KR102816921B1 - Phytoplankton Collection apparatus and collecting method using theirof - Google Patents

Abstract

The present invention relates to a phytoplankton collection device and a phytoplankton collection method using the same, comprising: a container having a sample space formed inside which can accommodate a sample including phytoplankton and a plurality of sample holes formed connected to the sample space; a stopper part detachably connected to a sample hole selected from the plurality of sample holes; a volume setting part which is inserted into the sample space through a sample hole to which the stopper part is not connected and adjusts the volume of the sample space to control the volume of the sample; a collection part detachably connected to a sample hole to which the stopper part is not connected; and a suction part detachably connected to the collection part and capable of sucking a sample in the sample space.
After the sample space is filled with the sample, the capacity setting unit flows into the sample space through the sample hole, and the sample in the sample space overflows to the outside of the container by the volume of the capacity setting unit, so that the capacity of the sample is set, and the sample in the sample space is discharged to the outside of the container through the collection unit, so that phytoplankton can be collected in the collection unit.

Description

Phytoplankton collection apparatus and collecting method using the same {Phytoplankton Collection apparatus and collecting method using the same}

The present invention relates to a phytoplankton collection device and a collection method using the same.

Among the survey items for assessing aquatic environment pollution is the measurement of phytoplankton biomass. A representative method for obtaining phytoplankton biomass is to indirectly obtain biomass by measuring the amount of chlorophyll-a, a basic pigment possessed by all phytoplankton.

In order to measure the amount of chlorophyll-a, a collection net (filter paper) is first required to collect phytoplankton by filtering an appropriate amount of water. There is a suction collection method using an electric pump as a method of collecting phytoplankton, and most researchers are currently using this method.

However, since an electric pump that can apply pressure to a funnel must be used for the suction collection method using an electric pump, conditions where electricity can be provided are necessary. There will be no difficulty in using electricity in research vessels or large ships that are optimized for experimental conditions, but it is difficult to use an electric pump when conducting research using a general small ship that is not equipped with electricity.

In addition, in order to measure the appropriate collection capacity, a measuring cylinder is generally used to take the appropriate capacity, but this is a method that is possible on land, and measuring the appropriate capacity using a measuring cylinder is an inappropriate method for general ships that shake significantly.

Therefore, a method is needed to obtain the desired volume without using a measuring cylinder. In addition, the chlorophyll-a concentration method currently in use is inconvenient because it requires separate bottles and collecting devices to collect the water, so equipment simplicity is also required.

Republic of Korea Publication Patent No. 10-2010-0028061 (Published on March 11, 2010) Republic of Korea Patent No. 10-2445705 (10-2445705. Announcement)

The present invention provides a technology capable of collecting phytoplankton by taking a sample of a desired appropriate volume regardless of location or environmental conditions.

The present invention provides a technology capable of collecting phytoplankton even in places where electricity supply is impossible.

A phytoplankton collection device according to one embodiment of the present invention comprises: a container having a sample space formed inside which can accommodate a sample including phytoplankton and a plurality of sample holes formed connected to the sample space; a stopper part detachably coupled to a sample hole selected from the plurality of sample holes; a volume setting part inserted into the sample space through a sample hole to which the stopper part is not coupled to adjust the volume of the sample space to control the volume of the sample; a collection part detachably coupled to a sample hole to which the stopper part is not coupled; and a suction part detachably coupled to the collection part and capable of sucking a sample in the sample space.

After the sample space is filled with the sample, the capacity setting unit flows into the sample space through the sample hole, and the sample in the sample space overflows to the outside of the container by the volume of the capacity setting unit, so that the capacity of the sample is set, and the sample in the sample space is discharged to the outside of the container through the collection unit, so that phytoplankton can be collected in the collection unit.

The above collection unit may include a collection body having a sample suction hole penetrating the inside thereof and detachably coupled to the sample hole, a collection net disposed in the sample suction hole through which the water of the sample can pass and through which the phytoplankton is collected, and a support disposed in the sample suction hole and supporting the collection net.

