JP2011050813A - Method for producing oil adsorbing particle and water treatment method using the particle - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an oil adsorbing particle which efficiently adsorbs the oil, that is included in factory effluents or domestic waste water or flows in rivers or the ocean, and the components of which do not contaminate the treated water and to provide a water treatment method using the oil adsorbing particle. <P>SOLUTION: A method for producing the oil adsorbing particle comprises the steps of: dispersing a carrier uniformly in a polymer emulsion; withdrawing the dispersed carrier from the polymer emulsion; removing the water contained in the withdrawn carrier; and granulating the water-removed carrier to obtain the oil adsorbing particle. The water treatment method using the oil adsorbing particle comprises a step of dispersing/immersing the oil adsorbing particle in oil-including waste water so that the oil in the waste water is adsorbed on the oil adsorbing particle and the oil-adsorbed oil adsorbing particle is removed. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to a method for producing an oil adsorbing powder.

  Wastewater discharged from factories, restaurants, general houses, etc. often contains pollutants, especially mineral oils and vegetable oils, and is a major problem from the viewpoint of environmental protection due to spills into rivers and oceans. It was. Generally, removal of oil that has flowed in large quantities into rivers, oceans, and the like is performed by preventing oil from diffusing using an oil fence and collecting the oil in the oil fence. Furthermore, a method of adsorbing, solidifying and recovering an oil component with an oil gelling agent or the like is also performed. However, it is difficult to adsorb and immobilize oil when the river flow rate is high or the ocean is rough. In such a case, the oil that could not be fixed drifts to the coast and has a great impact on seabirds and marine resources. In particular, the impact on living creatures in the surrounding area was very large, and the impact of the ecosystem was immeasurable.

  On the other hand, in a wastewater treatment facility that removes oil from wastewater in which a minute amount of oil is diffused in water, it is common to remove the oil by filtering with a filter. However, in such a method, there is a problem that the filter is frequently clogged by the oil contained in the waste water, and the time and cost for maintenance of the waste water treatment apparatus such as filter replacement are large.

  In addition, when a large amount of oil is mixed in the wastewater, the oil may be separated and exist in the upper layer of the wastewater. In such a case, if the filter is used as it is, the filter will be immediately clogged. Therefore, it is difficult to spray organic oil adsorbents such as lipophilic polymers, or inorganic adsorbents such as silica and pearlite, and then filter them. Processing was necessary. In addition, the organic adsorbent may be difficult to recover after being sprayed, and as a result, the inorganic adsorbent cannot obtain a sufficient adsorbing capacity, and it has been a problem to treat the adsorbed oil.

  Various attempts have been made to solve the problems caused by such adsorbents. Examples of the method for adsorbing oil in water include a method in which oil is adsorbed using an adsorbing polymer having a hydrophilic block and a lipophilic block, and then the adsorbing polymer is removed from water. Such a polymer is disclosed in Patent Document 1, for example. However, this method not only requires labor to separate the adsorbed polymer and water, but also has the problem that the polymer adsorbed with oil is softened and the workability is poor.

  On the other hand, a method is also known in which magnetized adsorptive particles are used to separate the adsorptive particles after adsorbing oils using magnetism. For example, Patent Document 2 discloses a method in which the surface of a magnetic material is modified with stearic acid, and oil in water is adsorbed to the magnetic material and recovered. However, this method uses a low molecular weight compound such as stearic acid or a silane coupling agent to modify the surface of the magnetic material, so that there is a high possibility that these low molecular weight compounds will contaminate water. .

Japanese Patent Application Laid-Open No. 07-102238 JP 2000-176306 A

  The present invention is an oil-adsorbing particle that efficiently adsorbs oil contained in factory wastewater or household wastewater, or oil that has flowed into rivers, oceans, etc., and contaminates treated water with components contained in the oil-adsorbing particles. It is an object of the present invention to provide an oil adsorbing particle that does not spill and a water treatment method using the same.

  One aspect of the present invention comprises a step of uniformly dispersing a carrier in a polymer emulsion, and a step of removing the carrier from the polymer emulsion, heat-vaporizing the contained water, and then granulating. The present invention relates to a method for producing oil-adsorbing particles.

