WO2017217402A1 - 養殖用または排水処理用超微細気泡発生装置 - Google Patents
養殖用または排水処理用超微細気泡発生装置 Download PDFInfo
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- WO2017217402A1 WO2017217402A1 PCT/JP2017/021789 JP2017021789W WO2017217402A1 WO 2017217402 A1 WO2017217402 A1 WO 2017217402A1 JP 2017021789 W JP2017021789 W JP 2017021789W WO 2017217402 A1 WO2017217402 A1 WO 2017217402A1
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- Prior art keywords
- liquid
- passage
- bubble generating
- gas
- bubble
- Prior art date
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- 238000009360 aquaculture Methods 0.000 title claims abstract description 30
- 244000144974 aquaculture Species 0.000 title claims abstract description 30
- 238000004065 wastewater treatment Methods 0.000 title claims abstract description 27
- 239000007788 liquid Substances 0.000 claims abstract description 139
- 230000006835 compression Effects 0.000 claims abstract description 37
- 238000007906 compression Methods 0.000 claims abstract description 37
- OKTJSMMVPCPJKN-UHFFFAOYSA-N Carbon Chemical compound [C] OKTJSMMVPCPJKN-UHFFFAOYSA-N 0.000 claims abstract description 21
- 229910052799 carbon Inorganic materials 0.000 claims abstract description 21
- 239000011148 porous material Substances 0.000 claims abstract description 13
- 238000005086 pumping Methods 0.000 claims abstract description 8
- 238000003756 stirring Methods 0.000 claims description 14
- 230000005465 channeling Effects 0.000 abstract 1
- 239000007789 gas Substances 0.000 description 93
- CBENFWSGALASAD-UHFFFAOYSA-N Ozone Chemical compound [O-][O+]=O CBENFWSGALASAD-UHFFFAOYSA-N 0.000 description 38
- QVGXLLKOCUKJST-UHFFFAOYSA-N atomic oxygen Chemical compound [O] QVGXLLKOCUKJST-UHFFFAOYSA-N 0.000 description 24
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- 229910052760 oxygen Inorganic materials 0.000 description 24
- 239000002351 wastewater Substances 0.000 description 12
- 238000000034 method Methods 0.000 description 11
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- 239000001257 hydrogen Substances 0.000 description 6
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- 241000251468 Actinopterygii Species 0.000 description 5
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- 238000011144 upstream manufacturing Methods 0.000 description 5
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- 229910010272 inorganic material Inorganic materials 0.000 description 3
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- QGZKDVFQNNGYKY-UHFFFAOYSA-N Ammonia Chemical compound N QGZKDVFQNNGYKY-UHFFFAOYSA-N 0.000 description 2
- VYPSYNLAJGMNEJ-UHFFFAOYSA-N Silicium dioxide Chemical compound O=[Si]=O VYPSYNLAJGMNEJ-UHFFFAOYSA-N 0.000 description 2
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- 239000010840 domestic wastewater Substances 0.000 description 2
- 239000010842 industrial wastewater Substances 0.000 description 2
- 238000006864 oxidative decomposition reaction Methods 0.000 description 2
- 230000001590 oxidative effect Effects 0.000 description 2
- -1 rivers and lakes Substances 0.000 description 2
- 238000010008 shearing Methods 0.000 description 2
- 239000000741 silica gel Substances 0.000 description 2
- 229910002027 silica gel Inorganic materials 0.000 description 2
- 239000002699 waste material Substances 0.000 description 2
- XSQUKJJJFZCRTK-UHFFFAOYSA-N Urea Chemical compound NC(N)=O XSQUKJJJFZCRTK-UHFFFAOYSA-N 0.000 description 1
- 230000001154 acute effect Effects 0.000 description 1
- 241001148470 aerobic bacillus Species 0.000 description 1
- 238000013019 agitation Methods 0.000 description 1
- 229910021529 ammonia Inorganic materials 0.000 description 1
- 239000004202 carbamide Substances 0.000 description 1
- 238000004140 cleaning Methods 0.000 description 1
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- 238000012258 culturing Methods 0.000 description 1
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- 150000004767 nitrides Chemical class 0.000 description 1
- 230000002093 peripheral effect Effects 0.000 description 1
- 238000001556 precipitation Methods 0.000 description 1
- 108090000765 processed proteins & peptides Proteins 0.000 description 1
- 238000000746 purification Methods 0.000 description 1
- 239000000758 substrate Substances 0.000 description 1
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Images
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Definitions
- the present invention relates to the technology of an ultrafine bubble generator for aquaculture or wastewater treatment for purifying wastewater or purifying aquaculture water and supplying oxygen to the aquaculture water, and in particular, aquaculture that generates fine bubbles in a liquid.
- an ultrafine bubble generator for aquaculture or wastewater treatment has been known.
- ultrafine bubble generating devices that supply oxygen to oxidize and purify nitrides such as ammonia and urea that inhibit growth when cultivating seafood are well known (for example, patent documents) 1).
- the supplied oxygen activates fishery products and promotes growth.
- an ultrafine bubble generating device that supplies oxygen, ozone, or the like to perform oxidative decomposition treatment of organic substances contained in the wastewater is known (for example, see Patent Document 2).
- ultrafine bubbles having a bubble size (diameter) of less than 100 ⁇ m at room temperature and normal pressure in liquids such as tap water, lakes, rivers, and seawater.
- the ultra-fine bubbles have a very large surface area and physicochemical characteristics such as a self-pressurizing effect, and are used for drainage purification, cleaning, gas dissolution, stirring, etc. by taking advantage of these characteristics.
- a liquid jet nozzle As a method of generating ultrafine bubbles having the above characteristics, a liquid jet nozzle has been conventionally arranged around a nozzle that discharges gas pumped by a compressor, and bubbles discharged from the nozzle by the force of the jet of the liquid jet nozzle are generated.
- the method of tearing and miniaturizing is known.
- a method of subdividing the bubbles while applying the aerated bubbles to the mesh member is also known (see, for example, Patent Document 3).
- the apparatus is large. For this reason, it was difficult to arrange in the liquid flow path.
- the ratio of the ultrafine bubbles in the liquid reaching the gas-liquid interface is relatively large, and the amount of gas that remains dissolved or coexists in the liquid is small.
- the present invention is capable of efficiently dissolving a gas in a liquid or allowing ultrafine bubbles to coexist, and increasing the concentration of the gas in the liquid.
