JP2004190970A - Hot air heater - Google Patents

Abstract

The present invention relates to a hot air heating apparatus for mixing indoor air and a high-temperature gas for heating, and efficiently generates and replenishes a large amount of negative ions at the time of hot air heating to provide high comfort. The purpose is to realize a heating device.
A discharge-type negative ion generating means is disposed at an appropriate position in an air flow path from a blower, so that negative ions are replenished even when used in a closed room for a long time, thereby improving the indoor environment with high quality. In addition, the entire room can be heated while maintaining the temperature, and the negative ion generating means 22 is located at a position where the negative ion generated by the negative ion generating means 22 is not in contact with the electrical ground plane of the device until the negative ions are released from the device. Is provided to prevent the negative ions generated from the negative ion generating means 22 from being attenuated by contacting the electrical ground surface of the device until the negative ions are emitted from the device.
[Selection diagram] Fig. 1

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a hot air heating device that mixes room air and high-temperature gas and uses the mixed air for heating.
[0002]
[Prior art]
Conventionally, as shown in FIG. 6, in this type of hot air heating apparatus, fuel is supplied from a cartridge tank 2 to a tank 1, and fuel in the tank 2 is supplied to a vaporizing section 4 by a pump 3. The gas is vaporized by the vaporizing section 4 to become a fuel gas, and is ejected from the nozzle 5 in a horizontal direction. The fuel ejected from the nozzle 5 is ejected into a mixing pipe 6 provided at a position downstream of the vaporizing section 4 while sucking primary air by an ejector effect, and is mixed here to form a line integrated with the mixing pipe 6. It is supplied to the burner section 7 having a shape and burned. The generated combustion gas is guided upward by a combustion tube 8 disposed so as to cover the periphery of the burner unit 7, mixed with a room air flow from a blower 10 by a duct 9 covering the combustion tube 8, and heated. It is discharged as wind and used for heating. The hot-air heating device performs a predetermined operation in a sequence predetermined by the controller, such as automatically adjusting the fuel supply amount by changing the driving frequency or applied voltage of the pump 3 according to the room temperature and the set temperature. Is controlled as follows. As described above, the conventional hot air heating device generally does not include the negative ion generating means.
[0003]
However, in recent years, there has been an increase in interest in health aspects, and equipment that attaches negative ion generating means, such as a composite ceramic obtained by mixing several types of ceramics, to the hot air outlet and actively supplies negative ions indoors Has been developed (see Patent Document 1).
[0004]
[Patent Document 1]
JP-A-11-212236
[Problems to be solved by the invention]
The hot air heater without the above-mentioned negative ion generating means is mainly used for heating indoors in winter, so it is used for a long time in the closed room, and as the indoor environment, the indoor temperature is set to the set temperature Although it is kept, it is often used when it is not very good in terms of air quality, dusty or carbon dioxide gas increases, that is, VOCs such as smoking components, odors, formaldehyde etc. contained in indoor air It is often assumed that it will be used in a bad environment where accumulation of microorganisms such as, other chemical substances, carbon monoxide, carbon dioxide, ozone, bacteria, molds and viruses, and reduction of negative ions will occur. Was done.
[0006]
In the above-described conventional heating heat source using combustion heat, a large amount of positive ions and negative ions are generated in substantially the same amount by the flame plasma effect of combustion, but negative ions are quickly generated by dust in the room. As a result, the balance between the positive and negative ions in the room is lost as a result, and the ion ratio between the positive and negative ions does not become too large, and the indoor temperature is maintained at the set temperature, but the indoor environment is reduced. There was a worry that it would get worse.
[0007]
In addition, in the case where a substance that generates negative ions is attached to the hot air outlet, if a predetermined amount of negative ions are to be secured, a considerably large volume is required and the substance that generates negative ions throughout the hot air outlet is required. Will be arranged. In this case, there arise problems such as an increase in airflow resistance at the hot air outlet, making it impossible to secure an appropriate air volume, and an abnormal rise in temperature inside the device.
[0008]
Therefore, the present invention solves the above-described problems, and efficiently generates and replenishes a large amount of negative ions during warm air heating, thereby improving the balance between positive ions and negative ions and maintaining a high-quality indoor environment while maintaining the overall indoor environment. It is intended to realize a highly comfortable heating device capable of heating.
