JP2007195410A - Cultivation system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a cultivation system capable of preventing lowering of sterilizing power, precipitation caused by oxidation of nourishment, and cost increase. <P>SOLUTION: This cultivation system 101 is composed of a cultivation tank 3a, a collecting apparatus 3c collecting liquid discharged from the cultivation tank, a filtration apparatus 5 having a filtration film, and a collecting pump 16 for circulation. Since the filtration film of the filtration apparatus 5 is formed to be able to remove germs while passing nourishment contained in raw water and drainage through, it is possible to prevent precipitation of nourishment oxidized by ultraviolet ray irradiation and prevent lowering of sterilizing power in the case that the flow velocity of discharge is fast or by turbidity, like a cultivation system of a type of sterilizing through ultraviolet ray irradiation. Furthermore, it is possible to reduce apparatus cost because the system has no need of setting of an expensive large size ultraviolet ray lump. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a cultivation system, and more particularly to a cultivation system that can prevent a decrease in sterilizing power, precipitation due to oxidation of nutrients, and an increase in cost.

  In general, a cultivation system is one that automates irrigation of a plant-growing medium, and can be regularly irrigated even if no worker is present. Can be reduced.

  Here, in the cultivation system, the amount of water increased by about 30% to the amount of water necessary for the plant is irrigated in consideration of water permeability to the medium. And excess water is collect | recovered from a culture medium, it prevents that the drainage liquid containing a nutrient flows out to the surrounding water system, and prevents environmental pollution. In addition, the recovered drainage is irrigated again to reduce costs.

  In addition, in the circulation type cultivation system in which the collected water is irrigated again, it is necessary to sterilize water in order to prevent the spread of waterborne infectious pathogens.

Therefore, as disclosed in Japanese Patent Application Laid-Open No. 11-275988, by irradiating the collected effluent with ultraviolet rays, the collected effluent can be sterilized and the plant can be prevented from being infected with a disease.
Japanese Patent Laid-Open No. 11-275988 (paragraph [0010], FIG. 1, etc.)

  However, in the method of sterilizing by irradiating with ultraviolet rays as described above, when the flow rate is high or the turbidity of the effluent is high, the whole effluent is not sufficiently irradiated with ultraviolet rays, so that plant pathogens that are not irradiated with ultraviolet rays remain. That is, there is a problem that the sterilizing power is reduced.

  Moreover, when irradiated with ultraviolet rays, there is a problem that nutrients mixed in the drainage liquid may be oxidized and precipitated.

  Furthermore, in order to irradiate the whole drainage with ultraviolet rays, a large ultraviolet lamp is required. However, since such a large ultraviolet lamp is very expensive, there is a problem that the cost of the entire cultivation system increases. It was.

  The present invention has been made to solve the above-described problems, and an object of the present invention is to provide a cultivation system that can prevent a decrease in sterilizing power, precipitation due to oxidation of nutrients, and an increase in cost.

  In order to achieve this object, the cultivation system according to claim 1 includes a cultivation tank for cultivating a plant, a collection device for collecting liquid drained from the cultivation tank, and the liquid collected by the collection device. A filtration device having a filtration membrane to be filtered, and a circulation device for returning the liquid filtered by the filtration device to the cultivation tank, wherein the filtration membrane has a membrane pore diameter of 0.5 nm or more, and It is set within a range of 0.5 μm or less, and nutrients contained in the liquid are allowed to pass therethrough so that phytopathogenic fungi contained in the liquid can be removed.

  A cultivation system according to a second aspect is the cultivation system according to the first aspect, wherein the filtration membrane is made of a hydrophilic material.

  The cultivation system of Claim 3 is a cultivation system of Claim 1 or 2, The said filtration membrane is comprised by the hollow fiber membrane.

  The cultivation system according to claim 4 is the cultivation system according to claim 3, wherein the filtration membrane is washed by flowing washing water in a direction opposite to a filtration direction for filtering the liquid collected by the collection device. A plurality of filtration devices, and when one filtration device of the plurality of filtration devices is washed, the filtration device except the one filtration device is excluded. At least one is configured to be able to filter the liquid recovered by the recovery device.

  The cultivation system according to claim 5 is the cultivation system according to any one of claims 1 to 4, an acquisition means for acquiring water from a water source, and an oxidation means for oxidizing the water component acquired by the acquisition means. The water acquired by the acquisition means is oxidized by the oxidation means and then filtered by the filtration device.

  The cultivation system according to claim 6 is obtained by the cultivation system according to any one of claims 1 to 5 by an acquisition unit that acquires water from a water source, a nutrient mixing device that mixes nutrients in the water, and the acquisition unit. Supply means for supplying the collected water and the liquid recovered by the recovery device to the nutrient mixing device, respectively, wherein the nutrient mixing device mixes nutrients into the water, and And mixing control means for stopping the mixing of nutrients.

  The cultivation system according to claim 7 is the cultivation system according to any one of claims 1 to 5, an acquisition means for obtaining water from a water source, a nutrient mixing device for mixing nutrients in water, the filtration device, and the A short path that bypasses the nutrient mixing device between the cultivation tank and the water acquired by the acquisition means is supplied to the cultivation tank after the nutrient is mixed by the nutrient mixing device, The liquid recovered by the recovery device is supplied to the cultivation tank via the shortening path.

  According to the cultivation system of Claim 1, the liquid drained from a cultivation tank is collect | recovered by the collection | recovery apparatus, The collected liquid is filtered by the filtration membrane of a filtration apparatus, and is returned to a cultivation tank by a circulation apparatus. Here, since the membrane pore diameter of the filtration membrane is set within a range of 0.5 μm or less, the plant pathogen having a size value larger than 0.5 μm is removed, and the plant is infected with the disease by the plant pathogen. There is an effect that can be prevented.

  Moreover, since the membrane pore diameter of the filtration membrane is set within a range of 0.5 nm or more, it is possible to allow nutrients having a dimensional value smaller than 0.5 nm to pass through the filtration membrane, and in the filtrate after filtration. Can be kept the same as the nutrient concentration in the liquid before filtration.

  As a result, there is an effect that it is not necessary to mix the nutrients again into the filtrate, and the cost can be reduced accordingly.

  Furthermore, the work of mixing the nutrients again into the filtrate becomes unnecessary, so that the work efficiency can be improved accordingly.

  Furthermore, since the membrane pore diameter is set within a range of 0.5 nm or more, the filtration efficiency is improved compared with the case where the membrane pore diameter is set within a range smaller than 0.5 nm, and the flow rate of the filtrate is increased. There is an effect that can be secured.

  In addition, as described above, the filtration membrane is configured to be removable by filtering the phytopathogenic fungi contained in the liquid, so that the flow rate of the drainage is the same as in a cultivation system that sterilizes by irradiating with ultraviolet rays. There is an effect that the phytopathogenic fungi contained in the liquid can be surely removed without the sterilizing power being reduced due to early cases or turbidity.

  In addition, since the filtration membrane is configured to allow the nutrients contained in the liquid to pass through, the nutrients are not oxidized and precipitated by the irradiation of ultraviolet rays, as in a cultivation system that sterilizes by irradiating ultraviolet rays. There is an effect that the nutrient concentration in the filtrate after filtration can be kept the same as the nutrient concentration in the liquid before filtration.

  In addition, since plant pathogens can be removed by arranging a filtration device having a filtration membrane, an expensive large-scale ultraviolet lamp should be arranged like a cultivation system that sterilizes by irradiating with ultraviolet rays. There is an effect that the cost of the apparatus can be reduced.

  According to the cultivation system of Claim 2, in addition to the effect which the cultivation system of Claim 1 shows, since the filtration membrane is comprised with the hydrophilic material, it prevents that protein adsorbs, ie, a filtration membrane. Therefore, there is an effect that it is possible to suppress a decrease in filtration efficiency due to the protein passing through and adsorbed on the filtration membrane.

  According to the cultivation system of Claim 3, in addition to the effect which the cultivation system of Claim 1 or 2 shows, since the filtration membrane is comprised with the hollow fiber membrane, intensity | strength is ensured and it is with respect to a filtration membrane. Thus, it is possible to perform backwashing in which washing water is poured in the direction opposite to the filtration direction.

  Here, when the filtration membrane is composed of a thin plate-like flat membrane, if the pressure is applied, the flat membrane is damaged, and therefore backwashing cannot be performed.

  On the other hand, when the filtration membrane is composed of a hollow fiber membrane, backwashing can be performed, so that the residue on the filtration membrane can be removed. As a result, when the filtration efficiency is reduced due to the accumulation of the residue, backwashing is performed, so that the filtration efficiency can be recovered and the flow rate of the filtrate can be secured.

  According to the cultivation system of Claim 4, in addition to the effect which the cultivation system of Claim 3 shows, when one filtration device of a plurality of filtration devices is backwashed, one filtration device is used. Since at least one of the plurality of filtering devices is configured to filter the liquid collected by the collecting device, even when one filtering device is backwashed, the other filtering device filters the liquid. By doing so, it is possible to continuously perform the filtration process and to prevent the work efficiency from being lowered.

  According to the cultivation system of Claim 5, in addition to the effect which the cultivation system in any one of Claim 1 to 4 shows, it has a bad influence on the growth of a plant, or the obstacle of cultivation systems, such as clogging of a watering tube, A component in water that causes a factor is oxidized by the oxidizing means to become an oxide, and the particle size of the oxide becomes larger than the component before being oxidized.

  As a result, the oxide is filtered by the filtration device, so that the growth of the plant is removed by removing components in the water that adversely affect the growth of the plant, or that cause clogging of the irrigation tube and cause a failure of the cultivation system. Can be prevented and can prevent clogging of the irrigation tube.

  Furthermore, since water components that adversely affect the growth of plants or cause clogging of the cultivation system such as clogging of the irrigation tube are filtered by the filtration device, a removal device for removing the above components is required. There is an effect that the cost of the apparatus can be reduced correspondingly by eliminating the need for a separate arrangement.

  According to the cultivation system of Claim 6, in addition to the effect which the cultivation system in any one of Claim 1 to 5 shows, the water acquired by the acquisition means and the liquid collect | recovered by the collection | recovery apparatus are supplied by the supply means. Each of the nutrient mixing devices is supplied to the nutrient mixing device. The nutrient mixing device mixes the nutrients into the water and stops the mixing of the nutrients into the liquid.

  Here, the liquid recovered by the recovery device has already been mixed with nutrients by the nutrient mixing device. Therefore, in the case where water and liquid are mixed and supplied to the nutrient mixing device, the nutrient mixing device calculates the mixing ratio of water and liquid and sets the amount of nutrient mixing based on the calculated value. There is a need.

  On the other hand, in the case where water and liquid are respectively supplied to the nutrient mixing device, it is only necessary to determine whether the nutrient is mixed or not, and control for calculating the mixing ratio of water and liquid is unnecessary. There is an effect that the control of the nutrient mixing device can be facilitated.

  According to the cultivation system of Claim 7, in addition to the effect which the cultivation system in any one of Claim 1 to 5 produces | generates, the water acquired by the acquisition means is cultivated after nutrients were mixed with the nutrient mixing apparatus. The liquid supplied to the tank and recovered by the recovery device is supplied to the cultivation tank via a shortened path that does not pass through the nutrient mixing device.

  Here, the liquid recovered by the recovery device has already been mixed with nutrients by the nutrient mixing device. Therefore, when the liquid recovered by the recovery device is supplied to the cultivation tank via the nutrient mixing device, the nutrient mixing device converts the liquid recovered by the recovery device to keep the nutrient ratio in the liquid constant. On the other hand, it is necessary to stop mixing nutrients. As a result, the nutrient mixing device requires determination means for determining whether or not the liquid has been recovered by the recovery device, and mixing determination means for determining whether or not to mix nutrients according to the determination means.

  On the other hand, the liquid recovered by the recovery device is supplied to the cultivation tank via the shortening path, that is, the liquid recovered by the recovery device is supplied without going through the nutrient mixing device, as described above. There is an effect that the determination unit and the mixing determination unit are not necessary, and the nutrient mixing device can be easily controlled accordingly.

  DESCRIPTION OF EXEMPLARY EMBODIMENTS Hereinafter, preferred embodiments of the invention will be described with reference to the accompanying drawings. FIG. 1 is an overall view schematically showing a cultivation system 101 in the first embodiment of the present invention.

  As shown in FIG. 1, the cultivation system 101 is a device for automatically irrigating raw water and drainage, and filters the raw water supplied by the well pump 11 and the drainage supplied by the recovery pump 16. An apparatus 5; a raw water tank 6 that is disposed downstream of the filtering apparatus 5 and stores filtered raw water; and a drainage tank that is disposed downstream of the filtering apparatus 5 and stores drained liquid after filtration. 7, a nutrient mixing device 2 that is disposed downstream of the drainage tank 7 and the raw water tank 6 and mixes nutrients with the raw water to produce an aqueous solution, and is disposed downstream of the nutrient mixing device 2. An irrigation device 3 for irrigating an aqueous solution into the cultivation tank 3a, a recovery tank 4 for recovering drainage discharged from the irrigation device 3, and a compressor 13 connected to the filtration device 5 and the raw water tank 6. In addition, communication and blocking (off) of the flow path ) Three-way valve 20 (first to fifth three-way solenoid valves 21 to 25), sixth three-way valve 26, solenoid valve 30 (first to seventh solenoid valves 31 to 37), first to n-th line solenoid Valves 2b and the like are disposed at various places.

