JP2016036271A - Granular material scattering apparatus, and scattering mobile vehicle having the same - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a granular material scattering apparatus enabled to enhance the convenience by effectively exploiting an electric motor for driving a let-off part.SOLUTION: A fertilizer applicator 8x comprises a hopper, a let-off part, drive input gears 49L and 49R, an electric motor 50x and drive output gears 53L and 53R. To the drive input gears 49L and 49R, there is inputted a driving force to the let-off part for letting off the fertilizer in the hopper. The drive output gears 53L and 53R output the driving force of the electric motor 50x to the drive input gears 49L and 49R. The fertilization applicator 8x can output the driving force of the electric motor 50x to the construction other than the drive input gears 49L and 49R.SELECTED DRAWING: Figure 12

Description

  The present invention mainly relates to a configuration for utilizing an electric motor that is a drive source of a feeding unit in a granular material spraying apparatus.

  Conventionally, a fertilizer applicator provided on the body of a rice transplanter is known. This fertilizer spreader applies solid granular fertilizer to the ground. The fertilizer applicator includes a hopper that is a container for storing fertilizer and a feeding unit that feeds the fertilizer in the hopper by a predetermined amount. Such a fertilizer applicator is described in Patent Document 1, for example.

  In the fertilizer application described in Patent Document 1, the driving force output from the engine of the vehicle body is input to the first upper fertilizer through a plurality of transmission shafts and clutches. Moreover, the fertilizer application of patent document 1 is provided with the connection mechanism for transmitting motive power from a 1st upper fertilizer to a 2nd upper fertilizer. With this configuration, the feeding portion of the first upper fertilizer and the second upper fertilizer is driven by the driving force of the engine.

JP 2010-130932 A

  Since the fertilizing apparatus described in Patent Document 1 is configured to drive the feeding portion by the driving force of the engine of the vehicle body, a transmission mechanism (such as a transmission shaft) for transmitting the driving force is provided between the engine and the feeding portion. is necessary. If the fertilizer is arranged at a position away from the engine, the transmission mechanism becomes long, and the cost and weight increase. Moreover, it is necessary to provide a clutch etc. between an engine and a fertilizer, and a transmission mechanism becomes complicated.

  Therefore, it is conceivable to provide an electric motor separately from the engine of the vehicle body and to drive the fertilizer applicator by the electric motor. Thus, if an electric motor is provided as a dedicated drive source for a fertilizer applicator, a clutch or the like as in the fertilizer application of Patent Document 1 becomes unnecessary. Moreover, since the electric motor has a high degree of freedom in arrangement, it can be arranged in the vicinity of the fertilizer applicator, the transmission mechanism from the electric motor to the fertilizer applicator can be shortened, and the configuration can be simplified.

  Thus, it is considered that the merit of providing a dedicated electric motor as a drive source for the fertilizer applicator is great. However, when a dedicated electric motor for the fertilizer is provided, when the fertilizer is not driven, the electric motor is not effectively used, and there remains room for improvement in this respect.

  The present invention has been made in view of the above circumstances, and a main object of the present invention is to provide a granular material spraying device that enhances convenience by effectively using an electric motor for driving a feeding portion. is there.

Means and effects for solving the problems

  The problems to be solved by the present invention are as described above. Next, means for solving the problems and the effects thereof will be described.

  According to the viewpoint of this invention, the granular material spreading | diffusion apparatus of the following structures is provided. In other words, the granular material spraying device includes a hopper, a feeding portion, a driven member, an electric motor, and an output member. The hopper contains a granular material. The feeding unit feeds the granular material in the hopper. A driving force to the feeding portion is input to the driven member. The electric motor is a drive source for the feeding section. The output member outputs a driving force of the electric motor to the driven member. The granular material spraying device is configured to be able to output the driving force of the electric motor to a configuration other than the driven member.

  According to this configuration, since the driving force of the electric motor can be used for other purposes, the convenience of the granular material spraying device can be enhanced.

  The granular material spraying apparatus preferably has the following configuration. That is, the granular material spraying device includes a connection / disconnection mechanism that can switch the output member between a state where the output member is connected to the driven member and a state where the output member is disconnected from the driven member. The granular material spraying device is configured to be capable of outputting the driving force of the electric motor to a configuration other than the driven member in a state where the output member is separated from the driven member.

  According to this configuration, the driving force of the electric motor can be used for other purposes in a state where the output member is separated from the driven member (that is, the state where the feeding portion is not driven by the electric motor).

  The granular material spraying apparatus preferably has the following configuration. That is, a second driven member to which a driving force for a configuration other than the feeding portion is input is provided separately from the driven member. The connecting / disconnecting mechanism moves the output member in a direction away from the driven member, thereby separating the output member from the driven member and connecting the output member to the second driven member.

  According to this configuration, the output member can be connected to one of the driven member and the second driven member. When the output member is connected to the driven member, a driving force is output to the feeding portion via the driven member. On the other hand, when the output member is connected to the second driven member, the driving force can be output to the configuration other than the feeding portion via the second driven member. As described above, any one of the feeding portion and the other configuration can be selectively driven by the electric motor. Therefore, the electric motor when the feeding portion is not driven can be used effectively.

  The granular material spraying apparatus preferably has the following configuration. That is, the output member is an output gear. The driven member is a driven gear. The second driven member is a second driven gear. The driven gear and the second driven gear are arranged so as to be able to mesh with the output gear, respectively.

  According to this configuration, by separating the output gear from the driven gear, the meshing between the output gear and the driven gear can be released and the output gear can be meshed with the second driven gear. Therefore, the output destination of the driving force can be switched with a simple configuration.

  The granular material spraying apparatus preferably has the following configuration. That is, the granular material spraying device includes a speed reducer that decelerates the output of the electric motor and outputs it to the output member. In a state where the output member is separated from the driven member, the driving force of the electric motor decelerated by the speed reducer can be output to a configuration other than the driven member.

  Thereby, structures other than a delivery part can be driven, without providing a reduction gear separately.

  The granular material spraying apparatus preferably has the following configuration. That is, the hopper is supported so as to be rotatable around a rotation axis. The fluid spraying device rotates the hopper around the rotation shaft by the driving force of the electric motor decelerated by the speed reducer.

  According to this configuration, the hopper can be rotated around the rotation axis by using the driving force of the electric motor. Therefore, the granular material remaining in the hopper can be easily discharged. Further, even if the hopper is heavy due to the granular material, the hopper can be strongly rotated by the driving force of the electric motor whose torque is enhanced by the speed reducer.

  The granular material spraying apparatus is preferably configured to be able to output the driving force of the electric motor decelerated by the speed reducer to a rotary tool.

  According to this configuration, the rotary tool can be strongly rotated using the driving force of the electric motor whose torque is enhanced by the speed reducer.

  The above-mentioned granular material spraying device can be configured as follows. That is, the granular material spraying device includes a speed reducer that decelerates the output of the electric motor and outputs it to the output member. In a state where the output member is separated from the driven member, the driving force of the electric motor can be output to a configuration other than the driven member without passing through the speed reducer.

  That is, since the feeding portion needs to be driven at a relatively low speed, a reduction gear is provided between the output shaft of the electric motor and the output member, so that the driving force of the electric motor is decelerated and output from the output member. On the other hand, by outputting the driving force of the electric motor to the outside without decelerating, it is possible to drive the components other than the feeding unit at a relatively high speed.

  In the granular material spraying device, it is preferable that the driving force of the electric motor can be output to a fan that generates an air flow.

  According to this configuration, a sufficient air volume can be obtained by rotating the fan at a relatively high speed by the electric motor.

  According to another aspect of the present invention, a scattering work vehicle including the granular material spraying device, a vehicle body that can travel by mounting the granular material spraying device, and an engine that is a travel drive source of the vehicle body. Is provided.

  Thereby, the motive power of the electric motor of a granular material spreading | diffusion apparatus can be utilized effectively, and a highly convenient spreading work vehicle can be provided. Further, since the electric motor can be driven independently of the engine of the vehicle body, the electric motor can be widely used.

The side view which shows the whole structure of the rice transplanter which concerns on one Embodiment of this invention. The skeleton figure which shows the power transmission structure of a rice transplanter. The skeleton figure which shows the power transmission structure which concerns on a planting part and a fertilizer applicator. The rear view of a fertilizer applicator. The top view of a fertilizer applicator. The side view of a fertilizer applicator. Side surface sectional drawing of a fertilizer applicator. The perspective view which shows the structure of the electric motor which drives a fertilizer applicator. The rear view which shows a mode that the supply part of the fertilizer applicator was rotated. The side view which shows a mode that a feeding part is spaced apart from a conveyance part. Side surface sectional drawing which shows a mode that a feeding part is spaced apart from a conveyance part. The perspective view which shows the fertilizer machine of the 1st modification comprised so that the motive power of an electric motor could be utilized elsewhere. The front view which emphasizes and shows the structure for raising / lowering a supply part in the fertilizer application of a 1st modification. The front view which shows the fertilizer application of the 2nd modification which changed arrangement | positioning of an electric motor. The rear view which shows the fertilizer application of the 3rd modification which has arrange | positioned the electric motor to the supply part side. The rear view which shows a mode that the supply part was rotated in the fertilizer applicator of the 3rd modification. The side view which shows the fertilizer application of the 4th modification which changed the direction which a supply part rotates. The block diagram which shows the structure which controls the electric motor of a fertilizer applicator. The front view of the operation panel for operating a fertilizer applicator. The graph which shows the example of control of the drive speed of an electric motor. The fragmentary sectional view which shows the discharge | release guide member with which the grooving machine of a fertilizer applicator is equipped.

  Next, embodiments of the present invention will be described with reference to the drawings. FIG. 1 is a side view of a rice transplanter 1 according to an embodiment of the present invention.

  As shown in FIG. 1, a rice transplanter 1 as a spreading work vehicle (work vehicle) according to the present embodiment includes a vehicle body 2, a planting unit (work unit) 3 disposed behind the vehicle body 2, and a fertilizer applicator. (Granular material dispersion device) 8.

  The vehicle body 2 includes a pair of left and right front wheels 4 and a rear wheel 5, and is configured to be able to travel by the driving force of the engine 10. In addition, a driver's seat 6 on which an operator rides is provided at a position between the front wheel 4 and the rear wheel 5 in the front-rear direction of the vehicle body 2. In front of the driver seat 6, a steering handle 7 for the operator to steer the vehicle body 2 is disposed.

  In addition, spare seedling stands 9 are provided on the left and right of the steering handle 7. A seedling box containing spare mat seedlings can be mounted on the spare seedling stand 9.

  The planting part 3 is connected to the rear of the vehicle body 2 via a lifting link mechanism 12. In addition, a PTO shaft 13 for outputting the driving force of the engine 10 to the planting unit 3, an elevating cylinder 14 for driving the planting unit 3 up and down, and the like are disposed at the rear part of the vehicle body 2.

  The elevating link mechanism 12 includes a parallel link mechanism including a top link 18, a lower link 19, and the like. Further, the elevating cylinder 14 is connected to the lower link 19. The entire planting part 3 can be raised and lowered by extending and retracting the lifting cylinder 14.

  The planting unit 3 includes a line drawing marker 16 (rotating marker, rotating body), a seedling stage 17, and a plurality of planting units 20.

  Each planting unit 20 is configured as a rotary planting device provided with two planting claws 22 in a rotating case 21. The rotating case 21 is rotationally driven by the driving force input from the engine 10 via the PTO shaft 13 so as to plant seedlings. Therefore, the engine 10 is a drive source for the planting unit 3. In addition, the rice transplanter of this embodiment is comprised as a 4-row planting rice transplanter, and is provided with the planting unit 20 for 4 strips arranged in the left-right direction of the vehicle body 2.

  The drawing marker 16 is disposed on each of the left and right sides of the vehicle body 2. In FIG. 1, in order to show the configuration of the fertilizer applicator 8 in an easy-to-understand manner, the drawing marker 16 that should be drawn with a solid line is shown with a chain line. The left and right drawing markers 16 are rotatably attached to the tip of the marker support arm 58. As shown in FIG. 1, the left and right drawing markers 16 each have a marker state in which the marker support arm 58 is substantially upright and the drawing marker 16 is lifted from the ground, and the marker support arm 58 is tilted in a direction away from the vehicle body 2 It is possible to switch between the contact state in which the line drawing marker 16 is in contact with the ground.

