JP2002015842A - Infrared lamp and device using the same - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an infrared lamp, capable of preventing breakage of a heating element caused by vibration or shock in the infrared lamp using a sinter of a material containing carbon as the heating element, and provide a device using the infrared lamp. SOLUTION: An electrode-constituting body is composed of a block, comprising a carbon base material joined to both end parts of a heating element made of the sinter of the material containing carbon with a carbon base adhesive; an internal lead wire whose each end is wound on the block; a molybdenum foil joined to the other end of each internal lead wire; an outer lead wire joined to each molybdenum foil; and a support member fixed to at least one portion of the heating element 1. The electrode constituting body is sealed in a quartz glass tube, an inert gas is sealed therein, and the quartz glass is melted and sealed in the part of the molybdenum foil.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an infrared light bulb and an apparatus used for heating, heating, cooking, drying or the like using the infrared light bulb. The present invention relates to an infrared light bulb having a body.

[0002]

2. Description of the Related Art Conventionally, there are a Colts lamp and a halogen lamp using a tungsten filament as an infrared bulb which emits near-infrared rays and far-infrared rays used as a heat source. An infrared light bulb using a sintered body of a substance containing carbon as a heating element is disclosed in, for example, Japanese Patent Application Laid-Open No. H11-54092. Further, as a heat source other than the infrared light bulb, a nichrome wire heater or a sheathed heater in which a metal resistance wire is inserted into a stainless steel tube and a heat-resistant insulating inorganic powder is packed between the resistance wire and a steel tube around the resistance wire may be used. Used.

The former Colts lamps and halogen lamps are
A tungsten spiral filament is held at the center of a quartz glass tube, and an inert gas is sealed inside. Generally, a Coltz lamp uses argon gas as an inert gas, and a halogen lamp generally uses argon gas to which a small amount of halogen gas is added. The infrared emissivity of the tungsten spiral filament used in these Colts lamps and halogen lamps is 30 to 3
The inrush current is as low as 9%, and the inrush current is large. At the moment when the power switch is turned on, an inrush current of about 10 times the rated value flows.
Therefore, the configuration of the control circuit is difficult, and noise is generated due to a large inrush current, affecting peripheral devices. Furthermore, since tungsten spiral filaments have very low strength, it is necessary to use a large number of tungsten support members in order to hold the filaments in the center of the quartz glass tube, and the assembly is complicated and requires a lot of assembly time. Was required.

[0004] In order to solve these problems, an infrared light bulb using a sintered body of a carbon-containing substance formed in a rod shape or a plate shape as a heating element instead of the conventional tungsten spiral filament is disclosed in Japanese Patent Laid-Open Publication No. Hei 11 (1999). -54092. The infrared emissivity of the carbon-containing substance of the heating element used in this infrared bulb is 78 to 84%.
Therefore, the infrared emissivity of the infrared bulb is also high.
Further, since the carbon-containing substance has a slightly negative or positive resistance characteristic with respect to temperature, the resistance value before lighting is sufficiently high, and the rush current at the moment of lighting is suppressed. Therefore, the configuration of the control circuit may be simple, and the infrared light bulb has practically no effect on peripheral devices due to noise.

[0005] The latter nichrome wire heater and sheathed heater, although having a small inrush current, require about 1 to 5 minutes for the resistance wire to glow red, and have a problem with rapid heating.

[0006]

As described above, a conventional infrared light bulb using a sintered body of a substance containing carbon as a heating element does not cause much problem if the heating element is short in length. However, in the case of an infrared light bulb using a rod-shaped or plate-shaped object with a long heating element or a thin plate-shaped heating element, if an external shock or vibration is applied, heat is generated. If the body itself vibrates and the state in which it resonates continues, there is a serious problem that the heating element is damaged in the worst case.

An object of the present invention is to provide an infrared light bulb having high strength against shock and vibration even in an infrared light bulb using a long heating element or a thin plate-shaped heating element.

[0008]

In order to achieve the above-mentioned object, in the infrared light bulb of the present invention, a round or flat heating element formed of a sintered body made of a substance containing carbon, A heat-resistant and electrically conductive block having one end joined to both ends, an internal lead wire attached to each block by a tight fit via a spring portion, and each internal lead wire , And an external lead wire connected to the other end of each of the molybdenum foils forms an electrode assembly. The infrared light bulb includes a transparent quartz glass tube in which the electrode structure is inserted, and an inert gas sealed therein, and a quartz glass tube attached to at least one or more portions of the heating element. It has a support member having an outer shape slightly smaller than the inner diameter.

