WO2022105330A1

WO2022105330A1 - Crushed coal pressurized gasification coal gas-water separation and recycling system and method capable of recycling sewage

Info

Publication number: WO2022105330A1
Application number: PCT/CN2021/113369
Authority: WO
Inventors: 左永飞; 李小红; 范辉; 施福富; 周恩利; 刘丰力; 李金洲; 楚可嘉; 车丽玮; 韩鑫凤; 袁辉峰; 刘利利; 李树枫; 李叶珺; 徐景亮; 赵宇宏; 刘于英; 陈党辉
Original assignee: 赛鼎工程有限公司
Priority date: 2020-11-19
Filing date: 2021-08-18
Publication date: 2022-05-27
Also published as: CN112408709A

Abstract

Provided in the present invention are a crushed coal pressurized gasification coal gas-water separation and recycling system and method capable of recycling sewage, belonging to the field of gas separation and recycling. According to the present invention, different types of coal gas-water are respectively separated and recycled, such that the whole system has the advantages of a small occupied area, low investment, low operation costs, a short treatment flow, few apparatuses, and few pollutant discharge points, and same is not prone to causing environmental pollution. Apparatuses such as a medium-pressure flash evaporator, a vacuum flash evaporator, a vacuum flash separator and an ammonia still are arranged, and a settling tank and the top of a coal gas-water tank are hermetically connected to an inert gas pipeline, such that the whole system and the separation and recycling process can maintain operation at a micro-positive pressure of greater than 0.2 kPa, and VOCs and odors discharged from the system can thus be subjected to centralized processing. A water outlet of a second vacuum flash evaporator is connected to a water inlet of a heat exchanger connected to a waste heat boiler by means of a pipeline and a water pump, such that waste water is recycled, the waste water quantity sent to a biochemical processing apparatus can be reduced, and the heat in the waste water can be fully utilized.

Description

System and method for separation and reuse of crushed coal pressurized gasification gas water that can be reused from sewage

technical field

The invention relates to the technical field of gas separation and reuse, in particular to a system and method for separating and reusing crushed coal pressurized gasification gas water that can be reused from sewage.

Background technique

The crude gas produced by the pressurized gasification of crushed coal contains a large amount of water vapor, dust and carbonized by-products, such as tar, light oil, naphthalene, phenol, fatty acid, dissolved gas and inorganic salts, etc., and the temperature is also high . Therefore, it needs to be cooled and washed to reduce the temperature and remove harmful substances in the raw gas. During the washing and cooling process of the crude gas, these impurity components enter the water to form gas water with multiple components in the three states of gas, liquid and solid. The content of various ingredients is also not the same. Gas water cannot be directly treated by conventional biochemical, filtration, reverse osmosis and other methods. Oil, dust, phenol, ammonia, etc. must be separated and recovered. On the one hand, valuable substances in wastewater are recovered, which can produce certain Economic benefits; on the other hand, the wastewater can meet the influent requirements of general wastewater treatment methods, and then be discharged after biochemical treatment to meet the national discharge standards.

The "Modern Coal Chemical Technology Manual" briefly describes the most classic gas-water separation and recovery process, which is also the process commonly used in the current crushed coal pressurized gasification technology. After the gas water and the shift cooling gas water are respectively sent to the gas water separation system, they are first cooled to 90°C, and then enter the gas water expander for flash evaporation to normal pressure, and the dissolved CO ₂ , NH ₃ and part of the water vapor in the gas water are removed. Wait for the gas to flash off. The flashed gas water enters the lower tar separator to separate the gas water and tar by using the density difference, and the dusty tar with a density greater than water is discharged from the bottom, which can be used as a product or returned to the gasifier for gasification again; density Light oil and gas water smaller than water overflow from the upper part of the tar separator into the gas water buffer tank, part of the gas water is sent back to the gasification cycle by the high pressure pump, and the excess gas water enters the light oil separator. The light oil separator is equipped with coke and TPI plate components. On the one hand, impurities are filtered. On the other hand, the oil droplets are condensed and floated on the water surface to form an oil layer. The light oil is led out through the upper overflow weir and sent to the oil storage tank. The water enters the water chamber after passing through the TPI plate, and is then drawn out through the overflow weir. After passing through the buffer tank, the water is pumped into the dual-media filter for further dust removal and then sent to the phenol and ammonia recovery device. The purpose is to remove the dust, oil and The dissolved gas is separated, most of the water is used for recycling, and a small part of the water is further deoiled, ammonia distilled, and dephenolized, and then the water quality is de-biochemically treated to meet the biochemical requirements.

However, with the development of gas technology, it is gradually developing in the direction of large-scale, energy-saving, environmental protection, high-efficiency and stability. The gas-water separation and recovery process of the conventionally used crushed coal pressurized gasification technology cannot meet modern requirements, mainly reflected in: 1. The existing gas water treatment system aggregates different types of gas water from different equipment for gas water separation and recovery, resulting in a large area of the entire gas water separation and recovery system, high investment and high operating costs; 2. The current gas-water separation and recovery process is long and there are many equipments, resulting in many pollutant discharge points, which is likely to cause serious environmental pollution; 3. The existing gas-water separation and recovery system will use multiple gas-water storage tanks and oil Separators, etc., these devices operate at atmospheric pressure, which is easy to cause the emission of VOCs (Volatile Organic Compounds, volatile organic compounds), odors, etc. cannot be collected and processed centrally, making the on-site environment harsh.

4. The condensed water obtained by heat exchange in the existing gas-water separation and recovery system is often directly discharged as waste water, which not only makes the amount of waste water going to the biochemical treatment equipment relatively large, but also cannot make full use of the heat in the condensed liquid.

technical problem

In order to solve the above-mentioned technical problems, the present invention provides a system and method for separating and reusing crushed coal pressurized gasification gas and water, which can be reused for sewage.

