WO2015076052A1 - 抽出分離方法 - Google Patents
抽出分離方法 Download PDFInfo
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- WO2015076052A1 WO2015076052A1 PCT/JP2014/078150 JP2014078150W WO2015076052A1 WO 2015076052 A1 WO2015076052 A1 WO 2015076052A1 JP 2014078150 W JP2014078150 W JP 2014078150W WO 2015076052 A1 WO2015076052 A1 WO 2015076052A1
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- extraction
- fluid
- raw material
- separation
- extractant
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B01—PHYSICAL OR CHEMICAL PROCESSES OR APPARATUS IN GENERAL
- B01D—SEPARATION
- B01D11/00—Solvent extraction
- B01D11/04—Solvent extraction of solutions which are liquid
- B01D11/0446—Juxtaposition of mixers-settlers
- B01D11/0453—Juxtaposition of mixers-settlers with narrow passages limited by plates, walls, e.g. helically coiled tubes
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B01—PHYSICAL OR CHEMICAL PROCESSES OR APPARATUS IN GENERAL
- B01D—SEPARATION
- B01D11/00—Solvent extraction
- B01D11/04—Solvent extraction of solutions which are liquid
-
- B—PERFORMING OPERATIONS; TRANSPORTING
- B01—PHYSICAL OR CHEMICAL PROCESSES OR APPARATUS IN GENERAL
- B01D—SEPARATION
- B01D11/00—Solvent extraction
- B01D11/04—Solvent extraction of solutions which are liquid
- B01D11/0446—Juxtaposition of mixers-settlers
-
- B—PERFORMING OPERATIONS; TRANSPORTING
- B01—PHYSICAL OR CHEMICAL PROCESSES OR APPARATUS IN GENERAL
- B01D—SEPARATION
- B01D11/00—Solvent extraction
- B01D11/04—Solvent extraction of solutions which are liquid
- B01D11/0488—Flow sheets
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B01—PHYSICAL OR CHEMICAL PROCESSES OR APPARATUS IN GENERAL
- B01D—SEPARATION
- B01D11/00—Solvent extraction
- B01D11/04—Solvent extraction of solutions which are liquid
- B01D11/0496—Solvent extraction of solutions which are liquid by extraction in microfluidic devices
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B01—PHYSICAL OR CHEMICAL PROCESSES OR APPARATUS IN GENERAL
- B01J—CHEMICAL OR PHYSICAL PROCESSES, e.g. CATALYSIS OR COLLOID CHEMISTRY; THEIR RELEVANT APPARATUS
- B01J19/00—Chemical, physical or physico-chemical processes in general; Their relevant apparatus
-
- B—PERFORMING OPERATIONS; TRANSPORTING
- B01—PHYSICAL OR CHEMICAL PROCESSES OR APPARATUS IN GENERAL
- B01D—SEPARATION
- B01D11/00—Solvent extraction
- B01D2011/002—Counter-current extraction
-
- B—PERFORMING OPERATIONS; TRANSPORTING
- B01—PHYSICAL OR CHEMICAL PROCESSES OR APPARATUS IN GENERAL
- B01D—SEPARATION
- B01D11/00—Solvent extraction
- B01D2011/005—Co-current extraction
Definitions
- the present invention relates to an extraction and separation method for extracting and separating a specific component from a raw material fluid.
- Patent Document 1 discloses an example of such an extraction / separation method.
- an apparatus including a flow channel structure in which a large number of flow channels are provided is used for extracting and separating a specific component (extraction target) from a raw material fluid (extracted fluid).
- the raw material fluid and the extractant are flowed in contact with each other, and the specific component is extracted from the raw material fluid to the extractant in the flow process.
- a separation header is attached to the outer surface of the flow channel structure.
- the outlet of the upstream channel provided in the channel structure and the inlet of the downstream channel communicate with the internal space of the separation header.
- the mixed fluid of the raw material fluid and the extractant that has flowed through the upstream flow path is discharged from the outlet of the flow path to the internal space of the separation header.
- the mixed fluid discharged into the internal space of the separation header is separated into the raw material fluid and the extractant in the internal space due to the specific gravity difference.
- the separated raw material fluid is introduced into the downstream flow path to further extract the specific component.
- An object of the present invention is to reduce the processing time required for extracting and separating a specific component from a raw material fluid while downsizing an extraction apparatus.
- An extraction / separation method is a method for extracting and separating a specific component from a raw material fluid, wherein the specific component is extracted from the raw material fluid using an extraction device including a plurality of stages of extraction units connected in sequence.
- An extraction / separation step for extracting and separating components wherein the extraction / separation step circulates in a state where a raw material fluid and an extractant having a specific gravity difference with respect to the raw material fluid are in contact with each other in the extraction section of each stage Extracting the specific component from the raw material fluid into the extract, and introducing at least a part of the fluid discharged from the extractor into the extractor in the next stage in a state where the raw material fluid and the extract are mixed
- the extraction / separation method according to the first embodiment of the present invention is a method for extracting and separating a specific component from a raw material fluid using the extraction / separation apparatus 1.
- an extraction / separation apparatus 1 used in the extraction / separation method according to the first embodiment will be described with reference to FIGS.
- FIG. 1 schematically shows the overall configuration of the extraction / separation apparatus 1.
- the extraction / separation apparatus 1 is configured to perform a five-stage extraction process of specific components from a raw material fluid, and to perform a separation process that separates the fluid after the extraction process into a raw material fluid and an extractant.
- the extraction / separation apparatus 1 is configured to perform extraction using an extractant having a specific gravity smaller than that of the raw material fluid.
- the extraction / separation apparatus 1 includes a raw material supply pump 2a, an extractant supply pump 2b, an extraction apparatus 3 having first to fifth extraction units 4 to 8 connected in sequence, a settler 9, and first to fifth Inflow amount adjustment valves 10 to 14, first to fourth discharge amount adjustment valves 15 to 18, a final discharge amount adjustment valve 19, and a liquid level gauge 20 are provided.
- the raw material supply pump 2 a is a pump that supplies (sends) a raw material fluid containing a specific component to the first extraction unit 4 of the extraction device 3.
- the extractant supply pump 2b is a pump that supplies (sends) extractant for extracting a specific component from the raw material fluid to the first to fifth extraction units 4 to 8 of the extraction device 3.
- the extraction device 3 sequentially extracts specific components from the raw material fluid into the extractant by the first to fifth extraction units 4 to 8. That is, the extraction device 3 is configured to perform a five-stage extraction process.
- the first extraction unit 4 is an example of the “first stage extraction unit” in the present invention.
- the fifth extraction unit 8 is an example of the “final stage extraction unit” in the present invention.
- the first extraction unit 4 performs the first stage extraction process. Although the first to fifth extraction units 4 to 8 are schematically shown in FIG. 1, the first extraction unit 4 specifically has a structure as shown in FIG. 2, for example.
- the first extraction unit 4 includes a stacked body 24, a raw material supply header 25, an extractant supply header 26, and a discharge header 27.
- the laminate 24 is formed by a large number of plates 30 that are laminated in the thickness direction.
- a large number of extraction plates 31 are included in the large number of plates 30 forming the stacked body 46.
- Each extraction plate 31 is provided with a large number of extraction flow paths 33 that are microchannels (fine flow paths) for circulating the raw material fluid and the extractant.
- Each extraction flow path 33 has a structure as shown in FIG. 3, for example. Specifically, each extraction flow path 33 includes a raw material introduction path 34, an extractant introduction path 35, a merging portion 36, and a merging fluid flow path 37.
