JP2017510782A - Infrared gas stove stove core structure - Google Patents

Abstract

The stove core structure of the infrared gas stove has a storage tank in the bottom lid, and a gas through hole is formed in the bottom for introducing gas into the storage tank from the bottom to the top. The flow guide plate is pushed up in the storage tank, there is a pitch between the flow guide plate and the bottom of the storage tank of the bottom cover, the gas through hole is not covered, and the flow guide plate A gap through which gas passes is formed on the peripheral side, and after the gas has entered the storage tank through the gas through hole, the gap on the peripheral side of the flow guide plate is used as a main flow line through which the gas flows. Using the gas flow line composed of pits and gaps formed between the flow guide plate and the outer lid, gas flows out smoothly from the peripheral side of the flow guide plate, and infrared rays are received at the opening of the bottom cover storage tank. It is mounted so that the ceramic piece is exposed, and the gas is in full contact with the air around the infrared ceramic piece and burns completely, preventing carbon monoxide poisoning, incomplete gas combustion, and wasting gas. Prevent and increase thermal efficiency. [Selection] Figure 1

Description

  The present invention relates to a stove core structure of an infrared gas stove that can be applied to a portable gas stove, a private gas stove, a gas water heater, and the like.

The structure of the conventional infrared gas stove mainly includes an ignition device, a stove core, and an exhaust adjustment device, and when the flame comes out directly from a plurality of flame holes formed in the stove core, the food on the vessel is heated, When used, the flame was easily blown out by the wind. When cooking food, if boiling water overflows, even if the stove core gets wet and the flame disappears, the gas will continue to be discharged, and if the user does not notice that the flame has disappeared, the gas will stop immediately. Otherwise, dangerous accidents such as gas explosions will occur.
For this reason, some manufacturers conducted research and development, and installed members such as a bottom lid, gas separation member, and perforated furnace plate on the stove core. After passing the gas through the gas separation member, it is ignited through the perforated furnace plate to generate a flame, and after the gas is output from a small small hole on the perforated furnace plate, it is burned again to generate a flame. Therefore, although the protection by the perforated furnace plate can be used, the problem that the flame is blown out by the wind or blown out is easily caused.

The following two cases are already published patent documents as well as improving the above-mentioned problems.
Patent Document 1 is a Taiwan utility model registration No. M387967 publication “Gas burner head and portable gas stove using the same”, and typical products among those commercially available include a gas separation member and a porous furnace plate structure. A stove core structure of a gas stove having a top lid, a porous furnace plate provided below the top lid and having a number of through holes through which gas flows out, and a mesh provided under the perforated furnace plate and having many meshes A member, a porous gas separation member provided under the mesh member, in which many through holes through which gas flows are formed, and an upper lid, and a porous furnace plate, a mesh member and a porous gas separation member are sandwiched therebetween The peripheral sides of the perforated furnace plate, the net member and the porous gas separation member are in close contact with the storage tank of the bottom lid, maintaining the assembly stability, and the perforated furnace plate, the net member and the porous gas separation member are shaken within the bottom lid. Prevent And the lid, mainly including.
When used, the gas is output from the through hole in the center of the bottom lid, and the gas is guided and diverted through the hole on the porous gas separation member, and then distributed to the porous furnace plate after passing through the mesh of the mesh member. It flows out of the small hole made and burns when ignited by an ignition device, and heats or cooks food on the vessel.

Patent Document 2 is a Taiwan utility model registration No. M387967 publication "Gas burner head and portable gas stove using the same", and when actually used, gas passes from the hole of the porous gas separation member to the net member and the porous furnace. The burner fires through the plate and concentrates in the center, and when the vessel is placed on the gas burner head, the upper part of the center burner fire is covered with the vessel and the food placed in the vessel is removed. Heat or cook.
However, the burner fire generated in the center of the gas burner head is completely covered by the vessel, and the contact with the outside air is greatly reduced, so that there is a lack of air auxiliary combustion and the phenomenon of incomplete gas combustion occurs. . According to national safety standards, the amount of carbon monoxide contained in the air released from the gas stove must be less than 1400PPM, and when using the gas stove, too much carbon monoxide is released into the air. Therefore, there is a risk that the user may become poisoned with carbon monoxide.
Therefore, if the amount of carbon monoxide released into the air can be reduced when using a gas stove, it can be used safely, and incomplete gas combustion and inappropriate waste of gas Can be reduced and thermal efficiency can be increased.

