KR101263860B1 - Far infrared ray irradiating tube type heater having supplementary forced convection device - Google Patents

Abstract

The present invention relates to a forced convection far-infrared heater, in the case of integrating a forced convection device to the far-infrared heater to form a hot air blowing housing on the rear side of the uppermost far-infrared tube of the far-infrared heater, while forming a hot air inlet opening on the inclined bottom thereof. By injecting high temperature hot air flowing through the hot air induction port directly toward the lower part of the front center, the hot air temperature is maintained at a constant and high temperature, and the area adjacent to the indoor floor is heated by forced convection, As a result, turbulent flow is formed, thereby improving the overall heating efficiency, and rapidly absorbing upward heat flow generated from the surface of the far-infrared tube heater upwards, thereby deteriorating the far-infrared radiation coating coated on the surface by the temperature reduction effect of the surface of the far-infrared tube. Delaying Writing a new yuyongwon invention that can extend the life of the infrared heater.

Description

Forced Convection Far Infrared Heater {FAR INFRARED RAY IRRADIATING TUBE TYPE HEATER HAVING SUPPLEMENTARY FORCED CONVECTION DEVICE}

The present invention relates to a forced convection far-infrared heater, and more particularly, in the incorporation of a forced convection device into the far-infrared heater, a hot air blowing housing is formed on the rear side of the uppermost far-infrared tube of the far-infrared heater, but the hot air on the inclined bottom thereof. By forming the inlet opening and injecting the high temperature hot air introduced therethrough directly through the hot air induction port, the temperature of the spraying hot air is kept constant and high while forcing the convection adjacent to the indoor floor by forced convection. As it warms up, it creates turbulent flow as a whole, thereby improving the overall heating efficiency and rapidly sucking upwards the rising heat flow generated from the far-infrared tube heater surface, thereby reducing the temperature of the far-infrared tube surface. Far infrared rays coated on its surface by The present invention relates to a forced convection far-infrared heater that can prolong the life of the far-infrared heater by delaying deterioration of the spinning paint.

Infrared rays are rays emitted in the form of radiant heat from a heated object with strong resonance and resonance effects on organic compound molecules. Rays in the wavelength range of 0.76 to 1.5 μm (760 to 1500 nm) are near infrared, 1.5 Light rays in the ˜5.6 μm (1,500 to 5,600 nm) region are classified as mid-infrared rays, and light rays in the 5.6 to 100 μm (5,600 to 100,000 nm) region are classified as far infrared rays.

In particular, the far-infrared rays activate the cellular tissues by vibrating the cells finely when the human body is irradiated due to the heat ray effect indicating a strong penetration force, and the blood vessels are expanded by the expansion of the capillaries by the increase of body temperature caused by the heat energy. By improving the constitution to weak alkaline by activating the body's immune mechanism, by activating the body's immune mechanism, anti-aging, pain relief and promoting metabolism, sleep-inducing effect, prevention of adult diseases such as chronic fatigue, heavy metals and waste products by sweating It is known to be effective.

In addition, since far infrared rays have the characteristic of raising the temperature at the same time as the inside and the surface, uniform heating and drying are possible, which shortens the heating time and saves energy. Therefore, it is applied to the field of heating and drying, and eliminates the bacteria that cause various diseases. As it helps to prevent germs and mold growth, deodorization and dehumidification, and air purification, it is applied to various fields such as housing and building materials, kitchen utensils, textiles, clothing, bedding, medical equipment, and jjimjilbang.

Far-infrared heaters, unlike conventional convection heaters or conventional heaters with air heating, are far-infrared and irradiate directly to the human body to generate heat, so they are not affected by wind and have excellent directivity of infrared rays. Due to the large heating effect, especially the downward heating effect is large, suitable for indoor use as well as indoors, due to the development of combustion technology has been spotlighted as the next-generation heater because there is no dust, noise and smell.

