JP3220613U - Thermal energy generation module - Google Patents

Abstract

[PROBLEMS] To generate a large amount of thermal energy so that the mist-like fuel is not completely burned to generate harmful exhaust gas, effectively improving the conversion efficiency of the fuel into thermal energy, and low energy Provided is a thermal energy generation module that can generate high thermal energy by consumption and has advantages of energy saving and environmental conservation.
A body includes a main body, a fuel supply line, a catalytic converter for auxiliary combustion, and a heating unit. The main body is provided in a first chamber and on one side of the first chamber, and the first chamber. A second chamber 30 communicating with the first chamber 10, and the fuel supply line 20 is connected to one side of the first chamber 10 away from the second chamber 30 to supply the mist fuel to the first chamber 10. Supplying to the first chamber 10, the auxiliary combustion catalytic converter 40 is provided in the second chamber 30, and the heating unit 50 is provided in the main body 100 to operate necessary for the auxiliary combustion catalytic converter 40. Heat until the temperature rises.
[Selection] Figure 1

Description

  The present invention relates to a heating module, and more particularly to a high-performance heating module that generates thermal energy by accelerating an oxidation reaction of atomized fuel by a catalytic reaction.

  The conventional heating method that provides thermal energy by burning fuel needs to consume a large amount of fuel, the conversion efficiency of fuel into thermal energy is poor, high temperature cannot be generated quickly, and Due to incomplete combustion, harmful exhaust gas is easily released and environmental pollution is likely to occur. Therefore, energy-saving and environment-friendly heating methods are an important research subject.

  In the conventional fuel combustion system, the conversion efficiency of fuel into thermal energy is poor, and harmful exhaust gas is likely to be generated. The main purpose of the present invention is to oxidize atomized fuel using catalytic reaction. Is to provide a thermal energy generation module that generates high thermal energy without exhaust gas being discharged.

In order to achieve the above object, the thermal energy generation module according to the present invention is:
A main body including a first chamber and a second chamber provided on one side of the first chamber and communicating with the first chamber and having an exhaust port formed on one side away from the first chamber; ,
A fuel supply line having a conical shape connected to one side of the first chamber away from the second chamber and having a connection port with the first chamber increasing to the fuel supply line;
A catalyst converter for auxiliary combustion provided in the second chamber and coated with an auxiliary catalyst on the surface;
A heating unit provided in the main body.

  By the technical means described above, the thermal energy generator of the present invention is heated by the heating unit until the initial operating temperature (about 50 ° C. or higher) of the catalytic converter for auxiliary combustion is reached, and the auxiliary combustion gas and, for example, methanol are supplied via the fuel supply pipe. When the atomized fuel enters the second chamber and comes into contact with the catalytic converter for auxiliary combustion, it is catalyzed by the auxiliary catalytic converter and oxidized. Performs a reduction reaction, generates a large amount of heat energy, quickly rises to a temperature of 600 ° C. or higher, and can reach a high temperature of 800 ° C. Therefore, high heat energy for heating can be quickly supplied. In addition, the atomized fuel is completely oxidized by the catalytic action, the generation of harmful exhaust gas is suppressed, the conversion efficiency of the fuel into thermal energy is improved, and the low energy It is possible to generate a high heat energy Energy consumption has the advantage of energy saving and environmental protection.

1 is a perspective external view of a preferred embodiment of the present invention. 1 is a cross-sectional side view of a preferred embodiment of the present invention. FIG. 5 is another side cross-sectional view of a preferred embodiment of the present invention. It is side surface sectional drawing of the pipe | tube heating apparatus applied to the suitable Example of this invention. It is another side sectional drawing of the pipe | tube heating apparatus applied to the suitable Example of this invention. 1 is a perspective external view of a pipe heating device applied to a preferred embodiment of the present invention.

  In order to understand the technical features and practical effects of the present invention in detail and to realize them in accordance with the contents of the specification, the preferred embodiments shown in the drawings will be described in detail below.

  As shown in FIGS. 1 to 3, the thermal energy generation module according to the present invention includes a main body 100, a fuel supply pipe 20, an auxiliary combustion catalytic converter 40, and a heating unit 50.

  The main body 100 includes a first chamber 10 and a second chamber 30, and the first chamber 10 has a conical shape with the bottom portion gradually increasing upward, and the top is open. The side wall of the first chamber 10 is provided with at least one hole 11 for communication with external air and heat dissipation, and the second chamber 30 is located above the first chamber 10 and has a bottom end. Is communicated with the first chamber 10, and an exhaust port is formed at the top. Preferably, a partition plate 13 is provided between the first chamber 10 and the second chamber 30, and the partition plate 13 Is provided with a through-hole 131 that allows the first chamber 10 and the second chamber 30 to communicate with each other.

