JP2019184134A - Flame generator - Google Patents

Abstract

To provide a flame generator capable of enhancing visibility of flame.SOLUTION: A flame generator includes a housing body, a hydrogen fuel, a nozzle, a flow passage constituting part, a flame reaction body and a vent hole. The hydrogen fuel is built in the housing body. The nozzle jets the hydrogen fuel upward in the housing body. With respect to the flow path, a nozzle tip end part is inserted into the inside of the flow inlet on the lower end side, and the flow outlet on the upper end side is opened to the outside part of the housing body. The flame reaction body is installed on the inner wall of the flow passage ranging from the flow inlet to the flow outlet, and colors the hydrogen flame formed above the nozzle by flame reaction. The vent hole penetrates through the wall part of the flow passage.SELECTED DRAWING: Figure 1

Description

  Embodiments described herein relate generally to a flame generator.

  Conventionally, since a flame generator generally uses a hydrocarbon-based liquid fuel, fine particles such as carbon dioxide and soot are generated during combustion. Therefore, there is a concern that this type of flame generating device has a high environmental load.

  Therefore, there is a demand for application of hydrogen fuel that does not release fine particles such as carbon dioxide and soot during combustion. However, since the hydrogen flame is colorless and transparent, there is a problem that it cannot be visually recognized. For this reason, a technique for coloring a hydrogen flame using a flame reactive substance has been proposed.

  Specific examples of this coloring technique include a mechanism for spraying a flame-reactive substance-containing solution into a hydrogen flame, or a flame-reactive substance carried on a mesh-like member so as to come into contact with the hydrogen flame. The configuration and the like are illustrated.

JP 2017-17029 A

  However, the above-described flame coloring technique produces colored spots on the flame. That is, although the outer periphery of the flame is colored, the center of the flame is weakly colored, and the flame visibility is not sufficient when the environment in which the flame generator is used is, for example, outdoors. Similarly, when the flame generating device is used outdoors, the length of the flame itself is shortened due to the influence of wind, and the visibility of the flame is also reduced at this time.

  The problem to be solved by the present invention is to provide a flame generating device capable of enhancing the visibility of a flame.

  The flame generator according to the embodiment includes a housing, hydrogen fuel, a nozzle, a flow path component, a flame color reactant, and a vent. Hydrogen fuel is built in the housing. The nozzle ejects hydrogen fuel upward in the housing. In the flow path, the tip of the nozzle is inserted inside the inlet on the lower end side, and the outlet on the upper end side opens to the outside of the casing. The flame reactant is provided on the inner wall of the flow path from the inlet to the outlet, and colors the flame of hydrogen formed above the nozzle by flame reaction. The vent hole penetrates the wall portion of the flow path.

  ADVANTAGE OF THE INVENTION According to this invention, it is possible to provide the flame generator which can improve the visibility of a flame.

The figure which shows typically the structure of the flame generator which concerns on 1st Embodiment. The horizontal sectional view of the flow-path structural unit with which the flame generator of FIG. 1 was equipped. FIG. 2B is a vertical sectional view of the flow path constituting unit of FIG. 2A. The photograph of the flame generated with the flame generator of FIG. The photograph of the flame generated with the flame generator of the comparative example. The figure which shows schematically the flow-path structural unit with which the flame generator which concerns on 2nd Embodiment was equipped. The figure which shows schematically the flow-path structural unit with which the flame generating apparatus which concerns on 3rd Embodiment was provided. The figure which shows schematically the flow-path structural unit with which the flame generator which concerns on 4th Embodiment was provided. The figure which shows schematically the flow-path structural unit with which the flame generating apparatus which concerns on 5th Embodiment was provided. The top view which shows roughly the flow-path structural unit with which the flame generator which concerns on 6th Embodiment was equipped. The perspective view which shows the external appearance of the flow-path structural unit of FIG. 9A. The top view which shows roughly the flow-path structural unit with which the flame generator which concerns on 7th Embodiment was provided. The perspective view which shows the external appearance of the flow-path structural unit of FIG. 10A. The top view which shows roughly the flow-path structural unit with which the flame generator which concerns on 8th Embodiment was provided. The perspective view which shows the external appearance of the flow-path structural unit of FIG. 11A. A top view showing roughly a channel composition unit with which a flame generating device concerning a 9th embodiment was provided. The perspective view which shows the external appearance of the flow-path structural unit of FIG. 12A. A top view showing roughly a channel composition unit with which a flame generating device concerning a 10th embodiment was provided. The perspective view which shows the external appearance of the flow-path structural unit of FIG. 13A. The top view which shows roughly the flow-path structural unit with which the flame generator which concerns on 11th Embodiment was equipped. The perspective view which shows the external appearance of the flow-path structural unit of FIG. 14A.

