JP4937932B2 - Infrared generator - Google Patents

Description

  The present invention relates to an infrared ray generator that emits infrared rays.

Patent Document 1 discloses a liquid fuel combustion infrared generator. This infrared ray generator is equipped with a nozzle spray burner at the rear of the combustion cylinder. Further, in this infrared ray generator, a perforated metal plate having a large number of holes perforated substantially uniformly is attached to the front surface of the combustion cylinder. This type of infrared ray generator burns liquid fuel in a combustion cylinder (combustion chamber) and radiates infrared rays from the front surface of a perforated metal plate (heat radiating plate).
Japanese Patent Laid-Open No. 5-322120

  As an infrared ray generator, a device that is warmer with a small amount of combustion and that has a relatively low operating noise is required.

One aspect of the present invention includes a chamber having an outer periphery formed by a heat insulating wall and extending forward from the rear, a porous heat dissipating plate disposed at the front of the chamber, a rotary burner and a fan disposed at the rear of the chamber, In the rotary burner, a rotary vaporization cylinder, a cylindrical combustion disk, and a combustion outer cylinder for forming a gas chamber between the combustion disk and the combustion disk are arranged in this order from the inside. The supplied liquid fuel is vaporized in the rotary vaporization cylinder, and burned as a mixed gas together with the combustion air supplied from the fan through the gas chamber to the chamber through the gas chamber, and the heat radiating plate radiates infrared rays forward , Further, the cylinder has an accommodating cylinder provided outside the combustion outer cylinder, and a part of the air supplied by the fan flows as cooling air between the combustion outer cylinder and the accommodating cylinder, and the combustion gas flows. Emitted along the inside of the heat insulating wall of Nba is an infrared generator.

  This infrared ray generator is provided with a rotary burner (rotating atomizing burner), and blows out a mixed gas containing vaporized liquid fuel and combustion air from a cylindrical combustion disc and burns it. For this reason, in the rotary burner, an annular blue fire is generated, combustion noise is small, and combustion efficiency can be improved. In this infrared ray generator, the heat generated by the rotary burner heats the front radiator plate through the chamber, and is mainly output to the outside as infrared rays from the radiator plate. Therefore, an infrared generator with low noise and high output can be obtained. Therefore, according to this infrared ray generator, compared with an infrared ray generator provided with a gun type burner (nozzle spray type burner), an infrared ray generator having higher combustion efficiency, warmer and less operating noise is provided. it can.

  In an infrared ray generator equipped with a gun type burner, a plurality of holes are usually formed uniformly in a heat sink. However, the inventors of the present invention, in the infrared generator having a rotary burner, rather than uniformly forming a plurality of holes in the heat sink, changing the diameter of the plurality of holes, the infrared radiation is forwarded from the heat sink. It has been found that an infrared ray generator that can be more uniformly radiated (a red hot part can be formed uniformly) can be provided.

  That is, the heat generated by the rotary burner heats the heat sink through the chamber. In order to secure an area for generating infrared rays, it is desirable to increase the area of the heat sink, and the chamber is wider from the rear than the rear. It has been found that the heating state of the heat sink attached to such a chamber can be controlled by changing the diameters of a plurality of holes provided in the heat sink. For example, in an infrared generator equipped with a rotary burner, the heat output from the rotary burner is transmitted through the chamber including radiation and high-temperature combustion gas. This is considered to be because an effect such as equalization of the distribution in the interior can be obtained.

  In this infrared ray generator, the heat radiating plate is porous and includes a plurality of holes. The plurality of holes preferably have a hole diameter that decreases in the vertical direction from the lower side toward the upper side. A rotary burner installed in a substantially horizontal direction blows out hot combustion gas in a substantially horizontal direction. Therefore, compared with the case where the mist-like fuel is ejected horizontally by the gun-type burner and a flame is generated in front of the burner, the high temperature part tends to spread above the chamber. Further, the chamber whose front surface is a heat radiating plate extends from the rear to the front in order to secure the area of the heat radiating plate, and the space expands not only in the left and right directions but also in the vertical direction in front of the rotary burner. Therefore, by reducing the diameter of the plurality of holes of the heat sink from the lower side toward the upper side, the high temperature portion can be made difficult to rise upward in the chamber. Therefore, infrared rays can be radiated uniformly forward from the heat radiating plate (the red hot part can be formed uniformly).