technical solutions

In order to solve the above-mentioned technical problems, the technical scheme adopted in the present invention is: a crushed coal pressurized gasification gas water separation and reuse system that can be reused from sewage, which includes a medium pressure flasher, a first vacuum flasher, a settling tank , gas water tank, deacidification tower, first vacuum flasher, ammonia distillation tower, second vacuum flasher, second vacuum flasher, third vacuum flasher, flocculant tank, filter press , filtrate tank, several water pumps and pipelines, wherein: the first water inlet of the medium pressure flasher is connected with the transformation high temperature condensate pipeline, and the second water inlet of the medium pressure flasher is connected with the gasification dust-containing gasification water pipeline connection, the water outlet of the medium-pressure flasher is connected with the first water inlet of the first vacuum flasher through the pipeline, the second water inlet of the first vacuum flasher is connected with the low-pressure gasification gas water pipeline, the first vacuum flasher The third water inlet is connected to the low-pressure start-up gas water pipeline, the water outlet of the first vacuum flasher is connected to the water inlet of the sedimentation tank through the pipeline and the water pump, and the water outlet of the sedimentation tank is connected to the water inlet of the filter press through the pipeline and the water pump Connection, the water outlet of the filter press is connected to the water inlet of the filtrate tank through the pipeline, the water outlet of the filtrate tank is connected to the water inlet of the sedimentation tank through the pipeline and the water pump, and the water inlet of the sedimentation tank is also connected to the flocculant tank through the pipeline. The gas water outlet of the settling tank is connected to the gas water inlet of the gas water tank through the pipeline, and the gas water outlet of the gas water tank is connected to the gas water biochemical treatment equipment and the gas water reuse equipment through the pipeline and the water pump. , the top of the settling tank and the gas water tank are hermetically connected to the inert gas pipeline; the air outlet of the medium pressure flasher is connected to the air inlet of the deacidification tower through the pipeline, and the water inlet of the second vacuum flasher is connected to the low temperature condensing unit The water outlet of the second vacuum flasher is connected to the water inlet of the heat exchanger connected to the waste heat boiler through the pipeline and the water pump, and the water outlet of the deacidification tower is connected to the water inlet of the ammonia distillation tower through the pipeline and the water pump. , the water outlet of the ammonia distillation tower is connected with the crude gas washing equipment; the air outlet of the first vacuum flasher is connected with the air inlet of the first vacuum flash separator through a pipeline, and the air outlet of the first vacuum flash separator passes through The pipeline is connected with the air inlet of the third vacuum flash separator, the water outlet of the first vacuum flash separator is connected with the water inlet of the deacidification tower through the pipeline and the water pump; the gas outlet of the second vacuum flash separator is connected by the pipe The pipeline is connected to the air inlet of the second vacuum flash separator, and the air outlet of the second vacuum flash separator is connected to the air inlet of the third vacuum flash separator through the pipeline. The water outlet is connected to the water inlet of the deacidification tower through a pipeline, and the water outlet of the third vacuum flash separator is connected to the water inlet of the deacidification tower through a pipeline.

Optionally, the crushed coal pressurized gasification gas water separation and reuse system that can be reused with sewage also includes an oil collecting float and an oil tank, the oil collecting float is arranged inside the gas water tank, and the bottom of the oil collecting float passes through the water tank. The hose is connected to the tank.

Optionally, a cooling water jacket is provided outside the gas water tank and the breathing gas discharge pipeline at the top of the settling tank.

A method for separating and reusing crushed coal pressurized gasification gas and water that can be reused with sewage, which comprises the following steps: S1, transforming high-temperature condensate and gasification dust-containing gasification water after degassing by a medium-pressure flasher, and degassing them with gas The low-pressure gas water and gasification start-up gas water enter the first vacuum flasher together and the dissolved gas is deeply removed in the first vacuum flasher; S2, the gas water after the de-dissolved gas is mixed with the flocculant from the flocculant tank and sent to the into the settling tank; S3, the solid material settled at the bottom of the settling tank is dehydrated by the filter press to make mud cake, the filtrate generated by the pressure filtration and dehydration enters the filtrate tank and returns to the settling tank, and the gas water in the upper part of the settling tank is sent into Gas water tank, a part of the gas water in the gas water tank is used as the washing water for gasification of low-pressure gas water and reused for the gas water reuse equipment, and the remaining gas water goes to the gas water biochemical treatment equipment; S4, the medium pressure flasher flashes out The flash steam from the deacidification tower is sprayed into the deacidification tower from the bottom of the deacidification tower as the heat source of the deacidification tower, and the acid gas in the flash steam is removed from the deacidification tower at the same time; After the dissolved gas is removed, it is pressurized and heat exchanged and sent to the waste heat boiler for use as supplementary water to reduce the amount of water in the degassed water biochemical treatment equipment; S6, the condensation formed by the flashing of the first vacuum flasher and the second vacuum flasher The liquid enters the first vacuum flash separator, the second vacuum flash separator and the third vacuum flash separator for vacuum flash separation, and passes through the first vacuum flash separator, the second vacuum flash separator and the third vacuum flash separator. The condensed liquid condensed by the three vacuum flash separators is sent from the top of the deacidification tower to the deacidification tower for deacidification; S7, the deacidification gas desulfurization recovery equipment obtained from the deacidification of the deacidification tower, the deacidified gas water enters the ammonia distillation Tower, the gas water after ammonia distillation in the ammonia distillation tower is reused as washing water for the crude gas washing equipment, and the ammonia water/liquid ammonia produced in the ammonia distillation tower is recycled and reused.

Optionally, the transformed high-temperature condensate is gas water with a dust content of not more than 2000 mg/L, a temperature of 150-190 ° C, and a pressure of 3.0-7.0 MPa; the gasified dust-containing gasified water is the dust-containing water Gas water with a temperature of 180-200°C and a pressure of 3.0-7.0MPa not more than 3000mg/L; the transformation low temperature condensate is a dust content less than 50mg/L, a temperature of 40-80°C, and a pressure of 3.0-5.0 MPa gas water; the low-pressure gasification gas water is gas water with a dust content of less than 100 mg/L, a temperature of 60-80 °C, and a pressure of 0.5-0.7 MPa; the low-pressure start-up gas water is a gas water with a dust content of less than 200 mg /L gas water with a temperature of 60-80°C and a pressure of 0.5-0.7MPa.

Optionally, the flash temperature of the medium-pressure flash evaporator is 140-160° C. and the pressure is 0.4-0.5 MPa.

Optionally, the flash temperature of the first vacuum flasher is 80-86° C. and the vacuum degree is 50-60 kPa.

Optionally, the added amount of the flocculant is 1 ton of coal gas water and 3-5 g of the flocculant.

Optionally, inert gas is continuously introduced into the top of the settling tank and the gas water tank.

beneficial effect

The beneficial effects of the present invention are as follows: 1. By separating and reusing the gas water of different classifications, not only the entire system occupies a small area, the investment is low, and the operating cost is low, but also the treatment process is short and the equipment is small, so that the pollutants are reduced. There are few discharge points, it is not easy to cause environmental pollution, and it has the advantages of energy saving, environmental protection, high efficiency and stability.

2. By setting up equipment such as medium-pressure flasher, vacuum flasher, vacuum flasher separator and ammonia distillation tower, and setting the settling tank and the top of the gas water tank to be sealed with the inert gas pipeline, the whole system and the separation and reuse process are made possible. Maintain a slight positive pressure operation greater than 0.2kPa, so as to ensure that the VOCs and odors discharged from the system can be centrally treated, making the site environment friendly.

3. The whole system of the present invention has simple equipment, safe and stable operation, and can effectively reduce the cost of gas water treatment.

4. By setting the water outlet of the second vacuum flasher to be connected with the water inlet of the heat exchanger connected to the waste heat boiler through pipelines and pumps, the gas water part after the sewage cleaning and shunting can be used as the supplementary water of the waste heat boiler, and the sewage steam is produced as the waste heat boiler. The use of gasification agent realizes the recycling of waste water, which not only reduces the amount of waste water going to the biochemical treatment equipment, but also makes full use of the heat in the waste water.