Hereinafter, embodiments will be described with reference to the drawings.
<First Embodiment>
As shown in FIG. 1, the flame generator 10 includes a bottomed cylindrical housing 8, a columnar hydrogen tank 1, a ball valve 2, an orifice member 3, a regulator 4, a nozzle 5, a gas pipe 6, and a fixed base 7. , A heat conductor 9 and a flow path constituting unit 18.

  The hydrogen tank 1 contains hydrogen fuel that serves as fuel for the flame generator 10. The hydrogen tank 1 contains a hydrogen storage alloy that stores gaseous hydrogen (hydrogen gas) as the hydrogen fuel. The hydrogen tank 1 has a hydrogen discharge hole in the direction opposite to the side on which the hydrogen flame is generated. A magnesium alloy or the like can be selected as the hydrogen storage alloy. Instead of this, the hydrogen tank 1 may be configured by a high-pressure tank, a low-pressure tank, or the like that stores liquid hydrogen or gaseous hydrogen.

  The housing 8 has a casing body 8a and an upper lid 8b. The housing 8 accommodates (built-in) internal components such as the hydrogen tank 1 that contains the hydrogen fuel, the ball valve 2, the orifice member 3, the regulator 4, the nozzle 5, and the gas pipe 6.

  The fixed base 7 is a base for fixing the nozzle 5. The nozzle 5 ejects hydrogen fuel upward in the housing 8. The nozzle 5 includes a hydrogen fuel injection port at the most distal end (uppermost end). In addition, the nozzle 5 may be provided with the cyclic | annular jet nozzle comprised by a double pipe | tube etc.

  As shown in FIG. 1, the gas pipe 6 transfers hydrogen (hydrogen fuel) released from the hydrogen storage alloy in the hydrogen tank 1 to the nozzle 5 via the ball valve 2, the orifice member 3, and the regulator 4. To do. That is, the upstream end of the gas pipe 6 is connected to the hydrogen tank 1, while the downstream end of the gas pipe 6 is connected to the nozzle 5.

  The ball valve 2 controls the timing of ignition by turning on (opening) and turning off (blocking) the flow of hydrogen passing through the gas pipe 6. The orifice member 3 is interposed between the regulator 4 on the gas pipe 6 and the ball valve 2, and the diameter of the gas pipe 6 is narrowed by an orifice (hole) so that rapid discharge of hydrogen when the ball valve 2 is opened. Suppress. The regulator 4 is interposed between the hydrogen tank 1 and the orifice member 3 on the gas pipe 6 and is a pressure regulator for keeping the pressure (high pressure) in the gas pipe 6 constant.

  The heat conductor 9 is a heat transfer member for transferring heat of the hydrogen flame formed on the upper portion of the housing 8, transferring the transferred heat to the hydrogen storage alloy in the hydrogen tank 1, and heating it. is there. Here, the hydrogen storage alloy in the hydrogen tank 1 is highly dependent on the temperature. For example, when the temperature is greatly decreased, a hydrogen storage function may occur. Can be efficiently transmitted to the hydrogen tank 1 side, so that a decrease in the temperature of the hydrogen storage alloy can be suppressed.

  Next, the structure of the flow path constituting unit 18 will be described in detail. As shown in FIG. 1, FIG. 2A, and FIG. 2B, the flow path constituting unit 18 includes a holding container 12 constituted by a mesh-like member (material) and a gas of hydrogen fuel (hydrogen gas) ejected from the nozzle 5. It is a flame coloring unit provided with a flow path 15 serving as a flow passage, a flame-colored reactant 14, and a ventilation portion 16 having a ventilation hole 16a.

  In the flow path 15, the tip 5 a of the nozzle 5 is inserted inside the inlet 15 a on the lower end side, and the outlet 15 b on the upper end side opens to the outside of the housing 8. More specifically, a fitting hole that fits the outer diameter of the nozzle 5 is provided as an inflow port 15a in the center portion of the bottom (lower end) of the holding container 12. Moreover, as shown in FIG. 1, the outflow port 15b of the flow path 15 is arrange | positioned in the position which protrudes from the upper end (upper end of the upper cover 8b) 8c of the housing | casing 8. As shown in FIG.

  The flame reactant 14 is provided on the inner wall of the flow channel 15 from the inlet 15a to the outlet 15b. A hydrogen flame formed above the nozzle 5 (a flame generated by hydrogen burning in the flow path 15) is colored by a flame reaction. The ventilation hole 16 a of the ventilation part 16 penetrates the wall part 15 c of the flow path 15. The air holes 16a allow the air outside the wall 15c (oxygen in the air) to flow into the flow path 15 that has become a negative pressure when hydrogen fuel is ejected from the nozzle 5, so that the combustion efficiency of the hydrogen fuel is increased. It is a component for enhancing

  Here, the holding container 12 (mesh-like member) constitutes the entire wall portion 15c of the flow path 15, and holds the flame-colored reactant 14 on a part of the inside of the holding container 12 main body. . More specifically, as shown in FIGS. 2A and 2B, the holding container 12 is configured in a rectangular tubular shape, and a pair of inner wall surfaces (mesh-like inner wall surfaces) facing each other is connected to the flame-colored reactant 14. Covered with. Further, the outer shape of the holding container 12 is in contact with the heat conductor 9, thereby fixing the holding container 12 in a stable state.

