JP2019106968A - Agriculture implement and wear determination method for cultivation claw - Google Patents

Abstract

To provide a method capable of determining a degree of wear of a cultivation claw, without visual inspection by a farmer.SOLUTION: An agriculture implement comprises: a cultivation rotor including a plurality of cultivation claws; a shield cover arranged on an upper side of the cultivation rotor; a ground leveling body which is connected to the shield cover rotatably in a vertical direction; a transmission circuit which is electrically connected to at least one of the plurality of cultivation claws; a reception circuit; and an antenna electrically connected to the reception circuit. The transmission circuit can supply power to at least one of the plurality of cultivation claws, and the antenna receives a wave radiated from the cultivation claws.SELECTED DRAWING: Figure 3

Description

  BACKGROUND OF THE INVENTION Field of the Invention The present invention relates to a method of determining wear of a farming machine and a tiller.

  Plow nails equipped in rotary work machines for agricultural work gradually wear out due to contact with the soil during the plow work. As the wear progresses, the tillage performance declines, and eventually the discharge capacity and the reversal ability of the soil decrease, resulting in a state in which appropriate tillage work can not be performed. For this reason, the farmer regularly checks the degree of abrasion of the cultivating nails, and promptly responds when the abrasion progresses to a certain extent.

  For example, Patent Document 1 describes a technique for providing ribs visible on both sides at a position along a line after abrasion, which serves as a guide for replacing a tillage nail, in order to determine the replacement time of such a tillage nail. There is.

Utility model registration No. 3198032 gazette

  However, in the case of the technique described in Patent Document 1, after all, the degree of abrasion of the cultivating nails has to be visually confirmed by the farm worker, and if the confirmation is forgotten or troublesome. There is a problem that there is a possibility that the time for replacing the tillage nails may be missed.

  Moreover, when carrying out a tilling operation with a rotary work machine, soil may adhere to the tilling nail. In such a case, the technology described in Patent Document 1 has a problem that the rib can not be visually recognized due to the influence of soil, and the degree of wear may not be determined.

  The present invention has been made in view of the above problems, and an object of the present invention is to provide a method of determining the degree of abrasion of a cultivating nail without visual inspection by a farm worker.

  A farm work machine according to an embodiment of the present invention includes a tillage rotor including a plurality of tillage nails, a shield cover disposed on the tillage rotor, and a ground surface rotatably connected to the shield cover in a vertical direction. A plurality of transmitting circuits electrically connected to at least one of the plurality of tillers, a receiving circuit, and an antenna electrically connected to the receiving circuits; Power can be supplied to at least one of the tillage nails, and the antenna receives radio waves emitted from the tillage nails.

  A farm work machine according to an embodiment of the present invention includes a tillage rotor including a plurality of tillage nails, a shield cover disposed on the tillage rotor, and a ground surface rotatably connected to the shield cover in a vertical direction. And a receiving circuit electrically connected to at least one of the plurality of tillers, a transmitting circuit, and an antenna electrically connected to the transmitting circuit, the transmitting circuit including the antenna Power can be supplied to the at least one of the plurality of plows to receive radio waves emitted from the antenna.

  The antenna may be disposed between the tillage rotor and the shield cover, or may be disposed to face the tillage rotor via an opening provided in the shield cover.

  The above-described agricultural work machine may further include a control unit, and the transmission circuit or the reception circuit may be included in the control unit.

  The control unit includes a central processing unit and a storage unit, and the storage unit causes the central processing unit to wear the cultivating claw based on a signal input to the control unit via the receiving circuit. A program may be stored to execute the process of determining the degree of.

  The control unit includes a central processing unit and a storage unit, and the storage unit causes the central processing unit to execute processing of analyzing the strength of the signal input to the control unit through the reception circuit. You may store a program for

  The storage device stores the maximum value of the strength of the first signal input to the control unit via the receiving circuit, and the program is stored in the storage device in the central processing unit. A process may be performed to obtain a difference by comparing the maximum value of the intensity of one signal with the maximum value of the intensity of the second signal input to the control unit via the receiving circuit.

  In the method for determining abrasion of a tillage nail in an embodiment of the present invention, a radio wave is emitted from the tillage nail by supplying power from a transmission circuit, and based on the intensity of the radio wave received by an antenna connected to a reception circuit. , Determine the degree of wear of the cultivating nails.

  In the method for determining abrasion of a tillage nail in an embodiment of the present invention, the radio wave is emitted from an antenna of the agricultural work machine by supplying power from a transmission circuit, and the radio wave received by the tillage nail connected to a reception circuit The degree of wear of the cultivating nails is determined based on the strength of.

  The above-described method for determining the wear of the tillage nail is to determine the degree of wear of the tillage nail by converting the received radio wave into a signal by the receiving circuit and analyzing the strength of the signal. Good.

  The above-described method for determining the wear of the cultivating nail reads the maximum value of the strength of the first signal from the storage device, converts the received radio wave into a second signal by the receiving circuit, and reads the first signal read from the storage device. The degree of wear of the cultivating nail may be determined by comparing the maximum value of the strength of the second and the maximum value of the strength of the second signal to obtain a difference.

  A program according to an embodiment of the present invention causes a computer to execute the process of determining the degree of abrasion of the above-described tiller.

  ADVANTAGE OF THE INVENTION According to this invention, it becomes possible to determine the degree of abrasion of a plow nail irrespective of visual observation of a farm worker.