  Furthermore, it is preferable that the plurality of holes of the heat sink have a smaller hole diameter in the left-right direction toward the center. By doing in this way, the high temperature part can be expanded (diffused) in the left and right in the chamber that is also expanded to the left and right, and the intensity of infrared rays emitted forward from the heat sink can be made more uniform.

  Further, the pore diameter (a plurality of holes) of these heat radiating plates may be continuously changed in diameter. In the production of a heat sink, it is desirable that the hole diameter changes step by step. Moreover, many heat sinks are curved forward and are subjected to pressing. It is possible to make a hole before pressing, and in this case, a plurality of elliptical holes are formed in the heat sink by the pressing.

  In addition, in the infrared generator provided with the rotary burner, the inventors of the present application may cause so-called back combustion (backfire) in which flame is blown into the gas chamber between the combustion disc and the combustion outer cylinder. I found out. If back combustion occurs, it is difficult to continue combustion, which is not preferable.

According to this infrared ray generator, the storage cylinder is further provided outside the combustion outer cylinder, and a part of the air supplied by the fan is allowed to flow as cooling air between the combustion outer cylinder and the storage cylinder . Since the temperature of the gas chamber can be lowered by flowing cooling air supplied by a fan between the combustion outer cylinder and the housing cylinder, a flame is generated in the gas chamber between the combustion disk and the combustion outer cylinder. So called back combustion can be suppressed. On the other hand, since the combustion plate is not cooled directly, it is possible to suppress the temperature of the combustion plate from greatly decreasing, thereby inhibiting the vaporization of liquid fuel, or the temperature of the mixed gas blown out from the combustion plate is greatly decreased. This can be suppressed.

  This cooling air is not expected to contribute to combustion as combustion air of mixed gas blown out directly into the chamber and blown out of the combustion disc. Therefore, the method of flowing the cooling air between the combustion outer cylinder and the housing cylinder and the direction in which the cooling air blows out to the chamber can be freely selected so as to be suitable for cooling the combustion outer cylinder. For example, it is possible to blow out along the inside of the heat insulating wall of the chamber or to increase the amount of air flowing above the housing cylinder.

  In addition, it is desirable to provide a discharge path for discharging the remaining liquid fuel from the lower side of the combustion plate of the rotary burner and the lower side of the combustion outer cylinder to the fuel tank for storing the liquid fuel. There is also a method in which drain is blown forward and discharged to the chamber, and evaporated or burned by heat in the chamber or radiant heat from the heat sink. However, when the rotary burner is directed upward, draining is difficult, and if it accumulates, a situation may occur in which the motor shaft flows backward. By providing a discharge path (discharge pipe) for returning the drain from the rotary burner to the fuel tank, the drain can be discharged from the rotary burner to a place other than the chamber.

  That is, the rotary burner has a posture in which the axis of the rotary vaporization cylinder is inclined so as to face upward, and the discharge path discharges drain to the fuel tank from the lower rear side of the combustion disk and the lower rear side of the combustion outer cylinder. It is desirable to do so. By doing so, liquid fuel remains on the lower rear side of the combustion plate and the lower rear side of the combustion outer cylinder even when the rotary vaporization cylinder is used in an attitude in which the axis is inclined upward. There is almost nothing, and it becomes possible to turn the attitude of the rotary burner upward in order to turn the heat sink upward or to adjust the red hot part of the heat sink.

Furthermore, according to this infrared generator, the combustion disk is provided with a plurality of openings for blowing out the mixed gas, and the diameter R of these openings preferably satisfies the following condition (0).
1.60 mm ≦ R ≦ 2.20 mm (0)
Moreover, it is more preferable that the diameter R of the opening satisfies the following condition (1).
1.85 mm ≦ R ≦ 2.00 mm (1)
When the diameter R of the plurality of openings of the combustion disk is formed so as to satisfy the expression (1), the combustion efficiency is improved. In addition, the driving sound can be further reduced.

