KR101370690B1 - Unattended control system capable of spraying pesticide in a state of nano-fog to get best control effects and preventing pesticide poisoning - Google Patents

Abstract

The present invention relates to a chemical sprayer with improved functions. Chemical-spraying time per one period, air cleaning time per one period, and water washing time are set by a timer. A chemical-supplying channel and an air-supplying channel for cleaning are opened and closed and the operation of an air compressor is controlled so the set chemical-spraying time per one period (t2) and the set air cleaning time per one period are alternately conducted for the total spraying time. If chemicals in a chemical case are exhausted out, the operation of a chemical sprayer is ceased even before a preset total spraying time (t1) is over. After finishing the spray of the chemicals, each spray nozzles is washed by pumping and supplying water to the nozzles. When spraying the chemicals, carbon dioxide and/or ozone can be supplied into an air-supplying channel for spraying and can be sprayed together. By connecting multiple chemical sprayers to one controller through control signal wires, the operation of the multiple chemical sprayers which are arranged in different areas in a vinyl green house can be simultaneously controlled.

Description

Unattended control system capable of spraying pesticide in a state of nano-fog to get best control effects and preventing pesticide poisoning}

The present invention relates to an unmanned control system capable of automatically spraying a chemical solution, and more particularly, to obtain the best control effect by spraying the drug in a nano-fog atomized state, and to prevent pesticide poisoning, and during the spraying of the chemical solution. After the completion of the cleaning process, to ensure the complete control and over-operation of the prepared chemical at the same time, it is related to the unmanned control system with a combination of several improvements, such as spraying carbon dioxide and the like.

In general, when growing crops in a large-scale plastic house or the like, spray the chemicals such as pesticides and nutrients at the appropriate time using a chemical sprayer to prevent pests from occurring in the crops and to supply proper nutrition to the crops. I am trying to. Most chemical liquid atomizers have a chemical liquid container for storing the chemical liquid for spraying, a spray nozzle for spraying the chemical liquid, and a chemical liquid supply pipe connected to the injection nozzle at one end thereof and extending into the chemical liquid container, and the chemical liquid stored in the chemical liquid container is sprayed through the chemical liquid supply pipe. It is configured to be supplied to the nozzle and sprayed.

However, after the spraying of the chemical solution, the remaining chemical liquid is present inside the chemical supply pipe and the injection nozzle, and the residual chemical liquid dries over time, blocking the chemical supply pipe or the injection nozzle, which greatly affects the subsequent use. Occurs. Therefore, in order to solve this problem, a simple washing method was used, but it was not a fundamental solution of the problem. In particular, in the case of the chemical liquid diluted in water, the chemical liquid powder blocked the injection nozzle due to the spray for a long time. This clogging problem of spray nozzles can occur during spraying, and thus cannot be solved by 'cleaning after use' alone.

When using a chemical sprayer, it is necessary to spray the chemical without leaving it. This is because the remaining chemical is dangerous or harmful to the environment, making it difficult to treat. Most existing chemical spray machines are configured to set the chemical spray time using a timer. However, if the amount of chemical liquid spraying time is insufficient compared to the amount of chemical liquid is left. To prevent such a problem, the user sets a sufficient time so that no chemical liquid remains. Then, complete control of the chemical liquid is possible, but there is a problem of excessive operation in which the chemical sprayer continues to operate for a long time even after all the chemical liquid is sprayed. It is most desirable to stop the operation of the chemical sprayer as soon as the spraying of all chemicals is completed.

When spraying a medicament into a plastic house, it is necessary to spray all over the house at once. If the area of the vinyl house is large, it must be sprayed using several chemical sprayers. Also, even in the case of a single-dong vinyl house, when spraying with a single chemical sprayer, it should be sprayed from one end to the opposite end. If so, the chemical is not easy to reach the opposite end. Does not pass evenly. This is because a strongly sprayed chemical liquid-containing air stream impinges on the opposite end of the chemical sprayer to form a stream of air toward the chemical sprayer. This is because it impedes the airflow from the chemical sprayer to the opposite end. Therefore, when spraying the single-dong vinyl house, two chemical sprayers are placed at one end and the middle point of the vinyl house, respectively, and sprayed at the same time. When operating several chemical sprayers at the same time, the user should not benefit from pesticide poisoning. However, when a plurality of chemical sprayer is distributed, there is a risk of pesticide poisoning because one has to go to operate the other chemical sprayer while the drug is sprayed in the chemical sprayer. In addition, the existing chemical liquid atomizer is a high price per unit is composed of mechanical components (spray nozzle, chemical liquid and air supply pipe, valves, pumps, etc.) and the control box for controlling their operation.