It is a figure showing composition of a farm work machine of a 1st embodiment from the back side. It is sectional drawing which shows the structure of the farming machine of 1st Embodiment from the left side. It is a figure for demonstrating the wear determination method of the tillage nail in the agricultural working machine of 1st Embodiment. It is a figure for demonstrating the wear determination method of the tillage nail in the agricultural working machine of 1st Embodiment. It is a wave form diagram for explaining change of the receiving intensity of the electric wave received by the antenna of a 1st embodiment. It is a figure for demonstrating the wear determination method of the tillage nail in the agricultural working machine of 2nd Embodiment. It is sectional drawing which shows the structure of the farm work machine of 3rd Embodiment from the left side. It is the figure which looked at the cultivating nail | claw of 4th Embodiment from the left side of a farm work machine. It is a top view which shows the structure of the flange provided in the tillage rotor of 4th Embodiment. It is sectional drawing which shows the state which mounted | worn the tillage nail | claw with the flange provided in the tillage rotor of 4th Embodiment. It is sectional drawing which shows the state which mounted | wore the holder provided in the tillage rotor of 4th Embodiment with the tillage nail.

  Hereinafter, embodiments of a determination method of a cultivating nail and a cultivated nail according to the present invention will be described with reference to the drawings. However, the determination method of the cultivation nails and the cultivation nails of the present invention can be implemented in many different modes, and is not interpreted as being limited to the description of the examples shown below. Note that in the drawings referred to in this embodiment, the same portions or portions having similar functions are denoted by the same reference numerals, and the description thereof will not be repeated.

  In the specification and claims of the present application, "upper" indicates the direction of moving away vertically from the horizontal surface (ground), and "lower" indicates the direction of approaching vertical to the horizontal surface. Moreover, "front" shows the direction in which a traveling body is located on the basis of a working machine, and "rear" shows the direction 180 degrees opposite to front. Moreover, "left" shows the left when it went to the direction where a traveling body is located on the basis of a work machine, and "right" shows a direction 180 degrees opposite to left.

First Embodiment
[Composition of farm work machine]
FIG. 1 is a view showing the configuration of the agricultural working machine 100 of the first embodiment from the back side. FIG. 2: is sectional drawing which shows the structure of the agricultural-services machine 100 of 1st Embodiment from the left side. Specifically, FIG. 2 shows a state in which the apron (also referred to as a ground body) 130 of the agricultural working machine 100 is lowered to the normal position from the left side.

  The agricultural working machine 100 of this embodiment roughly includes a frame 110, a shield cover 120, an apron 130, a side plate 140, a tilling rotor 150, a control unit 170, an antenna 180, and the like.

  The frame 110 is connected by a traveling airframe (not shown) such as a tractor, a top mast 135 and a lower link connecting portion 136. The frame 110 is, for example, cylindrical, and has a power transmission shaft (not shown) at the inside communicating with the chain case 105. The power transmission shaft serves to switch the direction of rotational power transmitted from the PTO shaft of a traveling vehicle such as a tractor via a PIC (Power Input Connection) shaft 137 in the lateral direction to the traveling direction. The power transmission shaft in the frame 110 is connected to a chain case 105 disposed on the side of the agricultural machine 100, and power is transmitted to the rotation shaft 152 of the tillage rotor 150 by a chain transmission mechanism in the chain case 105. .

  The cultivating rotor 150 is configured of a rotating shaft 152 extending in the width direction of the agricultural working machine 100 and a plurality of cultivating claws 154 attached to the rotating shaft 152 via a flange 153. As shown in FIG. 1, when viewed from the back side of the agricultural working machine 100, the plurality of tillering claws 154 are curved in the left direction and are in the right direction with the tilling claws 154L (hereinafter referred to as “L claws 154L”). It is composed of a curved tillage 154R (hereinafter referred to as "R claw 154R"), and is attached at a predetermined interval in the axial direction of the rotation shaft 152. Furthermore, in the present embodiment, a plurality of tilling claws 154 are attached to one flange 153. Although two L claws 154L and two R claws 154R are attached to one flange 153 in FIG. 2, the type and the number of the attached plows are limited to this. Absent.

  As shown in FIG. 1, when the agricultural working machine 100 is viewed from the back side, the R claws 154R and L claws 154L arranged to face each other overlap each other at their toes. Therefore, the width of the region where the individual L claws 154L and R claws 154R dig the soil partially overlaps between the adjacent L claws 154L and R claws 154R. In addition, in the agricultural-services machine 100 of this embodiment, the tillage rotor 150 rotates in the direction shown by arrow R in FIG.

  The shield cover 120 is disposed to cover the top of the tilling rotor 150. A side plate 140 is provided on the side surface of the shield cover 120. The side plate 140 may be referred to as a chain case plate, a side frame, a support frame or the like. In FIG. 2, the side plate 140 is not shown.

  The apron 130 is disposed at the rear of the tilling rotor 150, and can be vertically rotated with respect to the shield cover 120 about the connection portion 160 as an axis. Since the center of gravity of the apron 130 is behind the connection portion 160, the apron 130 tends to descend by its own weight. A stainless steel ground plate 132 is attached to the tip of the apron 130. The ground leveling plate 132 is configured to draw a loop from the inside to the outside of the apron 130. The ground plate 132 flattens the field dug up by the tilling rotor 150.

  Further, movable extendable leveling plates 134 are provided at both ends of the leveling plate 132. By opening the extended ground leveling plate 134, it becomes possible to level the wide width range with the leveling plate 132.