- the raw material introduction path 34 is a portion through which the raw material fluid is introduced and flows.
- the extract introduction path 35 is a portion where the extract is introduced and flows.
- the junction 36 is connected to the downstream end of the raw material introduction path 34 and the extract introduction path 35, and is a part where the raw material fluid that flows through the raw material introduction path 34 and the extract that flows through the extract introduction path 35 merge.
- the merging fluid flow path 37 is a portion that is connected to the downstream side of the merging portion 36 and flows in a state where the raw material fluid after the merging and the extractant are in contact with each other.
- Each raw material introduction path 34 and each extract introduction path 35 form a groove on one plate surface in the thickness direction of the extraction plate 31, and the groove opening formed on the plate surface is laminated on the plate surface and joined. It is formed by sealing with another plate 30 formed.
- each merging fluid flow path 37 is formed on the plate surface by forming a groove on a plate surface opposite to one plate surface of the extraction plate 31 in which the raw material introduction channel 34 and the extractant introduction channel 35 are formed. It is formed by sealing the opening of the groove with another plate 30 laminated and bonded on the plate surface.
- Each joining portion 36 includes a through hole that penetrates the extraction plate 31 in the thickness direction.
- the plurality of extraction flow paths 33 provided in each extraction plate 31 are arranged in a direction orthogonal to the stacking direction of the extraction plates 31.
- the laminate 24 is a multi-channel structure having a large number of extraction channels 33 inside.
- the raw material supply header 25 (see FIG. 2) is a header for distributing and supplying the raw material fluid to each raw material introduction path 34 (see FIG. 3) of each extraction flow path 33.
- the raw material supply header 25 is attached to the laminated body 24 so that the internal space thereof communicates with the inlets 34 a of the raw material introduction paths 34 of all the extraction flow paths 33 provided in the laminated body 24.
- a raw material supply pipe 21 connected to the discharge port of the raw material supply pump 2a (see FIG. 1) is connected to the raw material supply header 25.
- the extract supply header 26 (see FIG. 2) is a header for supplying the extract to each extract introduction path 35 (see FIG. 3) of each extraction flow path 33.
- the extract supply header 26 is attached to the laminate 24 so that the internal space thereof communicates with the inlets 35 a of the extract introduction paths 35 of all the extraction channels 33 provided in the laminate 24.
- a first branch pipe 22a of the extract supply pipe 22 connected to the discharge port of the extract supply pump 2b (see FIG. 1) is connected to the extract supply header 26.
- the discharge header 27 (see FIG. 2) is a header from which the mixed fluid of the raw material fluid and the extractant is discharged from the outlet 37a (see FIG. 3) of each merged fluid flow path 37 of each extraction flow path 33.
- the discharge header 27 is attached to the stacked body 24 so that the internal space thereof communicates with the outlets 37 a of the merged fluid flow paths 37 of all the extraction flow paths 33 provided in the stacked body 24.
- a first connection pipe 23 a (see FIG. 1) is connected to the lower portion of the discharge header 27.
- a first discharge pipe 28 a is connected to the upper portion of the discharge header 27.
- the second to fifth extraction units 5 to 8 perform the second to fifth extraction processes, respectively.
- the second to fifth extraction units 5 to 8 have the same configuration as that of the first extraction unit 4, respectively.
- the second extraction unit 5 includes a laminate 40, a raw material supply header 41, an extract supply header 42, and a discharge header 43.
- the third extraction unit 6 includes a laminated body 46, a raw material supply header 47, an extractant supply header 48 and a discharge header 49.
- the fourth extraction unit 7 includes a stacked body 52, a raw material supply header 53, an extractant supply header 54, and a discharge header 55.
- the fifth extraction unit 8 includes a stacked body 58, a raw material supply header 59, an extractant supply header 60 and a discharge header 61.
- the stacked bodies 40, 46, 52 and 58 of the second to fifth extraction units 5 to 8 have a structure corresponding to the stacked body 24 of the first extraction unit 8.
- the raw material supply headers 41, 47, 53 and 59 of the second to fifth extraction units 5 to 8 have a structure corresponding to the raw material supply header 25 of the first extraction unit 8.
- the extract supply headers 42, 48, 54 and 60 of the second to fifth extraction units 5 to 8 have a structure corresponding to the extract supply header 26 of the first extraction unit 4.
- the discharge headers 43, 49, 55, 61 of the second to fifth extraction units 5 to 8 have a structure corresponding to the discharge header 27 of the first extraction unit 8.
- the discharge headers 27, 43, 49, 55, and 61 are examples of the discharge unit of the present invention.
- the raw material supply header 41 of the second extraction unit 5 is connected to the discharge header 27 of the first extraction unit 4 via the first connection pipe 23a. That is, the inlet 34a of the raw material introduction path 34 of each extraction flow path 33 of the second extraction unit 5 is first extracted through the internal space of the raw material supply header 41 of the second extraction unit 5 and the flow path in the first connection pipe 23a. It communicates with the internal space of the discharge header 27 of the section 4.
- a second branch pipe 22b of the extract supply pipe 22 connected to the discharge port of the extract supply pump 2b is connected to the extract supply header 42 of the second extraction unit 5.
- a second connection pipe 23 b is connected to the lower part of the discharge header 43 of the second extraction unit 5.
- a second discharge pipe 28 b is connected to the upper portion of the discharge header 43.
- the raw material supply header 47 of the third extraction unit 6 is connected to the discharge header 43 of the second extraction unit 5 via the second connection pipe 23b. That is, the inlet 34a of the raw material introduction path 34 of each extraction flow path 33 of the third extraction section 6 is extracted through the internal space of the raw material supply header 47 of the third extraction section 6 and the flow path in the second connection pipe 23b. It communicates with the internal space of the discharge header 43 of the section 5.
- a third branch pipe 22c of the extract supply pipe 22 connected to the discharge port of the extract supply pump 2b is connected to the extract supply header 48 of the third extraction unit 6.
- a third connection pipe 23 c is connected to the lower part of the discharge header 49 of the third extraction unit 6.
- a third discharge pipe 28 c is connected to the upper portion of the discharge header 49.
- the raw material supply header 53 of the fourth extraction unit 7 is connected to the discharge header 49 of the third extraction unit 6 via the third connection pipe 23c. That is, the inlet 34 a of the raw material introduction path 34 of each extraction flow path 33 of the fourth extraction unit 7 is extracted through the internal space of the raw material supply header 53 of the fourth extraction unit 7 and the flow path in the third connection pipe 23 c. It communicates with the internal space of the discharge header 49 of the section 6.
- a fourth branch pipe 22d of the extract supply pipe 22 connected to the discharge port of the extract supply pump 2b is connected to the extract supply header 54 of the fourth extraction unit 7.
- a fourth connection pipe 23 d is connected to the lower part of the discharge header 55 of the fourth extraction unit 7.
- a fourth discharge pipe 28 d is connected to the upper portion of the discharge header 55.
- the raw material supply header 59 of the fifth extraction unit 8 is connected to the discharge header 55 of the fourth extraction unit 7 via the fourth connection pipe 23d. That is, the inlet 34a of the raw material introduction path 34 of each extraction flow path 33 of the fifth extraction unit 8 is extracted through the internal space of the raw material supply header 59 of the fifth extraction unit 8 and the flow path in the fourth connection pipe 23d. It communicates with the internal space of the discharge header 55 of the section 7.
- a fifth branch pipe 22e of the extract supply pipe 22 connected to the discharge port of the extract supply pump 2b is connected to the extract supply header 60 of the fifth extraction unit 8.
- a fifth connection pipe 23 e is connected to the discharge header 61 of the fifth extraction unit 8.