[0009]
[Means for Solving the Problems]
In order to solve the above problems, the present invention provides a hot gas generating means, a blower for supplying an air flow, and a hot air blower for mixing the air flow from the blower and the high temperature gas from the high temperature gas generating means and discharging the mixture as hot air. An outlet and a metal housing having an electric ground plane, and a discharge-type negative ion generating means disposed at an appropriate position in an air flow path from the blower, and negative ions generated from the negative ion generating means are provided. The configuration is such that it does not contact the electrical ground plane of the device until it is released from the device.
[0010]
According to the above invention, the discharge-type negative ion generating means is disposed at an appropriate position in the air flow path from the blower, so that the air path resistance does not occur and even if the device is used for a long time in a closed room, The negative ions are replenished, and the ratio of positive ions to negative ions can be prevented from becoming too large, and the entire room can be heated while maintaining a high-quality indoor environment.
[0011]
Until the negative ions generated from the discharge-type negative ion generating means are released from the equipment, the negative ion generating means is disposed at a position not in contact with the electrical ground plane of the equipment. The generated negative ions can be prevented from being attenuated by coming into contact with the electrical ground surface of the metal housing, and can be efficiently released in large quantities from the device, so that a highly comfortable heating device can be provided.
[0012]
Furthermore, since the negative ion generating means is located at the appropriate position in the air flow path, the negative ions released from the negative ion generating means can reach the entire room by the warm air, and the effect of the negative ions can be further improved. In addition to this, the air blowing means can serve both for generating the hot air of the device and for the negative ions, and can be provided with a simple and inexpensive structure.
[0013]
BEST MODE FOR CARRYING OUT THE INVENTION
The hot-air heating apparatus according to claim 1, wherein the hot-air generating means, a blower for supplying an air flow, and a hot air for mixing the air flow from the blower and the high-temperature gas from the high-temperature gas generating means to discharge as hot air. An air outlet, and a metal housing having an electric ground surface, a discharge-type negative ion generating means disposed at an appropriate position in an air flow path from the blower, and negative ions generated from the negative ion generating means. Until it is released from the device, it does not touch the electrical ground plane of the device.
[0014]
According to the above invention, the discharge-type negative ion generating means is disposed at an appropriate position in the air flow path from the blower, so that the air path resistance does not occur and even if the device is used for a long time in a closed room, The negative ions are replenished, and the ratio of positive ions to negative ions can be prevented from becoming too large, and the entire room can be heated while maintaining a high-quality indoor environment.
[0015]
Until the negative ions generated from the discharge-type negative ion generating means are released from the equipment, the negative ion generating means is disposed at a position not in contact with the electrical ground plane of the equipment. The generated negative ions can be prevented from being attenuated by coming into contact with the electrical ground surface of the metal housing, and can be efficiently released in large quantities from the device, so that a highly comfortable heating device can be provided.
[0016]
Furthermore, since the negative ion generating means is located at the appropriate position in the air flow path, the negative ions released from the negative ion generating means can reach the entire room by the warm air, and the effect of the negative ions can be further improved. In addition to this, the air blowing means can serve both for generating the hot air of the device and for the negative ions, and can be provided with a simple and inexpensive structure.
[0017]
Further, the hot air heating apparatus according to claim 2 includes a burner section for burning fuel, a frame rod for detecting a combustion state, a blower for supplying an air flow, and an air flow from the blower and a high temperature from the burner section. A hot air outlet for mixing or exchanging gas or exchanging heat as hot air, and a metal housing having a ground surface of the frame rod, and a discharge-type negative ion generating means in an appropriate position in an air flow path from the blower. And is configured not to come into contact with the electrical ground plane of the device until the negative ions generated from the negative ion generating means are released from the device.
[0018]
The effect of claim 1 can be obtained even in a room using combustion heat as a heating heat source in which the balance between the positive ions and the negative ions in the room is lost and the ion ratio of the positive ions and the negative ions tends to increase. Negative ion generation means is installed at the appropriate position in the air flow path from the blower, so negative ions are replenished and the ion ratio of positive ions to negative ions becomes too large even if used for a long time in the closed room Can be prevented, and the entire room can be heated while maintaining a high quality indoor environment.
