JP2023055019A - Farm work sensor unit, tilling tine, farm work machine, and farm work detection control system - Google Patents

Abstract

To detect an appropriate data amount of farm work detection information in accordance with timing of farm work.SOLUTION: There is provided a farm work sensor unit disposed at a farm work machine, the farm work sensor unit including a sensor for detecting farm work detection information generated at the time of farm work and a controller connected to the sensor. The controller comprises: an acquisition unit for acquiring the farm work detection information from the sensor; a first setting section for setting a control mode on the basis of the acquired farm work detection information; and a second setting section for setting a detection frequency of the sensor according to the control mode.SELECTED DRAWING: Figure 2

Description

The present invention relates to an agricultural work sensor unit, a tillage claw, an agricultural work machine, and an agricultural work detection control system.

2. Description of the Related Art In the technical field of agricultural work machines, work machines that are mounted on a traveling machine body such as a tractor and perform various operations in a field along the traveling direction of the traveling machine body are known. There are various types of such work machines according to the type of work to be performed. For example, a power tiller is known as a work machine for working a position behind the traveling position of the traveling machine body.

Further, in recent years, in order to obtain detailed information about agricultural machinery during agricultural work, development of agricultural machinery equipped with sensors has been promoted. For example, Patent Literature 1 discloses an agricultural work machine provided with a sensor.

Japanese Patent Application Laid-Open No. 2021-108618

When the sensor is provided in the agricultural implement, the detected information is stored in the storage device. However, depending on the sensor detection conditions, unnecessary information may also be detected and stored. As a result, the storage device is occupied with unnecessary information.

Moreover, when a sensor is provided in the agricultural implement, it is necessary to supply power to the sensor. At this time, when the sensor is installed in a place where electric power cannot be easily supplied, a method of driving the sensor with a battery (battery) is used. However, depending on the season or the time of day, there are many times when the agricultural implement is not used, resulting in wasteful power consumption.

In view of such problems, one of the objects of the present invention is to detect an appropriate amount of farm work detection information in accordance with the timing of farm work. Another object of the present invention is to detect appropriate information with low power consumption.

According to one embodiment of the present invention, an agricultural work sensor unit arranged in an agricultural work machine includes a sensor for detecting agricultural work detection information generated during agricultural work, a control device connected to the sensor, and the control device is connected to the sensor. The apparatus includes an acquisition unit that acquires the agricultural work detection information from the sensor, a first setting unit that sets a control mode based on the acquired agricultural work detection information, and a detection frequency of the sensor according to the control mode. A farm work sensor unit is provided, which has a second setting portion for setting the .

The agricultural work sensor unit may further include a power supply section having a battery for supplying power to the sensor and the control device.

In the agricultural work sensor unit, the control mode includes a first control mode and a second control mode, and the first setting unit performs the first control when the acquired agricultural work detection information satisfies a first setting condition. The mode is changed to the second control mode, and the second setting unit adjusts the sensor so that the detection frequency of the sensor in the second control mode is higher than the detection frequency of the sensor in the first control mode. may be set.

In the agricultural work sensor unit, the control device continues to acquire the agricultural work detection information that does not satisfy the first set condition after the farm work detection information does not satisfy the first set condition in the second control mode. A measurement unit that measures an elapsed time may be provided, and the first setting unit may change the second control mode to the first control mode when the measured elapsed time satisfies a second setting condition. .

According to one embodiment of the present invention, there is provided a tillage tine including the above farm work sensor unit.

According to one embodiment of the present invention, an agricultural work machine is provided that includes an agricultural work sensor unit and a tillage tine on which the agricultural work sensor unit is arranged.

In the above farm work machine, the farm work detection information may be an acceleration signal when the tillage tine receives an impact.

According to one embodiment of the present invention, the agricultural work sensor unit and a receiver unit are included, and the agricultural work sensor unit transmits the acquired agricultural work detection information to the receiver unit via a wireless communication device. , an agricultural detection and control system is provided.

By using an embodiment of the present invention, it is possible to detect an appropriate amount of agricultural work detection information in accordance with the timing of agricultural work. Also, by using an embodiment of the present invention, appropriate information can be detected with low power consumption.