  Control unit 170 includes a central processing unit (CPU), a storage unit (memory) and a communication unit (not shown), processes signals received from the outside (for example, remote control signals), and conversely, internally generated signals It has a function of transmitting (for example, a control signal of the drive unit) to the outside. The storage device stores various data and various programs. The central processing unit may control the operation of a driving unit such as an actuator provided in the agricultural working machine 100 by reading and executing a program from the storage unit, or may execute a determination processing of a cultivating nail described later. it can.

  The communication device is a device for performing wired communication or wireless communication. For example, in the case of wireless communication, for example, a module capable of near-field wireless communication or a module capable of wireless communication conforming to a communication standard such as WiFi may be mounted. That is, the communication device included in the control unit 170 has a function of controlling communication with an information terminal such as a server or user terminal connected on a network or an information terminal such as a tablet PC mounted on a traveling machine. It may be

  Further, in the present embodiment, the control unit 170 is electrically connected to the antenna 180 disposed between the tilling rotor 150 and the shield cover 120. In the present embodiment, the antenna 180 is used as a receiving antenna. Therefore, the control unit 170 incorporates a receiving circuit (not shown) including a filter, an amplifier, and the like.

  In the present embodiment, as shown in FIG. 1, a plurality of antennas 180 are arranged side by side in the width direction of the agricultural working machine 100. Specifically, the antenna 180 is disposed at a position approximately equidistant from both of the R claw 154R and the L claw 154L overlapping each other (ie, a position at a substantially middle point between two adjacent flanges 153). . However, the present invention is not limited to this, and the position where the antenna 180 is disposed may be appropriately determined in consideration of the reception sensitivity and the like. Even if a rubber cover or the like is disposed between the tilling rotor 150 and the shield cover 120, the radio wave is hardly affected by the rubber cover, so the influence on the reception sensitivity is considered to be small. Moreover, although illustration is abbreviate | omitted in FIG.1 and FIG.2, the antenna 180 may be enclosed by a protective case etc. FIG.

  Although any known antenna may be used as the antenna 180, when it is disposed between the tilling rotor 150 and the shield cover 120 as in the present embodiment, a planar antenna such as a directional microstrip antenna is used. It is desirable to use

  The control unit 170 is also electrically connected to the tilling claw 154. Specifically, the control unit 170 and the rotary shaft 152 of the tillage rotor 150 are electrically connected using a cable (not shown) such as an insulated wire, and a configuration capable of supplying power to the rotary shaft 152 It has become. The rotary shaft 152 is electrically connected to the tillage claw 154 via the flange 153, so the control unit 170 can supply power to the tillage claw 154 via the rotary shaft 152 and the flange 153. . Thus, in the present embodiment, the tilling claw 154 can be used as a transmission antenna.

  The control unit 170 incorporates a transmission circuit (not shown) including an oscillation circuit, a filter, an amplifier and the like in order to supply power to the tilling claw 154. The transmitter circuit supplies power, including a sinusoidal signal, to the cultivator claw 154.

[Composition of the method of determining the wear of the tillage nail]
As described above, in the agricultural work machine 100 according to this embodiment, the control unit 170 is electrically connected to the tilling claw 154 and the antenna 180. Specifically, the transmission circuit included in the control unit 170 is electrically connected to the tilling claw 154, and the reception circuit included in the control unit 170 is electrically connected to the antenna 180. Therefore, radio waves can be transmitted and received between the tilling claw 154 and the antenna 180.

  FIG.3 and FIG.4 is a figure for demonstrating the wear determination method of the cultivation nail | claw 154 in the agricultural-service implement 100 of 1st Embodiment. FIG. 5 is a waveform diagram for explaining changes in the reception strength of radio waves received by the antenna 180. As shown in FIG. In addition, although FIG.3 and FIG.4 has shown the R nail | claw 154R as an example of the cultivating nail | claw 154, even if it is the L nail | claw 154L, a principle is the same.

  In FIG. 3, the tilling claw 154 is electrically connected to the transmission circuit 190. The transmission circuit 190 is a transmission circuit for supplying power (energy) to the tilling claw 154, and is incorporated in the control unit 170 in the present embodiment. However, the agricultural working machine 100 may have the transmission circuit 190 separately from the control unit 170. In the present embodiment, the transmission circuit 190 and the cultivating claw 154 are electrically connected via the rotating shaft 152 and the flange 153 shown in FIG. 2 as described above.

  The transmission circuit 190 outputs power including, for example, a sine wave signal. There is no particular limitation on the frequency of the sine wave signal, but it is not necessary to limit to the use of the high frequency band because it does not carry information in particular. For example, a low frequency band around 0.5 kHz used in Morse communication etc. may be used. In any case, it is preferable to use a frequency band with minimal interference. Further, the power output from the transmission circuit 190 is not limited to a sine wave, but may include another waveform or a rectangular wave that changes continuously, such as a cosine wave, a triangular wave, or a sawtooth wave.

  The electric power output from the transmission circuit 190 is supplied to the rotating shaft 152 via a known slip ring or the like (not shown) and is supplied to the cultivating claw 154 via the flange 153. The power supplied to the cultivating claw 154 is radiated from the cultivating claw 154 as a radio wave. That is, in the present embodiment, the tilling claw 154 functions as a transmitting antenna that radiates the radio wave 185.

