JP4832987B2 - Weeding machine - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a weeding machine weeding weeds growing on the surface of ground without depending on the kind of weeds, size of stems, degree of overcrowdedness, etc. <P>SOLUTION: The invention relates to the weeding machine 1 which pulls weeds 71 growing on the ground by traveling forward, comprising a first roller 4 rotating forward centering a rotating axis 41 set horizontally in the right-angle to the traveling direction, a second roller 5 parallelly set on the rear side of the first roller 4 and rotating rearward, and the second roller 5 is installed on a position wherein the peripheral face of the roller 5 and the peripheral face of the roller 4 form a spacing capable of holding weeds 71, and the roller 5 has a spacing adjusting section 3 adjusting the spacing between the peripheral face 4 of the first roller and the peripheral face of the second roller 5. The spacing adjusting section 3 is provided with a temporal extending means 37 to temporally extend the spacing in a time when a force is added to extend the spacing between the peripheral face 4 of the first roller 4 and the peripheral face of the second roller 5, and an energizing means 37 to energize return of the temporally extended spacing to the normal spacing. <P>COPYRIGHT: (C)2008,JPO&amp;INPIT

Description

  The present invention relates to a weeding machine.

  Conventionally, a weeding machine including a plurality of rollers as shown in FIG. 13 is known (see, for example, Patent Document 1).

  The weeding machine 101 includes a base 102, a driving roller 103, a first conveying roller 104 disposed to face the driving roller 103, and a plurality of first rollers disposed behind the first conveying roller 104. Two conveying rollers 105 and a driving roller 103 are provided in contact with the first conveying roller 104 and the plurality of second conveying rollers 105 and in contact with the outer peripheral surface of the belt 106. A tension roller 107 provided to adjust the tension of the belt 106 and a grass collection box 108 disposed behind and below the second conveying roller 105 are provided.

  The base body 102 includes a generator 109 at the front end, a front wheel 110a and a rear wheel 110b that are rotatably supported at a lower portion of the base body 102, and a handle 111 at the rear. The upper part of the base 102 is covered with a cover 112.

  A driving roller 103 and a first conveying roller 104 are suspended below the base body 102 via a suspension device 113. The suspension device 113 has a configuration capable of adjusting the heights of the driving roller 103 and the first conveying roller 104, and a cam plate 114 provided in the middle of the suspension device 113 and a cam groove of the cam plate 114. The driving roller 103 is supported by the pin 116 slidable on the belt 115 so as to move obliquely downward along the belt 106. Above the driving roller 103, a guide member 117 is provided for guiding the extracted grass to the belt 106 side.

The generator 109 is connected to an electric motor 118 provided in front of the drive roller 103. The electric motor 118 is connected to the driving roller 103 by a chain / sprocket mechanism 119, and the driving roller 103 is rotated by the power of the generator 109.

  The weeding of the grass protruding from the lawn by the weeding machine 101 is performed as follows. First, when the operator starts the generator 109, the electric motor 118 is driven to rotate the driving roller 103. Due to the rotation of the driving roller, the belt 106 in contact with the driving roller 103 is rotated.

  Next, the operator grasps the handle 111 and causes the weeding machine 101 to travel forward. The grass growing on the ground is guided upward by the driving roller 103 and the belt 106 when it comes between the driving roller 103 and the first conveying roller 104 as the weeding machine 101 travels. Next, the guided grass is pinched by the contact portion between the driving roller 103 and the belt 106, and pulled out by being pulled upward. The extracted grass comes into contact with the guide member 117, is guided to the belt 106 side, is placed on the belt 106, is conveyed rearward by the rotation of the belt 106, and is accommodated in the grass collection box 108.

  By the way, the grass growing on the ground has different stem thicknesses depending on the type of grass, and the density of the grass varies.

However, the weeding machine 101 is provided so that the driving roller 103 and the belt 106 always come into contact with each other so that the belt 106 is rotated by the rotation of the driving roller 103. The sandwiched grass may be cut off in the middle, or the grass may be clogged between the driving roller 103 and the belt 106, and the driving roller 103 may stop rotating. Further, when grass that grows densely on the ground is sandwiched between the driving roller 103 and the belt 106, the driving roller 103 and the belt 106 are not in contact with each other, so that the rotation of the driving roller 103 is not transmitted to the belt 106. The rotation of the belt 106 may stop.
JP-A-4-11803

  An object of the present invention is to provide a weeding machine that can remove such inconvenience and can extract grass growing on the ground regardless of the kind of grass, the thickness of the stem, the density, and the like.

In order to achieve such an object, the weeding machine of the present invention is a weeding machine that pulls out grass growing on the ground while moving forward, and is provided in a direction perpendicular to the moving direction and in a horizontal direction. A first roller that rotates forward about a rotation axis, and a plurality of protruding plates that are juxtaposed behind the first roller and extend in the axial direction on the outer peripheral surface, and a second roller that rotates backward A roller and a grass box disposed behind the second roller , wherein the second roller has the protrusion plate when the protrusion plate is closest to the outer peripheral surface of the first roller. The tip of the first roller and the outer peripheral surface of the first roller are provided at a position having a space where the grass can be sandwiched, and the grass collection box includes a contact portion that contacts the protruding plate, and the second with the rear rotation of the roller is swingably formed, and the outer peripheral surface of the first roller Serial characterized in that it comprises an adjustable interval adjusting unit the distance between the tip portion of the projection plate.

