RU2471128C1 - Hot-water solid-fuel boiler - Google Patents

Abstract

FIELD: heating.

SUBSTANCE: hot-water solid-fuel boiler includes housing, at least two fuel filling hoppers, air-gas pass formed with vertical walls at least of two fuel filling hoppers and located along the perimetre of air-gas pass, furnace chamber installed under air-gas pass, air supply mechanism and heat exchanger. In furnace chamber there installed is fuel supply device from filling hoppers to fire ball, above fire ball, in air-gas pass there located is afterburner of combustible gases, and air supply mechanism is made of two channels: air flow is directed via one channel to fire ball, and via the other one to afterburner of combustible gases.

EFFECT: improvement of effective fuel combustion die to separation of combustion process of volatile matter separately from coke residue is provided.

7 cl, 1 dwg

Description

The invention is intended for heating water and can be used in a power system. Known hot-water solid fuel boiler, comprising a housing, at least two filling bunkers for fuel, an air-gas passage formed by the vertical walls of at least two filling bunkers for fuel located around the perimeter of the air-gas passage, a combustion chamber mounted under the air-gas passage, air supply mechanism, heat exchanger (1).

The technical result is to increase the efficiency of burning fuel, in particular coal, pallets, by separating the process of burning separately volatile substances and solid residue.

The essence of the invention lies in the fact that in the furnace chamber there is a device for supplying fuel from filling bunkers to the fuel ignition core, above the fuel ignition core, in the air-gas passage, there is a combustible gas afterburner, and the air supply mechanism is made of two channels: one each channel, air flow is directed to the core of fuel ignition, and through another channel, air flow is directed to the combustible gas afterburner. The channel through which the air flow is directed to the fuel ignition core is located under the fuel ignition core and is an ash pan with a grate, and the channel through which the air flow is directed to the combustible gas afterburner is the injector cavity of the external medium flow, and the internal medium flow are combustible gases passing through a passage formed in an air-gas passage. A device for supplying fuel from filling bunkers to the fuel ignition core consists of a moving mechanism having elements for shutting off fuel supply from filling bunkers to the fuel ignition core. The moving mechanism is at least two rollers rotating around their axis, the lateral surfaces of which are elements for shutting off the fuel supply from the filling bunkers to the fuel ignition core, and working in conjunction with each other, so that when the rollers rotate, part of the fuel from the filling bunkers moves to the core of fuel ignition, formed on the area of convergence of the rollers. The rollers below are surrounded by a grate. The rollers have ribs for moving part of the fuel from the filling bunkers into the fuel ignition core.

In Fig.1 shows a solid fuel boiler. A solid fuel boiler consists of a housing 1, at least two filling bunkers for fuel 2, an air-gas passage 3 formed by vertical walls of at least two filling bunkers for fuel 2, located around the perimeter of the air-gas passage 3, the combustion chamber 4, installed under the air-gas passage 3, heat exchanger 5, air supply mechanism.

In the combustion chamber 4 there is a device for supplying fuel from two filling bins 2 to the fuel ignition core 6, which is located in the combustion chamber 4. Above the fuel combustion chamber 6, in the air-gas passage 3, there is a combustible gas afterburner 7. Air supply mechanism made of two channels 8 and 9, through which the air flows: on one channel 8, the air stream is directed to the core of fuel combustion 6, and on the other channel 9, the air stream is directed to the combustible gas afterburning chamber 7. Channel 8, through which the air flow equal to the fuel combustion chamber 6, located under the fuel ignition core 6 and is an ash pan having a grate 10, and the channel 9, through which the air flow is directed to the combustible gas afterburning chamber 7, is the cavity of the injector 11, in which the internal flow of the medium is combustible gases passing through the passage channel 12 formed in the air-gas passage 3, and the external flow of the medium is an air stream that exits through openings 13 in the channel 9 installed around the perimeter of the air-gas passage 3. Device for feeding fuel (coal, pallets, wood chips) from filling hoppers for fuel 2, into the fuel ignition core 6, consists of a moving mechanism having elements for blocking the bottom of the filling hoppers for fuel 2. The moving mechanism is at least two rotating around its axis rollers 14, the side surfaces 15 of which are elements for overlapping the bottom of the through filling bunkers for fuel 2, and working in conjunction with each other, so that when turning the rollers 14 part of the fuel (coal, pallets, chips) from the filling bins for fuel 2 it moves to the core of ignition of fuel 6. The grate 10 and the core of ignition of fuel 6 are located on the area of convergence of the rollers 14. In this case, each grate 10 surrounds the rollers 14 in a circle from below, through which the ash is screened. The rollers 14 have lamellar ribs 16 for moving part of the fuel from the through filling bunkers 2 to the core of fuel ignition 6 and for cleaning the grate 10 from unburned solid residue.

