KR100891491B1 - Generating System using Catalytic heater - Google Patents

Abstract

The present invention is a portable ceramic platinum, platinum / ruthenium, platinum / palladium catalyst (spherical and pellet type) or metal platinum catalyst mesh, metal platinum catalyst honeycomb, that is, collectively combines a catalytic heater and a thermoelectric power generation module (Themoelectric power generation module) It is characterized by consisting of a three-dimensional structure of the generator. The portable power supply and the generator according to the present invention can be operated for a long time and can secure the power required for portable, emergency, military, agricultural and household power supply, does not require electricity during initial operation, and generally primary battery And compared to the rechargeable secondary battery has the advantage that can be used infinitely only by the fuel supply. It also has no noise and is not explosive compared to batteries.

Non-combustion non-ignition, catalytic heater, thermoelectric element, Ziebeck effect, power generation system

Description

Generating System Using Catalytic Heater

1 is a perspective view showing a power generation system using a non-combusted non-ignition catalytic heater according to the present invention.

Figure 2 is an exploded perspective view showing a power generation system using a non-burning non-ignition catalytic heater according to the present invention.

3 is a perspective view showing a thermoelectric element.

Figure 4 is a state of use of the power generation system using a non-combustion non-ignition catalytic heater according to the present invention.

<Description of the symbols for the main parts of the drawings>

10: fuel container 11: fuel inlet

20: catalytic heater heating unit 30: thermoelectric element

31: metal plate 40: thermoelectric contact surface

50: cooler 51: heat sink

51a: pin 52: cooling fan

60: voltmeter 70: thermometer

The present invention relates to a power generation system using a non-combustible non-ignition catalyst heater that generates heat by a catalyst using methanol fuel, which is a liquid fuel, and a non-combustion non-ignition catalyst heater that generates direct current electricity using a thermoelectric element.

As the use of energy increases rapidly due to the development of the current industry, active alternatives to future energy depletion, such as effective use of alternative energy, are required. In addition, power generation through fossil energy is gradually being exhausted due to increasing demand. In the aftermath, it may cause serious problems that have a big impact on oil prices and the economy. In order to meet these demands, many advanced countries such as the United States and Japan have been actively researching and developing alternative energy. Looking at the prior art, the thermoelectric effect (thermoelectric effect), which refers to the conversion of thermal energy and electrical energy, is a phenomenon in which an electromotive force is generated by moving a carrier inside the device while a temperature difference occurs between the conversion elements. This phenomenon has been studied since the early 1900s, and the conversion efficiency is about 10% or more. The Seebeck Effect is used to obtain the electromotive force, and the cooling and heating with the electromotive force is the Peltier Effect, and the electromotive force generated by the temperature difference on the conductor line can be obtained by the Thompson Effect.

The Peltier effect is a positively charged cell in which electrons absorbing ambient heat energy are transferred to the inside of the thermoelectric semiconductor by applying a direct current to an np type device and absorbing the surrounding thermal energy from the negatively charged metal / semiconductor contact. At the contacts, heat is generated by the release of thermal energy from electrons. The field using these effects is applied to various fields such as semiconductor manufacturing, medical, communication, and electronic fields. In the Seebeck effect, if a constant temperature difference is maintained across a circuit to which all semiconductors are connected, a potential difference occurs between the contacts due to the movement of electrons including thermal energy to generate electricity. The development of thermoelectric generators using these is being actively conducted, and it is used for power supply for portable devices and portable generators.

In terms of research trends at home and abroad, the most advanced fields of system technology using thermoelectric devices are space, aviation, military, biological, and electronics. Specifically, it is as follows.

Usage subject Autumn still life Dehumidifier, cold / hot water purifier, vending machine, vehicle refrigerator, functional cosmetic storage box, etc. Industrial Machine Tool Substrate Cooling, Distribution Board Cooler, Calorimeter, Semiconductor Equipment, etc. Anti-aircraft Black box chiller, avionics cooler, heat controller Universe Dragon Generator, heater, cooler etc Military use Infrared detector, missile guidance circuit cooler, laser observation equipment, etc. For research Various test equipment, thermostat, constant temperature heater, cooling equipment Medical equipment Thermostat, blood storage device, heating device cooling etc.