  By running the vehicle body 2 with the drawing marker 16 in contact with the ground, the drawing marker 16 rotates while rolling on the ground. Thereby, a reference line can be clearly formed on the ground. This reference line is drawn in parallel with the seedling line planted by the planting claws 22 of the planting unit 20. In addition, since the some nail | claw part is provided in the outer periphery of the drawing marker 16, the drawing marker 16 rotates without the nail | claw part biting into the ground and slipping. For this reason, the reference line which the drawing marker 16 draws on the ground is clear. The operator can plant in parallel with the seedlings planted so far by running the rice transplanter 1 while referring to the reference line.

  The seedling placing stand 17 is arranged above the planting unit 20 and is configured to be able to place a mat seedling. In addition, since the rice transplanter of this embodiment is 4 row planting, the seedling mounting stand 17 is comprised so that the mat seedlings for 4 rows can be mounted side by side in the left-right direction of the vehicle body 2.

  The seedling stage 17 includes a transport mechanism (a well-known vertical feed mechanism and horizontal feed mechanism) that supplies the mat seedlings to the planting units 20. Thereby, since a seedling can be sequentially supplied with respect to each planting unit 20, each planting unit 20 can plant a seedling.

  The fertilizer applicator 8 is a device that sprays fertilizer (granular material), which is a granular solid, on the field. The detailed configuration of the fertilizer applicator 8 will be described later.

  Then, the drive transmission path | route in the rice transplanter 1 of this embodiment is demonstrated with reference to FIG.2 and FIG.3. FIG. 2 is a skeleton diagram showing a power transmission configuration of the rice transplanter 1. FIG. 3 is a skeleton diagram showing a power transmission configuration related to the planting unit 3 and the fertilizer applicator 8.

  As shown in FIG. 2, the driving force of the engine 10 is input to a mission case 71 disposed in front of the engine 10 via a drive transmission belt 70. A hydraulic continuously variable transmission 72 is provided inside the mission case 71, and the driving force of the engine 10 is shifted by the hydraulic continuously variable transmission 72. As this hydraulic continuously variable transmission 72, for example, a known HST (hydrostatic continuously variable transmission) or the like can be employed. The gear ratio of the hydraulic continuously variable transmission 72 can be changed by the operator operating the shift pedal.

  A part of the output from the hydraulic continuously variable transmission 72 is input to the gear-type main transmission 74 via the main clutch 73 to be shifted. The main transmission device 74 is configured to be switchable by an operator operating a main transmission lever. The main transmission lever is configured to be able to select at least the positions of “forward”, “reverse”, and “seed”. When the main transmission lever is operated to the “advance” position, axles 75 and 76, which will be described later, are driven to rotate in the direction in which the vehicle body 2 is advanced. On the other hand, when the main transmission lever is operated to the “reverse” position, the axles 75 and 76 are rotationally driven in a direction in which the vehicle body 2 is moved backward. Further, when the main transmission lever is operated to the “seed joint” position, the transmission of drive to the axles 75 and 76 and the PTO shaft 13 is cut off.

  A part of the rotational driving force shifted by the main transmission 74 is transmitted to a front axle case 77 formed integrally with the transmission case 71 to rotationally drive the front axles 75L and 75R that are the axles of the front wheels 4. Further, a part of the rotational driving force shifted by the main transmission 74 is input to the rear axle case 79 via a propeller shaft 78 protruding rearward from the transmission case 71, and the rear axle 76L, which is the axle of the rear wheel 5. , 76R are driven. With the above configuration, the vehicle body 2 can be driven by driving the front wheels 4 and the rear wheels 5. The traveling speed of the vehicle body 2 can be arbitrarily changed by the operator operating the shift pedal.

  A left side clutch 80L is disposed between the drive transmission path from the propeller shaft 78 to the left rear axle 76L. Similarly, a right side clutch 80R is disposed between the drive transmission path from the propeller shaft 78 to the right rear axle 76R. The left and right side clutches 80L and 80R can switch connection / disconnection independently of each other.

  Part of the output of the hydraulic continuously variable transmission 72 is taken out from the rear end of the transmission case 71 and input to the planting transmission unit 82 via the planting drive transmission shaft 81. A speed change device composed of a plurality of gears is provided in the planting speed change portion 82, and is configured to appropriately shift the input driving force and output it from the PTO shaft 13. The planting part 3 shown in FIG. 3 is driven by the driving force transmitted by the PTO shaft 13. With the above configuration, the speed at which the rotary case 21 is rotationally driven can be changed, so that the interval for planting seedlings can be changed.

  In the planting transmission unit 82 shown in FIG. 2, the driving force is transmitted to the PTO shaft 13 via the planting clutch 83. By cutting the planting clutch 83, the driving of the planting unit 3 can be stopped. The connection / disconnection of the planting clutch 83 can be switched by the operator operating a planting clutch operating lever (not shown). The planting clutch 83 can also be switched by a controller (not shown) that controls the operation of the vehicle body 2 and the planting unit 3 of the rice transplanter 1.

  In the mission case 71, a rotation sensor (working speed detector) 84 for detecting the rotation of the planting drive transmission shaft 81 is attached. The rotation sensor 84 can be configured by a rotary encoder, for example. The planting clutch 83 is provided with a planting clutch sensor 89 capable of detecting connection / disconnection of the planting clutch 83. The detection results of the rotation sensor 84 and the planting clutch sensor 89 are input to a control unit 60 (FIG. 18) described later provided in the fertilizer applicator 8.

  The power output from the planting transmission unit 82 is input into the planting case 85 of the planting unit 3 shown in FIG. 3 via the PTO shaft 13. The driving force input to the planting case 85 is transmitted to the rotary case drive shaft 88 via the plurality of transmission shafts 86 and the plurality of transmission gears 87. The rotating case 21 of the planting unit 20 is attached to both ends of the rotating case drive shaft 88.

  With the above configuration, the rotary case 21 can be rotationally driven, so that seedlings can be planted by the planting unit 20 configured as a rotary planting device.

  As described above, the driving force input to the rotary case drive shaft 88 is shifted according to the operation amount of the shift pedal by the HST in the mission case 71. On the other hand, the traveling speed of the vehicle body 2 is also changed according to the operation amount of the shift pedal. Therefore, the rotational speed of the rotating case 21 (and thus the planting speed of the planting unit 3) changes according to the traveling speed of the vehicle body 2. More specifically, when the vehicle body 2 travels at a high speed, the rotation cycle of the rotating case 21 is shortened, and when the vehicle body 2 is traveled at a low speed, the rotation cycle of the rotating case 21 becomes longer. Thereby, seedlings can be planted at equal intervals regardless of the traveling speed of the vehicle body 2.

  Next, the fertilizer applicator 8 with which the rice transplanter 1 of this embodiment is provided is demonstrated in detail. 4 is a rear view of the fertilizer applicator 8, and FIG. FIG. 6 is a side view of the fertilizer applicator 8, and FIG.

  As shown in FIGS. 4 and 5, the fertilizer applicator 8 includes a fertilizer application frame (base unit) 55, a hopper 27, a feeding unit 11, a transport unit 33, a blower 37, and an air supply pipe 38. ing.

  The fertilizer frame 55 is configured as a frame-like structure that supports the hopper 27, the feeding unit 11, the transport unit 33, the blower 37, the air supply pipe 38, and the like, and is fixed to the vehicle body 2. The fertilizer application frame 55 includes a plurality of rod-like members 56 arranged along the left-right direction of the machine body, a connecting plate 57 that connects these rod-like members 56, and support stays 48L and 48R. The support stays 48 </ b> L and 48 </ b> R are disposed at both left and right end portions of the fertilization frame 55. A plurality of connecting plates 57 are provided side by side in the left-right direction of the machine body at an appropriate interval between the support stays 48L and 48R.

  As shown in FIG. 1, the hopper 27 is disposed at a position between the driver seat 6 and the seedling stage 17 in the front-rear direction of the vehicle body 2. As shown in FIG. 4, the hopper 27 includes a hopper body 30 and a lid portion 31. The hopper body 30 is configured as a container having an open top, and fertilizer is accommodated in the hopper body 30. The lid portion 31 is disposed so as to cover the open portion at the top of the hopper body 30.

  As shown in FIGS. 4, 6, and 7, the lower portion of the hopper body 30 is a passage portion 32 that is formed in a funnel shape so as to become narrower as it approaches the lower side. Since the lower portion of the passage portion 32 is open, the fertilizer in the hopper body 30 flows downward through the passage portion 32.

  Next, the feeding unit 11 will be described. The feeding portion 11 is disposed below the hopper 27. The feeding unit 11 is configured to feed the fertilizer supplied from the hopper 27 downward little by little.

  The feeding portion 11 includes a feeding case 28 that is formed in a hollow shape, and a guide portion 40 that is fixed to the lower portion of the feeding case 28. The feeding case 28 is configured to be attached to the lower portion of the passage portion 32 of the hopper body 30. As shown in FIG. 7, a fertilizer inflow space 25 is formed inside the feeding case 28. The fertilizer inflow space 25 communicates with the passage portion 32. Accordingly, the fertilizer supplied from the hopper 27 flows into the fertilizer inflow space 25.

  As shown in FIG. 7, in the feeding case 28, a feeding plate (feeding rotary body) 15 is disposed in the lower part of the fertilizer inflow space 25. The feeding plate 15 is a member formed in a substantially disc shape. A rotating shaft 23 is fixed to the axial center of the feeding plate 15.

  A driven bevel gear 34 is fixed to the rotating shaft 23 of the feeding plate 15. Further, the drive shaft 26 is rotatably supported by the feeding case 28. As shown in FIG. 7, a drive side bevel gear 35 is fixed to the drive shaft 26. The driving side bevel gear 35 meshes with the driven side bevel gear 34.

  For example, as shown in FIG. 3, the driving force output by the electric motor 50 that is a driving source is input to the driving shaft 26 (details will be described later). The driving force is transmitted to the rotary shaft 23 via the bevel gears 34 and 35. Thereby, the feeding plate 15 is rotationally driven around the rotation shaft 23.

  As shown in FIG. 7, the feeding plate 15 has a plurality of feeding holes 24 penetrating the feeding plate 15 in the thickness direction. The feeding hole 24 is formed in a size that can accommodate a predetermined amount (about 1 to several grains) of fertilizer. Thereby, the fertilizer in the fertilizer inflow space 25 is taken into the feeding hole 24 by a predetermined amount. In this manner, when the predetermined amount of fertilizer is taken into the feeding hole 24, the feeding plate 15 is driven to rotate, so that the feeding hole 24 in the state in which the fertilizer is taken moves around the rotation shaft 23. When the position of the feeding hole 24 coincides with a predetermined feeding position, the fertilizer that has been taken into the feeding hole 24 is released downward. With the above configuration, the fertilizer in the hopper 27 can be fed downward by a predetermined amount (from one to several grains).

  The guide portion 40 is formed in a hollow shape and is fixed to the lower portion of the feeding case 28. As shown in FIG. 7 and the like, the upper portion of the guide portion 40 is open and connected to the lower end portion of the feeding case 28. Moreover, the guide part 40 is formed in the funnel shape so that it may become thin gradually as it approaches a lower side. The lower end of the guide unit 40 is configured to be connectable to a connection path 41 of the transport unit 33 described later. In addition, an elastically deformable connection ring 65 is fixed to the lower end of the guide portion 40.

  Next, the air supply pipe 38 and the blower 37 will be described. The air supply pipe 38 is a substantially pipe-shaped member formed in a straight line, and is disposed along the left-right direction of the vehicle body 2 as shown in FIG. The air supply pipe 38 is disposed so as to penetrate through the plurality of connecting plates 57 and is fixed to the fertilization frame 55. One end of the air supply pipe 38 (the right end in the present embodiment) is closed, and the blower 37 is connected to the other end (the left end in the present embodiment). Has been. The air supply pipe 38 is fixed so as not to move relative to the vehicle body 2. The blower 37 is attached to the fertilization frame 55 and is configured to send air into the air supply pipe 38.

  Next, the transport unit 33 will be described. The transport unit 33 includes a connection path 41, a transport hose 42, and a groove generator 43.

  The connection path 41 is disposed below the guide part 40 provided in the feeding part 11. As shown in FIG. 7 and the like, the connection path 41 is formed in a circular tube shape, and is disposed substantially along the front-rear direction of the vehicle body 2. An introduction port is opened at an upper portion of the intermediate portion in the front-rear direction of the connection path 41, and a lower end portion of the guide portion 40 can be connected to the introduction port via the connection ring 65. Thereby, the internal space of the connection path 41 communicates with the guide unit 40. In the present embodiment, the guide portion 40 (connection ring 65) is configured as a member different from the connection path 41, and is configured to be connectable / separable from each other.

