UA59637A - Light source with a heater - Google Patents

Abstract

The proposed light source with a heater contains a casing, electrodes, spiral or another heating element, and a power-supply source. The electrodes and heating element are placed in solution containing fusible salts, alkalis, and metals. The temperature within the area of the heating element is up to 1000 tC, and the temperature in the casing is up to 900 CC.

Description

Description of the invention

The proposed invention relates to heat and electrical energy, in particular to light sources and heaters - fireplaces, dryers, furnaces for instant heating of parts and products from 100 to 3000 °C, for heaters of automobile engines.

Known gas lamps and heated, containing a burner with a cylinder and a tank with gas. Incandescent lamps are known, which contain a glass cylinder with a tungsten spiral and a power source. Arc lamps containing a glass cylinder with carbon rods are known. 70 well-known branded modern home heaters. Of course, in their porous ceramic burners, fuel is burned much more efficiently than in furnaces, gas lamps, steam locomotive furnaces, but still with the same final consequences, carbon monoxide, nitrogen and sulfur compounds, hydrocarbons, lead oxides will be formed if burned gasoline, and many other things. Known catalytic gas lamps and heated. However, they work only on specified clean fuel and often become clogged (zh. Technika moluda Mo 7.95, p. 31). 12 The closest technical solution chosen as a prototype is a gas light source and heater. (w.

Technology and Science, 82, Mo. 7, p. 35).

High-quality, expensive fuel is used in light sources and heaters - electricity, gasoline, diesel fuel.

Large heat losses occur. Only up to 5095 heat is directly used for heating and lighting. The basis of the invention is the task of heating in molten salts containing a mixture of liquid low-melting salts and alkalis with particles of oxides and metals, with a surface temperature of up to 800°C and in the combustion zone up to 3000°C. Use any kind of fuel - waste, ore. Due to the internal oxidation of part of the fuel in the melt of low-viscosity salts at 500-10007C, the temperature in the pyrolysis zone can be increased to 3000C, and the brightness of the glow of traps and filaments of materials, such as tungsten, with an efficiency of up to 9595. At the same time, combustion takes place at a constant temperature only in the volume of the melt without the formation of harmful substances. 29 The technical result that can be obtained during the implementation of the invention consists in the use of any type of fuel, in increasing the efficiency of heating, glow and service life of light and heat sources, efficiency of reliability, simplification structures. In reducing harmful emissions, mass-dimensional characteristics and cost. In reducing the danger of fires. The task is carried out due to the fact that the electrodes, spiral or burner are placed in a melt of liquid low-melting salts and alkalis with particles of oxides and metals, and the temperature in the torch heating up to 10000"С, and the case up to 9007С. The essence of the invention is explained by the drawing. co

Figure 1 shows a general view of the proposed light source and heater in section.

A cylinder of quartz glass 1 from the bottom to 1/4 of the height, filled with a liquid, low-melting at 8007С common salt ee, 2, which repels particles and ions of metals, alkalis, chalk, calcium carbonate. Burner Z is installed in a fusible link 2. Fuel and air are supplied through nozzles 5, 6. A tungsten screen 4 is installed above the molten salt.

The work of the light source and the heater is carried out in the following way. The raw materials, which are used as industrial and household waste, coal or oil and air, are loaded into cylinder 1 through the burner. The pyrolysis of raw materials into carbon and hydrogen takes place in the molten salt. "

The temperature regime is maintained due to their internal oxidation in molten salts. At the same time, 9990 - 70 of the chemical energy of the fuel is used to heat the melt and waste. The salt is heated up to 600" in the body and more than 3000" in the center and on the surface of the melt. Light is emitted by a tungsten plate or grid, which

It is installed over a heating torch with a temperature of up to 30007С, powders and ions of materials heated to 100007С and transformed into plasma, a filament made of melt. Vapors and gases are cooled to the temperature of the walls of the bulb and are released through nozzle 4. The salt source of heat and light does not release energy and light from combustion, but from low-temperature oxidation of the fuel - in molten salts. There is still no glow in the torch at a temperature of up to 3000°C. (se) In "flameless" salt conditions, there is a clear division into hydrogen and carbon, which burn completely to CO.

