JP5525223B2 - Diluted liquid fertilizer supply method - Google Patents

Description

  The present invention relates to a supply method in which liquid fertilizer is diluted to a predetermined magnification and mixed with water to form diluted liquid fertilizer, which is supplied to a plant.

The present inventor has developed a fertilizer supply device that mixes liquid fertilizer with water to form diluted liquid fertilizer and supplies this to plants. (See Patent Document 1)
The above supply device supplies water to the rear end of the discharge line with the water replenishment section, supplies liquid fertilizer to the discharge line with a liquid fertilizer pump to make diluted liquid fertilizer, and supplies the diluted liquid fertilizer to the irrigation tube through the discharge line Then, feed the crops with irrigation tubes. The irrigation tube is a tube provided with an infinite number of irrigation holes, and dilute fertilizer supplied from the rear end is irrigated to each crop at the same flow rate from each irrigation hole. The irrigation hole is a constant flow hole having a specific amount of drainage per unit time, and is a fine hole having a drainage amount of about 20 ml per minute, for example. Since the irrigation tubes are arranged along the ridges where the crops are planted, a plurality of irrigation tubes are provided in a field with a plurality of vines. In a field where a plurality of crops having different growth states and types are planted, a plurality of groups of irrigation tubes 91 are connected to the discharge line 92 as shown in FIG.

  The above supply device supplies a predetermined amount of diluted manure to the discharge line 92, transfers the diluted manure from the discharge line 92 to the irrigation tube 91, and irrigates the crop from the irrigation hole 97 of the irrigation tube 91. The supply device does not continuously supply dilute fertilizer but irrigates several times a day. The timing of irrigation is adjusted to an optimum state by the amount of solar radiation, the type of plant being planted, the moisture content of the medium, and the like, for example, irrigating at a rate of 1 to several tens of times a day.

  The above supply apparatus can adjust the supply amount of dilution liquid fertilizer and can water in an ideal state for various crops. However, there is a drawback that clogging of the irrigation tube that occurs with time cannot be resolved. In particular, since the irrigation tube is provided with a large number of very small irrigation holes, the irrigation holes tend to be clogged, and when clogged, there is a drawback that irrigation cannot be performed at the same flow rate from all the irrigation holes. If the irrigation hole of the irrigation tube is clogged, the amount of irrigation supplied to the crops changes, causing variations in growth, which makes it impossible to grow all crops in an ideal state. In particular, when an organic fertilizer preferable for crop growth is supplied, the irrigation hole of the irrigation tube tends to be clogged. Furthermore, the phosphoric acid contained in the fertilizer is combined with calcium and magnesium, which becomes a scale and easily adheres.

  By the way, in the liquid fertilizer supply apparatus, an apparatus for cleaning a part of a line pipe for supplying liquid fertilizer has been developed. (See Patent Document 2)

JP 2005-278415 A JP-A-9-28140

  The supply apparatus described in Patent Document 2 is shown in FIG. The apparatus shown in this figure has a chemical supply line 82 connected in the middle of the main pipe 81, and an automatic valve 84 for cleaning water connected to an appropriate position of the main pipe 81 downstream of the cleaning required part 80 of the chemical supply line 82. And a three-way selector valve 86 having a discharge channel 85 is provided on the upstream side of the cleaning-necessary portion 80, and the cleaning water automatic valve 84 and the three-way selector valve 86 are also controlled by the control device. 87. When the cleaning start time stored in advance in the program of the control device 87 is reached, the control device 87 opens the cleaning water automatic valve 84 provided in the branch flow path 83, and the flow path of the three-way switching valve 86 is connected to the discharge flow path 85 side. Switch to. The washing water 88 from the main pipe 81 is discharged from the branch flow path 83 through the cleaning required portion 80 and the discharge flow path 85. In this way, the cleaning required portion 80 is cleaned.

  Although the above apparatus can prevent clogging of a part of the supply line, there is a drawback that clogging of liquid fertilizer cannot prevent clogging of an irrigation tube particularly hindering crop growth.

  Furthermore, since the dilution liquid fertilizer supply device irrigates a large number of bottles with one unit, a plurality of groups of irrigation tubes are connected to a long discharge line. If it becomes this structure, the bad effect which cannot supply optimal dilution liquid manure to the irrigation tube of each group will also generate | occur | produce. For example, in a state where two groups of irrigation tubes for irrigating strawberries and cucumbers are connected to one discharge line, a part of the diluted fertilizer supplied to the strawberries remaining in the discharge line is irrigated to the cucumbers, On the other hand, a part of the diluted liquid fertilizer that irrigates the cucumber also has an adverse effect on the strawberry.

The present invention has been developed for the purpose of solving the above drawbacks. An important object of the present invention is to provide a method for supplying diluted liquid fertilizer that can effectively prevent clogging of distribution lines such as irrigation tubes and uniformly grow all crops in an ideal state.
In addition, another important object of the present invention is to supply a dilute fertilizer in an ideal state to each group distribution line, even when a plurality of group distribution lines are connected to the discharge line. It is in providing the supply method of the diluted liquid manure which can be grown in an ideal state.

Means for Solving the Problems and Effects of the Invention

Method for supplying dilution liquid fertilizer of the present invention is to supply a predetermined amount of diluting liquid fertilizer emissions line 2, after discharging the water of water discharge line 2 from the front end, to stop the waste water from the tip, the discharge line 2 The liquid fertilizer supplied to the distribution line 1 is supplied to the distribution line 1, the liquid fertilizer supply process for supplying the liquid dilution fertilizer to the crop with the distribution line 1, and after the liquid fertilizer supply process, water is supplied to the discharge line 2 and supplied. The dilute fertilizer of the discharge line 2 is transferred to the distribution line 1 with water, and further, the dilute fertilizer of the distribution line 1 is supplied to the crop, and the water filling process is performed to fill the distribution line 1 and the discharge line 2 with water. The dilute fertilizer is supplied to the crop by repeating the supply process and the water filling process .

  The above method effectively prevents clogging of the distribution line. For example, in a distribution line such as an irrigation tube provided with an infinite number of fine irrigation holes that are easily clogged, the clogging of these irrigation holes is prevented. It is characterized by uniformly irrigating from the irrigation holes and allowing all the planted plants to grow uniformly in an ideal state. This is because the above-described method for supplying diluted fertilizer fills both the discharge line and the distribution line with water without supplying the diluted fertilizer to the crop. In addition, since the distribution line filled with water drains the stored water and discharges the irrigation holes before discharging the diluted liquid fertilizer, the irrigation holes are washed each time the diluted liquid fertilizer is drained, effectively clogging. Is prevented.

