JPH08159484A - Heating and cooking device - Google Patents

Abstract

PURPOSE: To realize a heat source part of less-expensive price of a thermal insulating configuration with a superior reduction in increasing of temperature at a cooking heater case and with a superior productivity in an application of a material of the heating device case and a thermal insulation configuration in a heating and cooking device in which a halogen lamp for radiating far- infrared rays is applied as the heating source. CONSTITUTION: A hating top part 2 is provided with a glass 2a for passing far-infrared rays, and a heat source part 3 having a lamp heater 7 for radiating far-infrared rays therein while its upper surface opening is being abutted against the glass 2a is installed just below the heating top part 2. A heating device case 13 of the heat source part 3 is made of an aluminum material having a high reflection rate, its outer wall surface is hot melted with ceramics 14 to make a thermal insulating layer thereat, so that the efficiency of the heated item for a far-infrared ray energy is improved more.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a heating cooker having a lamp heater such as a halogen lamp emitting infrared rays as a heat source.

[0002]

2. Description of the Related Art Conventionally, there has been a heating cooker 1 using a lamp heater such as a halogen lamp which emits infrared rays as a heat source, as shown in FIGS. In FIG. 7 and FIG. 8, the heating top portion 2 is provided with the glass 2a that transmits infrared rays, and the heat source portion 3 is provided immediately below the glass 2a. The heat source unit 3 includes a heat insulating material A5 on the floor surface inside the stove case 4 and a heat insulating material B6 on the side surface.
Further, a plurality of (for example, four) lamp heaters 7 for radiating infrared rays are arranged in parallel inside, and the upper part is in contact with the heating top portion 2.

The lamp heater 7 emits high heat while emitting light through a quartz tube such as a halogen lamp. An example of this is disclosed in Japanese Utility Model Laid-Open No. 62-25496.

Further, the operation section 8 is provided with a driving ON / OFF switch SW9 and a heat source section ON / OFF switch SW10. Then, in the heating cooker 1, when the operation ON / OFF switch SW9 and the heat source part ON / OFF switch SW10 are turned on to start energization, the plurality of lamp heaters 7 inside the heat source part 3 generate heat and the crystallized glass 2a of the top heating part 2 just above. The object to be heated (not shown) such as a pan is heated by radiation and conduction.

Next, another conventional example is shown in FIG. Heat source part 3
Has a heat insulating material 11 inside the stove case 4 and further has a reflector 12 inside. A plurality of (for example, four) lamp heaters 7 for radiating infrared rays are arranged in parallel inside the reflection plate 12, and the upper part of the heating top portion 2 is arranged above.
Is in contact with

The lamp heater 7 emits light through a quartz tube such as a halogen lamp and emits high heat. An example of this is described in JP-A-2-94386.

[0007]

However, although the former type of the heating cooker 1 having the heating top portion 2 made of glass has excellent heat insulation performance, a low heat conductivity heat insulation material having good heat insulation performance has poor moldability. Awkward. Therefore, it is formed by a three-piece member or a two-piece member, so that the number of assembling steps is time-consuming and the cost is high. Although the latter is excellent in energy efficiency by making it a heat source part configured to reflect infrared rays by a reflector, it is surrounded by a heat insulating material for heat insulation because the temperature of the reflector becomes high. Although not expensive, there were similar problems.

The present invention has been made to solve the above-mentioned problems, in which the stove case serving as the heat source is made of an aluminum material having the highest infrared reflectance, and the outer wall surface is thermally sprayed with a ceramic instead of a heat insulating material. The first purpose is to realize a stove case at a low cost.

Further, the stove case as the heat source is made of an aluminum material having the highest reflectance of infrared rays and has a double structure of an inner circumference and an outer circumference, and a ceramic is sprayed on the outer wall surface of the outer circumference to have a heat insulation structure. The second purpose is to improve the heat insulation performance and to realize a stove case at a low cost without using a heat insulation material.

