JPH11113304A - Controlling device or method for rotary tiller - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a controlling device and method for rotary tiller that can exactly detect the tillage depth and the soil characteristics and efficiently perform the uniform tillage. SOLUTION: In a farm working machine equipped with a rotary tillage unit, a means for measuring the rotation angle of the rotary-driving shaft is set to the rotary-driving shaft, while a means for measuring the tillage load on the rotary tillage line is set to the member for fitting the rotary tillage tine to the rotary-driving shaft. Then, both detected values of the rotation angle of the rotary-driving shaft and the tillage depth or the soil properties are detected from the relationship between the rotation angle of the rotary- driving shaft and the tillage load on the rotary tillage tine.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an apparatus and method for controlling tillage of a rotary tillage apparatus, and more particularly to an apparatus for detecting tillage depth and soil characteristics and optimizing and controlling the height of a rotary rotary shaft from the ground and the driving mode. And methods.

[0002]

2. Description of the Related Art When tilling is performed using an agricultural working machine such as a tractor equipped with a rotary tilling device, information on the tilling depth and soil characteristics is useful for improving the accuracy and efficiency of the operation. When these pieces of information are sequentially obtained during the tillage work, it is easy to till efficiently at a certain depth by feeding it back to the tillage device.

In order to keep the tillage depth constant, the following contrivance has been conventionally made. For example, JP-A-8-317
No. 710 “Plowing depth control device in agricultural work machine” discloses a device that detects the tillage depth by raising and lowering the tail wheel and feeds back the detected value to a hydraulic lift that pivotally supports the rotary tillage device. . As described above, when the grounding member such as the tail wheel is used as the detector, there is an advantage that the tillage depth can be detected with a simple configuration. It is difficult to obtain accurate detection due to noise caused by the unevenness of the surface, sedimentation and discontinuous operation of the grounding member caused by friction with the soil. Further, even with a separation detector such as an ultrasonic sensor, accurate detection has been difficult due to a time error caused by a difference in position between the rotary claw and noise caused by unevenness of soil. On the other hand, there has been no device for obtaining information on the tilling characteristics of the soil, such as soil mass size and viscosity. Therefore, the rotary device could not be controlled according to the characteristics of the soil.

[0004]

SUMMARY OF THE INVENTION The present invention has been made in view of the above-mentioned problems of the prior art, and an object of the present invention is to accurately detect the tillage depth and soil characteristics to achieve uniform tillage. An object of the present invention is to provide a rotary tillage control device and method that can be performed efficiently and contribute to improvement in productivity.

[0005]

According to a first aspect of the present invention, there is provided a rotary tilling control device for an agricultural work machine having a rotary tilling device. Along with the rotation angle measuring means for measuring, the load measuring means for measuring the tillage load applied to the rotary claw, or the mounting member for attaching the rotary claw to the rotary shaft is installed, and the rotation angle is obtained by both means. A configuration for detecting the tillage depth or soil characteristics from the correlation between the rotation angle of the rotary shaft and the tillage load applied to the rotary claw. Here, the correlation between the rotation angle and the tillage load is
A standardized correlation is obtained by induction, and the obtained standard correlation is used a priori to determine the tillage depth or soil characteristics from the rotation angle of the rotary shaft and the tillage load on the rotary claw. Then, during the tilling operation, the tilling depth or the soil characteristics may be sequentially and accurately and promptly detected. In addition, the standard correlation
The height or drive of the rotary shaft may be optimized and controlled in comparison with the tillage load applied to the rotary claw to contribute to efficient uniform tillage.

A first aspect of the present invention is a method for optimizing and controlling a tilling operation of an agricultural machine equipped with a rotary tilling device. Along with the rotation angle measuring means for measuring, the load measuring means for measuring the tillage load applied to the rotary claw, or the mounting member for attaching the rotary claw to the rotary shaft is installed, and the rotation angle is obtained by both means. The correlation between the rotation angle of the rotary shaft and the tillage load on the rotary claw,
Standardized by induction, the standard correlation is obtained, and the obtained standard correlation is used a priori to determine the tillage depth or soil characteristics from the rotation angle of the rotary shaft and the tillage load applied to the rotary claw, This is a rotary tilling control method for optimizing and controlling the height or drive of a rotary rotary shaft by comparing a standard correlation with a tilling load applied to a rotary claw.

