阅读说明：本技术 一种气化煤气燃料的制备系统 (Preparation system of gasified gas fuel ) 是由 程珩 叶文约 苟立刚 于 2021-09-30 设计创作，主要内容包括：本发明公开了一种气化煤气燃料的制备系统,包括工业炉窑,具有热风出口、烟气出口和蒸汽出口；气化炉,具有热风进口、烟气进口、蒸汽进口、氧气进口、原料进口和出气口；供氧系统,与氧气进口连接,供氧系统用于给所述气化炉提供氧气；热空气、烟气、蒸汽、氧气、低质煤粉和可燃物粉末在所述气化炉内混合反应以产生气化煤气燃料,出气口用于输出气化煤气燃料。本发明将低质煤转化为煤气,用于工业炉窑燃烧使用,实现低质煤的优化使用。(The invention discloses a preparation system of gasified gas fuel, which comprises an industrial furnace kiln, a gasification furnace and a gasification furnace, wherein the industrial furnace kiln is provided with a hot air outlet, a flue gas outlet and a steam outlet; the gasification furnace is provided with a hot air inlet, a flue gas inlet, a steam inlet, an oxygen inlet, a raw material inlet and an air outlet; the oxygen supply system is connected with the oxygen inlet and is used for supplying oxygen to the gasification furnace; the hot air, the flue gas, the steam, the oxygen, the low-quality coal powder and the combustible powder are mixed and reacted in the gasification furnace to generate gasified coal gas fuel, and the gas outlet is used for outputting the gasified coal gas fuel. The invention converts the low-quality coal into coal gas for combustion in an industrial furnace, thereby realizing the optimized use of the low-quality coal.)

1. A system for producing a gasified gas fuel, comprising:

an industrial furnace (1) having a hot air outlet (120), a flue gas outlet (110) and a steam outlet (130);

the gasification furnace (2) is provided with a hot air inlet (220), a flue gas inlet (210A), a steam inlet (230), an oxygen inlet (240), a raw material inlet (250) and an air outlet (260), the hot air inlet (220) is communicated with the hot air outlet (120) to provide hot air for the gasification furnace (2), the flue gas inlet (210A) is communicated with the flue gas outlet (110) to provide flue gas with carbon dioxide for the gasification furnace (2), the steam inlet (230) is communicated with the steam outlet (130) to provide steam for the gasification furnace (2), and the raw material inlet (250) is used for feeding low-quality coal powder and combustible powder;

the oxygen supply system (3) is connected with the oxygen inlet (240), and the oxygen supply system (3) is used for supplying oxygen to the gasification furnace (2);

the hot air, the flue gas, the steam, the oxygen, the low-quality coal powder and the combustible powder are mixed and reacted in the gasification furnace (2) to generate gasified coal gas fuel, and the gas outlet (260) is used for outputting the gasified coal gas fuel.

2. A system for the production of a gasified gas fuel according to claim 1, wherein the gas outlet (260) is connected to a fuel inlet of the industrial furnace (1), and the gasified gas fuel is directly used for combustion in the industrial furnace (1).

3. The system for preparing the gasified gas fuel according to claim 1, wherein the gasification furnace (2) comprises a furnace body (270), the furnace body (270) is connected with an air inlet flue (210B), and a multi-channel burner (4) is communicated with the furnace body (270);

the raw material inlet (250) comprises a coal powder inlet and a combustible inlet;

the flue gas inlet (210A) is an inlet of the air inlet flue (210B), and the hot air inlet (220), the steam inlet (230), the oxygen inlet (240) and the pulverized coal inlet are inlets of any one channel of any one multi-channel burner (4) respectively;

the combustible inlet is an inlet of any channel of any multi-channel burner nozzle (4), or an auxiliary material inlet (290) arranged on the side wall of the furnace body (270), and the auxiliary material inlet (290) is arranged opposite to the air inlet pipeline (280);

the gasification furnace (2) further comprises an air inlet pipeline (280) arranged on the side wall of the furnace body (270), one end of the air inlet pipeline (280) is communicated with the furnace body (270), and the other end of the air inlet pipeline (280) is communicated with the air inlet flue (210B);

wherein the gas inlet pipeline (280) is eccentrically arranged with the central axis of the furnace body (270).