[0019]
Further, since the negative ion generating means is disposed at a position where the negative ion generated by the negative ion generating means does not come into contact with the electric ground plane of the device until the negative ions are released from the device, the negative ion generating means generates the negative ion. Until the discharged negative ions are released from the device, it can be prevented from being attenuated by contacting the electrical ground surface of the device, and a large amount of the ions can be efficiently released from the device, thereby providing a suitable heating device. can do.
[0020]
Furthermore, since the negative ion generating means is disposed at an appropriate position in the air flow path, the negative ions released from the negative ion generating means can reach the entire room by the warm air, and the negative ion The effect can be exhibited more effectively.
[0021]
Further, the hot air heating device according to claim 3 is provided at an appropriate position in the middle of the air flow path from the blower on the upstream side of the negative ion generation means so that the air flow from the blower does not directly contact the negative ion generation means. A shield is provided so that negative ions generated from the negative ion generating means are diffused by an airflow from a blower flowing around the negative ion generating means.
[0022]
Then, a shield is disposed at an appropriate position in the air flow path from the blower on the upstream side of the negative ion generating means, so that the negative ions generated from the negative ion generating means can be removed from the air from the blower flowing around the negative ion generating means. Since it is configured to diffuse with the flow, it is possible to prevent the air flow from the blower from directly contacting the negative ion generation means, and foreign substances such as dust mixed in the air flow from the blower to the negative ion generation means Accumulates to prevent the generation of negative ions, or to prevent the generation of smoke or smoke from dust. Equipment can be obtained.
[0023]
Further, in the warm air heating device according to the fourth aspect, the wall surface of the air flow path on the downstream side of the negative ion generating means is formed of an electric insulator so as not to reduce the amount of negative ions.
[0024]
Since the wall surface of the air flow path on the downstream side of the negative ion generating means is formed of an electric insulator so as not to reduce the amount of negative ions, the discharge of the negative ion generating means is restricted due to design restrictions inside the device. Even if the unit is located in the back of the device, for example, the air flow path on the downstream side is formed of a wall connected to the electrical grounding surface of the device, the wall may be formed of an electrical insulator such as a resin material. Forming the downstream air flow path with an electrical insulator, such as by covering with, prevents a decrease in the amount of negative ions emitted from the negative ion generation means and greatly reduces the design constraints on the arrangement of the negative ion generation means. You can relax.
[0025]
In the warm air heating apparatus according to the fifth aspect, the surface of the air flow path on the downstream side of the negative ion generating means is coated with an insulating paint or precoated with an insulating paint so as not to reduce the amount of negative ions. It is configured to be made of painted steel plate.
[0026]
The surface of the air flow path on the downstream side of the negative ion generating means is formed of a coated steel sheet coated with an insulating paint or pre-coated with the insulating paint so as not to reduce the amount of negative ions. 4 can be obtained with a simple configuration.
[0027]
In other words, even if the air flow path on the downstream side of the negative ion generating means is constituted by a wall connected to the electric ground plane of the device due to design constraints inside the device, the wall surface is kept electrically insulative. Processing such as applying an insulating paint or forming a material that retains electrical insulation, such as a coated steel sheet pre-coated with an insulating paint, so that the wall surface of the downstream air flow path has electrical insulation, The design restrictions on the arrangement of the negative ion generating means can be greatly eased while preventing the negative ions emitted from the negative ion generating means from decreasing.
[0028]
In addition, means for forming the air flow path with an electrical insulator, by applying an insulating paint or by forming a coated steel sheet pre-coated with the insulating paint, so that only the wall surface has electrical insulation, In addition to the effect of the structure covered with an electrical insulator such as the resin material of claim 4, high heat resistance can be obtained, and there is no need to worry about deformation of the resin material, ignition or smoke, and the structure is simplified and the cost is reduced. Can be
[0029]
【Example】
Hereinafter, embodiments of the present invention will be described with reference to the drawings.
[0030]
(Example 1)
FIG. 1 is a sectional view of a main part of a hot air heating device according to an embodiment of the present invention, FIG. 2 is a sectional view of the device, and FIG. 3 is a control block diagram of the device.
