Title of Invention	AN INFRARED RADIATING PANEL
Abstract	An infrared radiating panel includes a wall made from ceramic fiber material. An electric heating element is adapted for connection to an electric current source for heating the element to a high temperature at which it will emit infrared radiation is fastened to the wall with the aid of staples. The heating element is mounted in spaced relationa ship with die surface of the wall and is retained between pairs of ceramic rods that engage opposite faces of the heating element.

Title of Invention

AN INFRARED RADIATING PANEL

Abstract

An infrared radiating panel includes a wall made from ceramic fiber material. An electric heating element is adapted for connection to an electric current source for heating the element to a high temperature at which it will emit infrared radiation is fastened to the wall with the aid of staples. The heating element is mounted in spaced relationa ship with die surface of the wall and is retained between pairs of ceramic rods that engage opposite faces of the heating element.

Full Text	The present invention relates to an infrared radiation panel. Infrared radiation panels are known in the art and have been supplied by Kanthal AB, Sweden, among others. Such panels are, in principle, constructed by mounting an electric resistor wire on a wall of ceramic fibre material. The resistor wire is connected to a source of current, so that the wire can be heated to high temperatures, for instance temperatures in the order of 1500-1600°C. The resistor wire then emits infrared radiation. One problem with these known panels is that the effective life of the resistor wire is not sufficiently long in relation to the desired effective life span of the panel. For instance, in the paper industry, where infrared radiation panels could be used to dry paper and paper pulp, a long effective life span is required because of the continuity of the manufacturing processes involved. For instance, the paper industry desires an effective life span of 16000 hours. Known panels that include a known resistor element that are marketed by Kanthal AB under the name Kanthal Super 1800 have an effective life span of 6000 hours. Electric resistor elements of the molybdenum silicide type have long been known. These resistor elements find use primarily in so-called high temperature applications, such as ovens that operate at temperatures of up to about 1700°C. Swedish Patent Specification 458 646 describes the resistor element Kanthal Super 1900. The material used is an homogenous material with the chemical formula MoxW1_xSi2. In the chemical formula, the molybdenum and tungsten are isomorphous and can thus replace one another in the same structure. The material does not consist of a mixture of the materials MoSi2 and Wsi2. SiO2 grows on the surface of the heating element at a parabolic growth rate upon exposure to oxygen at high temperatures, this growth rate being the same irrespective of the cross-sectional dimensions of the heating element. The thickness of the layer may be 0.1 to 0.2 mm after some hundred hours in operation at a temperature of 1850°C,. When cooling down to room temperature, this glass layer will solidify and subject the basic material of the heating element to tension forces owing to the fact that the coefficients of thermal expansion of the basic material differs significantly from that of the glaze. The coefficient of thermal expansion of the glaze is 0.5xlO~ , whereas the thermal coefficient of expansion of the basic material is 7-8xlO~6. These tension forces will, of course, increase with increasing thicknesses of the glaze layer. When the tension forces exceed the mechanical strength of the basic material fractures will occur therein, which takes place when the glaze has grown above a certain critical thickness. In the case of more slender elements, the proportion of the cross-sectional area constituted by the glaze in relation to the basic material will be larger than in the case of coarse elements. The critical glaze thickness will therewith be reached after a much shorter working time in the case of slender elements than in the case of coarser elements at the same working temperature and under the same operating conditions in general. It has been believed hitherto that this has been the dominant factor in the effective life span of an infrared radiation panel. It has been found, however, that the panel construction with respect to the attachment of the resistance wire is highly significant. The present invention provides an infrared radiation panel whose effective life span is much longer than that of known panels when using the same resistance wire. The present invention thus relates to an infrared radiation panel that includes a wall of ceramic fibre material on which an electric resistor element is mounted and which is adapted for connection to a current source so that the resistor element can be heated to a high temperature at which it emits infrared radiation, said resistor element being attached to the wall with the aid of staples, and is characterized in that the resistor element is mounted on the surface of said wall in spaced relationship therewith. The invention will now be described in more detail with reference to an exemplifying embodiment thereof and also with reference to the accompanying drawings, in which X4 Figure 1 illustrates an infrared radiation panel immediately from the front; and - Figure 2 is a sectional view of the panel taken on the line A-A in Figure 1. Figures 1 and 2 illustrate an infrared radiation panel that includes a wall 1 of ceramic fibre material on which an electric resistor element 2 is mounted. The ceramic fibre material may be an aluminium-silicate type material that includes about 50% A12O3. The resistor element is adapted for connection to a source of electric current through the