4. A system for preparing a gasified gas fuel according to claim 3, wherein the outlet of each multi-channel burner (4) is in the gas inlet duct (280) and the direction of the outlet is inclined toward the central direction of the furnace body (270), each multi-channel burner (4) is arranged by deviating from the axis of the gas inlet duct (280) and the outlet directions converge to a point or a plane, so that the multi-channel burners (4) form a plane of impact and generate a cyclone after being jetted.

5. The system for preparing a gasified gas fuel according to claim 3, wherein the outer profile of the gas inlet duct (280) is in a trumpet shape, the gas inlet duct (280) has a narrow end and a wide end, the wide end is disposed near the furnace body (270), and the narrow end is disposed near the gas inlet flue (210B).

6. A system for the production of gasified gas fuel according to claim 3, wherein a thickening layer (281) is provided around the inner peripheral wall of the gas inlet duct (280), the thickening layer (281) has a wave shape with two lower ends and a raised middle, and the thickening layer (281) divides the inner duct of the gas inlet duct (280) into a gourd shape with two wider ends and a narrowed middle.

7. A system for producing a gasified gas fuel according to claim 3, wherein the steam generating unit (5) is fixedly installed on the side wall of the furnace body (270) for absorbing the heat dissipated from the furnace body (270) and generating steam.

8. A method for manufacturing a system for manufacturing gasified gas fuel according to any of claims 1 to 7, comprising the steps of:

step 100, preparing low-quality coal materials and combustible materials into powder to obtain low-quality coal powder and combustible material powder;

step 200, introducing hot air, steam and flue gas generated by an industrial furnace from the side wall of the top end of a gasification furnace, introducing low-quality coal powder and combustible powder into the gasification furnace, and conveying oxygen to the gasification furnace through an oxygen supply system;

300, arranging the low-quality coal dust, the hot air, the steam, the flue gas and the oxygen to be firstly gathered together after entering the gasification furnace, and finishing multiphase mixing reaction so as to ensure that volatile matters and part of fixed carbon in the coal dust and O₂Conversion to CO by reaction₂And CO, steam and C into H₂Forming a combustion zone with CO, i.e. in the feed portion of the gasifier;

step 400, excessive CO is generated along with the sinking of high-temperature mixed gas in the combustion area of the gasification furnace₂And further reacting with the fixed carbon in the residual coal powder to reduce the fixed carbon into CO so as to form gasified coal gas which can be used as fuel, namely forming a reduction zone at the middle position and the discharge end of the gasification furnace.

9. The method for preparing gasified gas fuel according to claim 8, further comprising a gasified gas recycling method step 500, wherein a gas outlet of a gasification furnace is provided to be connected to a fuel inlet of an industrial furnace, and the gasified gas is directly introduced into the industrial furnace to be used as fuel;

wherein the gas outlet (260) comprises a main gas outlet (261) and an auxiliary gas outlet (262).

10. A method for producing a gasified gas fuel according to claim 8, wherein a water jacket (6) is provided on a side wall of the reduction zone for cooling the furnace body (270).

Technical Field

The invention relates to the technical field of industrial furnace and kiln gasification furnaces, in particular to a preparation system of gasified gas fuel.

Background

In modern industrial production, the coal gasifier has a wide application range, and is mainly applied to the chemical fields of ammonia synthesis, methanol, glycol, olefin, hydrogen production and the like, the electric power field of IGCC power generation and the energy fields of oil products, natural gas and the like. At present, coal gasification furnaces are mainly developed towards large-scale production, and the requirements on product quality are higher, such as the strict requirements on coal gas components in the field of coal chemical industry, and the requirements on coal gas heat value of IGCC power generation are higher. Along with the increase of the requirements of the gasification furnace on the coal quality, the supporting facilities are more and more complex, complex systems such as gas cooling, desulfurization, tar removal, naphthalene removal, dust removal, gas separation, purification, dehydration and drying and the like are required to be equipped, and the corresponding investment scale is also more and more large.

