JPH0437382Y2 - - Google Patents

Description

[Detailed description of the invention] "Industrial application field" This invention connects a support frame to a traveling vehicle via a link mechanism so that it can move up and down, and a planting section is provided on the support frame so that it can swing freely in the left and right directions. The rice transplanter also includes a sensor float that detects the horizontal inclination of the planting section, and a rolling adjustment member that tilts the planting section left and right, and performs rice planting work by supporting the planting section approximately horizontally with respect to the planting field surface. This invention relates to a rolling control device for a machine.

"Conventional Technology" Conventionally, there has been a technology in which sensor floats are placed on both sides of the planting area to detect the horizontal inclination of the planting area.

"Problems to be Solved by the Invention" In the prior art, the sensor float hangs down even when the sensor float is not needed except during rolling control, so the sensor float is likely to collide with a ridge or the like and be damaged. At the same time, the sensor floats caused problems such as disturbing the planting field, impairing the flow of water on the field, and causing problems in the growth and growth of seedlings.

"Means for Solving the Problems" However, the present invention provides a device equipped with a float sensor that detects the difference in ground height between the left and right sides of the planting area with respect to the planted field surface, and a sensor float that operates the float sensor. The present invention is characterized in that a lifting member for lifting and supporting is provided, and the sensor float is raised and fixed by the pulling member in conjunction with the off-operation of the float sensor.

"Function" Therefore, the sensor float can be automatically stored in a fixed position except during rolling control, and damage to the sensor float can be prevented, and the problem of roughening the planted field surface due to the sensor float can be avoided.
It is possible to easily achieve uniform growth of seedlings by preventing deterioration of water flow on the rice field, and it is possible to easily improve handling operability and safety compared to the conventional method.

"Embodiments" Examples of the present invention will be described below in detail based on the drawings. Figure 1 is an explanatory diagram of the raising and lowering operation of the sensor float.
Fig. 2 is a side view of the riding rice transplanter, and Fig. 3 is a plan view of the same. A front wheel 6 for driving in paddy fields is supported on both sides of the front part of the transmission case 4 via an axle case 5, and a transmission case 7 is connected to both sides of the rear part of the transmission case 4. Rear wheel 8 for running in paddy fields at the rear end of case 7
to support. Then, a spare seedling stand 10 is attached to both sides of the bonnet 9 that covers the engine 2, etc., and the transmission case 7, etc. is covered with the vehicle body cover 12 forming the step 11, and the vehicle body cover 1
2, a driver's seat 13 is attached to the upper part, and a steering handle 14 is attached to the rear of the bonnet 9 in front of the driver's seat 13.
will be established.

In addition, reference numeral 15 in the figure is a planting section that is equipped with a seedling stand 16 for multi-row planting, a plurality of planting claws 17, etc. The planting claws are supported by the planting case 20 via the rails 18 and guide rails 19 so as to be slidable back and forth in the left and right directions, and are attached to the planting case 20 via the planting arm 21 and the planting claw drive shaft 22 which are moved by a crank. Install 17. And the planting case 2
Leveling floats 23, 24, 24 for planting below 0
are supported via a planting depth adjustment link 25, each of the planting cases 20... is connected to a planting mission case 27, and a three-point link mechanism 30 including a top link 28 and a lower link 29 is connected. This planting mission case 27 is placed on the rear side of the traveling vehicle 1 using
A hydraulic cylinder 31 for raising and lowering the planting part 15 is interposed between the rear part of the transmission case 4 and the top link 28,
While the planting section 15 is raised and lowered by the expansion and contraction motion of the hydraulic cylinder 31, the planting section 15 is lowered to land each of the floats 23 and 24, and one seedling is placed on the seedling stand 16 which is moved back and forth from side to side. It is configured such that the seeds are taken out and planted one by one using the planting claws 17.

In addition, in the figure, 32 is a travel gear shift lever, 33 is a planting lift lever, 34 is a planting depth sensitivity adjustment lever, and 35 is a planting depth sensitivity adjustment lever.
is a travel clutch pedal, and 36, 36 are left and right brake pedals.