  In the present embodiment, the “liquid” according to claims 1 to 7 indicates an aqueous solution in which nutrients are mixed using water as a solvent. Further, in the present embodiment, the aqueous solution is not limited to that newly generated using raw water as a solvent, but also includes “drainage”.

  The water source 17 is a supply source such as well water or tap water supplied as raw water in the cultivation system 101. A water source supply path 17 a for supplying raw water is extended from the water source 17, and a first merging port is connected to the tip (downstream end) of the water source supply path 17 a via a first three-way valve 21. The supply path 17b is connected. A well pump 11 is disposed on the water source supply path 17a, and the raw water obtained from the water source 17 by the well pump 11 passes through the water source supply path 17a to the first confluence supply path 17b side. Sent out.

  An oxidation supply path 8a extending from the oxidation tank 8 is connected to the water source supply path 17a. The oxidation tank 8 is a tank for storing a sodium hypochlorite aqueous solution. An electromagnetic metering pump 12 is disposed on the oxidation supply channel 8a. The sodium hypochlorite aqueous solution stored in the oxidation tank 8 is supplied to the water source through the oxidation supply channel 8a by the electromagnetic metering pump 12. It is sent to the path 17a. Accordingly, the raw water flowing through the water source supply path 17a is introduced into the filtration device 5 in a state where the aqueous sodium hypochlorite solution is mixed.

Sodium hypochlorite is a reagent for oxidizing iron ions (Fe ²⁺ ) and manganese ions (Mn ²⁺ ) in raw water, and its supply position, that is, the oxidation supply path 8 a and the water source supply path 17 a Is connected to a specific position on the upstream side of the filtering device 5 so that the flow time of the raw water from the position to the filtering device 5 becomes a predetermined reaction time.

  On the other hand, the main cultivation system 101 is configured to perform irrigation using drainage in addition to the system using raw water, and stores the drainage supplied to the cultivation tank 3a as described above. A collection tank 4 is provided. The collection tank 4 is provided with a collection pump 16 that sends out the drainage liquid stored in the collection tank 4. A recovery supply path 4 b for feeding the drainage is extended from the recovery pump 16, and a first combined supply is provided via a first three-way valve 21 at the tip (downstream end) of the recovery supply path 4 b. The path 17b is connected. The drainage liquid pumped up from the recovery tank 4 by the recovery pump 16 is sent to the first merging supply path 17b side via the recovery supply path 4b.

  The first merging supply path 17b connected to the water source supply path 17a and the recovery supply path 4b supplies the raw water supplied by the water source supply path 17a or the drainage supplied by the recovery supply path 4b to the filtration device 5. A pipe to be introduced and connected to the filtration device 5.

  The first three-way valve 21 provided at the connecting portion of the water source supply path 17a, the recovery supply path 4b, and the first merge supply path 17b is one of the three-way valves 20 provided in the main cultivation system 101. The three-way valve 20 (first to fifth three-way valves 21 to 25) is disposed at a portion where the supply path branches in a substantially T-shape, and the communication of each supply path is achieved by switching the valve provided therein. And a valve configured to be able to selectively switch off and shut off. The three-way valve 20 allows two selected supply paths to communicate with each other among the three supply paths connected in a T shape, and the remaining one supply path can be shut off. Further, the three-way valve 20 can block all three supply paths without any communication between the three supply paths.

  Therefore, when the water source supply path 17 a and the first merge supply path 17 b communicate with each other by the operation of the first three-way valve 21, raw water is introduced into the filtration device 5. Further, when the recovery supply path 4 b and the first merge supply path 17 b communicate with each other by the operation of the first three-way valve 21, the drainage liquid is introduced into the filtration device 5.

  Moreover, the 1st confluence | merging supply path 17b is branched and comprised so that it may connect with the filtration apparatus 5 and the external supply path 5c mentioned later, and the 1st confluence | merging supply path is the front (upstream side) of the branch position. A first electromagnetic valve 31 that closes 17b so as to be openable and closable is disposed. The first electromagnetic valve 31 is one of the electromagnetic valves 30 provided in the main cultivation system 101. The solenoid valve 30 (first to seventh solenoid valves 31 to 37) is for communicating and shutting off the supply path, and opens and closes each supply path by opening and closing a valve provided in the solenoid valve. Selectively switch.

  A branch portion toward the external supply path 5c, which is one of the branch portions of the first merge supply path 17b, is connected to the external supply path 5c at the tip thereof, and to the first merge supply path 17b in a backwash process described later. The discharged water can be led out to the external supply path 5c. A third electromagnetic valve 33 that connects and disconnects the first merge supply path 17b and the external supply path 5c is disposed at a branch portion of the first merge supply path 17b toward the external supply path 5c. When a normal filtration process is performed, the first electromagnetic supply path 17b and the external supply path 5c are blocked by the third electromagnetic valve 33, and the raw water and drainage supplied to the first combined supply path 17b , It is not led to the external supply path 5c.

  The branch portion on the filtration device 5 side, which is the other branch portion of the first merge supply path 17b, further branches in two directions on the tip side (before the filtration device 5), and one tip portion is filtered by the filtration device 5 The tank 5A (inlet 5A1, see FIG. 2) is connected, and the other tip is connected to the filtration tank 5B (inlet 5B1, see FIG. 2) of the filtration device 5. A third three-way valve 23 is disposed at the branch point, and the flow path of the raw water or the drainage is restricted to one of the filtration tanks 5A and 5B by the operation of the third three-way valve 23. The That is, the raw water or the drained liquid sent from the water source 17 or the recovery tank 4 flows into one of the filtration tanks 5A and 5B provided in the filtration device 5. In addition, an air supply path 13d for supplying compressed air from the compressor 13 is provided at a position between the branch source and the branch point before the filtration apparatus 5 at the branch portion of the first merging supply path 17b on the filtration apparatus 5 side. One end is connected.

  The filtration device 5 is connected to the first merging supply path 17 b described above, and is used for filtering raw water such as well water or tap water obtained from the water source 17 and waste liquid stored in the recovery tank 4. Yes, and includes two filtration tanks 5A and 5B, and these filtration tanks 5A and 5B include a filtration membrane 5a (see FIG. 2) for filtering raw water and waste liquid.

  One end of a filtrate supply path 5b is connected to each of the outlets 5A2 and 5B2 (see FIG. 2) of the filtration tanks 5A and 5B of the filtration device 5. The filtrate supply path 5b is connected to the second supply path extending from each of the outlets 5A2 and 5B2 via the fourth three-way valve 24 and integrated into one supply path. The valve 24 extends further forward. In the filtrate supply path 5b, a second electromagnetic valve 32 that closes the filtrate supply path 5b so as to be openable and closable is disposed in the vicinity of the filtration tanks 5A and 5B and downstream of the fourth three-way valve 24. . When the second electromagnetic valve 32 is opened, the filtrate (raw water or waste liquid) discharged from the filtration tanks 5A and 5B is sent to the downstream side of the filtrate supply path 5b.

  A second three-way valve 22 is disposed at the end of the filtrate supply path 5b, and through the second three-way valve 22, the filtrate supply path 5b, the first raw water supply path 6b, and the first drainage supply path 7b. And are connected. Therefore, when the filtrate supply path 5b and the first raw water supply path 6b are communicated by the operation of the second three-way valve 22, the filtrate (raw water) flows into the first raw water supply path 6b, and the first raw water supply path The filtrate (raw water) is supplied to the raw water tank 6 disposed at the tip of 6b. Further, when the filtrate supply path 5b and the first drainage supply path 7b are communicated by the operation of the second three-way valve 22, the filtrate (drainage) flows into the first drainage supply path 7b, and the first Filtrate (drainage) is supplied to the drainage tank 7 disposed at the tip of the drainage supply path 7b.

  The raw water tank 6 is disposed on the downstream side of the filtration device 5 and is a filtrate filtered by the filtration device 5 for storing the filtered raw water. The raw water tank 6 is provided with a raw water tank liquid level sensor 6a for detecting the amount of raw water stored in the tank.

  From the raw water tank 6, a second raw water supply path 6 c for leading raw water stored in the raw water tank 6 to the nutrient mixing device 2 is extended. A first water pump 14 is disposed on the supply path of the second raw water supply path 6 c, and the raw water stored in the raw water tank 6 is passed through the second raw water supply path 6 c by the first water pump 14. Via the nutrient mixing device 2 side.

  On the other hand, the drainage tank 7 is disposed on the downstream side of the filtering device 5 and is a filtrate that has been filtered by the filtering device 5 and is used to store the filtered drainage. The drainage tank 7 is provided with a drainage tank liquid level sensor 7a for detecting the amount of drainage stored in the tank.

  From the drainage tank 7, a second drainage supply path 7 c for leading the drainage stored in the drainage tank 7 to the nutrient mixing device 2 is extended. A second water supply pump 15 is disposed on the supply path of the second drainage supply path 7 c, and the drainage liquid stored in the drainage tank 7 is second drained by the second water supply pump 15. It is sent to the nutrient mixing device 2 side via the supply path 7c.

  The downstream ends of the second raw water supply path 6c and the second drainage supply path 7c are connected to the second merge supply path 2c connected to the nutrient mixing device 2 via the sixth three-way valve 26, respectively. Yes. The sixth three-way valve 26 is for switching the supply path that communicates with the second merge supply path 2c, and is configured in the same manner as the three-way valve 20 described above. By the sixth three-way valve 26, one of the second raw water supply path 6c and the second drainage supply path 7c is communicated with the second merge supply path 2c.

  When the second raw water supply path 6c communicates with the second merge supply path 2c by the operation of the sixth three-way valve 26, the raw water from the raw water tank 6 flows into the second merge supply path 2c, and the second merge The raw water is supplied to the nutrient mixing device 2 disposed at the tip of the supply path 2c. Conversely, when the second drainage supply path 7c is communicated with the second junction supply path 2c by the operation of the sixth three-way valve 26, the drainage liquid from the drainage tank 7 flows into the second junction supply path 2c. Then, the drainage liquid is supplied to the nutrient mixing device 2.

  As described above, the nutrient mixing device 2 is for producing an aqueous solution by mixing nutrients in the raw water, and includes a mixing electromagnetic valve 2a for communicating and blocking a nutrient tank (not shown). When the electromagnetic valve 2a is opened, nutrients are mixed into the raw water supplied from the raw water tank 6, and when mixed electromagnetic valve 2a is closed, the nutrients are mixed into the drainage supplied from the drainage tank 7. To pause. Details will be described later (see FIG. 9). An irrigation device 3 is connected to the nutrient mixing device 2 via an aqueous solution supply path 2d.

  The nutrient mixing device 2 in the present embodiment is configured to control the mixing of nutrients by opening and closing the mixing electromagnetic valve 2a, but is not necessarily limited to this, for example, driving an electromagnetic metering pump You may comprise so that mixing of a nutrient may be controlled by.

  The irrigation device 3 is for giving an aqueous solution supplied from the nutrient mixing device 2 to a plant, a cultivation tank 3a for growing the plant, a dropping device 3b for dropping the aqueous solution into the cultivation tank 3a, and the dropping device A recovery device 3c that recovers the aqueous solution dripped by 3b as a drainage from the cultivation tank 3a is provided.

  The cultivation tank 3a is configured to include soil for cultivating plants, and a plurality (n pieces) of beds (plants) for planting plants are formed by the soil. In each cocoon, plants to be cultivated are arranged so as to be aligned at a predetermined interval.

  In addition, although the cultivation tank 3a in this Embodiment is comprised with soil, it is not necessarily restricted to this, For example, you may comprise with an agar-like culture place, a fibrous culture place, etc.

  The dropping device 3b includes a dropping tube (not shown) that drops the supplied aqueous solution toward a plant planted in the cultivation tank 3a. The dripping tube is provided with a plurality of pipes branched into lines along each ridge (branching to the number of ridges (n)), and each of the pipes is configured similarly to the solenoid valve 30. First to nth line solenoid valves 2b (see FIG. 5) are provided.

  The first to n-th line electromagnetic valves 2b individually open and close the n pipes of the dropping tube. The most upstream side of the dropping tube is connected to the aqueous solution supply path 2d, and each pipe of the dropping tube and the aqueous solution supply path 2d are communicated by opening the first to n-th line electromagnetic valves 2b. Accordingly, the aqueous solution is supplied only to the piping in which the first to nth line solenoid valves 2b are opened (turned on).

  The collection device 3c is disposed below the cultivation tank 3a for collecting the drainage discharged from the cultivation tank 3a, and the collected drainage is drained from the collection device 3c. It is stored in the collection tank 4 through the supply path 4c.

  The recovery tank 4 is disposed on the downstream side of the irrigation device 3 and stores the drainage recovered by the recovery device 3c, and detects the amount of the aqueous solution stored in the recovery tank 4. The recovery tank liquid level sensor 4a is provided.