The development of the industrial furnace goes through a plurality of stages, and solid fuels such as lump coal, coke, coal powder and the like are adopted in the initial stage; then gas or liquid energy such as generated gas, city gas, natural gas, diesel oil, fuel oil and the like is gradually used as fuel. In the existing technology, the generated gas and the urban gas are both conventional coal gasification technologies, and a large amount of impurities are inevitably carried when fuel is provided for the industrial furnace, so that the industrial furnace needs to be matched with complex auxiliary equipment when in use, and the investment and maintenance cost of related equipment increase the production cost.

With the attention on environmental protection, the high pollution of the conventional coal gasification technology does not meet the requirement of the development of the times, so that the coal is gradually used to replace coal gas in the application of industrial furnaces. In order to ensure the product quality, production enterprises tend to adopt high-quality coal as fuel, such as cement kiln calcined clinker in building material industry, and adopt high-quality bituminous coal with the heat value of more than 5000 kcal and the volatile matter of more than 25%.

In practice, the low-quality coal has high reserve ratio and low high-quality coal has small percentage, and the consumption of coal resources is increased along with the enlargement of the modern industrial scale; industrial kilns are used in industrial fields where coal resources are consumed greatly, and reasonable development and utilization of low-quality coal are not available.

Therefore, the prior art lacks necessary technical measures for how to effectively utilize low-quality coal in an industrial furnace.

Disclosure of Invention

The invention aims to provide a preparation system of gasified gas fuel, which solves the problem that how to effectively utilize low-quality coal in an industrial furnace lacks necessary technical measures.

In order to solve the technical problems, the invention specifically provides the following technical scheme:

a system for producing a gasified gas fuel, comprising:

the industrial furnace kiln is provided with a hot air outlet, a smoke outlet and a steam outlet;

the gasification furnace is provided with a hot air inlet, a smoke inlet, a steam inlet, an oxygen inlet, a raw material inlet and an air outlet, the hot air inlet is communicated with the hot air outlet to provide hot air for the gasification furnace, the smoke inlet is communicated with the smoke outlet to provide smoke with carbon dioxide for the gasification furnace, the steam inlet is communicated with the steam outlet to provide steam for the gasification furnace, and the raw material inlet is used for feeding low-quality coal powder and combustible powder;

the oxygen supply system is connected with the oxygen inlet and is used for supplying oxygen to the gasification furnace;

the hot air, the flue gas, the steam, the oxygen, the low-quality coal powder and the combustible powder are mixed and reacted in the gasification furnace to generate gasified coal gas fuel, and the gas outlet is used for outputting the gasified coal gas fuel.

In a preferred embodiment of the present invention, the gas outlet is connected to a fuel inlet of the industrial furnace, and the gasified gas fuel is directly used for combustion in the industrial furnace.

As a preferred scheme of the invention, the gasification furnace comprises a furnace body, the furnace body is connected with an air inlet flue, and a multi-channel burner nozzle is communicated and arranged on the furnace body;

the raw material inlet comprises a coal powder inlet and a combustible material inlet;

the flue gas inlet is an inlet of the air inlet flue, and the hot air inlet, the steam inlet, the oxygen inlet and the pulverized coal inlet are inlets of any one channel of any one multi-channel burner;

the combustible inlet is the inlet of any one channel of any one multi-channel burner or an auxiliary material inlet arranged on the side wall of the furnace body, and the auxiliary material inlet is arranged opposite to the air inlet pipeline;

the gasification furnace also comprises an air inlet pipeline arranged on the side wall of the furnace body, one end of the air inlet pipeline is communicated with the furnace body, and the other end of the air inlet pipeline is communicated with the air inlet flue;

the gas inlet pipeline and the central axis of the furnace body are eccentrically arranged.