  In addition, the above method supplies ideal dilute fertilizer to each distribution line even if multiple distribution lines are connected to a single discharge line, so that all crops are in an ideal state. There is a feature that can grow. After supplying dilute fertilizer to the crop from the distribution line, fill the discharge line and distribution line with water, and then supply dilute fertilizer to the crop, supply dilute fertilizer to the discharge line and distribute to the discharge line This is because the diluted fertilizer supplied to the discharge line can be supplied to the crop by draining the line water.

In the method of supplying diluted manure according to the present invention, a plurality of groups of distribution lines 1 are connected to the discharge line 2, a group of distribution lines 1 for supplying the diluted manure is selected from the discharge line 2, and the distribution lines 1 of each group are selected. The dilute fertilizer can be supplied separately.
According to the above method, all the crops can be grown in an ideal state by supplying an ideal dilute fertilizer to each group distribution line while connecting a plurality of group distribution lines to the discharge line.

In the method for supplying diluted liquid fertilizer of the present invention, a bactericidal agent can be added to the water filling the discharge line 2 and the distribution line 1 in the water filling step.
In the above method, after supplying the diluted liquid fertilizer, the discharge line and the distribution line can be sterilized with a disinfectant. For this reason, it is possible to prevent microorganisms from propagating on the discharge line and the distribution line, and to maintain a clean state. This prevents the microorganisms propagated on the inner surface of the discharge line and the distribution line, the irrigation holes, and the like from adhering, and can effectively prevent the distribution line from being clogged with the microorganisms.

In the method for supplying diluted liquid fertilizer of the present invention, a cleaning agent can be added to the water filling the discharge line 2 and the distribution line 1 in the water filling step.
In the above method, after supplying the diluted liquid fertilizer, the discharge line and the distribution line can be cleaned with the cleaning agent. For this reason, it can prevent that a foreign material adheres to the inner surface of a discharge line and a distribution line, and can maintain it in a beautiful state. This also prevents the scale from adhering to the inner surface of the discharge line and the distribution line, the irrigation holes, etc., and can effectively prevent the distribution line from being clogged.

The method for supplying diluted fertilizer according to the present invention detects the clogged state of the distribution line 1, detects that the distribution line 1 is in a predetermined clogged state, and fills the discharge line 2 and the distribution line 1 in the water filling process. Either or both of a disinfectant and a cleaning agent can be added to the base.
The above method detects the clogging of the distribution line and fills the discharge line and the distribution line with sterilized water or sterilized water, so the discharge line and the distribution line are always kept clean and the distribution line is clogged. Can be effectively prevented. Further, since the disinfectant and the cleaning agent are not always supplied to the discharge line and the distribution line, it is possible to reduce the amount of the disinfectant and the cleaning agent used and to prevent the distribution line from being clogged while reducing the running cost.

In the method for supplying diluted liquid fertilizer according to the present invention, the distribution line 1 is connected to the discharge line 2 via the on-off valve 8, and the drain valve 9 for draining the water of the discharge line 2 in the liquid fertilizer supply process The inspection process which inspects the operating state of the on-off valve 8 or the drain valve 9 can be provided as a pre-process of the liquid fertilizer supply process or a post-water filling process.
The above method can quickly detect an abnormal operation of the on-off valve and the drain valve in the inspection process, and can effectively prevent water and diluted fertilizer from being drained wastefully or being excessively sprinkled on the crop.

It is the schematic which shows an example of the fertilizer supply apparatus formed by connecting a plurality of groups of distribution lines to the discharge line. It is the schematic which shows the supply apparatus of the conventional liquid manure. It is a schematic block diagram of the dilution liquid fertilizer supply apparatus used for the dilution liquid fertilizer supply method concerning one Example of this invention. It is a schematic sectional drawing which shows the state which filled the distribution line of the several group of the supply apparatus shown in FIG. 3 with water. It is a schematic sectional drawing which shows the liquid fertilizer supply process which supplies dilution liquid fertilizer to the distribution line of a 1st group. It is a schematic sectional drawing which shows the liquid fertilizer supply process which supplies dilution liquid fertilizer to the distribution line of a 1st group. It is a schematic sectional drawing which shows the liquid fertilizer supply process which supplies dilution liquid fertilizer to the distribution line of a 1st group. It is a schematic sectional drawing which shows the liquid fertilizer supply process which supplies dilution liquid fertilizer to the distribution line of a 2nd group. It is a schematic sectional drawing which shows the liquid fertilizer supply process which supplies dilution liquid fertilizer to the distribution line of a 2nd group. It is a schematic sectional drawing which shows the liquid fertilizer supply process which supplies dilution liquid fertilizer to the distribution line of a 2nd group. It is a schematic sectional drawing which shows the liquid fertilizer supply process which supplies dilution liquid fertilizer to the distribution line of a 3rd group. It is a schematic sectional drawing which shows the liquid fertilizer supply process which supplies dilution liquid fertilizer to the distribution line of a 3rd group. It is a schematic sectional drawing which shows the liquid fertilizer supply process which supplies dilution liquid fertilizer to the distribution line of a 3rd group.

  Embodiments of the present invention will be described below with reference to the drawings. However, the Example shown below illustrates the supply method of the dilution liquid fertilizer for embodying the technical idea of this invention, Comprising: This invention does not specify the supply method of dilution liquid manure to the following method.

  Further, in this specification, in order to facilitate understanding of the scope of claims, numbers corresponding to the members shown in the examples are indicated in the “claims” and “means for solving problems” sections. It is added to the members. However, the members shown in the claims are not limited to the members in the embodiments.

  The dilute fertilizer supply device shown in FIG. 3 includes a discharge line 2 connecting a plurality of distribution lines 1 for irrigating a crop to the tip side, a water replenishment unit 3 for supplying water to the discharge line 2, and this The liquid fertilizer supply mechanism 4 that supplies liquid fertilizer of a predetermined concentration to the water supplied by the water replenishment unit 3 to form the diluted liquid manure, and the water replenishment unit 3 and the liquid fertilizer supply mechanism 4 are controlled, and the diluted liquid manure is supplied to the discharge line 2 And a control circuit 6 for supplying. In addition to the liquid fertilizer supply mechanism 4, the supply device of FIG. 3 includes a chemical liquid supply mechanism 5 that supplies a bactericide and a cleaning agent.

