KR0172190B1 - Catalytic combustion iron - Google Patents

Abstract

The present invention aims to control the bottom of the garment at a temperature suitable for ironing by spreading wrinkles of clothing and the like by using heat obtained by catalytic combustion of liquefied fuel gas. In the iron body (1), the liquefied fuel gas in the fuel tank (3) installed in the iron main body (1) is vaporized and ejected from the nozzle (11), and the fuel gas and air ejected from the nozzle (11) to the mixing device (13). Mix. The mixed gas supplied from the mixing device 13 is ignited by the ignition device 21, catalytically burned by the catalyst 19 in the combustion chamber 14, and the bottom portion ( 23). The heat of combustion of the catalyst 19 is sensed by an operating member operating in response to a predetermined temperature, associated with the operating member, and associated with the combustion heat of the catalyst 19 to the combustion chamber 14. It is characterized in that the supply is controlled by the valve device (7).

Description

Catalytic Combustion Iron

1 is a cross-sectional view showing an embodiment of the catalytic combustion iron of the present invention.

2 is an enlarged cross-sectional view of a main portion of the catalytic combustion iron.

3 is a sectional view A-A in FIG. 1 of the catalytic combustion iron.

4 is a cross-sectional view taken along line B-B in FIG. 1 showing an off state of the catalytic combustion iron.

5 is an enlarged sectional view of the main portion of FIG. 4 of the catalytic combustion iron.

6 is a sectional view taken along line B-B in FIG. 1 showing the on-state of the catalytic combustion iron.

7 is an enlarged sectional view of the main portion of FIG. 6 of the catalytic combustion iron.

8 is an exploded perspective view of a portion of the catalytic combustion iron cut out and enlarged.

FIG. 9 is a sectional view taken along line B-B in FIG. 1 showing a state in which the blocking device of the catalytic combustion iron is operated. FIG.

10 is a sectional view showing the main parts of another embodiment of the catalytic combustion iron of the present invention.

11 is a sectional view showing the main portion of another embodiment of the catalytic combustion iron of the present invention.

* Explanation of symbols for main parts of the drawings

1: iron body 2: handle

3: fuel tank 7: valve device

11 nozzle 13 mixing device

14 combustion chamber 19 catalyst

21: ignition device 23: bottom

32: operating member

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a catalytic combustion iron for unwrinkling clothes and the like using heat obtained by catalytic combustion of liquefied fuel gas.

Conventionally, this type of catalytic combustion iron is, for example, as described in Japanese Patent Application Laid-Open No. 62-144697, and vaporizes a fuel tank filled with fuel made of combustible gases such as propane and butane and fuel gas. And a nozzle which blows out, a valve is provided between the fuel tank and the nozzle to manually operate the supply and stop of the gas. The fuel gas ejected from the nozzle is mixed with air in a mixing device, and catalytic combustion is performed on a catalyst provided in the combustion chamber to generate combustion heat. This heat is transferred from the combustion chamber to the bottom and wrinkles of the garment are performed by the heated bottom.

However, such a conventional catalytic combustion iron does not have a temperature control device for controlling the bottom portion to a predetermined temperature, and the temperature is always adjusted because the user manually operates the valve to supply and stop the gas. There is an inconvenience that the ironing must be performed while paying attention to the negative temperature.

In order to solve such inconvenience in use, it is conceivable to limit the amount of fuel gas ejected so that the bottom portion is saturated at a predetermined safe temperature, but in such a configuration, the amount of catalyst combustion by the catalyst cannot be increased. Since it takes a long time to reach a predetermined temperature and the amount of catalytic combustion is small and sufficient calories cannot be obtained, the temperature of the bottom portion rapidly decreases when ironing, so that the temperature sufficient for wrinkles of clothing cannot be maintained. In addition, there has been a problem that the temperature of the catalyst also rapidly decreases and the catalytic combustion stops, so that stable catalytic combustion cannot be continued.

Therefore, in order to make such a catalytic combustion iron convenient for use, it is conceivable to install a temperature control device. However, the temperature of the catalyst decreases with the lowering of the bottom temperature caused by ironing, so that stable catalytic combustion cannot be continued. . Therefore, it is not necessary to significantly increase the amount of combustion by the catalyst so that the temperature of the bottom portion reduced by ironing can be recovered quickly.

This is because it is possible to prevent the rapid temperature drop of the catalyst caused by the rapid decrease in the temperature of the bottom or the vaporization chamber, and to maintain stable catalytic combustion unless the catalyst is kept above its activation temperature. However, when the catalytic combustion iron which has such a large heat capacity and can always control the bottom part at the temperature suitable for ironing, and improves the convenience of use, the following problem arises in terms of stability.

That is, if the catalytic combustion iron having such a large heat capacity fails to control the supply of the combustion gas due to a failure of the temperature control device, the bottom or iron body is suddenly overheated by the large heat capacity and burned, There was problem to cause.

In addition, the wrinkle spreading effect of the clothing is not sufficient by heat alone, and it is effective to supply water vapor. However, vaporizing water by the heat of combustion of the catalyst further accelerates the temperature decrease of the combustion chamber, and thus rapidly lowers the temperature of the catalyst. As a result, there has been a problem that if the steam is continuously ejected, the combustion of the medium stops during use, and the ironing operation must be stopped.

Therefore, the catalytic combustion iron of the present invention solves such a conventional problem, and a first object is to obtain a catalytic combustion iron which can be ironed at a temperature suitable for unwrapping clothes. A second object is to obtain a catalytic combustion iron capable of steadily controlling the amount of fuel gas supplied to the combustion chamber on the basis of the heat of combustion by the catalyst so as to continue stable catalytic combustion. A third object is to obtain a safe catalytic combustion iron which can reliably stop the catalytic combustion of the mixed gas when the combustion chamber is abnormally overheated and exceeds a predetermined temperature. A fourth object is to increase the wrinkle spreading effect of the garment by maintaining the combustion state in a stable state without lowering the temperature of the catalyst even when steam is ejected.

In order to achieve the first object of the present invention, an iron main body having a handle, a fuel tank for storing liquefied fuel gas installed in the iron main body, and a liquefied fuel gas in the fuel tank are vaporized and ejected. A nozzle, a mixing device for mixing the fuel gas ejected from the nozzle and air, a catalyst for catalytically burning the mixed gas supplied from the mixing device, an ignition device for igniting the mixed gas supplied from the mixing device, and A combustion chamber incorporating a catalyst, a bottom portion heated by the heat of combustion by the catalyst, an operating member that senses the heat of combustion of the catalyst and operates in response to the heat, and the heat of combustion of the catalyst in association with the operating member And a valve device for controlling the supply of the mixed gas to the combustion chamber in connection with the fuel cell, and the closing direction of the valve device is a fuel tank. By the pressure of the gas of the emitter and that is set in the direction receiving the force a valve body of the first problem solving means.