[0009] In the infrared light bulb of this configuration, a support member is attached to at least one or more locations of the heating elements of various shapes. Accordingly, even if vibration or shock is applied to the infrared light bulb from the outside, the outer shape of the support member abuts against the inner wall of the quartz glass tube, and the amplitude of the vibration of the heating element is suppressed to a small value. As a result, it is possible to provide an infrared light bulb in which the resonance of the heating element does not occur and the heating element is not damaged.

According to another aspect of the present invention, there is provided an infrared light bulb according to the present invention, wherein a round bar or a flat heating element formed of a sintered body made of a carbon-containing substance is provided. Heat-resistant and electrically-conductive blocks joined, internal leads attached to each of the blocks by close fitting, molybdenum foil joined to the other end of each of the internal leads, and An electrode structure is formed by an external lead wire bonded to the other end of each of the molybdenum foils. The infrared light bulb includes a transparent quartz glass tube in which the electrode structure is inserted, and an inert gas sealed therein, and a quartz glass tube attached to at least one or more portions of the heating element. It has a support member having an outer shape slightly smaller than the inner diameter.

[0011] In the infrared light bulb having this configuration, in order to prevent bending of the heating element due to slight thermal expansion when the heating element generates heat, a spring portion for applying tension to the heating element is not provided on a part of the internal lead wire. However, when at least one or more support members are attached to the heating element, it has a function of suppressing bending due to thermal expansion when the heating element generates heat, so that a spring portion is formed on a part of the internal lead wire. No need to do. As a result, the structure of the internal lead wire is simplified and contributes to cost reduction, and a spring portion is not required. Therefore, the total length of the infrared light bulb can be shortened and the infrared light bulb can be reduced in size.

In the infrared light bulb having the above two constitutions, it is preferable that the support member has a circular or non-circular ring shape. For example, the support member is formed from a wire so as to have a circular or non-circular ring shape. In this case, since it is a wire, the support member can be formed simply by winding it around the heating element, and the conventional technology for forming a support ring attached to a tungsten filament can be applied as it is. Also, because of the ring shape, it has flexibility and has a great effect on shock absorption.

The shape of the ring may be completely circular,
It may be non-circular, that is, elliptical, triangular, square or polygonal. Further, in the case of a round bar-shaped heating element, a three-point support type in which the circumference is divided at every 120 ° is formed, and in the case of a plate-shaped heating element, a two-point support type in which the circumference is divided at about 180 °. The ring shape is preferable. The number of turns of the ring is effective if it is at least one or more, and a ring wound two or three times is preferable.

It is preferable that the support member having the above-mentioned structure is formed of a molybdenum or tungsten wire. When the circular or non-circular support ring is formed of molybdenum or tungsten wire, these materials have a high melting point and are suitable for application to a portion having a heat generation temperature of 1000 ° C. or higher.

In the infrared light bulb having the above two constitutions, the support member may be formed of a round, triangular, square or polygonal plate. By forming the support member from a plate-like material, it is particularly preferable to apply the present invention to a member such as a plate-like heating element in which a ring-shaped support made of a wire is difficult to form. The shape may have a function of holding the heating element in the vicinity of the center of the quartz glass tube. Therefore, a polygon having at least a triangle or more satisfies the function. Further, the thickness thereof is preferably as thin as possible within the range of the strength of the plate material since heat dissipation via the support member is small.

Further, the plate-like support member is made of carbon,
It may be formed of graphite, a compound containing carbon and graphite as main components, or an inorganic material having heat-resistant insulation. Since the heating element is a sintered body of a substance containing carbon, carbon or graphite material is preferable. However, the material is not limited to the carbon or graphite material as long as the material has heat resistance and insulating properties.

In an infrared light bulb according to still another aspect of the present invention, a round bar or a flat heating element formed of a sintered body made of a carbon-containing substance, and one end thereof is joined to both ends of the heating element. Heat-resistant and electrically conductive blocks, internal lead wires attached to each of the blocks by tight fitting via a spring portion, and joined to the other end of each of the internal lead wires. An electrode structure is formed by the molybdenum foil and external lead wires joined to the other end of each of the molybdenum foils. This infrared light bulb has an inner wall of the quartz glass tube having at least one portion of a transparent quartz glass tube in which the electrode structure is inserted and an inert gas is sealed therein, from the outer shape of the heating element. Has a concave portion (hereinafter, referred to as a rimple) that slightly increases the diameter.

