阅读说明：本技术 一种带压富氧循环流化床气化工艺方法与系统 (Gasification process method and system for pressurized oxygen-enriched circulating fluidized bed ) 是由 孙玉娟 卞海峰 赵新 王超 李涛 于 2019-10-28 设计创作，主要内容包括：本发明公开了一种带压富氧循环流化床气化工艺方法与系统,包括原料煤煤仓、螺旋给料机、带压富氧循环流化床气化炉和出渣皮带,所述原料煤煤仓与洗煤机相互连接,所述渣锁斗与滚筒冷渣机相互连接,且滚筒冷渣机旁设置有出渣皮带,所述高温旋风分离器顶部与气化剂预热器顶部相互连接,且气化剂预热器与蒸汽过热器相互连接,所述省煤器与旋风除尘器相互连接,且旋风除尘器与高温过滤器本体相互连接,并且高温过滤器本体与增湿除尘塔相互连接。该带压富氧循环流化床气化工艺方法与系统,采用新型的结构设计,使得本工艺流程简单、易于提高气化压力、系统运行成本和投资成本低,并且除尘效率高,生产出的煤气中水蒸汽含量大。(The invention discloses a gasification process method and a gasification process system of a pressurized oxygen-enriched circulating fluidized bed, which comprise a raw material coal bunker, a screw feeder, a pressurized oxygen-enriched circulating fluidized bed gasification furnace and a slag belt, wherein the raw material coal bunker is mutually connected with a coal washer, a slag lock hopper is mutually connected with a roller slag cooler, the slag belt is arranged beside the roller slag cooler, the top of a high-temperature cyclone separator is mutually connected with the top of a gasification agent preheater, the gasification agent preheater is mutually connected with a steam superheater, the coal economizer is mutually connected with a cyclone dust collector, the cyclone dust collector is mutually connected with a high-temperature filter body, and the high-temperature filter body is mutually connected with a humidifying dust removal tower. The pressurized oxygen-enriched circulating fluidized bed gasification process method and the system adopt a novel structural design, so that the process flow is simple, the gasification pressure is easy to improve, the system operation cost and the investment cost are low, the dust removal efficiency is high, and the produced coal gas has high water vapor content.)

1. The utility model provides an oxygen boosting circulating fluidized bed gasification system is pressed in area, includes raw materials coal bunker (1), screw feeder (2), presses oxygen boosting circulating fluidized bed gasifier (3) and slagging tap belt (17), its characterized in that: the raw material coal bunker (1) is connected with a coal washer (15), the coal washer (15) is connected with a screw feeder (2), the screw feeder (2) is connected with an under-pressure oxygen-enriched circulating fluidized bed gasifier (3), a slag lock hopper (14) is installed at the bottom end of the under-pressure oxygen-enriched circulating fluidized bed gasifier (3), the top of the under-pressure oxygen-enriched circulating fluidized bed gasifier (3) is connected with the upper part of a high-temperature cyclone separator (4), a material returning device (5) is installed at the bottom end of the high-temperature cyclone separator (4), the material returning device (5) is connected with the under-pressure oxygen-enriched circulating fluidized bed gasifier (3), the slag lock hopper (14) is connected with a roller slag cooler (16), a slag discharging belt (17) is arranged beside the roller slag cooler (16), and the top of the high-temperature cyclone separator (4) is connected with the top of a gasifying agent preheater (6), and gasification agent pre-heater (6) and steam superheater (7) interconnect to exhaust-heat boiler (8) and economizer (10) interconnect are provided with steam pocket (9) between exhaust-heat boiler (8) and economizer (10) simultaneously, economizer (10) and cyclone (11) interconnect, and cyclone (11) and high temperature filter body (12) interconnect, and high temperature filter body (12) and humidification gas wash tower (13) interconnect.