Most of the countries where research is being actively conducted, such as the United States, Japan, and Russia, are conducted in advanced countries of technology development. In the U.S., research is being actively conducted on thermoelectric devices at DOE, NASA, Hi-Z, SERI, Global, GE, Teledyne, Ohio and Utah State University. In the case of Japan, research on thermoelectric cooling is mainly carried out at Northeast University, Tokyo University, Daepan University, Yamaguchi University, and Jeon Joong-yeon. In Korea, KIST has accumulated material technology for 10 years and has been active in cooling materials. Recently, many researches including the Electric Research Institute, Yonsei University, Yeungnam University, Chungnam University, Korea University, Korea Electronics, Energy Research Institute, etc. We have accumulated a lot of know-how in the field of constant temperature and humidity, medical field, and thermal power generation. The thermoelectric material is different depending on the temperature range, the Bi-Ti system is excellent below about 200 ℃, Pb-Tb system is used up to about 500 ℃, Si-Ge system is known to have the best performance above this temperature. It is affected by the heat transfer characteristics of the peripheral connection used according to the thermoelectric efficiency coefficient and shows the difference in performance depending on the smoothness, roughness, and pressing force of the joint. Thermoelectric power generation is a system that can obtain electricity by using the temperature difference. It can use natural energy such as solar heat and geothermal heat, fossil fuel heating energy, urban arrangement and industrial waste heat as energy sources. Thermoelectric power generation uses geothermal, solar, seawater temperature difference, fuel cell, array cell, array gas, passenger car, reactor, gas, and power system as heat sources.The research of this part is OTEC (Ocean thermal energy conversion), FTG (Fueled thermoelectric) Generators, RTG (Radioisotope thermoelectric generator), NTG (Nuclear thermoelectric generator) are progressing. The characteristics of thermoelectric power generation can be generated even under 150 ℃ heat, which is considered to have no recovery value, and a thermoelectric power generation system can be constructed that uses industrial exhaust and waste heat as fuel. Can be. Advantages of thermoelectric power generation are simple configuration, little noise during operation, and high reliability. It is easy to maintain the equipment and the number of devices can be adjusted to use from large output to low output. Domestic and overseas research activities on thermoelectric materials are actively underway, and future application fields are expected to expand further. In addition, the field using thermoelectric materials can be applied to various fields such as heat and cooling systems, power plants. Thermal power plant has the advantages of simple configuration, no noise, high reliability, easy maintenance, and easy change depending on the use of low and high power.

The generator is a device that is manufactured for waste heat recovery power generation and is a technology for generating power through the Seebeck Effect of thermoelectric devices. Here, the waste heat is a method of generating direct current electricity to a power generator by using heat that is wasted from an existing heating device or a heat source of an industrial production plant. This technology is applied in the United States, Japan, Russia, Korea, and Europe by using existing heat sources in a fixed state. This prior art has been a method of utilizing waste heat in systems that artificially require a heat source.

Thermoelectric power plant is a thermocouple (many kinds, but generally linear conductive material) that joins one end of P-type semiconductor and N-type semiconductor with metal plate. There is a negative electric charge of the type, which is the thermoelectric element using this function.

In the prior art, a generator of 5W to several KW has been put into practical use using propane gas or gasoline, coal, etc. as a heat source for heating. Conventionally, since the fossil fuel is used as a heat source for heating, there is a problem that soot or air pollutant is generated after combustion. In addition, there is a problem that the device is large, the structure is complicated, equipment costs a lot, and can not be manufactured by portable.

The present invention is to solve the above-mentioned conventional problems, the object of the present invention is a non-combustion non-ignition type catalyst that is simple in structure and can be manufactured in a small size, to prevent noise and to not generate air pollution after combustion. It is to provide a power generation system using a heater.

In addition, another object of the present invention is to provide a power generation system using a non-burning non-ignition type catalytic heater that can extend the use time according to the purpose by maintaining the power generation duration continuously.

The present invention for achieving the above object, the fuel container provided with a fuel inlet; A catalyst heater heating unit provided at an upper portion of the fuel container and coated with a metal catalyst to allow the fuel supplied from the fuel cell to generate heat by oxygen and a non-combustion catalytic chemical reaction; A thermoelectric element provided on an upper portion of the catalytic heater heating unit and generating electricity by a Ziebeck effect; A cooler provided above the thermoelectric element; Characterized in that consists of.

In addition, the catalyst of the catalytic heater heating unit of the present invention is platinum (Pt), palladium (Pd), ruthenium (Ru), vanadium (V), nickel (Ni), tungsten (W), iridium (Ir), cerium (Ce ), Any one of the catalysts selected from the combination of these metals or combinations of these metals.

In addition, the fuel of the present invention is characterized in that any one selected from hydrogen, hydride compounds, methanol, ethanol, propanol, natural gas, propane, butane.

In addition, the present invention is characterized in that the upper portion of the catalyst heater heat generating unit is provided with a heat transfer from the heat generated from the catalyst heater heat dissipation and the ceramic catalyst heating element coated with ceramic.