- the first inflow control valve 10 is provided in the first branch pipe 22a.
- the second inflow amount adjusting valve 11 is provided in the second branch pipe 22b.
- the third inflow amount adjusting valve 12 is provided in the third branch pipe 22c.
- the fourth inflow amount adjusting valve 13 is provided in the fourth branch pipe 22d.
- the fifth inflow amount adjusting valve 14 is provided in the fifth branch pipe 22e.
- the first to fifth inflow rate adjusting valves 10 to 14 are provided with the extractant supply headers 26, 42, and 48 of the first to fifth extraction units 4 to 8 through the first to fifth branch pipes 22a to 22e provided with them. , 54, 60 to adjust the flow rate of the extractant.
- the first discharge amount adjustment valve 15 is provided in the first discharge pipe 28a.
- the second discharge amount adjustment valve 16 is provided in the second discharge pipe 28b.
- the third discharge amount adjusting valve 17 is provided in the third discharge pipe 28c.
- the fourth discharge amount adjustment valve 18 is provided in the fourth discharge pipe 28d.
- the first to fourth discharge amount control valves 15 to 18 are discharged through the first to fourth extraction sections 4 to 7 through the discharge headers 27, 43, 49, and 55 through the first to fourth discharge pipes 28a to 28d, respectively. This adjusts the flow rate of the extractant discharged from the upper part.
- the settler 9 is connected to the discharge header 61 of the fifth extraction unit 8 through the fifth connection pipe 23e.
- the settler 9 has an internal space into which the fluid discharged from the internal space of the discharge header 61 of the fifth extraction unit 8 to the fifth connection pipe 23e is introduced through the fifth connection pipe 23e.
- the settler 9 retains the fluid introduced into its internal space, and separates the fluid into the extractant from which the specific component has been extracted and the raw material fluid from which the specific component has been extracted due to the difference in specific gravity.
- a lower discharge pipe 38 is connected to the lower portion of the settler 9.
- An upper discharge pipe 39 is connected to the upper part of the settler 9.
- the separated raw material fluid is stored on the lower side, and the separated extract is stored on the upper side of the raw material fluid.
- the raw material fluid separated in the inner space of the settler 9 is discharged through the lower discharge pipe 38.
- the extract separated in the inner space of the settler 9 is discharged through the upper discharge pipe 39.
- the final discharge amount adjustment valve 19 is provided in the upper discharge pipe 39.
- the final discharge amount adjusting valve 19 is for adjusting the flow rate of the extractant discharged from the inner space of the settler 9 through the upper discharge pipe 39.
- the settler 9 is provided with a liquid level gauge 20.
- the liquid level gauge 20 detects the height position of the interface between the raw material fluid separated in the internal space of the settler 9 and the extractant. Data on the height position of the interface detected by the liquid level gauge 20 is input to the final discharge amount adjustment valve 19. Based on the input interface height position data, the final discharge amount adjustment valve 19 is maintained above the interface height position of the connection portion of the fifth connection pipe 23e with respect to the settler 9. Thus, the discharge flow rate of the extractant from the settler 9 is controlled.
- an extraction / separation step of extracting and separating a specific component from a raw material fluid using the extraction / separation apparatus 1 having the above-described configuration is performed.
- the extraction and separation process will be described in detail.
- the raw material fluid is supplied from the raw material supply pump 2a to the raw material supply header 25 of the first extraction unit 4 through the raw material supply pipe 21, and the extractant is supplied from the extractant supply pump 2b to the first branch pipe of the extractant supply pipe 22. It is supplied to the extractant supply header 26 of the first extraction unit 4 through 22a.
- the raw material fluid for example, an aqueous solution containing a specific component such as a rare earth metal is used.
- the extractant an organic solvent capable of selectively extracting a specific component in the aqueous solution of the raw material fluid is used.
- the raw material fluid introduced into the internal space of the raw material supply header 25 is distributed and introduced to the raw material introduction paths 34 of the respective extraction flow paths 33 in the stacked body 24.
- the extract introduced into the internal space of the extract supply header 26 is distributed and introduced into the extract introduction path 35 of each extraction flow path 33 in the stacked body 24.
- each raw material introduction path 34 and the extract introduced into each extract introduction path 35 join at the corresponding junction 36 and flow to the corresponding junction fluid flow path 37.
- each merging fluid flow path 37 the raw material fluid and the extract flow in contact with each other, and a specific component is extracted from the raw material fluid to the extract in the flow process.
- the raw material fluid and the extractant that have flowed through each merged fluid flow path 37 are discharged from the outlet 37 a of the merged fluid flow path 37 to the internal space of the discharge header 27.
- the raw material fluid and the extractant discharged to the internal space of the discharge header 27 are mixed with each other.
- the raw material fluid having a large specific gravity is biased downward.
- the extractant with a small specific gravity is biased upward.
- the extractant is discharged from the upper part of the internal space of the discharge header 27 through the first discharge pipe 28a, and the fluid located at the lower part of the internal space of the discharge header 27 is discharged to the first connection pipe 23a.
- the fluid discharged into the internal space of the discharge header 27 is roughly separated due to the difference in specific gravity, and the extracted fluid, which is one fluid after the separation, is discharged to the first discharge pipe 28a and the other fluid after the separation. Is discharged to the first connection pipe 23a.
- the discharge flow rate of the extractant from the discharge header 27 by adjusting the discharge flow rate of the extractant from the discharge header 27 by the first discharge amount adjustment valve 15, the length of time that the fluid stays in the internal space of the discharge header 27 is reduced. It is set shorter than the residence time required for the fluid to be completely separated into the raw material fluid and the extractant in the internal space. Thereby, the fluid discharged
- the fluid discharged from the first connection pipe 23a is a fluid in which the ratio of the extractant in the fluid is lower than the ratio of the raw material fluid in the fluid.
- the length of time during which the fluid stays in the internal space of the discharge header 27 is such that the mixed fluid in a state where the extractant having a maximum volume fraction of 10% is mixed with the raw fluid from the internal space of the discharge header 27.
- the length is set so as to be discharged to the one connection pipe 23a.
- the mixed fluid discharged from the discharge header 27 of the first extraction unit 4 to the first connection pipe 23 a is introduced into the raw material supply header 41 of the second extraction unit 5.
- the mixed fluid separated by the discharge header 27 and discharged to the first connection pipe 23a is an example of the first fluid of the present invention.
- the extract separated by the discharge header 27 and discharged to the first discharge pipe 28a is an example of the second fluid of the present invention.
- the flow rate of the extract that is supplied to the extract supply header 26 and flows to each extraction flow path 33 is adjusted by the first inflow amount adjusting valve 10, and the discharge header 27 to the first discharge pipe.
- the flow rate of the extractant discharged through 28 a is adjusted by the first discharge amount adjustment valve 15.
- the length of time for which the raw material fluid and the extractant are kept in contact with each other in the first extraction unit 4 is set so that the specific component from the raw material fluid to the extractant after the extractant contacts the raw material fluid. Set shorter than the time it takes for the extraction to reach equilibrium.
- the correlation as shown in FIG. 4 is established between the retention time in which the raw material fluid and the extract are in contact with each other (retention time) and the extraction rate of the specific component from the raw material fluid to the extract.
- retention time retention time
- extraction rate of the specific component from the raw material fluid to the extract it takes 150 seconds or more for the extraction of the specific component from the raw material fluid to the extract to reach the equilibrium state, and the extraction rate of the specific component when reaching the equilibrium state is 65. %.