  An air supply pipe 38 is connected to the front end of the connection path 41. As a result, the air flow generated by the blower 37 is supplied into the connection path 41 via the air supply pipe 38 and flows backward in the connection path 41. The connection path 41 is fixed to the fertilization frame 55 so as not to move relative to the air supply pipe 38.

  With the above configuration, the fertilizer fed by the feeding unit 11 is introduced into the connection path 41 through the introduction port. Then, the fertilizer introduced into the connection path 41 is transported backward on the air flow.

  A conveyance hose 42 is connected to the rear end of the connection path 41. The conveyance hose 42 is a tubular member having flexibility. As shown in FIG. 1, a groove forming device 43 arranged close to the ground is connected to the end of the transport hose 42 on the side opposite to the connection path 41. The grooving device 43 can form a groove in the field and allow the material to fall on the groove portion. With this configuration, the fertilizer rides on the air flow generated by the blower 37 and is transported through the transport hose 42 to the grooving device 43, and from the grooving device 43 to the ground (groove) that is the application target surface. Is released towards.

  With the fertilizer applicator 8 configured as described above, the fertilizer in the hopper 27 can be fed out by a predetermined amount by the feeding unit 11 and can be transported to the ground by the transport unit 33 and sprayed.

  In addition, since the rice transplanter of this embodiment is 4 row planting, the fertilizer applicator 8 of this embodiment has four feeding parts 11 and four conveyance parts 33 so that four fertilizers can be sprayed simultaneously. These are provided side by side in the left-right direction of the vehicle body 2 (see FIG. 4).

  Moreover, the hopper 27 of this embodiment is comprised so that the fertilizer for 2 strips may be accommodated. That is, as shown in FIG. 4, the lower part of each hopper body 30 is divided into two parts to form two passage parts 32. The feeding portion 11 is connected to each passage portion 32. Thereby, the fertilizer can be supplied to the two feeding parts 11 by one hopper 27.

  In the fertilizer applicator 8 of the present embodiment, the two hoppers 27 are arranged side by side in the left-right direction of the vehicle body 2 so that the four fertilizers can be accommodated. Here, the left hopper 27 may be referred to as a left hopper 27L, and the right hopper 27 may be referred to as a right hopper 27R.

  As described above, the fertilizer applicator 8 has the drive shaft 26 for rotationally driving the feeding plate 15 of the feeding unit 11. In the present embodiment, the two feeding portions 11 provided in one hopper 27 are configured to be driven by a single common drive shaft 26. Therefore, the fertilizer applicator 8 of this embodiment has two drive shafts 26. Specifically, as shown in FIG. 4, the fertilizer applicator 8 includes a left drive shaft 26L and a right drive shaft 26R. The left and right drive shafts 26L and 26R are independent of each other.

  As shown in FIG. 4, the left drive shaft 26L is disposed across the two feeding portions 11 connected to the left hopper 27L. By inputting a driving force to the left driving shaft 26L, the two feeding parts 11 connected to the left hopper 27L can be driven simultaneously.

  As shown in FIG. 4, the right drive shaft 26 </ b> R is disposed across the two feeding portions 11 connected to the right hopper 27 </ b> R. By inputting a driving force to the right drive shaft 26R, the two feeding parts 11 connected to the right hopper 27R can be driven simultaneously.

  On the left and right drive shafts 26L, 26R, drive input gears (driven gears, driven members) 49L, 49R are fixed on the inner side in the left-right direction of the vehicle body 2, respectively. The drive input gears 49L and 49R can mesh with drive output gears (output gears and output members) 53L and 53R included in the electric motor 50 described later, respectively.

  Next, the electric motor 50 provided to drive the fertilizer applicator 8 through the drive shafts 26L and 26R will be described in detail with reference to FIGS. FIG. 8 is a perspective view showing the configuration of the electric motor 50 of the fertilizer applicator 8.

  The vehicle body 2 (specifically, the fertilizer application frame 55 of the fertilizer applicator 8) is provided with an electric motor 50 that is a drive source of the fertilizer applicator 8, as shown in FIGS. That is, the fertilizer applicator 8 is not supplied with driving force from the planting unit 3 of the rice transplanter 1 or the engine 10 that is the driving source of the vehicle body 2, but is driven by the electric motor 50 that is a special driving source. The electric motor 50 is configured as a brushless DC motor, for example, and includes a rotary housing 51 and a fixed shaft 52.

  As shown in FIG. 8, the rotary housing 51 is formed in a cylindrical shape, and a rotor, a stator, and a speed reducer (not shown) are incorporated therein. The rotary housing 51 is disposed at the center of the left and right sides of the vehicle body 2 with its axis line directed in the left and right direction of the vehicle body 2.

  As described above, in the fertilizer applicator 8 of the present embodiment, the four feeding units 11 and the four transport units 33 are provided side by side in the left-right direction of the vehicle body 2. In other words, the fertilizer applicator 8 is provided with four paths that pass when the fertilizer in the hopper 27 is sprayed. And as shown in FIG. 4 etc., when it sees in the direction perpendicular | vertical to the direction where the fertilizer path | route for four said strips is arranged, while the electric motor 50 (rotating housing 51) is arrange | positioned in the position lower than the hopper 27, Of the four fertilizer paths, the two fertilizer paths adjacent to each other on the center side of the fuselage are arranged. As described above, the electric motor 50 is disposed at a position avoiding the fertilizer paths for a plurality of strips, thereby realizing a compact configuration that does not easily disturb the work. Moreover, while the electric motor 50 is arrange | positioned between adjacent fertilizer paths | routes, while being able to avoid interference with the planting part 3 etc. of the rice transplanter 1, reducing the width | variety of the fertilizer application machine 8 in a machine body left-right direction. Can do.

  Further, the fertilizer applicator 8 of the present embodiment is configured such that the hopper 27, the feeding unit 11, the transport unit 33, the electric motor 50, and the like are attached to the fertilizer frame 55 and the rotating stay 47. Accordingly, a coherent configuration is realized with the fertilizer frame 55 and the rotation stay 47 as the center, and it is easy to retrofit the existing rice transplanter 1 for use.

  The fixed shaft 52 is configured as a round bar-shaped shaft disposed so as to coincide with the axis of the cylindrical rotary housing 51. Both ends of the fixed shaft 52 are configured to protrude from the rotary housing 51. Further, among the plurality of connecting plates 57 constituting the fertilization frame 55, two connecting plates 57 on the center side of the machine body, which are arranged so as to sandwich the rotating housing 51 therebetween, are respectively connected to fixed stays 54 (on the left side). The fixed stay 54L and the right fixed stay 54R) are formed so as to protrude upward. Both ends of the fixed shaft 52 are fixed to the upper ends of the pair of fixed stays 54L and 54R so as not to rotate.

  A pair of drive output gears 53 are fixed to both end surfaces of the rotating housing 51 in the axial direction. Specifically, the left drive output gear 53L is disposed on the left end surface of the rotary housing 51, and the right drive output gear 53R is disposed on the right end surface. The drive output gears 53 </ b> L and 53 </ b> R are each configured as a spur gear, and the axis thereof coincides with the rotation axis of the rotary housing 51.

  In this configuration, when the electric motor 50 is driven by supplying electric power, the rotary housing 51 rotates with respect to the fixed shaft 52, and the drive output gears 53L and 53R also rotate integrally. Thereby, the motive power of the electric motor 50 can be taken out via the drive output gears 53L and 53R. Therefore, in the present embodiment, the rotary housing 51 corresponds to the output shaft of the electric motor 50. The axis of the output shaft is arranged in parallel with the axis of the drive shafts 26L and 26R.

  As described above, the electric motor 50 provided in the fertilizer applicator 8 of the present embodiment is configured not to fix the housing and rotate the output shaft but to output the driving force by rotating the entire rotating housing 51. ing. For this reason, since it becomes difficult for the powder of manure to accumulate on the rotation housing 51, the trouble of cleaning can be reduced and the occurrence of rust can be prevented.

  In addition, as shown in FIG. 8, you may provide the brush (cleaning member) 96 so that the surface (for example, outer peripheral surface) of the rotation housing 51 may be contacted. In this case, since the cleaning with the brush 96 is performed simultaneously with the rotation of the rotary housing 51, the electric motor 50 can be kept clean.

  The electric motor 50 according to the present embodiment incorporates a reduction gear using, for example, a planetary gear mechanism so that a rotation output decelerated at an appropriate reduction ratio (for example, about 1/20) can be obtained from the rotary housing 51. It has become. Therefore, rotation at an appropriate speed for driving the feeding unit 11 can be taken out without providing a large speed reduction mechanism.

  In the present embodiment, the electric motor 50 is configured such that the fixed shaft 52 protrudes from both axial sides of the rotary housing 51, and both ends thereof are fixed to the fixed stays 54L and 54R, respectively. . As described above, since both ends are supported, even if a reaction force is applied to the electric motor 50 side when driving the drive input gears 49L and 49R, it is possible to reduce the bending that occurs in the configuration.

  Next, the rotation mechanism of the hopper 27 will be described. FIG. 9 is a rear view showing a state where the supply unit of the fertilizer applicator 8 is rotated.

  That is, the fertilizer applicator 8 of the present embodiment is configured to be able to rotate the hopper 27 so that the fertilizer in the hopper 27 can be discharged to the outside. That is, from the state shown in FIG. 4, the lid 31 is removed from the hopper body 30 and the hopper body 30 is rotated so that the upper open portion faces downward (state shown in FIG. 9). The fertilizer inside can be discharged. Moreover, since the hopper body 30 can be rotated as described above, maintenance such as cleaning the inside of the hopper body 30 can be easily performed.

  The configuration that enables the hopper 27 to rotate will be described in detail as follows. That is, the fertilizer applicator 8 of the present embodiment includes a rotation shaft 46 and a rotation stay 47 as shown in FIG. The rotating stay 47 and the fertilization frame 55 described above constitute an attachment member for attaching the fertilizer applicator 8 to the rice transplanter 1.

  As described above, the fertilizer applicator 8 of the present embodiment has the two hoppers 27 (the left hopper 27L and the right hopper 27R) arranged in the left-right direction of the vehicle body 2. Therefore, in the present embodiment, as shown in FIG. 4, the rotation shaft 46 and the rotation stay 47 are provided on the left side and the right side of the fertilizer applicator 8, respectively. Further, as described above, the support stays 48 are disposed at the left and right ends of the fertilization frame 55, respectively. In the following description and drawings, the structure on the left side is indicated when “L” is appended to the reference numeral, and the structure on the right side is indicated when “R” is appended after the reference numeral.

  The support stay 48 forms a part of the fertilization frame 55 fixed to the vehicle body 2. That is, the support stay 48 is fixed to the vehicle body 2. The left support stay 48 </ b> L is disposed in the vicinity of the left end of the air supply pipe 38. The right support stay 48R is disposed in the vicinity of the right end of the air supply pipe 38.

  A rotating shaft 46 is supported on the support stay 48. The rotation shaft 46 is disposed in parallel with the front-rear direction of the vehicle body 2. The left rotation shaft 46L is supported by the left support stay 48L, and the right rotation shaft 46R is supported by the right support stay 48R.

  As shown in FIG. 4, the rotation stay 47 is disposed substantially along the vertical direction. The lower end of the rotation stay 47 is supported by the support stay 48 via the rotation shaft 46. Thereby, the rotation stay 47 can rotate around the rotation shaft 46 with respect to the support stay 48. The left rotation stay 47L is supported by the left support stay 48L via the left rotation shaft 46L. The right rotation stay 47R is supported by the right support stay 48R via the right rotation shaft 46R.

  The upper end of the rotating stay 47 is fixed to the hopper body 30. Thereby, the hopper 27 can be rotated around the rotation shaft 46. Specifically, the upper end of the left rotating stay 47L is fixed to the left side surface of the hopper body 30 of the left hopper 27L. Thereby, the left hopper 27L can be rotated around the left rotation shaft 46L in the upper left direction (see arrow P in FIG. 9). Further, the upper end portion of the right rotating stay 47R is fixed to the right side surface of the hopper body 30 of the right hopper 27R. As a result, the right hopper 27R can be rotated to the upper right around the right rotation shaft 46R (see arrow Q in FIG. 9).