According to the infrared light bulb of this configuration, since the quartz glass tube is formed with the rimple and the heating element is held at that portion, it is possible to prevent the heating element from shaking due to vibration or impact. Therefore, since the ring-shaped support member and the plate-shaped support member are not required, it is effective for an infrared light bulb in which such a support member is difficult to be formed. As preferred rimples, three places are formed at intervals of about 120 ° for a rod-shaped heating element, and two places are formed at an interval of about 180 ° for a plate-shaped heating element.
When the rimple is formed in a quartz glass tube, its function is satisfied. The position may be formed at least at one position in the center of the heating element in the longitudinal direction, and when the heating element is long, two or more positions are more reliable.

In an infrared light bulb according to still another aspect of the present invention, a round bar or a flat heating element formed of a sintered body made of a carbon-containing substance, and one end is joined to both ends of the heating element. Heat-resistant and electrically conductive blocks, internal lead wires attached to each of the blocks by tight fitting, molybdenum foil joined to the other end of each of the internal lead wires, And an external lead wire joined to the other end of the molybdenum foil to form an electrode structure. In this infrared light bulb, the inner wall of the quartz glass tube has a small diameter due to the outer shape of the heating element in at least one portion of the transparent quartz glass tube in which the electrode structure is inserted and an inert gas is filled. It is characterized by having a rimple that becomes larger.

According to the infrared light bulb having this configuration, since the flexure is formed in the quartz glass tube, the flexure due to the thermal expansion of the heating element at the time of heat generation is received by the inner wall portion of the flexure. This eliminates the need for a spring portion provided to prevent the above. As a result, materials and man-hours for forming the spring portion on the internal lead wire are not required, so that the machining cost can be reduced and the size can be reduced.

An apparatus using the infrared light bulb of the present invention is an apparatus equipped with the infrared light bulb resistant to vibration or impact of the present invention. By using this infrared bulb, heating, heating,
A safe, time-efficient and highly reliable device for home or business use such as drying, cooking, medical treatment, baking, roasting, fermentation, aging, sterilization, and thawing can be realized.

[0022]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Preferred embodiments of the infrared light bulb according to the present invention will be described below with reference to the accompanying drawings.

Embodiment 1 FIG. 1 is a cross-sectional view of an infrared light bulb having a ring-shaped support according to Embodiment 1 of the present invention. In FIG. 1, blocks 3a and 3b formed of a graphite material having heat resistance and electrical conductivity are provided at both ends of a heating element 1 using a sintered body of a substance containing carbon so that electrical conduction can be obtained. Are bonded by a carbon-based adhesive. At the other end of each of the blocks 3a, 3b, there is provided an internal lead wire 4a, 4a having a coiled portion 6a, 6b wound thereon so as to form a tight fit with the outer shape of the block 3a, 3b.
b is attached. These internal lead wires 4a, 4b
Has spring portions 5a, 5b connected to the respective coiled portions 6a, 6b.

At the other ends of the internal lead wires 4a and 4b,
The molybdenum foils 7a and 7b are respectively welded and joined, and external lead wires 8a and 8b are joined to the molybdenum foils 7a and 7b to form an electrode structure. This electrode assembly is inserted into the quartz glass tube 2 and the molybdenum foils 7a, 7b
Is fused to seal the quartz glass tube 2. In addition,
An inert gas, for example, an argon gas is sealed inside the quartz glass tube 2. At the center of the heating element 1, both ends 10 a and 10 b of a support ring 9 formed by forming a tungsten wire into a coil shape having an outer diameter slightly smaller than the inner diameter of the quartz glass tube 2 are wound around the heating element 1. Is fixed.

The joining of the heating element 1 and the blocks 3a and 3b in the infrared light bulb of the first embodiment will be described in more detail. A hole slightly larger than the heating element 1 is formed in the center of the blocks 3a and 3b formed by molding a graphite material into a cylindrical shape, and the heating element 1 is inserted into the hole and joined with a carbon-based adhesive. . As the carbon-based adhesive, for example, a paste obtained by blending fine powder of carbon or graphite with a phenol resin or the like was used. This paste-like carbon-based adhesive was applied to the joint, dried, and fired in an inert gas at 1000 ° C. or higher to adhere. In the infrared light bulb having the structure of the first embodiment, the support ring 9 abuts against the inner wall of the quartz glass tube 2 to suppress the swing of the heating element 1 even if the heating element 1 shakes due to vibration or impact due to external force. The heating element 1 does not resonate, and there is no fear of damage, and a highly reliable infrared light bulb can be realized.

