KR20090056289A - Regenerative far infrared ray irradiating tube type heater - Google Patents

Abstract

A regenerative far infrared ray irradiating tube type heater is provided to maintain heat emission for a long time by forming a thermal storage pipe of a thermal storage boiler longitudinally to the rear side of at least one among a combustion chamber, a straight flue, and an arch type flue. A regenerative far infrared ray irradiating tube type heater comprises a combustion chamber(7) whose outer surface is coated with far infrared ray irradiating material; a plurality of linear flues(8) and a bow shaped flue(9); and a heat storage pipe(11) through which water heated passing through the combustion chamber, the straight flue, and the arch type flue passes. A thermal storage pipe is covered in zigzag type along the circumference at the rear side of the straight flue.

Description

Regenerative tubular far-infrared heater {REGENERATIVE FAR INFRARED RAY IRRADIATING TUBE TYPE HEATER}

The present invention relates to a regenerative tubular far-infrared heater, and more particularly, is formed so as to cover a predetermined distance apart along the outer circumference of the back of at least one of the combustion chamber, the linear flue, and the arch year of the far-infrared heater, the heated By installing a heat storage boiler having a heat storage pipe in which the heat storage heat is circulated by heat on the ship and the arch, the heat generation can be continued for a long time by the heat accumulated by the heat storage pipe even if the burner and the combustion chamber are not operated due to the stopped operation. The present invention relates to a heat storage tubular far-infrared heater that can achieve a cumulative and synergistic increase in heating effect and can significantly reduce heating costs.

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 positioned between the visible light wavelength band and the microwave wavelength band. The infrared rays emit light in the wavelength range of 0.76 to 1.5 µm (760 to 1500 nm) and near infrared rays in the range of 1.5 to 5.6 µm (1,500 to 5,600 nm). Mid-infrared rays and light rays in the region of 5.6 to 100 µm (5,600 to 100,000 nm) are classified as far infrared rays.

In particular, when far infrared rays are irradiated to the human body by the heat ray effect of strong penetration force, the cells are vibrated at least about 2,000 times per minute to activate cell tissues. It promotes the formation of tissues and promotes the body's immune system by improving the body's constitution, which is acidified by pH synergism, and activates the immune system of the human body, thus preventing aging, reducing pain and promoting metabolism, inducing sleep, and chronic fatigue. It is known to have the same 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 indoor use because it has a long distance and has a large heating effect on the lower side, and it is 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' of the type shown shows a control and display panel 3 ', a burner 4', a fuel tank. (6 '), combustion chamber (7'), linear and arched flue (8 ', 8a') and exhaust filter section coated on the outer surface with a ceramic layer that emits far infrared rays when heated ( 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 linear and arched flue (8', 8a ') along with the combustion gas via zigzag of the linear and arched flue (8', 8a '), so that the outer surface of the flame is coated on its outer surface. A large amount of far infrared rays 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 unburned powder in the combustion chamber is instantaneously subjected to secondary combustion. This contributes to the cleanup of the exhaust gas along with the increase in calorific value.

An exhaust filter portion 9 'is mounted at the end of the arch flue 8a' at the end, and the adsorption member (not shown) therein adsorbs and collects the unburned powder and the harmful gas in the exhaust gas and discharges it through the discharge hole. Deodorization and purification are performed while evaporating gradually by the heat continuously obtained from exhaust gas in a completely burned state, and in addition, a noise function is performed in part, thereby enabling more comfortable heating.

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

However, the conventional far-infrared heater 1 'as described above mainly intends only a heating effect according to the far-infrared emission by the far-infrared radioactive ceramic coating layer, and cools immediately when the burner 4 and the combustion chamber 7 stop without being operated. When it is thrown away and it does not operate, there was a limit which cannot attain heating effect at all.

In addition, the configuration is complicated by the need for a separate exhaust filter portion 9 'for adsorption and collection of unburned dust and noxious gases at the end of the arch flue 8a' at the end of the conventional far-infrared heater 1 '. There are disadvantages.

