KR101760491B1 - Soil sterilizer - Google Patents

Abstract

A soil sterilizer capable of reducing the load the worker receives from the chemical liquid is provided. A soil sterilizer (1) composed of a chemical liquid supply part (30), a control part (90) and a chemical liquid injecting part (10) and injecting a chemical liquid into the soil by the chemical liquid injecting part (10) And is disposed at a position spaced apart from the driver's seat 116. In addition, The delivery tube 3 connecting the chemical solution supply unit 30 and the chemical solution injection unit 10 is disposed outside the driver's seat 116.

Description

Soil sterilizer {SOIL STERILIZER}

TECHNICAL FIELD The present invention relates to a technology of a soil sterilizer for injecting a chemical solution into soil.

Description of the Related Art [0002] Conventionally, a technique of a soil sterilizer for injecting a chemical solution for sterilizing and insecting soil into a soil is known.

As the chemical solution used in such a soil sterilizer, for example, a substance having high toxicity such as chloropicrin is used. For this reason, when the chemical solution is not injected into the soil but is exposed to the outside (when the chemical solution is dropped), an irritating odor is generated around the chemical solution, causing inconvenience to the operator. Therefore, there is a demand for a technology of a soil sterilizer that can reliably prevent the chemical liquid from falling off.

The technology of the soil disinfector disclosed in Patent Document 1 is a technique for preventing the chemical liquid from dropping at the time of driving. The soil disinfector disclosed in Patent Document 1 includes a chemical liquid tank, a suction hose, a discharge hose, an intermittent drive pump, a chemical solution injection nozzle, a chemical solution injection rake, a chemical solution flow meter, and a cock.

A chemical liquid for disinfecting the soil is stored in the chemical tank.

The suction hose connects the chemical tank and the intermittent drive pump. The discharge hose connects the intermittent drive pump and the chemical solution injection nozzle. The suction hose and the discharge hose are each composed of a suitable hard member having corrosion resistance so as not to be corroded by a chemical liquid.

The intermittent drive pump sucks the chemical liquid in the chemical liquid tank through the suction hose and sends it out through the discharge hose to the chemical liquid injection nozzle.

The chemical liquid injecting nozzle is provided with an opening that opens outward. The opening discharges the chemical liquid sent out from the intermittent drive pump.

The chemical solution injection rake is equipped with a chemical solution injection nozzle.

The liquid chemical identification system is provided with a fluid that moves in a flowing direction when the chemical liquid flows. The chemical solution identification system is supported on the suction hose so that the direction of movement of the fluid is parallel to the vertical direction.

The cock is provided in the middle of the discharge hose. So that the flow path in the discharge hose can be closed or opened by operating the cock. In other words, the cock can regulate the flow of the chemical liquid sent from the intermittent drive pump or allow the flow of the chemical liquid.

The soil sterilizer disclosed in Patent Document 1 structured as above operates the cock to stop the intermittent drive pump and then regulate the flow of the chemical liquid when the disinfection of the soil is finished. This makes it possible to completely prevent the chemical liquid from dropping from the chemical liquid injecting nozzle.

However, in the soil sterilizer disclosed in Patent Document 1, it was necessary to operate the cock after the intermittent drive pump was started and stopped. That is, the disinfection of the soil is disadvantageous in that the process is increased.

In addition, when an operator unfamiliar with the operation of the soil disinfector is working, there is a possibility of forgetting to operate the coke. If the operation of the cock is forgotten before driving the intermittent drive pump, there is a possibility that a load is applied to the intermittent drive pump because the fluid passage is closed. Further, when the operation of the cock is forgotten after the intermittent drive pump is stopped, there is a possibility that the chemical liquid is dropped from the chemical liquid injection nozzle because the chemical liquid flow path is opened.

In view of not forgetting the operation of the cock, when the soil sterilizer of this kind is towed by the working vehicle, it is necessary to dispose the cork in the vicinity of the operator, that is, near the driver's seat of the working vehicle on which the soil sterilizer is mounted. In this case, the discharge hose is installed on the working vehicle so as to pass near the driver's seat.

In such a case, since the discharge hose passes near the operator, there is a possibility that the discharge hose is cut off, for example, when the operator comes into contact with the discharge hose when getting on and off the work vehicle. In addition, there was a possibility that the discharge hose was missing from the two-way cock. At this time, irritating odor is generated in the vicinity of the operator, which may cause inconvenience to the operator.

Further, the manipulation (opening and closing) of the anisotropic coke is repeated several times, so that the anisotropic coke is deteriorated, and there is a possibility that the chemical liquid may leak at a portion where the anisotropic coke is manipulated. At this time, irritating odor is generated in the vicinity of the operator, which may cause inconvenience to the operator.

Further, in a working vehicle having a cabin, it is necessary to provide a discharge hose, an anvil cock, and a controller in the vicinity of the driver's seat, that is, in the cabin. In this case, since the door of the cabin can not be opened or closed, the soil sterilizer could not be mounted on the working vehicle having the cabin.

Patent Document 1: Japanese Patent Application Laid-Open No. 2007-195423

SUMMARY OF THE INVENTION The present invention has been made in view of such a situation, and it is an object of the present invention to provide a soil sterilizer which can reduce the burden on the operator from the chemical liquid.

The problem to be solved by the present invention is as described above, and means for solving this problem will be described next.

The soil sterilizer includes a chemical liquid supply unit, a control unit, and a chemical liquid injecting unit. The soil sterilizer injects the chemical liquid into the soil from the chemical liquid injecting unit by operating the control unit. And the chemical liquid supply unit is disposed at a position away from the driver's seat.

According to claim 2, a connecting member for connecting the chemical liquid supply unit and the chemical liquid injecting unit is disposed outside the driver's seat.