Further, the stove case as the heat source is made of an aluminum material having the highest infrared reflectance, and the infrared reflecting ceramic is coated on the lower surface of the lamp heater, so that the temperature rise of the aluminum material can be reduced. The third object of the present invention is to simplify the heat insulating structure of the heat insulating material, reduce the number of assembling steps, and realize the stove case at a low cost.

A fourth object of the present invention is to realize a stove case at a low cost, in which the stove case of the heat source section is made of a metal material and the inner peripheral wall surface is thermally sprayed with ceramics to form a heat insulating structure.

Further, the stove case as the heat source section is made of an aluminum material having the highest infrared reflectance, and a low heat conductivity heat insulating material of a molded product type is inserted on the outer periphery of the stove case, so that the number of assembling steps can be reduced. The fifth object is to realize a stove case at a low cost.

[0013]

In order to achieve the first object of the present invention, a glass for transmitting infrared rays is provided in a heating top portion, and an opening of an upper surface is brought into contact with the glass immediately below the infrared rays so that infrared rays can be emitted inside the glass. A heat source section having a radiating lamp heater is provided, and the stove case of the heat source section is made of an aluminum material having a high reflectance of infrared rays, and a ceramic is sprayed on the outer wall surface of the stove case to form a heat insulating structure.

Further, in order to achieve the second object, a glass for transmitting infrared rays is provided in the heating top portion, and a heat source portion having a lamp heater for directly radiating infrared rays inside thereof is provided with an upper surface opening portion abutting the glass directly below. The stove case of the heat source section is made of an aluminum material having a high infrared reflectance and has a double structure of an inner circumference and an outer circumference, and a ceramic is sprayed on the outer wall surface of the outer circumference to have a heat insulation structure.

Further, in order to achieve the third object, a glass for transmitting infrared rays is provided in the heating top portion, and a heat source portion having a lamp heater for directly radiating infrared rays inside thereof is provided with an upper surface opening portion abutting the glass. The heat source stove case is made of an aluminum material having a high reflectance of infrared rays, and the outer wall surface is thermally sprayed with a ceramic to form an adiabatic structure, and the infrared ray-reflecting ceramic is coated on the lower surface of the lamp heater. It is a thing.

Further, in order to achieve the fourth object, a glass for transmitting infrared rays is provided in the heating top portion, and a heat source portion having a lamp heater for radiating infrared rays to the inside by directly contacting an opening of an upper surface of the glass directly below the glass. And a stove case of the heat source section is made of a metal material, and a ceramic is sprayed on the inner peripheral wall surface of the metal material to form a heat insulating structure.

Further, in order to achieve the fifth object, a glass for transmitting infrared rays is provided in the heating top portion, and a heat source portion having a lamp heater for radiating infrared rays inside thereof is provided immediately below the upper opening portion abutting the glass. The stove case is made of an aluminum material having a high infrared ray reflectance, and a low-thermal-conductivity heat insulating material of a molded product type is inserted on the outer periphery of the stove case.

[0018]

With the above construction, the present invention makes it possible to reflect the infrared rays of the lamp heater toward the glass directly above by using an aluminum material for the stove case as the heat source. As a result, the absorption rate of infrared energy to the object to be heated is increased. Therefore, the aluminum material of the stove case does not increase in temperature so much that the ceramic material is sprayed on the outer wall surface of the stove case.

Further, since the stove case has a double structure of the inner circumference and the outer circumference, it is air layer heat insulation and the heat insulation effect is improved, so that the outer wall surface of the outer circumference is sprayed with ceramics. .

The lower surface of the lamp heater is coated with ceramic. Thereby, the infrared rays of the lamp heater are mainly radiated toward the glass directly above and the radiation toward the aluminum material is reduced. Therefore, the temperature rise of the aluminum material does not become too high.

Further, the stove case of the heat source section is made of a metal material, and the inner peripheral wall surface of the metal material is thermally sprayed with a ceramic so as to have a heat insulating structure. As a result, a stove case is realized with an inexpensive material obtained by surface-treating an iron plate.

