KR101526284B1 - Apparatus for Alignment for Even Drying of Transportation Coal in System for Drying Coal using Reheat Steam - Google Patents

Abstract

The present invention relates to an alignment apparatus for evenly drying a transfer coal. The present invention comprises: a first coal dryer where a pair of first guide rails, a pair of second guide rails, a first steam chamber, a second steam chamber, a first exhaust gas chamber, and a second exhaust gas chamber are installed; and a second coal dryer where a pair of third guide rails, a pair of fourth guide rails, a third steam chamber, a fourth steam chamber, a third exhaust gas chamber, and a fourth exhaust gas chamber are installed. Moreover, the present invention comprises a coal fixed quantity supply device. The coal drying device comprises: a lifting plate; a plurality of first penetration holes formed on the lifting plate; a descending plate having an inclination; and a pair of fixing members. The present invention enables the reheat steam having high temperature to easily come in contact with coal particles and improves drying efficiency of a coal and reliability and prevents incomplete combustion of the coal and increases utilization of the low quality coal for which demand is low to improve coal supply stability.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an apparatus and a method for arranging coals in a coal drying apparatus using a reheat steam,

The present invention relates to a device for aligning coal for the uniform drying of transferred coal in an apparatus for drying coal using reheat steam, more particularly, to a device for drying coal by reheating steam, The present invention relates to a sorting apparatus for uniformly drying transfer coal for improving drying efficiency by aligning a coal pile to be fed so that reheated steam is evenly injected into a pile of coal fed from a coal feeder for feeding, rotating and dropping.

Generally, a coal-fired thermal power plant burns approximately 180 tons / hr of coal per 500 MW, and supplies approximately 37 tons of coal to the boiler per diffuser. A 500 MW coal-fired thermal power plant will have approximately six 500-ton capacity coal reservoirs, five of which will be supplied with normal coal, and the other will have a reserve coal reserve It is operated with low-fidelity.

Moreover, in the coal-fired thermal power plant, the standard thermal power design standard for coal is 6,080 Kcal / Kg, designed to use low-moisture bituminous coal of less than 10%. Some coal-fired power plants use imported coal, some of which have an average moisture content of at least 17%, which reduces the combustion efficiency of the boiler. If the calorific value of the coal used as the standard thermal power combustion limit is 5,400 Kcal / Kg is low, it is expected that the power generation will decrease and the fuel consumption will increase due to the decrease of combustion efficiency. In addition, when the coarse coal with a low calorific value of high water content is used, the water content is higher than the design standard and the conveying system for conveying the coal is not smooth, and when the coal is pulverized by the differentiator, the efficiency is lowered, , It may happen that the heat distribution generated in the boiler is operated with drift and abnormal condition. However, in order to reduce fuel costs in thermal power plants, the proportion of sub-bituminous coal is gradually increasing to about 41 ~ 60%.

In addition, with the expectation of the global economic recovery and the destruction of nuclear power plants due to the Japanese earthquake, the demand for coal-fired power plants is expected to rise steadily as the demand for thermal power plants increases. The global coal market is changing from the consumer to the supplier, and it is difficult to supply and supply stable coal. Production of high calorific coal is expected to remain at the current level, which is unbalanced supply and demand.

Among the total coal reserves of the world coal, the low calorific value is about 47%, but the calorific value is low and the water content is high, so the low calorific value burning of high water such as combustion trouble at the time of combustion is difficult to completely ignite in the market. Until now, there has been a high tendency to rely on stable oil prices and low production costs of nuclear power generation worldwide, but there are many plans for the construction of coal-fired thermal power plants due to the rapid rise in oil prices and anxiety about nuclear power generation .

Conventionally, the technique of drying coal (thermal drying) is a rotary drying method in which coal particles in the inside are dried with a high temperature gas while rotating a shell of a cylinder into which coal is charged, and a rotary drying method in which coal is dried from a high temperature (Flash, Pneumatic) drying method in which the gas is raised from the bottom to the top, and a fluid-bed drying method in which the high-temperature drying gas rises to the top with fine particles to dry the coal.

Coal is divided into surface moisture attached to the pores between the coal particles and bonded water which is bound to the pores inside the coal. The surface moisture occupies most of the water sprayed during the washing process, transportation and storage in the mountain, and its amount is determined by the surface area and the water absorption. The smaller the particle size, the larger the surface area and the capillary between particles and particles is formed. And the water content becomes larger. The combined moisture is formed in coal-fired generators, which are lignite, bituminous coal (bituminous coal, bituminous coal), and anthracite. If the coal has a lot of water, the calorific value is lowered and the transportation cost is increased, so it is necessary to control the water in the process of mixing, grinding and separating the coal.

