RU2725338C2 - Continuous burning boiler - Google Patents

Abstract

FIELD: fuel combustion methods and devices.SUBSTANCE: invention relates to continuous burning boilers. Continuous burning boiler comprise waterproof housing equipped with exhaust pipe, in cavity of which there is a furnace with upper loading hatch, ash pit of which is separated by horizontal grate plate with grates, equipped with vertical grate grid. Vertical grate grid has vertical grates and forms vertical cavity over furnace height, made in the form of cylindrical annular gap with wall of furnace or containing separate segments, which is located on periphery of furnace and is connected with ash pit and exhaust pipe, wherein grates of vertical and horizontal grate grids are hollow, rectilinear and parallel. At that, their chambers are interconnected with cavity of waterproof case.EFFECT: invention is aimed at improvement of combustion efficiency of solid fuel loaded into boiler.1 cl, 3 dwg

Description

The invention relates to the field of energy and can be used in autonomous heating systems, preferably for private and small buildings, as a solid fuel boiler of long burning.

A long-burning solid fuel boiler is known, comprising a housing that consists of an external and an internal heat exchanger tanks, the space between which is filled with a coolant and in the last of which there is a loading hole, a furnace with a grate and an ash pan (see UA No. 60970, F24H 1/24, 2011). At least one gas duct is installed in the inner tank, the intake part of which is connected through an opening to the air intake and through the injection channel to the lower part of the furnace, and the outlet part is led out to the upper part of the furnace.

The disadvantage of this boiler is the inefficient burning of solid fuel and the low environmental characteristics of the emissions of the boiler.

A solid fuel boiler of long burning is also known, containing a waterproof casing equipped with an exhaust pipe, in the cavity of which, with a gap for placing water, a furnace is placed, the blower of which is separated from the furnace space by a horizontal grate, and the furnace is equipped with a vertical grate and an upper loading hatch ( see RU No. 2092746, F24H 1/36, 1991).

The disadvantage of this boiler is the insufficiently efficient combustion of solid fuel since the vertical grate is formed in the middle of the boiler coaxially with its vertical axis, therefore, the fuel combustion process occurs in the lower part of the furnace (above the horizontal grate) and around the vertical channel, while the heat from the fuel burns does not go to the walls of the furnace, since the latter are protected by a layer of fuel.

The objective of the invention is to increase the efficiency of burning solid fuel loaded into the boiler.

The technical result obtained when solving the problem of the invention, ensuring the transfer of heat from fuel combustion to the walls of the furnace.

The technical problem is solved due to the fact that a long-burning boiler containing a waterproof casing, equipped with an exhaust pipe, in the cavity of which there is a firebox, with a top loading hatch, blowing which is separated by a horizontal grate, equipped with a vertical grate, forming a vertical cavity along the height of the firebox, characterized in that at least two vertical cavities are made, which are located on the periphery of the furnace, communicated with the blower and exhaust pipe and separated from its rest by a vertical grate with vertically oriented grates, while the grates of the vertical and horizontal grate are hollow, moreover, their cavities are in communication with the cavity of the waterproof housing. In addition, the grate of the vertical and horizontal grate grates are made parallel and rectilinear. In addition, the perimeter of the vertical cavities is formed by the wall section of the furnace and the associated vertical grate. In addition, the exhaust pipe is in communication with the exhaust pipe in communication with one of the vertical cavities below the upper end of the boiler.

A comparative analysis of the features of the claimed solution with the features of the prototype and analogues indicates the compliance of the claimed solution with the criterion of "novelty."

Moreover, the totality of the features of the characterizing part of the claims provides an increase in the efficiency of burning solid fuel loaded into the boiler, and the distinguishing features of the characterizing part of the claims provide a solution to the following set of functional tasks.

Signs indicating that “at least two vertical cavities are made that are located on the periphery of the furnace” provide direct transfer of heat from the fuel combustion to the furnace walls on the horizontal grate, and part of this heat is transferred to the pyrolysis of the fuel in contact with the vertical cavities, maintaining this burning and the possibility of imparting a column of coal of transverse dimensions, providing air supply "throughout the thickness" of the fuel volume.

Signs indicating that the vertical cavities are "communicated with the blower and exhaust pipe" provide the necessary air circulation through the boiler furnace and thereby the possibility of supplying air and heat to the vertical surfaces of the solid fuel in contact with the vertical grate.