In addition, the present invention is characterized in that the temperature control unit for controlling the temperature of the catalytic heater heat generating unit is further provided.

In addition, a voltage converter for converting the DC voltage generated in connection with the thermoelectric element into an AC voltage is further provided.

In addition, the present invention is characterized in that the thermoelectric element between the thermoelectric element and the catalytic heater heating unit is further provided with a thermoelectric element contact surface for transferring the heat generated by the catalytic heater heating unit to the thermoelectric element.

In addition, the present invention is characterized in that the lower portion of the catalytic heater heating unit is further provided with a porous ceramic filter in contact with the fuel.

In addition, the cooler of the present invention is characterized by consisting of a heat sink provided with a fin, and a cooling fan provided on the upper portion of the fin.

In addition, the thermoelectric device of the present invention is provided with a plurality, characterized in that each thermoelectric device is connected in series or in parallel.

The present invention applies to a heat source device using a spontaneous catalytic oxidation reaction, that is, a Korean patent (10-2005-0032089), that is, a porous ceramic catalyst heater or a metal platinum catalyst mesh network that spontaneously generates heat when only fuel is supplied. It is a structure combined with the power plant. The present invention is characterized in that the conventional heat source can be portable, i. In addition, it is possible to spontaneously generate a heat source without artificially generating heat.

The technique of the present invention is based on the above-mentioned theory to supply heat to the catalytic heater using a portable or stationary heat source and the fuel used here is liquid fuel, that is, methanol. In addition, hydrogen gas can be used directly, and city gas or LPG can be used as a heat source using water introduction nitrogen.

1 is a perspective view showing a power generation system using a non-burning non-ignition catalytic heater according to the present invention, Figure 2 is an exploded perspective view showing a power generation system using a non-burning non-ignition catalytic heater according to the present invention, Figure 3 is a thermoelectric element 4 is a perspective view of a power generation system using a non-combusted non-ignition catalytic heater according to the present invention.

As shown, the power generation system using a non-combustion non-ignition type catalytic heater according to the present invention includes a fuel container (10) having a fuel inlet (11); A catalytic heater heating unit 20 for generating fuel generated from the fuel container 10; A thermoelectric element 30 disposed above the catalytic heater heat generating unit 20; A cooler 50 provided on the thermoelectric element 30; It consists of.

The fuel container 10 is provided with a fuel inlet 11, and accommodates a fuel selected from hydrogen, hydride compounds, methanol, ethanol, propanol, natural gas, propane and butane.

The catalyst heater heat generating unit 20 is provided on the upper portion of the fuel cell 10 and is coated with a metal catalyst to allow the fuel supplied from the fuel cell 10 to generate heat by oxygen and non-combustion catalytic chemical reaction. The metal catalyst is preferably in the form of a mesh or honeycomb.

The metal catalyst of the catalytic heater heating unit 20 is platinum (Pt), palladium (Pd), ruthenium (Ru), vanadium (V), nickel (Ni), tungsten (W), iridium (Ir), cerium (Ce) ), Preferably selected from any one of the catalysts selected from combinations of these metals or combinations of these metals. In addition, the heat generated from the catalyst heater heating unit 20 is transferred to the upper portion of the catalyst heater heating unit 20, it is preferable that the ceramic catalyst heating element (not shown) coated with a ceramic is further provided. The ceramic catalyst heating element is provided on the upper portion of the catalytic heater heating element, the ceramic is coated on the surface, and the ceramic heater heating unit (20) can be used as a three-dimensional structure such as a ceramic or a honeycomb, such as the catalytic heater heating unit (20) 20) to transfer heat generated from. In addition, the lower portion of the catalytic heater heat generating unit 20 is preferably provided with a porous ceramic filter (not shown) in contact with the fuel. Accordingly, the fuel filtered by the porous ceramic filter is transferred to the catalytic heater heating unit 20, so that air pollution is not generated.

The thermoelectric element 30 is provided on the catalytic heater heat generating unit 20 and serves to generate electricity by Ziebeck effect. The thermoelectric element 30 is formed by joining p-type and n-type elements in a π type, connecting them in series, and arranging them in a zigzag to combine the upper and lower elements with a metal plate 31. When current flows through these devices, one side absorbs heat and the other side releases heat due to the Joule thermal effect generated when the current flows through the conductor. In the present invention, by using the thermoelectric element 30, one side of the thermoelectric element is configured to transfer heat generated by the catalytic heater heating unit 20, and the other side of the thermoelectric element is discharged of heat, that is, a temperature difference ΔT. Equation 2 generates electricity due to the Seebeck Effect. At this time, since the temperature rises due to heat transfer by the catalytic heater heat generating unit 20, the upper portion of the thermoelectric element 30 is provided with a cooler 50 that can cool the heat in the upper portion of the thermoelectric element 30 to make a temperature difference ΔT. Generate electricity by zooming. Only one thermoelectric element 30 may be used, and a plurality of thermoelectric elements 30 may be provided, and each thermoelectric element 30 may be connected in series or in parallel.

