RU68659U1 - WATER BOILER - Google Patents

Abstract

The utility model relates to the field of boiler construction, in particular to the designs of units and assemblies of boilers. A water boiler includes a fuel hopper, a furnace with a grate, a screwing bar and a drive, convective tube bundles, a forced air supply system to the boiler and heat carrier furnace into convective tube bundles, a wiring, while the grate is inclined from the fuel supply hopper, a screwing bar made in the form of a pendulum formed by a bar and two sidewalls, kinematically connected using the axis of rotation of a screwing bar mounted in the cavity of the boiler on its side walls with a crank drive, the furnace grate the boiler, like the base of the furnace, is made in the form of an arc, the pipe for supplying air to the furnace chamber of the forced air supply system to the furnace is made with a bell providing a uniform air supply over the entire height of the inclined grate, guides are installed in the socket that evenly distribute the air flow along the height of the grate, openings for the passage of air through the grate are made slotted across the entire width of the grate in the form of forward sloping forward slats partially overlapping one another, the slats, the tilt of the lattice strips is made from 0 to 15 degrees. Currently, the authors have made a prototype of the proposed boiler, which showed good preliminary results. Coal in the furnace easily moved along the generatrix of the base of the furnace, mixed well and burned. A decision was made after the completion of industrial-operational tests, the proposed boiler was put into production.

Description

The utility model relates to the field of industrial and municipal heat power engineering, namely to heat supply, and can be used in the construction of low-power hot water boilers.

Known hot water boiler containing a fuel hopper, a firebox with a screwing bar, a combustion chamber with a forced air system in the furnace, a system of slag removal and ash collection, as well as radiation and convective heat transfer zones. The hot water boiler is designed to generate thermal energy for heat supply systems of buildings and structures when burning coal and works with forced circulation of water at a working pressure of up to 0.6 MPa and a temperature of heating water to 95 ° C. The radiation surface of the combustion chamber and two stages of convective surfaces ensure the transfer of heat of the burning fuel to the water forcibly circulating through the pipes forming these surfaces. External lining of the boiler prevents heat leakage. See the manual for low-capacity boiler plants edited by K.F. Roddatis. M. Energoatomizdat, 1989. pg. 266-267.

The disadvantages of the known design of boilers include the instability of the combustion processes of fuel over time. After loading the fuel during the release of volatiles, there is a lack of air, which contributes to the formation of soot and creates explosive conditions in the areas of radiation and convective heat transfer of the boiler. A contradiction arises - in order to improve and increase the completeness of fuel combustion, it is necessary to supply more air to the fuel combustion zone. But with a larger air supply, heat losses with the gases leaving the boiler increase. In addition, due to the lack of the possibility of fresh air entering the entire volume of burning fuel, heat losses from underburning and incomplete combustion of fuel occur and, accordingly, a low efficiency.

More advanced water-heating boilers DSE-1,6-14C, USSHV-1,5-14C manufactured by PA Biyskenergomash CJSC are known - prototype - see the catalog Boilers and Boiler Accessories of PO Biiskenergomash CJSC TSNIITEityazhmash, Moscow 1999 , pp. 94-95, containing a firebox with a grate in the base, a screwing bar (Fig. 71) of a mechanical, monoblock, designed for burning coal and lignite, a combustion chamber with a forced air system into the furnace, and ash removal and ash collection systems. The thermal air-gas flow from the zone of radiation heat transfer sequentially passes to the bundles of convective heat transfer pipes. Famous boilers have the ability to upgrade to other, including non-traditional, fuels.

The disadvantages of the hot water boiler - the prototype - include the fact that the boiler has a rather complicated design, low reliability of the drive of the screwing strap and significant heat loss.

The technical task of this utility model is to eliminate the disadvantages of the prototype, in particular, simplifying the design of the boiler and increasing the efficiency and reliability of its operation.

The technical problem posed by the utility model is achieved by the fact that the grate is inclined from the fuel supply hopper, the screwing bar is made in the form of a pendulum formed by a bar and two sidewalls kinematically connected using the crank axis mounted in the cavity of the boiler on its side walls with a crank - connecting rod drive.

The grate of the boiler furnace, as well as the base of the furnace, is made in the form of an arc.

The pipe for supplying air to the combustion chamber of the forced air supply system to the furnace is made with a bell that provides uniform air supply over the entire height of the inclined grate.

At least two guides are mounted in the bell, which evenly distribute the air flow along the height of the grate.