  Further, in place of the configuration example of FIGS. 2A and 2B, the inner wall of the flow path described above is a flame with a portion provided with a vent hole formed of a mesh-like member and a solid flat plate that is not mesh-like. And a portion holding the reactant.

  In the following description, the numerical range represented by “to” and the lower and upper limit values before and after the numerical value range is a numerical range that is greater than or equal to the lower limit value and less than or equal to the upper limit value (a numerical range including the numerical values before and after “to”) Is specified.

  Moreover, it is preferable that the mesh-shaped member provided with the above-described vent holes or the mesh-shaped holding container 12 has an opening smaller than the particle diameter of the particles constituting the flame-colored reactant 14. That is, the flame-colored reactant 14 can be a molded product having a granule larger than the above-mentioned opening, and the flame-colored reactant 14 can be reliably held. An example of the material of the holding container 12 is a wire mesh having 10 to 100 meshes.

  The flame reactant 14 described above is a pellet of a flame reaction reagent (flame reaction material) such as sodium chloride that can color the flame orange. The phenomenon in which a flame is colored by a flame reaction is a phenomenon called chemiluminescence. Chemiluminescence is energy that is released when the flame state reactant 14 returns to the ground state instantaneously when the electronic state of the flame reactant 14 changes from a stable ground state to a higher energy excited state due to thermal energy generated by combustion. Due to the energy difference between the excited state and the ground state.

  The luminescence produced by sodium chloride is given by the following equation 1.

  NaCl + Q → NaCl * → NaCl + hν Formula 1

  Here, Q represents heat energy, NaCl * represents the excited state of sodium chloride, and hν represents light energy.

  In the case of sodium chloride, it looks orange because the light energy corresponds to the orange wavelength of visible light. It can be seen from Equation 1 that a large amount of thermal energy is desirable in order to improve the visibility of light. As shown in FIGS. 2A and 2B, in the flow path constituting unit (flame coloring unit) 18, hydrogen (hydrogen fuel) ejected from the nozzle 5 moves above the flow path 15 while being in contact with the flame color reactant 14. .

  Further, since hydrogen is ejected from the nozzle 5, the inside of the flow path 15 becomes negative pressure, so that the air outside the wall portion 15 c in the flow path 15 becomes the vent hole 16 a of the vent section 16 (and the bottom surface of the holding container 12). And is introduced into the flow path 15. The air introduced into the flow path 15 through the vent hole 16a and the hydrogen ejected from the nozzle 5 into the flow path 15 are mixed to produce efficient combustion and form a flame. The flame-colored reactant 14 placed in contact with the flame receives the thermal energy of the flame and emits orange light by the reaction shown in Formula 1, so that the flame can be visually recognized.

  Also, the flame is generated in the direction of hydrogen flow, and heat is propagated to the upper part of the flame-colored reactant 14 in the flow path 15, so that it is good even at the upper part of the flame-colored reactant 14 having a relatively low flame temperature. It is possible to cause a flame reaction.

  When the flame generator 10 is used in an outdoor environment, the phenomenon in which the flame shrinks due to the influence of wind occurs because the flame is cooled by the separation of the boundary film between the flame and the outside air by the wind. . Here, the outlet 15b of the flow path 15 is located above the upper lid 8b, and a flame is also generated at the upper end of the flow path 15 in the flame reaction body 14 to cause a flame reaction. Specifically, although the outlet 15b of the flow path 15 protrudes from the upper end 8c of the upper lid 8b, the high-temperature outlet 15b where the flame reaction occurs as described above cancels the effect of cooling the flame by the wind. It is possible to secure a sufficient amount of heat, thereby suppressing the reduction of the flame due to the wind.

  In addition, as the holding container 12, for example, a rectangular parallelepiped holding container having a bottom of 10 mm × 10 mm and a depth of 40 mm was applied to the flame generator 10, and a combustion test was performed for 10 minutes at a hydrogen blowing flow rate of 4 L / min. In this case, a good flame can be confirmed when the thickness of each flame reactant (flame reaction reagent pellet) 14 is in the range of 0.1 to 0.4 cm.

  At this time, the weight of each flame reaction reactant 14 is 1 to 3 g, and the amount of the flame reaction reactant 14 is 25 to 75 mg / L per unit hydrogen release amount. Consider the aperture ratio as a measure of air intake. When the opening ratio is defined by the ratio of the area of the ventilation portion 16 to the inner area of the rectangular parallelepiped holding container, the opening ratio is 32 to 44%.

