Pulverized Coal Gasification Furnace with Multi-level Feeding of High Speed Circulating Gasification Agent and Gasification Method

Abstract

A pulverized coal gasification furnace with multi-level feeding of high speed circulating gasification agent which includes a pulverized coal gasification furnace and a gasification method. The present invention solves the existing problems in short life of burner, uneven slag deposition on the surface of the gasification device which causes burning and corrosion, and uneven temperature distribution along the height direction. The steps are: 1. setting parameters for the gasification chamber; 2. feeding pulverized coal; 3. burning pulverized coal to form molten slag; 4. gasification process of molten slag inside the gasification furnace; 5. removing slag. In the present invention, the furnace body is divided into different levels for the gasification agent, the internal temperature of the furnace along the height direction is evenly distributed, and the furnace is applicable to the coal types which has severe change in ash viscosity in response to temperature changes.

Claims

1. A pulverized coal gasification furnace with multi-level feeding of high speed circulating gasification agent which a pulverized coal burner (1), a gasification furnace body (2), a water-cool wall (4), a syngas channel (5), wherein said water-cool wall (4) is arranged on an inner wall of said gasification furnace body (2), wherein said water-cool wall (4) is formed by a plurality of vertical tubes, and a gasification chamber (3) is defined through a circulating cavity encircled by said water-cool wall (4), said pulverized coal burner (1) is positioned on a top portion of said gasification furnace body (2) and defines an axis of said pulverized coal burner (1) which is overlapped with an axis of said gasification chamber (3), wherein a slag pool (6) is arranged in a bottom portion of said gasification furnace body (2), wherein said syngas channel (5) is arranged at an outer side wall in a lower portion of said gasification furnace body (2) in a manner that said syngas channel (5) and said gasification chamber (3) is channeled through, characterized in that: said pulverized coal gasification furnace with multi-level feeding of high speed circulating gasification agent further comprises a number of gasification agent injection ports (7), a plurality of flow control valves (8), a plurality of swirl vane units (9), a pulverized coal channel (10) and a plurality of gasification agent channels (11), wherein said injection ports (7) are arranged at a side wall in an upper portion of said gasification furnace body (2), said injection ports (7) are inserted inside said gasification chamber (3) along a tangential direction of said gasification chamber (3), each said gasification agent injection port (7) comprises one said flow control valve (8), said ring-shaped gasification agent channel (11) and said ring-shaped pulverized coal channel (10) are arranged coaxially and radially extending from said inner side to said outer side of said pulverized coal burner (1), and one said swirl vane unit (9) is provided for said pulverized coal channel (10) and said gasification agent (11) near a combustion side respectively.

2. The pulverized coal gasification furnace with multi-level feeding of high speed circulating gasification agent according to claim 1, characterized in that, said number of gasification agent injection port (7) is 1, 2, 3 or 4.

3. The pulverized coal gasification furnace with multi-level feeding of high speed circulating gasification agent according to claim 1, characterized in that, said gasification agent injection ports (7) are evenly distributed and sequentially arranged from said top to said bottom along a height direction in said upper portion of said gasification furnace body (2).

4. The pulverized coal gasification furnace with multi-level feeding of high speed circulating gasification agent according to claim 3, characterized in that, a center of all said gasification agent injection ports (7) are positioned on the same vertical line perpendicular to a horizontal plane.

5. The pulverized coal gasification furnace with multi-level feeding of high speed circulating gasification agent according to claim 3, characterized in that, said gasification agent injection ports (7) are aligned in a staggered arrangement or evenly distributed along said circumferential direction of said gasification furnace body (2).

6. A method of gasification utilizing the pulverized coal gasification furnace with multi-level feeding of high speed circulating gasification agent according to claim 1, characterized in that, said method comprises the following steps of: Step 1: setting parameters for said gasification chamber 3; Setting an internal pressure of said gasification chamber to 0.1˜4 MPa, an operating temperature to 1250˜1600° C.; Step 2: feeding said pulverized coal; feeding said pulverized coal with a temperature of 25˜100° C., carried by nitrogen gas or carbon dioxide gas in a circulating airflow pattern through said pulverized coal channel (10) on said pulverized coal burner (1) to said gasification chamber (3); injecting said gasification agent, which is 10%˜40% of a total volume and has a temperature of 20˜400° C. with a circulating airflow pattern, through said gasification agent channel (11) on said pulverized coal burner (1) to said gasification chamber (3), wherein said gasification agent and said pulverized coal are mixed in said top portion of said gasification furnace and flow at the same direction downwardly in a circular pattern; Step 3: burning said pulverized coal to form molten slag; a mixture gas flow of said pulverized coal and said gasification agent contacts an entrained high temperature syngas in a center backflow region and is ignited by said high temperature syngas to form molten slag through burning in said top portion of said gasification chamber (3); Step 4: Gasification process of said molten slag inside said gasification furnace; injecting a remaining portion of gasification agent, which is 60%˜90% of the total volume and has a temperature of 20˜400° C. through said gasification agent injection ports (7) on said side wall into said gasification chamber (3) at a tangential direction and at a speed of 100˜200 m/s, wherein said gasification agent at high speed forms a very strong circular airflow after flowing into said gasification chamber (3), then under a centrifugal effect, 70%˜80% of said molten slag is forced to said inner wall to form a relatively thick slag layer, that said slag layer is a uniform slag layer, and said circular airflow is acting onto said slag layer on said inner wall of said gasification chamber continuously through which a very vigorous gasification reaction is occurred; Step 5: removing slag; a crude coal syngas produced by said gasification process flows out said gasification chamber (3) through said syngas channel (5), a liquid slag being produced flows to said slag pool (6) along said wall surface and is discharged from said gasification furnace through a slag outlet in said bottom portion.

