KR101873599B1 - Simple sprayer - Google Patents

Abstract

There is a demand for a liver transplantation atomizer capable of further continuing the spraying operation even when a battery charged with electric power is used.
The liver transplantation atomizer 1 includes a hand drag type cart body 4 having at least one wheel 8, a liquid medicine tank 14 and a diluent liquid tank 15 mounted on the cart body 4, A pump for pumping up the diluted solution in the chemical liquid in the tank 15 and the diluting liquid in the diluting liquid tank 14 and a diluting liquid from the diluting liquid tank 14 are mixed with the chemical liquid from the chemical liquid tank 15, A mixer, a spray nozzle 50 for spraying the mixed liquid discharged from the pump, a solar battery panel 5 for converting solar energy into electric power, a storage battery 5 for accumulating electric power from the solar battery panel 5 or an external power source, And a power supply device for supplying power from the solar cell panel 5 or the battery to the pump.

Description

{SIMPLE SPRAYER}

The present invention relates to a hand drag-type liver transplantation atomizer in which a liquid tank, a pump, a pump driving source, and a spray nozzle are mounted on a cart body running on a wheel.

Conventionally, as such a kind of atomizer, for example, one disclosed in Patent Document 1 below is known. The sprayer described in this document is equipped with a power unit for spraying, such as a prime mover and a pump, a spray liquid tank, and a spray nozzle, mounted on a mount portion of a hand drag type two-wheeled carriage body. In this sprayer, while holding the handle with one hand and dragging the cart body, a chemical solution such as herbicide is sprayed from the spray nozzle held by the other hand.

Japanese Patent Application Laid-Open No. 2010-100185

However, since the above-described conventional atomizer is equipped with a prime mover, there is no need to worry about consumption of the charged amount as in the case of using a battery. However, since prime movers are relatively heavy, it is considered unsuitable for working on farmland where slopes of mountains are steep.

Therefore, it is considered to drive the pump by using the charging power of the storage battery as a power source. However, since the charging capacity of the storage battery is limited, there is a fear that the spraying operation for a long time can not be performed. For this reason, it is desired that the spraying operation in the case of using the battery is further continued. On the other hand, there are places where it is not possible to drive a car in a mountainous area or farmland with severe slope.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a liver transplantation atomizer capable of further continuing a spraying operation even when a battery charged with electric power is used.

In order to achieve the above object, a liver transplantation atomizer according to the present invention is a liver transplantation atomizer comprising: a hand drag type cart body having at least one wheel; a chemical liquid tank and a diluent liquid tank mounted on the cart body; A mixer for mixing the chemical liquid from the chemical liquid tank and the diluting liquid from the diluting liquid tank and sucking the mixed liquid into the pump, a spray nozzle for spraying the mixed liquid discharged from the pump, A battery for accumulating electric power from the solar panel or an external power source, and a power supply for supplying electric power from the solar panel or the battery to the pump.

In the above arrangement, it is preferable that a cart unit is constituted of a cart body and a solar cell panel, and a spray unit is constituted from a chemical liquid tank, a diluting liquid tank, a pump, a mixer, a spray nozzle, a battery and a power supply device, And is detachably mounted on the cart unit.

In each of the above-described configurations, the solar cell panel is supported on the cart body by the up and down movement.

And an injector for sucking and sucking the chemical liquid in the chemical liquid tank and injecting a predetermined amount of the chemical liquid into the diluting liquid tank, wherein the injector includes a metering cylinder, A metering piston having a diameter larger than that of the metering cylinder and extending from the metering cylinder; and a metering piston extending from the metering piston, A first air passage for introducing the liquid into the chemical liquid in the chemical liquid tank and the other end connected to the opening of the metering cylinder and allowing the fluid to flow only in the direction toward the metering cylinder; A suction pipe having a check valve, And a second check valve which is connected to the chemical liquid tank and whose other end is connected to the chemical liquid tank and allows fluid to flow only in a direction toward the chemical liquid tank, and a second check valve which has one end connected to the opening of the metering cylinder and the other end connected to the diluent tank And a third check valve that allows fluid to flow only in a direction toward the diluent tank.