Furthermore, since the pulverized coal is conveyed through a multi-stage dryer, that is, a conveyor having a plurality of through-holes formed therein for passing the reheat steam, or coal conveyed through a plurality of conveying plates while spraying high- There is a problem in that the water contained in the coal can not be effectively dried even if the reheated steam is sprayed in a state where it is not evenly dispersed. As a result, the number and length of the dryer for drying the coal have to be increased, and the amount of the reheated steam for drying has been increased, thereby increasing the cost and time for drying the coal.

As a prior art related to the present invention, Patent Document 1 discloses a method for improving the drying efficiency of a primary coal, which is primarily dried in a low-grade coal stabilizer, by using a wave-type vibration for uniform mixing with a heavy oil powder And a flow plate is provided. The vibration plate allows the low-grade coal and the heavy oil powder to be mixed evenly. The drying steam for drying the coal can not be uniformly sprayed on the surface of the coal, thereby reducing the drying efficiency.

Korean Patent Registration No. 10-0960793 (Jun. 3, 2010, Announcement, High-grade method and apparatus for lower coal)

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems, and it is an object of the present invention to provide a coal drying apparatus for drying a coal used as a fuel of a thermal power plant by a reheat steam while transferring the coal to a multi- The purpose is to effectively dry the coal by reheating steam injected into the coal by allowing the coal piles to be uniformly distributed and evenly distributed so that the piles of coal do not stick together in one place.

Another object of the present invention is to improve the combustion efficiency of a thermal power plant boiler by increasing the heating value of coal by making it possible to maintain an appropriate moisture content of coal by effectively drying coal, thereby reducing fuel consumption.

It is another object of the present invention to provide a drying technology and a technology applicable to a thermal power plant that can prevent environmental problems due to incomplete combustion of coal by controlling moisture contained in coal.

In order to achieve the above object, the present invention is characterized in that a pair of first driving sprockets and a pair of first driven sprockets are separated from each other by a predetermined distance and are respectively fastened to first chains, A pair of first guide rails horizontally supporting the upper first transfer plate are provided below the upper first chain connected between the first drive sprocket and the first driven sprocket, A pair of second guide rails horizontally supporting the lower first transfer plate are provided under the lower first chain connected between the first driven sprockets and a pair of second guide rails for spraying the reheated steam supplied from the reheater under the upper first chain A first vapor chamber in which a first vapor chamber is installed and in which a second vapor chamber for spraying reheated steam supplied from a reheater is provided below the lower first chain, A first coal dryer member is installed, and a second off-gas chamber for collecting exhaust gas on the lower side chain installed first; And a pair of second drive sprockets and a pair of second driven sprockets are separated from each other by a predetermined distance and connected to second chains, a plurality of second transfer plates are hingedly coupled between the second chains, A pair of third guide rails horizontally supporting the upper second transfer plate are provided below the upper second chain connected between the drive sprocket and the second driven sprocket, and a pair of third guide rails provided between the second drive sprocket and the second driven sprocket, A pair of fourth guide rails for horizontally supporting the lower second transfer plate are provided under the second chain, a third vapor chamber for spraying the reheated steam supplied from the reheater is installed under the upper second chain, A third exhaust chamber for collecting exhaust gas is provided on the upper second chain, and a third exhaust chamber for collecting the exhaust gas is installed on the upper second chain, And a second coal dryer provided with a fourth exhaust gas chamber for collecting exhaust gas, wherein a first conveying roller is hinged between the center of both sides of the first conveying plate and the first chains, and a first conveying roller is hinged to the left and right sides of the first conveying roller, And a second conveying roller is hingedly coupled between the center of both sides of the second conveying plate and the second chains, respectively, and the second conveying roller is hinged to the left and right sides of the second conveying roller, And a first guide bar for upwardly rotating the lower first transfer plate separated from the second guide rail in one direction is hinged to the upper side of the first drive sprocket A second guide bar which is installed up to the lower side along the side surface and rotates the upper first transfer plate separated from the first guide rail in one direction and supports the lower guide plate in the lower direction, A third guide bar installed up to the upper side along the side from the lower portion and rotating up and supporting the lower second transfer plate separated from the fourth guide rail in one direction to the lower portion along the side from the upper portion of the second drive sprocket, And a fourth guide bar for lowering and supporting the upper second transfer plate separated from the third guide rail in one direction is installed from the lower part of the second driven sprocket to the upper part along the side, And a coal quantity feeder for supplying a predetermined amount of coal to the surface facing the first coal dryer, wherein the coal is dried in the first coal dryer by the second coal dryer, A rising plate having a slope rising at a predetermined angle from the front to the back, A first through hole formed at a predetermined distance and a plurality of lengths in the direction of the first plate and a second plate having a slope that is joined to the end of the plate and descending at a predetermined angle toward the rear, Wherein the aligner is installed at one or more intervals with a predetermined distance to horizontally distribute the density of the coal pile transferred from the surface facing the upper side of the first transfer plate and to align The present invention is directed to an apparatus for aligning dried coal in a coal drying apparatus using a reheat steam which causes the reheated steam passing through the first conveyance plate to uniformly contact the surface of coal particles.