  On the other hand, the contact time between the flame-colored reactant 14 and the hydrogen fuel in the flow path 15 is the volume flow rate of the hydrogen fuel ejected from the nozzle 5 by the volume of the flame-colored reactant provided on the inner wall of the flow path 15. Therefore, it is preferably set to a time of 0.002 to 0.4 seconds (0.002 seconds or more and 0.4 seconds or less) obtained by dividing.

  Therefore, the flame reactant is set to a weight in the range of 0.025 to 0.075 g / L per unit hydrogen ejection amount, the opening ratio of the ventilation portion 16 is set to 32 to 44%, and the hydrogen fuel, the flame reactant and By applying the conditions in which the contact time is 0.002 to 0.4 seconds to the flame generating device 10, it is possible to confirm a highly visible flame without colored spots. The flame in this case can obtain good visibility even in an outdoor environment (bright environment equivalent to 100,000 Lx).

  Here, FIG. 3 is a photograph of a flame generated after setting the above-described conditions in the flame generator 10 of the present embodiment. On the other hand, FIG. 4 is a photograph of a flame generated mainly by a flame generating apparatus of a comparative example in which no ventilation part is provided. The flame shown in FIG. 3 is a flame having a long length (about 30 cm in FIG. 3) and high visibility without colored spots. On the other hand, the flame shown in FIG. 4 has a short length (about 9 cm in FIG. 4) and also has colored spots, and is inferior in visibility to the flame shown in FIG.

The flame-colored reactant is composed of at least one of the following compound groups. Alkali metal chlorides (LiX, NaX, KX, RbX, CsX, X = Cl, Br, I), alkaline earth metal chlorides (CaX ₂ , CaX ₂ , SrX ₂ , BaX ₂ , X = Cl, Br , I), boric acid (H ₃ BO ₃ ), copper chloride (CuCl ₂ ), strontium carbonate (SrCO ₃ ), sodium carbonate (Na ₂ CO ₃ ), indium (In), lithium oxide (Li ₂ O).

  As described above, in the flame generator 10 of the present embodiment, as shown in FIGS. 1 and 2B, the tip 5 a of the nozzle 5 that ejects hydrogen fuel is located on the lower end side (upstream side) of the flow path 15. It is inserted inside the inflow port 15a. As shown in FIGS. 2A and 2B, the hydrogen flame formed above the nozzle 5 in the vicinity of the inlet 15a is a flame reactant 14 provided on the inner wall of the flow path 15 from the inlet 15a to the outlet 15b. It is colored by the flame reaction with this flame reactant 14.

  At this time, air (oxygen in the air) is introduced from the outside of the flow path 15 into the flow path 15, which has become negative pressure due to the ejection of hydrogen fuel from the nozzle 5, mainly through the vent holes 16 a of the vent section 16. As a result, hydrogen combustion is effectively promoted. Further, the flame thus obtained is colored by a good flame reaction because it is always in contact with the flame reactant 14 in the process from the inlet 15a side of the flow path 15 to the outlet 15b. .

  As a result, a large flame is formed that extends long from the outlet 15b of the flow path 15 upward. Such a flame obtained by efficient combustion and a good flame reaction has a long length and the occurrence of colored spots and the like is also suppressed, so that visibility is enhanced. Moreover, in the flame generator 10 of this embodiment, as shown in FIG. 1 and FIG. 2B, the inside of the casing 8 in the flow path 15 is opposed to the outlet 15 b of the flow path 15 protruding from the upper end of the casing 8. Since the fire type is formed in the vicinity of the inflow port 15a, the reduction of the flame due to the influence of the wind is suppressed, and thereby the visibility of the flame can be improved.

<Second Embodiment>
Next, a second embodiment will be described with reference to FIG. In FIG. 5, the same constituent elements as those in the first embodiment shown in FIG. 2B are assigned the same reference numerals and redundant description is omitted. As shown in FIG. 5, the flame generating apparatus of the present embodiment includes a flow path forming unit 28 instead of the flow path forming unit 18 included in the flame generating apparatus 10 of the first embodiment.

In the flow path constituting unit 28, a part of the flame reactant 24 is made of a metal oxide 24a. The metal oxide 24a includes at least one of the following compound groups as a material. Copper oxide (CuO), cobalt oxide (Co ₃ O ₄ ), iron oxide (Fe ₂ O ₃ ), aluminum oxide (Al ₂ O ₃ ), silicon oxide (SiO ₂ ).