  One embodiment of the present invention includes a step of immersing the oil-adsorbing particles in waste water to adsorb the oil in the waste water, and magnetically separating the oil-adsorbing particles from the waste water after adsorbing the oil. And a step of collecting the water treatment method.

  According to the present invention, oil-adsorbing particles that efficiently adsorb oil contained in factory wastewater or household wastewater, or oil that has flowed into rivers, oceans, etc., and water treated by the components contained in the oil-adsorbing particles It is possible to provide oil-adsorbing particles that do not contaminate water and a water treatment method using the same.

It is a schematic block diagram which shows an example of the water treatment apparatus in this embodiment. It is a schematic block diagram which shows the other example of the water treatment apparatus in this embodiment.

(Uniform dispersion)
In this embodiment, first, the carrier is uniformly dispersed in the polymer emulsion. The uniform dispersion is performed using a dispersion apparatus such as a bead mill.

(Carrier)
The carrier in the present embodiment is appropriately selected from those that do not cause a large chemical change even when immersed in water for a long time. For example, fused silica, crystalline silica, glass, talc, alumina, calcium silicate, calcium carbonate, barium sulfate, magnesia, silicon nitride, boron nitride, aluminum nitride, magnesium oxide, beryllium oxide, mica and other ceramic particles, and aluminum Further, metal particles such as iron, copper, and alloys thereof, and oxides thereof such as magnetite, titanite, pyrrhotite, magnesia ferrite, cobalt ferrite, nickel ferrite, barium ferrite, and the like can be used.

  In particular, as described below, the carrier preferably contains a magnetic substance because it is advantageous when recovering the oil-adsorbing particles.

  The magnetic material is not particularly limited, but is preferably a substance exhibiting ferromagnetism in a room temperature region. However, the present embodiment is not limited thereto, and ferromagnetic materials can be generally used. For example, iron and alloys containing iron, magnetite, titanite, pyrrhotite, magnesia ferrite, Examples thereof include cobalt ferrite, nickel ferrite, and barium ferrite.

Of these, ferrite compounds having excellent stability in water can achieve the present invention more effectively. For example, magnetite (Fe ₃ O ₄ ), which is a magnetite, is preferable because it is not only inexpensive, but also stable as a magnetic substance in water and safe as an element, so that it can be easily used for water treatment.

  In this case, the magnetic body is configured as a magnetic powder, and can take various shapes such as a spherical shape, a polyhedron, and an indefinite shape, but is not particularly limited. In addition, the particle size and shape as a desirable magnetic powder may be appropriately selected in view of manufacturing costs, and a polyhedral structure having a spherical shape or rounded corners is particularly preferable.

  If the particles have sharp corners, the polymer layer that covers the surface after subsequent spraying may be damaged, making it difficult to maintain the shape of the resin composite, that is, the desired oil-adsorbing particles. is there. These magnetic powders may be subjected to ordinary plating treatment such as Cu plating and Ni plating if necessary. Moreover, the surface may be surface-treated for the purpose of corrosion prevention.

  In this embodiment, it is not necessary for all of the carriers to be made of a magnetic material. That is, a very fine magnetic powder may be bonded with a binder such as a resin. Further, the surface of the magnetic powder may be subjected to a hydrophobic treatment with an alkoxysilane compound such as methyltrimethoxysilane, methyltriethoxysilane, phenyltrimethoxysilane, or phenyltriethoxysilane. That is, as will be described later, when the functional particles finally obtained are recovered by magnetic force in water treatment, it is only necessary to contain a magnetic material that can exert magnetic force.

  Moreover, the magnitude | size of magnetic powder changes with the density of magnetic powder other than a magnetic force of a processing facility, a flow rate, and an adsorption method, and various conditions. However, the average particle diameter of the magnetic powder in this embodiment is generally 0.05 to 100 μm. The average particle diameter of the magnetic powder can be measured by a laser diffraction method. Specifically, it can be measured by a SALD-3100 type measuring device (trade name) manufactured by Shimadzu Corporation. . In addition, when the term “average particle diameter” appears below and specific numerical values are described, the “average particle diameter” is determined by the laser diffraction method as described above, unless otherwise described. It is measured.