Practice has proved that compared with the current gas-water separation and reuse system, the system and method of the present invention reduce investment by 50%, operation cost by 50%, and waste water removed from biochemical treatment equipment by 25%.

Description of drawings

FIG. 1 is a schematic diagram of the system composition of the present invention.

FIG. 2 is a schematic diagram of the connection relationship between the present invention and the gasification unit, the washing unit and the transformation unit.

Embodiments of the present invention

The present invention will be described in further detail below with reference to the accompanying drawings and embodiments.

As shown in Figure 1, the crushed coal pressurized gasification gas water separation and reuse system that can be reused for sewage in this embodiment includes a medium pressure flasher 1, a first vacuum flasher 2, a settling tank 3, a gas Water tank 4, deacidification tower 5, first vacuum flash separator 6, ammonia distillation tower 7, second vacuum flasher 8, second vacuum flash separator 9, third vacuum flash separator 10, flocculant Tank 11, filter press 12, filtrate tank 13, several water pumps and pipelines, wherein: the first water inlet of the medium pressure flasher 1 is connected to the transformation high temperature condensate pipeline, and the second inlet of the medium pressure flasher 1 is connected. The water outlet is connected to the gasification dust-containing gasification water pipeline, the water outlet of the medium pressure flasher 1 is connected to the first water inlet of the first vacuum flasher 2 through the pipeline, and the second water inlet of the first vacuum flasher 2 is connected to the low pressure The gasification gas water pipeline is connected, the third water inlet of the first vacuum flasher 2 is connected with the low pressure start-up gas water pipeline, the water outlet of the first vacuum flasher 2 is connected with the water inlet of the settling tank 3 through the pipeline and the water pump, and the sedimentation The water outlet of the tank 3 is connected to the water inlet of the filter press 12 through the pipeline and the water pump, the water outlet of the filter press 12 is connected to the water inlet of the filtrate tank 13 through the pipeline, and the water outlet of the filtrate tank 13 is connected by the pipeline and the water pump. It is connected with the water inlet of the sedimentation tank 3, the water inlet of the sedimentation tank 3 is also connected with the discharge port of the flocculant tank 11 through the pipeline, and the gas water outlet of the sedimentation tank 3 is connected with the gas water inlet of the gas water tank 4 through the pipeline. , the gas water outlet of the gas water tank 4 is connected with the gas water biochemical treatment equipment and the gas water reuse equipment (coal lock gas washing equipment and driving gas washing equipment) through pipelines and water pumps, and the settling tank 3 and the gas water tank 4 The top is sealed with the inert gas pipeline to maintain a slight positive pressure greater than 0.2kPa in the settling tank 3 and the gas water tank 4; the air outlet of the medium pressure flasher 1 is connected to the air inlet of the deacidification tower 5 through the pipeline, The water inlet of the second vacuum flasher 8 is connected with the transformation low temperature condensate pipeline, the water outlet of the second vacuum flasher 8 is connected with the water inlet of the heat exchanger connected to the waste heat boiler through the pipeline and the water pump, and the outlet of the deacidification tower 5 is connected. The water outlet is connected with the water inlet of the ammonia distillation tower 7 through the pipeline and the water pump, and the water outlet of the ammonia distillation tower 7 is connected with the crude gas washing equipment; the air outlet of the first vacuum flasher 2 is connected with the first vacuum flash separator through the pipeline 6 is connected to the air inlet, the air outlet of the first vacuum flash separator 6 is connected to the air inlet of the third vacuum flash separator 10 through a pipeline, and the water outlet of the first vacuum flash separator 6 is connected through a pipeline Connect with the water inlet of the water pump and the deacidification tower 5; the air outlet of the second vacuum flasher 8 is connected with the air inlet of the second vacuum flash separator 9 through the pipeline, and the air outlet of the second vacuum flash separator 9 It is connected to the air inlet of the third vacuum flash separator 10 through a pipeline, the water outlet of the second vacuum flash separator 9 is connected to the water inlet of the deacidification tower 5 through a pipeline, and the third vacuum flash separator 10 The water outlet is connected to the water inlet of the deacidification tower 5 through a pipeline.

As shown in FIG. 2 , a gasification unit, a washing unit and a transformation unit are connected before the pressurized gasification gas-water separation and reuse system of crushed coal that can be recycled from sewage according to the embodiment of the present invention. Specifically, the crushed coal raw material is added to the crushed coal pressurized gasifier through the coal hopper for pressurized gasification to generate gasified crude gas. The gasified crude gas is dedusted by the cyclone separator before reaching the waste heat boiler, and the waste heat boiler recovers the gas After the heat in the medium is removed, the gas will continue to be dedusted in three stages by the Venturi washing equipment and the crude gas washing equipment, and then sent to the conversion equipment, precooler, intermediate and final cooling equipment and ammonia washing tower in the conversion unit. Part of the gas in the crushed coal pressurized gasifier enters the coal lock gas washing equipment, and the other part also enters the start-up gas washing equipment. The crushed coal is any one of anthracite, coke or semi-coke. Among them, the precooler produces a high-temperature condensate that is transformed. The intermediate and final cooling equipment and the ammonia washing tower produce shifted cryogenic condensate. The Venturi scrubber produces gasified dust-laden gasified water. Coal lock gas scrubbing equipment produces low pressure gasification gas water. The driving gas washing equipment produces low pressure driving gas water.

Optionally, the crushed coal pressurized gasification gas-water separation and reuse system that can be reused for sewage also includes an oil-collecting float 14 and an oil tank 15, the oil-collecting float 14 is arranged inside the gas-water tank 4, and the oil-collecting float The bottom of 14 is connected to the oil tank 15 through a hose. The height of the oil collecting float 14 can change with the liquid level in the gas water tank 4. The light oil floating on the upper part of the gas water tank 4 can enter the oil collecting float 14 and be collected by the hose to In the oil tank 15, the collection of light oil is realized.

Optionally, a cooling water jacket 16 is provided outside the breathing gas discharge pipes at the top of the gas water tank 4 and the settling tank 3 . The cooling water jacket 16 can cool the breathing gas discharged from the breathing gas discharge pipe at the top of the gas water tank 4 and the settling tank 3, so that the condensable odor can be condensed and flow back to the equipment, so as to avoid VOCs or odor from the gas water. Tank 4 and settling tank 3 discharge.

The embodiment of the present invention also provides a method for water separation and reuse of crushed coal pressurized gasification gas that can be reused for sewage. The crushed coal pressurized gasification gas-water separation and reuse system shown in 1 is realized, which specifically includes the following steps: S1, transforming the high-temperature condensate and the gasification dust-containing gasification water to be removed by the medium pressure flasher 1. After gasification, it enters the first vacuum flasher 2 together with the gasification low-pressure gas water and the gasification start-up gas water, and the dissolved gas is deeply removed in the first vacuum flasher 2 .