Further, in each of the above-described configurations, the chemical liquid tank is mounted on the back surface of the diluting liquid tank, which is the rear side in the direction in which the cart body is drawn, and the liquid input port formed in the upper portion of the chemical liquid tank, And is inclined rearward with respect to the back surface of the diluent tank by an angle which is a direction substantially perpendicular to the core.

Further, in each of the above-described configurations, a suction port is further attached to the front end of a channel in which one end is connected to the suction port side of the pump is formed at the front part of the bottom surface in the diluent tank, And the suction port is placed on the bottom surface in the diluent tank.

According to the liver transplantation atomizer of the present invention, since the solar cell is provided with a solar cell panel for converting solar energy into electric power, a battery, and a power supply device for supplying electric power from the solar cell panel or battery to the pump, The pump can be driven and sprayed from the spray nozzle. Accordingly, even when the electric power charged in the battery is consumed by the spraying operation and it becomes difficult to continue the operation, the spraying operation can be further continued by using electric power from the solar cell panel. Alternatively, in the case where the spraying operation is not performed, it is also possible to charge the storage battery with electric power from the solar cell panel in preparation for the next operation.

The fact that the spraying unit is detachably mounted on the cart unit allows the spraying unit to be taken out of the cart unit and used for the spraying operation so that even if the carriage of the cart unit is difficult or impossible to move, And the spraying operation is possible.

The reason why the solar cell panel is supported on the cart body by the up-and-down swinging material is that the solar cell panel is attached to the cart body in accordance with the vertical posture of the cart body, the inclined posture at the spraying operation, It is possible to make an appropriate angle for receiving sunlight by swinging up and down. This makes it possible to use solar energy efficiently and to perform various operations with ease.

In addition, in the case of having an injector for sucking the chemical liquid in the chemical liquid tank and injecting a predetermined amount of the chemical liquid sucked into the diluting liquid in the diluent tank, it is possible to accurately dilute a predetermined amount of the chemical liquid by mixing with the diluting liquid, A mixed liquid having an accurate dilution ratio can be obtained. As a result, even insecticides with a high helium multiplication factor can be appropriately used for spraying. In addition, there is no need to use a small-capacity measuring cup which tends to cause a mistake, and the labor of cleaning the cup after use can be reduced.

In addition, when the liquid transfer port of the chemical liquid tank is inclined backward by a predetermined angle, the chemical liquid can be easily injected into the chemical liquid tank from the liquid input port when the liver transplantation atomizer is erected. Further, during the spraying operation, even when the cap for sealing the liquid inlet is loosened, the chemical liquid does not leak out easily from the liquid inlet. Thus, it is possible to prevent the chemical liquid from overflowing during the spraying operation.

And when the liver transplantation atomizer tilts forward during spraying, the diluent tank is also tilted. In this case, since the front portion of the diluent tank is always in a low position, the lowest floor is the lowest among all the floor surfaces. Therefore, the additional inlet port attached to the tip of the pipeline is placed on the bottom surface in the diluent tank, since the inlet port with the additional port moves to its lowest position by its own weight, it always exists on the bottom floor. As a result, the diluent can be used for spraying without wasting to the end.