  The metal oxide 24a itself consumes oxygen to oxidize hydrogen and generate a large amount of heat at that time, so that the flame sustainability is improved. Further, as shown in FIG. 5, the metal oxide 24a is arranged in the vicinity of the nozzle 5 (on the inlet 15a side of the flow path 15), so that the hydrogen that is abruptly ejected from the nozzle 5 at the initial stage of combustion is reduced. Among them, hydrogen that cannot be burned by air can be oxidized, and a larger flame can be generated. Further, the heat generated by the reaction between the metal oxide 24a and hydrogen serves as a heating source for the flame reactant located above the metal oxide, and improves the durability of the flame even in a heat removal environment such as wind and rain. It becomes possible.

<Third Embodiment>
Next, a third embodiment will be described with reference to FIG. As shown in FIG. 6, the flame generator of this embodiment includes a flow path component unit 38 instead of the flow path component unit 18 included in the flame generator 10 of the first embodiment. The flow path constituting unit 38 includes a mesh-like holding container 32 in place of the mesh-like holding container 12 provided in the flow path constituting unit 18.

  The mesh-like holding container (mesh-like member) 32 includes a first mesh-like member constituting portion 32a constituting the inlet 15a side of the flow path 15 and a second mesh constituting the outlet 15b side of the flow path 15. And a member-shaped member constituting portion 32b. Here, the opening of the first mesh member constituting part is formed larger (coarse) than the opening of the second mesh member constituting part.

  In the flame generating apparatus of the present embodiment, a large amount of air is positively introduced into the flow path 15 from the first mesh-like member constituting portion 32a having a large opening, so that the nozzle 5 rapidly It becomes possible to oxidize hydrogen that cannot be burned by air among the hydrogen jetted to the air, and a larger flame can be generated. On the other hand, the heat generated by the reaction between the flame reactant and the hydrogen held by the first mesh member constituting portion 32a reduces the mesh size (it is difficult to dissipate heat and has a high heat storage effect). Since it becomes a heating source of the flame-colored reactant held in the constituent portion 32b, an effective flame-color reaction can be obtained and the sustainability of the formed flame can be improved.

  The first mesh-like member constituting portion 32a is formed of a first punching metal having a large opening ratio, while the second mesh-like member constituting portion 32b is a second having a smaller opening ratio than the first punching metal. You may form with the punching metal of.

<Fourth embodiment>
Next, a fourth embodiment will be described with reference to FIG. As shown in FIG. 7, the flame generating apparatus of this embodiment includes a flow path forming unit 48 instead of the flow path forming unit 18 included in the flame generating apparatus 10 of the first embodiment. The flow path constituting unit 48 includes a venturi tube 42 having a venturi structure instead of the mesh-shaped holding container 12 provided in the flow path constituting unit 18. That is, the flow path 45 in the venturi pipe 42 extending from the lower end side inlet 45a of the venturi pipe 42 to the upper end side outlet 45b is at the central portion in the axial direction of the venturi pipe 42 having a narrow cross section. Hydrogen fuel flow rate increases.

  Here, a flame-colored reactant is provided on the inner wall of the flow path 45 (venturi tube 42) from the inlet 45a to the outlet 45b. On the other hand, a vent hole 36a penetrating the wall portion 45c of the flow path 45 (the wall portion of the venturi tube 42) 45c is formed in the above-described central portion 42a in the axial direction of the venturi tube 42.

  Therefore, in the flame generating apparatus of the present embodiment, air can be introduced into the portion (the central portion 42a) where the flow velocity of the hydrogen fuel increases in the venturi tube 42, so that the hydrogen fuel can be burned more efficiently. Can do. Thereby, the visibility of the flame extended upwards of the outflow port 45b (upper end 8c of the upper cover 8b) of the flow path 45 can be improved.

<Fifth embodiment>
Next, a fifth embodiment will be described with reference to FIG. As shown in FIG. 8, the flame generating apparatus of the present embodiment includes a flow path forming unit 58 instead of the flow path forming unit 18 included in the flame generating apparatus 10 of the first embodiment. The flow path constituting unit 58 includes a porous body 52 formed in a cylindrical shape instead of the mesh-shaped holding container 12 provided in the flow path constituting unit 18. The cylindrical porous body 52 includes a flow path 45 that extends from the lower inlet 53a to the upper outlet 55b. In other words, the porous body 52 main body forms the wall portion 55 c of the flow path 55.

  Here, a flame reactant may be provided on the inner wall of the channel 55 (porous body 52) from the inlet 55a to the outlet 55b, or the porous body 52 itself is made of a flame reactant material. It may be configured. In addition, the plurality of pores of the porous body 52 constitute a vent hole 56 a that penetrates the wall portion 55 c of the flow path 45. According to the flame generator of the present embodiment, the structure of the flow path component unit (flame coloring unit) 58 can be simplified.