In a preferred embodiment of the present invention, the outlet of each multi-channel burner is located in the air inlet duct, the direction of the outlet is inclined toward the center of the furnace body, the multi-channel burner is arranged offset from the axis of the air inlet duct, and the outlet directions converge into one point or one plane, so that the multi-channel burner forms a hedging plane after being jetted and generates a cyclone.

As a preferred scheme of the invention, the outer contour of the air inlet pipeline is in a horn shape, the air inlet pipeline is provided with a narrow opening end and a wide opening end, the wide opening end is arranged close to the furnace body, and the narrow opening end is arranged close to the air inlet flue.

As a preferable scheme of the present invention, a thickening layer is provided around the inner circumferential wall of the air inlet pipe, the thickening layer presents a wave crest shape with two low ends and a raised middle part, and the thickening layer divides the inner pipe of the air inlet pipe into a gourd shape with two wide ends and a narrow middle part.

In a preferred embodiment of the present invention, a steam generating assembly is fixedly installed on a side wall of the furnace body for absorbing heat dissipated by the furnace body and generating steam.

A preparation method of a preparation system of gasified gas fuel comprises the following steps:

step 100, preparing low-quality coal materials and combustible materials into powder to obtain low-quality coal powder and combustible material powder;

step 200, introducing hot air, steam and flue gas generated by an industrial furnace from the side wall of the top end of a gasification furnace, introducing low-quality coal powder and combustible powder into the gasification furnace, and conveying oxygen to the gasification furnace through an oxygen supply system;

step 300, arranging the low-quality coal dust, the hot air, the steam, the flue gas and the oxygen to be mixed together after entering the gasification furnace, and completing multiphase mixing reaction, so that volatile matters and part of fixed carbon in the coal dust are reacted with O2 to be converted into CO₂And CO, steam and C into H₂Forming a combustion zone with CO, i.e. in the feed portion of the gasifier;

step 400, excessive CO is generated along with the sinking of high-temperature mixed gas in the combustion area of the gasification furnace₂And further reacting with the fixed carbon in the residual coal powder to reduce the fixed carbon into CO so as to form gasified coal gas which can be used as fuel, namely forming a reduction zone at the middle position and the discharge end of the gasification furnace.

As a preferred scheme of the invention, the method also comprises a gasification gas recycling method step 500, wherein a gas outlet of a gasification furnace is arranged to be connected with a fuel inlet of an industrial furnace, and the gasification gas is directly introduced into the industrial furnace to be used as fuel;

wherein, the gas outlet includes main coal gas export and vice coal gas export.

In a preferred embodiment of the present invention, a water jacket is provided on the side wall of the reduction zone for cooling the furnace body.

Compared with the prior art, the invention has the following beneficial effects:

the invention converts low-quality coal into gasified coal gas by fully utilizing products (smoke, steam and hot air) of the industrial furnace as a carbon dioxide source, a heat energy source, a moisture source and an air source of the reaction in the gasification furnace, and recycles the gasified coal gas as a fuel source of the industrial furnace, thereby realizing the optimized use of the low-quality coal.

The invention utilizes more carbon dioxide generated by the industrial furnace to convert the low-quality coal powder in the furnace body into carbon monoxide, reduces the accumulation of solid carbon in the low-quality coal powder, not only reduces solid impurities in a final product (gasified coal gas), but also prevents the accumulation of solid matters in the furnace body of the gasification furnace and reduces the risk of explosion caused by the blockage of a sundry material outlet pipeline of the furnace body.

The invention can also introduce carbon monoxide generated by the conversion of low-quality coal powder into the industrial furnace to be used as fuel, effectively neutralize oxynitride in the industrial furnace and effectively reduce the emission of harmful gas.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below. It should be apparent that the drawings in the following description are merely exemplary, and that other embodiments can be derived from the drawings provided by those of ordinary skill in the art without inventive effort.