  In the weeding machine of the present invention, when the grass growing on the ground is positioned between the first roller and the second roller by moving the weeding machine forward, the first roller Is sandwiched between the outer peripheral surface of the first roller and the outer peripheral surface of the second roller along with the forward rotation of the second roller and the backward rotation of the second roller, and is displaced upward and pulled out from the ground. .

Further, since the outer peripheral surface of the first roller and the tip of the protruding plate are adjusted in advance to an interval at which the grass can be sandwiched according to the state of the grass growing on the ground, the weeding of the present invention According to the machine, the grass growing on the ground can be pulled out regardless of the type of grass, the thickness of the stem, the density, etc.
Next, the withdrawn grass is conveyed rearward as the second roller rotates backward, and is accommodated in the grass collection box.
At this time, as the second roller rotates backward, the projection plate comes into contact with the contact portion or comes out of contact, so that the grass collection box is swung. By the swinging of the grass collection box, the soil contained in the grass collection box is separated from the soil such as soil, sand, stone, etc. attached to the root.
By the above operation, the entire grass including the roots can be pulled out reliably, and earth attached to the pulled grass roots can be removed.

  The forward rotation refers to the rotation direction when the upper end portion rotates forward when each roller is viewed from the axial direction, and the backward rotation refers to the reverse rotation.

Further, in the weeding machine according to the present invention, the interval adjusting unit temporarily sets the interval when a force is applied in a direction in which the interval between the outer peripheral surface of the first roller and the tip of the protruding plate is increased. It is desirable to include temporary expansion means that expands to a normal distance and biasing means that biases the temporarily expanded interval in a direction to return to the normal interval. When a force is applied by the grass growing on the ground in the direction of increasing the distance between the outer peripheral surface of the first roller and the tip of the projection plate , the distance is temporarily expanded by the temporary expansion means. Grass that exceeds the interval is sandwiched between the outer peripheral surface of the first roller and the tip of the protruding plate . The sandwiched grass is displaced upward along with the forward rotation of the first roller and the backward rotation of the second roller, and is pulled out from the ground. The extracted grass is further displaced upward along with the forward rotation of the first roller and the backward rotation of the second roller, and is caused by the outer peripheral surface of the first roller and the tip of the protruding plate. It is displaced to a position where it is not pinched. Then, the temporarily expanded interval is returned to the normal interval by the biasing means.

  Therefore, according to the weeding machine of the present invention, even when grass having a stem thickness and density that exceeds the previously adjusted interval grows on the ground, the operator adjusts the interval. It is possible to pull out the grass without any adjustment, and thereafter, the operator can pull out the normal grass that is held by the interval before expansion without adjusting the interval.

  Next, embodiments of the present invention will be described in more detail with reference to the accompanying drawings. FIG. 1 is an explanatory side view showing a configuration example of the weeding machine of the present embodiment, FIG. 2 is an explanatory plan view showing the weeding machine of the present embodiment shown in FIG. 1, and FIG. It is explanatory front view which shows the weeding machine of this embodiment shown in FIG. 4 is an explanatory front view showing the support of the weeding machine of this embodiment shown in FIG. 1, and FIG. 5 shows the system configuration of the control device of the weeding machine of this embodiment shown in FIG. FIG. 6 is a flowchart showing a control flow of the control device of the weeding machine of this embodiment shown in FIG. 1, and FIGS. 7 to 12 are weeding by the weeding machine of this embodiment shown in FIG. It is explanatory drawing which shows operation | movement. In FIG. 2, in order to facilitate understanding of the structure, a first roller, which will be described later, is illustrated by being shifted from the actual position in the direction of the arrow in the drawing.

  The weeding machine 1 is a weeding machine that pulls out grass growing on the ground while moving forward, and as shown in FIG. A first roller 4 that is pivotally supported via a support 3 and a shaft that is pivotally supported by the base 2 via the support 3 below and behind the first roller 4. A second roller 5, a pair of wheels 6 rotatably supported on the base 2 behind the second roller 5, and rotating on the ground, and a grass collection pivotally supported behind the base 2 A box 7 and a handle 8 attached so as to rise obliquely backward from the base 2 are provided. The front refers to the direction indicated by the arrow in the figure.

  As shown in FIGS. 2 and 3, the base body 2 includes a pair of side plates 21 and a top plate 22 that connects the side plates 21, and is formed by bending a metal plate into a square U shape. The first roller 4, the second roller 5, the grass collection box 7, and the like are accommodated in an inverted U-shape.

  As shown in FIG. 4, the support 3 is composed of a substantially I-shaped first support plate 31 and a substantially inverted L-shaped second support plate 32, and each pair is attached to the side plate 21 of the base 2. ing. The first support plate 31 is pivotally supported inside the side plate 21 via a rotation shaft 33 that penetrates the upper portion, and the first roller 4 via a first rotation shaft 41 that penetrates the lower portion. Is pivotally supported. Further, since the rotation shaft 33 is provided in the side plate 21 and penetrates the square hole 34 formed in two stages, the position of the first support plate 31 can be changed in the vertical direction. On the other hand, the second support plate 32 is pivotally supported on the outer side of the side plate 21 via a rotating shaft 33 that penetrates the front portion, is fixed to the side plate 21 via a bolt 35 that penetrates the rear portion, and penetrates the lower portion. The second roller 5 is rotatably supported via the second rotating shaft 42.