  In the present embodiment, as shown by a two-dot chain line in FIG. 5, the blower 37 can be retracted in a direction away from the left hopper 27 </ b> L. This is because the blower 37 is disposed immediately on the left side of the left hopper 27L as shown in FIG. 4, and thus interferes with the blower 37 when the left hopper 27L rotates. Thus, as described above, by allowing the blower 37 to be retracted from the left hopper 27L, the left hopper 27L can be rotated upward without interfering with the blower 37.

  As shown in FIG. 5, a handle 36 is provided corresponding to each of the left and right hoppers 27. The handle 36 is fixed to the hopper 27. Therefore, the operator can rotate the hopper 27 upward so that the hopper 27 jumps up around the rotation shaft 46 by grasping and lifting the handle. As shown in FIG. 5, the handle 36 of the present embodiment is disposed so as to protrude forward (toward the driver's seat 6) from the hopper 27. Thereby, the operator can easily perform the turning operation of the hopper 27 from the driver seat 6 side.

  In the present embodiment, the hopper 27 is configured to rotate integrally with the two feeding parts 11 connected to the hopper 27 when rotating around the rotation shaft 46 ( (See FIG. 9). Therefore, when the hopper 27 is rotated, an operation of separating the hopper 27 from the feeding portion 11 is not necessary.

  In order to allow the hopper 27 and the feeding part 11 to rotate integrally around the rotation shaft 46, the feeding part 11 needs to be separated from the transport part 33. Therefore, as shown in FIG. 11, the feeding unit 11 is configured to be separated upward from the connection path 41 of the transport unit 33.

  Further, as described above, since the driving shaft 26 is supported by the feeding case 28 of the feeding portion 11, it can be said that the hopper 27 rotates integrally with the driving shaft 26. Specifically, the left drive shaft 26L rotates integrally with the left hopper 27L around the left rotation shaft 46L. Further, the right drive shaft 26R rotates integrally with the right hopper 27R around the right rotation shaft 46R.

  As described above, in the fertilizer applicator 8 of the present embodiment, the hopper 27, the two feeding portions 11 attached to the hopper 27, and the drive shaft 26 arranged across the two feeding portions 11 are It can rotate integrally around the moving shaft 46. Here, the hopper 27, the feeding unit 11, and the drive shaft 26 supply fertilizer to the transport unit 33. Therefore, in the following description, among the configurations of the fertilizer applicator 8, the hopper 27, the feeding unit 11, and the drive shaft 26 are collectively referred to as a “supply unit”.

  More specifically, the left hopper 27L, the two feeding portions 11 attached to the left hopper 27L, and the left drive shaft 26L can rotate integrally around the left rotation shaft 46L (see FIG. 9 (see arrow P). Therefore, these are collectively referred to as the “left supply unit”. Further, the right hopper 27R, the two feeding portions 11 attached to the right hopper 27R, and the right drive shaft 26R can be rotated integrally around the right rotation shaft 46R (arrow Q in FIG. 9). See). Therefore, these are collectively referred to as the “right supply unit”.

  As described above, in the fertilizer applicator 8 of the present embodiment, the left and right supply units can rotate around the rotation shaft 46, respectively. Accordingly, the left and right supply units can move between the work position (FIGS. 4 and 5) and the discharge position (FIG. 9), respectively.

  Here, the work position of the supply unit refers to a position when the supply unit is in a state where fertilizer can be supplied to the transport unit 33. Specifically, each of the two feeding units 11 included in the supply unit is connected to the upper part of the connection path 41 of the corresponding transport unit 33 (the state illustrated in FIGS. 4, 6, and 7). The working position of the supply unit. In this state, by inputting a driving force to the drive shaft 26 provided in the supply unit, the feeding plates 15 of the two feeding units 11 provided in the supply unit are respectively driven to rotate, and two manures are fed out by a predetermined amount. Thus, the fertilizer can be supplied to the corresponding transport unit 33.

  By rotating the supply unit upward from the work position around the rotation shaft 46, the supply unit can be separated from the transport unit 33 (for example, the state of FIG. 9). The position of the supply unit in this state is called a discharge position. Note that the supply unit in this state cannot supply fertilizer to the conveyance unit 33.

  When the left supply unit is set to the above-described working position, the left drive shaft 26L is disposed so as to be substantially parallel to the left-right direction of the vehicle body 2, as shown in FIG. Further, the left supply unit has a left drive input gear 49L fixed to the left drive shaft 26L. The left drive input gear 49L is disposed in the vicinity of the end portion on the side close to the right supply portion (the right end portion) of the both ends of the left drive shaft 26L. The left drive input gear 49L is a spur gear (spur gear).

  Further, when the right supply unit is set to the above-described work position, the right drive shaft 26R is disposed so as to be substantially parallel to the left-right direction of the vehicle body 2, as shown in FIG. Further, the right supply unit has a right drive input gear 49R fixed to the right drive shaft 26R. The right drive input gear 49R is disposed in the vicinity of the end portion on the side close to the left supply portion (left end portion) among the both end portions of the right drive shaft 26R. The right drive input gear 49R is a spur gear (spur gear).

  As shown in FIGS. 4 and 5, when the left and right supply units are both in the working position, the left and right drive shafts 26L, 26R are aligned so that the axis lines of the left drive shaft 26L and the right drive shaft 26R coincide. Is arranged. At this time, the left and right drive input gears 49L and 49R are arranged adjacent to each other in the axial direction.

  As shown in FIGS. 4 and 5, the left drive input gear 49L is arranged to mesh with the left drive output gear 53L when the left supply unit is in the working position. By driving the electric motor 50 in this state, the rotational driving force is transmitted to the left drive shaft 26L via the left drive output gear 53L and the left drive input gear 49L. Thereby, the two feeding parts 11 with which the left supply part is equipped can be driven.

  As shown in FIGS. 4 and 5, the right drive input gear 49R is arranged to mesh with the right drive output gear 53R when the right supply unit is in the working position. By driving the electric motor 50 in this state, the rotational driving force is transmitted to the right drive shaft 26R via the right drive output gear 53L and the right drive input gear 49R. Thereby, the two feeding parts 11 with which the right supply part is equipped can be driven.

  As shown in FIGS. 3 to 5, the left and right drive input gears 49 </ b> L and 49 </ b> R can mesh with drive output gears 53 </ b> L and 53 </ b> R that rotate integrally with the rotary housing 51 in the electric motor 50, respectively. Arranged to be able to. With the above configuration, a driving force can be transmitted from one electric motor 50 to each of the left and right drive shafts 26L and 26R.

  In the above-described Patent Document 1, since the driving force is input only to the right driving shaft (first input shaft), the driving force is transmitted to the left driving shaft (second input shaft). Therefore, a connection mechanism that connects the left and right drive shafts is necessary. In this respect, in the present embodiment, since the driving force is transmitted from the single electric motor 50 to the left and right drive shafts 26L and 26R, the drive force is transmitted from the right drive shaft 26R to the left drive shaft 26L. There is no need to communicate. Therefore, the fertilizer applicator 8 of the present embodiment does not have a connection mechanism that connects the left and right drive shafts 26L and 26R. Thereby, the fertilizer applicator 8 can be comprised simply.

  As shown in FIG. 6, the axis center of the right drive input gear 49R is arranged at a position higher than the axis center of the right drive output gear 53R. In other words, the right drive input gear 49R is arranged to mesh with the right drive output gear 53R from above (obliquely upward).

  Accordingly, as shown in FIG. 10, the right drive input gear 49R is moved upward to release the meshing with the right drive output gear 53R and to be separated from the drive output gear 53R. Is possible. On the contrary, the right drive input gear 49R can be engaged with the right drive output gear 53R by making the right drive input gear 49R approach the right drive output gear 53R from above.

  Although the relationship between the right drive input gear 49R and the right drive output gear 53R has been described above, the relationship between the left drive input gear 49L and the left drive output gear 53L is the same.

  Therefore, as shown in FIG. 9, the left drive input gear 49L can be separated upward from the left drive output gear 53L by moving the left supply section from the work position to the discharge position ( (See arrow P in FIG. 9). As a result, the connection between the electric motor 50 and the left drive shaft 26L is released. Conversely, the left drive input gear 49L and the left drive output gear 53L can be engaged with each other by moving the left supply section from the discharge position to the work position (state shown in FIG. 4). Thereby, the electric motor 50 and the left drive shaft 26L are connected.

  As described above, according to the configuration of the present embodiment, the electric motor 50 and the left drive shaft 26L are connected or disconnected by moving the left supply portion around the left rotation shaft 46L. be able to. The connection and disconnection are realized by separating or approaching the left drive input gear 49L and the left drive output gear 53L. Therefore, a clutch or the like for realizing the connection and disconnection is unnecessary. Therefore, in the present embodiment, no clutch is provided between the electric motor 50 and the left drive shaft 26L.

  Similarly, by moving the right supply unit from the work position to the discharge position, the right drive input gear 49R can be separated upward from the right drive output gear 53R (arrow in FIG. 9). See Q). As a result, the connection between the electric motor 50 and the right drive shaft 26R is released. Conversely, the right drive input gear 49R and the right drive output gear 53R can be engaged with each other by moving the right supply unit from the discharge position to the work position (state shown in FIG. 4). As a result, the output shaft of the electric motor 50 and the right drive shaft 26R are connected.

  As described above, according to the configuration of the present embodiment, the right supply unit is moved around the right rotation shaft 46R to connect or disconnect between the electric motor 50 and the right drive shaft 26R. be able to. The connection and disconnection are realized by separating or approaching the right drive input gear 49R and the right drive output gear 53R. Therefore, a clutch or the like for realizing the connection and disconnection is unnecessary. Therefore, in this embodiment, no clutch is provided between the electric motor 50 and the right drive shaft 26R.

  In addition, in the above-mentioned patent document 1, when rotating a supply part (upper fertilizer machine), operation which cut | disconnects a clutch and a connection mechanism was required. For this reason, when forgetting the operation which cut | disconnects a clutch or a connection mechanism when rotating a supply part, there existed a possibility of damaging the said clutch or a connection mechanism.

  In this respect, since the fertilizer applicator 8 of the present embodiment does not have the clutch and the coupling mechanism as described above, the problem that the clutch and the coupling mechanism are damaged does not occur. In addition, when the supply unit is moved around the rotation shaft 46, it is not necessary to operate the clutch or the coupling mechanism. Therefore, the supply unit can be moved around the rotation shaft 46 with a simple operation.

  By the way, the clutch of patent document 1 controls connection / disconnection of an engine and a supply part (upper fertilizer). In the configuration of Patent Document 1, if the clutch is omitted, the supply unit cannot be disconnected from the engine, and the supply unit cannot be stopped. Therefore, in the configuration of Patent Document 1, the clutch is an essential configuration in order to separate and stop the supply unit from the engine.

  On the other hand, in the rice transplanter 1 of this embodiment, the electric motor 50 is provided as a drive source for exclusive use for driving the supply part of the fertilizer applicator 8. Since the electric motor 50 can be controlled independently of the engine 10, the electric motor 50 may be stopped to stop the supply unit. Thus, in the fertilizer applicator 8 of this embodiment, since a supply part is driven by the electric motor 50 as a dedicated drive source, a clutch for separating and stopping the supply part from the engine is unnecessary. As a result, the clutch can be omitted as described above.

  Moreover, in the rice transplanter 1 of this embodiment, when the drive source of the supply unit is the engine 10, it is necessary to provide a drive transmission mechanism for transmitting the drive from the engine 10 to the drive output gears 53L and 53R. . For this reason, it is difficult to dispose the drive output gears 53L and 53R at the center portion in the left-right direction of the vehicle body 2 due to restrictions on the layout of the drive transmission mechanism. As a result, it becomes difficult to dispose the drive output gears 53L and 53R at positions where the left and right drive input gears 49L and 49R can mesh with each other.

  In this respect, the electric motor 50 needs to be provided with a cable for connecting to a power supply source and supplying a control signal. It is easy to arrange 53L and 53R at the center in the left-right direction of the vehicle body 2. In this embodiment, as shown in FIGS. 4 and 5, the drive output gears 53L and 53R are arranged at the center in the left-right direction of the vehicle body 2, and therefore, the left and right drive inputs with respect to the drive output gears 53L and 53R. The gears 49L and 49R can mesh with each other.

  Patent Document 1 describes an operation member for performing an operation of releasing the above-described coupling mechanism. In Patent Document 1, the operation member is disposed in the vicinity of the handle (second gripping portion). Therefore, the operator can release the connection of the connection mechanism by holding the operation member together with the handle (second holding portion). Here, since the operation member needs to be disposed in the vicinity of the coupling mechanism, the handle (second grip portion) needs to be disposed in the vicinity of the coupling mechanism. As described above, in the configuration of Patent Document 1, the position of the handle is restricted.