FIG. 5 is a front view of a typical far-infrared heater 1 'of the cabinet type by white kerosene combustion, in which the tubular far-infrared heater 1' of the illustrated type is provided with a control and display panel 2a ', a burner 4', a fuel tank. (6 '), combustion chamber (7'), linear and arched flue (8 ', 9') and exhaust filter section coated on the outer surface with a ceramic layer emitting far-infrared rays when heated ( 11 ').

Above the casing 2 'is provided a control and display panel 2a' which is operated by remote control operation. A burner 4 ', its control unit (not shown) and an intake vent (not shown) are provided in the casing 2'. Is installed, and the fuel tank 6 'is housed below the burner 4'.

When combustion is started from the burner 4 ', the flame 5' generated from the burner 4 'is extended to the inside of the combustion chamber 7', and combustion of fuel such as kerosene is continuously performed, and the combustion chamber 7 ′) The inner flame heats the above-mentioned linear and arched flue (8 ′, 9 ′) while zigzag the linear and arched flue (8 ′, 9 ′) together with the combustion gas, so that it is covered on its outer surface. A large amount of far infrared is emitted by the far infrared radioactive ceramic coating layer. Since the above-described linear and arched flue (8 ', 9') having a zigzag and extended length is heated to a high temperature, the unburned unburned powder in the combustion chamber is instantaneously secondary burned in the process. This contributes to the increase of calorific value and contributes to the purification of exhaust gas.

In some cases, the traces of the fines contained in the combustion gas are tertiarily combusted and exhausted by passing through a catalytic filter (not shown) mounted in the above-described linear and arched flue 8 'and 9'. Instant deodorization and purification can also be achieved.

An exhaust filter portion 11 'is mounted at the end of the end of the annular flue 9', so that an adsorption member (not shown) adsorbs and collects a small amount of unburned dust and noxious gas in the exhaust gas through an exhaust hole. Deodorization and purification are performed while evaporating gradually by the heat continuously obtained from the exhaust gas in the exhausted combustion state, and the noise is also partially performed, thereby enabling more comfortable heating.

On the other hand, since the exhaust hole (not shown) for discharging high-temperature exhaust gas is formed at the outer end of the exhaust filter part 11 ', a guard net 11a' is installed to prevent injuries of hands due to carelessness. Although not shown, a safety net (not shown) is mounted on the front of the far infrared heater 1 '.

However, the conventional far-infrared heater 1 'as described above mainly intends only the radiant heating effect due to the far-infrared emission by the far-infrared radioactive ceramic coating layer, and does not perform forced circulation of the heat flow due to blowing, thus accumulating the heating effect. There was a lack of enemy and synergistic gains.

Accordingly, in order to solve the problems of the conventional most common type of far infrared heater 1 'as described above, the present applicant uses a forced convection far infrared heater 1 ″ as shown in FIGS. 6A to 6C. It was proposed as an issue (registered on June 04, 2004).

6A, 6B, and 6C are respectively referred to as a perspective view, a partial cross-sectional front view, and a cross-sectional view taken along line A-A of FIG. 6B of a conventional forced convection far-infrared heater 1 ″, respectively, for convenience of explanation.

Since the basic structure of the conventional forced convection far-infrared heater 1 ″ shown is substantially the same as the case of FIG. 5 described above, only the differences or non-explained parts will be mainly described.

The illustrated example shows a forced convection type structure in which a multi-purpose blower 5 'is disposed inside the lower box body 3' to perform forced circulation of heat flow due to forced blowing. The multiple blower 5 'is a motor 5a', a rotary shaft 5b 'connected thereto, and a plurality of linear or arc-shaped rotary vanes 5c' extending longitudinally along the periphery of the rotary shaft 5b '. And the bearing part 5d 'which rotatably supports the above-mentioned rotating shaft 5b'. In general, the air blower 5 'has a large air volume and a low noise and vibration.

