JP5512922B2 - Gas purification system and cleaning wastewater treatment method in the system - Google Patents

Description

  The present invention relates to a gas purification system and a cleaning wastewater treatment method in the system, and more specifically, a low-temperature dust collection facility for dusting gasification gas generated from a gasification facility, and a gasification gas removed by the low-temperature dust collection facility. The present invention relates to a gas purification system having a gas cleaning facility for cleaning and a wastewater treatment facility for processing cleaning wastewater discharged from the gas cleaning facility, and a cleaning wastewater treatment method in the system.

  Gasification technology has attracted attention as a technology for converting energy efficiently from waste (organic waste) containing organic matter such as wood chips and sewage sludge and biomass fuel. It is possible to generate power by burning the gas generated by gasification in an internal combustion engine such as a gas engine or a gas turbine, and the power generation efficiency is to directly burn fuel to generate steam. It has a feature of higher efficiency by a boiler power generation system that generates power by using a power source (Patent Document 1).

  However, the product gas generated from the gasifier contains harmful corrosive substances and pollutants such as dust, tar, ammonia, dioxins, heavy metals and hydrogen chloride. Problems such as clogging and corrosion, and an increase in gas processing equipment after the power generation equipment arise.

  Therefore, a low-temperature dust collection facility that removes the gasified gas generated from the gasification furnace, a gas cleaning facility that cleans the gasification gas removed by the low-temperature dust collection facility, and a cleaning wastewater that is discharged from the gas cleaning facility. Has already been invented by the present applicant (Patent Document 2).

JP 2003-65084 A JP 2007-63539 A

  In the case of the technique of Patent Document 2 above, the tar content that could not be adsorbed by the low temperature dust collecting equipment is mixed with the water phase by the gas washing equipment, and when discharged as it is, it is organic such as COD (chemical oxygen demand). An increase in the amount of water is a problem that causes the water quality to deteriorate.

  In addition, when a distillation tower or a stripping tower equipped with a condenser is used for cleaning and wastewater treatment of the gas cleaning equipment, if the tar content is concentrated in the upper part of the distillation tower or the stripping tower and adheres to the condenser, it causes operating trouble. In order to avoid this, maintenance such as cleaning is required in a short period of time.

  In addition, the solid content that has not been collected by the low-temperature dust collection facility is a problem that deteriorates the water quality of the water when it is mixed into the water phase by the gas washing facility and discharged as it is. In particular, underwater DXN (dioxins) is mostly adhered to the SS component, and therefore, the concentration of DXN in water becomes a problem unless the SS component is removed.

  Therefore, in view of the above-mentioned problems of the prior art, the object of the present invention is to clean the gasified gas removed by the low-temperature dust collection equipment and the low-temperature dust collection equipment for removing the gasification gas generated from the gasification equipment. A gas purification system having a gas cleaning facility and a wastewater treatment facility for treating cleaning wastewater discharged from the gas cleaning facility, which removes suspended matter SS from the cleaning wastewater and exits the wastewater treatment facility An object of the present invention is to provide a gas purification system capable of removing a tar content from a gas. Another object of the present invention is to provide a cleaning wastewater treatment method in the system.

The above-mentioned subject is achieved by the invention described in each claim. That is, the gas purification system according to the present invention includes a low-temperature dust collection facility that removes gasification gas generated from the gasification facility, a gas cleaning facility that cleans the gasification gas removed by the low-temperature dust collection facility, A gas purification system having a wastewater treatment facility for treating cleaning wastewater discharged from a gas cleaning facility,
A condenser for separating a liquid component from the ammonia-containing gas discharged from the wastewater treatment facility;
And a separator for separating the tar component from the liquid component discharged from the condenser.

  According to this configuration, since the liquid component can be separated from the ammonia-containing gas discharged from the wastewater treatment facility and the tar component can be separated from the liquid component, the tar component is not discharged out of the system. There is no deterioration in the quality of the discharged water. Further, the tar content is concentrated in the upper part of the distillation tower or the stripping tower, and does not adhere to the condenser to cause operational troubles, and maintenance such as cleaning is greatly reduced.

  Moreover, in this invention, it is preferable to have a supply means which supplies the tar component isolate | separated with the separator to the said gasification installation.

  According to this configuration, since the separated tar component can be supplied to the gasification facility, the tar system is not separately required, and the entire system is simplified. Examples of the supply method include a supply method using a blowing nozzle and a method of supplying the fuel mixed with fuel, and a method of spraying in the vicinity of an air supply port using a blowing nozzle is particularly preferable.