2. A gasification process method of a pressurized oxygen-enriched circulating fluidized bed comprises the following steps:

discharging raw material coal from a raw material coal bunker (1) and feeding the raw material coal into a coal washer (15), removing dust and waste rocks by the coal washer (15), reducing the ash content and the sulfur content so as to achieve the purpose of environmental protection and improve the utilization rate of the coal, and conveying the treated raw material coal to a pressurized oxygen-enriched circulating fluidized bed gasification furnace (3) by the coal washer (15);

secondly, raw material coal is subjected to gasification reaction with a gasification agent introduced from the bottom and the lower part of a hearth of the pressurized oxygen-enriched circulating fluidized bed gasification furnace (3) through a pipeline, a sufficient amount of gasification agent is added into a gasification agent preheater (6), the slag discharged from the pressurized oxygen-enriched circulating fluidized bed gasification furnace (3) is continuously discharged through a slag lock hopper (14), then enters a roller slag cooler (16) through a pneumatic gate valve of the pressurized oxygen-enriched circulating fluidized bed gasification furnace (3) for cooling, the cooled slag temperature is less than 100 ℃, and then falls into a slag discharging belt (17) and is transported away from a device;

thirdly, after gas and particle gas-solid mixture discharged from the top of a hearth of the pressurized oxygen-enriched circulating fluidized bed gasification furnace (3) is separated by a high-temperature cyclone separator (4), particles are returned to the pressurized oxygen-enriched circulating fluidized bed gasification furnace (3) for internal circulating fluidization by a return feeder (5), the separated gas enters a gasification agent preheater (6), a steam superheater (7) and a waste heat boiler (8) for sufficient heat exchange, sensible heat of the high-temperature gas is recovered to generate medium-pressure saturated steam, a small part of the saturated steam is extracted for the oxygen supply preheater, the rest of the saturated steam is superheated by the steam superheater (7), a small part of the superheated steam enters the pressurized oxygen-enriched circulating fluidized bed gasification furnace (3) for use as a gasification agent, and the rest of the steam is sent out;

fourthly, gas-solid separation is carried out on the gas passing through a waste heat recovery system consisting of a gasifying agent preheater (6), a steam superheater (7) and a waste heat boiler (8) through a cyclone dust collector (11), most of fly ash in the gas is removed, and the dust removal burden of a subsequent high-temperature filter body (12) is reduced;

fifthly, after heat is recovered by a waste heat recovery system consisting of a gasifying agent preheater (6), a steam superheater (7) and a waste heat boiler (8), coal gas with the temperature of about 180 ℃ is purified, and micron-sized dust in the coal gas is purified by a high-temperature filter body (12);

sixthly, after dust removal is carried out on the purified gas by the high-temperature filter body (12), the purified gas is washed by a humidifying and dust removing tower (13), the coal gas is washed by the humidifying and dust removing tower (13), the water vapor content in the gas is improved while the gas is purified, the steam supplement amount of a downstream working section to the crude gas is reduced, and then the crude gas is sent to a downstream device for subsequent processing through a pipeline arranged on the humidifying and dust removing tower (13).

3. The pressurized oxygen-enriched circulating fluidized bed gasification process and system as claimed in claims 1 and 2, wherein: the pressure range of the pressurized oxygen-enriched circulating fluidized bed gasification furnace (3) is 50 kPaG-1.0 MPaG.

4. The pressurized oxygen-enriched circulating fluidized bed gasification process and system as claimed in claims 1 and 2, wherein: the gasifying agent added into the gasifying agent preheater (6) adopts any one of air, oxygen, carbon dioxide gas, raw gas at the outlet of the gasification furnace or steam, or the combination of the two media or a plurality of media.

5. The pressurized oxygen-enriched circulating fluidized bed gasification process and system as claimed in claims 1 and 2, wherein: the byproduct of the waste heat recovery system consisting of the steam superheater (7), the waste heat boiler (8) and the steam drum (9) is medium-pressure superheated steam, and the steam pressure range is 1.0-4.5 MPaG.

6. The pressurized oxygen-enriched circulating fluidized bed gasification process and system as claimed in claims 1 and 2, wherein: the cyclone (11) removes large particle dust with a particle size of more than 200 μm.