7. The method of gasification according to claim 6 in which the strong airflow of said gasification agent is injected from said top portion and said furnace body for pulverized coal gasification process, characterized in that, in said step 4, said gasification agent is injected through said injection port (7) into said gasification chamber (3) on said side wall at a tangential direction in a multi-stage manner or at a multi-level manner along said height direction of said gasification chamber (3).

8.-10. (canceled)

11. The pulverized coal gasification furnace with multi-level feeding of high speed circulating gasification agent according to claim 2, characterized in that, said gasification agent injection ports (7) are evenly distributed and sequentially arranged from said top to said bottom along a height direction in said upper portion of said gasification furnace body (2).

12. The pulverized coal gasification furnace with multi-level feeding of high speed circulating gasification agent according to claim 11, characterized in that, a center of all said gasification agent injection ports (7) are positioned on the same vertical line perpendicular to a horizontal plane.

13. The pulverized coal gasification furnace with multi-level feeding of high speed circulating gasification agent according to claim 11, characterized in that, said gasification agent injection ports (7) are aligned in a staggered arrangement or evenly distributed along said circumferential direction of said gasification furnace body (2).

14. A method of gasification utilizing the pulverized coal gasification furnace with multi-level feeding of high speed circulating gasification agent according to claim 2, characterized in that, said method comprises the following steps of: Step 1: setting parameters for said gasification chamber 3; Setting an internal pressure of said gasification chamber to 0.1˜4 MPa, an operating temperature to 1250˜1600° C.; Step 2: feeding said pulverized coal; feeding said pulverized coal with a temperature of 25˜100° C., carried by nitrogen gas or carbon dioxide gas in a circulating airflow pattern through said pulverized coal channel (10) on said pulverized coal burner (1) to said gasification chamber (3); injecting said gasification agent, which is 10%˜40% of a total volume and has a temperature of 20˜400° C. with a circulating airflow pattern, through said gasification agent channel (11) on said pulverized coal burner (1) to said gasification chamber (3), wherein said gasification agent and said pulverized coal are mixed in said top portion of said gasification furnace and flow at the same direction downwardly in a circular pattern; Step 3: burning said pulverized coal to form molten slag; a mixture gas flow of said pulverized coal and said gasification agent contacts an entrained high temperature syngas in a center backflow region and is ignited by said high temperature syngas to form molten slag through burning in said top portion of said gasification chamber (3); Step 4: Gasification process of said molten slag inside said gasification furnace; injecting a remaining portion of gasification agent, which is 60%˜90% of the total volume and has a temperature of 20˜400° C. through said gasification agent injection ports (7) on said side wall into said gasification chamber (3) at a tangential direction and at a speed of 100˜200 m/s, wherein said gasification agent at high speed forms a very strong circular airflow after flowing into said gasification chamber (3), then under a centrifugal effect, 70%˜80% of said molten slag is forced to said inner wall to form a relatively thick slag layer, that said slag layer is a uniform slag layer, and said circular airflow is acting onto said slag layer on said inner wall of said gasification chamber continuously through which a very vigorous gasification reaction is occurred; Step 5: removing slag; a crude coal syngas produced by said gasification process flows out said gasification chamber (3) through said syngas channel (5), a liquid slag being produced flows to said slag pool (6) along said wall surface and is discharged from said gasification furnace through a slag outlet in said bottom portion.

15. The method of gasification according to claim 14 in which the strong airflow of said gasification agent is injected from said top portion and said furnace body for pulverized coal gasification process, characterized in that, in said step 4, said gasification agent is injected through said injection port (7) into said gasification chamber (3) on said side wall at a tangential direction in a multi-stage manner or at a multi-level manner along said height direction of said gasification chamber (3).