In addition, in order to achieve the second object, an iron body having a handle, a fuel tank for storing liquefied fuel gas installed in the iron body, a nozzle for vaporizing and ejecting liquefied fuel gas in the fuel tank, A mixing device for mixing the fuel gas and air ejected from the nozzle, a catalyst for catalytically burning the mixed gas supplied from the mixing device, an ignition device for igniting the mixed gas supplied from the mixing device, and the catalyst A combustion chamber, a bottom portion heated by the heat of combustion by the catalyst, an operating member that senses the temperature of the heat of combustion of the catalyst and operates in response to the temperature, and in conjunction with the operating member, furthermore, the heat of combustion of the catalyst In connection with the above, after the supply of the mixed gas to the combustion chamber is stopped, the heat of combustion of the catalyst is reduced until the catalyst lowers to the lower ignition limit temperature. According to the second problem solving means, the valve device is driven and set so as to start the supply of the mixed gas to the combustion chamber.

In order to achieve the object of 3, an iron body having a handle, a tank for storing liquefied fuel gas installed in the iron body, a nozzle for vaporizing and ejecting the liquefied fuel gas in the tank, and A mixing device for mixing the fuel gas and air ejected, a catalyst for catalytic combustion of the mixed gas supplied from the mixing device, an ignition device for igniting the mixed gas supplied from the mixing device, a combustion chamber incorporating the catalyst; And a bottom portion heated by the heat of combustion by the catalyst, a valve device for controlling the supply of the mixed gas to the combustion chamber, a heat sensing member for sensing the heat of combustion by the catalyst, and the heat sensing member at a predetermined temperature. The third problem solving means provided with the interruption | blocking apparatus which cuts off the said valve apparatus and the intake part of air in response to operation | movement of this heat sensing member when it exceeds this. I am doing it.

In order to achieve the fourth object, an iron body having a handle, a fuel tank for storing liquefied fuel gas installed in the iron body, a nozzle for vaporizing and ejecting the liquefied fuel gas in the fuel tank, A mixing device for mixing fuel gas and air ejected from the nozzle, a water tank for storing water, a vaporization chamber for vaporizing water supplied from the water tank, and a water control device for controlling the supply of water to the vaporization chamber. And a ignition device for igniting the mixed gas supplied from the mixing device, a first catalyst for catalytically burning the mixed gas to heat the vaporization chamber, a second catalyst disposed close to the first catalyst, and a catalyst. The bottom part heated by the combustion heat by this, the combustion chamber in which the said 1st catalyst and the 2nd catalyst were built-in, and the valve apparatus which controls the supply of the mixed gas to this combustion chamber are the 4th problem solution number. As it is.

In order to achieve the fourth object, an iron body having a handle, a fuel tank for storing liquefied fuel gas installed in the iron body, a nozzle for evaporating and liquefying liquefied fuel gas in the fuel tank, A mixing device for mixing the fuel gas and air ejected from the nozzle, a combustion chamber supplied with the mixed gas from the mixing device, a fin protruding toward the inner surface of the combustion chamber, a catalyst covering the fin and disposed inside the combustion chamber; And the bottom part heated by the heat of combustion by this catalyst, and providing the space part between the said catalyst and the fin as 5th subject solving means.

In order to achieve the fourth object, an iron body having a handle, a fuel tank for storing liquefied fuel gas installed in the iron body, a nozzle for vaporizing and ejecting the liquefied fuel gas in the fuel tank, A mixing device for mixing the fuel gas and air ejected from the nozzle, a combustion chamber supplied with the mixed gas from the mixing device, a catalyst disposed in the combustion chamber, and a downstream side of the catalyst, The sixth problem solving means is provided with an auxiliary catalyst having a low ignition lowering temperature.

In order to achieve the fourth object, an iron body having a handle, a fuel tank for storing liquefied fuel gas installed in the iron body, a nozzle for vaporizing and ejecting the liquefied fuel gas in the fuel tank, A mixing device for mixing the fuel gas and air ejected from the nozzle, a combustion chamber supplied with the mixed gas from the mixing device, a catalyst disposed in the combustion chamber, and a downstream side of the catalyst, The seventh problem solving means is provided with an auxiliary catalyst having a small temperature drop characteristic.

The present invention is directed to a valve for controlling supply of a mixed gas to a combustion chamber in association with an operating member which senses and operates heat of combustion of a catalyst by the first problem solving means described above. Since the closing direction of the device can be the direction in which the valve body is forced by the pressure of the gas, even if the temperature of the fuel tank rises as the temperature of the iron body rises, and the pressure of the liquefied fuel gas in the fuel tank rises, Since the pressure of the gas from the fuel tank operates in the direction of closing the valve element, the temperature can be controlled to be suitable to a temperature suitable for unwrinkling without abnormally increasing the temperature.

In addition, by the second problem solving means, the operation member stops the supply of the mixed gas to the combustion chamber and then starts the supply of the mixed gas to the combustion chamber until the catalyst is lowered to the lower ignition temperature. When the supply of the mixed gas to the combustion chamber is stopped and supplied again, the temperature of the catalyst is not lowered below the lower ignition lower limit temperature, so that the catalytic combustion can be resumed at the same time as the supply of the mixed gas, so that stable combustion continues. It can be done.

Further, by the third problem solving means, the heat sensing member for sensing the heat of combustion by the catalyst, and when the heat sensing member exceeds a predetermined temperature, the blocking device operates in response to the operation of the heat sensing member, It is possible to stop the supply of the mixed gas to the combustion chamber by shutting off the valve device for controlling the supply of fuel gas and the intake of air, so that the catalytic combustion can be stopped immediately and prevented from being burned and damaged by overheating.

In addition, even if the first catalyst for heating the vaporization chamber by the vaporization of water is cooled by the fourth problem solving means, the first catalyst is kept warm by the heat of combustion by the second catalyst disposed close to the first catalyst. Therefore, the water vapor can be continuously ejected without stopping the combustion due to the temperature decrease of the catalyst during use.

In addition, by the fifth problem solving means, it is possible to suppress heat dissipation of the heat of combustion from the catalyst to the fins and to keep the temperature of the catalyst high. . As the mixed gas flows between the catalyst and the fin, the catalyst can be installed and combusted on the surface of the fin side, and the fin can be prevented from overheating by reducing contact with the fin and the catalyst.

In addition, even when the bottom temperature is set in accordance with the use condition of the iron by the sixth problem solving means, the supply of fuel gas is controlled from the nozzle, and even if the catalyst temperature drops to a temperature at which reignition is impossible, The lower catalyst can be deposited by a cocatalyst having a low lower temperature, so that stable catalytic combustion can be continued.

In addition, according to the seventh problem solving means, even when the catalyst is lowered to a temperature at which reignition is impossible, the cocatalyst is kept at a high temperature so that it can be re-ignited immediately and stable combustion can be continued.

EMBODIMENT OF THE INVENTION Hereinafter, one Example of the catalytic combustion iron of this invention is described based on an accompanying drawing. In Figs. 1 to 9, reference numeral 1 denotes an iron main body, which has a handle 2 at the top and a fuel tank 3 for storing liquefied fuel gas such as propane, butane and isobutane at the rear. It is built. The fuel tank 3 has an injection section 4 for injecting liquefied fuel gas, and is provided with a partition 6 having a communication section 5 therein. The communication section 5 is set above the maximum storage amount of the liquefied fuel gas defined by the injection section 4.