On the other hand, a rotary tillage control device according to a second aspect of the present invention is an impact measuring means for measuring the impact of soil mass plowed and scattered by a rotary claw on an inner surface of a rotary cover in an agricultural work machine equipped with a rotary tillage device. Is installed, the correlation between the impact obtained by the impact measurement means and the soil property is standardized by induction to obtain a standard correlation, and the obtained standard correlation is used a priori,
A configuration is provided in which soil characteristics are obtained from the impact of the earth mass on the inner surface of the rotary cover. In this case, in comparison with the standard correlation and the impact of the earth mass on the inner surface of the rotary cover, the height or drive of the rotary shaft may be optimized and controlled to contribute to efficient uniform tillage. .

A rotary tillage control method according to a second aspect of the present invention is a method for optimizing and controlling a tillage operation of an agricultural work machine provided with a rotary tillage device. The impact measurement means to measure the impact of the soil mass was installed, and the correlation between the impact determined by the impact measurement means and the soil properties was standardized by induction, and the standard correlation was determined. Using the a priori correlation to determine the soil properties from the impact of the clod on the inner surface of the rotary cover, and comparing the standard correlation with the impact of the clod on the inner surface of the rotary cover, This is a rotary tilling control method for optimizing and controlling the drive or drive.

[0009]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The embodiments of the present invention will be described below with reference to the embodiments shown in the drawings. Here, a tractor is described as an agricultural work machine, but the present invention is applicable to general agricultural work machines having a rotary tilling device. Further, the embodiment can be appropriately changed in design without departing from the gist of the present invention. FIG. 1 is a front view showing an overview of a tractor provided with a rotary tilling device, and FIG.
FIG. 2 is a side view of a main part of the rotary tillage device. At the rear of the tractor (T) (to the right in the coordinate system of the drawing)
A rotary tilling device (R) is equipped.

First, the outline of the tractor (T) is as follows. An engine (11), a clutch case (12), and a transmission case (13) are integrally connected in order from the front to form an airframe, and front and rear wheels (14, 15) for traveling are arranged before and after the body. Is established. A driver's seat (16) and a traveling handle (17) are provided at the upper part. A rotary tilling device (R) is provided at the rear of the body so as to be vertically movable by a three-point link mechanism (20) and a hydraulic lift (21).

[0011] The body (30) of the rotary tilling device (R)
Is connected and supported by the tractor (T) by the top link (25) and the lower link (24). The lower link (24) is connected via a lift rod (23) to a lift arm (22) of the hydraulic lift (21). Therefore, by controlling the hydraulic lift (21), the rotary tilling device (R) is controlled via the lift arm (22), the lift rod (23), and the lower link (24).
Is controlled to move up and down.

The outline of the rotary tilling device (R) is as follows. The driving force of the rotary tilling device (R) is PT
The electric power is transmitted from the O-axis (18) to the rotary shaft (33) via the chain case (31). The rotary shaft (33) is installed in the machine body width direction, and a plurality of rotary claws (36) are mounted substantially vertically. Therefore, when the rotary shaft (33) rotates, the rotary claws (36) plow the soil. A rotary cover (32) is provided in a curved shape to cover the rotary claw (36) from above in order to prevent the cultivated soil mass from scattering upward.

In the first invention of the present invention, such a rotary tilling device (R) is provided with a rotary rotating shaft (33).
And a load measuring means for measuring the tillage load applied to the rotary claw (36). As the rotation angle measuring means, any conventionally known meter can be arbitrarily used as long as it has a function of measuring the rotation of the shaft. For example, a rotation angle measuring device (not shown) is installed on the bearing (37) of the rotary rotation shaft (33) to measure the rotation angle θ of the rotary claw (36). The rotation angle θ of the rotary claw (36) is an index for measuring how much the rotary claw (36) has rotated downward from the horizontal plane as a starting point, as shown in FIG. The calibration of the starting point is performed using the bearing (3
7) It is sequentially performed by a horizontal standard device (not shown) attached to the above.