4. The apparatus according to claim 3, wherein the chemical liquid supply unit includes a chemical liquid tank for storing the chemical liquid, a leakage preventing valve for preventing the chemical liquid from falling from the chemical liquid injecting unit when the chemical pump is stopped, And a confirmation system for confirming whether or not the liquid is sent out from the pump to the chemical liquid injecting unit.

5. The apparatus according to claim 4, wherein the control unit closes the chemical liquid supply path by closing the leakage preventing valve when the chemical liquid dispensing pump is stopped, and opens the leakage preventing valve when the chemical liquid dispensing pump is driven, Open the path.

The leakage preventing valve according to claim 5, wherein the leakage preventing valve closes the chemical liquid supply path by externally applying pressure.

According to claim 6, there is provided a cover member for covering the leakage preventing valve from the outside.

[Claim 7] The method according to claim 7, wherein a pair of communication holes are formed in the cover member at positions corresponding to the chemical solution supply path, and a soft member supporting the constituent members of the chemical solution supply path is mounted to the pair of communication holes.

[Claim 9] The apparatus according to claim 8, wherein the cover member is provided with a through hole at a position where the leakage preventing valve can visually confirm a portion where the chemical liquid supply path is closed.

The present invention exhibits the following effects.

According to claim 1, since the chemical liquid supply unit can be disposed at a position away from the operator, the burden on the operator from the chemical liquid can be reduced.

According to claim 2, it is possible to prevent the operator from coming into contact with the connecting member, so that it is possible to prevent the connecting member from being cut off, and further, the burden on the worker from the chemical liquid can be reduced.

According to Claim 3, since the chemical liquid supply portion can be disposed at a position away from the operator, the burden on the operator from the chemical liquid can be reduced.

According to claim 4, since it is possible to prevent the liquid medicine delivery pump from being driven in a state in which the chemical liquid supply path is closed, it is possible to reduce the load applied to the chemical liquid delivery pump and further reduce the burden on the worker . In addition, the work process for soil disinfection can be simplified.

According to claim 5, it is possible to prevent the leakage preventing valve from directly contacting the chemical liquid. That is, it is possible to reliably prevent the leakage preventing valve from being corroded by the chemical liquid. Therefore, maintenance can be improved.

According to Claim 6, it is possible to reduce a portion where the leakage preventing valve is exposed to the outside. Therefore, deterioration of the leakage preventing valve can be prevented, and the maintenance property can be improved.

According to Claim 7, the load applied to the constituent members of the chemical liquid supply path can be reduced when the leakage preventing valve closes the chemical liquid supply path. That is, maintenance can be improved.

According to claim 8, since the operation of the leakage preventing valve can easily be confirmed by eyes, it contributes to the specification of the failure point. That is, maintenance can be improved.

1 is a side view showing the overall configuration of a work vehicle on which a soil sterilizer is mounted.
2 is a partial side sectional view showing the overall configuration of the chemical liquid supply portion.
3 is an enlarged side sectional view showing the configuration of the pinch valve and the cover member.
4 is an enlarged side sectional view showing a state in which the pinch valve presses the first delivery tube;
5 is an exploded perspective view showing a configuration of the cover member.
6 is a front view showing the connection state of the chemical solution delivery pump and the cover member.
7 is a flowchart showing the operation of the control unit.

Next, a soil sterilizer 1, which is an embodiment of a soil sterilizer according to the present invention, will be described with reference to the drawings.

As shown in Fig. 1, the soil sterilizer 1 is mounted on a movable work vehicle, in this embodiment, a tractor 100. The soil sterilizer (1) injects the chemical liquid into the soil while moving along with the movement of the tractor (100).

On the other hand, the soil sterilizer 1 of the present embodiment is applied to the tractor 100 for convenience of explanation, but is not limited thereto.

Hereinafter, for convenience of description, the traveling direction (the direction of the arrow A) of the tractor 100 shown in Fig. 1 is defined as the forward and backward directions.

First, the overall configuration of the tractor 100 will be described.

The tractor 100 includes a traveling part 110, a mounting part 120, and the like.

The traveling unit 110 includes an engine frame 111, a front wheel 112 · 112, a rear wheel 113 · 113, a bonnet 114, a steering wheel 115, a driver seat 116 and a side column 117 .

The engine frame 111 is provided in the traveling portion 110 in the longitudinal direction.

The front wheel 112 · 112 is supported on the axle and spans the front portion of the engine frame 111. The rear wheels 113 and 113 are disposed behind the front wheels 112 and 112 in a state of being supported by the axle.

An engine, a battery, or the like is mounted on the bonnet 114, and is fixed on the front portion of the engine frame 111. The tractor 100 is configured to be movable by the power of the engine being transmitted to the front wheel 112 · 112 and the rear wheel 113 · 113.

Steering handle 115 is disposed at the rear of bonnet 114. By rotating the steering handle 115 along its circumferential direction, the tractor 100 is configured to be steerable around the engine frame 111. [

The driver's seat 116 is disposed behind the steering handle 115.

The side column 117 is provided with various operating mechanisms such as a peripheral speed lever and a PTO shift lever and is disposed on both sides of the driver's seat 116. [ Further, in front of the driver's seat 116, more specifically, when the operator is seated in the driver's seat 116, an operation pedal 118 (foot accelerator pedal, etc.) is disposed at a position corresponding to the foot of the operator.

The mounting portion 120 includes a top link, a lower link, and the like, and is installed at a rear portion of the traveling portion 110. [ The tractor 100 is configured to be pullable by connecting a predetermined working device to a top link and a lower link or the like.

Next, the construction of the soil sterilizer 1 will be described.