The valve device 7 includes a vaporization device 8 for vaporizing liquefied fuel gas ejected from the fuel tank 3, a first valve body 9 and a second valve body 10 for opening and closing the vaporized fuel gas. And a nozzle 11 for ejecting the vaporized fuel gas, and the fuel gas from the fuel tank 3 is vaporized by the vaporization device 8, and then the first valve body 9 and the second valve body ( 10, the fuel gas is discharged from the nozzle 11, and the air drawn from the intake unit 12 and fuel gas are attracted by the fuel gas flow discharged from the nozzle 11. Mix evenly on

The combustion chamber 14 is comprised from the 1st combustion chamber structure 15 formed from aluminum, and the 2nd combustion chamber structure 16 arrange | positioned under this 1st combustion chamber structure 15, The 1st combustion chamber structure 15 is comprised. The inner surface of the plurality of upper pins 17 protrude along the flow direction of the mixed gas. In addition, a plurality of lower pins 18 protrude from the inner surface of the second combustion chamber structure 16 along the flow direction of the mixed gas, and the upper pins 17 and the lower pins 18 are shifted from each other. And a predetermined space is formed between them, and they are deeply engaged with each other.

On the upper pin 17 and the lower pin 18, a catalyst 19 having a noble metal catalyst such as platinum or palladium is attached to the bent thin metal plate along each surface, and the upper pin 17 is attached to the upper pin 17. It consists of the 1st catalyst 19a and the 2nd catalyst 19b provided in the lower pin 18. As shown in FIG.

The distance between the first catalyst 19a and the second catalyst 19b is set almost equally and is closely arranged, and the mixed gas flows uniformly in the space formed between them, and the first catalyst 19a and The contact area between the second catalyst 19b and the fuel gas flowing inside the combustion chamber 19 is increased. In addition, a space portion 20 is formed between the upper fin 17 and the first catalyst 19a, and between the lower fin 18 and the second catalyst 19b, respectively. The size of the fuel gas is in contact with the inside of 19).

In addition, the first combustion chamber structure 15 and the second combustion chamber structure 16 are coupled to the outside of the catalyst 19, and the upper fins 17 covered with the first catalyst 19a are arranged in the first combustion chamber structure 15. ) And integrally formed.

Further, the catalyst 19 is mounted so that its upstream end 19c protrudes outward from the upper pin 17 and the lower pin 18. Further, the downstream end 19d of the catalyst 19 is mounted so as to protrude outward from the upper pin 17 and the lower pin 18, and the ignition device 21 near the downstream end 19d. ) Is installed. The ignition device 21 discharges the high voltage generated by operating the ignition piezoelectric element 22 to ignite the mixed gas supplied from the mixing device 13. In addition, the ignition device 21 may be configured to ignite and heat the electric heater red using a battery or the like.

The bottom part 23 is provided in the lower surface side of the 2nd combustion chamber structure 16 which comprises the combustion chamber 14, and is heated by the heat of combustion by the catalyst 19, and this bottom part 23 and the 2nd An exhaust passage 24 for discharging the combustion gas combusted in the combustion chamber 14 is formed between the combustion chamber members 16. A downstream portion of the exhaust passage 24 includes a bottom 23 and a main body cover ( An exhaust port 26 is formed in the gap on the outer circumferential side surface between 25, and combustion gas is discharged out of the iron body 1 from the exhaust port 26.

The vaporization chamber 27 is formed on the upper surface of the first combustion chamber structure 15 and covered with the vaporization chamber lid 28, and is connected to the water tank 30 via the water supply passage 29. The heat transfer member 31 thermally connects the vaporization chamber lid 28 and the valve device 7, and returns a part of the combustion heat by the catalyst 19 to the vaporization device 8 inside the valve device 7. I'm making it.

As shown in FIG. 2, the operating member 32 is located on the upper surface of the first combustion chamber assembly 15 and is disposed upstream of the catalyst 19, and the catalyst is provided through the first combustion chamber assembly 15. As shown in FIG. The temperature control device 34 is configured to operate by sensing the heat of combustion of 19 and to control the valve device 7 in connection with the heat of combustion of the catalyst 19 via the linkage device 33. Then, the temperature control device 34 stops the supply of the mixed gas to the combustion chamber 14, and then closes the valve on the basis of the heat of combustion of the catalyst 19 until the catalyst 19 drops to the lower limit of ignition temperature. The apparatus 7 is driven and set to start supply of the mixed gas to the combustion chamber 14.

The linkage device 33 transmits the displacement of the operation member 32 to the valve device 7. As shown in FIG. 8, one end portion of the linkage device 33 is fixed to the fixed shaft portion 35. The driving pedestal 36 mounted with the dowel, the plurality of links 38 with the dowel mounted by the first shaft 37 on the opposite side of the fixed shaft portion 35, and the second shaft at the other end of the link 38 39 and a spring support 41 for driving the valve device 7, a spring body 41 for biasing the drive support 36 toward the valve device 7, and a drive support ( The cam body 42 which displaces 36 in the driving direction of the valve apparatus 7, and the manual body 43 which were connected to the cam body 42 are provided, and this manual body 43 is equipped with the main body cover 25 I can operate it from the outside.

That is, a plurality of parallel links 38 are rotatably coupled to the valve operating body 40 by the first shaft 37, and the other end of the link 38 is connected by the second shaft 39. It is rotatably mounted on the drive support (36). The link 38 cannot move in contact with the driving support 36 at the lower side in the drawing, but moves freely in the upper direction.

The adjustment screw 44 abuts against the valve operating body 40, thereby adjusting the contact position with the actuating member 32 by rotating it so that the opening and closing position of the valve device 7 can be adjusted. The temperature of the operating member 32 at the position where the valve device 7 closes is the temperature controlled, and the temperature of the bottom 23 at this time is the bottom temperature at the time of control.

In addition, by manually operating the manual operation body 43 from the outside of the main body cover 25, the cam body 42 is rotated, and the driving support 36 is moved downward to the lower side in FIG. 9 against the elastic force of the spring body 41. FIG. By pushing down, the valve operating body 40 is moved downward to open the second valve body 10 inside the valve device 7 and close the second valve body 10 by the opposite operation. The 2nd valve body 10 is provided upstream of the 1st valve body 9 which controls supply of the mixed gas to the combustion chamber 14 in connection with the heat of combustion of the catalyst 19, and the 1st valve body 9 ) Is set in a direction in which the direction of closing the fuel cell 3 is biased by the pressure of the gas from the fuel tank 3.

