WO2011002187A2 - Method and apparatus for upgrading low-rank coal - Google Patents

Abstract

The present invention relates to a method and apparatus for upgrading low-rank coal, which upgrade low-rank coal, having a water content of 30% or more, into coal for generating power and having a water content of 10% or less and a calorific value of 6,500 kcal/kg or more, through the use of heavy oil ash and a microwave drying process, which prevents the spontaneous combustion of the coal upgraded into high-rank coal.

Description

High Quality Coking Method and Apparatus of Low Coal

In order to use low-grade coal as a fuel of a coal-fired power plant, low-grade coal having a moisture content of 30% or more is converted into high-grade coal with a heat generation capacity of 6,500 kcal / kg or more and less than 10% moisture, thereby preventing spontaneous ignition of high-grade coal. The present invention relates to a method and apparatus for high quality coal production.

Coal is generally divided into peat, brown coal, lignite, sub-bituminous coal, bituminous coal and anthracite grades. , Heavy or high voluminous bituminous coal, and anthracite is divided into semi-anthracite, anthracite, meta-anthracite and graphite anthracite. Low rank coal (LRC) refers to brown coal, lignite sub-bituminous coal, and bituminous coal and anthracite are classified as high rank coal (HRC).

Low and high here do not mean the quality of coal, just the difference in carbonization. Conventionally, high water high ash lignite (low grade) is used to dehydrate, dry and stabilize bitumen coal (high grade, HRC: High Rank Coal).

Lower coal, such as lignite, has many pores and a lot of peripheral hydrocarbons (volatiles), which increases the temperature due to the heat of adsorption and desorption of moisture, and the possibility of spontaneous combustion due to oxygen functional groups, which occupy a considerable amount of volatiles. Use has been limited.

The moisture of lower coal is divided into free water, interstitial water (pore water), surface water, bound water, and the like. A large part of the lower coal water is the free water adhering to the lower coal surface, the water present between the molecules of the lower coal and the inner water, and the bound water is chemically bonded to the lower coal molecules. The free and surface waters are dried at 100 ± 5 ° C., but the internal and bonded waters are destroyed and dried at about 400 ° C.

Therefore, in order to remove moisture of the lower coal, it must be dried at a high temperature of 400 ° C. or higher, and thus, there is a disadvantage in that a high cost and energy consumption are required. In addition, in the case of high-grade drying of low-grade coal at such a high temperature, oxygen pores of the coal, hydroxyl groups (Hydroyxl groups, -OH), carboxyl groups (Carboxyl group, -COOH), carbonyl Carbonyl group (-C = O) is created. They react with moisture and oxygen components when exposed to air and oxidize, raising the temperature inside the pores, causing spontaneous ignition. Therefore, in most high-definition technology, the coal dried with moisture content of 10% or less through the drying process is adsorbed into the pores and stabilized by briquetting and pelletizing.

Accordingly, an object of the present invention is to classify low-grade coal having a water content of 30% or more into a coal for power generation of 6,500 kcal / kg or more of water having a moisture content of 10% or less, and a high-grade method of low-grade coal capable of preventing spontaneous ignition of high-grade coal. To provide a device.

In order to achieve the above object, the present invention, the primary coal is dried by injecting heated air of 100 ~ 130 ℃ to low-grade coal having a particle size of 10 ~ 30mm and a water content of 30% or more, here the heavy oil ash having a particle size of 74㎛ or less 5 to 20 parts by weight of the powder is added to 100 parts by weight of the lower coal, and then mixed, and then microwave is used as a heat source to provide a high quality method for lower coal, characterized in that the secondary drying at 120 ~ 150 ℃.

