KR101281016B1 - A gasification system - Google Patents

Abstract

PURPOSE: A gas fuel system and apparatus thereof is provided to increase the combustion efficiency of combustion gas and reduce the waste factor of energy. CONSTITUTION: Petroleum cokes are supplied in the form of carbide mass, which is stored in storage (10) without being micronized, to a combustion chamber (20). Multiple nozzles (21) are formed at a lower part of an inside of the combustion chamber, and a cyclone (20a) is formed at a lateral part of the combustion chamber in order to be connected with a discharge path and an inlet at the upper part and lower part of the combustion chamber. An outlet (21a) in which incompletely burned gas is discharged is formed at the top of the cyclone. The cyclone is connected with the discharge path (21a-1) and inlet (22a). The air for flotation is supplied to an air injection line (23a,23b) by pan (23). Fire fuel and combustion air are supplied through a fire fuel line (2) and a combustion air line (3) and burned by an ignition burner (4). A steam line (5) is connected to a steam outlet (33) of a boiler (30) for the generation of H2.

Description

Gas fuelization system and apparatus using petroleum coke fuel in undifferentiated solid state to have excellent combustion efficiency by circulating floating combustion method.

The present invention is a by-product discharged from the final stage of crude oil refinery, so that the high-temperature low-grade petroleum coke (Petro Cokes), which is a carbon mass of solids, can be burned without being subjected to undifferentiated processing, thereby reducing processing costs and inducing incomplete combustion during combustion. It is to solve the problem that the limited use of solid fuel is regulated by enabling gasification as fuel.

In addition, to reduce the consumption of petroleum coke by recycling the unburned fuel generated during the gasification process.

At the same time, by using steam in the gasification process, CO and H ₂ are contained in the gasified combustion gas to improve the efficiency of the combustion gas.

In addition, when the steam used at this time is produced using waste heat, the water pipe is formed on the inner wall of the combustion chamber to simplify the facility.

In addition, to improve the productivity of the incomplete combustion gas heat exchanged by such water pipes, and to use the steam obtained in the industrial field at the same time to supply to the steam line to obtain H ₂ at the same time when ignition fuel is used as bunker C oil It can also be used as a steam for.

For direct heating by steam or burner used as energy in current industrial field, most boilers are operated by using heavy oil such as natural gas or bunker-C oil or coal, or used directly in burner. In the case of the use of coal, solid fuels are restricted or are not allowed to be used due to environmental pollution caused by fly ash.

In addition, such coal has the advantage that the price is cheaper than bunker-C oil, but there is a problem that the calories are lower than the bunker-C oil has a problem in practical use.

However, these also required the development of alternative energy in situations where productivity and oil producers' rising oil prices could not reduce energy use.

Therefore, in recent years, there have been many attempts to use petroleum coke, which is a petroleum by-product generated from refining crude oil refinery, to remove various oils and remain as solid carbides, but these petroleum cokes are easily used. It is not burned, and even if it is burned, it generates a large amount of harmful gas components such as sulfur oxides and nitrogen oxides, which are considered as the main causes of environmental pollution.

Therefore, recently, in order to solve this problem, pulverized petroleum coke in solid form is subjected to micronization processing, and then mixed with bunker C oil, etc. At this time, minimizing the air cost to suppress the generation of nitrogen oxides, thereby saving energy and environmental pollution. Although it is expected to prevent the generation of nitrogen oxides, the use of direct combustion has been problematic because it does not completely suppress the generation of nitrogen oxides.

Therefore, in recent years, it is mostly used in a boiler having a separate combustion chamber for steam production, because the general combustion characteristics of the pulverized petroleum coke fuel is characterized in that the fuel itself burns on the surface.

That is, in order to activate the reaction of the surface combustion of the pulverized petroleum coke, the inside of the combustion chamber of the boiler must be maintained at a high temperature of about 1200 ° C to 1400 ° C and the combustion flame must be made long.

However, even when used in the boiler equipped with a combustion chamber, the cost is increased, there is a problem that the damage of the boiler equipment occurs.

