JP2015096048A - Organism rearing device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an organism rearing device easy to be cleaned even if it is a large-scale device where organisms are arranged in multiple stages.SOLUTION: The above subject is solved by using as a guttering a circulation flow channel which collects effluents flowing out of organism containers, and, in addition, using as a guttering an effluent collection channel which is preferably located in an organism housing unit lower part, and supplies the effluent collected from the circulation flow channel to a storage tank.

Description

  The present invention relates to an organism-growing device.

In order to carry out industrial production of organisms on a large scale, it is necessary to increase the space for growing organisms. Therefore, not only the cost of land procurement and construction increases, but also the energy consumption necessary for air conditioning and the like increases. As a result, since the cost required for the growth of organisms increases, it has hindered the scale expansion of the industrial production of organisms that require strict management of the growth environment.
As a solution to this problem, there has been proposed a living body breeding apparatus in which a living body is stored in a plurality of storage containers and connected to a support structure and stacked in the vertical direction. For example, a growing apparatus having a multi-stage storage container is known for growing plants (Patent Document 1, Non-Patent Document 1).

Japanese Patent Laid-Open No. 2005-21064

Complete plant factory July 28, 2010 Issued by Nikkei Business Publications, Inc.

In the organism growing apparatus of the form in which the organisms are stored in a plurality of containment containers and connected to the support structure and stacked in the vertical direction as proposed above, the apparatus becomes large and difficult to clean. Become. In particular, when cleaning pipes, it is generally performed by applying high pressure, but in a large-scale apparatus equipped with a multi-stage organism storage container, the exhaust discharged from each organism storage container. The pipe where the liquid collects needs to have a large diameter. In this case, when cleaning the upper part of the pipe, there is a difficulty in that a large amount of cleaning liquid is required.
Particularly in the case of genetically modified organisms, the criteria for washing are strict and a high level of washing is required.
This invention makes it a subject to provide the biological body cultivation apparatus which is easy to clean even if it is a large-scale apparatus.

  The inventors of the present invention have made researches to solve the above-mentioned problems. As a result, the circulation flow path for collecting the drainage liquid flowing out from the organism storage container is used as a reed, and in addition, a circulation flow preferably located below the organism storage unit is used. The present inventors have found that the problem can be solved by using a drainage collecting passage for supplying drainage collected from the passage to the storage tank, and completed the present invention.

The present invention is as follows.
An organism storage unit including an organism storage container for storing the organism, and a support structure capable of supporting them;
A storage tank for storing a nutrient solution and / or a drainage solution for growing organisms (in the present invention, a nutrient solution discharged from the organism storage container is referred to as “drainage solution”), and supplying a nutrient solution for the storage tank A liquid supply mechanism, and a liquid supply mechanism including a liquid supply pipe for supplying a nutrient solution from the liquid supply pump to the organism storage container, and a biological body disposed beside or below the organism storage container. A collection bottle that can collect the drainage flowing out of the containment vessel, a drainage pipe that sends the drainage collected by the collection bowl to the collection bowl, and a drainage that is sent through the drainage pipe, A drainage mechanism, including a collecting bowl poured into the storage tank,
An organism training apparatus comprising:

  Further, in a preferred embodiment of the present invention, a cleaning mechanism is further provided, and the cleaning mechanism can recover the cleaning liquid discharged from the discharge port of the storage tank, and the cleaning liquid recovered by the cleaning tank, A cleaning bypass pipe for supplying the recovery tank, the drain pipe, or the collecting tank.

In the present invention, since the upper surface of the soot is opened by using the horizontal flow path of the drainage as a soot, the soot can be easily washed using a sponge or the like. Moreover, the effect of washing | cleaning can be visually recognized without performing decomposition | disassembly etc. of piping, and it can also confirm easily the generation | occurrence | production conditions of algae, bacteria, a biofilm, etc.
Moreover, the number of pipe connection places can be reduced by using a gutter, and the leakage of the liquid from a connection part and the residue to a clearance gap can be suppressed.
Furthermore, the flow path that maximizes the amount of cleaning liquid and cleaning water is the drainage collecting flow path, and a pump that reduces the amount of cleaning liquid and cleaning water and applies pressure to the liquid by preparing the drainage collecting flow path as a preparation is prepared. There is no need to do this and the cost can be reduced.

  In addition, according to a preferred embodiment of the present invention, it is possible to remove the organism storage container and clean the piping etc. in parallel by installing the cleaning dredge, thereby shortening the cleaning time of the entire apparatus. Can do.

It is a perspective view which shows one embodiment of the biological body cultivation apparatus of this invention. It is a perspective view which shows the liquid supply mechanism of the biological body cultivation apparatus of this invention, and a drainage mechanism. It is sectional drawing which shows the specific example of the flow of the drainage from the organism storage container to the collection container in the organism growing device of this invention. It is a perspective view which shows the aspect of the organism storage container periphery of the organism cultivation apparatus of this invention. It is a schematic diagram which shows supply of the waste_water | drain between the waste_water | drain piping of the biological body cultivation apparatus of this invention, and the collection basket. It is a schematic diagram which shows the example of a shape of the gathering cage | basket of the biological body breeding apparatus of this invention. It is a perspective view which shows the liquid supply mechanism, drainage mechanism, and washing | cleaning mechanism of the biological body growing apparatus of this invention.