medium of conductors 3, 4, so that the element can be heated to high temperatures at which the resistance wire will emit infrared radiation. The resistance wire is attached to the wall 1 by means of staples 5. The wall 1 is carried by an appropriate material, preferably a sheet 7 whose aluminium oxide content is lower than that of the wall 1. According to the present invention, the resistor element is mounted on the surface 6 of the wall 1 in spaced relationship / therewith. This is a highly significant feature which enables a higher power concentration to be used than that which can be used when the resistor element lies in contact with the wall 1. Because the resistor element is spaced from the wall, the entire outer surface of the element is able to radiate freely. There is also no risk of the element becoming overheated, as in the case when the element 2 is in abutment with the wall 1. This embodiment obviates the necessity to cool the element 2 or its conductors 3, 4. This feature is highly advantageous and enables the efficiency of the delivered power in relation to the radiation power to be increased by 20-30% in comparison with systems that use halogen lamps. The energy density in the infrared radiation can be made from two to three times higher than the energy density achieved with known gas radiators. Radiation of shorter wavelengths is also obtained, which makes for more effective drying operations. Infrared radiation with a main peak at a wavelength of 1.5 micrometers and a secondary peak at 2.2 micrometers is typical of a Kanthal resistor element. The energy density in an inventive panel may reach to 250-340 kw/m2 with an efficiency of above 60% in paper drying. The corresponding energy density of a gas radiator is 90-150 kW/m2 and for an halogen infrared radiator 220-300 kw/m2. A halogen infrared radiator has an efficiency of about 30-40%. It is therefore evident that the invention reduces the cost of necessary equipment, because no cooling is required and the energy density can be high with high efficiency as a result. It is also evident that an infrared radiation panel according to the invention will have a much better performance than a gas radiator and halogen radiator. If the resistor element, or heating element, is allowed to abut the wall 1, the glaze that forms during operation of the element will fasten to the wall. As the element cools, the glaze will first solidify with the serious risk of the element being pulled away as it shrinks, because the tensile strength of the element is lower than the compression strength of the fibre material in the wall and the adhesion of the glaze to the fibre material. According to one highly preferred embodiment of the invention, ceramic rods 8, 10, 12, 14, 16 are disposed in mutually spaced relationship between the wall surface 6 and the resistor element 2. Mutually spaced ceramic rods 9, 11, 13, 15 are also disposed on the other side of the resistor element. The ceramic rods 8-16 are secured to the wall 1 with the aid of staples 5 that engage around respective rods. The rods and the staples are referred to hereinafter as support ceramic. The resistor element 2 is thus held in place between the front and the rear rods and the rods are held in place by the staples. As a result of this very advantageous design, the resistor element will only be in punctiform contact with the support ceramic and the surface area over which the glaze adheres to the support ceramic will be so small that the element will be unable to pull apart the solidified glaze as the element shrinks or contracts. According to one preferred embodiment of the invention, respective ceramic rods on opposite sides of the heating element or heating resistor are offset in relation to one another at a location parallel with the surface of said wall, such that when a ceramic rod 10, 12, 14, 16 is present on one side of the heating resistor 2, there will be no rod on the other side of said heating resistor. Such parallel displacement of the ceramic rods 10, 12 and 14, 16 in relation to the rods 9, 11, 13 and 15 is evident from the drawings. This arrangement avoids so-called hot spots, i.e. points at which the temperature can become higher than the maximum permitted temperature of the resistor element, or heating element, and results in fractures. Because radiation is solely inhibited on one side of the heating element, the temperature at this location will be lower than if the rods were not offset relative to one another in parallelism. It is preferred that the ceramic rods 9-16 are comprised of a ceramic tube within which a rod comprised of resistor-element material extends. This provides security against breakdowns as a result of a ceramic rod breaking. The ceramic rods may, alternatively, be comprised of solid ceramic material. It is also preferred that the ceramic tube accommodating the rods is divided along its length into two or more tubes 17, as illustrated in Figure 1 with the rod 9. This obviates the risk of the ceramic tube being broken as a result of thermal stresses. According to one preferred embodiment, the rod-like resistor element that extends in the ceramic rods is divided into two rods 18, 19 which are attached to the wall 1 such that respective free ends 20, 21 of said rods will not contact one another. This is illustrated in Figure 1 with the rod 18. This enables a higher maximum electric voltage to be applied over respective rods without the occurrence of creep currents and spark-overs or short-circuiting. «.»