Accordingly, the present invention has been made to solve the above problems, an object of the present invention, heating by spaced apart a predetermined distance along the outer periphery of the back of at least one of the combustion chamber, the linear flue, and the arch year of the far infrared heater. By forming the heat storage pipe in which the heat accumulating water that is heated and heat-exchanged by the linear and arched flue is circulated, the heat generated by the heat storage pipe can be sustained for a long time even if the burner and the combustion chamber are not stopped and operated. Accordingly, it is possible to provide a cumulative and synergistic increase in heating effect and to provide a heat storage tubular far-infrared heater that can reduce heating costs.

The regenerative tubular far-infrared heater according to the present invention for achieving the above object of the present invention is a combustion chamber and a tubular far-infrared heater having a plurality of linear flue and arch flue coated with a far-infrared radioactive material on the outer surface, the combustion chamber, the linear And a heat storage pipe circulated with a predetermined distance along the outer circumference of at least one of the back side of the flue and the arch year, and the heat storage pipe circulated with the heated heat exchanged by the heated combustion chamber, the shipboard flue, and the arch flue. do.

Here, the heat storage pipe is preferably covered in a zigzag form along the outer periphery of the back side of the linear flue.

In addition, the heat storage pipe is preferably formed to cover a plurality in a zigzag form along the longitudinal direction on the back side of the linear flue.

In addition, it is preferable that a heat storage tank case is connected to one end of the heat storage pipe via a circulation pump to supply the heat storage water and in which the heat storage water is stored.

In addition, the heat storage case is preferably further included a latent heat material.

In addition, it is preferable to blow a heat flow generated by a multi-purpose blower inside the heat storage tubular far-infrared heater or the heat storage generated by the heat storage pipe to its entire surface.

As described above, according to the heat storage tubular far-infrared heater according to the present invention, the heat storage pipe of the heat storage boiler is terminated toward the rear surface of at least one of the combustion chamber, the linear flue, and the arch flue. By forming in the direction, the heat storage water in the heat storage pipe is heated and regenerated in accordance with the far infrared radiation emitted by the far-infrared radioactive ceramic coating layer, so that the heat generated by the heat storage heat of the heat storage boiler of the heat storage boiler is stopped even when the heating by the burner and the combustion chamber is stopped. It has an effect that can last a long time.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art may easily implement the present invention.

2A and 2B are front views of the regenerative tubular far infrared heater according to the present invention, respectively, and FIGS. 2C and 2D are schematic enlarged views showing the shape of the heat storage pipe corresponding to FIGS. 2A and 2B, respectively, for convenience of description. do.

As shown, the regenerative tubular far-infrared heater 1 according to the invention basically comprises a casing 2, a lower box 3, a burner 4, a fuel tank 6, and a far-infrared radiation upon heating to heat radiation. The ceramic layer to be radiated is composed of a combustion chamber 7 coated with an outer surface and linear and arched flues 8, 9 having wrinkles 8a formed thereon.

Above the casing 2, a control and display panel 2a operated by a remote control is installed, and a burner 4, a control unit (not shown) and an intake port (not shown) are installed therein. It is substantially the same as the conventional example shown in FIG.

Here, as in the conventional example shown in Fig. 1 described above, unlike the exhaust filter portion 9 'through which the high-temperature exhaust gas is discharged, the distal end side of the linear flue 8 formed at the top is completely closed.

Further, in the heat storage tubular far-infrared heater 1 according to the present invention, at least one of the back of the combustion chamber 7, the linear flue 8, and the arch flue 9 is provided. The rear surface is spaced apart a predetermined distance along the outer periphery, and the heat storage water is heated by the combustion chamber 7 and heated and heat-exchanged by a large amount of far-infrared rays emitted from the linear and arched flue 8, 9 circulating. The heat storage boiler 10 in which the heat storage pipe 11 is formed is further installed.