In other words, the micronized state becomes more micronized than that of conventional coal, and the micronized fuel is micronized to a fine size that can be all burned before passing through the combustion chamber, which increases the processing cost.

In addition, the combustion temperature of the combustible ash is very high, the temperature rises to a high temperature above the melting point that can melt the ash contained in the non-combustible ash, so that the water pipe in the boiler chamber due to the melting of such ash (ash), or It is attached to the refractory bricks forming the inner wall of the combustion chamber, causing serious problems of the installation.

Therefore, the use of such petroleum coke has a lot of restrictions on the use of the environment in consideration of the environment, which means that low-cost fuel is not generally used.

Therefore, in recent years, the operation of gasification which heats petroleum coke to high temperature, contacts it with air or steam, and converts carbon components other than ash into a flammable gas by pyrolysis is performed actively.

However, even at this time, in order to burn petroleum coke fuel, undifferentiated work is needed, and thus additional costs for processing and considerable equipment are required. Existing fuels such as petroleum coke and bunker-C oil are mixed. The use of additional fuel, as well as the need for separate heating equipment, means that no substantial savings can be expected.

Therefore, the applicant of the present application induces incomplete combustion without undifferentiated petroleum coke so that the gasification can be carried out by allowing the petroleum coke, which is a lump of carbide, to be floated by the base metal heated at a certain temperature and pneumatically to be mixed and combustible. In order to make the combustion lasting, load oxygen is added and the load oxygen is introduced to the minimum to induce continuous combustion and incomplete combustion so that combustion gas, a clean fuel containing a large amount of CO gas, can be obtained. will be.

However, the disadvantage of this is that unburned fuel is generated when petroleum coke fuel is floated and burned like a heated base material by pneumatic pressure. This unburned fuel is raised by pneumatic and unburned fuel is just discharged into the atmosphere. Additional removal of minutes was required.

In addition, the main components of the combustion gas are CO and H ₂ , and the lack of H _{2 means} that the combustion efficiency is lowered in practical use. When bunker C oil is used for heating the base metal, it is difficult to atomize the combustion of the bunker C oil. The difficulty in heating the base metal, of course, is that bunker C oil lost due to incombustibility is present.

Therefore, in the present invention, petroleum by-products generated in the process of refining crude oil in oil refineries are removed from various oils and then petroleum cokes (Petro cokes), which remain as solid carbide lumps, are burned in undifferentiated lumps to be undifferentiated. To reduce processing costs for

In addition, combustion of combustion gas obtained by gasification process by generating H ₂ gas in addition to CO gas generated when incomplete combustion occurs when burning petroleum cokes, which remain as solid carbide masses, with a heated base metal. To improve efficiency,

In addition, by reducing the waste of energy by re-injecting the unburned dust generated during the combustion process into the combustion chamber,

In addition, even when ignition fuel for heating the base metal is used as bunker C oil, it is possible to prevent waste of bunker C oil while improving combustion rate.

In addition, it is possible to produce steam without using a separate boiler for the generation of steam for this purpose, and at the same time to induce the time of heat exchange quickly while maintaining the simplicity of the facility,

In addition, the waste heat is used to save energy by producing steam without using a separate boiler, and the steam obtained by heat exchange can be used in industrial facilities.

To this end, in the present invention, petroleum coke, which is left as a solid carbide mass in the form of undifferentiated processing, is injected into the combustion chamber, and the combustion is performed by using the ignition fuel and the combustion air in the combustion chamber. Heat the base material in the chamber to a certain temperature,

When the heating is completed, petroleum coke in the form of carbide agglomerate is put into the combustion chamber to shut off the supply of ignition fuel, and at the same time, air is injected into the combustion chamber at the bottom of the combustion chamber so that they start mixing as they vortex and float together. Forever,

At this time, the combustion air (loaded oxygen or pure oxygen) is supplied for the continuous combustion, and the combustion air is supplied to the minimum to obtain the CO gas from the incomplete combustion while the combustion is continued.

At this time, when petroleum coke is introduced to obtain H ₂ simultaneously with the obtained CO gas, steam is simultaneously introduced.