  Hereinafter, the present invention will be specifically described with reference to the drawings. However, the present invention is not limited to the contents described below, and can be arbitrarily changed and implemented without changing the gist thereof. is there. In addition, the drawings used in the description schematically show the organism growing apparatus according to the present invention or its constituent members, and are partially emphasized, enlarged, reduced, omitted, etc. to deepen understanding. In some cases, it does not accurately represent the scale or shape of each component. Furthermore, the various numerical values used in the description with reference to the drawings are only examples, and can be variously changed as necessary.

FIG. 1 shows a living body growing apparatus according to this embodiment.
The organism training apparatus 100 according to this embodiment includes an organism storage unit, a liquid supply mechanism, and a drainage mechanism. The organism growing apparatus 100 includes a three-stage organism storage container 1 supported by the support structure 10 and supplies the nutrient solution stored in the storage tank 11 to each organism storage container 1 by a liquid supply mechanism. The nutrient solution that has been liquefied and supplied to each organism storage container 1 is returned to the storage tank 11 by the drainage mechanism so that the nutrient solution can circulate.
The organism growing apparatus 100 according to this embodiment is characterized by a mechanism for feeding nutrient solution, particularly a drainage mechanism, and will be described in detail below.

1 Organism Storage Unit The organism growth apparatus 100 includes a organism storage unit, and the organism storage unit includes a organism storage container 1 and a support structure 10 that supports the organism storage container 1. It is also possible to have a lighting device (not shown) for growing a living organism. It can also have a working scaffold.
The biological body growing apparatus 100 has a framework formed by the support structure 10 and supports the biological body storage container 1. The organism storage container 1 includes three stages, but is not limited thereto. In order to grow many organisms at once, it is preferably a multi-stage configuration of two or more stages, preferably three or more stages, five or more stages, eight or more stages, ten or more stages, 15 or more stages, or more than 20 stages. it can.
The upper limit of the stage that the organism storage container has is 30 stages, and usually 25 stages or less. The number of stages of the organism storage container can be appropriately determined depending on the size of the organism to be grown.
In addition, if the organism growing device is high, for example, if it is 10 m or more, when using an aerial work vehicle for the planter supply work in the upper part, the worker may be restricted. It is preferable to determine the number of steps so as to suppress the height to 10 m or less. For example, the upper limit level of height that can be handled by a picking fork or the like is 6 m.
By increasing the number of stages, the productivity per area is the same, so the building cost and site preparation cost can be reduced.

1.1 Organism Storage Container The organism storage container 1 is for growing, cultivating, and / or holding a living organism.
It has the function of holding and / or discharging water as needed.
Although the shape is arbitrary, in order to increase the efficiency of the space required for installing the organism growing apparatus, it is desirable to stack the organism storage containers vertically at a narrow interval, so a relatively thin tray shape in the horizontal direction is preferable. Used.

  The shape of the bottom surface, that is, the shape in the horizontal direction is not particularly limited, and may be any of a circle, an ellipse, and / or a polygon, but a quadrangle is preferable from the viewpoint of space use efficiency. The size in the horizontal direction is not particularly limited, but in the case of a circle, the diameter is long, in the case of an ellipse, the longest diameter is in the case of a polygon, and the maximum diagonal length is usually 20 m or less, preferably 5 m or less, more preferably 2 m. Hereinafter, it is further preferably 1.5 m or less, usually 10 cm or more, preferably 20 cm or more, more preferably 30 cm or more. The height is usually 2 m or less, preferably 1 m or less, more preferably 50 cm or less, still more preferably 10 cm or less, and the lower limit is usually 5 mm or more, preferably 1 cm or more, more preferably 3 cm or more. In the case of having side surfaces, the height of the side surfaces is preferably constant.

  When the size of the organism storage container is less than or equal to the above upper limit, the management of the organism, the handling of the organism storage container, and the like are facilitated and can be used practically. By being above the above lower limit, it is possible to properly grow by securing a growth space for organisms, and furthermore, the number of necessary organism storage containers can be reduced, which is necessary for maintenance and management of organism storage containers. It is preferable at the point which can suppress time.

The organism storage container may be provided with a partition or a plurality of small containers as required.
The containment vessel may be appropriately provided with a structure such as a flow channel for supplying water, a water supply unit, a drainage unit, or the like, such as a section or a holding part for holding or fixing a living organism.

  There are no particular restrictions on the material of the biological containment vessel, but resin materials such as ABS, vinyl chloride, polypropylene, polystyrene, acrylic resin, polycarbonate, urethane, and polystyrene, and their alloys and filler composite materials, carbon steel, stainless steel, aluminum Metal materials such as steel, wood, and glass materials are used. Among these, a resin material is preferable in that a component that affects the growth of a living organism is hardly generated.

1.2 Support Structure The support structure is used to support a plurality of organism storage containers in the vertical direction. The support may be fixed or placed.
The method in the case of fixation will not be specifically limited if the support structure and the organism storage container are fixed with the required intensity | strength. It is fixed directly or via a connecting member between the organism growing apparatus and the support structure. Specifically, screwing, bolting, welding, adhesion and the like can be mentioned. The support structure and the organism storage container may be fixed on the side surface or the bottom surface of the organism storage container.
In the case of being fixed via the connection member, the connection member may be installed between the support structure and the side surface of the organism storage container, or installed between the support structure and the bottom surface of the organism storage container. Also good.
When installing between a support structure and the bottom face of a biological storage container, the method of installing a biological body storage container directly or indirectly on the upper surface of the mounting member mentioned later is mentioned.

