RU2376525C1 - Hot water boiler furnace - Google Patents

Abstract

FIELD: heating systems.

SUBSTANCE: invention refers to industrial and public heat engineering, and namely to heat supply, and can be used in low-power hot water boilers. Hot water boiler furnace includes hopper fuel supply system, air supply system and ash disposal system with ash discharge opening; at that, grates of full supply system are made at least in the form of four in-series and overlapped hinged transverse rows of grates, from which, for example uneven ones are mounted on rod and kinematically connected drive and even ones are rigidly connected to steady furnace bottom; on external surface of grates at least one protrusion is made; at furnace bottom an ash discharge opening is made, which is provided with hinged pendulum-type grate with counterbalance. At that, furnace is also equipped with air supply channel to hopper fuel outlet zone.

EFFECT: simplifying hot water boiler design and providing furnace operating reliability.

8 cl, 4 dwg

Description

The invention relates to the field of industrial and municipal heating, in particular 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 during the combustion of coal and works with forced circulation of water at a working pressure of up to 0.6 MPa and a temperature of water heating up 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, pp. 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 ZAO Biyskenergomash, are known as a prototype, see the catalog Boilers and Boiler Accessories of ZAO PO Biiskenergomash TsNIITEItyazhmash, Moscow 1999 , pp. 94-95, containing a firebox with grates in the base, a screwing bar (Fig. 71) of a mechanical, monoblock, designed for burning stone and brown coals, 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 boiler - the prototype - include the fact that the boiler has a rather complicated design, low efficiency of coal combustion, low reliability of the screwing bar, including when using sintering coals, heat loss.

The technical task of the present invention is to eliminate the disadvantages of the prototype, in particular, simplifying the design of the boiler, increasing the efficiency of fuel combustion and improving the reliability of the furnace and boiler as a whole.

The technical problem posed by the present invention is achieved by the fact that the grid-irons in the fuel supply system are made of at least four successively and overlapping pivotally mounted transverse rows of grid-irons, which, for example, are odd, are mounted on the rod and kinematically connected to the drive, and even ones are rigidly connected with a fixed base of the furnace, while at least one protrusion is made on the outer surface of the grid-irons, the window for unloading ash, made on the base, is pivotally mounted a pendulum-type grate with a counterweight, while the furnace is additionally equipped with an air supply channel to the fuel exit zone from the hopper.

In each row of the furnace grates, the protrusions on the outer surface are at least made on two grates.

The protrusions on the outer surface of the even and odd rows of grates are made mismatched along the longitudinal line of the reciprocating movement of the grates.

The height of the protrusions of the grates on the outer surface is made of 0.5-1.0 of the maximum height of the layer of coal located on the grate of the furnace.

The injection of air to the burning fuel layer is carried out using at least two zones of blast, equipped with flaps that regulate the volume of air supply to each zone.

The grate of the grates to the horizontal is made from 10 to 30 degrees.

The coal bin is mounted above the first rows of even and odd grates.

At least one hole is made between the longitudinal sides of the grates in contact with each other in each transverse row.

The novelty of the proposed boiler is the implementation of grates in the fuel supply system, at least in the form of four sequentially and overlapping pivotally mounted transverse rows of grates, which, for example, are odd, are mounted on the rod and kinematically connected to the drive, and even ones are rigidly connected to the fixed base of the furnace at the same time, at least two protrusions are made on the outer surface of the grid-irons, the window for unloading the ash, made on the basis of the furnace, is provided with an articulated grate m pendulum type with a counterweight, while the furnace is additionally equipped with a channel for supplying air to the zone of fuel exit from the hopper.

These signs are new, non-obvious, industrially feasible, giving an unexpected additional positive effect of the destruction of the coked (sintered) layer of coal during its movement along the furnace without operator intervention, providing additional afterburning of coal on the grate, aimed at achieving the simplified boiler design posed by the invention and increasing the efficiency of fuel combustion and its reliability.