Further, in the present invention, the aligner may be installed in each of the first exhaust gas chamber, the second exhaust gas chamber, the third exhaust gas chamber and the fourth exhaust gas chamber, respectively, or may be installed in the first exhaust gas chamber, the second exhaust gas chamber, And may be installed in each of the exhaust gas chambers.

Further, in the present invention, a plurality of second through holes may be formed in the lower steel plate at a predetermined interval and width in the transverse direction.

Further, in the present invention, a flat member having elasticity may be coupled to the lower plate longitudinal section.

According to the present invention, an aligning apparatus for uniform drying of transfer coal in a coal drying apparatus using a reheat steam is sprayed through a plurality of through holes in a transfer plate while transferring a coal pile on a plurality of transfer plates for transferring coal The high-temperature reheated steam is used to disperse and equalize the density of the coal piles transferred to make it effectively take away the moisture contained in the coal, thereby allowing the coal particles to easily contact the high-temperature reheated steam. And the conveying plate is smoothly operated by feeding, rotating and dropping, thereby improving the drying efficiency of the coal, and by minimizing the coal drying device, it is possible to minimize dust generation during conveyance of the coal, Along with the improvement, It is possible to easily remove the moisture contained in the coal by effectively contacting the coal particles with the high-temperature reheated steam by the high-temperature reheating steam injected through the through holes penetrating the transfer plate while transferring the coal pile to the transfer plate, It is possible to prevent incomplete combustion of coal by removing water remaining inside and outside the coal which is used fuel, and to improve the coal heat quantity, minimize the emission of pollutants, reduce the spontaneous ignition rate due to the decrease of water content of coal, It is possible to improve the stability of coal supply by increasing the utilization of low grade coal. In addition, it is possible to use low-calorific charcoal, which is cheaper in price than high-calorie coal, reduce fuel cost and cost due to reduction of coal import quantity, and reduce coal consumption relatively, thereby reducing waste and pollutant discharge And carbon dioxide can be reduced, and the effect of substitution of foreign technology and overseas export of facilities can be expected.

1 is a block diagram showing a coal drying apparatus using a reheat steam according to the present invention.
FIG. 2 is a front view of a coal drying apparatus using a reheat steam according to the present invention.
FIG. 3 is a side view of a coal drying apparatus using a reheat steam according to the present invention.
FIG. 4 and FIG. 5 are perspective views each showing a main part provided with an aligner for even drying of the coal transferred in the coal dryer using the reheat steam according to the present invention.
6 is an exploded perspective view showing a main part of a transfer apparatus in a coal drying apparatus using a reheat steam according to the present invention.
7 and 8 are sectional views respectively showing the operation of the transfer device in the coal drying apparatus using the reheat steam according to the present invention.
9 is a perspective view showing an embodiment of an aligner in a coal drying apparatus using a reheat steam according to the present invention.
10 is a perspective view showing another embodiment of the aligner in the coal drying apparatus using the reheat steam according to the present invention.
11 is a front view, a side view, and a plan view showing the operation of the sorting apparatus for the even drying of the transfer coal in the coal drying apparatus using the reheat steam according to the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT Hereinafter, an embodiment of an aligning apparatus for uniformly drying transfer coal in a coal drying apparatus using a reheat steam according to the present invention will be described in detail with reference to the accompanying drawings.

The present invention minimizes the generation of dust in coal when the coal is fed into a conveying device such as a conveyor or a conveying plate, and distributes and supplies coal. In addition, the apparatus for dispersed feed and dust reduction is installed in a coal drying apparatus that feeds high-temperature reheated steam while coal is fed by feeding coal from a coal feeder feeding a predetermined amount of pulverized coal, do.

