RU2006741C1 - Furnace - Google Patents

Abstract

FIELD: heat and power engineering. SUBSTANCE: furnace has prismatic vertical combustion chamber, fuel burners, blast-furnace gas burners mounted on common vertical wall, and secondary-air nozzles tilted down. Fuel burners are placed above blast-furnace burners and are tilted down, and secondary-air nozzles are mounted on opposite vertical wall of combustion chamber. EFFECT: improved design. 2 cl, 1 dwg

Description

 The invention relates to devices for burning various types of fuels, including blast furnace gas, and can be used on steam and hot water boilers.

 Known dust and gas and gas-oil furnaces of boilers having an opposite arrangement of burners and burning along with other types of fuel natural gas, which has a high calorific value and reactivity [1].

 The disadvantage of such furnaces is their inability to burn blast furnace gas, which has a low calorific value and reactivity, which requires the use of special burners and the organization of the corresponding torch aerodynamics.

 Known firebox (prototype), containing a vertical prismatic combustion chamber, fuel burners, blast furnace gas burners and secondary air nozzles located on one vertical wall of the combustion chamber, with horizontally directed fuel burners installed below downwardly inclined blast furnace gas burners and secondary air nozzles [2] .

 The disadvantage of this furnace, when burning coal dust along with blast furnace gas supplied to the furnace through fuel burners, is the unstable ignition of coal dust and blast furnace gas due to the supply of all the amount of secondary air in-line with the blast furnace gas to the root of the pulverized coal torch, as well as the separation of unburned coal dust in cold funnel with the formation of a mechanical burn.

 The aim of the invention is to increase the efficiency of fuel combustion.

 This goal is achieved by the fact that in the proposed furnace, containing a vertical prismatic combustion chamber, fuel burners and blast furnace gas burners placed on one vertical wall, and also installed with a downward inclination of the secondary air nozzle, the fuel burners are placed above the blast furnace gas burners and are directed with an inclination down, and secondary air nozzles are mounted on the opposite vertical wall of the combustion chamber.

 To achieve the greatest effect, fuel burners, blast furnace gas burners and secondary air nozzles are installed in the same vertical planes.

Thanks to these distinguishing features, fuel combustion efficiency is increased. First of all, this is expressed in the fact that the stability of ignition of coal dust moving with an inclination downward in the mixture with primary air increases due to the fact that this process occurs in oncoming, rising upward flow of hot flue gases and, therefore, is characterized by increased heat and mass transfer. Reliably ignited coal dust particles, especially relatively large ones, are introduced into the burning torch of blast furnace gas, contributing to its turbulization and heating. In addition, not all secondary air (as in the prototype furnace) is supplied to the blast furnace gas burner, but only a part of it. Given that blast furnace gas itself contains a significant amount of inert products (55% H ₂ and 12% H ₂ O), its heating and ignition is intensified when only part of the secondary air is supplied to the furnace with it. The other part is supplied from the opposite wall with a downward slope and enters the combustion process after the steady ignition of both torches. As regards the separation of unburnt dust particles of coal into a cold funnel, it is significantly reduced for two reasons: due to the early and sustained ignition of the coal dust torch, and also because the torch of the blast furnace gas is a kind of curtain on the way of the separated particles.

 Since the proposed arrangement of fuel burners, blast furnace gas burners and secondary air nozzles is not known from information sources and provides an interconnected flow of combustion processes to achieve the goal, we can conclude that the claimed furnace meets the criterion of "significant differences".

 The drawing shows a section of the proposed furnace.

The furnace contains a vertical prismatic combustion chamber 1, fuel burners 2 and blast furnace gas burners 3 mounted on one vertical wall 4. Fuel burners 2 in this case are inclined downward by an angle of 60 ^o to the horizontal plane. On the opposite vertical wall 5 mounted with an inclination downward (in this case, at an angle of 30 ^o ) nozzles 6 of the secondary air.

 It is advisable that the axes of the fuel burners 2, the blast furnace 3 burners and the secondary air nozzles 6 are located in the same vertical planes, and the intersection point of the axes of the fuel burners 2 and the secondary air nozzles 6 is in half the furnace adjacent to the wall 4, but above the upper boundary of the torch blast furnace gas, as is done in the drawing of the proposed furnace.

 The furnace works as follows.

 The coal dust in the mixture with the primary air is blown downwardly into the combustion chamber from the fuel burners 2. It is heated well by the upward flow of the combustion gases and is reliably ignited. At a certain distance from the mouth of the fuel jets, sufficient for the complete ignition of the pulverized coal torch, secondary air mixed with combustion products is supplied to it. This air enters the combustion chamber from the secondary air nozzles 6 tilted downward and placed on the vertical wall 5. After mixing the secondary air into the pulverized coal torch, the latter interacts with the blast furnace gas torch, intensively heating it, including due to inertial penetration of burning coal dust into its stream. and ashes. The blast-gas torch flow prevents the intensive unburnt coal particles from falling into the cold funnel, as it increases their soaring time and trajectory. The root of the blast furnace gas torch, freed from part of the secondary air, quickly warms up and ignites. The mixed stream of both torches moves to the wall 5, then rises up, interacting with fresh jets flowing from the nozzles 6 of the secondary air. The location of the axes of the fuel burners 2, blast furnace burners 3 and secondary air nozzles 6 in the same vertical planes ensures that both types of fuel find their air, necessary for their complete burnout, almost within the combustion chamber 1 of the furnace. It should also be noted that the use of step-by-step burning of both types of fuel, when part of the secondary air flowing out of the secondary air nozzles 6 is used to burn fuel away from the torch core, and in the core itself the oxygen concentration is much less than the stoichiometric amount, is accompanied by a decrease in the formation of oxides in the furnace nitrogen.

 Using the proposed furnace allows to increase the efficiency of fuel combustion. (56) 1. Reznikov M.I. Steam generator plants of power plants. M: Energy, 1974, Fig. 18-2 (p. 275) and 18-4 (p. 280).

 2. USSR author's certificate N 1154512, cl. F 23 C 5/28, 1985.

Claims (2)

 1. A burner containing a vertical prismatic combustion chamber, fuel burners and blast-furnace gas burners placed on one vertical wall, as well as secondary air nozzles installed with a downward inclination, characterized in that, in order to increase combustion efficiency, fuel burners are placed above the blast-furnace burners gas and directed downwardly, while secondary air nozzles are mounted on the opposite vertical wall of the combustion chamber.  2. A furnace according to claim 1, characterized in that the fuel burners, blast furnace gas burners and secondary air nozzles are installed in the same vertical planes.

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