KR100762077B1 - Combustion apparatus for R.P.F Boiler - Google Patents

Abstract

The present invention is a solid fuel boiler using the heat generated by burning a solid fuel (RPF: Refuse Derived Fuel), by installing a spiral air nozzle in the combustion furnace to increase the combustion efficiency and burned The present invention relates to a combustion device for a solid fuel boiler, in which ash is reburned again to prevent loss of fuel and maximize fuel efficiency.

Heat and dry gas generated by burning solid fuel in the combustion furnace 100 are re-burned and recovered and used as hot water and hot air, and the combustion gas is exhausted through the semi-dry absorption tower 400 and the bag filter 500. In the configured solid fuel boiler,

Spiral air nozzles (1,1 ') are installed on the great (101, 101') in which the solid fuel is combusted and installed downward in the combustion furnace (100) so that the combustion air is cyclone into the combustion furnace (100). Air nozzles (2,2 ') for supplying combustion air to reburn the incompletely burned solid fuel at both sides of the inlet of the reprocessing device (300) through which the burned incinerator is discharged. It is characteristic of one thing.

Solid fuel boilers, solid fuel boilers, solid fuels, RPF boilers, solid fuel boilers, solid fuel boilers

Description

Combustion apparatus for solid fuel boiler {Combustion apparatus for R.P.F Boiler}

1 is an overall configuration diagram of a boiler for solid fuel to which the present invention is applied

2 is an excerpt configuration diagram of a combustion apparatus to which the present invention is applied

Figure 3 is an enlarged view of the main portion excerpt of the present invention

4 and 5 is an enlarged view of the excerpt of the present invention

☞ Explanation of the main symbols used in the main part of the drawing ☜

100: combustion furnace 200: waste heat boiler

300: reprocessing device 400: semi-dry absorption tower

500: bag filter 600: re-feeding device

101,101 ': Great

1,1 ': Spiral air nozzle 11: Coil pipe

12: Supply pipe 13: Nozzle ball

2,2 ': Air nozzle 21: Coil pipe part

22: supply pipe 23: nozzle ball

The present invention relates to a combustion apparatus for a solid fuel boiler, and more particularly, in a solid fuel boiler using a heat generated by burning a solid fuel (RPF: Refuse Derived Fuel), The present invention relates to a combustion apparatus for a solid fuel boiler, in which a spiral air nozzle is installed in a combustion furnace to increase combustion efficiency and to reburn the combusted ash once again, thereby preventing fuel loss and maximizing fuel efficiency.

Solid fuel (RPF: Refuse Derived Fuel) developed as one of the alternative energy sources due to the depletion of petroleum resources sorts and combusts flammable wastes generated from workplaces and household wastes, and then crushes, dries, compresses and desorbs them. Refers to the manufacture of solidified fuel through injection of chlorine and additives, forming process, etc.

These solid fuels are not only inexpensive due to high calorific value and waste regenerated as fuel, but also economical benefits from the recycling of waste resources. It has many advantages, such as no equipment, and is widely used as an alternative energy in various industries and farming and fishing villages where oil cost is high.

    As described above, solid fuel boilers of various structures capable of supplying thermal energy necessary for various industrial sites by burning solid fuels are known from Patent Publication Nos. 2004-0107168 and No. 20-0319212 and 20-0390958. And, looking at the solid fuel boiler related to the present invention.

    Looking at the solid fuel boiler in accordance with the present invention; As shown in FIG. 1, a combustion furnace 100 in which solid fuel is supplied and combusted in a fuel reservoir is configured, and several stepped grate 101, 101 ′ in which solid fuel is injected and combusted are installed in the combustion furnace 100. The combustion operation of the solid fuel is made, the heat and dry gas generated while the solid fuel is combusted in the combustion furnace 100 are reburned and recovered in the waste heat boiler 200, and used as hot water, hot air, etc., and the combustion gas is a semi-dry type. It is configured to exhaust through the absorption tower 400, the bag filter 500, and the like.

   The conventional solid fuel boiler has a great step (101, 101 ') is installed in the multi-stage staircase in the combustion furnace 100 for burning solid fuel and the air nozzle is configured to supply the combustion air below the great (101, 101') Combustion of the fuel takes place.