_rovided outside the wire in at least that region of the staple 5 which comes into contact with the heating element, 3r resistor element 2. This prevents electric short-circuiting between the legs of the element. According to one preferred embodiment of the invention, the surface of the ceramic rods and the ceramic surface of the staples is comprised of a material that has a high A1203 content. The material will preferably have an Al2O3-content of about 99% and an Si02-content of about 1%. It has been found that adhesion between glaze and the support ceramic is much lower when the material used has a high aluminium oxide content than when having a low aluminium oxide content. One important feature of the invention is that respective staples 5 will be spaced from the ceramic rods 9-16 held thereby. This enables the rods to move relative to the staples 5 and also relative to the heating element 2 when the structure moves in response to changes in temperature. According to one highly preferred embodiment, the heating element 2, or resistor element, is comprised of an homogenous silicide material that contains molybdenum and tungsten and has the chemical formula MoxW1_xSi2, where x is between 0.5 and 0.75, and where 10% to 40% of the total weight is replaced by at least one of the compounds molybdenum boride or tungsten boride, said compounds existing in particle form in the silicide material. This material has been found capable of withstanding high temperatures and to give rise to a smaller amount of glaze than earlier elements. The problems associated with element fractures due to adhesion of the glaze to the structure are alleviated when using the aforementioned heating resistor element, while efficiency increases with increasing temperature at the same time. According to one preferred embodiment of the invention, the heating element conductors 3, 4 are glued in the wall 1, 7, with ceramic cement 24 wherein the conductors pass through the wall in a manner which prevents the conductors from rotating about their own axis relative to the wall. Such rotation would otherwise occur when the heating element reaches its operating temperature. Rotation of the conductors is caused by magnetic fields that are generated around the heating element, where the various legs of the element influence one another. Although a panel of one particular design has been described in the aforegoing, it will be understood by the persons skilled in this art that the concept of the invention can be applied to all infrared radiating panels irrespective of the shape of the panel and irrespective of how the heating element is bent. The present invention is therefore not restricted to the aforedescribed and illustrated embodiments thereof, since modifications can be made within the scope of the following Claims. WE CLAIM: 1 An infrared radiating panel which includes a wall (1) comprised of ceramic fibre material on which there is mounted an electric heating element (2) which is adapted for connection to an electric current source for heating the element to a high temperature at which it will emit infrared radiation, said heating element being fastened to said wall with the aid of staples, characterized in that the heating element (2) is mounted in spaced relationship with the surface (6) of said wall (1). 2 A panel as claimed in claim 1, wherein ceramic rods (10, 12, 14, 16) are disposed in mutually spaced relationships and between the wall surface (6) and the heating element (2); in that the ceramic rods (9, 11, 13, 15) are disposed in mutually spaced relationship on the other side of said heating element (2), said ceramic rods being secured to said wall (1) by means of staples (5) that grip around respective ceramic rods (9-16). 3 A panel as claimed in claim 2, wherein said material is comprised of 99% A1203 and about 1% SiO2. 4 A panel as claimed in claim 2 or 3, wherein respective ceramic rods (9-16) on respective sides of the heating element (2) are offset in relation to one another in a plane parallel with said wall surface (6), so that when a ceramic rod is present on one side of the heating element, no rod will be present on the opposite side of said element. 5 ' A panel as claimed in claim 2, 3 or 4, wherein the ceramic rods (8, 9-16) are comprised of ceramic tubes (26) which enclose a rod (25) comprised of heating-resistor material. 6 A panel as claimed in claim 5, wherein the ceramic tubes (26) are divided along their lengths into two or more tubes (17). 7 A panel as claimed in claim 5 or 6, wherein the rod of heating- resistor material is divided into two rods (18, 19) mounted in said wall (1) such that the free ends (20, 21) of said rods (18, 19) do not meet one another. 8 A panel as claimed in any of the preceding claims, wherein the staples (5) are comprised of a wire (27) of heating-resistor material; and in that a ceramic tube (22, 23) is provided outside the wire in at least that region of the staple that comes into contact with the heating element (2). 9 A panel as claimed in any one of claims 2-8, wherein the surfaces of respective ceramic rods (8, 9-16) and the ceramic surfaces of respective staples (5) have a high AlaOa-content. 10 A panel as claimed in any one of claims 2-9, wherein the staples (5) are distanced from the ceramic rods (8, 9-16) held by said staples. 11 A panel as claimed in any one of the preceding claims, wherein the heating element (2) is comprised of an homogenous silicide material that includes molybdenum and tungsten with the chemical formula MoxWi-xSi2, where x is between 0.5 and 0.75, and where 10% to 40% of the total weight is replaced by at least one of the compounds molybdenum boride or tungsten boride; and in that said compounds are present in the silicide material in particle form. 12 A panel as claimed in any one of the preceding claims, wherein conductors (3, 4) of the heating element (2) are glued in the wall (1, 7) with a ceramic cement (24) at that location where the conductors pass through said wall, such that the conductors will be unable to rotate about their own axis relative to the wall (1). 13 An infrared radiating panel substantially as herein described with reference to and as illustrated in the accompanying drawings.