FIG. 1 is a schematic diagram illustrating an overall structure of a system for producing a gasified gas fuel according to an embodiment of the present disclosure;

fig. 2 is a schematic view showing an overall structure of a gasification furnace of a system for producing a gasified gas fuel according to still another embodiment of the present disclosure;

FIG. 3 is a schematic side view in the direction A of FIG. 2;

FIG. 4 is a schematic cross-sectional view taken at angle B-B of FIG. 2;

fig. 5 is a schematic view of an overall structure of a gasification furnace of a system for producing a gasified gas fuel according to another embodiment of the present disclosure.

The reference numerals in the drawings denote the following, respectively:

1-industrial furnace kiln; 2-gasifying a furnace; 3-an oxygen supply system; 4-a multi-channel burner; 5-a steam generating assembly; 6-water jacket;

110-flue gas outlet; 120-hot air outlet; 130-a steam outlet; 210A-a flue gas inlet; 210B-an intake flue; 220-hot air inlet; 230-a steam inlet; 240-oxygen inlet; 250-raw material inlet; 260-air outlet; 261-main gas outlet; 262-auxiliary gas outlet; 270-furnace body; 280-an air inlet duct; 281-thickening layer; 290-adjuvant inlet.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Example 1:

as shown in fig. 1, the present invention provides a system for preparing gasified coal gas fuel, mainly aiming at the high-quality utilization of low-quality coal powder, and specifically comprises: an industrial furnace 1 having a hot air outlet 120, a flue gas outlet 110 and a steam outlet 130; the gasification furnace 2 is provided with a hot air inlet 220, a flue gas inlet 210A, a steam inlet 230, an oxygen inlet 240, a raw material inlet 250 and an air outlet 260; the hot air inlet 220 is communicated with the hot air outlet 120 to provide hot air for the gasifier 2, the flue gas inlet 210A is communicated with the flue gas outlet 110 to provide flue gas with carbon dioxide for the gasifier 2, the steam inlet 230 is communicated with the steam outlet 130 to provide steam for the gasifier 2, and the raw material inlet 250 is used for feeding low-quality coal powder and combustible powder; and an oxygen supply system 3 connected to the oxygen inlet 240, wherein the oxygen supply system 3 is used for supplying oxygen to the gasification furnace 2.

Wherein, the hot air, the flue gas, the steam, the oxygen, the low-quality coal powder and the combustible powder are mixed and reacted in the gasification furnace 2 to generate the gasified coal gas fuel, and the gas outlet 260 is used for outputting the gasified coal gas fuel.

In the specific working process, hot air, flue gas (containing a large amount of carbon dioxide) and steam provided by the industrial furnace 1 enter the gasification furnace 2, and oxygen, low-quality coal powder and combustible particles are also included in the hot air, the flue gas and the steam; the low-quality coal powder and combustible particles are catalyzed at high temperature by hot air and oxygen in the gasification furnace 2, steam passes through the scorching coal powder to react to generate carbon monoxide and hydrogen, and meanwhile, the flue gas contains excessive carbon dioxide and can generate carbon monoxide with the coal powder which does not react in time, so that the gasified coal fuel (carbon monoxide and hydrogen) required by combustion is prepared.

It is required to be particularly noted that carbon dioxide is excessively input, and in practice, the flue gas in the industrial furnace kiln has high carbon dioxide content and large input amount of the flue gas, so that the requirement of the excessive carbon dioxide can be basically and fully met. Because the excessive carbon dioxide can be subjected to reduction reaction with the coal dust to the maximum extent to generate carbon monoxide, the accumulation of solid coal dust is reduced. And carbon dioxide can not be combusted and can be recycled.

In this embodiment, the gas outlet 260 of the gasification furnace 2 may be connected to the fuel inlet of the industrial furnace 1, and the gasified gas fuel is directly used for combustion in the industrial furnace 1 by adding a gas transportation pressurization device, so as to form a circulation system for preparing the gasified fuel from low-quality coal powder by using various products of the industrial furnace and recycling the gasified fuel to the industrial furnace 1.

Further, the gas outlet 260 is arranged below the furnace body 270 and comprises a main gas outlet 261 and an auxiliary gas outlet 262, and the pipe diameter of the main gas outlet 261 is larger than that of the auxiliary gas outlet 262.