The above container may be formed with a connecting portion extending the sample hole, and the connecting portion may be formed with a settling groove connected to the sample hole and in which the collection net is positioned.

The outer periphery of the above-mentioned connecting portion is inserted into the interior of the collecting body, and the above-mentioned connecting portion and the collecting body can be screw-connected.

The above collection member may further include a sealing member arranged between the fixing groove and the collection net.

The above capacity setting unit may include a first block unit that is seated in the seating groove and inserted into the sample space, and a second block unit that is detachably coupled to the first block unit and located in the sample space.

The above first block portion may include a flange placed in the mounting groove, and a coupling body protruding from the flange and passing through the sample hole.

A screw is formed on the outer periphery of the above-mentioned joining body, a gap is formed between the outer periphery of the above-mentioned joining body and the periphery of the above-mentioned sample hole, and the gap can gradually widen from the outside to the inside of the above-mentioned joining portion.

The second block portion may have a fastening groove formed to be coupled with the coupling body, and a screw may be formed on the outer periphery.

The above plug part may include a plug body surrounding the outer periphery of the above connecting part, and an insertion body protruding from the plug body and inserted into the sample hole.

A gap is formed between the outer periphery of the above insert body and the periphery of the above sample hole, and the gap can gradually widen from the outside to the inside of the joint portion.

The above suction unit may include a cylinder that is detachably connected to the collecting body, a piston arranged to be linearly movable inside the cylinder, and a rod connected to the piston and exposed to the outside of the cylinder.

The above cylinder may have a protruding insertion portion that is inserted into the sample suction hole.

A method for collecting phytoplankton according to one embodiment of the present invention may include the steps of: attaching a stopper to a first sample hole connected to a sample space having a preset volume therein and preparing an open container for a second sample hole; filling the sample space with a sample including phytoplankton; a volume control step for controlling the sample volume of the sample space by attaching a volume setting unit to the second sample hole so that a portion of the sample is inserted into the sample space; a step for separating the volume setting unit from the second sample hole; a step for installing a collection unit having a collection net and a support arranged thereon in the second sample hole; a step for installing a suction unit in the collection unit; a step for separating the stopper from the first sample hole; a step for sucking a sample of the sample space using the suction unit; and a step for separating the collection net from the collection unit to collect phytoplankton.

The sample in the above sample space passes through the collection net and the support and flows into the interior of the suction unit, and phytoplankton in the sample can be collected in the collection net.

According to an embodiment of the present invention, since the block of the capacity setting unit is positioned in the sample space and the capacity of the sample is controlled, there is an effect of being able to obtain a desired capacity even in an environment with severe shaking.

According to an embodiment of the present invention, when the capacity setting unit is inserted into the sample space through the second sample hole, the sample in the sample space is discharged to the outside of the container through the gap. There is an effect that the sample is easily discharged through the gap.

According to an embodiment of the present invention, since the piston moves by pulling the rod, the sample in the sample space passes through the collection section and flows into the suction section, so that the sample in the sample space can be sucked without using electric energy, so that it can be freely used in places where electric energy is not supplied, so that usability is improved.

According to an embodiment of the present invention, the entire process from water collection to concentration can be performed using a single piece of equipment, thereby providing convenience and simplicity in the work process.

According to an embodiment of the present invention, the number of second blocks is selectively combined with the first block of the capacity setting section, and the sample capacity of the sample space is set according to the number of second blocks, so that various capacities can be achieved.