  With this configuration, after supplying the aqueous solution generated from the raw water obtained from the water source 17 to the cultivation tank 3a (irrigation), the excess aqueous solution is recovered as drainage, and the recovered drainage is again, Circulation supply supplied to the cultivation tank 3a can be realized.

  The compressor 13 is for compressing air, and is configured to send compressed air to the pressurized supply path 13a. One end of the pressure supply path 13a is connected to the compressor 13, and the other end is connected to the side surface where the backwash supply path 13b and the bubbling supply path 13c connected in the vertical direction are formed in a T shape. ing. Note that one electromagnetic valve is provided above and below across the connection position of the pressure supply path 13a. Specifically, a sixth electromagnetic valve 36 is disposed on the upper backwash supply path 13b side, and a seventh electromagnetic valve 37 is disposed on the lower bubbling supply path 13c side. For this reason, by opening and closing the sixth electromagnetic valve 36 and the seventh electromagnetic valve 37, the compressed air can be circulated only in one direction of the backwash supply path 13b and the bubbling supply path 13c.

  The tip of the backwash supply path 13b extending from the connection position with the pressure supply path 13a is connected to the filtrate supply path 5b. Here, since the filtrate supply path 5b extends from the outlets 5A2 and 5B2 of the filtration tanks 5A and 5B, the compressed air from the compressor 13 is added (if the second solenoid valve 32 is closed). It can be introduced into the filtration tanks 5A and 5B via the pressure supply path 13a, the backwash supply path 13b, the filtrate supply path 5b, and the outlets 5A2 and 5B2. In addition, the 4th electromagnetic valve 34 is provided in the connection position of the backwash supply path 13b and the filtrate supply path 5b, and unless the 4th electromagnetic valve 34 is open | released, the backwash supply path 13b and the filtrate supply path 5b Are configured not to communicate with each other. Accordingly, when the fourth electromagnetic valve 34 is closed, the compressed air is not introduced from the outlets 5A2 and 5B2 to the filtration tanks 5A and 5B.

  Further, one end of an air supply path 13d is further connected to the backwash supply path 13b in a section from the connection position with the pressurized supply path 13a to the filtrate supply path 5b. As described above, the other end of the air supply path 13d is connected to the first merge supply path 17b in front of the inlets 5A1 and 5B1 of the filtration tanks 5A and 5B. The first merge supply path 17b is connected to the filtration tank 5A and 5B. Since the tanks 5A and 5B are connected to the inlets 5A1 and 5B1, the compressed air from the compressor 13 is supplied to the pressurized supply path 13a, the backwash supply path 13b, the air supply path 13d, the first combined supply path 17b, It can introduce into filtration tanks 5A and 5B via inlets 5A1 and 5B1. The air supply path 13d is provided with a fifth electromagnetic valve 35 before the connection position with the first merging supply path 17b. Unless the fifth electromagnetic valve 35 is opened, the air supply path 13d and the air supply path 13d The first confluence supply path 17b is configured not to communicate. Therefore, when the fifth electromagnetic valve 35 is closed, the compressed air is not introduced from the inlets 5A1 and 5B1 to the filtration tanks 5A and 5B.

  The tip of a bubbling supply path 13 c extending downward from the connection position with the pressurized supply path 13 a is inserted below the raw water tank 6. Therefore, the compressed air from the compressor 13 can be introduced into the raw water tank 6 and bubbling can be performed on the raw water stored in the raw water tank 6.

  In addition, one end of an external supply path 5c that connects the filtration tanks 5A, 5B and the outside is connected to each of the discharge ports 5A3, 5B3 (see FIG. 2) disposed on the side surfaces of the filtration tanks 5A, 5B. Yes. This external supply path 5c is formed in the fifth three-way after the two supply paths extending from the respective discharge ports 5A3 and 5B3 are connected via the fifth three-way valve 25 and integrated into one supply path. The valve 25 extends further forward. Further, as described above, one branch portion of the first combined supply path 17b is connected to the external supply path 5c at a predetermined position downstream of the fifth three-way valve 25.

  This external supply path 5c is for discharging air, water, and the like removed from the filtration tanks 5A and 5B after the backwash process to the outside of the cultivation system 101, and the filtration tank 5A in the backwash process. , 5B, air, water and the like discharged from the respective inlets 5A1, 5B1 and the respective outlets 5A3, 5B3 are discharged out of the system from this external supply path 5c.

  In addition, the main cultivation system 101 is provided with two control devices that control the liquid supply system. One control device is the central control device 1 and is disposed in the nutrient mixing device 2. The central control device 1 is a device that controls the mixing electromagnetic valve 2a of the nutrient mixing device 2 to generate an aqueous solution of a predetermined concentration and controls the entire liquid supply system (irrigation operation) to the cultivation tank 3a. The other control device is the filtration control device 100, and is disposed in the filtration device 5. The filtration control device 100 is a device that operates the three-way valve 20 or the electromagnetic valve 30 according to whether the object to be filtered is raw water or drainage, and controls different filtration operations according to the raw water and drainage. The central control device 1 and the filtration control device 100 control each device provided in each place in the main cultivation system 101 and appropriately perform filtration and irrigation.

  Next, the flow of raw water and drainage in the main cultivation system 101 will be described based on the operation of each electromagnetic valve and three-way valve controlled by the central control device 1 and the filtration control device 100.

  First, the operation of the system when raw water is filtered will be described. When raw water is filtered, the first three-way valve 21 is switched so that the water source supply path 17a and the first merge supply path 17b communicate with each other along with the driving of the well pump 11 and the electromagnetic metering pump 12. In addition, the first electromagnetic valve 31 is opened, and the third three-way valve 23 is switched to communicate with any filtration tank 5A, 5B. Thereby, raw | natural water is introduce | transduced into one of filtration tank 5A, 5B from the water source 17 via the water source supply path 17a and the 1st confluence | merging supply path 17b. Further, the fourth three-way valve 24 is switched so that the filtration tanks 5A, 5B on the side where the raw water is introduced communicates with the filtrate supply path 5b. Further, the second electromagnetic valve 32 is opened, and the second three-way valve 22 is switched so that the filtrate supply path 5b and the first raw water supply path 6b communicate with each other. Thereby, the raw water filtered by the filtration tanks 5A and 5B is stored in the raw water tank 6 via the filtrate supply path 5b and the first raw water supply path 6b.

  Next, the operation of the system when drainage is filtered will be described. When the drainage is filtered, the first three-way valve 21 is switched so that the recovery supply path 4b and the first merging supply path 17b communicate with each other along with the drive of the recovery pump 16. Similarly to the raw water filtration, the first electromagnetic valve 31 is opened, and the third three-way valve 23 is switched so as to communicate with any of the filtration tanks 5A and 5B. As a result, drainage is introduced from the recovery tank 4 to one of the filtration tanks 5A and 5B via the recovery supply path 4b and the first merge supply path 17b. Further, the fourth three-way valve 24 is switched so that the filtration tanks 5A and 5B on the side where the drainage is introduced communicate with the filtrate supply path 5b. Further, the second electromagnetic valve 32 is opened, and the second three-way valve 22 is switched so that the filtrate supply path 5b and the first drainage supply path 7b communicate with each other. As a result, the drainage filtered by the filtration tanks 5A and 5B is stored in the drainage tank 7 via the filtrate supply path 5b and the first drainage supply path 7b.

  Next, the operation of the system when an aqueous solution based on raw water is supplied to the cultivation tank 3a will be described. In such a case, first, with the driving of the first water supply pump 14, the sixth three-way valve 26 is switched so as to communicate the second raw water supply path 6c and the second combined supply path 2c. Further, the mixing electromagnetic valve 2a is opened, and the nutrient is mixed into the raw water introduced into the nutrient mixing device 2 from the second raw water supply path 6c via the second combined supply path 2c. Moreover, the 1st-nth line electromagnetic valve 2b provided for every piping of the dripping tube of the irrigation apparatus 3 is opened and closed in order, and a line electromagnetic valve is opened via the aqueous solution supply path 2d from the nutrient mixing device 2. An aqueous solution produced from raw water is supplied to the piping of the dropping tube.

  Finally, the operation of the system when the drainage is supplied to the cultivation tank 3a will be described. In such a case, first, with the driving of the second water pump 15, the sixth three-way valve 26 is switched so as to communicate the second drainage supply path 7c and the second merge supply path 2c. Here, the mixing electromagnetic valve 2a is kept closed, and no nutrient is mixed in the drainage introduced into the nutrient mixing device 2 from the second drainage supply path 7c via the second junction supply path 2c. Moreover, the 1st-nth line electromagnetic valve 2b provided for every piping of the dripping tube of the irrigation apparatus 3 is opened and closed in order, and a line electromagnetic valve is opened via the aqueous solution supply path 2d from the nutrient mixing device 2. Drained liquid is supplied to the piping of the dripping tube.

  In this way, the main cultivation system 101 can smoothly execute the four system operations of raw water or drainage filtration and raw water or drainage liquid supply (irrigation). The liquid system can be operated well.

  Next, the details of the filtration tanks 5A and 5B will be described with reference to FIG. FIG. 2A is a cross-sectional view schematically showing the filtration tanks 5A and 5B, and FIG. 2B is an enlarged cross-sectional view schematically showing the filtration membrane 5a. In FIG. 2A, for easy understanding, the filtration membrane 5a is shown from the front, and the cross section is not shown.

  As shown in FIG. 2 (a), the filtration tanks 5A and 5B are substantially cylindrical case bodies, and have inlets 5A1 and 5B1 that are open at one end in the longitudinal direction (the lower side in FIG. 2 (a)). The outlets 5A2 and 5B2 that are disposed opposite to the inlets 5A1 and 5B1 and that are formed to open, the outlets 5A3 and 5B3 that are formed to open on the side surfaces, and the filtration membrane 5a disposed inside It is prepared for.

  The inflow ports 5A1 and 5B1 are openings through which raw water or drainage supplied from the first merging supply path 17b (see FIG. 1) flows, and are formed at one end in the longitudinal direction of the filtration tanks 5A and 5B. It is connected to the first merge supply path 17b.

  The outlets 5A2 and 5B2 are openings through which the raw water or drained liquid filtered by the filtration membrane 5a flows out to the filtrate supply path 5b (see FIG. 1), and the other ends in the longitudinal direction of the filtration tanks 5A and 5B (see FIG. 2). (A) It is drilled in the upper side and is connected to the filtrate supply path 5b.

  The discharge ports 5A3 and 5B3 are openings for discharging the raw water or the drainage liquid and air in the filtration tanks 5A and 5B to the external supply path 5c (see FIG. 1), and the inflow port 5A1 than the partition wall member 5a3 described later. , 5B1 side (the lower side in FIG. 2A) and are formed in the side surfaces of the filtration tanks 5A, 5B.

  The filtration membrane 5a is constituted by a straw-like hollow fiber membrane, and a module in which a plurality of the filtration membranes 5a are bundled is enclosed in the case body of the filtration tanks 5A and 5B. In this module, the upper support member 5a1 is fixed to the outer periphery on one end side in the longitudinal direction (upper side in FIG. 2 (a)) and the lower support is provided on the end portion on the other end side in the longitudinal direction (lower side in FIG. 2 (a)). The member 5a2 is fixed and fixed in the filtration tanks 5A and 5B via the upper support member 5a1 and the partition member 5a3.

  In addition, in the filtration tanks 5A and 5B, raw water or drainage is always stored, and is set so that the filtration membrane 5a is always wetted.

  The upper support member 5a1 is for binding the module, and is disposed on the outer periphery on one end side in the longitudinal direction of the module, and binds the module in a state where one end side in the longitudinal direction of the module is opened.

  The lower support member 5a2 is for holding the module, and is disposed at the end portion on the other end side in the longitudinal direction of the module, and holds the module in a state where the other end side in the longitudinal direction of the module is closed.

  The partition member 5a3 is a plate-like member whose outer diameter is set to be substantially equal to the inner diameter of the filtration tanks 5A and 5B, and the outer peripheral portion of the partition member 5a3 is fixed to the filtration tanks 5A and 5B with the upper support member 5a1 fixed to the center. In addition, the filtration membrane 5a is fixed in the filtration tanks 5A and 5B, and the raw water or the drained liquid flowing in from the inflow ports 5A1 and 5B1 flows out from the outflow ports 5A2 and 5B2 without passing through the filtration membrane 5a. To prevent that.

  As shown in FIG. 2 (b), the filtration membrane 5a is a straw-like hollow fiber membrane formed by entanglement of fibers 5a4 covered with a hydrophilic polymer, and a hollow hole 5a5 having a substantially circular cross section in the center. It is formed along the axial direction (vertical direction in FIG. 2B).

  As a result, the raw water or drainage that has flowed in from the inflow ports 5A1 and 5B1 (see FIG. 2A) enters from the micropores formed between the fibers 5a4 on the outer wall of the filtration membrane 5a and is filtered by the fibers 5a4. The As a result, the raw water or the drainage filtered by the fibers 5a4 flows out from the outlets 5A2 and 5B2 side (upper side in FIG. 2B) of the formed filtration membrane 5a while passing through the hollow hole 5a5.

  The membrane pore diameter of the filtration membrane 5a is set to 0.1 μm. The membrane pore diameter corresponds to a value measured by a bubble point measurement method (see Japanese Industrial Standard (JIS) K3832).