16. A method of gasification utilizing the pulverized coal gasification furnace with multi-level feeding of high speed circulating gasification agent according to claim 3, characterized in that, said method comprises the following steps of: Step 1: setting parameters for said gasification chamber 3; Setting an internal pressure of said gasification chamber to 0.1˜4 MPa, an operating temperature to 1250˜1600° C.; Step 2: feeding said pulverized coal; feeding said pulverized coal with a temperature of 25˜100° C., carried by nitrogen gas or carbon dioxide gas in a circulating airflow pattern through said pulverized coal channel (10) on said pulverized coal burner (1) to said gasification chamber (3); injecting said gasification agent, which is 10%˜40% of a total volume and has a temperature of 20˜400° C. with a circulating airflow pattern, through said gasification agent channel (11) on said pulverized coal burner (1) to said gasification chamber (3), wherein said gasification agent and said pulverized coal are mixed in said top portion of said gasification furnace and flow at the same direction downwardly in a circular pattern; Step 3: burning said pulverized coal to form molten slag; a mixture gas flow of said pulverized coal and said gasification agent contacts an entrained high temperature syngas in a center backflow region and is ignited by said high temperature syngas to form molten slag through burning in said top portion of said gasification chamber (3); Step 4: Gasification process of said molten slag inside said gasification furnace; injecting a remaining portion of gasification agent, which is 60%˜90% of the total volume and has a temperature of 20˜400° C. through said gasification agent injection ports (7) on said side wall into said gasification chamber (3) at a tangential direction and at a speed of 100˜200 m/s, wherein said gasification agent at high speed forms a very strong circular airflow after flowing into said gasification chamber (3), then under a centrifugal effect, 70%˜80% of said molten slag is forced to said inner wall to form a relatively thick slag layer, that said slag layer is a uniform slag layer, and said circular airflow is acting onto said slag layer on said inner wall of said gasification chamber continuously through which a very vigorous gasification reaction is occurred; Step 5: removing slag; a crude coal syngas produced by said gasification process flows out said gasification chamber (3) through said syngas channel (5), a liquid slag being produced flows to said slag pool (6) along said wall surface and is discharged from said gasification furnace through a slag outlet in said bottom portion.

17. The method of gasification according to claim 16 in which the strong airflow of said gasification agent is injected from said top portion and said furnace body for pulverized coal gasification process, characterized in that, in said step 4, said gasification agent is injected through said injection port (7) into said gasification chamber (3) on said side wall at a tangential direction in a multi-stage manner or at a multi-level manner along said height direction of said gasification chamber (3).

18. A method of gasification utilizing the pulverized coal gasification furnace with multi-level feeding of high speed circulating gasification agent according to claim 4, characterized in that, said method comprises the following steps of: Step 1: setting parameters for said gasification chamber 3; Setting an internal pressure of said gasification chamber to 0.1˜4 MPa, an operating temperature to 1250˜1600° C.; Step 2: feeding said pulverized coal; feeding said pulverized coal with a temperature of 25˜100° C., carried by nitrogen gas or carbon dioxide gas in a circulating airflow pattern through said pulverized coal channel (10) on said pulverized coal burner (1) to said gasification chamber (3); injecting said gasification agent, which is 10%˜40% of a total volume and has a temperature of 20˜400° C. with a circulating airflow pattern, through said gasification agent channel (11) on said pulverized coal burner (1) to said gasification chamber (3), wherein said gasification agent and said pulverized coal are mixed in said top portion of said gasification furnace and flow at the same direction downwardly in a circular pattern; Step 3: burning said pulverized coal to form molten slag; a mixture gas flow of said pulverized coal and said gasification agent contacts an entrained high temperature syngas in a center backflow region and is ignited by said high temperature syngas to form molten slag through burning in said top portion of said gasification chamber (3); Step 4: Gasification process of said molten slag inside said gasification furnace; injecting a remaining portion of gasification agent, which is 60%˜90% of the total volume and has a temperature of 20˜400° C. through said gasification agent injection ports (7) on said side wall into said gasification chamber (3) at a tangential direction and at a speed of 100˜200 m/s, wherein said gasification agent at high speed forms a very strong circular airflow after flowing into said gasification chamber (3), then under a centrifugal effect, 70%˜80% of said molten slag is forced to said inner wall to form a relatively thick slag layer, that said slag layer is a uniform slag layer, and said circular airflow is acting onto said slag layer on said inner wall of said gasification chamber continuously through which a very vigorous gasification reaction is occurred; Step 5: removing slag; a crude coal syngas produced by said gasification process flows out said gasification chamber (3) through said syngas channel (5), a liquid slag being produced flows to said slag pool (6) along said wall surface and is discharged from said gasification furnace through a slag outlet in said bottom portion.

