RU2412400C1 - Hot-water solid-fuel "blago" boiler - Google Patents

Abstract

FIELD: power industry. ^ SUBSTANCE: hot-water solid-fuel boiler includes body, fuel filling silo, air-gas passage, heat exchanger located in air-gas passage, furnace chamber, air supply mechanism to furnace chamber. Air-gas passage consists of inner walls at least of two vertical filling silos located along the perimetre of air-gas passage, and external walls are the part of external wall of the body; furnace chamber is installed under air-gas passage. At that, air supply mechanism to furnace chamber consists at least of one nozzle located under each one at least of two vertical filling silos, with direction of air flow at a tangent to lower bed of solid fuel, which is located in vertical filling silo, and air flow is directed into furnace chamber. ^ EFFECT: activation of thermochemical decomposition process of hydrocarbon material into generator gas and solid residue with their more complete combustion in the medium containing excess air oxygen. ^ 5 cl, 1 dwg

Description

The invention relates to energy, in particular to devices for heating individual houses and hot water for household needs in places where there are no modern heat sources.

A device for a solid fuel boiler, comprising a housing, a charging hopper for fuel, an air-gas passage located in the air-gas passage, a heat exchanger, a combustion chamber, an air supply mechanism to the combustion chamber [1].

The technical result is the activation of the process of thermochemical decomposition of hydrocarbons into generator gas and a solid residue with their more complete combustion in a medium containing excess oxygen.

This is achieved by arranging a solid fuel boiler, creating conditions for efficient mixing with the air oxygen of the products of thermochemical decomposition of solid fuel, for efficient transfer of part of the released energy during an exothermic chemical reaction of combustion of products of thermochemical decomposition of fuel during the endothermic chemical reaction of decomposition of solid fuel into generator gas and solid the remainder.

The essence of the device for a solid fuel boiler is that the air-gas passage is formed from the inner walls of at least two vertical filling bins located around the perimeter of the air-gas passage, and the outer walls are part of the outer wall of the casing, the combustion chamber is installed under the air -gas passage, while the mechanism for supplying air to the combustion chamber is made of at least one nozzle located under each of at least two vertical filling bunkers, the direction of air flow at a tangent to the lower layer of solid fuel disposed in a vertical filling hopper and the air flow is directed deep into the heating chamber. In the air-gas passage in front of the heat exchanger, a thermal energy storage device is installed. The air-gas passage sections where the heat energy storage device and the heat exchanger are installed have a detachable connection. The air-gas passage and the upper outer wall of the boiler body have a detachable connection. The filling hopper has a pipe for supplying steam to the drying zone.

The drawing shows a solid fuel boiler.

A solid fuel boiler consists of a housing 1, at least two vertical filling bins for fuel 2, an air-gas passage 3 formed (in our case) from two internal walls 4 of vertical filling bunkers for fuel 2 and two walls of the housing 1, located along the perimeter of the air-gas passage 3. The outer walls of the fuel hoppers 2 are part of the outer wall of the housing 1. Under the air-gas passage 3, a combustion chamber 5 is installed, having an ash bin under it 6. Between the ash bin 6 and then the grate 7 is installed by the face-to-face chamber 5. Air is supplied through the grate 7 to carry out an exothermic chemical reaction of burning the solid residue formed during the thermochemical decomposition of solid fuel in the vertical filling hoppers for fuel 2, and fresh solid fuel fed into the combustion chamber 5. Vertical the filling hopper for fuel 2 and the combustion chamber 5 are separated by the grate 8. A scheme of a two-zone gasification process in a vertical filling hopper is provided for for fuel 2. The vertical filling hopper for fuel 2 is conditionally divided into five zones: a drying zone, a dry distillation zone, two oxygen zones and a recovery zone. Above the grate 8 is an oxygen zone. Then - the recovery zone. Further, beyond the recovery zone is the oxygen zone. And further dry distillation and drying zone. In the drying zone, a pipe 9 for supplying steam is installed. And in the recovery zone there are openings 10 for the output of the generator gas. A nozzle 11 is installed under the grate 8 for supplying air tangentially to the lower layer of solid fuel located in the vertical filling hopper for fuel 2, and the air flow is directed deep into the combustion chamber 5. The air-gas passage 3 is divided into two sections. In one, there is a heat exchanger 12, and in the other, a thermal energy storage device 13, which uses talchochlorite, chromite. They have a detachable connection. The thermal energy storage device 13 is installed above the openings 10 for the output of the generator gas. Above the heat energy storage 13, a heat exchanger 12 is installed, made of smoke tubes, between which hot flue gases pass. Water circulates in the pipes. A riser 14 with a steam trap 15 is integrated in the heat exchanger 12 to collect and withdraw the generated steam.