Optionally, the flashing temperature of the medium pressure flasher 1 is 140-160° C. and the pressure is 0.4-0.5 MPa. The flashing temperature of the first vacuum flasher 2 is 80-86° C., and the vacuum degree is 50-60 kPa.

S2 , the gas water after de-dissolved gas is mixed with the flocculant from the flocculant tank 11 and then sent to the sedimentation tank 3 .

S3, the solid material settled at the bottom of the settling tank 3 is dehydrated by the filter press 12 to make mud cake, and the filtrate generated by the pressure filtration and dehydration enters the filtrate tank 13 and returns to the settling tank 3 again, and the gas water at the top of the settling tank 3 sends Into the gas water tank 4, a part of the gas water in the gas water tank 4 is used as the washing water for gasification of low-pressure gas water for the gas water reuse equipment (coal lock gas washing equipment and driving gas washing equipment), and the remaining gas water goes to Gas water biochemical treatment equipment.

S4, the flash steam flashed from the medium pressure flasher 1 is sprayed into the deacidification column 5 from the bottom of the deacidification column 5 as the heat source of the deacidification column 5, and the acid gas in the flash steam is removed from the deacidification column 5 at the same time.

S5, transform the low-temperature condensate to de-dissolved gas in the second vacuum flasher 8, remove the dissolved gas, pressurize and exchange heat, and then send it to the waste heat boiler for use as supplementary water, so as to reduce the amount of water in the degassed water biochemical treatment equipment .

S6, the condensate formed by the flashing of the first vacuum flasher 2 and the second vacuum flasher 8 respectively enters the first vacuum flasher 6, the second vacuum flasher 9 and the third vacuum flasher 10 for processing Vacuum flash separation, the condensed liquid condensed through the first vacuum flash separator 6, the second vacuum flash separator 9 and the third vacuum flash separator 10 is sent from the top of the deacidification tower 5 to the deacidification tower 5 for deacidification. acid.

S7, the deacidification gas desulfurization recovery equipment obtained by the deacidification of the deacidification tower 5, the gas water after the deacidification enters the ammonia distillation tower 7, and the gas water after the ammonia steaming in the ammonia distillation tower 7 is the crude gas washing equipment as washing water Reuse, the ammonia water/liquid ammonia produced in the ammonia distillation tower 7 is recycled and reused.

Wherein, the transformed high-temperature condensate is gas water with a dust content of not more than 2000 mg/L, a temperature of 150-190 °C, and a pressure of 3.0-7.0 MPa; 3000mg/L gas water with a temperature of 180-200°C and a pressure of 3.0-7.0MPa; the transformation low temperature condensate is one with a dust content of less than 50mg/L, a temperature of 40-80°C and a pressure of 3.0-5.0MPa Gas water; the low-pressure gasification gas water is gas water with a dust content of less than 100 mg/L, a temperature of 60-80 °C, and a pressure of 0.5-0.7 MPa; the low-pressure start-up gas water is a gas water with a dust content of less than 200 mg/L , Gas water with temperature of 60-80℃ and pressure of 0.5-0.7MPa.

Optionally, inert gas is continuously introduced into the top of the settling tank 3 and the gas water tank 4, so that the interior of the settling tank 3 and the gas water tank 4 always maintains a slight positive pressure (0.2-0.5 kPa) greater than 0.2 kPa.

The methods provided by the embodiments of the present invention are illustrated below with several examples.

Example 1.

The crushed coal in this embodiment is Jincheng anthracite with a water content of 5%. The coal sample is crushed and sieved to obtain a coal sample with a particle size of 5-50 mm, which is loaded into a crushed coal pressurized gasifier for crushed coal pressurized gasification , the gasification pressure is 4.0MPa, and the gasification temperature is 1250℃. The crude gas produced by gasification is divided into high temperature gas water and low temperature gas water according to the dust content, temperature and pressure in the water during washing. Temperature and pressure are divided into high temperature condensate and gasification dust-containing gasification water, low temperature gas water is divided into low temperature condensate conversion, low pressure gasification gas water and low pressure driving gas water according to dust content, temperature and pressure. Different types of gas water are separated and reused separately. The whole process of separation and reuse of gas water is maintained at a slight positive pressure of more than 0.2kPa and protected by inert gas to ensure that VOCs and odors in the system can be centrally treated.

The above coal samples are processed by the gasification unit, washing unit and conversion unit, and the dust content of the transformed high-temperature condensate is 1900 mg/L, the temperature is 150 °C, and the pressure is 4 MPa, and the dust content of the gasification dust-containing gasification water is 2800 mg/L, temperature of 189°C, and pressure of 4.0 MPa. The dust content of the transformed low-temperature condensate is 45mg/L, the temperature is 67.5°C, and the pressure is 3.75MPa. The dust content of the low-pressure gasification gas water is 90mg/L, the temperature is 70°C, and the pressure is 0.5MPa. The dust content is 180mg/L, the temperature is 65℃, and the pressure is 0.65MPa.

Among them, the main pollutant characteristics data of high temperature gas water and low temperature gas water are shown in Table 1 and Table 2, respectively.

.

Wherein, the transformed high-temperature condensate and gasification dust-containing gasification water are first degassed by the medium pressure flasher 1, and then enter the first vacuum flasher 2 together with the gasification low pressure gas water and the gasification start-up gas water to remove the dissolved gas in depth. The flashing temperature of the flasher 1 is 144°C, the pressure is 0.4MPa, the flashing temperature of the first vacuum flasher 2 is 84.8°C, and the vacuum degree is 50kPa; the gas water after de-dissolved gas is added according to 1 ton of gas water The proportion of 3g flocculant is added into the flocculant and mixed and then sent to the settling tank 3. The solid material settled at the bottom of the settling tank 3 is dehydrated by the filter press 12 to make a mud cake with a water content of 22%, and the filtrate enters the filtrate tank 13. Then return to the settling tank 3, and the gas water in the upper part of the settling tank 3 is sent to the gas water tank 4 as the washing water of the gasification low-pressure gas water, which is reused for the coal lock gas washing equipment and the driving gas washing equipment, and the biochemical treatment of the remaining degassing water. equipment. The flash steam flashed from the medium pressure flasher 1 is injected from the bottom of the deacidification tower 5 as a heat source of the deacidification tower 5, and the acid gas in the flash steam is removed at the same time. The transformed low-temperature condensate is first removed from the dissolved gas by the second vacuum flasher 8, and then sent to the waste heat boiler for use as supplementary water after pressurization and heat exchange. The condensed liquid condensed by the device 9 and the third vacuum flash separator 10 is sent from the top of the deacidification tower 5 to the deacidification tower 5 for deacidification, the deacidification gas desulfurization recovery equipment, and the gas water after the deacidification enters the ammonia distillation tower 7 After steaming ammonia, it is reused as washing water for the crude gas washing equipment, and the produced ammonia water/liquid ammonia is recycled and reused.

