Crop growth sensing apparatus and method supporting agricultural machinery variable-quantity fertilization operations

Abstract

A crop growth sensing apparatus and method supporting agricultural machinery variable-quantity fertilization, includes a shock-absorbing support, a shock-absorbing frame, and a cantilever beam. The shock-absorbing support is connected to an agricultural machinery vehicle frame. The cantilever beam is pivotally connected above a shock-absorbing spring of the shock-absorbing support. The cantilever beam, by means shock-absorbing springs mounted thereabove and thereunder, is pivotally connected to the shock-absorbing frame. The shock-absorbing frame is fixedly connected to a crop growth sensor. The crop growth sensing method employs an engine vibration model of the agricultural machinery and a vibration model for vehicle wheels and farmland road surface as excitations in analyzing vibrations of a crop growth multispectral sensor shock-absorbing apparatus to determine the number and mount positions of sensitive elements of the crop growth multispectral sensor. Also provided are a self-balancing apparatus and a self-balancing method for the crop growth multispectral sensor.

Claims

1. A crop growth sensing apparatus supporting agricultural machinery variable-quantity fertilization operations, comprising a shock-absorbing support, a first shock-absorbing spring, a cantilever beam, a shock-absorbing frame, a second shock-absorbing spring, upper and lower plates, and a position-adjustable connecting plate, wherein the first shock-absorbing spring is disposed between the cantilever beam and the shock-absorbing support to implement vibration isolation between the cantilever beam and an agricultural machinery frame; the second shock-absorbing spring is disposed between the shock-absorbing frame and the cantilever beam to implement vibration isolation between the sensor and the cantilever beam; the cantilever beam is pivotally connected to the shock-absorbing frame; the shock-absorbing frame is fixedly connected to a crop growth sensor; one end of the shock-absorbing support is fixedly connected to the agricultural machinery frame; the cantilever beam is pivotally connected above the shock-absorbing spring through a king pin; the shock-absorbing frame is pivotally connected to the cantilever beam by presetting a preload of the second shock-absorbing spring through the upper and lower plates; and the position-adjustable connecting plate is configured to fixedly mount the crop growth sensor and adjust a height of the crop growth sensor.

2. A crop growth multispectral sensor self-balancing apparatus, comprising a simple pendulum gear damping system, a simple pendulum non-circular gear damping system, a simple pendulum gear driving system, and a control assembly, wherein the crop growth sensor self-balancing apparatus is mounted on an agricultural machinery frame by means of a fastening plate; a first gear; a second gear, a third gear, and a fourth gear form the simple pendulum gear damping system; a first non-circular gear and a second non-circular gear form the simple pendulum non-circular gear damping system, wherein the simple pendulum gear damping system and the simple pendulum non-circular gear damping system are configured to inhibit an impact of a tilt of an agricultural machinery; the simple pendulum gear damping system constituted by the first gear, the second gear, the third gear, and the fourth gear is mounted on a frame; the third gear and the fourth gear are mounted on the fastening plate by means of a third shaft pin with a third bearing, and the first non-circular gear and the second non-circular gear are mounted on the frame respectively by means of a first shaft pin with a first bearing and a second shaft pin with a second bearing; a crop growth multispectral sensor is mounted on a position-adjustable plate; a gyroscope detects attitude information of the crop growth multispectral sensor, and applies, according to a predetermined target, a target control signal to a simple pendulum gear pair and the simple pendulum gear driving system constituted by a first brushless motor driver, a second brushless motor driver, and a third brushless motor driver; the target control signal implements a closed-loop control on the crop growth multispectral sensor in a balanced and steady state by using a PID control strategy based on an excitation-response model; and the control assembly comprises a processor and the gyroscope; wherein the gyroscope detects attitude information of the crop growth sensor, and the processor controls, according to the attitude information of the crop growth multispectral sensor; an assembly of the first brushless motor driver; the second brushless motor driver and the third brushless motor driver to controls the simple pendulum gear driving system to drive the agricultural machinery frame to perform an attitude adjustment on the crop growth multispectral sensor, to ensure that a angle between the crop growth multispectral sensor and a monitored crop is always kept within a range.

3. The crop growth sensing apparatus according to claim 2, wherein a simple pendulum gear pair system is used as a damping system and a driving system of the crop growth multispectral sensor self-balancing apparatus.

4. A crop growth sensing method supporting agricultural machinery variable-quantity fertilization operations, comprising the following steps: performing a vibration finite element analysis on a crop growth sensor shock-absorbing frame by using ANSYS software; during analysis, applying vibration models of an agricultural machinery, comprising an engine vibration model of the agricultural machinery and a vibration model for vehicle wheels and a farmland road surface, to a model as excitation inputs; respectively analyzing vibration amounts of crop growth sensors mounted at different positions of a cantilever beam, to obtain vibration amplitudes of the different positions; obtaining a union set of mounting positions satisfying the following two conditions: [1] H=H.sub.sH.sub.v and H.sub.LHH.sub.H, wherein in a vibration condition, H is a distance between a crop growth multispectral sensor and a crop; H.sub.s is a mounting height of the crop growth multispectral sensor; H.sub.v is a vibration amplitude; H.sub.L is a lowest monitoring height of the crop growth multispectral sensor; and H.sub.H is a highest monitoring height of the crop growth multispectral sensor; and [2] RL1.5R, wherein R is a diameter of the field of view of the crop growth multispectral sensor; and L is a mounting distance of the crop growth multispectral sensor.