- a bubble generator is provided.
- a passage for flowing a liquid a passage for flowing a liquid, a compression device for pumping gas to the passage, and a bubble generating medium that discharges the gas pumped by the compression device to the liquid in the passage as ultrafine bubbles
- An ultrafine bubble generating device for aquaculture or wastewater treatment wherein the bubble generating medium is formed of a carbon-based porous material, and is below horizontal with respect to the direction of liquid flow in the passage. It is arranged to become.
- the passage is constituted by at least one or more pipes
- the bubble generating medium is disposed in the pipe
- the pipe is a liquid that flows in the pipe. It may be formed so as to be arranged in series in a direction parallel to the direction.
- a collecting device for collecting the gas released from the liquid, and a retransmission for pumping the gas from the collecting device to the bubble generating medium A compression device for re-transmission, and the compression device for retransmission is configured to pump gas from the collection device to the bubble generating medium when the amount of gas collected by the collection device exceeds a predetermined amount. May be.
- a storage tank may be provided on the downstream side of the passage, and the storage tank may be provided with a stirring device.
- an internal space is formed inside the bubble generating medium, and the distance from the internal space to the surface of the bubble generating medium is such that the ratio of the shortest distance to the longest distance is 1: It may be configured to be 40 or less.
- the bubble generation medium is formed of a carbon-based porous member, a large amount of ultrafine bubbles can be generated without generating a liquid flow with a liquid jet nozzle or the like.
- the bubble generating medium is arranged so as to be horizontal or lower with respect to the liquid flow direction, the ultrafine bubbles are easily released downward, and the amount of gas that reaches the liquid surface and is released into the air. Can be reduced.
- the bubble generating medium in series in the liquid flow direction, the time for the liquid to contact the bubble generating medium is lengthened, and the liquid flow is effectively used to increase the concentration with less power. Ultrafine bubbles can coexist.
- the gas can be circulated without being released into the air and released again into the liquid.
- the organic matter contained in the wastewater when the organic matter contained in the wastewater is oxidatively decomposed in the storage tank, the organic matter contained in the wastewater can be prevented from being precipitated by agitation and efficiently discharged.
- an internal space is formed inside the bubble generating medium, and the distance from the internal space to the surface of the bubble generating medium is such that the ratio of the shortest distance to the longest distance is 1:40 or less.
- the front view which showed the whole structure of the ultrafine bubble generator which concerns on one Embodiment of this invention.
- the front sectional view of the pipe concerning the first embodiment of the present invention, and a bubble generation medium.
- the cross-section partially enlarged view of the bubble generating medium according to the first embodiment of the present invention.
- the front view of the bubble generation medium which concerns on 1st embodiment of this invention.
- the top view of the bubble generation medium which concerns on 1st embodiment of this invention.
- the front enlarged view of the bubble generation medium which concerns on 1st embodiment of this invention.
- the plane enlarged view of the bubble generation medium which concerns on 1st embodiment of this invention.
- tube which concerns on 1st embodiment of this invention.
- FIG. 10 is a cross-sectional view taken along line AA of a bubble generating medium according to a fifth embodiment of the present invention.
- the cross-section partially enlarged view of the bubble generating medium according to the fifth embodiment of the present invention.
- the ultrafine bubble generating device 1 is an aquatic bubble generating device for aquaculture or wastewater treatment, and is a device for generating ultrafine bubbles in a liquid.
- the ultrafine bubbles mean bubbles having a size (diameter) of less than 100 ⁇ m at normal temperature and normal pressure. As shown in FIG.
- the ultrafine bubble generating device 1 is a device that supplies a liquid in which a gas is dissolved or coexisted to a storage tank 11, and a passage 21 for flowing a liquid, A compression device 22 and a bubble generating medium 23 that discharges the gas pumped by the compression device 22 to the liquid in the passage 21 as ultrafine bubbles are provided.
- the storage tank 11 is a tank for storing a liquid in which gas is dissolved or coexisted as ultrafine bubbles.
- dissolved means a state in which a gas is dissolved in the liquid.
- coexistence means the state in which gas exists as a superfine bubble in a liquid.
- the liquid stored in the storage tank 11 is seawater or fresh water such as rivers and lakes if it is an aquaculture ultrafine bubble generator, and if it is an ultrafine bubble generator for wastewater treatment, Fresh water such as rivers and lakes, domestic wastewater, and industrial wastewater.
- the gas supplied to the storage tank 11 is air, oxygen, ozone, hydrogen peroxide or the like if it is an aquaculture ultrafine bubble generator, and if it is an ultrafine bubble generator for wastewater treatment, A gas having an oxidizing action, such as oxygen, ozone or hydrogen peroxide.
- the ultra-fine bubble generator for aquaculture fish and shellfish are cultured in the storage tank 11.
- culturing fish and shellfish in a liquid in which gas is dissolved or coexisted as ultrafine bubbles aerobic bacteria that decompose fish and shellfish excretion can be activated, and the liquid is purified. be able to.
- the immunity of the seafood to be cultivated can be improved, and the growth of the seafood can be promoted.
- wastewater is treated in the storage tank 11.
- bacteria or the like that decompose organic substances in the wastewater can be activated, and the liquid can be purified.
- the passage 21 is a member for passing a liquid.
- the upstream end of the passage 21 in the liquid flow is connected to a liquid tank, the sea, a river, or the like. Further, the middle part of the passage 21 is constituted by a pipe 25.
- the compression device 22 is a device for pumping gas to the bubble generating medium 23.
- the compression device 22 includes a gas storage container 22A that stores gas and a check valve 22B.
- the bubble generating medium 23 is disposed inside a tube 25 that constitutes the middle part of the passage 21.
- the bubble generating medium 23 is arranged to be horizontal or lower with respect to the direction in which the liquid in the tube 25 flows (the direction of the black arrow in FIG. 2).
- the bubble generating medium 23 is disposed so that the downstream side is inclined downward with respect to the longitudinal direction of the tube 25.
- the bubble generating medium 23 is made of a carbon-based porous material, and has a large number of fine holes 23A having a diameter of several ⁇ m to several tens of ⁇ m, as shown in FIG.
- the bubble generating medium 23 is a conductor, and the bubbles generated from the bubble generating medium 23 are charged with a negative charge.
- the carbon-based porous material is a composite material containing only carbon or carbon and ceramic, and is an inorganic material. A film having a thickness of several nm is formed on the surface of the carbon-based porous material. The film is formed of an inorganic film containing silicon.
