FI81473B - UPPVAERMNINGSELEMENT FOER ELECTRIC RUMSUPPVAERMARE, SPECIELLT AV GENOMSTROEMNINGSTYP. - Google Patents

Description

1 81473 Provincial element especially for flow-through type electric room heaters

The invention relates to a provincial element which is particularly suitable for use in flow-through type electric room heaters and which comprises at least one tube-type electric resistor and an associated rib structure extending the heat transfer surface.

Such heating elements are intended to be fitted inside the housing structure of the electric heater, which is provided with suitable air inflow and outflow openings. Several alternative embodiments of a rib structure related to pipe resistance are known. This rib structure can consist, for example, of a metal strip wound around a tubular resistor, which forms a helical structure. Such a rib may also be soldered to the metal sheath of the pipe resistor. A series of metal plates can also be arranged around the pipe resistor, in which case the resistor is mounted by pushing it through the holes in the plates 20. To improve heat transfer, these plates can be connected to the jacket surface of the pipe resistor by means of a crimp or solder joint. A metal plate, for example an aluminum plate, can also be pressed around the pipe resistor, which can also be ribbed to enhance the heat transfer. Various techniques are used to accomplish this type of compression. The ribbed western element can also be made of a unitary piece, which can be, for example, extruded aluminum. Such a body has a tubular part into which the heat-generating, electrically insulated structure 30 can be implemented in a manner similar to the pipe resistance technique. Protruding vanes that promote heat transfer can be formed into the body by post-treatment. A variation of this solution is a structure in which a tubular resistor 35 is placed inside the tubular part of the body, and the tubular part is pressed tightly around the tubular resistor 2 81473. All of the above solutions have drawbacks.

The spiral rib is manufactured on a special machine built for this purpose. The method is relatively slow and thus also expensive. In addition, the helical rib has technical weaknesses: its heat transfer capacity is not as good as that of the individual rib plates perpendicular to the pipe resistance. In addition, in order to allow rotation, the helical rib has to be crimped from its lower part, whereby dust-collecting pockets are easily formed in the heating element. If it is desired to get the electrical connections of the heating element close to each other, the helically ribbed resistor has to be bent into a U-shape, which in the case of the ribbed resistor is a rub-15 sect operation. In some cases, the outer diameter of the heating element also becomes too large, which is a problem for thin heaters according to the current trend.

The advantage of a rib structure formed of separate lamellae over the previous spiral rib structure is better heat transfer capacity and less tendency to collect dust. Also, a situation where electrical connections are side by side is more easily achieved. However, the problem is the relatively laborious assembly and the higher material costs due to the individual lamellae. It is also difficult to manufacture very long heating elements with this technology.

In solutions where the pipe resistor and the rib structure made of different materials are assembled by compression, the weakness is the different thermal expansion of the different materials, which can lead to a deterioration of the heat transfer between the pipe resistor and the rib structure. As a result, the resistor may overheat and be destroyed. In addition, the problem with compressed structures is the sounds due to differences in thermal expansion as the pieces move relative to each other.

The problem with uniform ribbed heating elements made entirely of aluminum is mechanical weakness at high temperatures, the awkward formability of the aluminum profile and, for example, bending so that the electrical connections are obtained side by side. In addition, 5 aluminum is a more expensive material than, for example, steel.

It is an object of the present invention to provide a heating element by means of which the above-mentioned problems and disadvantages can be at least substantially eliminated. This heating element according to the invention is characterized in that the rib structure comprises at least one metal plate with one or more grooves parallel to the plane of the plate into which the electric resistor or resistors are soldered and flaps or ribs projecting from the plane of the plate. Preferably, the rib structure is made by molding from a sheet blank. The rib structure 15 may be unitary, individually adapted to each application, or may consist of standard-sized modules. The heating element is made of such a rib structure and standard tubular resistors, which may be one or more pieces, by placing the put-20 groove or resistors in the grooves of the rib structure and soldering the parts together to provide a mechanically strong and thermally conductive joint. As the rib material, ordinary steel can be used, so that the material cost is as low as possible. If necessary, when the requirements are higher than usual due to, for example, corrosion or high temperatures caused by the environment, coated (e.g. nickel-plated) or stainless steel can also be used.