In addition, another gas purification system according to the present invention includes a low temperature dust collection facility for removing gasified gas generated from the gasification facility, and a gas cleaning facility for cleaning the gasification gas removed by the low temperature dust collection facility. , A gas purification system having a wastewater treatment facility for treating cleaning wastewater discharged from the gas cleaning facility,
When the treated water discharged from the wastewater treatment facility is discharged out of the system, it has a solid-liquid separator that separates the suspended solid SS from the treated water.

  According to this configuration, since the suspended matter SS can be separated from the treated water discharged outside the system, the suspended matter SS is not discharged outside the system, and the quality of the discharged water is not deteriorated. .

  Moreover, in this invention, it is preferable to have further a supply means to supply the floating substance SS isolate | separated with the solid-liquid separator to the said gasification installation.

  According to this configuration, since the suspended solid SS separated by the solid-liquid separator can be supplied to the gasification facility, no separate processing for SS is necessary, and DXN adhering to SS is not removed. Since it can be decomposed | disassembled by the temperature environment of gasification equipment, it is preferable.

In addition, another gas purification system according to the present invention includes a low temperature dust collection facility for removing gasified gas generated from the gasification facility, and a gas cleaning facility for cleaning the gasification gas removed by the low temperature dust collection facility. , A gas purification system having a wastewater treatment facility for treating cleaning wastewater discharged from the gas cleaning facility,
A condenser for separating a liquid component from the ammonia-containing gas discharged from the wastewater treatment facility;
A separator for separating a tar component from a liquid component discharged from the condenser;
And a solid-liquid separator that separates the suspended solid SS from the treated water when the treated water discharged from the wastewater treatment facility is discharged to the outside of the system.

  Further, in the present invention, supply means for supplying the tar component separated by the separator to the gasification facility, and supply means for supplying the suspended matter SS separated by the solid-liquid separator to the gasification facility, It is characterized by having.

  The operational effects of the gas purification system are the same as the operational effects described above.

Further, another cleaning wastewater treatment method according to the present invention includes a low-temperature dust collection facility that removes gasification gas generated from the gasification facility, and a gas cleaning facility that cleans the gasification gas removed by the low-temperature dust collection facility. And a waste water treatment method in a gas purification system having waste water treatment equipment for treating the waste water discharged from the gas washing equipment,
Separating liquid components from ammonia-containing gas discharged from the wastewater treatment facility,
Separating the tar component from the condensed liquid component;
The separated tar component is supplied to the gasification facility.

Further, another cleaning wastewater treatment method according to the present invention includes a low-temperature dust collection facility that removes gasification gas generated from the gasification facility, and a gas cleaning facility that cleans the gasification gas removed by the low-temperature dust collection facility. And a waste water treatment method in a gas purification system having waste water treatment equipment for treating the waste water discharged from the gas washing equipment,
When the treated water discharged from the wastewater treatment facility is discharged out of the system, the suspended matter SS is separated from the treated water,
The separated suspended matter SS is supplied to the gasification facility.

  The operational effects of the cleaning wastewater treatment method are the same as the operational effects of the gas purification system described above.

(Embodiment 1)
Embodiments of the present invention will be described in detail with reference to the drawings. FIG. 1 shows a schematic flow of a gas purification system according to an embodiment of the present invention.

  The gas purification system shown in FIG. 1 is a gas cooling system in which gasified gas generated from a gasification facility 18 such as a fluidized bed gasification furnace or a circulating fluidized bed gasification furnace is processed by a low temperature dust collector such as a bag filter. It is fed to the equipment 19 where it is cooled to about 200 ° C. or less by water spraying or heat exchange.

  The gasified gas cooled by the gas cooling facility 19 is sent to the low temperature dust collecting facility 20 through the pipe 25. In the middle, an adsorbent such as slaked lime or activated carbon powder is blown by a feeding device (not shown) in the vicinity of the inlet of the low-temperature dust collection facility 20. Therefore, harmful substances such as dioxins, tars, and heavy metals that may be contained in the gasification gas are adsorbed by the adsorbent that is blown in, collected by the low-temperature dust collection facility 20, and collected. . The dust collected by the low temperature dust collection equipment 20 is sent to the ash treatment equipment or carried out of the field and detoxified. The present invention is characterized by a method for removing a substance and a tar content that are not adsorbed by the adsorbent, and details thereof will be described later.

