EP2860468A2 - Heating boiler - Google Patents

Abstract

The invention relates to a boiler construction for solid fuels for heating of household and industrial spaces with a possibility of recovery of carbonaceous waste. It is an object of the invention to increase the operating characteristics at the expense of increasing the combustion maturity of the fuel. The stated object is achieved in that the heating boiler has a fire chamber, in the combustion chamber, a post-combustion chamber in the form of a horizontally located cylindrical tube with an anvilized end face and openings are arranged on its surface and an ash case, which is connected to a forced feed source of oxidizing agent. In addition, the heating boiler to a heat exchanger and a flue pipe, which are interconnected with exhaust ducts. Guide rails from the cylindrical tube of the post-combustion chamber and the reaction chamber are in the form of ovals whose major axes are oriented perpendicular to the base of the combustion chamber. The afterburner is formed with longitudinal inclined edges on its side surface and openings therebetween. The afterburner chamber is supplied with the reaction chamber in the form of a cylinder with openings on its side surface. The cylinder therein is arranged coaxially with a ring clearance. The cylinder is connected to an oxidant forcing passage, the reaction chamber being connected to a heat exchanger via a catalyst located in its free end face.

Description

The invention relates to a heating boiler with a fire chamber according to the preamble of claim 1.

The invention can be used in a boiler construction for solid fuels for the heating of household and industrial spaces with a possibility of recovery of carbonaceous waste.

A catalytic boiler with a delayed combustion (patent of the Russian Federation no. 2319909 , F24H1 / 46, F23B 10/00, publ. 2008r.), Which consists of a combustion chamber, under which an ash case with an ash trap door and a grid is arranged. Around the boiler vertical straight convector pipes are built from the inner side. In the upper part of the combustion chamber is a compartment wall which forms a secondary combustion chamber and a heat exchange chamber. The Nachbrenneinrichtung consists of a body in the fold two catalytic lattice are set between which nozzles of a top air supply are placed. The number of top air supply control sheet-like bimetallic valves. Hot fire gases from the heat exchange chamber enter a thermostatic chamber. An exhaust pipe connects the combustion chamber and the thermostatic chamber. A technical result of this embodiment consists in a Nachbrennverbesserung the exhaust gases and in a safety increase of the device.

The lack of the known boiler is a low work efficiency, which is due to the fact that the post combustion of the exhaust gases in the upper air supply into the combustion zone in the upper part of the combustion chamber is spontaneous. In the design, regulation of the oxygen super-air supply in proportion to the gases formed is not provided. At elevated temperature, a larger amount of fire gas will escape in the boiler and a larger amount of oxygen will be required for its full combustion. The nozzles can only pass a fixed amount of air, so unburned fire gases go into the atmosphere, which reduces the operating characteristics.

As a prototype, a furnace, an air duct and a heat exchanger are selected (Russian Federation Patent No. 2408822 , F24B5 / 02, publish in 2011), which has a fire chamber with an ash trap, an afterburner, a heat exchanger and a flue pipe, which are connected to each other via exhaust ducts. The afterburner chamber is disposed in a firebox and formed in the form of a horizontally located cylindrical tube. It is supplied by a vortex pattern and an air duct in the form of an additional tube, which is arranged after the tube axes of the afterburner. A reheat tube is provided near the front wall of the combustion chamber with longitudinal cuts with a formation of blades. The vortex image is in the form of inflected vanes, and the tube opening is stunned from the front.

The shortcoming of the prototype furnace, air duct and heat exchanger is its low work efficiency due to incomplete combustion of the fuel. This is due to the fact that the ratio of the leaked fuel gases to the feed air has an unstable character. The gas formation processes depend on the temperature in the combustion chamber, which is also unstable. The amount of air that arrives at a steady rate is not proportional to the rate of reaction of the fuel combustion. As a result, there is a deficit of oxygen or excess, which complicates regulation and violates the fuel to air ratio. If you increase the supply of first air under the grate, then the particles of fuel, which is located on the grid, the air rush act. The air rush, which counteracts the gravity of the fuel particles, proves to be levitating in a hovering state, which increases the thickness of the burning layer or does not burn it out of the chamber at the expense of increased vortex formation.

