KR102651387B1 - Apparatus for manufacturing bioadsorbent - Google Patents

Abstract

The biological adsorbent production device of the present invention includes: a stirring unit for performing cation treatment on the surface of the microalgae by stirring the mixed solution containing an iron ion solution, a zinc ion solution, and microalgae; When cationic microalgae treated with cationic ions on the surface are provided from the stirring unit, a drying unit that dries and powders the cationic microalgae; And when the dried and powdered powdered microalgae is provided from the drying unit, it comprises a thermal decomposition unit that generates a biosorbent by thermally decomposing the powdered microalgae within a certain temperature range.

Description

Apparatus for manufacturing bioadsorbent}

The present invention relates to a device for producing a biosorbent using microalgae.

Microalgae are single-celled organisms that photosynthesize in aquatic environments and are called phytoplankton. Their sizes vary from several μm to hundreds of μm, and it is estimated that there are more than 200,000 types. In addition, microalgae are rich in nutrients and are used as health functional foods, feed, and fertilizers. They also contain various types of useful substances depending on the species, so they are also used as raw materials for medicines and cosmetics. In addition, it is commonly used in alternative energy fields such as biodiesel, and species with the ability to absorb heavy metals are also used in environmental purification research, such as wastewater treatment.

Microalgae have favorable conditions for adsorption of heavy metals, etc., because their cell walls are adhesive, have an electric charge, and have a large surface area due to folding of the cell wall surface. According to domestic and international literature, Chlorella, Spirulina, Cenedesmus, and Botryococcus are reported to have the ability to adsorb pollutants such as heavy metals in wastewater. Therefore, microalgae itself has the ability to adsorb pollutants, but the adsorption ability can be improved through modification, and research is being conducted on methods to improve the adsorption ability by modifying microalgae. Methods such as acid/base treatment, methanol solvent and ultrasound to remove substances such as chlorophyll a contained in microalgae, and production of biochar are used to modify microalgae.

Biochar is a compound word of biomass and charcoal, and is a material made to have properties intermediate between organic matter and charcoal. Therefore, it has been reported that biochar neutralizes the soil and stores carbon in the soil by pyrolyzing it without oxygen, so there is no risk of air pollution as there is no emission of carbon dioxide. Therefore, research on biochar is being actively conducted as a way to utilize biomass, and it is being used as an adsorbent by utilizing the porous structure and adsorption capacity of charcoal.

In order to manufacture a biosorbent to utilize the adsorption capacity of these microalgae, many processes must be performed, so there is a problem in that the manufacturing takes a considerable amount of time and cost. [Prior Art Document] Patent No. 2151440 Publication

The problem to be solved by the present invention is to manufacture a biosorbent using microalgae, and to provide an integrated biosorbent manufacturing device so that various processes for producing a biosorbent can be performed with one device.

The biological adsorbent production device of the present invention to solve the above problem performs cation treatment on the surface of the microalgae by stirring the mixed solution containing an iron ion solution, a zinc ion solution, and microalgae. a stirring unit that does; When cationic microalgae treated with cationic ions on the surface are provided from the stirring unit, a drying unit that dries and powders the cationic microalgae; And when the dried and powdered powdered microalgae is provided from the drying unit, it comprises a thermal decomposition unit that generates a biosorbent by thermally decomposing the powdered microalgae within a certain temperature range.

The stirring unit includes a stirring body of a cylindrical structure with a closed upper part and an open lower part, and a stirring case including an inlet formed on the upper surface of the stirring body for introducing the mixed solution; and a stirring impeller disposed at the inner center of the stirring case to stir the mixed solution.

The stirring impeller is characterized in that it includes a rotating shaft that is fixed to the center of the stirring case and rotates, and a stirring blade in the form of an anchor that is coupled to the end of the rotating shaft and rotates.

The drying unit includes a drying cover that is coupled to the stirring unit and filters and accommodates cationic microalgae provided from the stirring unit; A drying housing disposed below the drying cover and having an internal space for drying the cationic microalgae; and a pipe structure having elasticity, wherein the pipe structure includes a flexible tube disposed between the large chamber and the thermal decomposition unit to transfer the powdered microalgae to the thermal decomposition unit.