  The main object of the present invention is to provide an infrared gas stove that forms a smooth flow line between a flow guide plate and a bottom cover, guides gas, and outputs the gas smoothly upward from the circumferential side of the flow guide plate. It is to provide a stove core structure.

  In order to achieve the above-mentioned object, the stove core structure of the infrared gas stove which is the technical means of the present invention has a bottom lid, the bottom lid has a storage tank, and gas flows from the bottom to the top. A gas through-hole introduced into the storage tank is formed at the bottom, a flow guide plate is installed in the storage tank, and an infrared ceramic piece is installed above the bottom cover, which is located above the flow guide plate. In addition, in the stove core structure of the infrared gas stove in which a pitch is formed between the flow guide plate, a pitch exists between the above-described flow guide plate and the bottom of the storage tank of the bottom lid, and gas penetration The holes are not covered, and a gap for allowing a large amount of gas to pass therethrough is formed on the circumferential side of the flow guide plate. After the gas has entered the storage tank through the gas through holes, the flow guide plate passes through the pitch. It is used as a main flow line where gas flows upward from the gap on the circumferential side of the gas.

  Furthermore, in the above-mentioned technical means, a height is formed between the above-described flow guide plate and the bottom cover storage tank by an elevated portion, and a pitch is formed between the flow guide plate and the bottom cover storage tank. In addition, the outer diameter of the flow guide plate is smaller than the inner diameter of the storage tank, and an annular gap is formed between the outer peripheral edge of the flow guide plate and the inner wall of the storage tank.

  Furthermore, in the above-mentioned technical means, the above-described elevated portion is configured by at least two hollow tube bodies, and is installed so as to correspond at equal intervals with the center of the bottom tank as a circular center, The bottom surface of the plate and the tank bottom of the storage tank are in contact with each other, and at least two lock holes corresponding to the hollow tube are formed on the tank bottom of the storage tank. Then, the nut is screwed and fixed through the tube hole of the hollow tube body and the lock hole previously formed in the flow guide plate.

  Furthermore, in the above-described technical means, the above-described elevated portion is configured by a support column extending upward from the tank bottom of the storage tank of the two bottom lids, and the upper end of the support column is in contact with the bottom surface of the flow guide plate, The flow plate has two lock holes corresponding to the above-mentioned support columns, and after two threaded members such as screws are inserted from top to bottom, they are fixed by screwing in the lock holes into which the support columns are screwed. To do.

  Furthermore, in the above-mentioned technical means, the above-described elevated portion is constituted by a bump extending upward from the bottom of the storage tank of the two bottom lids, and the outer edge of the flow guide plate is fitted into the step on the inner edge of the upper end of the bump. A recessed step is provided which is fixed.

  Furthermore, in the above-mentioned technical means, the above-described elevated portion is constituted by an elastic piece, the elastic piece is screwed to the bottom surface of the flow guide plate, and both elastic pieces are bent downward so that two elastic pieces are formed. A support leg is formed, and two engaging grooves corresponding to the above-mentioned elastic support legs are formed on the tank wall of the storage tank of the bottom lid, and the above-mentioned elastic support legs are fitted and fixed.

  Furthermore, in the above-described technical means, the above-described elevated portion is formed by an elastic support leg that is bent by pressing the peripheral edge of the flow guide plate downward, and the elastic support leg is fitted to the tank wall of the storage tank of the bottom lid. Thus, an engagement groove corresponding to the elastic support leg to be fixed is formed.

  Furthermore, in the above-mentioned technical means, the above-described elevated portion is at least an elastic member, the upper end of the elastic member is assembled on the bottom surface of the flow guide plate, and the other end is in contact with the tank bottom of the storage tank of the bottom lid. The

  Further, in the above technical means, the flow guide plate is formed with a plurality of small holes through which gas passes.