  The gasified gas discharged from the low temperature dust collection equipment 20 is supplied to the gas cleaning equipment A and cleaned. The gas cleaning equipment A includes a temperature reducing tower 21, an absorption tower 34, and the like, and these equipment absorb and remove corrosive substances, pollutants and the like in the gasification gas. Thereafter, the gasified gas is used in a gas utilization facility such as a gas engine or a gas turbine in the subsequent stage.

  Circulating water W4 circulating through the temperature reducing tower 21 is circulated between the absorption tower 34 while releasing heat in the heat exchanger 35. A portion of this dewarming tower circulating water W4 is withdrawn as discharged water W5 from the absorption tower 34 and supplied to the diffusion tower 33 through a heat exchanger 29 for increasing the thermal efficiency, and a carrier gas such as air. While Ga1 is being supplied, the vapor S is used as a heat source to be dissipated.

  The ammonia-containing gas that exits from the outlet of the stripping tower 33 is condensed by the heat exchanger 101 (corresponding to the condenser) with the cooling water supplied from the cooling tower C, and the ammonia-containing gas Ga2 is separated as a gas. The The liquid component condensed and separated is further sent to the separator 102, where it is separated into moisture Wr and tar component Tr. Examples of the separator 102 include, but are not limited to, a sedimentation separator based on a specific gravity difference. In the separator 102, the water Wr is circulated to the diffusion tower 33 by overflow. The tar component Tr is sent to the gasification facility 18 and supplied to the gasification facility 18 by the supply means 103. The supply unit 103 may be, for example, a blowing nozzle, but is not limited thereto, and may be a unit that supplies the fuel mixed with fuel.

  The ammonia-containing gas Ga2 can be used by being supplied to a denitration facility (not shown) disposed downstream of the gasification facility 18 or the gas utilization facility, or can be used for other purposes. The water W6 at the bottom of the stripping tower 33 is supplied again to the absorption tower 34 by the pump P, and a part thereof is withdrawn and discharged outside the system. The amount corresponds to the condensed water in the exhaust gas discharged from the low temperature dust collection facility 20.

  According to this embodiment, the tar component Tr is not discharged out of the system, and the quality of the discharged water is not deteriorated. Further, the tar component Tr is concentrated in the upper part of the distillation tower or the stripping tower, and does not adhere to the condenser to cause operational troubles, and maintenance such as cleaning is greatly reduced. Further, since the separated tar component Tr can be supplied to the gasification facility 18, the tar system Tr is not required to be separately processed, and the entire system is simplified.

(Embodiment 2)
Embodiments of the present invention will be described in detail with reference to the drawings. FIG. 2 shows a schematic flow of a gas purification system according to an embodiment of the present invention. The gas purification system of the present embodiment has a configuration in which the separator 102 and the supply means 103 are not provided in the gas purification system. Then, from the outlet of the diffusion tower 33, the water is condensed by the cooling water supplied from the cooling tower C in the heat exchanger, the gas Ga2 containing ammonia is separated as a gas, and the separated water is directly diffused. Sent to tower 33.

  The present embodiment is characterized in that the following processing is performed when part of the water W6 at the bottom of the diffusion tower 33 supplied again to the absorption tower 34 by the pump P is discharged out of the system. That is, when the treated water (water W6 at the bottom of the stripping tower 33) discharged from the stripping tower 33, which is a wastewater treatment facility, is discharged out of the system, it floats from the treated water (water W6 at the bottom of the stripping tower 33). The substance SS is separated, and the separated suspended substance SS is supplied to the gasification facility 18.

  When part of the water W6 supplied again to the absorption tower 34 by the pump P is discharged out of the system, it is sent to the solid-liquid separator 111, where the suspended matter SS is separated. The separated suspended matter SS is sent to the gasification facility 18 and supplied to the gasification facility 18 by the supply means 112. The solid-liquid separator 111 is exemplified by a filtration type separator, but is not limited thereto. The supply means 112 is exemplified by, for example, a belt conveyor, a rotary conveyor, or the like, and may be a means for supplying the fuel mixed with fuel.

(Embodiment 3)
The third embodiment is a gas purification system having both the features of the first and second embodiments. That is, the configuration includes the heat exchanger 101, the separator 102, and the supply unit 103 according to the first embodiment, and the solid-liquid separator 111 and the supply unit 112 according to the second embodiment.

(Another embodiment)
(1) The gas cleaning facility A is not limited to the above configuration, and may be configured from a temperature reducing tower, an acid cleaning tower, an alkali cleaning tower, or the like, or may be configured only by a temperature reducing tower.

  (2) The waste water treatment facility may be a distillation tower instead of a stripping tower.