19. A method of gasification utilizing the pulverized coal gasification furnace with multi-level feeding of high speed circulating gasification agent according to claim 5, characterized in that, said method comprises the following steps of: Step 1: setting parameters for said gasification chamber 3; Setting an internal pressure of said gasification chamber to 0.1˜4 MPa, an operating temperature to 1250˜1600° C.; Step 2: feeding said pulverized coal; feeding said pulverized coal with a temperature of 25˜100° C., carried by nitrogen gas or carbon dioxide gas in a circulating airflow pattern through said pulverized coal channel (10) on said pulverized coal burner (1) to said gasification chamber (3); injecting said gasification agent, which is 10%˜40% of a total volume and has a temperature of 20˜400° C. with a circulating airflow pattern, through said gasification agent channel (11) on said pulverized coal burner (1) to said gasification chamber (3), wherein said gasification agent and said pulverized coal are mixed in said top portion of said gasification furnace and flow at the same direction downwardly in a circular pattern; Step 3: burning said pulverized coal to form molten slag; a mixture gas flow of said pulverized coal and said gasification agent contacts an entrained high temperature syngas in a center backflow region and is ignited by said high temperature syngas to form molten slag through burning in said top portion of said gasification chamber (3); Step 4: Gasification process of said molten slag inside said gasification furnace; injecting a remaining portion of gasification agent, which is 60%˜90% of the total volume and has a temperature of 20˜400° C. through said gasification agent injection ports (7) on said side wall into said gasification chamber (3) at a tangential direction and at a speed of 100˜200 m/s, wherein said gasification agent at high speed forms a very strong circular airflow after flowing into said gasification chamber (3), then under a centrifugal effect, 70%˜80% of said molten slag is forced to said inner wall to form a relatively thick slag layer, that said slag layer is a uniform slag layer, and said circular airflow is acting onto said slag layer on said inner wall of said gasification chamber continuously through which a very vigorous gasification reaction is occurred; Step 5: removing slag; a crude coal syngas produced by said gasification process flows out said gasification chamber (3) through said syngas channel (5), a liquid slag being produced flows to said slag pool (6) along said wall surface and is discharged from said gasification furnace through a slag outlet in said bottom portion.

20. The method of gasification according to claim 19 in which the strong airflow of said gasification agent is injected from said top portion and said furnace body for pulverized coal gasification process, characterized in that, in said step 4, said gasification agent is injected through said injection port (7) into said gasification chamber (3) on said side wall at a tangential direction in a multi-stage manner or at a multi-level manner along said height direction of said gasification chamber (3).

21. A method of gasification utilizing the pulverized coal gasification furnace with multi-level feeding of high speed circulating gasification agent according to claim 11, characterized in that, said method comprises the following steps of: Step 1: setting parameters for said gasification chamber 3; Setting an internal pressure of said gasification chamber to 0.1˜4 MPa, an operating temperature to 1250˜1600° C.; Step 2: feeding said pulverized coal; feeding said pulverized coal with a temperature of 25˜100° C., carried by nitrogen gas or carbon dioxide gas in a circulating airflow pattern through said pulverized coal channel (10) on said pulverized coal burner (1) to said gasification chamber (3); injecting said gasification agent, which is 10%-˜40% of a total volume and has a temperature of 20˜400° C. with a circulating airflow pattern, through said gasification agent channel (11) on said pulverized coal burner (1) to said gasification chamber (3), wherein said gasification agent and said pulverized coal are mixed in said top portion of said gasification furnace and flow at the same direction downwardly in a circular pattern; Step 3: burning said pulverized coal to form molten slag; a mixture gas flow of said pulverized coal and said gasification agent contacts an entrained high temperature syngas in a center backflow region and is ignited by said high temperature syngas to form molten slag through burning in said top portion of said gasification chamber (3); Step 4: Gasification process of said molten slag inside said gasification furnace; injecting a remaining portion of gasification agent, which is 60%˜90% of the total volume and has a temperature of 20˜400° C. through said gasification agent injection ports (7) on said side wall into said gasification chamber (3) at a tangential direction and at a speed of 100˜200 m/s, wherein said gasification agent at high speed forms a very strong circular airflow after flowing into said gasification chamber (3), then under a centrifugal effect, 70%˜80% of said molten slag is forced to said inner wall to form a relatively thick slag layer, that said slag layer is a uniform slag layer, and said circular airflow is acting onto said slag layer on said inner wall of said gasification chamber continuously through which a very vigorous gasification reaction is occurred; Step 5: removing slag; a crude coal syngas produced by said gasification process flows out said gasification chamber (3) through said syngas channel (5), a liquid slag being produced flows to said slag pool (6) along said wall surface and is discharged from said gasification furnace through a slag outlet in said bottom portion.

22. A method of gasification utilizing the pulverized coal gasification furnace with multi-level feeding of high speed circulating gasification agent according to claim 12, characterized in that, said method comprises the following steps of: Step 1: setting parameters for said gasification chamber 3; Setting an internal pressure of said gasification chamber to 0.1˜4 MPa, an operating temperature to 1250˜1600° C.; Step 2: feeding said pulverized coal; feeding said pulverized coal with a temperature of 25˜100° C., carried by nitrogen gas or carbon dioxide gas in a circulating airflow pattern through said pulverized coal channel (10) on said pulverized coal burner (1) to said gasification chamber (3); injecting said gasification agent, which is 10%˜40% of a total volume and has a temperature of 20˜400° C. with a circulating airflow pattern, through said gasification agent channel (11) on said pulverized coal burner (1) to said gasification chamber (3), wherein said gasification agent and said pulverized coal are mixed in said top portion of said gasification furnace and flow at the same direction downwardly in a circular pattern; Step 3: burning said pulverized coal to form molten slag; a mixture gas flow of said pulverized coal and said gasification agent contacts an entrained high temperature syngas in a center backflow region and is ignited by said high temperature syngas to form molten slag through burning in said top portion of said gasification chamber (3); Step 4: Gasification process of said molten slag inside said gasification furnace; injecting a remaining portion of gasification agent, which is 60% ˜90% of the total volume and has a temperature of 20˜400° C. through said gasification agent injection ports (7) on said side wall into said gasification chamber (3) at a tangential direction and at a speed of 100˜200 m/s, wherein said gasification agent at high speed forms a very strong circular airflow after flowing into said gasification chamber (3), then under a centrifugal effect, 70%˜80% of said molten slag is forced to said inner wall to form a relatively thick slag layer, that said slag layer is a uniform slag layer, and said circular airflow is acting onto said slag layer on said inner wall of said gasification chamber continuously through which a very vigorous gasification reaction is occurred; Step 5: removing slag; a crude coal syngas produced by said gasification process flows out said gasification chamber (3) through said syngas channel (5), a liquid slag being produced flows to said slag pool (6) along said wall surface and is discharged from said gasification furnace through a slag outlet in said bottom portion.