1 is a hardware configuration diagram of an agricultural work detection control system according to an embodiment of the present invention; FIG. 1 is a rear view of an agricultural implement according to one embodiment of the present invention; FIG. 1 is a side view of an agricultural implement according to one embodiment of the present invention; FIG. 1 is a schematic diagram of a tillage tine on which a sensor unit according to one embodiment of the present invention is arranged; FIG. 1 is a block diagram of an agricultural work detection control system according to an embodiment of the present invention; FIG. FIG. 5 is a flowchart showing an example of farm work detection control processing in the farm work sensor unit according to one embodiment of the present invention. FIG. 4 is a flowchart showing an example of farm work detection control processing in the receiver unit according to one embodiment of the present invention;

BEST MODE FOR CARRYING OUT THE INVENTION Hereinafter, embodiments of the present invention will be described with reference to the drawings. However, the present invention can be implemented in many different aspects and should not be construed as being limited to the description of the embodiments exemplified below. Although the drawings may be represented schematically in order to make the description clearer, they are only examples and do not limit the interpretation of the present invention.

In addition, the letters "first" and "second" for each element are labels for convenience used to distinguish each element, and unless otherwise specified, have more meaning. do not have. In the drawings referred to in this embodiment, the same parts or parts having similar functions are denoted by the same reference numerals or similar reference numerals (numerals xxx followed by A, B, 1, 2, etc.). However, the repeated description may be omitted. Also, part of the configuration may be omitted from the drawings. In addition, no particular description will be given if it is something that can be recognized by a person who has ordinary knowledge in the field to which the present invention belongs.

<First embodiment>
A farm work sensor unit, a tillage tine, a farm work machine, and a farm work detection control system according to the present embodiment will be described in detail with reference to the drawings.

(1-1. Hardware configuration of agricultural work detection control system)
FIG. 1 shows a hardware configuration diagram of an agricultural work detection control system 1. As shown in FIG. In a part of the configuration of the farm work detection control system 1, farm work detection control processing for detecting farm work detection information of an appropriate amount of data in accordance with the timing of farm work and detecting suitable farm work detection information with low power consumption is performed. executed.

The farmwork detection control system 1 includes a farmwork sensor unit 10 and a receiver unit 20 . The farm work sensor unit 10 has a function of setting a control mode based on sensing data transmitted from the sensor and setting the detection frequency of the sensor according to the control mode. The receiver unit 20 has a function of receiving various sensing data from the farm work sensor unit 10 and generating operating time of each sensor and farm work data (field mapping data, etc.). Each configuration is shown below.

(1-1-1. Hardware configuration of agricultural work sensor unit)
The farm work sensor unit 10 has a microcomputer 11 (also referred to as a control device), a sensor 13 , a communication section 15 and a power supply section 17 . Microcomputer 11, sensor 13, communication unit 15, and power supply unit 17 are electrically connected via a wiring bus.

The microcomputer 11 includes a control section 11a and a memory 11b. The control unit 11a is one of computers, and in this example, a CPU (Central Processing Unit) is used. The memory 11b includes at least one of ROM (Read On Memory) and RAM (Random Access Memory). The control unit 11a executes various kinds of arithmetic processing based on the agricultural work detection control program stored in the memory 11b. Note that the control unit 11a is not limited to the CPU. In addition to the CPU, the control unit 11a may use an ASIC (Application Specific Integrated Circuit), an FPGA (Field Programmable Gate Array), or other arithmetic processing circuits.

The sensor 13 detects sensing data (also referred to as farm work detection information) generated during farm work. A triaxial acceleration sensor is used for the sensor 13 in this example. By using the triaxial acceleration sensor, it is possible to detect an acceleration signal when a tillage tine to which the sensor is attached receives an impact (during tillage work). The detection frequency of the sensor 13 is set according to the detection mode. Specifically, in the low power mode (also called intermittent mode), the detection frequency is 1 Hz. Also, in normal mode, the detection frequency is 1000 Hz.

The communication unit 15 transmits and receives information to and from the receiver unit 20 by wireless communication. In this example, the communication unit 15 uses a beacon transmitter/receiver. The beacon transmitter/receiver can transmit and receive information with low power consumption by using BLE (Bluetooth Low Energy) radio waves. The communication unit 15 can be said to be a wireless communication device.