7. The pressurized oxygen-enriched circulating fluidized bed gasification process and system as claimed in claims 1 and 2, wherein: the high-temperature filter body (12) adopts a high-temperature sintered metal filter or a high-temperature ceramic filter, and the particle size of the high-temperature filter body (12) removed is 0200 mu m of small-particle dust, and the dust content in the coal gas is less than or equal to 10mg/Nm after the coal gas is filtered by the high-temperature filter body (12)³。

8. The pressurized oxygen-enriched circulating fluidized bed gasification process and system as claimed in claims 1 and 2, wherein: high temperature filter body (12) and humidification gas wash tower (13) adopt dry process and wet process mixed dusting technology, the upper segment of humidification gas wash tower (13) is equipped with spray set (133), and the middle section is equipped with heat exchanger (132), and the hypomere is equipped with regular packing district (131), unites two into one heat exchanger (132) and dust removal water conservation tower, is about to install heat exchanger (132) in humidification gas wash tower (13) top.

9. The pressurized oxygen-enriched circulating fluidized bed gasification process and system as claimed in claims 1 and 2, wherein: the middle lower part of the gasification furnace (3) adopts an oxygen inlet pipe (18) to be matched with an oxygen ring pipe (19), and the oxygen ring pipe (19) is divided into 8 branch pipes to be sprayed up and down oppositely.

Technical Field

The invention relates to the technical field of fuel coal gasification equipment, in particular to a gasification process method and a gasification system of a pressurized oxygen-enriched circulating fluidized bed.

Background

The fuel coal gasification equipment is a device for converting coal or coke, semicoke and other solid fuels into gas products and a small amount of residues by reacting with a gasification agent under the conditions of high temperature, normal pressure or pressurization, wherein the gasification agent is added to carry out gasification reaction with the fuel to obtain coal gas with less impurities.

During the continuous use of the circulating fluidized bed and the associated production system, the following problems were found:

the existing large-scale circulating fluidized bed gasification process is characterized in that normal-pressure slag discharge is basically normal-pressure gasification, process flows such as bag-type dust remover dust removal and water cooler indirect heat exchange are adopted, normal-pressure gasification is adopted, on one hand, gasification strength cannot be improved, carbon conversion rate is influenced, on the other hand, follow-up pressurization needs to consume large compression work, and the temperature of an inlet of the bag-type dust remover is strictly controlled by adopting bag-type dust remover dust removal, so that a security heat exchanger is generally additionally arranged at the inlet of the bag-type dust remover, meanwhile, the dust removal effect of the bag-type dust remover is poor, crude gas subjected to dust removal by the bag-type dust remover adopts the water cooler indirect heat exchange, the water content in the crude gas is only saturated water content at corresponding temperature due to the fact that the.

Therefore, a gasification process method and a system of the pressurized oxygen-enriched circulating fluidized bed are needed to be designed for solving the problems.

Disclosure of Invention

The invention aims to provide a gasification process method and a gasification process system of a pressurized oxygen-enriched circulating fluidized bed, which aim to solve the problems of low gasification strength of normal-pressure gasification, poor dust removal effect of a bag-type dust remover and low water vapor content in coal gas in the background technology.

In order to achieve the purpose, the invention provides the following technical scheme: a belt pressure oxygen-enriched circulating fluidized bed gasification system comprises a raw material coal bunker, a screw feeder, a belt pressure oxygen-enriched circulating fluidized bed gasification furnace and a slag discharging belt, wherein the raw material coal bunker is connected with a coal washer, the coal washer is connected with the screw feeder, the screw feeder is connected with the belt pressure oxygen-enriched circulating fluidized bed gasification furnace, a slag lock bucket is installed at the bottom end of the belt pressure oxygen-enriched circulating fluidized bed gasification furnace, the top of the belt pressure oxygen-enriched circulating fluidized bed gasification furnace is connected with the upper part of a high-temperature cyclone separator, a material returning device is installed at the bottom end of the high-temperature cyclone separator, the material returning device is connected with the belt pressure oxygen-enriched circulating fluidized bed gasification furnace, the slag lock bucket is connected with a roller slag cooler, the slag discharging belt is arranged beside the roller slag cooler, the top of the high-temperature cyclone separator is connected with the, and exhaust-heat boiler and economizer interconnect are provided with the steam pocket simultaneously between exhaust-heat boiler and the economizer, economizer and cyclone interconnect, and cyclone and high temperature filter body interconnect to high temperature filter body and humidification gas wash tower interconnect.