Furthermore, it is desirable that the plurality of openings of the combustion disk are two-dimensionally arranged in a staggered manner. An interval (pitch) between a plurality of openings can be secured. In the plurality of openings, it is desirable that the pitch P1 every other column in the first direction and the pitch P2 every other row in the second direction satisfy the following condition (2).
5.0 mm ≦ P1, P2 ≦ 8.0 mm (2)

  Another aspect of the present invention is an infrared heating device having the above infrared generator and a fuel tank for storing liquid fuel.

  Hereinafter, an infrared generator according to an embodiment of the present invention will be described with reference to the drawings. FIG. 1 is a side view of an infrared heater (infrared heater) including an infrared generator and a fuel tank. FIG. 2 is a side view showing a part of an infrared heater provided with an infrared generator. FIG. 3 is an end view of the infrared generator provided in the infrared heater. FIG. 4 shows a state in which the infrared ray generator is tilted and used.

  As shown in FIG. 1 and FIG. 2, the infrared heater 1 includes an infrared generator 10, a housing 2 that houses the infrared generator 10, a fuel tank 11 disposed below the housing 2, the housing 2 and the fuel. It has a frame 3 that supports the tank 11, and wheels 4 a and casters 4 b provided on the frame 3. The housing 2 is supported by the frame 3 so as to turn up and down (turn) through a turning shaft 6. For this reason, the infrared ray generator 10 has an attitude in which the axis L (the axis L of the rotary vaporization cylinder of the rotary burner 20) is substantially horizontal (see FIG. 3) and an attitude in which the axis L is inclined upward (FIG. 4). (See)) and can be turned up and down (rotated). Further, the infrared heater 1 can be moved to an arbitrary place by wheels 4a and casters 4b.

  The infrared ray generator 10 housed in the housing 2 includes a substantially truncated cone-shaped or truncated pyramid-shaped chamber 12 whose front is wider than the rear, and a porous heat sink 30 disposed in front of the chamber 12. , And a rotary burner 20 disposed behind the chamber 12. The rotary burner 20 is housed in a housing cylinder 15 behind the chamber 12, and a fan cover 16 that houses the fan 13 and the motor 14 is disposed further rearward. A safety guard 7 is attached to the front of the housing 2. A circulator 65 for ventilating the inside of the housing 2 is attached to the upper part of the housing 2. Ventilation air 68 is sucked from suction ports 61 and 62 provided in the lower part of the housing 2 and discharged from a discharge port 63 provided in the upper part of the housing 2. By ventilating the inside of the housing 2, the internal temperature of the housing 2 is prevented from excessively rising. At the same time, the heated ventilation air 68 is emitted from the front surface of the housing 2, so that the room can be heated together with the infrared rays emitted from the radiator plate 30.

  A heat shield plate 66 is disposed behind the housing (exterior) 2 so as to divide the interior of the housing 2 into front and rear. The chamber 12 and the rotary burner 20 are accommodated in front of the heat shield plate 66, and the fan 13 and the motor 14 accommodated in the fan cover 16 are accommodated in the rear of the heat shield plate 66. Further, the housing cylinder 15 housing the rotary burner 20 and the fan cover 16 are respectively attached to the front and rear of the heat shield plate 66. The front side of the heat shield plate 66 is a section in which a portion that generates heat is stored, and the front section of the housing 2 is ventilated by air 68 for ventilation. By separating the front and rear of the housing 2 with the heat shield plate 66 and suppressing the temperature rise behind the housing 2, heat is released to the rear of the housing 2, and the fan and the motor are affected by thermal expansion (thermal deformation). Can be suppressed.

  As shown in FIGS. 3 and 4, the infrared generator 10 includes a chamber 12, a porous heat dissipating plate 30 disposed in front of the chamber 12, a rotary burner 20 and a fan 13 disposed in the rear of the chamber 12. And a rotary vaporizer cylinder 21 provided in the rotary burner 20 and a motor 14 for rotating the fan 13, a storage cylinder 15 for storing the rotary burner 20, and a fan cover 16 for storing the fan 13 and the motor 14. Yes.

