GB2160400A - Radiant heater - Google Patents

Abstract

An electric heater for a glass ceramic top (6) cooker comprises a base layer (1) of thermal insulation material such as ceramic fibre or a microporous thermal insulation, a source of infra-red radiation such as an infra-red lamp (3, 4) and a reflector (7) which is positioned so as to reflect infra-red radiation emitted by the source towards the layer of thermal insulation material. The reflector (7) may be a specular reflector such as a coating of a reflecting metal deposited internally or externally of the source of infra-red radiation or may be a diffuse reflector such as a layer of fine particulate alumina deposited on to the external surface of the source of infra-red radiation. <IMAGE>

Description

SPECIFICATION Electric heaters The present invention relates to electric heaters which incorporate a source of infra-red radiation and to electric cookers incorporating such heaters.

Electric cookers which incorporate infra-red radiation heaters are known, for example, from British Patent Specifications Nos. 1 273 023 and 1 406028. Further, it is known from GB 1 406028 to provide a reflective coating on the bottom half of the infra-red lamp which forms part of the heater so as to reflect infra-red radiation out of the heater.

However, the provision of such a reflective coating can result in an unsatisfactory distribution of infrared radiation from the heater giving rise to undesirably high temperatures adjacent to the or each lamp and can result in non-uniform heating and poor performance of the heater. This problem arises particularly when the infra-red lamp or lamps are confined to a relatively small area of the heater.

A relatively even distribution of infra-red radiation can be achieved by arranging the lamp or lamps towards the bottom of a bowl-shaped heater.

However, there is a demand for heaters to be as shallow as possible which restricts the application of such bowl-shaped reflectors.

It is an object of the present invention to provide an electric heater which incorporates a source of infra-red radiation with a relatively even distribution of infra-red radiation issuing from the heater.

According to one aspect of the present invention there is provided an electric heater which comprises a source of infra-red radiation, a layer of thermal insulation material and a reflector positioned to reflect infra-red radiation emitted by the source towards the layer of thermal insulation material.

The source of infra-red radiation may comprise one or more infra-red lamps.

The layer of thermal insulation material may comprise a ceramic fibre material or a microporous thermal insulation material. The layer of thermal insulation material may be coated with a specular or diffuse infra-red reflecting material or may incorporate a suitable infra-red reflecting material such as titanium dioxide. The layer of thermal insulation material may be supported in a metal dish.

The reflector may be a specular reflector such as a coating of a reflecting metal deposited externally or internally ofthe source of infra-red radiation or may be a metallic reflector positioned externally of the source of infra-red radiation. Alternatively, the reflector may be a diffuse reflector such as a layer of fine particulate alumina deposited onto the external surface of the source of infra-red radiation or may be a suitably shaped body formed of fine particulate alumina or other suitable material arranged externally of the source of infra-red radiation.

According to a further aspect of the present invention there is provided an electric cooker which incorporates one or more electric heaters according to the first aspect of the present invention.

Four a better understanding of the present invention and to show more clearly how it may be carried into effect reference will now be made, by way of example, to the accompanying drawings in which: Figure 1 is a cross-sectional view of an electric heater according to the prior art; Figure 2 is a cross-sectional view of one embodiment of an electric heater according to the present invention; Figures 3 and 4 are graphs showing the temperature of a cooking surface heated by prior art electric heaters; and Figures 5 and 6 are graphs showing the temperature of a cooking surface heated by electric heaters according to the present invention.

Figure 1 shows a layer 11 of a thermal insulation material supported in a metal dish 12. Two infra-red lamps 13, 14 are mounted above the layer 11 and a thermal cut-out device 15 passes over the lamps 13, 14. A smooth cooking surface 16 of an electric cooker extends over the heater and is conventionally made of a glass ceramic material. A reflective coating 17 is provided on the bottom half of the lamps 13, 14 in order to reflect infra-red radiation out of the heater.

Figure 2 shows a layer 1 of thermal insulation material such as ceramic fibre or microporous thermal insulation material supported in a shallow metal dish 2. Mounted above the layer 1 are two infra-red lamps 3, 4, although the number of lamps may be varied so that fewer than two or more than two may be provided. A thermal cut-out device 5 passes over the lamps 3,4 in the illustrated embodiment, but the position of the thermal cut-out device may be varied, for example the thermal cutout device may pass between the lamps 3, 4. A smooth cooking surface 6 of an electric cooker of which the heater forms a part extends over the heater and may be made, for example, of a glass ceramic material.

In contrast with the embodiment of the prior art shown in Figure 1, a reflective coating is not provided on the bottom half of the lamps 3,4 so as to reflect radiation out of the heater, but on the contrary a reflector 7 is arranged over or on the upper portion (with regard to Figure 2) of the lamps so as to reflect infra-red radiation towards the layer 1 of thermal insulation material.