  The fuel supply line 20 is connected to the bottom of the first chamber 10, supplies atomized fuel such as atomized methanol, gasoline, diesel, volatile organic solvent, etc., mixes auxiliary combustion gas, and particles A mist-shaped fuel having a diameter of 0.5 micron (μm) to 1250 microns (μm) may be directly supplied. In the fuel supply line 20, an atomized fuel is sprayed by an ultrasonic spray nozzle or a spray based on the Venturi tube principle. Fuel may be generated. In this embodiment, the fuel supply line 20 includes a fuel channel 21 and an air channel 23 that are in communication with each other, and the fuel channel 21 is connected to a fuel supply unit, such as methanol, gasoline, diesel, and volatile. Supply fuel stock solutions such as organic solvents. The air channel 23 is used to supply auxiliary combustion gas, and is connected to a pump 60 to mix and spray the fuel stock solution and auxiliary combustion gas in the fuel supply line 20 to obtain a particle size of 0.5 microns. (Μm) -1250 micron (μm) of atomized fuel is formed, and a large amount of auxiliary combustion gas is mixed into the atomized fuel and introduced into the first chamber 10 from the conical seam at the bottom of the first chamber 10. When the atomized fuel enters the first chamber 10, a pressure difference is generated. Thus, the auxiliary combustion gas flows into the second chamber 30 after being uniformly mixed with a large amount of auxiliary combustion gas in the first chamber 10.

The auxiliary combustion catalytic converter 40 is provided in the second chamber 30 and is a porous solid structure. The auxiliary combustion catalytic converter 40 has a large surface area, and the surface is coated with the auxiliary combustion catalyst. The temperature is the operating temperature of the auxiliary combustion catalyst. At about 50 ° C., the auxiliary combustion catalyst reacts with the atomized fuel to generate a strong oxidation-reduction reaction in the atomized fuel, thereby generating carbon dioxide CO ₂ and water vapor H ₂ O, and thermal energy. Is generated.

  The heating unit 50 is provided in the main body 100 and heats the main body 100 to raise the temperature, thereby bringing the inside to the operating temperature of the catalytic converter 40 for auxiliary combustion. The heating method of the heating unit 50 may be heating by an electric heating tube, ignition heating, hot air heating, or the like. In the present embodiment, the heating unit 50 includes an igniter 51 and a heater 53, and the igniter 51 is connected to the first chamber 10, generates a spark, and ignites the atomized fuel in the first chamber 10. The plug may be a plug, whereby the mist fuel burns in the first chamber 10 to generate heat, and the inside of the main body 100 is set to the operating temperature of the catalytic converter 40 for auxiliary combustion. The heater 53 is provided on the outer periphery near the bottom of the catalytic converter 40 for auxiliary combustion, and raises the internal temperature of the main body 100 by direct heating.

  The thermal energy generation module according to the present invention can be used in devices such as water heating, kerosene heating, air heating, and water vapor production. 4 to 6 show a pipe heating device applied to the thermal energy generating module according to the present invention. The pipe heating device includes a heating pipe 80 and a cover 70, and the heating pipe The path 80 surrounds the outer periphery of the thermal energy generating module according to the present invention and has a spiral shape that turns upward, and a liquid or gaseous object to be heated such as water, gas, oil, or the like from the inlet end 81 at the bottom. And the object to be heated is swung upward on the outer periphery of the thermal energy generation module according to the present invention along the heating pipe 80 and discharged from the discharge end 83 at the top of the heating pipe 80. The cover 70 is provided on the outer periphery of the heating line 80, the top is sealed and the bottom end is open, and thus heat energy is directly dissipated from the top of the cover 70. There is no.

In use, first, the mist fuel in the first chamber 10 is ignited by the igniter 51, the mist fuel burns in the first chamber 10 to generate thermal energy, and the operating temperature of the auxiliary combustion catalytic converter 40 is obtained. Since the atomized fuel generates a flame retardant gas such as carbon dioxide CO ₂ in the first chamber 10 after the combustion to extinguish the open flame, the atomized fuel that is not completely burned together with the thermal energy It enters into the second chamber 30 and again undergoes a redox reaction by the auxiliary combustion catalytic converter 40 to generate carbon dioxide CO ₂ , steam H ₂ O and thermal energy, and then the atomized fuel is continuously supplied. Then, the oxidation-reduction reaction is performed by the catalyst of the auxiliary combustion catalytic converter 40 to generate a large amount of heat energy, so that the temperature is 600 ° C. or higher, and the maximum is 850 ° C. within a short time (5 to 10 minutes). The heat energy and gas generated by the catalyst of the auxiliary combustion catalytic converter 40 flow upward from the top opening of the second chamber 30 to raise the temperature in the cover 70 and heat the pipe 80. For this reason, when an object to be heated flows in the heating pipe 80, a large amount of heat energy and high temperature heating thereby are applied, so that water, gas, and oil in the heating pipe 80 are rapidly heated. obtain.

  The thermal energy generating module according to the present invention is directly heated by the electric heater 53 until the operating temperature of the auxiliary combustion catalytic converter 40 is reached, and then the atomized fuel is continuously supplied and oxidized by the catalyst of the auxiliary catalytic converter 40. A reduction reaction may be performed to generate a large amount of thermal energy. In such a case, continuous heating can be realized without requiring ignition.