In the conventional forced convection corrugated far-infrared heater 1 ″, the multi-wing blower 5 'is located at the upper rear side of the lower box body 3' and the upper side thereof is open, and the lower box body 3 'is opened. A plurality of slits (3a ') as the inlet port is formed on the upper front of the guide plate, and guide plates (20', 21 ', 22', 23 for guiding a heat flow during forced blowing by the above-mentioned multi-blown blower (5 ')). ′) Is formed on the back side.

In the example shown, the guide plates 20 ', 21', 22 ', 23' are located slightly above the combustion chamber 7 'and the plurality of linear flues 8', respectively, and the extension length thereof is Mutually identical. Here, the openings 20a ', 21a', and 22a 'are formed in the guide plates 20', 21 ', and 22', respectively, whereas the openings are not formed in the guide plate 23 '. The diameter of the opening 20a 'is larger than the diameter of the opening 21a', and the diameter of the opening 21a 'is larger than the diameter of the opening 22a'.

By adopting such a configuration, the airflow forcedly blown from the multi-purpose blower 5 'collides with the guide plate 20' and forms a turbulent flow, so that the residence time around the combustion chamber 7 'is extended. While being heated and converted into a heat flow, the airflow passing through the relatively large diameter openings 20a 'formed there impinges on the guide plate 21' directly above and forms turbulence, which is further influenced by the linear flue 8 '. The heat flow heated and passed through the opening 21a 'formed therein impinges on the guide plate 22' directly above it, forms turbulence and is further heated again by the linear flue 8 ', and finally the opening Is collided with the guide plate 23 'which is not formed, and turbulence is formed, and further heated by the linear flue 8' again.

On the other hand, in the illustrated example, one end of the combustion chamber 7 'is placed on the support 12' and is firmly attached to the bottom by a looped fixing strip 13 'extending upward from the support 12'. It is fixed, and one end of the uppermost linear flue 8 'is also firmly fixed to the bottom of the ceiling by a fixing strip 15' extending from the fixture 14 '.

The combustion chamber 7 ', the linear flue 8', and the arch flue 9 'may be integrally formed, but are generally formed in a separate type.

In addition, a viewing window 7d 'for observing the flame 4a' ignited from the burner 4 'may be provided at one front side of the combustion chamber 7'.

In the figure, reference numeral 10 'is a silencer as an optional configuration, and 16' is a caster for easy movement.

However, in the conventional forced convection far-infrared heater 1 ″, which has been proposed by the present applicant, the hot air flow path is formed at a 90 ° angle by installing the multi-blown blower 5 'behind the lower box body 3'. In addition to the problem that the hot air is dispersed in each stage, not only the amount of hot air blown toward the front is not satisfactory, but also the temperature of the hot air blown out is low. ) As it flows in through the front slit (3a '), the temperature fluctuation around the fuel tank (6') increases, which causes condensation in the fuel tank (6 '), which causes burners (4') to contain moisture in the fuel. There was a problem that there is a risk of causing undesired results such as the sudden stop of combustion.

As a result, the above-mentioned conventional forced convection far-infrared heater 1 ″ attempts to incorporate a forced convection device into the far-infrared heater can be evaluated, but the forced convection effect has not been sufficiently satisfactory.

Therefore, the first object of the present invention is to carry out convection heating according to forced circulation of heat flow by blowing along with radiant heating by far-infrared rays, so that efficient and economical forced convection far-infrared radiation can be achieved. It is to provide a heater.

The second object of the present invention is to provide a forced convection far-infrared heater that maximizes the heating effect by forced convection by selecting only the heat flow having the highest temperature in the center among the rising heat flows by the far-infrared heater. It is for.

The third object of the present invention is, in addition to the above-mentioned first and second objects, forced convection to effectively carry out cumulative and synergistic increase or maximize of the heating effect by intensively guiding the heat flow by the blowing downwardly forward. It is to provide a food far infrared heater.