- the length of time for which the source fluid and the extractant are kept in contact with each other in the first extraction unit 4 is set to 15 seconds.
- the extraction rate of the specific component from the raw material fluid is only obtained up to 40%, which is lower than the extraction rate (65%) when the extraction reaches an equilibrium state.
- the extraction rate increases rapidly, so that it can reach a certain level of extraction rate in a short time with respect to the extraction rate in the equilibrium state. For this reason, setting the length of time for which the raw material fluid and the extractant are in contact with each other in the first extraction unit 4 to 15 seconds is effective for shortening the processing time.
- the fluid flowing to the raw material supply header 41 of the second extraction unit 5 is distributed from the internal space of the raw material supply header 41 to the raw material introduction path 34 of each extraction flow path 33 in the stacked body 24 of the second extraction unit 5. be introduced.
- the extract is supplied from the extract supply pump 2b to the extract supply header 42 of the second extraction unit 5 through the second branch pipe 22b of the extract supply pipe 22.
- the extract supplied to the extract supply header 42 is distributed and introduced from the internal space of the extract supply header 42 to the extract introduction path 35 of each extraction flow path 33 in the stacked body 24 of the second extraction unit 5.
- the fluid introduced into each raw material introduction path 34 and the extract introduced into each extract introduction path 35 correspond to the corresponding merging unit as in the process in the first extraction unit 4.
- the specific components from the raw material fluid to the extractant are extracted by joining at 36 and flowing through the joining fluid flow path 37.
- the raw material fluid and the extractant are discharged from the merging fluid flow path 37 of the second extraction unit 5 into the internal space of the discharge header 43.
- the extractant is discharged from the upper portion in the discharge header 43 through the second discharge pipe 28b and the lower portion in the discharge header 43.
- the fluid in a state where the extractant is mixed with the raw material fluid is discharged to the second connection pipe 23b.
- the fluid discharged to the second connection pipe 23 b flows to the raw material supply header 47 of the third extraction unit 6.
- the second extraction unit 5 the supply flow rate of the extractant to the extractant supply header 42 by the second inflow amount adjustment valve 11 and the discharge flow rate of the extractant from the discharge header 43 by the second discharge amount adjustment valve 16 are adjusted. This adjustment is also performed in the same manner as the process in the first extraction unit 5.
- the fluid introduced into the internal space is retained, whereby the fluid is completely separated by the difference in specific gravity between the extractant from which the specific component has been extracted and the raw material fluid from which the specific component has been extracted.
- the separated raw material fluid accumulates in the lower side in the inner space of the settler 9. Since the separated extract has a specific gravity smaller than that of the raw material fluid, it accumulates above the raw material fluid in the inner space of the settler 9.
- the raw material fluid from which the specific component has been extracted is discharged from the inner space of the settler 9 through the lower discharge pipe 38, and the specific component is extracted from the inner space of the settler 9 through the upper discharge pipe 39. Is discharged.
- the final discharge amount adjusting valve 19 is based on the height position data of the interface between the raw material fluid and the extractant in the settler 9 detected by the liquid level gauge 20. Is controlled at a position higher than the height position of the connection portion of the fifth connection pipe 23e with respect to the settler 9.
- the extraction and separation method according to the first embodiment of the present invention is performed.
- a part of the fluid discharged from the extraction flow path 33 to the corresponding internal space of the discharge headers 27, 43, 49, 55, 61 in the first to fourth extraction units 4 to 7 is used as the raw material fluid.
- the extractant are mixed and introduced into the extraction channel 33 of the extraction units 5 to 8 in the next stage. For this reason, compared with the case where a retention part is provided for each extraction part of each stage and the fluid discharged from the corresponding extraction flow path is retained until the fluid is completely separated into the raw material fluid and the extractant.
- the processing time required for extraction and separation can be shortened.
- each staying part must be enlarged.
- the raw material fluid and the extractant are discharged from the discharge headers 27, 43, 49, 55 of the first to fourth extraction units 4-7 to the extraction flow path 33 of the extraction units 5-8 of the next stage.
- the residence time of the fluid in the internal space of the discharge headers 27, 43, 49, and 55 of the first to fourth extraction units 4 to 7 can be shortened. For this reason, the discharge headers 27, 43, 49, 55 can be reduced in size. Further, it is not necessary to separate the fluid in the discharge header 61 of the fifth extraction unit 8, and in order to separate the fluid into the raw material fluid and the extractant in the subsequent settler 9, the inside of the discharge header 61 of the fifth extraction unit 8 The residence time of the fluid in the space can also be shortened. As a result, the discharge header 61 of the fifth extraction unit 8 can also be reduced in size. From the above, in the first embodiment, the extraction device 3 (extraction / separation device 1) can be downsized.
- the fluid discharged from the extraction flow path 33 of the fifth extraction unit 8 to the corresponding discharge header 61 is introduced into the inner space of the settler 9 to be retained, thereby allowing the fluid to flow into the specific component. Is separated by the specific gravity difference between the raw material fluid after extraction of the water and the extractant from which the specific component has been extracted. For this reason, even if the retention time of the fluid in the discharge headers 27, 43, 49, and 55 in each stage is shortened as described above and the processing time is shortened, the fluid after the extraction processing is extracted after the specific component is extracted. It is possible to completely separate the raw material fluid and the extract from which the specific component is extracted.
- the mixed fluid separated by the discharge headers 27, 43, 49, and 55 of the first to fourth extraction units 4 to 7 and having a ratio of the extractant lower than that of the raw material fluid is added to the next stage.
- the extraction flow path 33 of the extraction section it can suppress that the flow volume of the fluid which should be processed increases toward the latter extraction part, promoting the extraction of the specific component from a raw material fluid toward the latter extraction part.
- the extraction / separation apparatus 1 includes the stacked bodies 24 each including a plurality of plates 30 in which the first to fifth extraction units 4 to 8 are stacked, and the extraction units 4 to 8 thereof.
- a structure in which a plurality of microchannels constituting a plurality of extraction flow paths 33 are arranged on each extraction plate 31 of the laminate 24 is used.
- a specific component is supplied from the raw material fluid to the extract while flowing the raw material fluid and the extract in contact with each other. Extract.
- each merging fluid flow path 37 is a microchannel, the contact area between the raw material fluid and the extractant per unit volume in each merging fluid flow path 37 can be increased. As a result, the processing efficiency of extraction / separation can be increased.
- the length of time that the raw material fluid and the extractant are kept in contact with each other in each of the first to fifth extraction units 4 to 8 is determined after the extractant contacts the raw material fluid. It is set shorter than the time required for the extraction of the specific component from the raw material fluid to the extract to reach the equilibrium state. For this reason, the extraction rate per unit time is high and efficient extraction processing can be performed.
- the extraction / separation apparatus 1 as shown in FIG. 5 is used to extract and separate specific components from the raw material fluid.
- the extraction / separation apparatus 1 includes a latter-half extraction / separation apparatus 1b in addition to the first-half extraction / separation apparatus 1a having the same configuration as the extraction / separation apparatus 1 of the first embodiment.
- the second-half extraction / separation apparatus 1b is connected to the rear stage side of the first-half extraction / separation apparatus 1a, and performs the same extraction / separation as that performed in the first-half extraction / separation apparatus 1a after the extraction / separation process discharged from the first-half extraction / separation apparatus 1a. The process is performed again on the raw material fluid.
- the first-half extraction / separation device 1a includes a first raw material supply pump 2a, a first extractant supply pump 2b, a first extraction device 3, a first settler 9, first to fifth inflow amount regulating valves 10 to 14, and first to second. 4
- the discharge amount adjusting valves 15 to 18, the first half final discharge amount adjusting valve 19, and the first liquid level meter 20 are provided.
