KR101109135B1 - Far infrared ray irradiating tube type heater - Google Patents

Abstract

The present invention is a semi-circular arc or polygonal shape of the tube of the rear reflector and the linear flue, or the burner of the boiler is installed on one side of the tubular far infrared heater and the combustion chamber from the upper side to the lower side. By forming vertically long, the present invention relates to a tubular far-infrared heater in which three-dimensional heating is possible through the front and side grills of the tubular far-infrared heater, and the heat transfer effect and far-infrared radiation of heat dissipation can be maximized.
To this end, the tubular far-infrared heater of the present invention is a tubular far-infrared heater having a combustion chamber having a far-infrared radioactive material coated on its outer surface, and a linear flue and an arch flue, wherein the tubular shape of the linear flue is horizontally semicircular or polygonal. A bent or burner is installed above one side of the tubular far-infrared heater and the combustion chamber is formed vertically from the upper side to the lower side so that the heat of combustion of the flame heated from the burner descends vertically in the combustion chamber and then again on the multi-stage line. Configure to release heat flow through the flue and arch year.

Description

Tubular Far Infrared Heater {FAR INFRARED RAY IRRADIATING TUBE TYPE HEATER}

The present invention relates to a tubular far-infrared heater, and more particularly, to a variety of shapes, such as semi-circular arc or polygonal convex rear reflector forward, and thus the tubular shape of the linear flue By horizontally bending the semi-circular arc or polygonal shape, the three-dimensional heating is possible through the front and side grills of the tubular far-infrared heater, further maximizing the heat transfer effect of heat dissipation and far-infrared radiation. To a tubular far infrared heater.

Infrared radiation is a kind of electromagnetic waves with a stronger thermal action than the red region of visible light. It is invisible, absorbed by materials, and has strong resonance and resonance effects on organic compound molecules. Emitted in the form of radiant heat from a heated object.

Infrared rays are light rays located between the visible wavelength band and the microwave wavelength band. The infrared rays are near-infrared rays and the rays in the 1.5-5.6 μm (1,500-5,600 nm) range. Infrared rays are classified as far infrared rays with light rays in the 5.6-100 μm (5,600-100,000 nm) region.

In particular, when the infrared rays are irradiated to the human body by the heat ray effect of strong penetration force, the micro-vibration activates cell tissues by vibrating the cells more than 2,000 times per minute, and the capillaries are enlarged by the increase of body temperature by the heat energy generated. By promoting the formation of tissues and improving the constitution of the modern man, which is acidified by pH synergism, to weak alkalinity, it activates the immune system of the human body, thus preventing aging, reducing pain and promoting metabolism, inducing sleep, and chronic fatigue. It is known that there is an effect of preventing adult diseases, heavy metals and waste products by sweating.

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 heater, unlike the conventional convection type heater or conventional heater of air heating method, is a method of directly irradiating far infrared rays to the human body, so it is not affected by wind and has a heating effect due to the excellent straightness of infrared rays. It is suitable for indoor use as well as for outdoor use because it has a long distance and has a large heating effect in the downward direction, and has been spotlighted as a next-generation heater due to the absence of dust, noise and odor due to the development of combustion technology.

1 is a front view of a general far infrared heater 1 'of a cabinet type by white kerosene combustion, in which the tubular far infrared heater 1' with an ocher slab of the illustrated type has a control and display panel 3 'and a burner 4'. , Fuel tank 6 ', combustion chamber 7', and linear and arched flue 8 ', 8a' coated with an outer surface coated with a ceramic layer emitting far-infrared radiation upon heating and exhaust It consists of a filter part 9 '.

Above the casing 2 'is provided a control and display panel 3 which is operated by remote control operation, and inside the casing 2' a burner 4 ', its control unit (not shown) and an intake port (not shown). ) 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 flame inside ') heats the above-mentioned linear and arched flue (8', 8a ') along with the combustion gas by way of zigzag along the linear and arched flue (8', 8a '), and is therefore coated on the outer surface thereof. A large amount of far infrared is emitted by the far infrared radioactive ceramic coating layer. The linear and arched flue 8 ', 8a', which is formed zigzag and has an extended length, is heated to a high temperature so that unburned unburnt 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, a small amount of unburnt contained in the combustion gas is tertiarily combusted and exhausted by passing through a catalyst filter (not shown) mounted in the above-described linear and arched flue 8 'and 8a'. Instant deodorization and purification can also be achieved.

An exhaust filter part 9 'is mounted at the end of the arch flue 8a' at the end, and an adsorption member (not shown) inside thereof adsorbs and collects a small amount of fine dust and harmful gas in the exhaust gas, In addition to purifying while gradually evaporating by the heat continuously obtained from the exhaust gas of the exhausted combustion state, it also performs a partial noise (消音) partly more comfortable heating is possible.