Although there is no restriction | limiting in particular in the shape of a support structure, The pillar which consists of a square-shaped or rod-shaped material is used preferably.
In the case where the support is by placing the organism storage container on the support structure, the support structure is a member (hereinafter referred to as a placement member) on which the organism storage container can be placed on a pillar made of a square or rod-like material. (Also referred to as a plurality of) in the vertical direction, and the organism storage container is placed on the member.
As a specific method of fixing the mounting member to the column, there is a method of fixing the mounting member to the column directly or via a fixing member by a method such as screwing, bolting, welding, or adhesion.
By placing the organism storage container on each of the plurality of mounting members, the organism storage containers are stacked in the vertical direction. The mounting member may be provided with a member for aligning the organism storage container on the upper surface thereof.
When support is placed, the biological containment vessel can be handled independently of the support structure, so that the biological containment vessel can be carried into the support structure from another location, and can be carried out from the support structure to another location. This is preferable.

The size of the whole organism storage unit including the support structure and the organism storage container as a component is not particularly limited as long as the organism storage container can be appropriately accommodated, but the maximum horizontal length is usually 100 m. In the following, it is preferably 50 m or less, more preferably 20 m or less, still more preferably 15 m or less, and the lower limit thereof is 10 cm or more, preferably 20 cm or more, more preferably 30 cm or more. The upper limit of the height is usually 20 m or less, preferably 10 m or less, more preferably 8 m or less, and the lower limit is usually 1 m or more, preferably 1.5 m or more, more preferably 2 m or more, still more preferably 4 m or more, and most preferably It is 5 m or more. When the size of the support structure is equal to or less than the above upper limit, the space for installation does not become too large, air conditioning is facilitated, and the operation path of work when performing industrial production of organisms is appropriate. It can be a range. On the other hand, by being more than a lower limit, the required quantity of the support structure required for a certain amount of organism growth can be suppressed, and the volume of space required around each support structure can also be suppressed. The upper limit of the height of the mounting member is usually 50 cm or less, preferably 15 cm or less, more preferably 10 cm or less, further preferably 5 cm or less, most preferably 3 cm or less, and the lower limit is usually 1 mm or more, preferably 3 mm or more. is there. When the height is equal to or less than the upper limit, the weight of the entire support structure can be suppressed, which is preferable in terms of facilitating installation work. On the other hand, if it is too small, it is preferable that it is equal to or more than the lower limit in that it is easy to ensure sufficient strength to mount the organism storage container.

  There are no particular restrictions on the materials of the support structure and the mounting member, but wood or metal materials such as carbon steel, stainless steel, and aluminum steel are preferably used in terms of high strength, but they are more stable and have high installation accuracy. A metal material is more preferable. When water is used for organism growth, metal materials that are not easily corroded, such as stainless steel, aluminum steel, and alloy materials thereof are preferable. For the purpose of preventing corrosion, it is also possible to use a metal material that has been appropriately coated, passivated or plated.

1.3 Illumination device When light is required for the growth of a living organism, an illumination device may be provided in the organism growth device. Specific examples of cases where light is necessary for the growth of organisms include those that require a light-dark period in order for the organism to maintain life for the intended period or to promote the growth of organisms, For example, when it is desired to stimulate and grow in the desired shape and direction, light energy for photosynthesis is required.
Since the light emitted from the lighting device needs to be appropriately irradiated according to the purpose, the lighting device is usually installed relatively close to the living organism storage container. . In particular, it is convenient for the lighting device to be installed on the upper part of the organism storage container for the convenience of the operator and engineer to observe and manage the growth state of the organism.

  As a specific installation method, screws or bolts are directly or via a fixing member on the lower surface of another organism storage container existing above the organism storage container or the lower surface of the mounting member constituting the support structure. A fixing member for a lighting device having a fitting portion or an uneven portion provided to the support structure by the above method is fixed to the supporting structure, and the fixing member is fixed to the fitting portion or the uneven portion. For example, there is a method of mounting and fixing the lighting device so that the position does not fluctuate. In that case, it is preferable to arrange so that light can be uniformly irradiated to the organism to be grown without waste.

The lighting device is not limited as long as the object can be achieved, and a known lighting device can be used. Specific examples of types of lighting devices include sodium lamps, mercury lamps, fluorescent lamps, metal halide lamps, ultraviolet lamps, infrared lamps, far-infrared lamps, microwave irradiation apparatuses, LEDs, electroluminescence, neon lamps, and the like. Among these, fluorescent lamps and LEDs with high luminous efficiency are preferable.
As a specific example of the form of the lighting device, in order to save the installation space and increase the efficiency of air conditioning, a cylindrical or flat transparent or semi-transparent case containing or emitting a light emitting part is used. The The upper limit of the size in the horizontal direction is usually 3 m or less, preferably 2 m or less, more preferably 1.5 m or less, and the lower limit is 30 cm or more, preferably 50 cm or more, more preferably 1 m or more. If this size is too large, installation work becomes difficult, which is not preferable. On the other hand, if it is too small, light irradiation unevenness tends to occur, and the electrical wiring required for the lighting device becomes complicated, which is not preferable.
You may give a waterproof specification by the method of covering the electrical connection part of an illuminating device with a cap.

1.4 Others The organism containment unit may include a working scaffold. Scaffolds are used for the purpose of observing and managing the growth state of organisms and managing and maintaining the growth devices related to water. There is no particular limitation as long as an operator or a technician can get on to access the vicinity.
In particular, when using a support structure on which a plurality of organism storage containers are placed at a relatively high position, a support structure is installed to improve workability when an operator or engineer performs a predetermined work. It is preferable to install the scaffold at a position higher than the formed surface.