  Further, in the above technical means, the outer diameter of the flow guide plate is close to the maximum inner diameter of the storage tank, and the periphery of the flow guide plate is fitted to the tank wall of the storage tank of the bottom lid, A large number of slits through which gas passes are distributed in the outer ring region, and the slits are distributed at an equal angle and formed in a gap on the circumferential side of the flow guide plate, which becomes a main flow path of the gas.

  As described above, the stove core structure of the infrared gas stove of the present invention utilizes the pitch formed between the flow guide plate and the bottom of the storage tank of the bottom cover, and the gap on the circumferential side of the flow guide plate. Constructs one smooth gas flow line, guides the gas to flow out from the peripheral side of the flow guide plate, and the infrared ceramic piece assembled in the opening of the storage tank of the bottom lid outputs upward , The gas is in full contact with the air around the infrared ceramic piece and burns completely, effectively preventing the risk of carbon monoxide poisoning, preventing the gas from becoming incomplete and wasting gas, Thermal efficiency can be greatly improved.

It is a disassembled perspective view of 1st Example of the stove core of this invention. It is sectional drawing of the stove core of this invention of FIG. It is a perspective view which shows the state which uses this invention for a gas stove. It is sectional drawing of 2nd Example of the stove core of this invention. It is sectional drawing of 3rd Example of the stove core of this invention. It is sectional drawing of 4th Example of the stove core of this invention. It is sectional drawing of 5th Example of the stove core of this invention. It is sectional drawing of 6th Example of the stove core of this invention. It is sectional drawing of the 7th Example of the stove core of this invention. It is sectional drawing of 8th Example of the stove core of this invention. It is a disassembled perspective view of the flow guide plate and bottom cover of FIG. It is sectional drawing of 9th Example of the stove core of this invention. It is a disassembled perspective view of the flow guide plate and bottom cover of FIG.

  Hereinafter, embodiments will be described in detail with reference to the drawings.

  As shown in FIGS. 1 and 2, the first embodiment of the infrared gas stove core structure of the present invention mainly has a bottom lid 1, and a storage tank 11 is formed in the bottom lid 1. A gas through hole 12 is formed in the center of the tank bottom of the storage tank 11, a flow guide plate 2 is installed in the storage tank 11 of the bottom lid 1, and an infrared ceramic is disposed above the flow guide plate 2. The piece 3 is installed and attached on the opening of the storage tank 11 of the bottom lid 1. The infrared ceramic piece 3 has minute holes through which gas flows out. The infrared ceramic piece 3 is fixed on the opening of the bottom lid 1 via the annular upper lid 4, and a hollow hole 41 through which the infrared ceramic piece 3 is exposed is formed at the center thereof.

The flow guide plate 2 is pushed up in the storage tank 11, there is a pitch 6 between the flow guide plate 2 and the tank bottom of the storage tank 11 of the bottom lid 1, the gas through-hole 12 is not covered, A gap 7 through which a large amount of gas passes is formed on the peripheral side of the flow plate 2, and after the gas enters the storage tank 11 through the gas through holes 12, the gas passes through the pitch 6 and surrounds the flow guide plate 2. It flows upward from the gap 7 on the side and is used as the main flow line where the gas flows.
Between the above-described flow guide plate 2 and the storage tank 11 of the bottom lid, an elevated portion 5 for increasing the height is installed, and the outer diameter of the flow guide plate 2 is smaller than the inner diameter of the storage tank 11. An annular gap 7 is formed between the outer peripheral edge of the storage tank 11 and the inner wall of the storage tank 11.

The above-described elevated portion 5 is composed of at least two hollow tube bodies 51 and is installed so as to correspond at equal intervals with the center of the storage tank 11 as a center, and the upper and lower ends thereof are the bottom surface of the flow guide plate 2 and Each is in contact with the tank bottom of the storage tank 11.
At least two lock holes 13 corresponding to the hollow tube body 51 are formed at the bottom of the storage tank 11, and after inserting a screwing member 52 such as a screw from below to above, the hollow tube Since the nut 53 is screwed through the tube hole 511 of the body 51 and the lock hole 21 formed in the flow guide plate 2 in advance, the tip 521 of the screw member 52 is exposed from the bottom surface of the bottom lid 1. Here, the bottom cover 1, the flow guide plate 2, and the elevated portion 5 are combined and fixed, and an appropriate pitch is formed between the flow guide plate 2 and the infrared ceramic piece 3.