  In this respect, since the fertilizer applicator 8 of the present embodiment does not have the clutch and the coupling mechanism as described above, an operation member for operating the clutch or the coupling mechanism is also unnecessary. Therefore, there is no restriction that the handle 36 must be disposed in the vicinity of the operation member. Thus, according to the configuration of the present embodiment, the handle 36 can be freely arranged. Accordingly, the handle 36 can be disposed at a position where the operator can easily grip it, so that the operation of moving the supply unit by gripping the handle 36 can be easily performed.

  Next, a first modification example in which the left and right supply units can be moved up and down by a driving force of an electric motor instead of manual work will be described with reference to FIGS. 12 and 13. FIG. 12 is a perspective view showing a fertilizer applicator 8x of a first modified example configured to be able to utilize the power of the electric motor 50x elsewhere. FIG. 13: is a front view which emphasizes and shows the structure for raising / lowering a supply part in the fertilizer applicator 8x of a 1st modification. In the description after the present modification, the same or similar members as those of the above-described embodiment may be denoted by the same reference numerals in the drawings, and the description may be omitted.

  In this modification, an electric motor 50x having a configuration in which the housing does not rotate is provided instead of the electric motor 50 shown in FIG. As shown in FIG. 12, the electric motor 50x includes a fixed housing 51x in which a reduction gear using, for example, a planetary gear mechanism is incorporated. The fixed housing 51x is fixed to the upper surface of the slide plate 131 installed so as to bridge between the two connecting plates 57 on the center side of the machine body.

  The output shaft of the electric motor 50x (that is, the output shaft of the speed reducer) protrudes from both sides of the fixed housing 51x, and drive output gears (output gears, output members) 53L and 53R are fixed to the protruding portions, respectively. . Therefore, by driving the electric motor 50x, the drive output gears 53L and 53R can be rotated with respect to the fixed housing 51x.

  Drive input gears (driven gears, driven members) 49L, 49R are arranged in the vicinity of the drive output gears 53L, 53R, as in the embodiment shown in FIG. Further, in the present embodiment, supply unit raising / lowering input gears (second driven gear, second driven member) 66L, 66R are disposed in the vicinity of the drive output gears 53L, 53R. The supply unit raising / lowering input gears 66L and 66R are configured to be able to mesh with the drive output gears 53L and 53R.

  The upper ends of the pair of connecting plates 57 are bent inward in the left-right direction of the machine body with a predetermined width, and a slide plate 131 is placed on the upper side. A plurality of elongated holes 132 elongated in the front-rear direction are formed in the slide plate 131, and a stepped bolt 133 inserted into the elongated hole 132 is fixed to a bent portion at the upper end of the connecting plate 57. As a result, the slide plate 131 can slide with a predetermined stroke in the front-rear direction.

  A lock mechanism 134 is disposed below the slide plate 131. The lock mechanism 134 includes a rod 135 slidably supported in the left-right direction of the machine body, a spring 136 that urges the rod 135 to one side in the longitudinal direction, and an operator pulling in a direction that resists the spring force of the spring 136. And a knob 137 capable of supporting the above.

  The rod 135 is attached to the lower surface side of the slide plate 131 with its longitudinal direction facing the left-right direction of the machine body. One end of the rod 135 protrudes through an elongated hole 138 formed in the connecting plate 57 on one side in the longitudinal direction, and the knob 137 is fixed to the end portion. On the other hand, on the other connection plate 57, three lock holes 139 into which the rod 135 can be inserted are formed side by side in the front-rear direction.

  With the above configuration, when the operator pulls the knob 137 and removes the rod 135 from the lock hole 139, the slide plate 131 can be moved in the front-rear direction. Then, by moving the electric motor 50x and the drive output gears 53L and 53R together with the slide plate 131, the state of FIG. 12 where the drive output gears 53L and 53R mesh only with the drive input gears 49L and 49R, and the supply unit elevating input gear It is possible to switch between a state in which only 66L and 66R are engaged and a state in which neither is engaged. After the operator moves the slide plate 131 to a desired position, the operator returns the pulling knob 137, and the rod 135 to which the spring force of the spring 136 acts is provided in accordance with the three states described above. It is inserted into any one of the lock holes 139. Thereby, the slide plate 131 can be locked so as not to move.

  As described above, the drive output gears 53L and 53R are separated from the drive input gears 49L and 49R and the drive input gears 49L and 49R by the slide plate 131 that can move back and forth, the lock mechanism 134, and the like. The connecting / disconnecting mechanism 150 is switchable between states.

  Hereinafter, a configuration for raising and lowering the left and right supply units will be described. As shown in FIG. 13, the supply unit elevating input gears 66 </ b> L and 66 </ b> R are fixed to the ends of the pair of supply unit elevating transmission shafts 141 </ b> L and 141 </ b> R that are rotatably supported on the left and right central sides. The rotation of the supply unit lifting / lowering transmission shafts 141L and 141R is transmitted to worm gears 143L and 143R rotatably supported at the left and right ends of the fertilizer applicator 8 via appropriate gear trains 142L and 142R. On the other hand, the left and right supply units including the hopper 27, the feeding unit 11, the drive shafts 26L and 26R, and the drive input gears 49L and 49R are configured to be rotatable about the rotation shafts 46L and 46R. Further, elevating gears 144L and 144R are fixed to rotating stays 47L and 47R that are connected to the rotating shafts 46L and 46R and support the left and right supply parts, respectively. The worm gears 143L and 143R mesh with the elevating gears 144L and 144R.

  Accordingly, when the electric motor 50x is driven in a state where the drive output gears 53L and 53R included in the electric motor 50x are connected to the supply unit elevating input gears 66L and 66R, the left and right supply units including the hopper 27 and the like are rotated. The shaft 46L, 46R can be turned upward so as to jump up. On the other hand, the electric motor 50x is configured to be capable of forward and reverse rotation, and by rotating the electric motor 50x in the reverse direction, the left and right supply units can be rotated downward. Accordingly, the operator does not lift the heavy hopper 27 by grasping the handle 36, and lifts the left and right supply parts with the power of the electric motor 50x to discharge the fertilizer inside the hopper 27. Since it can be returned, a significant labor saving can be realized.

  In the present embodiment, as described above, the power of the electric motor 50x that drives the feeding unit 11 can be used for raising and lowering the left and right supply units, but can also be used for other purposes. .

  Specifically, the drive output gears 53L and 53R are provided with attachment output shafts 67L and 67R as external output shafts as shown in FIGS. The attachment output shafts 67L and 67R receive the output of the electric motor 50x (the output decelerated by the speed reducer) and rotate integrally with the drive output gears 53L and 53R.

  A replaceable attachment (tool) can be attached to the attachment output shafts 67L and 67R. FIG. 12 shows a rotary driver (rotary tool) 145 as an example of the attachment. The rotary driver 145 includes a joint part 146 that can be attached to and detached from the attachment output shafts 67L and 67R, a flexible wire 147 having one end connected to the joint part 146, a chuck part 148 connected to the other end of the flexible wire 147, It has. In the example of FIG. 12, a minus driver bit is attached to the chuck portion 148, but a plus driver bit, a drill, or the like may be attached, for example.

  With this configuration, the drive output gears 53L and 53R are attached to the attachment output shaft 67L with the rotation driver 145 in a state where the drive output gears 53L and 53R are not meshed with the drive input gears 49L and 49R and the supply unit elevating input gears 66L and 66R. By driving 50x, the rotational power is transmitted to the chuck portion 148 via the flexible wire 147, and the driver bit can be rotated. Thus, the electric motor 50x can be used as a rotational power source for the driver.

  In the example shown in FIG. 12, the rotation of the electric motor 50x after being decelerated by a reduction gear (not shown) built in the fixed housing 51x is transmitted to the attachment output shafts 67L and 67R. Therefore, the rotary driver 145 can be driven with a strong torque. However, if the configuration is changed, it is possible to utilize the output rotation of the electric motor 50x without passing through the reduction gear. For example, a configuration in which the attachment output shafts 67L and 67R can be rotated relative to the drive output gears 53L and 53R, and the rotor (not shown) included in the electric motor 50x and the attachment output shafts 67L and 67R are directly connected is considered. It is done. Thereby, it can be set as the structure which the attachment output shafts 67L and 67R rotate at high speed simultaneously with the drive output gears 53L and 53R rotating at low speed. In this case, if a blower fan for cleaning, a fan for cooling the electric motor 50x, or the like is connected to the attachment output shafts 67L and 67R as attachments, high-speed rotation of the fans can be easily realized, and a sufficient air volume can be obtained. Can be obtained.

  Next, a second modification in which the electric motor is further changed from the first modification will be described with reference to FIG. FIG. 14 is a front view showing a fertilizer applicator 8y of a second modified example in which the arrangement of the electric motor 50x is changed.

  In the fertilizer applicator 8y of this modification, as shown in FIG. 14, one electric motor 50x is disposed on each of the left and right sides of the fertilizer applicator 8y. Each electric motor 50x is arranged between the portions where the lower part of the hopper body 30 provided in each of the left and right hoppers 27 is divided into two.

  Although not shown in detail, when configured as in the present modification, the drive shafts 26L and 26R that drive the feeding portion 11 of the left and right hoppers 27 are divided into two parts with the electric motor 50x as a boundary. Will be.

  Next, a third modified example in which the electric motor is changed to be disposed on the supply unit side will be described with reference to FIGS. 15 and 16. FIG. 15 is a rear view showing a fertilizer applicator 8z of a third modified example in which the electric motor 50x is disposed on the supply unit side. FIG. 16: is a rear view which shows a mode that the supply part was rotated in the fertilizer applicator 8z of a 3rd modification.

  In the fertilizer applicator 8z of this modification, as shown in FIG. 15, one electric motor 50x is arranged at each of the left and right ends of the body of the fertilizer applicator 8z. Similar to the first and second modifications, the electric motor 50x is an electric motor having a structure in which the housing does not rotate, and its output shaft projects toward the center of the machine body. The output shafts of the respective electric motors 50x are arranged so that their axes coincide with the drive shafts 26L and 26R of the left and right supply units, and are connected to the drive shafts 26L and 26R.

  The left and right electric motors 50x are attached to the rotation stays 47L and 47R. Therefore, when the supply unit is moved with respect to the fertilizer frame 55, the electric motor 50x also moves integrally with the supply unit as shown in FIG. That is, in the fertilizer applicator 8z of the present modification, the left and right supply units can be moved between the work position and the discharge position while maintaining the connection state between the electric motor 50x and the feeding unit 11. Therefore, since it is not necessary to provide a mechanism (a clutch or a coupling mechanism provided in Patent Document 1) for transmitting or interrupting the driving force of the electric motor 50x to the feeding unit 11, the fertilizer applicator 8z is configured at low cost. Can do. Moreover, since it is not necessary to operate a clutch, a connection mechanism, etc. like patent document 1, there is no fear of damaging a mechanism by forgetting to operate.

  Moreover, in this modification, the electric motor 50x is arrange | positioned 1 each on either side, the left side electric motor 50x can drive the supply part 11 for two pieces on the left side, and the right electric motor 50x can make two pieces on the right side. The feeding section 11 can be driven. Thereby, since the feeding part 11 for the left two strips and the feeding part 11 for the two right strips can be driven individually, for example, it becomes easy to feed the fertilizer by only the two strips on the left and right sides.

  As shown in FIG. 15, a discharge opening 151 is formed at the left and right end portions of the fuselage in the left and right hopper main bodies 30 (that is, the lower part when the supply unit is rotated to the discharge position). A detachable closing member 152 is attached to 151. Accordingly, when discharging fertilizer, without removing the lid 31 at the top of the hopper body 30, the closing member 152 is removed and the supply unit is rotated as shown in FIG. The fertilizer can be quickly discharged from the discharge opening 151. When fertilizer is discharged from the discharge opening 151 instead of from the opening portion of the hopper body 30, it is not necessary to rotate the large amount as in the above-described embodiment (FIG. 9), and only by tilting to some extent as shown in FIG. Almost all fertilizer can be discharged. Further, since the discharge opening 151 is smaller than the opening on the upper side of the hopper body 30, it is not necessary to prepare a container or bag for receiving discharged fertilizer with a wide mouth. Therefore, it is easy to miniaturize containers and bags, and workability at the time of discharging fertilizer is good.