The operating pressure of the entire gas-water separation and reuse process is a micro-positive pressure operation greater than 0.2kPa. The top of the settling tank 3 and the gas-water tank 4 is continuously supplied with an inert gas as a protective gas to ensure that the system pressure is greater than 0.2kPa micro-positive pressure , so that VOCs and odors in the system can be collected in a centralized manner, by-product steam from incineration or RTO. The function of continuously feeding inert gas into the sedimentation tank 3 and the gas water tank 4 to seal their tops is mainly to prevent the negative pressure of the sedimentation tank 3 and the gas water tank 4 from inhaling air from their breathing valves to keep the tank slightly positive. The normal pressure setting value of the sealing valve should be 0.2kPa, and the intersection with the set pressure of the breathing valve, single exhalation valve or control valve should be avoided to generate unnecessary inert gas circulation and high operating costs.

The pressure gasification of anthracite crushed coal in the embodiment of the present invention utilizes the characteristics of low oil content, low COD content and low dust content in the gas water. In this embodiment, anthracite is used for pressurized gasification. Since anthracite has low water content, generally the total water content is below 10%, the volatile matter is less than 10%, the carbon content is high, the coal ash melting point is high, and the ash content is high. The true density is generally 1.4-1.8g/cm ³ , the mineral content of anthracite is high, and the true density is 1.8-1.9g/cm ³ . In addition, the thermal stability of anthracite is high, and it is not easy to powder into the gasifier. The amount of coal dust brought out of the gasifier is small, and the density difference between the coal dust particles and the gas water is about large, so the coal dust is easier to separate, and the residence time of the dusty gas water separator can be shortened.

At present, the water quality requirements for entering the biochemical treatment equipment are generally COD less than or equal to 3500mg/L, pH between 8.0-9.0, oil content less than or equal to 50mg/L, and BOD not more than 1100mg/L. The current gas water effluent and reuse indicators are shown in Table 3. The oil content of the gas water removed from the biochemical treatment equipment is high, and it needs to be oxidized before entering the biochemical treatment to reduce the COD content.

.

After being processed by the method provided in the embodiment of the present invention, the ammonia content and COD content of the gas water going to the biochemical treatment equipment and the gas water for reuse of the gas water are far less than those obtained by the current gas water separation and recovery system and method. gas water.

Example 2.

The crushed coal in this example is Jincheng anthracite with a water content of 6%. The coal sample is crushed and sieved to obtain a coal sample with a particle size of 5-50 mm, which is loaded into the crushed coal pressurized gasifier for crushed coal pressurized gasification , the gasification pressure is 5.0MPa, and the gasification temperature is 1250℃. The crude gas produced by gasification is divided into high temperature gas water and low temperature gas water according to the dust content, temperature and pressure in the water during washing. Temperature and pressure are divided into high temperature condensate and gasification dust-containing gasification water, low temperature gas water is divided into low temperature condensate conversion, low pressure gasification gas water and low pressure driving gas water according to dust content, temperature and pressure. Different types of gas water are separated and reused separately. The whole process of separation and reuse of gas water is maintained at a slight positive pressure of more than 0.2kPa and protected by inert gas to ensure that VOCs and odors in the system can be centrally treated.

The dust content of the transformed high-temperature condensate obtained from the above coal samples processed by the gasification unit, the washing unit and the transformation unit is 1800 mg/L, the temperature is 158 °C, and the pressure is 5 MPa, and the dust content of the gasification dust-containing gasification water is 1985mg/L, temperature 196℃, pressure 5.0MPa. The dust content of the transformed low-temperature condensate is 48mg/L, the temperature is 70.5℃, and the pressure is 4.75MPa. The dust content of the low-pressure gasification gas water is 98mg/L, the temperature is 72℃, and the pressure is 0.6MPa. The dust content of water was 160 mg/L, the temperature was 75°C, and the pressure was 0.55 MPa.

Among them, the high-temperature condensate of the transformation and the gasification dust-containing gasification water are first degassed by the medium pressure flasher 1, and then enter the first vacuum flasher 2 together with the gasification low pressure gas water and the gasification start-up gas water to remove the dissolved gas in depth. The flash temperature of the evaporator 1 is 148°C, the pressure is 0.5MPa, the flash temperature of the first vacuum flasher 2 is 86°C, and the vacuum degree is 60kPa; the gas water after the de-dissolved gas is added with 4.5 ton of gas water according to 1 ton. The proportion of g flocculant is added into the flocculant and mixed and then sent to the settling tank 3. The solid material settled at the bottom of the settling tank 3 is dehydrated by the filter press 12 to make a mud cake with a water content of 28%, and the filtrate enters the filtrate tank 13. Then return to the settling tank 3, and the gas water in the upper part of the settling tank 3 is sent to the gas water tank 4 as the washing water of the gasification low-pressure gas water, which is reused for the coal lock gas washing equipment and the driving gas washing equipment, and the remaining degas water biochemical treatment equipment. . The flash steam flashed from the medium pressure flasher 1 is injected from the bottom of the deacidification tower 5 as a heat source of the deacidification tower 5, and the acid gas in the flash steam is removed at the same time. The transformed low-temperature condensate is first removed from the dissolved gas by the second vacuum flasher 8, and then sent to the waste heat boiler for use as supplementary water after pressurization and heat exchange. The condensed liquid condensed by the device 9 and the third vacuum flash separator 10 is sent to the deacidification from the top of the deacidification tower 5, and the deacidification gas desulfurization recovery equipment, and the gas water after the deacidification enters the ammonia distillation tower 7 and is used as the ammonia distillation tower. The washing water is reused by the crude gas washing equipment, and the ammonia water/liquid ammonia produced is recycled and reused.

The operating pressure of the entire gas-water separation and reuse process is operated with a slight positive pressure greater than 0.2kPa. The top of the sedimentation tank 3 and the gas-water tank 4 is continuously supplied with an inert gas as a protective gas to ensure that the system pressure is greater than 0.2kPa. The slight positive pressure operation, the system Middle VOCs and odors can be collected in a centralized manner, by-product steam from incineration or RTO. The function of continuously feeding inert gas into the sedimentation tank 3 and the gas water tank 4 to seal their tops is mainly to prevent the negative pressure of the sedimentation tank 3 and the gas water tank 4 from inhaling air from their breathing valves to keep the tank slightly positive. The normal pressure setting value of the sealing valve should be 0.2kPa, and the intersection with the set pressure of the breathing valve, single exhalation valve or control valve should be avoided, resulting in unnecessary inert gas circulation and high operating costs.

Example 3.

