KR101459327B1 - System for classification and supplying biomass to powerstation boiler - Google Patents

Abstract

The present invention relates to a system for supplying and classifying solid fuel to a boiler for thermal power generation including: a collecting step of collecting super-solid fuel; a wind power selecting step of separating light materials from heavy materials by wind; a volume selecting step of separating and removing materials which are too large or small in volume; a magnetic force selecting step of removing metal powder by a magnetic force; a storing step of storing the solid fuel in a rectangular silo having a plurality of compartments; a collecting step of collecting generated dust; a mixing step of mixing the collected dust with the stored solid fuel; and an inserting step of putting the solid fuel mixed with the dust into a boiler. The system for supplying and classifying solid fuel can enhance purity of the solid fuel by classifying according to weight, volume and magnetic force, select a proper solid fuel as occasion demands and put the selected solid fuel into a boiler of a thermoelectric power plant, and collect dust scattered to the outside and mix with fuel to reuse.

Description

FIELD OF THE INVENTION [0001] The present invention relates to a system for supplying and classifying solid fuel into a boiler for thermal power generation,

The present invention relates to a system for supplying and sorting a solid fuel to a boiler for thermal power generation, and more particularly, to a system for sorting and sorting the solid fuel into boilers of a thermal power plant, will be.

Generally, a power plant has a facility to convert thermal energy and mechanical energy into electrical energy, and it generates electricity through a generator connected to the turbine by rotating the turbine using energy sources such as water, oil, coal, natural gas, and nuclear power .

Among these various types of power plants, thermal power plants use fossil fuels such as coal as their main fuel sources, but fossil fuels are required to change to use renewable energy due to the problem of exhaustion of resources and environmental pollution.

However, existing thermal power plants must solve various problems in operating various solid fuels replacing fossil fuels.

Document 1: Registration Patent Publication 10-0779421 (Nov. 20, 2007) Document 2: Published Patent Application No. 10-2007-0084297 (Aug. 24, 2007)

Accordingly, it is an object of the present invention to provide a fuel cell system that can use various solid fuels without using only standard fossil fuels, and more particularly, to classify solid fuels according to types and characteristics, And to provide a system for supplying and sorting solid fuel to a boiler for thermal power generation capable of appropriately injecting a solid fuel into a boiler of a thermal power plant when necessary.

According to an aspect of the present invention, there is provided a system for supplying and sorting solid fuel to a boiler for thermal power generation, comprising: a collecting step of collecting and collecting crude solid fuel; A wind separation step of separating and removing heavy and light materials such as stones from the collected and collected crude solid fuel by wind; A volume sorting step of separating and removing a material that is too large or too small in the crude solid fuel from which the material is removed due to the difference in weight in the wind power sorting step; A magnetic force selecting step of removing foreign substances such as iron by magnetic force after the volume selecting step; A storage step of storing foreign matter in the wind power sorting step, the volume sorting step, and the magnetic force sorting step in a rectangular sail furnace having a plurality of compartments; A collecting step of collecting dust generated in the collecting step, the wind power selecting step, the volume selecting step, the magnetic force selecting step and the storing step; Mixing the dust collected in the collecting step with the solid fuel stored in the storing step; And an injecting step of injecting solid fuel mixed with dust into the boiler in the mixing step.

And an automatic transferring step of automatically transferring the crude solid fuel collected in the collecting step to the upper surface of the transfer conveyor by scraping by the reciprocating motion of the ladder device is added.

According to another aspect of the present invention, the wind separation step is characterized in that the material is separated from the crude solid fuel introduced by the wind generated by the operation of the wind power fan.

In addition, the volume screening step may be divided into a first screen step of selecting a material having a volume larger than a reference value and a second screen step of selecting a material having a volume less than a reference value.

In the present invention, in the collecting step, dust is collected by a filter, a cyclone, or an electric dust collecting method and mixed with and reused with the solid fuel.

The present invention can increase the purity of raw materials according to their weight and volume, classify them into solid fuels having various kinds and characteristics, store the solid fuels sorted into the respective compartments, It is possible to select a solid fuel suitable for the boiler of the thermal power plant and to collect the dust that is scattered to the outside and use it as the fuel of the boiler.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is an overall process diagram of a system for supplying solid fuel to a boiler for thermal power generation according to an embodiment of the present invention; FIG.
Fig. 2 is an overall configuration diagram of the invention shown in Fig. 1; Fig.
Fig. 3 is an overall configuration diagram according to another embodiment; Fig.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is an overall process diagram of a system for supplying solid fuel to a boiler for thermal power generation according to an embodiment of the present invention.

As shown in the figure, a system for supplying solid fuel to a boiler 100 for thermal power generation includes a collecting step S10, an automatic transferring step S20, a wind power sorting step S30, a volume sorting step S40, A sorting step S50, a storing step S60, a collecting step S70, a mixing step S80, and an inputting step S90.