- the configuration of each element constituting the first half extraction / separation apparatus 1a is the same as the configuration of each element assigned the same reference numeral in the extraction / separation apparatus 1 according to the first embodiment.
- the configuration of the second half extraction / separation apparatus 1b is the same as the configuration of the first half extraction / separation apparatus 1a. That is, the latter half extraction / separation apparatus 1b has the same configuration as the extraction / separation apparatus 1 of the first embodiment.
- the second-half extraction / separation device 1b includes a second raw material supply pump 62a, a second extractant supply pump 62b, a second extraction device 63 having sixth to tenth extraction units 64 to 68, a second settler 69, a second extractor. 6th to 10th inflow amount adjusting valves 70 to 74, 6th to 9th discharge amount adjusting valves 75 to 78, a latter half final discharge amount adjusting valve 79, and a second liquid level meter 80 are provided.
- the configuration of the second extraction device 63 is the same as the configuration of the first extraction device 3.
- the sixth to tenth extraction units 64 to 68 are configured in the same manner as the first to tenth extraction units 4 to 8 and are similarly connected by connection piping.
- the first settler 9 of the first half extraction / separation apparatus 1a is connected to the raw material supply header 64a of the sixth extraction unit 64 of the second half extraction / separation apparatus 1b via the lower discharge pipe 38.
- the lower discharge pipe 38 is provided with a second raw material supply pump 62a.
- the raw material fluid separated in the internal space of the first settler 9 and discharged to the lower discharge pipe 38 is sent to the raw material supply header 64a of the sixth extraction unit 64 by the second raw material supply pump 62a.
- the configuration of the second extract supply pump 62b is the same as the configuration of the first extract supply pump 2b.
- the connection configuration of the second extractant supply pump 62b to the sixth to tenth extraction units 64 to 68 is the same as the connection configuration of the first extractant supply pump 2b to the first to fifth extraction units 4 to 8.
- the second extract supply pump 62b supplies the extract to the sixth to tenth extraction units 64 to 68 in the same manner as the first extract supply pump 2b.
- the sixth to tenth inflow amount regulating valves 70 to 74 are provided in the same form as the first to fifth inflow amount regulating valves 10 to 14 in the first half extraction / separation apparatus 1a. .
- the sixth to tenth inflow amount adjusting valves 70 to 74 have functions corresponding to the first to fifth inflow amount adjusting valves 10 to 14.
- the sixth to ninth discharge amount control valves 75 to 78 are provided in the same form as the first to fourth discharge amount control valves 15 to 18 in the first half extraction / separation apparatus 1a. .
- the sixth to ninth discharge amount adjustment valves 75 to 78 have functions corresponding to the first to fourth discharge amount adjustment valves 15 to 18.
- the latter half final discharge amount adjustment valve 79 is provided in the same form as the first half final discharge amount adjustment valve 19 in the first half extraction / separation apparatus 1a.
- the latter half final discharge amount adjustment valve 79 has a function corresponding to the first half final discharge amount adjustment valve 19.
- the second liquid level gauge 80 is provided in the same form as the first liquid level gauge 20 in the first half extraction / separation apparatus 1a.
- the second liquid level gauge 80 has a function corresponding to the first liquid level gauge 20.
- the same process as that of the extraction / separation method according to the first embodiment is performed.
- the specific component is extracted from the raw material fluid into the extractant.
- the first settler 9 of the first-half extraction / separation apparatus 1a as in the case of the settler 9 of the first embodiment, the raw material fluid and the specific component are extracted after the specific component is extracted from the fluid after the extraction process. Separated into extractant.
- the raw material fluid separated in the internal space of the first settler 9 of the first-half extraction / separation apparatus 1a is discharged to the lower discharge pipe 38.
- the raw material fluid discharged to the lower discharge pipe 38 is supplied to the raw material supply header 64a of the sixth extraction unit 64 of the second half extraction / separation apparatus 1b through the lower discharge pipe 38 by the second raw material supply pump 62a. It is introduced into each extraction channel (not shown) of the section 64.
- the extract delivered by the second extract supply pump 62 b is introduced into each extraction channel (not shown) of the sixth extraction unit 64.
- each extraction flow path (not shown) of the sixth extraction unit 64 the specific component is extracted from the raw material fluid to the extract while flowing while the raw material fluid and the extract are in contact with each other.
- a fluid in a state where the extractant is mixed with the raw material fluid after the extraction processing in the sixth extraction section 64 is supplied.
- the specific component is extracted from the fluid supplied from the sixth extraction unit 64. Thereafter, similar extraction processing is sequentially performed in the eighth to tenth extraction units 66 to 68.
- the fluid after extraction discharged from the tenth extraction unit 68 is separated into the raw material fluid after extraction of the specific component and the extract from which the specific component has been extracted.
- the extraction process steps performed in the sixth to tenth extraction units 66 to 68 are the same as the extraction process steps performed in the first to fifth extraction units 4 to 8.
- the separation process performed in the second settler 69 is the same as the separation process performed in the first settler 9.
- the extraction and separation method according to the second embodiment of the present invention is performed.
- the second extraction device 63 and the second settler 69 of the second-half extraction / separation device 1b are used to extract from the raw material fluid that has been extracted and separated by the first extraction device 3 and the first settler 9 of the first-half extraction / separation device 1a. Furthermore, specific components can be extracted and separated. For this reason, the extraction separation of the specific component from the raw material fluid can be further promoted.
- the corresponding discharge headers 27, 43, 49, 55, 61 are obtained after the raw material fluid and the extractant merge in each of the first to fifth extraction units 4-8.
- the time until the fluid is discharged that is, the time during which the raw material fluid and the extractant are in contact with each other in each of the first to fifth extraction units 4 to 8, is set to 15 seconds. In this case, it can be seen from the correlation between the residence time and the extraction rate shown in FIG. 4 that an extraction rate of 40% is obtained in each of the extraction units 4 to 8.
- the concentration of the specific component in the raw material fluid discharged from the discharge header 27 of the first extraction unit 4 is 60 ppm.
- emitted from the discharge header 43 of the 2nd extraction part 5 will be 36 ppm.
- emitted from the discharge header 49 of the 3rd extraction part 6 will be 21.6 ppm.
- emitted from the discharge header 55 of the 4th extraction part 7 will be 12.96 ppm.
- the concentration of the specific component in the raw material fluid discharged from the discharge header 61 of the fifth extraction unit 8 is 7.77 ppm. Further, the total time during which the raw material fluid and the extractant are in contact with each other in the first to fifth extraction units 4 to 8 is 75 seconds.
- FIG. 6 shows a partial configuration of an extraction / separation apparatus used in the extraction / separation method according to this comparative example.
- the first stage extraction unit 104 and the first stage settler 106 attached thereto, and the second stage extraction unit 105 and the second stage settler 107 attached thereto are shown.
- the second extraction unit 105 and the third setter 107 having the same configuration as the second extraction unit 105 and the second extraction unit 107 are sequentially arranged after the second extraction unit 107.
- a connected extraction / separation apparatus shall be used.
- the extraction / separation apparatus used in this comparative example includes a five-stage extraction unit and a five-stage settler, and the extraction unit and the settler are alternately connected.
- the configuration of each extraction unit in this comparative example is the same as the configuration of the extraction units 4 to 8 in the first embodiment.
- the configuration of each settler in this comparative example is the same as the settler 9 of the first embodiment.