1 is an external view of a liver transplantation atomizer according to an embodiment of the present invention.
2 is a side cross-sectional view of the diluent tank and the chemical tank of the liver transplantation atomizer.
3 is a front sectional view of the diluent tank.
4 is an external view of the mixer of the liver transplantation atomizer.
5 is a schematic overall configuration diagram of the liver transplantation atomizer.
6 is a configuration diagram of the control system of the liver transplantation atomizer.
7 is a side view of the liver transplantation atomizer.
8 is a state explanatory diagram showing the state battery panel of the liver transplantation atomizer in a state of being oriented horizontally.
Fig. 9 is a use state explanatory diagram showing a state in which the chemical implantation is performed while the liver transplantation atomizer is manually dragged. Fig.
10 is a side cross-sectional view of the diluent tank and the chemical liquid tank at an oblique angle.
11 is a use state explanatory diagram showing a state in which a spray unit separated from the cart unit is used.
12 is an external view of the injector of the liver transplantation atomizer.
Fig. 13 is a side cross-sectional view showing the above-mentioned injector and its bag structure.
FIG. 14 is an explanatory view showing the operation of sucking the chemical liquid and the air into the metering cylinder and the air bleeding cylinder of the injector.
15 is an explanatory view showing an operation of returning a part of the sucked chemical liquid and the air to the chemical tank.
16 is an explanatory diagram showing the operation of dispensing the chemical liquid after metering with the metering cylinder to the diluent tank.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. The embodiments described below are merely examples embodying the present invention, and do not limit the technical scope of the present invention. FIG. 1 is a perspective view of a liver transplantation atomizer according to an embodiment of the present invention, FIG. 2 is a side sectional view of a diluent tank and a chemical liquid tank of the liver transplantation atomizer, FIG. 3 is a front sectional view of the diluent tank, FIG. 5 is a schematic overall configuration diagram of the liver transplantation atomizer, and FIG. 6 is a configuration diagram of the control system of the liver transplantation atomizer.

In each drawing, the liver transplantation atomizer 1 according to this embodiment includes a cart unit 2 in which a solar cell panel 5 for converting solar energy S into electric power is mounted on a cart body 4, , A spray nozzle (50), and the like. The atomizing unit 3 is provided with a control device 60 including a chemical liquid tank 15, a diluting liquid tank 14, a pump 46, a mixer 28, a spray nozzle 50 and a power supply 61, .

Vertical frames 11 and 11 are installed on the front end portions of the front and rear frames 9 and 9 disposed in parallel and the cart body 4 is mounted on the front and rear frames 9 and 9, ) Are installed vertically. The rear portions of the front and rear frames 9 and 9 are bent downward to form a connected leg 9A. Left and right side bearings 10, 10 are provided below the front and rear frames 9, 9. Two wheels 8 and 8 are pivotally supported on the vehicle bearings 10 and 10. [ At the upper end of the vertical frames (11, 11), a handle (12) for hand dragging is stuck. A diluent tank 14 is mounted on the upper surface of the mounting table 13 of the cart body 4. Receiving members 54 and 54 formed in a concave shape are fixed (fixed) by welding or the like in a posture protruding rearward at the upper and lower central lower portions of the left and right vertical frames 11 and 11 of the cart body 4 . Screws 55 and 55 corresponding to the female screw holes (not shown) formed on the left and right sides of the diluent tank 14 are mounted on the receiving members 54 and 54 of the cart body 4 as detent materials So that the atomizing unit 3 is detachably mounted on the cart unit 2.

The diluent tank 14 is a rectangular box-like container having a liquid inlet 16 on its upper surface and is adapted to store a diluent W (e.g., water). And a containment recess 26 is formed on the back surface of the dilution liquid tank 14. The drive portion 40 described later is accommodated in the accommodating concave portion 26 of the diluent tank 14 later. The liquid inlet (16) of the diluent tank (14) is sealed with a cap (17). The front left-right center portion at the bottom of the diluent tank 14 is the lowest lowest floor surface 19. On both left and right sides of the lowermost bottom surface 19, inclined bottom surfaces 20, 20 for collecting liquid are formed on the lowermost bottom surface 19. A liquid discharge port 18 is formed on the side surface near the lowermost bottom surface 19, and the liquid discharge port 18 is sealed by a cap in a normal state. Ribs 21, 21 are formed on the left and right upper end portions of the diluent tank 14. Each of the ribs 21 has a hook hole 22 for hooking a snap ring 68 (see FIG. 11) of the belt 69, which will be described later.