  The chamber 12 is formed in an open shape so that its diameter increases toward the front side. The outer periphery of the chamber 12 is formed by a heat insulating material wall (heat insulating wall) 17. A storage cylinder 15 is provided behind the chamber 12, and a rotary burner 20 is stored inside the storage cylinder 15. A fan cover 16 is provided behind the housing cylinder 15, and the motor 14 and the fan 13 are housed in the cover 16. Therefore, in this example, the motor 14 is provided behind the rotary burner 20, and the fan 13 is provided behind the motor 14.

  In the rotary burner 20, a cylindrical rotary vaporizing cylinder 21, a cylindrical combustion disc 22, and a cylindrical combustion outer cylinder 23 are arranged in this order from the inside. The rotary vaporizing cylinder 21 is a bottomed cylindrical (cup-shaped) member having an end wall 21a on the front side. A substantially conical diffuser 24 for guiding the liquid fuel F to the rotary vaporizing cylinder 21 is provided inside the end wall 21 a of the rotary vaporizing cylinder 21. The diffuser 24 is rotated integrally with the rotary vaporizing cylinder 21 by the motor 14. The combustion disc 22 is a bottomed cylindrical member having an end wall 22a on the rear side. The end wall 22a is annular and has an opening 22b in the center, and rotates so as to face the opening 22b. A vaporizing cylinder 21 is provided. A gap between the edge of the opening 22b and the rotary vaporizing cylinder 21 serves as a first fuel scattering hole (gap) 25 in which fuel that is not vaporized at the time of startup or the like is sprayed.

  The combustion outer cylinder 23 disposed outside the combustion disk 22 is also a bottomed cylindrical member having an end wall 23a on the rear side, and is formed slightly larger than the combustion disk 22. The end wall 23a is annular and has an opening 23b at the center, and a partition wall 23c rises from the edge of the opening 23b toward the inside of the rotary vaporizing cylinder 21. The inside of the partition wall 23 c becomes a space for supplying combustion air from the fan 13 to the rotary vaporizing cylinder 21. The combustion plate 22 is a porous member in which a plurality of holes (openings, porous holes, flame holes) 22c are arranged in a staggered manner. A space between the combustion plate 22 and the combustion outer cylinder 23 serves as a gas chamber 26 for blowing out a mixed gas in which the liquid fuel vaporized by the rotary vaporization cylinder 21 and the combustion air are mixed from the porous 22c of the combustion disk 22. .

  The rotary burner 20 is connected to the fuel tank 11 by a fuel pipe 41, and a pump 42 is provided in the middle of the pipe 41. By driving the pump 42, the liquid fuel F supplied from the fuel tank 11 is sprayed to the diffuser 24 of the rotary vaporization cylinder 21 through the fuel pipe 41, and diffused integrally with the rotary vaporization cylinder 21 by the motor 14. When the body 24 is rotated, the liquid fuel F evaporates (vaporizes) while spreading in a thin film shape on the inner surface of the diffuser 24 due to centrifugal force. The evaporated liquid fuel F is first blown out from the first fuel scattering hole 25 and burned. Next, the vaporized liquid fuel F is mixed with the combustion air supplied from the fan 13 (see arrow Y in FIG. 3) to become a gaseous state, and the mixed gas B is discharged from the porous 22c of the combustion plate 22 through the gas chamber 26. And burns in the vicinity of the combustion plate 22.

  A flame rod 18 and an ignition rod (electrode) 19 for ignition are arranged inside the combustion disk 22. When ignited, the fuel released from the fuel scattering hole 25 provided in the rotary vaporizing cylinder 21 is ignited by the ignition rod 19. When combustion occurs in the vicinity of the combustion plate 22 and the inside of the chamber 12 is heated, a mixed gas B in which the liquid fuel F vaporized by the diffuser 24 of the rotary vaporization cylinder 21 and the combustion air is mixed is obtained and burned. Will continue.

  The heat sink 30 is formed in a curved shape so as to protrude to the front side. In this infrared ray generator 10, the mixed gas B obtained by vaporizing the liquid fuel F supplied from the fuel tank 11 is annularly burned by the combustion plate 22 of the rotary burner 20, and the heat radiating plate 30 is heated by the heat generated by the combustion. . The burned combustion gas heats the porous heat radiating plate 30 through the chamber 12, and is further discharged forward through the holes of the heat radiating plate 30. In this infrared ray generator 10, there is heat dissipation by the emitted combustion gas, but the thermal energy obtained by the combustion of the mixed gas B is released to the outside mainly as infrared rays radiated forward from the radiator plate 30.