It is H2O, and other components, including harmful ones, are synthesized into useful substances or restored to the original substances - sulfur, metal. They are easily removed and recycled. When oxidizing ores, slags in general

Ge) 20 gasless combustion occurs.

In traditional "flame" radiation heaters, most of the infrared radiation of the spectrum simply does not reach the surrounding objects or you and me. Because the air itself is almost opaque for such wavelengths. He is the servant who mainly warms himself, and all the others receive warmth from him.

But this is very wasteful, because the thermal conductivity of the air environment is quite low. 29 The other one on the right is a SITS that oxidizes fuel "without fire" Simply speaking, it lights up and warms more. And in more specifically - up to 909o of energy at a balloon temperature of up to 800"С is released in a very narrow area of IR - the range of 2-16μm - the most favorable for the human body. Such heat is also well absorbed by most household materials, and the air, on the contrary, is transparent to it. As a result SITS heats us and the surrounding objects first of all, and they already heat the air due to heat transfer. 60 Salts and oxides accelerate the decomposition of coal due to the introduction of K, Ca into the interbasic layers of graphite, reduce the bond energy and serve as a catalyst for the combustion of carbon and CO. For example, CaCO 3 accelerates their burning rate by 7 times, Mass by 3 times. Water vapor also serves as a combustion catalyst. Without water vapor, carbon monoxide does not burn. Under such conditions, extremely high temperatures and pressures develop in the combustion zone.

The burning rate is easy to control. For example, the introduction of 195 iodine or its salts reduces the burning rate by 100 times.

Release of H, heat and acceleration of reactions is also produced by electrochemical reactions when metal particles are introduced into the melt, because a mass of galvanic elements is formed - the electrodes are metals and coke, and the electrolyte is molten salts. These elements are electrochemical catalysts for the synthesis of substances. In them, the electrolysis of substances occurs with the formation of atomic oxygen, hydrogen, Ma, SI, electric discharges with speeds close to light, and electro-hydraulic impact cavitation. At the same time, the huge electric energy in the electric double layers on the surface of the metal particles charges the fuel.

The kinetic energy of the collapsed bubble reaches 119J, or 7.44.1020eV, or 7.44.1011GeV. This is a huge amount. Therefore, cavitation bubbles destroy the strongest materials. Modern accelerators make only hundreds of Hev. 70. Pressure in the bubble (2.107Pa) 1Omln. N/m2 and expansion speed up to 200m/s, temperature up to 100002С. When the gas bubble reaches its largest size, the pressure inside it drops sharply. The molten metal contained in it boils and is ejected into the melt together with the enormous electrical energy of the electric double layers on the surface of the metal particles. The cavitation bubble works as a universal accelerator of reactions of any substances that fall into its volume. Exothermic and endothermic chemical and nuclear reactions, distribution and synthesis reactions can take place in it, for example: "Well, well -" 1442 MeV.

Local overheating above 3000°C and cavitation also occur during thermal reactions of ionized aluminum and sodium oxides. The speed of reactions is also controlled by magnetic fields and cavitation.

An increase in fuel combustion energy yield and abnormally high temperatures is achieved due to the active interaction of electrically charged fuel particles with the surrounding ionized oxidizer, the formation of atomic hydrogen, OH, O from water, as well as sodium and chlorine during electrolysis, during reactions with red-hot metals and graphite, under the influence of high temperature. When atomic substances are joined, abnormally high temperatures and the formation of plasma are reached, which melt, vaporize, cut, and flow even refractory materials. The presence of molten salt with high thermal conductivity and heat capacity, and powerful cavitation and electro-hydraulic shocks enhance this effect, "comparing it with the effect of temperature increase to 10,000 9C in a plasma compressed by magnetic fields."