  If the average particle size of the magnetic powder is larger than 100 μm, the sedimentation in water tends to become severe, and the dispersion in water tends to be poor. Also, the effective surface area of the particles decreases, and the amount of adsorption of oils and the like Is not preferable because it tends to decrease. On the other hand, when the particle diameter is smaller than 0.05 μm, the primary particles are densely aggregated and float on the upper layer of the treatment liquid, which is not preferable because the dispersibility tends to decrease.

(Polymer emulsion)
The polymer emulsion used in this embodiment is a commonly used water-based polymer emulsion. That is, the predetermined polymer particles are configured to be suspended in water.

  Polyvinyl chloride, polyvinyl acetate, polyethylene, polyacrylic acid, polystyrene, polyester, polyisoprene, polybutadiene and copolymers thereof are used as the polymer constituting the polymer emulsion, that is, the polymer suspended in water. Is preferred. These can be used alone or in combination of two or more. These polymers are easy to obtain and are formed so as to cover the surface of the carrier as a layer of particles, exhibiting high lipophilicity and low solubility in water. When it is subjected to the above, it contributes to the adsorption of the oil without dissolving in water and exhibits high oil adsorption performance, and also shows high resistance particularly to the organic solvent used in the regeneration treatment step.

  The average particle diameter of the dispersed polymer is preferably 900 nm or less. When the average particle diameter exceeds 900 nm, the film formability is poor, and it may be difficult to form a stable particle layer on the surface of the carrier. Moreover, the lower limit value of the average particle diameter of the dispersed polymer can be set to, for example, 10 nm. When the average particle size is smaller than 10 nm, the storage stability is lowered, and the film formability may be deteriorated in the same manner as described above. In addition, in the following granulation operation, oil-adsorbing particles having a predetermined size are produced. In some cases, granulation may take a long time.

  Polymer emulsions in which polymers as described above are dispersed are commercially available. For example, Vinibrand 271, Vinibrand 278, Vinibrand 690, Vinibrand 900, Vinibrand 902, Vinibrand 985, Vinibrand 603, Vinibrand 700, Vinibrand 700 manufactured by Nissin Chemical. Examples thereof include a vinyl chloride / acrylic resin emulsion such as 701, a vinyl chloride emulsion, and a vinyl chloride / vinyl acetate emulsion.

  Further, as polymer emulsions manufactured by JSR, 0533, 0545, 0548, 0561, 0568, 0569, 0573, 0589, 0597C, 0602, 0614, 0619, 0623A, 0695, 0696, 0850Z, 2108, 2853, 2855, 2877A styrene butadiene Examples thereof include acrylic latexes such as AE116, AE120A, AE150B, AE200A, AE337, SX8900D, AE610H, SX872, AE945H, AE981A, AE982, AE986B, and SX997.

  Furthermore, as a polymer emulsion manufactured by Dainippon Ink, Inc., Luck Star 7300A, Luck Star DS-602, Luck Star 7310-K, Luck Star 2800A, Luck Star 3009A, Luck Star DS-410, Luck Star CB-2, Luck Star DS -407H, rack star 3307BE, rack star DS-205, rack star 7440N, rack star DN-703, rack star 1570B, rack star 6541G, rack star DM-886, rack star DM-801, rack star DM-808, rack Examples thereof include butadiene-based resin latexes such as Star 1181F and Bateracol E-301. Also AB-901, AN-155-E, AN-200, ED-85-E, R-3380-E, AN-782-E, Ab-886, AN-1190, H-5, S-5, AC Examples include acrylic emulsion systems such as -501, HV-E, TA-96, SFA-33, SFC-571, AK-261E, AK-3090, AK-2100, SEP-119, and EN-0270.

  The polymer emulsion preferably contains a dispersant from the viewpoint of the storage stability of the polymer emulsion. Specific examples of the dispersant include those having a contradictory property of new oil and hydrophilic in the molecule, and generally used surfactants can also be used. Surfactants include anionic surfactants, nonionic surfactants, zwitterionic surfactants, cationic surfactants, and other reactive surfactants having a crosslinking group such as a vinyl group in the molecular chain. Use is also possible. These dispersants can uniformly disperse oily polymer particles that are difficult to disperse, prevent sedimentation and aggregation of carrier particles, and provide a polymer emulsion that is stable for a long period of time.

(Granulation)
Next, in the present embodiment, the carrier is taken out from the polymer emulsion, the water contained therein is removed, and then granulated.