  As described above, the infrared ray generator 10 includes the rotary burner (rotary atomizing burner) 20, and the liquid fuel F is vaporized in the burner to be blown out and burned. For this reason, the combustion in the rotary burner 20 becomes blue fire combustion by the combustion of the mixed gas B which has been vaporized, and the combustion efficiency is good. Further, the mixed gas B is blown out from the cylindrical combustion disk 22 in an annular shape, and blue fire is also formed in an annular shape. Furthermore, according to the infrared ray generator 10, the mixed gas B is completely burned at a short distance. For this reason, the distance between the heat sink 30 and the rotary burner 20 can be reduced.

  Therefore, the infrared ray generator 10 can efficiently heat the heat radiating plate 30 on the front surface of the chamber 12 by the rotary burner 20 having good combustion efficiency. For this reason, more infrared rays are emitted with a small amount of combustion, and the warm infrared heater 1 can be provided. In addition, the rotary burner 20 that blows out and burns after the liquid fuel is vaporized inside the burner has a relatively low operating noise. In the infrared ray generator 10 of this example, the driving sound was about 55 dB.

  Further, as indicated by an arrow X in FIG. 3, in the infrared ray generator 10 of this example, the rotary burner 20 is accommodated in the accommodating cylinder 15 and is supplied by the fan 13 between the combustion outer cylinder 23 and the accommodating cylinder 15. A part of the air that flows is allowed to flow as cooling air A. By flowing the cooling air A supplied by the fan 13 between the combustion outer cylinder 23 and the housing cylinder 15, the gas chamber 26 is cooled via the combustion outer cylinder 23 outside the gas chamber 26. It is possible to suppress the temperature from rising too much. By doing so, it is possible to suppress so-called back combustion, in which flame enters the gas chamber 26 between the combustion disc 22 and the combustion outer cylinder 23.

  In the rotary burner 20, since the mixed gas B containing the vaporized fuel burns in the vicinity of the rotary burner 20, it is possible to adopt an arrangement in which the rotary burner 20 and the heat radiating plate 30 face each other at a relatively narrow interval. it can. Therefore, the rotary burner 20 is easily heated by the radiant heat of the heat radiating plate 30 while being compact and easily configured to heat the entire surface of the heat radiating plate 30. As a result, the temperature of the rotary burner 20 rises and back combustion is likely to occur. Cooling the combustion plate 22 is one effective method for suppressing back combustion. However, in order to cool the combustion disk 22, the structure of the rotary burner 20 becomes complicated, or depending on the heat load, it becomes difficult to promote the vaporization of liquid fuel by cooling the combustion disk 22, or This causes the temperature of the mixed gas B to be lowered. The rotary burner 20 is housed in the housing cylinder 15, a space is provided between the combustion outer cylinder 23 and the housing cylinder 15, and the cooling air A is allowed to flow in the space, thereby suppressing the temperature rise of the gas chamber 26 with a simple configuration. It is possible to prevent the temperature of the combustion plate 22 from decreasing.

  It is desirable that the cooling air A is excess air with respect to the combustion air. The cooling air A can be blown out in the direction X along the heat insulating wall 17 opposite to the flame, or the distribution of the cooling air A can be adjusted to be suitable for cooling the combustion outer cylinder 23.

  Further, the housing 2 has a posture (see FIG. 3) in which the axis L of the rotary vaporizing cylinder 21 provided in the rotary burner 20 is substantially horizontal, and a posture in which the axis L of the rotary vaporizing cylinder 21 is inclined upward (FIG. 4). It is supported by the frame 3 via the turning shaft 6 so as to turn (turn). By turning the housing 2 up and down, the direction of the heat sink 30 can be adjusted up and down. On the other hand, when the infrared ray generator 10 is used in a posture (see FIG. 4) that is inclined so that the axis L of the rotary vaporization cylinder 21 faces upward, uncombusted liquid fuel F is placed behind the combustion plate 22. May remain. Drainage is likely to occur when the rotary burner 20 is ignited, extinguished, or misfired. However, if the combustion plate 22 and / or the combustion outer cylinder 23 are cooled to prevent back combustion, drainage may occur depending on the heat load. May be easier.