A gasification process method of a pressurized oxygen-enriched circulating fluidized bed comprises the following steps:

discharging raw material coal from a raw material coal bunker, feeding the raw material coal into a coal washer, removing dust and waste rocks by the coal washer, reducing the ash content and the sulfur content so as to achieve the purpose of environmental protection and improve the utilization rate of the coal, and conveying the treated raw material coal to a pressurized oxygen-enriched circulating fluidized bed gasification furnace by the coal washer;

secondly, raw material coal is subjected to gasification reaction with a gasification agent introduced from the bottom and the lower part of a hearth of the pressurized oxygen-enriched circulating fluidized bed gasification furnace through pipelines, a sufficient amount of gasification agent is added into a gasification agent preheater, slag is discharged from the pressurized oxygen-enriched circulating fluidized bed gasification furnace and is continuously discharged through a slag lock hopper, then the raw material coal enters a roller slag cooler through a pneumatic gate valve of the pressurized oxygen-enriched circulating fluidized bed gasification furnace to be cooled, the temperature of the cooled slag is lower than 100 ℃, and the cooled slag falls into a slag discharging belt and is transported away from a device;

thirdly, after gas-solid mixture of gas and particles discharged from the top of a hearth of the pressurized oxygen-enriched circulating fluidized bed gasifier is separated by a high-temperature cyclone separator, the particles are returned to the pressurized oxygen-enriched circulating fluidized bed gasifier for circulating fluidization by a material returning device, the separated gas enters a gasifying agent preheater, a steam superheater and a waste heat boiler for sufficient heat exchange, sensible heat of the high-temperature gas is recovered to generate medium-pressure saturated steam, a small part of the saturated steam is extracted for the oxygen-supplying gas preheater, the rest of the saturated steam is superheated by the steam superheater, a small part of the superheated steam enters the pressurized oxygen-enriched circulating fluidized bed gasifier for use as a gasifying agent, and the rest of the steam is sent out;

gas-solid separation is carried out on the gas passing through a waste heat recovery system consisting of a gasifying agent preheater, a steam superheater and a waste heat boiler by a cyclone dust collector, most of fly ash in the gas is removed, and the dust removal burden of a subsequent high-temperature filter body is reduced;

fifthly, after heat is recovered by a waste heat recovery system consisting of a gasifying agent preheater, a steam superheater and a waste heat boiler, coal gas with the temperature of about 180 ℃ is purified by a high-temperature filter body to obtain micron-sized dust in the coal gas;

sixthly, after dust removal is carried out on the purified gas by the high-temperature filter body, the purified gas is washed by a humidifying and dedusting tower, the coal gas is washed by the humidifying and dedusting tower, the content of water vapor in the gas is improved while the gas is purified, the steam supplement amount of the crude gas in a downstream working section is reduced, and the crude gas is sent to a downstream device for subsequent processing through a pipeline installed on the humidifying and dedusting tower.

Preferably, the pressure range of the pressurized oxygen-enriched circulating fluidized bed gasification furnace is 50 kPaG-1.0 MPaG.

Preferably, the gasifying agent added in the gasifying agent preheater adopts any one of air, oxygen, carbon dioxide gas, raw gas at the outlet of the gasification furnace or steam, or a combination of two or more of the above media.

Preferably, a byproduct of a waste heat recovery system consisting of the steam superheater, the waste heat boiler and the steam drum is medium-pressure superheated steam, and the steam pressure range is 1.0-4.5 MPaG.