The fourth object of the present invention is, in addition to the first to the third objects described above, far-infrared radiation coated on the surface by the effect of reducing the temperature of the far-infrared tube surface by quickly sucking and discharging the upward heat flow heated by the far-infrared heater from the top. It is to provide a forced convection far-infrared heater which can delay the deterioration of paint and extend the life of the far-infrared heater.

According to a preferred aspect of the present invention for achieving the above-mentioned first, second, and fourth objects of the present invention, a combustion chamber, a plurality of linear flues and arches, And a forced convection far-infrared heater having a multi-fly blower, the convective far-infrared heater having a sloped bottom surface formed with a hot air inflow opening and a front surface formed with a hot air discharge opening, which is installed behind the uppermost linear ship of the plurality of linear years. A heat flow blower housing in which the multi-wing blower is installed; The hot air inlet is formed at one end coupled to the front surface of the hot air blower housing and in communication with the hot air discharge opening, and the hot air inlet is formed at the other end thereof, and an upwardly inclined or gradient portion is formed at a portion adjacent to the hot air inlet. And a hot air induction port extending forward through an area between the uppermost linear year of the plurality of linear years and the bottom of the ceiling of the forced convection far-infrared heater. Integrally formed by upward extension and protrusion of the rear reflector of the far-infrared heater; A safety net is installed on the front surface of the forced convection far-infrared heater, and the hot air inlet opening and the hot air discharge opening are perforated horizontally in the center at a length that is 1/5 to 1/3 of the length of the safety net. A forced convection far-infrared heater is provided, which is formed in the form of an opening.

According to another preferred aspect of the present invention for achieving the above object of the present invention, the hot air inlet opening of the inclined bottom surface of the hot air blowing housing and the hot air discharge opening of the front face are formed in the center portion of the inclined bottom and the front face. Iii) a forced convection far-infrared heater which is laterally formed.

According to another preferred aspect of the present invention for achieving the above object of the present invention, the forced convection type in which at least one outward guide or inward guide is formed in the hot air inlet opening formed in the inclined bottom surface of the hot air blowing housing. A far infrared heater is provided.

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According to a preferred aspect of the present invention for achieving the third object of the present invention, there is a forced convection far-infrared heater having a hot air guide inclined downward formed on the top and bottom of the hot air injection port of the hot air induction port Is provided.

As described above, the forced convection far-infrared heater according to the present invention performs the convection heating according to the forced circulation of the heat flow by the blowing in conjunction with the radiant heating by the far-infrared rays, the most in the middle of the rising heat flow by the far-infrared heater By selecting only the heat flow having a high temperature and intensively guiding the heat flow by the blower downwardly, the cumulative and synergistic increase or maximization of the heating effect by the forced convection is achieved to realize excellent efficiency and economy. At the same time, it is possible to extend the life of the far infrared heater by delaying the deterioration of the far-infrared radiation coating coated on the surface by the effect of reducing the temperature on the surface of the far infrared tube by rapidly sucking and discharging the upward heat flow heated by the far infrared heater from the top. .

1 is a perspective photographic view of the performance of the forced convection far-infrared heater according to the present invention.
2 is a side cross-sectional view of a forced convection far infrared heater according to the present invention.
3 is a perspective view of a hot air induction port according to a preferred embodiment applicable to the forced convection far-infrared heater according to the present invention.
4A to 4D are partial cross-sectional views each showing a preferred bottom opening form of the hot air induction port-mounted hot air generating housing of FIG. 3.
5 is a front view of a conventional general far infrared heater.
6A is a perspective view of a conventional general forced convection far infrared heater.
6B is a partial cross-sectional front view of FIG. 6A.
FIG. 6C is a cross-sectional view taken along the line AA of FIG. 6B.

Hereinafter, the present invention will be described in more detail with reference to the accompanying drawings.