On the other hand, as the load measuring means, any conventionally known sensor can be used as long as it has a function of directly or indirectly measuring the stress. For example, a piezoelectric element (36
Using s), the rotary pawl (36) or the mounting member for attaching the rotary pawl (36) to the rotary rotating shaft (33) is attached. In the embodiment shown, a rotary claw (36) is provided on the outer peripheral surface of the rotary shaft (33).
A plurality of substantially cylindrical holders (34) for fitting and supporting the roots of the bosses are integrally provided. The rotary claw (36)
It is fitted into this holder (34) and fixed with bolts (35). And the piezoelectric element (36s) is arranged between the rotary claw (36) and the holder (34). Thereby, the tillage load applied to the rotary claw (36) can be measured as the stress s sensed by the piezoelectric element (36s).

Here, the piezoelectric element (36s) is composed of a rotary claw (36) and a holder (3) as independent members.
Although positioned between 4), the piezoelectric element (36s) may be integrally formed with the rotary claw (36) or the holder (34). Further, the piezoelectric element (36s) may be provided on bolts (35) for fixing the rotary claws (36).

The rotation angle θ of the rotary shaft (33) determined by the rotation angle measuring means and the tillage load on the rotary claw (36) determined by the load measuring means, that is, the piezoelectric element (36s) are sensed. There is a specific correlation with the stress s. For example, in the case of FIG.
When the rotation angle θ is about 20 degrees, the rotary claws (36) are driven into the soil, and the tilling load starts to be applied. This tillage load is strongly applied while the rotary claw (36) is plowing the soil, and when the rotation angle θ exceeds about 90 degrees, only the load for discharging the plowed soil mass is obtained. When finished, there is no tillage load.

As described above, there is a specific correlation between the rotation angle θ of the rotary rotary shaft (33) and the tillage load applied to the rotary claw (36). To determine the rotation angle θ from
It is possible to both determine the tillage load from the rotation angle θ.

The main factors that determine the magnitude of the tillage load are the tillage depth h and the soil characteristics p. Examples of the soil property p include the bond strength of the constituents of the soil, the macroscopic viscosity of the soil, the particle size of the soil mass, and the hardness of the ground surface. Therefore, in the present invention, the rotation angle θ of the rotary rotation shaft (33) is
And the tilling load applied to the rotary claw (36), that is, the stress s sensed by the piezoelectric element (36s), is used to detect the tilling depth h or the soil characteristic p which is the main cause of the tilling load. The information is used for controlling the rotary tillage device (R).

[0019] For example, but only one measurement s = f (theta), the rotation angle theta _h start takes stress s for tilling load or the piezoelectric element (36 s) is sensed, that determine the tilling depth h by the following formula It is possible. h = r (1−sin θ _h ) where r is a rotary claw (3
Diameter of 6)} However, a plurality of measurements _{s i = f i (θ)} , the previously obtained standard correlation <f _i>, successively during tilling, precisely the tilling depth h or soil properties p And it detects quickly and optimizes and controls the height or drive of the rotary shaft (33) to contribute to efficient uniform plowing. The preferred embodiment will be described with reference to the flowchart shown in FIG.

1. s _i = f _i (θ) The correlation f _i between the rotation angle θ of the rotary shaft (33) and the tillage load (the stress s _i sensed by the piezoelectric element (36s)) applied to the rotary claw (36). Are collected experimentally in large numbers.

2. s _i = standardized by induction of <f _i (θ)> resulting correlation f _i, standard correlations Request <f _i>. The standard correlation fa shown in FIG. 4 is one example.

3. _{<F i> = fa, fb} , fc, ··
• Each field of and soil characteristic p of climate weather conditions were also taken into account, tillage depth standard correlation in accordance with the terms and conditions of such h to typify <f _i>, various patterns fa standard correlation <f _i> ,
fb, fc, ... are obtained. For example, depending on the soil hardness and viscosity, standard correlations <f _i> will be different patterns. The standard correlations fa and f shown in FIGS.
b is an example.