On the other hand, carbon dioxide (CO ₂ ) is a necessary element for photosynthesis of plants, and when sufficient amount of carbon dioxide is supplied to the crop, the leaf flesh becomes thick, the absorption of nutrients is improved, and the fruiting is easy due to the increase in the number of fruits and vegetables. It is known to increase the number of flowers and clarity, and to extend the life of cut flowers. It is known that early photosynthesis and quality can be improved by increasing the amount of photosynthesis, and the effects of reducing pests and reducing the amount of pesticides are known. The amount of CO ₂ required by plants for sufficient photosynthesis is known to be between 1,000 and 1500 ppm, and CO ₂ deficiency can cause delays in plant growth, deterioration of quality and yield reduction. Crops inside closed plastic houses consume much CO ₂ in a short time during photosynthesis. Therefore, it is necessary to supply CO ₂ effectively to crops in the greenhouse. Although devices supplying only CO ₂ are commercially available, they are expensive to purchase and maintain. If chemical spraying and chemical supply of CO ₂ can be combined, it can be greatly welcomed by farmers in terms of cost and work efficiency.

Ozone (O3) also has a sterilizing function against bacteria or fungi that are harmful to crops, so it may be desirable to supply an appropriate amount. It is also effective to inject this ozone into the plastic house together with chemical liquid spraying like carbon dioxide.

The present invention is to solve the above problems, one object of the present invention is to provide an unmanned control system configured to ensure the complete control of the chemical solution and the prevention of excessive operation of the sprayer at the same time.

Another object of the present invention is to provide an unmanned control system configured to allow simultaneous spraying of chemical liquid and supply of carbon dioxide (and ozone).

The present invention further can control a plurality of chemical sprayer with a single control unit when spraying a large plastic house at the same time with multiple sprayers, the unmanned control system is configured so that the user is not addicted to pesticides and reduced the unit price Another purpose is to provide.

Another object of the present invention is to provide an unmanned spray control system configured to automatically prevent washing during the spraying of the chemical liquid and after the end of spraying, thereby preventing the nozzle from being blocked by the drug.

It is another object of the present invention to provide an unmanned control system which can obtain the best control effect by spraying a drug in a nano-fog atomized state.

According to the present invention for achieving the above object, a chemical liquid supply pipe including at least one injection nozzle, and a chemical liquid supply pipe for supplying the chemical liquid of the chemical liquid container to the first inlet of each of the injection nozzles and a first valve for opening and closing the pipeline. And an air compressor for generating a high pressure air flow, an air supply pipe for supplying the high pressure air flow from the air compressor to the second inlet of each of the injection nozzles, and a second valve for opening and closing the pipeline; A chemical liquid sprayer including a supply air supply line for supplying a high pressure air stream from a compressor to each of the first inlets of the injection nozzles and a cleaning air supply line including a third valve for opening and closing the pipe; And first to third timers T1, T2, and T3 for setting a total spray time, a chemical spray time per cycle, and an air cleaning time per cycle, and a chemical liquid for detecting whether the chemical liquid remains in the chemical container. The residual sensor and the spraying of the chemical liquid and the air cleaning operation of the spray nozzle during the set total spraying time t1 are alternately made by the set chemical spraying time t2 and the set air cleaning time t3 per cycle. While controlling the opening and closing of the first to third valves and the driving of the air compressor, if the chemical liquid residual sensor provides a detection signal indicating that the chemical liquid in the liquid container is exhausted before the set total spraying time (t1) elapsed Even if there is provided an unmanned control system comprising a control unit including a controller for controlling the operation of the chemical spray, including the operation of the air compressor.

According to another feature of the present invention, the unmanned control system supplies a fourth timer (T4) that can set the water washing time, a pump for pumping the water in the bucket and the pumped water to the first inlet of each of the injection nozzles. It further includes a water supply pipe for cleaning including a water supply pipe. After the chemical liquid spraying is completed, the controller drives the pump for the set water washing time t4 and controls the first to third valves to be closed so that the pumped water is supplied to each of the spray nozzles to supply each spray nozzle. Control to wash as it passes.

According to another feature of the invention, the unmanned control system is connected to the carbon dioxide generator for generating carbon dioxide, and the carbon dioxide generator to any point to the spraying air supply pipe so that the carbon dioxide is introduced into the spraying air supply pipe to the CO ₂ to be delivered to each injection nozzle It is preferable to further provide a supply pipe.

According to another feature of the present invention, the unmanned control system is connected to the ozone generator for generating ozone, and the ozone generator to any point to the spray supply pipe to the ozone is injected into the spray supply pipe to the injection It is preferable to further provide an ozone supply pipe to be delivered to each nozzle.

According to another feature of the present invention, the control unit and the chemical sprayer is mechanically separated, but electrically controlled by a plurality of the chemical sprayer is connected to one of the control unit by a control signal line, one control unit vinyl It is preferable that it is comprised so that the operation | movement of the some chemical liquid atomizer respectively arrange | positioned in the different position in a house can be controlled simultaneously.

According to another feature of the present invention, the unmanned control system is branched from the spray air supply pipe extending to the inside of the chemical liquid container, a high-pressure air flow is supplied into the chemical liquid when spraying the chemical liquid to the stirring supply pipe to be stirred the chemical liquid It is preferable to further provide.