In addition, the present invention, the lower coal storage tank for storing the lower coal, the lower coal supply unit including a lower coal rotary feeder and a diaphragm for transporting the lower coal stored in the lower portion; Heavy oil ash powder storage tank in which heavy oil ash powder is stored, heavy oil ash powder mill for pulverizing the heavy oil ash powder to a particle size of 74 μm or less, heavy oil ash powder storage tank for storing the finely divided heavy oil ash powder, and scattering in the storage tank A heavy oil ash powder supply unit including a heavy oil ash powder bag filter for collecting the powder, and a rotary valve for transporting the heavy oil ash powder to a lower portion, and a heavy oil ash powder supply screw; A heat-air supply unit comprising a blower, a heat exchanger for recovering heat of dried and stabilized high-quality coal, and a heater for heating the heat-exchanged air with drying air; Lower coal inlet through which the coal transported through the lower coal supply unit is input, heavy oil ash powder inlet through which the heavy oil ash powder transported through the heavy oil ash powder supply unit is injected, and heated air transferred through the heating air supply unit is injected. A porous plate having a hot air inlet and an air inlet on one side for firstly drying the lower coal through the lower coal introduced through the lower coal inlet, and the first dried lower coal and heavy oil ash. Lower coal stabilization apparatus for secondary drying at 120 ~ 150 ℃ by mixing the powder as a microwave as a heat source, steam suction unit for sucking the steam decomposed during the drying process of the lower coal, for discharging the dried and stabilized coal High quality coal outlet, fine powder to discharge unadsorbed heavy oil fine powder in matrix form A lower coal drying and stabilizing unit including a discharge unit; And a high quality coal storage unit comprising a rotary feeder of high quality coal transported through the high quality coal outlet and a high quality coal storage tank for storing the transferred high quality coal. to provide.

The lower coal stabilization device is a wave-type vibration flow plate for uniform mixing of the primary dried lower coal and heavy oil ash powder introduced from the heavy oil ash powder inlet, and the lower coal and heavy oil And a microwave feeder for microwave drying the mixture of ash powder and a temperature sensor for measuring the temperature inside the mixture of the lower coal and heavy oil ash powder.

In addition, the low-grade coal high-quality device: a vapor phase powder recovery device for collecting the powder in the dry steam sucked by the steam suction unit attached to the upper portion of the low coal stabilizer, heavy oil ash powder for recycling the recovered powder A recirculation blower, a powder suction pump for sucking dry steam after the powder collection, a condenser for condensing the inhaled vapor phase air, a gas-liquid separator separating gas from the condensed condensate, and a condensate storage tank for storing condensate from the gas-liquid separator It may further comprise a decomposition gas phase powder recovery unit comprising a circulating pump for sending the condensed water to the cooling water.

In addition, the low-grade coal high-quality device may further comprise an accessory facility consisting of a vibration fluidizer lower spring, a vibration supply device, a vibration fluid supporter.

In this case, the vibration fluid plate is preferably made of a material having a low permittivity (Permittivity) that can transmit the supplied microwave.

The above-described high-grade coal production method and apparatus for low-grade coal according to the present invention can high-grade low-grade coal with water content of 30% or more by using microwave drying and heavy ash powder with high-grade heat of 6,500 kcal / kg or more of heat generation capacity of 6,500 kcal / kg or more. In addition, it has a useful effect to prevent spontaneous ignition of high-grade coal.

1 is a system diagram of a high quality coalescing apparatus of lower coal according to the present invention.

2 is an enlarged view illustrating main parts of FIG. 1.

3 is an enlarged view of the porous plate illustrated in FIG. 1.

4 is a cross-sectional view taken along the line A-A of FIG.

5 is an enlarged cross-sectional view of the vibrating fluid plate shown in FIG.

6 is a graph showing the results of the pyrophoric test.

Hereinafter, the present invention will be described in more detail.

First of all, the high-grade method of lower coal according to the present invention is first dried by injecting 100 to 130 ° C. heating air into lower coal having a particle size of 10 to 30 mm and a water content of 30% or more, and having a particle size of 74 μm or less. 5 to 20 parts by weight of heavy oil ash powder is added to 100 parts by weight of the lower coal and mixed, followed by secondary drying at 120 to 150 ° C. using microwave as a heat source.

Here, it is not necessary to limit the kind of low-grade coal, if the moisture content is more than 30% can be used without limitation. In addition, the particle size of the lower coal need not necessarily be limited, but lower coal having a particle size of 10 to 30 mm is used so that drying can be performed smoothly. If necessary, it may be ground before drying to have the above-described particle size.

Low-grade coal is subjected to the primary drying to heat the low-grade coal to 100 ~ 130 ℃ to remove free water and surface water adhering to the surface. The above-mentioned primary drying is generally performed in the art, and in the present invention, the primary drying is performed by injecting heated air.