As a material for the blocks 3a and 3b, other than graphite, a metal material such as tungsten or molybdenum may be used as long as it has heat resistance and electrical conductivity. Absent. Also,
There is no problem if the shape is other than a circle, for example, a polygon or a plate.

In the infrared light bulb of the first embodiment, the example in which the support ring 9 is formed at one place is shown. However, when a longer heating element 1 is used, it is more reliable to mount the support ring at two or more places. The performance is improved. As long as the material of the support ring 9 can withstand the heat generation temperature of the heating element 1,
Although the material is not limited, a heat-resistant metal wire such as tungsten or molybdenum is preferable. The shape of the line is
A circular, plate-like, or linear twisted wire may be used. The number of turns of the support ring 9 may be one or more, but preferably two or three. Also,
The shape of the support ring 9 may be circular, triangular, polygonal, or a rod-like structure protruding radially in several directions such as 90 ° or 180 °.

In the first embodiment, the shape of the heating element 1 has been described as a rod. However, the support ring 9 of the first embodiment can be applied to a plate or any other shape.

Embodiment 2 An infrared light bulb according to Embodiment 2 of the present invention will be described with reference to FIG. FIG. 2 shows the second embodiment.
FIG. 2 is a sectional view of the infrared light bulb of FIG.

In FIG. 2, both ends of a heating element 1 made of a sintered body of a carbon-containing substance are inserted into openings formed in columnar blocks 3a and 3b formed of graphite material, and both are inserted at the insertion section. Adhesive bonding with a carbon-based adhesive. Block 3a,
3b are connected to internal leads 11a, 11b, respectively.
The coil-shaped portions 12a and 12b formed at one end of each of the above are inserted and attached by close fitting. The internal lead wires 11a, 1
Molybdenum foils 7a and 7b are respectively welded to the other end of 1b, and external lead wires 8a and 8b are respectively bonded to the molybdenum foils 7a and 7b to form an electrode assembly.
This electrode assembly was inserted into a quartz glass tube 2 and the quartz glass tube 2 was melted at the molybdenum foils 7a and 7b to produce an infrared light bulb of Example 2. Near the center of the heating element 1, both ends 10 a and 10 b of the support ring 9 are wound around and joined to the heating element 1. Since the material and shape of the support ring 9 are the same as those described in the first embodiment, the same reference numerals are given and the duplicate description will be omitted.

A tungsten wire or a molybdenum wire was suitable for the internal lead wire shown in Example 1 or 2, and a molybdenum wire material was suitable for the external lead wire. These wires can also be used without problems, whether they are round, ribbon-like, or stranded thin wires.

The infrared light bulb according to the second embodiment includes a spring 5 provided on the internal lead wires 4a and 4b described in the first embodiment.
It is characterized by a structure in which a and 5b are omitted. The role of the springs 5a and 5b is to apply tension to the heating element 1, and its purpose is to prevent the heating element 1 from expanding by thermal expansion when the heat is generated and to bend. However, in the infrared light bulb of the second embodiment, since the bending caused by the thermal expansion of the heating element 1 is suppressed by the support ring 9, there is no problem even without the spring portions 5a and 5b. If the spring portion of the internal lead wire can be omitted, the expensive molybdenum or tungsten material used for the internal lead wire can be shortened, and the cost of the material can be reduced. Further, the man-hour for forming the spring portion can be omitted,
Further cost reduction is possible.

Embodiment 3 An infrared light bulb according to Embodiment 3 of the present invention will be described with reference to FIGS. FIG.
FIG. 4 is a sectional view of the infrared light bulb of the third embodiment, and FIG. 4 is a perspective view of a support member used for the infrared light bulb of the third embodiment.

Both ends of the plate-shaped heating element 20 formed of a sintered body of a carbon-containing substance are inserted into cutouts provided in columnar blocks 21a and 21b respectively formed of a graphite material. Are bonded with a carbon-based adhesive. Coiled portions 24a, 24b formed at one end of internal lead wires 22a, 22b made of tungsten or molybdenum material are screwed into the blocks 21a, 21b in a tight fit. Coiled portion 2 of internal lead wires 22a, 22b
Spring portions 23a and 23b connected to 4a and 24b are formed.

Molybdenum foils 7a and 7b are welded to the other ends of the internal lead wires 22a and 22b, respectively. External lead wires 8a and 8b made of a molybdenum material are joined to the molybdenum foils 7a and 7b, respectively, to form an electrode structure. The electrode assembly is inserted into the quartz glass tube 2, and the quartz glass tube 2 is melted and sealed at the molybdenum foils 7a and 7b. Quartz glass tube 2
Is filled with argon gas. A plate-like support member 25 made of a graphite material is engaged near the center of the plate-like heating element 20.