In FIG. 1, the low-lean burn 200 is a place for storing and storing coal for use as a boiler fuel for a thermal power plant. Coal contains surface moisture and internal moisture. Furthermore, the coal stored in the low-leaner (200) is sprayed with water periodically to prevent scattering of coal dust. The coal stored in the low-carbon plant 200 is transferred to the coal drying apparatus 100 through a conveying system or the like. At this time, coal of low-leaner (200) whose moisture has not been removed may be transferred to a drying coal supply tank (300) connected to the coal drying apparatus. The coal stored in the coal supply tank 300 is supplied to the coal drying apparatus 100 by a predetermined amount in the coal quantity feeder 400. The coal drying apparatus 100 includes a first coal dryer 110 installed in a multi-layered structure and a third coal dryer 170 for naturally drying coal discharged through a second coal dryer 140 at room temperature. The first coal dryer 110 and the second coal dryer 140 have substantially the same structure. The naturally dried coal passing through the third coal dryer (170) is stored in the dry coal storage tank (600) and supplied to the boiler fuel of the thermal power plant (700).

2 to 4, there is shown an example of a coal drying apparatus 100 equipped with an aligning device for even drying of conveyed coal according to the present invention. The coal drying apparatus 100 includes a coal loader 400 and a coal dryer 140. The coal dryer 100 includes a multi-stage dryer such as a first coal dryer 110, a second coal dryer 140 for secondarily drying coal dried in the first coal dryer, And a third coal dryer 170 for naturally drying the coal dried in the second coal dryer and supplying the dried coal to the dry coal storage tank 600.

The first coal dryer 110 includes a pair of first drive sprockets 111 and a pair of first driven sprockets 112 spaced apart from each other by a predetermined distance and fastened to the first chains 113, A plurality of first transfer plates 114 are hingedly coupled between the first drive sprocket 111 and the first driven sprocket 112 so that the upper first chain 113a is connected to the first driven sprocket 111, A pair of first guide rails 115 for horizontally supporting the transfer plate 114 is provided and a lower first chain 113b connected between the first drive sprocket 111 and the first driven sprocket 112 A pair of second guide rails 116 for horizontally supporting the lower first transfer plate 114 and a second guide rail 116 for spraying the reheat steam supplied from the reheater 500 below the upper first chain 113a, 1 vapor chamber 120 and a second vapor chamber 123 for spraying the reheated steam supplied from the reheater 500 below the lower first chain 113b And, a first off-gas chamber 124 for collecting the exhaust gas over the upper first chain (113a) is provided, and a second off-gas chamber 126 for collecting the exhaust gas over the lower first chain 113 is installed.

6, a first conveying roller 133 is hinged between the centers of both sides of the first conveying plate 114 and the first chains 113, respectively. That is, the first conveying roller 133 is hinged between the first conveying plate 114 side center and the first chain 113. A first auxiliary roller 134 is hinged to the side of the first transfer plate 114 on the left and right sides of the first transfer roller 133, respectively. The first sub-rollers 134 are hingedly coupled to the sides of the first transfer plate 114, i.e., the left and right sides.

Grooves 115a and grooves 116a for guiding the rotation of the first conveying roller 133 and the first sub-roller 134 are formed on the surfaces of the first guide rail 115 and the second guide rail 116, respectively do. The first conveyance plate 114 is rotated by the hinge-coupled first conveyance roller 133 and the first sub-roller 134 in the direction of the second guide rail 116 and the groove 115a formed on the surface of the first guide rail 115, And is conveyed along the groove 116a formed on the surface.

7 and 8, a first guide bar 117 which rotates and lifts the lower first transfer plate 114 separated from the second guide rail 116 in one direction is supported by a first drive sprocket 111 ) From the top to the bottom along the side. A first trigger 117a is coupled to the end of the first guide bar 117, and the first trigger 117a is composed of a roller that rotates axially. The first trigger 117a is installed at a position in contact with one side of the bottom surface of the upper first transfer plate 114.

A second guide bar 119 which rotates and supports the upper first transfer plate 114 separated from the first guide rail 115 in one direction is supported by the upper Respectively. A second trigger 119a is coupled to the end of the second guide bar 119, and the second trigger 119a is configured of a roller that rotates axially. The second trigger 119a is installed at a position in contact with one side of the lower first transfer plate 114 plane.

The second coal dryer 140 includes a pair of second drive sprockets 141 and a pair of second driven sprockets 142 spaced apart from each other by a predetermined distance and connected to the second chains 143, A plurality of second transfer plates 144 are hingedly coupled between the chains 143 and an upper side chain 143a connected between the second drive sprocket 141 and the second driven sprocket 142, A pair of third guide rails 145 for horizontally supporting the second transfer plate 144 and a lower second chain 143b connected between the second drive sprocket 141 and the second driven sprocket 142 A pair of fourth guide rails 146 for horizontally supporting the lower second transfer plate 144 are installed and the reheat steam supplied from the reheater 500 is sprayed below the upper second chain 143a A third vapor chamber 150 is installed and a fourth vapor chamber 15 for spraying reheat steam supplied from the reheater 500 below the lower second chain 143b A third exhaust gas chamber 154 for collecting exhaust gas is provided on the upper second chain 143a and a fourth exhaust gas chamber 156 for collecting exhaust gas on the lower second chain 143b. Respectively.