  As shown in FIG. 3, in the infrared generator 10 of this example, instead of expecting that drain is discharged into the chamber 12 and vaporized or burned, the lower rear side of the combustion plate 22 and the combustion outer cylinder 23. On the lower rear side, means for discharging the remaining liquid fuel F as drain are provided. Specifically, drain holes 51 and 52 serving as discharge paths are provided at a corner portion between the combustion disc 22 and its end wall 22a and at a corner portion between the combustion outer cylinder 23 and its end wall 23a, respectively. Further, a drain pipe 53 is provided at a position facing the hole 52 in the housing cylinder 15. The drain pipe 53 communicates with the fuel tank 11 via a pipe (tube) 54. Therefore, even when the infrared heater 1 is used in a posture in which the axis L of the rotary vaporizing cylinder 21 is substantially horizontal, the infrared heater 1 is used in an attitude in which the axis L of the rotary vaporizing cylinder 21 is inclined so as to face upward. Even in this case, the liquid fuel F remaining in the rotary burner 20 can be returned to the fuel tank 11 from the lower rear side of the combustion disk 22 and the lower rear side of the combustion outer cylinder 23.

  Therefore, the liquid fuel (drain) does not easily accumulate as drain inside the rotary burner 20, particularly, below the combustion plate 22 and below the combustion outer cylinder 23. For this reason, at the time of ignition, at the time of fire extinguishing, or at the time of ignition failure, it is possible to prevent the drain or its vaporized component from being released as unburned or the drain from seeping out to the rear of the rotary burner 20 via the motor shaft or the like it can. Therefore, the infrared heater 1 can be tilted up to 30 degrees upward.

  FIG. 5 is a front view of the heat sink 30 of the infrared ray generator 10. The heat sink 30 disposed in front of the chamber 12 is porous and has a plurality of holes 31. In the vertical direction, the plurality of holes 31 gradually decrease in diameter from the lower side toward the upper side. In addition, the plurality of holes 31 are gradually reduced in diameter in the left-right direction toward the center.

  The infrared ray generator 10 of the present example includes a heat radiating plate 30 having a heat radiating area of about 390 mm in length and about 500 mm in width, and the area of about 360 mm in the center and about 425 mm in the center of the heat radiating plate 30 is staggered. A plurality of holes 31 are provided and are porous. The plurality of holes 31 provided in the heat radiating plate 30 are classified into four sizes. The first largest holes 31a are provided at the left end and the right end in four rows and two lower ends, respectively, and the diameter is 8.0 mm, and a total of 196 holes are formed. The second largest holes 31b are provided in four rows on the left and right, and two rows on the lower side inside the first largest hole 31a. The diameter is 7.0 mm, and a total of 180 holes are formed. Yes. The third largest hole 31c is provided inside the second largest hole 31b so as to form a substantially square region including the vicinity of the center, and its diameter is 5.0 mm. 522 are formed. The fourth largest holes (smallest holes) 31d are provided in five rows on the upper side (upper end) of the substantially square area, and the diameter thereof is 2.8 mm, and a total of 90 holes are provided. Yes. Therefore, as described above, the plurality of holes 31 of the heat radiating plate 30 have a hole diameter that decreases from the lower side toward the upper side in the vertical direction, and the hole diameter decreases toward the center in the left-right direction. It is getting smaller.

  According to the experiments by the inventors of the present application, it was found that when a heat sink with a hole having a uniform diameter was used, the red hot part that was red hot by the rotary burner was easily limited to the center of the upper half of the heat sink. . On the other hand, when the heat radiating plate 30 in which holes are distributed in a plurality of diameters as described above is adopted, the red hot part extends up and down, left and right almost uniformly in a porous region, and the area where the temperature of the heat radiating plate 30 is increased is increased. It turns out that it can be expanded. According to the infrared generator 10 provided with the heat radiating plate 30, high-temperature hot air (combustion gas) generated by the combustion in the vicinity of the combustion plate 22 is biased above the chamber 12 and concentrated above the heat radiating plate. As a result, it is possible to suppress the occurrence of a problem that the red heat region is limited and the generation amount of infrared rays does not increase. That is, the heat sink 30 in which holes having different diameters are distributed can appropriately adjust the discharge amount of the combustion gas (differential pressure when released), and the release of the combustion gas is large around the heat sink 30. It is thought that it can be reduced in the center and less in the upper part. As a result, it is considered that the high-temperature combustion gas can be prevented from being unevenly distributed upward in the chamber 12, the distribution of the high-temperature combustion gas can be averaged, and heating around the radiator plate 30 can be promoted. Therefore, infrared rays can be uniformly radiated forward from the heat radiating plate 30 (red hot portions can be uniformly formed).