In this embodiment, the gasified coal fuel is introduced into the industrial furnace 1 in stages, and the main gasified coal fuel is used for combustion, and in addition, a part of carbon monoxide and hydrogen gas is subjected to a reduction reaction with the nitrogen oxide in the industrial furnace 1 to generate nitrogen gas without pollution.

As a specific embodiment of the present specification, the gasification furnace 2 includes a furnace body 270, the furnace body 270 is connected to the air inlet flue 210B, and the furnace body 270 is provided with a multi-channel burner;

the raw material inlet 250 comprises a pulverized coal inlet and a combustible inlet;

the flue gas inlet 210A is an inlet of an air inlet flue 210B, and the hot air inlet 220, the steam inlet 230, the oxygen inlet 240 and the coal powder inlet are inlets of any one channel of any one multi-channel burner respectively;

the multi-channel burner 4 has a plurality of relatively independent input channels so that various raw materials required for the reaction can be supplied through at least one multi-channel burner 4.

Example 2:

as shown in fig. 2 to 4, as another specific example of the present specification, the gasification furnace 2 includes a furnace body 270, the furnace body 270 is connected to the air inlet flue 210B, and the furnace body 270 is provided with a multi-channel burner;

the raw material inlet 250 comprises a pulverized coal inlet and a combustible inlet;

the flue gas inlet 210A is an inlet of an air inlet flue 210B, and the hot air inlet 220, the steam inlet 230, the oxygen inlet 240 and the coal powder inlet are inlets of any one channel of any one multi-channel burner respectively;

the multi-channel burner 4 has a plurality of relatively independent input channels, so that various raw materials required for the reaction can be delivered through at least one multi-channel burner 4;

the combustible inlet is an inlet of any one channel of any multi-channel burner, or an auxiliary material inlet 290 arranged on the side wall of the furnace body 270, and the auxiliary material inlet 290 is arranged opposite to the air inlet pipeline 280.

Through setting up multichannel burner tip 4, can be in the same place most delivery port is integrated, reduce the required time of multiple material mixture to increase the speed of multiple material reaction.

Further, the gasification furnace 2 further comprises an air inlet pipeline 280 arranged on the side wall of the furnace body 270, one end of the air inlet pipeline 280 is communicated with the furnace body 270, and the other end of the air inlet pipeline 280 is communicated with the air inlet flue 210B;

wherein the gas inlet pipe 280 is eccentrically disposed with respect to the central axis of the furnace body 270.

The gas inlet pipe 280 is used as a main area for low-quality coal powder gasification, and carbon monoxide and hydrogen which are generated in large quantity, flue gas (large quantity of carbon dioxide) and coal powder which does not participate in reaction are mixed and continuously enter the furnace body 270; the central axes of the gas inlet pipe 280 and the furnace body 270 are eccentrically arranged, and after the pulverized coal, the gasified coal and the flue gas enter the inner cavity of the furnace body 270, the pulverized coal, the gasified coal and the flue gas do not directly flow to the central part of the furnace body 270 but generate cyclone, so that the low-quality pulverized coal and the flue gas are fully dispersed and mixed in the furnace body 270, the efficiency of reduction reaction is improved, and more pulverized coal is converted into carbon monoxide.

The outlet of each multi-channel burner is eccentrically arranged in the air inlet pipe 280 and faces the center direction of the furnace body 270, so that the multi-channel burners 4 form a facing surface after being sprayed and generate a cyclone.

Because the flame of the multi-channel burner 4 generates extremely high temperature, the inner wall of the air inlet pipeline 280 is easy to deform at high temperature, therefore, preferably three multi-channel burners 4 are arranged to form a hedging surface, the flame can be prevented from being directly sprayed to the inner wall of the air inlet pipeline 280, and the deformation of the air inlet pipeline 280 due to high temperature is avoided.