The distribution line 1 can be an irrigation tube having a large number of irrigation holes 7 at regular intervals. The distribution line 1 which is an irrigation tube has irrigation holes 7 having constant flow characteristics so that all crops can be irrigated at the same flow rate. As the distribution line 1, an irrigation tube having an irrigation hole 7 that can be irrigated at an optimum flow rate for a crop is selected and used. For example, in cultivation of strawberries and cucumbers, an irrigation tube is used in which the drainage flow rate of the irrigation hole 7 is 20 ml per minute.
However, the present invention does not specify the distribution line as the above structure. In the distribution line, instead of the irrigation holes having a constant flow rate characteristic, members that bleed out water and diluted liquid fertilizer with pressure can be arranged at predetermined intervals. In this distribution line, for example, a plurality of holes are provided at predetermined intervals in a pipe, and each hole is provided with a sponge-like or cloth-like irrigation section that exudes water or dilute fertilizer with pressure. This distribution line can also irrigate water and dilution liquid fertilizer supplied from the discharge line at an optimum flow rate for the crop. Further, the distribution line may be formed by connecting a plurality of elongated sub-pipes to a thick main pipe connected to the discharge line. This distribution line can be irrigated at an optimum flow rate by placing the tip of each sub-pipe branching from the main pipe at the root of the crop. Further, the distribution line may be a watering device such as a micro sprinkler. That is, the present invention can use various structures that can supply water and diluted liquid fertilizer supplied from the discharge line to the crop at an optimum flow rate as the distribution line.

  In the supply device of FIG. 3, four distribution lines 1 are connected at one end to form one group of distribution lines 1, and three groups of distribution lines 1 are connected to one discharge line 2. The distribution lines 1 of each group are connected to one end of the four distribution lines 1, and an on-off valve 8 is connected to the connection end, and the four distribution lines 1 are grouped into the discharge line via the on-off valve 8. 2 is connected. When one on-off valve 8 is opened, diluted fertilizer and water are supplied to the four distribution lines 1 that are connected to each other at one end. Opening and closing of each on-off valve 8 is controlled by the control circuit 6 and irrigated to the distribution line 1 of each group. Each distribution line 1 is arranged along each row of ridges and is arranged to irrigate one row of ridges with one distribution line 1. A supply device that connects three groups of distribution lines 1 to one discharge line 2 can irrigate crops of different sizes, that is, with different growth conditions, or different types of crops. Can be irrigated. However, the same size and type of crops may be planted in all culms and irrigated in the same way on the distribution lines of each group.

  The discharge line 2 has a rear end portion connected to the water replenishment portion 3 and the liquid fertilizer supply mechanism 4 and a front end portion connected to a drain valve 9 that drains the stored water. The discharge line 2 is long and uses a thick pipe having a diameter of 40 mm to 50 mm in order to reduce pressure loss, that is, to uniformly irrigate the plurality of distribution lines 1 at a predetermined flow rate. For the discharge line 2, a vinyl chloride pipe or a polyethylene pipe is used. The discharge line 2 is connected so as to connect one end of the distribution lines 1 arranged in a plurality of rows so as to supply water and diluted liquid fertilizer to each distribution line 1. The discharge line 2 connecting a large number of distribution lines 1 becomes longer and the internal volume becomes larger. For example, the discharge line 2 having a diameter of 40 mm stores about 125 liters of water at 100 meters. In the present invention, since water is stored in the discharge line 2 when the crop is not irrigated, it is necessary to discharge the water in the discharge line 2 when supplying the diluted fertilizer. In the discharge line 2 for storing 125 liters of water, the drain valve 9 is opened to drain 125 liters of water, and then the drain valve 9 is closed to supply the diluted liquid fertilizer to the distribution line 1.

  The water supply unit 3 includes a raw water tank 10, two pumps 11 and 12 that supply water from the raw water tank 10, and a water amount sensor 13 that detects a flow rate supplied by the pumps 11 and 12. The water supply unit 3 operates the two pumps 11 and 12 simultaneously to supply the water in the raw water tank 10 to the discharge line 2. The two pumps 11 and 12 are simultaneously stopped to stop supplying water. The water replenishment unit 3 operates the two pumps 11 and 12 in a state where the liquid fertilizer supply mechanism 4 does not supply liquid fertilizer, and supplies the water in the raw water tank 10 to the discharge line 2. Further, the water replenishment unit 3 supplies the liquid fertilizer between the two pumps 11 and 12 by the liquid fertilizer supply mechanism 4 while the two pumps 11 and 12 are operated, and is supplied by the liquid fertilizer supply mechanism 4. The liquid fertilizer is diluted and supplied to the discharge line 2 as a diluted liquid fertilizer. The pumps 11 and 12 of the water supply unit 3 are operated in a state in which water is supplied to the discharge line 2 and in a state in which diluted liquid fertilizer is supplied, and operation is stopped in a state in which water and diluted liquid fertilizer are not supplied.

  The water replenishment unit 3 that connects the two pumps 11 and 12 in series can use an inexpensive pump with a low head for the two pumps 11 and 12. Moreover, since the pressure between the two pumps 11 and 12 can be set to a low pressure of 1 atm or more, a diaphragm pump having check valves on the inflow side and the discharge side is used as the liquid manure pump 15 for supplying liquid manure. And liquid fertilizer can be injected accurately. However, the water replenishment unit does not necessarily need to use two pumps, and can suck water from the raw water tank and supply it to the discharge line with one pump.

  The water replenishment unit does not necessarily need to be provided with a pump and a raw water tank. For example, it is possible to use a raw water tank arranged at a higher position than the discharge line, or to use a water supply as a water supply unit. Raw water tanks and tap water replenishment units located at high places have water supply valves instead of pumps on the discharge side. This water supply valve is controlled by a control circuit to control the supply of water to the discharge line.

  The water amount sensor 13 detects the flow rate of the water supplied to the discharge line 2 by the water supply unit 3 and outputs it to the control circuit 6. The water amount sensor 13 outputs a flow rate pulse signal to the control circuit 6 every time a minimum measured amount of water passes. For this type of water amount sensor 13, a water meter that outputs one flow rate pulse signal each time passage of 10 to 150 ml of water is detected is optimal. However, as the water amount sensor 13, any device that can detect the flow rate of water and output a flow rate signal to the control circuit 6 can be used.