  In this combustion operation, the combustion air supplied from the blower into the combustion furnace 100 through the air nozzle is distributed in a straight line so that the air supply is partially and deflected so that the combustion air is not diffused widely in the combustion furnace. It was not mixed enough with the fuel, so the combustion rate was high and the combustion efficiency was low.

   In the combustion process with high incombustibility, many incompletely burned solid fuels are discharged, leading to various problems such as loss of fuel.

   That is, the incineration ash of the solid fuel burned in the combustion furnace 100 is discharged to the outside through the reprocessing device 300 is transferred and processed through the retransmission device 600, in which the lump form is not completely burned Incineration of incompletely burned solid fuel is also discharged as it is, so there is not much waste of fuel, resulting in low combustion efficiency and low thermal efficiency.

In the present invention, by installing a spiral air nozzle on the grate in the combustion furnace in which the solid fuel is injected and combusted, the combustion air can be diffused more widely supplied to mix well with the fuel, thereby improving the combustion efficiency,

By installing an air nozzle supplying combustion air in front of the reprocessing device where the burned incinerator is discharged, the solid fuel material which is not completely burned is reburned before discharge, thereby minimizing fuel waste and maximizing combustion efficiency. will be.

1 is an overall configuration diagram of a solid fuel boiler to which the present invention is applied, FIG. 2 is an excerpt configuration diagram of a combustion apparatus to which the present invention is applied, FIG. 3 is an enlarged view of an excerpt of the present invention, and FIGS. An enlarged view of the main excerpts.

In the present invention, the solid fuel injected from the fuel reservoir is burned in the combustion furnace 100, and the heat and dry gas generated therefrom are reburned and recovered in the waste heat boiler 200, and used as hot water, hot air, and the combustion gas is a semi-dry absorption tower. In the solid fuel boiler configured to exhaust through the 400 and the bag filter 500, etc.,

Spiral air nozzles 1 and 1 'are installed on the bottom or side surfaces of the great 101 and 101' which are installed in a stepped downward shape of the combustion furnace 100, and the inlet of the reprocessing apparatus 300 of the combustion furnace 100 is also provided. Characterized in that the air nozzles (2, 2 ') for the reburn of the incompletely burned solid fuel, characterized in detail below with respect to the configuration of the present invention.

Spiral air nozzles 1 and 1 'are provided on the respective Great 101 and 101' which are stepped downward in the combustion furnace 100. As shown in FIG.

The spiral air nozzles 1 and 1 'installed on the grate 101 and 101' form a coil pipe part 12 formed by coiling a portion of the end of the supply pipe 12 into a supply pipe 12 connected to the blower. The combustion air supplied from the gas is injected into the vortex via the coil pipe part 12 to cause the cyclone (Cyclone) in the combustion furnace 100 to be supplied to diffuse the supply of the combustion air in the combustion furnace (100) It mixes well with solid fuels and promotes combustion.

It will be apparent that the spiral air nozzles 1 and 1 'should be formed such that the nozzle hole 13 has a turning angle so that combustion air is supplied into the combustion furnace 100 through the coil pipe part 12 in a vortex.

Meanwhile, air nozzles 2 and 2 'are installed on both sides of the inlet of the ash door 301 through which the incineration ash of the burned solid fuel is discharged to the reprocessing apparatus 300 to reburn the incineration ash of the incompletely burned solid fuel. do.

The air nozzles 2 and 2 'supply combustion air to the incinerated ash of the incompletely burned solid fuel immediately before being discharged to the retransmission apparatus 600 through the reprocessing apparatus 300 to supply the solid fuel incinerator of the incomplete combustion state. By reburning, the loss of solid fuel is reduced and the combustion efficiency is increased.

The air nozzles 2 and 2 'are also composed of a coil pipe part 21 formed in a spiral shape at a portion of the end of the supply pipe 22 as in the case of the spiral air nozzles 1 and 1' described above. It may be desirable to allow combustion air supplied from the supply pipe 22 connected to the blower to be supplied to the vortex through the nozzle hole 23 while passing through the coil pipe part 21 to increase combustion efficiency by diffusion supply of the combustion air. .