As shown in FIGS. 4 to 7, seedling take-out plates 37 that face the lower end of the slanted seedling stand 16 are fixed on both sides of the top of the planting case 20, and the seedling take-out openings 38 of the seedling take-out plates 37 are connected to the planting claws 17. At the same time, the planting depth adjustment shaft 39 connecting the planting depth adjustment link 25 is pivotally supported on the lower surface side of the planting case 20, and the planting depth adjustment shaft 39 is supported on the lower side of the planting case 20, and a lever guide 40 is installed on the left side of the planting mechanism case 27. A planting depth adjustment lever 41 provided at A seedling vertical harvesting adjustment lever 43 is attached to the right side of the transmission case 27 on the opposite side through a lever guide 42.

Further, a board 44 is fixed to the front outer surface of the left and right outer planting cases 20, 20, and the base end of a support 45 supporting the seedling stand 16 is integrally connected to the board 44 via the guide rail 19. A pipe frame 46 integrally connected to the substrate 44 is provided to extend substantially horizontally toward the outside of the machine, and a streak marker 47 that forms a planting locus on the unplanted side rice field is supported by the pipe frame 46 in a freely undulating manner.

Also, a side bumper 48 surrounding the outside of the end of the seedling take-out plate 37 is bent into an L shape and integrally connected to the base plate 44, and the middle of the front and rear extending portion of the side bumper 48 is connected to the outside end of the pipe frame 46. At the same time, a fulcrum bracket 49 is fixed between the left and right extending portions of the side bumper 48, and left and right sensor floats 50, 50 are placed adjacent to the outer side of the flattened floats 24, 24 on the outermost side of the planting section 15. The sensor float 50 is supported by the bracket 49 via the fulcrum shaft 51, and the rear part of the float 50 moves up and down due to changes in ground pressure, and the amount of vertical displacement is adjusted in conjunction with the up and down movement of the float 50. Potentiometer-type float sensors 52a, 52b for detection are attached to the bracket 50, and configured to convert the amount of vertical displacement of the left and right sensor floats 50, 50 into linear outputs of the left and right float sensors 52a, 52b. are doing.

Further, the lower end of a regulating link 55, which is a regulating tool, is connected to the rear upper surface of the sensor float 50 via a bracket 53 and a pin 54, and a guide pin 56 fixed to the pipe frame 46 is connected to the elongated hole 57 of the link 55. through the elongated hole 57.
The vertical stroke of the sensor float 50 is set depending on the length of the planting part 15 in plan view.
A sensor float 50 is disposed inward from the outermost side bumper 48, and the sensor float 50 is configured to move up and down within a certain range under the guidance of the regulation link 55.

Next, as shown in FIGS. 8 to 10, a hit plate 60 is connected to the rear ends of the top link 28 and the lower link 29 via pins 58 and 59, and upper and lower hit pins 61 and 62 are connected to the hit plate 60. A rolling fulcrum plate 63 serving as a support frame is removably locked through the fulcrum plate 63, and a rolling fulcrum shaft 6 is attached to the fulcrum plate 63.
4, and supports the planting part 15 so as to be able to swing left and right around the fulcrum shaft 64, and the left and right sensors are symmetrically connected to each other around the fulcrum shaft 64. Floats 50, 50 are arranged.

A portal frame 65 is integrally connected to the upper end of the fulcrum plate 63, and a rolling cylinder 68, which is an actuator, is supported at the upper end of the frame 65 via a bracket 66 and a support shaft 67, and the planting section 15 is tilted in the left-right direction. The cylinder 6
8 is connected to the vicinity of the upper end of the fulcrum plate 63, and a support 69 is provided on the planting mechanism case 27 to support the seedling stand 16 via the guide rail 19. A piston rod 72 of the cylinder 68 is connected to the fulcrum plate 63 via a ball joint 71. In addition, a planting input shaft 74 is provided on the right side of the front surface of the planting transmission case 27, and a horizontal sensor 76 is provided on the left side thereof via a bracket 75. The horizontal sensor 76 detects the left and right inclination.
It is configured to be detected by

Next, as shown in FIG. 11, a power steering cylinder 81 is connected to tie rods 79, 80 for steering the front wheels 6, 6, and the steering handle 1 is connected to the tie rods 79, 80.
A hydraulic pump 84 is connected to the cylinder 81 through a power steering valve 83 that is switched by a Pitman arm 82 that is linked to the hydraulic cylinder 31 that raises and lowers the planting section 15 through a lifting valve 85 and the power steering valve 83. A hydraulic pump 84 is connected, and each of the valves 83 and 85 is provided in series with the hydraulic pump 84 via a throttle valve 87 of a branch valve 86.