As such, the incomplete combustion gas containing CO and H ₂ is elevated by the rising air generated by the heat of combustion in the combustion chamber and the air injection for floating, and is first heat exchanged and purified, thereby stopping the combustion chamber at the top. The unburned gas contained in the incomplete combustion gas containing CO and H ₂ is passed through the cyclone while being heat exchanged and purified secondly by the installed water pipe to be separated through the cyclone and sent to the combustion chamber for recombustion.

The combustion gas containing CO and H ₂ purified by heat exchange is exchanged with water supplied to the economizer and exchanged with the water supplied to the economizer, and the heat exchanged to low temperature for use as the combustion gas, and at the same time, the water supplied to the water pipe by waste heat during such heat exchange. Is converted into hot water so that the heat exchange efficiency in the water pipe is excellent, and the heat exchange and purification,

The unburned dust separated from the cyclone is guided to the lower portion of the cyclone to be re-injected into the combustion chamber by the injection of air for flotation, thereby re-burning, thereby reducing energy waste and simultaneously removing the unburned dust. This would allow gasification for use as a clean fuel.

When bunker C oil is used as the ignition fuel to heat the base material firstly, the water pipe installed on the inner wall of the combustion chamber for the second heat exchange of steam input to improve the use efficiency of the bunker C oil as the ignition fuel is required. It is to improve the use efficiency of bunker C oil by injecting steam obtained through the atomization to atomize bunker C oil,

The water supplied to the water pipe is to prevent the corrosion of the water pipe of the boiler due to rapid condensation during heat exchange of incomplete combustion gas while using the heated water obtained by the third heat exchange in the crusher. .

At this time, if bunker C oil is not used as ignition fuel and LNG is used, steam is not used in the heating step of the base metal.

Therefore, by forming only the cyclone in communication with the combustion chamber, it is possible to reburn unburned by a simple equipment, saving energy efficiency of more than 20%,

In addition, when bunker C oil is used as the ignition fuel for the primary heating of the base material for burning the petroleum coke in the lumped state, the waste heat is used for heat exchange in the combustion chamber, and the steam generated by the water pipe installed on the inner wall of the combustion chamber is used. By making it atomize, it makes the use of ignition fuel excellent, and it saves energy by using steam obtained from the water pipe installed on the inner wall of combustion chamber in industrial field, and by continuously injecting this steam into combustion chamber. In addition to CO gas generated when petroleum coke is injected into incomplete combustion, H ₂ gas is generated to improve the quality of the combustion gas obtained in the final stage.

In addition, when the unburned fraction separated from the cyclone is re-injected into the combustion chamber, the base material and petroleum coke are floated, and only the air of the same pressure is injected into the cyclone to inject the incomplete combustion gas which is injured during combustion in the combustion chamber. Instead of backflow, it is automatically fed into the combustion chamber.

1 is a system diagram showing the structure of an overall system of the present invention.
Figure 2 is a connection state diagram of the steam line of the present invention
Figure 3 is a state in which a water pipe is installed on the inner wall of the combustion chamber of the present invention.
4 is a state in which the cyclone is mounted on the combustion chamber of the present invention.
5A to 5D are state diagrams of the nozzle of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

Figure 1 shows the overall system of the present invention, Figure 2 is a state of mounting the cyclone in the combustion chamber of the present invention, Figure 3 is a state diagram of the water pipe is installed on the inner wall of the combustion chamber, Figure 4 is a diagram of various embodiments of the nozzle.

1 and 4, a reservoir 10 in which petroleum coke in a carbide mass is stored;

BLOWER 11 or screw to supply petroleum coke in the form of undifferentiated carbide mass stored in the reservoir 10

A combustion chamber 20 for burning the petroleum coke supplied using the blower 11 or a screw;

The combustion chamber 20 has a plurality of nozzles 21 are formed at the lower end of the inside of the combustion chamber 20 is formed long vertically, and discharged in communication with the upper and lower ends of the combustion chamber 20 toward the side of the combustion chamber 20 Incomplete combustion gas including unburned gas in which incomplete combustion gas incompletely burned in the combustion chamber 20 is discharged through the discharge flow path, and the cyclone 20a connected to the flow path 21a-1 and the inlet port 22a. The discharge port 21a is formed so as to separate the unburned dust so as to discharge only the incomplete combustion gas, and the inlet 22a for feeding the separated unburned dust back into the combustion chamber 20 below the discharge port 21a. ) Is formed.