  The method for removing moisture contained in the carrier can be performed by separately performing a drying process, but can also be performed simultaneously with the granulation in the process of granulating.

  Granulation can be performed by, for example, spray drying, rotary granulation, or stirring granulation. In the case of the spray drying method, the particle size distribution of oil-adsorbing particles obtained after granulation can be narrowed, and oil-adsorbing particles having a uniform particle size can be easily obtained. In addition, since the water contained in the carrier can be evaporated in the process of spray drying, granulation and water removal can be performed simultaneously as described above. In this case, for example, oil-adsorbing particles having an average particle diameter of 10 μm to 50 μm can be formed.

  On the other hand, the rotary granulation method and the agitation granulation method are suitable for forming oil-adsorbing particles having a relatively large particle size. For example, by rotating and granulating at a relatively low speed, the particle size exceeds 100 μm. It is possible to obtain oil adsorption particles having a large particle size. In addition, the rotational granulation method and the agitation granulation method also mechanically and thermally remove moisture contained in the carrier during the granulation process.

(Oil adsorbed particles)
Through the steps as described above, the desired oil-adsorbing particles can be obtained. In this case, the oil-adsorbing particles generally become a porous body due to the manufacturing method as described above. Further, the average particle diameter of the oil-adsorbing particles can be appropriately controlled within a range of 5 μm to 5 mm. The specific surface area is preferably 2 m ² / g or more. By having such a high specific surface area, a high oil content adsorptivity is exhibited.

  The specific surface area having the above-mentioned size depends on, for example, the size of primary particles obtained by coating the carrier surface before granulation with polymer particles, the amount of polymer, and the granulation time. In general, the specific surface area tends to increase by reducing the particle size of the primary particles, decreasing the amount of polymer, or reducing the granulation time. In this case, however, the amount of polymer becomes too small and the oil content decreases. Since there may be a problem that the original function as the adsorbent particles is not achieved, the above-mentioned specific surface area is realized by appropriately selecting optimum production conditions.

Moreover, although the upper limit of a specific surface area is not specifically limited, At present, it is 50 m < ² > / g, for example.

  Furthermore, it is preferable that the polymer content of the oil-adsorbing particles is 8% or less and the porosity is 50% or more. A polymer content of 8% is required to obtain a relatively large specific surface area as described above. For example, if the polymer content of the oil-adsorbing particles exceeds 8%, the polymer tends to embed voids, so that oil-adsorbing particles with a high specific surface area cannot be obtained as described above. In order for the oil adsorbing particles to perform oil adsorbing utilizing the lipophilicity of the polymer, the polymer content is, for example, 1% as a lower limit.

  Further, as described above, since the oil adsorbing particles are a porous body, oil adsorbing can also be performed using the voids (holes). That is, oil can be adsorbed by adsorbing oil in the pores. In this case, when the porosity is 50% or more, it is possible to increase the oil adsorption action using the pores. The upper limit of the porosity can be set to 70%, for example. If it exceeds this, the strength of the oil-adsorbing particles cannot be sufficiently maintained.

  The oil adsorbing particles may contain various additives as necessary. For example, an oil-absorbing inorganic compound can be added and blended in order to further increase the oil adsorption capacity. As such an oil-absorbing inorganic compound, a fine silica filler having an average particle diameter of 40 nm or less is particularly preferable. Specific examples thereof include Aerosil 130, Aerosil 200, Aerosil 200V, Aerosil 200CF, Aerosil 200FAD, Aerosil 300, Aerosil 300CF, Aerosil 380, Aerosil R972, Aerosil R972V, Aerosil R972CF, Aerosil R974, Aerosil R202, Aerosil R805, , Aerosil R812S, Aerosil OX50, Aerosil TT600, Aerosil MOX80, Aerosil MOX170, Aerosil COK84, Aerosil RX200, Aerosil RY200 (all trade names: manufactured by Nippon Aerosil Co., Ltd.), etc. Silica is good.