Thus, the heat storage pipe 11 of the heat storage boiler 10 toward the rear surface of at least one of the combustion chamber 7, the linear flue 8, and the arch flue 9. Is formed in the vertical direction, and the heat storage water in the heat storage pipe 11 is heated and regenerated in accordance with the far infrared radiation emitted by the far-infrared radioactive ceramic coating layer, so that the heating by the burner 4 and the combustion chamber 7 stops and does not operate. The heat accumulated by the heat storage pipe 11 of 10 allows the heat generation to continue for a long time.

On the other hand, the end of the linear flue 8 is completely closed, because the linear and arched flue 8, 9 having a length extending in a zigzag is heated to a high temperature so that the unburned fine powder is not burned in the combustion chamber 7. Iii) the secondary combustion is instantaneously in the process of passing through this to clean up the exhaust gas with an increase in the calorific value, and also through the catalyst filter (not shown) mounted in the shipboard and arch flue (8, 9). This is because a complete combustion is performed so that unburned fine fuel is not generated at all. However, in the present invention, it is optional to completely close the end of the linear flue 8, and as in the prior art, an exhaust filter part 9 'through which exhaust gas is discharged may be provided.

Here, in the illustrated example, the heat storage pipe 11 is formed in a vertical direction along the rear shape of the linear flue 8 only, and is zigzag along the outer circumference of the rear side of the linear flue 9. 2a or 2c, or a plurality of zigzag-shaped covers (refer to FIG. 2d) along the longitudinal direction on the rear surface of the linear flue 9, but the combustion chamber 7 Of course, it is also possible to form a form that covers all the back or only a portion of the linear year (8), and the arch type year (9).

When explaining the structure of the heat storage boiler 10 in more detail, the heat storage boiler 10 is installed on one side in the heat storage tubular far-infrared heater 1 according to the present invention, the heat storage water is stored, a resin material or a metal material A heat storage tank case 12 having a substantially rectangular box shape; One end thereof is connected to the heat storage tank case 12 to supply the heat storage water, and a rear surface of the combustion chamber 7, the linear flue 8, and the arch flue 9. The heat storage pipe 11 is formed in the vertical direction along the shape; It consists of a circulation pump 13 interposed between the heat storage tank case 12 and the heat storage pipe 11 to circulate the heat storage water stored in the heat storage tank case 12 to the heat storage pipe 11.

In addition, in the heat storage water of the heat storage case 12, a known latent heat material in a liquid or solid state is contained, and the heat storage pipe 11 is heated in accordance with the far infrared radiation emitted by the far infrared radiation ceramic coating layer. The regenerative water can be prevented from being cooled by the latent heat dissipated by the latent heat material, so that the further accumulated heat can last for a long time in the heat storage pipe 11.

On the other hand, as shown in Figure 2a, in order to improve the heating efficiency by maximizing the far-infrared radiation and heat dissipation area, the entire outer surface of the arch year (9) is formed with wrinkles (not given the drawing number), linear year A large number of wrinkles 8a are formed in part of the outer surface of (8). In the illustrated example, the wrinkles 8a are formed only on a part of the outer surface of the linear flue 8, but may be formed continuously over the entire outer surface of the linear flue 8, and the present invention defines the forming region. It is not.

Thus, with this configuration, the surface area of the linear flue 8 is dependent on the height and depth of the ridges and valleys of the corrugation 8a, but generally referred to as about 40% at the same length compared to the case of simply consisting of smooth surfaces. The surface area increased by about 200% can be given, and thus the heating efficiency due to the dramatic increase in the far-infrared radiation surface area and the heat dissipation surface area per unit length of the linear flue 8 is also significantly increased.

The entire outer surface forming the ridges and valleys of the corrugation 8a is coated with a far-infrared radioactive material, similar to the outer surface of the combustion chamber 7 and the arch flue 9, and a large amount of far infrared rays from the increased outer surface when heated. It is formed to radiate by thermal radiation.