At this time, the bottom of the combustion chamber 20 and the cyclone (20a) is a floating air injection line for causing the base material (1) heated by the air injected by the fan 23 and the petroleum coke in the lump state to rise ( 23a, 23b) is formed.

In addition, the upper portion of the nozzle 21 mounted inside the combustion chamber 20 is filled with a base material 1 for burning petroleum coke in a constant layer, and the lower end of the nozzle 21 has an ignition fuel line ( 2) and an ignition burner 4 through which the ignition fuel and the combustion air are supplied through the combustion air line 3 so that the ignition fuel is burned;

When the lumped petroleum coke supplied by the blower 11 or the screw 11a is combusted from the base material 1 and the reservoir 10 heated by the ignition burner 4 at the temperature of H ₂ , A steam line 5 for injecting steam generated from the water pipe 25 installed on the inner wall of the combustion chamber 20 for generation;

Steam generated from the water pipe 25 and the water pipe 25 installed on the inner wall of the combustion chamber 20 to heat exchange the incomplete combustion gas generated by incomplete combustion in the combustion chamber 20 to the industrial equipment line 31. A steam controller is provided with a vent 32 for supplying water or a natural discharge of steam for maintaining a constant pressure, a gate 33 for supplying water to the water pipe 25, and a discharge line 34 for discharging steam. 30) is formed.
At this time, the water supplied through the gate 33 is supplied to the heated water that is heat-exchanged in the coke 40.

In addition to the upper side in communication with the discharge port (21a) of the cyclone (20a) to ever temporarily stored for a surplus of the water tube 25, the combustion gas heat exchanger contains a purified CO and H ₂ via the CO and H ₂ Temporary storage tank 80 for temporarily storing the contained combustion gas is formed, the temporary storage tank 80 is a vent 81 is formed for safety.

In addition, the final heat exchange of the combustion gas containing CO and H ₂ which are discharged through the outlet 21a of the cyclone 20a and heat exchanged and purified, and the temperature of the water flowing in the water pipe 25 installed on the inner wall of the combustion chamber 20 When the low temperature is used to prevent the corrosion of the water pipe 25 by the rapid condensation of the high temperature incomplete combustion gas while using the heated water that is heat-exchanged in the blower 40 to improve the heat exchange efficiency.

In addition, in order to supply the combustion gas containing CO and H ₂ heat exchanged to the burner 40 to the burner 70 so as to maintain a uniform pressure, the combustion gas heat-exchanged in the blower 40 is forcibly blown. The blower 50 and the storage tank 60 for storing the combustion gas blown through the blower 50 to maintain a constant pressure is provided.

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Therefore, the burner 70 is configured to operate with combustion gas containing CO and H ₂ uniformly provided under a constant pressure in the reservoir 60.

Combustion air injected into the combustion air line (3) in the present invention is to use the load oxygen having a higher content of oxygen than the oxygen contained in the general air, so that the duration of combustion is excellent.

At this time, the heating temperature of the base material (1) heated before the petroleum coke in the form of agglomeration by the combustion air supplied through the combustion air line (3) and the ignition fuel supplied through the ignition fuel line (2) is In the present invention, it is to be heated to 1100 ~ 1200 ℃, this temperature is changed according to the combustion state of petroleum coke, the temperature range does not limit the object of the present invention.

In addition, the base material 1 heated to such a temperature is to use a material that does not melt even under such heating.

In the present invention, the base material 1 uses sand containing a lot of silicon dioxide (SiO ₂ ) whose melting point is higher than the heating temperature, and the particle size of the petroleum coke in the lump state is about 1 cm larger than the particle size of the sand. Was used.

However, the kind of the base material 1 and the size of the particles of petroleum coke do not limit the object of the present invention.