The chemical liquid tank 15 is a box-like container for storing a chemical liquid M (for example, an insecticide) with an liquid inlet 34 at the upper portion thereof. In most cases, the chemical liquid tank 15 has a smaller capacity than the diluent tank 14. The chemical liquid tank 15 is mounted on the back surface of the casing of the driving unit 40 accommodated in the accommodating concave portion 26 of the diluting liquid tank 14. The liquid input port 34 is arranged rearwardly at an angle of? With respect to the back surface 14A of the dilute liquid tank 14 which is the rear side of the direction in which the cart body 4 is pulled. This angle becomes an angle at which the chemical liquid M can easily be poured from the liquid inlet 34 when the liver transplantation atomizer 1 is erected (see Fig. 7), and the angle? 1) is tilted by hand, it is an angle (see FIG. 10) in which the center of gravity J of the liquid inlet port 34 is almost the direction of the vertical line K. This angle θ prevents the chemical liquid M from easily overflowing from the liquid inlet 34 even when the cap 35 for sealing the liquid inlet 34 is loosened.

In the side wall of the diluting liquid tank 14 in the containing recess 26, the relay tube portion 23 is disposed. Channels 24 and 24 are connected to both ends of the relay tube portion 23. At the tip of one of the channels 24, an additional suction port 25, which is placed on the bottommost bottom surface 19 of the diluent tank 14, is attached. The tip of the other channel 24 is connected to the diluent inlet channel 29 of the mixer 28 described later. A relay tube portion (38) is disposed through the sidewall of the chemical liquid tank (15) and the side wall of the casing of the driving portion (40). Channels 36 and 36 are connected to both ends of the relay tube portion 38. At the tip of one of the conduits 36, there is attached a suction port 37 which is additionally provided on the bottom surface of the chemical liquid tank 15. And the other end of the conduit 36 is connected to the drug inlet side conduit 31 of the mixer 28. One of these conduits 36, 36 is provided with, for example, an on-off valve 56 which is manually opened and closed.

The mixer 28 includes a main body casing casing 30 and a diluting liquid inlet side pipeline 29 branchably connected to the inlet side of the main casing 30 to introduce the diluting liquid W in the diluting liquid tank 14, A chemical solution inlet side pipeline 31 branched and connected to the inlet side of the casing 30 for introducing the chemical solution M in the chemical solution tank 15 and a liquid outlet side pipeline 32 connected to the outlet side of the main body casing 30 ). The liquid outlet side conduit 32 is connected to the suction port side of the pump 46 via the conduit 45. The diluent inlet side conduit 29 and the chemical liquid inlet side conduit 31 are each divisible, and each divided portion is detachably connected by caps 33, 33. A check valve 42 and an orifice 41 are disposed in the diluent inlet side conduit 29 for allowing fluid to flow only toward the pump 46. A check valve 44 is provided in the chemical liquid inlet conduit 31 for permitting only fluid to flow toward the pump 46 and an orifice 44 having an orifice 41 having a diameter smaller than the hole diameter? 43 are disposed. The diameter ratio (=? 1 /? 2) of the orifice 41 and the orifice 43 varies depending on the kind, application and working state of the chemical liquid M, but when the chemical liquid M is, for example, a herbicide, = 9/1 to 50/1. The mixer 28 mixes the chemical liquid M from the chemical liquid tank 15 and the diluting liquid W from the dilution liquid tank 14 at a predetermined ratio and supplies the mixed liquid Y to the pump 46 So as to be sucked.

The discharge side of the pump 46 is connected to the distal end side of the grip 48 of the spraying rubber via the hose 47. [ The handle 48 is provided with a valve body (not shown) that is opened and closed by a handle 52 swinging around a chucking portion 51 and a valve body A hand switch 53 is disposed. A spray pipe 49 is connected to the tip of the handle 48 and a spray nozzle 50 for spraying the mixed liquid Y mixed in the mixer 28 is disposed at the tip of the spray pipe 49.