6, a second conveying roller 135 is hinged between the center of both sides of the second conveying plate 144 and the second chain 113, respectively. That is, the second conveying roller 135 is hingedly coupled between the second conveying plate 144 side center and the second chain 143. On the left and right sides of the second transport rollers 135, second auxiliary rollers 136 are hinged to side surfaces of the second transport plate 144, respectively. The second sub-rollers 136 are hingedly coupled to the sides of the second transfer plate 144, i.e., the left and right sides.

Grooves 145a and grooves 146a for guiding the rotation of the second conveying roller 135 and the second sub-roller 136 are formed on the surfaces of the third guide rail 145 and the fourth guide rail 146, respectively do. The second transfer plate 144 is rotated by the second conveying roller 135 and the second auxiliary roller 136 hinged to the fourth guide rail 146 and the groove 145a formed on the surface of the third guide rail 145, And is conveyed along the groove 146a formed in the surface.

7 and 8, a third guide bar 157 which rotates and lifts the lower second transfer plate 144 separated from the fourth guide rail 146 in one direction is supported by the second drive sprocket 141 ) From the top to the bottom along the side. A third trigger 157a is coupled to the end of the third guide bar 157, and the third trigger 157a is configured to rotate the shaft. The third trigger 157a is installed at a position where it contacts one side of the bottom surface of the upper second transfer plate 144.

A fourth guide bar 159 which rotates and supports the upper second transfer plate 144 separated from the third guide rail 145 in one direction is supported by the upper Respectively. A fourth trigger 159a is coupled to the end of the fourth guide bar 159 and a fourth trigger 159a is configured to rotate the shaft. The fourth trigger 159a is installed at a position in contact with one side of the lower second transfer plate 144 plane.

The first transfer plate 114 is provided with a plurality of through holes 114a so that the reheated steam injected from the first and second vapor chambers 120 and 123 passes through the first transfer plate 114 and comes into contact with the coal particles. Is formed. Guard 114b of a predetermined height is provided at left and right sides of the top surface of the first transfer plate 114 so that the charged coal pile does not flow down to the left or right of the first transfer plate 114. [ The guard 114b has a substantially trapezoidal shape and a shape with a wide upper side and a narrow lower side. Therefore, the guards 114b of the first transfer plate 114 are overlapped with the guards 114b adjacent to each other. At this time, it is preferable that the guard 114b of the first transfer plate 114 is installed in a substantially zigzag direction with the guard 114b adjacent to each other. The reheat steam injected from the first and second steam chambers 120 and 123 is supplied to the left and right sides of the bottom surface of the first transfer plate 114 in the first and second steam chambers 120 and 123 The shielding plate 114c is installed so as not to be lost.

The second transfer plate 144 is provided with a plurality of through holes 144 for allowing the reheated steam injected from the third and fourth steam chambers 150 and 153 to pass through the second transfer plate 144, 144a are formed. A guard 144b having a predetermined height is provided on the left and right sides of the upper surface of the second transfer plate 144 so as to prevent the charged coal pile from flowing down to the left or right of the second transfer plate 144. The guard 144b has a substantially trapezoidal shape and an upper light-narrow narrow shape with a narrow lower portion. Therefore, the guards 144b of the second transfer plate 144 are overlapped with the guards 144b adjacent to each other. At this time, it is preferable that the guard 144b of the second transfer plate 144 is provided in a substantially zigzag direction with the guard 144b adjacent to each other. The reheat steam injected from the third steam chamber 150 and the fourth steam chamber 153 is supplied to the left and right sides of the lower end surface of the second transfer plate 144 by the third steam chamber 150 and the fourth steam chamber 153 And the shielding plate 144c is installed so as not to be lost.

8A, the upper first transfer plate 114 is transferred to the end of the first guide rail 115 by the rotation of the first driven sprocket 112. 8B, when the left bottom surface of the upper first transfer plate 114 is moved away from the end of the first guide rail 115, the lower right surface of the upper first transfer plate 114 is moved to the second trigger 119a of the second guide bar 119 . The upper first transfer plate 114 hinged to the upper first chain 113 by the first transfer roller 133 is separated from the first guide rail 115 and at the same time the first transfer roller 133 is separated from the first guide rail 115, And the stack of coal is dropped downward. 8C, the bottom surface of the upper first transfer plate 114 is moved downward along the second trigger 119a. 8D, the upper first transfer plate 114 is moved without turning along the rotation radius of the first driven sprocket 112 in a state in which the bottom surface is in contact with the second guide bar 119 while maintaining a substantially vertical state . In FIG. 8E, the upper first transfer plate 114 transported downward is moved over the second guide rail 116, and a stack of coal dropped from the first transfer plate following the lower first transfer plate 114 is loaded . Then, the coal pile loaded on the lower first transfer plate 114 is conveyed and dried by reheating steam.