1 is a perspective perspective view showing a forced convection far-infrared heater 1 according to the present invention, the overall structural characteristics of which can be clearly understood from the side cross-sectional view of Fig. This will be described.

The forced convection far-infrared heater 1 according to the present invention is substantially the same as the basic configuration of the conventional far-infrared heater except for the presence of the hot air blowing housing 20 and the hot air induction port 30, but with respect to this. In other words, the forced convection far-infrared heater 1 according to the present invention is a control tank (not shown), a burner (not shown), a fuel tank (not shown) installed in the lower box body 3, a combustion chamber 7 ), A ceramic layer emitting far-infrared rays upon heating is composed of linear and arched flues (8, 9) coated on the outer surface.

When combustion is started from a burner (not shown), the flame generated from the burner is extended to the inside of the combustion chamber 7 to continuously burn fuel such as white kerosene, and the flame inside the combustion chamber 7 is combined with the combustion gas. A large amount of far-infrared rays are emitted by the far-infrared radioactive ceramic coating layer coated on the outer surface by heating the above-mentioned linear and arched flue (8, 9) while passing through the linear and arched flue (8,9) with zigzag. Since the above-described linear and arched flue (8, 9), which is formed in a zigzag and has an extended length, is heated to a high temperature, the unburned unburned powder in the combustion chamber (7) is secondarily instantaneously in the process of passing therethrough. Combustion will contribute to the cleanup of the exhaust gas with an increase in calorific value.

On the other hand, an exhaust filter part (not shown) is mounted at the end of the end of the arch in the end of the end, so as to continuously absorb the trace amount of unburnt and harmful gas in the exhaust gas and obtain continuously from the exhaust gas in a completely combustion state discharged through the exhaust hole. Deodorizing and purifying while gradually evaporating by heat, as well as noise (消音) effect is performed so that more comfortable heating is possible.

On the other hand, the outer end portion of the exhaust filter portion is formed in the exhaust hole for the discharge of the high-temperature exhaust gas, a protection net (not shown) for preventing the burn due to carelessness is provided as described in the conventional example.

In addition, one end of the combustion chamber 7 is firmly fixed to the bottom surface by a loop-shaped fixing strip 13 extending upwardly from the support 12, and one end of the uppermost linear flue 8 is also fastened 14. It is firmly fixed to the bottom of the ceiling by a fixing strip 15 extending from it.

Although the combustion chamber 7 and the linear flue 8 and the arch flue 9 may be formed integrally, the combustion chamber 7 is generally formed from a separate type in view of convenience in fabrication and assembly.

Next, the hot air blower housing 20 and the hot air induction port 30 adopted by the forced convection far-infrared heater 1 according to the present invention will be described in sequence.

The hot air blowing housing 20 is provided adjacent to the rear of the top linear flue 8 among the plurality of linear flues 8, and has an inclined bottom surface 21 with a hot air inflow opening 22 and a hot air discharge opening. A multi-head blower 5 is installed therein with the front surface 23 formed therein.

The hot air inlet opening 22 formed in the inclined bottom surface 21 of the hot air blowing housing 20 and the hot air discharge opening 24 formed in the front surface 23 are the inclined bottom surface 21 and the front surface 23, respectively. Is formed laterally in the center of the object.

In the present invention, the shape of the hot air inlet opening 22 and the hot air discharge opening 24 is not particularly limited, but is approximately 1/5 to the length of the front safety net 18 on the front surface of the forced convection far infrared heater 1. It is generally formed in the form of an aperture that is fully perforated transversely to the object in the center at about one-third of its length, but optionally, if necessary, multiple small longitudinal or inclined aperture openings, or multiple Of course, it may be formed in the form of a circular perforated opening.

In the case where the above-mentioned puncture length is less than 1/5 of the length of the front safety net 18, the discharge pressure and speed of the heat flow may be too high, which may damage the comfortable indoor heating environment. It is also undesirable because there is a problem that the discharge pressure and speed are too low to achieve smooth forced convection efficiency.