The openings for the passage of air through the grate are made slotted over the entire width of the grate in the form of forward sloping slats that partially overlap one another.

The slope of the bars of the lattice is made from 0 to 15 degrees.

The boiler is equipped with a blower fan mounted in front of the bell of the forced air supply system.

Convective blocks are interconnected by a gas duct made in the form of a box hermetically connected to each of the convective blocks.

In the upper part of the boiler, a heat-insulated hatch is made for cleaning the coils of convective blocks.

The novelty of the proposed hot-water boiler is the design of the boiler lattice inclined from the fuel supply hopper, the making of a screwing bar in the form of a pendulum formed by a bar and two sidewalls, kinematically connected using the axis of rotation of the screwing bar mounted in the cavity of the boiler on its side walls with a crank drive. These signs are new, non-obvious, industrially applicable, giving an unexpected additional positive effect of a more complete combustion of fuel

when moving it uniformly-sequentially from the hopper, they are aimed at achieving the technical task posed by the invention to simplify the design of the boiler and increase the efficiency and reliability of its operation.

So, when moving the screwing plate along the arc (forming the base of the furnace of the grate), solid fuel - coal, easily moves along the path of the screwing plate easily and intensively mixes, while providing intensive access of atmospheric oxygen to the entire volume of burning fuel, the forced air supply system promotes fuel on an inclined grate. The design of the boiler and maintenance are greatly simplified.

The signs of the grate of the boiler furnace, as well as the base of the furnace, are made in the form of an arc, a pipe for supplying air to the furnace chamber of the forced air supply system to the furnace with a bell with guides providing uniform air supply over the entire height of the inclined grate, the cross-section in the form of a triangle with a hypotenuse at the base and an acute angle to the side opposite to the inclination of the lattice, as well as making holes for air to pass through the lattice with slots along the entire width of the lattice in the form of inclined from 0 to 15 degrees ahead, partially overlapping one another, strips, the presence of a blower fan installed in front of the bell of the forced air supply system, the convection blocks are connected to each other by a duct made in the form of a box hermetically connected to each of the convective blocks, and also the execution in the upper part of the boiler a heat-insulated hatch for cleaning coils of convective blocks - are signs of additional, new, industrially feasible, revealing the specific implementation of the main recognized to intensify

the process of fuel combustion along the height of the fuel layer, and also contribute to the mixing of the fuel and its movement along the combustion grate.

The openings for the passage of air in the furnace grate with slit made in the form of inclined steps prevents the fall of small, including unburned, fuel fractions through the furnace grate, and also contribute to more intensive mixing of the fuel moved by the screwing bar along the furnace grate.

Figure 1 schematically shows the proposed hot water boiler.

The hot water boiler proposed as a utility model consists of a furnace 1 with a screwing plate 2, a combustion chamber 3 (a radiative heat exchange surface), an air duct 4 for supplying air to the furnace 1, a slag removal system 5. A furnace grate 6 mounted at the base of the combustion chamber 3 is made inclined in arc form from the hopper 7. Convective unit 8 (first convective heating surface) and convective block 9 (second convective heating surface) are mounted sequentially in the wells 10 and 11 of the boiler along the air zovogo stream. From the hopper 7, the fuel under the action of its own weight when opening the gate 12 enters the most elevated part of the grate 6 and begins to heat up and burn. Further, the fuel is periodically exposed to a screwing plate 2 and is fed into the furnace 1. The screwing plate 2 is mounted in the cavity of the combustion chamber 3 using two sidewalls 13 fixed on a common axis 14. The screwing plate 6 is kinematically, using a crank mechanism (the mechanism not shown) is connected to the drive motor. Coal from the hopper 7 enters the furnace 1 when the gate is opened 12. The pipes of the radiation furnace chamber 3 and the pipes 8 and 9 of the convection zones of the boiler, as well as the wells 10 and 11 of the boiler are lined with heat-resistant fireclay brick 15. The bell 16 of the air supply system to the furnace with guides 17 covers the combustion grate 6 over its entire height. The fan 18 provides air injection into the combustion chamber. At the top

convective bundles of pipes made hatch 19 for cleaning the coils of convective blocks. Box 20 connects the ducts of convective blocks.

