KR20020027876A - A gas burner combustion apparatus using metal oxidization catalyst - Google Patents

Abstract

PURPOSE: A combustion system of a gas burner is provided to improve safety against fire, to use a low-density gas fuel, and to achieve non-flame low temperature combustion by using metal oxide catalyst. CONSTITUTION: A combustion system includes an air supplying pipe(111) connected to an air supplying line(110) for supplying air. A fuel supplying pipe(121) is connected to a fuel supplying line(120) for supplying gas. A mixer(130) is provided to mix air supplied through the air supplying pipe(111) with the fuel supplied through the fuel supplying pipe(121). An air-fuel mixing pipe(131) is provided to supply the mixing fuel mixed in the mixer(130) into a gas burner(160). The gas burner(160) burns the mixing fuel supplied through the air-fuel mixing pipe(131). A heat collecting shielding plate(133) is installed at a lateral portion of the gas burner(160) so as to collect the radiation energy, such as a far-infrared ray generated from the gas burner(160).

Description

A gas burner combustion apparatus using metal oxidization catalyst

The present invention is a gas burner combustion device using a metal oxide catalyst, high fire safety, using a low concentration of gas fuel, enabling low-temperature flameless combustion and a combustion device using a catalytic device for radiant heat transfer. The present invention relates to a gas burner combustion apparatus using a metal oxide catalyst using a catalyst material in which platinum Pt, paradium, and rhodium are deposited on steel.

In general, catalytic combustion is adsorbed on the surface of the catalyst by fuel gas diffusion, and oxidation reaction occurs on the surface of the catalyst, so that the generated gas is diffused on the surface of the catalyst and desorbed. It is burned without flame. In other words, it uses a solid catalyst to oxidize fuel at relatively low or low concentrations, which is essentially flameless combustion, and when burning flames at low temperatures while significantly reducing NOx and carbon monoxide production. It is using the energy that appears.

New combustion has been developed in consideration of emission control, energy efficiency and safety of pollutants. As one of new combustion methods to satisfy these requirements, catalytic combustion that performs surface reaction by applying catalyst to combustion reactor Has been required.

1 is a forced convection-diffusion combustion apparatus using a conventional catalytic apparatus.

1 is a catalytic combustion apparatus using conventional catalytic reactions to prevent contaminants such as nitrogen oxides (NOx) and carbon monoxide, and to reduce the damage caused by the combustion of flames. Can be applied to airless process in air diffusion catalytic combustor, and it is possible to obtain the useful far-infrared radiation effect below 300 ℃ by forcibly activating the reaction of catalytic combustion through catalytic combustor. It is a forced convection-diffusion combustor using a catalytic device.

The technical configuration for achieving the above object is as follows. The catalytic combustor 1 is provided with a main body of the fuel supply unit 10 and the air supply unit 20 which are largely divided into the combustion unit 30 so as to supply air at room temperature and gas which is fuel.

The fuel supply unit 10 is provided with a first solenoid 11 for controlling the supply of fuel from the control panel 2 in the fuel supply pipe 10a for supplying fuel to the catalytic combustor 1, and the first A fuel flowmeter 12 for measuring the amount of gas to be supplied is connected to the fuel supply pipe 10a on the solenoid 11 side, and the fuel supply pipe 10a on the fuel flowmeter 12 side controls the amount of fuel. A fuel control valve is installed, an air control valve 24 for adjusting the amount of air is installed in the air supply pipe 20a of the air flow measurement, and one end of the air supply pipe 20a is equipped with a catalytic combustor 1 An air distributor 25 is provided for uniformly dispersing air from the lower side.

The combustion unit 30 includes a heating layer for initially supplying heat required for catalytic combustion from the air distributor 25 and the fuel distributor 14 installed to be connected to the fuel supply unit 10 and the air supply unit 20. The heating wire having a 31 is installed, the lower side of the heating wire 31 is made of a heat insulating material and a thermostat for automatically cutting the heating wire 31 during the catalytic reaction is installed, the catalyst layer having a predetermined thickness on the front of the heating wire Is installed in close contact.

A gas analyzer 40 having a thermocouple 41 for measuring the temperature of the catalyst layer 33 is installed at the center of the front surface of the catalyst layer 33.

In addition, the catalyst layer is used by supporting a rhodium catalyst on an aluminum mat having a large specific surface area and heat resistance.