Next, in Fig. 7A, the lower first transfer plate 114 is transferred to the end of the second guide rail 116 by the rotation of the first drive sprocket 111. Fig. 7B, the lower surface of the lower first transfer plate 114 is moved away from the end of the second guide rail 116 and the lower surface of the lower first transfer plate 114 is moved to the first trigger 117a of the first guide bar 117 . At this time, the lower first transfer plate 114 hinged to the lower first chain 113 by the first transfer roller 133 is separated from the second guide rail 116, and simultaneously the first transfer roller 133 is separated from the second guide rail 116, And the stack of coal is dropped downward. 7C, the plane of the upper first transfer plate 114 is moved upward along the first trigger 117a. 7D, the lower first transfer plate 114 is moved without rotating along the rotation radius of the first drive sprocket 111 in a state where the first guide bar 117 is in plane contact with the first guide bar 117 while maintaining a substantially vertical state . 7E, the lower first transfer plate 114 is moved to the upper side first transfer plate 114 while being moved over the first guide rails 115, and the coal pile feeder 400, And transported. The coal pile loaded on the upper first transfer plate 114 is conveyed and dried by reheating steam. The coal pile dropped from the lower first transfer plate 114 is discharged to the discharge port 131 along the first slope 139.

The coal puddle discharged from the first coal dryer 110 to the discharge port 131 is introduced into the inlet 160 of the second coal dryer 140 and discharged to the upper second transfer plate 144 of the second coal dryer 140 ) Surface and transported. The coal pile loaded on the upper second transfer plate 144 is conveyed and dried by reheating steam.

The transferring process of the coal in the second coal dryer 140 is performed in the same manner as the transferring process of the first coal dryer 110. The coal pile dropped from the lower second transfer plate 144 is discharged to the discharge port 161 along the second slope 149. The coal pile discharged from the second coal dryer 140 to the discharge port 161 is subjected to a natural drying process while being supplied to and transported to the third coal dryer 170.

The steam supply pipe 121 for supplying the high-temperature reheated steam generated in the reheater 500 is connected to one side of the first steam chamber 120 and the second steam chamber 123, 150 and the fourth steam chamber 153 are connected to a steam supply pipe 151 for supplying the high-temperature reheated steam generated in the reheater 500, respectively. And a plurality of first steam injection holes 11 formed in the upper portion of the first steam chamber 120, the second steam chamber 123, the third steam chamber 150 and the fourth steam chamber 153, And the vapor distribution piercing plates 10 are respectively coupled. The first steam chamber 120 to the fourth steam chamber 153 are injected with the reheat steam of uniform pressure through the first steam injection hole 11, respectively.

3, the first vapor chamber 120 is installed below the first guide rail 115, and the second vapor chamber 123 is installed below the second guide rail 116. The third vapor chamber 150 is installed below the third guide rail 145 and the fourth vapor chamber 153 is installed below the fourth guide rail 146. The first to fourth vapor chambers 120 to 153 may be partitioned into one or more.

A first exhaust gas chamber 124 is provided on the first guide rail 115 and a second exhaust gas chamber 126 is provided on the second guide rail 116. A third exhaust gas chamber 126 is provided on the third guide rail 145, An exhaust gas chamber 154 is provided and a fourth exhaust gas chamber 156 is provided on the fourth guide rail 146. [ The first exhaust gas chamber 124 to the fourth exhaust gas chamber 156 may be partitioned into one or more. The first exhaust gas chamber 124 to the fourth exhaust gas chamber 156 are respectively injected in the first to fourth vapor chambers 156 to 156 and then collected in the first gas exhaust pipe 125 or So that the gas can be discharged to the outside through the second gas discharge pipe 155.

4, the dust reducer 1 is installed at the lower end of the coal quantitative feeder 400. [ The dust reducer 1 is installed at a predetermined interval from the surface of the first coal dryer 110 facing the upper side of the plurality of first transfer plates 114. Furthermore, the dust reducer 1 changes the direction of the coal supplied from the coal quantitative feeder 400 through a zigzag shape, a twisted shape, or a spiral shape, and decelerates the speed at which the coal is supplied, So that it is slowed down to the surface facing the upper side of the first transfer plate 114 to suppress dust generation.

