SU1751597A1 - Furnace - Google Patents

Abstract

Use: in the field of fuel combustion to improve efficiency. SUMMARY OF THE INVENTION: Each output window 4 of each of the pre-furnaces 3 is located at its rear end, and the pre-furnaces 3 are installed horizontally and counter to each other on opposite sides of the afterburner chamber 1, which ensures the interaction of gas flows from the pre-furnaces 3 and the hot gases to windows 4, thereby increasing the efficiency of combustion in chamber 1. 2 Il.

Description

The invention relates to the combustion of fuel and can be used in thermal power plants.

Known furnaces containing a vertical prismatic afterburner with an air nozzle and cylindrical pre-furnaces connected to the afterburner using exit windows and equipped with a burner coaxially located at the front end of each pre-burner.

A disadvantage of the known furnaces is the underburning that enters the afterburner, due to the short contact time of dust with air in the pre-furnaces.

Known furnaces containing a vertical prismatic afterburner with air nozzles and cylindrical pre-furnaces connected to the afterburner using exit windows and equipped with a burner and a window for exhausting gases coaxially located at the front end of each pre-burner.

A disadvantage of the known furnaces is the tangential supply of oxidizer and fuel, which lengthens the flame and increases the burning time.

A furnace is known that contains a vertical prismatic afterburner with an air nozzle located in its upper part and cylindrical pre-furnaces connected to the afterburner using exit windows and equipped with a burner and a window for suctioning gas coaxially located on the front end of each pre-burner.

A disadvantage of the known firebox is the confined movement of dust and air, which increases the burnup time of the fuel and leads to underburning:

The purpose of the invention is improving efficiency.

This goal is achieved by the fact that in a furnace containing a vertical prismatic afterburner with an air nozzle located in its upper part, and cylindrical pre-furnaces connected to the afterburner using exit windows and equipped with a burner and a suction window coaxially located on the front end of each pre-burner gases, the exit window of each of the pre-furnaces is located at its rear end, the pre-furnaces are installed horizontally and counter to each other, and the air nozzle of the afterburner is slotted and placed on inclined downward and tangentially to a conditional circle equal to the diameter of the exit window of the pre-heating on one of the side walls.

Placing the air nozzle of the afterburning chamber obliquely downward to the tangential circumference equal to the diameter of the exit window of the pre-furnace on one of the side walls, and making it slotted allows for forced air to flow through the entire pre-furnace 3, since the windows 7 for suctioning gas are located at end 5, opposite end 8 with an exit window 4 ^ into the afterburning chamber 1, in which air nozzles 2 are installed. This provides a countercurrent meeting of the oxidizing agent and fuel, which is the most effective for their interaction. In this case, the interaction products are constantly sucked out through the window 7 from the combustion zone, which increases the concentration of the starting materials and leads to an increase in the burning rate.

The installation of the exit window of each of the pre-furnaces at its rear end, opposite the end 5, on which the windows 7 for suctioning the gas are located, makes it possible to suck air into the pre-furnace 3 through this window, which passes through the entire pre-furnace of dust coming from the burners 6, which kindles dust, as it blows off from every dust particle the shell of carbon dioxide, which prevents combustion.

Opposite placement of the exit window 4 and the window 7 for gas suction at opposite ends 8 and 5 of the preheater 3 allows for countercurrent combustion of dust according to a short-flare pattern, since the oncoming air stream shortens the torch.

The counter and horizontal installation of the pre-furnaces allows you to organize a vortex in the chamber 1 afterburning, which is rotated due to the tangential air supply from nozzles 2 centered in the pre-furnaces, which reduces the under-burn.

In this case, the angular velocities are maximum at the exit windows 4, which are the input for the vortex and air. This improves economy.

In FIG. 1 shows a firebox, a longitudinal section; in FIG. 2 is a section AA in FIG.

1.