23. A method of gasification utilizing the pulverized coal gasification furnace with multi-level feeding of high speed circulating gasification agent according to claim 13, characterized in that, said method comprises the following steps of: Step 1: setting parameters for said gasification chamber 3; Setting an internal pressure of said gasification chamber to 0.1˜4 MPa, an operating temperature to 1250˜1600° C.; Step 2: feeding said pulverized coal; feeding said pulverized coal with a temperature of 25˜100° C., carried by nitrogen gas or carbon dioxide gas in a circulating airflow pattern through said pulverized coal channel (10) on said pulverized coal burner (1) to said gasification chamber (3); injecting said gasification agent, which is 10%˜40% of a total volume and has a temperature of 20˜400° C. with a circulating airflow pattern, through said gasification agent channel (11) on said pulverized coal burner (1) to said gasification chamber (3), wherein said gasification agent and said pulverized coal are mixed in said top portion of said gasification furnace and flow at the same direction downwardly in a circular pattern; Step 3: burning said pulverized coal to form molten slag; a mixture gas flow of said pulverized coal and said gasification agent contacts an entrained high temperature syngas in a center backflow region and is ignited by said high temperature syngas to form molten slag through burning in said top portion of said gasification chamber (3); Step 4: Gasification process of said molten slag inside said gasification furnace; injecting a remaining portion of gasification agent, which is 60%˜90% of the total volume and has a temperature of 20˜400° C. through said gasification agent injection ports (7) on said side wall into said gasification chamber (3) at a tangential direction and at a speed of 100˜200 m/s, wherein said gasification agent at high speed forms a very strong circular airflow after flowing into said gasification chamber (3), then under a centrifugal effect, 70%˜80% of said molten slag is forced to said inner wall to form a relatively thick slag layer, that said slag layer is a uniform slag layer, and said circular airflow is acting onto said slag layer on said inner wall of said gasification chamber continuously through which a very vigorous gasification reaction is occurred; Step 5: removing slag; a crude coal syngas produced by said gasification process flows out said gasification chamber (3) through said syngas channel (5), a liquid slag being produced flows to said slag pool (6) along said wall surface and is discharged from said gasification furnace through a slag outlet in said bottom portion.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0037] FIG. 1 is an illustration of the overall structure of the gasification furnace with one gasification agent injection port according to the preferred embodiment of the present invention. (the curve lines with arrows refer to the airflow trajectory inside the gasification chamber 3, the numerical reference 12 refers to the flow of pulverized coal, the numerical reference 13 refers to the flow of gasification agent, the numerical reference 14 refers to circulating airflow near the wall in the top portion of the furnace, the numerical reference 15 refers to slag layer, the numerical reference 16 refers to backflow syngas, the numerical reference 17 refers to the boundary of the center backflow region, the numerical reference 19 refers to slag outlet, the numerical reference 20 refers to the injected pulverized coal and nitrogen or pulverized coal and carbon dioxide, the numerical reference 21 refers to the injected gasification agent); FIG. 2 is an A-A sectional view of FIG. 1; FIG. 3 is an illustration of the overall structure of the gasification furnace when the number of gasification agent injection port is 3 and the center of all the injection ports are aligned on the same vertical line perpendicular to the horizontal plane according to the preferred embodiment of the present invention; FIG. 4 is an A-A sectional view of FIG. 3; FIG. 5 is an illustration of the overall structure of the gasification furnace when the number of gasification agent injection port is 2 and the center of all the injection ports are aligned on the same vertical line perpendicular to the horizontal plane according to the preferred embodiment of the present invention; FIG. 6 is an A-A sectional view of FIG. 5; FIG. 7 is an illustration of the overall structure of the gasification furnace when the number of gasification agent injection port is 4 and the center of all the injection ports are aligned on the same vertical line perpendicular to the horizontal plane according to the preferred embodiment of the present invention; FIG. 8 is an A-A sectional view of FIG. 7; FIG. 9 is an illustration of the overall structure of the gasification furnace when the number of gasification agent injection port is 3 according to the preferred embodiment of the present invention; FIG. 10 is an A-A sectional view of FIG. 9 when the gasification agent injection ports are aligned in a staggered pattern; FIG. 11 is an A-A sectional view of FIG. 9 when the gasification agent injection ports are aligned uniformly; FIG. 12 is an illustration of the overall structure of the gasification furnace when the number of gasification agent injection port is 2 according to the preferred embodiment of the present invention; FIG. 13 is an A-A sectional view of FIG. 12 when the gasification agent injection ports are aligned in a staggered pattern; FIG. 14 is an A-A sectional view of FIG. 12 when the gasification agent injection ports are aligned uniformly; FIG. 15 is an illustration of the overall structure of the gasification furnace when the number of gasification agent injection port is 4 according to the preferred embodiment of the present invention; FIG. 16 is an A-A sectional view of FIG. 15 when the gasification agent injection ports are aligned in a staggered pattern; FIG. 17 is an A-A sectional view of FIG. 15 when the gasification agent injection ports are aligned uniformly; FIG. 18 illustrates the airflow trajectory of an existing furnace (the numerical reference 18 refers to gasification and pulverized coal, the numerical reference 18 refers to slag film).