Please refer to FIG. FIG. 3 is a diagram for explaining the present invention in detail, in which the portable gas stove is taken as an example and the infrared gas stove core structure of the present invention is described in detail.
First, when a user turns on the exhaust gas adjusting device 8 of the infrared gas stove and a storage tank (not shown) hidden inside the stove supplies gas, it flows into the gas through hole 12 of the bottom lid 1 of the stove core. From the storage tank 11. Between the flow guide plate 2 and the tank bottom of the storage tank 11 of the bottom lid 1, an elevated portion 5 that supports the flow guide plate 2 and forms a pitch 6 is provided. Since the gap 7 is formed between the bottom lid 1 and the tank wall of the storage tank 11, the gas flowing into the storage tank 11 from the gas through hole 12 of the bottom cover 1 flows into the gap 7 from the pitch 6 described above. From the periphery of the flow guide plate 2, it flows upward to the peripheral side of the infrared ceramic piece 3, and then is output upward from the minute holes on the peripheral side of the infrared ceramic piece 3 to ignite the ignition device. The gas burns and the vessel placed on the infrared ceramic piece 3 is heated or cooked.
Next, as can be seen from FIG. 2, the peripheral flame above the infrared ceramic piece 3 is larger than the central flame, but the peripheral gas flow rate is higher than the central flame, and the peripheral fire momentum is the central flame. It is because it is bigger than the momentum.

  Since the peripheral side of the infrared ceramic piece 3 is not covered by the vessel, the gas comes into contact with the surrounding air. Therefore, with sufficient auxiliary combustion of the air, the gas output from the peripheral side of the infrared ceramic piece 3 is completely burned, and the thermal efficiency is greatly increased. According to the present invention, the amount of carbon monoxide released into the air is 0.0084%, which is lower than the current emission standard of 1400 PPM or less, as detected by the detection standard of CNS 14529 of “Taiwan Fuel Appliance Research Center” I understood that. As can be seen from the above, the stove core structure of the infrared gas stove of the present invention has a very small amount of carbon monoxide released into the air during use, thus reducing carbon monoxide emissions and using it safely. In addition, since the gas is completely burned, waste of gas can be prevented.

  As described above, there are many embodiments of the elevated portion 5. Hereinafter, the relationship between the elevated portion 5 and the pitch 6 will be further described with reference to the drawings.

FIG. 4 is a drawing showing a second embodiment of the stove core of the present invention, which differs from the drawing of the first embodiment in that the above-described elevated portion 5 is from the bottom of the storage tank 11 of the two bottom lids. This is a point constituted by a support 54 extending upward.
The column 54 has a lock hole 541 and an upper end abutted against the bottom surface of the flow guide plate 2, and the flow guide plate 2 has two lock holes 21 corresponding to the above-described columns 54, such as screws. After the screw member 52 is inserted from the top to the bottom, the screw member 52 is screwed and fixed in the lock hole 541 into which the support column 54 is screwed. A pitch 6 is formed between the bottom of the tank 11.

FIG. 5 is a view showing a third embodiment of the stove core of the present invention. The difference from the drawing of the second embodiment is that the above-described elevated portion 5 is constituted by a column 54 extending upward from the tank bottom of the storage tank 11 of the two bottom lids.
The upper end of the column 54 is connected to the flow guide plate 2, and the bottom lid 1, the column 54 and the flow guide plate 2 are integrally formed. Thereby, the flow guide plate 2 is installed high, and the pitch 6 is formed between the tank bottom of the storage tank 11 of the bottom cover 1.

FIG. 6 is a drawing showing a fourth embodiment of the stove core of the present invention. The difference from the above-described embodiment is that the above-described elevated portion 5 is constituted by bumps 55 extending upward from the tank bottoms of the storage tanks 11 of the two bottom lids 1.
A concave step 551 is provided on the inner edge of the upper end of the bump 55, and the outer edge of the flow guide plate 2 is fitted and fixed in the step 551. A pitch 6 is formed between the tank bottom.