The power supply unit 17 has a battery and supplies power to the microcomputer 11 , the sensor 13 and the communication unit 15 . In this example, the battery of the power supply unit 17 is a secondary battery such as a nickel-metal hydride battery, a nickel-cadmium battery, a lithium-ion battery, a lithium ferrite battery, or an all-solid-state battery, or a primary battery.

(1-1-2. Hardware configuration of receiver unit)
The receiver unit 20 has a microcomputer 21 , a storage section 23 , a user interface section 25 , a communication section 27 and a power supply section 29 . The microcomputer 21, storage unit 23, user interface unit 25, communication unit 27, and power supply unit 29 are connected via a wiring bus.

The microcomputer 21 includes a control section 21a and a memory 21b. The control unit 21a is one of computers, and a CPU is used in this example. The memory 21b includes at least one of ROM and RAM. The control unit 21a executes various kinds of arithmetic processing based on the agricultural work detection control program or related programs stored in the memory 21b.

The storage unit 23 uses a semiconductor memory such as an SSD (Solid State Drive), a magnetic recording medium (magnetic tape, magnetic disk, etc.), an optical recording medium, a magneto-optical recording medium, and other storage devices. The storage unit 23 functions as an agricultural work detection information database that stores information transmitted from the agricultural work sensor unit 10 .

The user interface unit 25 inputs and outputs information with the user. The user interface section includes a display section 25a and an operation section 25b. The display unit 25 a is a display device such as a liquid crystal display or an organic EL (Electro Luminescence) display, and its display contents are controlled by signals input from the microcomputer 21 . The operation unit 25b includes a controller, buttons, or switches. When the user performs an operation such as vertical or horizontal movement, pressing, or rotation using the operation unit 25b, information based on the operation is input to the control unit 21a. Note that the display unit 25a and the operation unit 25b of the user interface unit 25 may be arranged at the same place as long as the display device (touch panel) has a touch sensor.

The communication unit 27 transmits and receives information to and from the farm work sensor unit 10 by wireless communication. In this example, the communication unit 27 uses a beacon transmitter/receiver. In addition to the beacon transmitter/receiver, other receivers such as a GPS (Global Positioning System) receiver may be used as the communication unit 27 .

The power supply unit 29 supplies power to the microcomputer 21 , storage unit 23 , user interface unit 25 and communication unit 27 . A battery such as a lithium ion battery may be used for the power supply unit 29, or a power supply from a tractor or a generator may be used.

(1-1-3. Arrangement configuration of farm work sensor unit and configuration of farm work machine)
Here, the arrangement configuration of the farm work sensor unit 10 and the farm work machine on which the farm work sensor unit 10 is arranged will be described. FIG. 2 is a rear view of an agricultural work machine 100 (sometimes referred to as a rotary work machine or a cultivator) in which the farm work sensor unit 10 is arranged. FIG. 3 is a side view of the agricultural work machine 100. FIG. As shown in FIGS. 2 and 3, the agricultural implement 100 according to this embodiment includes a main body 101 (including a main frame 110 and a shield cover 120), a rotary working portion 102, an apron 130, and the like.

The main frame 110 of the main body 101 is attached (connected) to the rear portion of a traveling body 300 such as a tractor. The main frame 110 is cylindrical and has a power transmission shaft inside. A gearbox 125 is attached to the main frame 110 . The receiver unit 20 is arranged on the traveling body 300 .

Rotational power from a traveling body 300 such as a tractor that travels forward is transmitted to a PIC (Power Input Connection) shaft 106 of the agricultural implement 100, gears (not shown) in the gear box 125, and a shaft (not shown) in the left side of the main frame 110. be. Further, this rotational power turns to the left in the traveling direction of the agricultural implement 100 and is transmitted to the tillage shaft 104 of the rotary working unit 102 by the chain transmission mechanism in the chain case 105 . Then, the agricultural work machine 100 advances along with the forward traveling of the traveling machine body 300 while rotating the rotary working part 102 to cultivate the field.