In general, in the high quality process of low-grade coal, in order to remove difficult-to-water moisture such as gap water, capillary coupling water, internal reserve water, etc. in the lower coal, it has been dried at 400 ° C. or higher, but there are certain problems such as spontaneous combustion. In order to solve this problem, in the present invention, microwaves are used as the heat source, and the second drying is performed by mixing a hydrophobic heavy oil powder having a high affinity with a carbon component and a high affinity with the binding water. That is, 5 to 20 parts by weight of heavy oil ash powder having a particle size of 74 μm or less is added to 100 parts by weight of the lower coal and mixed with the first dried lower coal, followed by secondary drying at 120 to 150 ° C. using microwave as a heat source. will be.

Here, although the particle size of the heavy oil ash powder does not necessarily need to be limited, it is preferable to use a particle size of 74 μm or less for effective drying. In addition, considering the scattering in the work process, it is better to use a particle size of 0.01㎛ or more.

In addition, the heavy oil ash powder is used 5 to 20 parts by weight based on 100 parts by weight of the lower coal, if the heavy oil ash powder is less than 5 parts by weight based on the above, there is a disadvantage that the temperature for secondary drying is increased and the drying time is long. When the heavy oil ash powder exceeds 20 parts by weight, the calorie of coal obtained may be reduced.

As described above, the present invention is a heavy oil-fired power plant that is similar in composition to coal, not a method of applying a microwave heat source to a heat source application technology such as a heating furnace and an electric furnace, but adding an oil component such as heavy oil when moisture is dried. It is a technology to increase the drying speed through the hydrophobic action with bound water by adding heavy oil ash fine powder, a by-product of combustion, and to prevent spontaneous ignition by adsorption.

Microwave is a kind of electromagnetic wave (300MHz ~ 300GHz) located between spectral far infrared and radio wave (high frequency). The biggest feature of microwave is that the heating method uses friction force by molecular rotation or rearrangement as much as speed corresponding to the frequency of electromagnetic wave, so that it can raise the temperature faster than conventional thermal conductive heating. In addition, microwave energy has low energy that does not damage chemical bonds, and thus does not alter or destroy molecular structure. Because of the rapid temperature rise and chemical stability, microwave technology has already been applied in various chemical fields. In addition, the principle of microwaves is that the material with low dielectric constant (permeability) transmits microwaves, while internal moisture (gap water, bound water) such as polar solvent with high transmittance absorbs microwaves and thus maintains its own molecular rotation. Evaporate while releasing heat through.

On the other hand, heavy oil ash powder can be easily obtained as a combustion by-product of a heavy oil-fired power plant. For example, Korea Western Power Co., Ltd.'s Pyeongtaek Thermal Power Plant No. 1 generates 3,134 tons per year, and other heavy oil-fired power plants such as Yeosu Thermal Power in Korea are also generated in large quantities. Therefore, heavy oil ash powder may have the effect of reinforcing the fixed carbon component of lower coal and recycling heavy oil ash, which is designated waste.

The present invention takes advantage of the difference in wettability of the carbon component of the hydrophobic heavy ash powder with hydrophobic (Hydrophobic) and the combined water having hydrophilic (ie, wettability), that is, the repulsion between the hydrophilic bonded moisture and the carbon component of hydrophobic lower coal, In order to increase the repulsion, a certain amount of heavy oil ash powder is used as a catalyst, which increases hydrophobicity with the combined moisture and increases surface tension to promote decomposition with lower coal, which irradiates microwaves. By increasing the molecular rotational power of the bonded water such as the pore water and the capillary bond water, it generates heat, drying the bonded water and the capillary water at a temperature of 150 ° C. or lower, and ejecting it as a vapor and adsorbing heavy oil powder in the pores to prevent spontaneous ignition. In particular, the method according to the present invention as described above is about 2 to 120 to 150 ℃ drying carried out at conventional 400 ℃ or more After about 5 minutes, high-quality coal with moisture content of less than 10% and calorific value of 6,500 kcal / kg or more can be obtained.

According to the present invention, there is provided an apparatus for effectively achieving the above-described low-grade coal refinement method. Although this will be described in more detail with reference to the accompanying drawings, the accompanying drawings are presented to help understand the present invention, the present invention is not limited thereto.

FIG. 1 is a system diagram of a high-grade coal leveling device according to the present invention, FIG. 2 is an enlarged view of a main part of FIG. 1, FIG. 3 is an enlarged view of the porous plate shown in FIG. 1, and FIG. 4 is AA of FIG. 1. 5 is an enlarged cross-sectional view of the vibrating fluid plate shown in FIG. 1.