Signs indicating that the vertical cavities of the furnace are "separated from the rest by a vertical grate with vertically oriented grates" set the design parameters of the grate, providing the possibility of "automatic" downward displacement (by gravity) of loading solid fuel as it burns out on a horizontal grate and vertical surfaces of coal loading.

Signs indicating that “the grid-irons of the vertical and horizontal grid-irons are hollow, and their cavities are connected to the cavity of the waterproof housing” provide cooling of the grid-irons preventing them from burning out and increase the heat removal generated by burning coal, redirecting it to the cavity of the waterproof housing and increasing the boiler efficiency as a whole .

Signs indicating that “the perimeter of the vertical cavities is formed by a section of the furnace wall and the vertical grate connected with it” define the conditions under which the formation of vertical cavities on the periphery of the furnace is possible.

Signs indicating that “the grid-irons of the vertical and horizontal grid-iron gratings are made parallel and rectilinear” increase the area of heat-removing surfaces of the grate-iron grates and simplify the manufacture of grate-burners.

Signs indicating that “the exhaust pipe is in communication with the exhaust pipe communicated from one of the vertical cavities below the upper end of the boiler” provides “the formation of a thermal dome” that holds as much as possible the portion of the outgoing gases that have risen into the thermal dome and remain in this vertical trap ( vertical cavities described above) until it cools, transferring heat through the steel wall of the boiler to a heat transfer fluid that cools the furnace wall and helps to remove the thermal energy of hot gases from the heat dome, which increases the efficiency of the boiler as a whole and reduces the temperature of hot gases at the inlet to the exhaust pipe, helping to increase the life of the exhaust pipe (chimney).

In FIG. 1 schematically shows a vertical section through a boiler using upper collectors; in FIG. 2 schematically shows a vertical section through a boiler in the absence of upper collectors; in FIG. 3 schematically shows a view of the lower part of the boiler in a three-dimensional projection.

The drawings show a long-burning boiler containing a waterproof casing 1, an exhaust pipe 2, a furnace 3, a vertical cavity 4, a top loading hatch 5, blown 6, a horizontal grate 7, a vertical grate 8, parallel straight grates 9, a section of the wall 10 of the furnace 3, the gap 11 (water jacket) of the furnace 3, the inlet and outlet pipes 12 and 13, the gas outlet pipe 14, the lower manifolds 15 and the upper manifolds 16, grates 17 of the horizontal grate 7, the longitudinal axis 18 of the boiler. In addition, an intermediate manifold 19, an air inlet 20, a fuel 21, an ignition layer 22 are shown.

For example, a boiler is shown in the cavity of which there are two vertical cavities 4 placed symmetrically with respect to the longitudinal axis 18 of the boiler

A solid fuel boiler of long burning, contains a waterproof casing 1 (preferably provided with a heat-insulating layer - not shown in the drawings), equipped with an exhaust pipe 2. In the cavity of the waterproof casing 1 with a gap 11, a furnace 3 is placed (the furnace wall is the inner wall of the waterproof case 1). The gap 11 is made waterproof, with the possibility of using a furnace 3 as a water jacket, and is equipped with inlet and outlet pipes 12 and 13, respectively, of cold water inlet and hot outlet, gas outlet pipe 14 connects one of the vertical cavities 4 and the exhaust pipe 2.

The furnace 3 is equipped with an upper loading hatch 5. The blower 6 of the furnace 3 is separated from its overlying volume by a horizontal grate 7 (the gap between the grates is about 20 mm). The horizontal grate 7 contains two parallel lower collectors 15, made tubular, while the ends of the collectors are in communication with the cavity of the gap 11 and hermetically fastened to the walls of the furnace, and the grate 17 of the horizontal grate 7 made hollow (tubular), placed parallel to each other, and their ends are tightly connected with the collectors.

The two upper collectors 16 lie in the same plane with the corresponding lower collectors 15, while parallel rectilinear grates 9 are made hollow (tubular), placed parallel to each other. Their upper ends are hermetically connected to the upper collectors 16, and the lower ones to the lower collectors 15. It is possible that the lower ends of the rectilinear grates 9 are also tightly connected to the lower collectors 15, and their upper ends are not hermetically communicated with the upper collectors 16, but directly with the upper part of the boiler water jacket (in this case, the upper collectors 16 are absent).