The rotary working part 102 is composed of a tillage shaft 104 of the main body 101 and a plurality of tillage tines 103 provided on the tillage shaft 104 . A rotary working part 102 is supported by the main body 101 . As shown in FIG. 3, the plurality of tillage tines 103 includes a vertical blade portion 103a extending perpendicularly to the tillage shaft 104 from the mounting portion, and a horizontal blade portion 103b bent to the right or left with respect to the traveling direction. have. In the plurality of tillage tines 103 , there is an overlap between the adjacent tillage tines 103 in the area (width) in which each of the tillage tines 103 digs up the soil. The rotary working part 102 rotates counterclockwise when viewed from the side in FIG.

The shield cover 120 is arranged to cover the upper part of the rotary working part 102 . A side plate 121 is provided on the side surface of the shield cover 120 .

The apron 130 is supported so as to be rotatable downward and upward around a fulcrum 140 fixed to the rear end of the shield cover 120 . The apron 130 is arranged behind the rotary working part 102 . Since the center of gravity of the apron 130 is behind the pivot fulcrum 140, the apron 130 tends to descend due to its own weight.

An apron pressing mechanism 150 is provided between the pedestal 111 provided on the main frame 110 and the apron 130 . The apron pressurizing mechanism 150 functions to press the apron 130 and the leveling plate 131 against the field with a constant pressure when the apron 130 is in the lowered state. The magnitude of the force applied by the apron pressing mechanism 150 can be adjusted by the operator's operation. Also, the apron pressurizing mechanism 150 is locked according to each work state.

FIG. 4A is a front view of the tillage tine 103. FIG. FIG. 4B is a side view of the tillage tine 103. FIG. FIG. 4C is a plan view of the tillage tine 103. FIG. As shown in FIGS. 3 and 4 (A) to (C), in this embodiment, the agricultural work sensor unit 10 is arranged on the tillage tines 103 of the agricultural work machine 100 . More specifically, the farm work sensor unit 10 is arranged on the crest side of the vertical blade portion 103 a of each tillage tine 103 . The farm work sensor units 10 provided on the respective tillage tines 103 operate independently. The X-axis direction of the sensor 13 (three-axis acceleration sensor) corresponds to the direction from the tillage shaft 104 of the rotary work unit 102 toward the farm work sensor unit 10 . The Y-axis direction of the sensor 13 is perpendicular to the X-axis direction and corresponds to the tangential direction of the virtual circle formed by the tillage tines 103 . The Z-axis direction in the sensor 13 is perpendicular to the X-axis direction and the Y-axis direction and corresponds to the direction in which the tillage shaft 104 of the rotary working unit 102 extends.

(1-2. Functional configuration of agricultural work detection control system)
FIG. 5 is a functional block diagram configured by each component of the agricultural work detection control system 1. As shown in FIG.

The microcomputer 11 of the farm work sensor unit 10 has functional units that control a program (farm work detection program) that implements the farm work detection function. As shown in FIG. 5, the microcomputer 11 includes, as functional units, an acquisition unit 11a1, a determination unit 11a2, a first setting unit 11a3, a second setting unit 11a5, a measurement unit 11a7, and a transmission unit 11a9.

The acquisition unit 11 a 1 has a function of acquiring sensing information (acceleration signal, farm work detection information) transmitted from the sensor 13 .

The first setting unit 11a3 has a function of setting the control mode of the microcomputer 11 based on the acquired farm work detection information. In this example, the first setting unit 11 a 3 switches the microcomputer 11 from sleep mode (also referred to as first control mode) to wake-up mode (also referred to as second control mode) according to an acceleration signal in the X-axis direction acquired from sensor 13 . set to

The second setting unit 11a5 has a function of setting the detection frequency of the sensor 13 according to the control mode. In this example, the second setting unit 11a5 sets the detection frequency of the sensor 13 to 1 Hz when the microcomputer 11 is in sleep mode. Alternatively, the second setting unit 11a5 sets the detection frequency of the sensor 13 so that when the microcomputer is in the wakeup mode, it is higher than the detection frequency of the sensor 13 in the sleep mode. Specifically, the second setting unit 11a5 sets the detection frequency of the sensor 13 to 1000 Hz when the microcomputer is in the wakeup mode.