The shut-off device 45 stops the supply of fuel gas to the combustion chamber 14 when the combustion chamber 14 rises abnormally above the predetermined temperature controlled by the temperature control device 34. It consists of a heat-sensing member 46 made of a constant-temperature molten metal, for example, eutectic solder, or the like, and a tubular body 47 and a spring device 48 that are melted when heated to a high temperature. The heat sensing member 46 is mounted so as to sense the temperature of the combustion chamber 14, and specifically, is arranged concentrically toward the outside of the cylindrical body 47 which is freely provided so as to surround the mixing device 13. One end of the cylindrical body 47 faces the valve operating body 40 for driving the valve device 7 at a predetermined interval, while the other end thereof is disposed between the support member 49 and the heat sensing member 46. ), And pressurizes the heat sensing member 46 by the spring device 48, and the cylindrical body 47 is applied to the valve device 7. As shown in FIG.

The water control device 50 controls the supply of water from the water tank 30 to the vaporization chamber 27 connected via the water supply passage 29. The water control device 50 controls the operation unit 51 provided on the handle 2. By operating in the direction of arrow X, the wire 52 is pulled, the water supply port 54 is opened by displacing the lever 53 in the direction of arrow X, and water is supplied to the vaporization chamber 27. As shown in FIG. In addition, the water inlet 54 is provided at the rear portion of the water tank 30, and the water in the water tank 30 can be supplied to the vaporization chamber 27 even when the bottom portion 23 is vertically upright. It is supposed to be. Water vapor generated in the vaporization chamber 27 passes through the water vapor passage 55 and is discharged to the outside from the water vapor ejection hole 56 formed in the bottom surface of the bottom 23.

The opening and closing device 57 which operates in response to the predetermined heat opens the water supply passage 29 when the vaporization chamber 27 is heated to a predetermined temperature, and closes the water supply passage 29 when the vaporization chamber 27 falls to the predetermined temperature. It operates so as to control the supply of water to the vaporization chamber 27, and it drives by the inversion operation of the bimetal 58 arrange | positioned near the vaporization chamber 27. FIG.

Next, the action of the catalytic combustion iron configured as described above will be described. In the state shown in FIG. 4 and FIG. 5, the valve apparatus 7 is pushed up by the valve operating body 40, and the 2nd valve body 10 is closed and the gas outlet of the vaporization apparatus 8 is closed. The liquefied fuel gas in the fuel tank 3 is not supplied. In this state, when the manual operation body 43 is operated and moved to the lower side, the cam body 42 is rotated, and the driving support 36 is pushed downward against the elastic force of the spring body 41, and the valve operating body 40 is moved. ) Is moved downward to open the second valve body 10 as shown in FIG.

Therefore, the liquefied fuel gas inside the fuel tank 3 is vaporized by the vaporization apparatus 8, supplied from the nozzle 11 to the mixing apparatus 13, and air is attracted by the gas flow which spouted from the nozzle 11 The gas is introduced into the mixing device 13 from the intake section 12, so that air and fuel gas are uniformly mixed in the mixing device 13, and the mixed gas is supplied to the combustion chamber 14.

At this time, the ignition piezoelectric element 22 is operated at the same time, and the ignition apparatus 21 ignites the mixed gas proximate to the catalyst 19, and when the catalyst 19 is heated to the activation temperature, the catalyst 19 is heated on the catalyst 19. Initiate an exothermic reaction.

This exothermic reaction gradually develops into the entire interior of the combustion chamber 14, and heats the vaporization chamber 27 and the bottom 23 by heat conduction from the combustion chamber 14, while the combustion gas is exhausted from the combustion chamber 14. Via 24, it is discharged from the exhaust port 26 to the atmosphere.

When the combustion chamber 14 rises to a predetermined temperature, the temperature of the operating member 32 also rises and displaces downward. As a result, the valve operating body 40 moves downward, and closes the first valve body 9 as shown in FIG. When the combustion chamber 14 again falls below a predetermined temperature, the operation member 32 is displaced upward, and the valve operating body 40 is pushed up to open the first valve body 9. Thereby, fuel gas is supplied to the combustion chamber 14, and such operation is repeated and controlled to predetermined temperature.

The pressure of the fuel gas stored in the fuel tank 3 is highly dependent on temperature. For example, in the case of isobutane, which is commonly used, it is 3 kg per unit area (cm 2) at 20 ° C. It becomes 6 kg. Therefore, the force which opens and closes the nozzle 11 becomes large in proportion to it.

According to this structure, when the force which opens the 1st valve body 9 becomes large, a set temperature acts in the direction which goes down. When the temperature of the gas, which was 20 ° C. at the time of start of use, exceeded 40 ° C. during use due to heat from the surroundings, in the above configuration, the set temperature acts in a downward direction, and as a result, the temperature of the fuel tank 3 decreases. Go and the pressure drops. Thus, stability can be improved by setting it as the structure which self control is performed.

In this way, the supply of the mixed gas to the combustion chamber 14 to the valve device 7 in association with the heat of combustion of the catalyst 19 is linked to the operating member 32 which senses and operates the heat of combustion of the catalyst 19. By controlling by this, even if the amount of catalytic combustion is increased, the temperature of the bottom portion 23 heated by the catalytic combustion can be controlled to a predetermined temperature.

In addition, the operation member 32 stops the supply of the mixed gas to the combustion chamber 14 and then, based on the heat of combustion of the catalyst 19 until the catalyst 19 falls to the lower limit of ignition temperature, the valve device ( 7) is driven and the supply of the mixed gas to the combustion chamber 14 is started so that the supply of the mixed gas to the combustion chamber 14 is stopped and supplied again, the temperature of the catalyst 19 is equal to or lower than the lower limit of ignition temperature. Since it is not lowered, the catalytic combustion can be restarted at the same time as the supply of the mixed gas again, and stable combustion can be continued.

In addition, since the combustion state at the time of catalytic combustion generates heat from the upstream side of the catalyst 19, the temperature upstream of the catalyst 19 is high, and the operating member 32 is disposed by disposing the operating member 32 upstream of the catalyst. Improves sensitivity.

Also, by setting the closing direction of the valve device 7 to the direction in which the valve body is forced by the pressure of the gas from the fuel tank 3, the temperature inside the iron main body 1 rises when the catalytic combustion is continued. Since the temperature of the fuel tank 3 also rises, the pressure of the liquefied fuel gas inside the fuel tank 3 increases, but the pressure of the gas from the fuel tank 3 when the temperature inside the iron body 1 rises. Since the valve acts in the direction of closing the valve device 7, the temperature does not rise abnormally and the safety is improved.

Moreover, in connection with the heat of combustion of the catalyst 19, supply and stop of supply of the mixed gas to the combustion chamber 14 to the upstream of the 1st valve body 9 which controls supply of the mixed gas to the combustion chamber 14 are manually performed. By disposing the second valve body 10 connected to the valve operating body 40 to be controlled by the controller, the second valve body 10 can be provided in close proximity to the vaporization device 8 for vaporizing the liquefied fuel gas. Therefore, when the 2nd valve body 10 is closed, liquefied fuel gas does not accumulate between the vaporization apparatus 8 and the 2nd valve body 10, and the 2nd valve body 10 at the time of start-up is carried out. When the fuel cell is opened, the liquefied fuel gas is not vaporized through the nozzle 11, so that it is not supplied to the mixing device 13.