2 Liquid supply mechanism In this embodiment, the liquid supply mechanism is a storage tank that stores nutrient solution and / or drainage for growing organisms, a supply pump that supplies nutrient solution in the storage tank, and a supply pump. A liquid supply pipe for supplying a nutrient solution to the organism storage container. The liquid supply mechanism will be described with reference to FIG.
FIG. 2-1 also shows the organism growing apparatus according to the present embodiment, and the organism storage container is not shown in order to easily show the feeding route of the nutrient solution.

In FIG. 2-1, the nutrient solution in which the concentration, pH value, temperature, etc. of nutrients are adjusted and managed in the storage tank 11 is forcibly fed by the feed pump 13, and the path to the organism storage container It passes through the liquid supply pipe 14 and is supplied from the nozzle 15 to each organism storage container. The nutrient solution used for the growth of the organism in the organism storage container is recovered by the recovery cage 16 located adjacent to the upper part of the organism storage container or at the lower part of the organism storage container, and is stored in the storage tank. A circulation path is formed that passes through the drainage pipe 17 serving as a path to return to 11, gathers in the gathering basket 18 located at the lower part of the organism breeding unit, and is collected again in the storage tank 11.
Adjustment and management of nutrient concentration and pH value of nutrient solution in the storage tank 11 is based on feedback of data collected from conductivity meter, pH meter, temperature sensor, and supply amount of nutrient, acid and alkali supply pumps. It can be managed by controlling. The temperature can be adjusted with a chiller (refrigerator) or the like.

2.1 Storage Tank The storage tank 11 is disposed in a gap formed by the support structure and / or piping, and stores a nutrient solution for growing organisms. The capacity of the storage tank may be appropriately selected according to the scale of the organism growing apparatus, but is usually 400L or more, preferably 1000L or more, more preferably 2000L or more, and usually 20000L or less, preferably 15000L or less. Preferably it is 10,000L or less. It is preferable to have a capacity that is at least equal to the amount of nutrient solution or cleaning solution used.
When the organism storage container is configured in three stages, for example, a tank having a capacity of 600 L can be used.
The storage tank 11 can store not only the nutrient solution but also the effluent once supplied to the organism.
The stored drainage liquid can be circulated again as a nutrient solution, and can also be sent to the drainage channel by the drainage pipe 12.
In addition, the cleaning liquid can be stored at the time of cleaning.
Two or more storage tanks may be provided, and the number of tanks can be selected according to the purpose. Increasing the number of storage tanks is preferable in that the liquid can be easily managed. For example, by providing two storage tanks, the storage of the nutrient solution and the storage of the cleaning solution can be performed in different tanks. Further, by providing three storage tanks, in addition to the nutrient solution and the cleaning solution, it is possible to store the nutrient solution or the drainage of the cleaning solution in another tank. Furthermore, by providing four storage tanks, the nutrient solution, the cleaning solution, the drainage of the nutrient solution, and the drainage of the cleaning solution can be stored in another tank. On the other hand, in order to facilitate cleaning of the entire organism growing apparatus, it is better that the number of storage tanks is small.

The shape of the storage tank 11 is usually a rectangular parallelepiped, but may be polygonal, cylindrical, or spherical. Moreover, you may connect with a supply nozzle, a drain nozzle, a collar, etc.
The material of the storage tank may be a metal such as iron, stainless steel or aluminum, or a resin. Since the storage tank 11 is not pressurized, the storage tank 11 has a shape in which the upper part is opened to a content that can be cleaned. In addition, a drainage pipe 12 is provided for discharging the drainage liquid from the lower and side surfaces of the storage tank 11, and a mechanism that can supply water and a regulator to the tank from the upper and side surfaces of the storage tank 11 is provided. The upper part of the storage tank 11 may be open.

  The nutrient solution used in the present embodiment needs to adjust and manage the nutrient concentration, pH value, temperature, etc. for the growth of organisms, and may require sterilization. In addition, when draining the nutrient solution used for the growth of genetically modified organisms, special wastewater treatment is also required, which must be recycled and reused from the viewpoint of economy and risk reduction of external environmental pollution. Is preferred.

2.2 Liquid Supply Pump The nutrient solution stored in the storage tank 11 is pushed out by the two liquid supply pumps 13 and supplied to the organism through the liquid supply pipe 14 via the nozzle 15.
The feed pump is only required to forcibly transfer the nutrient solution, and the type of pump is not limited. Examples of the liquid circulation pump include a submersible pump, a magnet pump, a vortex pump, and a vane pump. A submersible pump and a magnet pump in which the pump rotating shaft is not in contact with the liquid are preferable. Further, the liquid supply pump may be used by directly entering the storage tank, or the storage tank and the liquid supply pump may be connected by piping.

2.2 Liquid Supply Pipe The liquid supply pipe 14 is a nutrient solution flow path from the storage tank 11 to the organism, and the nutrient solution is supplied to the organism storage container via the nozzle 15. The nozzle 15 is not essential, and the nutrient solution may be directly supplied to the organism from the liquid supply pipe.
When the nozzle is not provided, a method can be adopted in which a horizontal hole or a vertical hole is formed in the pipe and the nutrient solution is supplied from the hole to the organism storage container. When such a method is employed, the position of the cleaning liquid falling on the cleaning basket changes depending on the flow rate during cleaning, which will be described later. Therefore, it is necessary to adjust the amount of the cleaning liquid in order to reliably drop the cleaning liquid on the cleaning basket. . Moreover, an air layer may be formed on the upper part of the pipe. In such a case, there is a possibility that unwashed parts in the pipe may be generated during cleaning.
The material of the liquid supply pipe may be a metal such as iron, stainless steel, or aluminum, or a resin. The shape of the liquid supply pipe is usually a cylinder.
The diameter of the liquid supply pipe is not particularly limited, and can be set as appropriate according to the horizontal length of the organism storage container and the type of organism.