At this time, the size of the heated base material 1 is formed to be smaller than the size of the particles of petroleum coke in the form of a carbide mass burned in contact with the base material 1 through the floating air injection line (23a) by the fan 23 In the case where the base material 1 and the petroleum coke are floated by the strong air supplied, it is desirable to be intimately mixed with the petroleum coke in the form of a lump and to burn.

In addition, when the base material 1 is heated to the combustible temperature of the petroleum coke by the combustion air supplied through the combustion air line (3) and the ignition fuel supplied through the ignition fuel line (2). Shutting off the supply and continuously injecting only combustion air, the petroleum coke fuel in the form of agglomerate is injected into the combustion chamber 20.

At this time, the nozzle 21 is formed with a shade 22 at the upper end of the nozzle 21 in order to prevent the entry of the ignition flame by the burner 4 and to prevent the base material 1 from blocking the nozzle 21. 1) of the combustion chamber 20 when the strong air for the injury blown from the combustion air line 3 and the fan 23 is supplied by the floating air injection line 23a while preventing 1) from clogging the nozzle 21. As the vortex is generated inside, the heated base metal 1 and the lumped petroleum coke are mixed with each other to float and start combustion.

In addition, in the present invention, when the base material 1 is primarily heated to a predetermined temperature by the combustion air supplied through the combustion air line 3 and the ignition fuel supplied through the ignition fuel line 2, the ignition fuel is used. If liquefied gas is used or bunker C oil is used, the steam generated from the water pipe 25, which is heat-exchanged by waste heat, is used to improve the efficiency of fuel use if bunker C oil with high viscosity is used. By injection into the interior of the combustion chamber 20) by the atomization of the bunker C oil ignition fuel is to improve the use efficiency of the fuel.

In this way, the base material 1 is ignited in a state where the heating is completed in a state where combustion of petroleum coke is possible by the combustion air supplied through the combustion air line 3 and the ignition fuel supplied through the ignition fuel line 2. The injection of ignition fuel through the fuel line 2 is stopped, and only the combustion air is kept at a minimum injection amount when continuously injected by the combustion air injection line 3, thereby inducing incomplete combustion. .

For example, complete combustion occurs when the air content in combustion is 1.3 when the fuel is 1, but incomplete combustion occurs by using 1.3 or less for incomplete combustion.

In the present invention, in consideration of the persistence of combustion and the amount of CO gas generated during incomplete combustion, the most economical range is 0.5 to 0.9, but the present invention can achieve the object even when the combustion is less than or equal to.

However, when the supply amount of combustion air is less than 0.5, it was confirmed that a problem occurs in continuous combustion.

In addition, when the incomplete combustion gas rises as the lumped petroleum coke introduced into the upper portion of the heated base material 1 is incompletely burned at the lower end of the combustion chamber 20, the combustion chamber 20 is formed high up and down. As the temperature of the upper layer is lower than the lower layer, the incomplete combustion gas is first heat exchanged as it rises to the upper layer and drops to 800 to 900 ° C. Then, the second gas is heat-exchanged by the water pipe 25 installed on the inner wall of the upper layer of the combustion chamber, thereby incomplete combustion gas. The ash (ASH) contained in is lowered as it condenses, and then is discharged through the drain 24 formed in the lower portion of the combustion chamber 20.

In addition, when the incomplete combustion gas is increased while the lumped petroleum coke is incompletely burned, unburned unburned coal is simultaneously raised, which is burned while the lumped petroleum coke is floated by the strong air blown from the fan 23. When supplied through the floating air injection line 23a, the heated base material 1 and the lumped petroleum coke are floated and mixed with the heated base material 1 to burn the petroleum coke in the incomplete combustion. When the incomplete combustion gas is raised while the unburned unburned fuel is generated, the incomplete combustion gas containing unburned fuel is introduced into the cyclone 20a through the discharge passage 21a-1, and the CO gas usable as the combustion gas is In order to exchange heat and purify, it is discharged to the next process through the discharge port 21a Minute song and advance is to be input again while falling to the bottom of the cyclone (20a) through the inlet (22a) to the bottom of the combustion chamber 20.