The standard correlation <f _i > = fa shown in FIG.
Is a case where the hardness of the soil is large and the viscosity is small. If the hardness of the soil increased viscosity is low, immediately after the rotation angle theta _h Rotary pawl (36) starts plowing in contact with the soil, taking the tillage load increases rapidly stress s maximum value s _m, decreasing thereafter However, when the rotation angle θ exceeds about 90 degrees, only the load for throwing out the plowed soil is suddenly reduced, and when the throwing is completed, there is no tillage load.

On the other hand, the standard correlation <f _i > shown in FIG.
= Fb is the case where the soil hardness is small and the viscosity is large. If due to such a high water content and clay mineral hardness of soil large small viscosity, tilling the load begins to increase slightly from the rotation angle theta _h, stress s is a state that does not change much from the maximum value s _m maintained Shows a substantially box-shaped potential that gradually decreases thereafter. Even if the rotation angle θ exceeds about 90 degrees, the soil adheres to the rotary claws (36) due to the large viscosity, and the tillage load does not decrease rapidly.

4. <F> = fa The rotation angle θ of the rotary shaft (33) during the tilling operation.
When measures correlations f between stress s _i according to the rotary claw (36). Then, a standard correlation <f> that approximates the pattern to the correlation f, for example, fa is selected, and it is determined to which type the field under tillage belongs.

In selecting the standard correlation <f>,
The measured correlation f is smoothed. For example,
The values that greatly change discontinuously, such as s ₁ , s ₂ , and s ₃ in FIG. 4, are determined when the rotary claw (36) hits a soft material such as root vegetables or a hard material such as rock. And discard it. The exclusion criterion is that the change rate ds / dθ of the stress s is as follows: ds / dθ> a where a is a constant that indicates a predetermined threshold value and a domain Δθ (s ≒ s ₁ ) of the rotation angle θ that indicates a surge. small _{Δθ (b · s 1 <s} <c · s 1) <d {b, c, d is a constant indicating a predetermined threshold value} utilize like.

[0027] 5. Rotation angle θ, stress s »tillage depth h, soil characteristics p (<f> = fa ⇒ p = hardness small, viscosity large _{h = r (1-sinθ h} ) <f> = fb ⇒ p = hardness large, viscous small h = r {1−sin (90 + θ ₁ −θ ₂ )} <f> = fc ⇒ p = ... h = ... <f> = ... ⇒ p = ... h =...) The selected standard correlation <f> For example, by using a priori, from the rotation angle θ of the rotary rotation shaft (33) and the stress s _i applied to the rotary claw (36), The tillage depth h or soil characteristic p is detected.

For example, when the measured correlation f is statistically identified as the standard correlation fa shown in FIG.
The soil characteristic p is judged to have high hardness and low viscosity indicated by the standard correlation fa. Further, the rotation angle theta _h start takes stress s, tillage depth h is determined by the following equation. h = r (1−sin θ _h )

When the measured correlation f is statistically identified as the standard correlation fb shown in FIG. 5, the soil characteristic p has a small hardness indicated by the standard correlation fb. It is determined that the viscosity is large. in this case,
Since the rise of the stress s from the rotation angle θh is very small, θ
Precise detection of _h is not easy. Therefore, when the half height width θ ₁ −θ ₂ of the box-shaped potential is used to determine θ _h , the tillage depth h is obtained by the following equation. θ _h = 90 + θ ₁ −θ ₂ h = r (1−sin θ _h ) = r ｛1−sin (90 + θ
₁ −θ ₂ )｝ Thus, during the tilling operation, the rotary shaft (33)
The correlation f between the rotation angle θ and the tillage load (the stress s _i sensed by the piezoelectric element (36s)) applied to the rotary claw (36) is measured, and a standard correlation approximating the correlation f in a pattern is obtained. By selecting the relations fa, fb, fc,..., It is possible to detect the soil characteristics p and the tillage depth h from the rotation angle θ and the stress s.

