DE8809545U1 - Panel radiators - Google Patents

Description

Panel radiators Description

The invention relates to radiators, in particular panel, surface or flat radiators, with at least one plate-shaped

Heating surface and with at least one attached to it the room _

facing convector.

In the case of known flat radiators, it is usual for the convector or the convector surface to be installed on the back of the plate-shaped heating surface or, in the case of radiators with several plate-shaped heating surfaces, between them. Due to the particularly favorable power-to-weight ratio W/kg, the design with one convector surface on each side of a plate-shaped heating surface is particularly advantageous. However, since the surface of the plate-shaped heating surface, which is shaped by the water channels, is sometimes already perceived as disturbing, radiators with additional, strongly structured convector surfaces on the visible side cannot prevail.

Subsequent or factory-fitted cladding, particularly on the visible side of panel radiators, as also specified in G 87 15 122.7, always leads to a reduction in performance of between 3 and 6 %. If the additional material weight of the cladding is also taken into account, the power-to-weight ratio deteriorates many times over. In addition, with a

Execution according to the above mentioned document, according to which the front or .i

Visible side of a plate-shaped heating surface of an embossed ■

panel radiator is covered with a glued-on plate, which I

visible side also involved in a convective heat transfer through |

the cladding is reduced. J

According to DE-OS 35 19 424, a plate arranged on the front serves in particular to keep the emission of convection heat as low as possible.

Since convective heat transfer plays a significant role in the heat transfer from the panel radiator to the room air, the aim of the invention was to achieve good heat transfer and an attractive external shape at the same time.

The solution to this problem is specified in claim 1. Expedient further developments of the panel radiator according to the invention are described in claims 2 to 10.

According to the invention, it is important that the panel-shaped cladding surface actively participates in the power output of the panel radiator. To this end, additional surfaces are created that are exposed to air and heated by the heating medium. The creation of flow channels between the cladding surface and the underlying convector surface, in addition to the flow channels between the convector surface and the panel-shaped radiator, is of crucial importance. The geometric dimensions of the flow channels are chosen so that, given the thermal conductivity of the material, on the one hand, enough air can be guided in the flow channels and, on the other hand, the cooling of the cladding surface still ensures a sufficiently high proportion of radiant heat. A good connection between the cladding surface and the convector surface is also important. In a special version of the panel radiator according to the invention, this connection is made by an adhesive layer that remains elastic, especially after it has hardened. In order to achieve an even better heat transfer between the cladding surface and the convector surface, good heat-conducting material, preferably in the form of metallic particles, is added to the adhesive layer. Since the

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of metallic particles. Since the visible surfaces of the convector surface are occasionally not exactly in one plane, according to an embodiment of the invention , an adhesive is expediently used which increases in volume when it hardens, whereby the manufacturing tolerances of the convector surface are compensated and a largely continuous contact is established between the visible surfaces of the convector surface and the cladding surface.

Bonding can be carried out with heat-curing adhesives before painting, with moisture-curing adhesives during final assembly, or with separately painted or coated individual parts.

In the interests of assembly line production, it is advisable to design the parts to be joined by the adhesive in such a way that they remain mechanically fixed in their position relative to one another until the adhesive has completely hardened. This measure is particularly important when the adhesive is applied to the raw sheet metal surfaces and the subsequent treatment steps such as degreasing up to and including priming and coating are carried out and the hardening only takes place during the final baking process.

Mechanical fixing is also required for bonding finished coated components with moisture-curing adhesives with a long curing time. In particular, to prevent the adhesive from being washed out during the manufacturing process, a recess can be formed in the visible surfaces of the convector surface to accommodate the adhesive. By using an adhesive that increases in volume when it sets, a gap remains between the cladding surface and the convector surface in this design, which serves to prevent expansion noises when it heats up quickly.

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The cladding surface is preferably substantially flat and only ϕ

at the edges, especially for fastening and connecting with |

other trim parts, deformed. Their surface can be painted !

and/or be designed decoratively in a suitable manner. In addition to the design of the cladding surfaces, which serve for mechanical fixation, these can be deformed at their edges to such an extent that

be that by putting on side and top covers .<

completely covered radiators are created. According to a further embodiment of the invention, the side covers and the top cover can also be molded directly onto the covering surface. In the case of free-standing panel radiators, convector surfaces with covering surfaces are attached to both visible sides according to the invention.

The invention is illustrated and described below using exemplary embodiments.
Show it:

Fig. 1 is a perspective view of a single or multi-layer panel radiator,

Fig. 2 a section A-A through the upper part of a single-layer panel radiator,

Fig. 3 a section A-A through the lower part of a single-layer panel radiator,

Fig. 4 a section D-D through a side part of a single-layer panel radiator for free-standing installation,

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Fig. 5 a section D-D through a two-layer panel radiator with molded side and top cover,

Fig. 6 a section A-A through a two-layer panel radiator with molded side and top covers for free-standing installation,

Fig. 7 a detail of a section D-D with a recess formed in the visible surface of the convector surface.