[0031]
1 and 2, reference numeral 11 denotes a main body case formed of a metal housing having an electric grounding surface. A tank 12 holding liquid fuel is provided on a lower side thereof, and a detachable cartridge tank 13 is provided above the tank 12. Is arranged. Reference numeral 14 denotes a pump mounted on the upper surface of the tank 12, and supplies a fuel from an upper end thereof to a burner 16 which is a high-temperature gas generating means via an oil supply pipe 15. The burner section 16 is covered with a heavenly cylindrical combustion cylinder 17 having an opening at the entire upper surface arranged to guide generated combustion gas upward. A blower 18 for taking in and sending out the flow is provided, and a part of the air flow from the blower 18 is taken into the combustion cylinder 17 and used as combustion air.
[0032]
Reference numeral 19 denotes a duct which forms a blowing path for mixing the high-temperature combustion exhaust gas from the combustion tube 17 and the indoor air flow from the blower 18 to generate hot air at the downstream side. The air is discharged from a hot air outlet 21 having a louver 20 for controlling the direction, and the material forming the hot air outlet 21 and the louver 20 is formed of a coated steel sheet having an electrically insulating surface. I have.
[0033]
Reference numeral 22 denotes a negative ion generating means provided at the hot air outlet 21. A shield 23 is disposed on the upstream side of the air flow flowing around the negative ion generating means 22 so that negative ions generated from the negative ion generating means 22 are removed. The air flow from the blower flowing around the negative ion generating means 22 is diffused so that the air flow from the blower 18 does not directly contact the negative ion generating means 22.
[0034]
Reference numeral 24 denotes a control unit for controlling the pump 14 and the blower motor 19 to burn the burner unit 16, and based on an operation condition signal input from the operation unit, the pump 14, the burner unit 16, the negative ion generating means 22, and the like. Are controlled in a predetermined sequence.
[0035]
Reference numeral 25 denotes a frame rod for detecting a combustion state. A predetermined voltage is applied between the frame rod 25 and the main body case 11 to detect an ion current. At this time, the main body case 11 is used as an electric ground plane.
[0036]
In the above configuration, the liquid fuel supplied from the cartridge tank 13 to the tank 12 so as to maintain a constant oil level is pumped up from the tank 12 by the pump 14 and sent to the burner 16 via the oil supply pipe 15. The high-temperature combustion exhaust gas generated by the combustion flows upward through the combustion cylinder 17 and is mixed with the indoor air flow from the blower 18 in the duct 19, and is blown out from the hot-air outlet 21 through the louver 20 as hot air. Is controlled and discharged and used for heating.
[0037]
The control unit 24 operates the negative ion generating means 22 in synchronization with the blowing of the blower 18, and the negative ions generated from the negative ion generating means 22 are provided with the shield 23. The airflow from the blower 18 does not directly contact the negative ion generating means 22, but is diffused by the airflow from the blower 18 flowing around the negative ion generating means 22.
[0038]
Here, the negative ion generating means 22 is disposed in the hot air outlet 21 in the case of using a heating heat source using combustion heat, in which the balance between the positive ions and the negative ions in the room is lost and the ion ratio of the positive ions and the negative ions tends to increase. Because it is installed, negative ions are replenished, and even if used in a closed room for a long time, the ion ratio of positive ions to negative ions can be prevented from becoming too large, keeping the indoor environment high quality and the whole room Will also be able to heat.
[0039]
Until the negative ions generated from the negative ion generating means 22 are released from the device, there is a problem in that the negative ions are deprived of electrons when they come into contact with the electric ground plane of the device, and are extremely reduced.
[0040]
Therefore, the negative ion generating means 22 is disposed at the hot air outlet 21, and the negative ion generated from the negative ion generating means 22 is placed in a position where it does not come into contact with the electrical ground plane of the device until the negative ions are released from the device. Since the ion generating means 22 is provided, the negative ions generated from the negative ion generating means 22 can be prevented from being attenuated by coming into contact with the electric ground plane of the device until the negative ions are emitted from the device. A large amount can be efficiently discharged from the device, and a highly suitable heating device can be provided.
[0041]
Further, since the negative ion generating means 22 is disposed at the hot air outlet 21, the negative ions emitted from the negative ion generating means 22 can reach the entire room by the warm air, and the negative ions can be discharged. Can be more effectively exerted, and the blower can also serve as a hot air generator and a negative ion blower for the device with the blower 18, so that the configuration can be simplified and the cost can be reduced. You can do it.