  The radio wave 185 emitted from the cultivating claw 154 is received by the antenna 180 which functions as a receiving antenna. The radio wave received by the antenna 180 is converted into power including a sine wave signal, and is input to the reception circuit 182 via a shielded wire (not shown) or the like. As described above, in the present embodiment, the receiving circuit 182 is incorporated in the control unit 170. However, the agricultural working machine 100 may have the receiving circuit 182 separately from the control unit 170. The receiving circuit 182 amplifies or filters the signal received through the antenna 180 to extract the sine wave signal sent from the transmitting circuit 190.

  At this time, the reception intensity of the radio wave received by the antenna 180 (that is, the intensity of the sine wave signal extracted by the reception circuit 182) changes in accordance with the distance between the tilling claw 154 and the antenna 180. Therefore, when the distance between the cultivating nail 154 and the antenna 180 is increased by the abrasion of the cultivating nail 154, the reception intensity of the radio wave 185 is reduced by that much. In the present embodiment, the degree of wear of the cultivating claw 154 can be determined by detecting the difference in the reception intensity.

  In the present embodiment, as shown in FIG. 3, the receiving strength when the cultivating claw 154 comes closest to the antenna 180, that is, when the distance between the rotating cultivating claw 154 and the antenna 180 becomes the minimum distance L Use to detect differences. When the distance between the cultivating claw 154 and the antenna 180 becomes the minimum distance L, the reception intensity of the radio wave 185 takes a maximum value. That is, by detecting the change in the maximum value of the reception intensity of the radio wave 185, it is possible to detect the change in the minimum distance L (ΔL shown in FIG. 4), and the degree of wear of the tillage claw 154 can be determined. It is possible.

  In the case of the present embodiment, strictly speaking, the radio wave 185 is radiated from the whole of the rotating shaft 152, the flange 153 and the tilling claw 154. Therefore, it can be said that the radio wave 185 received by the antenna 180 is a composite of the radio wave radiated from the rotating shaft 152, the flange 153 and the adjacent tilling claw 154. However, as described above, in the present embodiment, using the maximum value of the reception intensity of the radio wave 185, the rotational shaft 152 is used to detect the difference between the reception intensity before the cultivation nail 154 wears and the reception intensity after wearing. The influence of radio waves received from etc. is not a problem in particular.

  Extraction of the maximum value of the reception intensity by the antenna 180 can be realized by appropriately setting the size and position of the antenna 180. In particular, as shown in FIG. 1, it is preferable to arrange the antenna 180 at a position substantially at the midpoint between the two adjacent flanges 153. As a result, since the vicinity of the tip of the curved cultivating nail 154 passes near the antenna 180, the minimum distance L can be shortened, and the maximum value of the reception intensity by the antenna 180 can be easily extracted.

Here, in FIG. 5, the waveform 51 is in a new state before the cultivating claw 154 is worn, that is, when the minimum distance L between the cultivating claw 154 and the antenna 180 is “L ₀ ”. It is an intensity waveform of the received sine wave signal. In this case, it is assumed that the maximum value of the intensity I of the sine wave signal received by the antenna 180 is “I ₀ ” (hereinafter referred to as “reference value I ₀ ”).

On the other hand, in FIG. 5, as shown in FIG. 4, the waveform 52 shows that the minimum distance L between the cultivating claw 154 and the antenna 180 is “L _1, ” as shown in FIG. Is an intensity waveform of a sine wave signal received in the case of In this case, it is assumed that the maximum value of the intensity I of the sine wave signal received by the antenna 180 is “I ₁ ” (hereinafter referred to as “measurement value I ₁ ”).

  However, the waveform shown in FIG. 5 shows an ideal curve on the assumption that one antenna 180 is provided for one tilling claw 154.

As shown in FIG. 5, when the cultivating claw 154 is worn, the minimum distance L with the antenna 180 changes from “L ₀ ” to “L ₁ ”, and the maximum value of the reception strength of the antenna 180 is The reference value I ₀ changes to the measured value I ₁ . Therefore, by detecting the change in the maximum value of the reception intensity of the antenna 180, it is possible to detect the change in the minimum distance L between the tillage nail 154 and the antenna 180. That is, in the present embodiment, by analyzing the reception intensity of the antenna 180 and detecting a change in the maximum value of the reception intensity of the antenna 180, it is possible to determine the degree of wear of the tillage claw 154.

  The detection process of the change in the maximum value of the reception strength described above can be performed using hardware resources such as a central processing unit and a storage device included in the control unit 170. The storage device of the control unit 170 of the present embodiment stores a program that causes the central processing unit to execute processing for determining the degree of wear of the tillage nail described below. Then, the central processing unit executes the program to perform the detection process of the change in the maximum value of the reception intensity described above. However, the program described above can also be downloaded and executed from a server or the like via a network.

First, the central processing unit analyzes the sine wave signal input from the receiving circuit 182 to obtain the maximum value I ₀ (that is, the reference value I ₀ ) of the intensity of the sine wave signal shown by the waveform 51 and performs control. It is stored in the storage device included in the unit 170.

  Next, when the central processing unit receives an instruction to execute the determination of the abrasion of the tillage nail, the central processing unit reads out and executes the program for the judgment of the abrasion of the tillage nail from the storage device. However, the central processing and the like may execute the above program in the background in conjunction with the operation of the tillage rotor 150 without receiving any instruction.