The soil sterilizer 1 includes a chemical liquid injecting section 10, an installation section 20, a chemical liquid supply section 30, and a control section 90.

The chemical solution injecting section 10 injects the chemical solution into the soil. The chemical liquid injecting portion 10 includes a chemical liquid injecting rake 11 and a chemical liquid injecting nozzle 12.

The chemical solution injection rake (11) is inserted into the soil to dig a groove having a desired depth. One end of the liquid injecting rake 11 is gently bent and formed in a substantially J-shape as shown in Fig. The chemical solution injection rake 11 is connected to the mounting portion 120 through a top link mast or the like.

The chemical liquid injecting nozzle 12 discharges the chemical liquid. The chemical liquid injecting nozzle 12 is a tubular member having both ends open, and one end of the chemical liquid injecting nozzle 12 is mounted to the rear portion of the chemical liquid injecting rake 11 through a predetermined holder. The other end of the chemical liquid injection nozzle 12 is formed as an opening 12a.

The chemical liquid injecting unit 10 configured as described above is moved by being pulled by the tractor 100. [

The mounting portion 20 fixes the chemical solution supply portion 30 on the front portion of the tractor 100. The mounting portion 20 includes a support frame 21, a chemical tank mounting base 22, and a guide member 23.

The support frame 21 is mounted on the front end of the engine frame 111 so as not to interfere with the bonnet 114. The support frame 21 is constituted by connecting a plurality of angular pipes.

The chemical solution tank mounting base 22 is mounted on the support frame 21 via a stay or the like. The chemical-solution tank mounting base 22 is formed by connecting a plurality of plate-like members so as to have a substantially U-shape in Fig.

As shown in Figs. 1 and 2, the guide member 23 is mounted to the support frame 21 via a stay or the like. The upper end portion of the guide member 23 is fitted with a plate-like member which is folded at right angles to the upper and lower both ends toward the rear.

The chemical liquid supply unit (30) supplies the chemical liquid to the chemical liquid injection unit (10). The chemical liquid supply unit 30 includes a chemical liquid tank 31, a chemical liquid delivery pump 41, a pinch valve 61, a cover member 71 and an identification system 81.

The chemical liquid tank 31 stores the chemical liquid. The chemical liquid tank 31 is formed with an opening that opens outward. The chemical liquid tank 31 is provided on the chemical liquid tank mounting base 22, and the rubber belt 22a is wound around the outer periphery of the chemical liquid tank mounting base 22 and fixed.

Examples of the chemical solution stored in the chemical liquid tank 31 include chloropicrin.

The chemical liquid dispensing pump 41 sends the chemical liquid in the chemical liquid tank 31 to the chemical liquid injecting nozzle 12. The chemical liquid delivery pump 41 has a pump drive case 42, a drive device 44, and a diaphragm pump 52.

Hereinafter, the flow path of the chemical liquid from the chemical liquid tank 31 to the chemical liquid injecting nozzle 12 will be referred to as "chemical liquid supply path C ".

The side of the chemical liquid tank 31 in the chemical liquid supply path C is referred to as the "upstream side of the chemical liquid supply path C" and the side of the chemical liquid injecting nozzle 12 is referred to as the "downstream side of the chemical liquid supply path C" Quot;

The pump drive case 42 accommodates the drive device 44 and is fixed on the support frame 21 with the diaphragm pump 52 mounted on the upper surface of the pump drive case 42. Here, the chemical tank mounting base 22 is mounted on the support frame 21 as described above. Therefore, the chemical liquid dispensing pump 41 is disposed adjacent to the chemical liquid tank 31.

The drive device 44 drives the diaphragm pump 52 by moving the swing crank 45 up and down. A driving shaft 46 connected to the motor is connected to the rear portion of the swing crank 45 through an eccentric cam 47 or the like. The rocking crank 45 is mounted on the middle portion thereof with a fulcrum cam 48 and is connected to the diaphragm pump 52 through the connecting rod 49 and the connecting pin 50 at the front upper portion thereof.

Accordingly, when the drive shaft 46 is rotated, the drive device 44 is configured such that the swing crank 45 moves up and down with the fulcrum point cam 48 as a fulcrum. Therefore, the up-and-down movement of the swing crank 45 is transmitted to the diaphragm pump 52 through the connecting rod 49 and the connecting pin 50.

The diaphragm pump 52 vertically moves the diaphragm 53 to send the chemical liquid to the chemical liquid injecting nozzle 12. The diaphragm pump 52 is fixed on the diaphragm mounting member 54 and the valve mounting member 55 with the diaphragm 53 sandwiched in the vertical direction.

The diaphragm pump 52 is provided with a suction port 52a and a discharge port 52b.

The suction port 52a is open to the outside, and one end of the suction tube 2 is connected to the end of the opening.

The other end of the suction tube 2 passes through the opening of the chemical liquid tank 31 and is disposed inside the chemical liquid tank 31. Thus, the suction tube 2 connects the chemical liquid tank 31 and the chemical liquid dispensing pump 41.

A suction-side check valve 56 is provided at an intermediate portion of the suction port 52a. A valve 56a and a spring 56b are disposed in turn on the suction side check valve 56 from the opening side of the suction port 52a. The valve 56a is fastened by the spring 56b and biased toward the outside. Further, the valve 56a is fastened to the suction port 52a.

The suction side check valve 56 restricts the flow in the direction from the downstream side of the chemical liquid supply path C toward the upstream side (from the outside to the inside of the suction port 52a), and at the same time, Allowing the flow in the direction from the upstream side to the downstream side (the inside to the outside of the suction port 52a) of the chemical solution supply path C is allowed.

The delivery port 52b is open to the outside, and one end of the delivery tube 3 is connected to the end of the delivery port 52b which is opened.