Preferably, the cyclone removes large particle dust with a particle size of more than 200 μm;

preferably, the high-temperature filter body adopts a high-temperature sintered metal filter or a high-temperature ceramic filter, small particle dust with the particle size of 0-200 mu m is removed by the high-temperature filter body, and the dust content in the coal gas is less than or equal to 10mg/Nm after the coal gas is filtered by the high-temperature filter body³。

Preferably, the high-temperature filter body and the humidifying dust removal tower adopt a dry method and wet method mixed dust removal process, a spraying device is arranged at the upper section of the humidifying dust removal tower, a heat exchanger is arranged at the middle section of the humidifying dust removal tower, a regular packing area is arranged at the lower section of the humidifying dust removal tower, the heat exchanger and the dust removal water-saving tower are combined into a whole, namely, the heat exchanger is arranged at the top of the humidifying dust removal tower, the heat transfer effect is increased, the hydrogen sulfide corrosion of the heat exchanger is effectively slowed down, the dust removal effect is enhanced, meanwhile, the water vapor; the gas discharged from the top of the humidifying dust removal tower can be cooled directly by the heat exchanger, so that the gas in the downstream process can carry as much water as possible, and the purpose of steam supplement in the downstream conversion process is reduced; a spraying device is additionally arranged above the heat exchanger to further humidify the coal gas after heat exchange by the heat exchanger, so that trace hydrogen sulfide contained in the coal gas is further dissolved into water to prevent the trace hydrogen sulfide from being brought into a downstream process.

Preferably, the lower part of the gasification furnace is matched with an oxygen ring pipe through an oxygen inlet pipe, the oxygen ring pipe is divided into 8 branch pipes to be sprayed up and down, the mixing degree is increased, the local temperature is increased to enhance the gasification efficiency, and the purpose of removing tar and phenol is achieved, the 8 branch pipes, the upper part of the gasification furnace is provided with 4 branch pipes, the lower part of the gasification furnace is provided with 4 branch pipes, the upper part of the gasification furnace is provided with 4 downward-spraying oxygen, the lower part of the gasification furnace is provided with 4 upward-spraying oxygen, the branch pipes and the axis of the gasification furnace form a certain included angle, the included angle.

Compared with the prior art, the invention has the beneficial effects that: the pressurized oxygen-enriched circulating fluidized bed gasification process method and the system adopt a novel structural design, so that the process flow is simple, the gasification pressure is easy to improve, the system operation cost and the investment cost are low, the dust removal efficiency is high, and the produced coal gas has high water vapor content;

1. compared with the conventional normal-pressure gasification, the pressure range of the pressurized oxygen-enriched circulating fluidized bed can realize the higher pressure of the crude gas at the outlet of the gasification furnace, thereby greatly saving the downstream compression work;

2. the waste heat boiler, the steam drum and the steam superheater system can produce medium-pressure superheated steam as by-products, so that the steam grade and the utilization efficiency are improved;

3. the coal washer can reduce impurities in raw coal, and is matched with a two-stage grading dust removal structure consisting of the cyclone dust collector and the high-temperature filter body, so that the dust removal efficiency is higher, and the impurities in the produced coal gas are less;

4. the humidifying dust removal tower washes the coal gas, so that the water vapor content in the coal gas is improved while the coal gas is purified, and the steam supplement amount of a downstream working section to the raw coal gas is reduced.

Drawings

FIG. 1 is a schematic diagram of a process flow diagram and system structure according to the present invention;

FIG. 2 is a schematic view of the structure of the oxygen inlet tube and the oxygen loop tube of the present invention.

In the figure: 1. a raw material coal bunker; 2. a screw feeder; 3. a pressurized oxygen-enriched circulating fluidized bed gasification furnace; 4. a high temperature cyclone separator; 5. a material returning device; 6. a gasifying agent preheater; 7. a steam superheater; 8. a waste heat boiler; 9. a steam drum; 10. a coal economizer; 11. a cyclone dust collector; 12. a high temperature filter body; 13. a humidifying and dedusting tower; 131. a structured packing zone; 132. a heat exchanger; 133. a spraying device; 14. a slag lock hopper; 15. a coal washer; 16. a roller slag cooler; 17. a slag belt; 18. an oxygen inlet pipe; 19. an oxygen loop.

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.