- the bubble generating medium 23 is formed in a polygonal column shape, and a bubble generating medium passage 27 is formed therein as an internal space.
- the bubble generating medium inner passage 27 is provided inside the bubble generating medium 23, and is provided from two surfaces of the bubble generating medium 23 in parallel with the sides in the short direction when viewed from the front.
- an inclined passage 29 that connects the parallel passages 28 to each other.
- the parallel passage 28 includes a first parallel passage 28a having a large cross-sectional diameter and a second parallel passage 28b having a small cross-sectional diameter.
- the first parallel passage 28a is formed so as to penetrate through the bubble generating medium 23.
- One end of the second parallel passage 28b communicates with the surface (upper surface) of the bubble generating medium 23, and the other end of the second parallel passage 28b. It is arranged in the bubble generating medium 23.
- the first parallel passages 28a and the second parallel passages 28b are alternately arranged.
- the inclined passage 29 is a passage connecting the first parallel passage 28a and the second parallel passage 28b, and has an upper end of the first parallel passage 28a and a lower end (closed end) of the second parallel passage 28b. It is the channel
- the total surface area of the surface of the bubble generation medium 23 where bubbles are generated is formed to be 2000 cm 2 or less.
- the surface of the bubble generating medium 23 where bubbles are generated is the side surface excluding the upper and lower surfaces of the polygonal column, and the total surface area is approximately 1600 cm 2 .
- the distance between the surface of the bubble generation medium 23 (mainly the side surface excluding the upper and lower surfaces) and the bubble generation medium inner passage 27 is configured such that the ratio of the shortest distance to the longest distance is 1:40 or less. ing. As shown in FIGS. 6 and 7, in the present embodiment, the length Lmin at the place where the distance between the surface of the bubble generating medium 23 and the bubble generating medium passage 27 is the shortest is approximately 3.5 mm. In contrast, in the present embodiment, the length Lmax at the place where the distance between the surface of the bubble generation medium 23 and the bubble generation medium inner passage 27 is the longest is 140 mm or less.
- the length Lmax at the place where the distance between the surface of the bubble generating medium 23 and the bubble generating medium passage 27 is the longest is inclined with respect to the first parallel passage 28a of the bubble generating medium 23 in a front view.
- the distance from the intersection P of the bisector of the acute angle ⁇ provided between the passage 29 and the lower end surface of the bubble generating medium 23 to the bubble generating medium passage 27 is approximately 8 mm.
- the tube 25 and the bubble generating medium 23 can be provided as a unit 31 as shown in FIG.
- the unit 31 in which the bubble generating medium 23 is arranged inside the tube 25 is configured to be connectable in series in a direction parallel to the direction of the liquid flowing in the tube 25 (the direction of the black arrow in FIG. 2). That is, the cylindrical connection part 32 is provided in the upstream edge part and downstream edge part of the pipe
- FIG. By configuring in this way, the ultrafine bubbles can be further supplied by the fine bubble generator 1 to the liquid in which the ultrafine bubbles are already present.
- the ultrafine bubbles are recombined, so the amount of coexisting ultrafine bubbles is rather reduced.
- the bubble generating medium 23 in series in the liquid flow direction, the time for the liquid to contact the bubble generating medium 23 is lengthened, and the liquid flow is effectively used to reduce the high concentration with a small amount of power. Fine bubbles can coexist. Further, since the bubble generating medium 23 is arranged in series, it can coexist without recombining the ultrafine bubbles. By comprising in this way, the quantity of the ultrafine bubble which coexists in the liquid can be increased.
- a collection device 41 for collecting a gas released from the liquid is disposed on the downstream side of the passage 21.
- the collection device 41 is composed of a container, and an upper surface is provided with a discharge passage 42 for sending a gas released outside the liquid that does not dissolve or coexist in the liquid.
- a level sensor 45 is provided inside the collection device 41.
- the level sensor 45 is connected to a control device (not shown), and is a device that detects whether or not the height of the liquid in the collection device 41 is below a certain level.
- a water intake 43 is provided at the bottom of the collection device 41.
- the water intake 43 is a hole for taking out a liquid in which gas is dissolved or in which ultrafine bubbles coexist, and is connected to the storage tank 11 that performs wastewater treatment or aquaculture.
- a dehydrator 51 In the middle of the discharge passage 42, a dehydrator 51, a re-sending compressor 52, and a check valve 53 are provided.
- the retransmission compression device 52 is connected to a control device (not shown).
- the dehydrating device 51 is a device for adsorbing and desorbing moisture contained in the gas discharged to the discharge passage 42.
- the dehydrating device 51 is a device provided with a film for desorption and a water absorbing agent such as silica gel.
- the re-sending compressor 52 pumps the gas to the bubble generating medium 23 on the upstream side of the passage 21 only when the amount of the gas released outside the liquid in the collection device 41 exceeds a predetermined value.
- the compression device 22 and the compression device 52 for retransmission and the bubble generating medium 23 are connected by a gas passage 55, and an ozone generation device 56 is provided in the middle of the gas passage 55.
- the ozone generator 56 is a device that generates ozone from oxygen molecules by ultraviolet irradiation.
- a method for generating ultrafine bubbles by the ultrafine bubble generator 1 will be described. Specifically, a method for generating ultrafine bubbles when ozone is used as a gas will be described.
- oxygen is pumped from the compression device 22.
- the oxygen pumped from the compressor 22 is supplied into the ozone generator 56 through the gas passage 55.
- ozone generator 56 ozone is generated from oxygen, and ozone is supplied to the bubble generating medium passage 27 in the bubble generating medium 23.
- the ozone supplied to the bubble generation medium inner passage 27 passes through fine holes 23A having a diameter of several ⁇ m to several tens of ⁇ m provided in the bubble generation medium 23 to become ultrafine bubbles and is released into the liquid.
- the ultrafine bubbles released into the liquid are separated from the surface by the flow of the surrounding liquid (flow in the direction of the arrow in FIG. 3) at the moment when they are released onto the surface of the bubble generating medium 23.
- the bubble generating medium 23 is arranged so as to be horizontal or lower with respect to the liquid flow in the tube 25, the ultrafine bubbles easily move downward when being separated from the surface of the bubble generating medium 23. (In the direction of the white arrow in FIG. 2), it tends to accumulate downward. By comprising in this way, it will move to a liquid independently, without uniting with the ultrafine bubble generated later and the ultrafine bubble generated from the surrounding hole 23A.