  A fibrous or layered filler can also be used in combination. Fibrous fillers include titania, aluminum borate, silicon carbide, silicon nitride, potassium titanate, basic magnesium, zinc oxide, graphite, magnesia, calcium sulfate, magnesium borate, titanium diboride, α-alumina , Whiskers such as chrysotile, wollastonite, and other amorphous fibers such as E glass fiber, silica alumina fiber, silica glass fiber, Tyranno fiber, silicon carbide fiber, zirconia fiber, γ-alumina fiber, α-alumina Examples thereof include crystalline fibers such as fibers, PAN-based carbon fibers, and pitch-based carbon fibers. Examples of the layered compound include hydrotalcite, talc, layered titanium oxide, montmorillonite, bentonite, hectorite, beidellite, saponite, and stevensite.

  Furthermore, activated carbon powder can be used in combination with oil adsorbent particles to remove oil components dissolved and emulsified in water, 2-methylisoborneol such as odor mold components, and diosmin. As a specific example of the activated carbon, any activated carbon for water treatment can be used, but the pore diameter can be selected and used according to the substance to be adsorbed.

  The oil-adsorbing particles in the present embodiment can be produced, for example, as follows. First, the magnetic substance, polymer emulsion, and the above-mentioned additives are blended in a predetermined ratio, diluted with pure water to a viscosity of 1 to 3 poise, and the magnetic substance and polymer emulsion are uniformly mixed by a dispersing device such as a predetermined bead mill. To do. Next, granulation is performed by spray drying, rotary granulation, and stirring granulation, in which moisture is vaporized by heating. As described above, the spray-drying method is preferable as a method having a relatively small particle size and a sharp particle size distribution of the obtained functional powder, and oil-adsorbing particles of 10 to 50 μm can be produced. In the case of a large particle size exceeding 100 μm, a rotary granulation method and a stirring granulation method which rotate at a low speed are preferable.

The average particle size of the oil-adsorbing particles can be appropriately determined from handling properties and ease of recovery, but is preferably in the range of 5 μm to 5 mm. Further, the specific surface area is preferably 2 m ² / g or more from the viewpoint of adsorption performance, and when the specific surface area is low, the adsorption performance is lowered, which is not preferable. In addition, the polymer content of the oil-adsorbing particles is preferably 8% or less for producing a porous body having a large specific surface area. If the polymer content exceeds 8%, the polymer tends to completely fill the voids. It becomes difficult to create a porous body. Furthermore, the porosity is preferably 50% or more, and if it does not reach 50%, the adsorption performance may deteriorate.

  The final shape of the oil-adsorbing magnetic particles is not only the porous shape described above, but also workability such as spherical, sub-spherical, fibrous, sheet-like, string-like, drainage flow rate, recovery method, oil removal. It can be processed into various shapes from the viewpoint of the separation method, and the oil-adsorbing particles can be immobilized on different carriers.

  Further, the oil-adsorbing particles can be further processed, and by performing a surface treatment on the oil-adsorbing particles, it is possible to adsorb P, B and metal compounds other than the oil.

(Water treatment)
The oil-adsorbing particles obtained as described above can be used for water treatment that adsorbs and removes oil in the waste water by immersing the oil-adsorbing particles in the waste water. Here, the oil component is generally a liquid at room temperature, hardly soluble in water, relatively high in viscosity, and smaller in specific gravity than water. More specifically, they are mineral oils, animal and vegetable oils, hydrocarbons, aromatic oils and the like.

  When performing water treatment using the oil-adsorbing particles, first, the oil-adsorbing particles are dispersed and immersed in the waste water. At this time, the oil component in the waste water is adsorbed by the oil component adsorbing particles due to the affinity between the particle surface of the oil component adsorbing particles and the oil component, and the oil adsorbing action into the pores of the oil component adsorbing particles.

  The oil adsorption rate of the oil adsorbing particles is very high although it depends on the oil concentration in the waste water, the surface area of the oil adsorbing particles, and the amount added. Specifically, when a sufficient amount of oil adsorbing particles is added, generally 80% or more, preferably 97% or more, more preferably 98% or more, and most preferably 99% or more of the oil adsorbing particles. Adsorbed on the surface.

  In this embodiment, since the polymer particles formed on the surface of the oil adsorbing particles are formed using a polymer emulsion, even if the oil adsorbing particles are immersed in the wastewater, the oil adsorbing particles are discharged from the wastewater. Alternatively, the water remaining in the oil-adsorbing particles only dissolves in the purified water. Therefore, as described in Patent Document 2, the low molecular weight compound does not start to dissolve in the waste water and contaminate the water.