The crushed coal in this example is Yangquan anthracite with a water content of 8%. The coal sample is crushed and sieved to obtain a coal sample with a particle size of 5-50 mm, which is loaded into the crushed coal pressurized gasifier for crushed coal pressurized gasification , the gasification pressure is 7.0MPa, and the gasification temperature is 1350℃. The crude gas produced by gasification is divided into high temperature gas water and low temperature gas water according to the dust content, temperature and pressure in the water during washing, and the high temperature gas water is based on the dust content. , temperature and pressure are divided into transformation of high temperature condensate and gasification of dust-containing gasification water, low temperature gas water is divided into transformation of low temperature condensate, low pressure gasification gas water and low pressure driving gas water according to dust content, temperature and pressure. Different types of gas water are separated and reused separately. The whole process of separation and reuse of gas water is maintained at a slight positive pressure of more than 0.2kPa and protected by inert gas to ensure that VOCs and odors in the system can be centrally treated.

The dust content of the transformed high-temperature condensate obtained from the above-mentioned coal samples processed by the gasification unit, the washing unit and the transformation unit is 1785 mg/L, the temperature is 170 °C, and the pressure is 7 MPa, and the dust content of the gasification dust-containing gasification water is 1650 mg/L, temperature of 197°C, and pressure of 7.0 MPa. The dust content of the transformed low-temperature condensate is 35mg/L, the temperature is 67.5°C, and the pressure is 3.75MP. The dust content of the low-pressure gasification gas water is 65mg/L, the temperature is 70°C, and the pressure is 0.5MPa. The dust content of water was 150 mg/L, the temperature was 60°C, and the pressure was 0.5 MPa.

Among them, the high-temperature condensate of the transformation and the gasification dust-containing gasification water are first degassed by the medium pressure flasher 1, and then enter the first vacuum flasher 2 together with the gasification low pressure gas water and the gasification start-up gas water to remove the dissolved gas in depth. The flash temperature of the evaporator 1 is 144°C, the pressure is 0.4MPa, the flash temperature of the first vacuum flasher 2 is 84.8°C, and the vacuum degree is 50kPa; the gas water after de-dissolved gas is added with 4.8 ton of gas water according to 1 ton of gas water. The proportion of g flocculant is added into the flocculant and mixed and then sent to the settling tank 3. The solid material settled at the bottom of the settling tank 3 is dehydrated by the filter press 12 to make a mud cake with a water content of 28%, and the filtrate enters the filtrate tank 13. Then return to the settling tank 3, and the gas water in the upper part of the settling tank 3 is sent to the gas water tank 4 as the washing water of the gasification low-pressure gas water, which is reused for the coal lock gas washing equipment and the driving gas washing equipment, and the remaining degas water biochemical treatment equipment. . The flash steam flashed from the medium pressure flasher 1 is injected from the bottom of the deacidification tower 5 as a heat source of the deacidification tower 5, and the acid gas in the flash steam is removed at the same time. The transformed low-temperature condensate is first removed from the dissolved gas by the second vacuum flasher 8, and then sent to the waste heat boiler for use as supplementary water after pressurization and heat exchange. The condensed liquid condensed by the device 9 and the third vacuum flash separator 10 is sent to the deacidification from the top of the deacidification tower 5, and the deacidification gas desulfurization recovery equipment, and the gas water after the deacidification enters the ammonia distillation tower 7 and is used as the ammonia distillation tower. The washing water is reused by the crude gas washing equipment, and the ammonia water/liquid ammonia produced is recycled and reused.

The operating pressure of the entire gas-water separation and reuse process is operated with a slight positive pressure greater than 0.2kPa. The top of the sedimentation tank 3 and the gas-water tank 4 is continuously supplied with an inert gas as a protective gas to ensure that the system pressure is greater than 0.2kPa. The slight positive pressure operation, the system Middle VOCs and odors can be collected in a centralized manner, by-product steam from incineration or RTO. Settling tank 3 and gas water tank 4 continue to pass inert gas to seal their tops to prevent negative pressure in sedimentation tank 3 and gas water tank 4 and inhale air from their breathing valves to maintain a slight positive pressure in the tank , the normal pressure setting value of the sealing valve should be 0.2kPa, and the intersection with the set pressure of the breathing valve, single exhalation valve or control valve should be avoided, resulting in unnecessary inert gas circulation and high operating costs.

Example 4.

The crushed coal in this example is semi-coke with a water content of 8%. The coal sample is crushed and sieved to obtain a coal sample with a particle size of 5-50 mm, which is loaded into a crushed coal pressurized gasifier for crushed coal pressurized gasification , the gasification pressure is 3MPa, and the gasification temperature is 1250℃. The crude gas produced by gasification is divided into high temperature gas water and low temperature gas water according to the dust content, temperature and pressure in the water during washing. Temperature and pressure are divided into high temperature condensate and gasification dust-containing gasification water, low temperature gas water is divided into low temperature condensate conversion, low pressure gasification gas water and low pressure driving gas water according to dust content, temperature and pressure. Different types of gas water are separated and reused separately. The whole process of separation and reuse of gas water is maintained at a slight positive pressure of more than 0.2kPa and protected by inert gas to ensure that VOCs and odors in the system can be centrally treated.

The dust content of the transformed high-temperature condensate obtained by the above-mentioned coal samples processed by the gasification unit, the washing unit and the transformation unit is 980 mg/L, the temperature is 155 °C, and the pressure is 3 MPa, and the dust content of the gasification dust-containing gasification water is 1250 mg/L, temperature of 185°C, and pressure of 3.0 MPa. The dust content of the transformed low-temperature condensate is 30mg/L, the temperature is 66°C, and the pressure is 3MPa. The dust content of the low-pressure gasification gas water is 65mg/L, the temperature is 75°C, and the pressure is 0.5MPa. The dust content is 120mg/L, the temperature is 60℃, and the pressure is 0.5MPa.

Among them, the high-temperature condensate of the transformation and the gasification dust-containing gasification water are first degassed by the medium pressure flasher 1, and then enter the first vacuum flasher 2 together with the gasification low pressure gas water and the gasification start-up gas water to remove the dissolved gas in depth. The flash temperature of the evaporator 1 is 142°C, the pressure is 0.4MPa, the flash temperature of the first vacuum flasher 2 is 82°C, and the vacuum degree is 50kPa; the gas water after the de-dissolved gas is added 3g according to 1 ton of gas water The proportion of the flocculant is added to the flocculant and mixed and then sent to the settling tank 3. The solid material settled at the bottom of the settling tank 3 is dehydrated by the filter press 12 to make a mud cake with a water content of 23%, and the filtrate enters the filtrate tank 13. Return to the settling tank 3, the gas water in the upper part of the settling tank 3 is sent to the gas water tank 4 as the washing water for gasification of low-pressure gas water, which is reused for the coal lock gas washing equipment and the driving gas washing equipment, and the remaining gas water is removed from the biochemical treatment equipment. The flash steam flashed from the medium pressure flasher 1 is injected from the bottom of the deacidification tower 5 as a heat source of the deacidification tower 5, and the acid gas in the flash steam is removed at the same time. The transformed low-temperature condensate is first removed from the dissolved gas by the second vacuum flasher 8, and then sent to the waste heat boiler for use as supplementary water after pressurization and heat exchange. The condensed liquid condensed by the device 9 and the third vacuum flash separator 10 is sent to the deacidification from the top of the deacidification tower 5, and the deacidification gas desulfurization recovery equipment, and the gas water after the deacidification enters the ammonia distillation tower 7 and is used as the ammonia distillation tower. The washing water is reused by the crude gas washing equipment, and the ammonia water/liquid ammonia produced is recycled and reused.