FIG. 7 is a view showing a fifth embodiment of the stove core of the present invention. The difference from the above-described embodiment is that the above-described elevated portion 5 is constituted by an elastic piece 56.
The elastic piece 56 is screwed to the bottom surface of the flow guide plate 2, and two elastic support legs 561 are formed by bending both sides of the elastic piece 56 downward. The two engaging grooves 57 corresponding to the above-mentioned elastic support legs 561 are formed to fit and fix the elastic support legs 561, whereby the flow guide plate 2 is installed high, and the tank of the storage tank 11 of the bottom lid 1. A pitch 6 is formed between the bottom.

FIG. 8 is a view showing a sixth embodiment of the stove core of the present invention. The difference from the above-described embodiment is that the elastic support leg 22 is formed by pressing and bending the peripheral edge of the flow guide plate 2 of the above-described elevated portion 5 downward.
Engaging grooves 57 corresponding to the above-mentioned elastic support legs 22 for fitting and fixing the elastic support legs 22 are formed in the tank wall of the storage tank 11 of the bottom lid. A pitch 6 is formed between the bottom of the storage tank 11 of the lid 1.

FIG. 9 is a view showing a seventh embodiment of the stove core of the present invention. The difference from the above-described embodiment is that the above-described elevated portion 5 is at least an elastic member 58.
The upper end of the elastic member 58 is assembled on the bottom surface of the flow guide plate 2, and the other end is brought into contact with the bottom of the bottom cover storage tank 11, whereby the flow guide plate 2 is installed higher and the bottom cover 1 is stored. A pitch 6 is formed between the tank 11 and the tank bottom.

FIG. 10 is a drawing showing an eighth embodiment of the stove core of the present invention. The stove core is different from the above-described embodiment in that a plurality of small holes 25 are formed in the flow guide plate 2.
As shown in FIG. 11, after the gas enters the storage tank 11 from the gas through hole 12, the gap 7 on the circumferential side of the flow guide plate 2 is used as the main flow path of the gas. The plurality of small holes 12 are used as a flow path for a small amount of gas, whereby a large flame is concentrated on the peripheral side of the infrared ceramic piece 3 and a small flame is distributed in the central region of the infrared ceramic piece 3.

FIG. 12 is a drawing showing a ninth embodiment of the stove core of the present invention. The stove core is different from the above embodiment in that the outer diameter of the flow guide plate 2 is close to the maximum inner diameter of the storage tank 11 and the peripheral edge of the flow guide plate 2 is fitted to the tank wall of the storage tank 11 of the bottom lid. It is a point.
As shown in FIG. 13 again, a large number of slits 24 through which gas passes are distributed in the outer ring region of the flow guide plate 2. Since the slits 24 are distributed at an equal angle, after the gas enters the storage tank 11 from the gas through-holes 12, the slits 24 in the outer ring region of the flow guide plate 2 are formed in the gap 7 on the circumferential side, and the gas Will be the main flow path.

  The drawings of the above-described embodiments do not limit the stove core structure of the infrared gas stove of the present invention, and the same scope of the same effect can be obtained by directly replacing equivalent means that are the same as or similar to the technical means to which the present invention belongs. It is included in the protection scope of the present invention as long as it is within.

DESCRIPTION OF SYMBOLS 1 Bottom cover 11 Storage tank 12 Gas through-hole 13 Lock hole 2 Flow guide plate 21 Lock hole 22 Elastic support leg 23 Hook piece 24 Slit 25 Small hole 3 Infrared ceramic piece 4 Upper lid 41 Hollow hole 5 Elevated part 51 Tube body 511 Tube hole 52 Screw member 521 Tip 53 Nut 54 Strut 541 Lock hole 55 Bump 551 Step 56 Elastic piece 561 Elastic support leg 57 Engaging groove 58 Elastic member 6 Pitch 7 Gap 8 Exhaust adjustment device

Claims (10)