  As shown in FIG. 4A, the support 3 attached to the right side plate 21 further includes a distance adjusting screw 36 and a roller clamping tension coil spring 37. The distance adjusting screw 36 has a head abutting against the rear end portion of the first support plate 31 and a front end portion screwed into the front end portion of the second support plate 32. By adjusting the projecting length of the distance adjusting screw 36 from the second support plate 32, the first support plate 31 is rotated, and the distance between the first rotation shaft 41 and the second rotation shaft 42. That is, the distance between the first roller 4 and the second roller 5 can be adjusted. Further, the roller clamping tension coil spring 37 includes a first latching bolt 38 provided at the front end of the first support plate 31 and a second latch provided at the rear end of the second support plate 32. The first support plate 31 is hooked to the bolt 39 and urged in a direction to bring the first support plate 31 closer to the second support plate 32. On the other hand, the support 3 attached to the left side plate 21 does not include the interval adjusting screw 36 and the roller clamping tension coil spring 37 as shown in FIG.

The first roller 4 has a cylindrical shape with a diameter of about 28 mm, and is provided at a position where the lowermost part of the outer peripheral surface does not contact the ground. The first roller 4 is driven by a first electric motor 43 that is directly connected, and is about 100 min ⁻¹ (100 rpm) around a first rotating shaft 41 provided in a direction perpendicular to the moving direction and in the horizontal direction. Rotate with.

  The outer peripheral surface of the first roller 4 is formed of a rubber material having a predetermined thickness, and the grass contacting the outer peripheral surface of the first roller 4 is moved downward from the front of the first roller 4 by friction. It is possible to guide backwards through. In the present embodiment, a pair of flange portions 44 are provided at the axial end of the first roller 4 to prevent grass from being caught by the first rotating shaft 41.

The second roller 5 has a columnar shape with a diameter of about 40 mm, and has a plurality of protruding plates 45 extending in the axial direction on the outer peripheral surface. The second roller 5 is juxtaposed behind the first roller 4, and when the projection plate 45 a is closest to the outer peripheral surface of the first roller 4, the tip of the projection plate 45 a and the first roller 4 are arranged. It is provided at a position having a distance C ₀ that can sandwich the grass by the outer peripheral surface (see FIG. 8). The second roller 5 is driven by a second electric motor 47 connected by a belt drive mechanism 46 and rotates around a second rotating shaft 42 provided in parallel with the first rotating shaft 41. Further, with the rotation of the second roller 5, the tip portions of the plurality of protruding plates 45 rotate at about 120 min ⁻¹ on a rotation path having an outer diameter of 50 mm.

  The protruding plate 45 protrudes below the wheel 6 when the weeding machine 1 is installed on the ground and the protruding plate 45 is vertically downward. That is, the protruding plate 45 is disposed at a position where the ground below the second roller 5 is thinly scraped when the second roller 5 rotates.

  Further, in the present embodiment, a plurality of protruding plates 45 are attached to the outer periphery of the second roller 5 at five equal intervals. As a result, when one protruding plate 45 b is in a proximity position with respect to the outer peripheral surface of the first roller 4, the other protruding plate 45 c located behind the first protruding plate 45 b in the rotational direction is moved to the first roller 4. It arrange | positions so that it may come to the position which grinds the ground 72 located between the 2nd rollers 5 (refer FIG.7 (c)).

  The grass collection box 7 is a rectangular parallelepiped box having a front surface and an upper surface opened to form an opening 51, and a bottom surface provided with a through hole 52 through which earth such as soil, sand, and stone can pass. The grass collection box 7 is disposed behind the second roller 5 and includes a contact portion 53 that contacts the protruding plate 45 of the second roller 5 at the front edge. Further, the grass collection box 7 is rotatably attached to the side plate 21 via a rotation shaft 54 at a position ahead of the center in the front-rear direction, and contacts a stopper provided inside the side plate 21 (not shown). The contact is positioned so that the bottom surface is horizontal. This grass collection box 7 has a damping coil spring 55 for damping that urges the swinging grass collection box 7 downward, with one end hooked to the side surface of the grass collection box 7 and the other end hooked to the side plate 21. It is attached.

The handle 8 is formed of a steel pipe and has a height that is located exactly at the waist level of a person of average height. A control device 61 and a battery 62 are attached to the intermediate portion. The casing 63 in which the control device 61 is built is provided with a power switch 64 that can be switched between “normal”, “reverse”, and “OFF”, and the first electric motor 43 is connected to the first electric motor 43 by electricity supplied from the battery 62. The second electric motor 47 is driven. When the power switch 64 is in the “positive” position, the control device 61 rotates the first electric motor 43 forward and the second electric motor 47 backward, thereby rotating the first roller 4 forward. At the same time, the second roller 5 is rotated backward. The forward rotation refers to the rotation direction when the upper end portion rotates forward when each motor and each roller is viewed from the axial direction, and the backward rotation refers to the reverse rotation.

  When the power switch 64 is positioned in the “reverse” direction, the control device 61 rotates the first electric motor 43 rearward and the second electric motor 47 forward, thereby causing the first roller 4 to move rearward. The second roller 5 is rotated forward while rotating. Further, when the power switch 64 is positioned “OFF”, the control device 61 stops the supply of electricity from the battery 62 and stops the first electric motor 43 and the second electric motor 47, thereby The rotation of the first roller 4 and the second roller 5 is stopped.