When the central processing unit or the like executes the above program, the sine wave signal input from the receiving circuit 182 is analyzed during or before the tilling operation, and the maximum value I ₁ of the intensity of the sine wave signal shown by the waveform 52 (Ie, the measurement value I ₁ ) is obtained. Then, the aforementioned reference value I ₀ is read from the storage device and compared with the acquired measured value I ₁ . Specifically, the difference “I ₀ −I ₁ ” between the reference value I ₀ and the measured value I ₁ is calculated, and the degree of wear of the cultivating nail 154 is determined based on the calculation result of the difference. This difference is compared with a threshold value stored in advance in the storage device, and if the threshold value is exceeded, it is determined that the wear has progressed to a predetermined level.

  For example, if three wear detection levels from the first threshold to the third threshold are stored as the threshold, it is possible to detect three levels of wear. In this case, when the control unit 170 determines that the wear detection level 1 has been reached, a notification indicating the possibility that the tillage performance of the tillage nail is degraded is given to the user terminal or the information terminal, If it is determined that the detection level 2 has been reached, notification is given that the replacement time of the tillage claw 154 is approaching, and if it is determined that the wear detection level 3 has been reached, replacement of the tillage claw 154 is necessary. It is possible to notify that effect.

  In this case, the more the threshold value to be set, the finer the degree of wear of the cultivating claw 154 can be determined. And by grasping | ascertaining the degree of abrasion finely, the history of abrasion can be accumulate | stored and it can utilize for estimation of the lifetime of the tillage nail 154, or it can utilize for estimation of the use condition of a farm work machine by a user. Also, such information can be transmitted from the control unit 170 to a server or the like and accumulated as a database.

  The “wear detection level” mentioned here is a level at which it is desired to detect the degree of wear, and a desired level can be set. For example, it may be a level at which a decrease in tillage performance is expected, and there is a need to encourage replacement, or it may be a level predicted in consideration of the use limit of a tillage nail (the limit at which adequate tillage performance can be exhibited). Can.

Also, for example, the difference between the reference value (initial value) and the measurement value in the case where the minimum distance L is changed at predetermined intervals is experimentally determined in advance, and the difference and the minimum distance L are associated and stored. By storing it, it is also possible to store a reference table in which the difference and the amount of wear of the cultivating claw 154 are associated with each other in the storage device. Thus, the difference between the reference value I ₀ and the measured value I ₁ is obtained by the above-described method, and the current amount of wear of the cultivating nail 154 can be determined by referring to the reference table stored in the storage device. .

  The degree of abrasion of the cultivating nails is determined during or after the tilling operation by executing the method for determining abrasion of the tillage nail of the present embodiment described above and radiating radio waves from the tillage nails and analyzing the reception intensity thereof. It can be determined. Thereby, it becomes possible to determine the degree of abrasion of the cultivating nail regardless of visual observation by the farm worker.

  Further, in the present embodiment, when the control unit 170 determines that the degree of wear of the cultivating nail has reached a predetermined level, the user terminal such as a smartphone or the information terminal mounted on a traveling machine such as a tractor is used. Notification of when it is time to replace the tillage nail 154, a notice that suggests that the tillage performance of the tillage nail 154 may be degraded, a notice that suggests that the fuel efficiency of the traveling vehicle may be degraded, etc. Various notices may be made regarding events that may occur due to wear.

  In addition to such notification, it is the cultivated nail 154 that has been worn to a certain level, such as adjustment of the cultivation depth and adjustment of the rotational speed of the cultivation rotor 150 in consideration of the decrease in the cultivation performance of the cultivation nail 154 It is also possible to control so that various adjustment of agricultural machinery 100 can be performed so that appropriate agricultural work can be performed to a field.

  Furthermore, the information that it is the replacement time of the tillage nail 154 can be transmitted from the control unit 170 to the server of the business operator and the like and accumulated as a database. If such information is used, the operator can handle a wide variety of tillage nails, such as maintenance management of farming machines (especially for tillage nails), delivery services for tillage nails to farmers, and rental services for tillage nails to farmers. It can be used for service.

Second Embodiment
In the first embodiment, an example in which the cultivating claw 154 is used as a transmitting antenna and the antenna 180 is used as a receiving antenna is shown, but conversely, an example in which the cultivating claw 154 is used as a receiving antenna and the antenna 180 is used as a transmitting antenna Will be described with reference to FIG. The same reference numerals as in the first embodiment denote the same parts as in the first embodiment, and the detailed description will be omitted.

  FIG. 6 is a view for explaining a method of determining wear of the tillage claw 154 in the agricultural working machine of the second embodiment. In the present embodiment, as shown in FIG. 6, the cultivating claw 154 and the receiving circuit 182 are electrically connected, and the antenna 180 and the transmitting circuit 190 are electrically connected. Also in this case, the receiving circuit 182 may be directly and electrically connected to the rotating shaft 152 (see FIG. 2), and the power received by the cultivating claw 154 is transmitted through the flange 153 or the rotating shaft 152. The signal is transmitted to the receiving circuit 182.

  Also in the present embodiment, the transmission circuit 190 and the reception circuit 182 may be incorporated in the control unit 170 (see FIG. 2). Of course, either or both of the transmission circuit 190 and the reception circuit 182 may be provided separately from the control unit 170.

