NL8600989A - Electric heating element for ovens, dryers or central heating - has two internal reflectors of coated corrugated paper and insulators sealed inside element casing - Google Patents

Abstract

The heating element is contained in a rectangular box-shaped housing (1), which has a front wall (3), sidewalls (4,5) and a rear wall (6). The front wall is has a matt black coating to maximise heat radiation, while the other walls are polished inside and out to minimise heat radiation and maximise reflection of heat back into the unit. The heating spirals are embedded in a heat conductor e.g. MgO, which is retained at the front of the unit by an internal wall (7). Between the internal wall and the back wall are two reflectors (14,15) consisting of corrugated paper coated with a reflective layer. The insides of the rear and side walls are lined with heat insulating material (16).

Description

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Electric heating element.

The invention relates to a heating element comprising an electrically fed heat source and at least one reflecting surface facing the heat source.

Such heating elements are widely used in ovens, and drying ovens and for heating purposes in homes.

A problem with such heating elements is that the heat source itself radiates the heat in all directions, while for a large number of applications it is desirable that the heat radiation is directed.

Therefore, heat reflectors are often used for this purpose, which bundle the heat radiation in a certain direction. A drawback of such reflectors is that under the influence of the environment oxidation and contamination of the reflecting surface occurs, as a result of which less and less heat is reflected and the efficiency of the heating element decreases.

The object of the invention is to provide a heating element in which contamination and oxidation of the reflector is impossible or at least minimal.

To this end, the invention provides a heating element of the above-mentioned type, wherein the heat source is arranged in a closed housing with a number of housing walls, wherein at least the side of the housing walls facing the heat source forms the reflecting surface and at least another of the housing walls on the side facing the heat source have a surface with good heat-absorbing properties.

Because in the heating element according to the invention the heat source and the reflector or reflectors C "ί Λ ** *» Λ -v one «ί -2- are housed in one closed housing, the reflector is not exposed to the atmosphere in the heated room and therefore cannot pollute, the heat is thereby always reflected to the same extent 5 and the efficiency of the heating element remains essentially constant.

Another advantage is that, due to the reflection in the interior of the heating element, its temperature constant is small, so that it can also be used in places where rapid temperature control is required.

Another advantage is the simple construction of the heating element, which allows the cost price to be low.

The heating element according to the invention has the shape of a beam and can be easily attached and removed, while the juxtaposition of a number of heating elements to obtain a large heating surface does not pose any problems either.

20 During manufacture, the number of heat sources in one heating element can be easily adapted to the specific application.

The invention will be explained in more detail below with reference to a number of exemplary embodiments with reference to the drawing, in which: Fig. 1 shows a cross-section in a first embodiment; and Fig. 2 shows in cross section a second embodiment of a heating element according to the invention.

FIG. 1 shows a first embodiment of the heating element according to the invention. The heating element comprises an elongated, box-shaped housing 1, in which one or more heat sources are arranged.

In the exemplary embodiment, the heat sources are formed by three per se known heating coils 2, which are also suspended from their ends in a known manner, and are provided with an electric energy supply. However, the number and type of heat sources is of no importance to the invention.

The housing 1 consists of a front wall 3, side walls 5 and 5 and a rear wall 6. The walls are preferably made of stainless steel. The aim is to achieve a maximum heat output through the front wall 3, which is directed towards the product to be heated or a space to be heated, and a minimum heat output 10 through the walls 4, 5 and 6. To this end, the interior of the housing faces sides of walls 4, 5 and 6 are polished so that they reflect a maximum amount of heat towards the front wall 3.

The side of the front wall 3 which faces the heating coils 2 is also processed in such a way that this wall absorbs a maximum amount of heat and gives off on the outward facing side of front wall 3, the inward facing side of front wall 3 is preferably provided for this purpose. of a matte black coating.

20 In order to counteract the heat transfer in the direction of walls 4, 5 and 6 as much as possible, the heating coils are surrounded by a first U-shaped wall 7, which rests with the free ends of the legs of the U against the inside of front wall 3. The space that is created between the front wall 3 and the first U-shaped wall 7, in which space the heating coils 2 are present, is completely filled with a material which has very good heat conducting properties, eg MgO. As a result, the heat transfer from the heating coils 2 to in particular the front wall 3 is optimal. If the heating coils 2 were to hang freely in the formed space, the heat transfer was considerably poorer because air has very poor thermal conductivity properties. In addition, the MgO ensures that the 35 heating coils cannot come into electrical contact with the metal walls 3 and 7, which leads to 8.? Λ, Λ .Λ> £ 1

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-4- short circuit would result. In order to obtain an optimal reflection of heat to the front wall 3, wall 7 is preferably made of stainless steel, the side of 5 facing the heating coils 2 being polished.