The drying cover includes a cover case coupled to the stirring unit and having a blower through which wind for drying flows in and an exhaust port through which the wind is discharged; It includes a conical structure, wherein the conical structure is disposed in the central area of the cover case, one end of the conical structure is coupled to the stirring unit, and the cationic microalgae are delivered into the chamber to the other end of the conical structure. A spray module with a nozzle for: And it is coupled to the injection module, and characterized in that it includes a first drying valve that adjusts the inflow amount of the cationic microalgae supplied into the chamber from the injection module.

The dry housing includes an outer case of a cylindrical structure; A chamber comprising a conical structure, wherein the conical structure is disposed inside the outer case, one end of the conical structure is coupled to the top of the outer case, and the other end of the conical structure is coupled with the flexible tube. ; And it is coupled to the chamber, and characterized in that it includes a second drying valve that adjusts the inflow amount of the powdered microalgae supplied from the chamber into the flexible tube.

The external case is characterized by including an external outlet formed on the side surface to discharge the bioadsorbent pyrolyzed by the thermal decomposition unit.

The flexible tube is characterized in that its shape is deformed by an external force and then its shape is restored when the external force is removed.

The pyrolysis unit includes a pyrolysis housing that is fixed to the inner surface of the drying unit to enable seesaw movement and includes a plate-shaped receiving structure for accommodating the powdered microalgae flowing through the drying unit; an elastic member disposed below the pyrolysis housing and providing an elastic force so that the pyrolysis housing seesaws upward; a stick member disposed on an upper portion of the pyrolysis housing and applying an external force so that the pyrolysis housing seesaws downward; and a heat supply module that heats the pyrolysis housing.

The pyrolysis housing includes a pyrolysis connector on an upper surface for connection to a flexible tube constituting the drying unit; and an internal outlet disposed on a side surface of the plate-shaped accommodation structure to discharge the biological adsorbent pyrolyzed by the heat supply module.

The stick member has an “L” shaped bending structure, is rotatably fixed to the side surface of the dryer, and is characterized in that it seesaws the pyrolysis housing in a downward direction whenever it rotates by the driving force of the motor. Do it as

According to the present invention, the production time of a biosorbent can be significantly shortened by providing an integrated biosorbent manufacturing device so that various processes for producing a biosorbent can be performed in one device.

In particular, by integrating the stirring process, spraying process, and thermal decomposition process, heat can be utilized efficiently, thereby reducing the heat energy used in each process.

Figure 1a is a perspective view for explaining the biosorbent production device according to the present invention.
FIG. 1B is a vertical cross-sectional view of the biosorbent production device shown in FIG. 1A.
FIG. 2A is a perspective view illustrating the stirring unit shown in FIG. 1.
FIG. 2B is a vertical cross-sectional view of the stirring unit shown in FIG. 2A.
FIG. 3A is a perspective view illustrating the drying unit shown in FIG. 1.
FIG. 3B is a vertical cross-sectional view of the dryer shown in FIG. 3A.
Figure 4A is an enlarged perspective view illustrating the drying cover shown in Figures 3A and 3B.
FIG. 4B is a vertical cross-sectional view of the drying cover shown in FIG. 4A.
Figure 5 is a perspective view illustrating an injection module and a first drying valve.
Figure 6A is a perspective view illustrating a dry housing.
FIG. 6B is a vertical cross-sectional view of the dry housing shown in FIG. 6A.
Figure 7 is a perspective view illustrating a flexible tube.
8 is a reference diagram illustrating a thermal decomposition unit.
Figure 9 is a perspective view illustrating the pyrolysis housing shown in Figure 8.
Figure 10 is a reference diagram illustrating the operation of the thermal decomposition unit.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the attached drawings.

The embodiments of the present invention are provided to more completely explain the present invention to those skilled in the art, and the following embodiments may be modified in various other forms, and the scope of the present invention is limited. It is not limited to the examples below. Rather, these embodiments are provided to make the disclosure more faithful and complete and to fully convey the spirit of the invention to those skilled in the art.

The terms used herein are used to describe specific embodiments and are not intended to limit the invention. As used herein, the singular forms include the plural forms unless the context clearly indicates otherwise. As used herein, the term “and/or” includes any one and all combinations of one or more of the listed items.

FIG. 1A is an external perspective view for explaining the biological adsorbent production device 10 according to the present invention, and FIG. 1B is a vertical cross-sectional view of the biological adsorbent production device 10 shown in FIG. 1A.