As shown in FIG. 4, the support member 25 has a notch 26 having a width slightly larger than the thickness of the plate-shaped heating element 20. The plate-shaped heating element 20 is inserted into the notch 26, and both are joined with a carbon-based adhesive. There is no problem if the shape of the support member 25 is a polygon such as a triangle or a quadrangle other than the circle shown in FIG. The thickness of the support member 25 only needs to withstand the impact force, and the heat dissipation of the heating element is small. The number of support members is determined by the length of the plate-shaped heating element 20. For example, in the example, when the length of the plate-shaped heating element was 30 cm and the thickness was 0.5 mm, the effect was confirmed by providing the support member at about two places.

In the third embodiment, the internal lead wires 22a,
Although the structure having the spring portions 23a and 23b is shown in FIG. 2b, even if the spring portions 23a and 23b are omitted as in the second embodiment, the deflection of the plate-like heating element 20 is suppressed by the support member 25, so that there is no problem. Absent. In the third embodiment, the infrared light bulb using the plate-shaped heating element 20 has been described. However, the plate-shaped support member 25 of the third embodiment can be applied to an infrared light bulb using a rod-shaped heating element without any problem.

Embodiment 4 An infrared light bulb according to Embodiment 4 of the present invention will be described with reference to FIG. FIG. 5 is a sectional view of the infrared light bulb of the fourth embodiment. The infrared light bulb of the fourth embodiment uses a plate-shaped heating element 20, similarly to the infrared light bulb of the third embodiment shown in FIG. The third embodiment is the same as the third embodiment except that the shape of the quartz glass tube 2 and the use of the support member are omitted. In the first to third embodiments, the configuration in which the support members having various shapes are joined to the heating element has been described. However, the infrared light bulb of the fourth embodiment has a quartz glass tube 2 as a support unit for suppressing vibration and bending of the heating element. It is the one that formed a rimple.

As shown in FIG. 5, in the infrared light bulb of the fourth embodiment, the quartz glass tube 2 has the rimples 30a and 30b. These quartz glass tubes 2 of the rimples 30a and 30b
Are formed so as to reach near both surfaces of the plate-shaped heating element 20. This tip is a plate-like heating element 20.
It has the function of preventing the swaying. Rimple 30a,
In order to form 30b, after assembling the infrared light bulb, the quartz glass tube 2 is cooled with water except for the center of the infrared light bulb.
The vicinity of the center portion of the rimple-forming portion was heated with a burner and pressed with a thin rod-shaped material.

The structure of the infrared light bulb of the fourth embodiment can be applied to not only the plate-shaped heating element 20 but also a rod-shaped heating element. In the case of a rod-shaped heating element, a support having a support function can be realized by forming rimples at three places on the circumference of the quartz glass tube 2 at an angle of about 120 °.

The infrared light bulb of the present invention has been described above with reference to Examples 1 to 4. It has been confirmed by experiments that any of the above-described support members and rimples of various shapes can be applied to both rod-shaped or plate-shaped heating elements. I have.

Embodiment 5 An apparatus using an infrared light bulb according to Embodiment 5 of the present invention will be described. Various devices using the infrared light bulb of the present invention of Example 5 have stronger vibrations and vibrations than conventional devices using an infrared light bulb using a sintered body of a carbon-containing substance without a support member as a heating element. Can withstand shock. In particular, some devices having a drive unit, such as business devices, generate large vibrations, so that the infrared light bulb of the present invention is very effective. Applicable devices include heating, heating, drying, cooking, medical care, roasting, fermentation, aging, baking, sterilizing, and thawing devices.

[0043]

As described in detail in the above embodiments, the infrared light bulb of the present invention using a sintered body of a substance containing carbon as a heating element has a support structure for preventing the heating element from shaking. Thus, an infrared light bulb that is resistant to vibration and shock due to external force can be realized. In addition, by using the infrared light bulb of the present invention as a heating source, improvements in reliability, time efficiency, and the like of heating, heating, drying, cooking, medical care, roasting, fermentation, aging, baking, sterilizing, and thawing devices have been achieved. it can. In particular, in a device having a driving unit, it is possible to provide a device in which a heating element is prevented from being damaged by vibration generated by the driving unit.