In addition to the pump 46, the control unit 60 is disposed in the driving unit 40 described above. The control device 60 includes a power supply device 61, a toggle switch 62, an AD converter 63, a socket 64, a storage battery 65, and a connection terminal 66 . The connection terminal 66 is detachably connected to the connection terminal 67 of the solar cell panel 5. A solar battery panel 5, a hand switch 53, a toggle switch 62, an AD converter 63, and a battery 65 are connected to the input side of the power supply device 61, and a power supply device 61 Is connected to the motor of the pump 46 and the accumulator 65 at the output side thereof. The toggle switch 62 interrupts the wiring between the battery 65 and the power supply device 61 to prevent unnecessary discharge from the battery 65 when the battery 65 is not needed.

Although the contents of the liver transplantation atomizer 1 are each an example, the contents of the diluent tank 14 is 5L, the contents of the chemical liquid tank 15 is 500mL, the total weight is 4.4kg, the height to the handle 12 is 1m to be. The pump 46 has a motor output of 3 W, a spray amount of 0.1 L / min, and a spray pressure of 0.1 to 0.15 MPa. The power generation capacity of the solar panel is 5.6W (12V). The continuous use time of the liver transplantation sprayer 1 is about 2 hours from the full charge state in the cloudy weather and about 4 hours from the full charge state in the clear weather. Here, an example is shown in which a herbicide is used as the chemical liquid (M) and a mixed liquid (Y) diluted with a dilution ratio of 10/1 is sprayed.

The operation of the liver transplantation atomizer 1 configured as described above will be described next. The solar cell panel 5 is provided with support plates 6 and 6 fixed to the upper and lower central upper portions of the right and left vertical frames 11 and 11 of the cart body 4 by welding backward, 7, as shown by the arrow R in Fig. 7, when the dilute solution W is introduced into the diluent tank 14 or the chemical liquid M is introduced into the chemical liquid tank 15, the leading end portion of the solar cell 5 It is possible to easily and effectively perform the liquid dispensing operation and the maintenance of each device.

On the other hand, during the standby time before the spraying operation, the solar cell panel 5 may be set in a horizontal posture as shown in Fig. Accordingly, the solar panel 5 can receive a large amount of solar energy and generate a large amount of electric power. The power supply device 61 receiving the electric power from the solar panel 5 has a well-known charge / discharge control function. When the charge capacity of the battery 65 is not full during the stoppage of the pump 46 , The electric power from the solar panel 5 is supplied to the battery 65 and charged. During the driving of the pump 46, the electric power from the solar panel 5 is supplied to the pump 46.

Therefore, before the spraying operation, the plug of the commercial AC power source (external power source) is plugged into the outlet 64, and the DC power converted into the AD converter 63 is fully charged in the battery 65 by the power supply device 61 You can leave it. In the spraying operation, the solar cell panel 5 is lowered in the horizontal posture by an angle? (See FIG. 9) in a direction perpendicular to the vertical frame 11. This angle? Is an angle at which the solar cell panel 5 of the liver transplantation atomizer 1, which is pulled by hand and tilted forward, becomes almost horizontal. However, the posture of the solar cell panel 5 is not limited to the horizontal posture, but may be set to an angle corresponding to the position of the sun. Also, the on-off valve 56 is opened.

Then, as shown in Fig. 9, the handle portion 12 of the liver transplantation atomizer 1 is grasped by hand and pulled forward (in the direction of the arrow F). Then, the vertical frame 11 is inclined forward, and the solar cell panel 5 is in a substantially horizontal posture. Accordingly, the solar panel 5 receives the solar energy S as much as possible, generates a large amount of electric power, and outputs it to the electric power supply device 61.

Further, when the worker grasps the handle 52, the hand switch 53 enters while the valve in the handle 48 is opened. Thereby, the power supply device 61 feeds the pump 46 to drive it.

The diluent W in the diluting liquid tank 14 and the chemical liquid M in the chemical liquid tank 15 are pumped up by the pump 46 and the diluted liquid W in the diluting liquid W (M) = 9/1) to obtain a mixed solution (Y). The mixed liquid (Y) is discharged from the pump (46) and sprayed from the spray nozzle (50). 10, the diluted liquid tank 14 also tilts. When the lowermost bottom surface 19 is disposed at the front portion of the diluent tank 14, Even when the diluent tank 14 is inclined at the time of spraying operation, the additional inlet 25 is always at the lowest position. Therefore, the last diluent (W) can be used for spraying.