5. A crop growth multispectral sensor self-balancing method, comprising the following steps: performing kinetic analysis and dynamic analysis; finding response models of a crop growth multispectral sensor self-balancing apparatus according to claim 2 under different excitations by means of numerical simulation and experiment analysis methods, wherein a gear engagement force of a simple pendulum gear, a length between an engagement point and a pivot point, and a sensor weight are all related to the response model, and their relationship is: $\left(t\right)=A\cos \left[\sqrt{\frac{g+\frac{F_n}{m}\frac{\mathrm{df}\left(t\right)}{\mathrm{dt}}}{L}t}+\right]$ wherein A and are constants, depending on an initial state of the simple pendulum gear, g is gravitational acceleration, F.sub.n is a gear engagement force of a simple pendulum gear, L is a length between an engagement point and a pivot point, m is a sensor weight, t is a simple pendulum swinging time and (t) is an applied excitation; and designing a PID control algorithm according to an excitation-response model of the crop growth multispectral sensor self-balancing apparatus, to implement closed-loop control on a crop growth multispectral sensor in a balanced and steady state.

6. A crop growth multi spectral sensor self-balancing method, comprising the following steps: performing kinetic analysis and dynamic analysis; finding response models of a crop growth multispectral sensor self-balancing apparatus according to claim 3 under different excitations by means of numerical simulation and experiment analysis methods, wherein a gear engagement force of a simple pendulum gear, a length between an engagement point and a pivot point, and a sensor weight are all related to the response model, and their relationship is: $\left(t\right)=A\cos \left[\sqrt{\frac{g+\frac{F_n}{m}\frac{\mathrm{df}\left(t\right)}{\mathrm{dt}}}{L}t}+\right]$ wherein A and are constants, depending on an initial state of the simple pendulum gear, g is gravitational acceleration, F.sub.n is a gear engagement force of a simple pendulum gear, L is a length between an engagement point and a pivot point, m is a sensor weight, t is a simple pendulum swinging time and f(t) is an applied excitation; and designing a PID control algorithm according to an excitation-response model of the crop growth multispectral sensor self-balancing apparatus, to implement closed-loop control on a crop growth multispectral sensor in a balanced and steady state.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) FIG. 1 is a schematic structural diagram of a crop growth multispectral sensor shock-absorbing apparatus according to the present invention;

(2) FIG. 2 is a schematic diagram of a shock-absorbing support and its mounting according to the present invention;

(3) FIG. 3 is a schematic diagram of a shock-absorbing frame and its mounting according to the present invention;

(4) FIG. 4 is a schematic diagram of a result of ANSYS-based vibration modal analysis on a mounting frame according to the present invention;

(5) FIG. 5 is a schematic structural diagram 1 of a crop growth multispectral sensor self-balancing apparatus according to the present invention;

(6) FIG. 6 is a schematic structural diagram 2 of a crop growth multispectral sensor self-balancing apparatus according to the present invention; and

(7) FIG. 7 is a principle diagram of a simple pendulum damping system according to the present invention.

DETAILED DESCRIPTION OF THE EMBODIMENTS

(8) The present invention is further described below with reference to the accompanying drawings.

(9) A preferred embodiment of the present invention is shown in FIG. 1, FIG. 2, FIG. 3, and FIG. 4: In a crop growth sensing apparatus supporting agricultural machinery, variable-quantity fertilization operations, a crop growth multispectral sensor shock-absorbing apparatus thereof includes a shock-absorbing support 2, a first shock-absorbing spring 3, a cantilever beam 5, a shock-absorbing frame 6, a second shock-absorbing spring 7, upper and lower plates 8, and a position-adjustable connecting plate 9, where the second shock-absorbing spring 7 and the first shock-absorbing spring 3 are respectively disposed above or under the cantilever beam 5, the cantilever beam 5 is pivotally connected to the shock-absorbing frame 6, the shock-absorbing frame 6 is fixedly connected to a crop growth sensor, one end of the shock-absorbing support 2 is fixedly connected to an agricultural machinery frame 1, the cantilever beam 5 is pivotally connected above the shock-absorbing spring 3 through a king pin 4, the shock-absorbing frame 6 is pivotally connected to the cantilever beam 5 by presetting a preload of the shock-absorbing spring 7 through the upper and lower plates 8, and the position-adjustable connecting plate 9 is configured to fixedly mount the crop growth sensor and adjust a height of the crop growth sensor.