Figure 1 is an exploded view showing a phytoplankton collection device according to one embodiment of the present invention.
Figure 2 is a schematic diagram showing a state in which a suction unit is connected to the collection unit of Figure 1.
Figure 3 is an exploded view schematically showing the plug and container of Figure 1.
Figure 4 is an exploded view for explaining the capacity setting section of Figure 1.
Figure 5 is a cross-sectional view showing the capacity setting part of Figure 4 combined with the container.
Figure 6 is an exploded view of the collection unit and container of Figure 1.
Fig. 7 is a cross-sectional view of the collection section and container of Fig. 6 combined.
Fig. 8 is a cross-sectional view showing a state in which a suction part is connected to the collection part of Fig. 7.
Figure 9 is a block diagram showing a phytoplankton collection method according to one embodiment of the present invention.
Figure 10 is a process diagram showing the phytoplankton collection method of Figure 9.

Hereinafter, embodiments of the present invention will be described in detail with reference to the attached drawings so that those skilled in the art can easily practice the present invention. However, the present invention may be implemented in various different forms and is not limited to the embodiments described herein. Like parts are designated by the same reference numerals throughout the specification.

Then, a phytoplankton collection device according to one embodiment of the present invention will be described with reference to FIGS. 1 to 7.

First, referring to FIGS. 1 and 2, the phytoplankton collection device (1) according to the present embodiment includes a container (10), a stopper (20), a volume setting unit (30), a collection unit (40), and a suction unit (50), and enables collection of phytoplankton by taking an appropriate volume of sample even on a ship that experiences shaking.

Inside the container (10), a sample space (10a) having a preset volume and capable of accommodating a sample containing phytoplankton is formed.

A first coupling portion (11) protrudes from one side of the container (10), and a second coupling portion (12) protrudes from the other side. A first sample hole (111) connected to a sample space (10a) is formed in the first coupling portion (11), and a second sample hole (121) connected to a sample space (10a) is formed in the second coupling portion (12).

The sample space (10a) is open to the outside of the container (10) through the first sample hole (111) and the second sample hole (121). A sample containing phytoplankton can be injected into and filled into the sample space (10a) through the first sample hole (111) or the second sample hole (121).

The first joint part (11) and the second joint part (12) are each formed with a settling groove (111a, 121a). Each settling groove (111a, 121a) is connected to the first sample hole (111) and the second sample hole (121), respectively. The circumferential diameter of the settling groove (111a, 121a) is larger than the circumferential diameter of the first sample hole (111) and the second sample hole (121).

The cross-sectional areas of the first sample hole (111) and the second sample hole (121) gradually increase from the bottom of the mounting groove (111a, 121a) toward the inside (Z) of the container (10). Accordingly, the perimeters of the first sample hole (111) and the second sample hole (121) are formed as inclined surfaces.

Screws are formed on the outer periphery of the first joint part (11) and the second joint part (12). However, guide grooves or guide projections may be formed along the circumferential direction on the outer periphery of the first joint part (11) and the second joint part (12).

The container (10) can be made of a transparent material so that the sample in the sample space (10a) can be seen. The container (10) is not limited to a transparent material.

Referring further to drawings 3 and 5, the plug part (20) includes a plug body (21) and an insertion body (22), and is connected to the first coupling part (11) or the second coupling part (12) to block the first sample hole (111) or the second sample hole (121) when filling the sample space (10a) with a sample. Hereinafter, it will be described that the plug part (20) is connected to the first coupling part (11) to block the first sample hole (111).

The plug body (21) surrounds the circumference of the first connecting portion (11). A screw is formed on the inner circumference of the plug body (21). Accordingly, the plug body (21) can be connected to the first connecting portion (11) in a screw manner. However, if a guide groove or guide projection is formed in the first connecting portion (11), a corresponding guide projection or guide groove can be formed.

The insertion body (22) protrudes from the inner center of the plug body (21). The insertion body (22) is formed in a multi-stage shape. The first end portion (221) of the insertion body (22) is seated in the seating groove (111a), and the second end portion (222) is inserted into the first sample hole (111). The second end portion (222) has no change in cross-sectional area along the longitudinal direction. A gap (22a) is formed between the second end portion (222) and the inclined surface by the inclined surface of the seating groove (111a). The gap (22a) gradually widens as it moves away from the first end portion (221).