<Sixth Embodiment>
Next, a sixth embodiment will be described with reference to FIGS. 9A and 9B. 9A and 9B, in addition to the flow path constituting unit 58 (18, 28, 38 or 48) provided in the flame generators of the first to fifth embodiments, the flame generator of the present embodiment. Further, a protective mechanism 61 is further provided. The protection mechanism 61 protects the flame extending upward from the outlet 55b of the flow channel 55 from the wind (the influence of the wind). The protection mechanism 61 is provided at a position above the upper end 8c of the upper lid 8b illustrated in FIG. 1 and FIG. Further, a protection mechanism according to an embodiment to be described later is also provided at a position above the upper end 8c of the upper lid 8b in the flow path constituting unit 58. Further, as shown in FIGS. 9A and 9B, the protective mechanism 61 is a pair of structures in which a cylindrical member having a diameter larger than that of the flow path constituting unit 58 is divided into four at equal intervals (90 degrees). A protective member 62 and a pair of protective members 63.

  The pair of protection members 62 and the pair of protection members 63 are arranged at positions facing each other with the flow path constituting unit 58 sandwiched from the radial direction. The pair of protection members 62 and the pair of protection members 63 are joined to the outer peripheral surface of the flow path constituting unit 58 in such a positional relationship that the upper ends thereof and the upper ends of the flow path constituting units 58 are aligned. Further, the pair of protection members 62 are provided with through holes penetrating the inside of the protection member 62 main body in the radial direction. Air can be introduced into the flow path 55 through the through hole and the vent hole 56 a of the flow path forming unit 58.

  Here, for example, the flow of the wind from the height position lower than the upper ends of the protection members 62 and 63 toward the outlet 55b (the outlet end of the outlet) at the upper end of the flow path component unit 58 is shown in FIG. 9A. As shown in Fig. 5, the flow direction is changed by being blocked by the protective members 62 and 63. That is, the protection members 62 and 63 reduce the influence of wind on the flame extending upward from the outlet 55 b of the flow path 55. Thereby, since the fall of the temperature of the flame by the influence of a wind is suppressed, the sustainability of the stable flame can be improved.

  The protective members 62 and 63 described above are arranged in a positional relationship in which the upper ends of the protective members 62 and 63 are aligned with the upper ends of the flow path forming units 58. You may arrange | position in the position slightly higher than the upper end of the unit 58. FIG. In this case, it is possible to more reliably block the flow of wind toward the outflow port 55b (opening end of the outflow port) at the upper end of the flow path constituting unit 58, and to further reduce the influence of the wind on the flame. Also, in the embodiments described later, the upper end of the protection member may be disposed at a slightly higher position than the upper end of the flow path constituting unit.

<Seventh embodiment>
Next, a seventh embodiment will be described with reference to FIGS. 10A and 10B. In addition to the flow path constituting unit 58 (18, 28, 38 or 48) provided in the flame generators of the first to fifth embodiments, the flame generator of this embodiment is as shown in FIGS. 10A and 10B. In addition, a protective mechanism 71 is further provided. The protection mechanism 71 protects the flame extending upward from the outlet 55b of the flow channel 55 from the wind (the influence of the wind). As shown in FIGS. 10A and 10B, the protective mechanism 71 includes four channels extending radially from the peripheral surface of the flow channel component unit 58 at an equal angle (90 degrees) around the flow channel component unit 58. Four plate-like protection members 72 are arranged via plate-like support members 72a. One set of protection members 72 and the other set of protection members 72 are arranged in a positional relationship facing each other with the flow path constituting unit 58 sandwiched from the thickness direction of the protection member 72.

  As shown in FIG. 10A, the four support members 72a are arranged in such a direction that the thickness of the support member 72a can be seen from the axial direction of the flow path constituting unit 58, and between the peripheral surface of the flow path constituting unit 58 and the protective member 72. It is interposed between. The four protection members 72 are arranged in a positional relationship in which the upper ends of the four protection members 72 and the upper ends of the flow path constituting units 58 are aligned.

  Therefore, for example, the flow of the wind from the height position below the upper end of the protective member 72 toward the outlet 55b (opening end of the outlet) at the upper end of the flow path component unit 58 is as shown in FIG. 10A. In addition, the flow direction is changed by being blocked by the protective member 72. Such a protective member 72 protects the flame extending upward from the outlet 55b of the flow path 55 from the influence of the wind, so that a decrease in the temperature of the flame can be suppressed and the flame can be stabilized.

<Eighth Embodiment>
Next, an eighth embodiment will be described based on FIGS. 11A and 11B. In addition to the flow path constituting unit 58 (18, 28, 38 or 48) provided in the flame generators of the first to fifth embodiments, the flame generator of this embodiment is as shown in FIGS. 11A and 11B. In addition, a protective mechanism 81 is further provided. The protection mechanism 81 protects the flame extending upward from the outlet 55b of the flow path 55 from the wind (the influence of the wind). As shown in FIGS. 11A and 11B, the protection mechanism 81 includes four channels extending while being curved from the peripheral surface of the flow path component unit 58 at an equal angle (90 degrees) around the flow path component unit 58. A plate-like protection member 72 is provided.