Referring to fig. 1, the present invention provides a technical solution: a gasification process method and a system of a pressurized oxygen-enriched circulating fluidized bed comprise a raw material coal bunker 1, a screw feeder 2, a pressurized oxygen-enriched circulating fluidized bed gasifier 3, a high-temperature cyclone separator 4, a material returning device 5, a gasifying agent preheater 6, a steam superheater 7, a waste heat boiler 8, a steam pocket 9, a coal economizer 10, a cyclone dust collector 11, a high-temperature filter body 12, a humidifying dust removal tower 13, a slag lock hopper 14, a coal washer 15, a roller slag cooler 16 and a slag discharge belt 17, wherein the raw material coal bunker 1 is connected with the coal washer 15, the coal washer 15 is connected with the screw feeder 2, the screw feeder 2 is connected with the pressurized oxygen-enriched circulating fluidized bed gasifier 3, the slag lock hopper 14 is arranged at the bottom end of the pressurized oxygen-enriched circulating fluidized bed gasifier 3, the top of the pressurized oxygen-enriched circulating fluidized bed gasifier 3 is connected with the upper part of the high-temperature cyclone separator 4, and the material returning device, meanwhile, the material returning device 5 is connected with the pressurized oxygen-enriched circulating fluidized bed gasification furnace 3, the slag lock hopper 14 is connected with the roller slag cooler 16, a slag discharging belt 17 is arranged beside the roller slag cooler 16, the top of the high-temperature cyclone separator 4 is connected with the top of the gasifying agent preheater 6, the gasifying agent preheater 6 is connected with the steam superheater 7, the waste heat boiler 8 is connected with the economizer 10, a steam pocket 9 is arranged between the waste heat boiler 8 and the economizer 10, the economizer 10 is connected with the cyclone dust collector 11, the cyclone dust collector 11 is connected with the high-temperature filter body 12, and the high-temperature filter body 12 is connected with the humidifying dust-removing tower 13.

A gasification process method of a pressurized oxygen-enriched circulating fluidized bed comprises the following steps:

feeding raw material coal from a raw material coal bunker 1 into a coal washer 15, removing dust and waste rocks by the coal washer 15, reducing the ash content and the sulfur content so as to achieve the purpose of environmental protection and improve the utilization rate of the coal, and conveying the processed raw material coal to a pressurized oxygen-enriched circulating fluidized bed gasifier 3 by the coal washer 15;

secondly, the raw material coal is subjected to gasification reaction with a gasification agent introduced from the bottom and the lower part of a hearth of the pressurized oxygen-enriched circulating fluidized bed gasification furnace 3 through a pipeline, a sufficient amount of gasification agent is added into a gasification agent preheater 6, the slag discharged from the pressurized oxygen-enriched circulating fluidized bed gasification furnace 3 is continuously discharged through a slag lock hopper 14, and then enters a roller cooling furnace 16 for cooling through a pneumatic gate valve of the pressurized oxygen-enriched circulating fluidized bed gasification furnace 3, the temperature of the cooled slag discharged is less than 100 ℃, and the cooled slag falls into a slag discharging belt 17 and is transported away from a device;

thirdly, after gas-solid mixture of gas and particles discharged from the top of a hearth of a pressurized oxygen-enriched circulating fluidized bed gasifier 3 is separated by a high-temperature cyclone separator 4, the particles are returned to the pressurized oxygen-enriched circulating fluidized bed gasifier 3 for circulating fluidization by a material returning device 5, the separated gas enters a gasifying agent preheater 6, a steam superheater 7 and a waste heat boiler 8 for sufficient heat exchange, sensible heat of the high-temperature gas is recovered to generate medium-pressure saturated steam, a small part of the saturated steam is extracted for supplying the oxygen preheater, the rest of the saturated steam is superheated by the steam superheater 7, a small part of the superheated steam enters the pressurized oxygen-enriched circulating fluidized bed gasifier 3 for being used as a gasifying agent, and the rest of the steam is sent out;

gas-solid separation is carried out on the gas passing through a waste heat recovery system consisting of a gasifying agent preheater 6, a steam superheater 7 and a waste heat boiler 8 through a cyclone dust collector 11, most fly ash in the gas is removed, and the dust removal burden of a subsequent high-temperature filter body 12 is reduced;

gas with the temperature of about 180 ℃ after heat is recovered by a waste heat recovery system consisting of a gasifying agent preheater 6, a steam superheater 7 and a waste heat boiler 8, and micron-sized dust in the gas is purified by a high-temperature filter body 12;

sixthly, after dust removal is carried out on the purified gas by the high-temperature filter body 12, the purified gas is washed by the humidifying and dedusting tower 13, the coal gas is washed by the humidifying and dedusting tower 13, the water vapor content in the gas is improved while the gas is purified, the steam supplement amount of the crude gas in a downstream working section is reduced, and then the crude gas is sent to a downstream device for subsequent processing through a pipeline arranged on the humidifying and dedusting tower 13.