  (3) In the above embodiment, examples using slaked lime and activated carbon as the adsorbent were given, but the adsorbent is not limited to these, and sodium bicarbonate and other sodium-based adsorbents can be used. Furthermore, these may be used alone or in combination.

  (4) Examples of gas utilization equipment applicable to the present invention include power generation equipment such as a gas engine and a gas turbine, and liquid fuel production equipment such as methanol production equipment.

  (5) Examples of the fuel that can be applied to the present invention include various solid fuels and industrial wastes in addition to various organic wastes.

Schematic flowchart showing a gas purification system according to an embodiment of the present invention. Schematic flowchart showing a gas purification system according to another embodiment of the present invention.

Explanation of symbols

18 Gasification gas equipment 20 Low temperature dust collection equipment 21 Temperature reduction tower 33 Radiation tower 34 Absorption tower 101 Heat exchanger 102 Separator 103 Supply means 111 Solid-liquid separator 112 Supply means A Gas cleaning equipment Ga1 Carrier gas Ga2 Ammonia containing gas

Claims (8)

Removing low-temperature dust collection equipment that removes gasification gas generated from gasification equipment and gasification gas removed by the low-temperature dust collection equipment into contact with the aqueous phase to remove harmful substances in the gasification gas A gas purification system having a gas cleaning facility for cleaning, and a waste water treatment facility for removing the harmful substances from the cleaning waste water containing the harmful substances discharged from the gas cleaning facility,
A condenser for separating a liquid component from the ammonia-containing gas discharged from the wastewater treatment facility;
And a separator for separating a tar component from a liquid component discharged from the condenser.   The gas purification system according to claim 1, further comprising supply means for supplying the tar component separated by the separator to the gasification facility. Removing low-temperature dust collection equipment that removes gasification gas generated from gasification equipment and gasification gas removed by the low-temperature dust collection equipment into contact with the aqueous phase to remove harmful substances in the gasification gas A gas purification system having a gas cleaning facility for cleaning, and a waste water treatment facility for removing the harmful substances from the cleaning waste water containing the harmful substances discharged from the gas cleaning facility,
A gas purification system having a solid-liquid separator that separates suspended matter SS from the treated water before the treated water discharged from the wastewater treatment facility is discharged out of the system.   The gas purification system according to claim 3, further comprising a supply unit configured to supply the suspended matter SS separated by the solid-liquid separator to the gasification facility. Removing low-temperature dust collection equipment that removes gasification gas generated from gasification equipment and gasification gas removed by the low-temperature dust collection equipment into contact with the aqueous phase to remove harmful substances in the gasification gas A gas purification system having a gas cleaning facility for cleaning, and a waste water treatment facility for removing the harmful substances from the cleaning waste water containing the harmful substances discharged from the gas cleaning facility,
A condenser for separating a liquid component from the ammonia-containing gas discharged from the wastewater treatment facility;
A separator for separating a tar component from a liquid component discharged from the condenser;
A gas purification system comprising: a solid-liquid separator that separates suspended solids SS from the treated water before the treated water discharged from the wastewater treatment facility is discharged out of the system. Supply means for supplying tar components separated by the separator to the gasification facility;
The gas purification system according to claim 5, further comprising supply means for supplying the suspended matter SS separated by the solid-liquid separator to the gasification facility. Removing low-temperature dust collection equipment that removes gasification gas generated from gasification equipment and gasification gas removed by the low-temperature dust collection equipment into contact with the aqueous phase to remove harmful substances in the gasification gas Washing wastewater treatment in a gas purification system having a gas washing facility for washing and a wastewater treatment facility for removing the harmful substances from the washing wastewater containing the harmful substances discharged from the gas washing facility A method,
Separating liquid components from ammonia-containing gas discharged from the wastewater treatment facility,
Separating the tar component from the condensed liquid component;
A cleaning wastewater treatment method, wherein the separated tar component is supplied to the gasification facility. Removing low-temperature dust collection equipment that removes gasification gas generated from gasification equipment and gasification gas removed by the low-temperature dust collection equipment into contact with the aqueous phase to remove harmful substances in the gasification gas Washing wastewater treatment in a gas purification system having a gas washing facility for washing and a wastewater treatment facility for removing the harmful substances from the washing wastewater containing the harmful substances discharged from the gas washing facility A method,
Before releasing the treated water discharged from the wastewater treatment facility to the outside of the system, the suspended matter SS is separated from the treated water,
A cleaning wastewater treatment method, wherein the separated suspended matter SS is supplied to the gasification facility.

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