Therefore, the lump of petroleum coke is introduced into the upper portion of the heated base material (1) by the air injection through the air injection line (23a) that is strongly supplied by the fan 23 into the heated base material (1) and lumps Combustion is started when the petroleum coke is made to float, and the combustion is continued by injection of combustion air through the combustion air line 3 which is greater than the load oxygen, and the amount of the combustion air is minimized. As combustion continues while being supplied, incomplete combustion is achieved by the minimum amount of combustion air.

Therefore, the heated base material 1 and the air petroleum coke introduced thereafter are blown from the fan 23 are supplied to the combustion chamber 20 through the floating air injection line 23a and floated while being mixed and in close contact with each other. As the air is injected, the lumped petroleum coke is easily combusted by the heated base material 1 and at the same time, the base material 1 is continuously maintained by the heat of combustion and the combustion air of the petroleum coke.

In this case, the combustion air for combustion is made by injecting only the minimum amount of air into the combustion air including the load oxygen. Thus, incomplete combustion is performed while the combustion continues. Thus, incomplete combustion gas generated in the state of incomplete combustion is CO. The gas is contained in a large amount and such incompletely burned CO gas is raised to the upper layer of the combustion chamber 20 by the heat of combustion and the air pressure of the air injected through the floating air injection line 23a blown from the fan 23. Will be.

At this time, since steam is supplied from the water pipe 25 formed on the inner wall of the combustion chamber 20 by the steam line 5 at the same time, the steam is pyrolyzed to generate H ₂ . Excellent combustion gas consisting of H ₂ is obtained.

Thus incomplete been containing CO and H ₂ combustion gases When raised to an upper layer of the combustion chamber 20 by the updraft combustion chamber 20 has an upper layer temperature of the formed higher up and down lower than the lower CO and H ₂ As the incomplete combustion gas containing is gradually lowered as the temperature rises, the first heat exchange to 800 ~ 900 ℃ while the temperature is dropped to 300-350 ℃ again by the water of the water pipe 25, in this case contains CO and H ₂ Ash ASH contained in the incomplete combustion gas is gradually condensed and refined to descend to the lower end of the combustion chamber 20. At the same time, uncondensed non-condensed gas is discharged to be transferred to the next process (crusher). a cyclone (20a) is only the combustion gas containing CO and H ₂ can been used as a pure fuel gas is discharged while passing through the section is sent to the tangi 40 for the third heat exchanger, the non-drawn minutes It would be to fall to the bottom of the cycle theory (20a).

As described above, when the unburned powder dropped to the lower end of the cyclone 20a is also injected into the lower portion of the cyclone 20a through the floating air injection line 23b, the unburned powder may be Unburned powder is injected into the lower end of the combustion chamber 20 through the inlet 22a.

Then, when the injection of air for floating is supplied through the floating air injection line 23a, the unburned powder, the heated base material and the petroleum coke lump are floated at the same time in the combustion chamber 20, and combustion occurs to enable complete combustion of the unburned powder. Will be.

At this time, the CO gas is generated while the incomplete combustion is made as described above, and at the same time, ₂ H gas is generated by the steam supplied through the steam line 5, thereby producing a combustion gas containing CO and H ₂ .

At this time, when the unburned powder is introduced into the combustion chamber 20 through the inlet 22a of the cyclone 20a, the pressure of the inlet 22a is formed higher than the pressure inside the combustion chamber 20. 22a), the petroleum coke or the base metal 1, which floats in the combustion chamber 20, does not flow back.

The reason is that the combustion chamber 20 and the cyclone 20a communicate with each other, and the base material supplied from the fan 23 and the lumped petroleum coke are supplied through the floating air injection line 23a for floating combustion. The uniform pressure is generated in the combustion chamber and the cyclone by the pressure of the floating air, and the air of the same pressure is additionally injected through the floating air injection line 23b from the fan 23 at the lower portion of the cyclone 20a. This is because the pressure of the cyclone 20a is increased that much.