[0042]
Further, a shield 23 is provided on the upstream side of the air flow of the negative ion generating means 22, and the negative ions generated from the negative ion generating means 22 are diffused by the air flow from the blower 18 flowing around the negative ion generating means 22. Since the air flow from the blower 18 does not directly contact the negative ion generating means 22, foreign matter such as dust mixed in the air flow from the blower 18 To prevent the generation of the amount of negative ions, or to prevent the generation of fire and smoke from dust, and to obtain a stable generation of negative ions over time, High equipment can be obtained.
[0043]
And since the surface of the air flow path around and on the downstream side of the negative ion generating means 22 is formed of a coated steel plate having electrical insulation, it can be released from the device without reducing the amount of negative ions. Higher heat resistance can be obtained than in a configuration covered with an electrical insulator such as a resin material, and there is no need to worry about deformation of the resin material, ignition or smoke, and the configuration can be simplified and inexpensive. .
[0044]
(Example 2)
FIG. 4 is a cross-sectional view of a main part of a hot air heating device according to a second embodiment of the present invention. The same parts as those in the first embodiment are denoted by the same reference numerals, and description thereof is omitted.
[0045]
In FIG. 4, reference numeral 31 denotes a negative ion generating means provided in the duct 19 at a distance from the hot air outlet 21. A shield 32 is arranged on the upstream side of the airflow flowing around the periphery, so that the negative ions generated from the negative ion generating means 31 are diffused by the airflow from the blower 18 flowing around the negative ion generating means 31. It is.
[0046]
Reference numeral 33 denotes a negative ion cover made of a resin material of an electric insulator provided so as to cover the wall surface of the air flow path on the downstream side of the negative ion generating means 31. It is designed so as not to contact the electrical ground plane of the device and not to reduce the amount of negative ions.
[0047]
In the above-described configuration, there are various design restrictions, that is, the negative ion generation means 31 such as a discharge plasma type and a photoelectric plasma type. However, when any of the methods is arranged at a position where the user can easily touch, the negative ion generation amount varies. If the user tries to place the negative ion generating means 31 in a position where the user does not touch and touch it, the air flow downstream of the negative ion generating means 31 is inevitable. The electrical ground plane of the device is located on the wall of the road, which imposes restrictions on safety and performance of the negative ion generating means 31.
[0048]
Therefore, in the present embodiment, the wall surface of the air flow path on the downstream side of the negative ion generating means 31 is covered with a negative ion cover made of a resin material of an electric insulator so as not to reduce the amount of negative ions. Therefore, due to design constraints inside the device, even if the emission portion of the negative ion generating means 31 is located in the interior of the device, the negative ions do not come into contact with the electrical ground plane of the device, and the negative ion generating means The design constraint on the arrangement of the negative ion generating means 31 can be greatly eased while preventing a decrease in the amount of negative ions emitted from the negative ion generator 31.
[0049]
(Example 3)
Third Embodiment FIG. 5 is a sectional view of a main part of a hot air heating device according to a third embodiment of the present invention. The same parts as those in the first embodiment are denoted by the same reference numerals, and description thereof is omitted.
[0050]
In FIG. 5, reference numeral 41 denotes a negative ion generating means 41 provided in the duct at a distance from the hot air outlet 21. A shield 42 is provided on the upstream side of the airflow flowing around the periphery, and the negative ions generated from the negative ion generating means 41 are diffused by the airflow from the blower 18 flowing around the negative ion generating means 41. It is.
[0051]
The surface of the duct 43, the hot air outlet 21 and the louver 16 is formed of a coated steel sheet having an electrically insulating property, and the negative ions generated from the negative ion generating means 41 generate an electric grounding surface of the device. So that the amount of negative ions is not reduced.
[0052]
In the above-described configuration, the material constituting the duct 43, the hot air outlet 21 and the louver 20 is formed of a coated steel plate having an electrically insulating surface, so that the air flow path on the downstream side of the negative ion generating means 41 is provided. The wall surface has electrical insulation properties, so that the negative ions generated from the negative ion generating means 41 do not come into contact with the electric ground plane of the device, and the negative ions emitted from the negative ion generating means 41 are reduced. While preventing this, the design restriction on the arrangement of the negative ion generating means 41 can be greatly eased.
[0053]
Further, since the means 41 for forming the air flow path with an electric insulator is formed of a coated steel sheet having a treatment for maintaining electric insulation, that is, an electric insulator such as the resin material of the second embodiment. In addition to the effect of the covering configuration, high heat resistance can be obtained, and there is no need to worry about deformation of the resin material portion, ignition or smoking, and the configuration can be simplified and the cost can be reduced.