According to the above-described liver transplantation atomizer 1, since the solar cell panel 5 is provided, the pump 46 can be driven using the solar energy S and sprayed from the spray nozzle 50. Thus, even when the electric power charged in the accumulator 65 is consumed by the spraying operation and it becomes difficult to continue the operation, the spraying operation can be continued while using the electric power from the solar cell 5 . Alternatively, when the operation is not performed, it is possible to charge the battery 65 in preparation for the next operation.

Since the solar cell panel 5 is supported on the cart body 4 by the up-and-down pivotal movement of the cart body 4, The solar panel 5 can be rotated up and down to have an appropriate angle. Thus, the solar energy S can be efficiently used, and various operations can be easily performed.

When the driving of the liver transplantation atomizer 1 is difficult, the engagement between the screw 55 and the receiving member 54 is released, and the atomizing unit 3 is lifted by hand and removed from the cart unit 2 And the connection terminal 67 on the solar panel 5 side is disconnected from the connection terminal 66 on the spraying unit 3 side. Thereafter, snap rings 68 and 68 at both ends of the belt 69 are put on the hook holes 22 and 22 of the diluting liquid tank 14, as shown in Fig. Thereby, the belt 69 can be hung on the shoulder, and the spraying operation can be performed by holding the handle 48 of the spray nozzle 50 by hand.

That is, according to the liver transplantation atomizer 1, since the atomizing unit 3 is detachably attached to the cart unit 2, the atomizing unit 3 can be separated from the cart unit 2 and used for the atomizing operation . Therefore, even if the cart unit 2 is difficult or impossible to travel on the road, only the spray unit 3 can be moved to the attraction force to perform spraying work.

However, the chemical solution (M) has been measured using various measuring cups of about 5 mL to 100 mL so far. However, in the case of a drug which is used at a large dilution ratio (for example, 1000/1) such as an insecticide, if the dilution magnification is wrong, it may become too light to lose insecticidal effect or become too dark to adversely affect the human body. Particularly, when the dilution magnification is large, a very small measuring cup must be used, so that the measurement can not be performed with high accuracy. Also, after the weighing, due to safety concerns, it was necessary to wash the finished measuring cup with effort.

Therefore, the liver transplantation atomizer 1 is provided with the injector 80 as shown in Figs. 12 and 13. The injector 80 includes a metering piston 83 having a metering cylinder 82 and an O-ring 84 slidingly moved into the metering cylinder 82 in the main body casing 81 as a tubular container And a metering piston 83 extending upward from the metering cylinder 82 with a larger diameter than the metering cylinder 82 and formed upwardly from the metering piston 83 And an air venting portion 89 composed of an air venting piston 87 having an O-ring 88 slidingly moved in the air venting cylinder 86. The main body casing 81 includes a connecting pipe portion 90 connected to the front end opening 95 of the metering cylinder 82, a connecting pipe portion 110 connected to the inlet side of the air purging cylinder 86, And a connection pipe portion 101 connected to the front end opening 95 of the metering cylinder 82. [

The other end of the suction duct 91 inserted into the chemical liquid M in the chemical liquid tank 15 is connected to the connection pipe portion 90. [ The suction channel 91 has a first check valve 92 that allows the fluid to flow only in the direction toward the metering cylinder 82 (the direction of the arrow C in Fig. 14). The first check valve 92 is constituted by a valve seat 93 arranged with the valve seat portion upward and a ball valve 94 opening and closing the valve seat 93 in accordance with the flow of the self weight and the chemical liquid M do. The other end of the return duct 96, one end of which is connected to the air venting cylinder 86, is connected to the connecting pipe portion 110. [ The return conduit 96 has a second check valve 97 that allows the fluid to flow only in the direction toward the chemical liquid tank 15 (direction of arrow E). The second check valve 97 is composed of a valve seat 98 disposed upward and a ball valve 99 for opening and closing the valve seat 98 in accordance with the flow of the self-weight and the chemical liquid M.