Full Text

The present invention relates to an infrared radiation panel.
Infrared radiation panels are known in the art and have been supplied by Kanthal AB, Sweden, among others.
Such panels are, in principle, constructed by mounting an electric resistor wire on a wall of ceramic fibre material. The resistor wire is connected to a source of current, so that the wire can be heated to high temperatures, for instance temperatures in the order of 1500-1600°C. The resistor wire then emits infrared radiation.
One problem with these known panels is that the effective life of the resistor wire is not sufficiently long in relation to the desired effective life span of the panel. For instance, in the paper industry, where infrared radiation panels could be used to dry paper and paper pulp, a long effective life span is required because of the continuity of the manufacturing processes involved. For instance, the paper industry desires an effective life span of 16000 hours. Known panels that include a known resistor element that are marketed by Kanthal AB under the name Kanthal Super 1800 have an effective life span of 6000 hours.
Electric resistor elements of the molybdenum silicide type have long been known. These resistor elements find use primarily in so-called high temperature applications, such as ovens that operate at temperatures of up to about 1700°C.

Swedish Patent Specification 458 646 describes the resistor element Kanthal Super 1900. The material used is an homogenous material with the chemical formula MoxW1_xSi2. In the chemical formula, the molybdenum and tungsten are isomorphous and can thus replace one another in the same structure. The material does not consist of a mixture of the materials MoSi2 and Wsi2.
SiO2 grows on the surface of the heating element at a parabolic growth rate upon exposure to oxygen at high temperatures, this growth rate being the same irrespective of the cross-sectional dimensions of the heating element. The thickness of the layer may be 0.1 to 0.2 mm after some hundred hours in operation at a temperature of 1850°C,. When cooling down to room temperature, this glass layer will solidify and subject the basic material of the heating element to tension forces owing to the fact that the coefficients of thermal expansion of the basic material differs significantly from that of the glaze. The coefficient of thermal expansion of the glaze is 0.5xlO~ , whereas the thermal coefficient of expansion of the basic material is 7-8xlO~6.
These tension forces will, of course, increase with increasing thicknesses of the glaze layer. When the tension forces exceed the mechanical strength of the basic material fractures will occur therein, which takes place when the glaze has grown above a certain critical thickness.
In the case of more slender elements, the proportion of the cross-sectional area constituted by the glaze in relation to the basic material will be larger than in the case of coarse
elements. The critical glaze thickness will therewith be reached after a much shorter working time in the case of slender elements than in the case of coarser elements at the same working temperature and under the same operating conditions in general.
It has been believed hitherto that this has been the dominant factor in the effective life span of an infrared radiation panel.
It has been found, however, that the panel construction with respect to the attachment of the resistance wire is highly significant.
The present invention provides an infrared radiation panel whose effective life span is much longer than that of known panels when using the same resistance wire.
The present invention thus relates to an infrared radiation panel that includes a wall of ceramic fibre material on which an electric resistor element is mounted and which is adapted for connection to a current source so that the resistor element can be heated to a high temperature at which it emits infrared radiation, said resistor element being attached to the wall with the aid of staples, and is characterized in that the resistor element is mounted on the surface of said wall in spaced relationship therewith.
The invention will now be described in more detail with reference to an exemplifying embodiment thereof and also with reference to the accompanying drawings, in which
X4 Figure 1 illustrates an infrared radiation panel
immediately from the front; and
- Figure 2 is a sectional view of the panel taken on the line A-A in Figure 1.
Figures 1 and 2 illustrate an infrared radiation panel that includes a wall 1 of ceramic fibre material on which an electric resistor element 2 is mounted. The ceramic fibre material may be an aluminium-silicate type material that includes about 50% A12O3. The resistor element is adapted for connection to a source of electric current through the medium of conductors 3, 4, so that the element can be heated to high temperatures at which the resistance wire will emit infrared radiation. The resistance wire is attached to the wall 1 by means of staples 5. The wall 1 is carried by an appropriate material, preferably a sheet 7 whose aluminium oxide content is lower than that of the wall 1.
According to the present invention, the resistor element is
mounted on the surface 6 of the wall 1 in spaced relationship
/ therewith. This is a highly significant feature which enables
a higher power concentration to be used than that which can be used when the resistor element lies in contact with the wall 1. Because the resistor element is spaced from the wall, the entire outer surface of the element is able to radiate freely. There is also no risk of the element becoming overheated, as in the case when the element 2 is in abutment with the wall 1.
This embodiment obviates the necessity to cool the element 2 or its conductors 3, 4. This feature is highly advantageous
and enables the efficiency of the delivered power in relation to the radiation power to be increased by 20-30% in comparison with systems that use halogen lamps.
The energy density in the infrared radiation can be made from two to three times higher than the energy density achieved with known gas radiators. Radiation of shorter wavelengths is also obtained, which makes for more effective drying operations. Infrared radiation with a main peak at a wavelength of 1.5 micrometers and a secondary peak at 2.2 micrometers is typical of a Kanthal resistor element.
The energy density in an inventive panel may reach to 250-340 kw/m2 with an efficiency of above 60% in paper drying. The corresponding energy density of a gas radiator is 90-150 kW/m2 and for an halogen infrared radiator 220-300 kw/m2. A halogen infrared radiator has an efficiency of about 30-40%.