Meanwhile, the combustion chamber 7 and the linear flue 8 and the arch flue 9 may be integrally formed, but may be formed in a separate type, and in the case of the separate type, the linear flue 8 of the connection portion may be formed. The insertion end is formed in the form of a cylindrical body having a smooth surface for ease of insertion fixing to one end of the arch flue 9 during assembly.

In addition, one side of the front side of the combustion chamber (7) as an optional component of the present invention for observing the flame (4a) ignited from the burner (4) observation window made of quartz having high transparency, heat resistance and excellent strength characteristics ( 7d) may be provided, and the viewing window 7d allows the observer to induce a sense of warmth by seeing the ignition flame through it.

3 is a partial cutaway front view of a regenerative tubular far infrared heater 1a according to another embodiment of the present invention.

As shown in FIG. 3, a multi-purpose blower 5 is disposed inside the lower box body 3 to generate a regenerative tubular far-infrared heater 1a having a regenerative boiler 10 according to the present invention by forced blowing. It is possible to forcibly blow the heat stored in the heat generated by the heat flow and the heat storage pipe 11 to the front thereof, so that the heating efficiency can be further improved by rapid heating.

Here, the position of the multi-blown blower 5 is arbitrary in the present invention, and of course, may be located in other suitable positions as necessary. In the illustrated example, the blade blower 5 includes a motor 5a, a rotary shaft 5b connected thereto, a plurality of linear or arc rotary blades 5c extending in the longitudinal direction along the periphery of the rotary shaft 5b, It is comprised by the bearing part 5d which supports the said rotating shaft 5b freely.

In the illustrated example, the air blower 5 has a large amount of air and a low noise and vibration. However, the present invention is not limited thereto, and a plurality of small circular blowers (not shown) may be used as the length of the combustion chamber 7. Of course, it may be positioned at regular intervals along the direction.

Except for the above, the configuration of the regenerative tubular far infrared heater 1a having the multi-wing blower 5 according to the present invention is the same as that of the regenerative tubular far infrared heater 1 shown in FIGS. 2A to 2D. Further explanation of the details will be omitted.

4 is a partially cutaway front view of the regenerative tubular far-infrared heater 1b according to another embodiment of the present invention, and since the basic configuration thereof is substantially the same as that of the above-described embodiments, a detailed description of the same configuration is omitted and is different. Only the configuration will be mainly described.

That is, in the heat storage tubular far-infrared heater 1b according to the present invention shown in FIG. 4, a ceramic layer that radiates far infrared rays by heat radiation during heating is coated on the outer surface, as compared with the embodiment shown in FIG. 2A. The rear reflector 30 and the side reflector 31 are formed on the rear and both sides of the linear and arched flues 8 and 9 having the combustion chamber 7 and the corrugated portion 8a. There is a difference in one respect.

That is, the rear reflector 30 and the side reflector 31 are radiated to the rear and side surfaces of the linear and arched flues 8 and 9 in which the combustion chamber 7 and the corrugations 8a are formed. By collecting the heat storage from the far infrared or heat storage pipe 11 and reflecting to the front surface of the tubular far infrared heater 1b, it is possible to maximize the heating efficiency more.

The rear reflector 30 and the side reflector 31 are preferably formed up and down in the shape of a concave plate in accordance with the combustion chamber 7 and the lower linear flue 8 and the upper two linear flue 8, respectively, It is arbitrary according to the number of linear years 8, etc., and does not limit the number of top and bottom.

In addition, since the combustion chamber 7 is generally larger in circumference than the linear flue 8, the size of the lower rear reflector 30 and the side reflector 31 corresponding to the combustion chamber 7 is larger than that of the upper flue 8. Is more preferably formed.

The material of the back reflector 30 and the side reflector 31 is preferably aluminum, but the material of the back reflector 30 and the side reflector 31 is not limited to the material of the back reflector 30 and the side reflector 31. Through the sheet metal cutting step and the pressing step of forming a concave reflecting plate to one side by pressing the molding step and the like is completed, it is a well-known technology of such a rear reflecting plate 30 and the side reflecting plate 31, the more detailed description It will be omitted.