A chemical liquid injection nozzle (12) is connected to the other end of the delivery tube (3). Such a delivery tube 3 is constituted by connecting the first delivery tube 3a and the second delivery tube 3b through a joint 4. The joint 4 is disposed in the vicinity of the check system 81 between the pinch valve 61 and the check system 81.

The first delivery tube 3a is composed of a soft member which is resistant to corrosion by the chemical liquid and which is susceptible to plastic deformation under external pressure. The first delivery tube 3a may be, for example, a silicone tube.

The second delivery tube 3b is made of a rigid tube which is resistant to corrosion by the chemical liquid and which is difficult to be plastically deformed by external pressure.

The second delivery tube 3b is connected to the chemical liquid injection nozzle 12 through the outside of the driver's seat 116 so as to bypass the driver's seat 116 and the operation pedal 118. [

Thus, it is possible to prevent the operator from accidentally stepping on (making contact with) the delivery tube 3. In other words, since the second delivery tube 3b can be prevented from being cut off, irritating odor is generated in the vicinity of the operator and burden on the operator can be prevented.

Two check valves 5 占 are mounted in the vicinity of the chemical liquid injection nozzle 12 of the second delivery tube 3b. The two check valves 5, 5 are respectively provided with valves and springs from the upstream side of the chemical liquid supply path C, respectively. The two check valves 5 and 5 restrict the flow in the direction from the downstream side to the upstream side of the chemical liquid supply path C and are arranged in the upstream side of the chemical liquid supply path C To the downstream side.

Thus, the delivery tube 3 connects the chemical liquid dispensing pump 41 and the chemical liquid injecting nozzle 12. The delivery tube 3 (second delivery tube 3b), which is a connecting member for connecting the medicament solution supply portion 30 and the chemical solution injection portion 10, is disposed outside the driver's seat 116 without a joint.

A delivery check valve 57 is provided in the middle of the delivery port 52b. The delivery check valve 57 is provided with a spring 57b and a valve 57a in order from the opening side of the delivery port 52b. The valve 57a is fastened by the spring 57b and biased toward the outside. Further, the valve 57a is fastened to the suction port 52b.

The delivery check valve 57 controls the flow in the direction from the upstream side to the downstream side (from the inside to the outside of the delivery port 52b) on the upstream side of the chemical solution supply path C, and at the same time, And allows the flow in the direction from the downstream side of the chemical liquid supply path C to the upstream side (from the outside to the inside of the delivery port 52b).

The chemical liquid delivery pump 41 thus configured moves the diaphragm 53 up and down by the power transmitted from the drive device 44. [ Thus, the chemical liquid in the chemical liquid tank 31 is supplied into the diaphragm 53 through the suction port 52a. Then, the chemical liquid in the diaphragm 53 passes through the delivery port 52b and is sent to the chemical liquid injection nozzle 12. [

3, the pinch valve 61 as a leakage preventing valve includes a housing case 62, a connecting portion 63, a flange 64, a spring 65, and a solenoid 66. [

The housing case 62 is constituted by a predetermined member having a space formed therein. A flange 64, a spring 65, and a solenoid 66 are accommodated in the housing case 62. A connecting portion 63 is mounted outside the housing case 62. The first insertion tube 62a has a shape capable of inserting the first delivery tube 3a and has a first insertion portion 62a and a second insertion portion 62b communicating with the outside space . The first insertion portion 62a and the second insertion portion 62b are formed by cutting the housing case 62, respectively.

The connection unit 63 is connected to a predetermined power source via a cable, and supplies power supplied from the power source to the solenoid 66. [

The plunger 64 is configured to be reciprocally movable in the vertical direction. The flange 64 is formed with a first pressing portion 64a and a second pressing portion 64b. The first pressing portion 64a and the second pressing portion 64b are formed by cutting the lower end of the flange 64, respectively. That is, the first pressing portion 64a is the upper end of the portion where the flange 64 is cut. The second pressing portion 64b is the lower end of the portion where the flange 64 is cut.

The spring 65 is fitted on the outer side of the flange 64 and biases the flange 64 downward.

The solenoid 66 is disposed on the upper portion of the housing case 62.

When power is not supplied to the pinch valve 61 constructed as described above, the biasing force of the spring 65 biases the plunger 64 downward as shown in Fig. Therefore, the first pressing portion 64a of the flange 64 and the first insertion portion 62a come close to each other. On the other hand, the second pressing portion 64b and the second insertion portion 62b of the flange 64 are distant from each other.

Therefore, when the first delivery tube 3a is inserted into the first insertion portion 62a, the first delivery tube 3a is pressed downward by the first pressing portion 64a of the flange 64. [ For this reason, the first delivery tube 3a is plastically deformed so as to reduce its inner diameter, in other words, to close the flow path of the first delivery tube 3a. That is, the pinch valve 61 regulates the flow of the chemical liquid.

When power is supplied to the pinch valve 61, the plunger 64 is biased upward by the magnetic action of the solenoid 66, as shown in Fig. Therefore, the first pressing portion 64a of the plunger 64 and the first insertion portion 62a are distant from each other. On the other hand, the second pressing portion 64b of the plunger 64 and the second insertion portion 62b are close to each other.

Therefore, when the first delivery tube 3a is inserted into the first insertion portion 62a, the downward pressure of the first delivery tube 3a by the first pressure portion 64a of the flange 64 is released do. Therefore, the first delivery tube 3a returns to its original shape. Accordingly, the pinch valve 61 allows the flow of the chemical liquid.

Thus, when the first delivery tube 3a is inserted into the first insertion portion 62a, the pinch valve 61 opens the chemical solution supply path C when power is supplied, and when the power is not supplied The chemical liquid supply path C is closed.