The joint use of the physical and chemical processes listed above leads to the autocatalytic acceleration of combustion reactions and an increase in the combustion temperature, to the achievement of high energy density in the local area of space, to the formation of new substances and the use of electrical and internal energy of substances. -

Melting salts with catalysts creates conditions for the implementation of a controlled process of disruption and is a heat-intensive environment for the selection and accumulation of energy. A special geometric shape of the reactor is required to obtain high energy density. This hole 12 is created in the cold layer of salt by a burning torch. uh-oh

In the chamber, C, CO, and H burn with the oxygen of the air and metal vapor and CO 5 are formed. Vapors and gases F) bubble through the salt layer and enter the nozzle of the gas outlet node 6, and cause the tungsten to heat up and 32 to glow and pass after the nozzle 6 through the refrigerator and returned to the system or released into the air (not shown).

Example 2. Iron ore and solid waste are fed into the burner as fuel. In this case, the recovery of the ore occurs with the release of heat. The addition of potash accelerates the reaction rate several times. "

Эе2О3 nya Ne - 2BezO, nya nya -v 70 The reaction takes place with subsequent production of pure metals. c Example 3. Oxides, such as boron and silicon, are used as fuel in fuel tanks. In this case, there is a "non-basin burning" in molten salt with the release of heat.

Examples of how fuel is loaded for dusting ore and metals. In this case, H is the oxidizing agent. Reactions take place in molten salt with heat release - TiIN» - 69.5, ReН» - 0.84, 7pН»о - 169.3kKJ/mol. The resulting expensive sl 75 products are used to preserve hydrogen, to obtain powders and coatings.

Toxic substances С, Е, З react in molten salts with metals and alkalis with the formation of useful substances (Се) and heat, for example: 2Са(он)» with Сі» - Сасі» - Са(СН)» - 2Н50

Air nitrogen at a temperature in the combustion zone of З000С reacts in a melt of salts with nonmetals and metals and their oxides and oxygen with the release of heat and the formation of nitrides - hard, refractory materials, and also fuel.

When using an electric power source, electrodes or a spiral are placed in the melt.

An experienced source of light and heat, the size of a three-liter jar, despite its small size, develops a power of 4 kW, consuming a liter of any fuel per hour (solid waste, coal with rock, iron ore, etc., wood dust, fuel oil, gas) with a phenomenal light output and thermal efficiency up to 99.895. in. The physico-chemical processes taking place in the proposed light source and heaters make it possible to obtain substances, the cost of which is much higher than that of the original fuel, and to transform harmful substances, for example, hydrogen sulfide and chlorine into environmentally safe compounds and pure sulfur, and to reduce emissions into the atmosphere to acceptable

DOT The composition of gaseous products and coke meets environmental requirements and permissible concentrations. 60 Emissions test results are given below.

CO"5,Omg/m?, 8Oo"0.5mg/m?, MO"o"0.85mg/m In, diokeins and furans "B5gn/m?

Claims (7)

The formula of the invention b5 1. A light source and a heater that contains a housing, such as a cylinder, a heating device, such as electrodes, a spiral or a burner, and a power source, which is distinguished by the fact that the electrodes, spiral or burner are placed in a melt of liquid low-melting salts and alkalis with particles of oxides and metals , and the temperature in the heating torch reaches 10000", and in the case - 90070. 2. The light source and heater according to claim 1, which is characterized by the fact that it contains a tungsten plate or grid heated to 300°C, which is installed above the heating torch. C. The light source and heater according to claim 1, which differs in that the powders and ions of the materials are heated to 100007C and transformed into plasma. 70 4. The light source and heater according to claim 1, which is characterized by the fact that the filament is made of melt. 5. The light source and heater according to claim 1, which is characterized by the fact that the accelerator of reactions is cavitation, galvanic elements in molten salts and a magnetic field. 6. Light source and heater according to claim 1, which differs in that the fuel is ores, for example RezOz, slags, household and industrial waste, oxides, nitrogen. 7. The light source and heater according to claim 1, which differs in that hydrogen, chlorine, fluorine, sulfur, nitrogen, oxides and ores of elements, CaO, 50", Be2O3z, H2O can serve as an oxidizer. « in (ze) (Se) (o) And in) - and? 1 se) (o) (95) that 60 b5