Further, a low thermal conductivity heat insulating material of a molded product type is inserted around the outer periphery of the stove case.

[0023]

Embodiments of the present invention will be described below with reference to FIGS.

A heating cooker 1 according to a first embodiment of the present invention will be described with reference to FIGS. 1 and 2. The heating top portion 2 is provided with glass 2a that transmits infrared rays, and the heat source portion 3 is provided immediately below the glass 2a. The heat source unit 3 is composed of a stove case 13 in which a plurality of (for example, four) lamp heaters 7 for radiating infrared rays are arranged in parallel, and is made of an aluminum material 13a having the highest reflectance with respect to infrared rays. The surface of the lamp heater 7 side is chemically polished. Further, the stove case 13 has an extremely large radius at the corners 13b and 13c, and has a heat insulating structure in which a ceramic 14 is sprayed on the outer wall surface.

At this time, the material of the ceramic 14 is A
Those having a low thermal conductivity such as ZrO ₂ and TiO ₂ are preferable to l ₂ O ₃ .

Further, the operation section 8 is provided with a driving ON / OFF switch SW9 and a heat source section ON / OFF switch SW10. Then, in the heating cooker 1, when the operation ON / OFF switch SW9 and the heat source part ON / OFF switch SW10 are turned on to start energization, the plurality of lamp heaters 7 inside the heat source part 3 generate heat and the crystallized glass 2a of the top heating part 2 just above. And heats an object to be heated (not shown) such as a pan by radiation and conduction.

The operation of the configuration shown in FIGS. 1 and 2 will be described. In the heating cooker 1 having glass as the heating top portion 2, when the operation ON / OFF switch SW9 and the heat source portion ON / OFF switch SW10 are turned on to start energization, a plurality of lamp heaters 7 inside the heat source portion 3 generate heat and the top heating portion immediately above is provided. An object to be heated (not shown) such as a pot is heated by radiation and conduction through the second glass 2a.

At this time, the stove case 13 is made of an aluminum material 13a having the highest reflectance with respect to infrared rays, and the reflectance is further increased by chemically polishing the surface of the aluminum material 13a on the lamp heater 7 side.
As a result, infrared rays from the lamp heater 7 having a quartz tube lamp configuration are reflected toward the crystallized glass 2a immediately above. That is, the absorption rate of infrared energy to the object to be heated is increased. Therefore, the temperature rise of the aluminum material 13a of the stove case 13 does not become so high that the outer wall surface of the stove case 13 is thermally sprayed with the ceramic 14.

Further, the stove case 13 has a corner portion 13
By making the radiuses of b and 13c extremely large, the ceramic 14 is easily sprayed.

As described above, according to the first embodiment of the present invention, the stove case as the heat source is made of the aluminum material having the highest infrared reflectance, and the surface of the A1 material 13a is chemically polished. The efficiency of infrared energy to the object to be heated is further enhanced by spraying ceramics on the outer wall surface instead of a heat insulating material to form a heat insulating structure. In addition, the number of assembling steps can be reduced and an inexpensive stove case can be realized. Further, by increasing the bending radius of the corner of the stove case, there is an effect that ceramic spraying is easy.

A second embodiment of the present invention will be described with reference to FIG. Glass 2a that transmits infrared rays to the heating top portion 2
Is provided, and the heat source unit 3 is provided immediately below. The heat source part 3 is a double layer composed of the stove case 15, and the inner peripheral wall 15
a is made of an aluminum material having the highest reflectance with respect to infrared rays, and a plurality of (for example, four) lamp heaters 7 for radiating infrared rays are arranged in parallel inside. Further, the surface on the lamp heater 7 side is chemically polished. Then, the outer peripheral wall 15b is made of a metal material whose surface is treated on an iron plate,
The corners 15c and 15d are extremely large in radius, and the outer wall surface is thermally insulatively coated with the ceramic 16. That is, the air insulation region 15e is provided. At this time, the material of the ceramic 16 is Al ₂ O ₃
The material has a degree of thermal conductivity.