(10) A preferred embodiment of the present invention is shown in FIG. 5, FIG. 6, and FIG. 7: In a crop growth sensing apparatus supporting agricultural machinery variable-quantity fertilization operations, a crop growth multispectral sensor self-balancing apparatus thereof includes a simple pendulum gear damping system, a simple pendulum non-circular gear damping system, a simple pendulum gear driving system, and a control assembly; the crop growth multispectral sensor self-balancing apparatus may mount the apparatus on the agricultural machinery frame by means of a fastening plate 16; a first gear 10, a second gear 11, a third gear 13, and a fourth gear 14 form the simple pendulum gear damping system; a non-circular gear 19 and a non-circular gear 20 form the simple pendulum non-circular gear damping system, configured to inhibit an impact of a tilt of agricultural machinery; the simple pendulum gear damping system constituted by the first gear 10, the second gear 11, the third gear 13, and the fourth gear 14 is mounted on a frame 15; both of the third gear 13 and the fourth gear 14 are mounted on the fastening plate 16 by means of a shaft pin 25 with a bearing, and the non-circular gear 19 and the non-circular gear 20 are mounted on the frame 15 respectively by means of a first shaft pin 21 with a bearing and a second shaft pin 23 with a bearing; a crop growth multispectral sensor 12 is mounted on a position-adjustable plate 22; a gyroscope detects attitude information of the crop growth multispectral sensor 12, and applies, according to a predetermined target, a control signal to a simple pendulum gear pair and the simple pendulum gear driving system constituted by a first brushless motor driver 17, a second brushless motor driver 18, and a third brushless motor driver 24; a target control signal implements closed-loop control on the crop growth multispectral sensor in a balanced and steady state by using a PID control strategy based on an excitation-response model; and the control assembly includes a processor and a gyroscope, where the gyroscope detects attitude information of the crop growth multispectral sensor, and the processor controls, according to the attitude information of the crop growth multispectral sensor, a driver assembly of the brushless motor to control the simple pendulum gear driving system to drive the frame assembly to perform attitude adjustment on the crop growth multispectral sensor, to ensure that a angle between the crop growth multispectral sensor and a monitored crop is always kept within a range.

(11) A simple pendulum gear pair system is used as a damping system and a driving system of the crop growth multispectral sensor self-balancing apparatus.

(12) A crop growth sensing method supporting agricultural machinery variable-quantity fertilization operations includes the following steps:

(13) (1) A method for determining the number of and positions of mounted crop growth sensors includes:

(14) performing vibration finite element analysis on a crop growth sensor shock-absorbing frame by using ANSYS software;

(15) during analysis, applying vibration models of agricultural machinery, including an engine vibration model of the agricultural machinery and a vibration model for vehicle wheels and a farmland road surface, to a model as excitation inputs;

(16) respectively analyzing vibration amounts of crop growth sensors mounted at different positions of a cantilever beam, to obtain vibration amplitudes of the different positions; and

(17) obtaining a union set of mount positions satisfying the following two conditions:

(18) [3] in a vibration condition, a distance H between a crop growth multispectral sensor and a crop=a mounting height H.sub.s of the crop growth multispectral sensora vibration amplitude H.sub.v satisfies that a lowest monitoring height H.sub.L of the crop growth multispectral sensorHa highest monitoring height H.sub.H of the crop growth multispectral sensor; and

(19) [4] a diameter R of the field of view of the crop growth multispectral sensora mounting distance L of the crop growth multispectral sensor1.5R. Further, vibration finite element analysis is performed on the crop growth sensor shock-absorbing frame by using the ANSYS software, and the number and mount positions of the crop growth sensors are determined with reference to a size of the field of view of the crop growth multispectral sensor, to achieve an optimal crop growth monitoring effect.

(20) (2) A crop growth multispectral sensor sell-balancing method includes:

(21) as shown in FIG. 7, for kinetic analysis and dynamic analysis, finding a response model of a crop growth multispectral sensor self-balancing apparatus under different excitations by means of numerical simulation and experiment analysis methods, where a gear engagement force F.sub.n of a simple pendulum gear, a length L between an engagement point and a pivot point, and a sensor weight m are all related to the response model, and their relationship is:

(22) $\left(t\right)=A\cos \left[\sqrt{\frac{g+\frac{F_n}{m}\frac{\mathrm{df}\left(t\right)}{\mathrm{dt}}}{L}t}+\right]$

(23) where A and are constants, depending on an initial state of the simple pendulum gear, and f(t) is an applied excitation; and

(24) designing a PID control algorithm according to an excitation-response model of the crop growth multispectral sensor self-balancing apparatus, to implement closed-loop control on a crop growth multispectral sensor in a balanced and steady state.

(25) The foregoing embodiments are merely descriptions on preferred implementations of the present invention, rather than limitations to the concept and scope of the present invention. Various variations and improvements made by a person of ordinary skill in the art on the technical solutions of the present invention without departing from the design concept of the present invention shall all fall within the protection scope of the present invention. The technical contents claimed by the present invention are all recorded in the claims.