The measurement unit 11a7 has a function of measuring the elapsed time during which the acceleration signal in the X-axis direction less than the first threshold continues to be obtained from the timing when the acceleration signal in the X-axis direction less than the first threshold is obtained in the wakeup mode.

The transmitting section 11 a 9 transmits various information to the receiver unit 20 via the communication section 15 .

The determination unit 11a2 has a function of determining based on the information acquired from the acquisition unit 11a1 or the measurement unit 11a7. For example, the determination unit 11a2 determines whether the sensing information acquired from the acquisition unit 11a1 satisfies a predetermined condition (also referred to as a first setting condition). The first setting condition is that the acquired acceleration signal in the X-axis direction is greater than or equal to a preset first threshold. Alternatively, the determination unit 11a2 determines whether the time information measured by the measurement unit 11a7 satisfies a predetermined condition (also referred to as a second setting condition).

The microcomputer 21 of the receiver unit 20 includes an acquisition section 21a1, a generation section 21a3, and a display control section 21a5 as functional sections.

The acquisition unit 21 a 1 has a function of acquiring farm work detection information transmitted from the farm work sensor unit 10 . The acquired farm work detection information is stored in the storage unit 23 . Further, the acquisition unit 21a1 may acquire information other than the farm work detection information, such as GPS information.

The generation unit 21a3 has a function of generating various types of information from the acquired information. Specifically, the data of the acquired triaxial acceleration signal is arithmetically processed to generate analysis data. Moreover, the generation unit 21a3 may generate field mapping information together with the GPS information. The generated various information is stored in the storage unit 23 .

The display control unit 21a5 has a function of controlling the display unit 25a to display various information generated on the display unit 25a.

(1-3. Agricultural work detection control process)
Next, farm work detection control processing in the farm work detection control system 1 will be described in detail with reference to the drawings. FIG. 6 is a flowchart showing an example of farm work detection control processing in the farm work sensor unit 10. As shown in FIG. FIG. 7 is a flowchart showing an example of farm work detection control processing in the receiver unit 20. As shown in FIG.

First, the microcomputer 11 of the agricultural work sensor unit 10 is set to sleep mode in advance when the agricultural work machine 100 is not operating (S101). The receiver unit 20 is on standby in a state in which wireless reception is possible (S201).

The sensor 13 (three-axis acceleration sensor) is set to the low power mode while the agricultural implement 100 is not operating (S103). The detection frequency of the sensor 13 is set to 1 Hz in the low power mode. In this case, sensing data is acquired intermittently (S103), so the amount of data detected by the sensor 13 can be reduced. This can prevent a large number of unnecessary information from being detected. In addition, by intermittently acquiring data, power consumption in the agricultural work sensor unit 10 can be reduced when the agricultural work machine 100 is not operating. Acquisition unit 11 a 1 acquires agricultural work detection information (specifically, an acceleration signal in the X-axis direction) detected by sensor 13 .

Next, the determination unit 11a2 determines whether the acceleration signal in the X-axis direction acquired by the acquisition unit 11a1 satisfies a predetermined condition (first setting condition) (in this example, whether it is equal to or greater than a preset first threshold value). whether) is determined (S105). The acceleration signal in the X-axis direction varies according to the operation of the rotary working unit 102, that is, the rotating operation of the tillage tines 103 provided on the rotary working unit 102 (tillage shaft 104). Therefore, when the agricultural implement 100 is not operating, the acceleration signal in the X-axis direction is less than the first threshold value (S105; No), so the process loops.

Next, when the agricultural implement 100 starts to operate, the tillage tines 103 on which the sensor 13 is arranged start to rotate, so the acceleration signal of the sensor 13 in the X-axis direction increases. As a result, if the acceleration signal in the X-axis direction is greater than or equal to the first threshold value (S105; Yes), the first setting unit 11a3 sets the microcomputer 11 to wakeup mode (also referred to as first control mode) (S107). . Further, the second setting unit 11a5 may set the detection mode of the sensor 13 from the low power mode to the normal mode in accordance with the change of the control mode of the microcomputer 11 from the sleep mode to the wakeup mode. At this time, the second setting unit 11a5 sets the detection frequency of the sensor 13 from 1 Hz corresponding to the low power mode to 1000 Hz corresponding to the normal mode (S109).