- the time from when the raw material fluid and the extractant merge at the extraction unit of each stage to when the separated raw material fluid is discharged from the settler at that stage, that is, extraction at each stage The time in which the raw material fluid and the extractant are in contact with each other in the section and the settler is set to 150 seconds.
- an extraction rate of 65% is obtained by the extraction separation process in each stage. Accordingly, when a raw material fluid containing a specific component of 100 ppm at the initial concentration is supplied to the first stage extraction unit, the concentration of the specific component in the raw material fluid after separation in the first stage settler is 35 ppm.
- the concentration of the specific component in the raw material fluid after the separation in the second stage settler is 12.25 ppm
- the concentration of the specific component in the raw material fluid after the separation in the third stage settler is about 4. 28 ppm.
- the concentration of the specific component in the raw material fluid after separation in the fourth stage settler is about 1.50 ppm
- the concentration of the specific component in the raw material fluid after separation in the fifth stage settler is about 0.52 ppm.
- the total time for which the raw material fluid and the extractant are in contact with each other in the first to fifth extraction units and the settler is 750 seconds.
- the concentration (7.77 ppm) of the specific component in the final raw material fluid after the treatment by the extraction and separation method of the first embodiment is the concentration of the specific component in the final raw material fluid after the treatment by the extraction and separation method of the comparative example. Although it is higher than (about 0.52 ppm), it can be reduced to a relatively low concentration of 10 ppm or less. For this reason, it turns out that a useful extraction separation effect is acquired.
- the time (75 seconds) for keeping the raw material fluid and the extractant in contact with each other is 1/10 of the corresponding time (750 seconds) in the extraction / separation method of the comparative example. Become. From this, it can be seen that a significant reduction effect of the processing time can be obtained.
- the extraction and separation method of the second embodiment may be used.
- the concentration of the specific component therein is 7.77 ppm, which is the same as that in the first embodiment.
- the time during which the raw material fluid and the extractant are in contact with each other is the same as in the first to fifth extraction units 4 to 15.
- the concentration of the specific component in the raw material fluid discharged from the discharge header of the sixth extraction unit 64 is about 4.7 ppm.
- the concentration of the specific component in the raw material fluid discharged from the discharge header of the seventh extraction unit 65 is about 2.8 ppm
- the concentration of the specific component in the raw material fluid discharged from the discharge header of the eighth extraction unit 66 is The concentration is about 1.68 ppm
- the concentration of the specific component in the raw material fluid discharged from the discharge header of the ninth extraction unit 67 is about 1.01 ppm.
- the concentration of the specific component in the raw material fluid separated by the second settler 69 after being discharged from the discharge header of the last tenth extraction unit 68 is about 0.60 ppm.
- the total time during which the raw material fluid and the extractant are in contact with each other in the first to tenth extraction units 4 to 8 and 64 to 68 is 150 seconds.
- concentration of the specific component in the final raw material fluid after the process by the extraction separation method of this 2nd Embodiment becomes substantially equal to the density
- the extraction / separation method of the second embodiment can provide an extraction / separation effect substantially equivalent to the extraction / separation method of the comparative example.
- the time for which the raw material fluid and the extractant are in contact with each other is 1/5 of the corresponding time (750 seconds) in the extraction / separation method of the comparative example. It's time. That is, it can be seen that the extraction / separation method of the second embodiment can sufficiently achieve the effect of reducing the processing time.
- the extraction device, the first extraction device, and the second extraction device each include five stages of extraction units, but the present invention is not necessarily limited to such a configuration.
- the extraction device only needs to include two or more extraction units.
- the settler is provided after the final extraction unit of the two or more extraction units included in the extraction device, and the fluid discharged from the final extraction unit is used as the raw material fluid and the extractant. What is necessary is just to separate.
- the settler may be omitted, and the final separation step may be performed by separation means other than the settler.
- each extraction unit is not necessarily limited to the configuration described above. Specifically, for the arrangement and structure of each header provided in each extraction unit, the shape, arrangement, and number of extraction channels in the stack, a configuration other than the configuration described above or the configuration shown in the drawings is adopted. May be.
- the discharge unit 27a may be configured by a discharge header 27b and a simple liquid separation tank 27c connected to the discharge header 27b.
- the simple liquid separation tank 27c is an example of the liquid separation tank of the present invention.
- the discharge header 27b is connected to the outlet of the corresponding extraction flow path, and the fluid discharged from the extraction flow path to the discharge header 27b is introduced into the internal space of the simple separation tank 27c, and the specific gravity is determined in the internal space. It separates into the extractant and the mixed fluid by the difference.
- the first discharge pipe 28 a is connected to the extract supply header 42 of the second extraction unit 5, and the second discharge pipe 28 b is connected to the extract supply of the third extraction unit 6.
- the third discharge pipe 28 c may be connected to the extract supply header 54 of the fourth extraction section 7, and the fourth discharge pipe 28 d may be connected to the extract supply header 60 of the fifth extraction section 8. .
- the extractant separated by the discharge headers 27, 43, 49, and 55 of the first to fourth extraction units 4 to 7 is supplied to the extraction channel of the extraction unit of the next stage, and the raw material in the extraction channel
- the said extractant can be reused for extraction of the specific component from the fluid. For this reason, the usage-amount of an extractant can be reduced.
- the second discharge pipe 28 b is connected to the extractant supply header 26 of the first extraction unit 4, and the third discharge pipe 28 c is connected to the extractant of the second extraction unit 5.
- the fourth discharge pipe 28 d is connected to the extractant supply header 48 of the third extraction unit 6, and the upper discharge pipe 39 connected to the upper part of the settler 9 is supplied to the extractant of the fourth extraction unit 7 It may be connected to the header 54.
- the upper discharge pipe 39 is provided with a pump 2 c that sends the extract discharged from the settler 9 to the upper discharge pipe 39 to the extract supply header 54 of the fourth extraction unit 7.
- the fourth discharge pipe 28d is provided with a pump 2d that sends the extract discharged from the discharge header 55 of the fourth extraction unit 7 to the extract supply header 48 of the third extraction unit 6.
- a pump 2e for sending the extract discharged from the discharge header 49 of the third extraction unit 6 to the extract supply header 42 of the second extraction unit 5 is provided in the third discharge pipe 28c.
- the second discharge pipe 28 b is provided with a pump 2 f that sends the extract discharged from the discharge header 43 of the second extraction unit 5 to the extract supply header 26 of the first extraction unit 4.
- the extract supply pipe 22 is connected to the extract supply header 60 of the fifth extraction unit 8. Fresh extractant is supplied to the extractant supply header 6 through the extractant supply pipe 22. That is, the extract that does not contain a specific component as an extraction target is supplied to the extract supply header 6.
- the extractant separated by the discharge headers 43, 49, and 55 of the second to fourth extraction units 5 to 7 is supplied to the extraction flow channel of the previous extraction unit,
- the extract separated by the settler 9 is supplied to the extraction flow path of the fourth extraction unit 7.
- the extractant separated by the discharge headers 43, 49, 55 and the settler 9 of the second to fourth extraction units 5 to 7 is used to extract a specific component from the raw material fluid in the extraction flow path of the previous extraction unit. Can be reused. As a result, the amount of extractant used can be reduced.
- the raw material fluid is not necessarily limited to an aqueous solution containing a specific component such as a rare earth metal.
- the extractant is not necessarily limited to the organic solvent.
- the specific component extracted and separated from the raw material fluid may be a removal component that is desired to be removed from the raw material fluid, such as impurities or contaminants. That is, the extraction and separation method of the present invention can be used both for the purpose of collecting useful specific components from the raw material fluid and for the purpose of removing unnecessary specific components from the raw material fluid.