On the other hand, when the first delivery tube 3a is inserted into the second insertion portion 62b, the pinch valve 61 closes the chemical solution supply path C when power is supplied, and when the power is not supplied, The supply path C is opened.

Further, the pinch valve 61 closes the chemical liquid supply path C passing through the first delivery tube 3a by externally applying pressure. Therefore, the pinch valve 61 can regulate the flow of the chemical liquid without directly contacting the chemical liquid. This makes it possible to more reliably prevent the pinch valve 61 from being corroded by the chemical liquid, as compared with the case where the pinch valve 61 is in direct contact with the chemical liquid. That is, deterioration of the pinch valve 61 can be prevented, and maintenance and maintenance can be improved.

5, the cover member 71 includes a bottom plate 72, a pair of side plates 73L and 73R, a top plate 74, and a flexible member 75 · 75.

The bottom plate 72 is formed as if the both end portions of the substantially plate-shaped member are folded perpendicular to the plate surface.

The pair of side plates 73L and 73R are formed so that both end portions of a substantially plate-like member are bent and bent perpendicularly to the plate surface. The size of the portion of the pair of side plates 73L and 73R forming the plate surface is smaller than the size of the portion of the bottom plate 72 that forms the plate surface.

At both ends where the pair of side plates 73L and 73R are bent, first semicircular first notches 73a and 73a having an inner diameter slightly larger than the outer diameter of the first delivery tube 3a are formed, respectively. An upper half of the first notched portion 73a is provided above the first notched portion 73a (in the present embodiment, the first notched portion 73a in the present embodiment) Shaped second notch portion 73c is formed.

A substantially circular through hole 73e is formed in the portion of the side plate 73R that forms the plate surface.

The ceiling plate 74 is formed so that both end portions of a substantially plate-shaped member are bent and bent perpendicularly to the plate surface.

The soft members 75 and 75 are each formed into a substantially disk shape. The flexible members 75 and 75 are each provided with a hole portion 75a having an inner diameter substantially equal to the outer diameter of the first delivery tube 3a. The flexible members 75 and 75 are each made of a resin material such as rubber.

As shown in Fig. 3 and Fig. 6, the pair of side plates 73L, 73R are disposed at the bottom of the bottom plate 72 with their bent ends abutting each other. In addition, the upper ends of the pair of side plates 73L, 73R are disposed inside the ceiling plate 74. The pair of side plates 73L and 73R are fixed to the bottom plate 72 and the ceiling plate 74 through bolts or the like.

Thus, the pair of side plates 73L and 73R are fixed in a state in which the bent portions are in contact with each other. Accordingly, the first notch portions 73a and 73a form a pair of substantially circular first communication holes 73b and 73b. Further, the second notch portion 73c forms a substantially circular second communication hole 73d.

The pair of first communication holes 73b and 73b are provided with flexible members 75 and 75, respectively. The first delivery tube 3a is inserted into the hole portion 75a. As described above, in the cover member 71, a pair of first communication holes 73b and 73b are formed at positions corresponding to the chemical solution supply path C, and at the same time, The flexible members 75 and 75 supporting the tube 3a are mounted on the pair of first communication holes 73b and 73b.

2 and 6, the cover member 71 is fixed on the pump drive case 42 by connecting the bottom plate 72 and the pump drive case 42 via bolts or the like. The cover member 71 is fixed to the guide member 23 by connecting the side plate 73R and the guide member 23 through bolts or the like.

A pinch valve 61 is mounted on the inside of the cover member 71 through bolts or the like. At this time, the first delivery tube 3a is inserted into the first insertion portion 62a of the housing case 62. [ Further, the connection section 63 is connected to the control section 90 via a cable. Such a cable is inserted into the second communication hole 73d.

Accordingly, the pinch valve 61 (and the cover member 71) is disposed adjacent to the chemical liquid delivery pump 41. [ Further, the cover member 71 covers the pinch valve 61 from the outside.

With this configuration, the portion where the pinch valve 61 is exposed to the outside can be reduced. That is, deterioration of the pinch valve 61 can be prevented, and maintenance and maintenance can be improved.

The confirmation system 81 confirms whether the chemical liquid is dispensed from the chemical liquid dispensing pump 41 to the chemical liquid injecting nozzle 12. 2, the confirmation system 81 is mounted on the upper end of the guide member 23 via a stay or the like. Therefore, the confirmation system 81 is disposed above the pinch valve 61. [ That is, the confirmation system 81 is disposed in the vicinity of the chemical liquid delivery pump 41.

A buoy is provided inside the confirmation system 81. The buoy moves inside the confirmation system 81 when the chemical liquid is supplied to the confirmation system 81. Therefore, by confirming the state in which the buoy is moving inside the confirmation system 81, the worker can confirm the flow of the chemical liquid. In addition, the second delivery tube 3b is connected to the confirmation system 81.

The confirmation system 81 is arranged such that the moving direction of the buoy is the up-and-down direction. Therefore, the second delivery tube 3b disposed in the vicinity of the confirmation system 81 is in a state of following the vertical direction.

Further, the portion of the first delivery tube 3a that passes through the pinch valve 61 is disposed along the horizontal direction. Therefore, the first delivery tube 3a and the second delivery tube 3b are substantially perpendicular to each other.

Here, since the first delivery tube 3a is constituted by the flexible member as described above, the layout is easy. In other words, the joint 4 connected to the second delivery tube 3b can be easily arranged. In addition, the flow path can be reliably closed by the pinch valve 61.