  The signal of the water amount sensor 13 is input to the control circuit 6, and the control circuit 6 detects the flow rate of water by the flow rate signal input from the water amount sensor 13. Furthermore, the control circuit 6 controls the liquid fertilizer pump 15 of the liquid fertilizer supply mechanism 4 based on the flow rate signal of the water amount sensor 13 so that the amount of fertilizer discharged from the electromagnetic metering pump that is the liquid fertilizer pump 15 becomes a predetermined dilution factor. To control.

  Further, the control circuit 9 detects from the flow rate signal input from the water amount sensor 13 whether the on-off valve 8 and the discharge valve 9 provided in the discharge line 1 are normally opened or closed. The control circuit 6 operates the pumps 11 and 12 for a short time (for example, for several seconds) with all the on-off valves 8 and the discharge valves 9 closed, and at this time, determines whether or not water flows into the discharge line 1. An abnormal operation of the on-off valve 8 or the discharge valve 9 is detected from the signal of the water amount sensor 13. This is because the amount of water flowing through the discharge line 1 becomes 0 when all the on-off valves 8 and the discharge valves 9 are closed. When the control circuit 9 detects an abnormality in the on-off valve 8 or the discharge valve 9, this is displayed to the outside.

  The liquid fertilizer supply mechanism 4 includes a plurality of liquid fertilizer tanks 14 that store liquid fertilizers of a predetermined concentration, and a liquid fertilizer pump 15 that supplies liquid fertilizers stored in the respective liquid fertilizer tanks 14 to the discharge line 2. The liquid fertilizer pump 15 is controlled by the control circuit 6 and supplies liquid fertilizer to the discharge line 2.

  The liquid fertilizer supply mechanism 4 shown in the figure includes three groups of liquid fertilizer tanks 14A, 14B, and 14C. However, the liquid fertilizer supply mechanism may be provided with one or two or four or more liquid fertilizer tanks. The liquid fertilizer tank 14 stores liquid fertilizer diluted with water at a predetermined magnification, for example, 10 times, or dissolves and stores powder or solid fertilizer in water. One or a plurality of fertilizers can be diluted and stored in the liquid fertilizer tank 14. The liquid fertilizer tank 14 shown in the figure is connected to the liquid fertilizer pump 15 via a foot valve 16 with a strainer so that the liquid fertilizer in the tank can be stably supplied.

  The liquid fertilizer pump 15 is controlled by the control circuit 6 to supply the fertilizer stored in the liquid fertilizer tanks 14A, 14B, and 14C to the discharge line 2 with a predetermined supply amount. The liquid manure pump 15 is an electromagnetic metering pump that is controlled by the control circuit 6 and discharges the liquid manure to the discharge line 2. The electromagnetic metering pump is a diaphragm pump. However, a piston pump or a plunger pump can be used instead of the diaphragm pump. These electromagnetic metering pumps discharge liquid fertilizer by reciprocating movement of a diaphragm, a piston, and the like. The control circuit 6 controls the number of times that the diaphragm or piston is reciprocated, that is, the number of strokes, thereby controlling the amount of liquid fertilizer supplied from the liquid fertilizer tank 14 to the discharge line 2, that is, the flow rate. An apparatus using an electromagnetic metering pump for the liquid fertilizer pump 15 can accurately supply the liquid fertilizer with the liquid fertilizer pump 15, and can accurately supply the liquid fertilizer over a long period of time with fewer failures. However, as the liquid fertilizer pump, all constant flow pumps that can supply liquid fertilizer at a predetermined flow rate can be used instead of the electromagnetic metering pump.

  The liquid fertilizer supply mechanism 4 shown in the figure connects three liquid fertilizer pumps 15A, 15B, and 15C to three groups of liquid fertilizer tanks 14A, 14B, and 14C separately. However, the supply device of the present invention is not shown, but the liquid manure pump can be connected to a plurality of liquid fertilizer tanks via a switching valve so that the number of liquid manure pumps is smaller than the number of liquid fertilizer tanks. The liquid fertilizer pump can switch a plurality of liquid fertilizer tanks to be connected by a switching valve and supply the liquid fertilizer of each liquid fertilizer tank to the discharge line.

  Similar to the liquid fertilizer supply mechanism 4, the chemical solution supply mechanism 5 includes a chemical solution tank 17 that stores a chemical solution having a predetermined concentration, and a chemical solution pump 18 that supplies the chemical solution stored in each chemical solution tank 17 to the discharge line 2. The chemical liquid pump 18 is controlled by the control circuit 6 to supply the chemical liquid to the discharge line 2.

  The chemical solution supply mechanism 5 shown in the figure includes two groups of chemical solution tanks 17A and 17B. One chemical solution tank 17A is filled with a bactericidal agent, and the other chemical solution tank 17B is filled with a cleaning agent. Hydrogen peroxide water can be used as a disinfectant, and an acid can be used as a cleaning agent. The hydrogen peroxide solution is diluted about 5000 times to 50000 times and supplied to the discharge line 2 to have a sterilizing action. Further, by adding a small amount of hydrogen peroxide solution, oxygen is supplied to the roots, and there is also a rooting promoting effect. Citric acid, malic acid, acetic acid or the like is used as the acid. The acid cleaning agent removes scales such as calcium and magnesium adhering to the discharge line 2 and the distribution line 1. The acid is diluted 200 to 500 times and added to the discharge line 2.

  The chemical solution supply mechanism 5 of FIG. 3 includes two chemical solution tanks 17A and 17B, since the sterilizing agent and the cleaning agent are supplied to the discharge line 2. The chemical solution tank 17 is specified by the number of chemical solutions supplied to the discharge line 2 and the distribution line 1. Therefore, in the apparatus that supplies only the bactericidal agent, one chemical liquid tank is provided.

  The chemical pump 18 is controlled by the control circuit 6 and supplies the chemical stored in the chemical tank 17 to the discharge line 2 with a predetermined supply amount. The chemical liquid pump 18 can be the same as the liquid fertilizer pump 15 used in the liquid fertilizer supply mechanism 4. The chemical liquid pump 18 is controlled by the control circuit 6 to control the supply amount of the chemical liquid supplied from the chemical liquid tank 17 to the discharge line 2, that is, the flow rate.

  The chemical solution supply mechanism 5 shown in the figure separately connects two chemical solution pumps 18A and 18B to two groups of chemical solution tanks 17A and 17B. However, although not shown, the chemical liquid pumps can be connected to a plurality of chemical liquid tanks via switching valves so that the number of chemical liquid pumps is smaller than the number of chemical liquid tanks. This chemical pump switches a plurality of chemical tanks to be connected with a switching valve, and supplies the chemical liquid in each chemical tank to the discharge line.