Solid fuel boiler operates as follows.

On the grate 10, in the area of convergence of the rollers 14, stack chips, fine coal, pallets. On flaring wood chips, coal is blown from below by an air stream. When the fuel flames up and a temperature occurs under the air-gas passage 3, allowing volatile substances to evaporate from the fuel, the rollers 14 are rotated. fuel 2 and direct them to the grate 10. During the combustion of the fuel, the chemical process of combining the oxidizing agent (air) with the combustible fuel elements occurs. Combustible fuel elements include: carbon (C), hydrogen (H), sulfur (S), as well as combustible gases CO, H ₂ , C _m H _n . The ignition temperature of combustible gases in the air has the following values: hydrogen 580-590 degrees, carbon monoxide 644-658 degrees, methane 650-750 degrees. At low combustion temperatures of the fuel above the grate 10, in the fuel ignition core 6, the average energy of the molecules is much lower than the activation energy and therefore only a small fraction of the fuel and oxidizer molecules are capable of reaction. The main part of the combustible fuel elements is released from the fuel in the form of combustible gases, which, passing through the passage 12 in the air-gas passage 3, are mixed with oxygen in the air flow through the openings 13 located in the cavity of the injector 11. There, at corresponding to a temperature of 580-750 degrees and the supply of oxidizing agent (air) they burn in the combustible gas afterburner 7 formed in the air-gas passage 3.

The remaining solid residue - coke - is picked up by plate ribs and when the rollers 14 rotate, it again enters the filling hopper for fuel 2, and the ash wakes up through the grate 10.

The proposed technical solution allows to increase the efficiency of burning fuel, in particular coal, due to the separation of the process of burning separately volatile substances and coke residue.

Information sources

1. Patent for the invention RU 2412400 C1, 07/31/2009, "Hot-water solid fuel boiler" BLAGO.

Claims (7)

1. A solid fuel boiler containing a housing, at least two filling hoppers for fuel, an air-gas passage formed by the vertical walls of at least two filling hoppers for fuel, located around the perimeter of the air-gas passage, a combustion chamber mounted under the air -gas passage, air supply mechanism, heat exchanger, characterized in that a device for supplying fuel from filling bunkers to the fuel ignition core, above the fuel ignition core, is installed in the combustion chamber in a stuffy-gas passage, a combustible gas afterburner is located, and the air supply mechanism is made of two channels: through one channel, the air flow is directed to the fuel ignition core, and through the other channel, the air flow is directed to the combustible gas afterburner. 2. The solid fuel boiler according to claim 1, characterized in that the channel through which the air flow is directed to the fuel ignition core is located under the fuel ignition core and is an ash pan having a grate. 3. The solid fuel boiler according to claim 1, characterized in that the channel through which the air flow is directed to the combustible gas afterburning chamber is the injector cavity of the external medium flow, and the internal medium stream is combustible gases passing through the passage channel formed into the air gas passage. 4. The solid fuel boiler according to claim 1, characterized in that the device for supplying fuel from the filling bunkers to the fuel ignition core consists of a moving mechanism having elements for shutting off the fuel supply from the filling bunkers to the fuel ignition core. 5. The solid fuel boiler according to claim 4, characterized in that the moving mechanism is at least two rollers rotating around their axis, the side surfaces of which are elements for shutting off the fuel supply from the filling bunkers to the fuel ignition core, and working in conjunction with each other another in such a way that when the rollers turn, part of the fuel from the filling bunkers moves to the fuel ignition core formed at the roller convergence site. 6. The solid fuel boiler according to claim 5, characterized in that the grate below the rollers is bent around. 7. The solid fuel boiler according to claim 5, characterized in that the rollers have ribs for moving part of the fuel from the filling bunkers to the fuel ignition core.

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