In this case, too, the nozzle hole 23 of the air nozzles 2 and 2 'is formed such that the nozzle hole 23 has a turning angle so that combustion air can be supplied while causing vortex flow through the coil pipe part 21.

The present invention configured as described above can maximize the combustion efficiency of fuel by supplying combustion air that is more widely spread through the spiral air nozzles (1,1 ') formed on the Great (101, 101') of the combustion furnace 100. In addition, by supplying the combustion air through the air nozzles (2, 2 '), the combustion incineration ash is reburned and treated before being discharged, thereby reducing the loss of fuel and increasing the combustion efficiency.

The solid fuel boiler is burned while the solid fuel is supplied into the combustion furnace 100 and passes through the great steps 101 and 101 'formed in a downward step shape, and heat and dry gas generated at this time are burned again in the waste heat boiler 200. The recovered ash is used for hot water, hot air, and the like, and the incinerated ash is discharged through a reprocessing apparatus.

The great 101 and 101 ′ in the combustion furnace 100 in which solid fuel is injected and combusted are richly and quickly supplied with combustion air as the combustion air supplied in the vortex form into the combustion furnace 100 via the coil pipe part 11. It is made to maximize the combustion efficiency.

    The spiral air nozzles 1, 1 ′ formed on the great 101, 101 ′ of the combustion furnace 100 are connected to the coil pipe part 11 while the air passing through the coil pipe part 11 enters the combustion furnace 100. It is injected by the injection to cause the vortex from the inside, a large amount of air in a short time is evenly and widely spread and supplied throughout the combustion furnace 100, and the solid fuel is mixed with the combustion of the solid fuel more actively The efficiency will be greatly increased.

In addition, the air nozzles 2 and 2 'installed at both sides of the inlet of the ash door 301 of the reprocessing apparatus 300 through which the burned incineration ash is discharged to the retransmission apparatus 600 are incompletely combusted in the Great 101 and 101'. Combustion air is supplied to the incinerated ash to be reburned.

That is, the air nozzles 2 and 2 'supply combustion air to the incompletely burned incineration ash immediately before being discharged to the retransmission apparatus 600 through the reprocessing apparatus 300 to reduce the loss of fuel and burn the fuel. It is to increase the efficiency.

In addition, when the air nozzles 2 and 2 'for supplying the combustion air are also helically configured as the spiral air nozzles 1 and 1' described above, the combustion air is supplied to the vortex to increase its combustion efficiency. will be.

As described above, in the solid fuel boiler, the helical air nozzles 1 and 1 'are installed in the combustion furnace 100 to increase the combustion efficiency by spreading and supplying the combustion air more widely and evenly.

Air nozzles (2,2 ') are provided at the inlet of the reprocessing device (300) for the supply of combustion air, and the fuel is burned again and discharged again to discharge the burned incineration ash, thereby reducing the loss of fuel and maximizing the combustion efficiency. This can lead to various economic benefits, such as increasing thermal efficiency and minimizing fuel waste.

Claims (3)

Heat and dry gas generated by burning solid fuel in the combustion furnace 100 are reburned and used as hot water, hot air, etc., and the combustion gas is exhausted through the semi-dry absorption tower 400 and the bag filter 500. In the configured solid fuel boiler, Spiral air nozzles (1,1 ') installed in the combustion furnace (100) in a step-down manner and supplying combustion air to the inside of the combustion (100) cyclone (Cyclone) on the great (101, 101') where the solid fuel is burned. Combustion device of a solid fuel boiler, characterized in that installed). The method of claim 1, The spiral air nozzles 1 and 1 'form a coil pipe part 11 formed by coiling a portion of the end of the supply pipe 12 and form a nozzle hole 13 having a turning angle to supply a supply pipe connected to the blower. Combustion air supplied from (12) is injected into the vortex via the coil pipe portion (11) is a combustion apparatus for a boiler for solid fuel, characterized in that to be supplied by causing a cyclone (Cyclone) in the combustion furnace (100). delete

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