The vertical cavity 4 in the volume of the furnace 3 can be made in the form of a cylindrical annular gap with the wall of the furnace or contain several separate segments without forming a continuous annular cavity. For example, a boiler is shown in the cavity of which there are two vertical cavities 4 placed symmetrically with respect to the longitudinal axis 18 of the boiler

The gas outlet pipe 14 connects one of the vertical cavities 4 and the exhaust pipe 2.

And in the first and second case, the vertical cavity 4 in the volume of the furnace 3, to its entire height, is formed by a vertical grate 8 made of parallel rectilinear grates 9 (the gap between the grates is about 20 mm).

Vertical cavities 4 (if there are several) or one (if it is circular or sector) are located on the periphery of the furnace 3, are aerodynamically communicated from below with a cavity 6, and above - with a gas outlet 14 connected to the exhaust pipe 2. The volume of the blower should accommodate the entire the amount of ash obtained when the furnace is fully loaded with coal (calculated taking into account the highest ash content of coal grades used for burning).

In addition, the perimeter of each vertical cavity (if there are several) is formed by a section of the wall 10 of the furnace 3 and the associated vertical grate 8 connected to it.

The work of the proposed boiler is as follows.

Water is poured into the gap 11 (cavity of the water jacket) through the inlet pipe 12 until it is completely filled, after which the gap 11 is connected to the heating system by means of the outlet pipe 13. Then, a layer of wood pulp is laid on the horizontal grate 7 for subsequent ignition of coal (ignition layer 22) then, through the upper loading hatch 5, the remaining volume of the furnace 3 (except for the volumes of the vertical cavities) is filled with solid fuel 21 (coal) and ignited, for example, with a household gas burner (via blown 6) a layer of wood pulp. After the ignition of coal in contact with wood pulp, the combustion process is in the "automatic mode". In this case, the combustion products, together with the air flow coming through the blower 6 and then through the slots between the grates of the horizontal grate 7, interact with the lower layer of coal, and also fall into the vertical cavities 4 where they interact (through the gaps between the parallel rectilinear grates 9 of the vertical grate gratings 8) with a vertical layer of coal adjacent to the grate.

With appropriate control of the volumes of air supplied, direct heat transfer (from burning fuel on the horizontal grate) to the vertical surface of coal in contact with the vertical grate leads to pyrolysis of this part of the fuel. In addition, there is an intensive direct transfer to the walls of the furnace of heat from fuel combustion on the horizontal grate.

Further, along the vertical cavities 4, the combustion products flow upward, so that the hottest volume of gases accumulates at the top in the thermal dome (formed due to the displacement of the exhaust pipe 14 downward from the upper end of the boiler), while water is “cooling this volume” in the boiler’s water jacket and forcing it out with new portions of hot gas, gradually the lower boundary of the thermal dome falls to the exhaust pipe 14 through which the cooled gases fall into the exhaust pipe 2 and are removed into the atmosphere.

Under the action of heat from burning fuel, the water in the gap 11 (cavity of the water jacket) is heated and fed to the circulation through a heating system (not shown) and, thereby, heats the room.

As the fuel burns in the furnace 3, the ash and slag through a horizontal grate 7 by gravity go into the blower 6 from the bottom of the furnace 2, and a layer of coal is pressed in their place (under their own weight) adjacent to the burned out one. In this case, air freely enters the combustion zone from the bottom of the fuel column and onto its vertical surfaces in contact with the vertical cavities 4. As the fuel burns, slag and ash are removed from the blower 6, and the next portion of coal is poured into the furnace, and the process continues.

The use of the invention will improve the operational quality of the heating boiler and ensure a guaranteed continuous combustion process during long-term operation of the boiler without constant monitoring and maintenance of the combustion process.

Claims (1)

A long-burning boiler containing a waterproof case equipped with an exhaust pipe, in the cavity of which there is a firebox with an upper loading hatch, the blower of which is separated by a horizontal grate with grates, equipped with a vertical grate, characterized in that the vertical grate has vertical grates and forms a vertical cavity the height of the furnace, made in the form of a cylindrical annular gap with the wall of the furnace or containing separate segments, which is located on the periphery of the furnace and communicated with the blower and exhaust pipe, while the grid-irons of the vertical and horizontal grid-iron gratings are hollow, rectilinear, parallel, and their cavities are communicated with cavity waterproof housing.

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