It also includes a rolling valve 90 having left and right tilting solenoids 88 and 89.
The double-acting rolling cylinder 68 is operated and controlled, and the rolling valve 90 is connected to the hydraulic pump 84 via the throttle valve 91 of the diverter valve 86, and a slow-acting circuit 93 and a short-circuit circuit 94 having a variable throttle valve 92 are connected. A speed change valve 95 is provided which connects the rolling valve 90 and the throttle valve 91 via one of the valves, and the operating speed of the rolling cylinder 68 is changed by switching the valve 95 having a speed change solenoid 96. Due to the pressure reducing action of the valve 91, high pressure oil from the hydraulic pump 84 is always applied to the variable speed valve 95 at a substantially constant pressure regardless of changes in the rotational speed of the engine 2, and the amount of horizontal tilt correction of the planting section 15 per unit time is adjusted. is kept substantially constant regardless of the engine 2 rotation speed, and the rolling cylinder 68 is always operable at the set speed even if the engine 2 rotation speed changes.

Furthermore, as shown in FIG. 12, a horizontal control circuit 97 configured with a microcomputer is provided, and the sensors 52a, 52b, 73, 76 and the solenoids 88, 89, 96 are controlled by the control circuit 97.
and an automatic lamp 98 that displays the automatic control state by lighting, an abnormality alarm lamp 99 that warns of an abnormality detection state by lighting based on the output outside the detection range of the float sensors 52a and 52b, and fixed and automatic lamps. and ridge mode terminal 100
an automatic changeover switch 100 having terminals a, 100b, 100c, and upper left and upper right terminals 101a, 1
01b, and low speed, medium speed and high speed terminals 102a, 102b, 102c.
A control speed changeover switch 102 that changes the duty ratio of the pulses that drive the solenoids 88, 89, and 96, and a control speed changeover switch 102 that changes the duty ratio of the pulses that drive each solenoid 88, 89, and 96, and a Left and right ridge sensors 103a and 103b that detect ridges by bringing sensor arms into contact with each other, left and right marker standing sensors 104a and 104b that are installed on the pipe frame 46 and detect the rising movement of the striation marker 47, and a float sensor 52a. , 52b output and the horizontal sensor 76 output;
Traveling gear shift lever 32 or traveling clutch pedal 35
A main clutch switch 106 detects the "off" operation of the main clutch (not shown) in conjunction with the operation, and each of the switches 77, 78, 100, 10
1, 102, 103a, 103b, 104a, 1
04b, 105, 106 and each of the lamps 9
8 and 99 are connected to the control circuit 97,
The ridge sensors 103a, 103b and marker standing sensors 104a, 104b are provided as discriminating means for determining whether or not ridge processing is being performed, and sensor output switching means is provided to perform control based on the output of the horizontal sensor 76 during ridge processing. The control circuit 97 is provided,
In the center of the field, a float sensor 52 detects the difference in ground height between the left and right sides of the planting section 15 with respect to the planting field surface.
Based on the outputs a and 52b, and the output of a horizontal sensor 76 that detects the horizontal inclination of the planting section 15 with respect to the horizon at the edge of the ridge, the rolling cylinder 68 is operated and controlled to correct the horizontal inclination of the planting section 15. It is configured to do so.

Further, as shown in FIG. 1, the sensor float 5
A lifting lever 107 is provided which is a lifting member for lifting and supporting the float sensor 0, and the lever 107 is connected to the left and right sensor floats 50, 50 via lifting wires 108, 109, and is linked to the off operation of the float sensors 52a, 52b. a lifting solenoid 110 that operates to pull up the lever 107;
and the solenoid 110 is connected to the control circuit 9.
7, and when the output of the float sensors 52a, 52b is turned off, the solenoid 110 is actuated to fix the left and right sensor floats 50, 50 upwardly.