On the other hand, since the exhaust hole (not shown) for discharging high-temperature exhaust gas is formed at the outer end portion of the exhaust filter part 9 ', a guard net 9a' is installed to prevent hand burns due to carelessness. Although not shown, a safety net (not shown) is mounted on the front of the far infrared heater 1 '.

However, in the case of the conventional far-infrared heater as described above, the time that the burned heat source stays in the combustion chamber 7 ', the shipboard and the arch flue 8', 8a 'is short, so that the heat energy of the heat of combustion is not sufficiently transferred. However, since a large amount of thermal energy is released into the atmosphere through the combustion chamber, the shipboard and the arch flue as it is, waste of thermal energy is severe and thermal efficiency is lowered, thereby increasing the fuel cost burden.

Moreover, in the case of the conventional far-infrared heater as described above, heat emission and far-infrared radiation are performed only in the forward direction, thereby limiting three-dimensional heating.

Moreover, in the case of the conventional far-infrared heater as described above, since the combustion chamber is formed horizontally from the lower side, the combustion chamber is not vertically elongated from the upper side to the lower side.

Accordingly, an object of the present invention is to form a semi-circular arc or polygonal shape in which the rear reflector is forwardly convex, thereby converting the tubular shape of the linear flue into a semi-circular arc or polygonal shape. By forming a long bending, it is possible to provide a three-dimensional heating through the front and side grille of the tubular far infrared heater to provide a tubular far infrared heater that can further maximize the heat transfer effect and far-infrared radiation of heat emission.

Another object of the present invention, the burner of the boiler is installed on the upper side of the tubular far-infrared heater and the combustion chamber is formed vertically long from the upper side to the lower side so that the heat of combustion of the flame heated from the burner is lowered and then multistage By moving it upward through the semicircular arc-shaped flue, the discharge time is extended, so that the residence time of combustion heat is further extended, and the new concept of heat transfer effect and far-infrared radiation of heat emission can be further maximized. It is to provide a tubular far infrared heater.

In the present invention for achieving the above object, the exhaust tubular far-infrared heater is a tubular far-infrared heater having a combustion chamber in which a far-infrared radioactive material is coated on an outer surface, and a linear flue and an arc flue, wherein the tubular shape of the linear flue is horizontal. It is characterized in that it is bent into a semi-circular arc or polygon.

The exhaust tubular far-infrared heater according to the present invention for achieving the above object is a tubular far-infrared heater having a combustion chamber and a linear flue and an annular flue coated with a far-infrared radioactive material on an outer surface thereof, wherein a burner has an upper portion on one side of the tubular far-infrared heater. And the combustion chamber is formed vertically from the upper side to the lower side so that the heat of combustion of the flame heated from the burner is vertically lowered in the combustion chamber and then discharges heat flow through the multi-stage linear and arch flutes. It is done.

Here, the rear reflector of the planar semi-circular arc or polygonal shape is installed to protrude forward at the rear side of the semi-circular arc-shaped or polygonal tube-shaped linear flue, and the curved year of the curved semi-circular arc or polygonal tubular shape ( Preferably, the rear reflection plate protruding in the semi-circular arc or polygonal shape is accommodated in the inner space surrounded by the path.

Further, a front grille that is open to the outside is formed in front of the tubular far-infrared heater, and side grilles that are open to both sides are formed to form the rear reflector, the combustion chamber, and the linear and arch flues. It is preferable to radiate far infrared rays or heat flow radiated from the front and both sides of the tubular far infrared heater.

As described above, according to the tubular far-infrared heater according to the present invention, the rear reflector is formed into a semicircular arc or polygonal shape in which the rear reflection plate is convex in the forward direction, and thus the tubular shape of the linear flue is semicircular arc ( Iii) bent in a long shape or polygonal shape, or the burner of the boiler is installed on the upper side of the tubular far infrared heater and the combustion chamber is formed vertically long from the upper side to the lower side so that the heat of combustion of the flame heated from the burner is lowered. By going back and going through the multi-stage semi-circular arc-shaped flue, it is discharged and discharged upward, enabling three-dimensional heating through the front and side grills of the tubular far-infrared heater. There is an effect that the heat transfer effect of the emission and far infrared radiation can be maximized.

1 is a front view of a conventional tubular far infrared heater.
2A is a front view of a tubular far infrared heater according to the present invention.
2B is a side view of a tubular far infrared heater according to the present invention.
FIG. 2C is a plan view of the linear flue of FIG. 2A.
3A is a front view of a tubular far infrared heater according to another embodiment of the present invention.
3B is a side view of a tubular far infrared heater according to another embodiment of the present invention.
3C is a plan view of the linear flue of FIG. 3A.
4 is a front view of a tubular far infrared heater according to another embodiment of the present invention.
5 is a plan view of a tubular far infrared heater according to another embodiment of the present invention.
6 is an enlarged cross-sectional view illustrating a noise tube of a tubular far infrared heater according to still another embodiment of the present invention.