The resistor can be set for soldering on the side of the rib, i.e. without having to push it through the holes. Thus, the assembly work is accelerated and the rib structure does not limit the length of the heating element. In addition, the rib can be made of a steel strip of suitable width as a continuous product, either made to size for each purpose or, for example, modularly dimensioned. This means considerable cost savings compared to, for example, a lamella element.

The heating element according to the invention offers several advantages for the construction of the heater itself. The structure is 5 thin, so it does not place restrictions on the thickness of the heater itself. The heating element can be implemented using either one straight resistor, one U-shaped bent resistor, two straight resistors or a combination of these. Thus, the designer of the device is free to choose the location of the coupling heads 10 and different power combinations as needed. The heating element also has a low tendency to collect dust.

The heating element according to the invention will now be described in more detail with reference to the accompanying drawing, in which Figure 1 shows a rib structure of a heating element according to the invention, Figure 2 shows a heating element according to the invention with one U-shaped tube resistor and Figure 3 shows a heating element 20 with two straight tube resistors.

Figure 1 shows a rib structure of a heating element according to the invention, which is made of a single sheet blank by molding. As a suitable sheet material, for example, a steel strip can be mentioned, the width of which can be, for example, 140 mm and a thickness of 0.75 mm. Such a steel strip is formed into a rib structure according to Figure 1 by means of a suitable tool. In this case, two grooves 2 in the longitudinal direction of the plate 1 and in the plane direction of the plate 1 are formed in the plate material 1 for soldering the electric resistor or resistors. The dimensions of these grooves 2 are adapted to correspond to the outer diameter of the pipe resistor 4 intended for use with the rib structure. In addition, wings or ribs 3 are bent out of the sheet material 1. These wings are bent relatively sharply against the plane of the strip 1, almost at an almost right angle thereto. It is advantageous from the point of view of heat transfer 5 81473 that as much of the surface area of the rib plate 1 as possible is formed into wings or ribs 3.

Fig. 2 shows a heating element according to the invention, in which a U-shaped tubular resistor 4 is arranged in the grooves 25 of the rib structure according to Fig. 1. The casing of this tubular resistor is made of ordinary steel, surface-treated (e.g. nickel-plated) steel or stainless steel. A suitable solder, for example copper wire or paste 10, is placed at the joint of the resistor 4 and the groove 2 and the structure is soldered in a suitable atmospheric furnace to provide a mechanically strong and highly thermally conductive connection between the pipe resistor sheath 4 and the rib structure sheet material 1. After soldering the pipe resistor, the ends of the resistance rod 4 are sealed in a conventional manner 15 and are provided with the necessary parts 5 for the electrical connection.

Figure 3 shows an embodiment of a heating element according to the invention, in which the rib structure is formed of several modules of a certain size. In addition, unlike the heating element of Fig. 2, the heating element of Fig. 3 is provided with two straight resistance rods 4. The heating element is assembled in the same manner as described above in connection with the heating element of Fig. 2. By using two separate resistance rods 4, a heating element 25 is provided, for which two power ranges can be provided by means of a selection circuit.

The heating element according to the invention has been described above with regard to the rib structure on the basis of only two exemplary construction alternatives, which are completely identical in terms of the appearance and implementation of the rib structure itself. It is to be understood, however, that the shape and structure of the ribs themselves, as well as the location of the grooves formed on the tube resistors, may be altered, for example for flow engineering or other reasons, without departing from the scope of the appended claims.

Claims (3)

1. Heating elements for electric room heaters in particular of the flow-through type, which element comprises at least 5 a pipe resistance type electrical resistor (4) and a metal plate structure (1, 3) connected thereto which increases the heat supply surface, characterized in that the construction is made of a plate blank by forming ribs or flaps (3) protruding therefrom from the plate surface and in the direction of the plate plane one or more rafters (2), similar to a groove, to which or which rafters the resistor or resistor (4) are soldered. Heating element according to claim 1, characterized in that the metal plate structure, which increases the heat-emitting surface, consists of a part adapted for each individual use. Heating element according to claim 1, characterized in that the metal plate structure, which increases the heat-emitting surface, consists of two or more parts 20. standard format.