6. f → <f> The selected standard correlation <f> For example, fa is compared with the measured value of the tillage load applied to the rotary claw (36) to optimize and control the rotary tillage device. The main object to be controlled is the height of the rotary shaft (33) or the manner of driving. The height of the rotary rotary shaft (33) contributes to keeping the tillage depth h constant, and the driving mode of the rotary rotary shaft (33) is effective and efficient tillage according to each soil characteristic p. Contributes to doing. In the following, the mode of drive control is defined as the selected standard correlation <f
An example in which> is fa will be described.

FIG. 6 is a graph showing the relationship between the rotation angle θ of the rotary rotary shaft (33) and the torque t. The pattern of the ideal curve I substantially approximates the standard correlation fa shown in FIG. That is, using the rotation angle θ of the rotary rotating shaft (33) as a parameter, the torque t is substantially similar to the change in the stress s in the standard correlation fa.
It is preferable to drive the rotary shaft (33) to actively change the rotation angle. In other words, if the torque t is actively changed in accordance with the change in the tillage load applied to the rotary claw (36), efficient and effective tillage can be performed. For example, P
When the rotation speed of the TO shaft (18) is constant, when a large tillage load is suddenly applied, the torque t of the rotary claw (36) decreases passively and suddenly, and the rotation of the rotary rotation shaft (33) stops. It can happen. In order to eliminate such problems and perform efficient and effective tillage,
The driving mode of the rotary shaft (33) is actively controlled.

For this purpose, the drive system such as the rotation speed of the PTO shaft (18) is controlled so that the measurement curve E measured during the tilling operation coincides with the ideal curve I. At that time, using a learning means such as a neural network, the soil characteristic p of the field is quickly detected in the initial stage of the tilling operation, thereby contributing to an effective and efficient driving mode of the rotary rotary shaft (33). . For example, just before increasing the rotation speed of the rotary rotary shaft (33) immediately before the rotation angle θ at which the tilling load starts to apply a large amount, an effect of preventing the abnormal reduction of the torque t due to the tilling load is prevented.

By the way, as shown in FIG. 2, in the present invention, the photoelectric sensor (41) is attached to the rotary tillage device (R).
May be added to fulfill the function. Rotary rotary shaft (3
A rod-shaped holding member (40) is provided below the bearing (37) of 3).
Through the rotary claw (3)
Set up for 6). When this is added, the tillage depth h
Detection accuracy is improved.

As described above, the rotary tillage device (R) is provided with a rotation angle measurement means for measuring the rotation angle θ of the rotary rotation shaft (33) and a load measurement means for measuring the tillage load applied to the rotary claw (36). The second invention device of the present invention relates to the first invention device. In addition to the rotation angle measuring means for measuring the rotation angle θ of the rotary shaft (33), the second invention device also includes a rotary claw (36) for plowing and scattering. Impact measuring means for measuring the impact i of the soil mass is attached to the inner surface of the rotary cover (32). Hereinafter, the rotary tillage control device and method according to the second invention device of the present invention will be described, but points common or similar to the rotary tillage control device and method according to the first invention will be described for simplification of description. I omit it.

According to the second invention, the impact measuring member (32s) for measuring the impact i of the soil mass plowed and scattered by the rotary claws (36) is replaced with a rotary cover (instead of the tilling load measuring means in the first invention). 32). Therefore, the rotary claw (3
Instead of the tillage load applied to 6), that is, the stress s sensed by the piezoelectric element (36s), the impact i of the soil mass plowed and scattered by the rotary claws (36) applied to the inner surface of the rotary cover (32) is treated as a variable. Then, similarly to the first invention, the rotary tillage device (R) can be optimized and controlled. That is, the correlation f between the impact i obtained by the impact measuring member (32s) and the soil property p is
Standardized by induction to find a standard correlation <f>,
Using the obtained standard correlation <f> a priori, from the impact i of the earth mass on the inner surface of the rotary cover (32),
Determine the soil property p. And this standard correlation <
By comparing f> with the impact i of the earth mass on the inner surface of the rotary cover (32), the height or drive of the rotary shaft (33) is optimized and controlled to contribute to efficient uniform tillage.