So, during the reciprocating movement of the furnace grate, solid fuel - coal, easily moves along the path of the grate, while moving in horizontal and vertical planes, while simultaneously loosening the surface of the coal layer and providing intensive access of air oxygen to the entire volume of burning fuel. The presence of protrusions on the grate and the alternate raising and lowering of the coal layer due to the movement of the moving grate contribute to the breaking of the sintering layer of coal and its efficient combustion, including the burning of coal on the pendulum grate. The presence of an additional air supply channel to the fuel exit zone from the hopper creates conditions that prevent overheating of the boiler wall facing the hopper, provides additional drying of the fuel and increases the amount of air supplied to the furnace.

Signs of the execution of the protrusions of the odd and even grid-irons mismatching or coinciding along the longitudinal line of their reciprocal translational movement, the execution in each row of the grid-irons of the furnace of the protrusions on the outer surface of at least two grid-irons, the execution of the protrusions of the grid-irons on the outer surface of 0.5-1.0 the maximum height of the layer of coal located on the grate of the furnace, the inclination of the grate to the horizontal from 10 to 30 degrees, as well as the injection of air to the burning layer of fuel with at least two blast zones, provides gas flaps that regulate the volume of air supply to each zone, the installation of a coal hopper above the first rows of even and odd grates and the execution of at least one hole between the longitudinal sides of the grates in each transverse row are additional signs that contribute to the achievement of the technical invention tasks revealing the specific design of the main features of the furnace. Thus, the presence, coincidence or mismatch of the protrusions of the grid-irons in the longitudinal direction, their height, inclination and alternation make it possible to destroy the fuel, which is prone to sintering when moving along the transverse rows of the grid-irons, contribute to the mixing of the fuel, which affects the combustion efficiency of the fuel, the efficiency of the furnace and boiler generally. The presence of several zones of supply of blast allows you to change the modes of burning coal - when, for example, more air is supplied to the beginning of the furnace, intensify the combustion process at the beginning and vice versa. The presence of additional openings between the side surfaces of the grates provides better air access to the entire volume of burning fuel.

Figure 1 schematically shows the proposed furnace of a hot water boiler - a longitudinal section aa.

Figure 2 is a cross section bb in the pre-furnace with additional air supply channels.

Figure 3 shows a fragment of the grate with one protrusion on the outer surface.

Figure 4 shows the holes between the sides of the grate.

The combustion chamber of a hot water boiler proposed as an invention consists of a base 1, on which movable 2 and fixed 3 grid-irons with a rod 4 are mounted in transverse rows. On the base 1, a hopper 5, a rod 4, a drive 6. is mounted. The protrusions 7 are made on the outer surface of the grid-irons 2 and 3 for breaking sintering-prone coal. From the hopper 5, the coal is lowered onto the grates 2 and 3. The thickness of the coal layer on the transverse rows of the grates 2 and 3 is regulated by the stopper 8 mounted on the hopper 5 in front of the pre-furnace 9. On the base 1 at the end of the furnace there is a window 10 for unloading ash which is closed by a pivot-mounted grate 11 of a pendulum type with a counterweight 12. Air supply to the furnace is carried out using at least two blast zones 13 and 14 (three zones are shown, third zone 15), equipped with shutters 16 and 17. Additional channels 18 and 19 innings air in the furnace extension mounted laterally of the furnace and are connected to one of two blast zones, such as zone 13. The blowing openings 20 between the side surfaces of the grate are formed poluovalami formed on the sides of the grate opposite each other, which provide additional air flow to the burning fuel.

The proposed furnace of a hot water boiler operates as follows.