Further, when the acceleration signal of the tillage tines 103 in the X-axis direction is greater than or equal to the threshold value (S105; Yes), the control unit 11a generates tillage shaft rotation start information. The transmitter 11a9 transmits the generated tillage shaft rotation start information to the receiver unit 20 (S111). The acquisition unit 21a1 of the receiver unit 20 acquires the transmitted tillage shaft rotation start information (S203). At this time, the acquired tillage shaft rotation start information may include identification information (also referred to as a sensor ID) for identifying the sensors 13 arranged on the plurality of tillage tines. That is, it is possible to identify which sensor 13 is operating. Moreover, in the case of the sensor 13 with no battery capacity of the power supply unit 17, the acceleration signal of the sensor 13 is not transmitted. Therefore, it is possible to identify the sensor 13 whose battery has run out.

Next, in the wakeup mode, the measurement unit 11a7 determines that the acceleration signal in the X-axis direction detected by the sensor 13 at 1000 Hz no longer satisfies the first setting condition (the acceleration signal in the X-axis direction that is less than the first threshold The elapsed time (referred to as sleep time) during which the acceleration signal in the X-axis direction less than the first threshold continues to be acquired from the acquired timing is measured (S113). As for the sleep time, the measurement ends when the acceleration signal in the X-axis direction is equal to or greater than the first threshold, and the sleep time is measured again from 0 sec after the acceleration signal in the X-axis direction becomes less than the first threshold again. is started.

If the sleep time does not exceed the predetermined time (S115; No), the determination unit 11a2 determines whether the acceleration signal in the Y-axis direction among the acquired acceleration signals satisfies a predetermined condition (is it equal to or greater than the second threshold). ) is determined (S117). When the acceleration signal in the Y-axis direction is less than the second threshold (S117; No), the process returns to S115.

When the acceleration signal in the Y-axis direction is equal to or greater than the second threshold (S117; Yes), the transmitter 11a9 transmits acceleration signals in the X-axis direction, the Y-axis direction, and the Z-axis direction to the receiver unit 20 (S119). . Subsequently, the control process returns to S115.

At this time, in the receiver unit 20, when the acquisition unit 21a1 acquires the acceleration signal (S205), the generation unit 21a3 generates analysis data (S207). Furthermore, the display control unit 21a5 transmits a display instruction signal to the display unit 25a for the generated analysis data. As a result, the analysis data is displayed on the display section 25a (S209).

On the other hand, if the sleep time satisfies the second setting condition (exceeds the predetermined time) (S115; Yes), the first setting unit 11a3 sets the microcomputer 11 to the sleep mode (S121). Further, the second setting unit 11a5 sets the detection mode of the sensor 13 from the normal mode to the low power mode in accordance with the change of the control mode of the microcomputer 11 from the wakeup mode to the sleep mode. At this time, the second setting unit 11a5 sets the detection frequency of the sensor 13 from 1000 Hz corresponding to the normal mode to 1 Hz corresponding to the low power mode (S109). Subsequently, the control process returns to S101. The above is the farm work detection control process.

By using this embodiment, the sensor can detect an appropriate amount of sensing data according to the timing of farm work. Therefore, unnecessary data detected by the sensor is reduced, and the calculation load on the receiver unit 20 and the amount of data to be transmitted and received can be reduced.

Moreover, by using this embodiment, the detection frequency of the sensor 13 is changed according to the control mode of the farm work sensor unit 10 . In particular, when the microcomputer 11 is in sleep mode, the sensor detection frequency is set to be extremely low. As a result, unnecessary power consumption can be suppressed, so the agricultural work sensor unit 10 can be used for a long period of time.

(Modification)
Within the scope of the idea of the present invention, those skilled in the art can come up with various modifications and modifications, and it is understood that these modifications and modifications also belong to the scope of the present invention. For example, additions, deletions, or design changes of components, or additions, omissions, or conditional changes to the above-described embodiments by those skilled in the art are also subject to the gist of the present invention. is included in the scope of the present invention as long as it has

In the first embodiment of the present invention, the example in which the sensor 13 is provided on the tillage tine 103 of the agricultural work machine 100 is shown, but the present invention is not limited to this. The sensor 13 may be arranged on another member (for example, an apron) of the agricultural implement 100 .