  After the oil is adsorbed on the surface of the oil adsorbing particles, the oil adsorbing particles are separated from the waste water, and as a result, the oil is removed from the waste water. Here, when the oil-adsorbing particle carrier has magnetism, the magnetic force can be used for separation from the waste water, that is, the oil-adsorbing particles can be attracted by, for example, a magnet, so that the oil-adsorbing particles can be easily recovered. can do. Here, sedimentation by gravity and separation by centrifugal force using a cyclone can be used together with separation by magnetism, and by using these together, workability can be improved and recovery can be performed more quickly. It becomes.

  There is no particular limitation on the wastewater to be treated. Specifically, industrial wastewater, sewage, domestic wastewater, etc. can be illustrated. Also, the concentration of contaminants contained in the water to be treated is not particularly limited. However, if the concentration of contaminants is excessively high, a large amount of oil adsorbing particles is required. It is more efficient to attach to the water treatment method according to the present embodiment.

  As an apparatus for carrying out such a water treatment method according to the present invention, an apparatus as shown in FIGS. 1 and 2 can be used. FIG. 1 shows a relatively small-scale facility, which is preferable when it is used for domestic wastewater treatment with a small amount of wastewater flow. Wastewater introduced from the drainage inlet 1 passes through a pipe around which a magnet 2 is arranged, and is discharged from the treated drainage outlet 3. Oil adsorbed particles are mixed with the waste water before being introduced from the drain inlet 1. The oil in the waste water is adsorbed by the oil adsorbing particles, and the oil adsorbing particles that have adsorbed the oil are deposited inside the pipe on which the magnet 2 is arranged, collected and collected.

  Further, the apparatus shown in FIG. 2 is effective when oil flows out to the ocean in a factory where a large amount of wastewater treatment is required or a tanker stranded. As in the apparatus of FIG. 1, the oil adsorbing particles are mixed in the waste water and then introduced from the drain inlet 1 and are suspended in the waste water by the superconducting magnet 2 a close to the tank. Are collected and removed, and the treated waste water is discharged from the outlet 3.

  These are devices that immobilize the oil adsorbing particles on the magnet and adsorb the oil in the wastewater. However, in order to further increase the processing capacity, there is also a method of immobilizing the oil adsorbing particles by arranging a net-like magnet in the pipe. Can be adopted.

  In order to recover the oil, the oil adsorbed particles are taken out from the pipe or tank, washed with an oil extraction solvent such as n-hexane or alcohol or an oil washing solvent, desorbed contaminants, and oil adsorbed magnetic particles. Can be played.

  In addition to installing and fixing these recovery facilities, they can also be used by being mounted on a processing ship having these devices as a mobile type in order to handle on-site processing such as in the ocean and rivers.

  The oil-adsorbed particles recovered after the treatment can be regenerated and reused. In order to regenerate, it is necessary to desorb the adsorbed oil from the oil adsorbing particles. In order to desorb such contaminants, it is preferable to use washing with a solvent. The washing solvent or oil extraction solvent used in this case is a solvent that does not dissolve the polymer particles or the resin binder but can dissolve the oil, such as methanol, ethanol, n-propanol, isopropanol, acetone, tetrahydrofuran, n-hexane, Preference is given to using cyclohexane and mixtures thereof. Further, other solvents may be used.

Example 1
As a magnetic powder, 2.67 kg of spherical ferrite with an average particle size of 0.79 μm (magnetic strength 84.4 emu / g), 6.58 kg of pure water, and 0.37 kg of Viniblanc 271 were charged into a bead mill, mixed for 30 minutes, and then a disk-type spray. The material was pumped with a material at 150 ml / min, atomizer speed 25000 rpm, blower temperature 200 ° C., and exhaust fan 110 ° C. to produce oil adsorbed particles.

Example 2
As a magnetic powder, 2.67 kg of spherical magnetite (magnetic strength 84.4 emu / g) with an average particle size of 0.79 μm, 6.77 kg of pure water and 0.19 kg of Viniblanc 271 were charged into a bead mill, mixed for 30 minutes, and then a disk-type spray. The material was pumped with a material at 150 ml / min, atomizer rotation speed 25000 rpm, blower temperature 200 ° C., and exhaust fan 110 ° C. to produce oil adsorbed particles.