Fig. 1 shows a perspective view of a panel radiator 4 with front cladding surfaces 3, 30, rear cladding surface 3, 16, side cladding surfaces 13, 18 and upper cladding surfaces 14, 17. The upper cladding surfaces have openings 15 for the passage of air. The cutting planes A-A and D-D are also indicated.

Fig. 2 shows a section A-A through the upper part of a single-layer panel radiator. The panel radiator consists of a heating surface 1, which is made up of two half-shells 5. Horizontal water channels 6 and vertical water channels 7 are formed on the half-shells 5. A convector surface 2 is welded onto the heating surface 1, on whose visible surfaces 10 adhesive layers 9 are applied for bonding to a cladding surface 3. The cladding surface 3 has an approximately Z-shaped bend 20 on its upper edge, which serves to fix the cladding surface 3 to the convector surface 2 with a clamp 19. The approximately Z-shaped bend 20 can also be designed as an angle mounted on the cladding surface 3.

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In Fig. 3, a section A-A through the lower section of a single-layer panel insulation body is shown. In the area of the lower edge of the cladding surface 3, an approximately U-shaped bend 21 is made, which serves for mechanical fixation in the area of the lower edge of the cladding surface 3. The U-shaped bend 21 can also be designed as a clamp mounted on the cladding surface 3.

Fig. 4 shows a section D-D through a single-layer panel radiator for free-standing installation. The cladding surfaces 3 have approximately Z-shaped bends 22 on their side edges, onto which side covers 18 are attached. If such a radiator is to be installed in front of a wall, a preferably flat cladding surface 3 with only the edges bent is sufficient on the side facing the room. In this design, in addition to the bend 22, a chamber (not shown in the drawing) is provided on the side cover 18 for attachment to the heating plate 1. However, if such radiators are installed freely, especially in front of a wall,

f window areas, the second, only indicated by dashed lines,

y Cladding surface 3 provided.

In Fig. 5 a section D-D through a two-layered

k Panel radiatorsr shown. The panel surface 30 is connected to the

f. side cover 13 with a rear heating plate 1

_r ; gripping bend 131 is formed. Between the heating plates 1

^I I indicates a supply 8 for heating water.

In Fig. 6 is a section A-A through the upper part of a two-layer

designed panel radiator for free-standing installation. The cladding surface 30 has a molded upper cover 14 with a bend 141, which grips over the approximately Z-shaped bend 20 of the upper edge of the cladding surface. A clamp 23 serves to mechanically fix the

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Covering surface 16 opposite the convector surface 2.

In Fig. 7, a detail of a convector surface 2 is shown in a section D-D. A recess 11 for receiving an adhesive layer 9 is formed in the visible surface 10 of the convector surface 2. A gap 12 remains between the visible surface 10 and the cladding surface 3, 16, 30.

Claims (10)

&bull;t - · Panel radiators Protection claims 1. Panel radiator with at least one heating surface and at least one cladding surface on a visible side, characterized in that the heating surface (1) has at least one welded convection surface (2) forming convection channels on a visible side and the cladding surface (3, 16, 30) is connected to the visible surfaces (10) of the convection surface (2) to form further flow channels. 2. Panel radiator according to claim 1, characterized in that the connection between the cladding surface (3, 16, 30) and the visible surfaces (10) of the convector fish (2) is carried out as an adhesive bond by means of an adhesive layer (9). 3. Panel radiator according to claim 2, fi characterized in that the cladding surface (3, 16, 30) &ngr; by means of a material that remains elastic after curing Adhesive layer (9) is connected to the convector surface (2). !; 4. Panel radiator according to claim 2 or 3, jji characterized in that for the formation of a well ! thermally conductive connection between the cladding surface (3, &ngr; 16, 30) and the convector surface (2) the adhesive layer (9) t particles made of at least one material with good heat conduction, ; preferably made of metal. 5. Panel radiator according to one of claims 1 to 4, characterized in that the cladding surface (3, 16, 30) is connected to the convector surface (2) by means of an adhesive layer (9) which hardens with an increase in volume. 6. Panel radiator according to one of claims 1 to 5, characterized in that at least one covering surface (3) for receiving attached upper and side covers (17, 18) has approximately Z-shaped bends on the upper and side edges, a clamp (19) for fastening the covering surface (3) to the convector surface (2) being arranged on the upper bend (20) and an approximately U-shaped bend (21) reaching over the fan edge of the convector surface being attached to the lower edge. 7. Panel radiator according to one of claims 1 to 6, characterized in that a covering surface (30) has molded-on upper and side covers (14, 13) with bends (131, 141) that extend over a heating plate (1) or another covering surface (16). 8. Panel radiator according to one of claims 1 to ₁₁ , characterized in that the visible surface (10) of the convector surface (2) has a recess (11) into which an adhesive layer (9) is embedded such that a gap (12) remains between the visible surface (10) and the covering surface (3, 16, 30). 9. Panel radiator according to one of claims 1 to 8, characterized in that the adhesive layer (9) is formed from a thermosetting adhesive. 10. Panel radiator according to one of claims 1 to 8, characterized in that the adhesive layer (9) is formed from a liquid-curing adhesive.