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT

[0038] Embodiment 1: This embodiment is further described in connection with FIG. 1 to FIG. 17 as follows. According to this embodiment, the furnace comprises a pulverized coal burner 1, a gasification furnace body 2, a water-cool wall 4, a syngas channel 5, the water-cool wall 4 is arranged on an inner wall of the gasification furnace body 2, the water-cool wall 4 is formed by a plurality of vertical tubes, a circular cavity, namely the gasification chamber 3, is encircled by the water-cool wall 4, the pulverized coal burner 1 is positioned on a top portion of the gasification furnace body 2 and the axis of the pulverized coal burner 1 is overlapped with the axis of the gasification chamber 3 such that a flow of the pulverized coal is evenly distributed in all direction inside the furnace; a slag pool 6 is arranged in a bottom portion of the gasification furnace body 2, the syngas channel 5 is arranged at an outer side wall in a lower portion of the gasification furnace body 2 in a manner that the syngas channel 5 and the gasification chamber 3 is channeled through, the pulverized coal gasification furnace with multi-level feeding of high speed circulating gasification agent further comprises a gasification agent injection port 7, a flow control valve 8, a swirl vane unit 9, a pulverized coal channel 10 and a gasification agent channel 11, the injection port 7 is arranged at a side wall in an upper portion of the gasification furnace body 2, the injection port 7 is inserted inside the gasification chamber 3 along a tangential direction of the gasification chamber 3 such that a very strong field of circular gas flow inside the gasification furnace is facilitated; each gasification agent injection port 7 comprises a flow control valve 8, the ring-shaped gasification agent channel 11 and the ring-shaped pulverized coal channel 10 are coaxially and radially extended from the inner side to the outer side of the pulverized coal burner 1, the pulverized coal channel 10 and the gasification agent 11 comprise a swirl vane unit 9 near the combustion side respectively.

[0039] Embodiment 2: This embodiment is described in connection with FIG. 1 to FIG. 17 as follows. According to this embodiment, the number of gasification agent injection port 7 is 1, 2, 3 or 4. Accordingly, based on the size of the gasification furnace, the adjustment of the intensity distribution for the field of circular gas flow inside the gasification furnace is facilitated. The other components and connecting relationships are the same as that of the embodiment 1.

[0040] Embodiment 3: This embodiment is described in connection with FIG. 3 to FIG. 17 as follows. According to this embodiment, the plurality of gasification agent injection ports 7 are evenly distributed and sequentially arranged from the top to the bottom along the height direction in the upper portion of the gasification furnace body 2 such that a very strong field of circular gas flow inside the gasification furnace is facilitated. The other components and connecting relationships are the same as that of the embodiment 1.

[0041] Embodiment 4: This embodiment is described in connection with FIG. 3 to FIG. 8 as follows. According to this embodiment, the center of all the gasification agent injection ports 7 are positioned on the same vertical line perpendicular to the horizontal plane. The other components and connecting relationships are the same as that of the embodiment 1.

[0042] Embodiment 5: This embodiment is described in connection with FIG. 9 to FIG. 17 as follows. According to this embodiment, the gasification agent injection ports 7 are aligned in a staggered arrangement or evenly distributed along the circumferential direction of the gasification furnace body 2. The other components and connecting relationships are the same as that of the embodiment 1.

[0043] Embodiment 6: This embodiment is described in connection with FIG. 1 to FIG. 17 as follows. According to this embodiment, the implementation method is realized by the following steps:

[0044] Step 1: setting parameters for the gasification chamber 3;

[0045] Setting the internal pressure of the gasification chamber to 0.1˜4 MPa, the operating temperature to 1250˜1600° C.;

[0046] Step 2: feeding pulverized coal;

[0047] Feeding the pulverized coal with a temperature of 25˜100° C., carried by the nitrogen gas or carbon dioxide gas in a circulating gas flow pattern, through the pulverized coal channel 10 on the pulverized coal burner 1, to the gasification chamber 3, injecting the gasification agent, which is 10%˜40% of total volume and has a temperature of 20˜400° C. with a circulating gas flow pattern, through the gasification agent channel 11 on a pulverized coal burner 1 to the gasification chamber 3. The gasification agent and the pulverized coal are mixed in the top portion of the gasification furnace and flow at the same direction downwardly in a circular pattern;