At some distance, the first U-shaped wall 7 is surrounded by a second U-shaped wall 8, the free ends of the legs of the U of which also abut the inner side of front wall 3. The space 10 between wall 7 and wall 8 can are empty, but can also be filled with a heat-insulating material, e.g. a material sold under the brand name Ceraboard by Manville de France S.A.

Wall 8, like wall 7, is preferably made of stainless / 15 steel, with its side facing wall 7 being polished for maximum heat reflection.

The side of wall 7 facing wall 8 is preferably provided with a matte black coating for maximum absorption of the heat reflected by wall 8.

Finally, between the bottom side of wall 8, seen in Fig. 1, and the side of the back wall 6 facing the interior of the housing 1, an amount of heat-insulating material is provided. This material can e.g. consist of a thick layer of the above-mentioned Ceraboard, but preferably the layer is composed of a number, e.g. three, thin layers 9 ', 9 "and 9" ".

Between layers 9 'and 9 "and between layers 9" and 9 "" layers 10 and 11 of a heat-reflecting foil are arranged, eg aluminum foil with the reflecting side facing the heating coils 2. The partial layer 9 preferably consists of a blanket of a fiber ceramic material compressed to half a thickness, eg blankets which are marketed under the brand name Cerawool Blanket by Manville de France SA Such a blanket has a laminar structure, while the fibers have a high possess heat reflectivity.

The partial layers 9 "and 9H ', both of which have, for example, the double thickness of layer 9', can for instance again consist of Ceraboard.

It has been found that in particular the use of the materials Ceraboard and Cerawool is advantageous in order to obtain a low temperature constant for the heating element. The aforementioned materials are made of heat-reflecting fibers and absorb considerably less heat than conventional heat-insulating materials, so that their thermal storage capacity is low and therefore the temperature constant of the heating element can also be low.

The polished side of the rear wall 6 facing the interior of the housing 15 1 reflects that heat which has not yet been reflected successively by the walls 7 and 8 and the foil layers 10 and 11.

In order to prevent a heat flux from the interior of the housing 1 to the side walls 4, 5 and 6, it is necessary that the foil layers 10 and 11 do not touch the side walls. To prevent such a heat flux, strips 12 and 13 of a heat-insulating material are also provided, which strips are arranged on either side of outwardly projecting legs 4 'and 25' of respectively. the side walls 4 and 5 of the housing.

The rear wall 6 is folded around these legs 4f and 5 'to close the housing from the outside air and to form a whole.

Due to the construction of the heating element according to Fig. 1, an optimal transport of heat in the direction of the front wall 3 has been realized, by giving all walls in the housing on the side facing that front wall an optimally reflecting surface and by the heating elements facing side of the front wall 3 and all sides of the walls opposite a reflecting side, with the exception of

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-6- giving a maximum heat-absorbing surface, speaking from the outside of the housing walls 4, 5 and 6.

Experiments have shown that if the temperature of the heating coils 2 is 520 ° C, the temperature of the front wall 3 is 350 ° C and that of the back wall 6 is only 90 ° C. These very good properties of the heating element according to the invention are also ensured in the longer term because there is no risk of contamination of the reflecting surfaces under the influence of the environment. Only housing H2O and CO2 are released in housing 1, which do not adversely affect the reflectivity of the stainless steel walls and the reflective foils.

FIG. 2 shows in cross-section another embodiment of the heating element according to the invention.

In Fig. 2, like parts are indicated with the same reference numerals as in Fig. 1. Also in the embodiment according to Fig. 2, the sides of the walls 4, 5, 6 and 7 facing the front wall 3 are polished for maximum heat reflection, while the side of front wall 3 facing the heating coils 2 and the side of wall 7 facing away from the heating coils are preferably provided with a matt black coating for maximum heat absorption.

The space between wall 7 and the housing rear wall 6 in the embodiment according to Fig. 2 is filled with a number, e.g. two layers consisting of heat-resistant corrugated cardboard sheets, known per se, respectively. 14 and 15. These plates consist of a flat support with a corrugated layer thereon, so that elongated channels are formed between the support and the corrugated layer.

The supports of the plates 14 and 15 are provided with a layer of aluminum foil in order to obtain a maximum heat reflection 35 in the direction of the corrugated layers.