Solid fuel boiler operates as follows. The heating system and heat exchanger 12 are filled with water. Solid fuel is placed in the vertical filling hoppers for fuel 2 and in the combustion chamber 5. The fuel is ignited in the combustion chamber 5. The burning rate of the solid fuel in the combustion chamber 5 is regulated by the amount of air supplied under the combustion chamber 5 through the grate grate 7. When the fuel has sufficiently flared up and the water temperature at the outlet of the boiler reaches the required value, start supplying air to the nozzles 11. The air in the layer of gasified fuel is located In the vertical filling hopper for fuel 2, it is fed through the nozzle 11 under the grate 8 along the tangent to the layer of gasified fuel. The air passes through the gaps in the grate 8 and enters the oxygen zone, and the excess, passing tangentially to the fuel layer, goes deep into the combustion chamber, creating turbulence in it. The process of burning carbon proceeds with the release of heat. In this case, the temperature in the layer rises to 1200-1500 ° C. The interaction of carbon with oxygen is accompanied by the formation of carbon dioxide. The flow of gases from the oxygen zone, rising up, heats the fuel layer located above to a temperature of 900-1100 ° C. Here, carbon dioxide comes into contact with carbon and is partially reduced to carbon monoxide. In the recovery zone, the decomposition of water vapor from the riser 14 through the steam trap 15 also proceeds with the formation of carbon monoxide and hydrogen. Moreover, in the recovery zone, reactions proceed with heat absorption. The temperature conditions (300-900 ° C) of the fuel layers lying in the drying zone do not provide the reaction of carbon dioxide reduction and decomposition of water vapor, however, they are sufficient for the process of dry distillation of fuel. As a result of the process of decomposition of fuel proceeding without access of air, a generator gas is formed, consisting of CO, CO ₂ , H ₂ , CH ₄ , C _n H _m . The output of the generator gas is carried out from the recovery zone through openings 10. The temperature of the exhaust gases reaches 700 ° C. Ash and unburnt solid fuel formed in the core pass through the grate 8 and are lowered into the combustion chamber. The ash is lowered into the ash bin 6, and the unburned solid fuel, interacting with the oxygen of the air coming from below through the grate 7 and from above from the nozzle 11, burns out, generating additional heat. Exiting through openings 10, the generator gas is mixed with excess oxygen of the air supplied through the nozzles 11 in the layers of the thermal energy storage device 13 and burns out in it, releasing thermal energy. The generated heat energy is used for heat storage in the heat energy storage device 13, and most of the heat is transferred through the heat exchanger 12 to the water circulating in it.

The use of this layout of a solid fuel boiler will allow less frequent loading of vertical filling bunkers with fuel.

Information sources

 1. Patent RU 2363888 C1, 12/13/2007

Claims (5)

1. A solid fuel boiler comprising a housing, a fuel filling hopper, an air-gas passage located in the air-gas passage, a heat exchanger, a combustion chamber, an air supply mechanism to the combustion chamber, characterized in that the air-gas passage is formed of internal walls, at least two filling vertical hoppers located around the perimeter of the air-gas passage, and the outer walls are part of the outer wall of the housing, the combustion chamber is installed under the air-gas passage, while the air supply to the combustion chamber is made up of at least one nozzle located under each of at least two vertical filling bunkers, with an air flow tangential to the lower layer of solid fuel located in the vertical filling bunker, and the flow air directed deep into the combustion chamber. 2. A solid fuel boiler according to claim 1, characterized in that a heat energy storage device is installed in the air-gas passage in front of the heat exchanger. 3. The solid fuel boiler according to claim 2, characterized in that the sections of the air-gas passage where the heat energy storage device and the heat exchanger are installed have a detachable connection. 4. The solid fuel boiler according to claim 1, characterized in that the air-gas passage and the upper outer wall of the boiler body have a detachable connection. 5. The solid fuel boiler according to claim 1, characterized in that the filling hopper has a pipe for supplying steam to the drying zone.