  In addition, the hole 31 formed in the heat sink 30 is not limited to what is formed in steps, and the hole shape is not limited to a circle. As a whole, in the vertical direction, the hole diameter decreases from the lower side toward the upper side, and in the left-right direction, if the hole diameter decreases toward the center, the hole formed in the heat sink 30. 31 may be formed in an elliptical shape, a rectangular shape, a polygonal shape, or the like. Moreover, such a heat sink 30 may be formed by drawing or the like after making a hole in a flat plate, or may be molded by a mold.

  Moreover, it is preferable that the whole heat sink 30 is 10%-20% of aperture ratio. In this type of infrared heater, it is preferable to emit heat as infrared rays emitted from the heat sink 30 rather than releasing heat as hot air or warm air. Therefore, in the conventionally known infrared ray generator equipped with the gun type burner, the aperture ratio of the heat sink is about 1% to 5%, and the surface temperature of the heat sink is about 750 ° C. On the other hand, in the infrared heater 1 of this example, while using the rotary burner 20, contrary to a gun type, the aperture ratio of a heat sink is enlarged and combustion is further promoted. As a result, the temperature of the surface of the heat sink 30 can be increased, and in this example, it can be set to about 830 ° C. For this reason, the quantity of heat emitted as infrared rays can be increased, and the warmth (surface temperature of the radiator plate 30) obtained by the infrared ray generator 10 of this example can be improved by about 30%.

  FIG. 6 is a side view showing a partial section of the combustion plate 22 provided in the infrared ray generator 10. A plurality of holes (openings) 22 c for blowing out the mixed gas B are formed in a staggered pattern on the peripheral wall of the combustion plate 22. The diameter R of each hole 22c is 1.90 mm. The pitch P1 (every other row) in the lateral direction (circumferential direction, second direction) of the holes is 6.80 mm. The pitch P2 (every other row) in the vertical direction (front-rear direction, first direction) of the holes is 6.00 mm.

The combustion disk provided in the conventional rotary burner has a hole diameter of 2.50 mm, a number of 648, and a flame hole area of 3181 mm ² . On the other hand, the combustion disc 22 provided in the rotary burner 20 of the infrared ray generator 10 of the present example has the diameter R of the hole 22c reduced, and the number thereof is increased to 1160. Moreover, in the combustion board 22 with which the rotary burner 20 of the infrared rays generator 10 of this example is provided, a flame hole area is 3287 mm < ² >. This error is due to the hole pattern, and basically, the flame hole area is hardly changed from the conventional one. For this reason, the flame hole load (load per flame hole, kcal / piece) is 46.3 kcal in the prior art, but is reduced to 30.0 kcal in this example.

However, if the diameter R of the hole 22c is too small, a beep sound (wind noise called “pea”) is generated. Therefore, the diameter R of the hole 22c preferably satisfies the following expression (0).
1.60 mm ≦ R ≦ 2.20 mm (0)
Furthermore, the diameter R of the hole 22c preferably satisfies the following expression (1).
1.85 mm ≦ R ≦ 2.00 mm (1)

If the pitch of the holes 22c is too narrow, a large flame is formed by the mixed gas B blown from the plurality of holes 22c, and it is difficult to obtain the effect of reducing the flame hole load. For this reason, it is desirable that the pitches P1 and P2 satisfy the following expression (2).
5.0 mm ≦ P1, P2 ≦ 8.0 mm (2)

An example of the range of the pitches P1 and P2 when the holes 22c are arranged vertically and horizontally is as shown in the following formula (3).
5.0mm ≦ P1 ≦ 7.0mm
5.8 mm ≦ P2 ≦ 7.8 mm (3)

  By adopting the rotary burner 20 having such a combustion disc, it is possible to provide an infrared generator 10 with improved combustion efficiency and lower operating noise. Further, by employing this infrared ray generator 10, it is possible to provide an infrared heater 10 that is warmer with a small amount of combustion and that has a relatively low operating noise.