It has a bottom lid (1), the bottom lid (1) has a storage tank (11), and a gas through-hole (12) through which gas is introduced into the storage tank (11) from below to above. ) Is formed at the bottom, a flow guide plate (2) is installed in the storage tank (11), and an infrared ceramic piece (3) is installed above the bottom cover (1), which is the flow guide plate In the stove core structure of the infrared gas stove that is located above the plate (2) and has a pitch formed with the flow guide plate (2),
The flow guide plate (2) is pushed up, there is a pitch (6) between the bottom lid (1) and the tank bottom of the storage tank (11), and the gas through hole (12) is not covered. ,
On the circumferential side of the flow guide plate (2), a gap (7) for allowing gas to pass is formed,
After gas has entered the storage tank (11) through the gas through hole (12), it passes through the pitch (6) and is above the gap (7) on the circumferential side of the flow guide plate (2). It is used as a main flow line in which gas flows.
Infrared gas stove core structure.   The space between the flow guide plate (2) and the storage tank (11) of the bottom lid is raised by an elevated part (5), and the storage tank (of the flow guide plate (2) and the bottom cover (1) ( 11) The pitch (6) is formed between the tank bottom and the outer diameter of the flow guide plate (2) is smaller than the inner diameter of the storage tank (11), and the outer peripheral edge of the flow guide plate (2). The infrared gas stove core structure according to claim 1, wherein the annular gap (7) is formed between the storage tank (11) and the inner wall of the storage tank (11).   The elevated portion (5) is composed of at least two hollow tube bodies (51), and is installed so as to correspond at equal intervals with the center of the bottom tank (11) as a circular center, Two lock holes corresponding to the hollow tubular body (51) are in contact with the bottom surface of the flow plate (2) and the bottom of the storage tank (11), respectively. (13) is formed, and after passing through the screw member (52) from the bottom to the top, the tube hole (511) of the hollow tube (51) and the flow guide plate (2) An infrared gas stove core structure according to claim 2, wherein a nut (53) is screwed and fixed through a lock hole (21) formed in advance.   The elevated portion (5) is constituted by a column (54) extending upward from the tank bottom of the storage tank (11) of the two bottom lids, and the upper end of the column (54) is the flow guide plate (2). ), The flow guide plate (2) has two lock holes (21) corresponding to the columns (54), and the two screwing members (52) are hooked from top to bottom. The infrared gas stove stove core structure according to claim 2, wherein after being inserted, the infrared gas stove core structure is screwed and fixed in the lock hole (541) into which the column (54) is screwed.   The elevated portion (5) is configured by a bump (55) extending upward from the bottom of the storage tank (11) of the two bottom lids (1), and an upper end inner edge of the bump (55) The stove core structure of the infrared gas stove according to claim 2, wherein the step (551) is provided in which the outer edge of the flow guide plate (2) is fitted and fixed in the step (551). .   The elevated portion (5) is constituted by an elastic piece (56), and the elastic piece (56) is screwed to the bottom surface of the flow guide plate (2), and both sides of the elastic piece (56) face downward. Two elastic support legs (561) are formed by bending, and the elastic support legs (561) are fitted and fixed to the tank wall of the storage tank (11) of the bottom lid. The infrared gas stove stove core structure according to claim 2, wherein two engagement grooves (57) corresponding to the above are formed.   The elevated portion (5) is formed by an elastic support leg (22) which is formed by pressing and bending the periphery of the flow guide plate (2) downward, and the tank wall of the storage tank (11) of the bottom lid The infrared gas stove stove core structure according to claim 2, wherein an engagement groove (57) corresponding to the elastic support leg (22) for fitting and fixing the elastic support leg (22) is formed.   The elevated portion (5) is at least an elastic member (58), the upper end of the elastic member (58) is assembled to the bottom surface of the flow guide plate (2), and the other end is the storage tank ( The stove core structure of an infrared gas stove according to claim 2, which is in contact with the tank bottom of 11).   The infrared gas stove core structure according to claim 1, wherein the flow guide plate (2) has a plurality of small holes (25) through which gas passes.   The outer diameter of the flow guide plate (2) is close to the maximum inner diameter of the storage tank (11), and the periphery of the flow guide plate (2) is fitted to the tank wall of the storage tank (11) of the bottom lid. In the outer ring region of the flow guide plate (2), a large number of slits (24) through which gas passes are distributed, and the slits (24) are distributed at equal angles, and the flow guide plate (2) The stove core structure of an infrared gas stove according to claim 1, characterized in that it is formed in the gap (7) on the peripheral side and becomes a main flow path of gas.

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