Example 3
As a magnetic powder, 2.67 kg of spherical ferrite with an average particle size of 0.79 μm (magnetic strength 84.4 emu / g), 6.89 kg of pure water and 0.06 kg of Viniblanc 271 were charged into a bead mill, mixed for 30 minutes, and then a disk-type spray. The material was pumped with a material at 150 ml / min, atomizer rotation speed 25000 rpm, blower temperature 200 ° C., and exhaust fan 110 ° C. to produce oil adsorbed particles.

Example 4
As a magnetic powder, 2.67 kg of spherical magnetite with an average particle size of 0.79 μm (magnetic strength 84.4 emu / g), 6.66 kg of pure water, and 0.30 kg of Viniblanc 690 are charged into a bead mill, mixed for 30 minutes, and then a disk-type spray. The material was pumped with a material at 150 ml / min, atomizer rotation speed 25000 rpm, blower temperature 200 ° C., and exhaust fan 110 ° C. to produce oil adsorbed particles.

Example 5
As a magnetic powder, 2.67 kg of spherical ferrite with an average particle size of 0.79 μm (magnetic strength 84.4 emu / g), 6.66 kg of pure water and 0.15 kg of Viniblanc 690 are charged into a bead mill, mixed for 30 minutes, and then a disk-type spray. The material was pumped with a material at 150 ml / min, atomizer rotation speed 25000 rpm, blower temperature 200 ° C., and exhaust fan 110 ° C. to produce oil adsorbed particles.

Example 6
As a magnetic powder, 2.67 kg of spherical magnetite (magnetic strength 84.4 emu / g) with an average particle size of 0.79 μm, 6.91 kg of pure water and 0.05 kg of Viniblanc 690 are charged in a bead mill, mixed for 30 minutes, and then a disk-type spray. The material was pumped with a material at 150 ml / min, atomizer rotation speed 25000 rpm, blower temperature 200 ° C., and exhaust fan 110 ° C. to produce oil adsorbed particles.

Example 7
As a magnetic powder, 2.67 kg of spherical ferrite with an average particle size of 0.79 μm (magnetic strength 84.4 emu / g), 6.66 kg of pure water, and 0.30 kg of Viniblanc 603 are charged into a bead mill, mixed for 30 minutes, and then a disk-type spray. The material was pumped with a material at 150 ml / min, atomizer rotation speed 25000 rpm, blower temperature 200 ° C., and exhaust fan 110 ° C. to produce oil adsorbed particles.

Example 8
As a magnetic powder, 2.67 kg of spherical magnetite with an average particle size of 0.79 μm (magnetic strength 84.4 emu / g), 6.58 kg of pure water, and 0.37 kg of Viniblanc 985 are charged into a bead mill, mixed for 30 minutes, and then disk-type spray. The material was pumped with a material at 150 ml / min, atomizer rotation speed 25000 rpm, blower temperature 200 ° C., and exhaust fan 110 ° C. to produce oil adsorbed particles.

Comparative Examples 1-3
As commercially available oil gelling agents, styrene-butadiene copolymers having average particle sizes of 200, 780 and 920 μm were prepared as comparative oil-adsorbing particles. These were used for evaluation as they were.

<Evaluation of oil adsorption particles>
The following items were evaluated for the oil adsorbing particles obtained in Examples 1 to 8 and the oil adsorbing particles of Comparative Examples 1 to 3.