  Since this infrared ray generator 10 can emit a large amount of infrared rays at a low cost, it is suitable for being applied to a heater mainly for indoor and outdoor heating, but the application is not limited to the heater. The present invention can also be applied to other uses, for example, an apparatus intended for heating or drying.

The side view which shows an infrared heater. The side view which shows the infrared heater of FIG. 1 in a partial cross section. The end view (sectional drawing) which shows the infrared rays generator with which the infrared heater of FIG. 1 is provided. The end view (sectional drawing) which shows the state which uses the infrared rays generator with which the infrared heater of FIG. The front view of the heat sink with which the infrared rays generator of FIG. 3 is provided. The side view which shows the combustion disc with which the infrared rays generator of FIG.

Explanation of symbols

1 Infrared heater (Infrared heater)
DESCRIPTION OF SYMBOLS 10 Infrared generator, 11 Fuel tank 12 Chamber, 13 Fan 15 Housing cylinder, 17 Heat insulation wall 20 Rotary burner, 21 Rotation vaporization cylinder 21c Rotation vaporization cylinder hole, 22 Combustion board 23 Combustion outer cylinder, 26 Gas chamber 30 Heat sink, 31 Drain hole of heat sink 51 Drain hole of combustion panel, 52 Drain hole of combustion outer cylinder 53 Drain pipe

Claims (10)

A chamber whose outer periphery is formed by a heat insulating wall and whose front extends from the rear;
A porous heat sink disposed in front of the chamber;
A rotary burner and a fan disposed behind the chamber;
In the rotary burner, a rotary vaporization cylinder, a cylindrical combustion disc, and a combustion outer cylinder for forming a gas chamber between the combustion disc and the combustion disc are arranged in this order from the inside.
Liquid fuel is vaporized in the rotary vaporization cylinder, and burned as a mixed gas with the combustion air supplied from the fan through the gas chamber through the gas chamber, and the heat radiating plate radiates infrared rays forward . further,
A housing cylinder provided outside the combustion outer cylinder, and a portion of the air supplied by the fan flows as cooling air between the combustion outer cylinder and the housing cylinder, and the combustion gas flows An infrared ray generator that is emitted along the inside of the heat insulating wall of the chamber .   The infrared generator according to claim 1, wherein the pores of the heat radiating plate have a pore diameter that decreases in the vertical direction from the lower side toward the upper side.   The infrared generator according to claim 1 or 2, wherein the pores of the heat radiating plate have a hole diameter that decreases in the left-right direction toward the center.   4. The infrared ray generating device according to claim 1, wherein the hole diameter of the heat radiating plate changes in a stepwise manner. In any one of claims 1 to 4, wherein from the combustion plate below the lower side and the combustion barrel of the rotary burner, the remaining liquid fuel as a drain, for draining the fuel tank for storing the liquid fuel An infrared generator having a discharge path. The rotary burner according to claim 5 , wherein the rotary burner has a posture to be inclined so that an axis of the rotary vaporizing cylinder faces upward.
The infrared ray generator, wherein the discharge path is configured to discharge the drain to the fuel tank from a lower rear side of the combustion disc and a lower rear side of the combustion outer cylinder. In any one of claims 1 to 6, in the combustion plate, the mixture of a plurality of openings are provided for blowing gas, the diameter R of the opening satisfies the following conditions, an infrared generator.
1.85mm ≦ R ≦ 2.00mm 8. The infrared generator according to claim 7 , wherein the plurality of openings are two-dimensionally arranged in a staggered manner. 9. The infrared generator according to claim 8 , wherein the plurality of openings have a pitch P1 every other column in the first direction satisfying the following condition and a pitch P2 every other row in the second direction satisfying the following condition. .
5.0mm ≦ P1, P2 ≦ 8.0mm An infrared generator according to any of claims 1 to 9, and a fuel tank for reserving the liquid fuel, an infrared heating system.

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