  In the above-described dilute fertilizer supply device, the water replenishment unit 3 supplies water from the raw water tank 10 to the discharge line 2. The water stored in the raw water tank 10 is not only tap water but also river water. Water for agriculture, irrigation, etc. can also be used. However, since river water, agricultural water, ponds, and the like are not sterilized like tap water, microorganisms may inhabit them, and rainwater may contain dirt components. Depending on the quality of the water used in this way, the distribution line is more likely to become clogged. 3 can supply the chemical | medical solution, such as a disinfectant and a washing | cleaning liquid, to the discharge line 2 from the chemical | medical solution supply mechanism 5, and since the discharge line 2 and the distribution line 1 can be sterilized and cleaned regularly, the distribution line 1 is It has the feature that it can effectively prevent the occurrence of harmful effects that clog up in a short period of time and unbalance the growth of crops.

  The control circuit 6 irrigates the crop with the diluted manure by the following method. The control circuit 6 supplies a fixed diluted drug solution from the discharge line 2 to the distribution line 1 at a rate of several times a day to irrigate the crop. The control circuit 6 is controlled by a timer or controlled by a solar radiation sensor that detects the solar radiation quantity, or is also controlled by a moisture sensor that detects the water content of the medium in which the crop is planted. The diluted chemical solution is supplied from the discharge line 2 to the distribution line 1.

  When the dilute fertilizer supply apparatus is first installed, it operates the two pumps 11 and 12 of the water replenishment unit 3 to fill the discharge line 2 and the distribution line 1 with water. At this time, the drain valve 9 is closed and the on-off valve 8 is opened to supply water from the discharge line 2 to the distribution line 1. 3 in which a plurality of groups of distribution lines 1 are connected to one discharge line 2, all drain valves 9 are closed, all on-off valves 8 are opened, and all distribution lines 1 are supplied with water. Meet. It is also possible to open each open / close valve 8 in turn, fill the distribution line 1 connected to the open open / close valve 8 with water, and fill all the distribution lines 1 with water. After filling the discharge line 2 and the distribution line 1 with water, the drain valve 9 and all the on-off valves 8 are closed and the operation of the two pumps 11 and 12 is stopped. This state is maintained until the timing when the diluted liquid fertilizer is supplied.

When it is time to supply the diluted liquid fertilizer to the crop, the control circuit 6 repeats the liquid fertilizer supply process and the water filling process to irrigate the crop with the diluted liquid fertilizer as described below. The state in which the control circuit 6 supplies water and dilute fertilizer and irrigates the crop is shown in FIGS.
4 to 7 show a state in which water and dilute liquid fertilizer are supplied to the first group distribution line 1 for irrigation, and FIGS. 8 to 10 show water and dilute liquid manure in the second group distribution line 1. FIG. 11 to FIG. 13 show the state of supplying water and dilute fertilizer to the third group distribution line 1 and irrigating, respectively. In these figures, however, water is indicated by chain line hatching, and diluted liquid fertilizer is indicated by solid line hatching.

[State of irrigation from the distribution line of the first group]
(1) Liquid fertilizer supply process At the beginning of this process, the discharge line 2 and the distribution line 1 are filled with water as shown in FIG. In this process, the control circuit 6 opens the drain valve 9 and closes all the on-off valves 8 to operate the two pumps 11 and 12 and the liquid manure pump 15 to supply the diluted liquid manure to the discharge line 2. In this process, since the diluted liquid manure is supplied to the distribution line 1 of the first group, the control circuit 6 supplies the diluted liquid manure optimal for irrigation to the crops grown in the first group to the discharge line 2. That is, the control circuit 6 controls the liquid fertilizer pump 15 of the liquid fertilizer supply mechanism 4 so that the type and concentration of the diluted liquid fertilizer supplied to the discharge line 2 are optimum for the first group of crops. As shown in FIG. 5, the diluted liquid fertilizer supplied to the discharge line 2 pushes out the water filling the discharge line 2 from the drain valve 9 and drains it to the outside. At the timing when the dilute liquid fertilizer is supplied to the position of the on-off valve 8A connecting the first group of distribution lines 1, which is the distribution line 1 that needs to be irrigated, the control circuit 6 Closes the drain valve 9 and opens the on-off valve 8A. Thereafter, as shown in FIG. 6, the diluted liquid fertilizer supplied to the discharge line 2 is supplied from the on-off valve 8A to the first group distribution line 1 and supplied from the irrigation holes 7 of the distribution line 1 to the first group crop. To do.

  The control circuit 6 is provided with a sensor for discriminating dilute liquid fertilizer and water in the vicinity of the on-off valve 8A, and the on-off valve 8A is opened by a signal from this sensor, and the dilute liquid manure is discharged from the discharge line 2 to the first group distribution line 1. Can be supplied. In addition, the control circuit 6 stores the amount of water charged upstream of the on-off valve 8A of the discharge line 2, detects that this amount of water has been supplied to the discharge line 2, and opens the on-off valve 8A. Thus, the diluted liquid fertilizer can be supplied to the distribution line 1 of the first group. The control circuit 6 detects the amount of water supplied to the discharge line 2 with the water amount sensor 13, and when the diluted liquid manure stored in the upstream of the on-off valve 8A is supplied, the on-off valve 8A is opened to open the dilute liquid manure. Is supplied to the distribution line 1 of the first group.

  After a predetermined amount of diluted liquid fertilizer for irrigating the first group of crops is supplied to the discharge line 2, the control circuit 6 stops the operation of the liquid fertilizer pump 15 and stops the supply of the diluted liquid fertilizer. In this state, the diluted liquid fertilizer remains in the discharge line 2 and the first group distribution line 1.

(2) Water filling process Following the liquid fertilizer supply process, the control circuit 6 supplies water to the discharge line 2 in this process, as shown in FIG. 7, and remains in the discharge line 2 in the previous process. The diluted liquid manure is pushed out to the distribution line 1 of the first group, and the distribution line 1 and the discharge line 2 of the first group are filled with water. That is, the on-off valve 8A connecting the distribution line 1 of the first group for irrigating the crop is kept open, and the two pumps 11 and 12 are operated to supply water to the discharge line 2, Diluted liquid manure remaining in the discharge line 2 with the supplied water is supplied to the distribution line 1 of the first group, and further pushed out from the distribution line 1 and supplied to the crops of the first group. After the water is filled up to the tip of the first group distribution line 1, the operation of the two pumps 11 and 12 is stopped and the on-off valve 8A is closed. The control circuit 6 has an internal volume upstream of the discharge line 2 with respect to the on-off valve 8A connecting the first grouping distribution line 1 that is irrigated, and the distribution line 1 connected to the on-off valve 8A. The sum of the internal volumes can be supplied to the discharge line 2 to fill the discharge line 2 and the first group distribution line 1 with water. Since the internal volume upstream of the on-off valve 8A of the discharge line 2 and the internal volume of the distribution line 1 of the first group are specific volumes, the control circuit 6 stores this volume. After detecting that the volume of water is supplied to the discharge line 2 by the water quantity sensor 13, the operation of the two pumps 11 and 12 is stopped, the on-off valve 8A is closed, and the supply of water is stopped.