Referring to FIGS. 1A and 1B, the biosorbent manufacturing apparatus 10 of the present invention includes a stirring unit 100, a drying unit 200, and a thermal decomposition unit 300.

When a mixed solution containing an iron ion solution, a zinc ion solution, and microalgae is added to the stirring unit 100, the mixed solution is stirred to perform cation treatment on the surface of the microalgae. The type and composition ratio of the iron ion solution and zinc ion solution constituting the mixed solution may be changed as needed. A representative example of microalgae is spirulina, and various types of microalgae such as chlorella, whose adsorption performance is improved through a modification process, may be included.

The stirring unit 100 exists in a section from a point 2 m away from the heat source to a point 2 m 30 cm away, and the bottom is made of a thin insulating material to prevent excessive heating.

By stirring a solution containing iron ions (FeCl ₃ ) or zinc ions (ZnCl ₂ ) and microalgae at around 80°C, the surface of the microalgae is treated with positive ions, which improves the adsorption of anionic contaminants. It can be raised.

FIG. 2A is a perspective view illustrating the stirring unit 100 shown in FIG. 1, and FIG. 2B is a vertical cross-sectional view of the stirring unit 100 shown in FIG. 2A.

Referring to FIGS. 2A and 2B, the stirring unit 100 includes a stirring case 110 and a stirring impeller 120.

The stirring case 110 includes a case body 110-1 of a cylindrical structure with the upper part closed and the lower part open, and an inlet 110-2 formed on the upper surface of the case body for the introduction of the mixed solution. ) includes.

Here, the cylindrical structure of the case body 110-1 may be a cylindrical structure or a polygonal cylindrical structure. Additionally, the inlet 110-2 is formed with a hole through which the mixed solution can flow, and may include an inlet cover (not shown) that can block the hole entrance after the mixed solution flows into the inlet. The case body 110-1 may have a cylindrical structure whose diameter is approximately 1/2 smaller than that of the drying unit 200.

The lower end of the case body 110-1 may have a screw groove formed on either the inner or outer surface of the cylindrical structure to be coupled to the drying unit 200. Accordingly, the case body 110-1 can be combined with or separated from the drying unit 200.

The stirring impeller 120 is disposed at the inner center of the stirring case 110 to stir the mixed solution. The stirring impeller 120 includes a rotating shaft 120-1 that is fixed to the center of the stirring case 110 and rotates, and a stirring blade 120-2 in the form of an anchor that is coupled to the end of the rotating shaft 120-1 and rotates. do.

Although not shown, a motor is coupled to the end of the rotation shaft 120-1, so that the motor rotates when power is supplied, thereby rotating the rotation shaft 120-1. The stirring blade (120-2) rotates in accordance with the rotation of the rotating shaft (120-1), thereby appropriately agitating the iron ion solution, zinc ion solution, and microalgae that make up the introduced mixed solution. Cation-treated microalgae can be formed on the surface by stirring.

The drying unit 200 dries and powders the cationic microalgae when the surface of the cationic microalgae is provided from the stirring unit 100. In order to manufacture stirred cation-treated microalgae into biochar, a pretreatment process of drying and powdering is required before proceeding with pyrolysis. In this case, using the spray drying method is effective as drying and powdering occur simultaneously.

The drying unit 200 exists in a section from 1 m to 2 m away from the heat source to maintain the set temperature, and the chamber contains a thin insulating material to prevent excessive heating. When gas for spray drying is supplied from outside, the internal temperature can be checked through an internal temperature sensor and the incoming gas temperature can be adjusted. (If the internal temperature is already sufficient for spray drying, there is no need to heat the incoming gas, so energy savings are possible)

FIG. 3A is a perspective view illustrating the drying unit 200 shown in FIG. 1, and FIG. 3B is a vertical cross-sectional view of the drying unit 200 shown in FIG. 3A.

Referring to FIGS. 3A and 3B , the drying unit 200 includes a drying cover 210, a drying housing 220, and a flexible tube 230.

The drying cover 210 is coupled to the case body 110-1 of the stirring unit 100, and filters and accommodates the cationic microalgae provided from the stirring unit 100.

FIG. 4A is an enlarged perspective view illustrating the desiccant cover 210 shown in FIGS. 3A and 3B, and FIG. 4B is a vertical cross-sectional view of the desiccant cover 210 shown in FIG. 4A.