As shown in Figures 1 to 5, the high-grade carbonization unit of the lower carbon according to the present invention comprises a low coal supply unit, heavy oil ash powder supply unit, heating air supply unit, low coal drying and stabilization unit and high-grade coal storage unit.

The lower coal supply unit includes a lower coal storage tank 1 in which lower coal is stored, and a lower coal rotary feeder 2 and a diaphragm 3 for transferring the lower coal to the lower stored coal.

In this case, the lower coal need not be limited as described above, and may be used without limitation as long as the water content is 30% or more. In addition, the particle size of the lower coal need not necessarily be limited, but lower coal having a particle size of 10 to 30 mm is used so that drying can be performed smoothly. If necessary, it may be ground before drying to have the above-described particle size. Coal having such a particle size is transferred to the lower coal inlet 17 by the rotary feeder 2 and the diaphragm 3.

The heavy oil ash powder supply unit stores the heavy oil ash powder storage tank 4 in which the heavy oil ash powder is stored, the heavy oil ash powder powder mill 5 for grinding the heavy oil ash powder to a particle size of 74 μm or less, and the fine oil ash powder stored therein. Heavy oil ash powder storage tank (6), heavy oil ash powder bag filter (7) for collecting the powder scattering in the storage tank, and rotary valve (8) and heavy oil ash powder feed screw for transferring the heavy oil ash powder to the lower part (9) is made.

The heavy ash powder uses combustion by-products of heavy oil-fired power plants, and the particle size of the heavy oil ash powder is not necessarily limited, but it is preferable to use a particle size of 74 μm or less for effective drying.

The heated air supply unit is a heat exchanger 13 for recovering heat of the blower 10 and the dried and stabilized high quality coal, and a heater 14 for heating the heat exchanged air with the air for drying the heat exchanger 13. )

The heated air obtained from the heated air supply unit is used for primary drying of lower coal. At this time, the heating air supply unit is a pressure gauge 11 and a flow meter 12 for adjusting the air volume, a bypass valve 15 of the atmospheric air to be used as circulating air, heating injection air as shown in the drawing It may further comprise a temperature meter 16 for measuring the temperature of.

The lower coal drying and stabilizing unit is a lower coal inlet 17 into which coal transported through the lower coal supply unit is input, and a heavy oil ash powder inlet 18 into which heavy oil ash powder transferred through the heavy oil ash powder supply unit is input. Heated air inlet 19 for injecting heated air transferred through the heated air supply unit through a nozzle 212 formed on one side, and the injected heated air passes through the lower coal introduced through the lower coal inlet 17. The porous plate 211 is provided with an air inlet 20 on one side for primarily drying the lower coal, and the first dried lower coal and heavy oil ash powder are mixed to produce microwaves at 120-150 ° C. Lower coal stabilizer 21 for secondary drying, a steam suction unit 22 for sucking steam decomposed in the drying process of the lower coal, for discharging the dried and stabilized coal A high quality coal outlet 23, comprising a fine powder discharge portion 26 for discharging the heavy oil fine powder unabsorbed in the form of a matrix.

Here, the primary drying may be made by injecting heated air of 100 ~ 130 ℃ to the lower coal. In addition, in the secondary drying, heavy oil ash powder having a particle size of 74 μm or less is added in an amount of 5 to 20 parts by weight based on 100 parts by weight of lower coal.

At this time, the porous plate 211, as shown in Figure 3, the pore 211a size is maintained at 1/5 ~ 1/10 of the particle size of 10 ~ 30mm of the lower coal particles lower coal particles are the pores 211a It is desirable not to pass.

The lower coal stabilization device 21 is a wave-type vibration flow plate for uniform mixing of the primary dried lower coal and heavy oil ash powder introduced from the heavy oil ash powder inlet 18. 215, microwave feeders 213a and 213b for microwave drying the mixture of the lower coal and the heavy oil ash powder, and a temperature sensor 214 for measuring the temperature inside the mixture of the lower coal and the heavy oil ash powder. It can be made, including.

The microwave feeders 213a and 213b continue to irradiate microwaves until the temperature of the mixture of lower coal and heavy oil ash powder reaches 120-150 ° C, and the microwave irradiation stops automatically when the temperature inside the mixture exceeds 150 ° C. You can do that. To this end, the microwave supplies 213a and 213b may be partially or entirely formed on / off repeating structure.