Furthermore, pins 111, 112 and notches 113, 1 are attached to the travel gear shift lever 32 and the planting lift lever 33.
The lifting arms 115 and 116 are brought into engagement and contact with each other via the lever 107, and the wire 11 is connected to the lever 107.
7, 118 to each of the arms 115, 116
The sensor float 50 is lowered at the planting travel position of the traveling shift lever 32, and the sensor float 50 is raised and fixed at other shift positions of the lever 32, and the planting lift lever 33 is lowered and planted. Lower the sensor float 50 at the
The sensor float 50 is configured to be raised and fixed at other operating positions of the lever 33.

This embodiment is constructed as described above, and by performing the switching operation of the manual switch 101 as shown in the flowcharts of FIGS. 13 to 17, the switch 101 is raised to the left as shown in FIG. Or perform left-up or right-up control based on the right-up input, energize the left and right tilt solenoids 88 and 89 to switch the rolling valve 90, operate the rolling cylinder 68, and move the planting section around the rolling fulcrum shaft 64. 15 in the left and right direction,
After this state is maintained for a certain period of time, the manual control is released.

Further, when the manual switch 101 is not input and the automatic changeover switch 100 is located at the fixed mode terminal 100a and the fixed mode is input, the initially set reference slope value is input as shown in FIG. The machine sensor 73 value is input, and the planting portion 15 is fixedly supported at an inclination angle corresponding to the reference inclination value by performing left-up or right-up control so that the sensor 73 value matches the reference inclination value.

On the other hand, when the automatic changeover switch 100 is switched to a position other than the fixed mode, the planting lift lever 3
By raising the planting part 15 by the 3 operation, the speed change solenoid 96 is energized by switching the control speed to high speed as shown in FIG. The rolling cylinder 68 is connected to the pump 84, and the rolling cylinder 68 is operated by the input from the machine sensor 73 so that the planting part 15 is approximately horizontal with respect to the traveling vehicle 1. is supported horizontally with respect to the machine to prevent the planting part 15 from coming into contact with the rear fender part on the rear side of the vehicle body cover 12.

Furthermore, by operating the lift lever 33, the planting section 1
By lowering the lever 33, the control is suspended until a certain period of time has elapsed, and the lever 33 is kept on standby until the time required to switch from the lowered position to the planting position has elapsed, thereby preventing malfunctions at the initial stage of control operation. to prevent floating seedlings from occurring.

When a certain period of time has elapsed since the planting part 15 has been lowered, an input is received from the horizontal sensor 76 by operating the detection changeover switch 105, and as shown in FIG. This machine sensor 7
Based on 3 inputs, it is detected whether the horizontal inclination of the planting part 15 is within the control range, and if the planting part 15 is tilted more than the control range with respect to this machine, the abnormality warning lamp 99 is turned on. On the other hand, when the inclination of the planting section 15 is within the control range, the rolling cylinder 6 is activated based on the horizontal sensor 76 input.
8, the planting part 15 is supported substantially horizontally with respect to the planting field surface by left-up control and right-up control, and this state is maintained until a certain period of time has elapsed, and rolling control based on the horizontal sensor 76 is repeated. conduct.

Further, when the detection changeover switch 105 is operated to input from the float sensors 52a, 52b, it is checked whether the inputs of the left and right float sensors 52a, 52b are within the detection range, and if they are outside the detection range, the abnormality alarm lamp 99 is turned on to notify the operator of the abnormal vertical movement of the sensor floats 50, 50, and at the same time, the sensor float 50 is raised and fixed as shown in FIG. 17, and the horizontal sensor 76 performs rolling control. On the other hand, the sensors 52a, 52
When the b input is within the detection range, the automatic changeover switch 10
0 is the ridge mode, and if it is not the ridge mode, the main clutch switch 106 is turned on by the main clutch switching operation of the travel gear change lever 32 or the travel clutch pedal 35, and the horizontal control is stopped. At the same time, when the switch 106 is off and the main clutch is on, the signal is input from the engine sensor 73.