The multi-channel combustion nozzles 4 are eccentrically arranged, so that gas vortex can be generated, low-quality coal powder is facilitated, gasified coal and carbon dioxide enter the furnace body 270, the feeding efficiency is improved, and raw materials are prevented from being gathered in the gas inlet pipeline 280.

The air inlet duct 280 has a trumpet-shaped outer contour shape and is configured with a narrow end and a wide end, the wide end of the air inlet duct 280 is communicated with the furnace body 270, and the narrow end of the air inlet duct 280 is communicated with the air inlet flue 210B. The flared gas inlet pipe 280 is favorable for conveying materials to the interior of the furnace body 270 without obvious backflow phenomenon.

The thickening layer 281 is arranged around the inner peripheral wall of the air inlet pipe 280, and the thickening layer 281 can protect the inner wall of the air inlet pipe 280 and prevent high-temperature flame from deforming the air inlet pipe 280 at high temperature.

Further, a steam generating assembly 5 is fixedly installed on the side wall of the furnace body 270, and is used for absorbing heat dissipated by the furnace body 270 and generating steam.

The inner wall of the furnace body 270 is provided with a water jacket 6 which can reduce the temperature of the coal powder to below the ash melting point, so that the coal powder reacts with carbon dioxide instead of being changed into coal ash to enter the industrial furnace.

Example 3:

as shown in fig. 5, as another specific example of this specification, the gasification furnace 2 includes a furnace body 270, the furnace body 270 is connected to the air inlet flue 210B, and the furnace body 270 is communicated with a multi-channel burner;

the raw material inlet 250 comprises a pulverized coal inlet and a combustible inlet;

the flue gas inlet 210A is an inlet of an air inlet flue 210B, and the hot air inlet 220, the steam inlet 230, the oxygen inlet 240 and the coal powder inlet are inlets of any one channel of any one multi-channel burner respectively;

the multi-channel burner 4 has a plurality of relatively independent input channels, so that various raw materials required for the reaction can be delivered through at least one multi-channel burner 4;

the combustible inlet is an inlet of any one channel of any multi-channel burner, or an auxiliary material inlet 290 arranged on the side wall of the furnace body 270, and the auxiliary material inlet 290 is arranged opposite to the air inlet pipeline 280.

Through setting up multichannel burner tip 4, can be in the same place most delivery port is integrated, reduce the required time of multiple material mixture to increase the speed of multiple material reaction.

The gasification furnace 2 further comprises an air inlet pipeline 280 arranged on the side wall of the furnace body 270, one end of the air inlet pipeline 280 is communicated with the furnace body 270, and the other end of the air inlet pipeline 280 is communicated with the air inlet flue 210B;

the multi-channel burner 4 is arranged at the upper top of the furnace body 270, one end of the output material extends to the inside of the furnace body 270, the material output from the multi-channel burner 4 is ignited at the output port, and is mixed with the material entering from the air inlet pipeline 280 for combustion to generate coal gas.

Wherein the gas inlet pipe 280 is eccentrically disposed with respect to the central axis of the furnace body 270.

The air inlet duct 280 has a trumpet-shaped outer contour shape and is configured with a narrow end and a wide end, the wide end of the air inlet duct 280 is communicated with the furnace body 270, and the narrow end of the air inlet duct 280 is communicated with the air inlet flue 210B. The flared gas inlet pipe 280 is favorable for conveying materials to the interior of the furnace body 270 without obvious backflow phenomenon.

A thickening layer 281 is arranged around the inner peripheral wall of the air inlet pipe 280 and is in a wave crest shape with two low ends and a raised middle part, and the thickening layer 281 divides the inner pipe of the air inlet pipe 280 into a gourd shape with two wide ends and a narrow middle part.