- the aquaculture ultrafine bubble generating apparatus 1 since it is not necessary to use a powerful pump, noise generated in water can be suppressed, and stress on seafood can be reduced.
- the liquid in which ozone is dissolved or ultrafine bubbles coexist is temporarily stored in the downstream collection device 41.
- ozone that could not be dissolved or coexisted is released from the liquid surface to the outside of the liquid and collected in the collection device 41.
- the control device causes the retransmission compressor 52 to retransmit. To drive.
- the retransmission compression device 52 is driven, the ozone collected in the collection device 41 is adsorbed and desorbed by the dehydration device 51 and the gas passage 55 is again desorbed by the retransmission compression device 52. It is returned to the inside and supplied into the bubble generating medium 23.
- ozone released to the outside of the liquid can be dissolved or coexisted in the liquid again, and the amount of ultrafine bubbles present in the liquid can be increased. Further, since ozone released to the outside of the liquid is not released into the atmosphere, a harmful ozone treatment step can be omitted.
- the ozone generator 56 When oxygen or hydrogen is used as the gas, the ozone generator 56 is not driven, and the gas sent from the compressor 22 is pumped to the bubble generating medium 23 as it is. By configuring in this way, oxygen and hydrogen released to the outside of the liquid are not released into the atmosphere, so that oxygen and hydrogen can be used without waste.
- the liquid in which the gas is dissolved or coexists is sent to the storage tank 11 through the collection device 41.
- cultivation super fine bubble generating apparatus in the storage tank 11, fish and shellfish are cultured in the liquid which dissolved or coexisted gas.
- the storage tank 11 stores a liquid in which a gas is dissolved or coexists, and the action of the gas dissolved in the liquid or coexisted as an ultrafine bubble.
- the stored liquid is purified. More specifically, bacteria or the like that decompose organic substances in the wastewater can be activated by the action of the gas dissolved in the liquid or coexisted as ultrafine bubbles, and the liquid can be purified.
- the bubble generating medium 1 is formed of a carbon-based porous material and is horizontal with respect to the flow direction of the liquid in the passage 21. It is arranged to be as follows. With this configuration, the bubble generating medium 23 is formed of a carbon-based porous member, so that a large amount of ultrafine bubbles can be generated without generating a liquid flow with a liquid jet nozzle or the like. . In addition, since the bubble generating medium 23 is arranged so as to be horizontal or less with respect to the liquid flow direction, the ultrafine bubbles are easily released downward, and the gas that reaches the liquid surface and is released into the air. The amount can be reduced.
- the passage 21 is composed of at least one or more tubes 25, the bubble generating medium 23 is disposed in the tube 25, and the tube 25 is parallel to the direction of the liquid flowing in the tube 25. It is formed so that it can be arranged in series. By configuring in this way, by arranging the pipes 25 in series, it is possible to continuously release ultrafine bubbles in the liquid, to efficiently dissolve the gas in the liquid, or to coexist with the ultrafine bubbles. And the concentration of the gas in the liquid can be increased.
- a collection device 41 for collecting the gas released from the liquid, and a retransmission compression device 52 for pumping the gas from the collection device 41 to the bubble generating medium 23 are provided on the downstream side of the passage 21, a collection device 41 for collecting the gas released from the liquid, and a retransmission compression device 52 for pumping the gas from the collection device 41 to the bubble generating medium 23 are provided.
- the resending compression device 52 pressure-feeds the gas from the collection device 41 to the bubble generating medium 23 when the amount of gas collected by the collection device 41 exceeds a predetermined amount.
- the bubble generation medium passage 27 is formed inside the bubble generation medium 23, and the distance from the bubble generation medium passage 27 to the surface of the bubble generation medium 23 is 1 as the ratio of the shortest distance Lmin to the longest distance Lmax. : 40 or less.
- the bubble generating medium passage 27 is formed inside the bubble generating medium 23, and the distance from the bubble generating medium passage 27 to the surface of the bubble generating medium 23 is set to the shortest distance Lmin and the longest distance.
- the ratio to Lmax to be 1:40 or less, gas can be efficiently pumped to the surface of the bubble generating medium 23, and ultrafine bubbles are generated using the entire surface of the bubble generating medium 23. Can be made.
- the bubble generating medium 23 may be configured as shown in FIGS. As shown in FIG. 9, the bubble generating medium 23 is disposed inside a tube 25 that constitutes a midway portion of the passage 21. The bubble generating medium 23 is arranged to be horizontal or lower with respect to the direction in which the liquid in the tube 25 flows (the direction of the black arrow in FIG. 9). In the present embodiment, the bubble generating medium 23 is disposed so that the downstream side is inclined downward with respect to the longitudinal direction of the tube 25.
- the bubble generating medium 23 is made of a carbon-based porous material, and has a large number of fine holes 23A having a diameter of several ⁇ m to several tens of ⁇ m, as shown in FIG.
- the bubble generating medium 23 is a conductor, and the bubbles generated from the bubble generating medium 23 are charged with a negative charge.
- the carbon-based porous material is a composite material containing only carbon or carbon and ceramic, and is an inorganic material. A film having a thickness of several nm is formed on the surface of the carbon-based porous material. The film is formed of an inorganic film containing silicon.
- the bubble generating medium 23 is formed in a polygonal column shape, and a bubble generating medium passage 27 is formed therein as an internal space.
- the bubble generating medium inner passage 27 is provided inside the bubble generating medium 23, and is provided from two surfaces of the bubble generating medium 23 in parallel with the sides in the short direction when viewed from the front.
- an inclined passage 29 that connects the parallel passages 28 to each other.
- the parallel passage 28 includes a first parallel passage 28a having a large cross-sectional diameter and a second parallel passage 28b having a small cross-sectional diameter.
- One end of the first parallel passage 28 a communicates with the surface (upper surface) of the bubble generating medium 23 and is connected to the gas passage 55.
- one of the first parallel passages 28a is the first parallel passage 28a disposed at the end in the left-right direction.
- the other first parallel passage 28 a is disposed in the bubble generating medium 23 at both ends.
- both ends of the second parallel passage 28 b are disposed in the bubble generating medium 23.
- the first parallel passages 28a and the second parallel passages 28b are alternately arranged.