3 Drainage mechanism In this embodiment, the drainage mechanism is disposed on the side or the lower side of the organism containment vessel, and can recover the nutrient solution flowing out from the organism containment vessel. A drainage pipe for feeding the liquid to the collecting tank, and a collecting bowl for receiving the nutrient solution fed through the drainage pipe and flowing it into the storage tank.

The present invention solves the problem of washing, and in particular, a high level of washing is required for the growth of genetically modified organisms. On the other hand, in order to grow a large number of organisms at once, if a device becomes large by providing a plurality of organism containment vessels, a very high pressure is required when cleaning the upper part of the pipe where drainage collects. There is a problem that cleaning is difficult.
In the present invention, in the drainage mechanism, the channel for collecting the drainage is used as a trap, and specifically, the trap for collecting that receives the nutrient solution sent through the drainage pipe and flows into the storage tank. With this, the organism storage container has multiple stages, and cleaning can be easily performed even when the diameter of the flow path where a large amount of drainage collects increases.
In the description of the drainage mechanism in the present specification, the nutrient solution that has flowed out of the organism storage container is referred to as “drainage”.

3.1 Recovery Trap The drainage liquid supplied to the organism and flowing out of the organism storage container is received by the recovery rod 16 and sent to the drainage pipe 17.
Since the recovery basket 16 receives the drainage liquid flowing out from the organism storage container, the recovery basket 16 is arranged beside or below the organism storage container.
Moreover, it is preferable that the recovery basket 16 has a structure in which the drainage recovered from the organism storage container flows into the drainage pipe 17. With such a structure, the drainage liquid can be circulated regardless of the external force. Specifically, a gradient may be provided in the collection basket.
One end of the recovery tub 16 is connected to the drainage pipe 17 and the drainage is fed.

The cross section of the recovery basket 16 has a rectangular parallelepiped shape including a bottom surface and side surfaces, but is not limited thereto. It may be a tube having an opening and can transfer a fluid liquid without leaking or spilling in the middle, and may have a polygonal or cylindrical shape with an upper opening or a semicircular shape. A flexible type such as a bellows may be used.
In terms of ease of cleaning, it is preferable that the concave portion present on the inner side of the polygonal ridge is a curved surface with the corners of the polygonal shape being removed. The curved surface preferably has a larger radius of curvature. The radius of curvature is usually 1 mm or more, more preferably 5 mm or more, still more preferably 10 mm or more, and is usually 50 cm or less, preferably 30 cm or less, more preferably 10 cm or less.
In addition, when the ridge has a connecting portion, it is preferable not to form a recess that is difficult to clean in the connecting portion, so that the gap or step is not formed, or the recess is filled by caulking or the like. Furthermore, it is preferable that the inner surface of the ridge does not have fine irregularities and is a smooth surface.
By satisfying the above requirements, it becomes easier to perform the cleaning work to remove dirt on the inner side of the bag, and it becomes unnecessary to use a tool having a special hardness in cleaning, such as a hard scourer or steel wool, There is no need to damage the inner surface of the bag. On the other hand, if a tool having a particular hardness is used for cleaning, scratches are generated on the inner side surface of the bag, and the scratches become a new dirt deposit site, which is not preferable.
The collection gutter 16 may have an opening for joining with the drainage pipe 17. If a sharp end face is generated at the edge of the opening during the manufacture or molding of the ridge, it is dangerous to clean the ridge. Therefore, it is preferable to remove the sharp end face by chamfering or the like. As a result of chamfering, the edge of the opening has a curvature of 1 mm or more, preferably 2 mm or more, more preferably 3 mm or more, and is usually 5 cm or less, preferably 3 cm or less, more preferably 1 cm or less.
Further, the lid may be attached depending on applications such as dust prevention and light shielding. The collection basket has a sufficient cross-sectional area to prevent the drainage from overflowing, and may be inclined in the longitudinal direction in order to determine the flow direction.
The material of the recovery basket may be a metal such as iron, stainless steel, or aluminum, or a resin.
The recovery basket is usually a straight type, but may be a curved type or a loop shape, and may be formed integrally or can be divided.
When cleaning is necessary due to adhesion of drainage liquid to the collection basket or adhesion of algae and fungi, cleaning by hand washing is possible from the opening.
By using the recovery basket 16, it is not necessary to connect the drainage pipe to the organism storage container, and the drainage can be sent by simply opening and closing the opening provided in the organism storage container. When the storage container is carried into or out of the organism growing unit or moved, the operation becomes easy.
Hereinafter, an example of a specific structure for dropping the drainage liquid from the organism storage container to the collection basket will be described with reference to FIG.
In FIG. 2B, the nutrient solution from the liquid supply pipe 14 is supplied to the organism storage container 1 through the nozzle 15. The organism storage container 1 is provided with a discharge port 1a, and the drainage liquid flowing out from the discharge port 1a is received by a recovery bottle 16.
The position of the discharge port 1a is appropriately set depending on the position at which the recovery basket 16 is disposed.
FIGS. 2-2 (a) and (c) are examples in which the recovery basket 16 is disposed below the organism storage container 1. The discharge ports 1a and 1c are provided on the bottom surface of the organism storage container 1, and the recovery basket 16 is disposed under the discharge ports 1a and 1c and receives drainage. Further, the sizes of the discharge ports 1a and 1c may be set as appropriate according to the size of the recovery basket 16, the amount of nutrient solution supplied, and the amount of organisms to be grown.
FIG. 2-2 (b) is an example in which the recovery basket 16 is arranged on the side of the organism storage container 1. The discharge port 1b is provided on the side surface of the organism storage container 1, and the recovery basket 16 is disposed under the discharge port 1b and receives drainage. Further, the size of the discharge port 1b may be set as appropriate according to the size of the recovery basket 16, the amount of nutrient solution supplied, and the amount of organisms to be grown.