Plates 14 and 15 also have the property of being Λ---O; * *; "- * 1 -7- provide very good heat insulation and also have a low thermal storage capacity, so that the temperature constant of the heating element can be small.

Preferably, a layer 16 of heat-insulating material is provided between the housing walls 4, 5 and 6 and the plates 14 and 15, which layer extends along the inside of the walls 4 and 5 up to the front wall 3.

According to a further embodiment of the embodiment according to fig. 2, the plates 14 and 15 do not have longitudinal channels, because turbulence of the air present therein can occur in these channels, as a result of which the heat insulation properties may decrease somewhat, but at 15 top of the carrier provide air-filled, closed compartments. Such a plate has a wafer structure in top view.

It will be clear to a person skilled in the art that a large number of modifications are possible in the embodiments shown, such as applying even more reflective surfaces and thicker layers or more layers of heat-insulating material. However, as long as there is a closed housing containing the heat source (s), such modifications fall within the scope of the invention. Also, the invention is in principle not limited to a heating element with an elongated heat source and an elongated housing, round or square housings containing heat sources of a suitable shape are also possible.

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Claims (17)

Heating element comprising an electrically fed heat source and at least one reflecting surface facing the heat source, characterized in that the heat source is arranged in a closed housing 5 with a number of housing walls, at least the side of the heat source facing one of the housing walls form the reflecting surface and at least one of the housing walls on the side facing the heat source has a surface 10 with good heat-absorbing properties. 2. Electric heating element according to claim 1, characterized in that the housing is box-shaped, with a front wall, a rear wall and side walls, the heat source being arranged near the front wall, which front wall is provided with the surface with good heat-absorbing properties and in that the side walls and the rear wall all have a heat-reflecting surface. Electric heating element according to claim 2, 20, characterized in that the heat source is surrounded by a first U-shaped wall, the legs of which rest against the inner side of the front wall, the side of the U-shaped wall facing the heat source is provided with a heat-reflecting surface, the opposite side of this wall is provided with a surface with good heat-absorbing properties and that the space between the U-shaped wall and the front wall is filled with a medium with good heat-conducting properties. Electric heating element according to claim 3, characterized in that the medium is MgO. Electric heating element according to claim 3 or 4, characterized in that the first U-shaped wall is surrounded at some distance by a second U-shaped A. The wall, the legs of which also rest against the inner side of the front wall, that the side of the second U-shaped wall facing the first U-shaped wall is provided with a heat-reflecting surface and that the other side of the the second U-shaped wall has a surface with good heat-absorbing properties. 6. Electric heating element according to claim 5, characterized in that the space between the first and second U-shaped wall is filled with a heat-insulating material. Electric heating element according to at least one of claims 1 to 6, characterized in that a layer of heat-insulating material is arranged against the inside of the rear wall of the housing, 8. Electric heating element according to claim 7, characterized in that the layer of heat-insulating material is built up from a number of partial layers, wherein a heat-reflecting layer is disposed between the successive partial layers, the heat-reflecting surface of which is directed away from the rear wall. Electric heating element according to claims 5 and 7 or 8, characterized in that the layer of heat-insulating material fills the space between the rear wall and the second U-shaped wall. 10. Electric heating element according to claim 7, characterized in that the layer of heat-insulating material is at least partly built up from a number of partial layers, each of which consists of a flat heat-resistant carrier with a corrugated heat-resistant layer thereon, whereby elongated between the carrier and the corrugated layer air ducts are formed. 11. Electric heating element according to claim 10, characterized in that the carrier is provided on one side with a heat-reflecting layer, the heat-reflecting surface of which is directed away from the rear wall. O? λ '·> ·. * ν '"ν · -10- Electric heating element according to claim 10 or 11, characterized in that the elongated channels are closed in the longitudinal direction at regular distances to form a large number of closed, air-filled compartments on the carrier. Electric heating element according to at least one of claims 2 to 12, characterized in that a layer of heat-insulating material is arranged against the inside of the side walls. Electric heating element according to at least one of claims 2 to 13, characterized in that a layer of heat-insulating material is provided on the transition between each of the side walls and the rear wall. Electric heating element according to at least one of claims 1 to 14, characterized in that the heat-insulating material is made of ceramic fibers. 16. Electric heating element according to claims 8 and 15, characterized in that the part layer furthest from the rear wall consists of a compressed blanket made of ceramic fibers. Electric heating element according to at least one of claims 1 to 16, characterized in that the surfaces with good heat-absorbing properties are provided with a matt black coating. ^ - * \ λ \ i = * - ’Λ. -f