- the inclined passage 29 is a passage connecting the first parallel passage 28a and the second parallel passage 28b, and has an upper end of the first parallel passage 28a and a lower end (closed end) of the second parallel passage 28b. It is the channel
- the total surface area of the surface of the bubble generation medium 23 where bubbles are generated is formed to be 2000 cm 2 or less.
- the surface of the bubble generating medium 23 where bubbles are generated is the side surface excluding the upper and lower surfaces of the polygonal column, and the total surface area is approximately 1600 cm 2 .
- the gas supplied from the compression device 22 via the gas passage 55 is sent to the first parallel passage 28a disposed at the end in the left-right direction. A part of the gas sent to the first parallel passage 28 a is sent to the adjacent inclined passage 29. A part of the gas sent to the inclined passage 29 is sent to the adjacent second parallel passage 28 b, and a part of the gas is sent to the adjacent inclined passage 29. As a result, the gas is evenly sent to the entire bubble generating medium passage 27.
- the distance between the surface of the bubble generation medium 23 (mainly the side surface excluding the upper and lower surfaces) and the bubble generation medium inner passage 27 is configured such that the ratio of the shortest distance to the longest distance is 1:40 or less. ing.
- the length Lmin at the place where the distance between the surface of the bubble generation medium 23 and the bubble generation medium inner passage 27 is the shortest is approximately 3.5 mm.
- the length Lmax at the place where the distance between the surface of the bubble generation medium 23 and the bubble generation medium inner passage 27 is the longest is 140 mm or less.
- the storage tank 11 may preferably be provided with a stirring device 61.
- the stirring device 61 is provided at the lower part of the storage tank 11 and is a device for stirring the liquid in which the gas in the storage tank 11 is dissolved or in which ultrafine bubbles coexist.
- the stirring method of the stirring device 61 is not limited.
- the stirring device 61 includes an aeration type stirring device that stirs by aeration or a rotary type stirring device that stirs by a rotating flow generated by the rotation of a propeller. Is done.
- the structure which has the filtration membrane 71 for filtering the organic substance in the storage tank 11 may be sufficient in the ultrafine-bubble generator 1 for wastewater treatment.
- the filtration membrane 71 is provided in the vicinity of a discharge hole for discharging the wastewater treated in the storage tank 11.
- subjected the same number as 1st embodiment is the structure similar to 1st embodiment, description is abbreviate
- the organic matter decomposed using the ultrafine bubbles is converted into a peptide (miniaturized). For this reason, the organic matter remains in the treated water, causing turbidity and difficult to precipitate. Therefore, by providing a filtration membrane in the storage tank 11, it is possible to remove peptided organic substances and increase the efficiency of wastewater treatment.
- the ultrafine bubble generation device 101 is an aquaculture bubble generation device for aquaculture or wastewater treatment, and is a device for generating ultrafine bubbles in a liquid.
- the ultrafine bubbles mean bubbles having a size (diameter) of less than 100 ⁇ m at normal temperature and normal pressure.
- the ultrafine bubble generating device 101 is a device that dissolves gas in the liquid in the storage tank 111 or coexists the ultrafine bubbles, and the gas is supplied to the passage 21 and the passage 21.
- a rotary bubble generator 123 that discharges the gas pumped by the compressor 22 to the liquid in the storage tank 111 as ultrafine bubbles.
- the storage tank 111 is a tank for storing a liquid in which gas is dissolved or coexisted as ultrafine bubbles.
- dissolved means a state in which a gas is dissolved in the liquid.
- coexistence means the state in which gas exists as a superfine bubble in a liquid.
- the liquid stored in the storage tank 111 is seawater or fresh water such as a river or a lake if it is an aquaculture ultrafine bubble generator, and if it is a superfine bubble generator for wastewater treatment, Fresh water such as rivers and lakes, domestic wastewater, and industrial wastewater.
- the gas supplied to the storage tank 111 is air, oxygen, ozone, hydrogen peroxide, or the like if it is an aquaculture ultrafine bubble generator, and if it is an ultrafine bubble generator for wastewater treatment, A substrate having an oxidizing action, for example, oxygen, ozone or hydrogen peroxide.
- the passage 21 is a member for passing a liquid.
- the upstream end of the passage 21 in the liquid flow is connected to a liquid tank, the sea, a river, or the like.
- the compression device 22 is a device for pumping gas to the rotary bubble generating device 123.
- the compression device 22 includes a gas storage container 22A that stores gas and a check valve 22B.
- the rotary bubble generator 123 is a device for generating ultrafine bubbles in a liquid.
- the ultrafine bubbles mean bubbles having a size (diameter) of less than 100 ⁇ m at normal temperature and normal pressure.
- the rotary bubble generator 123 is a device that supplies gas into the storage tank 111 as ultrafine bubbles, and is provided so as not to rotate relative to the rotary shaft 124 and the rotary shaft 124.
- a bubble generating medium 127 fixed to the rotating body 125.
- the rotary bubble generating device 123 When the rotary bubble generating device 123 is used, the part from the middle to the lower part of the rotating shaft 124 is arranged in the liquid in the storage tank 111.
- an internal passage 126 for passing the gas pumped from the compression device 22 is provided inside the rotating shaft 124 and the rotating body 125.
- the internal passage 126 is a bubble generating medium internal passage 128 in the bubble generating medium 127. It is connected to the.
- the bubble generating medium 127 is disposed inside the storage tank 111.
- the bubble generating medium 127 is made of a carbon-based porous material, and has a large number of fine holes 127A having a diameter of several ⁇ m to several tens of ⁇ m, as shown in FIG.
- the bubble generating medium 127 is a conductor, and the bubbles generated from the bubble generating medium 127 are charged with negative charges. In other words, when free electrons are added to the ultrafine bubbles when passing through the bubble generating medium 127 that is a conductor, a negative charge is charged. This negative charge can prevent bubbles from repelling each other and coalescing into large bubbles.
- the carbon-based porous material is a composite material containing only carbon or carbon and ceramic, and is an inorganic material.
- a film having a thickness of several nm is formed on the surface of the carbon-based porous material.
- the film is formed of an inorganic film containing silicon.
- the bubble generating medium 127 is formed in a plate shape (substantially streamlined in cross section) so that the thickness at the beginning of the rotation direction (arrow direction in FIG. 16) is thick and the thickness at the end in the rotation direction is thin. .