[Brief description of the drawings]

FIG. 1 is a sectional view of an infrared light bulb according to a first embodiment of the present invention.

FIG. 2 is a sectional view of an infrared light bulb according to a second embodiment of the present invention.

FIG. 3 is a sectional view of an infrared light bulb according to a third embodiment of the present invention.

FIG. 4 is a perspective view of a support member of the infrared light bulb according to the third embodiment of the present invention.

FIG. 5 is a sectional view of an infrared light bulb according to a fourth embodiment of the present invention.

[Explanation of symbols]

1, 20 Heating element 2 Quartz glass tube 3a, 3b, 21a, 21b Block 4a, 4b, 11a, 11b, 22a, 22b Internal lead wire 5a, 5b, 23a, 23b Spring part 6a, 6b, 12a, 12b, 24a, 24b Coiled part 7a, 7b Molybdenum foil 8a, 8b External lead wire 9 Support ring 10a, 10b Support ring end 25 Support member 26 Notch 30a, 30b Rimple

──────────────────────────────────────────────────の Continued on the front page (51) Int.Cl. ⁷ Identification symbol FI Theme coat ゛ (Reference) H05B 3/14 H05B 3/14 F 3/44 3/44 (72) Inventor Hirofumi Tange Toyonaka, Mitoyo-gun, Kagawa 22 Mt.

Claims (9)

[Claims] 1. A round rod or flat heating element formed of a sintered body made of a substance containing carbon, having one end joined to both ends of the heating element and having heat resistance and electrical conductivity. A block, an internal lead wire attached to the other end of each of the blocks by a tight fit via a spring portion, a molybdenum foil bonded to the other end of each of the internal lead wires, each of the molybdenum foils An external lead wire joined to the other end of the transparent member; a transparent quartz glass tube into which an electrode assembly including the above components is inserted, and an inert gas sealed therein; and at least one portion of the heating element Attached to the above part,
An infrared light bulb having a support member having an outer shape slightly smaller than the inner diameter of the quartz glass tube. 2. A round bar or flat heating element formed of a sintered body made of a substance containing carbon, having one end joined to both ends of the heating element and having heat resistance and electrical conductivity. A block, an internal lead wire attached to the other end of each of the blocks by tight fitting, a molybdenum foil joined to the other end of each of the internal leads, a second end of each of the molybdenum foils A bonded external lead wire, a transparent quartz glass tube into which an electrode structure including the above components is inserted and an inert gas is sealed therein, and attached to at least one or more portions of the heating element And a support member having an outer shape slightly smaller than the inner diameter of the quartz glass tube. 3. The support member according to claim 1, wherein the support member has a circular or non-circular ring shape.
Infrared light bulb as described. 4. The device according to claim 1, wherein the support member is formed of molybdenum or tungsten.
2. The infrared light bulb according to 2 or 3. 5. The infrared light bulb according to claim 1, wherein the support member is formed of a plate having a round, triangular, square or polygonal outer shape. 6. The support member is made of a compound containing at least one of carbon and graphite, or an inorganic material having heat resistance and electric insulation. Infrared light bulb. 7. A round bar or flat heating element formed of a sintered body made of a carbon-containing substance, having one end joined to both ends of the heating element and having heat resistance and electrical conductivity. A block, an internal lead wire attached to the other end of each of the blocks via a spring portion in a tight fit, a molybdenum foil bonded to the other end of each of the internal lead wires, each of the molybdenum foils An infrared light bulb having a transparent quartz glass tube in which an external lead wire bonded to the other end of the electrode structure and an electrode assembly having the above-described components are inserted, and an inert gas is sealed therein. A concave portion (hereinafter, referred to as a rimple) that forms an inner wall portion slightly larger than the outer shape of the heating element, at least at one or more portions of the quartz glass tube; 8. A round bar or flat heating element formed of a sintered body made of a substance containing carbon, one end of which is joined to both ends of the heating element and has heat resistance and electrical conductivity. A block, an internal lead wire attached to the other end of each of the blocks by tight fitting, a molybdenum foil connected to the other end of each internal lead, a connection to the other end of each of the molybdenum foils An infrared light bulb having a transparent quartz glass tube in which an external lead wire and an electrode assembly including the above-described components are inserted, and an inert gas is sealed therein, at least the quartz glass tube. An infrared light bulb characterized in that one or more portions are provided with a rimple that forms an inner wall portion slightly larger than the outer shape of the heating element. 9. The method of claim 1, 2, 3, 4, 5, 6, or 7.
Or a heating device equipped with the infrared light bulb described in 8.