[0054]
In the above embodiment, the high-temperature gas generating means has the burner section 16 for burning fuel, and the burner gas is used. However, the burner section 16 may not burn the fuel. The negative ion cover 32 is made of a resin material of an electric insulator, but may be an electric insulator such as a ceramic. In the third embodiment, the entire duct 43 is formed of a coated steel sheet having electric insulation. However, this may be performed by a process of maintaining electrical insulation only on the wall surface of the air flow path on the downstream side of the negative ion generating means 41, for example, a coating having electrical insulation may be applied, or a coating having electrical insulation may be applied. It may be covered with a steel plate, and the configuration of each part may be any configuration as long as the object of the present invention is achieved.
[0055]
【The invention's effect】
As described above, according to the warm-air heating device of the present invention, the discharge-type negative ion generating means is disposed at an appropriate position in the air flow path from the blower, so that the air-flow resistance does not become the resistance of the air path, and the deadline is closed. Even when used for a long time in a closed room, negative ions are replenished, the ratio of positive ions to negative ions can be prevented from becoming too large, and the entire room can be heated while maintaining a high quality indoor environment Become like Until the negative ions generated from the discharge-type negative ion generating means are released from the equipment, the negative ion generating means is disposed at a position not in contact with the electrical ground plane of the equipment. The generated negative ions can be prevented from being attenuated by coming into contact with the electrical ground surface of the metal housing, and can be efficiently released in large quantities from the device, so that a highly comfortable heating device can be provided.
[0056]
Furthermore, since the negative ion generating means is located at the appropriate position in the air flow path, the negative ions released from the negative ion generating means can reach the entire room by the warm air, and the effect of the negative ions can be further improved. In addition to this, the air blowing means can serve both for generating the hot air of the device and for the negative ions, and can be provided with a simple and inexpensive structure.
[Brief description of the drawings]
FIG. 1 is a cross-sectional view of a main part of a hot air heating device according to a first embodiment of the present invention. FIG. 2 is a cross-sectional view of the same hot air heating device. FIG. 3 is a control block diagram of the same hot air heating device. FIG. 5 is a cross-sectional view of a main portion of a hot air heating device according to a second embodiment of the present invention. FIG. 5 is a cross-sectional view of a main portion of a hot air heating device according to a third embodiment of the present invention. Description]
11 Body case (metal housing)
16 Burner part (high-pressure gas generating means)
18 Blower 19 Duct (air flow path)
21 Hot air outlet 22 Negative ion generating means

Claims (5)

A metal having a high-temperature gas generating means, a blower for supplying an air flow, a hot-air outlet for mixing the air flow from the blower and the high-temperature gas from the high-temperature gas generating means and discharging it as hot air; A housing, and a discharge-type negative ion generating means disposed at an appropriate position in an air flow path from the blower, and until the negative ions generated from the negative ion generating means are released from the equipment, the electric power of the equipment is discharged. Hot air heating system that does not touch the ground surface. A burner section for burning fuel, a frame rod for detecting a combustion state, a blower for supplying an air flow, and mixing or heat exchange of the air flow from the blower and the high-temperature gas from the burner section to discharge as hot air. A hot air outlet, and a metal housing having a ground surface of the frame rod, a discharge type negative ion generating means disposed at an appropriate position in an air flow path from the blower, and a negative ion generating means generated from the negative ion generating means. 2. The hot air heating apparatus according to claim 1, wherein the apparatus does not contact the electrical ground surface of the device until the negative ions are released from the device. In order to prevent the air flow from the blower from coming into direct contact with the negative ion generating means, a shield is disposed at an appropriate position in the air flow path from the blower on the upstream side of the negative ion generating means. The hot air heating device according to claim 1 or 2, wherein the generated negative ions are diffused by an airflow from a blower flowing around the negative ion generating means. The warm air heating device according to any one of claims 1 to 3, wherein a wall surface of the air flow path on the downstream side of the negative ion generating means is formed of an electrical insulator so as not to reduce the amount of negative ions. The wall surface of the air flow path on the downstream side of the negative ion generating means is formed of a coated steel sheet coated with an insulating paint or pre-coated with the insulating paint so as not to reduce the amount of the negative ions. The hot air heating device according to any one of the above.

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