9, the aligner 10 includes a lift plate 11 having a slope rising from a front side to a rear side at a predetermined angle, a lower plate 12 having a slope that is joined to the lift plate end and descends at a predetermined angle toward the rear side ) Are integrally combined. A plurality of first through holes (13) are formed in the rising plate (11) at regular intervals and lengths in the longitudinal direction. The aligner 1, to which the ascending plate 11 and the descending plate 12 are integrally joined, is fixedly supported by a pair of fixing members 15 at each side. One side of the fixing member 15 is coupled to the side where the lift plate 11 and the lower plate 12 are joined and the other side of the fixing member 15 is fixed to the first guide rail 115.

Furthermore, the aligner 10 is arranged to horizontally distribute the density of coal piles transferred from the surface facing the first conveying plate 114 and to perform alignment to even out the distribution. The aligner 10 may be installed at one or more intervals.

10, a plurality of second through holes 14 are formed in the lower plate 12 of the aligner 10 at regular intervals and widths in the transverse direction. The second through holes 14 may be formed in the vertical direction on the lower steel plate 12. Also, the first through hole 13 formed in the rising plate 11 may be formed in the transverse direction. Therefore, the through holes formed in the rising plate 11 and the downward plate 12 can be formed in both the longitudinal direction and the transverse direction, and the longitudinal direction and the transverse direction can be selectively formed.

Further, a flat member 16 having elasticity is joined to the vertical plane of the lower plate 12 of the aligner 10. The flat member 16 is made of a material having elasticity such as synthetic resin or rubber, so that the irregularly conveyed coal can be flattened.

11A to 11C, the coal pile C fed into the surface of the first conveyance plate 114 in the dust reducer 1 is conveyed in a substantially circular arc shape. However, the coal pile C is formed to be deflected or irregular in height . Further, the density of coal pile C transferred to the center portion and the lower portion is increased by gravity. Therefore, the reheating steam injected from the bottom of the first transfer plate 114 is not uniformly injected into the coal particles in the coal pile C, so that the efficiency of the coal drying can be reduced. At this time, the coal pile C transferred from the first transfer plate 114 is horizontally separated while passing through the bottom of the elevating plate 11 of the aligner 10. The separated coal pile (C) rises on the surface of the rising plate (11). The coal pile C which has risen to the surface of the rising plate 11 flows under the rising plate 11 through the first through hole 13 or over the rising plate 11 and is transported to the surface of the lower steel plate 12. The coal pile C descending to the surface of the lower steel plate 12 flows into the lower steel plate 12 through the second through hole 14 or passes through the lower surface of the lower steel plate 12 through the surface of the lower steel plate 12 (C) of the coal.

If the bottom surface of the rising plate 11 of the aligner 10 and the bottom surface of the lower steel plate 12 are provided so as to be close to the surface of the first transfer plate 114, So that the bundle or density of the coal dumps C is dispersed and equalized and transported. Therefore, the aligner 10 scrambles the coal pile C to be conveyed uniformly, thereby maximizing the drying efficiency.

5, the aligner 10 is installed at a front end of the second exhaust gas chamber 126 to receive a coal dump C dropped from the upper first transfer plate 114 to the lower first transfer plate 114, To be dispersed and planarized. The aligner 10 is installed in the third exhaust chamber 154 and the fourth exhaust chamber 156, respectively, so as to disperse and planarize the coal dumps C transferred. In addition, the aligner 10 may be installed in the first exhaust gas chamber 124, the second exhaust gas chamber 126, the third exhaust gas chamber 154, and the fourth exhaust gas chamber 156 in one or more of them. Therefore, the sorter 10 is installed in the first exhaust gas chamber 124, the second exhaust gas chamber 126, the third exhaust gas chamber 154, and the fourth exhaust gas chamber 156, The density is dispersed and equalized so that the reheated steam passing through the first conveying plate 114 and the second conveying plate 144 is uniformly brought into contact with the surface of the coal particles, thereby making it possible to more effectively dry the coal.

As described above, in the coal drying apparatus using the reheat steam of the present invention, the sorting apparatus for the uniform drying of the transfer coal is provided with a plurality of transfer plates for transferring the coal, It is a high-temperature reheating steam that removes the moisture contained in the coal and can effectively dry it. It disperses and evenly distributes the load and density of the coal pile to be conveyed, so that the high temperature reheating steam easily contacts the coal particles. have.

While the invention has been shown and described with respect to the specific embodiments thereof, it will be understood by those skilled in the art that various changes and modifications may be made without departing from the spirit and scope of the invention as defined by the appended claims. Anyone who has it will know it easily.

