CH660518A5 - RADIATOR. - Google Patents

Description

The invention relates to a radiator according to the preamble of claim 1.

Such a radiator is known from GB PS 1 204 751. In this radiator, the ends of the longitudinal pipes are connected at both ends to a common cross-connection pipe for all longitudinal pipes. This design is comparatively complicated. If the tubular construction of the known radiator is realized by welding, many welding beads have to be ground down in order to ensure that the one side surface of the longitudinal tubes lies flush against the radiation plate. In addition, the longitudinal pipes in the known radiator are not connected in series but in parallel. As a result, the inflow and outflow of the medium either at a high speed, i.e. connected with noise or has to be done by comparatively large flow cross-sections.

In other known radiators of this type, a serpentine tube is used as the tube construction, which is arranged between two plates and either rests directly against these plates or is spaced from the plates by ribs arranged between these plates.

In order to be able to easily bend a tube into a serpentine tube, such a tube should generally have a circular cross section.

In addition, in order to transfer the heat of the medium flowing through the serpentine tube (e.g. hot water) to the radiation plate as expediently as possible, the serpentine tube rests against this plate. However, it is clear that the circular cross section of the tube does not contribute to optimal heat transfer.

Optimal heat transfer can be obtained if the tube is given a rectangular cross-section and the broad side is placed against the radiation plate. However, such a tube cannot be bent in a serpentine shape.

There are e.g. a construction in which a number of longitudinal tubes of equal length, rectangular in cross section, are arranged parallel to one another, while the open ends of these longitudinal tubes are connected to e.g. end pipes perpendicular to the longitudinal pipes can be connected, these end pipes always connecting two longitudinal pipes to one another, in such a way,

that the medium passed through the pipe construction flows in serpentines through the rectangular longitudinal pipes.

There is also a construction in which the front ends of the longitudinal tubes are fastened to common end tubes, transverse walls being provided in these end tubes in order to bring about the desired serpentine flow in the longitudinal tubes.

The production of these two constructions is very time-consuming and expensive, because the ends of the longitudinal tubes have to be welded to the side tubes and, in the case of the common end tubes, transverse walls also have to be welded therein. In addition, the welding beads must be ground away so that the pipe construction can rest against the radiation plate as expediently as possible.

The object of the invention is to provide a radiator of the type mentioned, in which the disadvantages mentioned have been substantially eliminated.

This object is achieved in that the radiator has the tubular structure with the features specified in the characterizing part of patent claim 1.

Because according to the invention the diameter of the cross-connection tubes is smaller than the height of the side walls of the longitudinal tubes and because the openings in the side walls are preferably at a distance from the surface of the longitudinal tubes resting against the radiation plate, the cross-connection tubes come at a distance from the surface of the radiation plate lie so that the weld seams of the cross-connection tubes welded into the side walls no longer need to be ground. This gives a considerable saving in work.

A further saving of work can be obtained by pinching the front ends of the longitudinal tubes in such a way that the surface resting against the radiation plate and the surface of the longitudinal tubes parallel to this are pressed towards one another, the gap thus obtained being closed by welding . As a result of the fact that the two surfaces mentioned are pressed towards one another, the weld seam comes to lie at a distance from the surface of the radiation plate, so that here too, no regrinding of the weld seams is necessary.

In addition to these advantages, the radiator according to the invention has a number of other advantages.

In modern construction - especially in commercial buildings and office buildings - it is often desirable to work with standard mounting plates for all kinds of purposes. For example, one of these plates

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be a radiator, which can then be part of a wall constructed from standard panels in an aesthetically responsible manner.

The advantage of the invention is that it is possible with a mounting plate of a certain size to easily adjust the heat capacity of the pipe structure. The number of longitudinal pipes to be arranged is determined by the length of the cross-connecting pipes. If the length of the cross-connection tubes is short, then more longitudinal tubes can be attached to the radiation plate, and if this length is greater, fewer longitudinal tubes can be attached to the radiation plate. It is clear that the heat capacity can be set very easily in this way. In addition, the heat can be distributed correctly over the entire surface of the radiation plate. There are therefore no cold parts in places that are furthest away from the supply, as is the case with conventional radiators.

It is only a question of the arrangement of the desired number of longitudinal tubes with the desired rectangular cross sections.

