 3. Radiant heater according to claim 1 and 2, characterized in that the radiant plate (2, 26) is predominantly flat and the distribution plate (3, 36) is profiled in cross section. 4. Radiant heater according to claim 1 to 3, characterized in that that the contact area (A6) of the jet plate (2, 26) to the pipe (1) is smaller than the contact area (B6) of the distributor plate (3, 36) to the pipe (1). 5. Radiant heater according to claim 1, characterized in that the jet plate (2, 25) and the distributor plate (3, 35) consist of a drawn light metal profile and that the outer surface of both profiles (25, 35) is predominantly flat and the inner profiles have guide sections (25', 35") for the tubes (V) and spacer sections (251, 351) for the formation of contact surfaces (G, H). 6. Radiant heater according to claim 1 to 4, characterized in that a distributor plate (34) is assigned to each tube (1) and that the distance between the contact surface (B) to the pipe (1) and the contact surface (F) to the jet plate (24) is smaller than half the distance to the adjacent pipe (1). 7. Radiant heater according to claims 1 to 4 and 6, characterized in that the distributor plate (3) consists of copper sheet and the thickness of the copper sheet is smaller than the thickness of the radiant plate (2, 24).