The present invention relates to a coal drying apparatus and a coal drying apparatus. The coal drying apparatus includes a first coal dryer, a first coal dryer, a second coal dryer, and a drive sprocket. A guide rail 117, 119, 157, 159, and a guiding plate 117. The guiding rails 117, 119, 157, and 159 guide the guiding rails 117, 119, And a gas discharge pipe 130. The gas discharge pipe 130 is connected to the discharge port 131 and the discharge port 133 is connected to the discharge port 133. [ And a coal supply device for supplying the coal to the coal supply tank, wherein the supply of the coal to the coal supply tank is controlled by a control unit, Quantity feeder 500: Reheating 600: Dry coal storage tank 700: Thermal power plant C: Coal pile

Claims (4)

A pair of first drive sprockets and a pair of first driven sprockets are spaced apart from each other by a predetermined distance and fastened to the first chains, a plurality of first transfer plates are hingedly coupled between the first chains, A pair of first guide rails horizontally supporting the upper first transfer plate is provided below an upper first chain connected between the sprocket and the first driven sprocket, A pair of second guide rails horizontally supporting the lower first transfer plate are provided under the chain, a first vapor chamber for spraying the reheated steam supplied from the reheater is provided below the upper first chain, A second exhaust chamber for discharging the reheated steam supplied from the reheater is provided under the first chain, a first exhaust chamber for collecting the exhaust gas is provided on the upper first chain, A first coal dryer having a second exhaust gas chamber for collecting exhaust gas; And
A pair of second drive sprockets and a pair of second driven sprockets are spaced apart from each other by a predetermined distance and connected to the second chains, a plurality of second transfer plates are hingedly coupled between the second chains, A pair of third guide rails horizontally supporting the upper second transfer plate are provided below the upper second chain connected between the sprocket and the second driven sprocket, A pair of fourth guide rails horizontally supporting the lower second transfer plate are provided under the chain, a third vapor chamber for spraying the reheated steam supplied from the reheater is provided below the upper second chain, A fourth exhaust chamber for discharging the reheated steam supplied from the reheater is provided under the second chain, a third exhaust chamber for collecting the exhaust gas is provided on the upper second chain, A second coal dryer the fourth off-gas chamber for collecting the switch is installed, and
A first conveying roller is hinged between the center of both sides of the first conveying plate and the first chains, a first sub-roller is hinged to the side of the first conveying plate on the left and right sides of the first conveying roller, A second conveying roller is hinged between the center of both sides of the second conveying plate and the second chains, a second auxiliary roller is hinged to the side of the second conveying plate on the left and right sides of the second conveying roller, A first guide bar for rotating and lowering the lower first transfer plate separated from the second guide rail in one direction is installed from the upper side to the lower side along the upper side of the first drive sprocket, A second guide bar for lowering and supporting the first transfer plate in one direction is installed from the lower portion of the first driven sprocket to the upper portion along the side thereof, A third guide bar for upwardly rotating the lower second transfer plate in one direction is installed from the upper side to the lower side along the upper side of the second drive sprocket and the upper second transfer plate separated from the third guide rail is moved in one direction And a fourth guide bar rotatably supporting the first conveying plate and the second conveying plate is installed from the bottom of the second driven sprocket to the top along the side thereof,
A coal drying apparatus using a reheat steam for secondary drying by charging primary coal dried in the first coal dryer with a secondary coal dryer,
A lift plate having a slope rising from a front side to a rear side at a predetermined angle; a first through hole formed in the lift plate at a predetermined interval and a plurality of lengths in the vertical direction; And an aligning device composed of a pair of fixing members for fixing and supporting the bonded elevation plate and the lower steel plate,
The aligner is installed at one or more intervals with a predetermined interval to allow the density of the coal pile to be conveyed from the surface facing the upper side of the first conveyance plate to be horizontally dispersed and to be evenly distributed through the first conveyance plate, Wherein the reheating steam is brought into even contact with the surface of the coal particles.
[Claim 2] The apparatus according to claim 1, wherein the aligner is installed in each of the first exhaust gas chamber, the second exhaust gas chamber, the third exhaust gas chamber, and the fourth exhaust gas chamber, or the first exhaust gas chamber, the second exhaust gas chamber, Arrangement for even drying of transferred coal in a coal drying apparatus using reheat steam installed in each of at least one chamber.
The apparatus according to claim 1, wherein the lower steel plate has a plurality of second through holes at a predetermined interval and width in the transverse direction.
The apparatus according to claim 1, further comprising a flat member having elasticity attached to the bottom surface of the lower steel plate for aligning the coal in the coal drying apparatus using the reheat steam.

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