In addition, as shown in FIG. 4, the microwave feeders 213a and 213b may be disposed to cross each other without facing each other for preventing a magnetron failure due to the inflow of microwaves and for uniform irradiation. However, the microwave feeders 213a and 213b are not limited to the accompanying drawings, and may be arranged in various shapes as necessary. In addition, the temperature sensor 214 is disposed between the microwave supply (213a, 213b) that is not irradiated with microwaves.

When the microwave is used as a heat source as in the present invention, it is preferable that the choke 218 is formed of an aluminum material having high microwave permeation resistance at the inlet and the outlet to prevent leakage thereof. Reference numerals 216 and 217 are connecting portions and fixing portions for connecting the upper and lower plates of the lower coal stabilization device, respectively.

In addition, as shown in Figure 5, the wave-shaped vibration flow plate 215 is adjusted in direction from the inlet to the outlet, as shown in Figure 5, and forms a wave shape for smooth mixing and adsorption with heavy oil ash powder In addition, it is preferable that the transmission resistance of the microwave is very low and composed of a Teflon material that transmits microwaves most of the time.

The high quality coal storage unit includes a rotary feeder 24 of high quality coal transferred through the high quality coal outlet 23 of the lower coal drying and stabilization unit, and a high quality coal storage tank 25 for storing the transferred high quality coal. It is configured to include.

When passing through the above apparatus, the low-grade coal having a moisture content of 30% or more and the calorific value of 4,500 kcal / kg or less is made into a high quality coal for generating power of 10% or less of the moisture content and 6,500 kcal / kg or more. In addition, it is possible to prevent spontaneous ignition of high-grade coal.

The high-grade coal-degrading device of the lower coal is a vapor phase powder recoverer 28 for collecting powder in dry steam sucked by the steam inlet 22 attached to the upper portion of the lower coal stabilizer 21, the recovered Heavy oil powder recirculation blower 27 for recirculating powder, a powder suction pump 29 for sucking dry steam after collecting the powder, a condenser 30 for condensing the inhaled vapor phase air, and gas in the condensed condensate The gas-liquid separator 31 for separating, a condensate storage tank 32 for storing the condensate coming down from the gas-liquid separator, and further comprising a decomposition gas phase powder recovery unit comprising a circulation pump 33 for sending the condensate to the cooling water. The heavy oil ash recovered through this process is recycled to use.

In addition, the low-grade coal high-quality device may further include an accessory facility comprising a vibration fluidizer lower spring 34, a vibration supply device 35, a vibration fluid support unit 36.

The low-grade coal high-quality device according to the present invention is made of aluminum oxide (Al2O3) material in order to block the leakage of microwaves, the porous plate 211 provided with the air inlet 20 is corrosion resistance and wear resistance Applying excellent stainless steel (SUS310) material, the vibrating fluid plate 215 is made of Teflon material with a low permittivity for the purpose of permeation of the supplied microwave, and the temperature inside the mixture of low coal and heavy ash powder Temperature sensor 214 for measuring is preferably made of a stainless steel shielding material.

Hereinafter, the present invention will be described in more detail with reference to the following examples.

Configuration of the device

The microwave supply is 2.45 GHz, 2 kW, 220 V, single phase, and two vibration supply devices 35 of 0.45 kW capacity are attached to both sides to uniformly vibrate the vibrating fluidized bed body. The overall low carbon high-definition device shape is shown in FIG. 2, and the device volume is 100 cm for the porous plate 211, and the wave shaped vibration flow plate 215 is 200 cm long, 30 cm wide, and 30 cm high. The temperature sensors 214a and 214b used a stainless steel shielded thermocouple, and the diameter of the mounting portion for installing them was 1 cm, and the steam suction portion 22, the lower coal inlet 17, and the heavy ash powder inlet 18 were installed. The area of was set to 2 inches x 2 inches. The size of the pores 211a of the perforated plate is 1 / 5-1 / 10 of the particle size of low coal particles 10-30mm, consisting of 154 5 shafts and 4 long shafts each with a diameter of 5mm. The plate 215 was composed of a thickness bottom side 215a 2cm, a top height side 215b 5cm, and a width 215c 20cm as shown in FIG.

Experimental conditions for using the above-described device is as follows.