From the hopper 5, the fuel, under the influence of its own weight, enters the grates 2 and 3, which are located at the beginning of the furnace under the hopper. When you turn on the actuator 6 of the rod 4, the latter begins to perform reciprocating movements, portionwise with the grates 2 and 3, moving the coal deep into the furnace. At the same time, air is supplied to the pre-furnace 9 behind the hopper 5 through additional channels 18 and 19, cooling the wall of the hopper 5 facing the boiler furnace, and preventing its warping and possible burning out. Further, the fuel, with periodic exposure to it of movable (odd) 2 and motionless (even) 3 grid-irons and protrusions 7, continues to burn and move along the firebox. In the case of using coal, which is prone to sintering during combustion, the protrusions 7 and the grates 2 and 3 provide effective breaking of the sintered layer of coal and ensure its intense combustion. The breaking of the coal layer is facilitated by the protrusions 7 mounted mismatched, or alternatively matching along the longitudinal line of the reciprocating movement of the grates 2 and 3. Performing the guts of the grates on the outer surface of 0.5-1.0 of the maximum height of the coal layer located on the grate of the furnace, allows you to effectively break the starting sintering coal. So, when the height of the protrusions is less than 0.5 of the height of the coal layer, a situation may arise when the surface layer of coal does not collapse, and at a height greater than the height of the coal layer, it is impractical to increase the height of the protrusions. Performing the inclination of the grate to the horizontal from 10 to 30 degrees allows you to effectively obtain the optimum heat transfer from the combustion in accordance with the rate of combustion of coal.

The installation of a coal bunker over the first rows of even and odd grates allows, starting from the first portions of coal coming from the bunker, to dispense metered coal deep into the furnace until it is completely burned.

The implementation between the longitudinal sides of the grates in contact with each other in each transverse row of at least one hole formed by semi-shafts made on opposite sides of the grate, contributes to a better supply (injection) of air into the furnace and, accordingly, contributes to better combustion of coal.

As the coal moves along the furnace, the unburned coal and ash are moved to the grate of the pendulum type 11 by the grid-irons. As soon as the weight of ash accumulated on the grate 11 exceeds the weight of the counterweight 12, the grate 11 overturns for a short time. At this time, ash is poured from the grate 11 and, under the influence of the counterweight 12, the grate again closes the window 10 to remove ash. In each row of the furnace grates, the protrusions on the outer surface are at least made on two grates.

To ensure intensive combustion of fuel, air is supplied (forced) to the combustion chamber through several zones of blast 13 and 14. The drawing shows three zones of blast (third zone 15). The air supply volumes are regulated by shutters 16 and 17. If the fuel in the furnace does not burn completely, the air supply to the blast zone 14 (or 15) is increased. Since there can be 3, 4, or more blast zones, the process of coal afterburning is carried out by changes in the air supply to the furnace along the blast zones.

At present, the enterprise has developed working drawings for the proposed boiler heating chamber, manufacturing technology has been developed and several prototypes of furnaces have been manufactured, which were transferred to a number of enterprises for testing and operation to verify reliability and efficiency. After receiving information about the operation of prototypes of boilers, a decision will be made on the organization of their production.

Claims (8)

1. The furnace of a hot water boiler, including a hopper, a fuel supply system, an air supply and ash removal system with a window for unloading ash, characterized in that the grates in the fuel supply system are made of at least four successively overlapping transverse rows of grates of which, for example, the odd ones are mounted on the rod and kinematically connected to the drive, and the even ones are rigidly connected to the fixed base of the furnace, at least one protrusion is made on the outer surface of the grid-irons, a window for ash discharge is made on the base of the furnace, equipped with a pivotally mounted pendulum-type grate with a counterweight, while the furnace is additionally equipped with an air supply channel to the fuel exit zone from the hopper. 2. The furnace of the hot water boiler according to claim 1, characterized in that in each row of the grate of the furnace, the protrusions on the outer surface are made of at least two grates. 3. The firebox of the boiler according to claim 1, characterized in that the protrusions on the outer surface of the even and odd rows of grates are made mismatched along the longitudinal line of the reciprocating movement of the grates. 4. The furnace of the boiler according to claim 1, characterized in that the height of the protrusions of the grates on the outer surface is made 0.5-1.0 of the maximum height of the layer of coal located on the grates of the furnace. 5. The combustion chamber of a hot water boiler according to claim 1, characterized in that the air is injected to the burning fuel layer using at least two blast zones equipped with flaps that regulate the volume of air supply to each zone. 6. The firebox of the boiler according to claim 1, characterized in that the inclination of the grate to the horizontal is made from 10 to 30 °. 7. The firebox of the boiler according to claim 1, characterized in that the coal hopper is mounted above the first rows of even and odd grates. 8. The furnace of the boiler according to claim 1, characterized in that between the longitudinal sides of the contacting grates in each transverse row, at least one hole is made.

Images