According to another feature of the invention, the first valve is a check valve, the second and the third valve is a solenoid valve which is controlled to open and close by a control signal provided by the controller, the second valve is open and the While the third valve is closed, the first valve is automatically opened to simultaneously spray airflow and chemical liquid into each of the injection nozzles, and the first valve is automatically opened while the second valve is closed and the third valve is open. It is preferable that only the air stream for cleaning is supplied to each of the injection nozzles.

According to another feature of the invention, the at least one injection nozzle comprises a plurality of injection nozzles are arranged at the top and the other part of the lower part, the injection direction of the injection nozzles disposed at the bottom is arranged at the top It is preferable that the spraying chemicals coming out from the upper injection nozzle and the lower injection nozzle collide with each other and are sprayed in a microparticulated state while crossing each other upwards than the spraying direction of the injection nozzle. In this case, the unmanned spray control system further includes a spraying duct for guiding the spraying of the spraying chemical liquid while surrounding the outlets of the plurality of spraying nozzles. It is preferable that the chemical liquid recovery hole is installed higher than the inside of the bottom and is connected to the chemical liquid container, and the chemical liquid condensed and dropped in the spray duct is recovered to the chemical liquid container through the chemical liquid recovery hole.

The unmanned spray control system according to the present invention automatically detects when all of the chemical liquid is injected to stop the chemical liquid spraying operation. Therefore, it is possible to ensure the complete control of the chemical solution and prevention of excessive operation of the sprayer at the same time.

According to the present invention, when spraying the chemical liquid can be sprayed with a mixture of carbon dioxide. There is no need to provide separate equipment for supplying carbon dioxide, and it is possible to save the effort of separate work for supplying carbon dioxide. Furthermore, ozone, which has a sterilizing action, can also be sprayed with the chemical liquid.

In addition, since a plurality of chemical sprayer can be operated by one control unit, the user can operate the chemical sprayer by operating the control unit disposed in a safe place, so that the unmanned control system can be operated without being poisoned by sprayed pesticides. In addition, since several chemical liquid nebulizers share a control unit, the unit cost of the unmanned spray control system can be lowered.

Furthermore, the chemical sprayer according to the present invention is performed alternately with chemical spray and air cleaning to prevent the injection nozzle is blocked during chemical cleaning. In addition, when the cleaning of the chemical solution is finished, it is possible to prevent the injection nozzles from being clogged by the water and the injection nozzles are damaged by the toxicity of the drug by thoroughly cleaning the injection nozzles with water.

The sprayed chemical liquids collide with each other to be sprayed in a mist state of a very small chemical liquid mass, and the chemical liquid condensed and dropped during the spraying process may be recovered into the chemical liquid container to prevent contamination of the surrounding soil by the chemical liquid. In addition, by configuring the spray duct in a removable type, there is also an advantage that can easily wash the spray duct.

1 is a block diagram schematically showing the conceptual configuration of an unmanned control system according to the present invention,
Figure 2 is a front perspective view showing an 8-nozzle type unmanned control system according to a preferred embodiment of the present invention,
Figure 3 is a front view showing an 8-nozzle type unmanned control system according to a preferred embodiment of the present invention,
Figure 4 is a perspective view showing an 8-nozzle type unmanned control system according to a preferred embodiment of the present invention,
Figure 5 is a flow chart briefly showing the entire operating procedure of the 8-nozzle type unmanned control system according to an embodiment of the present invention,
Figure 6 is a flow chart showing a chemical liquid spraying procedure of the 8-nozzle type unmanned control system according to a preferred embodiment of the present invention,
7 is a flowchart illustrating a water washing procedure after spraying a chemical solution of an 8-nozzle type unmanned control system according to a preferred embodiment of the present invention;
Figure 8 is a perspective view showing the overall configuration of the four-nozzle type unmanned control system according to another embodiment of the present invention with the case open;
9 illustrates a case where two unmanned control systems are operated by one control unit.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

1 is a block diagram schematically showing a conceptual configuration of an unmanned control system 100 according to the present invention. Unmanned control system 100 is largely composed of a sprayer 105 that performs the operation of spraying the chemical solution and washing itself and a control unit 110 for controlling the operation of the sprayer 105.

The nebulizer 105 includes chemical liquid supply passages 137, 140, 142, and 152 for supplying chemical liquid to the injection nozzle 150. The check valve 140 is disposed between the chemical liquid supply pipe 137 and the chemical liquid supply pipes 142 and 152 connected to the injection nozzle 150 to the bottom of the chemical liquid container 130 containing the chemical liquid. A sieve 132 may be connected to the inlet of the chemical supply pipe 137. The strainer 132 blocks debris in the chemical solution from flowing into the chemical liquid supply pipe 137, 140, 142, 152.

The nebulizer 105 also includes spraying air supply passages 162, 170, 172, and 154 for supplying a fast and strong airflow to the spray nozzle 150 to provide pressure for spraying the chemical liquid. The air supply pipe 162, one end of which is connected to the air compressor 160 for generating a high pressure air stream, the other end thereof is connected to the first solenoid valve 170, and the air supply pipe 172 connected to the outlet of the first solenoid valve 170. ) Is branched into the number of air supply pipes 154 as many as the number of injection nozzles 150 and connected to the injection nozzles 150 to form the air supply air supply passages 162, 170, 172, and 154. While the solenoid valve 170 is open, the airflow is supplied to the injection nozzle 150 through the air supply line 162, 170, 172, and 154 to spray the chemical liquid.