  The control device 61 has the system configuration shown in FIG. The power switch 64 includes a motor forward rotation switch 65 that issues a forward rotation command and a motor reverse rotation switch 66 that issues a reverse rotation command, and is connected to a battery 62 and a power supply circuit 67. The forward rotation command is a command for rotating the first electric motor 43 forward and rotating the second electric motor 47 backward (this is referred to as “forward rotation”). Rotates forward and the second roller 5 rotates backward. On the other hand, the reverse rotation command is a command for rotating the first electric motor 43 backward and rotating the second electric motor 47 forward (this is referred to as “reverse rotation”), whereby the first roller 4 Rotates backward and the second roller 5 rotates forward.

  The power supply circuit 67 is connected to the motor rotation direction switching circuit 68, the motor driver 69, and the determination circuit 70, and supplies electricity from the battery 62 to each.

  The motor rotation direction switching circuit 68 receives one of the above-described forward rotation command, reverse rotation command, and later-described reverse command, and issues a rotation direction command to the motor driver.

The motor driver 69, both to the drive current driving the DC motor 81 is supplied to the DC motor 81, and controls the amount of current and the current direction of the driving current. Here, the DC motor 81 refers to the first electric motor 43 and the second electric motor 47 shown in FIG. The amount of drive current flowing between the motor driver 69 and the DC motor 81 is measured by the current sensor 82 .

The determination circuit 70 issues an inversion command to the motor rotation direction switching circuit 68 when the amount of drive current measured by the current sensor 82 exceeds a specified value. The reversal command is a command for reversing the rotation of the first electric motor 43 and the second electric motor 47. For example, when the first electric motor 43 and the second electric motor 47 are rotating in the forward direction, the first electric motor 43 and the electric motor are reversed in accordance with the reverse command.

  Now, the control flow of the control device 61 is as shown in FIG.

  First, when the power switch 64 is set to the “forward” or “reverse” position, the control device 61 sets the overload timer to 0 (step (hereinafter referred to as “ST”) 1).

  Next, the control device 61 checks whether or not “overload timer> 0” (ST2). In the case of “YES”, the value of the overload timer decreases by 1, that is, waits for the overload timer to elapse for 1 second (ST3), and proceeds to ST14 described later. In the case of “NO”, it is checked whether the “motor forward rotation switch is ON” (ST4) and whether the “motor reverse rotation switch is ON” is checked (ST5 (ST5a, ST5b)).

  In ST4 and ST5, when “the motor forward rotation switch is ON and the motor reverse rotation switch is ON”, the control device 61 considers that either or both of the motor forward rotation switch and the motor reverse rotation switch are faulty, The first electric motor 43 and the second electric motor 47 are stopped (ST6). In ST6, the first roller 4 and the second roller 5 are stopped. If “the motor forward rotation switch is ON and the motor reverse rotation switch is not ON”, the control device 61 issues a normal rotation command to the motor rotation direction switching circuit 68. The motor rotation direction switching circuit 68 issues a rotation direction command to the motor driver 69 to cause the first electric motor 43 and the second electric motor 47 to perform normal rotation (ST7). In ST7, the first roller 4 rotates forward and the second roller 5 rotates backward.

  When the “motor forward rotation switch is not ON and the motor reverse rotation switch is ON”, the control device 61 issues a reverse rotation command to the motor rotation direction switching circuit 68. The motor rotation direction switching circuit 68 issues a rotation direction command to the motor driver 69 to reversely rotate the first electric motor 43 and the second electric motor 47 (ST8). In ST8, the first roller 4 rotates backward, and the second roller 5 rotates forward. Further, when “the motor forward rotation switch is not ON and the motor reverse rotation switch is not ON”, the control device 61 considers that either or both of the forward rotation switch and the reverse rotation switch are faulty, and the first The electric motor 43 and the second electric motor 47 are stopped (ST9). In ST9, the first roller 4 and the second roller 5 are stopped.

Next, in ST6 and ST9, the control device 61 ends the control process. In ST7 and ST8, the control device 61 causes the current sensor 82 to measure the amount of drive current flowing between the motor driver 69 and the DC motor 81 (ST10).

  Next, control device 61 causes determination circuit 70 to determine whether or not the amount of drive current measured is “drive current> specified value” (ST11). If “YES”, control device 61 sets an overload timer (ST12), and determination circuit 70 issues a reverse command to motor rotation direction switching circuit 68. The motor rotation direction switching circuit 68 issues a rotation direction command to the motor driver 69 to reverse the rotation directions of the first electric motor 43 and the second electric motor 47, that is, when the motor is rotating normally. If the rotation is reversed, the rotation is reversed (ST13), and the process proceeds to ST14. If “NO”, the process directly proceeds to ST14.

  Next, the control device 61 checks whether or not “power switch = OFF” (ST14). If “YES”, that is, if the power switch 64 is set to the OFF position, the control process is terminated. If “NO”, that is, if the power switch 64 is set to a position other than OFF, the process returns to ST2.

  In the above control flow, when the determination circuit 70 determines that the current amount of the drive current exceeds the specified value when the first electric motor 43 and the second electric motor 47 are rotating forward (in ST11, “ The flow of “YES” will be described.

  When the amount of drive current exceeds a specified value (for example, 1.5 A), the control device 61 sets an overload timer to, for example, 5 seconds (ST12), and the first electric motor 43 and the second electric motor 47 are set. The direction of rotation is reversed and reversed (ST13). If “NO” in ST14, the process proceeds to ST2 again.