Referring to FIGS. 4A and 4B, the drying cover 210 includes a cover case 210-1, an injection module 210-2, and a first drying valve 210-3.

The cover case 210-1 is coupled to the stirring unit 100 and has an outlet 210-11 through which wind for drying flows in and an exhaust port 210-12 through which the wind is discharged.

The cover case 210-1 has a cylindrical structure with an open bottom. The upper surface of the cylindrical structure is closed, and the central part of the upper surface is coupled to the upper part of the injection module 210-2.

The blower 210-11 and the exhaust port 210-12 are each formed on the outer surface of the cylindrical structure. The vent 210-11 is a passage through which wind for drying cationic microalgae flows in, and the exhaust port 210-12 is a passage through which wind used for drying cationic microalgae is discharged.

The injection module 210-2 filters the cationic microalgae provided from the stirrer 100.

Figure 5 is a perspective view illustrating the injection module 210-2 and the first dry valve 210-3.

Referring to FIG. 5, the injection module 210-2 includes an injection case 210-21, an injection filter 210-22, and an injection nozzle 210-23.

The injection case 210-21 includes a conical structure, the upper part of the conical structure is coupled to the central area of the cover case 210-1, and the lower part of the conical structure is coupled to the injection nozzle 210-23. .

The spray filter 210-22 performs a filtration function for cationic microalgae and may be a disk-shaped mesh material. The injection filter 210-22 is seated within the injection case 210-21 of a cone-shaped structure.

The spray filter 210-22 is used to prevent the nozzle from clogging when the cationic microalgae is sprayed into the drying unit 200 after stirring is completed and the microalgae clumps or there is mixed foreign matter. To this end, the size of the mesh pores of the injection filter 210-22 must be larger than the biosorbent raw material and smaller than the size that may cause nozzle clogging. Additionally, the spray filter 210-22 has a detachable structure so that it can be removed from the top for smooth cleaning.

The spray nozzle (210-23) is coupled to the bottom of the spray case (210-21) and sprays the cationic microalgae filtered by the spray filter (210-22) into the dry housing (220). The diameter of the spray nozzle 210-23 and the shape of the discharge port of the spray nozzle can be designed in various ways.

The first drying valve 210-3 is coupled to the injection module 210-2 and controls the inflow amount of cationic microalgae supplied from the injection module 210-2 into the drying housing 220. To this end, an opening and closing member (not shown) is formed in the passage of the injection module 210-2 to perform an opening and closing function by rotating the first drying valve 210-3.

The first dry valve 210-3 may be in the form of a stick that can be rotated by a machine or a person, and is coupled to the side portion of the spray nozzle 210-23 to perform an opening and closing function.

The drying housing 220 is disposed below the drying cover 210 and has an internal space for drying cationic microalgae.

FIG. 6A is a perspective view illustrating the dry housing 220, and FIG. 6B is a vertical cross-sectional view of the dry housing 220 shown in FIG. 6 A.

Referring to FIGS. 6A and 6B, the drying housing 220 includes an external case 220-1, a chamber 220-2, and a second drying valve 220-3.

The outer case 220-1 includes a cylindrical structure. The cylindrical structure may include a cylindrical structure, a polygonal cylindrical structure, etc. The outer case 220-1 includes a chamber 220-2 and a flexible tube 230, which are components of the dry housing 220, therein. Additionally, the external case 220-1 includes a thermal decomposition unit 300 therein.

The external case 220-1 includes an external outlet 220-11 formed on the side surface to discharge the bioadsorbent pyrolyzed by the thermal decomposition unit 300 to the outside. The external outlet (220-11) has a side cover, and the biosorbent can be discharged to the outside by opening and closing the side cover. The outlet size of the external outlet (220-11) may be larger than or equal to the size of the container that can contain the biosorbent.

The chamber 220-2 provides a space to accommodate the microalgae when they are delivered through the injection module 210-2. Within the chamber 220-2, the microalgae are dried by heat provided through the thermal decomposition unit 300.