The spray nozzle 150 may use a spray nozzle of the spray type. The chemical liquid supply pipe 152 and the air supply pipe 154 are connected to both inlets of the injection nozzle 150. The high pressure high speed air flows in through the inlet of the injection nozzle 150 and exits to the outlet, and the chemical liquid flows in through the other inlet, mixes with the air flow, and sprays the same outlet. That is, the high pressure air generated by the air compressor 160 is supplied to the injection nozzle 150 through the air supply pipe 154 while the first solenoid valve 170 is opened, and the center and the inner circumference of the injection nozzle 150 are provided. By forming the air flow quickly exits through, and by the negative pressure generated by the air flow is sucked into the injection nozzle 150, the chemical liquid of the chemical liquid container 130 is sucked into the chemical liquid supply passage (137, 140, 142, 152) The spray nozzle 150 is sprayed at high pressure through the injection nozzle 150 while being mixed with the airflow flowing through the air supply pipe 154. Thereby, the chemical liquid is sprayed in the form of a very fine chemical liquid mass, i.e., a dense fog, and spreads forward.

If the chemical liquid spray is continued for a long time, the drug particles may accumulate in the injection nozzle 150 may cause a problem of blocking the injection nozzle 150. In order to prevent this problem, the present invention introduces an air washing process for washing the injection nozzle 150 with air in the middle of chemical liquid spraying. Chemical spraying and air cleaning may be carried out by alternately performing, for example, 15 minutes and 15 seconds.

To this end, the nebulizer 105 includes a washing air supply line 164, 175, 177, 152 for supplying a washing air stream to the injection nozzle 150. One end of the air supply pipe 164 is connected to the air compressor 160, the other end is connected to the solenoid valve 175, the one end of the air supply pipe 177 is connected to the solenoid valve 175, and the other end is the chemical liquid supply pipe 152. Is connected to form a washing air supply passage (164, 175, 177, 152). While the solenoid valve 175 is open, a strong air flow is supplied to the chemical liquid supply pipe 152 of the injection nozzle 150 through the cleaning air supply line 164, 175, 177, and 152, whereby the injection nozzle 150 Accumulated such as medicine accumulated in the washing is washed out of the injection nozzle (150).

The unmanned spray control system 100 of the present invention performs a process of cleanly spraying the spray nozzle 150 and the chemical supply pipe 152 with water after spraying all of the predetermined chemical solution. To this end, the nebulizer 105 further includes a washing water supply line 192, 190, and 152 in which the high pressure pump 190 is mounted in the middle. The inlet side water supply pipe 192 of the high pressure pump 190 extends to the bottom of the washing bucket 180, and the outlet side water supply pipe 192 of the high pressure pump 190 is connected to the chemical liquid supply pipe 152. While the high pressure pump 190 is operated, the water in the washing bucket 180 is supplied to the injection nozzle 150 through the washing water supply lines 192, 190, and 152 at high pressure, whereby the chemical liquid supply pipe 152 and The residue left in the injection nozzle 150 is washed with water to exit the injection nozzle 150.

The stirring air supply pipe 178 branched from the air supply pipe 172 and extended into the chemical liquid container 130 may be further provided. When the chemical liquid is sprayed, the chemical liquid flows by the air stream ejected into the chemical liquid through the agitation feed pipe 178, so that the chemical powder may be kept evenly mixed without being precipitated in water. For efficient stirring, for example, the rotor blade and the stirrer 139 may be further provided at the outlet of the stirring air supply pipe 178.

In addition, it is preferable that a control mechanism for spraying the chemical liquid of the chemical liquid container 130 without leaving and stopping the operation of the unmanned control system 100 immediately after all the chemical liquid is sprayed. To this end, a chemical liquid residual sensor for detecting whether the chemical liquid to be sprayed in the chemical liquid container 130 is introduced, and the detection signal of the chemical liquid residual sensor is provided to the controller 120. As the chemical liquid residual sensor, for example, a flow rate sensor 135-1 which is installed in the chemical liquid supply pipe and detects whether the chemical liquid flows into the pipeline may determine whether the chemical liquid of the chemical liquid container 130 remains. The flow rate sensor 135-1 is provided at any point in the chemical liquid supply passages 137, 140, 142 and 152. The flow rate sensor 135-1 outputs a signal d1 which detects the chemical liquid when the chemical liquid does not flow in the chemical liquid supply passages 137, 140, 142 and 152. Instead of the flow rate sensor 135-1, the water level sensor 135-2 may be used as the chemical liquid residual sensor. The water level sensor 135-2 is installed at the bottom of the chemical liquid container 130. The water level detection sensor 135-2 outputs a signal d2 detecting the state when the level of the chemical liquid in the chemical liquid container 130 is lowered to the bottom.