The chemical liquid supply unit 30 is disposed at a position away from the driver's seat 116. [ That is, since the chemical liquid supply unit 30 can be disposed at a position away from the operator, it is possible to reduce the burden on the operator from the chemical liquid. In the chemical liquid supply unit 30, a chemical liquid tank 31, a pinch valve 61, and an identification system 81 are disposed in the vicinity of the chemical liquid delivery pump 41. The chemical liquid tank 31, the pinch valve 61, and the check system 81 are disposed at positions close to each other. In other words, it is concentrated.

For example, when the chemical liquid supply portion 30 is formed as an integral part, the integral part is housed in a relatively small case, the space between the respective members is reduced and the chemical liquid supply part 30 is separated from the driver's seat 116 , It is possible to reduce the burden on the operator from the chemical liquid.

As shown in Fig. 1, the control section 90 is provided in the side column 117. Fig. The controller 90 is provided with a controller 91, a pump switch 92, and a valve switch 93.

The controller 91 is connected to a battery mounted in the bonnet 114 via a cable or the like. The controller 91 is connected to the connection portion 63 of the chemical liquid delivery pump 41 and the pinch valve 61 through a cable or the like.

The pump switch 92 is connected to the controller 91 so as to supply power to the chemical liquid delivery pump 41. Therefore, the chemical liquid dispensing pump 41 can be driven or stopped by switching the pump switch 92.

The valve switch 93 is connected to the controller 91 so as to supply power to the pinch valve 61. Therefore, by switching the valve switch 93, it is possible to supply power to the pinch valve 61 or to stop the supply of electric power.

In other words, by opening or closing the chemical liquid supply path C by the pinch valve 61, by switching the valve switch 93 (to perform an operation of turning OFF or turning ON) Can be performed. At this time, the operation of the pinch valve 61 can be confirmed from the through hole 73e of the cover member 71. [

Next, the control configuration of the soil sterilizer 1 will be described.

First, the chemical solution injection rake 11 is inserted into the soil. Then, as shown in Figs. 1 and 7, the pump switch 92 of the control unit 90 is switched on to supply power to the chemical liquid dispensing pump 41 (S10, YES). Thereby, the motor for driving the chemical liquid delivery pump 41 is driven. Therefore, the chemical liquid is sucked from the chemical liquid tank 31 into the chemical liquid delivery pump 41 (see the arrow Y1 shown in Fig. 2).

At this time, the valve switch 93 is turned on by the controller 91 to supply power to the pinch valve 61 as well. 3 and FIG. 7, the plunger 64 is biased upward by the magnetic action of the solenoid 66, and the pinch valve 61 opens the chemical liquid supply path C (S20).

As shown in Fig. 2, the chemical liquid sucked into the chemical liquid dispensing pump 41 is sent out from the dispensing port 52b toward the chemical liquid injecting nozzle 12. Therefore, the chemical liquid passes through the pinch valve 61 and the check system 81 (see arrow Y2 in Fig. 2).

1, the chemical liquid is discharged from the opening 12a of the chemical liquid injecting nozzle 12 after passing through the confirming system 81. Then, as shown in Fig.

In this manner, the soil is disinfected by moving the tractor 100 in a state in which the chemical liquid is ejected from the chemical liquid injecting nozzle 12. 1 and 7, when the discharge of the chemical liquid is stopped, the pump switch 92 of the control unit 90 is switched and turned off to stop the supply of power to the chemical liquid delivery pump 41 (S10 , no).

At this time, the valve switch 93 is turned off by the controller 91, and the power supply to the pinch valve 61 is stopped. 4 and 7, the magnetic action of the solenoid 66 is not applied to the plunger 64, and the plunger 64 is biased downward by the biasing force of the spring 65. As shown in Fig. Therefore, the pinch valve 61 presses the first delivery tube 3a. That is, the pinch valve 61 closes the chemical liquid supply path C (S30). Accordingly, the supply of the chemical liquid can be quickly regulated by the pinch valve 61 on the upstream side of the chemical liquid supply path C, so that the chemical liquid can be prevented from being dropped from the chemical liquid injecting nozzle 12.

As described above, the pinch valve 61 functions as a leakage preventing valve that prevents the chemical liquid from falling from the chemical liquid injecting nozzle 12 when the chemical liquid dispensing pump 41 is stopped. Further, the control unit 90 controls the opening and closing operation of the pinch valve 61.

1, on the downstream side of the chemical liquid supply path C, when the chemical liquid dispensing pump 41 is stopped, the chemical liquid remaining in the delivery tube 3 by the two check valves 5, And is sent out to the chemical liquid injection nozzle 12. That is, since the flow of the chemical liquid is regulated on the upstream side and the downstream side of the chemical liquid supply path C, it is possible to reliably prevent the chemical liquid from falling off from the chemical liquid injecting nozzle 12.

4, since the soft members 75 and 75 can expose the center of the first delivery tube 3a, the first delivery tube 3a can be surely closed by the pinch valve 61 can do. Further, when the first delivery tube 3a is pressed against the pinch valve 61, the load applied to the first delivery tube 3a can be reduced. Therefore, deterioration of the first delivery tube 3a can be prevented, which contributes to improvement in maintenance.

Through the through hole 73e of the cover member 71 covering the pinch valve 61 so as to confirm the case where the first delivery tube 3a is in the pressed state due to a problem of the pinch valve 61 or the like, The first delivery tube 3a can be visually confirmed whether the first delivery tube 3a is closed or opened.

As described above, the cover member 71 is provided with a through hole 73e at a position where the pinch valve 61 can visually confirm the portion where the chemical liquid supply path C is closed. Therefore, it is possible not only to prevent the mistake that the chemical sterilizer 1 is caused to fail due to the failure of the soil sterilizer 1 due to the pinch valve 61, but also contributes to the specification of the failure location. That is, maintenance can be improved.