For this purpose, the chamber 220-2 may be formed in a cone-shaped structure. The cone-shaped chamber 220-2 is disposed inside the external case 220-1. That is, the upper part 220-21 of the conical structure of the chamber 220-2 is coupled to the upper inner surface of the external case 220-1, and the lower part 220-22 of the conical structure is connected to the flexible tube 230. ) is combined with the top of. The lower part 220-22 of the chamber 220-2 provides a collection space where microalgae can be collected, and also has a coupling structure for connection to the flexible tube 230. Since the chamber 220-2 has a conical structure that narrows downward, sufficient space is secured for the thermal decomposition housing 310 of the thermal decomposition unit 30 to perform a seesaw movement.

The second dry valve 220-3 is coupled to the chamber 220-2 and controls the inflow amount of powdered microalgae supplied from the chamber 220-2 into the flexible tube 230. For this purpose, an opening and closing member (not shown) that performs an opening and closing function by rotating the second drying valve 220-3 is formed in the passage of the lower end 220-22 of the chamber 220-2.

The second dry valve 220-3 may be in the form of a stick that can be rotated by a machine or a person, and is coupled to the side of the lower end 220-22 of the chamber 220-2 to perform an opening and closing function.

The flexible tube 230 includes an elastic pipe structure (for example, a cylindrical structure, a polygonal cylindrical structure, etc.), and the pipe structure is disposed between the chamber 220-2 and the thermal decomposition unit 300 to produce powder Microalgae are delivered to the thermal decomposition unit 300.

Figure 7 is a perspective view illustrating the flexible tube 230.

Referring to FIG. 7, the upper end 230-1 of the flexible tube 230 is coupled to the lower end of the chamber 220-2, and the lower end 230-2 of the flexible tube 230 is connected to the thermal decomposition unit ( It is combined with the upper part of 300).

The flexible tube 230 may be made of a material that has the flexibility to change its shape due to external force and then restore its shape when the external force is removed. Additionally, the flexible tube 230 may be formed of a heat-resistant material that does not deform in shape even by heat supplied from the thermal decomposition unit 300. For example, the material of the flexible tube 230 may be made of stainless steel wire and specially coated glass fiber that can withstand temperatures up to 1,100°C.

When dried and powdered powdered microalgae are provided from the drying unit 200, the thermal decomposition unit 300 generates a biosorbent by pyrolyzing the powdered microalgae within a certain temperature range.

Microalgae can be turned into biochar through a pyrolysis process of about 2 hours at 200-900℃ (generally 400℃ considering thermal efficiency, etc.), and in the case of large-scale production, mixing is necessary for uniform quality.

Figure 8 is a reference diagram illustrating the thermal decomposition unit 300.

Referring to FIG. 8 , the thermal decomposition unit 300 includes a thermal decomposition housing 310, an elastic member 320, a stick member 330, and a heat supply module 340.

The pyrolysis housing 310 is fixed to the inner surface of the drying unit 200 to enable seesaw movement, and includes a plate-shaped receiving structure for accommodating the powdered microalgae flowing through the drying unit 200.

FIG. 9 is a perspective view illustrating the pyrolysis housing 310 shown in FIG. 8.

Referring to FIG. 9, the pyrolysis housing 310 includes a housing body 310-1, a pyrolysis connector 310-2, and an internal outlet 310-3.

The housing body 310-1 has a plate-shaped receiving structure. The housing main body 310-1 has an internal space capable of accommodating powdered microalgae within a plate-shaped accommodating structure. In FIG. 9, the housing body 310-1 shows a disc-shaped accommodating structure, but this is an example and may be a polygonal plate-shaped accommodating structure rather than a disc-shaped accommodating structure.

The housing body 310-1 is fixed to the inner surface of the drying unit 200 and has fixing grooves 310-11 formed on both sides of the plate-shaped receiving structure so that it can perform a seesaw movement. Accordingly, the housing body 310-1 fixed to the fixing groove 310-11 can be fixed in the drying unit 200 and rotated by manipulating the elastic member 320 and the stick member 330.

The pyrolysis connector 310-2 is an opening formed in the center of the upper surface of the housing body 310-1. The pyrolysis connector 310-2 includes a structure for connecting to the flexible tube 230 constituting the drying unit 200, for example, a screw coupling structure, an insert coupling structure.

The internal discharge port 310-3 is disposed on the side portion of the plate-shaped receiving structure in the housing main body 310-1. The internal outlet 310-3 may be provided on the side of the housing body 310-1, which has a plate-shaped receiving structure, to discharge the bioadsorbent pyrolyzed by the heat supply module 340. The internal outlet (310-3) has a side cover, and the biosorbent can be discharged to the outside by opening and closing the side cover.