In the above state, all the distribution lines 1 and the discharge lines 2 are filled with water. This state is maintained until the timing when the diluted liquid fertilizer is irrigated to the distribution line 1 of any group next time.
In addition, the irrigation of the diluted liquid fertilizer to the first group of crops is performed by repeating the steps (1) and (2) several times a day.

[State of irrigation from distribution line of second group]
(1) Liquid fertilizer supply process At the beginning of this process, the discharge line 2 and the distribution line 1 are filled with water as shown in FIG. In this process, the control circuit 6 opens the drain valve 9 and closes all the on-off valves 8 to operate the two pumps 11 and 12 and the liquid manure pump 15 to supply the diluted liquid manure to the discharge line 2. In this step, since the dilute liquid fertilizer is supplied to the distribution line 1 of the second group, the control circuit 6 supplies the dilute liquid fertilizer optimal for irrigation to the crops grown in the second group to the discharge line 2. That is, the control circuit 6 controls the liquid fertilizer pump 15 of the liquid fertilizer supply mechanism 4 so that the type and concentration of the diluted liquid fertilizer supplied to the discharge line 2 are optimal for the second group of crops. As shown in FIG. 8, the diluted liquid fertilizer supplied to the discharge line 2 pushes out the water filled in the discharge line 2 from the drain valve 9 and drains it to the outside. At the timing when the dilute liquid fertilizer is supplied to the position of the on-off valve 8B connecting the distribution line 1 of the second group, which is the distribution line 1 that needs to be irrigated, the water in the discharge line 2 is drained. Closes the drain valve 9 and opens the on-off valve 8B. Thereafter, as shown in FIG. 9, the diluted liquid fertilizer supplied to the discharge line 2 is supplied from the on-off valve 8B to the second group distribution line 1 and supplied from the irrigation hole 7 of the distribution line 1 to the second group crop. To do.

  The control circuit 6 is provided with a sensor for discriminating dilution liquid fertilizer and water in the vicinity of the on-off valve 8B. The control signal 6 opens the on-off valve 8B with a signal from this sensor, and the dilute liquid fertilizer from the discharge line 2 to the distribution line 1 of the second group. Can be supplied. Further, the control circuit 6 stores the amount of water charged upstream of the on-off valve 8B of the discharge line 2, detects that this amount of water has been supplied to the discharge line 2, and opens the on-off valve 8B. Thus, the diluted liquid fertilizer can be supplied to the distribution line 1 of the second group. The control circuit 6 detects the amount of water supplied to the discharge line 2 with a water amount sensor 13, and when the diluted liquid manure stored in the upstream of the on-off valve 8B is supplied, the on-off valve 8B is opened to open the dilute liquid manure. Is supplied to the distribution line 1 of the second group.

  After a predetermined amount of diluted liquid fertilizer for irrigating the second group of crops is supplied to the discharge line 2, the control circuit 6 stops the operation of the liquid fertilizer pump 15 and stops the supply of the diluted liquid fertilizer. In this state, diluted manure remains in the discharge line 2 and the distribution line 1 of the second group.

(2) Water filling process Following the liquid fertilizer supply process, the control circuit 6 supplies water to the discharge line 2 and remains in the discharge line 2 in the previous process, as shown in FIG. The dilute liquid fertilizer is pushed out to the distribution line 1 of the second group, and the distribution line 1 and the discharge line 2 of the second group are filled with water. That is, holding the on-off valve 8B connecting the distribution line 1 of the second group for irrigating the crop, the two pumps 11 and 12 are operated to supply water to the discharge line 2, Diluted liquid manure remaining in the discharge line 2 with the supplied water is supplied to the distribution line 1 of the second group, and further pushed out from the distribution line 1 and supplied to the crops of the second group. After the water is filled up to the tip of the second group distribution line 1, the operation of the two pumps 11 and 12 is stopped and the on-off valve 8B is closed. The control circuit 6 has an internal volume upstream of the discharge line 2 relative to the on-off valve 8B connecting the distribution line 1 of the second group being irrigated, and the distribution line 1 connected to the on-off valve 8B. The sum of the internal volumes can be supplied to the discharge line 2 to fill the discharge line 2 and the second group distribution line 1 with water. Since the internal volume upstream of the on-off valve 8B of the discharge line 2 and the internal volume of the distribution line 1 of the second group are specific volumes, the control circuit 6 stores this volume. After detecting that the volume of water is supplied to the discharge line 2, the water sensor 13 stops the operation of the two pumps 11 and 12, closes the on-off valve 8B, and stops the supply of water.

In the above state, all the distribution lines 1 and the discharge lines 2 are filled with water. This state is maintained until the timing when the diluted liquid fertilizer is irrigated to the distribution line 1 of any group next time.
In addition, irrigation of the dilute fertilizer to the second group of crops is performed by repeating steps (1) and (2) several times a day.

[State of irrigation from the third group distribution line]
(1) Liquid fertilizer supply process At the beginning of this process, the discharge line 2 and the distribution line 1 are filled with water as shown in FIG. In this process, the control circuit 6 opens the drain valve 9 and closes all the on-off valves 8 to operate the two pumps 11 and 12 and the liquid manure pump 15 to supply the diluted liquid manure to the discharge line 2. In this process, since the diluted liquid fertilizer is supplied to the distribution line 1 of the third group, the control circuit 6 supplies the diluted liquid fertilizer optimal for irrigation to the crop grown in the third group to the discharge line 2. That is, the control circuit 6 controls the liquid fertilizer pump 15 of the liquid fertilizer supply mechanism 4 so that the type and concentration of the diluted liquid fertilizer supplied to the discharge line 2 are optimal for the third group of crops. As shown in FIG. 11, the diluted liquid fertilizer supplied to the discharge line 2 pushes out water filled in the discharge line 2 from the drain valve 9 and drains it to the outside. At the timing when the dilute liquid fertilizer is supplied to the position of the on-off valve 8C connecting the third group distribution line 1 which is the distribution line 1 that needs to be irrigated, the control circuit 6 Closes the drain valve 9 and opens the on-off valve 8C. Thereafter, as shown in FIG. 12, the diluted liquid fertilizer supplied to the discharge line 2 is supplied from the on-off valve 8C to the third group distribution line 1 and supplied from the irrigation holes 7 of the distribution line 1 to the third group crop. To do.