Coal: 1 type of imported coal from Indonesia

Total moisture content: 36.4%

Coal size: 20mm particle size

Vibration Flow Speed: 12cm / min

1st drying method: Heated air contact with perforated plate

Primary drying temperature: see Table 1 below

Primary dry air injection speed: 2m / s

Primary dry air injection rate: 0.36㎥ / min

Condensation prevention and upper circulation air injection volume: 0.72㎥ / min

Secondary drying method: microwave irradiation and binding water molecule rotation

Secondary drying temperature: see Table 1 below

Second drying time: see Table 1 below

Low coal throughput: 20 kg / hr

Heavy oil powder supply: 5kg / hr

<Example 1, Comparative Examples 1 to 3>

High quality of the lower coal was carried out using the conditions as shown in Table 1 below. The results are shown in Table 2.

That is, in Example 1, after the first drying, the secondary oil drying of the heavy oil ash powder and the microwave drying were performed in parallel. Comparative Example 1 was carried out in the same manner as in Example 1, except that heavy oil ash powder was not added, Comparative Example 2 was only microwave drying without the addition of heavy oil ash powder without the first drying, Comparative Example 3 2 We did not carry out car drying itself.

Table 1 Experimental conditions table

	Primary drying	Secondary drying
		Microwave probe	Heavy ash powder
Example 1	8 minutes at 120 ℃	17 minutes at 120 ° C	adding
Comparative Example 1	8 minutes at 120 ℃	17 minutes at 150 ° C	No addition
Comparative Example 2	Do not conduct	17 minutes at 150 ° C	No addition
Comparative Example 3	25 minutes at 120 ° C	Not investigated	No addition

TABLE 2 Characteristics of Low Coal Heavy Ash Powder and High Quality Coal

	supply		High quality coal
	Low-grade coal	Heavy ash powder	Example 1	Comparative Example 1	Comparative Example 2	Comparative Example 3
Total moisture (% by weight)	36.4	5.65	5.0	11.8	13.5	25.3
Ash (weight%)	3.0	7.08	3.21	3.09	3.08	2.89
Volatile matter (% by weight)	50.1	11.56	47.59	45.06	45.04	38.78
Fixed Carbon (wt%)	42.9	70.80	44.2	40.05	38.38	33.03
Fuel cost	0.86	4.28	0.93	0.89	0.85	0.85
Calorific Value (Kcal / kg)	6291	7553	7210	6950	6800	5300
C (% by weight)	69.76	95.24	71.03	71.02	70.58	70.5
H (% by weight)	4.82	0.3	4.59	4.67	4.97	5.12
N (% by weight)	1.15	1.56	1.16	1.14	1.13	1.14
S (% by weight)	0.12	1.14	0.16	0.14	0.13	0.15
O (% by weight)	24.13	ND	23.06	23.03	23.19	23.09
Particle size	Particle size 20mm	Particle size 74㎛	ㅡ	ㅡ	ㅡ	ㅡ

The fuel ratio is a fixed carbon content / volatile content (FC / VM).

As shown in Table 1 and Table 2, low-grade coal has a water content of about 36.4 (about 36%), and a heat content of 6,291 Kcal / kg based on drying is higher than anthracite but lower than 6,500 kcal / kg of coal for coal-fired power plants. On the side. The fuel cost was 0.86, which is similar to the sub-bituminous series, and it was confirmed that the fuel was suitable for the specification as a thermal power plant fuel when the moisture was dried to 10% or less. In addition, the heavy oil-powdered ash powder used as an additive has a moisture content of 5.65%, a calorific value of 7,553 Kcal / kg, and a high fixed carbon content of 70.80%.

In the case of Example 1 irradiated with heavy oil ash powder and microwave according to the present invention, the high-grade coal produced had a very low water content of 5.0% and a very high heat content of 7,210 kcal / kg. In particular, the fuel cost has a characteristic of greatly improved to 0.93. From the physical properties of Table 2, it was found to be suitable as a raw material for burning coal-fired power plants. However, Comparative Examples 1 to 3 corresponding to other methods were found to be very difficult to dry to less than 10% moisture.

Experimental Example 1

The spontaneous ignition was investigated using a bench scale test apparatus using the high quality coal produced in Examples 1 to 4, and the results are shown in FIG. 6.