The elastic member 320 is disposed at the lower part of the housing body 310-1 and provides elastic force so that the pyrolysis housing 310-1 seesaws upward. The elastic member 320 may have a spring structure and is made of a heat-resistant material. One end of the elastic member 320 is coupled to the lower surface of the housing body 310-1, and the other end of the elastic member 320 is fixed to the plate-shaped grid. At this time, the elastic member 320 must be elastic enough to facilitate seesaw movement.

The stick member 330 is disposed on the top of the pyrolysis housing 310 and applies an external force so that the pyrolysis housing 310 seesaws downward. For this purpose, the stick member 330 has an “L” shaped bent structure and is made of a heat-resistant material. In addition, one end of the stick member 330 that contacts the pyrolysis housing 310 is wrapped with a fiber material (aramid, etc.) to prevent wear.

The stick member 330 is rotatably fixed to the side part of the drying housing 220 constituting the drying unit 200, and rotates by a motor or a human driving force, and the end of the bending structure is bent according to the rotational movement to the pyrolysis housing. Press the upper surface of (310) to see-saw in the downward direction.

The heat supply module 340 heats the pyrolysis housing 310. The upper part of the heat supply module 340 may include a heat supply grid 340-1 to deliver heat supply in a balanced manner. The heat source of the heat supply module 340 can be various gases, refined oils, diesel fuel, and electricity used in general rotary kilns, and a direct heating method is used. In order to protect the inner shell from high temperatures and maintain heat retention, it is recommended that a non-metallic ceramic refractory be installed, and accordingly, the heat supply grid 340-1 may be a grid-shaped refractory.

Figure 10 is a reference diagram illustrating the operation of the thermal decomposition unit 300.

Referring to (a) of FIG. 10, when the stick member 330 of the thermal decomposition unit 300 is in a stationary state, the thermal decomposition housing 310 is tilted toward the outlet due to the influence of the elastic member 320. Meanwhile, referring to (b) of FIG. 10, when the motor operates after the start of pyrolysis and the stick member 330 rotates once per 30 seconds, the pyrolysis housing 310 when the 'ㄱ' shaped protrusion faces downward. is pressed, and as a result, the pressed portion of the pyrolysis housing 310 descends and performs a seesaw motion. Thereafter, when the 'L' shaped protrusion of the stick member 330 is directed upward again, the pressing force disappears and the elastic member 320 applies elastic force, causing the portion of the pyrolysis housing 310 to which the elastic force is applied to rise. do.

While drying is in progress in the drying unit, the second drying valve is closed. Afterwards, when drying is completed in the drying unit, the microalgae move to the thermal decomposition unit, and accordingly, the operation of the drying unit is stopped. Afterwards, when the microalgae is delivered to the pyrolysis unit, the pyrolysis unit operates, and the pyrolysis housing within the pyrolysis unit seesaws at a constant speed. Accordingly, the powdered microalgae repeatedly moves in the left and right directions according to the movement of the pyrolysis housing, which enables uniform mixing of the powder and even heat transfer. When pyrolysis is completed and the device is stopped, it stops with the left or right side down, and the external outlet of the drying unit and the internal outlet of the pyrolysis unit can be opened to recover the biosorbent.

The biosorbent produced by the biosorbent manufacturing device 10 described above has pores created on the surface of microalgae by thermal decomposition, the adsorption area is increased by increasing the specific surface area, and cationic heavy metals can be adsorbed on the anionic surface. It allows anionic heavy metals to adsorb to cationic surfaces. Additionally, these biosorbents can carry out interactions between the benzene rings of trace pollutants such as bisphenol A and the hydrophobic sites of biochar.

The device of the present invention has a structure in which there is a stirring part at the top, a drying part is located below it, and a thermal decomposition part is located below it. Lower temperatures are required as the process progresses from pyrolysis (approximately 400℃) → drying (approximately 180℃) → stirring (approximately 80℃). Therefore, when installing a heat source at the bottom of the pyrolysis process, the temperature is lowered step by step as it goes to the top. It is possible to maintain temperature.

In the above, the technical idea of the biological adsorbent production device of the present invention has been described along with the accompanying drawings, but this is an exemplary description of the best embodiment of the present invention and does not limit the present invention.