(1) Adsorption performance evaluation of oil-adsorbing particles: Add 50 g, 100 μL, 110 μL, and 120 μL of predetermined mineral oil components to 20 mL of pure water, add 0.1 g of oil adsorbing particles to the dispersed particles, and add 5 to a shaker. After performing a uniform mixing process for 5 minutes, the oil-adsorbing particles are removed with a magnet, and the oil-extracting solvent n-hexane is added to completely dissolve and extract the oil, and the oil-dissolved n-hexane solution is gas chromatographed. The residual oil amount was analyzed using a tograph-mass spectrometer (GC-MS), and the oil adsorption rate was calculated.
(2) Average particle diameter: As a particle size distribution measurement, the average particle diameter was measured by a laser diffraction method. Specifically, measurement was performed after ultrasonic dispersion after dropping a surfactant as a water dispersion medium with a SALD-DS21 type measuring device (trade name) manufactured by Shimadzu Corporation.
(3) State of particles during adsorption of oil: In (1), the state of oil adsorbed particles after the uniform mixing treatment was visually observed. The quality of the adsorbed particles was judged by visual observation based on the presence or absence of suspended particles after oil adsorption and the presence or absence of aggregation of adsorbed particles.
(4) Resistance to oil-extracting solvent: When treated with the oil-extracting solvent in (1), the state of the oil-adsorbed particles after being immersed in the solvent was visually observed. The quality of the oil-adsorbed particles was judged based on the change in particle shape due to solvent extraction, the presence or absence of a change in sedimentation velocity, and the degree of coloring of the extract.
(5) Collection of adsorbate by magnet: In (1), the magnet was brought close to the outside after the uniform mixing treatment, and it was visually observed whether the adsorbate after the mineral oil was adsorbed by the magnet could be collected.

  Table 3 shows (1) the amount of oil adsorbed on the adsorption performance evaluation of oil adsorbing particles, and Table 4 shows the characteristics evaluation on (2) to (5).

  As is apparent from Table 3, the oil-adsorbed particles relating to the examples obtained according to the present invention have a mineral oil content in pure water as compared with the commercially available oil gelling agent of styrene-butadiene copolymer shown in the comparative example. Regardless, it can be seen that it has a high oil content adsorptivity.

  Further, as is apparent from Table 4, the oil-adsorbed particles related to the examples obtained according to the present invention have a particle state at the time of oil-adsorbing as compared with the commercially available oil gelling agent of the styrene-butadiene copolymer shown in the comparative example. It was found to be good and tolerant to the oil extraction solvent. It was also found that recovery with a magnet is possible.

  While the present invention has been described in detail based on the above specific examples, the present invention is not limited to the above specific examples, and various modifications and changes can be made without departing from the scope of the present invention.

1 Drainage inlet 2 Magnet 2a Superconducting magnet 3 Treated drainage outlet

Claims (10)

Uniformly dispersing the carrier in the polymer emulsion;
Removing the carrier from the polymer emulsion, removing the moisture contained therein, and granulating;
A method for producing oil-adsorbing particles, comprising:   The method for producing oil-adsorbing particles according to claim 1, wherein the carrier is a magnetic substance.   The polymer emulsion is at least one selected from the group consisting of polyvinyl chloride, polyvinyl acetate, polyethylene, polyacrylic acid, polystyrene, polyester, polyisoprene, polybutadiene, and copolymers thereof. Item 3. The method for producing oil-adsorbing particles according to Item 1 or 2.   The method for producing oil-adsorbing particles according to any one of claims 1 to 3, wherein an average particle size of a dispersed polymer of the polymer emulsion is 900 nm or less.   The method for producing oil-adsorbing particles according to any one of claims 1 to 4, wherein a dispersant is contained in the polymer emulsion.   The oil content according to any one of claims 1 to 5, wherein the granulation is performed by at least one method selected from the group consisting of a spray drying method, a rotary granulation method, and a stirring granulation method. Method for producing adsorbed particles. The method for producing oil-adsorbing particles according to claim 1, wherein the oil-adsorbing particles have an average particle diameter of 5 μm to 5 mm and a specific surface area of 2 m ² / g or more.   The method for producing oil-adsorbing particles according to any one of claims 1 to 7, wherein the oil-adsorbing particles have a polymer content of 8% or less and a porosity of 50% or more. A step of immersing the oil-adsorbing particles according to any one of claims 1 to 8 in waste water to adsorb the oil in the waste water;
A step of magnetically separating and collecting the oil adsorbing particles from the waste water after adsorbing the oil; and
A water treatment method comprising the steps of:   After collecting the oil-adsorbed particles, the oil-adsorbed particles are contacted with at least one organic solvent selected from the group consisting of methanol, ethanol, n-propanol, isopropanol, acetone, tetrahydrofuran, n-hexane, and cyclohexane, and adsorbed on the oil-adsorbed particles. The water treatment method according to claim 9, further comprising the step of desorbing and regenerating the oil.

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