The provision of the thickening 281 divides the internal space of the air intake duct 280 into a gourd-shaped form, with several technical effects. Firstly, the high-speed airflow is blocked by the thickening layer 281 when the materials are delivered, only a single narrow channel is left, the materials can be effectively sucked into the air inlet pipeline 280 by utilizing the wind tunnel effect, and the efficiency of delivering the materials is improved; secondly, a narrow through hole is formed, so that gas convection can be effectively avoided, and the feeding efficiency can be improved; thirdly, the gas in the air inlet pipe 280 flows frequently, and the calabash-shaped space arrangement is adopted, so that the requirement of the air inlet pipe 280 on the space is met, the dispersion of the pulverized coal to the feeding direction can be effectively avoided, and the effect of blocking the backflow of the pulverized coal is achieved.

According to a plurality of specific embodiments provided by the above preparation system of gasified gas fuel, a preparation method of gasified gas fuel is provided, which comprises the following steps:

step 001: a hot air outlet, a flue gas outlet and a steam outlet of the industrial furnace are respectively communicated with a hot air inlet, a flue gas inlet and a steam inlet of the gasification furnace, the hot air inlet is communicated with the hot air outlet to provide hot air for the gasification furnace, the flue gas inlet is communicated with the flue gas outlet to provide flue gas with carbon dioxide for the gasification furnace, the steam inlet is communicated with the steam outlet to provide steam for the gasification furnace, the oxygen inlet is communicated with an oxygen supply system, an air outlet is communicated with the industrial furnace, and a raw material inlet is fed with low-quality coal powder and combustible powder;

step 002: the hot air and the oxygen catalyze the combustion of the pulverized coal, steam passes through the scorching pulverized coal to generate carbon monoxide and hydrogen, the pulverized coal and the oxygen combust to generate carbon dioxide and carbon monoxide, and the mixed carbon monoxide, carbon dioxide, hydrogen and pulverized coal are sent into the furnace body of the gasification furnace by airflow;

step 003: the carbon dioxide and the redundant coal powder react in the furnace body to generate carbon monoxide;

step 004: carbon monoxide and hydrogen are input into the industrial furnace kiln through the main gas outlet and the auxiliary gas outlet in a layered manner, the carbon monoxide and the hydrogen are mainly used for combustion, and the other part of the carbon monoxide and the hydrogen is combined with oxynitride in the industrial furnace kiln;

and 500, arranging a gas outlet of the gasification furnace to be connected with a fuel inlet of the industrial furnace, and directly introducing the gasified gas into the industrial furnace to be used as fuel.

In the above-mentioned method for producing gasified coal gas fuel, it is necessary to point out: the gas outlet comprises a main gas outlet and an auxiliary gas outlet, different flow rates are controlled by setting pipe diameters of the main gas outlet and the auxiliary gas outlet, the flow resistance is small when the pipe diameter is large, and the gas flow is correspondingly increased; the flow resistance is large when the pipe diameter is small, and the air flow is correspondingly reduced.

And a water jacket is arranged on the side wall of the reduction zone and used for cooling the furnace body.

In summary, the method fully utilizes products (flue gas, steam and hot air) of the industrial furnace as a carbon dioxide source, a heat energy source, a moisture source and an air source for reaction in the gasification furnace, converts low-quality coal into gasification coal gas, and recycles the gasification coal gas as a fuel source of the industrial furnace, thereby realizing the optimized use of the low-quality coal.

The industrial furnace is used for generating more carbon dioxide, so that the low-quality coal powder in the furnace body is converted into carbon monoxide, the accumulation of solid carbon in the low-quality coal powder is reduced, solid impurities in a final product (gasified coal gas) are reduced, the accumulation of solid matters in the furnace body of the gasification furnace is also prevented, and the risk of explosion caused by blockage of a sundry material outlet pipeline of the furnace body is reduced.

Carbon monoxide generated by the conversion of low-quality coal powder can be introduced into the industrial furnace to be used as fuel, nitrogen oxides in the industrial furnace can be effectively neutralized, and the emission of harmful gases is effectively reduced.

The above embodiments are only exemplary embodiments of the present application, and are not intended to limit the present application, and the protection scope of the present application is defined by the claims. Various modifications and equivalents may be made by those skilled in the art within the spirit and scope of the present application and such modifications and equivalents should also be considered to be within the scope of the present application.