The proposed hot water boiler operates as follows:

Fuel (coal) from the hopper 7 when opening the gate 12, under the influence of its own weight, is portioned onto the arcuate lattice 6 of the base of the furnace 1, along which, as it burns, the screwing bar 2, mounted on the axis 14 using the sidewalls 13, periodically moves along the arcuate the lattice 6 deep into the furnace 1, where, by burning, it creates heat that is transferred to the radiation surfaces of the heat exchange of the combustion chamber 3 of the boiler pipes. Simultaneously from the fan 18, the air through the duct 4 and the bell 16 with the guides 17 located therein is evenly distributed along the height of the inclined grate 6, which contributes to a more complete and efficient combustion of fuel. At the same time, the drive of the screwing strap 2 gives the latter a reciprocating movement with the help of a crank mechanism. When periodically moving in one direction - to the bunker 7, the screwing bar 2, basically, raises the burning coal, since the angle of inclination from this side of the cross-section of the screwing bar is sharp and since the movement in this direction goes up, and when moving to the other side - from the hopper 7, the screwing bar 2 agitates and moves the fuel a certain distance forward along the working space of the grate 6. The furnace grate 6 is made in an arc, its inclination facilitates easier movement of coal deeper into the furnace 1. In pipes, it is furnace chamber 3 and pipes of the convective blocks of the boiler, the coolant is pumped sequentially and forcibly - water, which is gradually heated and subsequently supplied to heat residential, or industrial, depending on the purpose, premises. With the help of the duct 4 and the bell 16, to ensure a more intense combustion of coal, air is constantly supplied to the furnace, which penetrates through the slotted holes

lattice and contributes to a more complete combustion of fuel. The heated air-gas stream exiting the combustion chamber 3, having given part of the heat to the surfaces of the pipes of the radiation zone of the boiler combustion chamber 3, still has a high temperature and maintains a heat reserve, which is subsequently received by the pipes of the convection unit 8 of the first convection zone located in the first well 10 the boiler and pipes of the convection unit 9 of the second convection zone located in the second well 11. When the thermal air-gas flow from the combustion chamber 3 passes sequentially into the first and subsequent convection zones, last one encounters in its path established by convection tube banks, in which the coolant is circulated and starts them uniformly heated, transferring heat to the heat carrier located therein - water. At the second stage of convective heating in the well 11, heat transfer from the air-gas stream to the water circulating in the tube bundles of the second convective heat exchange zone continues. As the burning coal moves along the arcuate lattice 6, the coal burns and enters through the slag removal mechanism into the slag removal channel. When portioning the fuel when opening the gate 12, the interaction of parts and mechanisms of the boiler is repeated.

At present, the company has developed working drawings for the proposed hot-water boiler, has developed production technology, and produced several pilot boilers that have been tested and put into operation to verify reliability and efficiency.

After receiving complete information about the operation of prototypes of boilers, it was decided to organize their production.

Claims (9)

1. A hot water boiler, including a fuel hopper, a furnace with a grate, a screwing bar and a drive, radiation and convection blocks, a forced air duct to the boiler furnace and a coolant supply pipe to convective blocks, a lining, characterized in that the grate is inclined from the hopper fuel supply, the screwing bar is made in the form of a pendulum formed by a bar and two sidewalls, kinematically connected using the axis of rotation of the screwing bar mounted in the cavity of the boiler on its side walls with rivoshipno-crank drive. 2. The hot water boiler according to claim 1, characterized in that the grate of the furnace of the boiler, as well as the base of the furnace, is made in the form of an arc. 3. The hot water boiler according to claim 1, characterized in that the pipe for supplying air to the combustion chamber of the forced air supply system to the furnace is made with a bell providing uniform air supply over the entire height of the inclined grate. 4. The boiler according to claim 1, characterized in that at least two guides are mounted in the socket, evenly distributing the air flow along the height of the grill. 5. The hot water boiler according to claim 1, characterized in that the openings for the passage of air through the grill are slotted over the entire width of the grill in the form of forward sloping slats that partially overlap one another. 6. The hot water boiler according to claim 1, characterized in that the inclination of the bars of the grate is made from 0 to 15 °. 7. The boiler according to claim 1, characterized in that the boiler is equipped with a blowing fan mounted in front of the bell of the forced air supply system. 8. The hot water boiler according to claim 1, characterized in that the convective blocks are interconnected by a gas duct made in the form of a duct, hermetically connected to each of the convective blocks. 9. The hot water boiler according to claim 1, characterized in that in the upper part of the boiler a heat-insulated hatch is made for cleaning the coils of convective blocks.