In addition, the linkage device 33 which transmits the displacement of the operation member 32 to the valve device 7 is opposite to the drive support 36 whose one end is fixedly mounted to the fixed shaft portion 35 and the fixed shaft portion 35. A plurality of links 38, which are mounted to each other, a valve operating body 40 to which the other end of the link 38 is mounted, which drives the valve device 7, and a driving support 36, A spring body 41 for exerting a force toward 7), a cam body 42 for displacing the driving support 36 in the driving direction of the valve device 7, and a manual operation body 43 opened in the cam body 42; By this, the operation direction of the valve apparatus 7 and the moving direction of the valve operation body 40 which drives this valve apparatus 7 can be formed in parallel and spaced apart.

Further, even if the operation member 32 is not displaced in the linear direction, the valve operating body 40 can be displaced in the linear direction, and the cam body 42 is operated by operating the manual operation body 43 to drive the support base. The valve device 7 can be controlled by displacing the 36 in the driving direction of the valve device 7 via the valve operating body 40.

In this way, in the state where the bottom part 23 rises to the temperature suitable for ironing, and the vaporization chamber 27 was heated to the temperature suitable for vaporization of water, the bimetal 58 reverses upwards, and the switchgear 57 is opening the water supply passage 29. Then, the operation unit 51 is operated to drive the water control device 50, and the water in the water tank 30 is supplied from the water supply port 53 to the vaporization chamber 27 through the water supply passage 29 to provide water vapor. Can be generated.

At this time, by supplying water to the vaporization chamber 27, the 1st combustion chamber structure which forms the vaporization chamber 27 is cooled by the heat of vaporization of water, and the 1st catalyst 19a is also upper fin 17 The temperature decreases through the. On the other hand, since the second combustion chamber structure 16 formed on the upper portion of the bottom 23 is not affected by the heat of vaporization of water, the temperature of the second catalyst 19b is maintained at a high temperature without lowering the temperature. This results in a heat storage portion inside the combustion chamber 14. Since radiation of the catalytic combustion heat generated in the second catalyst 19b heats the first catalyst 19a, even if water is supplied to the vaporization chamber 27, the temperature of the first catalyst 19a is the general activation temperature of the catalyst. It is possible to continue catalytic combustion while generating steam without lowering the phosphorus to 180 ° C or lower.

In addition, by forming the second combustion chamber structure 16 having the lower fin 18 having the second catalyst 19b on the upper surface of the bottom portion 23, heat necessary for maintaining the temperature of the bottom portion 23 is removed. It is supplied by the heat conduction from the heat of combustion of the two catalysts 19b. Therefore, even if steam is generated, the temperature of the bottom portion 23 is maintained at a high temperature suitable for ironing.

In addition, since the upper pin 17 and the lower pin 18 are displaced from each other to protrude, and are fitted with each other with a predetermined space, the first catalyst 19a and the second catalyst 19b face each other. The surface area increases, and the heat supply to the first catalyst 19a can be made favorable, and the temperature fall of the 1st combustion chamber structure 15 can be prevented.

In addition, the distance between the upper fin 17 and the lower fin 18 is set substantially evenly, and the mixed gas can be uniformly flowed in the space formed between the first catalyst 19a and the second catalyst 19b. At the same time, the contact area between the combustion gas flowing in the combustion chamber 14 and the catalyst 19 becomes large, and the mixed gas is catalytically burned in the entire region of the catalyst 19, so that the heat recovery is increased, and the upper fin 17 and the lower portion are The heat storage amount of the fin 18 becomes large and stable combustion can be continued.

Moreover, since the 1st combustion chamber structure 15 and the 2nd combustion chamber structure 16 are couple | bonded from the outer side of the catalyst 19, the heat required for vaporization of water is added to the heat of combustion of the 1st catalyst 19a, and it is 2nd. Since it is also supplied from the heat of combustion of the catalyst 19b, water vapor can be stably ejected.

In addition, since the upper fin 17 surrounded by the first catalyst 19a is integrally formed with the first combustion chamber structure 15 in which the vaporization chamber 27 is formed, heat generated in the first catalyst 19a is reduced. Since heat is transmitted to the vaporization chamber 27, the heat quantity of the vaporization chamber 27 can be increased remarkably, and the temperature suitable for generation | occurrence | production of steam can be maintained.

In this way, when the steam is blown out and the ironing is performed, when the temperature of the vaporization chamber 27 decreases to a predetermined temperature, the bimetal 58 senses the temperature of the vaporization chamber 27 and reverses it downward. By closing the water supply passage 29 by driving the switch 57, the supply of water to the vaporization chamber 27 can be stopped, and leakage from the water vapor ejection hole 56 can be prevented.

In addition, by forming the space portion 20 between the catalyst 19, the upper fin 17 and the lower fin 18, the heat dissipation characteristics from the catalyst 19 are lowered, and the catalyst 19 is in a high temperature state. Can be burned in a good activated state. Further, the downstream end portion 19d of the catalyst 19 protrudes outward from the upper fin 17 and the lower fin 18, and the ignition device 21 is provided near the flame to form a flame at the time of ignition. In this case, since the downstream end 19d of the catalyst 19 is not in contact with the upper fin 17 and the lower fin 18, it is easy to raise the temperature and reaches a temperature for transferring to the catalytic combustion in a short time. Ignition and temperature rise for a short time can be realized.

Further, the nozzles 11 can be controlled in accordance with the set temperature of the bottom 23 by projecting the upstream end 19c of the catalyst 19 outward from the upper fin 17 and the lower fin 18. Even when heat radiation by stopping the fuel gas and heating by resupply are performed, the temperature of the end portion 19c upstream of the catalyst 19 to which the fuel gas is supplied is kept high at the time of stopping the fuel gas, At the time of resupply, the stable re-ignition property can be realized, and at the time of catalytic combustion, the upstream end portion 19c at which the temperature of the catalyst 19 is the highest is higher than that of the upper fin 17 and the lower fin 18. Since it protrudes outward, the temperature of the upper pin 17 and the lower pin 18 can be made low.

Next, when the catalytic combustion is continued and used, if the temperature control device 34 breaks down and the supply of the mixed gas to the combustion chamber 14 continues, the temperature of the combustion chamber 14 rises abnormally. The abnormal temperature rise of the combustion chamber 14 is transmitted from the first combustion chamber structure 15 constituting the combustion chamber 14 to the heat sensing member 46 via the vaporization chamber lid 28. The heat sensing member 46 softens and melts when heated to a predetermined temperature, and presses and crushes the heat sensing member 46 by a force applied by the spring device 48 to raise the tubular body 47 to operate the valve. It fits into the protrusion part 40a of the sieve 40, and it raises.

Thereby, the 2nd valve body 10 is interrupted | blocked and the intake part 12 of the mixing apparatus 13 is closed by the cylindrical body 47. As shown in FIG. Therefore, the combustion of the fuel gas and the intake air from the valve device 7 are simultaneously stopped, and the catalyst combustion can be stably stopped by the shutoff device 45 without burning the iron body 1.