You can also set the mutual distance differently; e.g. in such a way that the distance between the longitudinal tubes gradually increases.

For the production of a radiator according to the invention with longer or shorter cross-connection pipes and / or longitudinal pipes with different cross-sections, the longitudinal pipes optionally being able to be attached at different mutual distances, no additional actions are required, so that a wide range of those described above can be obtained without additional costs Has possibilities in terms of heat capacity within a limited surface.

The invention is explained below with reference to an embodiment and with reference to the drawing. Show it:

Figure 1 shows the back of a radiation plate against which the tubular structure is attached, in a schematic representation.

Fig. 2 shows a section of FIG. 1 along the line II-II.

In the figures 1 and 2 a plate heater is shown, which with a radiation plate 1 and with a pipe construction 2 attached to the radiation plate for the passage of a transport medium, e.g. Warm-5 water is provided. This tube construction 2 consists of a number of longitudinal tubes 3 arranged essentially parallel to one another and at a distance from one another, which are sealed at their ends 4 and a number of cross-connecting tubes 5 for connecting the longitudinal tubes to one another in such a way that the transport medium flows through the successive longitudinal tubes in a serpentine manner.

The longitudinal tubes 3 have a substantially rectangular cross-section and rest with one of their wide walls 6 against the surface of the radiation plate 1. 15 The cross-connecting tubes 5 have a profile that is smaller than the height of the side walls 7 of the longitudinal tubes 3 and are preferably in arranged near the front ends 4 of the longitudinal tubes 3 and extend into the suitable opposite, provided in the side walls 7 provided 20 openings 8 of the adjacent longitudinal tubes 3. In connection with a flow of the medium as favorable as possible, a rectangular profile of the Cross-connection pipes 5 with the associated openings 8 are preferred.

The openings 8 are provided in such a way that the cross-connection tubes 5 inserted therein come to lie at a distance from the surface of the radiation plate, as is clearly indicated in FIG. 2.

The cross-connection pipes 5 are preferably welded to the 30 openings 8, or else - if a flow bore is used to produce the openings 8 - pressed and glued into them.

The tube structure 2 thus formed can e.g. by means of pipe clamps 9, see in particular Fig. 2, against the radiation plate 1, all this in cooperation with the fastening elements attached to the radiation plate in the form of e.g. Bolt 10 with screw thread and associated nuts 11.

To transport the medium through the pipe construction 2, a flow connection 12 or a return connection 13 is provided at the beginning and at the end of this pipe construction.

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1 sheet of drawings

Claims (6)

660518 PATENT CLAIMS 1. Radiator with a radiation plate and a pipe structure (2) attached to it for the passage of a medium in order to transfer its temperature to the radiation plate, the pipe structure (2) consisting of a number of essentially parallel and spaced longitudinal pipes (3) with a substantially rectangular cross-section, one flat wall (6) of which rests against the radiation plate (1), and of a number of cross-connection tubes (5) for connecting the successive longitudinal tubes (3), characterized in that the ends (4) of the longitudinal tubes (3) are closed so that the diameter of the cross-connection tubes (5) is smaller than the height of the side walls (7) of the longitudinal tubes (3) perpendicular to the radiation plate (1), the cross-connection tubes (5) being the successive longitudinal tubes (3) in this way connect with each other so that the flow directions of the medium in opposite longitudinal pipes (3) are opposite to each other d, for which purpose openings (8) are provided in these side walls (7) through which the cross-connection tubes (5) are in sealing connection with the side walls of the longitudinal tubes (3). 2. Radiator according to claim 1, characterized in that the longitudinal tubes (3) have the same cross-sectional shape. 3. Radiator according to claim 1 or 2, characterized in that the openings (8) are arranged at a distance from the wall (6) resting on the radiation plate. 4. Radiator according to one of claims 1 to 3, characterized in that the openings (8) in the longitudinal tubes (3) and the cross section of the cross-connecting tubes (5) are circular. 5. Radiator according to one of claims 1 to 3, characterized in that the openings (8) in the longitudinal tubes (3) and the cross section of the cross-connecting tubes (5) are rectangular. 6. Radiator according to one of claims 1 to 5, characterized in that the front ends of the longitudinal tubes (3) are closed in that the surfaces of the longitudinal tubes (3) parallel to the radiation plate are pressed against one another and the gap which is formed between them is welded.