3.2 Drainage Pipe The drainage pipe 17 is connected to the collection basket 16 at each stage of the biological containment vessel, and collects the drainage into the collection bowl 18. The material of the drainage pipe may be a metal such as iron, stainless steel or aluminum, or a resin.
The diameter of the drainage pipe is not particularly limited, and can be appropriately set according to the horizontal length of the organism storage container and the type of organism.

3.3 Collecting cage 18 The gathering cage 18 is usually located in the lower part of the organism storage unit, collects the drainage liquid from the organism storage container, and supplies the drainage liquid to the storage tank 11. The collecting basket 18 is preferably arranged on the upper part of the storage tank 11 from the viewpoint of facilitating the supply of drainage to the storage tank. In addition, when the collecting basket is not arranged at the lower part of the organism storage container, the drainage pipe 17 may be extended and the drainage may be collected by installing a pump if necessary. By arranging it at the lower part of the unit, gravity can be used for collecting the drainage, and an external power source such as a pump becomes unnecessary.
Moreover, it is preferable that the collecting basket 18 has a structure in which the drainage flows to a supply port that supplies the drainage to the storage tank. In order to obtain such a structure, the gathering cage 18 may be provided with a gradient.

The cross-section of the gathering cage 18 is a rectangular parallelepiped shape including a bottom surface and side surfaces, but is not limited thereto. It may be a tube having an opening and can transfer a fluid liquid without leaking or spilling in the middle, and may have a polygonal or cylindrical shape with an upper opening or a semicircular shape. A flexible type such as a bellows may be used.
Further, the lid may be attached depending on applications such as dust prevention and light shielding. The collecting basket has a sufficient cross-sectional area to prevent the drainage from overflowing, and may be sloped in the longitudinal direction to determine the flow direction.
The material of the gathering cage may be a metal such as iron, stainless steel or aluminum, or a resin.
The gathering basket is usually a straight type, but may be a curved type or a loop shape, and may be formed integrally or may be divided.
When washing is required due to the attachment of drainage to the collecting basket, or the attachment of algae or fungi, washing by hand washing is possible from the opening.

The size of the gathering cage can be appropriately set according to the number of stages of the organism storage container, but the cross-sectional area of the cage serving as the flow path is preferably 50 cm ² or more, and preferably 100 cm ² or more. More preferred. On the other hand, the upper limit is not particularly limited, but is preferably 3000 cm ² or less from the viewpoint of space saving.
The flow rate of the drainage liquid that can be fed by the collecting basket is preferably 0.1 L / s or more, more preferably 0.3 L / s or more, while the upper limit is not particularly limited, but space saving. In view of the above, it is preferably 60 L / s or less.
In the organism growing apparatus of the present invention, genetically engineered organisms may be grown, and in that case, cleaning of the circulating fluid system is essential. In the cleaning, it is difficult to clean the piping of the drainage mechanism that does not apply pressure. When piping is used for the drainage mechanism, it is necessary to provide a bypass circuit from the piping of the supply mechanism and wash it by applying pressure. However, in the drainage mechanism, the piping is merged toward the end so that pressure is not easily applied. By making the final junction part into a bowl and making it an open type, cleaning can be performed with a brush or the like.
In terms of easiness of cleaning, when the cross-section of the collecting cage 18 is polygonal, it is preferable that the concave portion present on the inner side of the basket is a curved surface with the corners of the polygonal apex taken. The curved surface preferably has a larger radius of curvature. The radius of curvature is usually 1 mm or more, more preferably 5 mm or more, still more preferably 10 mm or more, and is usually 50 cm or less, preferably 30 cm or less, more preferably 10 cm or less.
In addition, when the ridge has a connecting portion, it is preferable not to form a recess that is difficult to clean in the connecting portion, so that the gap or step is not formed, or the recess is filled by caulking or the like. Furthermore, it is preferable that the inner surface of the ridge does not have fine irregularities and is a smooth surface.
By satisfying the above requirements, it becomes easier to perform the cleaning work to remove dirt on the inner side of the bag, and it becomes unnecessary to use a tool having a special hardness in cleaning, such as a hard scourer or steel wool, There is no need to damage the inner surface of the bag. On the other hand, if a tool having a particular hardness is used for cleaning, scratches are generated on the inner side surface of the bag, and the scratches become a new dirt deposit site, which is not preferable.
The collecting basket 18 has a supply port for joining with the storage tank 11. If a sharp end face is generated at the edge of the supply port during the production or molding of the ridge, it is dangerous to clean the ridge. Therefore, it is preferable to remove the sharp end face by chamfering or the like. As a result of chamfering, the edge of the supply port has a curvature of 1 mm or more, preferably 2 mm or more, more preferably 3 mm or more, and is usually 5 cm or less, preferably 3 cm or less, more preferably 1 cm or less.
In addition, if the drainage pipe is directly connected to the tank, the installation space may increase as compared with the case of using the soot depending on the number of pipes and the like, and space saving can be achieved by using the gathering soot 18. Moreover, since the drainage pipe is cylindrical, when the storage tank is provided under the organism storage container, the first stage of the organism storage container may become higher. The height of the first stage of the body storage container can be suppressed.
Moreover, it is also possible to store a part or all of the nutrient solution in the collecting basket 18 by enlarging the collecting basket.