It is an object of the invention to increase the operating characteristics at the expense of increasing the combustion maturity of the fuel.

The stated object is solved by the features of claim 1.

This is achieved in that the heating boiler has a fire chamber, in the combustion chamber, a post-combustion chamber in the form of a horizontally located cylindrical tube with a stunned end face and openings are arranged on its surface and an ash. The heating boiler is connected to a forced feed source for an oxidizer. In addition, the heating boiler on a heat exchanger and a flue pipe, which are connected to each other via exhaust ducts. The afterburner chamber is formed with longitudinal inclined edges on its side surface and openings therebetween, and is provided with a reaction chamber in the form of a cylinder having openings on its side surface provided. The cylinder is coaxial therewith and disposed with an annular clearance connected to a forced feed channel for the oxidizer. The reaction chamber is connected to the heat exchanger via a catalyst which is arranged in its free end face.

Guide rails from the cylindrical tube of the post-combustion chamber and the reaction chamber are in the form of ovals whose major axes are perpendicular to the base of the combustion chamber.

The execution of the afterburner chamber with the longitudinal inclined edges on the side surface and the openings therebetween provided with the reaction chamber in the form of a cylinder with the openings on its side surface disposed therein coaxially and with an annular clearance provided with a forced feed passage for the oxidizer is associated contributes to a heterogeneous effect of the fuel combustion on various gasification steps and provides Nachbrennbedingungen for exhaust gases in the eddy current, which contributes to a balanced stable maintenance of a high temperature in the firebox and to a uniformity of the thermal processes.

This phenomenon is due to the fact that the combustion processes take place during concentrated heating and solid fuel combustion in which the contents of the volatile and solid carbon contents are not constant, since the interacting components are in different states of aggregation. At the same time on structure the various volatiles differ in different initial temperatures, and process is extended during its allocation. Therefore, its final step is combined with firing in a reaction chamber where it enters through the openings on the side surfaces of a reheat chamber and a reaction chamber. Thus, the number of reacted carbon of the number of oxidant supplied becomes stable correspond. The burning process of pure carbon in a reaction chamber is self-regulated, which also contributes to full fuel combustion. With stable oxidant consumption, the number of burned fuel also becomes stable at the expense of an aerodynamic reactive effect in the afterburner chamber. The change in thermal stress is produced at the expense of regulating the oxidant feed to the post-combustion chamber with the simultaneous oxidant feed to the ash.

The communication of a reaction chamber with a heat exchanger through the catalyst, which is arranged in its free end face, allows to catch different resinous and solid fuel particles, which substantially reduces the toxicity of exhaust gases. As a result, the ecological characteristics are improved, since the catalyst prevents the agglomeration or burning of active component in the heterogeneous catalysis. This allows to maintain a high contact area of active material and reagents.

The design of the guide rails from the cylindrical tube of the post-combustion chamber and the reaction chamber in the form of ovals, whose large axes are perpendicular to the base of the combustion chamber, contributes to the concentration of infrared radiation from their walls. This improves the gasification of solid fuel and the stabilization of the interaction processes of the oxidizer with the carbon of the fuel under the conditions of high temperatures. As a result, the coal mass burns most effectively, so that the utility of the boiler is increased overall.

• Fig. 1 den Heizungskessel im Längsschnitt,
• Fig. 2 die Ansicht auf den Heizungskessel nach Fig.1 und
• Fig. 3 den Schnitt nach A-A der Fig.1 (Nachbrennkammer im Schnitt).

The invention will be explained in more detail with reference to the drawings. Show it:

• Fig. 1 the heating boiler in longitudinal section,
• Fig. 2 the view on the boiler after Fig.1 and
• Fig. 3 the cut to AA the Fig.1 (Secondary combustion chamber on average).