In another embodiment, the first chamber 10 and the second chamber 30 of the main body 100 may be connected laterally, and the second chamber 30 is connected to one side of the first chamber 10. And an exhaust port is formed on one side of the second chamber 30 away from the first chamber 10, and the exhaust port is separated from the first chamber 10. The fuel supply line 20 may be located on an end wall or a side wall, and the fuel supply line 20 is connected to one side of the first chamber 10 away from the second chamber 30, and the atomized fuel is discharged from the first chamber 10. It flows into the second chamber 30 in the lateral direction, reacts with the catalytic converter 40 for auxiliary combustion, generates thermal energy, carbon dioxide CO ₂ and water vapor H ₂ O, and discharges it from the exhaust port.

  The thermal energy generation module according to the present invention has the following beneficial effects.

  1. Atomizing fuel is catalyzed by the catalytic converter 40 for auxiliary combustion to cause an oxidation-reduction reaction so that the atomized fuel is completely oxidized in the second chamber 30 to prevent harmful exhaust gas emission and reduce environmental pollution. Let

  2. Since the operation start temperature of the catalytic converter 40 for auxiliary combustion is low, if it is about 50 ° C. or more, it reacts with the mist fuel and catalyzes the mist fuel to cause an oxidation-reduction reaction to generate a large amount of thermal energy. Therefore, by providing low initial thermal energy, it can react quickly and continuously to generate a large amount of high thermal energy, thereby effectively improving the conversion efficiency of fuel into thermal energy. High heat energy can be generated with low energy consumption.

  3. High thermal energy can be supplied using a small amount of fuel stock solution. When the fuel stock solution is 240 milliliters (ml), the thermal reaction of the thermal energy generating module according to the present invention is maintained for about 1 hour when sprayed. In addition, since a high temperature of 650 ° C. or higher can be realized, there are advantages of energy saving and environmental conservation.

  4). Since the thermal energy generation module according to the present invention adopts a modular design, the thermal energy generation module has a scale-up property, and a plurality of thermal energy generation modules are connected in parallel to the fuel supply unit, so that each thermal energy generation module is Can be heated and reacted at the same time to generate heat energy, thereby increasing the heating efficiency.

  5. Since the joint connecting the first chamber 10 and the fuel supply pipe 20 has a conical shape increasing in a direction away from the fuel supply pipe 20, when the atomized fuel enters the first chamber 10, Before flowing into the two chambers 30 and reacting with the auxiliary combustion catalytic converter 40, a large amount of auxiliary combustion gas is uniformly mixed in the first chamber 10 due to the pressure difference, thus increasing the efficiency of the catalyst heating reaction of the atomized fuel. In addition, the atomized fuel is continuously catalyzed to perform a heating reaction, the volume of the main body 100 is reduced, the necessary use space is reduced, the generated heat energy is concentrated, and the volume of the entire main body 100 is increased. Is about 0.064 cubic meters.

  6). The thermal energy generation module according to the present invention is used in a heating device, and can quickly provide high thermal energy for heating.

  The above is only a preferred embodiment of the present invention, and does not limit the present invention in any way. Those skilled in the art will be able to disclose the present invention without departing from the scope of the technical features of the present invention. Equivalent embodiments in which partial changes or modifications are made based on the technical contents also belong to the scope of the technical features of the present invention without departing from the contents of the technical proposal of the present invention.

DESCRIPTION OF SYMBOLS 100 Main body 10 1st chamber 11 Hole 13 Partition plate 131 Through-hole 20 Fuel supply conduit 21 Fuel channel 23 Air channel 30 Second chamber 40 Auxiliary catalytic converter 50 Heating unit 51 Igniter 53 Heater 60 Pump 70 Cover 80 Heating conduit 81 Inlet end 83 Output end

Claims (7)

A thermal energy generation module,
A main body including a first chamber and a second chamber provided on one side of the first chamber and communicating with the first chamber and having an exhaust port formed on one side away from the first chamber; ,
A fuel supply line connected to one side of the first chamber away from the second chamber and having a conical shape with a connection port with the first chamber increasing to the fuel supply line;
A catalyst converter for auxiliary combustion provided in the second chamber and coated with an auxiliary catalyst on the surface;
And a heating unit provided in the main body.   The thermal energy generation module according to claim 1, wherein the fuel supply line includes a fuel channel and an air channel communicating with each other.   The thermal energy generation module according to claim 2, wherein at least one hole is provided in a side wall of the first chamber.   The thermal energy generation module according to any one of claims 1 to 3, wherein the heating unit includes an igniter connected to the first chamber.   The thermal energy generation module according to any one of claims 1 to 3, wherein the heating unit includes a heater provided on an outer periphery near the bottom of the catalytic converter for auxiliary combustion.   The thermal energy generation module according to claim 4, wherein the heating unit includes a heater provided on the outer periphery near the bottom of the auxiliary catalytic converter.   The thermal energy generation according to claim 6, wherein a partition plate is provided between the first chamber and the second chamber, and the partition plate has a through-hole that communicates the first chamber with the second chamber. module.

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