With the plug part (20) like this connected to the first connecting part (11), a sample containing phytoplankton can be introduced into the sample space (10a) through the second sample hole (121) to fill the sample space (10a).

Referring further to drawings 4 and 5, the capacity setting unit (30) includes a first block unit (31) and a plurality of second block units (32), and is connected to a second connecting unit (12) to which a plug unit (20) is not connected, thereby controlling the volume of the sample space (10a) and determining the capacity of the sample filled in the sample space (10a). The capacity setting unit (30) is separated from the container (10) after determining the sample capacity.

The first block part (31) includes a flange (311) and a coupling body (312) and is positioned in the second sample hole (121) to couple the capacity setting part (30) to the container (10).

The flange (311) has a preset diameter and is seated in the seating groove (121a). A gap is formed between the outer periphery of the flange (311) and the periphery of the seating groove (121a).

The coupling body (312) protrudes from the flange (311) and has a preset volume. The coupling body (312) has no change in cross-sectional area along the longitudinal direction. The coupling body (312) is inserted into the sample space (10a) through the second sample hole (121). A gap (312a) is formed between the outer periphery of the coupling body (312) and the inclined surface of the mounting groove (121a). The gap (312a) gradually widens as it gets farther away from the flange (311).

A screw is formed on the outer periphery of the connecting body (312). However, a guide groove or guide projection may be formed on the outer periphery of the connecting body (312).

The second block part (32) has a preset volume and has a fastening groove (321) formed on one side into which a connecting body (312) is inserted and fastened. A screw (322) is formed on the outer periphery of the second block part (32).

The second block portion (32) may be formed in multiple pieces and may be combined with each other. The volume of the sample space (10a) may be adjusted by the number of second block portions (32), thereby controlling the sample capacity. As the number of second block portions (32) increases, the volume of the sample filled in the sample space (10a) may decrease.

For example, the sample space (10a) has a volume that can fill 500 ml when filled with a sample. And the second block part (32) has a volume corresponding to 100 ml of a sample. When phytoplankton is to be collected from 300 ml of a sample, the sample space (10a) is filled with a sample, and then two second block parts (32) are assembled to the first block part (31). When the volume setting part (30) is inserted into the sample space (10a) through the second sample hole (121), the sample in the sample space (10a) can be discharged through the gap (312a) in an amount equal to the volume (200 ml) of the two second block parts (32). The formation of the gap (312a) facilitates the discharge of the sample. Accordingly, a sample with a volume of 300 ml can remain in the sample space (10a).

By setting the sample capacity of the sample space (10a) using the first block section (31) and the second block section (32), a sample of an appropriate capacity can be accurately taken compared to using a measuring cylinder on a rocking ship.

Referring further to drawings 6 and 7, the collection unit (40) includes a collection body (41), a support (43), and a collection net (44). The collection unit (40) is connected to a second connection unit (12) from which a capacity setting unit (30) is separated, so that phytoplankton included in the sample can be collected.

The collection body (41) has a sample suction hole (42) penetrating the inside. The sample suction hole (42) consists of a collection space (421) and a suction coupling space (422).

One side of the collecting body (41) forming the perimeter of the collecting space (421) surrounds the outer perimeter of the second connecting part (12). A screw is formed on the inside of one side of the collecting body (41) to be connected to the second connecting part (12). A support groove (421a) is formed in the collecting space (421).

The suction coupling space (422) is connected to the collection space (421) and is composed of a first space (422a) whose cross-sectional area gradually decreases, and a second space (422b) connected to the first space (422a) and to which the suction unit (50) is connected. The second space (422b) has no change in cross-sectional area. The suction coupling space (422) has a funnel structure.

A plurality of through holes (431) are formed in the support (43). The support (43) may be formed of a net. The support (43) may be made of a metal, plastic, or the like having strength. The support (43) is secured in the support groove (421a).