In addition, in the present invention, the inclination angle of the bottom surface on which the hot air inlet opening 22 is formed is not particularly limited, but an upward inclination angle in the range of 10 to 80 degrees, preferably 30 to 60 degrees, so that rising heat flow can be smoothly introduced therein. It may be formed to have an upward inclination angle, specifically, an upward inclination angle of 45 degrees.

The heat flow blowing housing 20 may be formed separately from the rear reflector 17, but may be integrally formed by upwardly extending and projecting the rear reflector 17.

4A to 4D are partial cross-sectional views respectively showing the shape of the opening 22 of the preferred inclined bottom surface 21 of the hot wind generating housing 20 of FIG. 3. Referring to this, FIGS. ) Shows an example in which two inward guides 22b are formed for effectively guiding the rising heat flow into the multi-purpose blower 5 by the upper and lower ends of one of the perforation openings 22 formed transversely. On the contrary, in the case of FIG. 4B, the upper and lower ends of one of the perforation openings 22 formed laterally to the object are extended outwards so that two outwards for effectively guiding the rising heat flow toward the hot wind generating housing 20. The example in which the guide 22a was formed is shown, and, in the case of FIG. 4C, the lower end of one of the perforation openings 22 formed laterally to the object is long inwardly lifted upward, and upwards the rising heat flow. Only one inward guide 22b having a long length for effectively guiding toward the multi-air blower 5 is formed, and in the case of FIG. 4D, one perforation opening 22 is formed laterally to the object. ) Shows an example in which only one outward guide 22b having a long length for effectively guiding the rising heat flow toward the hot wind generating housing 20 is formed.

In the present invention, the shape or the number of the above-described aperture openings 22 is optional as long as it meets its approximate specific position range as mentioned above, and thus the number of outward and inward guides 22a and 22b described above or Of course, the shape or location is also optional.

Meanwhile, in the present invention, the hot air inlet 31 is coupled to the front surface 23 of the hot air blower housing 20 so that the hot air inlet 31 is connected to one end thereof in communication with the hot air discharge opening 24. The hot air inlet 32 is formed at the other end, and the portion adjacent to the hot air inlet 31 is upwardly inclined or gradients 36a and 37a are formed at the lower plate 36 and the side plate 37, respectively. The rising heat flow is smoothly converted to the front by the multi-function blower 5 to form a structure capable of forced air blowing, and the upward inclination or the slopes 36a and 37a may be linear or curved.

In other words, as shown in perspective view in FIG. 3, the hot air inlet 31 has a hot air inlet 31 formed at one end thereof in communication with the hot air discharge opening 24 of the hot air blowing housing 20. And the other end is formed with a hot air jet hole 32, and consists of the upper plate 35 and the lower plate 36 and both side plates 37, in the illustrated example the upper plate 35 is formed of a smooth surface, while the lower plate ( 36 and both side plates 37 are inclined or gradient portions 36a and 37a are formed in an area adjacent to the hot air inlet 31 so as to be introduced into the hot air inlet opening 22 of the hot air blower housing 20. By changing the direction of 90 degrees through the hot air discharge opening 24 and the hot air inlet 31 of the hot air induction port 30 to function to be smoothly discharged to the hot air injection port (32).

Therefore, the inclined or gradient portions 36a and 37a may be manufactured in various forms having a straight line in one stage, a multi-stage bending straight line, or a gentle curved slope, which is also within the scope of the present invention. to be.

Also, if necessary, the coupling of the hot air inlet 30 to the front surface 23 of the hot air blowing housing 20 may be performed by any suitable fastening means known in the art, such as welding or fixing bolts. In the lower plate 36 and both side plates 37 illustrates a structure in which the bolts are fastened through the fixing portions (33, 34) formed with fixing holes (33a, 34a), respectively.