The present invention relates to a gas burner combustion apparatus using a metal oxide catalyst, which is connected to an air supply line and supplies air, a fuel supply pipe connected to an air supply fuel supply line and supplying fuel, and an air supply pipe. A mixer for mixing the air supplied through the fuel and the fuel supplied through the fuel supply pipe, an air mixed fuel pipe for supplying the air mixed fuel mixed in the mixer to the gas burner, the air mixed fuel supplied through the air mixed fuel pipe It is composed of a gas burner that burns the gas burner, and provides a gas burner combustion apparatus using a metal oxide catalyst which has high fire safety, uses a low concentration of gas fuel, and radiates heat transfer such as far-infrared rays generated by enabling low-temperature flameless combustion. .

The mixer includes a screw or amorphous spring inside the mixer as a means for reversing the path of the air supplied through the air supply pipe and the fuel supplied through the fuel supply pipe to completely mix air and fuel.

The gas burner includes a support for radiating heat burned by a metal oxidation catalyst that generates uncatalyzed activation energy, a protection net installed under the support to protect the metal oxidation catalyst, and conduction of heat generated from the metal oxidation catalyst. A band-shaped rectangular heat shield means having a predetermined thickness installed under the protection net, a metal oxidation catalyst installed under the heat shield means, and installed at a predetermined interval under the metal oxidation catalyst, through the air mixed fuel pipe. A preheating heater having a heating layer for supplying heat required for initial combustion of the supplied fuel, and surrounding the preheating heater in a honeycomb form so as to cover the metal oxidation catalyst underneath to burn the fuel combusted in the metal oxidation catalyst. Honeycomb-type diffusion network that serves to diffuse, and the bottom mounted under the diffusion network Comprising the housing, the air mixed fuel supplied through the air mixed fuel pipe is sealed.

Automatic preheating and blocking the gas burner through the preheating heater, and installed in the fuel supply pipe to control the fuel supply amount according to the temperature sensed by the temperature sensor installed in the gas burner. An automatic control unit for controlling the fuel control valve is provided. The air supply pipe is provided with an air control valve for properly adjusting the ratio of air.

The metal oxide catalyst of the gas burner is a deposition of platinum Pt, paradium or rhodium on stainless steel having excellent durability.

1 is a forced convection-diffusion combustion apparatus using a conventional catalytic apparatus.

2 is a gas burner combustion apparatus using a metal oxide catalyst according to the present invention.

3A is a cross-sectional view of an example of a structure of a gas burner viewed from the air mixed fuel pipe of FIG.

3 (b) schematically shows each component of FIG. 3 (a).

4 shows a sectional view of an example of the mixer according to FIG. 2.

Embodiments of the present invention will be described in detail as follows with reference to the drawings.

2 is a gas burner combustion apparatus using a metal oxide catalyst according to the present invention.

It is connected to the air supply line 110, the air supply pipe 111 for supplying air, the fuel supply pipe 121 is connected to the fuel supply line 120 for supplying gas and supply the fuel, the air supply pipe 111 Mixer 130 for mixing the air supplied through the fuel supplied through the fuel supply pipe 121, the air mixed fuel pipe 131 for supplying the air mixed fuel mixed in the mixer 130 to the gas burner, It has a structure including a gas burner 160 for burning the air mixed fuel supplied through the air mixed fuel pipe (131). In addition, a heat shield plate 133, which serves to collect radiant energy such as far infrared rays emitted from the gas burner 160, is installed on the side surface of the gas burner 160.

3A is a cross-sectional view of an example of a structure of a gas burner viewed from the air mixed fuel pipe of FIG.

3B schematically shows each component of FIG. 3A.

The mixer 130 changes the path of the air supplied through the air supply pipe 111 and the fuel supplied through the fuel supply pipe 121 to form a mixture of air and fuel to form an amorphous spring, screw, and force. A mixing fan or the like may be used, but here, the screw 135 is provided inside the mixer 130 in consideration of simplicity and cost. At this time, air and fuel are mixed with the skews 135 to cause a change in the path.