In addition, the temperature at which the heat sensing member 46 is pressed by the force of the spring device 48 is set to a predetermined amount higher than the temperature normally controlled, and shuts off the valve device 7 and the intake portion 12. The operating temperature of the cut-off device 45 is set so as not to be mistaken for the temperature range normally used, and is set so as to protect the iron body safely in case of abnormality.

FIG. 10 shows another embodiment of the present invention, in which a subcatalyst 60 having a lower ignition lower temperature than the catalyst 19 is provided downstream of the catalyst 19. When the heat dissipation by stopping the fuel gas and the heating by resupply are controlled by the control of the control method, even if the temperature of the catalyst 19 is lower than the optimum temperature for re-ignition at the stop of the fuel gas, the auxiliary catalyst 60 Since the lower ignition limit temperature is low, re-ignition becomes possible. When the fuel gas is re-supplied, catalytic combustion is started from the co-catalyst 60, and the catalyst 19 is heated by the co-catalyst 60 which has become hot. Catalytic combustion can be performed quickly. The cocatalyst 60 may be a catalyst having a composition different from that of the catalyst 19, and the amount of the catalyst may be increased only in the downstream portion.

In addition, by setting the temperature lowering characteristic of the cocatalyst 60 to be smaller than that of the catalyst 19, the cocatalyst 60 is kept at a low temperature even when the temperature of the catalyst 19 is lower than the minimum temperature at which the catalyst 19 can be recombined as described above. Since the deterioration characteristic is small, it is possible to maintain the temperature at which re-ignition is possible. Therefore, when the fuel gas is resupplied, the catalyst 19 can be heated by the cocatalyst 60 which has started the catalytic combustion from the cocatalyst 60 and has become a high temperature to perform catalytic combustion.

11 shows another embodiment of the present invention, in which the combustion chamber 63 is constituted by the bottom portion 61 and the vaporization chamber structure 62. According to this configuration, since the heat generated in the second catalyst 19b can be transferred directly to the bottom portion 61, the bottom portion 61 can be heated efficiently.

As described above, the catalytic combustion iron of the present invention includes an iron body having a handle, a fuel tank for storing liquefied fuel gas installed in the iron body, a nozzle for vaporizing and liquefying liquefied fuel gas in the fuel tank, A mixing device for mixing the fuel gas and air ejected from the nozzle, a catalyst for catalytically burning the mixed gas supplied from the mixing device, an ignition device for igniting the mixed gas supplied from the mixing device, and the catalyst A combustion chamber, a bottom portion heated by the heat of combustion by the catalyst, an operating member for sensing and operating the heat of combustion of the catalyst, the combustion chamber in association with the operating member and associated with the heat of combustion of the catalyst And a valve device for controlling the supply of the mixed gas to the fuel cell, the closing direction of the valve device being controlled by the pressure of the gas from the fuel tank. By setting the valve body in the direction in which the force is applied, even if the amount of catalytic combustion is increased, the temperature of the bottom portion heated by catalytic combustion can be controlled to a predetermined temperature, and at the same time, a temperature sufficient to wrinkle the clothes can be obtained, and an iron can be obtained. When the temperature in the main body rises, the pressure of the gas from the fuel tank acts in the direction of closing the valve device, so that excessive rise in temperature can be prevented and used safely.

In addition, a linkage device for transmitting a displacement of the operating member to the valve device is provided, wherein the linkage device includes a plurality of links, one end of which is fixed to the fixed shaft portion, and the other end of the link. By including a valve driving body for driving the device, a spring body for applying a force to the driving device toward the valve device, a cam body for displacing the driving support in the driving direction of the valve device, and a manual operation body connected to the cam body The direction of operation of the valve device and the direction of movement of the valve operating body for driving the valve device can be configured in parallel and at an interval, so that the opening and closing operation of the valve device can be performed to fit.

An iron body with a handle, a fuel tank for storing liquefied fuel gas installed in the iron body, a nozzle for vaporizing and releasing the liquefied fuel gas inside the fuel tank, fuel gas and air ejected from the nozzle Mixing apparatus, a catalyst for catalytically burning the mixed gas supplied from the mixing apparatus, an ignition apparatus for igniting the mixed gas supplied from the mixing apparatus, a combustion chamber incorporating the catalyst, and combustion heat by the catalyst. And a working member which senses the temperature of the heat of combustion of the catalyst and operates in response to the temperature, and which is associated with this working member and which is associated with the heat of combustion of the catalyst. And a valve device for controlling the supply of the mixed gas, and after stopping the supply of the mixed gas to the combustion chamber, the catalyst is ignited. When the valve device is driven based on the heat of combustion of the catalyst until the temperature falls to the lower limit temperature, the supply of the mixed gas to the combustion chamber is stopped by supplying the mixed gas to the combustion chamber. The catalyst combustion can be restarted at the same time as the supply of the mixed gas, and stable combustion can be continued.

An iron body with a handle, a fuel tank for storing liquefied fuel gas installed in the iron body, a nozzle for evaporating and liquefying liquefied fuel gas inside the fuel tank, fuel gas and air ejected from the nozzle Mixing apparatus, a catalyst for catalytically burning the mixed gas supplied from the mixing apparatus, an ignition apparatus for igniting the mixed gas supplied from the mixing apparatus, a combustion chamber incorporating the catalyst, and combustion heat by the catalyst. A bottom portion heated by heat, a valve device for controlling the supply of mixed gas in the combustion chamber, a heat sensing member for sensing combustion heat by the catalyst, and the heat sensing member when the heat sensing member exceeds a predetermined temperature. By providing a shutoff device for blocking the valve device and the air intake part in response to the operation of the sensing member, if the temperature of the combustion chamber Even when raised, when the heat sensing member reaches a predetermined temperature, the shutoff device is activated in response to the operation of the heat sensing member to shut off the valve device and the air intake, and to burn the iron body safely without burning the iron body. It can be realized.

An iron body with a handle, a fuel tank for storing liquefied fuel gas installed in the iron body, a nozzle for vaporizing and releasing the liquefied fuel gas inside the fuel tank, fuel gas and air ejected from the nozzle A mixing apparatus for mixing water, a water tank for storing water, a vaporization chamber for vaporizing water supplied from the water tank, a water controller for controlling supply of water from the vaporization chamber, and a supply from the mixing apparatus. A ignition device for igniting the mixed gas, a first catalyst for catalytically burning the mixed gas to heat the vaporization chamber, a second catalyst disposed close to the first catalyst, and a bottom heated by the heat of combustion by the catalyst And a combustion chamber containing the first catalyst and the second catalyst and a valve device for controlling the supply of the mixed gas to the combustion chamber, thereby heating the vaporization chamber by vaporization of water. Even if the catalyst is cooled, since the first catalyst is kept warm by the heat of combustion by the second catalyst disposed close to the first catalyst, it is possible to continuously eject water vapor without stopping the catalytic combustion during use, and at the same time to burn the catalyst. By burning, the temperature of the bottom portion is maintained at a high temperature, and furthermore, since the steam can be supplied to the clothes, the wrinkle spreading effect can be enhanced.