- the bubble generating medium 127 can be fixed by rotating in the vertical direction, whereby the inclination angle of the bubble generating medium 127 can be freely changed. In this embodiment, as shown in FIG. 17, it arrange
- the liquid in contact with the lower surface of the bubble generating medium 127 flows downward on the lower side of the bubble generating medium 127, thereby causing a downward liquid flow, and on the upper side of the bubble generating medium 127.
- the liquid flows along the upper surface of the bubble generating medium 127, thereby generating a downward liquid flow.
- a downward liquid flow can be caused and the liquid can be stirred.
- Even when a downward liquid flow is caused normal bubbles once sink downward and then rise upward again. Therefore, it is necessary to apply a large pressure to send the bubbles downward.
- it is possible to easily send the ultrafine bubbles downward by merely causing a downward liquid flow by utilizing the property of the ultrafine bubbles having small buoyancy.
- the bubble generating medium 127 is provided with a bubble generating medium passage 128.
- the bubble generating medium internal passage 128 is provided inside the bubble generating medium 127, and extends in the short direction of the bubble generating medium 127, and the first passage 128a.
- a plurality of second passages 128b extending from the middle to the longitudinal direction of the bubble generating medium 127 are provided.
- One end of the bubble generating medium passage 128 is connected to the internal passage 126.
- the total surface area of the surface of the bubble generating medium 127 where bubbles are generated is formed to be 2000 cm 2 or less.
- the surfaces of the bubble generating medium 127 where the bubbles are generated are two upper and lower surfaces, and the total surface area is approximately 1600 cm 2 .
- the distance between the surface of the bubble generation medium 127 and the bubble generation medium passage 128 is configured such that the ratio of the shortest distance to the longest distance is 1:40 or less.
- a level sensor 145 is provided inside the storage tank 111.
- the level sensor 145 is connected to a control device (not shown), and is a device that detects whether or not the height of the liquid in the storage tank 111 has become a certain level or less.
- a dehydrator 151 In the middle of the discharge passage 131, a dehydrator 151, a retransmission compressor 152, and a check valve 153 are provided.
- the retransmission compressor 152 is connected to a control device (not shown).
- the dehydrating device 151 is a device for adsorbing and desorbing moisture contained in the gas discharged to the discharge passage 131.
- the dehydrating device 151 is a device including a film for desorption and a water absorbing agent such as silica gel.
- the re-sending compressor 152 pumps the gas to the rotary bubble generator 123 only when the amount of the gas released from the liquid in the storage tank 111 exceeds a predetermined value.
- the compression device 22, the retransmission compression device 152, and the rotary bubble generation device 123 are connected by a passage 21, and an ozone generation device 157 is provided in the middle of the passage 21.
- the ozone generator 157 is a device that generates ozone from oxygen molecules by ultraviolet irradiation.
- a method for generating ultrafine bubbles by the ultrafine bubble generating apparatus 101 will be described. Specifically, a method for generating ultrafine bubbles when ozone is used as a gas will be described.
- oxygen is pumped from the compression device 22.
- the oxygen pumped from the compressor 22 is supplied into the ozone generator 157 through the gas passage.
- ozone generator 157 ozone is generated from oxygen, and the ozone is supplied to the rotary bubble generator 123.
- the ozone supplied to the rotary bubble generating device 123 is supplied to the bubble generating medium inner passage 128 through the internal passage 126 and passes through the fine holes 127A having a diameter of several ⁇ m to several tens ⁇ m provided in the bubble generating medium 127.
- the storage tank 111 In the storage tank 111, ozone that could not be dissolved or coexisted is released from the liquid surface to the outside of the liquid and is stored above the storage tank 111.
- the retransmission device 152 is driven by the control device.
- the retransmission compression device 152 When the retransmission compression device 152 is driven, the ozone accumulated in the storage tank 111 is adsorbed and desorbed by the dehydration device 151, and returned to the passage 21 again by the retransmission compression device 152. And supplied into the rotary bubble generator 123.
- ozone released to the outside of the liquid can be dissolved or coexisted in the liquid again, and the amount of ultrafine bubbles present in the liquid can be increased. Further, since ozone released to the outside of the liquid is not released into the atmosphere, a harmful ozone treatment step can be omitted.
- the ozone generator 157 is not driven, and the gas sent from the compressor 22 is directly pumped to the rotary bubble generator 123.
- oxygen and hydrogen released to the outside of the liquid are not released into the atmosphere, so that oxygen and hydrogen can be used without waste.
- an ultrafine bubble generating device for aquaculture fish and shellfish are cultivated in a liquid in which gas is dissolved or coexisted in the storage tank 111.
- the storage tank 111 stores a liquid in which a gas is dissolved or coexists, and the action of the gas dissolved in the liquid or coexisted as an ultrafine bubble.
- the stored liquid is purified. More specifically, bacteria or the like that decompose organic substances in the wastewater can be activated by the action of the gas dissolved in the liquid or coexisted as ultrafine bubbles, and the liquid can be purified.
- the present invention can be used for the technology of an ultrafine bubble generating apparatus for aquaculture or wastewater treatment for purifying wastewater or purifying aquaculture water and supplying oxygen to the aquaculture water. It can be used for the technology of an ultrafine bubble generator for aquaculture or wastewater treatment that generates water.