  In this modified example, as in the first modified example (FIG. 13), a gear mechanism and the like for raising and lowering the supply unit are provided, and an appropriate clutch mechanism is further provided, so that the power of the electric motor 50x can be increased. It can be used to rotate the left and right supply sections.

  Next, the 4th modification which changed the direction which a supply part rotates is demonstrated with reference to FIG. FIG. 17 is a side view showing a fertilizer applicator 8w according to a fourth modification.

  In the fertilizer applicator 8w of the present modification shown in FIG. 17, the rotation shaft 46, which is the rotation center of the supply unit, is arranged in the left-right direction of the body (that is, the direction parallel to the drive shaft 26) instead of the longitudinal direction of the body. ing. The supply unit including the hopper 27, the feeding unit 11, the drive shaft 26, and the like can be rotated in the front-rear direction of the machine body about the rotation shaft 46.

  Therefore, the operator can move the supply unit to the discharge position indicated by the chain line by tilting the supply unit forward from the working position indicated by the solid line in FIG.

  A discharge opening 151 is provided on the front side of the hopper main body 30 of this modification (that is, the portion that becomes the lower side when the supply unit is rotated to the discharge position). The discharge opening 151 is provided with a shutter member 152x that is a member capable of closing the opening. The shutter member 152x is a plate-like member that can slide, and can open and close the discharge opening 151.

  In addition, one end of a discharge guide tube 153 configured in a bellows shape is connected to the discharge opening 151. The discharge guide tube 153 has moderate flexibility and is configured to be extendable and contractible.

  With this configuration, when the supply unit is at the working position, the shutter member 152x closes the discharge opening 151 and the discharge guide tube 153 is contracted. On the other hand, when the supply unit is moved to the discharge position, if the discharge guide tube 153 is extended and the tip is inserted into the bag or container and the shutter member 152x is opened in this state, the fertilizer can be discharged to the bag or the like. it can.

  In the present modification, the fertilizer discharge path can be guided by the deformable discharge guide tube 153, so that it is not necessary to position the bag or container directly below the discharge opening 151. Therefore, the manure discharging operation becomes easier.

  In addition, in this modification, it comprises so that the two supply parts on either side which spread the fertilizer for 2 strips can rotate independently in the front-back direction. However, the present invention is not limited thereto, and the four supply lines may be configured as one supply unit, and the supply unit may be rotated in the front-rear direction. Further, although the electric motor is not illustrated in the present modification, the electric motor may be configured to rotate integrally with the supply unit when the supply unit is rotated, or the fertilizer application frame 55. You may comprise so that it may remain on the side. Further, the axis of the rotation shaft of the supply unit may be arranged so as to coincide with the axis of the drive shaft 26.

  Next, control of the electric motor 50 that drives the feeding portion 11 (that is, the feeding plate 15) of the fertilizer applicator 8 will be described with reference mainly to FIGS.

  As shown in FIG. 18, the rice transplanter 1 of this embodiment includes a control unit 60 that controls the electric motor 50. The control part 60 is comprised as a microcomputer which consists of CPU, ROM, RAM etc., for example. The control unit 60 can also control the electric motor 50 in conjunction with the controller (not shown) that controls the vehicle body 2, the planting unit 3 and the like of the rice transplanter 1. In addition, the electric motor 50 can be controlled independently. That is, the electric motor 50 is configured to be independently controllable regardless of the start / stop of the power of the rice transplanter 1 (start / stop of the engine 10).

  The control unit 60 has a spraying mode, a spraying stop mode, a metering mode, and a cleaning mode as control modes for spraying granular fertilizer.

  The rice transplanter 1 includes an operation panel (operation unit) 90 for operating the fertilizer applicator 8. For example, the operation panel 90 may be disposed in the vicinity of the steering handle 7 in front of the driver seat 6 or in the vicinity of the hopper 27 behind the driver seat 6. The operation panel 90 is electrically connected to the control unit 60.

  As shown in FIG. 19, the operation panel 90 includes a spraying mode switch 91, a metering mode switch 92, a cleaning mode switch 93, a fertilizer application amount adjustment dial 94, and a display (display unit) 121. .

  The operator can alternately switch between the spray mode and the spray stop mode by pressing the spray mode switch 91. The operator can switch the control mode to the metering mode or the cleaning mode by pressing the metering mode switch 92 or the cleaning mode switch 93. Moreover, the operator can perform the adjustment work of the fertilizer application amount in spray mode by rotating the fertilizer application dial 94. The fertilizer adjustment dial 94 is provided with scales in increments of 1.5 from 0 to 9 so as to divide the operation range. Details of the scales will be described later. The display 121 is configured, for example, as a liquid crystal display, and can display various information, for example, which control mode the control unit 60 is in.

  In the fertilizer applicator 8x of the first modification shown in FIGS. 12 and 13, the electric motor 50x can be used widely for purposes other than driving of the feeding section 11, depending on the operator's intention. It is preferable that 50x can be driven / stopped freely. For this reason, a second operation panel (not shown) provided with a switch or the like capable of switching forward / reverse / stop of the electric motor 50x and having a dial or the like capable of adjusting the speed is provided at an appropriate place, for example, the electric motor It is preferable to be installed in the vicinity of the motor 50x (such as around the knob 137).

  As shown in FIG. 18, a battery 111 is connected to the electric motor 50, and power can be supplied to the electric motor 50. An alternator 112 is attached to the engine 10 described above, and electric power generated by the alternator 112 is stored in the battery 111. In FIG. 18, the battery 111 is depicted as being connected to only the electric motor 50, but the power of the battery 111 is actually the control unit 60, the storage unit 61, the operation panel shown in FIG. 90, various sensors, and various actuators.

  The electric motor 50 is provided with a temperature sensor (motor abnormality detection unit) 95. The temperature sensor 95 is provided inside the rotary housing 51, and for example, by detecting an excessive temperature rise of the electric motor 50 when an excessive load is applied to the electric motor 50, an abnormality related to the load on the electric motor 50 is detected. The occurrence can be detected. The temperature sensor 95 is electrically connected to the control unit 60.

  Hereinafter, control modes that the control unit 60 can take will be described.

  The spraying mode is a mode for spraying fertilizer when planting seedlings with the rice transplanter 1. In this spraying mode, the control unit 60 sprays fertilizer by driving the feeding unit 11 via the electric motor 50 as the rice transplanter 1 travels while planting seedlings.

  In this spraying mode, the control unit 60 interlocks the rotational speed of the electric motor 50 with both the traveling speed of the vehicle body 2 (planting speed of the planting unit 3) and the operation position of the fertilizer application amount adjustment dial 94. To control.

  This will be specifically described below. As described above, the fertilizer applicator 8 feeds the fertilizer in the hopper 27 by a predetermined amount by the feeding unit 11, transports the fertilizer to the ground by the transport unit 33, and sprays it from the grooving device 43. And the quantity of the fertilizer paid out whenever the feeding board 15 with which the feeding part 11 is equipped rotates 1 round is decided by the volume and number of the feeding holes 24. Therefore, if the number of rotations (rotation speed) of the feeding plate 15 within the unit time is increased, the amount of fertilizer fed out within the unit time can be increased.

  On the other hand, since the power from the transmission case 71 is transmitted to the planting drive transmission shaft 81 shown in FIG. 2, the rotational speed thereof changes corresponding to the traveling speed of the vehicle body 2. Therefore, the traveling speed of the vehicle body 2 can be detected by detecting the rotational speed of the planting drive transmission shaft 81 by the rotation sensor 84. Since the planting unit 3 is driven at a speed corresponding to the traveling speed of the vehicle body 2 as described above, the rotation sensor 84 substantially detects the planting speed (working speed) of the planting unit 3. It can be said that there is. In the spraying mode, the control unit 60 calculates and acquires the rotation speed based on the rotation signal input from the rotation sensor 84, and the rotation speed of the feeding plate 15 in the fertilizer applicator 8 as the rotation speed increases. The rotational speed of the electric motor 50 is controlled so as to be faster. As a result, the fertilizer can be spread uniformly regardless of the traveling speed of the vehicle body 2.

  Further, in the spraying mode, the control unit 60 causes the electric motor 50 to increase the rotation speed of the feeding plate 15 in the fertilizer applicator 8 as the fertilizer application amount adjustment dial 94 is operated to increase the fertilizer application amount. To control the rotation speed. Accordingly, the operator can adjust the amount of fertilization by turning the fertilization amount adjustment dial 94.

  However, when the detection result of the planting clutch sensor 89 is input to the control unit 60 and the planting clutch 83 is disconnected, the control is performed so that the electric motor 50 is stopped. Thereby, only when planting of the seedling by the planting unit 3 is performed, the feeding unit 11 is driven and fertilization is performed.

  The control unit 60 of the present embodiment is electrically operated during a predetermined time (hereinafter, sometimes referred to as an increase time) after the planting clutch sensor 89 detects the connection of the planting clutch 83 in the spraying mode. Speed increase control for driving the motor 50 at a particularly high speed is performed, and when the above increase time elapses, basic control for driving the electric motor 50 at a normal speed is performed.

  The reason for this is as follows. That is, the control unit 60 controls the planting unit 3 to be driven by the connection of the planting clutch 83 and at the same time to start driving the fertilizer applicator 8 (feeding unit 11). However, fertilizer cannot be fertilized since there is a certain time lag until the fertilizer is transported through the transport unit 33 and actually sprayed from the grooving device 43 after starting the driving of the feed unit 11 and feeding the fertilizer. An interval will occur. In addition, below, the time which cannot be fertilized by said time lag may be called a non-fertilization time, and the area which cannot be fertilized as a result may be called a non-fertilization area.

  In consideration of this point, the control unit 60 of the present embodiment controls the electric motor 50 to be driven at a speed higher than normal (for example, about twice the normal speed) during at least the above-described non-fertilization time. (Acceleration control). In the following, the time during which this speed increase control is performed and more fertilizer is seeded than normal is sometimes referred to as an increase time. It is preferable that the time during which the speed increase control is performed (weight increase time) is the same as or slightly longer than the above non-fertilization time.

FIG. 20 shows a control example of the speed of the electric motor 50 when the planting clutch 83 is connected in a state where the rice transplanter 1 is stopped and the rice transplanter 1 is immediately started to be planted. FIG. 20 is a graph showing three cases in which the traveling acceleration of the rice transplanter 1 (planting speed of the planting unit 3) is constant and the set values of the fertilizer application amount adjusting dial 94 are different. In either case, speed increase control is performed until the increase time T _I elapses, and the rotation speed of the electric motor 50 is approximately twice the normal rotation speed (shown by a broken line). Be controlled. When the increase time T _I elapses, the basic control is performed, and the electric motor 50 returns to the normal rotation speed.

  As described above, FIG. 20 shows a graph in three cases where the traveling acceleration of the rice transplanter 1 is equal and the set values of the fertilizer application amount adjustment dial 94 are different. However, even when the set value of the fertilizer application dial 94 is constant and the traveling acceleration of the rice transplanter 1 is different, the control is performed in the same manner as the graph shown in FIG.

  As described above, after the planting clutch 83 is connected, immediately after the non-fertilization time, an increase time in which the fertilizer is doubled as usual continues. Therefore, it is possible to compensate for the shortage of fertilizer application immediately after the start of the fertilization work and to ensure the overall fertilization effect.

  Moreover, in the present embodiment, the direction in which the fertilizer is discharged is changed in the grooving device 43 in conjunction with the speed increase control. Specifically, as shown in FIG. 21, in the groove generator 43, a cylindrical discharge guide 43a connected to the transport hose 42 is formed, and the discharge guide 43a is opened downward and rearward. A spray port 43b is formed. A discharge guide member (guide member) 45 for guiding the fertilizer discharge direction is rotatably mounted in the discharge guide 43a and in the vicinity of the spray port 43b.

  The discharge guide member 45 is formed in a plate shape so as to partition the inside of the discharge guide 43a forward and backward. Further, the discharge guide member 45 is arranged so as to divide the cross section of the fertilizer passage formed inside the discharge guide 43a into approximately two equal parts. The discharge guide member 45 can be switched between a posture that is substantially perpendicular to the ground and an oblique posture that is lowered rearward by rotating about a shaft 45a attached to the discharge guide 43a. When the posture of the discharge guide member 45 is perpendicular to the ground, the entire amount of fertilizer is sown almost directly from the spray port 43b. When the posture of the discharge guide member 45 is an oblique posture, a part (almost half amount) of the fertilizer is guided by the discharge guide member 45 so as to be sown rearward, and the remaining fertilizer is sown directly below.