  Also in the present embodiment, as the wearing of the tillage claw 154 progresses, the reception intensity of the radio wave by the tillage claw 154 decreases. Therefore, by executing the method for determining the wear of the tillage nail described in the first embodiment and radiating radio waves from the antenna 180 and analyzing the reception intensity thereof, the wear of the tillage nail during or after the tillage work The degree can be determined. Thereby, it becomes possible to determine the degree of abrasion of the cultivating nail regardless of visual observation by the farm worker.

Third Embodiment
Although the example which arrange | positions the antenna 180 between the tillage rotor 150 and the shield cover 120 was shown in 1st Embodiment, in this embodiment, it illustrates about the example which arrange | positions the antenna 180 in the position different from 1st Embodiment. This will be described using 7. The same reference numerals as in the first embodiment denote the same parts as in the first embodiment, and the detailed description will be omitted.

  FIG. 7 is a cross-sectional view showing the configuration of the agricultural working machine 100 a of the third embodiment from the left side. As shown in FIG. 7, the shield cover 120 is provided with an opening 121. An antenna 180 a is disposed on the shield cover 120 so as to cover the opening 121. In the present embodiment, the position where the opening 121 and the antenna 180a are disposed is the same as the position of the antenna 180 shown in FIG.

  In the present embodiment, since the antenna 180a is disposed on the shield cover 120, the antenna 180a can be disposed even when there is not a sufficient space between the tillage rotor 150 and the shield cover 120. Moreover, if it exists on the shield cover 120, there also exists an advantage that the maintenance of the antenna 180a is easy.

Fourth Embodiment
In the first embodiment, an example is shown in which power is supplied from the transmission circuit 190 to the rotating shaft 152 and power is supplied to all the cultivating claws 154 via the rotating shaft 152 and the flange 153, but in the present embodiment An example in which power is supplied to an arbitrary cultivating nail 154 will be described with reference to FIGS. The same reference numerals as in the first embodiment denote the same parts as in the first embodiment, and the detailed description will be omitted.

  FIG. 8 is a view of the tilling claw 154 a of the fourth embodiment as viewed from the left side of the agricultural working machine. In addition, the shape of the tilling nail | claw 154a shown to this embodiment is only an example, and is not limited to this shape. Here, the description is given by exemplifying the R nail and the description of the L nail is omitted, but the following description is common to the R nail and the L nail except that the bending direction is different. .

  In FIG. 8, the cultivating claw 154 a is, in order from the right in the drawing, the mounting base 12, the longitudinal blade portion 14 and the horizontal blade portion 16 continuously extending from the mounting base 12, the blade edge 20, the ridge edge 22, and It has a head edge 24 that smoothly connects the blade edge 20 and the peak edge 22 in a curvilinear manner. In the present embodiment, the vertical blade portion 14 and the horizontal blade portion 16 may be collectively referred to as a blade portion. Further, in FIG. 8, it has a shape gently curved from the longitudinal blade portion 14 to the lateral blade portion 16 toward the back side of the drawing (the direction from the observer to the paper surface). In the present embodiment, the blade surface (side surface) of the cultivating claw 154a shown in FIG. 8 is referred to as an outer curved surface.

  The mounting base 12 is also provided with two mounting holes 18a and 18b in the longitudinal direction. The tilling claw 154 a is mounted on a flange 153 provided on the rotation shaft 152 of the tilling rotor 150 by inserting fixing members such as bolts into these mounting holes 18 a and 18 b. Such a mounting method is generally referred to as a flange method, but is not limited to this, and it is also possible to adopt a known holder method. In the present specification, the flange and the holder may be referred to as "mounting portion".

  Since the cultivating claw 154a shown in FIG. 8 is curved in one side with a substantially constant curvature radius toward the toe, the curved inner surface (inner curved surface) forms a rake surface. The tilling nail 154a of the present embodiment is capable of cultivating and releasing soil by this rake face and performing soiling.

  Here, in the tilling claw 154 a of the present embodiment, as shown in FIG. 8, the terminal 30 is disposed with respect to the mounting base 12 of the outer curved surface. The terminal 30 may be formed of a conductor, and may be formed on the surface of the mounting base 12 or may be embedded in a groove formed on the surface of the mounting base 12. In addition, since the above-mentioned rake surface acts on soil and exhibits a tillage performance fundamentally, compared with an outer side curved surface, in the case of an inner side curved surface, surface coating is easy to peel off. Therefore, it is desirable to arrange the terminals 30 on the outer curved surface. However, not limited to this, the terminal 30 can also be disposed on the inner curved surface. The terminal 30 functions as an input terminal when power is supplied to the tilling claw 154a.

  In order to supply power to the terminal 30, a means for transferring power from the flange 153 to the terminal 30 is required. Therefore, in the present embodiment, the terminal is also provided to the flange 153a to which the tilling claw 154a is attached.

  FIG. 9 is a plan view showing the configuration of the flange 153 a provided on the tillage rotor 150 of the fourth embodiment. Moreover, FIG. 10 is sectional drawing which shows the state which mounted | worn the tillage nail | claw 154a with the flange 153a provided in the tillage rotor 150 of 4th Embodiment.

  In FIG. 9, the flange 153a is provided with an opening 31 through which the rotation shaft 152 is inserted, and an opening 32 through which a fixing member (for example, bolts 34a and 34b in FIG. 10) is inserted. When mounting the tilling claw 154a on the flange 153a, the opening 32a overlaps the mounting hole 18a shown in FIG. 8, and the opening 32b overlaps the mounting hole 18b shown in FIG. That is, the flanges 153a are formed by overlapping the opening portions 32a and 32b of the flange 153a and the attachment holes 18a and 18b of the tilling claw 154a and fixing them using the bolts 34a and 34b and the nuts 35a and 35b shown in FIG. The tilling claw 154a can be attached.