The collecting step S10 collects and collects the crude solid fuel. In the present invention, the crude solid fuel means a state before classification into a suitable state as a fuel according to size, weight, etc., and the solid fuel means a state in which the crude solid fuel is purified to a suitable fuel state by various methods . And the solid fuel is a state in which foreign substances such as iron are removed.

The crude solid fuel includes BIOMASS (agricultural and forestry products, Energy Crop, organic waste), SRF, BIO-SRF, Fluff, waste, and sludge. Accordingly, the crude solid fuel having various characteristics can be selected at various stages and used for the boiler of the thermal power plant.

In the automatic transferring step S20, the crude solid fuel collected in the collecting step S10 is automatically transferred to the upper surface of the conveying screw 13 by scraping by the reciprocating motion of the ladder device 11 to be.

In the wind power sorting step S30, the crude solid fuel to be conveyed by the conveying conveyor 5 is sorted by the difference in weight between heavy materials such as stones and light materials using wind.

The volume sorting step S40 is a step of separating and removing a bulky or too small material based on a certain size in the crude solid fuel passed through the wind selection step S30. In the step S40, a first screen step for selecting a size larger than a predetermined reference value and a second screen step for selecting a material having a size smaller than a reference value may be categorized.

The crude solid fuel may include a metal foreign substance such as iron. However, since iron having an appropriate size and weight can pass through the volume sorting step (S40) or the wind power sorting step (S30), it is possible to reduce the magnetic force A magnetic force selecting step S50 for sorting and removing the magnetic force is performed.

When the crude solid fuel passes through the respective steps as described above, the size and weight are similar and the metal powder is removed and selected as the solid fuel.

Thus, the solid fuel classified based on the specific weight and volume is stored in the rectangular sachet 50 in the storing step S60. As shown in FIG. 2, the rectangular wrap 50 has a plurality of compartments 51a, 51b and 51c.

In addition, different solid fuel may be stored in each of the compartments 51a, 51b, and 51c provided in the rectangular wrap 50. 51b, and 51c. The solid fuel stored in the compartments 51a, 51b, and 51c may be classified into the compartments 51a, 51b, and 51c, So that it can be used.

The collecting step S70 is a step of collecting dust generated in the collecting step S10, the wind power sorting step S30, the volume sorting step S40 and the storing step S60. Although the method of collecting dust in the collecting step S70 is shown as a collecting method by a filter in FIG. 2, dust may be collected by a collecting method using a cyclone or an electrostatic collecting method if necessary.

The dust collected in the collecting step 70 is mixed with the stored solid fuel in the storing step S60 and the solid fuel mixed with the dust is charged into the boiler 100 Step S90 is proceeded.

A specific implementation of the system for supplying and sorting the solid fuel to the boiler (100) for thermal power generation according to the present invention will be described in detail with reference to Fig.

As shown in FIG. 10, in the collecting step S10, a collecting step (S10) for collecting and collecting the crude solid fuel conveyed from the outside to a vehicle or the like is performed, and the automatic transferring step (S20) Solidified fuel collected by the reciprocating motion of the ladder-shaped scraper 11 is automatically transferred to the upper surface of the conveying screw 13 (or the conveying conveyor).

The crude solid fuel defended by the conveying screw 13 is conveyed by the conveying conveyor 5, and the conveyed solid crude fuel is conveyed by the wind generated from the wind fan and the material having a heavy weight is almost freely dropped , And the less heavier material falls on a longer distance when the parabola is drawn. In addition, a light material such as dust is discharged to the outside together with the wind (S30).

If the crude solid fuel having a similar weight is selected by the wind selection step S30 as described above, the crude solid fuel selected by the transport conveyor 5 proceeds to the volume sorting step S40 and the volume sorting step S40), the clearance is selected by the first screen 31 and the second screen 33, which are different from each other (refer to reference numeral 30).

The clearance of the first screen 31 located at the upper part in the drawing is larger than the clearance of the second screen 33 located at the lower part.

Therefore, the crude solid fuel discharged to the upper surface of the first screen 31 is larger than the clearance of the first screen 31, and the smaller crude solid fuel is discharged to the outside And falls on the second screen 33.

The crude solid fuel dropped on the second screen 33 does not pass through the solidified fuel which is larger than the gap formed in the second screen 33, and when it is smaller, it passes through the lower portion and is discharged.

Since the metal powder such as iron powder may be contained in the crude solid fuel sorted by the volume in the volume sorting step S40 as described above, the magnetic force sorting step S50 for separating the iron powder or the like by the magnetic force of the magnet 40 proceeds .

When the crude solid fuel is subjected to the magnetic force selection step (S50), it becomes a solid fuel. The solid fuel is temporarily stored in the rectangular wrap 50 having the plurality of compartments 51a, 51b and 51c. Also, the solid fuel stored in the compartments 51a, 51b and 51c is discharged from the lower part to the respective conveying screws 53a, 53b and 53c.