The collection net (44) is placed in the settling groove (121a). A sealing member (45) is placed between the collection net (44) and the bottom of the settling groove (121a). The collection net (44) can be pressurized by the support (43) and the collection net (44) when the collection body (41) is combined with the second connecting portion (12). The sealing member (45) allows the sample to pass through the collection net (44) without passing through the perimeter between the collection net (44) and the settling groove (121a). The collection net (44) is supported by the support (43). Accordingly, the collection net (44) does not sag into the suction coupling space (422).

The collection net (44) can be made of a gain-flattening filter (GFF). Water in the sample passes through the collection net (44) and the through hole (431), but phytoplankton does not pass through. Accordingly, phytoplankton can be collected in the collection net (44) while being filtered.

The collection net (44) can be separated from the mounting groove (121a) to measure the chlorophyll -a concentration of phytoplankton in the sample after collecting phytoplankton. Thereafter, a new, unused collection net can be placed in the mounting groove.

Referring further to drawing Figure 8, the suction unit (50) includes a cylinder (51), a piston (52), and a rod (53) and is coupled to a suction coupling space (422) to suction a sample in the sample space (10a).

The cylinder (51) has a preset length and has an interior that is perforated along the length direction. One side of the cylinder (51) has an insertion portion (511) protruding that is inserted into the second space (422b). The interior of the cylinder (51) is connected to the suction coupling space (422). The cylinder (51) can be made of a transparent material.

The piston (52) is arranged inside the cylinder (51). The piston (52) can move linearly inside the cylinder (51). As the piston (52) moves from one side of the cylinder (51) to the other side, the sample in the sample space (10a) can pass through the collection net (44) and the support (43) and flow into the sample space (10a).

The rod (53) has one side connected to the piston (52) and the other side exposed to the outside of the cylinder (51). A handle is formed on the other side of the rod (53). The rod (53) can be pulled or pushed using the handle. The piston (52) can move inside the cylinder (51) by the movement of the rod (53).

The following describes a method of collecting phytoplankton using the phytoplankton collection device described above with further reference to FIGS. 9 and 10.

Referring to drawings 9 and 10, the phytoplankton collection method includes a container preparation step (S10), a sample filling step (S20), a capacity adjustment step (S30), a capacity setting section separation step (S40), a collection section installation step (S50), a suction section installation step (S60), a stopper section separation step (S70), a sample suction step (S80), and a phytoplankton collection step (S90).

The method for collecting phytoplankton according to the present embodiment can be performed on board a vessel. The vessel can travel on a river or reservoir and can be shaken by the flow of water.

In the container preparation step (S10), a container (10) having a sample space (10a) having a preset volume formed inside is prepared. Then, a stopper (20) is joined to a first joining part (11) that protrudes from one side of the container (10) and has a first sample hole (111) formed therein. A second sample hole (121) formed in a second joining part (12) that protrudes from the other side is maintained in an open state.

In the sample filling step (S20), water (sample) from a river, reservoir, etc. can be filled into the sample space (10a) to evaluate the level of aquatic environment pollution such as a river, reservoir, etc. The sample is filled into the sample space (10a) through the second sample hole (121). At this time, the sample space (10a) is filled to the full. 500 ml of the sample can be filled into the sample space (10a).

In the capacity adjustment step (S30), after determining the capacity of the sample, the capacity setting unit (30) is placed in the second sample hole (121). Depending on the determined capacity of the sample, the number of second block units (32) connected to the first block unit (31) may vary. If the capacity of the sample is to be 300 ml, two second block units (32) may be connected to the first block unit (31). The two second block units (32) have a volume corresponding to 200 ml of the sample. Accordingly, 200 ml of the sample filling the sample space (10a) can be discharged to the outside of the container (10) through the gap (312a). 300 ml of the sample remains in the sample space (10a).