In addition, the ash condensed and dropped in the combustion chamber 20 is discharged through the drain 24 formed in the lower portion of the combustion chamber 20, and contains CO and H ₂ discharged through the discharge port 21a to the upper side of the cyclone. The burned gas is separated and refined in the heat exchanged state, so that the combustion gas containing CO and H ₂ falls to 300 to 350 ° C., and is then transferred to the coal blower 40 for the heat exchange to a low temperature. It is possible to use as a combustion gas as a clean fuel by maintaining about 250 ℃ easy handling while heat exchange.

In addition, the incomplete combustion gas been a CO and H ₂ obtained from the combustion chamber 20 is contained as described above, the CO and H ₂ contained in the case to be heat exchange primarily by the water tube 25 provided on the inner wall of the combustion chamber 20, In order to prevent the high temperature incomplete combustion gas from being corroded to the water pipe 25 due to rapid condensation by the water pipe 25, the water supplied to the water pipe 25 is heated in a third heat exchanger in the cinder 40. By using hot water to prevent the corrosion of the water pipe 25 due to the rapid condensation of incomplete combustion gas containing CO and H ₂ by heat exchange in the water pipe 25, it is possible to provide at a low temperature for use of the combustion gas will be.

At this time, the water pipe 25 formed on the inner wall of the combustion chamber 25 is provided with a pump (not shown) for forcibly circulating in the steam controller 30 installed thereon to induce the flow of water flowing into the water pipe. Convection causes natural flow.

In addition, since the pressure in the combustion chamber 20 is kept lower than atmospheric pressure to prevent leakage, the combustion gas passing through the blower 40 due to the low pressure is forcibly blown using the blower fan 50. The combustion gas containing CO and H ₂ blown through the blowing fan 50 is supplied to the burner 70 in a uniform amount in a state of being stored at a constant pressure in the storage tank 60.

In addition, when the incomplete combustion gas which rises to the upper layer of the combustion chamber 20 and the unburned gas is separated and discharged from the cyclone 20a is discharged, the incomplete combustion gas is not transported to the coal blower 40 for heat exchange. If it is transported to the temporary storage tank 80 and nevertheless generated above, the vent 81 is formed in the temporary storage tank 80 for natural exhaust to the atmosphere.

10: storage 20: combustion chamber
20a: cyclone 21a: discharge outlet
22a: Inlet
21: Nozzle 22: Nozzle shade
23: Fan 23a, 23b: Air injection line
24: Drain 25: Water pipe
30: Steam controller 31: Industrial equipment line
32: Vent 33: Gate
34: discharge line
40: Blower 50: Blower fan
60: storage tank 70: burner
80: temporary storage tank 81: vent
1: Base material 2: Ignition fuel line
3: Combustion air line 4: Ignition burner
5: steam line

Claims (7)