  The shaft 45a of the discharge guide member 45 is connected to a discharge guide actuator 98 (FIG. 18) made of, for example, a solenoid or an electric motor. The discharge guide actuator 98 is electrically connected to the control unit 60. Then, the control unit 60 controls the discharge guide actuator 98 so that the discharge guide actuator 98 is in an oblique posture during the above-described increase time and assumes a normal upright posture after the increase time has elapsed.

  Thereby, a part of the fertilizer fed from the feeding plate 15 immediately after the start of the fertilization work can be sprayed to the rear non-fertilized section where the fertilizer amount is insufficient by the guide action of the discharge guide member 45. it can. Further, at this time, since the feeding plate 15 rotates faster than usual as a result of the speed-up control of the electric motor 50, even if a portion of the fertilizer is sown toward the rear, there is not enough manure to be sown just below. Absent. As described above, unevenness in fertilization can be improved.

  Further, in addition to the above control, the control unit 60 of the present embodiment can drive the electric motor 50 in consideration of slip when the vehicle body 2 travels. That is, the control unit 60 can detect the traveling speed of the vehicle body 2 by detecting the rotational speed of the planting drive transmission shaft 81 by the rotation sensor 84, and this traveling speed is the rotational speed of the axles 75 and 76. The slip generated when the rice transplanter 1 is traveling is not taken into consideration. Therefore, when slip occurs in the rice transplanter 1, the rice transplanter 1 cannot substantially travel that much. Even in this case, if fertilizer of the same amount as usual is fertilized by the fertilizer applicator 8, the amount of fertilizer will eventually become larger than the amount intended by the operator, resulting in waste of fertilizer, It can be a cause.

  In this respect, in the rice transplanter 1 of the present embodiment, the marker marker 16 (state detection unit, rotation detection unit) 99 is provided in the above-described drawing marker 16, and the marker rotation sensor 99 is electrically connected to the control unit 60. It is connected to the. Therefore, the control unit 60 can detect the rotation of the drawing marker 16.

  The rotation amount of the drawing marker 16 detected by the marker rotation sensor 99 is a value corresponding to the substantial travel distance of the vehicle body 2 as long as the drawing marker 16 is in good contact with the ground. The control unit 60 calculates a slip ratio using the traveling speed detected by the rotation sensor 84 and the net traveling speed of the vehicle body 2 detected by the marker rotation sensor 99, and the electric motor 50 is calculated based on the slip ratio. Correct the rotation speed to the deceleration side.

  As a result, even if slippage occurs when the rice transplanter 1 travels because the state of the field is poor, the amount of fertilizer desired by the operator can be accurately sprayed because the amount of fertilizer applied is controlled by the control unit 60. . Moreover, since the decrease control of the fertilizer amount resulting from the slip of the vehicle body 2 is automatically performed, when the slip occurs, the operator can concentrate on the operation of the rice transplanter 1 without adjusting the fertilizer amount. .

  Moreover, the net traveling speed of the rice transplanter 1 can be accurately detected by detecting the rotation of the line drawing marker 16 that rolls on the ground with the substantial traveling of the rice transplanter 1 by the marker rotation sensor 99. Thereby, even if slip occurs in the vehicle body 2, the fertilizer application amount intended by the operator can be reliably maintained. By the slip correction control described above, an amount of fertilizer intended by the operator can be applied accurately.

  Like the speed-increasing control and slip correction control described above, the control unit 60 of the present embodiment has a correspondence relationship between the driving speed of the feeding unit 11 in the fertilizer applicator 8 and the planting speed of the planting unit 3. It can be changed according to the situation. Such control can be easily performed because the feeding unit 11 is driven by the electric motor 50 which is a driving source different from the engine 10 (which is the driving source of the planting unit 3).

  The spraying stop mode is a mode in which the electric motor 50 is stopped and the feeding unit 11 is not driven. This mode is selected, for example, when fertilization is not necessary or when the rice transplanter 1 is traveling on the road.

  The metering mode is a mode in which the feeding plate 15 is rotated a predetermined number of times (for example, 50 times). When the metering mode starts, the control unit 60 drives the electric motor 50 to rotate the feeding plate 15 accurately at a predetermined rotation speed by a predetermined rotation amount, and then stops.

  Unlike the above-described spraying mode, the rotational speed of the electric motor 50 in the metering mode is not related to the traveling speed of the vehicle body 2 (regardless of the operating position of the fertilizer application amount adjusting dial 94 or the state of the planting clutch 83). It is constant at a predetermined speed. Further, as described above, the feeding unit 11 is driven by the electric motor 50 that is a drive source independent of the engine 10. Accordingly, the metering mode can be executed even when the rice transplanter 1 is stopped traveling or when the engine 10 is stopped.

  Hereinafter, the control of the electric motor 50 that rotates the feeding plate 15 at a predetermined speed by a predetermined rotation amount may be referred to as quantitative drive control. The control of the electric motor 50 in this metering mode is an example of quantitative drive control.

  Hereinafter, the fertilizer metering using the metering mode will be described. The operator, for example, puts the rice transplanter 1 in the garage, puts an appropriate container to receive fertilizer from the spraying port 43b of the fertilizer applicator 8 with the engine 10 stopped, and presses the metering mode switch 92 to measure the metering mode. Start. Then, the electric motor 50 is driven by the control unit 60 as described above, and the feeding plate 15 is accurately rotated a predetermined number of times and stopped.

  After the driving of the fertilizer applicator 8 is stopped, the operator measures the amount of fertilizer received in the container. The result (the result of metering) obtained by this measurement is useful for the operator to grasp the standard amount of fertilizer applied by the fertilizer applicator 8. Therefore, the operator decides what the fertilizer application amount in the actual fertilization operation is to be performed (to which position the fertilizer adjustment dial 94 should be operated) or predicts how much fertilizer is required. In this case, the result of the above metering can be used as an effective clue.

  This will be specifically described below. The target amount that the operator wants to fertilize is A (kg / 10 are), and the measured value of the spraying amount when the feeding plate 15 is rotated by 50 laps in the above metering mode for the fertilizer 8 for one line is B (Kg), where the number of fertilizer application is C, and the traveling speed of the rice transplanter 1 is V (m / s), the required number of turns of the feeding plate 15 per 10 ares is A × 50 / C / B (Lap). If the distance between each strip in the fertilizer applicator 8 is 30 cm, the time required to complete the fertilization work for 10 ares is 1000 / 0.3 / C / V. The rotational speed of the feeding plate 15 required when working with is 0.9 × A × V / B (rpm).

  On the other hand, the scale attached to the periphery of the fertilization amount adjusting dial 94 represents a reference for the rotational speed of the feeding plate 15 when the speed V of the rice transplanter 1 is 1 (m / s). For example, when the speed V of the rice transplanter 1 is 1 (m / s), when the fertilizer adjustment dial 94 is set to the scale of “6”, the feeding plate 15 rotates at a speed of 30 rpm, and “9”. Rotate at a speed of 45 rpm. Accordingly, the rotation speed of the feeding plate 15 necessary to achieve the target fertilizer application amount is obtained using the above calculation formula, and the fertilizer application amount adjustment dial 94 is aligned with the scale corresponding to this rotation speed, thereby obtaining the desired amount. Of fertilizer can be sprayed accurately.

  The operation panel 90 includes an input unit such as a numeric keypad (not shown) so that the operator can input and set the measured value B of the spray amount obtained in the metering mode. When the measurement value B of the metering mode is set, the control unit 60 uses the traveling speed of the rice transplanter 1 detected by the rotation sensor 84 or the marker rotation sensor 99 in the spraying mode, from the fertilizer application 8. The amount to be fertilized can be calculated from the above formula as needed, and for example, the fertilizer amount per predetermined distance, the fertilizer amount per predetermined area, the fertilizer amount per predetermined time, etc. can be displayed on the display 121 in real time. . Thereby, the operator can perform planting and fertilization work while confirming the amount actually spread.

  The cleaning mode is a mode in which the quantitative drive control is performed in the same manner as the above metering mode, and the feeding plate 15 is rotated a predetermined number of times. However, the cleaning mode is a metering mode in that the feeding plate 15 is rotated only by a small number of times (including a case where it is less than one) sufficient to discharge the fertilizer from the feeding hole 24 of the feeding plate 15. And different.

  Hereinafter, cleaning inside the fertilizer applicator 8 using the cleaning mode will be described. After the fertilization work is completed, the operator discharges the fertilizer remaining in the hopper 27 of the fertilizer applicator 8 by rotating the hopper 27 to the open position as shown in FIG. Thereby, most of the fertilizer in the hopper 27 and the fertilizer inflow space 25 can be discharged.

  However, it is difficult to discharge the fertilizer that has entered the feeding hole 24 formed in the feeding plate 15 of the feeding portion 11 even by flipping up the hopper 27 as described above. On the other hand, if the fertilizer contained in the feeding hole 24 is left for a long time, it sticks to the inner wall or the like of the feeding hole 24 and hardens, causing clogging.

  Therefore, the operator presses the cleaning mode switch 93 on the operation panel 90. Thereby, the cleaning mode is started, and the control unit 60 drives the electric motor 50 to rotate the feeding plate 15 by a predetermined rotation amount at a predetermined rotation speed, and then stops. The amount of rotation is sufficient for all the feeding holes 24 formed in the feeding plate 15 to pass through the place facing the internal space of the guide portion 40 disposed on the downstream side about once to several times. The amount of rotation can be determined, and is, for example, about a half turn, a turn, or a few turns. It is preferable that the blower 37 is driven in conjunction with the rotation of the feeding plate 15 to supply an air flow for discharging fertilizer from the air supply pipe 38. Thereby, the fertilizer remaining inside the feeding hole 24 of the feeding plate 15 can be easily discharged through the spray port 43b.

  The control unit 60 controls the electric motor 50 by issuing a control command based on a signal output by the operator operating the operation panel 90 and a signal from the temperature sensor 95 or the planting clutch sensor 89.

  The storage unit 61 stores information set in advance for driving the feeding unit 11. Examples of this information include information such as the rotation speed and rotation amount of the feeding plate 15 in the metering mode, the rotation amount of the feeding plate 15 in the cleaning mode, and a threshold value for determining a temperature abnormality of the electric motor 50.

  With the above configuration, the control unit 60 determines an operation command to be issued based on information such as the control mode of the fertilizer applicator 8 and the detection results of the planting clutch sensor 89 and the temperature sensor 95.

  Specifically, the control unit 60 issues a control command to the electric motor 50 according to the control mode, and appropriately controls driving / stopping of the electric motor 50, the rotation speed, and the like. Thereby, control of said dispersion | spreading mode, metering mode, cleaning mode, etc. is implement | achieved.

  In addition, when the motor temperature is detected by the temperature sensor 95 while the electric motor 50 is being driven, the control unit 60 sounds a buzzer (alarm unit) 97 electrically connected to the control unit 60. While notifying the operator, the electric motor 50 is automatically stopped. As a result, seizure of the electric motor 50 can be prevented, and an early response can be urged to the operator.

  By the way, when performing the planting work with the rice transplanter 1 while performing the fertilization work using the fertilizer applicator 8, the metering mode switch 92 or the cleaning mode switch 93 may be pressed for some reason such as an operator's mistake. There is sex. In this case, since the intended fertilization is not performed, part or all of the fertilization work for which the vehicle body 2 has traveled must be redone before the operator notices the erroneous operation, which deteriorates the work efficiency.

  For example, when the metering mode switch 92 or the cleaning mode switch 93 is pressed due to an operation mistake or the like while traveling on the road, the fertilizer is sprayed wastefully and the fertilizer must be collected.

  In this regard, the rice transplanter 1 of the present embodiment is configured to perform interlock control that does not switch the control mode even when the metering mode and cleaning mode switches are pressed during traveling or fertilization. ing.

  Specifically, when the metering mode switch 92 or the cleaning mode switch 93 is operated, the control unit 60 switches the control mode based on whether the rice transplanter 1 is working or running. Judge whether. The control unit 60 shifts to the metering mode or the cleaning mode only when the engine 10 is stopped or the main speed change lever is in the neutral position, and in other cases, the control mode is not switched (the control mode is not adjusted). The operation of the quantity mode switch 92 and the cleaning mode switch 93 is invalidated).

  Thus, the rice transplanter 1 of this embodiment is limited to be switchable to the metering mode or the cleaning mode only when the engine 10 is stopped or when the main transmission lever is in the neutral position.