It is therefore evident that the invention reduces the cost of necessary equipment, because no cooling is required and the energy density can be high with high efficiency as a result. It is also evident that an infrared radiation panel according to the invention will have a much better performance than a gas radiator and halogen radiator.
If the resistor element, or heating element, is allowed to abut the wall 1, the glaze that forms during operation of the element will fasten to the wall. As the element cools, the glaze will first solidify with the serious risk of the element being pulled away as it shrinks, because the tensile strength of the element is lower than the compression
strength of the fibre material in the wall and the adhesion of the glaze to the fibre material.
According to one highly preferred embodiment of the invention, ceramic rods 8, 10, 12, 14, 16 are disposed in mutually spaced relationship between the wall surface 6 and the resistor element 2. Mutually spaced ceramic rods 9, 11, 13, 15 are also disposed on the other side of the resistor element.
The ceramic rods 8-16 are secured to the wall 1 with the aid of staples 5 that engage around respective rods. The rods and the staples are referred to hereinafter as support ceramic.
The resistor element 2 is thus held in place between the front and the rear rods and the rods are held in place by the staples.
As a result of this very advantageous design, the resistor element will only be in punctiform contact with the support ceramic and the surface area over which the glaze adheres to the support ceramic will be so small that the element will be unable to pull apart the solidified glaze as the element shrinks or contracts.
According to one preferred embodiment of the invention, respective ceramic rods on opposite sides of the heating element or heating resistor are offset in relation to one another at a location parallel with the surface of said wall, such that when a ceramic rod 10, 12, 14, 16 is present on one side of the heating resistor 2, there will be no rod on the other side of said heating resistor. Such parallel
displacement of the ceramic rods 10, 12 and 14, 16 in relation to the rods 9, 11, 13 and 15 is evident from the drawings.
This arrangement avoids so-called hot spots, i.e. points at which the temperature can become higher than the maximum permitted temperature of the resistor element, or heating element, and results in fractures. Because radiation is solely inhibited on one side of the heating element, the temperature at this location will be lower than if the rods were not offset relative to one another in parallelism.
It is preferred that the ceramic rods 9-16 are comprised of a ceramic tube within which a rod comprised of resistor-element material extends. This provides security against breakdowns as a result of a ceramic rod breaking. The ceramic rods may, alternatively, be comprised of solid ceramic material.
It is also preferred that the ceramic tube accommodating the rods is divided along its length into two or more tubes 17, as illustrated in Figure 1 with the rod 9. This obviates the risk of the ceramic tube being broken as a result of thermal stresses.
According to one preferred embodiment, the rod-like resistor element that extends in the ceramic rods is divided into two rods 18, 19 which are attached to the wall 1 such that respective free ends 20, 21 of said rods will not contact one another. This is illustrated in Figure 1 with the rod 18. This enables a higher maximum electric voltage to be applied over respective rods without the occurrence of creep currents and spark-overs or short-circuiting.
«.»_rovided outside the wire in at least that region of the staple 5 which comes into contact with the heating element, 3r resistor element 2. This prevents electric short-circuiting between the legs of the element.
According to one preferred embodiment of the invention, the surface of the ceramic rods and the ceramic surface of the staples is comprised of a material that has a high A1203 content. The material will preferably have an Al2O3-content of about 99% and an Si02-content of about 1%. It has been found that adhesion between glaze and the support ceramic is much lower when the material used has a high aluminium oxide content than when having a low aluminium oxide content.
One important feature of the invention is that respective staples 5 will be spaced from the ceramic rods 9-16 held thereby. This enables the rods to move relative to the staples 5 and also relative to the heating element 2 when the structure moves in response to changes in temperature.
According to one highly preferred embodiment, the heating element 2, or resistor element, is comprised of an homogenous silicide material that contains molybdenum and tungsten and has the chemical formula MoxW1_xSi2, where x is between 0.5 and 0.75, and where 10% to 40% of the total weight is replaced by at least one of the compounds molybdenum boride or tungsten boride, said compounds existing in particle form in the silicide material.
This material has been found capable of withstanding high temperatures and to give rise to a smaller amount of glaze than earlier elements. The problems associated with element fractures due to adhesion of the glaze to the structure are alleviated when using the aforementioned heating resistor element, while efficiency increases with increasing temperature at the same time.
According to one preferred embodiment of the invention, the heating element conductors 3, 4 are glued in the wall 1, 7, with ceramic cement 24 wherein the conductors pass through the wall in a manner which prevents the conductors from rotating about their own axis relative to the wall. Such rotation would otherwise occur when the heating element reaches its operating temperature. Rotation of the conductors is caused by magnetic fields that are generated around the heating element, where the various legs of the element influence one another.
Although a panel of one particular design has been described in the aforegoing, it will be understood by the persons skilled in this art that the concept of the invention can be applied to all infrared radiating panels irrespective of the shape of the panel and irrespective of how the heating element is bent.
The present invention is therefore not restricted to the aforedescribed and illustrated embodiments thereof, since modifications can be made within the scope of the following Claims.