As mentioned above, it is preferable to spray carbon dioxide together while spraying the chemical liquid. To this end, the sprayer 105 is CO ₂ supply pipe connecting the CO ₂ supply pipe 202 is connected to the carbon dioxide generating unit 200 in an arbitrary point, for example tert engine 172 of (162, 172, 154) to the spraying-level organizations It includes more furnace. The controller 120 controls the carbon dioxide generator 200 to generate carbon dioxide while spraying the chemical liquid. The emitted carbon dioxide is supplied to each injection nozzle 150 in a state of being mixed with the airflow through the CO ₂ supply pipe 202 and the spray air supply passages 162, 172, and 154.

In order to be able to spray ozone (O ₃ ) together while spraying the chemical liquid, the nebulizer 105 carries the O ₃ supply pipe 212 connected to the ozone generator 210 into the air supply pipes 162, 172, and 154. It may further include an O ₃ supply line connected to an arbitrary point, such as the air supply pipe 172.

On the other hand, the control unit 110 for controlling the operation of the nebulizer 105, the total spray time (t1), chemical liquid spraying time (t2) per cycle, air cleaning time (t3), water washing time (t4) per cycle The timers 125 (T1, T2, T3, T4) that can be set, the set time (t1-t4) and the flow rate sensor 135-1 or the water level sensor 135-2 of these timers 125 The controller 120 controls the operation of the chemical nebulizer 105 on the basis of the detection signal d1 or d2 provided in the). Specifically, the controller 120 operates the first solenoid valve 170, the second solenoid valve 175, the high pressure pump 190, the air compressor 160, the carbon dioxide generator 200, and the ozone generator 210. The control signals s1, s2, s3, s4, s5 and s6 for controlling the signals are output to the corresponding components.

2 to 4 exemplarily illustrate the actual structure of the unmanned control system 100 provided with eight injection nozzles. In the drawings, like elements have been given the same reference numerals.

Two nozzle support 156 is fixed to the top of the sprayer body 300 up and down. Eight jet nozzles 150 are installed in each of the nozzle support 156, four in all, two upper and lower stages. In front of the injection nozzle 150, a spray duct 310 for guiding the chemical liquid spray flow is provided. The chemical liquid container 130 is disposed below the injection nozzle 150, and the bottom of the sprayer body 300 supports the chemical liquid container 130. Wheels 320 for movement are mounted on the bottom of the sprayer body 300. The check valve 140 is connected to the upper end of the chemical liquid supply pipe 137 immersed in the chemical liquid container 130, and the check valve 140 is branched into two chemical liquid supply pipes 142 from the outlet side. The chemical liquid supply pipe 142 is branched back into two chemical liquid supply pipes 152 through the branch connector 450. Thus, the chemical liquid exited through one chemical liquid supply pipe 137 is supplied to the left four injection nozzles 150. The other one chemical liquid supply pipe 137 on the right side of the drawing is branched to supply the chemical liquid to the right four injection nozzles 150 in the same form.

The spray duct 310 has an inner side surface 312 provided with openings for the injection nozzles 150 to extend the outlet, and an upper plate 314 and a lower plate 316 spaced apart from each other by extending forward from the upper and lower ends of the inner side. It is composed of a substantially rectangular cylindrical shape including), and the mist-like chemical liquid is sprayed out through the opening 316 between the upper plate 314 and the lower plate 316. However, the lower plate 316 is slightly inclined while being lifted up from the inner side 312 toward the opening 316. In addition, near the inner side 312 of the lower plate 316 is provided with a chemical recovery hole (not shown) that is open toward the chemical container 130. Some of the chemical solution of the nano-fog state spouted from the injection nozzle 150 is condensed and does not exit the opening 316 but falls to the lower plate 316 of the spray duct 310, and the condensed chemical liquid forms the lower plate 316. Ride down and is recovered to the chemical container 130 through the drug collection hole. Soil contamination can be reduced by increasing chemical recovery and reducing the amount of chemical falling into the surrounding soil.

The spray duct 310 is detachably coupled to the body 300. Therefore, there is an advantage that the spray duct 310 can be easily cleaned or washed.

The spray nozzles 150 are disposed to face the opening 316 through through holes (not shown) provided in the inner side 312 of the spray duct 310. In particular, it is preferable that the chemical liquids sprayed from each injection nozzle 150 are arranged to collide with each other. To this end, the injection nozzles 150 are arranged to form two rows up and down, and the injection nozzles 150 at the lower end of the injection nozzles 150 are arranged to be steeper upwards than the injection directions of the upper injection nozzles 150.

The chemical liquid spraying air supply pipe 172 connected to the first solenoid valve 170 connected to the air compressor 160 is branched into at least four air supply pipes 172 through the branch connector 410. Four branched air supply pipes 172 are each connected to four branch connectors 460 again. In addition, each branch connector 460 is branched back into two air supply pipes 154, and the two air supply pipes 154 are connected to a pair of injection nozzles 150 arranged up and down.

As a result, each of the eight injection nozzles 150 is connected with the chemical liquid supply pipes 137, 140, 142, and 152 and the spraying air supply pipes 162, 170, 172, and 154.