Hereinafter, the most preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art can easily carry out the present invention. .

FIG. 2A is a front view of the tubular far infrared heater according to the present invention, FIG. 2B is a side view of the tubular far infrared heater according to the present invention, and FIG. 2C is a plan view of the linear flue of FIG. 2A, which will be described together for convenience of description.

First, the tubular far infrared heater 1a according to the present invention has a casing 2, a control and display panel 3, a burner 4, a fuel tank 6, and a ceramic layer that emits far infrared rays upon heating is coated on the outer surface. Composed of a combustion chamber (7), linear and arch type flue (8, 8a) and exhaust filter section (9), which is operated above the casing (2) by remote control operation. The control and display panel 3 is provided, and the burner 4, its control unit (not shown), and the inlet port (not shown) are provided in the interior thereof, substantially the same as the conventional example shown in FIG.

On the other hand, the fuel tank 6 may be housed in the lower part of the casing 2 or, if necessary, may be installed outside as a separate tank.

In the example shown, linear and arched flues formed with a combustion chamber 7 and corrugations 8a, 9a coated on the outer surface with a ceramic layer which radiates far infrared rays by heating upon heating. On the rear side of (8, 9), a substantially semicircular arc shaped rear reflector plate 10 is formed in a plane projecting forward.

That is, the substantially semicircular arc-shaped rear reflector 10 is formed of linear and arched flues 8, 9 in which the combustion chamber 7 and the corrugations 8a, 9a are formed. By reflecting the far infrared rays or heat flow radiated to the rear and side to the front and both sides through the front grill 20 and the side grill 21 of the tubular far infrared heater 1, it is possible to maximize the heating efficiency more. .

The rear reflector 10 has a semicircular arc shape that is convex forward in a plane, and generates heat flow and far-infrared rays generated from the combustion chamber 7 and the lower linear flue 8 and the upper two linear flue 8. By reflecting not only the front grille 20 open to the outside of the tubular far-infrared heater 1, but also to the front and both sides through the side grille 21 which is also open to the outside, thereby providing the open side grille 21. More three-dimensional heating can be achieved than the prior art that does not.

The material of the rear reflecting plate 10 having a convex semicircular arc shape toward the front is preferably aluminum, but the material of the rear reflecting plate 10 is not limited thereto. Fabrication is completed through a sheet metal step of cutting, and a pressing step of forming a concave reflection plate to one side by coercionally forming the sheet.

In addition, in the illustrated example, to conform to the shape of the rear reflective plate 10 of the convex semi-circular arc shape forward, and maximize the residence time of the heat source through maximizing the heat transfer effect and far-infrared radiation of heat emission In order to improve the heating efficiency, the horizontal shape of the linear flue 8 is bent long in a substantially semicircular arc shape instead of a straight line. That is, since the horizontal shape of the linear flue (8) is bent long by a semi-circular arc-shaped tube, the surface area for transferring the heat source is greatly enlarged and lengthened, and thus the heat transfer effect and far-infrared radiation of the heat emission. Is maximized.

In this way, the rear reflector 10 is formed into a semicircular arc shape in which it is convex forward, and thus the tubular shape of the linear flue 8 is bent in a semicircular arc shape. By doing so, three-dimensional heating is possible through the open front and side grills 20 and 21 of the tubular far-infrared heater 1a, further maximizing the heat transfer effect and far-infrared radiation of heat dissipation.

3A is a front view of the tubular far infrared heater 1b according to another embodiment of the present invention, FIG. 3B is a side view of the tubular far infrared heater according to another embodiment of the present invention, and FIG. 3C is a plan view of the linear flue of FIG. 3A. In the illustrated example, the rear reflector 110 has a triangular shape protruding forward, and the tube of the linear flue 8 has an inner space in which the rear reflector 110 protruding in the triangular shape is accommodated. The form is shown to be formed in a long pentagonal shape, and all other matters are substantially the same as described above, so a detailed description thereof will be omitted.

In this way, the rear reflector 110 is formed in a convex forward triangle shape, and thus the tubular shape of the linear flue 108 is formed in a pentagonal shape so that the tubular far-infrared heater of FIGS. 2A to 2C ( The total length of the shipboard year is greater than in 1a), further maximizing the heat transfer effect and far-infrared radiation.

Here, in the illustrated example, the shape of the rear reflector is shown as a semi-circular arc or triangular shape, but also a rhombus or other polygonal shape is possible, and in addition to the semi-circular arc or pentagonal shape of the linear year, a rhombus or other polygonal shape is possible. It is a matter of course that the tubular shape of the linear flue can be variously applied in accordance with various shapes of the reflecting plate.