Further, the operation section 8 is provided with a driving ON / OFF switch SW9 and a heat source section ON / OFF switch SW10. Then, in the heating cooker 1, when the operation ON / OFF switch SW9 and the heat source part ON / OFF switch SW10 are turned on to start energization, the plurality of lamp heaters 7 inside the heat source part 3 generate heat and the crystallized glass 2a of the top heating part 2 just above. And heats an object to be heated (not shown) such as a pan by radiation and conduction.

The operation of the configuration shown in FIG. 3 will be described.
In the heating cooker 1 having the glass heating top part 2, when the operation ON / OFF switch SW9 and the heat source part ON / OFF switch SW10 are turned on to start energization, a plurality of lamp heaters 7 inside the heating source part 3 generate heat and the top part immediately above is heated. An object to be heated (not shown) such as a pot is heated by radiation and conduction through the glass 2a of the heating unit 2. At this time, the stove case 15 has a double layer structure, and the inner peripheral wall 15a is made of an aluminum material having a high reflectance, and the surface is chemically polished to increase the reflectance. As a result, infrared rays from the lamp heater 7 are reflected toward the glass 2a immediately above. In addition, the provision of the air insulation area 15e,
The thermal insulation effect becomes large by adopting the thermal insulation structure in which the ceramic 16 is sprayed on the outer peripheral wall 15b.

Further, the outer peripheral wall 15b has a corner portion 15c,
By making the radius of 15d extremely large, the ceramic 16 is made to be easily sprayed.

As described above, according to the second embodiment of the present invention, the stove case as the heat source part is made of aluminum material, the surface is chemically polished, and the stove case has a double structure of the inner and outer peripheries. As a result, the efficiency of infrared energy to the object to be heated is increased. Further, since it is air-insulated and the heat insulating effect is further improved, only thermal spraying on the outer wall surface of the outer circumference is required. Further, the number of assembling steps can be reduced and the stove case can be provided at a low cost. Further, by increasing the bending radius of the corner of the stove case, there is an effect that ceramic spraying is easy.

As a third embodiment of the present invention, there is a heating cooker 1 shown in FIG. That is, the heating top portion 2 is provided with the glass 2a that transmits infrared rays, and the heat source portion 3 is provided immediately below. The heat source unit 3 is composed of a stove case 17 in which a plurality (for example, four) of lamp heaters 19 for radiating infrared rays are arranged in parallel, and is made of an aluminum material 17a having the highest reflectance with respect to infrared rays. The surface on the lamp heater 19 side is chemically polished. Further, the lamp heater 19 having a quartz tube lamp has a coating 20 of a ceramic 20 that reflects infrared rays on the lower surface of the lamp.

Further, the stove case 17 has a corner portion 17
The radiuses of b and 17c are made extremely large, and the ceramics 18 is thermally sprayed on the outer wall surface.

At this time, the material of the ceramic 18 is A
Those having a low thermal conductivity such as ZrO ₂ and TiO ₂ are preferable to l ₂ O ₃ .

Further, the operation section 8 is provided with a driving ON / OFF switch SW9 and a heat source section ON / OFF switch SW10. Then, in the heating cooker 1, when the operation ON / OFF switch SW9 and the heat source part ON / OFF switch SW10 are turned on to start energization, a plurality of lamp heaters 7 inside the heat source part 3 generate heat and penetrate the glass 2a of the top heating part 2 immediately above. The object to be heated (not shown) such as a pan is heated by radiation and conduction.

The operation of the configuration shown in FIG. 4 will be described.
In the heating cooker 1 having the glass as the heating top portion 2, when the operation ON / OFF switch SW9 and the heat source portion ON / OFF switch SW10 are turned on to start energization, the plurality of lamp heaters 7 inside the heating source portion 3 generate heat and the top heating portion just above is heated. An object to be heated (not shown) such as a pot is heated by radiation and conduction through the crystallized glass 2a of the part 2.