The furnace contains a vertical prismatic afterburning chamber 1 with an air nozzle 2 located in its upper part, and cylindrical pre-furnaces 3 connected to the afterburning chamber 1 by means of exit windows 4 and equipped with a burner 6 and a window 7 coaxially located on the front end 5 of each pre-furnace 3 and a window 7 for gas suction. The exit window 4 of each of the pre-furnaces 3 is located on its rear end 8. The pre-furnaces 3 are installed horizontally and counter to each other, and the air nozzle 2 of the afterburning chamber 1 is made left and placed obliquely downward and tangentially to a conditional circle equal to the diameter of the exit window 4 of the pre-furnaces 3 on one cZ of the side walls 9 of the afterburning chamber 1.

The window 7 for exhausting gas from each pre-furnace 3 is connected to the inlet of the grinding device 10, connected by the pressure side through the dust concentrator 11 to the burner 6 of pre-furnace 3. The afterburning chamber 1 is equipped with an exhaust burner 12 connected to the exhaust pipe 13 of the dust concentrator 11. In the window 7 for exhausting gas, the pre-heating 3, a pipe 14 for supplying recirculation gases from the recirculation smoke exchanger to control the temperature of the gases in the grinding device 10 is installed opposite the flow to the inlet of the grinding device 10. A raw fuel estrus 15 is connected.

The furnace works as follows.

Crude fuel in flow 15 is fed to the inlet of the grinding device 10, where hot flue gases from the window 7 are simultaneously fed to exhaust gas from the pre-furnaces 3, the temperature of which is regulated by the additive of recirculation gases from the nozzle 14, the on-board supply of which contributes to dust blowing from the suction. The crushed and partially dried fuel through the dust concentrator 11 is fed into the burners 6 of the pre-furnace 3, and the spent drying agent is removed with a part of fine dust through the waste pipe 13 of the dust concentrator 11 into the waste burner 12 of the afterburner 1.

Passing the pre-furnace 3, the fuel is gasified, coked in countercurrent flowing hot flue gases sucked into the torch, sucked into the window 7, and effectively burns out in air jets, sucked to the window 4 from the nozzles 2 of the afterburner 1. Due to the forced intake of air in the pre-furnace 3 from the afterburning chamber 1, effective combustion in countercurrent occurs, which reduces the length of the flame and the dimensions of the furnace. Through the exit windows 4 only large particles enter the afterburning chamber 1 that do not have time to burn in _; 3, and all gas ballast is pumped by the grinding device from the 3 furnaces to the exhaust burners 12 of the afterburning chamber 1, bypassing the windows 4, which increases the concentration of the oxidizing agent in the active combustion zone and accelerates the burning of dust. Combustion in countercurrent blows dust particles with air, which kindles them. In the afterburning chamber 1, there is also oncoming combustion in the window zone 4.

Thus, the proposed device of the furnace allows to intensify the process of burning dust due to the oncoming supply of dust and air by forced suction through each other, which provides short-flame combustion without underburning, while the combustion products are continuously removed from the active zone of combustion through the windows 7 for gas suction. This increases the concentration of reactive fuel and oxidizer and the burning rate, which reduces the dimensions of the furnace and metal consumption and increases efficiency. In addition, as a result of thermal preparation of fuel in pre-furnaces 3, by the time of its interaction with air, its porosity and calorific value sharply increase, which enhances heat generation. The burn out of the windows 4 also passes up the afterburning chamber 1 through the oncoming air flow entering the windows 4, which leads to its reduction.

Claims (1)

Claim A furnace containing a vertical prismatic afterburner with an air nozzle located in its upper part, and cylindrical pre-furnaces connected to the afterburner using exit windows and equipped with a burner and a window for exhausting gases coaxially located on the front end of each pre-burner, characterized in that, in order to increase efficiency, the exit window of each of the pre-furnaces is placed at its rear end, the pre-furnaces are installed horizontally and counter to each other, and the air nozzle of the afterburner is made with slits m and placed obliquely downward and tangentially to a conditional circle equal to the diameter of the exit window of the pre-furnace on one of the side walls. , '1751597