  Moreover, since the filtration membrane 5a is comprised with the straw-shaped hollow fiber membrane as above-mentioned, intensity | strength can be ensured and the backwash process (refer FIG. 7) mentioned later can be performed.

  Here, when the filtration membrane 5a is formed of a thin plate-like flat membrane, the flat membrane is damaged when pressure is applied, so that the backwash process cannot be performed.

  On the other hand, when the filtration membrane 5a is composed of a hollow fiber membrane, a backwash process can be performed, so that the residue accumulated in the filtration membrane 5a can be removed. As a result, when the filtration efficiency decreases due to the accumulation of the residue, the filtration efficiency can be improved and the flow rate of the filtrate can be ensured by performing the backwash process.

  Moreover, since the filtration apparatus 5 in the present embodiment is configured to include two filtration tanks 5A and 5B (see FIG. 2A), for example, when one filtration tank 5A is backwashed. The other filtration tank 5B can filter the raw water or the drainage. As a result, even when the backwashing process is performed, the filtration process can be continuously performed, and a reduction in work efficiency due to the backwashing process can be prevented.

  Next, with reference to FIG. 3, evaluation results by two types of filtration tests (hereinafter referred to as “capture test” and “adsorption test”) performed for examining the performance of the filtration membrane 5 a will be described.

First, with reference to Fig.3 (a), the evaluation result by a capture test is demonstrated. In the capture test, the membrane pore size of the filtration membrane 5a is changed to compare the capture changes of phytopathogenic fungi (bacteria, Fusarium) and nutrients (N, Ca ²⁺ ). Was passed through the filtration membrane 5a, and the cell density and nutrient concentration of the aqueous solution before filtration were compared with the cell density and nutrient concentration of the filtrate.

Detailed specifications of the capture test are as follows: Filtration module: 20 m ² , Filtration differential pressure: 1.0 kg / cm ² , Flow rate: 10 l / min, Bacteria density before filtration (withering bacteria): 7.0 × 10 ⁷ CFU / ml, Cell density before filtration (Fusarium bacterium): 1.0 × 10 ⁴ CFU / ml.

  FIG. 3A is a diagram showing a test result of the capture test. In addition, "x" in Fig.3 (a) shows that the phytopathogen or nutrient was not detected in the filtrate. Moreover, "(triangle | delta)" in Fig.3 (a) shows that the microbial cell density and nutrient concentration in a filtrate decreased compared with the microbial cell density and nutrient concentration in the aqueous solution before filtration. In addition, “◯” in FIG. 3A indicates that the cell density and nutrient concentration in the filtrate are unchanged compared to the cell density and nutrient concentration in the aqueous solution before filtration. .

  The bacterial wilt is the smallest class of phytopathogenic fungi that cause plant diseases, and Fusarium is the largest phytopathogenic fungus that causes plant diseases.

N and Ca ²⁺ are typical nutrients.

  First, the test results of the capture test when the membrane pore diameter of the filtration membrane is set to 0.2 nm will be described. When the membrane pore size was set to 0.2 nm, no phytopathogenic fungi and nutrients were detected in the filtrate, indicating that the phytopathogenic fungi and nutrients were captured by the filtration membrane.

  Next, when the membrane pore diameter of the filtration membrane 5a is set to 0.5 nm, no phytopathogenic fungi were detected in the filtrate, indicating that the phytopathogenic fungi were captured by the filtration membrane 5a. Moreover, since the nutrient density in a filtrate did not change with the nutrient density in the aqueous solution before filtration, it is shown that the nutrient passed without being trapped by the filtration membrane 5a.

  Next, when the membrane pore diameter of the filtration membrane 5a is set to 0.1 μm, the phytopathogenic fungi are captured by the filtration membrane 5a and the nutrients are filtered in the same manner as when the membrane pore size is set to 0.5 nm. It is shown that the film 5a passed without being captured.

  Next, when the membrane pore diameter of the filtration membrane 5a is set to 0.5 μm, the phytopathogenic fungi are captured by the filtration membrane 5a as in the case where the membrane pore diameter is set to 0.5 nm and 0.1 μm, and It is shown that the nutrients passed without being captured by the filtration membrane 5a.

Next, when the membrane pore size of the filtration membrane is set to 0.6 μm, the bacterial density of the bacterial bacterium in the filtrate is 3.5 × 10 ⁷ CFU / ml, and the Fusarium fungus body in the filtrate Since the density was 5.0 × 10 ³ CFU / ml, it was shown that about half of the phytopathogenic fungi were captured by the filtration membrane and about half of the phytopathogenic fungi had passed through without being captured. Moreover, since the nutrient concentration in a filtrate did not change with the nutrient concentration in the aqueous solution before filtration, it is shown that the nutrient passed without being trapped by the filtration membrane.

  Finally, when the membrane pore size of the filtration membrane was set to 0.7 μm, the cell density and nutrient concentration in the filtrate did not change with the cell density and nutrient concentration in the aqueous solution before filtration. It has been shown that pathogens and nutrients have passed through without being trapped by the filter membrane.

  From the above, by setting the membrane pore diameter of the filtration membrane 5a within a range of 0.5 μm or less, it is possible to capture phytopathogenic fungi and prevent plants from being infected with diseases by phytopathogenic fungi.

  Furthermore, by setting the membrane pore diameter of the filtration membrane 5a within a range of 0.5 nm or more, the nutrients can be passed, and the nutrient concentration in the filtrate and the nutrient concentration in the filtered liquid can be kept the same.

  As a result, it is not necessary to mix the nutrients again into the filtrate, and the cost can be reduced accordingly. Furthermore, since the operation | work which mixes a nutrient again in a filtrate becomes unnecessary, the work efficiency can be improved by that much.

  Further, by setting the membrane pore diameter of the filtration membrane 5a within the range of 0.5 nm or more, the filtration efficiency is improved as compared with the case where the membrane pore diameter is set within the range of less than 0.5 nm. Can be ensured.

  Furthermore, since the filtration membrane 5a is configured to be removable by filtering the phytopathogenic fungi in the aqueous solution, the drainage fluid has a high flow rate or turbidity as in a cultivation system that sterilizes by irradiating with ultraviolet rays. The sterilizing power is not reduced by the above, and the phytopathogenic fungi contained in the aqueous solution can be surely removed.

  Moreover, since it is comprised so that a plant pathogenic microbe can be removed by arrange | positioning the filtration apparatus 5 which has the filtration membrane 5a, it is an expensive large-sized ultraviolet lamp like the cultivation system of the type which irradiates and sterilizes a pilgrimage Therefore, it is not necessary to dispose the device, and the device cost can be reduced.

  Moreover, since the filtration membrane 5a is configured to pass the nutrients in the aqueous solution, the nutrients are not oxidized and precipitated by the irradiation of ultraviolet rays, as in a cultivation system that sterilizes by irradiating ultraviolet rays. The nutrient concentration in the filtrate and the nutrient concentration after filtration can be kept the same.

  Next, the adsorption performance of the filtration membrane 5a will be described with reference to FIG. The filtration membrane 5a in the present embodiment is hydrophilic. Further, the adsorption performance is such that an aqueous solution containing a predetermined concentration of protein (albumin, γ globulin, and β lipoprotein) is passed through the hydrophobic filtration membrane and the hydrophilic filtration membrane 5a, so that the hydrophobic filtration membrane and the hydrophilic filtration membrane are passed through. The amount of protein adsorbed on the filtration membrane 5a is shown.

The detailed specifications of the adsorption test are as follows: filtration module: 100 cm ² , flow rate: 20 cc / min, membrane pore size: 0.1 μm, concentration before filtration (albumin): 0.03% aqueous solution, concentration before filtration (γ globulin): 0. 03% aqueous solution, concentration before filtration (β-lipoprotein): 0.01% aqueous solution.

FIG. 3B is a diagram showing the test results of the adsorption test. In addition, the adsorption amount in FIG.3 (b) shows the quantity (microgram) of protein adsorbed per 1 cm < ² > of filtration membranes.

  First, an adsorption test using a hydrophobic filter membrane will be described. When a hydrophobic filtration membrane was used, about 100 μg of albumin was adsorbed, about 170 μg of γ globulin was adsorbed, and about 90 μg of β lipoprotein was adsorbed.

  Next, when the hydrophilic filtration membrane 5a was used, about 25 μg of albumin and γ globulin were adsorbed and about 30 μg of β lipoprotein was adsorbed.

  From the above, it is shown that the hydrophilic filtration membrane 5a has less protein adsorption than the hydrophobic filtration membrane. Thereby, when the hydrophilic filtration membrane 5a is used, clogging of the filtration membrane 5a due to protein adsorption is reduced as compared with the case where a hydrophobic filtration membrane is used. It can suppress that the filtration efficiency falls by clogging.

  Next, with reference to FIG. 4, the operation | movement of the system of the whole liquid supply system in the cultivation system 101 is demonstrated. Fig.4 (a) is a figure which shows operation | movement of the cultivation system 101 with respect to raw | natural water, FIG.4 (b) is a figure which shows operation | movement of the cultivation system 101 with respect to drainage.

  As shown to Fig.4 (a), in the liquid supply system using raw | natural water, raw | natural water is first acquired from the water source 17 (S1).

Next, sodium hypochlorite is inject | poured with the electromagnetic metering pump 12 with respect to the raw | natural water acquired from the water source 17 (S2). As a result, iron ions (Fe ²⁺ ) and manganese ions (Mn ²⁺ ) in the raw water are oxidized to ferric hydroxide (2Fe (OH) ₃ ) and ferric hydroxide (2Mn (OH) ₃ ). . The particle sizes of the ferric hydroxide and manganese oxide are larger than the particle sizes of iron ions and manganese ions, and can be removed by the filtration membrane 5a.

  Thereafter, raw water containing ferric hydroxide and manganese oxide is filtered by the filtering device 5 (S3). Thus, ferric hydroxide and manganese hydroxide having a large particle size are removed by the filtration membrane 5a, that is, iron ions and manganese ions are removed from the raw water. It is possible to prevent adverse effects on the growth of the tube and clogging of the dropping tube (not shown).

  Subsequently, the raw water from which ferric hydroxide and manganese manganese hydroxide have been removed is stored in the raw water tank 6 (S4).

  Next, compressed air is supplied to the raw water tank 6 by the compressor 13, and bubbling is performed on the raw water stored in the raw water tank 6 (S5). Thereby, the unreacted sodium hypochlorite contained in the raw water stored in the raw water tank 6 is decomposed.

  Thereafter, the raw water from which sodium hypochlorite has been decomposed is sent to the nutrient mixing device 2, where the nutrient is mixed by the nutrient mixing device 2 to produce an aqueous solution (S6).

  Subsequently, the aqueous solution produced by the nutrient mixing device 2 is sent to the dropping device 3b and dropped into the cultivation tank 3a by the dropping device 3b (S7).

  And the drainage discharged | emitted from the cultivation tank 3a is collect | recovered by the collection tank 4 (S8).

  On the other hand, as shown in FIG. 4B, in the liquid supply system using the drainage, the drainage is acquired from the recovery tank 4 in which the drainage discharged from the cultivation tank 3a is stored. (S11).

  Next, the drainage liquid obtained from the collection tank 4 is filtered by the filtration device 5. Thereby, as above-mentioned, the nutrient in a drainage liquid passes and a plant pathogenic microbe is removed (S12).

  Thereafter, the drained liquid filtered by the filtering device 5 is stored in the drainage tank 7 (S13).

  Subsequently, the drainage liquid stored in the drainage tank 7 is sent to the nutrient mixing device 2 (S14). In addition, since the nutrient in a drainage liquid is not removed by the filtration apparatus 5, the nutrient mixing apparatus 2 obstruct | occludes the mixing electromagnetic valve 2a, and stops mixing of the nutrient with respect to a drainage liquid.

  Next, the drained liquid that passes through the nutrient mixing device 2 is sent to the dropping device 3b and dropped into the cultivation tank 3a by the dropping device 3b (S15).

  Thereafter, the drained liquid discharged from the cultivation tank 3a is collected again in the collection tank 4 (S15).

  Here, in the cultivation system 101, in consideration of the permeability of the aqueous solution to the soil in the cultivation tank 3a, the amount of the aqueous solution increased by about 30% to the amount of the aqueous solution necessary for the plant is irrigated. For this reason, in the normal irrigation method, excess water flows out to the surrounding water system and pollutes the surrounding environment.

  Therefore, as described above, the drainage discharged from the cultivation tank 3a is collected in the collection tank 4, thereby preventing nutrients from flowing into the surrounding water system and preventing the surrounding environment from being contaminated. ing.

  FIG. 5 is a block diagram showing an outline of the electric circuit configuration of the cultivation system 101. As shown in FIG. 5, the cultivation system 101 includes a central control device 1 and a filtration control device 100. As described above, the central controller 1 is a device that controls the entire liquid supply system (irrigation operation) to the cultivation tank 3a, and controls the liquid supply based on the liquid supply conditions stored in the device. It is. As such liquid supply conditions, the central controller 1 stores the number of pipes of the dropping tube, the number of times of liquid supply, the time of liquid supply, the amount of liquid supply, and the like. Further, the liquid supply conditions are stored (initially set) as default values in the central controller 1 and can be newly registered and changed by the user by operating the operation panel 41. .