At this time, the stove case 17 is made of an aluminum material 17a having the highest reflectance with respect to infrared rays, and the reflectance is increased by chemically polishing the surface of the aluminum material 17a on the lamp heater 19 side. . As a result, the lamp heater 1 having a quartz tube lamp configuration
Infrared rays from 9 are reflected toward the crystallized glass 2a immediately above.

That is, the absorption rate of infrared energy to the object to be heated is increased. Therefore, since the temperature rise of the aluminum material 17a of the stove case 17 does not become so high, the ceramic material 18 is thermally sprayed on the outer wall surface of the stove case 17. Further, the lamp heater 19 having a quartz tube lamp has a ceramic 20 that reflects infrared rays coated on the lower surface of the lamp. As a result, the temperature of the aluminum material 17a does not rise too high.

Further, the stove case 17 has a corner portion 17
By making the radiuses of b and 17c extremely large, the ceramic 18 is easily sprayed.

As described above, according to the third embodiment of the present invention, the effect obtained by using the aluminum material having the highest infrared reflectance as the stove case as the heat source and polishing the surface has the effect of the first embodiment. Similar to the example. Further, by coating the lower surface of the lamp heater with a ceramic that reflects infrared rays, the temperature rise of the aluminum material can be reduced, and the life can be further improved.
In addition, there is an effect that the heat insulation performance is improved.

A fourth embodiment of the present invention will be described with reference to FIG. Glass 2a that transmits infrared rays to the heating top portion 2
The heat source part 3 is provided immediately below. The heat source part 3 is composed of a stove case 21, is made of a metal material 21a, and has a heat insulating structure by spraying a ceramic 22 on the inner peripheral wall surface. Furthermore, a lamp heater 7 that radiates infrared rays inside
Are arranged in parallel (for example, four). This time,
The material of the ceramic 22 is ZrO rather than Al ₂ O _3.
A low thermal conductivity such as ₂ is preferable.

Further, the operation section 9 is provided with a driving ON / OFF switch SW9 and a heat source section ON / OFF switch SW10. Then, in the heating cooker 1, when the operation ON / OFF switch SW9 and the heat source part ON / OFF switch SW10 are turned on to start energization, a plurality of lamp heaters 7 inside the heat source part 3 generate heat and penetrate the glass 2a of the top heating part 2 immediately above. An object to be heated (not shown) such as a pan is heated by radiation and conduction.

The operation of the configuration shown in FIG. 5 will be described.
In the heating cooker 1 having glass as the heating top portion 2, when the operation ON / OFF switch SW9 and the heat source portion ON / OFF switch SW10 are turned on to start energization, a plurality of lamp heaters 7 inside the heat source portion 3 generate heat and the top heating portion immediately above is provided. An object to be heated (not shown) such as a pot is heated by radiation and conduction through the second glass 2a.

At this time, the stove case 21 has a heat insulating structure by spraying the ceramic 22 on the inner peripheral wall thereof. Ceramic 2
Since 2 has a low thermal conductivity such as Al ₂ O ₃ or ZrO _2, the metal material 21a of the stove case 21 does not rise to a very high temperature, so an iron plate may be surface-treated.

As described above, according to the fourth embodiment of the present invention, the stove case of the heat source portion is made of a metal material, and the inner peripheral wall surface is thermally sprayed with ceramics to form a heat insulating structure, which is less expensive than the A1 material. Becomes In addition, since the outer circumference of the ceramics is thermally sprayed to form a heat insulating structure and the metal material is used, and the temperature of the metal material portion is low, there is no temperature deterioration. Further, the effect of using no heat insulating material is similar to that of the first embodiment.

It is also possible to combine a lamp heater having a quartz tube lamp with a ceramic that reflects infrared rays on the lower surface of the lamp. According to this, a more adiabatic effect can be obtained.