Further, in the present invention, optionally, at least one strip in the longitudinal or transverse direction or the like on at least part of the back plate, both side plates, or the safety grill (not shown) of the linear flue 8 and the arch flue 9 may be used. Purified tablets made of various forms, salted plates, pressed charcoal plates, charred plates, or ocher plates, etc., may be left as they are or may be attached using a suitable known metal holder.

These ceramic materials are known to have excellent far-infrared radiation effect when heated.The use of these ceramic materials not only doubles aesthetic effects, but also responds well to the well-being hot air of the roots. Can be satisfied.

Although the present invention has been described in detail with reference to preferred embodiments according to the present invention, this is only for illustrating the present invention and is not intended to limit the present invention, and those skilled in the art can make various changes and modifications without departing from the scope of the present invention. It should be noted that this is possible as well as this is also within the scope of the present invention.

BRIEF DESCRIPTION OF THE DRAWINGS The front view of the general far infrared heater of the cabinet type by white kerosene combustion.

2A and 2B are front views of the regenerative tubular far infrared heater according to the present invention, respectively.

2C and 2D are schematic enlarged views illustrating the shape of a heat storage pipe corresponding to FIGS. 2A and 2B, respectively.

3 is a partially cutaway front view of a regenerative tubular far infrared heater according to another embodiment of the present invention.

4 is a partial cutaway front view of a regenerative tubular far infrared heater according to another embodiment of the present invention.

Explanation of symbols on the main parts of the drawings

1, 1a, 1b: Regenerative tubular far infrared heater of the present invention

2: casing 2a: control and display panel

3: lower box 4: burner

4a: flame

5: multi blower 5a: motor

5b: rotary shaft 5c: rotary blade

5d: bearing 6: fuel tank

7: combustion chamber 8: ship year

9: arch year 8a: crease

7d: viewing window

10: heat storage boiler 11: heat storage pipe

12: heat storage tank case 13: circulation pump

14: electric far infrared heater 16: caster

30: rear reflector 31: side reflector

Claims (9)

In the combustion chamber in which the far-infrared radioactive material is coated on the outer surface, and the tubular far-infrared heater having a plurality of linear flutes and arch flues, A regenerative pipe is formed in which the regenerated water circulated by a predetermined distance is spaced along the outer periphery of the rear surface of at least one of the combustion chamber, the linear flue, and the arch flue, and the heat accumulating water is heated and heat-exchanged by the heated flue. Regenerative tubular far-infrared heater, characterized in that. The method of claim 1, The heat storage pipe is a heat storage tubular far-infrared heater, characterized in that the zig-zag shape is covered along the outer periphery of the back side of the linear flue. The method of claim 1, The heat storage pipe is a heat storage tubular far-infrared heater, characterized in that formed in the zigzag form along the longitudinal direction on the back side of the linear flue cover. The method of claim 2 or 3, A heat storage tubular far-infrared heater, characterized in that the heat storage tank case is further connected to one end of the heat storage pipe via a circulation pump to supply the heat storage water, the heat storage water is stored. The method of claim 4, wherein The heat storage tubular far-infrared heater, characterized in that further includes a latent heat material in the heat storage case. The method of claim 1, A regenerative tubular far-infrared heater characterized in that the inside of the regenerative tubular far-infrared heater is blown to the front surface of the heat flow generated by the multi-wing blower and the heat generated by the heat storage pipe. The method of claim 1, A heat storage type tubular far-infrared heater, characterized in that the distal end of the uppermost linear flue is closed. The method of claim 1, A regenerative tubular far-infrared heater, characterized in that a plurality of rear reflecting plates and side reflecting plates are installed on the rear side and both side surfaces of the combustion chamber and the linear and arch type flue, respectively. The method of claim 1, At least one of the purgatory plate, the salt plate, the char plate, the ganban stone plate, and the ocher plate is attached to at least a portion of the back plate, both side plates, or the safety grilles of the ship year and the arch year. Regenerative tubular far infrared heater.

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