FIG. 3A shows details of the connection between the organism storage container, the liquid supply mechanism, and the drainage mechanism according to this embodiment.
The nutrient solution stored in the storage tank is fed through the liquid supply pipe 14 and supplied from the nozzle 15 to the organism storage nutrient solution 1.
The nutrient solution supplied to the organism storage container 1 flows out of the organism storage container 1 and is received by the recovery basket 16 located in the lower part (back of the figure) of the organism storage container 1. At this time, it is preferable that the organism storage container 1 has a structure in which the nutrient solution flows from the nozzle 15 side to the recovery basket 16 side (the rear side in the drawing). Specifically, a gradient can be provided.

The recovery tub 16 is connected to the drainage pipe 17 at the end thereof, and the recovered effluent is transferred to the collecting tub 18.
The collecting bowl 18 receives the drainage from the plurality of drainage pipes 17 and flows the drained liquid collected from the supply port 19 into the storage tank. It is not necessary to connect the drainage pipe 17 and the collecting cage 18, and it is sufficient that the drainage pipe 17 exists above the gathering cage 18.
As a method of connecting to the gathering cage 18, a method of connecting a pipe to the side of the cage is also possible.
The collecting bowl 18 preferably has a structure such that the collected drainage flows to the supply port 19. Specifically, a gradient can be provided.

FIG. 3-2 shows an example of drainage supply between the plurality of drainage pipes 17 and the collecting basket 18. (A) shows the aspect in which the drainage pipe 17 is connected to the side surface of the collecting basket 18 and the drainage liquid flows from the side surface of the basket to the collecting basket. (B) is a mode in which the drainage pipe 17 and the collecting rod 18 are not connected, and the drainage pipe 17 is positioned above the collecting rod 18 so that the collecting rod 18 can receive the drainage. Show. In the mode (b), the connection between the drainage pipe 17 and the collecting gutter 18 is unnecessary, and is a simpler mode.
FIG. 3-2 shows an example of the shape of the gathering cage 18. The shape of the gathering cage 18 may be appropriately set according to the size of the organism growing device, the number of drainage pipes, and the like. Specifically, (a) B-shaped set 樋, (b) U-shaped set 樋, (c) L-shaped set 樋, (d) T-shaped set 樋There may be. The collecting basket 18 is provided with a discharge port, and the discharged liquid is discharged from the discharge port to the storage tank 11.

4 Cleaning Mechanism FIG. 2A shows a liquid supply system including a liquid supply mechanism and a drainage mechanism in the organism growing apparatus, and the liquid supply mechanism and the drainage mechanism have been described. As a preferred embodiment, the present invention includes an organism growing apparatus further having a cleaning mechanism. The cleaning mechanism includes a cleaning tub that can recover the cleaning liquid supplied from the storage tank, and a cleaning bypass pipe that sends the cleaning liquid recovered by the cleaning tub to the drainage pipe. The cleaning mechanism will be described with reference to FIG.
FIG. 4 is a perspective view in which a cleaning mechanism is added to the organism growing device shown in FIG. At the time of cleaning, the liquid supply mechanism and the drainage mechanism can be cleaned by filling the storage tank 11 with the cleaning liquid and sending the cleaning liquid to the flow path.

4.1 Cleaning Basin The cleaning mechanism sends the cleaning fluid supplied from the storage tank 11 by the liquid supply pipe 14 to the cleaning basket 21 and the cleaning liquid collected by the cleaning basket 21 to the drain pipe 17. The cleaning bypass pipe 22 is included.
The cleaning tub 21 is disposed adjacent to the liquid supply pipe 14, and the cleaning liquid may flow into the cleaning tub 21 through the nozzle 15, and the nozzle is removed from the liquid supply pipe 14 by opening a horizontal hole or a vertical hole in the pipe. The cleaning liquid may be allowed to flow into the cleaning tub 21 from the hole without passing through 15, and by providing a switching valve or the like, the cleaning liquid is allowed to flow into the cleaning tub 21 without passing through the nozzle 15 from the liquid supply pipe 14. Also good.
One end of the cleaning tub 21 is connected to the cleaning bypass pipe 22, and the cleaning liquid collected by the cleaning tub 21 is sent to the drain pipe 17.

  The cleaning tub 21 is a flow path used when cleaning the liquid supply pipe 14, and feeds the cleaning liquid to the drainage pipe 17 through the cleaning bypass pipe 22. At the time of organism growth, the nutrient solution from the liquid supply pipe is supplied to the organism storage container via the nozzle 15, but at the time of cleaning, the supply destination of the cleaning liquid is changed to the cleaning bowl, thereby storing the organism. Even when the container is removed, the liquid supply pipe can be cleaned.