  By such interlock control, it is possible to reliably prevent a decrease in efficiency of the fertilization work due to the above-described operation mistake. Therefore, the operator can concentrate on fertilization work and the like without worrying about erroneous operations.

  As described above, the fertilizer applicator 8x of the first modification shown in FIG. 12 includes the hopper 27 and the feeding unit 11 as in the above-described embodiment. The fertilizer applicator 8x includes drive input gears 49L and 49R, an electric motor 50x, and drive output gears 53L and 53R. The hopper 27 stores fertilizer. The feeding unit 11 feeds the fertilizer in the hopper 27. Driving force to the feeding unit 11 is input to the drive input gears 49L and 49R. The electric motor 50 x is a drive source for the feeding unit 11. The drive output gears 53L and 53R output the drive force of the electric motor 50x to the drive input gears 49L and 49R. The fertilizer applicator 8x is configured to be able to output the driving force of the electric motor 50x to configurations other than the drive input gears 49L and 49R.

  Thereby, since the driving force of the electric motor 50x can be utilized for other uses, the convenience of the fertilizer applicator 8x can be enhanced.

  Further, the fertilizer applicator 8x of the first modified example can be switched between a state in which the drive output gears 53L and 53R are connected to the drive input gears 49L and 49R and a state in which the drive output gears 49L and 49R are disconnected from the drive input gears 49L and 49R. A connection / disconnection mechanism 150 is provided. The fertilizer applicator 8x is configured to be able to output the driving force of the electric motor 50x to configurations other than the drive input gears 49L and 49R in a state where the drive output gears 53L and 53R are disconnected from the drive input gears 49L and 49R. Has been.

  As a result, the driving force of the electric motor 50x is used for other purposes in a state where the driving output gears 53L and 53R are disconnected from the driving input gears 49L and 49R (that is, a state where the feeding portion 11 is not driven by the electric motor 50x). be able to.

  Further, the fertilizer applicator 8x of the first modified example includes supply unit elevating input gears 66L and 66R to which a driving force for components other than the feeding unit 11 is input separately from the drive input gears 49L and 49R. The connection / disconnection mechanism 150 moves the drive output gears 53L, 53R in a direction away from the drive input gears 49L, 49R, thereby separating the drive output gears 53L, 53R from the drive input gears 49L, 49R, and inputting / lowering the supply unit. The gears 66L and 66R are connected.

  Accordingly, the drive output gears 53L and 53R can be connected to any one of the drive input gears 49L and 49R and the supply unit elevating input gears 66L and 66R. When the drive output gears 53L and 53R are connected to the drive input gears 49L and 49R, a drive force is output to the feeding unit 11 via the drive input gears 49L and 49R. On the other hand, when the drive output gears 53L and 53R are connected to the supply unit elevating input gears 66L and 66R, the driving force is applied to the components other than the feeding unit 11 via the supply unit elevating input gears 66L and 66R. Can output. As described above, the electric motor 50x can selectively drive either the feeding unit 11 or the other configuration (that is, the lifting mechanism of the supply unit). Therefore, it is possible to effectively use the electric motor 50x when the feeding unit 11 is not driven.

  Further, in the fertilizer applicator 8x of the first modified example, the drive output gears 53L and 53R, the drive input gears 49L and 49R, and the supply unit elevating input gears 66L and 66R are all configured as gears. The drive input gears 49L and 49R and the supply unit elevating input gears 66L and 66R are arranged so as to be able to mesh with the drive output gears 53L and 53R, respectively.

  Accordingly, the drive output gears 53L and 53R are separated from the drive input gears 49L and 49R, thereby releasing the meshing between the drive output gears 53L and 53R and the drive input gears 49L and 49R, and the drive output gear 53L. , 53R can be meshed with the input / lowering input gears 66L, 66R. Therefore, the output destination of the driving force can be switched with a simple configuration.

  Further, the fertilizer applicator 8x of the first modified example includes a speed reducer (not shown) built in the fixed housing 51x that decelerates the output of the electric motor 50x and outputs it to the drive output gears 53L and 53R. In a state where the drive output gears 53L and 53R are disconnected from the drive input gears 49L and 49R, the driving force of the electric motor 50x decelerated by the reduction gear is configured to be a configuration other than the drive input gears 49L and 49R (for example, raising and lowering the supply unit) The input gears 66L and 66R and the rotation driver 145) can be output.

  Thereby, it is possible to drive a configuration (elevating mechanism of the supply unit and the rotary driver 145) other than the feeding unit 11 without separately providing a reduction gear.

  Further, in the fertilizer applicator 8x of the first modified example, the hopper 27 is supported so as to be rotatable around the rotation shafts 46L and 46R. The fertilizer applicator 8x rotates the hopper 27 around the rotation shafts 46L and 46R by the driving force of the electric motor 50x decelerated by the reduction gear.

  Accordingly, the hopper 27 can be rotated around the rotation shafts 46L and 46R using the driving force of the electric motor 50x. Therefore, the fertilizer remaining in the hopper 27 can be easily discharged. Further, even if fertilizer enters the hopper 27 and becomes heavier, the hopper 27 can be strongly rotated by the driving force of the electric motor 50x whose torque is enhanced by the reduction gear.

  The fertilizer applicator 8x of the first modification is configured to be able to output the driving force of the electric motor 50x decelerated by the speed reducer to the rotary driver 145.

  Thereby, the rotation driver 145 can be strongly driven to rotate by using the driving force of the electric motor 50x whose torque is enhanced by the speed reducer.

  However, in the fertilizer applicator 8x of the first modification, the driving force of the electric motor 50x is not passed through the speed reducer when the drive output gears 53L and 53R are disconnected from the drive input gears 49L and 49R. It is also possible to change the configuration so that output is possible for configurations other than the drive input gears 49L and 49R.

  That is, since the feeding unit 11 needs to be driven at a relatively low speed, the drive force of the electric motor 50x is reduced by providing a reduction gear between the output shaft of the electric motor 50x and the drive output gears 53L and 53R. Is output from the drive output gears 53L and 53R. On the other hand, by outputting the driving force of the electric motor 50x to the outside without decelerating, the components other than the feeding unit 11 can be driven at a relatively high speed.

  And when it changes as mentioned above, it is possible to output the driving force of the electric motor 50x with respect to the fan which generates an airflow.

  In this case, a sufficient air volume can be obtained by rotationally driving the fan at a relatively high speed by the electric motor 50x.

  Moreover, the rice transplanter 1 of the present embodiment includes the fertilizer applicator 8x, a vehicle body 2 that can travel by mounting the fertilizer applicator 8x, and an engine 10 that is a travel drive source of the vehicle body 2.

  Thereby, the motive power of the electric motor 50x of the fertilizer applicator 8x can be used effectively, and a highly convenient spraying work vehicle can be provided. Moreover, since the electric motor 50x can be driven independently of the engine 10 of the vehicle body 2, the electric motor 50x can be widely used.

  The preferred embodiments and modifications of the present invention have been described above, but the above configuration can be modified as follows, for example.

  The fertilizer applicator 8x of the first modification shown in FIG. 12 includes both a configuration in which the supply unit is moved up and down by the supply unit lifting input gears 66L and 66R and a configuration in which various attachments are driven by the attachment output shafts 67L and 67R. ing. However, any one of the above may be omitted.

  In the first modified example shown in FIG. 12, the connection / disconnection of the driving force is switched by the engagement / release of the drive output gears 53L, 53R and the supply unit elevating input gears 66L, 66R. However, the present invention is not limited to this, and the connection / disconnection between the output shaft of the electric motor 50x and the supply unit lifting / lowering transmission shafts 141L and 141R may be switchable by a clutch (for example, an electromagnetic clutch) having another configuration. Similarly, between the drive output gears 53L and 53R and the drive input gears 49L and 49R, the connection / disconnection of the drive force may be switched by a clutch having another configuration.

  In the fertilizer applicator 8x of the first modification, the speed reducer is built in the fixed housing 51x of the electric motor 50x, but the speed reducer may be disposed outside the motor housing.

  The configuration for raising and lowering the supply unit with the driving force of the electric motor 50x is not limited to the configuration using the worm gears 143L and 143R, and other various elevating mechanisms are conceivable.

  In the embodiment and the modified example, the feeding portion 11 is provided with a plurality of feeding holes 24 penetrating in the thickness direction in the disc-shaped feeding plate 15, and the feeding plate 15 is arranged in a substantially vertical direction. It is configured to rotate around 23. However, the configuration of the feeding unit 11 is not limited to this, and any configuration that can feed the fertilizer by a predetermined amount may be used. For example, a configuration may be employed in which a plurality of feeding holes are provided around a cylindrical feeding roll, and the feeding roll is rotationally driven around a rotation axis arranged in a substantially horizontal direction.

  Although the fertilizer of the said embodiment and a modification spreads the fertilizer for 4 strips, and it has the structure where the supply parts on either side supply the fertilizer for 2 strips, respectively, it is not limited to this. For example, as a fertilizer application machine which sprays the fertilizer for 6 strips, it can be set as the structure where the supply parts on either side supply the fertilizer for 3 strips. However, it is not necessary for the supply parts on the left and right to supply the same number of fertilizers. For example, in a fertilizer applicator for spraying 6 fertilizers, the left supply unit can supply 4 fertilizers and the right supply unit can supply 2 fertilizers.

  The structure of this invention is not limited to the rice transplanter 1 provided with the fertilizer applicator 8, but can apply widely to the dispersion | spreading work vehicle which pays out a granular material (granular solid substance) and spreads it on the ground.

1 Rice transplanter (dispersion work vehicle)
2 body 8x fertilizer applicator (granular material spraying device)
11 Feeding portion 27 Hopper 46L, 46R Rotating shaft 49L, 49R Drive input gear (driven gear, driven member)
50x Electric motor 53L, 53R Drive output gear (output gear, output member)
66L, 66R Supply unit lifting input gear (second driven gear, second driven member)
67L, 67R Attachment output shaft 145 Rotating screwdriver (Rotating tool)
150 Connection / disconnection mechanism

Claims (10)

A hopper for accommodating the granular material;
An unwinding section for unwinding the granular material in the hopper;
A driven member to which a driving force to the feeding portion is input;
An electric motor which is a drive source of the feeding unit;
An output member that outputs the driving force of the electric motor to the driven member;
With
A granular material spraying device configured to be capable of outputting the driving force of the electric motor to a configuration other than the driven member. The granular material spraying device according to claim 1,
The output member includes a connection / disconnection mechanism that is switchable between a state connected to the driven member and a state disconnected from the driven member,
In the state where the output member is separated from the driven member, the granular material spraying device is configured to be able to output the driving force of the electric motor to a configuration other than the driven member. The granular material spraying device according to claim 2,
Separately from the driven member, a second driven member to which a driving force for a configuration other than the feeding portion is input is provided.
The connecting / disconnecting mechanism moves the output member in a direction away from the driven member, thereby separating the output member from the driven member and connecting the output member to the second driven member. Body spraying device. The granular material spraying device according to claim 3,
The output member is an output gear;
The driven member is a driven gear;
The second driven member is a second driven gear;
The granular material spraying device, wherein the driven gear and the second driven gear are arranged so as to be able to mesh with the output gear. It is a granular material spreading device according to any one of claims 1 to 4,
A speed reducer that decelerates the output of the electric motor and outputs it to the output member;
In the state where the output member is separated from the driven member, the driving force of the electric motor decelerated by the speed reducer can be output to a configuration other than the driven member. Granule spraying device. The granular material spraying device according to claim 5,
The hopper is supported so as to be rotatable about a rotation axis;
The granular material spraying device, wherein the hopper is rotated around the rotation shaft by the driving force of the electric motor decelerated by the reduction gear. It is a granular material spraying device according to claim 5 or 6,
A granular material spraying device configured to be capable of outputting the driving force of the electric motor decelerated by the reduction gear to a rotating tool. It is a granular material spreading device according to any one of claims 1 to 4,
A speed reducer that decelerates the output of the electric motor and outputs it to the output member;
In a state where the output member is separated from the driven member, the driving force of the electric motor can be output to a configuration other than the driven member without passing through the speed reducer. A granular material spraying device. It is a granular material spreading device according to claim 8,
A granular material spraying device configured to be capable of outputting the driving force of the electric motor to a fan that generates an air flow. The granular material spraying device according to any one of claims 1 to 9,
A vehicle body that can travel with the granular material spraying device mounted thereon,
An engine that is a driving source of the vehicle body;
A dispersion work vehicle characterized by comprising:

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