In the embodiment, the pressure range of the pressurized oxygen-enriched circulating fluidized bed gasification furnace 3 is 50 kPaG-1.0 MPaG, compared with the conventional normal-pressure gasification, the pressurized oxygen-enriched circulating fluidized bed gasification furnace 3 can realize that the pressure of the crude coal gas at the outlet of the pressurized oxygen-enriched circulating fluidized bed gasification furnace reaches 0.9MPaG, thereby greatly saving the downstream compression work, and simultaneously, the pressurized oxygen-enriched circulating fluidized bed gasification furnace 3 can realize pressurized continuous slag discharge through the slag lock hopper 14;

the gasifying agent added into the gasifying agent preheater 6 adopts any one of air, oxygen, carbon dioxide gas, and gasifier outlet crude gas or steam, or the combination of the two media or a plurality of media, and carbon dioxide is used as the gasifying agent, thereby not only providing a carbon source, but also changing waste into valuable and recycling;

a byproduct of a waste heat recovery system consisting of the steam superheater 7, the waste heat boiler 8 and the steam drum 9 is medium-pressure superheated steam, the steam pressure range is 1.0-4.5 MPaG, and the waste heat recovery system improves the steam grade and the utilization efficiency;

the cyclone dust collector 11 removes large-particle dust with the particle size larger than 200 mu m, most of fly ash with larger diameter in the coal gas can be removed, and the dust removal burden of the high-temperature filter body 12 is reduced;

the high-temperature filter body 12 adopts a high-temperature sintered metal filter or a high-temperature ceramic filter, the high-temperature filter body 12 removes small particle dust with the particle size of 0-200 mu m, and the dust content in the coal gas is less than or equal to 10mg/Nm after the coal gas is filtered by the high-temperature filter body 12³The high-temperature filter body 12 and the cyclone dust collector 11 form a two-stage grading dust removal system, so that dust with smaller diameter is removed, and the dust removal efficiency is higher.

The high-temperature filter 12 body and the humidifying dust removal tower 13 adopt a dry-method and wet-method mixed dust removal process, the upper section of the humidifying dust removal tower 13 is provided with a spraying device 133, the middle section is provided with a heat exchanger 132, the lower section is provided with a regular packing area 131, the heat exchanger 12 and the dust removal water-saving tower are combined into a whole, namely, the heat exchanger 12 is arranged at the top of the humidifying dust removal tower 13, the heat transfer effect is increased, the hydrogen sulfide corrosion of the heat exchanger 12 is effectively slowed down, the dust removal effect is enhanced, meanwhile, the water vapor content is increased, and the; the gas discharged from the top of the humidifying and dust removing tower 13 is directly cooled by the heat exchanger 12, so that the gas in the downstream process can carry as much water as possible, and the purpose of steam supplement in the downstream conversion process is reduced; a spraying device 133 is additionally arranged above the heat exchanger 12 to further humidify the coal gas after heat exchange by the heat exchanger 12, so that trace hydrogen sulfide contained in the coal gas is further dissolved into water to prevent the hydrogen sulfide from being brought into a downstream process.

Adopt into oxygen pipe 18 and the cooperation of oxygen ring pipe 19 in gasifier 3 lower part, oxygen ring pipe 19 divides 8 branch pipes to spout from top to bottom, increase the degree of mixing, increase local temperature in order to strengthen gasification efficiency, reach the purpose of getting rid of tar and phenol, 8 branch pipes, 4 upper portion, 4 lower parts, 4 upper portion spout oxygen downwards, 4 lower portion spout oxygen upwards, the branch pipe forms certain contained angle with 3 axes of gasifier, the contained angle scope is 5 ~ 45 degrees, oxygen pressure is greater than 3 internal pressure 10bar of gasifier

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.