Here, spontaneous ignition is carried out by placing a sample of a certain volume (106 mm in diameter and 350 mm in height) in a bench test device, heating it to 50 ° C. in a nitrogen atmosphere, and then switching the atmosphere to dry air. It evaluated by comparing the time until the temperature of reaches 80 degreeC and 150 degreeC.

The control shown in Figure 6 shows the experimental results of the bituminous coal used in the coal-fired power plant.

As shown in FIG. 6, the high-grade coal of Example 1 according to the present invention covers the pores and active sites on the surface of the heavy oil fine powder added and mixed during the drying process to react with oxygen in the air. By interfering, the time to reach 80 ° C. and 150 ° C. was measured for a very long time compared to bituminous coal and other coals of the comparative examples, and as a result, it was found that spontaneous combustion was relatively low.

Claims (6)

1. Firstly dry by injecting heated air at 100 to 130 ° C into lower coal having a particle size of 10 to 30 mm and a water content of 30% or more, and adding heavy oil ash powder having a particle size of 74 μm or less to 100 parts by weight of the lower coal. After mixing by adding 20 parts by weight of a high-grade coal, characterized in that the secondary drying at 120 ~ 150 ℃ microwave as a heat source.
2. A lower coal supply unit including a lower coal storage tank in which lower coal is stored, and a lower coal rotary feeder and a diaphragm for transporting the lower coal to the lower portion;

   Heavy oil ash powder storage tank in which heavy oil ash powder is stored, heavy oil ash powder mill for pulverizing the heavy oil ash powder to a particle size of 74 μm or less, heavy oil ash powder storage tank for storing the finely divided heavy oil ash powder, and scattering in the storage tank A heavy oil ash powder supply unit including a heavy oil ash powder bag filter for collecting the powder, and a rotary valve for transporting the heavy oil ash powder to a lower portion, and a heavy oil ash powder supply screw;

   A heat-air supply unit comprising a blower, a heat exchanger for recovering heat of dried and stabilized high-quality coal, and a heater for heating the heat-exchanged air with drying air;

   Lower coal inlet through which the coal transported through the lower coal supply unit is input, heavy oil ash powder inlet through which heavy oil ash powder transferred through the heavy oil ash powder supply unit is input, and heated air transferred through the heating air supply unit to one side Heated air inlet for injecting through the formed nozzle, the porous plate is provided with an air inlet on one side for primarily drying the lower coal through the lower coal injected through the lower coal inlet, the primary Low coal stabilizer for drying secondary coal at 120-150 ° C. using microwave as a heat source by mixing dried lower coal and heavy oil ash powder, a steam suction unit for sucking steam decomposed during drying of the lower coal, the drying and High quality coal outlet for discharge of stabilized coal, heavy oil ash finely adsorbed in matrix form A fine powder discharge portion comprises a lower coal drying for discharging end and the stabilizing unit;

   And a high quality coal storage unit including a rotary feeder of high quality coal transported through the high quality coal outlet and a high quality coal storage tank for storing the transferred high quality coal.
3. The method according to claim 2,

   The lower coal stabilization device comprises: a wave-type vibration flow plate for uniform mixing of the first dried lower coal and the heavy ash powder introduced from the heavy oil ash powder inlet, and the lower coal And a microwave feeder for microwave drying the mixture of heavy oil ash powder and a temperature sensor for measuring the temperature inside the mixture of the lower coal and heavy ash powder.
4. The method according to claim 2,

   The low coal high quality device is: a vapor phase powder recovery device for collecting powder in dry steam sucked by a steam suction unit attached to an upper portion of the low coal stabilization device, and a heavy oil ash powder recycler for recycling the recovered powder A blower, a powder suction pump for sucking dry steam after collecting the powder, a condenser for condensing the sucked vapor phase air, a gas-liquid separator separating gas from the condensed condensate, a condensate storage tank for storing the condensed water from the gas-liquid separator, And a cracked gaseous powder recovery unit comprising a circulating pump for sending the condensed water to the cooling water.
5. The method according to claim 2,

   The low grade coal high quality device:

   High-grade coal low-grade coal, characterized in that it further comprises an accessory unit consisting of a vibration fluidizer lower spring, a vibration supply device, a vibration fluid support.
6. The method according to claim 3,

   The vibration fluidizing plate is a low-grade coal high quality device, characterized in that made of a material having a low permittivity (permittivity) is possible to transmit the microwave.

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