The cross-section of the cleaning basket 21 is a rectangular parallelepiped shape including a bottom surface and a side surface, but is not limited thereto, and may be a polygonal shape or a cylindrical shape with an upper opening or a semicircular shape. Further, the lid may be attached depending on applications such as dust prevention and light shielding. The cleaning basket has a sufficient cross-sectional area for preventing the cleaning liquid from overflowing, and may be inclined in the longitudinal direction in order to determine the flow direction.
The material of the cleaning basket may be a metal such as iron, stainless steel, or aluminum, or a resin.
The cleaning basket is usually a straight type, but may be a curved type or a loop shape, and may be formed integrally or can be divided.
When cleaning is required due to the attachment of the nutrient solution to the cleaning basket or the attachment of algae or fungi, the cleaning can be performed by hand washing from the opening.
It is preferable that the cleaning basket 21 has a structure in which the cleaning liquid flows through the cleaning bypass pipe 22. In order to obtain such a structure, a gradient may be provided in the cleaning basket 21.

4.2 Cleaning Bypass Pipe The cleaning bypass pipe 22 sends the cleaning liquid recovered by the cleaning tub 21 to the recovery tub 16, the drain pipe 17 or the collecting tub 18. The cleaning liquid sent to the recovery tub 16, the drain pipe 17 or the collecting tub 18 is discharged by a purge mechanism (not shown).
The material of the bypass pipe for cleaning may be a metal such as iron, stainless steel, or aluminum, or a resin.
The diameter of the bypass pipe for washing is not particularly limited, and can be set as appropriate according to the horizontal length of the organism storage container and the type of organism.

5 Others The organisms grown by the organism growing apparatus according to the present embodiment refer to organisms that can maintain their lives by supplying water and nutrients. Specifically, plants, animals, microorganisms, etc. Preferably, it is a plant.

The organism-growing device of the present invention is installed inside a closed space and can be used isolated from the external environment by a wall, ceiling, floor, door, etc. having a sealing property. By doing so, it is possible not to affect undesired organisms such as dust, dust, dust, and insects, organisms on which microorganisms, pathogens and the like are cultivated.
Moreover, the organism training apparatus of this embodiment can be used suitably for a gene recombinant. The genetic recombinants include genetically modified plants, genetically modified animals, genetically modified microorganisms, plants and animals on which genetically modified microorganisms are allowed to act. When the organism growing device of this embodiment is used for a genetically modified organism, in order to prevent diffusion of the recombinant gene and its deposit, it is installed inside a closed space as described above, and the recombinant gene and its deposit, etc. It is preferable to use an air conditioner equipped with a filter capable of removing fine objects and having a function of controlling the atmospheric pressure inside the space. Moreover, the front room can be installed in the entrance / exit part of the person and goods between this space and the external environment, and can also be more reliably cut off from the outside.
When a genetically modified product is grown, it often conforms to GMP (Good manufacturing Practice), so the criteria for washing are strict. Therefore, in the case of growing a genetically modified organism that requires a sufficient cleaning of the apparatus, the present invention that can be easily cleaned is suitably applied.
The grown organisms can be suitably used as food, food additives, chemicals such as cosmetics, pigments and fragrances, Chinese medicines, raw materials such as pharmaceuticals, or a place or host for producing them.

  The organism-growing device according to the present invention can be used for the overall growth of organisms, and is particularly suitable for growing plants, particularly genetically modified plants with severe restrictions on washing, and plants that have been treated with genetically modified microorganisms. Used. By using this apparatus, it becomes possible to produce the above-mentioned organisms appropriately, in high quality, stably, and in large quantities at an industrially low cost.

DESCRIPTION OF SYMBOLS 100 Organism upbringing apparatus 1 Organism storage container 1a, 1b, 1c Discharge port 10 Support structure 11 Storage tank 12 Drain pipe 13 Supply pump 14 Supply pipe 15 Nozzle 16 Recovery rod 17 Drainage pipe 18 Assembly rod 19 Supply port 21 Cleaning bowl 22 Bypass piping for cleaning

Claims (8)

Organism storage container for storing organisms,
And a support structure capable of supporting them,
Organism storage unit, including
A storage tank for storing nutrient solution and / or drainage for growing organisms;
A feed pump for supplying the nutrient solution of the storage tank;
And a liquid supply mechanism for supplying nutrient solution from the liquid supply pump to the organism containment vessel, and a drainage that is disposed beside or below the organism containment vessel and flows out of the organism containment vessel. Recovery bowl that can recover liquid,
A drainage pipe for feeding the drainage collected by the collection basket to the collection bowl;
And a collecting bowl that receives the drained liquid sent through the drain pipe and flows into the storage tank,
Drainage mechanism, including
An organism training apparatus comprising:   The organism development apparatus according to claim 1, wherein the organism storage unit includes an illumination device that is installed on an upper part of the organism and irradiates the organism with light.   A cleaning tub that can recover the cleaning liquid supplied from the storage tank, and a cleaning bypass pipe that sends the cleaning liquid recovered by the cleaning tub to the recovery tub, the drainage pipe, or the collecting tub The living body growing apparatus according to claim 1, further comprising a cleaning mechanism including.   The organism cleaning apparatus according to claim 3, wherein the cleaning basket has a structure in which the supplied cleaning liquid flows into the cleaning bypass pipe.   The organism collecting apparatus according to any one of claims 1 to 4, wherein the recovery basket includes a structure in which drained liquid flowing out of the organism storage container flows into the drainage pipe.   The biological body growing apparatus according to any one of claims 1 to 5, wherein the biological body storage container has a structure in which a nutrient solution flows from a nutrient solution discharge port side of the liquid supply pipe to a recovery bottle side.   The organism growing apparatus according to any one of claims 1 to 6, wherein the organism storage container is formed in multiple stages.   The organism growing apparatus according to any one of claims 1 to 7, wherein the organism is a genetically modified organism.