  As shown in FIG. 11A and FIG. 11B, the four protective members 72 that are curved are arranged in such a direction that the thickness of the protective member 82 can be seen from the axial direction of the flow channel constituting unit 58. It is joined to the surface. The four protection members 82 are arranged in a positional relationship in which the upper ends of the four protection members 82 and the upper ends of the flow path constituting units 58 are aligned. Further, a wind blow-through hole 82 a is formed in the base end portion of the protective member 82 on the side joined to the flow path constituting unit 58. The blow-through hole 82 a is formed at a position lower than the upper end of the protection member 82.

  Therefore, for example, the flow of the wind from the height position below the upper end of the protective member 82 toward the outlet 55b (the outlet end of the outlet) at the upper end of the flow path component unit 58 is as shown in FIG. 11A. In addition, the flow direction is changed by being blocked by the protective member 82 or through the blow-through hole 82a. Also in such a protective member 82, the flame extending upward from the outlet 55b of the flow path 55 is protected from the influence of wind, so that it is possible to suppress a decrease in temperature in the flame and maintain a stable flame. Become.

<Ninth embodiment>
Next, a ninth embodiment will be described with reference to FIGS. 12A and 12B. In addition to the flow path constituting unit 58 (18, 28, 38 or 48) provided in the flame generators of the first to fifth embodiments, the flame generator of this embodiment is as shown in FIGS. 12A and 12B. Further, a protective mechanism 91 is further provided. The protection mechanism 91 protects the flame extending upward from the outlet 55b of the flow path 55 from the wind (the influence of the wind). As shown in FIGS. 12A and 12B, the protection mechanism 91 includes four triangular prism-shaped protection members 92 with an equiangular interval (90 degrees) around the flow path constituting unit 58. The four protection members 92 are arranged in such a positional relationship that the upper ends of the four protection members 92 are aligned with the upper ends of the flow path constituting units 58.

  In the protection mechanism 91 configured as described above, for example, the wind that is directed from the height position below the upper end of the protection member 92 toward the outlet 55b (opening end of the outlet) at the upper end of the flow path constituting unit 58. As shown in FIG. 12A, the flow is blocked by the protective member 82 and the flow direction is changed. Therefore, in the triangular prism-shaped protection member 92, the flame extending upward from the outlet 55b of the flow path 55 is protected from the wind, so that a temperature drop in the flame can be suppressed and a stable flame can be formed.

<Tenth Embodiment>
Next, an eleventh embodiment will be described with reference to FIGS. 13A and 13B. In addition to the flow path constituting unit 58 (18, 28, 38 or 48) provided in the flame generators of the first to fifth embodiments, the flame generator of this embodiment is as shown in FIGS. 13A and 13B. Further, a protective mechanism 101 is further provided. The protection mechanism 101 protects the flame extending upward from the outlet 55b of the flow path 55 from the wind (the influence of the wind). As shown in FIGS. 13A and 13B, the protection mechanism 101 has eight plates extending radially from the peripheral surface of the flow path component unit 58 at equal intervals (45 degrees) around the flow path component unit 58. A protective member 102 is provided.

  As shown in FIGS. 13A and 13B, the eight plate-shaped protection members 102 are arranged in such a direction that the thickness of the protection member 102 can be seen from the axial direction of the flow path configuration unit 58. It is joined to. The eight protective members 102 are arranged in a positional relationship in which the upper ends of the eight protective members 102 are aligned with the upper ends of the flow path constituting units 58.

  Therefore, for example, the flow of wind from the height position below the upper end of the protective member 102 toward the outlet 55b at the upper end of the flow path constituting unit 58 is blocked by the protective member 102 as shown in FIG. 13A. The direction of the flow is changed. As described above, according to the protection mechanism 101 including the six protection members 102, the flame extending upward from the outlet 55b of the flow path 55 is protected from the influence of wind, so that the temperature drop in the flame is suppressed, and a stable flame is achieved. Can improve the sustainability.

<Eleventh embodiment>
Next, an eleventh embodiment will be described with reference to FIGS. 14A and 14B. In addition to the flow path constituting unit 58 (18, 28, 38 or 48) provided in the flame generators of the first to fifth embodiments, the flame generator of this embodiment is as shown in FIGS. 14A and 14B. Further, a plurality of (for example, four) cylindrical heat storage materials 111 are further provided so as to be in contact with the wall portion 55c of the flow channel 55 in the flow channel configuration unit 58. Each heat storage material 111 is supported by the flow path configuration unit 58 via a columnar support member 112 so as to surround the flow path configuration unit 58. The heat storage material 111 stores the heat of the peripheral surface (wall portion 55c of the flow channel 55) of the flow channel constituting unit 58 that is in contact. The heat storage material 111 and the support member 112 are provided in a position above the upper end 8c of the upper lid 8b illustrated in FIGS. 1 and 8 in the flow path component unit 58.