In the first embodiment of the present invention, an example was shown in which the measurement unit 11a7 measures the time from when one acceleration signal in the X-axis direction is received to when it receives another acceleration signal in the X-axis direction. , the invention is not limited thereto. The measurement unit 11a7 may measure the time to receive the acceleration signal in the Y-axis direction or the Z-axis direction.

Also, in the first embodiment of the present invention, an example in which a triaxial acceleration sensor is used as the sensor 13 was shown, but the present invention is not limited to this. Other sensors such as a pressure sensor may be used as the sensor 13 .

Moreover, although the receiver unit 20 showed the example provided in the traveling body 300 in 1st Embodiment of this invention, this invention is not limited to this. For example, the receiver unit 20 may be arranged at a location other than the traveling body 300 . At this time, the traveling body 300 may be provided with a relay device for relaying the farm work detection information detected by the farm work sensor unit 10 to the receiver unit 20 . Alternatively, wireless communication may be performed directly from the farm work sensor unit 10 to the receiver unit 20 .

DESCRIPTION OF SYMBOLS 1... Agricultural work detection control system, 10... Agricultural work sensor unit, 11... Microcomputer, 11a... Control part, 11a1... Acquisition part, 11a2... Judgment part, 11a3... First Setting unit 11a5 Second setting unit 11a7 Measurement unit 11a9 Transmission unit 11b Memory 13 Sensor 15 Communication unit 17 Power supply Unit, 20... Receiver unit, 21... Microcomputer, 21a... Control unit, 21a1... Acquisition unit, 21a3... Generation unit, 21a5... Display control unit, 21b... Memory, 23... Storage unit, 25... User interface unit, 25a... Display unit, 25b... Operation unit, 27... Communication unit, 29... Power supply unit, 100... Agricultural implement, DESCRIPTION OF SYMBOLS 101... Main body, 102... Rotary working part, 103... Tilling nail, 103a... Vertical blade part, 103b... Horizontal blade part, 104... Tilling shaft, 105... Chain case , 106... PIC shaft, 110... main frame, 111... pedestal, 120... shield cover, 121... side plate, 125... gear box, 130... apron, 131... Ground leveling plate 140 Rotation fulcrum 150 Apron pressurizing mechanism 300 Traveling body

Claims (8)

An agricultural work sensor unit arranged on an agricultural work machine,
a sensor that detects farm work detection information generated during farm work;
a controller connected to the sensor;
The control device is
an acquisition unit that acquires the agricultural work detection information from the sensor;
a first setting unit that sets a control mode based on the acquired agricultural work detection information;
Having a second setting unit that sets the detection frequency of the sensor according to the control mode,
Farm work sensor unit. a power supply having a battery for powering the sensor and the controller;
The agricultural work sensor unit according to claim 1. The control mode includes a first control mode and a second control mode,
The first setting unit changes the first control mode to the second control mode when the acquired agricultural work detection information satisfies a first setting condition,
The second setting unit sets the detection frequency of the sensor such that the detection frequency of the sensor in the second control mode is higher than the detection frequency of the sensor in the first control mode.
The agricultural work sensor unit according to claim 1 or 2. The control device measures the elapsed time during which the agricultural work detection information that does not satisfy the first set condition continues to be acquired from when the agricultural work detection information no longer satisfies the first set condition in the second control mode. has a part
The first setting unit changes the second control mode to the first control mode when the measured elapsed time satisfies a second setting condition.
The agricultural work sensor unit according to claim 3. including the agricultural work sensor unit according to any one of claims 1 to 4,
Tillage claw. A farm work sensor unit according to any one of claims 1 to 4;
a tillage tine on which the farm work sensor unit is arranged;
farm machine. The agricultural work detection information is an acceleration signal when the tillage tine receives an impact,
The agricultural working machine according to claim 6. A farm work sensor unit according to any one of claims 1 to 4;
a receiver unit;
The agricultural work sensor unit includes:
transmitting the acquired agricultural work detection information to the receiver unit via a wireless communication device;
Farming detection control system.

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