  The control circuit 6 is provided with a sensor for discriminating dilution liquid fertilizer and water in the vicinity of the opening / closing valve 8C, and the opening / closing valve 8C is opened by the signal of this sensor, and the dilution liquid fertilizer is discharged from the discharge line 2 to the distribution line 1 of the third group. Can be supplied. Further, the control circuit 6 stores the amount of water charged upstream of the open / close valve 8C of the discharge line 2, detects that this amount of water has been supplied to the discharge line 2, and opens the open / close valve 8C. Thus, the diluted liquid fertilizer can be supplied to the distribution line 1 of the third group. The control circuit 6 detects the amount of water supplied to the discharge line 2 with the water amount sensor 13, and when the diluted liquid manure stored in the upstream of the on-off valve 8C is supplied, the on-off valve 8C is opened to open the dilute liquid manure. Is supplied to the distribution line 1 of the third group.

  After a predetermined amount of diluted liquid fertilizer for irrigating the third group of crops is supplied to the discharge line 2, the control circuit 6 stops the operation of the liquid fertilizer pump 15 and stops the supply of the diluted liquid fertilizer. In this state, the diluted liquid fertilizer remains in the discharge line 2 and the third group distribution line 1.

(2) Water filling process Following the liquid fertilizer supply process, the control circuit 6 supplies water to the discharge line 2 and remains in the discharge line 2 in the previous process, as shown in FIG. The diluted liquid manure is pushed out to the distribution line 1 of the third group, and the distribution line 1 and the discharge line 2 of the third group are filled with water. That is, holding the on-off valve 8C connecting the distribution line 1 of the third group for irrigating the crop, the two pumps 11 and 12 are operated to supply water to the discharge line 2, The diluted liquid manure remaining in the discharge line 2 with the supplied water is supplied to the distribution line 1 of the third group, and further pushed out from the distribution line 1 and supplied to the crops of the third group. After water is filled up to the tip of the third group distribution line 1, the operation of the two pumps 11 and 12 is stopped and the on-off valve 8C is closed. The control circuit 6 has an internal volume upstream of the discharge line 2 relative to the open / close valve 8C connecting the third group distribution line 1 that is irrigated, and the distribution line 1 connected to the open / close valve 8C. The sum of the internal volume of water can be supplied to the discharge line 2 to fill the discharge line 2 and the third group distribution line 1 with water. Since the internal volume upstream of the on-off valve 8C of the discharge line 2 and the internal volume of the distribution line 1 of the third group are specific volumes, the control circuit 6 stores this volume. After the water amount sensor 13 detects that the volume of water has been supplied to the discharge line 2, the operation of the two pumps 11 and 12 is stopped, the on-off valve 8C is closed, and the water supply is stopped.

In the above state, all the distribution lines 1 and the discharge lines 2 are filled with water. This state is maintained until the timing when the diluted liquid fertilizer is irrigated to the distribution line 1 of any group next time.
It should be noted that the irrigation of the dilute fertilizer to the third group of crops is performed by repeating steps (1) and (2) several times a day.

  Further, the control circuit 6 periodically adds a disinfectant and a cleaning agent to the water supplied to the discharge line 2 and the distribution line 1. The control circuit 6 adds, for example, a bactericide such as hydrogen peroxide water to the discharge line 2 and the distribution line 1 at a cycle of once every 5 days to 10 days. When a bactericidal agent such as hydrogen peroxide solution is added at the same time as the diluted liquid fertilizer, the effect as a fertilizer may be suppressed by oxidizing trace elements such as phosphoric acid and iron manganese contained in the liquid fertilizer. Therefore, the addition of a bactericide such as hydrogen peroxide is preferably performed during the water filling process after the liquid fertilizer supply process. Thus, by adding the hydrogen peroxide solution at the time of the water filling process after the liquid fertilizer supplying process, it is possible to effectively prevent the adverse effect of oxidizing and degrading the liquid fertilizer while enhancing the cleaning effect. Furthermore, when the water supply unit uses river water, agricultural water, water for ponds, etc., to prevent clogging of the distribution line, sterilization of hydrogen peroxide etc. once a day to once a day It is preferable to add the agent to water and supply it to the discharge line 2 and the distribution line 1. Moreover, in this case, you may increase trace elements, such as phosphoric acid added to water as liquid fertilizer. Furthermore, the control circuit 6 cleans the discharge line 2 and the distribution line 1 by adding a cleaning agent that is an acid to water at a rate of once every several tens of days to several months, for example. Since the cleaning agent that is an acid may adversely affect the growth if it is frequently supplied to the crop, it is preferable to add acid to the water supplied to the discharge line 2 and the distribution line 1 at the timing after the crop is harvested. And wash.

  Further, the control circuit 6 can detect a clogged state of the distribution line 1 and add a disinfectant or a cleaning agent to the water supplied to the discharge line 2 and the distribution line 1. The control circuit 6 can detect the clogged state of the distribution line 1 with the water amount sensor 13. That is, it is determined that the distribution line 1 is clogged when the flow rate per unit time detected by the water amount sensor 13 is smaller than the set value while the two pumps 11 and 12 are in operation. This is because when the distribution line 1 is clogged, the amount of drainage of the irrigation holes 7 decreases and the flow rate decreases. For example, in a device that operates two pumps 11 and 12 and can supply water at a flow rate of 20 liters / minute without clogging the distribution line 1, when the flow rate is reduced to 15 liters / minute, distribution is performed. It is determined that the line 1 is clogged. When the clogged state of the distribution line 1 is detected, the control circuit 6 adds a sterilizing agent and a cleaning agent to the water supplied to the discharge line 2 in the water filling process.

  The chemical solution supply mechanism 5 in FIG. 3 controls the operation of the chemical solution pump 18 by the control circuit 9 and adds a sterilizing agent and a cleaning agent to the water supplied to the discharge line 2. The control circuit 9 operates a chemical pump 18A connected to a chemical tank 17A filled with a sterilizing agent such as hydrogen peroxide solution to add the sterilizing agent to the water, and also fills with an acid cleaning agent. The chemical pump 18B connected to the chemical tank 17B is operated to add the cleaning agent to the water. When the discharge line 2 and the distribution line 1 are filled with water in the water filling process, the control circuit 6 stops the operation of the chemical pump 18.