By ignition by ignition fuel and combustion air, the base metal filled in the combustion chamber by the ignition burner is heated to a constant temperature.
When the base material is heated to a certain temperature, the ignition fuel is shut off, and then the combustion air is continuously mixed with the heated base material. They are injured and burned,
When commencement of combustion, supply the combustion air to the minimum to incomplete combustion, and generate incomplete combustion gas containing a large amount of CO,
The incomplete combustion gas containing a large amount of CO is first heat exchanged while rising to the upper part of the combustion chamber by the rising air generated by the pressure of the injected air by the fan, and the ash is condensed and lowered, and the incomplete containing CO and unburned The combustion gas passes through a cyclone to separate unburned dust,
The separated fine dust is dropped to the bottom of the cyclone and re-injected into the lower part of the combustion chamber by forced air by injection air injected from the bottom of the cyclone.
Incomplete combustion gas containing unburned CO is circulated floating combustion by using undistilled solid petroleum coke fuel which is heated and purified secondly through a water pipe formed on the inner wall of the combustion chamber as it rises to the combustion chamber. Gas fueling system to have a good combustion efficiency in a manner. The method of claim 1, wherein when the ignition fuel is bunker C oil, the steam generated in the water pipe formed on the inner wall of the combustion chamber that is heat-exchanged by waste heat is supplied through the steam line through the discharge line of the steam controller to atomize the bunker C oil. A gas fuelization system that uses a petroleum coke fuel in an undifferentiated solid state to have excellent combustion efficiency in a circulating floating combustion method. The method of claim 1, wherein when the petroleum coke is injected and burned in the state in which the base material is heated, the CO is continuously contained through the steam line by continuously injecting steam generated in the water pipe formed on the inner wall of the combustion chamber by heat exchange. An undifferentiated solid state petroleum coke fuel containing H ₂ in the incomplete combustion gas which has been used, and a gas fuelization system having excellent combustion efficiency by a circulating floating combustion method. The method according to claim 1, wherein the cyclone communicating with the combustion chamber has a heated base material and agglomerated state in the combustion chamber when the unburned powder falling to the lower portion of the cyclone is introduced into the combustion chamber through an inlet. Undifferentiated solid petroleum coke fuel is injected into the lower part of the cyclone by using the air pressure for flotation to prevent backflow to the inlet when the base material and the petroleum coke are floated and burned in the combustion chamber. Gas fueling system to have excellent combustion efficiency by using circulating floating combustion system. The cyclone of claim 1, wherein the cyclone communicating with the combustion chamber maintains the pressure lower than atmospheric pressure, and when supplied to a burner for use in an industrial site, a blowing fan is forcibly blown and a blown storage tank. A gas fuelization system that uses an undifferentiated solid petroleum coke fuel, which is supplied in a state where it is stored at a constant pressure, to have an excellent combustion efficiency in a circulating floating combustion method. According to claim 3, The first heat exchanged combustion gas containing CO and H ₂ separated in the cyclone is to be heat-exchanged secondly by a water pipe formed on the inner wall of the combustion chamber, and the heat exchanger in the third stage in the burner again burner In case of supplying to the gas, the gas fuelization system uses the undifferentiated solid petroleum coke fuel, which is stored at a constant pressure in the reservoir through a blower fan and is supplied uniformly, so that the combustion efficiency is excellent by the circulating floating combustion method. . A reservoir 10 in which petroleum coke in a carbide mass is stored;
A combustion chamber 20 in which petroleum coke is supplied using a blower or a screw in the form of an undifferentiated carbide mass stored in the reservoir;
The combustion chamber 20 has a plurality of nozzles 21 are formed at the lower end of the combustion chamber 20 in the state formed long up and down, and discharge passages at the upper and lower ends of the combustion chamber 20 toward the side of the combustion chamber 20. Cyclone is formed in communication with the inlet,
The upper part of the cyclone 20a is formed with a discharge port 21a through which the incomplete combustion gas incompletely burned in the combustion chamber 20 is discharged, and below the discharge port 21a, the unburned powder contained in the incomplete combustion gas falls. It is to be re-inserted into the inlet communicating with the lower end into the combustion chamber 20,
Floating air injection lines 23a and 23b are formed at the lower ends of the combustion chamber 20 and the cyclone 20a to be supplied by the fan 23.
The upper part of the nozzle 21 mounted inside the combustion chamber 20 is filled with a base material 1 for burning petroleum coke in a predetermined layer, and an ignition fuel line 2 at the lower end of the nozzle 21. And an ignition burner (4) through which the ignition fuel and the combustion air are supplied and burned through the combustion air line (3);
A steam line 5 connected to the discharge line 34 of the steam controller 30 for generating H ₂ when the heated base material 1 and the petroleum coke are combusted;
Above the cyclone 20a, a temporary reservoir 80 in which a vent 81 for temporarily storing incomplete combustion gas is formed;
Steam controller 30 for controlling the steam generated in the water pipe for steam generation, as well as heat exchange and purification of incomplete combustion gas;
An economizer 40 for preventing the incomplete combustion gas from being rapidly condensed by the water pipe formed on the inner wall of the combustion chamber so as to heat-exchange the combustion gas secondaryly exchanged in the combustion chamber to the third;
A blower (50) for forcibly blowing the combustion gas heat-exchanged in the third mill
A reservoir 60 for storing the combustion gas blown by the blower to maintain a constant pressure;
And a gas fuelizing device having excellent combustion efficiency in a circulating floating combustion method using petroleum coke fuel in an undifferentiated solid state composed of a burner 70 operating with combustion gas uniformly provided in the storage.

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