Then, based on the input of the main unit sensor 73, it is determined whether or not the left and right float sensor 52a, 52b inputs are large. The solenoid 96 is energized, the variable speed valve 95 is switched, and the hydraulic oil of the hydraulic pump 84 is applied to the rolling valve 90 via the short circuit 94, and the rolling cylinder 68 is operated at high speed, while planting on the planting field. When the slope of part 15 is small,
By switching the control speed to a low speed, the variable speed valve 95 is connected to the rolling valve 90 via the delay circuit 93, and the rolling cylinder 68 is operated at a low speed.

Also, based on the output difference between the left and right float sensors 52a and 52b, the horizontal inclination angle of the planting section 15 with respect to the planted field surface is calculated, and after determining whether the planting section 15 is tilted to the left or right, the rolling cylinder 68 is operated at the set speed. Left-up and right-up controls are performed to eliminate the difference in output between the sensors 52a and 52b, and the planting portion 15 is supported substantially horizontally with respect to the planting field.

On the other hand, when the automatic changeover switch 100 is in the ridge mode, the rise of the left and right streak markers 47, 47 is detected by the marker standing sensors 104a, 104b, and the ridge is detected by either the left or right ridge sensors 103a, 103b. The left and right streak markers 47, 47 are raised and the planting area 1
5 is close to the ridge, the sensor float 50 is raised and fixed as shown in FIG. 17, and the horizontal sensor 76 performs rolling control.
Each of the sensors 103a, 103b, 104a, 1
04b, it is determined whether or not ridge processing is to be performed, and rolling control is performed based on the output of the horizontal sensor 76 during ridge processing.

Further, when the automatic changeover switch 100 is not in the ridge mode, when the traveling speed change lever 32 is at the planting speed change position, and when the planting elevator lever 33 is at the lowering and planting position, the sensor float 50 is moved around the fulcrum shaft 51. is supported so that it can be raised and lowered freely, and is maintained so that rolling control can be performed based on the outputs of the float sensors 52a and 52b, while when the automatic changeover switch 100 is in the ridge mode and when the travel shift lever 32 is in a position other than the planting shift position. In addition, when the planting lift lever 33 is in a position other than the lowered or planted position, or when the outputs of the float sensors 52a and 52b are controlled to be off, the left and right sensor floats 50 and 50 are raised and fixed by the pulling operation of the pulling lever 107. be.

"Effects of the Invention" As is clear from the above embodiments, the present invention provides an apparatus equipped with float sensors 52a and 52b for detecting the difference in ground height between the left and right sides of the planting section 15 with respect to the planted field surface. ,52b
A lifting member such as a pulling lever 107 is provided to raise and support the sensor float 50 that operates the sensor float 5.
The sensor float 50 can be automatically stored in a fixed position except during rolling control, and the sensor float 50 can be prevented from being damaged, and the sensor float 50 can prevent the planted field surface from being roughened. Problems can be eliminated,
It has practical effects such as preventing deterioration of water flow on the rice field, making it easier to uniformly grow seedlings, and easily improving handling operability and safety compared to conventional methods.

[Brief explanation of the drawing]

Fig. 1 is an explanatory diagram of the raising and lowering operation of a sensor float showing one embodiment of the present invention, Fig. 2 is a side view of the whole, Fig. 3 is a plan view of the same, Fig. 4 is a side view of the planting part, Fig. 5
6 is a side view of the sensor float section, FIG. 7 is a plan view of the same, FIG. 8 is a side view of the rolling cylinder section, FIG. 9 is a front view of the same, and FIG. 10 is the same section. Figure 11 is a hydraulic circuit diagram, Figure 12 is a rolling cylinder control circuit diagram, Figures 13 to 1
Figure 7 is a flowchart. 15... Planting section, 50... Sensor float, 5
2a, 52b...Float sensor, 107...Lifting lever (lifting member).

Claims (1)

[Scope of utility model registration request] In a device equipped with a float sensor that detects the difference in ground height between the left and right sides of the planting area with respect to the planted field surface,
A rolling control device for a rice transplanter, characterized in that a lifting member is provided to lift and support a sensor float that activates the float sensor, and the lifting member lifts and fixes the sensor float in conjunction with the off operation of the float sensor. .