The user can control the intensity of the wind of the wind-driven fan. Also, by switching the first screen 31 and the second screen 32, various types of solid fuel are sorted according to the weight and volume of the solid fuel to be sorted .

The solid fuel having the different kind is stored separately in the plurality of compartments 51a, 51b, and 51c formed in the rectangular wrap 50.

As shown in the figure, the dust generated in the picking step S10, the automatic transferring step S20, the wind selection step S30, the volume sorting step S40 and the magnetic force sorting step S50 The first housing 210 may be installed to prevent the dust from being scattered to the outside, and the dust collected by the dust collector 3 may be collected. A collector 3 is also installed in the rectangular wrap 50 and the second housing 72 is also provided with the collector 3 for collecting dust to prevent scattering in the mixing step S80 S70).

The collected dust is mixed with the solid fuel stored in the rectangular wrap 50 (S80), and the solid fuel mixed with the dust is injected into the boiler 100 to be used as fuel (S90).

In the mixing step S80, a plurality of receiving tanks 71a and 71b are provided. The solid fuel is temporarily stored in each of the receiving tanks 71a and 71b according to the type of the solid fuel, (Step S90).

Fig. 3 shows an overall configuration of the invention according to another embodiment.

The first screen 31 and the second screen 33 are selectively used in the volumetric sorting step S40 as shown in the figure.

As shown in the drawing, the first screen and the second screen are mounted apart from each other, and a conveying conveyor 5b is additionally provided below the first screen.

In the drawing, the foreign matter which has not passed through the first screen 31 located at the upper part is discharged by using the conveying conveyor 5a, and the crude solid fuel which has passed through the first screen 31 is discharged to the conveying conveyor (5b).

When it is desired to include a crude solid material having a small volume in the crude solid fuel dropped on the conveying conveyor 5b, it is conveyed through the conveyance conveyer 5 so that the later-described magnetic force selecting step S50 proceeds.

If it is desired to remove the coarse solids having a small volume from the crude solid fuel dropped on the conveying conveyor 5b, the user directs the conveying direction of the conveying conveyor 5b to the second screen 33, So that the crude solid fuel that has passed through the first screen (31) is dropped onto the upper surface of the second screen (33).

The crude solid fuel dropped on the second screen 33 does not pass through the solidified fuel which is larger than the gap formed in the second screen 33, and when it is smaller, it passes through the lower portion and is discharged. That is, the crude solid fuel that has not passed through the second screen 33 enters the volume sorting step S40 by using the conveying screw 5. [

The present invention is not limited to the above-described embodiments, and various modifications and changes may be made without departing from the scope of the present invention as set forth in the appended claims. It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined in the appended claims.

S10: Pickup phase
S20: Automatic transfer phase
S30: Phosphorus screening step
S40: Volume selection step
S50: magnetic force selection step
S60: Save step
S70: Collection step
S80: Mixing step
S90: input step

Claims (5)

A collecting step of collecting and collecting crude solid fuel;
A wind screening step of separating and removing heavy and light materials such as stones from the collected and collected crude solid fuel by wind;
A volume sorting step of separating and removing a material that is too large or too small in the crude solid fuel from which the material is removed due to the difference in weight in the wind power sorting step;
A magnetic force selecting step of removing foreign substances such as iron by magnetic force after the volume selecting step;
A storage step of storing foreign matter in the wind power sorting step, the volume sorting step, and the magnetic force sorting step in a rectangular box having a plurality of compartments;
A collecting step of collecting dust generated in the collecting step, the wind power selecting step, the volume selecting step, the magnetic force selecting step and the storing step;
Mixing the dust collected in the collecting step with the solid fuel stored in the storing step; And
And injecting the solid fuel mixed with the dust into the boiler in the mixing step. ≪ RTI ID = 0.0 > 11. < / RTI >
2. The method according to claim 1, characterized in that an automatic transferring step for automatically transferring the crude solid fuel collected in the collecting step to the upper surface of the conveying conveyor by scraping by a reciprocating motion of the ladder- Solid fuel supply and sorting system in boiler. The system for supplying and sorting solid fuel according to claim 1, wherein the wind power separation step separates the material from the crude solid fuel to be supplied by the wind generated by the operation of the wind power fan. The boiler for thermal power generation according to claim 1, wherein the volume screening step is divided into a first screen step of selecting a substance having a volume larger than a reference value and a second screen step of selecting a substance having a volume less than a reference value. Fuel supply and sorting system. The boiler for thermal power generation according to claim 1, wherein the dust collecting step collects dust by a filter collecting method, a cyclone collecting method, or an electric dust collecting method, and mixes and reuses the solid fuel with the solid fuel. Fuel supply and sorting system.

Images