WE CLAIM:
1 An infrared radiating panel which includes a wall (1) comprised
of ceramic fibre material on which there is mounted an electric
heating element (2) which is adapted for connection to an electric
current source for heating the element to a high temperature at which
it will emit infrared radiation, said heating element being fastened to
said wall with the aid of staples, characterized in that the heating
element (2) is mounted in spaced relationship with the surface (6) of
said wall (1).
2 A panel as claimed in claim 1, wherein ceramic rods (10, 12,
14, 16) are disposed in mutually spaced relationships and between
the wall surface (6) and the heating element (2); in that the ceramic
rods (9, 11, 13, 15) are disposed in mutually spaced relationship on
the other side of said heating element (2), said ceramic rods being
secured to said wall (1) by means of staples (5) that grip around
respective ceramic rods (9-16).
3 A panel as claimed in claim 2, wherein said material is
comprised of 99% A1203 and about 1% SiO2.
4 A panel as claimed in claim 2 or 3, wherein respective ceramic
rods (9-16) on respective sides of the heating element (2) are offset in
relation to one another in a plane parallel with said wall surface (6),
so that when a ceramic rod is present on one side of the heating
element, no rod will be present on the opposite side of said element.
5 ' A panel as claimed in claim 2, 3 or 4, wherein the ceramic rods
(8, 9-16) are comprised of ceramic tubes (26) which enclose a rod (25)
comprised of heating-resistor material.
6 A panel as claimed in claim 5, wherein the ceramic tubes (26)
are divided along their lengths into two or more tubes (17).
7 A panel as claimed in claim 5 or 6, wherein the rod of heating-
resistor material is divided into two rods (18, 19) mounted in said wall
(1) such that the free ends (20, 21) of said rods (18, 19) do not meet
one another.