On the other hand, although the through hole 73e of the present embodiment is formed in a substantially circular shape, it is not limited thereto. That is, the through hole 73e is not limited so long as it can confirm the operation of the pinch valve 61, for example, in a substantially rectangular shape.

Hereinafter, the mounting and dismounting of the soil sterilizer 1 will be described.

The chemical liquid tank 31, the pinch valve 61 and the confirmation system 81 are disposed in the vicinity of the chemical liquid dispensing pump 41 as described above. Therefore, when the soil sterilizer 1 is mounted on the tractor 100, the chemical liquid supply portion 30 can be mounted without moving around the tractor 100. [ That is, as compared with the case where the tractor 100 is dispersed and mounted at both ends of the tractor 100, the tractor 100 can be easily mounted.

Further, even when the soil sterilizer 1 is separated from the tractor 100, it can be easily separated. That is, the maintenance performance of the soil sterilizer 1 can be improved by concentrating the chemical liquid tank 31, the pinch valve 61 and the confirmation system 81, which are chemical solution supply related members.

Hereinafter, in order to understand the effect of the present invention, the operation of the soil sterilizer in the case where the anchoring cork is provided in place of the pinch valve 61 will be described as means for closing the delivery tube 3.

The anisotropic cock is mounted on the delivery tube 3 and is closed or opened by an operator or the like to operate (turn) the delivery tube 3. Such an anisotropic cock is mounted in the vicinity of the control section 90, for example.

First, before driving the chemical liquid dispensing pump 41, the delivery tube 3 is opened by operating the anisotropic cock. Then, the pump switch 92 of the control unit 90 is switched to drive the chemical liquid dispensing pump 41. As a result, the chemical liquid is ejected from the chemical liquid injecting nozzle 12. In this state, the tractor 100 is moved to disinfect the soil.

When disinfection of the soil is finished, the pump switch 92 of the control unit 90 is switched to stop the chemical liquid dispensing pump 41. Then, the delivery tube 3 is closed by operating the anisotropic cock.

Here, in the soil sterilizer using the anisotropic coke, it is necessary to operate the anion cock before and after the chemical liquid feed pump 41 is driven.

Further, by repeating such an operation of the anisotropic coke several times, the anisotropic coke is deteriorated, and there is a possibility that the chemical solution may leak at the portion where the anisotropic coke is manipulated. At this time, there is a possibility that irritating odor is generated in the vicinity of the operator, which may cause inconvenience to the operator.

On the other hand, in the soil sterilizer 1 using the pinch valve 61, the pinch valve 61 operates in conjunction with the chemical liquid delivery pump 41. Therefore, it is not necessary to perform an operation (process) for closing the separate delivery tube 3 separately. That is, when the pinch valve 61 is used as a means for preventing the chemical liquid from falling off, the work process for soil disinfection can be simplified.

In addition, it is possible to prevent the chemical liquid from leaking from the operated part of the anisotropic coke generated when the anisotropic coke is used, and it is possible to prevent the irritating odor from being generated in the vicinity of the worker, thereby imposing a burden on the operator.

Further, in the case of disinfecting the soil with a soil sterilizer using an anisotropic coke by an operator unfamiliar with the operation, there is a possibility that the operation of opening the anicolor cock before driving the chemical liquid delivery pump 41 may be forgotten. In this case, the chemical liquid dispensing pump 41 can not send the chemical liquid sucked from the chemical liquid tank 31 to the chemical liquid injecting nozzle 12. That is, the chemical liquid dispensing pump 41 is loaded.

Moreover, there is a possibility that the operation of closing the aniocoke after the drug solution delivery pump 41 is stopped may be forgotten. In this case, when the chemical liquid dispensing pump 41 is stopped, the chemical liquid remaining in the chemical liquid dispensing pump 41 sometimes drops from the chemical liquid injecting nozzle 12. [

On the other hand, in the soil sterilizer 1 using the pinch valve 61, it is not necessary to perform an operation for closing or opening the separate delivery tube 3 like the exotic cock. Therefore, before the chemical liquid dispensing pump 41 is driven, it is possible to prevent the operation of the anorectory cork from being forgotten and the chemical liquid dispensing pump 41 to be loaded. In other words, it is possible to reduce the load applied to the chemical liquid dispensing pump 41, thereby contributing to an improvement in maintenance performance. Further, after the chemical liquid dispensing pump 41 is stopped, it is possible to forget the operation of closing the anion cock and to prevent the chemical liquid from falling from the chemical liquid injecting nozzle 12. [

When the soil sterilizer 1 is mounted on the tractor 100 having the cabin (refer to reference numeral 130 in FIG. 1), in the soil sterilizer using the anisotropic coke, in the vicinity of the driver's seat 116, (3), an anastomotic cock, and a control unit (90). In this case, because the delivery tube 3 can not open and close the door of the cabin, the soil sterilizer can not be attached to the tractor 100 having the cabin.

On the other hand, in the soil sterilizer 1 using the pinch valve 61, the delivery tube 3 is disposed outside the driver's seat 116. That is, even when the soil sterilizer 1 is mounted on the tractor 100 having the cabin, since the door of the cabin can be opened and closed by disposing the delivery tube 3 along the side surface of the tractor fender, The soil sterilizer 1 can be mounted on the tractor 100.

As described above, the soil sterilizer 1 for injecting the chemical liquid into the soil through the chemical liquid supply path C by the chemical liquid injecting nozzle 12 includes a chemical liquid dispensing pump 41 for sending the chemical liquid to the chemical liquid injecting nozzle 12 The chemical liquid supply-related member is concentratedly arranged in the vicinity of the liquid supply member.