  Next, since the overload timer> 0 in ST2, the control device 61 waits until the overload timer is decremented by 1, that is, the overload timer reaches 4 seconds (ST3), and proceeds to ST14 again. Then, ST14, ST2 and ST3 are repeated until the value of the overload timer becomes 0, and during this time, the first electric motor 43 and the second electric motor 47 are continuously reversed. When the overload timer reaches 0, the control device 61 becomes “NO” in ST2, proceeds to ST4, proceeds to ST5a if “YES” in ST4, and proceeds to ST7 if “NO” in ST5a. In ST7, the control device 61 switches the rotation direction of the first electric motor 43 and the second electric motor 47 to perform normal rotation. As described above, when the determination circuit 70 determines that the amount of drive current exceeds the specified value when the first electric motor 43 and the second electric motor 47 are rotating forward, the first electric motor 43 The motor 43 and the second electric motor 47 are reversed for 5 seconds, and then return to normal rotation again.

  Next, weeding work by the weeding machine 1 of the present embodiment will be described. First, when the operator holds the handle 8 and sets the power switch 64 to the “positive” position, the control device 61 sets the overload timer to 0 (ST1). The control device 61 checks whether or not “overload timer> 0” (ST2), and if “NO” in ST2, checks whether the “motor forward rotation switch is ON” (ST4). If “YES” in ST4, the control device 61 checks whether the “motor reverse rotation switch is ON” (ST5a), and if “NO” in ST5a, issues a forward rotation command to generate the first electric motor. By rotating the motor 43 forward and rotating the second electric motor 47 backward (forward rotation), the first roller 4 is rotated forward and the second roller is rotated backward (ST7).

Next, the control device 61 uses the current sensor 82 to measure the amount of drive current flowing between the motor driver 69 and the DC motor 81 (ST10). The control device 61 uses the determination circuit 70 to determine whether the measured drive current amount is “drive current> specified value” (ST11). If “NO” in ST11, “power switch = OFF” Is checked (ST14). If “NO” in ST14, the control device 61 returns to ST2, repeats the above steps, and continues to normally rotate the first electric motor 43 and the second electric motor 47. As a result, the first roller 4 rotates forward and the second roller rotates backward.

Next, when the operator holds the handle 8 and moves forward while pushing the weeding machine 1 forward in this state, the weeding machine 1 moves forward as shown in FIG.

  Next, when the weeding machine 1 moves forward, the grass 71 growing on the ground comes into contact with the outer peripheral surface of the first roller 4. As shown in FIG. 7B, the grass 71 passes from the front of the first roller 4 to the rear by the friction of the outer peripheral surface of the first roller 4 and the forward rotation of the first roller 4. Be guided.

  Next, when the weeding machine 1 moves further forward, the grass 71 guided rearward comes between the first roller 4 and the second roller 5. As shown in FIG. 7C, the grass 71 is brought into a close position with respect to the outer peripheral surface of the first roller 4 with the forward rotation of the first roller 4 and the backward rotation of the second roller 5. While being sandwiched between the tip of a certain projection plate 45b and the outer peripheral surface of the first roller 4, it is pulled upward. At this time, the grass 71 is reliably clamped by the friction of the outer peripheral surface of the first roller. In addition, as the second roller 5 rotates backward, the protruding plate 45c located behind the outer peripheral surface of the first roller 4 in the rotational direction from the protruding plate 45b positioned in the proximity of the first roller 4 and the first roller 4 It becomes the state which stabbed into the ground 72 around the root of the grass 71 located between the two rollers 5.

  Next, the sandwiched grass 71 is dug out of the ground 72 around the root by another projection plate 45c in accordance with the forward rotation of the first roller 4 and the backward rotation of the second roller 5. As shown in FIG. 7D, the root is separated from the ground.

In this embodiment, when the diameter of the first roller 4 is D1, the rotation number is N1, the diameter of the rotation track of the tip of the projection plate 45 of the second roller 5 is D2, and the rotation number is N2. Then, it is comprised so that it may become D1 * N1 <D2 * N2. That is, the peripheral speed 2 (= π × D2 × D2) at the tip of the projection plate 45 of the second roller 5 is higher than the peripheral speed V1 (= π × D1 × N1) on the outer peripheral surface of the first roller 4. Is configured to be faster. Therefore, as shown in FIG. 8, the sandwiched grass 71 is caused by the forward rotation of the first roller 4 and the backward rotation of the second roller 5, as shown in FIG. 8. The entire grass 71 including the roots is pulled out from the ground, passing through the gap C ₀ with the tip of the projection plate 45a closest to the surface and being lifted upward and carried backward.

  Next, as shown in FIG. 9, the extracted grass 71 is conveyed backward from the front of the second roller 5 to the rear as the second roller 5 rotates rearward, and in the grass collection box 7. Is housed in.

  At this time, when the projection plate 45 comes into contact with the contact portion 53 as the second roller 5 rotates backward, the grass collection box 7 has the rear portion upward with the rotation shaft 54 as the center as shown in FIG. Lifted. Further, as shown in FIG. 10, when the contact of the projection plate 45 with the contact portion 53 is released as the second roller 5 is rotated backward, the grass collection box 7 is moved downward by the damping tension coil spring 55. The posture is returned to the state before the rear portion is lifted upward.