As the impact measuring member (32s), a conventionally known sensor such as a piezoelectric element having any function of directly or indirectly measuring the impact i can be arbitrarily used as in the first invention. However, a function is provided to measure the impact i as a vector, determine the direction of the impact force in addition to the magnitude, and also measure the point of action of the impact i, that is, the position on the rotary cover (32) where the earth mass collides. Is preferred. For example, measuring the height of the soil mass that collides with the rotary cover (32) from the field is useful for improving the accuracy of detecting the impact i.

For example, if a small impact i is detected throughout the rotary cover (32) from the field to a high position, it is determined that the soil mass p is small and the water content is low as the soil characteristic p of the field. Also, if a large impact i is detected only at a low position near the field in the rotary cover (32) and the detected value of the impact i is nil even if the rotation angle θ of the rotary rotary shaft (33) exceeds 90 degrees. If not, it is determined that the soil characteristics p of the field are large, such as the soil mass particle size and the water content are large.

The soil mass plowed and scattered by the rotary claws (36) is unavoidably affected by gravity in addition to the environment such as wind. FIG. 7 shows the particle size q of the soil mass plowed and scattered by the rotary claws (36) and the rotary cover (3).
2) It is a graph which shows the relationship with the impact i of the earth mass applied to the inner surface. As shown, the relationship between the particle size q of the earth mass and the impact i is non-linear. If the mass is larger than a certain size, the impact measurement member (3) provided on the inner surface of the rotary cover (32)
It falls freely before reaching 2s). This threshold q ₀
By correcting the impact i in consideration of nearby graph characteristics, more accurate detection can be obtained and uniform tilling can be performed efficiently.

[0039]

The rotary tilling control apparatus and method according to the present invention have the following effects due to the above-mentioned configuration. That is, according to the first invention rotary tilling control device of the first aspect, the tilling depth or the soil characteristics is detected from the correlation between the rotation angle of the rotary rotary shaft and the tilling load applied to the rotary claw, so that the uniformity is obtained. This contributes to efficient tilling. According to the first aspect of the present invention, the tilling depth or the soil characteristics is determined by using the standard correlation between the rotation angle of the rotary shaft and the tilling load applied to the rotary claw. The tillage depth or soil characteristics can be detected accurately and quickly in sequence. According to the first aspect of the present invention, the height or drive of the rotary rotary shaft is optimized and controlled in comparison with the standard correlation and the tillage load applied to the rotary claw, so that efficient uniformity is achieved. Tillage is easily achieved. According to the rotary tilling control method of the first invention according to claim 4, it is possible to easily achieve efficient uniform tilling by effectively utilizing the rotary tilling control device of the first invention according to claims 1 to 3. Can be.

According to the rotary tillage control device of the second aspect of the present invention, a standard correlation between the rotation angle of the rotary shaft and the impact of the plowed and scattered soil mass on the inner surface of the rotary cover is used. Since soil characteristics are required, soil characteristics can be detected accurately and quickly successively during tillage work. According to the second aspect of the present invention, the height or driving of the rotary shaft is optimized and controlled in comparison with the standard correlation and the impact of the earth mass on the inner surface of the rotary cover. Uniform tillage is easily achieved. According to the rotary tilling control method of the second invention according to claim 7, the rotary tilling control device of the second invention according to claim 5 or 6 is effectively used,
Efficient uniform tillage can be easily achieved.

[Brief description of the drawings]

FIG. 1 is a front view showing an overview of a tractor equipped with a rotary tilling device.

Fig. 2 Side view of the main part of the rotary tilling device

FIG. 3 is a flowchart showing a control example of a rotary tillage device.

FIG. 4 shows the rotation angle θ of the rotary shaft when the soil hardness is high and the viscosity is low, and the load s applied to the rotary claw.
Graph showing a standard correlation fa between

FIG. 5 is a graph showing a standard correlation fb when soil hardness is low and viscosity is high.

FIG. 6 is a graph showing a relationship between a rotation angle θ of a rotary rotary shaft and a torque t.

FIG. 7 is a graph showing the relationship between the particle diameter q of the soil mass plowed and scattered and the impact i of the earth mass on the inner surface of the rotary cover.