[0048] Step 3: burning pulverized coal to form molten slag;

[0049] The mixture gas flow of the pulverized coal and gasification agent contact the entrained high temperature syngas in the center backflow region and are ignited by the high temperature syngas, and form a molten slag through burning in the top portion of the gasification chamber 3;

[0050] Step 4: Gasification process of molten slag inside the gasification furnace;

[0051] The remaining gasification agent, which is 60%˜90% of total volume and has a temperature of 20˜400° C., through the gasification agent injection port 7 on the side wall, is injected into the gasification chamber 3 at a tangential direction and at a speed of 100˜200 m/s; the high speed gasification agent is flowed into the gasification chamber 3 and form a very strong circular gas flow; under the centrifugal effect, 70%-80% of the molten slag is forced to the inner wall to form a relatively thick slag layer, that the slag layer is a uniform slag layer; the circular gas flow is acting onto the slag layer on the inner wall of the gasification chamber continuously through which a very vigorous gasification reaction is occurred;

[0052] Step 5: Slag removal;

[0053] The crude coal gas produced by gasification process flows out the gasification chamber 3 through the syngas channel 5, the liquid slag produced flows to the slag pool 6 along the wall surface and is discharged from the gasification furnace through a slag outlet in the bottom portion.

[0054] Embodiment 7: This embodiment is described in connection with FIG. 1 to FIG. 17 as follows. According to this embodiment, in the step 1, the internal pressure of the gasification chamber 3 is set to 2.5 MPa, the operating temperature is set to 1500° C. The other steps are the same as the above embodiment.

[0055] Embodiment 8: This embodiment is described in connection with FIG. 1 to FIG. 17 as follows. According to this embodiment, in the step 2, the temperature of the pulverized coal is 50° C., the temperature of the gasification agent is 100° C. The other steps are the same as the above embodiment.

[0056] Embodiment 9: This embodiment is described in connection with FIG. 1 to FIG. 17 as follows. According to this embodiment, in the step 2, the temperature of the pulverized coal is 80° C., the temperature of the gasification agent is 200° C. The other steps are the same as the above embodiment.

[0057] Embodiment 10: This embodiment is described in connection with FIG. 1 to FIG. 17 as follows. According to this embodiment, in the step 4, the gasification agent is injected through the injection port 7 into the gasification chamber 3 tangentially at a multi-stage manner or at a multi-level manner along the height of the furnace. The other steps are the same as the above embodiment.

[0058] Embodiment 11: This embodiment is described in connection with FIG. 1 to FIG. 17 as follows. According to this embodiment, in the step 2, based on the total volume of gasification agent required for normal operation of the gasification furnace, 30% of the total volume is injected into the gasification chamber 3 through the gasification agent channel 11, in the step 4, the remaining 70% of the gasification agent is injected into the gasification chamber 3 tangentially at a speed of 150 m/s through the injection port 7. The other steps are the same as the above embodiment.

[0059] Embodiment 12: This embodiment is described in connection with FIG. 1 to FIG. 17 as follows. According to this embodiment, in the step 2, based on the total volume of gasification agent required for normal operation of the gasification furnace, 50% of the total volume is injected into the gasification chamber 3 through the gasification agent channel 11, in the step 4, the remaining 50% of the gasification agent is injected into the gasification chamber 3 tangentially at a speed of 160 m/s through the injection port 7. The other steps are the same as the above embodiment.

[0060] Embodiment 13: This embodiment is described in connection with FIG. 1 to FIG. 17 as follows. According to this embodiment, in the step 2, based on the total volume of gasification agent required for normal operation of the gasification furnace, 80% of the total volume is injected into the gasification chamber 3 through the gasification agent channel 11, in the step 4, the remaining 20% of the gasification agent is injected into the gasification chamber 3 tangentially at a speed of 150 m/s through the injection port 7. The other steps are the same as the above embodiment.

[0061] Embodiment 14: This embodiment is described in connection with FIG. 1 to FIG. 17 as follows. According to this embodiment, in the step 2 and the step 4, the gasification agent are both oxygen and steam, the mass ratio of steam and oxygen is 0˜0.4:1. The other steps are the same as the above embodiment.

[0062] Embodiment 15: This embodiment is described in connection with FIG. 1 to FIG. 17 as follows. According to this embodiment, in the step 2, the volume of pulverized coal is 1%˜25% of the total volume of the mixture gas of pulverized coal and nitrogen, or the volume of pulverized coal is 1%˜25% of the total volume of the mixture gas of pulverized coal and carbon dioxide, thereby the reduction in the amount of nitrogen or carbon dioxide is facilitated and the cost of gas transmission is reduced, while the content of the effective gas (carbon monoxide and hydrogen) in the synthetic gas generated by the gasification furnace is relatively high. The other steps are the same as the above embodiment.