The reflector 7 may be, for example, a specular reflector such as a coating of reflecting metal deposited on the inside or the outside of the quartz tube of the lamp or may be a metallic reflector positioned outside the lamp so as to reflect radiation towards the layer 1. Alternatively, the reflector 7 may be a diffuse reflector such as layer of fine particulate alumina deposited onto the outside of the tube of the lamp or a suitably shaped body formed of fine particulate alumina or other suitable material arranged outside the lamp so as to reflect radiation towards the layer 1.

Because a large proportion of the infra-red radiation emitted by the lamps 3, 4 is directed towards the layer 1, the layer 1 is itself preferably a relatively good reflector of the infra-red radiation.

For example, the layer 1 may be made of, or may be coated with, a diffuse reflecting material or may be coated with a specular reflecting material. However, we have found that a microporous thermal insulation which includes an opacifier, such as titanium dioxide in the form of its ore rutile, is a suitable reflecting material. The other constituents ofthe microporousthermal insulation material may comprise silica aerogel or pyrogenic silica and reinforcing fibres such as aluminosilicate fibres.

We have found that the reflector 7, particularly if only one or two infra-red lamps are used, results in a substantially more uniform distribution of radiation from the heater. This not only increases the efficiency of the heater, but also enhances the optical appearance of the heater when it is energised beneath the cooking surface 6.

Figure 3 is a graph showing the temperature of the cooking surface 6 for the prior art embodiment shown in Figure 1 in which a reflective coating is provided over an angle of about 165" on the bottom of the lamps. It can be seen that two temperature peaks arise, one peak above each lamp. The temperature difference between the peaks and the intermediate trough is approximately 48"C. It will be apparent that the temperature profile is taken in a direction perpendicular to the longitudinal axes of the lamps.

Figure 4 is a graph similarto Figure 3 but for an embodiment in which no reflective coating is provided either above or below the lamps. Figure 4 show that there are still two temperature peaks above the lamps, but that the temperature difference between the peaks and the intermediate trough is approximately 32"C.

Figure 5 is a graph similar to Figure 3 butforthe embodiment according to the present invention shown in Figure 2 in which a reflective coating is provided over an angle of about 165" on the upper portion of the lamps as shown in Figure 2. !t can be seen from Figure 5 that in this embodiment according to the present invention the temperature profile does not reveal any peaks above the lamps.

In the graph shown in Figure 6 the temperature profile is similar to the temperature profile of Figure 5, but the reflective coating is provided only over an angle of 90" on the upper portion of the lamps. The temperature profile shown in Figure 6 is wider and generally flatter than that shown in Figure 5 and there is an indication of a temperature peak on the cooking surface at a point between the lamps.

The heaters used to produce the temperature profiles of Figures 3 to 6 had a heated diameter of 145 mm with two 600 watt infra-red lamps arranged parallel with each other and positioned between a microporous thermal insulation base and a glass ceramic cooking surface. With regard to the temperature profile shown in Figure 6, a coating applied over an angle of 90" may not in all cases be preferable to any other angle, but the optimum coating angle will depend on the configuration of the heater and on the nature of the cooking surface.

In the illustrated embodiment the axes of the lamps were 60 mm apart and the cooking surface was a brown glass ceramic manufactured by Corning Glass Works, Corning, N.Y., U.S.A.

Claims (14)

1. An electric heater which comprises a source of infra-red radiation, a layer of thermal insulation material and a reflector positioned to reflect infra red radiation emitted by the source towards the layer of thermal insulation material.

2. An electric heater as claimed in claim 1, wherein the source of infra-red radiation comprises one or more infra-red lamps.

3. An electric heater as claimed in claims 1 or 2, wherein the layer of thermal insulation material comprises a ceramic fibre material or a microporous thermal insulation material.

4. An electric heater as claimed in claim 1,2 or 3, wherein the layer of thermal insulation material is coated with a specular or diffuse infra-red reflecting material.

5. An electric heater as claimed in claim 1,2or3, wherein the layer of thermal insulation material incorporates a suitable infra-red reflecting material such as titanium dioxide.

6. An electric heater as claimed in any preceding claim, wherein the layer of thermal insulation material is supported in a metal dish.

7. An electric heater as claimed in any preceding claim, wherein the reflector comprises a specular reflector.

8. An electric heater as claimed in claim 7, wherein the reflector comprises a coating of a reflecting metal deposited externally or internally of the source of infra-red radiation.

9. An electric heater as claimed in claim 7, wherein the reflector comprises a metallic reflector positioned externally of the source on infra-red radiation.

10. An electric heater as claimed in any one of claims 1 to 6, wherein the reflector comprises a diffuse reflector.

11. An electric heater as claimed in claim 10, wherein the reflector comprises a layer of fine particulate alumina deposited onto the external surface of the source of infra-red radiation.

12. An electric heater as claimed in claim 10, wherein the reflector comprises a suitably shaped body formed of fine particulate alumina or other suitable material arranged externally of the source of infra-red radiation.

13 An electric heater substantially as hereinbefore described with reference to, and as shown in, Figures 1,4 and 5 of the accompanying drawings.

14. An electric cooker which incorporates one or more electric heaters according to anyone of claims 1 to 13.