As a fifth embodiment of the present invention, there is a heating cooker 1 shown in FIG. That is, the heating top portion 2 is provided with the glass 2a that transmits infrared rays, and the heat source portion 3 is provided immediately below. The heat source unit 3 includes a stove case 2 in which a plurality of (for example, four) lamp heaters 7 that emit infrared rays are arranged in parallel.
3, the aluminum material 23a having the highest reflectance with respect to infrared rays, and the lamp heater 7
The side surface is chemically polished. Furthermore, the stove case 2
A heat insulating material 24 of a molded product type corresponding to the size and shape of the stove case 23 is inserted on the outer circumference of the No.

At this time, the material of the heat insulating material 24 is Al
It is made into fibers based on materials such as O ₂ O ₃ and SiO ₂ .

Further, the operation section 8 is provided with a driving ON / OFF switch SW9 and a heat source section ON / OFF switch SW10. Then, in the heating cooker 1, when the operation ON / OFF switch SW9 and the heat source part ON / OFF switch SW10 are turned on to start energization, a plurality of lamp heaters 7 inside the heat source part 3 generate heat and penetrate the glass 2a of the top heating part 2 immediately above. An object to be heated (not shown) such as a pan is heated by radiation and conduction.

The operation of the configuration shown in FIG. 6 will be described.
In the heating cooker 1 having glass as the heating top portion 2, when the operation ON / OFF switch SW9 and the heat source portion ON / OFF switch SW10 are turned on to start energization, a plurality of lamp heaters 7 inside the heat source portion 3 generate heat and the top heating portion immediately above is provided. An object to be heated (not shown) such as a pot is heated by radiation and conduction through the crystallized glass 2a of FIG.

At this time, the stove case 23 is made of an aluminum material 23a having the highest reflectance with respect to infrared rays, and the reflectance is enhanced by chemically polishing the surface of the aluminum material 23a on the lamp heater 7 side. As a result, infrared rays from the lamp heater 7 having a quartz tube lamp configuration are reflected toward the crystallized glass 2a immediately above. That is, the absorption rate of infrared energy to the object to be heated is increased. Therefore, the aluminum material 23a of the stove case 23 suppresses the temperature rise, so that the heat insulating material 24 of the molded product type is used.

As described above, according to the fifth embodiment of the present invention, the effect obtained by using the aluminum material having the highest infrared reflectance as the stove case as the heat source and polishing the surface has the effect of the first embodiment. Similar to the example. Further, the constant heat conductivity heat insulating material of the molded product type is inserted into the outer periphery of the stove case, which is advantageous in that the number of assembling steps can be reduced and the stove case can be realized at low cost.

It is also possible to consider a combination in which the lamp heater having a quartz tube lamp is coated with a ceramic for reflecting infrared rays on the lower surface of the lamp. According to this, a more adiabatic effect can be obtained.

[0058]

As described above, in the heating cooker of the present invention, the stove case as the heat source is made of the aluminum material having the highest infrared reflectance, and the outer wall surface is sprayed with the ceramic rather than the heat insulating material so as to have the heat insulating structure. By doing so, the efficiency of infrared energy to the object to be heated is further increased. In addition, the number of assembly steps can be reduced and an inexpensive stove case can be realized.

Further, the stove case as the heat source section is made of an aluminum material having the highest infrared reflectance, and the stove case has a double structure of the inner and outer circumferences, whereby the efficiency of infrared energy to the object to be heated is further improved. I am raising. Also, since it is air-insulated, the heat-insulating effect is greatly improved.
Furthermore, this only requires that the outer peripheral wall surface be sprayed with ceramic.

Further, by making the stove case as the heat source part an aluminum material having the highest reflectance of infrared rays, the infrared rays of the lamp heater mainly radiate toward the glass directly above due to the ceramic coating of the lamp heater. It reduces the radiation toward the. Therefore, the aluminum material has a smaller temperature rise than that without the ceramic coating, and the performance deterioration of the aluminum material is less. Further, since the temperature of the aluminum material does not become too high, the thermal spraying performance of the ceramic sprayed material on the outer wall surface can be ensured with Al ₂ O _{3 which} is relatively inexpensive.