The stirring air supply pipe 178 may branch from the branch connector 410 and extend into the chemical liquid container 130. Although the flow rate sensor 135-1 is not shown, it is embedded at any point of the chemical liquid supply pipes 137, 140, 142, and 152 (in FIG. 2, it is shown as embedded in the chemical liquid supply pipe 137). . Instead, the water level sensor 135-2 may be installed on the bottom of the chemical container 130, of course.

In the air supply pipe passages 177 and 152 for air cleaning between chemical spray cycles, a second solenoid valve 175 is connected to the air compressor 160 through the air supply pipe 164. The air supply pipe 177 connected to the outlet of the second solenoid valve 175 is branched into four air supply pipes 177 through the branch connector 430. The four branch pipes 177 which are branched are connected to each of the four branch connectors 450 one by one. Each branch connector 450 is branched into two chemical liquid supply pipes 152 and connected to two injection nozzles 150, respectively. Therefore, each of the four branched air supply pipes 177 is connected to two chemical liquid supply pipes 152 and two injection nozzles through a branch connector 450. Therefore, the washing air flow paths 164, 175, 177, 152, can be sent to the eight chemical liquid supply pipe 152 and the eight injection nozzles (150).

The water washing bucket 180 is disposed outside the sprayer body 300. The water supply pipe 192 connected to the inlet side of the high pressure pump 190 extends to be immersed in the water tank 180, and the water supply pipe 192 connected to the outlet side is connected to the branch pipe 430 so as to supply four air supply pipes 177 for air cleaning. It is supposed to go through. Therefore, the washing water pumped from the high pressure pump 190 is supplied to the eight chemical solution supply pipes 152 and the eight injection nozzles 180 to perform a washing action.

Next, the operation of the unmanned control system 100 having such a configuration will be described with reference to the flowcharts of FIGS. 5 to 7.

First, the overall operation of the unmanned control system 100 will be described first with reference to the flowchart of FIG. 5. The user uses the timers T1 to T4 to total spray time t1 and chemical liquid spray time t2 per cycle. Set desired values for air cleaning time t3 and water washing time t4 per cycle. The controller 120 reads the set values of the timers T1 to T4 (step S10). Then, the chemical liquid is sprayed by the set time of the timer T2, that is, the chemical liquid spraying time t2 per cycle (step S12). Immediately after the time t2 has elapsed, the chemical liquid spraying mode is stopped, and the air compressor 160 is driven by the set time of the timer T3, that is, the air cleaning time t3 per cycle, to clean the injection nozzle 150 with a strong air flow. Perform the air cleaning mode (step S14). This chemical spraying mode and the air cleaning mode is controlled to be repeatedly performed alternately for the set time of the timer T1, that is, the total spraying time (t1) (step S16). Then, when the operation time of the unmanned control system 100 passes the total spray time (t1), the water washing mode is immediately performed (step S18). The water washing mode is performed during the water washing time t4 which is the set time of the timer T4.

The flowchart of FIG. 6 shows in more detail the control contents which alternately perform the chemical spraying mode and the air washing mode. The controller 120 reads the total spraying time t1 set using the timer T1 (step S20). Even if the total operation time of the unmanned control system 100 has not yet passed the total spraying time t1, if the chemical liquid to be sprayed is not left in the chemical container 130 (step S22), the chemical liquid spraying operation is terminated (step S36). ). The controller 120 may determine whether the chemical liquid to be sprayed is determined through the detection signal d1 provided by the flow rate sensor 135-1 or the detection signal d2 provided by the level sensor 135-2. Can be.

When the chemical liquid to be sprayed is left, the controller 120 provides the control signals s1 and s2 to the first solenoid valve 170 and the second solenoid valve 175 to open the first solenoid valve 170 while the first solenoid valve 170 is opened. 2 solenoid valve 175 is controlled to close. In addition, the control signal s4 for operating the air compressor 160 is provided. Then, the high pressure air stream from the air compressor 160 is sprayed through the respective injection nozzles 150 through the spray air supply passages 162, 170, 172, and 154. Accordingly, the check valve 140 is opened while the negative pressure is applied to the injection nozzle 150, and the chemical liquid of the chemical liquid container 130 is introduced into each injection nozzle 150 along the chemical liquid supply pipes 137, 140, 142, and 152. , While being mixed with the high pressure air flow in the injection nozzle 150 is converted into a mist state and sprayed (step S24).

The chemical liquids injected from the upper injection nozzles 150 and the lower injection nozzles 150 collide with each other and are pulverized so that the particles of the chemical liquid become smaller, and then the outlet 318 of the spray duct 310 is opened. Sprayed forward through. In order to allow the spray chemical to be sent far, the opening 318 is made narrower toward the end. As such, the sprayed chemical liquid collides with each other and the particles are finely pulverized and then discharged to the outside through the opening 318 of the spray duct 310, so that the particles of the chemical liquid can effectively reach a distant place. There is an advantage that can extend the coverage of the system 100.