This allows for precise determination of the sample volume for collecting phytoplankton even from a rocking ship.

In the capacity setting unit separation step (S40), the capacity setting unit (30) is separated from the second coupling unit (12). The second sample hole (121) remains open.

In the collection unit installation step (S50), the collection unit (40) is installed in the second coupling unit (12) from which the capacity setting unit (30) is separated. The sealing member (45) is positioned at the bottom of the fixing groove (121a), and the collection net (44) and the support (43) are positioned sequentially. As the collection body (41) is coupled to the second coupling unit (12), the edge of the collection net (44) presses the sealing member (45).

In the suction unit installation step (S60), the insertion part (511) of the cylinder (51) is inserted into the second space (422b) to install the suction unit (50) in the collection unit (40).

In the plug separation step (S70), the container (10) is turned over and the plug (20) is separated from the first connecting part (11). The first sample hole (111) becomes open.

In the sample suction step (S80), when the handle of the load (53) is grabbed and pulled, the piston (52) moves away from the collection section (40) and the sample in the sample space (10a) passes through the collection net (44) and the support (43) and flows into the cylinder (51). When the sample passes through the collection net (44), the phytoplankton included in the sample is caught in the collection net (44) and is collected while being filtered, and the water in the sample passes through the collection net (44) and the support (43) and flows into the cylinder (51). Thus, phytoplankton can be collected from a sample with a capacity of 300 ml.

In the phytoplankton collection step (S90), after the collection body (41) is separated from the second connecting part (12), the collection net (44) in which the phytoplankton is collected is separated from the settling groove (121a). Then, an unused collection net is placed in the settling groove (121a) so that phytoplankton for the next sample can be collected.

The level of pollution in the aquatic environment is evaluated by measuring the concentration of chlorophyll -a of phytoplankton in a 300 ml sample through a separated collection net (44).

Accordingly, since the capacity of the sample is controlled by positioning the block of the capacity setting section in the sample space, there is an effect of being able to obtain the desired capacity even in an environment with severe shaking.

Although the preferred embodiments of the present invention have been described in detail above, the scope of the present invention is not limited thereto, and various modifications and improvements made by those skilled in the art using the basic concept of the present invention defined in the following claims also fall within the scope of the present invention.

1: Phytoplankton collection device 10: Container
10a: Sample space 11: First joint
111: 1st sample hole 12: 2nd joint
121: 2nd sample hole 111a, 121a: Fixing groove
20: Plug part 21: Plug body
22: Insert body 221: First section
222: Second section 22a, 312a: Gap
30: Capacity setting section 31: 1st block section
311: Flange 312: Joint body
32: 2nd block section 321: Fastening groove
322: Screw 40: Collection part
41: Collection body 42: Sample suction hole
421: Collection space 421a: Support home
422: Suction coupling space 422a: First space
422b: Second space 43: Support
431: Through hole 44: Collection net
45: Sealing member 50: Suction part
51: Cylinder 511: Insert
52: Piston 53: Rod

Claims (10)