Further, the stove case is made of a metal material such as iron as the heat source part, and the inner peripheral wall surface is thermally sprayed with a ceramic so as to have a heat insulating structure. The temperature rise due to absorption of infrared rays from the lamp heater causes the ceramic spraying. Since it does not reach a high temperature compared to the case without it, a stove case can be realized with an inexpensive material that is surface-treated on an iron plate. In addition, no heat insulation material is realized,
There is an effect that the number of assembling steps can be reduced and the stove case can be realized at a low cost.

Further, the stove case as the heat source is made of an aluminum material having the highest infrared reflectance, and a low heat conductivity heat insulating material of a molded product type is inserted around the outer circumference of the stove case. Since the temperature rise due to absorption reflects much on the aluminum material, the temperature does not become higher than that of the one that is directly insulated by the heat insulating material, so it does not have to be an extremely low thermal conductivity heat insulating material which is expensive as an insulating material and it is cheaper. . Further, since it is not necessary to use an extremely low thermal conductivity heat insulating material, a molded product mold can be realized, and the number of assembling steps can be reduced.

[Brief description of drawings]

FIG. 1 is an external view of a heating cooker according to a first embodiment of the present invention.

FIG. 2 is a sectional view of the main part of the heating cooker.

FIG. 3 is a sectional view of a heating cooker according to a second embodiment of the present invention.

FIG. 4 is a sectional view of a heating cooker according to a third embodiment of the present invention.

FIG. 5 is a sectional view of a heating cooker according to a fourth embodiment of the present invention.

FIG. 6 is a sectional view of a heating cooker according to a fifth embodiment of the present invention.

FIG. 7 is an external view of a conventional cooking device.

FIG. 8 is a cross-sectional view of the main parts of the heating cooker.

FIG. 9 is a cross-sectional view of the main parts of the heating cooker.

[Explanation of symbols]

 2 Heating top part 2a Glass 3 Heat source part 7 Lamp heater 13 Stove case 14 Ceramic

Claims (5)

[Claims] 1. An infrared ray transmitting glass provided on a heating top section, and a heat source section having a lamp heater for radiating infrared ray inside the glass, an upper surface opening section of which is in contact with the glass directly below the glass. A cooker that uses an aluminum material with a high infrared reflectance for the stove case of the heat source and has a heat insulating structure by spraying ceramic on the outer wall surface. 2. An infrared ray transmitting glass provided on a heating top section, and a heat source section having a lamp heater which radiates infrared rays inside the glass, an upper surface opening section of which is in contact with the glass directly below the glass. A heating cooker in which the stove case of the heat source section is made of an aluminum material having a high infrared reflectance and has a double structure of an inner circumference and an outer circumference, and a ceramic is sprayed on the outer wall surface of the outer circumference to have a heat insulating structure. 3. An infrared ray transmitting glass provided on a heating top section, and a heat source section having a lamp heater which radiates infrared rays inside the glass, an upper surface opening section of which is in contact with the glass directly below the glass. A cooker in which the stove case of the heat source section is made of an aluminum material having a high infrared reflectance, and the outer wall surface is thermally sprayed with a ceramic to provide a heat insulating structure, and the infrared reflecting ceramic is coated on the lower surface of the lamp heater. 4. An infrared ray transmitting glass provided on a heating top section, and a heat source section having a lamp heater which radiates infrared rays in the inside by directly contacting the glass with an upper surface opening section directly below the glass. A heating cooker in which the stove case of the heat source section is made of a metal material, and ceramics are thermally sprayed on the inner peripheral wall surface of the metal material so as to have a heat insulating structure. 5. A glass provided with a heating top portion and permeable to infrared rays; and a heat source portion having a lamp heater for radiating infrared rays inside thereof, with an upper surface opening portion abutting the glass directly below the glass. A cooker in which the stove case of the heat source section is made of an aluminum material having a high infrared reflectance, and a low thermal conductivity insulating material of a molded product type is inserted around the stove case.