  The central controller 1 includes a CPU 51, a ROM 52, a RAM 53, an EEPROM 54, a clock circuit 55, an input / output port 57, an operation panel 41, a display device 42, an alarm device 43, a driver circuit 44, and an A / D converter 45, which are arithmetic devices. I have.

  The ROM 52 is a non-rewritable nonvolatile memory that stores various control programs executed by the CPU 51 and fixed value data. The programs in the flowcharts of FIGS. 8 and 9 are stored in the ROM 52 as a part of the control program. The RAM 53 is a memory for temporarily storing various data.

  The EEPROM 54 is a rewritable nonvolatile memory, and includes a setting flag 54a, a default value memory 54b, an input value memory 54c, a raw water time memory 54d, and a drainage time memory 54e. Since the EEPROM 54 is a nonvolatile memory, the stored information is retained even after the power is turned off.

  The setting flag 54 a is stored as a default value in the central controller 1 when supplying the aqueous solution to the cultivation tank 3 a with both the aqueous solution generated from the raw water and the drainage stored in the recovery tank 4. It is a flag for indicating whether or not to carry out with a certain liquid supply amount. The main cultivation system 101 can perform the liquid supply to the cultivation tank 3a by any of the aqueous solution generated from the raw water and the drainage. For this reason, the respective liquid supply amounts (raw water supply amount and drainage supply amount) are set for the aqueous solution and drainage generated from the raw water, and stored in the central controller 1 as default values. On the other hand, the central controller 1 can input (set) user-supplied liquid supply conditions (liquid supply amount) by operating the operation panel 41. The setting flag 54a is turned on when the liquid supply with the input liquid supply amount is designated by the operation of the operation panel 41 by the user, and conversely, the liquid supply with the default liquid supply amount is designated. And turned off. In the initial setting, the setting flag 54a is turned off.

  The CPU 51 refers to the setting flag 54a when executing the liquid supply, and if the setting flag 54a is OFF, the aqueous solution generated from the raw water and the drained liquid are stored in the cultivation tank with the liquid supply amount stored as the default value. To 3a. Moreover, if the setting flag 54a is ON, the aqueous solution and waste liquid produced | generated from raw | natural water will be supplied to the cultivation tank 3a with the liquid supply amount input by the user.

  The default value memory 54b is a memory that stores liquid supply conditions that are initially set at the time of shipment. In the default value memory 54b, the raw water supply amount indicating the supply amount by the aqueous solution generated from the raw water, the drainage supply amount indicating the supply amount by the drainage, the raw water supply amount and the drainage supply amount are totaled. Three liquid supply amounts are stored together with the total liquid supply amount. In the present embodiment, each liquid supply amount is set as an amount supplied to one line for each liquid supply.

  The input value memory 54c is a memory for storing the liquid supply conditions input by the user's input operation. Similar to the default value memory 54b, the input value memory 54c has three types of raw water supply amount, drainage supply amount, and total liquid supply amount. The amount of liquid supply is stored. The three liquid supply amounts are respectively input by the operation of the operation panel 41 by the user. The input liquid supply amount is written and stored in the input value memory 54c corresponding to each liquid supply amount item. When a new input operation is performed, the corresponding value stored earlier is updated with the newly input value (liquid supply amount).

  The raw water time memory 54d is a liquid supply time for supplying the cultivation tank 3a with liquid, and stores raw water supply time to be executed only with an aqueous solution newly generated by mixing the nutrient with the raw water. It is memory. The raw water supply time is input as a user-desired value by operating the operation panel 41 by the user, and the input value (time) is stored in the raw water time memory 54d.

  The CPU 51 always manages the time, and triggered by the arrival of the raw water supply time stored in the raw water time memory 54d, the newly generated aqueous solution is supplied to the cultivation tank 3a to perform irrigation. To do. In addition, in the liquid supply performed at the raw water supply time stored in the raw water time memory 54d, the liquid supply by drainage is not executed. Accordingly, the newly generated aqueous solution is supplied to the cultivation tank 3a with the total amount of liquid stored in the default value memory 54b or the input value memory 54c.

  The main cultivation system 101 is configured to supply liquid to the cultivation tank 3a by 30% of the necessary amount, and collect surplus liquid supply as drainage. Therefore, the liquid supply to the cultivation tank 3a is mainly performed by an aqueous solution newly generated from raw water. This is because the total amount of liquid supply required cannot be covered only by drainage. Here, as a form of liquid supply, a pattern in which each time of liquid supply is performed with an aqueous solution and drainage from raw water, a part of the entire liquid supply is performed with an aqueous solution and drainage from raw water, and the rest is the raw water There is a pattern performed only with an aqueous solution. In the main cultivation system 101, the raw water time memory 54d is provided so that the liquid supply can be executed by either of the two patterns. Thereby, a variation can be given to a liquid supply form, and the cultivation system 101 which reuses a drainage can be provided with the form adapted to each user's request.

  The drainage time memory 54e stores the drainage liquid supply time that is the liquid supply time when the cultivation tank 3a is supplied with the liquid, and is executed by both the aqueous solution generated from the raw water and the drainage. It is memory. Similarly to the raw water time memory 54d, the user's desired drainage supply time is input by operating the operation panel 41, and the input value (time) is stored in the drainage time memory 54e.

  When the CPU 51 recognizes the arrival of the drainage supply time stored in the drainage time memory 54e, the supply stored in the memory indicated by the setting flag 54a in the default value memory 54b or the input value memory 54c. Based on the amount of liquid, drainage and a newly generated aqueous solution are supplied to the cultivation tank 3a and irrigation is performed.

  The clock circuit 55 is for measuring time, and the time counted by the clock circuit 55 is read by the CPU 51 and used for each processing. As described above, when the CPU 51 determines from the time read from the clock circuit 55 that the registered liquid supply time (raw water supply time, drainage liquid supply time) has arrived, the central control is performed. Among the devices connected to the apparatus 1, the CPU 51 instructs the driver circuit 44 to operate the device to be driven, and the liquid supply to the cultivation tank 3a is executed.

  The CPU 51, ROM 52, RAM 53, EEPROM 54, and clock circuit 55 are connected to each other via a bus line 56 constituted by a data bus and an address bus. The bus line 56 is connected to an input / output port 57. In addition to the bus line 56, an operation panel 41, a display device 42, an alarm device 43, a driver circuit 44, and an A / D converter 45 are connected to the input / output port 57.

  The operation panel 41 is an input device including a numeric keypad and command keys for inputting various commands. The user can input liquid supply conditions and parameter data by operating the operation panel 41. Data and commands input from the operation panel 41 are displayed on the display device 42. The display device 42 is configured by a liquid crystal display (LCD), and displays characters, images, and the like in order to visually confirm the processing contents and procedures executed by the central control device 1 and input data. is there.

  The driver circuit 44 is a circuit for operating each device connected to the central controller 1, and includes a well pump 11, an electromagnetic metering pump 12, a first water pump 14, a second water pump 15, a recovery pump 16, and a mixture Each of the devices such as the electromagnetic valve 2a, the first to n-th line electromagnetic valves 2b, and the sixth three-way valve 26 is connected.

  The driver circuit 44 is a circuit for operating a connected device, generates a voltage corresponding to each device in accordance with each instruction given from the CPU 51 described above, and the generated voltage is instructed time, Supply to the corresponding device.

  Specifically, when the aqueous solution newly generated from the raw water is supplied to the irrigation device 3, the CPU 51 drives the first water pump 14 for a predetermined time and the second raw water supply path of the sixth three-way valve 26. The driver circuit 44 is instructed to operate in a direction in which 6c communicates with the nutrient mixing device 2 and to release the mixing electromagnetic valve 2a for a predetermined time. The driver circuit 44 energizes the first water pump 14, the sixth three-way valve 26, and the mixed electromagnetic valve 2a in accordance with the instruction from the CPU 51. Thereby, the raw water stored in the raw water tank 6 is sent to the nutrient mixing device 2 by the first water pump 14, and liquid fertilizer (nutrient) is added from the mixing electromagnetic valve 2a to generate an aqueous solution of a predetermined concentration. The generated aqueous solution is introduced into the irrigation apparatus 3a.

  In addition, when supplying drainage to the irrigation device 3, the CPU 51 drives the second water pump 15 for a predetermined time, the second drainage supply path 7c of the sixth three-way valve 26, the nutrient mixing device 2, and the like. The driver circuit 44 is instructed to operate in the direction in which the communication is established. The driver circuit 44 energizes the second water pump 15 and the sixth three-way valve 26 in response to the instruction from the CPU 51. Thereby, the drainage liquid stored in the drainage tank 7 is sent to the nutrient mixing device 2 by the second water pump 15 and introduced into the irrigation device 3 via the nutrient mixing device 2. In addition, when the drainage is supplied, the energizing electromagnetic valve 2a is not energized, and the mixing electromagnetic valve 2a remains closed. Therefore, the drainage is supplied as it is to the cultivation tank 3a without adjusting the concentration such as adding new liquid fertilizer.

  The A / D converter 45 is a device that converts analog data into digital data, and is connected to the recovery tank liquid level sensor 4a, the raw water tank liquid level sensor 6a, and the drainage tank liquid level sensor 7a. An analog detection signal (input value) input from the recovery tank liquid level sensor 4a, raw water tank liquid level sensor 6a, and drainage tank liquid level sensor 7a is converted into digital data by the A / D converter 45, and the central control unit. 1 is input.

  Further, a filtration control device 100 is connected to the central control device 1 via an input / output port 57. The central control device 1 is connected to the filtration control device 100 in a wired or wireless manner so that information communication is possible. When the central control device 1 receives information (signal) from the filtration control device 100, the central control device 1 performs processing according to the received information. Is executed.

  The well pump 11, the electromagnetic metering pump 12, the first water pump 14, the second water pump 15, the recovery pump 16, the mixing electromagnetic valve 2a, the first to n-th line electromagnetic valves 2b, and the sixth three-way valve 26 are as described above. The device is connected to the central control device 1 via the driver circuit 44.

  The well pump 11, the electromagnetic metering pump 12, the first water pump 14, the second water pump 15, and the recovery pump 16 are metering pumps, and their driving is controlled by the central controller 1. The well pump 11, the electromagnetic metering pump 12, and the recovery pump 16 are controlled by the central control device 1 when the central control device 1 receives a drive request signal from the filtration control device 100. That is, the pump is indirectly controlled by the filtration control device 100. From the filtration control device 100, a drive request signal for requesting driving of the well pump 11 and the electromagnetic metering pump 12 is transmitted to the central control device 1 at a timing when the raw water from the well is filtered by the filtration device 5. Further, the filtration control device 100 transmits a drive request signal for requesting the central control device 1 to drive the recovery pump 16 at a timing when the drainage is filtered by the filtration device 5. An instruction (drive signal) is output from the central controller 1 to the driver circuit 44 based on the drive request signal, and the well pump 11 and the electromagnetic metering pump 12 or the recovery pump 16 are driven. The main cultivation system 101 may be configured such that the well pump 11, the electromagnetic metering pump 12, and the recovery pump 16 are connected to the filtration control device 100 and directly controlled by the filtration control device 100.

  The mixing electromagnetic valve 2a is a device that is provided in the nutrient mixing device 2 as described above, and functions as an open / close valve for a supply port that supplies a liquid fertilizer stock solution (nutrient) from the nutrient tank to the raw water. The mixed electromagnetic valve 2a is a proportional control electromagnetic valve in which the opening amount of the valve is adjusted in proportion to the energization amount. That is, by changing the amount of opening of the mixing electromagnetic valve 2a, the amount of nutrient produced by the nutrient mixing device 2 is adjusted, and the nutrient concentration in the aqueous solution can be changed. The central controller 1 stores the nutrient concentration of the aqueous solution to be supplied, and the mixing solenoid valve 2a is operated with an energization amount corresponding to the nutrient concentration. Therefore, an aqueous solution having a set concentration is generated.

  The first to n-th line electromagnetic valves 2b are valves provided one by one in each piping of the dropping tube, and the opening / closing operation thereof is individually controlled by the central controller 1. In the present embodiment, each of the first to n-th line solenoid valves 2b is operated so that liquid supply is performed for each line (pipe).

  The sixth three-way valve 26 is a valve that is controlled by the central controller 1, and is in a communication state in which the second raw water supply path 6 c and the second combined supply path 2 c communicate with each other, the second drainage supply path 7 c, The communication state in which the two merging supply paths 2 c are communicated is switched based on an instruction from the central control device 1.