In the chemical liquid spraying process, some of the chemical liquids injected from the injection nozzles 150 are not discharged to the outside and condensed with each other and fall or adhere to the inner side of the spraying duct 310 to be lowered. The chemical liquid condensed as described above is recovered to the chemical liquid container 130 through the chemical liquid recovery hole (not shown) provided near the inner side surface 312 along the lower plate 316 of the spray duct 310. By maximizing the recovery rate of the chemical liquid, there is an advantage that can prevent the chemical liquid from contaminating the soil to fall around the unmanned control system (100).

If necessary, the controller 120 may be driven by providing control signals S5 and S6 to the carbon dioxide generator 200 and / or the ozone generator 210 to spray the carbon dioxide and / or ozone together with the chemical liquid. .

This chemical liquid spray mode is to be continued for a chemical liquid spray time (t2) per cycle, which is the set value of the timer T2 (step S26). For this purpose, the controller 120 counts the spray time every cycle.

Then, the control to go to the air cleaning mode (step S28). The controller 120 provides the control signals s1 and s2 as opposed to the chemical spray mode while maintaining the operation of the air compressor 160 for the air cleaning mode, thereby closing the first solenoid valve 170 while 2 solenoid valve 175 is controlled to open. As the second solenoid valve 175 opens, the check valve 140 is closed by being pushed by the high pressure air stream. Accordingly, the high pressure air stream from the air compressor 160 is supplied to the injection nozzle 150 to the injection nozzle 150 through the cleaning air supply pipes 164, 175, 177, and 152 and accumulated in the injection nozzle 150. The chemical residue that may have been swept away.

This air cleaning mode is to be performed for the set time of the timer T3, that is, the air cleaning time (t3) per cycle (step S30). To this end, the controller 120 counts the cleaning time every cycle.

The controller 120 cumulatively counts the operation time while the chemical spraying mode and the air cleaning mode are performed. After the chemical spraying mode and the air cleaning mode of one cycle are performed, the controller 120 checks whether the accumulated accumulated operating time exceeds the set time of the timer T1, that is, the total spraying time t1. In order to perform the cycle, the process returns to step S22, and if exceeded, the spraying operation ends (step S34).

When the chemical spray operation is finished, the next operation is performed to wash the unmanned control system 100 with water. As shown in the flowchart of FIG. 7, the controller 120 controls the washing of all the spray nozzles 150 with water to be performed. Specifically, the controller 120 reads the water washing time t4 set by the timer T4 (step S40), and then the first solenoid valve 170 and the second solenoid valve with the control signals s1 and s2 for washing the water. Close the 175 and also drive the high-pressure pump 190 with the control signal (s3) (step S42). Then, the check valve 140 is also closed by the hydraulic pressure. In this state, when the high-pressure pump 190 is operated, the water in the bucket 180 is supplied only to each injection nozzle 150 through the water supply pipe passages 192, 190, and 152 for washing. The controller 120 accumulatively counts the water washing operation time and checks whether the set water washing time t4 is exceeded (step S44), and if so, terminates the water washing operation of the spray nozzle (step S46). By the water washing operation, all of the chemical liquid remaining in the injection nozzle 150 is washed out of the injection nozzle 150, and the inside of the injection nozzle 150 is in a clean state.

On the other hand, the unmanned control system according to the present invention can vary the number of injection nozzles as needed. For example, as shown in Figure 8, four injection nozzles 150 may be arranged in two stages up and down. The 4-nozzle type unmanned control system 400 only changes according to the change in the number of injection nozzles 150, and the basic configuration and operation of the unmanned control system 400 are described in the 8-nozzle type unmanned control system described above. Same as (100). In FIG. 8, the body 300 shows only the bottom to reveal the internal structure, and the controller 110 also shows only the front surface where the skeleton and the timers T1-T4 are arranged, and the controller 120 is not shown. .

9 illustrates a case where two chemical sprayers 500-1 and 500-2 are operated by one controller 510. The controller 510 and the timers T1 to T4 of FIG. 1 are installed in the control box to configure the controller 510. The controller 510 is connected to each chemical sprayer 500-1 and 500-2 and control signal lines 512 and 514. The controller 510, the chemical sprayer 500-1, and 500-2 exchange the detection signal d1 or d2 with the operation control signals S1-S6 through the control signal lines 512 and 514. . For example, the first chemical sprayer 500-1 is installed at the inlet of the vinyl house, the second chemical sprayer 500-2 is installed at the middle of the vinyl house, and the chemical spray direction is in the same direction, and the controller 510 is Install at the entrance or outside of the plastic house. The user can control the operation of the two chemical sprayers (500-1, 500-2) by operating the control unit 510 in a safe position, the user is free from pesticide poisoning. Of course, one control unit 510 can bite more chemical sprayer.

The above description of the present invention is merely a preferred embodiment of the present invention. Those skilled in the art can make various modifications and changes to the present invention without departing from the spirit and scope of the invention as set forth in the claims below. For example, the check valve 400 may be replaced with a valve for opening / closing a type that the controller 110 can control through a control signal. In addition, the solenoid valves 170 and 175 may also be replaced with other types of valves if the control unit 110 can open and close the pipeline through a control signal. In addition, it will be possible to install so that the washing bucket 180 is located inside the body 300. It is therefore intended that all changes which come within the meaning and range of equivalency of the claims are intended to be embraced therein.