- the raw material fluid may be a fluid having a specific gravity smaller than that of the extractant.
- the raw material fluid after the extraction process in the preceding extraction unit can be supplied to the subsequent extraction unit.
- a predetermined amount of mixed fluid may be extracted from the fluid discharged in the discharge part of each stage without being retained and supplied to the extraction part of the next stage.
- the entire amount of the fluid discharged to the discharge unit of each stage may be supplied to the extraction unit of the next stage in a state where the raw material fluid and the extractant are mixed.
- the extraction / separation method is a method for extracting and separating a specific component from a raw material fluid, and the specific component is extracted from the raw material fluid by using an extraction apparatus including a plurality of extraction units connected in sequence.
- An extraction step of extracting the specific component from the raw material fluid into the extract and an introduction step of introducing at least a part of the fluid discharged from the extraction unit into the extraction unit in the next stage in a state where the raw material fluid and the extract are mixed
- this extraction / separation method at least a part of the fluid discharged from the extraction unit is introduced into the next extraction unit in a state where the raw material fluid and the extractant are mixed. For this reason, compared with the case where a retention part is provided for each extraction part in each stage and the fluid is retained until the fluid is completely separated into the raw material fluid and the extractant in the retention part, the processing time required for extraction and separation is shortened. Can do. In addition, since the large retention portion necessary for completely separating the fluid into the raw material fluid and the extractant is not necessary, the extraction device can be downsized. Further, in this extraction / separation method, the fluid discharged from the extraction unit in the final stage is separated into the raw material fluid after the specific component is extracted and the extract from which the specific component is extracted. For this reason, even if it shortens the residence time of the fluid in the extraction part of each stage and shortens processing time, the extraction fluid which extracted the raw material fluid and specific component after the extraction of the specific component from the fluid after extraction processing And can be completely separated.
- the extraction unit of each stage has an extraction flow path for flowing the fluid introduced into the extraction unit, and at least the extraction of the final stage
- Each extraction unit other than the extraction unit uses an extraction device having a discharge unit connected to an outlet of the extraction flow channel of the extraction unit, and the introduction step is performed in each extraction unit other than the final stage extraction unit.
- emitted from the extraction flow path to the said discharge part may be divided into a 1st fluid and a 2nd fluid by specific gravity difference, and the 1st fluid may contain a raw material fluid and an extractant.
- a separation fluid introduction step of introducing the first fluid separated in the discharge section in each stage separation step into the extraction flow path of the extraction section in the next stage.
- the first fluid of the first fluid and the second fluid separated in each stage separation step is introduced into the extraction flow path of the extraction unit in the next stage in the separation fluid introduction step. For this reason, it can suppress that the flow volume of the fluid which should be processed increases toward the extraction part of a back
- the ratio of the extractant in the first fluid separated in each stage separation step is lower than the ratio of the raw material fluid in the first fluid.
- the first fluid separated so that the ratio of the extractant in the first fluid is lower than the ratio of the raw material fluid in the first fluid is supplied to the extraction unit in the next stage. Can be introduced. For this reason, the extraction of the specific component in the raw material fluid can be promoted while maintaining the amount of the raw material fluid as it goes to the subsequent extraction unit.
- the discharge unit is a discharge header connected to an outlet of the extraction flow path, and in each stage separation process, the extraction flow path is connected to the inside of the discharge header.
- the fluid discharged into the space may be separated into the first fluid and the second fluid by the specific gravity difference in the internal space.
- the fluid discharged from the extraction flow path in the internal space of the discharge header can be separated into the first fluid and the second fluid.
- the structure of an extraction apparatus can be simplified compared with the structure in which the extraction part of each stage is equipped with a liquid separation tank other than a discharge header.
- the discharge unit includes a discharge header connected to an outlet of the extraction flow path, and a liquid separation tank connected to the discharge header,
- the fluid discharged from the extraction flow path to the discharge header is introduced into the internal space of the liquid separation tank, and the first fluid and the second fluid are caused by the specific gravity difference in the internal space of the liquid separation tank. It may be separated into a fluid.
- the general discharge header which does not have the function to perform separation by specific gravity difference can be used.
- the discharge header may not have a function of performing separation based on the difference in specific gravity. For this reason, a compact discharge header with a small capacity can be used. For this reason, even if a liquid separation tank is provided, the size of the entire extraction device can be kept compact.
- the extraction / separation step may include a drawing agent supply step of supplying the second fluid separated in the discharge unit in each stage separation step to the extraction flow path of the extraction unit in the next stage. Further, in the configuration in which the introduction step includes each stage separation step, in each stage separation step, a predetermined amount of the extractant out of the fluid discharged to the discharge unit in each extraction unit is separated as the second fluid.
- the extraction / separation step may include a drawing agent supply step of supplying the second fluid separated in the discharge unit in each stage separation step to the extraction flow path of the extraction unit in the previous stage. .
- the extractant as the second fluid separated in each stage separation step can be reused for extraction of a specific component from the raw material fluid. For this reason, the usage-amount of an extractant can be reduced.
- the extraction units of the respective stages are stacked on each other as the extraction device.
- the raw material in each microchannel included in the extraction unit in each stage is used using an extraction device in which a plurality of microchannels each constituting the extraction flow path are arranged in each layer. It is preferable to extract the specific component from the fluid into the extract.
- the length of time for which the raw material fluid and the extractant are kept in contact with each other in the extraction unit of each stage is determined after the extractant contacts the raw material fluid. It is preferable to set it shorter than the time required for the extraction of the specific component from the extract to the extract to reach an equilibrium state.
- the extraction device used in the extraction / separation step is provided with a settler connected to the extraction unit in the final stage, and the fluid discharged from the extraction unit in the final stage in the final separation step. It is preferable that the fluid is separated into a raw material fluid after the specific component has been extracted and an extractant from which the specific component has been extracted, by introducing the fluid into the interior space of the settler and retaining the fluid in the internal space. .
- the fluid after the extraction process can be completely separated into the raw material fluid from which the specific component has been extracted by staying in the settler and the extract from which the specific component has been extracted. .