Further, the first catalyst and the second are provided on the inner surface side of the combustion chamber by protruding a plurality of fins along the flow direction of the mixed gas, and displacing the fins, and fitting each other with a predetermined space. The surface area which a catalyst opposes can be increased, and the heat supply suitable for a 1st catalyst can be performed.

In addition, by disposing the second combustion chamber constituent having the second catalyst on the upper surface of the bottom portion, heat necessary for maintaining the temperature of the bottom portion can be supplied by the heat conduction from the heat of combustion of the second catalyst, even when steam is ejected. The negative temperature can be maintained at a high enough temperature suitable for ironing.

In addition, by combining the second combustion chamber member with the first combustion chamber member on the outside of the second catalyst, not only the first catalyst but also the heat of combustion by the second catalyst can be used to generate steam, thereby increasing the amount of steam generated.

In addition, by projecting the first fins covered with the first catalyst toward the inner surface of the combustion chamber and forming the first fins integrally with the constituent members of the vaporization chamber, heat generated in the first catalyst is transferred to the heat conduction chamber. In order to transmit by this, the quantity of heat of a vaporization chamber is increased and water vapor can be stably ejected.

An iron body with a handle, a fuel tank for storing liquefied fuel gas installed in the iron body, a nozzle for evaporating and liquefying the liquefied fuel gas in the fuel tank, the ejection, fuel gas and air from the nozzle A mixing apparatus for mixing the mixture, a combustion chamber supplied with the mixed gas from the mixing apparatus, a fin protruding toward the inner surface of the combustion chamber, a catalyst covering the fin and disposed inside the combustion chamber, and heating by combustion heat by the catalyst. By providing a bottom portion and forming a space portion between the catalyst and the fin, the amount of heat released from the catalyst can be suppressed, and the contact area of the fuel gas can be increased, resulting in efficient combustion and improving the combustion rate of the fuel gas. You can.

Further, by protruding the fin toward the inner surface of the combustion chamber, the downstream end of the catalyst covering the fin and disposed in the combustion chamber is projected outward from the fin, and an ignition device is disposed near the downstream end of the catalyst. When the flame is formed at the time of ignition, the downstream end of the catalyst does not come into contact with the fin, so it is easy to raise the temperature, and at the time of ignition, it reaches a temperature which transitions to catalytic combustion in a short time. The temperature can be realized.

In addition, when the fin is projected toward the inner surface of the combustion chamber, the upstream end of the catalyst covering the fin and disposed in the combustion chamber is projected outward from the fin to control the nozzle according to the set temperature of the bottom part. Even if heat is released by stopping the fuel gas and heating by resupply, the temperature of the upstream end of the catalyst to which the fuel gas is supplied is kept high at the time of stopping the fuel gas, so that it is stably reignified at the time of resupply. Sex can be realized.

An iron body with a handle, a fuel tank for storing liquefied fuel gas installed in the iron body, a nozzle for vaporizing and liquefying the liquefied fuel gas inside the fuel tank, and a fuel gas and air ejected from the nozzle are mixed. A mixing apparatus, a combustion chamber to which the mixed gas is supplied from the mixing apparatus, a catalyst disposed in the combustion chamber, and a subcatalyst formed downstream of the catalyst and having a lower ignition lower temperature than the catalyst. Thus, even when the temperature of the catalyst is lower than the minimum temperature for reignition at the time of fuel gas, the cocatalyst can be reignited because the lower ignition lower limit temperature is low, so that stable combustion can be performed during control of the fuel gas supply by the nozzle. can do.

An iron body with a handle, a fuel tank for storing liquefied fuel gas installed in the iron body, a nozzle for evaporating and liquefying liquefied fuel gas inside the fuel tank, fuel gas and air ejected from the nozzle Mixing apparatus, a combustion chamber supplied with the mixed gas from the mixing apparatus, a catalyst disposed in the combustion chamber, and a subcatalyst provided at a downstream side of the catalyst and having a lower temperature drop characteristic than the catalyst. When the fuel gas is stopped, even if the temperature of the catalyst is lower than the minimum temperature at which reignition is possible, the auxiliary catalyst has a low temperature drop characteristic, so that the temperature at which recombustibility can be maintained can be maintained. In control, stable combustion can be performed.

An iron body with a handle, a fuel tank for storing liquefied fuel gas installed in the iron body, a nozzle for vaporizing and releasing the liquefied fuel gas inside the fuel tank, fuel gas and air ejected from the nozzle By means of a mixing device for mixing the mixture, a catalyst for catalytic combustion of the mixed gas supplied from the mixing device, a bottom portion heated by the heat of combustion by the catalyst, a water tank for storing water, and the heat of combustion by the catalyst. The heating chamber further includes a vaporization chamber for vaporizing water supplied from the water tank, and a combustion chamber having the catalyst therein and formed of the bottom portion and the vaporization chamber, so that heat generated from the catalyst can be directly transferred to the bottom portion. Therefore, the bottom part can be heated efficiently.

Claims (17)