  As described above, as the second roller 5 is rotated backward, the projection plate 45 comes into contact with the contact portion 53 or comes out of contact, so that the grass collection box 7 is lifted or lifted rearward. It can be swung by returning to the posture before being pushed. The grass 71 housed in the grass collection box 7 by the swinging of the grass collection box 7 separates soils such as soil, sand, stones, and the like attached to the roots from the roots, and the separated soils. Is sieved downward from the through hole 52. Only the grass 71 from which the earth attached to the roots has been removed remains in the grass collection box 7.

  With the above operation, the weeding machine 1 according to the present embodiment can reliably extract the entire grass 71 including the roots, and can remove the soil adhering to the extracted grass roots. Further, the weeding machine 1 of the present embodiment is configured such that the peripheral speed V2 at the tip of the protruding plate 45 of the second roller 5 is faster than the peripheral speed V1 at the outer peripheral surface of the first roller 4. As a result, the extracted grass 71 can be carried rearward and accommodated in the grass collection box 7, so that the driving roller 103, the first conveying roller 104, and the like as in the conventional weeding machine 101 Since a configuration such as the plurality of second conveying rollers 105, the tension roller 107, and the belt 106 is not required, the configuration for collecting the extracted grass can be reduced in size.

By the way, the grass growing on the ground has different grass heights, stem thicknesses, and the like depending on the type of grass. Therefore, when using the weeding machine 1, according to the state of the grass growing on the ground, the height of the outer peripheral surface of the first roller 4 with which the grass first contacts and the grass is sandwiched. It is desirable to adjust in advance the interval C ₀ between the outer peripheral surface of one roller 4 and the tip of the projection plate 45a closest to the outer peripheral surface.

  First, the height of the outer peripheral surface of the first roller 4 is adjusted as follows. The operator adjusts the position of the rotation shaft 33 that passes through the upper part of the first support plate 31 that passes through the square hole 34 of the side plate 21. As a result, the position of the first support plate 31 is adjusted in the vertical direction. As a result, the height of the first roller 4 that rotates about the first rotation shaft 41 that penetrates the lower portion of the first support plate 31 is increased. That is, the height of the outer peripheral surface of the first roller 4 is adjusted.

  Therefore, the weeding machine 1 of this embodiment can adjust the height of the outer peripheral surface of the first roller 4 in advance according to the state of the grass growing on the ground, so that the grass falls over or breaks. The first roller 4 comes into contact with the outer peripheral surface of the first roller 4 and is guided rearwardly as the first roller 4 rotates backward, and is sandwiched between the outer peripheral surface of the first roller 4 and the protruding plate 45. . Therefore, the weeding machine 1 of this embodiment can draw out the grass growing on the ground regardless of the kind and height of the grass.

On the other hand, the interval _C0 is adjusted as follows. The operator adjusts the protruding length from the second support plate 32 with respect to the interval adjusting screw 36 of the support 3 attached to the right side plate 21 shown in FIG. When the head of the distance adjusting screw 36 comes into contact with the rear end portion of the first support plate 31, the first support plate 31 rotates, and the first support plate 31 and the second support plate 32 are connected to each other. The distance is adjusted. As a result, the distance between the first rotating shaft 41 and the second rotating shaft 42 is adjusted, and as a result, the outer peripheral surface of the first roller 4 and the projection plate 45a located closest to the outer peripheral surface are arranged. interval C ₀ of the distal end portion is adjusted.

Therefore, the weeding machine 1 according to the present embodiment has a height of the outer peripheral surface of the first roller 4, the outer peripheral surface of the first roller 4, and the outer peripheral surface according to the state of the grass growing on the ground. The distance C _{0 from} the tip of the projection plate 45a at the closest position can be adjusted in advance. Thus, grass can together be held between the projection plates 45a and the outer peripheral surface of the first roller 4, it passes through the gap C _0. Therefore, the weeding machine 1 of the present embodiment can pull out the grass growing on the ground regardless of the kind of grass, the thickness of the stem, the degree of density, and the like.

Further, the weeding machine 1 of the present embodiment temporarily sets the interval C ₀ even when grass having a stem thickness and a degree of density exceeding the previously adjusted interval C ₀ grows on the ground. The grass can be pulled out by expanding. The interval _C0 is temporarily extended as follows.

First, as the weeding machine 1 moves forward, a stem that exceeds the interval C ₀ between the outer peripheral surface of the first roller 4 and the tip of the protruding plate 45a located closest to the outer peripheral surface. The grass 71 having a thickness and a degree of density contacts the outer peripheral surface of the first roller 4. As shown in FIG. 11A, the grass 71 passes from the front of the first roller 4 to the rear by the friction of the outer peripheral surface of the first roller 4 and the forward rotation of the first roller 4. Be guided.

Next, when the weeding machine 1 moves further forward, the grass 71 guided rearward comes between the first roller 4 and the second roller 5. As shown in FIG. 11 (b), the grass 71 is brought closer to the outer peripheral surface of the first roller 4 with the forward rotation of the first roller 4 and the rearward rotation of the second roller 5. While being sandwiched between the tip of a certain projection plate 45b and the outer peripheral surface of the first roller 4, it is pulled upward. Further, since the grass 71 is greater than distance C _0, a force in a direction to widen the spacing C ₀ to the tip portion of the projection plate 45b of the outer peripheral surface of the first roller 4 and the second roller 5 is applied. As a result, the first roller 4 rotates forward with the rotation shaft 33 as a fulcrum through the first support plate 31, so that the interval C ₀ is against the urging force of the roller clamping tension coil spring 37. It is extended grass 71 the clamping possible spacing C _1. And the grass 71 is clamped between the outer peripheral surface of the 1st roller 4, and the front-end | tip part of the projection plate 45b of a 2nd roller.