[0063] Working principle of the present invention:

[0064] The working principle in the gasification furnace is illustrated in FIG. 1 to FIG. 17 of the drawings. The pulverized coal carried by nitrogen or carbon dioxide is fed into the pulverized coal channel 10 of the burner 1, flows through the swirl vane unit 9 and then flows in a circulating pattern into the gasification chamber 3, forms a pulverized coal flow 12 with a circular and downward flow direction in the top portion of the gasification chamber 3. About 10%˜40% of the gasification agent 21 (oxygen and steam) flows into the gasification agent channel 11 of the burner 1, through the swirl vane unit 9 to become a circulating flow into the gasification chamber 3, and generates a gasification agent flow 13 with a circular and downward flow direction in the top portion of the gasification chamber 3. The pulverized coal flow 12 and the gasification flow 13 are both flowing in the same direction and in a circulating direction, through which the two gas flow are mixed continuously. The mixture gas flow of the pulverized coal and gasification agent is then ignited after mixing with the entrained high temperature syngas in the center backflow region, then burning to form a molten slag in a top portion of the gasification chamber 3. The remaining 60%˜90% gasification agent 21 is injected tangentially at high speed into the gasification chamber 3 through the gasification agent injection port 7 and is restricted by the inner wall of the gasification chamber 3, thus forming a very strong circulating flow of gasification agent. Under the effect of this strong flow of circulating gasification agent, the pulverized coal is burnt to form a molten slag, the flow of the entrained high temperature syngas and the gasification agent are flowing in a circulating and downward direction near the inner wall of the gasification chamber; under the centrifugal effect generated by the strong circulating gas flow, about 80% of the molten slag is forced onto the wall surface to form a uniform and thick layer of molten slag. The remaining 20% of molten slag, the flow of the entrained high temperature syngas and the gasification agent are mixed to flow together in a circulating and downward direction near the inner wall surface continuously. The slag layer flows downwardly and slowly along the inner wall, while the strong circulating flow of mixture gas keeps exerting force onto the slag layer on the inner wall. Through this process, strong gasification reaction occurs continuously between the gasification agent in the mixture gas flow, the slag layer on the wall surface, and the molten slag in the mixture gas flow. After the reaction, the slag layer continues to flow downwardly to the slag pool and is discharged from the slag outlet. The downward circulating mixture gas undergoes gasification reaction continuously and is converted into high temperature syngas flow when reaching to the bottom portion of the gasification furnace. Since the mixture gas flow is circulating near the inner wall of the furnace, the pressure in the center of the gasification chamber is relatively lower, the syngas in the bottom portion of the gasification chamber is then under the entrainment effect to flow upward in the center portion of the gasification chamber to form a stable high temperature center backflow region. The high temperature syngas drawn by the high temperature center backflow region flows back to the top portion of the gasification furnace and ignites the mixture gas flow of pulverized coal and gasification agent from the burner 1, which is then circulated downwardly near the inner wall again. Finally, the syngas produced flows out through the syngas channel 5.

[0065] Application of embodiment 1:

[0066] Based on a gasification furnace with a gas production capacity of 80000 Nm.sup.3/h according to the present invention, it is estimated that no burning damage will occur for 4 years and continuous running for 4 years is ensured. Compared to other technologies, the economic loss of 160 million yuan is reduced. Through verification by numerical methods: a thickness of the slag layer on the wall of the gasification furnace is 6 mm, the slag layer is even and is relatively thicker; the retention time of the pulverized coal inside the furnace is 14 s, that the retention time is relative longer; the highest temperature in the upper portion of the furnace is 1510° C., the lowest temperature in the bottom portion is 1420° C., the temperature difference along the same horizontal level inside the furnace is less than 30° C., the temperature along the height direction and the circumferential direction of the furnace are evenly distributed; the relative speed of the pulverized coal and the gasification agent at the inlet of the gasification agent is 150 m/s, the relative speed of the pulverized coal and the gasification agent at the syngas outlet is 75 m/s, the average relative speed of the pulverized coal and gasification agent is about 115 m/s, the relative speed of the pulverized coal and the gasification agent is high, the gas dispersion to the granular surface is fast and the reaction rate is high.

[0067] A chemical plant utilizes a gasification furnace with a gas production capacity of 80000 Nm.sup.3/h according to the present technology in the art, the retention time of the pulverized coal inside the furnace is about 5 s, the relative speed of the gasification agent and the molten slag is 0.1 m/s; a thickness of the slag layer on the water-cool wall surface is relatively thinner, which is about 2 mm, and the layer thickness is uneven; the temperature in the upper portion of the furnace is 1650° C., the temperature in the bottom portion is 1300° C., the temperature difference along the height direction is relatively high; some part of the inner wall surface is exposed under high temperature gas environment, the inner wall surface is easily burnt, the average number of incidence of stop running due to inner wall surface damage is one per year and the total economic loss of a one-time stop in operation is about 40 million yuan.

[0068] Preferably, the spacing along the height direction between the gasification agent injection port at the uppermost level and the gasification agent injection port at the lowermost level is 0.5D˜0.7D, wherein D refers to the diameter of the circle encircled by the center of the tubes of the water-cool wall, which is uniformly disposed in the middle between the gasification injection port at the uppermost level and the lowermost level along the height direction.