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Abstract
Description
次に、発明の実施の形態を説明する。
まず、本発明の一実施形態にかかる超微細気泡発生装置1の全体構成について図1を用いて説明する。
超微細気泡発生装置1は、養殖用または排水処理用の超微細気泡発生装置であり、液体中において超微細気泡を発生させるための装置である。ここで超微細気泡とは、常温常圧化においてサイズ(直径)が100μm未満の気泡を意味する。超微細気泡発生装置1は、図1に示すように、気体を溶存または共存させた液体を貯留槽11へ供給する装置であり、液体を流す通路21と、通路21へ気体を圧送するための圧縮装置22と、圧縮装置22により圧送された気体を超微細気泡として通路21内の液体へ放出する気泡発生媒体23とを備える。
ここで、溶存とは、液体内に気体が溶解して存在する状態を意味する。また、共存とは、気体が液体内に超微細気泡として存在する状態を意味する。
貯留槽11に貯留される液体は、養殖用の超微細気泡発生装置であれば、海水や、河川や湖沼などの淡水であり、排水処理用の超微細気泡発生装置であれば、海水や、河川や湖沼などの淡水や、生活排水や、工業排水等である。
また、貯留槽11に供給される気体は、養殖用の超微細気泡発生装置であれば、空気、酸素、オゾンまたは過酸化水素などであり、排水処理用の超微細気泡発生装置であれば、酸化作用を有する気体であり、例えば、酸素、オゾンまたは過酸化水素である。
炭素系の多孔質素材とは、炭素のみ若しくは炭素及びセラミックを含む複合素材であり、無機質の素材である。また、炭素系の多孔質素材の表面には、厚さ数nmの膜が形成されている。前記膜はケイ素を含む無機質の膜で形成されている。
捕集装置41の内部には、レベルセンサ45が設けられている。レベルセンサ45は、図示せぬ制御装置に接続されており、捕集装置41内の液体の高さが一定以下となったか否かを検知する装置である。
まず、圧縮装置22から酸素を圧送する。圧縮装置22から圧送された酸素は、気体通路55を通ってオゾン発生装置56内へ供給される。オゾン発生装置56内で、酸素からオゾンが生成され、オゾンが気泡発生媒体23内の気泡発生媒体内通路27へ供給される。気泡発生媒体内通路27へ供給されたオゾンは、気泡発生媒体23に設けられた直径数μm~数十μmの細かな孔23Aを通って、超微細気泡となり液体中へ放出される。液体中へ放出される超微細気泡は、気泡発生媒体23表面に放出された瞬間に、周りの液体の流れ(図3の矢印方向の流れ)によって、表面から離間される。このとき、気泡発生媒体23は、管25の液体の流れに対して水平以下となるように配置しているので、超微細気泡は気泡発生媒体23表面から離間する際に下方へ移動しやすくなり(図2の白塗り矢印方向)、下方に溜まり易くなる。このように構成することにより、後から発生する超微細気泡や周辺の孔23Aから発生する超微細気泡と合体することなく単独で液体中へ移動することとなる。また、養殖用の超微細気泡発生装置1においては、強力なポンプを用いる必要が無いため、水中で発生する騒音を抑えることができ、魚介類へのストレスを軽減することができる。
このように構成することにより、液体外へ放出される酸素及び水素を大気中に放出することが無いので、酸素及び水素を無駄なく用いることが可能となる。
そして、養殖用の超微細気泡発生装置の場合は、貯留槽11において、気体を溶存または共存させた液体内において魚介類を養殖する。
また、排水処理用の超微細気泡発生装置の場合は、貯留槽11において、気体を溶存または共存させた液体を貯留し、液体中に溶存させた、または超微細気泡として共存させた気体の作用により、貯留した液体を浄化するものである。より詳細には、液体中に溶存させた、または超微細気泡として共存させた気体の作用により、排水中の有機物を分解するバクテリア等を活性化させることができ、液体を浄化させることができる。
このように構成することにより、気泡発生媒体23を炭素系素材の多孔質部材で形成したことにより、液体ジェットノズルなどで液体流を発生させることなく、多量の超微細気泡を発生させることができる。また、気泡発生媒体23が液体の流れる方向に対して水平以下となるように配置したことにより、超微細気泡が下方へ放出されやすくなり、液体表面に到達して空気中に放出される気体の量を減らすことができる。
このように構成することにより、管25を直列に配置することにより、液体中に連続的に超微細気泡を放出することができ、液体内に効率よく気体を溶存させる、または超微細気泡を共存させることができ、液体内の気体の濃度を高めることができる。
このように構成することにより、気体を空気中に放出することなく循環させて液体中に再び放出することができる。
このように構成することにより、気泡発生媒体23の内部に気泡発生媒体内通路27を形成し、気泡発生媒体内通路27から気泡発生媒体23表面までの距離を、最も短い距離Lminと最も長い距離Lmaxとの比が1:40以下となるように構成したことにより、気泡発生媒体23の表面に効率よく気体を圧送することができ、気泡発生媒体23の表面全面を用いて超微細気泡を発生させることができる。
また、第二の実施形態として、図9から図11に示すように、気泡発生媒体23を構成してもよい。
気泡発生媒体23は、図9に示すように、通路21の中途部を構成する管25の内部に配置されている。気泡発生媒体23は、管25の液体が流れる方向(図9の黒塗り矢印方向)に対して水平以下となるように配置されている。本実施形態においては、気泡発生媒体23は、管25の長手方向に対して下流側が下方へ傾くように配置されている。
炭素系の多孔質素材とは、炭素のみ若しくは炭素及びセラミックを含む複合素材であり、無機質の素材である。また、炭素系の多孔質素材の表面には、厚さ数nmの膜が形成されている。前記膜はケイ素を含む無機質の膜で形成されている。
また、第三の実施形態として、図12に示すように、貯留槽11には、好ましくは撹拌装置61を設けてもよい。ここで、第一実施形態と同一の番号を付した部分は第一実施形態と同様の構成であるので説明を省略する。
撹拌装置61は、貯留槽11の下部に設けられており、貯留槽11内の気体が溶存する、または、超微細気泡が共存する液体を撹拌するための装置である。なお、撹拌装置61の撹拌方法は限定されるものではなく、例えば、撹拌装置61は、曝気により撹拌する曝気型撹拌装置や、プロペラの回転により生み出される回転流により撹拌する回転型撹拌装置で構成される。
このように構成することにより、排水処理においては、貯留槽11で排水に含まれる有機物の酸化分解処理を行う際に、撹拌により有機物の沈殿を防止し効率よく排水処理を行うことができる。
また、第四の実施形態として、図13に示すように、排水処理用の超微細気泡発生装置1において、貯留槽11内の有機物を濾過するための濾過膜71を有する構成であってもよい。濾過膜71は、例えば貯留槽11内で処理した排水を排出するための排出孔付近に設けられている。ここで、第一実施形態と同一の番号を付した部分は第一実施形態と同様の構成であるので説明を省略する。
超微細気泡を用いて分解された有機物はペプチド化(微細化)する。このため、有機物は処理水内に残って濁りの原因となり、沈殿し難くなる。そこで、貯留槽11に濾過膜を設けることで、ペプチド化した有機物を除去することができ、排水処理の効率を上げることができる。