Next, as shown in FIG. 11C, the sandwiched grass 71 is a distance between the outer peripheral surface of the first roller 4 and the tip of the protruding plate 45a located closest to the outer peripheral surface. through the C ₁ is pulled upwardly. Further, the grass 71 sandwiched between the roots is separated from the ground by cutting the ground 72 around the root by the projecting plate 45c located behind the projecting plate 45a in the rotation direction. Thereby, the grass 71 whole including a root is pulled out from the ground.

Next, as shown in FIG. 11 (d), the extracted grass 71 is conveyed rearward from the front of the second roller 5 along with the rearward rotation of the second roller 5. Further, when the grass 71 is removed between the outer peripheral surface of the first roller 4 and the tip end portion of the projection plate 45 due to the grass 71 being carried rearward, the interval C ₁ is separated from the roller clamping tension coil spring 37. It is caused to return to the interval C ₀ prior to expansion by the adjustment screw 36.

By the above operation, the weeding machine 1 of the present embodiment has a distance C ₀ between the previously adjusted outer peripheral surface of the first roller 4 and the tip of the protruding plate 45a located closest to the outer peripheral surface. When the grass 71 having a stem thickness and density that exceeds the height of the grass 71 grows on the ground, the interval C ₀ is expanded to the interval C ₁ where the grass 71 can be sandwiched. The grass 71 can be pulled out without bothering. Further, grass cutting machine 1 of this embodiment, since the return to the interval C ₀ in advance adjusted the gap C ₁ after withdrawal of the grass 71, without troubling the operator's hands, pinching the interval C ₀ The normal grass 71 can be pulled out.

By the way, not only grass grows on the ground, but also foreign objects such as large stones and garbage may fall. An interval in which the foreign object expands the interval C ₀ between the outer peripheral surface of the first roller 4 and the tip of the projection plate 45a closest to the outer peripheral surface to the limit (hereinafter referred to as “expansion limit interval”). When the size does not exceed C _max , the weeding machine 1 can collect the foreign matter in the grass collection box 7 as described above. However, if the foreign matter of a size greater than the extension limit interval C _max is, even if the gap C ₀ is extended to the extension limit interval C _max, foreign matter and the outer peripheral surface of the first roller 4 projecting It will stay without being able to pass between the plates 45. Then, due to the retention of the foreign matter, the outer peripheral surface of the first roller 4 and the projection plate 45 are damaged, or the rotation of the first roller 4 and the rotation of the second roller 5 are stopped, so that the first The electric motor 43 and the second electric motor 47 may be overloaded, and the weeding machine 1 may be damaged. The weeding machine 1 according to the present embodiment can prevent breakage due to mixing of large foreign matters as follows.

First, when the weeding machine 1 moves forward, the stone 73 larger than the expansion limit interval C ₀ contacts the outer peripheral surface of the first roller 4 between the first roller 4 and the second roller 5. Then, as shown in FIG. 12 (a) shows, a force is applied in a direction to widen the spacing C ₀ by a stone 73, extended to the limit interval C _max against the force of the interval C ₀ is a coil spring 37 tension roller nip Expanded. The expansion limit interval C _max is determined by the spring coefficient of the roller coil tension coil spring 37, the structure of the support 3, and the like. The stone 73 is sandwiched between the front end portion of the protruding plate 45 b located close to the outer peripheral surface of the first roller 4 and the outer peripheral surface of the first roller 4. With the rotation and the backward rotation of the second roller 5, it is pulled upward. However, since the stone 73 cannot pass between the outer peripheral surface of the first roller 4 and the tip of the projection plate 45b, the stone 73 is between the outer peripheral surface of the first roller 4 and the tip of the projection plate 45b. The stone 73 stays. Due to the staying, the rotation speed of the first roller 4 and the second roller 5 decreases or the rotation stops, and the first electric motor 43 and the second electric motor 47 are overloaded.

Next, when the control device 61 detects that the drive current measured by the current sensor 82 exceeds a specified value (for example, 1.5 A) (in the case of “YES” in ST11), the control device 61 overloads. For example, the timer is set to 5 seconds, and a reverse command is issued to reverse the rotation direction of the first electric motor 43 and the second electric motor 47 for 5 seconds, that is, the first electric motor 43 is rotated backward. At the same time, the second electric motor 47 is rotated forward. As a result, as shown in FIG. 12B, the first roller 4 rotates forward and the second roller 5 rotates backward, and the staying stone 73 is pulled downward along with these rotations. The nipping between the outer peripheral surface of the first roller 4 and the protruding plate 45b is released and falls to the ground.

Next, when the stone 73 disappears between the outer peripheral surface of the first roller 4 and the tip of the projection plate 45b, as shown in FIG. 12C, the expansion limit interval _Cmax is the tension coil spring 37 for pinching the roller. It is caused to return to the interval C ₀ prior to expansion by the urging force and the interval adjustment screw 36.

  Next, when the overload timer reaches 0, that is, when 5 seconds elapses, the control device 61 causes the first electric motor 43 and the second electric motor 47 to rotate forward (ST2), whereby FIG. d) As shown, the first roller 4 rotates forward again and the second roller 5 rotates backward.