A container having a sample space formed inside that can accommodate a sample including phytoplankton, a plurality of sample holes connected to the sample space, a joint portion extending the sample holes, and a mounting groove formed in the joint portion that is connected to the sample holes and in which a collection net is positioned.
A plug part that is detachably connected to a selected sample hole among the above multiple sample holes,
A capacity setting unit that controls the capacity of the sample by adjusting the volume of the sample space by inserting it into the sample space through the sample hole to which the above plug part is not connected,
A collection part that is detachably connected to a sample hole to which the above plug part is not connected, and
A suction unit that is detachably connected to the above collection unit and capable of sucking a sample from the above sample space
Including,
The above capacity setting section
A first block part that is placed in the above-mentioned fixing groove and inserted into the above-mentioned sample space, and
A second block part that is detachably connected to the first block part and is located in the sample space.
Including,
After the sample is filled in the sample space, the capacity setting unit flows into the sample space through the sample hole, and the sample in the sample space overflows to the outside of the container by the volume of the capacity setting unit, so that the capacity of the sample is set, and the sample in the sample space is discharged to the outside of the container through the collection unit, and phytoplankton is collected in the collection unit.
Phytoplankton collection device. In paragraph 1,
The above collection section
A collection body having a sample suction hole penetrating the interior and detachably connected to the sample hole;
A collecting net is placed in the above sample suction hole and the water of the sample can pass through it and the phytoplankton is collected.
A support placed in the above sample suction hole and supporting the above collection net
Including
Phytoplankton collection device. In paragraph 2,
The outer circumference of the above-mentioned connecting portion is inserted into the interior of the collecting body, and the connecting portion and the collecting body are screw-connected.
Phytoplankton collection device. In paragraph 3,
The above collection section
A phytoplankton collection device further comprising a sealing member arranged between the above-described settling groove and the above-described collection net. delete In paragraph 1,
The above first block part
A flange placed in the above-mentioned mounting groove, and
A joint body protruding from the above flange and passing through the above sample hole
Including,
A screw is formed on the outer periphery of the above-mentioned joint body,
A gap is formed between the outer perimeter of the above-mentioned joint body and the perimeter of the above-mentioned sample hole, and the gap gradually widens from the outside to the inside of the above-mentioned joint.
Phytoplankton collection device. In Article 6,
A phytoplankton collecting device having a fastening groove formed in the second block section to be coupled with the coupling body and a screw formed on the outer periphery. A container having a sample space formed inside that can accommodate a sample including phytoplankton, a plurality of sample holes connected to the sample space, a joint portion extending the sample holes, and a mounting groove formed in the joint portion that is connected to the sample holes and in which a collection net is positioned.
A plug part that is detachably connected to a selected sample hole among the above multiple sample holes,
A capacity setting unit that controls the capacity of the sample by adjusting the volume of the sample space by inserting it into the sample space through the sample hole to which the above plug part is not connected,
A collection part that is detachably connected to a sample hole to which the above plug part is not connected, and
A suction unit that is detachably connected to the above collection unit and capable of sucking a sample from the above sample space
Including,
The above plug part
A plug body surrounding the outer perimeter of the above joint, and
An insertion body protruding from the above plug body and inserted into the above sample hole
Including,
A gap is formed between the outer perimeter of the above insert body and the perimeter of the above sample hole, and the gap gradually widens from the outside to the inside of the joint.
Phytoplankton collection device. In paragraph 2,
The above suction part
A cylinder that can be detachably connected to the above collecting body,
A piston arranged so as to be able to move linearly inside the above cylinder; and
A rod connected to the piston and exposed to the outside of the cylinder
Including,
The above cylinder has a protruding insertion portion that is inserted into the sample suction hole.
Phytoplankton collection device. A method for collecting phytoplankton using a phytoplankton collection device defined in any one of claims 1 to 3 and claims 6 to 9,
A step of preparing an open container by attaching a stopper to a first sample hole connected to a sample space having a preset volume inside and a second sample hole;
A step of filling the sample space with a sample containing phytoplankton;
A capacity control step for controlling the sample capacity of the sample space by combining the first block part and the second block part of the capacity setting part in the second sample hole so that a part of the first block part is inserted into the sample space.
A step of separating the above capacity setting unit from the second sample hole;
A step of installing a collection unit with a collection net and a support arranged in the second sample hole;
Step of installing a suction unit in the above collecting unit,
A step of separating the plug part from the first sample hole,
A step of sucking a sample from the sample space using the above suction unit, and
A step of collecting phytoplankton by separating the collecting net from the collecting section.
Including,
The sample in the above sample space passes through the collecting net and the support and flows into the interior of the suction unit, and the phytoplankton in the sample is collected in the collecting net.
Methods for collecting phytoplankton.

Images