  At this time, a terminal 30a is provided on the flange 153a. However, in FIG. 9, since the terminal 30a is provided at the position on the back side (back side) of the surface of the flange 153a, the outline is shown by a dotted line.

  When the cultivating claw 154a shown in FIG. 8 is attached to the flange 153a shown in FIG. 9, the terminal 30 of the cultivating claw 154a and the terminal 30a of the flange 153a are electrically connected as shown in FIG. In the present embodiment, flat electrodes are illustrated as the respective terminals, but even in this case, the electrical connection can be sufficiently secured if they are fixed by the bolt 34 a and the nut 35 a or the like. Of course, a projection may be provided on the electrode of each terminal to make it easier to secure conduction.

  In addition, although the example which used the contact-type conduction system was shown in this embodiment, you may use not only this but a non-contact-type conduction system. For example, the terminals 30 and 30a may be coil antennas, and power may be supplied using an induced current generated by electromagnetic induction between the two.

  In addition, a plurality of wires (for example, shielded wires) connected to the terminals 30 of the respective tillage claws 154a are drawn into the inside of the rotary shaft 152, and finally, the control unit 170 (more specific) of the agricultural machine Are electrically connected to the transmission circuit 190). Thus, in the present embodiment, electrical continuity can be established between the control unit 170 and the optional tillage nail 154a, and power can be supplied to the optional tillage nail 154a.

  In addition, in this embodiment, although four tilling claws can be mounted | worn with the flange 153a, the tilling claw 154a which has the terminal 30 can be made into arbitrary numbers among four. This is because it is considered that the degree of wear of the plurality of cultivating nails disposed on the individual flanges 153a is approximately the same as long as it acts on the same soil. That is, it is considered that the degree of wear of the other tillers can be estimated by confirming the degree of wear of one tiller with respect to one mounting portion. According to this idea, for example, power may be supplied to any number of tillage nails among the tillage nails included in the tillage rotor 150.

  Moreover, FIG. 11 has shown the example at the time of mounting | wearing with the holder system the tillage nail | claw 154b of this embodiment. Specifically, FIG. 11 is a cross-sectional view showing a state in which the cultivating claw 154b is attached to the holder 156 provided on the cultivating rotor 150. As shown in FIG. The holder 156 has a cylindrical portion so that the mounting base 12 of the tilling claw 154b can be inserted. In the present embodiment, the terminal 30 b is disposed on the inner wall 156 a of the cylindrical portion of the holder 156. The terminal 30 b is provided at a position in contact with the terminal 30 of the tilling claw 154 b when the tilling claw 154 b is attached to the holder 156.

  That is, when the mounting base 12 of the cultivating claw 154b is inserted into the cylindrical portion of the holder 156 and fixed by the bolt 34c and the nut 35c, as shown in FIG. 11, the terminals 30 of the cultivating claw 154b and the holder 156 Terminal 30b is electrically connected. Also in the present embodiment, the terminal 30 b of the holder 156 is electrically connected to the control unit 170. Therefore, by the control of the control unit 170, power can be supplied to the cultivating claw 154b via the terminal 30b and the terminal 30 of the cultivating claw 154b.

  In the present embodiment, the projection 30b-1 is formed on the surface of the terminal 30b. By providing such a projection 30b-1, electrical connection with the terminal 30 of the cultivating claw 154b can be made more stably. Of course, in order to make electrical connection more stably, electrodes of other structures may be used. Moreover, it is also possible to use not only a contact-type conduction system but a non-contact-type conduction system.

  In the present embodiment, an example is shown in which the cultivating claws 154a and 154b are used as transmitting antennas and the antenna 180 is used as a receiving antenna, but conversely, the cultivating claws 154a and 154b are used as receiving antennas, and the antenna 180 is used. It is also possible to use as a transmitting antenna.

Fifth Embodiment
In the fourth embodiment, an example is shown in which radio waves are radiated from the individual cultivating claws 154a (or 154b), but in this case, a configuration using the shield cover 120 itself as an antenna is not limited to the configuration in which a plurality of antennas 180 are arranged. It is also possible to take. In the present embodiment, the shield cover 120 is electrically connected to the receiving circuit 182.

  In the case of the present embodiment, for example, electric power is supplied in time division to the individual cultivating nails 154a (or a block including a plurality of cultivating nails 154a), and radiation is sequentially emitted from the individual cultivating nails 154a at time intervals. The radio wave may be received by the shield cover 120 and transmitted to the control unit 170 (specifically, the reception circuit 182). Thereby, even when the shield cover 120 is used as a receiving antenna, it is possible to identify the individual tilling claws 154a (or the above blocks).

  In addition, it is also possible to identify the individual cultivating nails 154a (or the above-mentioned block) by changing the frequency or the phase of the supplied power for each of the tilling nails 154a (or the above-mentioned blocks).

  Furthermore, the present embodiment is not limited to the configuration capable of supplying power to the individual cultivating claws 154 a as in the fourth embodiment, but is configured to supply power to the rotating shaft 152 as in the first embodiment. Even it is possible to apply. In this case, since radio waves are radiated simultaneously from the individual cultivating claws 154, the reception strength of the power received by the shield cover 120 is averaged. However, if the wear of the individual cultivating nails 154 is progressing, the maximum value of the averaged received intensity is also obtained from the initial value (the maximum value of the averaged received intensity when using a new cultivated nail). Because of the decrease, it is possible to determine the degree of abrasion of the tiller by detecting the change in the maximum value of the reception intensity.