The other end of the infusion conduit 105, one end of which is connected to the diluent tank 14, is connected to the connecting tube portion 101. [ The infusion conduit 105 has a third check valve 100 that allows fluid to flow only in the direction toward the diluent tank 14 (in the direction of the arrow G). The third check valve 100 is composed of a valve seat 103 and a valve body 103 for opening and closing the valve seat 102 by the elastic force of the coil spring 104. The metering piston 83 and the air venting piston 87 are integrally formed as a part of the piston rod 106. The upper end of the piston rod 106 is a hand operated portion 107 that is vertically driven by a hand. The piston rod 106 is regulated or released by the locking and unlocking by the locking member 108. An upper surface opening of the air venting cylinder 86 is capped with a cap 109. The valve lock force of the coil spring 104 of the third check valve 100 is designed to be higher than the valve lock force of the second check valve 97 due to the self weight of the ball valve 99.

The injector 80 is used for sucking the chemical liquid M in the chemical liquid tank 15 and injecting a predetermined amount of the chemical liquid M into the diluting liquid W in the dilution liquid tank 14. [ In this case, since the quantified chemical liquid M is injected into the diluting liquid W in the diluting liquid tank 14 and mixed, and the chemical liquid M in the mixer 28 is not mixed, the opening / closing valve 56 ) Is closed.

14, when the worker pushes up the hand operated portion 107 as shown by the arrow B, the air venting piston 87 slides in the air venting cylinder 86 to the upper end thereof, The chemical liquid M and the air in the suction duct 91 are sucked into the metering cylinder 82 and the air venting cylinder 86. At this time, the ball valve 94 of the first check valve 92 opens the valve seat 93, and the ball valve 99 of the second check valve 97 closes the valve seat 98.

15, the ball valve 94 of the first check valve 92 closes the valve seat 93, and when the operator pushes down the hand operated portion 107 as indicated by the arrow D, the valve seat 93 of the first check valve 92 closes, The ball valve 99 of the check valve 97 opens the valve seat 98. The chemical liquid M and air in the cylinder 86 for evacuating air are returned to the chemical liquid tank 15 through the return line 96 and the second check valve 97 as indicated by the arrow E Loses.

The upper and lower operation of the air venting piston 87 in the air venting cylinder 86 shown in Figs. 14 and 15 is appropriately repeated so that the path on the suction port side of the injector 80 (the suction duct 91) The first check valve 92, the connecting pipe 90, the front end opening 95 and the metering cylinder 82) and is replaced with only the chemical liquid M.

16, when the locking member 108 is unlocked and the water control portion 107 is further pushed down, the metering piston 83 is slid in the metering cylinder 82 to the lower end of the cylinder Move. At this time, the first check valve 92 and the second check valve 97 are closed and the valve seat 102 of the third check valve 100 is open. The metered amount of the chemical solution M as a metering component corresponding to the content of the metering cylinder 82 is supplied to the third check valve 100, the connecting tube portion 101, (W) in the diluent tank (14) through the pipeline (105). In this case, assuming that the amount of the diluting liquid W in the diluting liquid tank 14 is 10 L, since the metering amount by the metering cylinder 82 is, for example, 5 mL, in order to make dilution 200 times, Operation is performed ten times. After finishing the desired metering and dosing operation, the operator returns the locking member 108 and puts the operating portion 107 in the locked state.

As described above, according to the injector 80, the air in the suction port side is eliminated by the air venting cylinder 86 and the air venting piston 87, and then the air is supplied to the metering cylinder 82 and the metering piston The amount of the chemical liquid M can be precisely metered and diluted and mixed with the diluting liquid W and the mixed liquid Y having an accurate dilution ratio can be accurately metered by feeding the chemical liquid M to the dilution tank 14, Can be obtained. As a result, insecticides diluted with high-helix magnification can be appropriately used for spraying. Further, there is no need to use a small-capacity metering cup which is liable to be mistakenly metered, and it is possible to reduce the labor of cleaning the cup after use.