As described above, in the weeding machine 1 of the present embodiment, foreign matter 73 such as stones and dust larger than the expansion limit interval _Cmax stays between the outer peripheral surface of the first roller 4 and the tip of the protruding plate 45b. Also in this case, the rotation of the first electric motor 4 and the second electric motor 47 is continuously reversed for a predetermined time, so that the rotation of the first roller 4 and the second roller 5 is reversed and stays at the interval. Since the foreign matter 73 is dropped on the ground, it is possible to prevent damage caused by the large foreign matter 73 exceeding the expansion limit interval _Cmax .

Further, the weeding machine 1 of the present embodiment is the control device 61 that measures the drive current flowing through the DC motor 81 and determines that the overload state occurs when the obtained drive current exceeds a predetermined value. Since this measurement can be realized with a simple circuit configuration, a weeding machine with a simple configuration can be realized.

  Since the weeding machine 1 of the present embodiment is configured as described above, the operator can operate the weeding machine 1 in an easy posture by holding the handle 8 at the waist and operating the weeding machine 1. Can reduce the burden of weeding work. Further, since the weeding machine 1 has a small configuration, it is convenient to carry and suitable for weeding work in a home garden or the like. Further, since the power source is the electric motors 43 and 47, the noise is low, and it is suitable for the early morning weeding work. Furthermore, since the weeding machine 1 includes the battery 62, the weeding machine 1 is suitable for weeding work such as a park open space where it is difficult to obtain power.

In the weeding machine 1 of the present embodiment, the first roller 4 has an outer peripheral surface made of a rubber material, but the outer peripheral surface may be made of metal and provided with irregularities on the surface. In addition, although the number of the projection plates 45 of the second roller 5 is five, it can be changed to an arbitrary number depending on the size of the second roller 5 and the like. Further, the rotation speeds of the first roller 4 and the second roller 5 may be variable. Furthermore, the control device 61 measures the amount of drive current flowing between the motor driver 69 and the DC motor 81 by the current sensor 82. However, the rotational speed of the DC motor 81 is provided by providing a tachometer (not shown). May be measured. In addition, the control device 61 reverses the rotation directions of the first electric motor 43 and the second electric motor 47 and rotates the original electric rotation direction again after the overload timer reaches zero. It may be stopped.

Explanatory side view showing one configuration example of the weeding machine of the present embodiment. Explanatory top view which shows the weeding machine of this embodiment shown in FIG. Explanatory front view which shows the weeding machine of this embodiment shown in FIG. Explanatory front view which shows the support body of the weeding machine of this embodiment shown in FIG. The block diagram which shows the system configuration | structure of the control apparatus of the weeding machine of this embodiment shown in FIG. The flowchart which shows the control flow of the control apparatus of the weeding machine of this embodiment shown in FIG. Explanatory drawing which shows the weeding operation | movement by the weeding machine of this embodiment shown in FIG. Explanatory drawing which shows the weeding operation | movement by the weeding machine of this embodiment shown in FIG. Explanatory drawing which shows the weeding operation | movement by the weeding machine of this embodiment shown in FIG. Explanatory drawing which shows the weeding operation | movement by the weeding machine of this embodiment shown in FIG. Explanatory drawing which shows the weeding operation | movement by the weeding machine of this embodiment shown in FIG. Explanatory drawing which shows the weeding operation | movement by the weeding machine of this embodiment shown in FIG. Explanatory drawing which shows the weeding machine of a prior art.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 1 ... Weeding machine, 3 ... Space | interval adjustment part, 4 ... 1st roller, 5 ... 2nd roller, 7 ... Grass collection box, 37 ... Temporary expansion means, 37 ... Energizing means, 41 ... 1st roller , 43 ... first electric motor, 45 ... projection plate, 45a ... projection plate located closest to the outer peripheral surface of the first roller, 45b ... proximal to the outer peripheral surface of the first roller Projection plate in position, 45c ... Projection plate in the rotational direction rearward from the projection plate in the proximity of the outer peripheral surface of the first roller, 47 ... Second electric motor, 49 ... Overload detection means, 52 ... Through hole, 53 ... contact portion, 55 ... return means, 61 ... control means, 70 ... overload detection means, 71 ... grass, 72 ... ground located between the first roller and the second roller.

Claims (2)

A weeding machine that pulls out the grass growing on the ground while moving forward,
A first roller that rotates forward about a rotation axis that is perpendicular to the moving direction and in a horizontal direction, and is arranged in parallel behind the first roller and extends in the axial direction on the outer peripheral surface. A second roller having a plurality of protruding plates and rotating backward, and a grass collection box disposed behind the second roller ;
The second roller has an interval at which grass can be sandwiched between the tip of the protruding plate and the outer peripheral surface of the first roller when the protruding plate is closest to the outer peripheral surface of the first roller. In place,
The grass collection box includes a contact portion that contacts the protruding plate, and is formed so as to be swingable in accordance with the backward rotation of the second roller.
A weeding machine comprising an interval adjusting unit capable of adjusting an interval between an outer peripheral surface of the first roller and a tip of the protruding plate . The weeding machine according to claim 1,
The interval adjusting unit includes a temporary expansion unit that temporarily expands the interval when a force is applied in a direction to increase the interval between the outer peripheral surface of the first roller and the tip of the protruding plate ; A weeding machine comprising biasing means for biasing the interval expanded to a normal interval.

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