At this time, the generated electricity can be confirmed by the voltmeter 60 and the temperature of the catalytic heater heating unit 20 can be confirmed the temperature generated by the thermometer 70 with a temperature sensor. The voltage generated can ignite a light bulb, or it can be used for a specific purpose, such as a charger for a generator, a laptop or a cell phone. In addition, the generated electricity is a DC voltage. Therefore, it can be converted to DC / DC and can be converted to DC / AC according to the purpose. When you want to convert voltage, a voltage converter (not shown) is generated at the voltage terminal. Additionally used.

The characteristic of the present invention is to maintain a constant temperature of the catalytic heater heating unit 20 is most important, it is preferable that a temperature control unit (not shown) for controlling the temperature of the catalytic heater heating unit 20 is further provided.

Between the thermoelectric element 30 and the catalyst heater heating unit 20, the heat generated by the catalytic heater heating unit 20 is directly transmitted to the thermoelectric element 30, the thermoelectric element 30 is subjected to thermal deformation In order to prevent it from being caused or damaged, it is preferable to attach the thermoelectric element contact surface 40 having a low thermal conductivity so as to allow heat transfer.

The lifetime of the thermoelectric element 30 is determined by the use temperature at the time of manufacturing each thermoelectric element and can be used almost semi-permanently when used within the use temperature range. Low temperature thermoelectric element is about 150 ~ 200 ℃, medium temperature thermoelectric element is about 250 ~ 300 ℃, high temperature is about 600 ~ 800 ℃, it is possible to increase the power generation capacity by using a catalytic heater that generates heat continuously. .

In addition, the power generation system of the present invention can be used continuously if the fuel is re-supplied at regular intervals when the fuel inlet 11 is used for a long time.

The cooler 50 is attached to an upper portion of the thermoelectric element 30 and includes a heat sink 51 having a fin 51a and a cooling fan 52. The cooler 50 generates a temperature difference by cooling the heat transferred from the catalyst heater heating unit 20 to the thermoelectric element 30. At this time, the cooling fan 52 is preferably operated by the electricity generated by the thermoelectric element (30).

As described above, the power generation system using the non-combustion non-ignition catalytic heater according to the present invention has a great advantage that it can efficiently replace high oil prices and renewable energy because it uses inexpensive fuel instead of fossil energy. In the future, there is an advantage that energy can be reduced and efficiency can be increased in the real world where energy shortage is serious.

In addition, the present invention can be used as a substitute for the conventional primary and secondary batteries, by using liquid fuel (methanol) excellent stability, can be used unlimitedly by supplying only fuel, noise and There is an advantage that does not cause pollution. Therefore, it is very suitable as an alternative energy source in the future, has a wide range of applications for civil and military use, can be applied as a charger for mobile phones or laptops, and can be used from small size to large size, that is, from 5W to hundreds of KW, and compared with fuel cells. Because of the low price and the ripple effect is very large.

Claims (11)

A fuel container provided with a fuel inlet; A non-combustion catalytic chemical reaction that is provided at the top of the fuel cell and is one selected from hydrogen, a hydride compound, methanol, ethanol, propanol, natural gas, propane, and butane supplied from the fuel cell and does not generate oxygen and a flame. From platinum (Pt), palladium (Pd), ruthenium (Ru), vanadium (V), nickel (Ni), tungsten (W), iridium (Ir), cerium (Ce), and combinations of these metals A catalytic heater heating unit coated with a metal catalyst selected from any one of selected catalysts or a combination of these metals; A porous ceramic filter provided under the catalytic heater heating unit and in contact with fuel; A ceramic catalyst heating element provided on an upper portion of the catalytic heater heating unit and dissipated by transferring heat generated from the catalytic heater heating unit and coated with ceramic; A thermoelectric element provided on an upper portion of the ceramic catalyst heating element and generating electricity by a Seebeck Effect; A thermoelectric element contact surface provided between the thermoelectric element and the ceramic catalyst heating element and configured to transfer heat generated from the catalytic heater heating unit to the ceramic catalyst heating element so that the transferred heat is transferred to the thermoelectric element; A cooler provided on the thermoelectric element, the heat sink having fins, and a cooling fan installed on the fins and operated by electricity generated by the thermoelectric element; Power generation system using a non-combustion non-ignition catalytic heater, characterized in that consisting of. delete delete delete delete delete delete delete delete delete delete

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