In the above-described embodiment, the liver 8 of the cart body 4 is exemplified by a liver transplantation atomizer having two wheels, but a liver transplantation atomizer having one or more than three wheels is also included in the present invention.

1: Liver transplantation atomizer 2: Cart unit
3: Spray unit 4: Cartridge
5: solar cell panel 6:
7: Chute shaft 8: Wheel
11: vertical frame 12: handle portion
13: Placeholder 14: Diluent tank
14A: back surface 15: chemical tank
19: lowest floor 25: additional intake
28: Mixer 29: diluent inlet channel
31: chemical liquid inlet side pipeline 32: liquid outlet side pipeline
34: liquid inlet port 46: pump
50: atomizing nozzle 54: receiving member
55: screw 60: control device
61: power supply device 63: AD converter
64: outlet 65: battery
66: connection terminal 67: connection terminal
80: Injector 82: Cylinder for metering
83: metering piston 85: metering section
86: cylinder for venting air 87: piston for venting air
89: air vent 91: suction pipe
92: first check valve 95: tip opening
96: conduit for returning 97: second check valve
100: third check valve 105: piping for injection
B, C, D, E, F, G, R: Arrow J:
K: vertical line M: chemical solution
S: Solar energy W: Diluent
Y: mixed liquid

Claims (6)

A hand drag type cart body having at least one wheel,
A chemical liquid tank and a diluent liquid tank mounted on the cart body,
A pump for pumping the diluted solution in the chemical liquid and the diluting liquid tank in the chemical liquid tank,
A mixer for mixing the chemical liquid in the chemical liquid tank and the diluting liquid in the diluting liquid tank and sucking the mixed liquid into the pump,
A spray nozzle for spraying the mixed liquid discharged from the pump,
A solar cell panel for converting solar energy into electric power,
A storage battery for storing electric power from a solar panel or an external power source,
A power supply device for supplying power from the solar panel or the battery to the pump,
And an injector for sucking the chemical liquid in the chemical liquid tank and injecting a predetermined amount of the chemical liquid into the diluting liquid in the diluent tank,
The injector
A metering unit comprising a metering cylinder and a metering piston slidingly moved in the metering cylinder;
An air venting cylinder formed of a cylinder for metering extending from the metering cylinder to a diameter larger than that of the metering cylinder and an air venting piston formed of a piston for metering out from the metering piston and slidable in the cylinder for venting air,
A suction pipe having a first check valve which is once inserted into the chemical liquid in the chemical liquid tank and whose other end is connected to the front end opening of the metering cylinder and permits fluid flow only in a direction toward the metering cylinder,
A second check valve having one end connected to the cylinder for bleeding and the other end connected to the chemical liquid tank and allowing the fluid to flow only in a direction toward the chemical liquid tank,
And a third check valve having one end connected to the opening of the metering cylinder and the other end connected to the diluent tank and allowing fluid to flow only in the direction toward the diluent tank. sprayer. The method according to claim 1,
A cart unit is constructed from a cart and a solar cell panel,
A spray unit is constructed from a chemical liquid tank, a diluent tank, a pump, a mixer, a spray nozzle, a battery, and a power supply,
Wherein the atomizing unit is detachably mounted on the cart unit. The method according to claim 1,
A liver transplantation atomizer in which a solar panel is supported on a cart body by up and down rocking materials. 4. The method according to any one of claims 1 to 3,
The liquid medicine tank is mounted on the back surface of the dilute liquid tank which is located behind the direction in which the cart body is pulled and the liquid injection port formed in the upper portion of the chemical liquid tank has an angle at which the center of the liquid injection port is almost vertical when the cart body is pulled and tilted Wherein the diluent tank is disposed rearwardly with respect to the back surface of the diluent tank. delete delete

Images