  Furthermore, the supply method of the present invention can be provided with an inspection step for inspecting whether the on-off valve 8 and the discharge valve 9 are operating normally. In this inspection process, for example, the control circuit 9 operates the pumps 11 and 12 for several seconds with all the on-off valves 8 and the discharge valves 9 closed, and the on-off valves 8 or the discharge from the signal of the water amount sensor 13 at this time. An abnormality of the valve 9 is detected. When all the on-off valves 8 and the discharge valves 9 are closed and water flows into the discharge line 1, it is determined that any of the valves is not closed, and this is warned to the outside, or While displaying on the outside, the operation of the pumps 11 and 12 is stopped. As described above, the inspection process for inspecting the abnormality of the on-off valve 8 and the discharge valve 9 is preferably performed as a process before and after the irrigation of the diluted liquid manure to the crops of each group, that is, the supply of the liquid manure to the distribution lines of each group. It is performed as a pre-process of the process and a post-process of the water filling process. Thereby, the operation abnormality of the on-off valve 8 which is a connection part of the distribution line and discharge line of each group can be detected quickly.

  In the above-described method for supplying diluted liquid fertilizer, after the diluted liquid fertilizer is irrigated to the crop in the liquid fertilizer supplying process, the discharge line 2 and the distribution line 1 are filled with water in the water filling process. Here, the water filled in the discharge line 2 may be adversely affected by the outside world depending on the environment, season, and the like in which the discharge line 2 is installed. For example, under the hot summer sun, the piping that becomes the discharge line 2 is heated by direct sunlight, and the temperature of the water filled in the discharge line 2 may become high (for example, 40 ° C. or more). Irrigation of crops with such high-temperature water may have adverse effects such as damaging the crops or slowing growth. In the liquid fertilizer supply method of the present invention, in the liquid fertilizer supply process, first, the drain valves 9 are opened with all the on-off valves 8 closed, the diluted liquid fertilizer is supplied to the discharge line 2, and the discharge line 2 is filled. Since the drained water is pushed out from the drain valve 9 and drained to the outside, the water heated to a high temperature in the discharge line 2 is not irrigated by the crop, and it is also possible to effectively prevent the crop from being adversely affected. .

  Further, in the method for supplying diluted liquid fertilizer according to the present invention, the discharge line 2 and the distribution line 1 are always filled with water except when the diluted liquid fertilizer is supplied. Is not kept for a long time. Therefore, it is ensured that the liquid fertilizer remaining in the discharge line and the distribution line is deteriorated by being heated to high temperature by direct sunlight and the altered liquid fertilizer is irrigated to the crop as in the past. There are also features that can be prevented.

DESCRIPTION OF SYMBOLS 1 ... Distribution line 2 ... Discharge line 3 ... Water supply part 4 ... Liquid fertilizer supply mechanism 5 ... Chemical solution supply mechanism 6 ... Control circuit 7 ... Irrigation hole 8 ... Open / close valve 8A ... Open / close valve
8B ... Open / close valve
8C ... Open / close valve 9 ... Drain valve 10 ... Raw water tank 11 ... Pump 12 ... Pump 13 ... Water volume sensor 14 ... Liquid fertilizer tank 14A ... Liquid fertilizer tank
14B ... Liquid fertilizer tank
14C ... Liquid fertilizer tank 15 ... Fertilizer pump 15A ... Liquid fertilizer pump
15B ... Liquid fertilizer pump
15C ... Liquid fertilizer pump 16 ... Foot valve with strainer 17 ... Chemical tank 17A ... Chemical tank
17B ... Chemical liquid tank 18 ... Chemical liquid pump 18A ... Chemical liquid pump
18B ... Chemical pump 80 ... Necessary portion for washing 81 ... Main pipe 82 ... Chemical solution supply line 83 ... Branch flow passage 84 ... Automatic valve for washing water 85 ... Discharge flow passage 86 ... Three-way switching valve 87 ... Control device 88 ... Washing water 91 ... Irrigation Tube 92 ... Discharge line 97 ... Irrigation hole

Claims (6)

Supplying a predetermined amount of diluting liquid fertilizer emissions line (2), after discharge of water of water discharge line (2) from the tip, to stop the waste water from the tip of the discharge line (2), the discharge line Supplying the diluted liquid fertilizer supplied to (2) to the distribution line (1), and supplying the diluted liquid fertilizer to the crop with the distribution line (1);
After the liquid fertilizer supply step, water is supplied to the discharge line (2) to transfer the diluted liquid fertilizer in the discharge line (2) to the distribution line (1), and further diluted in the distribution line (1). the liquid fertilizer is supplied to the crop, become dispensing line (1) and the discharge line (2) from the water filling the filling step with water,
A method for supplying diluted liquid fertilizer, wherein the liquid fertilizer supplying process and the water filling process are repeated to supply diluted liquid fertilizer to a crop.   A plurality of group distribution lines (1) are connected to the discharge line (2), a group of distribution lines (1) for supplying diluted liquid fertilizer from the discharge line (2) is selected, and each group distribution line (1) The method for supplying diluted liquid fertilizer according to claim 1, wherein the diluted liquid fertilizer is supplied separately.   The method for supplying diluted liquid fertilizer according to claim 1 or 2, wherein a fungicide is added to water filling the discharge line (2) and the distribution line (1) in the water filling step. The method for supplying diluted liquid fertilizer according to any one of claims 1 to 3, wherein in the water filling step, a cleaning agent is added to the water filling the discharge line (2) and the distribution line (1).   Detecting the clogged state of the distribution line (1), detecting that the distribution line (1) is in a predetermined clogged state, and filling the discharge line (2) and the distribution line (1) in the water filling process The method for supplying diluted fertilizer according to claim 3 or 4, wherein either or both of a disinfectant and a cleaning agent are added to the liquid.   The distribution line (1) is connected to the discharge line (2) through an on-off valve (8), and a drain valve (9) for draining water from the discharge line (2) is discharged in the liquid fertilizer supply process. Provided at the tip of the line (2), as a pre-process of the liquid fertilizer supply process or a post-process of the water filling process, an inspection process for inspecting the operating state of the on-off valve (8) or the drain valve (9) The method for supplying diluted liquid fertilizer according to claim 1 or 2 provided.

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