8 A panel as claimed in any of the preceding claims, wherein the
staples (5) are comprised of a wire (27) of heating-resistor material;
and in that a ceramic tube (22, 23) is provided outside the wire in at
least that region of the staple that comes into contact with the heating
element (2).
9 A panel as claimed in any one of claims 2-8, wherein the
surfaces of respective ceramic rods (8, 9-16) and the ceramic surfaces
of respective staples (5) have a high AlaOa-content.
10 A panel as claimed in any one of claims 2-9, wherein the staples
(5) are distanced from the ceramic rods (8, 9-16) held by said staples.
11 A panel as claimed in any one of the preceding claims, wherein
the heating element (2) is comprised of an homogenous silicide
material that includes molybdenum and tungsten with the chemical
formula MoxWi-xSi2, where x is between 0.5 and 0.75, and where 10%
to 40% of the total weight is replaced by at least one of the
compounds molybdenum boride or tungsten boride; and in that said
compounds are present in the silicide material in particle form.
12 A panel as claimed in any one of the preceding claims, wherein
conductors (3, 4) of the heating element (2) are glued in the wall (1, 7)
with a ceramic cement (24) at that location where the conductors pass
through said wall, such that the conductors will be unable to rotate
about their own axis relative to the wall (1).
13 An infrared radiating panel substantially as herein described
with reference to and as illustrated in the accompanying drawings.

Documents:

140-del-1998-abstract.pdf

140-del-1998-assignment.pdf

140-del-1998-claims.pdf

140-del-1998-Correspondence-Others-(12-10-2012).pdf

140-del-1998-Correspondence-Others-(15-10-2012).pdf

140-del-1998-correspondence-others.pdf

140-del-1998-correspondence-po.pdf

140-del-1998-descripton (complete).pdf

140-del-1998-drawings.pdf

140-del-1998-form-1.pdf

140-del-1998-form-13.pdf

140-del-1998-form-19.pdf

140-del-1998-form-2.pdf

140-del-1998-form-3.pdf

140-del-1998-form-4.pdf

140-del-1998-form-6.pdf

140-del-1998-gpa.pdf

140-del-1998-petition-137.pdf

140-del-1998-petition-138.pdf

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Patent Number

259537

Indian Patent Application Number

140/DEL/1998

PG Journal Number

12/2014

Publication Date

21-Mar-2014

Grant Date

15-Mar-2014

Date of Filing

19-Jan-1998

Name of Patentee

SANDVIK INTELLECTUAL PROPERTY AB

Applicant Address

S-811 81 SANDVIKEN, SWEDEN,

Inventors:

#	Inventor's Name	Inventor's Address
1	LARS GORAN JOHANSSON	SMULTRONVAGEN 10, S-734 31 HALLSTAHAMMER, SWEDEN

PCT International Classification Number

H05B 3/06

PCT International Application Number

N/A

PCT International Filing date

PCT Conventions:

#	PCT Application Number	Date of Convention	Priority Country
1	9700267.9	1997-01-29	Sweden