An iron body with a handle, a fuel tank for storing liquefied fuel gas installed in the iron body, a nozzle for vaporizing and liquefying the liquefied fuel gas inside the fuel tank, and a fuel gas and air ejected from the nozzle are mixed. By a mixing device, a catalyst for catalytically burning the mixed gas supplied from the mixing device, an ignition device for igniting the mixed gas supplied from the mixing device, a combustion chamber incorporating the catalyst, and heat of combustion by the catalyst. Supplying the mixed gas to the combustion chamber in relation to the bottom of the heated portion, the operating member which senses the heat of combustion of the catalyst and operates in response to the heat, and which is in connection with the operating heat of the catalyst; And a valve device for controlling the valve, the valve body being forced by the pressure of the gas from the fuel tank in the closing direction of the valve device. Catalytic combustion iron set to the incense. 2. A linking apparatus according to claim 1, further comprising a linking device for transmitting a displacement of the actuating member to the valve device, wherein the linking device comprises: a driving support having a fixed end mounted to the fixed shaft portion; A link, a valve drive body which is attached to the other end of the link, and which drives the valve device, a spring body which applies the drive support to the valve device, and the drive support in the driving direction of the valve device. A catalytic combustion iron comprising: a cam body to be displaced by a; and a manual operating body connected to the chem body. An iron body with a handle, a fuel tank for storing liquefied fuel gas installed in the iron body, a nozzle for vaporizing and liquefying the liquefied fuel gas inside the fuel tank, and a fuel gas and air ejected from the nozzle are mixed. By a mixing device, a catalyst for catalytically burning the mixed gas supplied from the mixing device, an ignition device for igniting the mixed gas supplied from the mixing device, a combustion chamber incorporating the catalyst, and heat of combustion by the catalyst. The bottom portion to be heated, the operating member which senses the temperature of the heat of combustion of the catalyst and operates in response to the heat, and in association with the operating member and further, the mixed gas to the combustion chamber in relation to the heat of combustion of the catalyst And a valve device for controlling the supply, wherein the operating member stops the supply of the mixed gas to the combustion chamber, and then the catalyst is ignited. Until the road decreases, combustion catalyst, characterized in that iron is set to start the supply of the mixed gas of the heat of combustion on the basis of the catalyst drives the valve device, and the combustion chamber. An iron body with a handle, a fuel tank for storing liquefied fuel gas installed in the iron body, a nozzle for vaporizing and liquefying the liquefied fuel gas inside the fuel tank, and a fuel gas and air ejected from the nozzle are mixed. By a mixing device, a catalyst for catalytically burning the mixed gas supplied from the mixing device, an ignition device for igniting the mixed gas supplied from the mixing device, a combustion chamber incorporating the catalyst, and heat of combustion by the catalyst. A bottom portion to be heated, a valve device for controlling the supply of the mixed gas to the combustion chamber, a heat sensing member for sensing the heat of combustion by the catalyst, and the heat sensing member when the heat sensing member exceeds a predetermined temperature. And a shutoff device for shutting off the valve device and the intake portion of air in response to the operation of the member. An iron body with a handle, a fuel tank for storing liquefied fuel gas installed in the iron body, a nozzle for vaporizing and liquefying the liquefied fuel gas inside the fuel tank, and a fuel gas and air ejected from the nozzle are mixed. A mixing device, a water tank for storing water, a vaporization chamber for vaporizing water supplied from the water tank, a water control device for controlling the supply of water to the vaporization chamber, and a mixed gas supplied from the mixing device. A ignition device, a first catalyst for heating the vaporization chamber by burning the mixed gas with a catalyst, a second catalyst disposed close to the first catalyst, a bottom portion heated by combustion heat by the catalyst, and A catalytic combustion iron comprising a combustion chamber incorporating a first catalyst and a second catalyst, and a valve device for controlling the supply of a mixed gas to the combustion chamber. 6. The catalyst according to claim 5, wherein a plurality of fins are protruded along the flow direction of the mixed gas toward the inner surface of the combustion chamber, and the fins are mutually displaced and fitted together with a predetermined space. Burning iron. The catalytic combustion iron according to claim 5, wherein the second combustion chamber structure provided with the second catalyst is disposed on the upper surface of the bottom portion. 6. The catalytic combustion iron according to claim 5, wherein the second combustion chamber construct is combined with the first combustion chamber construct outward of the second catalyst. 6. The catalytic combustion iron according to claim 5, wherein the first pin covered with the first catalyst protrudes toward the inner surface of the combustion chamber and the first pin is integrally formed with the constituent members of the vaporization chamber. An iron body with a handle, a fuel tank for storing liquefied fuel gas installed in the iron body, a nozzle for vaporizing and liquefying the liquefied fuel gas inside the fuel tank, and a fuel gas and air ejected from the nozzle are mixed. A mixing apparatus, a combustion chamber supplied with the mixed gas from the mixing apparatus, a fin protruding toward the inner surface of the combustion chamber, a catalyst covering the fin and disposed inside the combustion chamber, and a bottom heated by the heat of combustion by the catalyst. And a space portion is formed between the catalyst and the fin. The method according to claim 10, wherein the fin is projected toward the inner surface of the combustion chamber, and the downstream end of the catalyst covering the fin and disposed in the combustion chamber is projected outwardly from the fin and complexed near the downstream end of the catalyst. Catalytic combustion iron, characterized in that the device is disposed. The catalytic combustion iron according to claim 10, wherein the fin is projected toward the inner surface of the combustion chamber, and the upstream end of the catalyst covering the fin and disposed inside the combustion chamber is projected outward from the fin. An iron body with a handle, a fuel tank for storing liquefied fuel gas installed in the iron body, a nozzle for vaporizing and liquefying the liquefied fuel gas inside the fuel tank, and a fuel gas and air ejected from the nozzle are mixed. A mixing apparatus, a combustion chamber supplied with the mixed gas from the mixing apparatus, a catalyst disposed in the combustion chamber, and a subcatalyst provided at a downstream side of the catalyst and having a lower ignition lower temperature than the catalyst. Catalytic combustion iron, characterized in that one. An iron body with a handle, a fuel tank for storing liquefied fuel gas installed in the iron body, a nozzle for vaporizing and liquefying the liquefied fuel gas inside the fuel tank, and a fuel gas and air ejected from the nozzle are mixed. A mixing apparatus, a combustion chamber supplied with the mixed gas from the mixing apparatus, a catalyst disposed inside the combustion chamber, and a subcatalyst provided at a downstream side of the catalyst and having a lower temperature drop characteristic than the catalyst. Catalytic combustion iron, characterized in that one. An iron body with a handle, a fuel tank for storing liquefied fuel gas installed in the iron body, a nozzle for vaporizing and liquefying the liquefied fuel gas inside the fuel tank, and a fuel gas and air ejected from the nozzle are mixed. And a catalyst for catalytically burning the mixed gas supplied from the mixer, a bottom portion heated by the heat of combustion by the catalyst, a water tank for storing water, and heat of combustion by the catalyst, And a vaporization chamber for vaporizing water supplied from the water tank, and a combustion chamber having the catalyst therein and formed of the bottom portion and the vaporization chamber. An iron body with a handle, a fuel tank for storing liquefied fuel gas installed in the iron body, a nozzle for vaporizing and liquefying the liquefied fuel gas inside the fuel tank, and a fuel gas and air ejected from the nozzle are mixed. By a mixing device, a catalyst for catalytically burning the mixed gas supplied from the mixing device, an ignition device for igniting the mixed gas supplied from the mixing device, a combustion chamber incorporating the catalyst, and heat of combustion by the catalyst. Supplying the mixed gas to the combustion heat in association with the combustion heat of the bottom portion and the operating member which senses the heat of combustion of the catalyst and operates in response to the heat; The valve device for controlling, the heat sensing member for sensing the heat of combustion of the catalyst, and the heat sensing member when the heat sensing member exceeds a predetermined temperature Iron catalyst combustion, characterized in that in response to operation of a member provided with a blocking device for blocking the valve device with the air coming from the intake portion. An iron body with a handle, a fuel tank for storing liquefied fuel gas installed in the iron body, a nozzle for vaporizing and liquefying the liquefied fuel gas inside the fuel tank, and a fuel gas and air ejected from the nozzle are mixed. To a mixing device, a water tank for storing water, a vaporization chamber for vaporizing water supplied from the water tank, a water control device for controlling the supply of water to the vaporization chamber, and a mixed gas supplied from the mixing device. An ignition device for ignition, a first catalyst for catalytically burning the mixed gas to heat the vaporization chamber, a second catalyst disposed close to the first catalyst, a bottom portion heated by the heat of combustion by the catalyst, and A combustion chamber incorporating a first catalyst and a second catalyst, an operating member which senses the heat of combustion of the catalyst and operates in response to the heat; The catalytic combustion iron provided with the valve apparatus which controls the supply of the mixed gas to the said heat of combustion.