100: unmanned control system 105: chemical liquid spray
110: control unit 120: controller
125: timer 130: chemical container
140: check valve 150: injection nozzle
160: air compressor 170: the first solenoid valve
175: second solenoid valve 178: agitating air supply pipe
180: washing bucket 190: high pressure pump
137, 140, 142, 152: chemical supply line
162, 170, 172, 154: spraying air supply
164, 175, 177, 152: for cleaning
192, 190, 152: water supply line for cleaning
200: carbon dioxide generator 210: ozone generator
500-1, 500-2: Chemical sprayer

Claims (9)

A chemical liquid supply pipe including at least one injection nozzle, a chemical liquid supply pipe for supplying the chemical liquid in the chemical liquid bottle to the first inlet of each of the injection nozzles, and a first valve for opening and closing the pipe, an air compressor for generating a high pressure air flow, and A spraying air supply path including a supply pipe for supplying the high pressure air flow from the air compressor to the second inlet of each of the injection nozzles, and a second valve for opening and closing the pipe; and the high pressure air flow from the air compressor for each of the injection nozzles. A chemical sprayer including a supply air supply line for supplying a first inlet and a third valve for opening and closing the pipe; And
First to third timers T1, T2 and T3, which can set the total spraying time, chemical spraying time per cycle, and air cleaning time per cycle, and the chemical liquid residue that detects whether the chemical liquid remains in the chemical container. The sensing sensor and the spraying of the chemical liquid and the air cleaning operation of the spray nozzle for the set total spraying time t1 are alternately performed by the set chemical spraying time t2 and the set air cleaning time t3 per cycle. While controlling the opening and closing of the first to third valves and the driving of the air compressor, if the chemical liquid residual sensor provides a detection signal indicating that all of the chemical liquid in the liquid container is exhausted, even before the set total spraying time (t1) has elapsed And a control unit including a controller for controlling the operation of the chemical liquid nebulizer including driving of the air compressor. The washing machine according to claim 1, further comprising a fourth timer T4 for setting a water washing time, a pump for pumping water from the bucket, and a water supply pipe for supplying the pumped water to the first inlets of the spray nozzles. It further has a water supply line,
After the chemical liquid spraying is completed, the controller drives the pump for the set water washing time t4 and controls the first to third valves to be closed so that the pumped water is supplied to each of the spray nozzles to supply each spray nozzle. Unmanned control system, characterized in that to control to wash while passing. The method of claim 1, wherein the carbon dioxide generator for generating carbon dioxide, and the carbon dioxide generator is connected to any point of the spray air supply pipe so that carbon dioxide is introduced into the spray air supply pipe to be delivered to each of the injection nozzles ₂ Unmanned control system further comprising a supply pipe. The ozone generator according to claim 1, wherein the ozone generator for generating ozone and the ozone generator are connected to any point of the spray air supply pipe so that ozone is introduced into the spray air supply pipe so that the ozone is delivered to each of the spray nozzles. Unmanned control system further comprising a supply pipe. According to claim 1, wherein the control unit and the chemical sprayer is mechanically separated, but electrically controlled by a plurality of the chemical sprayer is connected to one of the control unit by a control signal line, the other control unit in the plastic house Unmanned control system, characterized in that configured to be able to control the operation of the plurality of chemical sprayers respectively disposed in the position at the same time. The method of claim 1, wherein the branched branch from the spray air supply passage extending to the inside of the chemical container, when the chemical liquid spraying is further provided with a stirring air supply for supplying a high pressure air flow into the chemical liquid to stir the chemical liquid Control system. The valve of claim 1, wherein the first valve is a check valve, and the second and third valves are solenoid valves whose opening and closing are controlled by a control signal provided by the controller. While the valve is closed, the first valve is automatically opened to simultaneously spray airflow and chemical liquid into each of the injection nozzles, and while the second valve is closed and the third valve is open, the first valve is automatically closed. Unmanned control system, characterized in that only the cleaning air flow is supplied to each injection nozzle. The injection nozzle of claim 1, wherein the at least one injection nozzle comprises a plurality of injection nozzles disposed at an upper end thereof and partially disposed at a lower end thereof, and an injection direction of the injection nozzles disposed at the lower end thereof disposed at an upper end thereof. Unattended control system, characterized in that the spraying liquid from the injection nozzle of the upper and lower injection nozzles are sprayed in a micro-particle state while colliding with each other toward the direction more upward than the injection direction of the. The method of claim 8, further comprising a spraying duct for guiding the injection of the spraying chemical liquid while surrounding the outlet of the plurality of spray nozzles, the bottom of the spray duct is more than the inside of the plurality of spray nozzles are disposed Unmanned control system, characterized in that the installation is high and provided with a chemical liquid recovery hole through the bottom of the chemical liquid container, and the chemical liquid condensed and dropped in the spray duct is recovered to the chemical liquid container through the chemical liquid recovery hole.

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