  The recovery tank liquid level sensor 4a, the raw water tank liquid level sensor 6a, and the drainage tank liquid level sensor 7a are electrode bar type sensors that detect the liquid level by a change in electrical resistance. Each sensor 4a, 6a, 7a is provided with three probes of different lengths that hang downward from the upper surface of each tank 4, 6, 7, and a pair of electrodes is arranged at the probe tip. The current value flowing between the electrodes (voltage value between the electrodes) is output as a detection value (signal). Since the value of the current flowing between the electrodes (the voltage value between the electrodes) changes depending on whether the electrode is in contact with the liquid or not, the change in the electrical resistance between the electrodes is the voltage value or the current value. Detected as a change. That is, when the electrode is not in contact with the liquid, the electric resistance value is increased as compared with when the electrode is in contact, and therefore the detection value (voltage value or current value) output from each sensor 4a, 6a, 7a is a predetermined value. Whether or not the probe tip of each of the sensors 4a, 6a, and 7a is immersed in the liquid is indicated by whether it is greater than or less than the determination value.

  Since each sensor 4a, 6a, 7a is provided with three probes having different lengths, each sensor 4a, 6a, 7a outputs three signals corresponding to each probe. Accordingly, the liquid level can be detected in three stages in each of the tanks 4, 6, and 7. The detection value from the longest probe allows the liquid level to fall below the tank (drought position), that is, it can detect drought. The detection value from the shortest probe detects the liquid level near the tank top surface. That is, it is possible to detect that the water is full. Therefore, the CPUs 51 and 71 can determine whether the tanks 4, 6 and 7 are full or drought by comparing the detection values (signals) from the sensors 4 a, 6 a and 7 a with predetermined determination values.

  The filtration control device 100 is a device that controls the filtration of raw water and drainage. Further, the filtration control device 100 is connected to the central control device 1 by wire or wirelessly, and is configured to perform information communication with the central control device 1.

  The filtration control device 100 includes a CPU 71, a ROM 72, a RAM 73, an EEPROM 74, a clock circuit 75, an input / output port 77, an operation panel 61, a display device 62, an alarm device 63, a driver circuit 64, and an A / D converter 65, which are arithmetic devices. I have.

  The ROM 72 is a non-rewritable nonvolatile memory that stores various control programs executed by the CPU 71 and fixed value data. The programs in the flowcharts of FIGS. 6 and 7 are stored in the ROM 72 as a part of the control program. The RAM 73 is a memory for temporarily storing various data.

  The EEPROM 74 is a rewritable nonvolatile memory for storing filtration conditions, various parameter values, and the like. The filtration control device 100 can register and change filtration conditions and various parameters by the user by operating the operation panel 61. The filtration conditions and various parameter values input by the user are held in the EEPROM 74 even after the power is turned off. In addition, when a filtering condition or the like is newly input, a value stored in advance is updated to the input value.

  The EEPROM 74 includes a raw water filtration time memory 74a and a drainage filtration time memory 74b. The raw water filtration time memory 74a is a memory that stores the raw water filtration time at which raw water is filtered. The raw water filtration time is input as a value desired by the user by operating the operation panel 61 by the user, and the input value (time) is stored in the raw water filtration time memory 74a.

  The CPU 71 always manages the time, and when the arrival of the raw water filtration time stored in the raw water filtration time memory 74a is recognized by the CPU 71, the filtration of the well pump 11 is performed by a filtration process (S22) described later. Driving, opening / closing of the corresponding electromagnetic valve 30 and switching of the three-way valve 20 are performed, and raw water is sent to the filtration device 5 to perform the filtration. When the raw water filtration time stored in the raw water filtration time memory 74a has arrived, if the raw water tank 6 is full, the CPU 71 determines that filtration is impossible and the raw water is not filtered.

  The drainage filtration time memory 74b is a memory that stores a drainage filtration time for filtering the drainage. As with the raw water filtration time, the drainage filtration time is input as a user-desired value by operating the operation panel 61 by the user, and the input value (time) is stored in the drainage filtration time memory 74b. When the CPU 71 recognizes the arrival of the drainage filtration time stored in the drainage filtration time memory 74b, the recovery pump 16 is driven, the corresponding electromagnetic valve 30 is opened and closed, and the three-way valve 20 is switched. The drainage is sent to the device 5 and the filtration is performed. When the drainage filtration time stored in the drainage filtration time memory 74b arrives, if the drainage tank 7 is full, the CPU 71 determines that filtration is impossible, and the drainage filtration is not executed. .

  In this embodiment, in order to eliminate clogging of the filtration membrane 5a, the above-described washing operation (back washing process) of the filtration membrane 5a is periodically performed. This backwash process is executed when the number of times of filtration in the filtration tanks 5A and 5B has reached a predetermined number. Although not shown, the EEPROM 74 is provided with a counter for counting the number of times of filtration, and the value is updated by 1 each time the filtration is executed. When the backwash process is executed, the counter value is cleared to zero.

  The clock circuit 75 is for measuring time, and the time counted by the clock circuit 75 is read by the CPU 71 and used for each processing. As described above, when the CPU 71 determines that the filtration time (raw water filtration time, drainage filtration time) stored in the EEPROM 74 is reached based on the time read from the clock circuit 75, the filtration control device Among the devices connected to 100, the CPU 71 instructs the driver circuit 44 to operate each device to be driven. Furthermore, in the case of raw water filtration, a drive request signal requesting the drive of the well pump 11 and the electromagnetic metering pump 12 is transmitted to the central control device 1, and in the case of drainage filtration, the recovery pump 16 A drive request signal for requesting drive is transmitted to the central controller 1.

  The CPU 71, ROM 72, RAM 73, EEPROM 74, and clock circuit 75 are connected to each other via a bus line 76 constituted by a data bus and an address bus. The bus line 76 is connected to the input / output port 77. In addition to the bus line 76, an operation panel 61, a display device 62, an alarm device 63, a driver circuit 64, and an A / D converter 65 are connected to the input / output port 77.

  The operation panel 61 is an input device including a numeric keypad and command keys for inputting various commands. The user can input data and commands to the filtration control device 100 by operating the operation panel. Data and commands input from the operation panel 61 are displayed on the display device 62. The display device 62 is configured by a liquid crystal display (LCD), and displays characters, images, and the like in order to visually confirm the processing contents and procedures executed by the filtration control device 100, input data, and the like. is there.

  The driver circuit 64 is a circuit for operating each device connected to the filtration control device 100, and includes the compressor 13, the electromagnetic valve 20 (first to seventh electromagnetic valves 31 to 37), and the three-way valve 30 (first to first valves). Each of the devices such as the fifth three-way valves 21 to 25) is connected.

  The driver circuit 64 is a circuit for operating a connected device, generates a voltage corresponding to each device in accordance with each instruction given from the CPU 71 described above, and the generated voltage is instructed time, Supply to the corresponding device.

  Specifically, when the raw water is filtered, the CPU 71 operates the first three-way valve 21, the second three-way valve 24, the third three-way valve 23, and the fourth three-way valve 24, and the first and second operations. The driver circuit 64 is instructed to open (turn on) the solenoid valves 31 and 32 for a predetermined time. In addition, about each 1st-4th three-way valve 21-24, operation | movement (switching) to the predetermined | prescribed position which forms the flow path of raw | natural water is instruct | indicated. The driver circuit 64 energizes the first to fourth three-way valves 21 to 24 and the first and second electromagnetic valves 31 and 32 in response to an instruction from the CPU 71. Thereby, the flow path of the raw water from the water source 17 to the raw water tank 6 is formed.

  In addition, when the drainage is filtered, the CPU 71 operates the first three-way valve 21, the second three-way valve 24, the third three-way valve 23, and the fourth three-way valve 24, and the first and second electromagnetic valves. The driver circuit 64 is instructed to open (turn on) 31 and 32 for a predetermined time. In addition, about each 1st-4th three-way valve 21-24, the operation | movement (switching) to the predetermined | prescribed position which forms the flow path of drainage is instruct | indicated. A drainage flow path from the recovery tank 4 to the drainage tank 7 is formed by energizing each device from the driver circuit 64 based on such an instruction.

  The A / D converter 65 is a device that converts analog data into digital data, and is connected to the can differential pressure sensor 5d. An analog detection signal (input value) input from the can differential pressure sensor 5 d is converted into digital data by the A / D converter 65 and input to the filtration control device 100.

  Moreover, the central control apparatus 1 is connected to the filtration control apparatus 100 via the input / output port 77, and as described above, information communication with the central control apparatus 1 is executed. . A drive request signal for requesting driving of the device is transmitted from the filtration control device 100 to the central control device 1. In the main cultivation system 101, some of the devices (well pump 11, electromagnetic metering pump 12, recovery pump 16) to be driven when filtering raw water and drainage are connected to the central controller 1, and the devices directly Control is performed by the central controller 1. Since the filtration control device 100 needs to drive the well pump 11, the electromagnetic metering pump 12, and the recovery pump 16 during the filtration, the filtration control device 100 transmits a drive request signal for requesting the drive to the central control device 1. When receiving the drive request signal, the central controller 1 drives the corresponding device requested to be driven.

  In addition, input values input to the central controller 1 from the recovery tank liquid level sensor 4a, raw water tank liquid level sensor 6a, and drainage tank liquid level sensor 7a are transmitted from the central controller 1 to the filtration controller 100. And received by the filtration control device 100. The filtration control device 100 determines whether or not the filtration process (S22) is executed according to the signal received from the central control device 1.

  The compressor 13, the three-way valve 20, and the electromagnetic valve 30 are devices connected to the filtration control apparatus 100 via the driver circuit 64 as described above.

  The compressor 13 is a device that produces compressed air, and the driving thereof is controlled by the filtration control device 100. The compressor 13 is driven at the timing of backwashing the filtration tanks 5A and 5B and the timing of filtering raw water. The produced compressed air is sent to the filtration device 5 at the timing of backwashing the filtration tanks 5A and 5B, and used for washing the filtration membrane 5a provided in the filtration device 5. Moreover, at the timing of raw water filtration, the produced compressed air is sent to the raw water tank 6 and used for bubbling (decomposition of residual hypochlorous acid) to the raw water after filtration stored in the raw water tank 6.

  The three-way valve 20 is a valve for defining one flow path in the main cultivation system 101 configured to be capable of forming a plurality of flow paths by a combination of a plurality of supply paths, and the first to fifth three-way valves 21. It has 5 three-way valves of ~ 25. The first to fifth three-way valves 21 to 25 are individually controlled by the filtration control device 100. The main cultivation system 101 executes a plurality of work operations such as raw water filtration and drainage filtration, and backwashing of the filtration tanks 5A and 5B. Here, when the work operation to be performed is different, it is necessary to form different flow paths. Therefore, the 1st-5th three-way valves 21-25 are driven according to the contents of work to perform.

  The electromagnetic valve 30 communicates and shuts off the supply path, and includes first to seventh electromagnetic valves 31 to 37. The first to seventh electromagnetic valves 31 to 37 are individually controlled by the filtration control device 100, and the necessary electromagnetic valves 30 among the first to seventh electromagnetic valves 31 to 37 are selected according to the work contents to be executed. Will be energized. A flow path corresponding to the content of work to be performed is formed by the operations (opening and closing) of the first to seventh electromagnetic valves 31 to 37 and the communication direction of the first to fifth three-way valves 21 to 25. The Rukoto.

  One can differential pressure sensor 5d is provided for each of the filtration tanks 5A and 5B. The can differential pressure sensor 5d is a device that detects a pressure difference (differential pressure) between the upstream side and the downstream side across the filtration membrane 5a, converts the detected differential pressure into an electrical signal, and outputs the electrical signal. As the degree of clogging of the filtration membrane 5a increases, the differential pressure increases.

  The electric signal (detected value) from the can differential pressure sensor 5d is input to the filtration control device 100 via the A / D converter 65 as described above. In the filtration control device 100, the input value from the can differential pressure sensor 5d is monitored, and when the input value (that is, the differential pressure) exceeds a predetermined value, it is determined that the signal is abnormal, and the filter membrane 5a You will be notified that the clog has reached its limit.

  Next, each control process executed in the filtration control device 100 will be described with reference to the flowcharts of FIGS. 6 and 7. FIG. 6 is a flowchart of main processing executed in the filtration control device 100.

  As shown in FIG. 6, the main process in the filtration control device 100 is started by turning on the power. First, based on the time of the clock circuit 75, the raw water and drainage stored in the raw water and drainage filtration time memories 74a and 74b are stored. It is confirmed whether or not the liquid filtration time has come (S21), and if the raw water and drainage filtration time has not come (S21: No), the process of S22 is skipped and the process proceeds to S23. On the other hand, if the raw water and drainage filtration time has come (S21: Yes), a filtration process (S22) for filtering the raw water and drainage is performed.

  When the raw water and drainage filtration time has not come (S21: No) or after the filtration process (S22) is executed, each process is executed (S23). In each processing (S23), for example, raw water and drainage filtration time setting processing, various parameter setting processing, informed alarm device 63 cancellation processing, and other processing performed in the filtration control device 100 are performed. Execute. And after performing each process (S23), this process transfers to the process of S21, and repeats the process of S21-S23 until a power supply is cut off.

  FIG. 7 is a flowchart of the filtering process (S22) executed in the main process of FIG. The filtration process (S22) is a process for performing filtration on the raw water or the drainage.