  Although the present invention has been described above with reference to the drawings, the present invention is not limited to the above embodiment, and can be appropriately modified without departing from the scope of the present invention. For example, those to which a person skilled in the art appropriately adds, deletes, or changes the design of components based on the method of determining wear of the agricultural working machine and the tillage according to each embodiment are also included in the scope of the present invention. Included in the scope of the invention. Furthermore, the embodiments described above can be combined appropriately as long as there is no contradiction between them, and the technical matters common to the embodiments are included in each embodiment even if there is no explicit description.

  In addition, even if other effects or effects different from the effects brought about by the aspects of the respective embodiments described above are apparent from the description of the present specification, or those which can be easily predicted by those skilled in the art, It is naturally understood that the present invention provides.

12: mounting base, 14: longitudinal blade, 16: horizontal blade, 18a, 18b: mounting hole, 20: blade edge, 22: peak edge, 24: head edge, 30, 30a, 30b: terminal, DESCRIPTION OF SYMBOLS 30b-1 ... Protrusion part, 34a-34c ... Bolt, 35a-35c ... Nut, 51, 52 ... Corrugated, 100, 100a ... Agricultural work machine, 105 ... Chain case, 110 ... Frame, 120 ... Shield cover, 130 ... Apron, 132 ... ground leveling board, 134 ... extended ground leveling board, 135 ... top mast, 136 ... lower link connection part, 137 ... PIC shaft, 140 ... side plate, 150 ... tilling rotor, 152 ... rotation axis, 153, 153 a ... flange, 31 32, 32, 32a, 32b: Openings, 154, 154a, 154b: tilling nails, 154L: L nails, 154R: R nails, 156: holders, 156a Inner wall 160 ... connection section, 170 ... control unit, 180, 180 ... antenna, 182 ... reception circuit, 185 ... radio wave, 190 ... transmission circuit

Claims (13)

A plow rotor, which includes a plurality of plow nails,
A shield cover disposed on the tilling rotor,
A leveling body rotatably connected to the shield cover in the vertical direction,
A transmitter circuit electrically connected to at least one of the plurality of tillage nails;
A receiver circuit,
An antenna electrically connected to the receiving circuit;
Have
The transmission circuit can supply power to at least one of the plurality of tillers.
The antenna receives a radio wave emitted from the plow nail.
Farm work machine. A plow rotor, which includes a plurality of plow nails,
A shield cover disposed on the tilling rotor,
A leveling body rotatably connected to the shield cover in the vertical direction,
A receiving circuit electrically connected to at least one of the plurality of tillage nails;
A transmitter circuit,
An antenna electrically connected to the transmission circuit;
Have
The transmitter circuit can supply power to the antenna;
At least one of the plurality of plows receives a radio wave emitted from the antenna,
Farm work machine.   The agricultural work machine according to claim 1, wherein the antenna is disposed between the tilling rotor and the shield cover.   The agricultural work machine according to claim 1, wherein the antenna is disposed to face the tillage rotor via an opening provided in the shield cover. It further has a control unit,
The agricultural work machine according to any one of claims 1 to 4, wherein the transmission circuit or the reception circuit is included in the control unit. The control unit includes a central processing unit and a storage unit.
The storage device stores a program for causing the central processing unit to execute a process of determining the degree of wear of the cultivating nail based on a signal input to the control unit via the receiving circuit. The agricultural working machine according to claim 5. The control unit includes a central processing unit and a storage unit.
The agricultural work machine according to claim 5, wherein the storage device stores a program for causing the central processing unit to execute a process of analyzing the strength of a signal input to the control unit through the reception circuit. . The storage device stores the maximum value of the strength of the first signal input to the control unit via the receiving circuit,
The program may include, in the central processing unit, the maximum value of the intensity of the first signal stored in the storage device and the maximum value of the intensity of the second signal input to the control unit via the receiving circuit. The agricultural-work machine of Claim 7 which performs the process which calculates | requires the difference by comparing. It is a wear judging method of the cultivation nail included in the cultivation rotor which a farm work machine has,
A radio wave is emitted from the tillage nail by supplying power from a transmission circuit, and the degree of wear of the tillage nail is determined based on the intensity of the radio wave received by an antenna connected to the reception circuit. Wear judgment method. It is a wear judging method of the cultivation nail included in the cultivation rotor which a farm work machine has,
By supplying power from a transmission circuit, radio waves are emitted from the antenna of the agricultural work machine, and the degree of wear of the cultivation nails is determined based on the intensity of the radio waves received by the cultivation nails connected to the reception circuit. How to judge the wear of plow nails.   The method according to claim 9 or 10, wherein the degree of wear of the cultivating nail is determined by converting the received radio wave into a signal by the receiving circuit and analyzing the intensity of the signal. . Read the maximum value of the first signal strength from the storage device,
The received radio wave is converted to a second signal by the receiving circuit, and the maximum value of the intensity of the first signal read from the storage device is compared with the maximum value of the intensity of the second signal to obtain a difference. The method according to claim 11, wherein the degree of wear of the cultivating nail is determined. The program for making a computer perform the wear determination method of the cultivation nail as described in any one of Claims 9-12.

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