4 is a front view of the tubular far-infrared heater 100 according to another embodiment of the present invention, in the illustrated example, the burner 104 of the boiler is installed on one side of the tubular far-infrared heater 100, the burner of the boiler The combustion chamber 107 associated with the 104 is formed to extend vertically from the upper side to the lower side of the tubular far-infrared heater 1b, and all other matters are substantially the same as described above, so the description thereof will be further described. It will be omitted.

In this way, the burner 104 of the boiler is installed on the upper side of one side of the tubular far-infrared heater 1b, and the combustion chamber 7 is vertically elongated from the upper side to the lower side so that the combustion heat of the flame 5 heated from the burner 104 is increased. This is a semicircular arc of a multi-stage (possibly increased from a three-stage structure to a four-stage staircase structure in Fig. 2a), which descends strongly by gravity vertically below it. By moving to the upper side through the exhaust), the residence time of the heat of combustion is further extended to provide a new concept tubular far-infrared heater 100 which can further maximize the heat transfer effect and far-infrared radiation of heat emission.

Here, in the illustrated example, the semicircular arc-shaped linear flue 8 is shown. However, the combustion chamber 107 having the vertical structure may be equally applied to the linear linear flue as in the prior art.

5 is a plan view of a tubular far-infrared heater 200 according to another embodiment of the present invention. In the illustrated example, the tubular shape of the combustion chamber 207 as well as the tubular shape of the linear flue 8 is also semicircular arc (polygonal). Form is also possible), and all other matters are substantially the same as described above, so the description thereof will be omitted.

6 is an enlarged cross-sectional view showing a noise tube of a tubular far infrared heater according to another embodiment of the present invention. In the illustrated example, the combustion chamber 7 and the arch flue 8a are connected to the combustion chamber 7 and the arch flue 8a. It has a structure in which a tubular expanded noise pipe portion 7-1 having a diameter larger than the diameter of 7) is installed, and all other matters are substantially the same as described above.

Thus, the combustion chamber 7 at the time of combustion is formed between the combustion chamber 7 and the connection part of the arch flue 8a with the noise pipe part 7-1 larger than the diameter of the combustion chamber 7 and the arch flue 8a. There is an effect that the noise generated from (7) can be suppressed and reduced through the noise pipe portion 7-1.

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.

1a, 1b, 100, 200: Pretzel tubular far infrared heater according to the present invention
2: casing 3: control and display panel
4: burner 5: flame
6: fuel tank 7, 107: combustion chamber
8: year on board 8a: year of palace type
9: exhaust filter unit 10, 110: rear reflector
20: front grill 21: side grill

Claims (6)

In the combustion chamber coated with the far-infrared radioactive material on the outer surface, and the tubular far-infrared heater having the linear flue and the arch flue,
The multi-stage pipe form of the linear year is bent horizontally in a semi-circular arc or polygon,
On the rear side of the semi-circular arc-shaped or polygonal tubular line (평면 道), a planar semi-circular arc-shaped or polygonal rear reflector is installed to protrude convexly forward, and the bent semi-circular arc or polygonal tubular line ( Tubular far-infrared heater characterized in that to accommodate the back reflector projecting in the semi-circular arc or polygonal shape to the inner space surrounded by the 煙道. In the combustion chamber coated with the far-infrared radioactive material on the outer surface, and the tubular far-infrared heater having the linear flue and the arch flue,
The multi-stage pipe form of the linear year is bent horizontally in a semi-circular arc or polygon,
A burner is installed above one side of the tubular far-infrared heater, and the combustion chamber is formed vertically from the upper side to the lower side so that the heat of combustion of the flame heated from the burner is vertically lowered in the combustion chamber, and then again the multi-stage linear flue and arches. To release heat flow through the year,
On the rear side of the semi-circular arc-shaped or polygonal tubular line (평면 道), a planar semi-circular arc-shaped or polygonal rear reflector is installed to protrude convexly forward, and the bent semi-circular arc or polygonal tubular line ( Tubular far-infrared heater characterized in that to accommodate the back reflector projecting in the semi-circular arc or polygonal shape to the inner space surrounded by the 煙道. delete The method according to claim 1 or 2,
In front of the tubular far-infrared heater is formed a front grill which is opened to the outside, and side grilles which are opened to both sides to the outside, so that the rear reflector, the combustion chamber, and the linear and arch flues are formed. Tubular far-infrared heater, characterized in that to radiate far infrared rays or heat flow emitted from the front and both sides of the tubular far-infrared heater. The method of claim 1,
Tubular far-infrared heater, characterized in that the tubular shape of the combustion chamber is also bent in a semi-circular arc or polygon. The method according to claim 1 or 2,
A tubular far-infrared heater, characterized in that a noise pipe is interposed between the combustion chamber and the connecting portion of the arch flue.

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