On the other hand, in the present invention, a set of hot wind guides 38 inclined slightly downwards are formed at the upper and lower ends of the hot air injecting holes 32 of the hot air induction hole 30 to maintain relatively low temperatures. It is designed to increase the forced convection effect by forming a turbulent flow by the heat flow throughout the room by spraying the heat flow toward the center bottom of the room, and the hot air guide 38 is formed on only one of the upper and lower sides. Of course you can.

In the present invention, the heat flow blowing housing 20 and the hot air induction port 30 may be made of a material having high heat reflection efficiency, for example, a stainless steel sheet or a galvanized steel sheet or a plated aluminum sheet in the form of a thin plate. have.

In the figure, reference numeral 16 is a caster for easy movement, and 18 is a front safety net.

On the other hand, although not shown, if necessary, it is possible to place a perfume generator (or filter), anion generator, oxygen generator, etc. in any location to make the heating more comfortable.

The negative ion generating assembly generates negative ions such as ozone by using silent discharge or electrolysis of a solution, but in the present invention, it is preferable to use a Siemens ozone tube.

Although the present invention has been described in detail with reference to preferred embodiments, it is not intended to limit the present invention but merely to illustrate the present invention, and various changes and modifications can be made by those skilled in the art without departing from the gist and scope of the present invention. Of course, this is also within the scope of the present invention.

1: Forced convection far-infrared heater of the present invention
2: casing 2a: control and display panel
3: lower box 4: burner
5: multiple blower 6: fuel tank
7: combustion chamber 8: ship year
9: arch year
10: exhaust filter part 11: protection net
12: support 13,15: fixing strip
14: fixture 16: caster
17: Reflector 18: Front Safety Net
20: heat flow blowing housing
21: slope bottom 22: hot air inlet opening
22a: outward guide 22b: inward guide
23: Front 24: Hot air discharge opening
30: hot air inlet
31: hot air inlet 32: hot air nozzle
33, 34: fixing part 33a, 34a: fixing hole
35: top plate 36: bottom plate
36a: inclined or gradient surface 37: side plate
37a: slope or slope 38: hot air guide

Claims (5)

In a forced convection far-infrared heater having a combustion chamber, a plurality of linear flutes and arch flutes, and a multi-fly blower,
A hot-flow blower housing disposed behind the uppermost line-like year of the plurality of linear years, the inclined bottom surface having a hot-air inlet opening, and the front surface having a hot-air discharge opening therein, wherein the multi-flow blower housing is installed;
The hot air inlet is formed at one end coupled to the front surface of the hot air blower housing and in communication with the hot air discharge opening, and the hot air inlet is formed at the other end thereof, and an upwardly inclined or gradient portion is formed at a portion adjacent to the hot air inlet. And a hot air induction port extending forward through an area between the uppermost linear year of the plurality of linear years and the ceiling bottom of the forced convection far-infrared heater:
The heat flow blowing housing is integrally formed by upward extension and protrusion of the rear reflector of the forced convection far infrared heater;
A safety net is installed on the front surface of the forced convection far-infrared heater, and the hot air inlet opening and the hot air discharge opening are perforated horizontally in the center at a length that is 1/5 to 1/3 of the length of the safety net. Characterized in that the opening is formed
Forced convection far infrared heater. The forced air flow opening according to claim 1, wherein the hot air inlet opening and the hot air discharge opening in the front of the inclined bottom of the hot air blower housing are formed laterally in the center of the inclined bottom and in the front. Convection Far Infrared Heater. The forced convection far-infrared heater according to claim 1 or 2, wherein at least one outward guide or inward guide is formed at a hot air inlet opening formed in the inclined bottom surface of the hot air blower housing. delete The forced convection far-infrared heater according to claim 1, wherein a hot air guide inclined downward is formed at at least one of an upper end and a lower end of the hot air injection port of the hot air induction port.

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