  Further, for example, the four heat storage materials 111 are arranged in a positional relationship in which the heights of the respective upper ends and the upper ends of the flow path constituting units 58 are aligned. Therefore, for example, the flow of wind from the height position lower than the upper end of the protection member 102 toward the outlet 55b at the upper end of the flow path component unit 58 is blocked by the heat storage material 111 as shown in FIG. 14A. The direction of the flow is changed. Furthermore, the heat storage material 111 heats the flame extending upward from the outlet 55b of the flow path 55 with the heat stored in itself.

  According to such a heat storage material 111, in addition to being able to protect the flame extending upward from the outlet 55b of the flow path 55 from the influence of wind, this flame can be heated by the heat of the heat storage material 111, so that the temperature of the flame The decrease is suppressed, and a stable flame can be continuously formed.

  As mentioned above, although several embodiment of this invention was described, these embodiment is shown as an example and is not intending limiting the range of invention. These novel embodiments can be implemented in various other forms, and various omissions, replacements, and changes can be made without departing from the spirit of the invention. These embodiments and modifications thereof are included in the scope and gist of the invention, and are included in the invention described in the claims and the equivalents thereof.

  DESCRIPTION OF SYMBOLS 1 ... Hydrogen tank, 5 ... Nozzle, 5a ... Tip part of nozzle, 8 ... Housing, 8a ... Casing main body, 8b ... Upper lid, 8c ... Upper end of upper lid, 10 ... Flame generating device, 12, 32 ... Holding container, 14 , 24 ... Flame colored reactants, 15, 45, 55 ... Channels, 15a, 45a, 55a ... Inlet, 15b, 45b, 55b ... Outlet, 15c, 55c ... Wall part, 16 ... Vent part, 16a, 36a , 46a, 56a ... vents, 18, 28, 38, 48, 58 ... flow path constituent unit (flame coloring unit), 24 ... flame colored reactant, 24a ... metal oxide, 32a ... first mesh member configuration Part, 32b ... second mesh-like member constituting part, 42 ... venturi pipe, 42a ... central part of the venturi pipe, 61, 71, 81, 91, 101 ... protection mechanism, 62, 63, 72, 82, 92, 102 ... Protective members, 82 ... well hole, 111 ... heat storage material.

Claims (11)

A housing,
Hydrogen fuel incorporated in the housing;
A nozzle for ejecting the hydrogen fuel upward in the housing;
A flow path in which the tip of the nozzle is inserted inside the inlet on the lower end side and the outlet on the upper end side opens to the outside of the housing;
A flame reactant that is provided on the inner wall of the flow path from the inlet to the outlet and colors a hydrogen flame formed above the nozzle by a flame reaction;
A vent passing through the wall of the flow path;
A flame generating device comprising: A part of the flame reactant is composed of a metal oxide,
The flame generator according to claim 1. The outlet is disposed at a position protruding from the upper end of the housing.
The flame generator according to claim 1 or 2. The flow path has a venturi structure,
The flame generating device according to any one of claims 1 to 3. The wall portion of the flow path is formed of a porous body.
The flame generating device according to any one of claims 1 to 4. A protective mechanism for protecting a flame extending upward from the outlet from a wind;
The flame generating device according to any one of claims 1 to 5. It further comprises a heat storage material arranged so as to be in contact with the wall portion of the flow path,
The flame generating device according to any one of claims 1 to 5. The contact time between the flame reactant and the hydrogen fuel in the flow path is determined by the volume flow rate of the hydrogen fuel ejected from the nozzle as the volume of the flame reactant provided on the inner wall of the flow path. , Is set to a time of 0.002 seconds or more and 0.4 seconds or less obtained by dividing,
The flame generator according to any one of claims 1 to 7. The inner wall of the flow path has a portion provided with the flame-colored reactant and a portion provided with the vent hole formed of a mesh-like member.
The flame generating device according to any one of claims 1 to 8. The entire wall portion of the flow path is made of a mesh-like member, and the flame-colored reactant is held on a part of the inside of the mesh-like member,
Further, the mesh-shaped member has a mesh opening smaller than the particle size of the particles constituting the flame reactant,
The flame generating device according to any one of claims 1 to 8. The mesh-like member has a first mesh-like member constituting portion that constitutes an inlet side of the flow path and a second mesh-like member constituting portion that constitutes an outlet side of the flow path,
The mesh opening of the first mesh member constituting part is larger than the mesh opening of the second mesh member constituting part,
The flame generating device according to claim 9 or 10.

Images