次に、第五の実施形態にかかる超微細気泡発生装置101について図14から図18を用いて詳細に説明する。ここで、第一実施形態と同一の番号を付した部分は第一実施形態と同様の構成であるので説明を省略する。
ここで、溶存とは、液体内に気体が溶解して存在する状態を意味する。また、共存とは、気体が液体内に超微細気泡として存在する状態を意味する。
貯留槽111に貯留される液体は、養殖用の超微細気泡発生装置であれば、海水や、河川や湖沼などの淡水であり、排水処理用の超微細気泡発生装置であれば、海水や、河川や湖沼などの淡水や、生活排水や、工業排水等である。
また、貯留槽111に供給される気体は、養殖用の超微細気泡発生装置であれば、空気、酸素、オゾンまたは過酸化水素などであり、排水処理用の超微細気泡発生装置であれば、酸化作用を有する基体であり、例えば、酸素、オゾンまたは過酸化水素である。
回転軸124及び回転体125の内部には、圧縮装置22から圧送された気体を通すための内部通路126が設けられており、内部通路126は、気泡発生媒体127内の気泡発生媒体内通路128に接続されている。
炭素系の多孔質素材とは、炭素のみ若しくは炭素及びセラミックを含む複合素材であり、無機質の素材である。また、炭素系の多孔質素材の表面には、厚さ数nmの膜が形成されている。前記膜はケイ素を含む無機質の膜で形成されている。
このように構成することにより、気泡発生媒体127の下側においては、気泡発生媒体127の下面と接触した液体が下側に流れることにより、下向きの液体流が起こり、気泡発生媒体127の上側においては、気泡発生媒体127の上面に沿って液体が流れることにより、下向きの液体流が発生する。これにより、気泡発生媒体127を回転させることで下向きの液体流を起こし、液体を攪拌することもできる。
下向きの液体流を起こした場合であっても、通常の気泡であれば一旦下方へ沈んだ後再び上方へ浮上するため、大きな圧力をかけて気泡を下方へ送る必要があった。しかし、本実施形態によれば、超微細気泡の浮力の小さい性質を利用して、下向きの液体流を起こすだけで超微細気泡を容易に下方まで送ることができる。
また、気泡発生媒体127の表面と気泡発生媒体内通路128との距離は最も短い距離と最も長い距離との比が1:40以下となるように構成している。
貯留槽111の内部には、レベルセンサ145が設けられている。レベルセンサ145は、図示せぬ制御装置に接続されており、貯留槽111内の液体の高さが一定以下となったか否かを検知する装置である。
まず、圧縮装置22から酸素を圧送する。圧縮装置22から圧送された酸素は、気体通路を通ってオゾン発生装置157内へ供給される。オゾン発生装置157内で、酸素からオゾンが生成され、オゾンが回転型気泡発生装置123へ供給される。回転型気泡発生装置123に供給されたオゾンは、内部通路126を介して気泡発生媒体内通路128へ供給され、気泡発生媒体127に設けられた直径数μm~数十μmの細かな孔127Aを通って、超微細気泡となり液体中へ放出される。回転する気泡発生媒体127と周りの液体との間に生まれた流れ(図17の矢印方向の流れ)によって、表面から離間される。このように構成することにより、後から発生する超微細気泡や周辺の孔127Aから発生する超微細気泡と合体することなく単独で液体中へ移動することとなる。
このように構成することにより、液体外へ放出される酸素及び水素を大気中に放出することが無いので、酸素及び水素を無駄なく用いることが可能となる。
また、排水処理用の超微細気泡発生装置の場合は、貯留槽111において、気体を溶存または共存させた液体を貯留し、液体中に溶存させた、または超微細気泡として共存させた気体の作用により、貯留した液体を浄化するものである。より詳細には、液体中に溶存させた、または超微細気泡として共存させた気体の作用により、排水中の有機物を分解するバクテリア等を活性化させることができ、液体を浄化させることができる。
11 貯留槽
21 通路
22 圧縮装置
23 気泡発生媒体
25 管
27 気泡発生媒体内通路
41 捕集装置
45 レベルセンサ
52 再送用圧縮装置
53 逆止弁
Claims (5)
- 液体を流す通路と、前記通路へ気体を圧送するための圧縮装置と、前記圧縮装置により圧送された気体を超微細気泡として前記通路内の液体へ放出する気泡発生媒体とを備える養殖または排水処理用の超微細気泡発生装置であって、
前記気泡発生媒体は、炭素系の多孔質素材で形成されており、前記通路内において液体の流れる方向に対して水平以下となるように配置された、
ことを特徴とする養殖または排水処理用の超微細気泡発生装置。 - 前記通路は、少なくとも一以上の管で構成されており、前記気泡発生媒体は、前記管内に配置されており、前記管は、前記管内を流れる液体の方向と平行な方向に直列に配置可能に形成された、
ことを特徴とする請求項1に記載の養殖または排水処理用の超微細気泡発生装置。 - 前記通路の下流側に、液体から放出される気体を捕集するための捕集装置と、前記捕集装置から気体を前記気泡発生媒体へ圧送する再送用圧縮装置とを設け、
前記再送用圧縮装置は、前記捕集装置で捕集された気体が所定量以上となった場合、前記捕集装置から気体を前記気泡発生媒体へ圧送する、
ことを特徴とする請求項2に記載の養殖または排水処理用の超微細気泡発生装置。 - 前記通路の下流側に、貯留槽を設け、前記貯留槽には、撹拌装置を設けた、
ことを特徴とする請求項3に記載の超微細気泡発生装置。 - 前記気泡発生媒体の内部に内部空間を形成し、前記内部空間から気泡発生媒体表面までの距離は、最も短い距離と最も長い距離との比が1:40以下となるように構成した、
ことを特徴とする請求項1から4のいずれか一項に記載の超微細気泡発生装置。
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DE102020002445A1 (de) | 2020-04-23 | 2021-10-28 | Messer Austria Gmbh | Verfahren und Vorrichtung zur Herstellung von gebleichtem Zellstoff |
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Also Published As
Publication number | Publication date |
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MY191545A (en) | 2022-06-30 |
CA3027660C (en) | 2020-09-29 |
JPWO2017217402A1 (ja) | 2019-10-17 |
CN109310958B (zh) | 2021-12-14 |
JP6815397B2 (ja) | 2021-01-20 |
EP3485968A4 (en) | 2020-02-12 |
US11084003B2 (en) | 2021-08-10 |
CA3027660A1 (en) | 2017-12-21 |
EP3485968B1 (en) | 2024-07-31 |
EP3485968A1 (en) | 2019-05-22 |
CN109310958A (zh) | 2019-02-05 |
US20190262783A1 (en) | 2019-08-29 |
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