The operating pressure of the entire gas-water separation and reuse process is operated with a slight positive pressure greater than 0.2kPa. The top of the sedimentation tank 3 and the gas-water tank 4 is continuously supplied with an inert gas as a protective gas to ensure that the system pressure is greater than 0.2kPa. The slight positive pressure operation, the system Middle VOCs and odors can be collected in a centralized manner, by-product steam from incineration or RTO. Settling tank 3 and gas water tank 4 continue to pass inert gas to seal their tops to prevent negative pressure in sedimentation tank 3 and gas water tank 4 and inhale air from their breathing valves to maintain a slight positive pressure in the tank , the normal pressure of the sealing valve is set to 0.4kPa, and the intersection with the set pressure of the breathing valve and the single exhalation valve or the control valve should be avoided, resulting in unnecessary inert gas circulation and high operating costs.

Example 5.

The crushed coal in this embodiment is coke with a water content of 5%. The coal sample is crushed and sieved to obtain a coal sample with a particle size of 5-50 mm, which is loaded into a crushed coal pressurized gasifier for crushed coal pressurized gasification. The gasification pressure is 3MPa, and the gasification temperature is 1250℃. The crude gas produced by gasification is divided into high temperature gas water and low temperature gas water according to the dust content, temperature and pressure in the water during washing. And pressure is divided into high temperature condensate transformation and gasification dust-containing gasification water, low temperature gas water is divided into transformation low temperature condensate, low pressure gasification gas water and low pressure driving gas water according to dust content, temperature and pressure. Different types of gas water are separated and reused separately. The whole process of separation and reuse of gas water is maintained at a slight positive pressure of more than 0.2kPa and protected by inert gas to ensure that VOCs and odors in the system can be centrally treated.

The dust content of the transformed high-temperature condensate obtained from the above coal samples processed by the gasification unit, the washing unit and the transformation unit is 1200 mg/L, the temperature is 164 °C, and the pressure is 3 MPa, and the dust content of the gasification dust-containing gasification water is 1800 mg/L, temperature of 185°C, and pressure of 3.0 MPa. The dust content of the transformed low-temperature condensate is 46mg/L, the temperature is 66°C, and the pressure is 3.0MPa. The dust content of the low-pressure gasification gas water is 84mg/L, the temperature is 75°C, and the pressure is 0.5MPa. The dust content of water was 170 mg/L, the temperature was 78°C, and the pressure was 0.7 MPa.

Among them, the high-temperature condensate of the transformation and the gasification dust-containing gasification water are first degassed by the medium pressure flasher 1, and then enter the first vacuum flasher 2 together with the gasification low pressure gas water and the gasification start-up gas water to remove the dissolved gas in depth. The flash temperature of the evaporator 1 is 142°C, the pressure is 0.4MPa, the flash temperature of the first vacuum flasher 2 is 82°C, and the vacuum degree is 50kPa; the gas water after the de-dissolved gas is added 3g according to 1 ton of gas water The proportion of flocculant is added to the flocculant and mixed and then sent to the sedimentation tank 3. The solid material settled at the bottom of the sedimentation tank 3 is dehydrated by the filter press 12 to make a mud cake with a water content of 22%, and the filtrate enters the filtrate tank 13. Return to the settling tank 3, the gas water in the upper part of the settling tank 3 is sent to the gas water tank 4 as the washing water for gasification of low-pressure gas water, which is reused for the coal lock gas washing equipment and the driving gas washing equipment, and the remaining gas water is removed from the biochemical treatment equipment. The flash steam flashed from the medium pressure flasher 1 is injected from the bottom of the deacidification tower 5 as a heat source of the deacidification tower 5, and the acid gas in the flash steam is removed at the same time. The transformed low-temperature condensate is first removed from the dissolved gas by the second vacuum flasher 8, and then sent to the waste heat boiler for use as supplementary water after pressurization and heat exchange. The condensed liquid condensed by the device 9 and the third vacuum flash separator 10 is sent to the deacidification from the top of the deacidification tower 5, and the deacidification gas desulfurization recovery equipment, and the gas water after the deacidification enters the ammonia distillation tower 7 and is used as the ammonia distillation tower. The washing water is reused by the crude gas washing equipment, and the ammonia water/liquid ammonia produced is recycled and reused.

The operating pressure of the entire gas-water separation and reuse process is operated with a slight positive pressure greater than 0.2kPa. The top of the sedimentation tank 3 and the gas-water tank 4 is continuously supplied with an inert gas as a protective gas to ensure that the system pressure is greater than 0.2kPa. The slight positive pressure operation, the system Middle VOCs and odors can be collected in a centralized manner, by-product steam from incineration or RTO. Settling tank 3 and gas water tank 4 continue to pass inert gas to seal their tops to prevent negative pressure in sedimentation tank 3 and gas water tank 4 and inhale air from their breathing valves to maintain a slight positive pressure in the tank , the normal pressure of the sealing valve is set to 0.5kPa, and the intersection with the set pressure of the breathing valve and the single exhalation valve or the control valve should be avoided, resulting in unnecessary inert gas circulation and high operating costs.

It can be understood that the above embodiments are only exemplary embodiments adopted to illustrate the principle of the present invention, but the present invention is not limited thereto. For those skilled in the art, without departing from the spirit and essence of the present invention, various modifications and improvements can be made, and these modifications and improvements are also regarded as the protection scope of the present invention.

Claims

A crushed coal pressurized gasification gas water separation and reuse system capable of recycling sewage, characterized in that it comprises a medium pressure flasher (1), a first vacuum flasher (2), a settling tank (3), a gas Water tank (4), deacidification tower (5), first vacuum flash separator (6), ammonia distillation tower (7), second vacuum flasher (8), second vacuum flash separator (9) , a third vacuum flash separator (10), a flocculant tank (11), a filter press (12), a filtrate tank (13), a number of water pumps and pipelines, wherein:

The first water inlet of the medium-pressure flasher (1) is connected to the high-temperature condensate transformation pipeline, the second water inlet of the medium-pressure flasher (1) is connected to the gasification dust-containing gasification water pipeline, and the medium-pressure flasher (1) The water outlet of (1) is connected to the first water inlet of the first vacuum flasher (2) through the pipeline, the second water inlet of the first vacuum flasher (2) is connected to the low-pressure gasification gas water pipeline, and the first vacuum flasher (2) The third water inlet of the flasher (2) is connected to the low-pressure start-up gas water pipeline, and the water outlet of the first vacuum flasher (2) is connected to the water inlet of the settling tank (3) through the pipeline and the water pump, and the settling tank (3) The water outlet of the filter press (12) is connected to the water inlet of the filter press (12) through a pipeline and a water pump, the water outlet of the filter press (12) is connected to the water inlet of the filtrate tank (13) through a pipeline, and the outlet of the filtrate tank (13) The water inlet is connected with the water inlet of the settling tank (3) through pipelines and a water pump, and the water inlet of the settling tank (3) is also connected with the discharge opening of the flocculant tank (11) through pipelines. The gas water in the settling tank (3) The outlet is connected with the gas water inlet of the gas water tank (4) through the pipeline, and the gas water outlet of the gas water tank (4) is connected with the gas water biochemical treatment equipment and the gas water reuse equipment through the pipeline and the water pump. (3) and the top of the gas water tank (4) are hermetically connected with the inert gas pipeline; the air outlet of the medium pressure flasher (1) is connected to the air inlet of the deacidification tower (5) through the pipeline, and the second vacuum flasher The water inlet of (8) is connected with the transformation low temperature condensate pipeline, the water outlet of the second vacuum flasher (8) is connected with the water inlet of the heat exchanger connected to the waste heat boiler through the pipeline and the water pump, and the deacidification tower (5) The water outlet of the first vacuum flasher (2) is connected to the water inlet of the ammonia distillation tower (7) through the pipeline and the water pump, and the water outlet of the ammonia distillation tower (7) is connected to the crude gas washing equipment; the air outlet of the first vacuum flasher (2) is connected through the pipeline is connected with the air inlet of the first vacuum flash separator (6), and the air outlet of the first vacuum flash separator (6) is connected with the air inlet of the third vacuum flash separator (10) through a pipeline, The water outlet of the first vacuum flash separator (6) is connected to the water inlet of the deacidification tower (5) through a pipeline and a water pump; the gas outlet of the second vacuum flasher (8) is connected to the second vacuum flash through a pipeline The air inlet of the separator (9) is connected, and the air outlet of the second vacuum flash separator (9) is connected to the air inlet of the third vacuum flash separator (10) through a pipeline, and the second vacuum flash separation The water outlet of the device (9) is connected to the water inlet of the deacidification tower (5) through a pipeline, and the water outlet of the third vacuum flash separator (10) is connected to the water inlet of the deacidification tower (5) through a pipeline.
The crushed coal pressurized gasification gas water separation and reuse system according to claim 1, characterized in that, further comprising an oil collecting float (14) and an oil tank (15), the oil collecting float (14) is arranged inside the gas water tank (4), and the bottom of the oil collecting float (14) is connected with the oil tank (15) through a hose.
The pulverized coal pressurized gasification gas water separation and reuse system according to claim 1 or 2, characterized in that, the breathing gas at the top of the gas water tank (4) and the settling tank (3) A cooling water jacket (16) is arranged outside the discharge pipe.
A method for water separation and reuse of crushed coal pressurized gasification gas that can be reused by sewage, characterized in that it comprises the following steps:

S1, after the transformed high-temperature condensate and the gasification dust-containing gasification water are degassed by the medium pressure flasher (1), they enter the first vacuum flasher (2) together with the gasification low pressure gas water and the gasification start-up gas water and enter the first vacuum flasher (2) in the first vacuum flasher (2). Dissolved gas is deeply removed from the vacuum flasher (2);

S2, the gas water after de-dissolved gas is mixed with the flocculant from the flocculant tank (11) and sent to the settling tank (3);

S3, the solid material settled at the bottom of the settling tank (3) is made into a mud cake through the filter press (12) pressure filtration dehydration, and the filtrate generated by the filter press dehydration enters the filtrate tank (13) and returns to the settling tank (3) again, The gas water in the upper part of the settling tank (3) is sent to the gas water tank (4), and a part of the gas water in the gas water tank (4) is used as the washing water for gasification of low-pressure gas water and is reused by the gas water reuse equipment, and the remaining gas Water to gas water biochemical treatment equipment;

S4, the flash steam flashed from the medium pressure flasher (1) is sprayed into the deacidification tower (5) from the bottom of the deacidification tower (5) as the heat source of the deacidification tower (5), and simultaneously the deacidification tower (5) is removed from the flash acid gas in vapour;

S5, the transformed low-temperature condensate is de-dissolved gas in the second vacuum flasher (8), and after the de-dissolved gas is removed, it is pressurized and heat-exchanged and sent to the waste heat boiler for use as supplementary water, so as to reduce the amount of degassed water biochemical treatment equipment amount of water;

S6, the condensate formed by the flashing of the first vacuum flasher (2) and the second vacuum flasher (8) respectively enters the first vacuum flasher (6), the second vacuum flasher (9) and the first vacuum flasher (9) The three vacuum flash separators (10) are used for vacuum flash separation, and the condensed particles are condensed through the first vacuum flash separator (6), the second vacuum flash separator (9) and the third vacuum flash separator (10). The condensate is sent from the top of the deacidification tower (5) to the deacidification tower (5) for deacidification;

S7, the deacidification gas desulfurization recovery equipment obtained by deacidification of the deacidification tower (5), the gas water after the deacidification enters the ammonia distillation tower (7), and the gas water after the ammonia distillation in the ammonia distillation tower (7) is used as washing The water is reused by the crude gas washing equipment, and the ammonia water/liquid ammonia produced in the ammonia distillation tower (7) is recycled and reused.
The method for separating and reusing crushed coal pressurized gasification gas with sewage reuse according to claim 4, wherein the transformed high-temperature condensate has a dust content of not more than 2000 mg/L and a temperature of 150- Gas water at 190°C and pressure of 3.0-7.0MPa; the gasification dust-containing gasification water is gas water with dust content not greater than 3000mg/L, temperature of 180-200°C, and pressure of 3.0-7.0MPa; The shift low-temperature condensate is gas water with a dust content of less than 50mg/L, a temperature of 40-80°C, and a pressure of 3.0-5.0MPa; the low-pressure gasification gas water is a gas water with a dust content of less than 100mg/L and a temperature of 60 -80°C gas water with pressure of 0.5-0.7MPa; the low-pressure start-up gas water is gas water with dust content less than 200mg/L, temperature of 60-80°C, and pressure of 0.5-0.7MPa.
The method for separating and reusing crushed coal pressurized gasification gas and water that can be reused with sewage according to claim 4, wherein the flash temperature of the medium-pressure flasher (1) is 140-160° C., pressure 0.4-0.5MPa.
The method for separating and reusing crushed coal pressurized gasification gas and water that can be reused with sewage according to claim 4, wherein the flash temperature of the first vacuum flasher (2) is 80-86°C, The degree of vacuum is 50-60kPa.
The method for separating and reusing the pressurized gasification gas water of crushed coal that can be reused by sewage according to claim 4, wherein the amount of the flocculant added is 3-5g of flocculant added to 1 ton of gas water.
The method for separating and reusing pulverized coal pressurized gasification gas water according to claim 4, wherein the top of the settling tank (3) and the gas water tank (4) is continuously fed with inert gas .