Accordingly, the present invention is not limited to the specific preferred embodiments described above, and various modifications may be made by anyone skilled in the art without departing from the gist of the present invention as claimed in the claims. Of course, such changes are possible and fall within the scope of the claims.

10: Biosorbent manufacturing device
100: stirring unit
200: drying section
300: Thermal decomposition unit

Claims (11)

When a mixed solution containing an iron ion solution, a zinc ion solution, and microalgae is introduced, a stirring unit that stirs the mixed solution to perform cation treatment on the surface of the microalgae;
When cationic microalgae treated with cationic ions on the surface are provided from the stirring unit, a drying unit that dries and powders the cationic microalgae; and
When the dried and powdered powdered microalgae is provided from the drying unit, it includes a thermal decomposition unit that thermally decomposes the powdered microalgae within a certain temperature range to produce a biosorbent,
The drying part,
A drying cover coupled to the stirring unit and filtering and receiving cationic microalgae provided from the stirring unit;
A drying housing disposed below the drying cover and having an internal space for drying the cationic microalgae; and
It includes a flexible pipe structure having elasticity, and the pipe structure includes a flexible tube disposed between the dry housing and the thermal decomposition unit to transfer the powdered microalgae to the thermal decomposition unit,
The dry cover is,
a cover case coupled to the stirring unit and having a blower through which drying wind flows in and an exhaust port through which the wind is discharged;
It includes a conical structure, wherein the conical structure is disposed in the central area of the cover case, one end of the conical structure is coupled to the stirring part, and the cationic microalgae are placed at the other end of the conical structure into the drying housing. A spray module formed with a nozzle for delivery; and
A biosorbent manufacturing device coupled to the injection module and comprising a first drying valve that adjusts the inflow amount of the cationic microalgae supplied from the injection module into the dry housing. In claim 1,
The stirring part,
A stirring case including a cylindrical stirring body with a closed upper part and an open lower part, and an inlet formed on the upper surface of the stirring body for introducing the mixed solution; and
A biological adsorbent production device comprising a stirring impeller disposed at the inner center of the stirring case to stir the mixed solution. In claim 2,
The stirring impeller is,
A biological adsorbent manufacturing device comprising a rotating shaft fixed to the center of the stirring case and rotating, and an anchor-shaped stirring blade coupled to an end of the rotating shaft and rotating. delete delete In claim 1,
The dry housing is,
External case of cylindrical structure;
A chamber comprising a conical structure, wherein the conical structure is disposed inside the outer case, one end of the conical structure is coupled to the top of the outer case, and the other end of the conical structure is coupled with the flexible tube. ; and
A biosorbent manufacturing device coupled to the chamber and comprising a second drying valve that adjusts the inflow amount of the powdered microalgae supplied from the chamber into the flexible tube. In claim 6,
The external case is,
A biological adsorbent manufacturing device comprising an external outlet formed on a side portion to discharge the biological adsorbent pyrolyzed by the thermal decomposition unit. In claim 1,
The flexible tube,
A biosorbent manufacturing device characterized in that the shape is deformed by external force and the shape is restored when the external force is removed. In claim 1,
The thermal decomposition unit,
A pyrolysis housing fixed to the inner surface of the drying unit to enable seesaw movement and including a plate-shaped receiving structure for accommodating the powdered microalgae flowing through the drying unit;
an elastic member disposed below the pyrolysis housing and providing an elastic force so that the pyrolysis housing seesaws upward;
a stick member disposed on an upper portion of the pyrolysis housing and applying an external force so that the pyrolysis housing seesaws downward; and
A biosorbent manufacturing device comprising a heat supply module that heats the pyrolysis housing. In claim 9,
The pyrolysis housing,
A pyrolysis connector on the upper surface for connection to the flexible tube constituting the drying unit; and
A biological adsorbent production device disposed on a side surface of the plate-shaped receiving structure and comprising an internal outlet disposed on a side surface of the plate-shaped receiving structure to discharge the biological adsorbent pyrolyzed by the heat supply module. In claim 9,
The stick member is,
Manufacture of a biological adsorbent having an "L" shaped bending structure, rotatably fixed to the side of the dryer, and causing the pyrolysis housing to see-saw downward each time it rotates by the driving force of the motor. Device.

Images