  As shown in FIG. 7, in the filtration process (S22), first, it is confirmed whether or not the signal inputted from the can differential pressure sensor 5d shows an abnormality (S41), and the signal is abnormal, that is, the filtration. If the membrane 5a is clogged (S41: Yes), a warning is given by the alarm device 63 (S47), and the filtration process (S22) is terminated. On the other hand, if the signal is not abnormal, that is, if the filtration membrane 5a is not clogged (S41: No), it is determined that the filtration process (S22) can be continued, and the drainage is performed based on the time of the clock circuit 75. It is confirmed whether or not the drainage filtration time stored in the filtration time memory 74b has arrived (S42).

  Here, when the drainage filtration time has not arrived (S42: No), that is, when it is the raw water filtration time, the raw water tank 6 is based on the signal of the raw water tank liquid level sensor 6a transmitted from the central controller 1. It is confirmed whether or not the water is full (S43). When the signal indicates that the raw water tank 6 is full (S43: Yes), it is determined that the iron removal filtration process (S44) cannot be performed, and a warning is given by the alarm device 63 (S52). The filtration process (S22) is terminated.

  On the other hand, when the signal indicates that the raw water tank 6 is not full (S43: No), the iron removal filtration process is executed (S44). In the iron removal filtration process (S44), as described above, the sodium hypochlorite aqueous solution stored in the oxidation tank 8 is injected into the raw water in the water source supply path 17a, and the water source supply path 17a and the first combined supply path 17b is used to perform filtration of raw water to remove ferric hydroxide and manganese oxide produced by oxidation of iron ions and manganese ions in the raw water using the filtration device 5; This is a process for switching the first and third three-way valves 21 and 23, opening the first electromagnetic valve 31, driving the electromagnetic metering pump 12, and the like.

  After performing the iron removal filtration process (S44), it is determined whether or not it is a backwash timing that is a timing for performing the backwash (S45). If it is not the backwash timing (S45: No), the process of S46 is skipped. And this filtration process (S22) is complete | finished, On the other hand, if it is a backwash timing (S45: Yes), a backwash process (S46) will be performed.

  In addition, although the backwash timing in this Embodiment arrives regularly, ie, when the filtration process of predetermined number of times is performed, in addition to this, a can body differential pressure sensor The filtration control device 100 may be controlled to perform backwashing when the signal input from 5d indicates an abnormality, that is, when the filtration membrane 5a is clogged.

  Here, the backwash process (S46) is a process for removing the residue clogged in the filtration membrane 5a. First, the fourth and sixth electromagnetic valves 34 and 36 are opened, and any filtration tank 5A, The fourth three-way valve 24 is switched so that 5B and the backwash supply path 13b communicate with each other, and the compressor 13 and the arbitrary filtration tanks 5A and 5B are communicated with each other via the pressurized supply path 13a and the backwash supply path 13b.

  Then, the compressor 13 is driven for a predetermined time. Thereby, the inside of the filtration tanks 5A and 5B is pressurized, and the residue clogged with the filtration membrane 5a is easily peeled off.

  Next, with the fourth and sixth electromagnetic valves 34 and 36 and the fourth three-way valve 24 held in the above-described state, the fifth filtration tanks 5A and 5B and the external supply path 5c are communicated with each other. The three-way valve 25 is switched. Thereby, the filtration tanks 5A and 5B are communicated with the outside via the external supply path 5c, and the pressurized filtration tanks 5A and 5B are leaked.

  Next, with the fourth and sixth electromagnetic valves 34 and 36 and the fourth and fifth three-way valves 24 and 25 held in the above-described state, the fifth electromagnetic valve 35 is opened, and any filtration tanks 5A and 5B The third three-way valves 24 and 25 are switched so as to communicate with the air supply path 13d.

  Then, the compressor 13 is driven for a predetermined time. As a result, air is supplied into the filtration tanks 5A and 5B and the raw water or drainage liquid stored in the filtration tanks 5A and 5B is bubbled.

  Next, with the fourth, fifth and sixth electromagnetic valves 34, 35, 36 and the third and fourth three-way valves 23, 24 held in the above-described state, the filtration tanks 5A, 5B and the external supply path 5c The fifth three-way valve 25 is switched so that the communication is cut off, and the third electromagnetic valve 33 is opened.

  Thereby, the water in filtration tank 5A, 5B containing a residue is discharged | emitted outside via the 1st confluence | merging supply path 17b and the external supply path 5c.

  Next, with the fifth electromagnetic valve 35, the third and fifth three-way valves 23, 25 held in the above-described state, the third and fourth electromagnetic valves 33, 34 are closed, and the filtration tanks 5A, 5B and the filtrate supply are supplied. The fourth three-way valve 24 is switched so that the communication with the path 5b is blocked, and the first electromagnetic valve 31 is opened.

  When the next filtration process is the iron removal filtration process (S44), the first three-way valve 21 is switched so that the water source supply path 17a and the first combined supply path 17b communicate with each other, and the well pump 11 is driven. Then, raw water is supplied into the filtration tanks 5A and 5B.

  Next, the first electromagnetic valve 31, the first and third three-way valves 31, 33 are held in the above-described state, the fifth electromagnetic valve 35 is closed, and the filtration tanks 5A, 5B and the external supply path 5c are in communication with each other. The fifth three-way valve 25 is switched so as to be shut off. Further, the fourth three-way valve 34 is switched so that the arbitrary filtration tanks 5A, 5B and the filtrate supply path 5b communicate with each other, and the second electromagnetic valve 32 is opened. Further, the second three-way valve 22 is switched so that the filtrate supply path 5b and the first raw water supply path 6b communicate with each other. Thereby, the air stored in the filtration tanks 5A and 5B is discharged to the raw water tank 6.

  On the other hand, when the next filtration process is the drainage filtration process (S50), the first three-way valve 21 is switched so that the recovery supply path 4b and the first merging supply path 17b communicate with each other. Further, the recovery pump 16 is driven to supply drainage into the filtration tanks 5A and 5B.

  Next, the first electromagnetic valve 31, the first and third three-way valves 31, 33 are held in the above-described state, the fifth electromagnetic valve 35 is closed, and the filtration tanks 5A, 5B and the external supply path 5c are in communication with each other. The fifth three-way valve 25 is switched so as to be shut off. Further, the fourth three-way valve 34 is switched so that the arbitrary filtration tanks 5A, 5B and the filtrate supply path 5b communicate with each other, and the second electromagnetic valve 32 is opened. Further, the second three-way valve 22 is switched so that the filtrate supply path 5b and the first drainage supply path 7b communicate with each other. Thereby, the air stored in the filtration tanks 5A and 5B is discharged to the drainage tank 7.

  After the backwashing process (S46) is performed, the filtering process (S22) is terminated.

  In the process of S42, if the drainage filtration time has come (S42: Yes), whether or not the recovery tank 4 is drought based on the signal of the recovery tank liquid level sensor 4a transmitted from the central controller 1 is determined. Is confirmed (S48). If the signal indicates that the recovery tank 4 is drought (S48: Yes), it is determined that the drainage liquid for drainage filtration (S50) is not stored in the recovery tank 4. Then, notification is given by the alarm device 63 (S51), and the filtering process (S22) is terminated.

  On the other hand, when it is indicated that the recovery tank 4 is not drought (S48: No), the drain tank 7 is full based on the signal from the drain tank level sensor 7a transmitted from the central controller 1. (S49). If the signal indicates that the drainage tank 7 is full (S49: Yes), it is determined that the drainage filtration process (S50) cannot be performed, and a warning is issued by the alarm device 63 (S51). The filtration process (S22) is terminated.

  On the other hand, if the signal indicates that the drain tank 7 is not full (S49: Yes), the drain filtration process (S50) is executed (S50). In the drainage filtration process (S50), as described above, the recovery supply path 4b and the first merging supply path 17b are communicated, and the nutrients in the drainage stored in the recovery tank 4 are allowed to pass through the phytopathogenic bacteria. A process for filtering the drainage liquid to be removed is a process for switching the first and third three-way valves 21 and 23, opening the first electromagnetic valve 31, and the like.

  Then, after executing the drainage filtration process (S50), the process proceeds to the process of S45.

  Next, each control process executed in the central controller 1 will be described with reference to the flowcharts of FIGS. FIG. 8 is a flowchart of main processing executed in the central controller 1.

  As shown in FIG. 8, the main process in the central controller 1 is started by turning on the power, and first, the raw water and drainage liquid stored in the raw water and drainage time memories 54d and 54e based on the time of the clock circuit 55. It is confirmed whether or not the liquid supply time has come (S31), and if the raw water and drainage liquid supply time has not come (S31: No), the process of S32 is skipped and the process proceeds to S32. On the other hand, if the raw water and drainage liquid supply time has arrived (S31: Yes), a liquid supply process for supplying raw water and drainage is performed (S32).

  When the raw water and drainage liquid supply time has not arrived (S31: No) or after the liquid supply process (S32) is executed, each process is executed (S33). In each process (S33), for example, a process for setting raw water and drainage liquid supply time, a process for setting various parameters, a cancel process for the alarm device 43 that has been informed, and other processes that are performed by the central controller 1 Execute. And after performing each process (S33), this process transfers to the process of S31, and the process of S31-S33 is repeated until a power supply is cut off.

  FIG. 9 is a flowchart of the liquid supply process (S32) executed in the main process of FIG. The liquid supply process (S32) is a process for controlling the supply of raw water or drainage to the cultivation tank 3a.

  As shown in FIG. 9, in the liquid supply process (S32), first, the time of the clock circuit 55 is read (S61). Next, based on the time of the read clock circuit 55, it is confirmed whether or not the drainage liquid supply time stored in the drainage time memory 54e has arrived (S62). (S62: Yes), it is confirmed whether or not the input value from the recovery tank liquid level sensor 4a is a value indicating drought (S63).

  Next, if the input value from the recovery tank liquid level sensor 4a is not a value indicating drought (S63: No), that is, if the recovery tank 4 stores more than a predetermined amount of drainage, the setting flag 54a is turned on. (S64).

  When the setting flag 54a is ON (S64: Yes), the waste water supply amount stored in the input value memory 54c is read in order to supply the raw water and the waste liquid under the conditions input by the user (S65). ). On the other hand, when the setting flag 54a is not on (S64: No), the drainage supply amount stored in the default value memory 54b is read in order to supply the raw water and drainage liquid under the preset conditions. (S74). After the processes of S65 and S74, the total drainage supply amount is calculated by multiplying the read drainage supply amount by the number of pipes (n) (S66).

  In addition, the number of piping is the number of piping of the dropping tube provided in the dripping apparatus 3b.

  Next, based on the value input from the drainage tank liquid level sensor 7a, it is confirmed whether or not the total drainage supply amount is larger than the drainage storage amount of the drainage tank 7 (S67). When the amount is larger than the total drainage supply amount (S67: No), that is, when the drainage liquid of the total drainage supply amount or more is stored in the drainage tank 7, the read drainage supply amount is stored in the RAM 53. Store in a predetermined area (S68).

  Next, after the raw water supply amount stored in the memories 54b and 54c indicated by the setting flag 54a is read out and stored in a predetermined area of the RAM 53 (S69), the drainage supply process is executed (S70).

  In the drainage supply process (S <b> 70), first, the sixth three-way valve 26 is switched so that the drainage tank 7 and the nutrient mixing device 2 communicate with each other, and the drainage stored in the drainage tank 7 by the second water pump 15. Is sent to the nutrient mixing device 2. At this time, the mixing electromagnetic valve 2a stops the mixing of nutrients in the closed state, that is, in the drainage sent from the drainage tank 7. And the waste liquid supplied to the dripping apparatus 3b via the nutrient mixing apparatus 2 is supplied to each piping of the dripping apparatus 3b by open | releasing the 1st-nth line electromagnetic valve 2b. Thereafter, raw water supply processing is performed (S71).

  In the raw water supply process (S71), first, the sixth three-way valve 26 is switched so that the raw water tank 6 and the nutrient mixing device 2 communicate with each other, and the raw water stored in the raw water tank 6 by the first water pump 15 is used as the nutrient mixing device. Send to 2. At this time, the mixing electromagnetic valve 2a is in an open state, that is, a nutrient solution is mixed into the raw water sent from the raw water tank 6 to produce an aqueous solution. And the aqueous solution manufactured by the nutrient mixing apparatus 2 and supplied to the dripping apparatus 3b is supplied to each piping of the dripping apparatus 3b by opening the first to n-th line electromagnetic valves 2b, and this liquid supply process (S32) is completed. To do.

  On the other hand, as a result of checking in the process of S62, if the drainage liquid supply time has not come (S62: No), it is checked whether or not the raw water supply time stored in the raw water time memory 54d has come (S72).

  If the raw water supply time has not come (S72: No), the liquid supply process (S32) is terminated. On the other hand, if the raw water supply time has come (S72: Yes), the raw water is supplied using only the raw water. It is determined that the liquid is to be used, and the total liquid supply amount stored in the memories 54b and 54c indicated by the setting flag 54a is read out and stored in a predetermined area of the RAM 53 (S73), and the process proceeds to the process of S71. .

  If the input value from the recovery tank liquid level sensor 4a is a value indicating drought (S63: Yes) as a result of checking in the process of S63, only the raw water is stored because no drainage is stored in the recovery tank 4. Is used to read the total liquid supply amount stored in the memory indicated by the setting flag 54a and stored in a predetermined area of the RAM 53 (S73), and the process proceeds to the process of S71. To do.