[Explanation of symbols]

T Tractor R Rotary tillage device 11 Engine 12 Clutch case 13 Transmission case 14 Front wheel 15 Rear wheel 16 Driver's seat 17 Running handle 18 PTO shaft 20 Three-point link mechanism 21 Hydraulic lift 22 Lift arm 23 Lift rod 24 Lower link 25 Top link 30 Body of rotary tilling device 31 Chain case 32 Rotary cover 32s Impact measuring member 33 Rotary rotating shaft 34 Holder 35 Bolt 36 Rotary claw 36s Piezoelectric element 37 Bearing 40 Holding member 41 Photoelectric sensor E Measurement curve I Ideal curve a, b, c, d Constant f Correlation <f>, fa, fb, fc Standard correlation h Cultivation depth i Impact on the rotary cover p Soil properties q Clot diameter r Rotary claw diameter s Rotary claw diameter Angle of rotation of the torque θ rotary axis of the t rotary claw

──────────────────────────────────────────────────の Continued on the front page (51) Int.Cl. ⁶ Identification code FI G05B 11/36 501 G05B 11/36 501F 13/02 13/02 Z

Claims (7)

[Claims] An agricultural work machine provided with a rotary tilling device, wherein a rotary angle measuring means for measuring a rotary angle of the rotary rotary shaft is installed on the rotary rotary shaft, and the rotary claw or the rotary claw is connected to the rotary rotary shaft. A load measuring means for measuring the tillage load applied to the rotary claw is installed on the mounting member to be attached, and from the correlation between the rotation angle of the rotary rotary shaft obtained by both means and the tillage load applied to the rotary claw, the tillage depth or Rotary tillage control device characterized by detecting soil characteristics. 2. The correlation in claim 1 is standardized by induction to obtain a standard correlation, and the obtained standard correlation is used a priori to determine the rotation angle of the rotary shaft and the rotary claw. A rotary tillage control device characterized in that a tillage depth or a soil characteristic is obtained from the tillage load. 3. A rotary tilling control device characterized by optimizing and controlling the height or drive of a rotary rotary shaft by comparing the standard correlation in claim 2 with the tilling load applied to a rotary claw. 4. A method for optimizing and controlling a tilling operation of an agricultural work machine equipped with a rotary tilling device, comprising: installing a rotation angle measuring means for measuring a rotation angle of a rotary rotation shaft on a rotary rotation shaft; A load measuring means for measuring the tillage load applied to the rotary claw is installed on the claw or on the mounting member for attaching the rotary claw to the rotary rotary shaft, and the rotation angle of the rotary shaft determined by both means and the load applied to the rotary claw are measured. The correlation with the tillage load is standardized by induction, the standard correlation is obtained, and the obtained standard correlation is used a priori to determine the rotation angle of the rotary shaft and the tillage load applied to the rotary claw. Determine the tillage depth or soil properties and compare the standard correlation with the tillage load on the rotary claw to determine the height of the rotary shaft. Other Rotary tiller control method and controlling optimize driving. 5. An agricultural work machine equipped with a rotary tilling device, wherein an impact measuring means for measuring an impact of a soil mass plowed and scattered by a rotary claw is installed on an inner surface of a rotary cover, and the impact measuring means determines the impact. The correlation between the impact and the soil properties is standardized by induction, the standard correlation is obtained, and the obtained standard correlation is used a priori to determine the soil properties from the impact of the clod on the inner surface of the rotary cover. Rotary tillage control device characterized by the need. 6. Rotary tillage control, wherein the height or drive of the rotary shaft is optimized and controlled by comparing the standard correlation according to claim 5 with the impact of the earth mass on the inner surface of the rotary cover. apparatus. 7. A method for optimizing and controlling a tilling operation of an agricultural work machine equipped with a rotary tilling device, comprising: an impact measuring means for measuring an impact of a soil mass plowed and scattered by a rotary claw on an inner surface of a rotary cover. Once installed, the correlation between the impact determined by the impact measurement means and the soil properties is standardized by induction, a standard correlation is determined, and the obtained standard correlation is used a priori to provide a rotary cover. The characteristics of the soil are determined from the impact of the mass on the inner surface, and the height or drive of the rotary shaft is optimized and controlled by comparing the standard correlation with the impact of the mass on the inner surface of the rotary cover. Rotary tilling control method.