The gas burner 160 is a support 161 for radiating the heat burned by the metal oxidation catalyst that generates the uncatalyzed activation energy, a protection net installed under the support 161 and protecting the metal oxidation catalyst 164 ( 162, a strip-shaped rectangular asbestos packing 163 having a predetermined thickness as a heat shielding means installed under the protection net 162 to block the heat generated from the metal oxide catalyst 164, the asbestos packing The metal oxide catalyst 164 installed under 163 and the metal oxide catalyst 164 are installed at predetermined intervals under the metal oxide catalyst 164 and heat necessary for initial combustion of the fuel supplied through the air mixed fuel pipe 131. Preheat heater 165 having a heating layer for supply, the fuel combusted in the metal oxidation catalyst 164 surrounding the preheating heater 165 in a honeycomb form to cover the metal oxidation catalyst 164 from below A honeycomb diffusion network 166 serves to diffuse the structure, and a housing 170 mounted under the diffusion network, the air mixture fuel supplied through the air mixed fuel pipe 131 is sealed structure It becomes

Pre-heat and shut off the gas burner 160 through the preheating heater 165 and control the fuel supply amount according to the temperature sensed by the temperature sensor 150 installed in the gas burner 160. Automatic control unit 140 made of a micro computer composed of a microprocessor (processor) installed in the supply pipe 121 and performs a specific application for the control of the automatic fuel control valve 125 that can automatically adjust the fuel cost ) Is provided. The air supply pipe 111 is provided with an air control valve 115 for adjusting the ratio of air.

4 shows a sectional view of an example of the mixer according to FIG. 2.

The metal oxide catalyst 164 of the gas burner 160 is formed by depositing platinum Pt, paradium, or rhodium on stainless steel having excellent durability. Since the metal oxide catalyst of the present invention has excellent durability compared to catalysts using metals such as ceramics and aluminum, the metal oxide catalyst can not only significantly reduce costs due to maintenance, but also excellent in terms of safety.

Gas burner combustion apparatus using a metal oxide catalyst has a high fire safety, low concentration of gas fuel and flameless low-temperature combustion enables radiant heat transfer of generated energy such as far-infrared rays, high thermal efficiency, and activation of uncatalytic reaction. It is possible to provide a gas burner combustion device using a metal oxide catalyst having excellent durability by using a metal oxide catalyst that causes an increase.

Claims (6)

Through the air supply pipe for supplying air, the fuel supply pipe for supplying fuel, the mixer for mixing the supplied air and fuel, the air mixed fuel pipe for supplying the air mixed fuel mixed in the mixer to the gas burner, through the air mixed fuel pipe Preheat and shut off the gas burner through the gas burner and the preheating heater which burns the supplied air mixed fuel, and adjust the amount of fuel according to the temperature detected by the temperature sensor installed in the gas burner. In the gas burner combustion apparatus consisting of an automatic control unit for controlling the automatic fuel control valve is installed, the air control valve is installed in the air supply pipe to adjust the amount of air, The mixer is provided with means for thorough mixing of air and fuel by redirecting the air and fuel supplied through the air supply and fuel supply lines, The gas burner is a support for radiating heat burned by the metal oxidation catalyst, a protection net installed under the support to protect the metal oxidation catalyst, and installed under the protection net to block conduction of heat generated from the metal oxidation catalyst. A heat shield means, the metal oxide catalyst installed under the heat shield means, a diffusion network serving to diffuse fuel combusted by the metal oxide catalyst, and a housing mounted to the diffusion network, Gas burner combustion apparatus using a metal oxidation catalyst, characterized in that the preheating heater is installed under a predetermined interval under the metal oxidation catalyst. The method of claim 1, Gas burner combustion apparatus using a metal oxide catalyst, characterized in that the mixer is provided with a screw or an amorphous spring as a means for mixing air and fuel. The method of claim 1, Gas burner combustion apparatus using a metal oxide catalyst, characterized in that the thermal barrier means under the protective net is asbestos packing. The method according to any one of claims 1 to 3, Gas burner combustion apparatus using a metal oxide catalyst, characterized in that the diffusion network surrounds the heater for preheating. The method of claim 4, wherein The metal oxide catalyst of the gas burner is a gas burner combustion apparatus using a metal oxide catalyst, characterized in that platinum, palladium or rhodium is deposited on stainless steel. The method according to any one of claims 1 to 3, The metal oxide catalyst of the gas burner is a gas burner combustion apparatus using a metal oxide catalyst, characterized in that platinum, palladium or rhodium is deposited on stainless steel.