  Further, as a result of checking in the processing of S67, the total drainage supply amount is larger than the drainage storage amount (S67: Yes), that is, the drainage of the total drainage supply amount is not stored in the drainage tank 7. After calculating the drainage supply amount per pipe that can be actually supplied by the drainage storage amount / the number of pipes (n) (S75), the calculated drainage supply amount is stored in the memory 54b indicated by the setting flag 54a. , 54c is subtracted from the total liquid supply amount, and the raw water supply amount supplied this time is calculated (S76).

  For example, when the number of pipes is 10, the total drainage supply amount is 10 liters, and the drainage storage amount is 5 liters, first, to evenly distribute the drainage stored in the drainage tank 7 to each pipe, The drainage supply amount is calculated to be 0.5 liters by 5 (liter) / 10 (main).

  Next, in the case where the total liquid supply amount stored in the memories 54b and 54c indicated by the setting flag 54a, that is, the total amount of raw water and drainage supplied to each pipe is 2 liters, 2 (liter) to 0.5 (Liter) is subtracted and the raw water supply amount is calculated as 1.5 liters.

  Then, after storing the calculated drainage supply amount and raw water supply amount in a predetermined area of the RAM (S77), the process proceeds to the process of S70.

  As described above, in the main cultivation system 101, the nutrient mixing device 2 mixes nutrients with the raw water, and pauses mixing of nutrients with respect to the drainage, and the aqueous solution derived from the nutrient mixing device 2. Or drainage is supplied to each piping of dripping device 3b, respectively.

  Here, the drainage is already mixed with nutrients by the nutrient mixing device 2. Therefore, when it is introduced into the nutrient mixing device 2 in a state where the raw water and the drainage liquid are mixed, it is necessary to calculate the mixing ratio of the raw water and the drainage and set the mixing amount of the nutrient based on the calculated value. is there.

  On the other hand, when the raw water and the drainage are respectively supplied to the nutrient mixing device 2, it is only necessary to determine whether the nutrient is mixed or not (open / close of the mixing electromagnetic valve 2a). The control for calculating the mixing ratio is not necessary, and the control of the central controller 1 can be facilitated accordingly.

  In the liquid supply process (S32) in the present embodiment, the raw water supply process (S71) is performed after supplying the drainage of the drainage supply amount to all the pipes by the drainage supply process (S70). It is configured to supply a supply amount of raw water to all the pipes. However, after supplying each pipe to each pipe, that is, after supplying the drainage of the drainage supply amount to one pipe, the raw water supply quantity of raw water is supplied to one pipe, and these operations are repeated for the number of pipes. It may be configured.

  Next, a second embodiment will be described with reference to FIG. In 1st Embodiment, although the 2nd drainage supply path 7c demonstrated the case where it comprised so that it might connect with the nutrient mixing apparatus 2 via the 2nd merge supply path 2c, in 2nd Embodiment, The two drainage supply passages 7c are configured to be connected to the aqueous solution supply passage 2d through the shortened supply passage 202d. In addition, the same code | symbol is attached | subjected to the part same as above-described 1st Embodiment, and the description is abbreviate | omitted.

  FIG. 10 is an overall view schematically showing the cultivation system 201 in the second embodiment.

  As shown in FIG. 10, the raw water stored in the raw water tank 6 is in a state where the raw water electromagnetic valve 14a interposed between the second raw water supply path 6c and the second combined supply path 2c is open. It is sent to the nutrient mixing device 2 by the water pump 14.

  On the other hand, the drainage liquid stored in the drainage tank 7 is in a state in which the drainage electromagnetic valve 15a interposed between the second drainage supply path 7c and the shortened supply path 202d is opened, and the second water pump 15 Is sent directly to the dropping device 3b without going through the nutrient mixing device 2.

  Further, in the present embodiment, the second water pump 15 is connected to the filtration control device 100 and is configured to be directly controllable by the filtration control device 100.

  Here, the drainage liquid stored in the drainage tank 7 has already been mixed with nutrients by the nutrient mixing device 2. Therefore, when the drainage liquid stored in the drainage tank 7 is supplied to the dropping device 3a via the nutrient mixing device 2, the nutrient mixing device 2 keeps the nutrient ratio in the drainage constant. It is necessary to stop mixing of nutrients to the drainage by controlling the mixing electromagnetic valve 2a. As a result, the central control device 1 requires determination means for determining whether it is raw water or drainage, and control means for controlling the mixing electromagnetic valve 2a according to whether it is raw water or drainage.

  On the other hand, in the case where the drainage liquid stored in the drainage tank 7 is supplied to the dropping device 3b without passing through the nutrient mixing device 2, the determination means and the control means described above are unnecessary, and the central control is accordingly performed. Control of the apparatus 1 can be facilitated.

  In addition, in the case where the filtration device 5 is introduced into a cultivation system constructed without the filtration device 5, as described above, only the raw water is supplied to the nutrient mixing device 2, so that FIG. In the process of S70, the pause control of the mixed electromagnetic valve 2a with respect to the drainage becomes unnecessary. As a result, it becomes unnecessary to add a control program for the mixed electromagnetic valve 2a for the drainage to the central controller 1, so that the filtration device 5 can be easily introduced into an existing cultivation system that does not have the filtration device 5. can do.

  Next, a third embodiment will be described with reference to FIG. In the first embodiment, the case where the filtration device 5 includes two filtration tanks 5A and 5B has been described. In the third embodiment, the filtration device 305 includes one filtration tank 305A. Has been. In addition, the same code | symbol is attached | subjected to the part same as above-described 1st Embodiment, and the description is abbreviate | omitted.

  FIG. 11 is an overall view schematically showing the cultivation system 301 in the third embodiment.

  As shown in FIG. 11, the filtration device 305 is for filtering raw water obtained from the water source 17 and drainage liquid stored in the recovery tank 4, and is configured to include one filtration tank 305A. The filtration tank 305A includes a filtration membrane 5a (see FIG. 2) for filtering raw water and waste liquid.

  A first merging supply path 17b and an air supply path 13d are connected to one end side (the lower side in FIG. 11) of the filtration device 305. The water source supply path 17a or the recovery supply path 4b and the filtration tank 305A are communicated with each other by the operation of the first three-way valve 21 and the opening of the first electromagnetic valve 31. Moreover, when the 1st confluence | merging supply path 17b and the external supply path 5c are connected by opening | releasing the 3rd solenoid valve 33, the filtration tank 305A and the exterior are connected. Further, when the fifth electromagnetic valve 35 is opened, the air supply path 13d and the filtration tank 305A are communicated with each other.

  On the other hand, one end of the filtrate supply path 5b and the backwash supply path 13b is connected to the other end side (upper side in FIG. 11) of the filtration device 305. The filtrate supply path 5b and the filtration tank 305A are communicated with each other by opening the second electromagnetic valve 32. Further, the back washing supply path 13b and the filtration tank 305A are communicated with each other by opening the fourth electromagnetic valve 34.

  In addition, one end of the external supply path 5c is connected to the side surface of the filtration tank 305, and the opening and closing of the eighth electromagnetic valve 338 provided in the external supply path 5c allows selective communication and blocking between the outside and the filtration tank 305A. Can be switched to.

  The eighth electromagnetic valve 338 is for communicating and blocking the external supply path 5c, and the communication and blocking between the outside and the filtration tank 305A are selectively switched by opening and closing a valve provided therein.

  Note that when the filtration tank 305 is backwashed, the first solenoid valve 31 is always closed, and the supply of raw water from the water source or the drainage from the recovery tank 4 is stopped. As a result, when the filtration tank 305 is backwashed, raw water or drainage is prevented from being mixed into the filtration tank 305.

  As described above, by configuring the filtration device 305 with one filtration tank 305A, it is possible to reduce the cost of the device as compared with the case where two or more filtration tanks are configured.

  In addition, a three-way valve for selectively switching the communication with each filtration tank is not required as in the case where two or more filtration tanks are provided, and the cost of the apparatus can be reduced accordingly. .

  The present invention has been described above based on the embodiments. However, the present invention is not limited to the above embodiments, and various improvements and modifications can be made without departing from the spirit of the present invention. It can be easily guessed.

  For example, in the cultivation systems 101 and 201 in the first and second embodiments, the filtration device 5 includes two filtration tanks 5A and 5B, and in the cultivation system 301 in the third embodiment, the filtration device 305 is provided. Although one filtration tank 305A is provided, it is not necessarily limited to this, and three or more filtration tanks may be provided.

  Moreover, in cultivation system 101,201,301 in this Embodiment, it is comprised so that iron and manganese in raw | natural water may be removed by inject | pouring a sodium hypochlorite aqueous solution into the water source supply path 17a, but this is not necessarily the case. However, the present invention is not limited to this, and it may be configured so that an aqueous solution of sodium hypochlorite is injected into the recovery supply path 4b to remove iron and manganese in the effluent stored in the recovery tank 4.

  In such a case, a supply path connecting the compressor 13 and the drainage tank 7 is provided, and the air supplied by the compressor 13 through the supply path decomposes unreacted sodium hypochlorite. It is desirable to configure as follows.

  Further, the filtration membrane 5a in the present embodiment has a membrane pore diameter set within a range of 0.5 nm or more and 0.5 μm or less, but a range of 0.5 nm or more and 0.1 μm or less. It is more preferable to set the value within the range. Thereby, compared with the case where the membrane pore diameter of the filtration membrane 5a is larger than 0.1 micrometer, a plant pathogenic microbe can be removed reliably.

It is a whole figure showing typically the cultivation system in a 1st embodiment of the present invention. (A) is sectional drawing which shows a filtration tank typically, (b) is an expanded sectional view which shows a filtration membrane typically. (A) is the figure which showed the test result of the capture test, (b) is the figure which showed the test result of the adsorption test. (A) is a figure which shows operation | movement of the cultivation system with respect to raw | natural water, (b) is a figure which shows operation | movement of the cultivation system with respect to drainage. It is a block diagram which shows the outline of the electric circuit structure of a cultivation system. It is a flowchart of the main process performed in the filtration control apparatus. It is a flowchart of the filtration process performed in the main process of FIG. It is a flowchart of the main process performed in a central control unit. It is a flowchart of the liquid supply process performed in the main process of FIG. It is a general view which shows typically the cultivation system in 2nd Embodiment. It is a general view which shows typically the cultivation system in 3rd Embodiment.

Explanation of symbols

1 Central control device (part of nutrient mixing device)
2 Nutrient mixing device 2a Mixing solenoid valve (mixing control means)
3a Cultivation tank 3c Recovery device 5,305 Filtration device 5A, 5B, 305A Filtration tank (part of filtration device)
5a Filtration membrane 8 Oxidation tank (part of oxidation means)
11 Well pump (part of acquisition means, part of supply means)
12 Electromagnetic metering pump (part of oxidation means)
13 Compressor (Backwash device)
14 First water pump (part of supply means)
15 Second water pump (part of supply means)
16 Recovery pump (circulation device, part of supply means)
17 Water source 100 Filtration control device (part of filtration device)
101, 201, 301 Cultivation system 202d Short supply path (shortening path)

Claims (7)

A cultivation tank for cultivating plants;
A collection device for collecting the liquid drained from the cultivation tank;
A filtration device having a filtration membrane for filtering the liquid collected by the collection device;
A circulation device for returning the liquid filtered by the filtration device to the cultivation tank,
The filtration membrane has a membrane pore diameter of 0.5 nm or more and 0.5 μm or less, allows nutrients contained in the liquid to pass through, and removes plant pathogens contained in the liquid The cultivation system characterized by being comprised in.   The cultivation system according to claim 1, wherein the filtration membrane is made of a hydrophilic material.   The cultivation system according to claim 1 or 2, wherein the filtration membrane comprises a hollow fiber membrane. A backwashing device for washing the filtration membrane by flowing washing water in a direction opposite to the filtration direction for filtering the liquid collected by the collection device;
A plurality of the filtration devices are provided, and when one filtration device of the plurality of filtration devices is washed, at least one of the plurality of filtration devices excluding the one filtration device is the The cultivation system according to claim 3, wherein the liquid collected by the collection device is configured to be filtered. An acquisition means for acquiring water from a water source;
An oxidation means for oxidizing the water component obtained by the obtaining means,
5. The cultivation system according to claim 1, wherein the water acquired by the acquisition unit is filtered by the filtration device after being oxidized by the oxidation unit. An acquisition means for acquiring water from a water source;
A nutrient mixing device for mixing nutrients in the water;
Supply means for supplying water obtained by the obtaining means and the liquid collected by the collecting device to the nutrient mixing device, respectively.
The said nutrient mixing apparatus is equipped with the mixing control means to mix the nutrient with respect to the said water, and to stop mixing of the nutrient with respect to the said liquid. The cultivation system described. An acquisition means for acquiring water from a water source;
A nutrient mixing device for mixing nutrients in the water;
A shortening path that bypasses the nutrient mixing device between the filtration device and the cultivation tank;
The water obtained by the obtaining means is supplied to the cultivation tank after nutrients are mixed by the nutrient mixing device,
The cultivation system according to claim 1, wherein the liquid collected by the collection device is supplied to the cultivation tank via the shortening path.

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