The boiler takes on a fire chamber, which consists of a combustion chamber 1 with a tightly closed hatch 2 and a door 3, a grid 4 and an ash trap 5 with a sealed door 6. In the combustion chamber 1, a post-combustion chamber 7 is arranged at the level of the door 3. The afterburner chamber 7 is formed in the form of a horizontally located cylindrical tube 8 with longitudinal inclined edges 9 on its side surface. Between the edges 9 8 openings 10 are formed on the tube. In the tube 8 is arranged coaxially and with a ring clearance 11, a reaction chamber 12 which is formed in the form of a cylinder 13 with openings 14 on their side surfaces. The annular clearance 11 is connected via a channel 15 to a forced supply source of oxidizing agent in the form of a fan 16. The fan 16 is connected via a channel 17 with the ash case 5. The free end face of the cylinder 13 of the reaction chamber 12 is connected via a catalyst 18, for. B. an oxidizing support (SiO 2, Al 2 O 3 and SiC), connected to a heat exchanger 19, in the upper part of a chimney 20 is formed.

• In der Brennkammer 1 wird durch die Tür 3 auf dem Gitterrost 4 ein leicht zu entzündeter Stoff - Brennholz - aufgestellt und angezündet.

The boiler works in the following way:

• In the combustion chamber 1, an easily inflamed material - firewood - is set up and lit by the door 3 on the grate 4.

Through the hatch 2, a set of coal of different fraction is fed to the firing layer. After the firing of the firewood and the laying of the foundation of a coal charge the fan 16 is started, which compresses through the channels 15 and 17, the oxidizing agent - the air - in the annular clearance 11 and the ash case 5 accordingly. The oxidizing agent from the ash deposit 5 passes through the grate 4 directly into the zone of the firing layer and accelerates the burning process of Coal and the process of separation of pyrolysis gases in the combustion chamber. In the combustion chamber 1 is a deep decomposition of organic carbon on solid and gaseous fractions happens. The gases accompanying the thermal reactions pass through the apertures 10 into the annular clearance 11 in which the combustion reaction steps proceed at a significant rate and enter the reaction chamber 12 through the apertures 14. In the reaction chamber 12 the temperature is at the expense of a high concentration of infrared radiation raised from the walls formed by their oval profile. This ensures an optimal burning rate of fire gases. The fuel gases pass through the catalyst 18, z. Oxidation support (SiO 2, Al 2 O 3 and SiC), where a decomposition reaction of the final hydrocarbons takes place. Their firing process is terminated with formation with the exit of thermal streams passing through the heat exchanger 19, where intensive cooling occurs, and then they pass through the chimney 20 into the external environment.

The loaded into the combustion chamber 1 fuel lowers depending on its burning under its own weight and requires no additional feeders.

The heating boiler of the offered construction has a high efficiency, corresponds to the conditions of an ecological and a fire safety and is besides user-friendly. An industrial sample has been made and thermal tests have been carried out to determine the efficiency and standards of harmful discharge efficiency in the atmosphere.

Claims (2)

Heating boiler with a fire chamber, in the combustion chamber (1) a Nachbrennkammer (7) in the form of a horizontally located cylindrical tube (8) with an anaesthetized end face and openings (10) on its surface and an ash deposit (5) are arranged with a supply source (fan 16) of oxidizer, and comprising a heat exchanger (19) and a flue pipe connected to each other via exhaust ducts (15, 17), characterized
in that the afterburner chamber (7) is formed with longitudinal inclined edges (9) on its side surface with openings (10) therebetween,
that a reaction chamber (12) in the form of a cylinder (13) with openings (14) on its side surface provides the post-combustion chamber (7),
that the cylinder (13) coaxially in the reaction chamber (12) with an annular clearance (11) is placed,
in that the cylinder (13) is connected to an oxidant supply forcible passage (15) and
in that the reaction chamber (12) is connected to a heat exchanger (19) via a catalyst (18), the catalyst (18) being set up in the free end face of the reaction chamber (12). Heating boiler according to claim 1,
characterized,
in that guide rails of the cylindrical tube (8) of the afterburner chamber (7) and of the reaction chamber (12) are in the form of ovals whose large axes are oriented perpendicular to the base of the combustion chamber (1).

Images