The chemical liquid supply related member includes a chemical liquid tank 31 for storing the chemical liquid, a pinch valve 61 for preventing the chemical liquid from falling from the chemical liquid injecting nozzle 12 when the chemical liquid dispensing pump 41 is stopped, And a confirmation system 81 for confirming whether or not the chemical solution is sent out from the chemical liquid dispensing pump 41 to the chemical liquid injecting nozzle 12.

As a result, the soil sterilizer 1 can be easily mounted and separated. That is, maintenance can be improved.

When the chemical liquid dispensing pump 41 is stopped, the control unit 90 closes the chemical liquid supply path C by closing the pinch valve 61, and when the chemical liquid dispensing pump 41 is driven, 61) to open the chemical liquid supply path (C).

As a result, it is possible to prevent an accident that the anisotropic coke is closed, which is caused when the anisotropic coke is used. That is, since the chemical liquid dispensing pump 41 can be prevented from being driven while the chemical liquid supply path C is closed, the load applied to the chemical liquid dispensing pump 41 can be reduced, The burden on the user can be reduced. In addition, the work process of soil disinfection can be simplified.

Further, the pinch valve 61 closes the chemical liquid supply path C by externally applying pressure.

This makes it possible to prevent the pinch valve 61 from directly contacting the chemical liquid. That is, it is possible to reliably prevent the pinch valve 61 from being corroded by the chemical liquid. Therefore, maintenance can be improved.

The soil sterilizer 1 also has a cover member 71 for covering the pinch valve 61 from the outside.

As a result, the portion of the pinch valve 61 exposed to the outside can be reduced. That is, deterioration of the pinch valve 61 can be prevented, and maintenance and maintenance can be improved.

A pair of communication holes 73b and 73b are formed in the cover member 71 at a position corresponding to the chemical solution supply path C and a chemical solution supply path C is formed in the pair of communication holes 73b and 73b, (First delivery tube 3a) which is a constituent member of the delivery tube 3 (first delivery tube 3a).

Thus, since the center of the first liquid medicament delivery tube 3a can be exposed, the first liquid medicament delivery tube 3a can be reliably closed by the pinch valve 61. Further, the load applied to the delivery tube 3 when the pinch valve 61 closes the chemical liquid supply path C can be reduced. That is, maintenance can be improved.

A through hole 73e is formed in the cover member 71 at a position where the pinch valve 61 can visually confirm the portion where the chemical liquid supply path C is closed.

Accordingly, since the operation of the pinch valve 61 can be easily confirmed, it contributes to the specification of the failure point. That is, maintenance can be improved.

The chemical liquid delivery pump 41 of the present embodiment uses a diaphragm pump, but the present invention is not limited thereto. That is, the chemical liquid dispensing pump 41 may be a reciprocating drive type, for example, a plunger type.

It is preferable that the chemical liquid dispensing pump 41 and the connecting member (for example, the delivery tube 3) and the joint are disposed at positions away from the driver's seat 116. Thus, the burden on the operator from the chemical liquid can be further reduced.

Although the chemical solution supply unit 30 of this embodiment is mounted at the front portion of the tractor 100 traveling unit 110, it is not limited thereto. That is, the chemical liquid supply unit 30 may be mounted on the rear portion of the running unit 110 of the tractor 100. [ In this case, since the chemical liquid supply path C does not pass the driver's seat 116, the burden on the operator from the chemical liquid can be further reduced.

1: Soil disinfector
12: Chemical solution injection nozzle
30:
31: chemical tank
41: drug delivery pump
61: Pinch valve
71: cover member
81: Confirmation
100: Tractor

Claims (8)

A soil sterilizer (1) comprising a chemical liquid supply unit (30), a control unit (90), and a chemical liquid injection unit (10) and injecting a chemical liquid into the soil from the chemical liquid injection unit (10)
The soil sterilizer (1) is installed in a movable work vehicle (100), injects a chemical liquid into the soil along with the movement of the work vehicle (100)
The chemical liquid injecting portion 10 is mounted on the mounting portion 120 on the rear side of the driver's seat 116 of the working vehicle 100,
The chemical liquid supply unit 30 is disposed at a forward position away from the driver's seat 116 of the working vehicle 100,
A chemical solution supply path C connecting the chemical solution supply part 30 and the chemical solution injecting part 10 is disposed outside the driver's seat 116,
The chemical liquid supply unit 30 includes a chemical liquid tank 31 for storing a chemical liquid, a chemical liquid delivery pump 41, and a leakage preventing valve 61,
The leakage preventing valve 61 closes the chemical liquid supply path C by externally applying pressure from the outside in accordance with an instruction from the control unit 90 when the chemical liquid dispensing pump 41 stops, ) Is driven by a pinch valve that opens the chemical liquid supply path (C)
Wherein when the chemical liquid dispensing pump (41) is stopped, the chemical liquid is prevented from being dropped from the chemical liquid injecting section (10). The method according to claim 1,
Wherein the chemical liquid supply unit (30) comprises a confirmation system (81) for confirming whether the chemical liquid is being sent from the chemical liquid delivery pump (41) to the chemical liquid injection unit (10). The method according to claim 1,
And a cover member (71) for covering the leakage preventing valve (61) from the outside,
Wherein the cover member (71) is provided with a through hole (73e) at a position where the leakage preventing valve (61) can visually confirm a portion where the chemical liquid supply path (C) is closed. The method of claim 3,
The cover member 71 is formed with a pair of communication holes 73b and 73b at positions corresponding to the chemical solution supply path C and the chemical solution supply path 73b and 73b are formed in the pair of communication holes 73b and 73b, And a flexible member (75) for supporting the delivery tube (3) constituting the cleaning tank (C). delete delete delete delete

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