Abstract
Description
本発明の第1実施形態による抽出分離方法は、抽出分離装置1を用いて原料流体から特定成分を抽出して分離する方法である。まず、図1~図4を参照して、この第1実施形態による抽出分離方法に用いる抽出分離装置1について説明する。
次に、本発明の第2実施形態による抽出分離方法について説明する。この第2実施形態による抽出分離方法では、図5に示すような抽出分離装置1を用いて原料流体からの特定成分の抽出分離を行う。
次に、上記各実施形態の抽出分離方法によって原料流体からの特定成分の抽出分離を行った場合に得られる効果を調べるために行ったシミュレーションの結果について説明する。
前記実施形態をまとめると、以下の通りである。
Claims (10)
- 原料流体から特定成分を抽出して分離する方法であって、
順次接続された複数段の抽出部を備えた抽出装置を用いて、原料流体から前記特定成分を抽出して分離する抽出分離工程を備え、
前記抽出分離工程は、
各段の前記抽出部において原料流体とその原料流体に対して比重差を有する抽剤とを互いに接触させた状態で流通させながら原料流体から抽剤へ前記特定成分を抽出する抽出工程と、
前記抽出部から排出される流体の少なくとも一部を次段の前記抽出部へ原料流体と抽剤が混ざった状態で導入する導入工程と、
最終段の前記抽出部から排出された流体を前記特定成分が抽出された後の原料流体と前記特定成分を抽出した抽剤とに分離する最終分離工程とを有する、抽出分離方法。 - 請求項1に記載の抽出分離方法において、
前記抽出分離工程では、前記抽出装置として、前記各段の抽出部がその抽出部に導入された流体を流通させる抽出流路を有し、且つ、少なくとも前記最終段の抽出部以外の前記各抽出部が前記抽出流路の出口に接続された排出部を有する抽出装置を用い、
前記導入工程は、前記最終段の抽出部以外の前記各抽出部において前記抽出流路から前記排出部に排出された流体を比重差により第1流体と第2流体とに分離し且つその第1流体には原料流体と抽剤が含まれるように分離する各段分離工程と、その各段分離工程において前記排出部で分離された前記第1流体を次段の前記抽出部の前記抽出流路へ導入する分離流体導入工程とを含む、抽出分離方法。 - 請求項2に記載の抽出分離方法において、
前記各段分離工程において分離される前記第1流体中の抽剤の比率は、その第1流体中の原料流体の比率よりも低い、抽出分離方法。 - 請求項2又は3に記載の抽出分離方法において、
前記排出部は、前記抽出流路の出口に接続された排出ヘッダであり、
前記各段分離工程では、前記抽出流路から前記排出ヘッダの内部空間に排出された流体をその内部空間で比重差により前記第1流体と前記第2流体とに分離する、抽出分離方法。 - 請求項2又は3に記載の抽出分離方法において、
前記排出部は、前記抽出流路の出口に接続された排出ヘッダと、その排出ヘッダに接続された分液槽とを有し、
前記各段分離工程では、前記抽出流路から前記排出ヘッダへ排出された流体を前記分液槽の内部空間に導入してその分液槽の内部空間で比重差により前記第1流体と前記第2流体とに分離する、抽出分離方法。 - 請求項2又は3に記載の抽出分離方法において、
前記各段分離工程では、前記各抽出部において前記排出部に排出された流体のうちの所定量の抽剤を前記第2流体として分離し、
前記抽出分離工程は、前記各段分離工程において前記排出部で分離された前記第2流体を次段の前記抽出部の前記抽出流路へ供給する抽剤供給工程を有する、抽出分離方法。 - 請求項2又は3に記載の抽出分離方法において、
前記各段分離工程では、前記各抽出部において前記排出部に排出された流体のうちの所定量の抽剤を前記第2流体として分離し、
前記抽出分離工程は、前記各段分離工程において前記排出部で分離された前記第2流体を前段の前記抽出部の前記抽出流路へ供給する抽剤供給工程を有する、抽出分離方法。 - 請求項2又は3に記載の抽出分離方法において、
前記抽出分離工程では、前記抽出装置として、前記各段の抽出部が互いに積層された複数の層を含み、各層においてそれぞれ前記抽出流路を構成する複数のマイクロチャネルが配列された抽出装置を用い、
前記抽出工程では、前記各段の抽出部が有する前記各マイクロチャネルにおいて原料流体から抽剤へ前記特定成分を抽出する、抽出分離方法。 - 請求項1~3のいずれか1項に記載の抽出分離方法において、
前記抽出工程では、前記各段の抽出部において原料流体と抽剤を互いに接触した状態にしておく時間の長さを、原料流体に抽剤が接触してからその原料流体から抽剤への前記特定成分の抽出が平衡状態に達するまでにかかる時間よりも短く設定する、抽出分離方法。 - 請求項1~3のいずれか1項に記載の抽出分離方法において、
前記抽出分離工程で用いる前記抽出装置には、前記最終段の抽出部と接続されたセトラーが付設され、
前記最終分離工程では、前記最終段の抽出部から排出された流体を前記セトラーの内部空間に導入してその内部空間で滞留させることにより、当該流体を、前記特定成分が抽出された後の原料流体と前記特定成分を抽出した抽剤とに分離する、抽出分離方法。
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US15/029,122 US10376812B2 (en) | 2013-11-21 | 2014-10-22 | Extraction and separation method |
EP14863253.2A EP3072569B1 (en) | 2013-11-21 | 2014-10-22 | Extraction and separation method |
KR1020167013050A KR101728651B1 (ko) | 2013-11-21 | 2014-10-22 | 추출 분리 방법 |
CN201480063635.4A CN105722573B (zh) | 2013-11-21 | 2014-10-22 | 提取分离方法 |
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Cited By (2)
Publication number | Priority date | Publication date | Assignee | Title |
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CN106902547A (zh) * | 2017-04-10 | 2017-06-30 | 赣州科源甬致科技有限公司 | 一种从废旧电池中提取硫酸镍用新式节能型萃取装置 |
CN115475408A (zh) * | 2022-08-31 | 2022-12-16 | 中材锂膜(宁乡)有限公司 | 一种湿法隔膜萃取装置及工艺 |
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EP3169172A4 (en) * | 2014-07-17 | 2018-05-30 | vapRwear Gear, LLC | Clothing top for technology concealment |
CN106474765B (zh) * | 2015-09-01 | 2019-02-05 | 广州科品生物科技有限公司 | 耦合式植物成份提取装置及工艺方法 |
CN109701297B (zh) * | 2019-03-05 | 2020-10-20 | 北京化工大学 | 一种超重力萃取分离耦合装置及应用 |
WO2021024820A1 (ja) | 2019-08-02 | 2021-02-11 | 株式会社神戸製鋼所 | 相互作用システム及び相互作用方法 |
JP2021045728A (ja) * | 2019-09-20 | 2021-03-25 | 株式会社神戸製鋼所 | 相互作用システム |
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- 2014-10-22 CN CN201480063635.4A patent/CN105722573B/zh not_active Expired - Fee Related
- 2014-10-22 US US15/029,122 patent/US10376812B2/en active Active
- 2014-10-22 WO PCT/JP2014/078150 patent/WO2015076052A1/ja active Application Filing
- 2014-10-22 EP EP14863253.2A patent/EP3072569B1/en active Active
- 2014-10-22 KR KR1020167013050A patent/KR101728651B1/ko active IP Right Grant
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JPH04322701A (ja) * | 1991-04-22 | 1992-11-12 | Ishikawajima Harima Heavy Ind Co Ltd | 多段遠心抽出器 |
JP2012196599A (ja) * | 2011-03-18 | 2012-10-18 | Kobe Steel Ltd | 流路構造体、流体の混合方法、抽出方法及び反応方法 |
JP2013103155A (ja) * | 2011-11-11 | 2013-05-30 | Kobe Steel Ltd | 流路構造体、分離方法、抽出方法及び反応方法 |
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CN106902547A (zh) * | 2017-04-10 | 2017-06-30 | 赣州科源甬致科技有限公司 | 一种从废旧电池中提取硫酸镍用新式节能型萃取装置 |
CN115475408A (zh) * | 2022-08-31 | 2022-12-16 | 中材锂膜(宁乡)有限公司 | 一种湿法隔膜萃取装置及工艺 |
CN115475408B (zh) * | 2022-08-31 | 2024-01-19 | 中材锂膜(宁乡)有限公司 | 一种湿法隔膜萃取装置及工艺 |
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EP3072569A1 (en) | 2016-09-28 |
CN105722573A (zh) | 2016-06-29 |
US10376812B2 (en) | 2019-08-13 |
KR20160070836A (ko) | 2016-06-20 |
US20160250565A1 (en) | 2016-09-01 |
KR101728651B1 (ko) | 2017-04-19 |
EP3072569B1 (en) | 2020-03-18 |
JP2015100718A (ja) | 2015-06-04 |
EP3072569A4 (en) | 2017-06-21 |
CN105722573B (zh) | 2017-11-24 |
JP5988504B2 (ja) | 2016-09-07 |
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