Journal of Jilin University(Engineering and Technology Edition) ›› 2022, Vol. 52 ›› Issue (10): 2486-2500.doi: 10.13229/j.cnki.jdxbgxb20210308

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Design and experiment of flexible clamping and conveying device for bionic ear picking of fresh corn

Guang-qiang ZHU1(),Tian-yu LI1,Fu-jun ZHOU2()   

  1. 1.College of Engineering,Northeast Agricultural University,Harbin 150030,China
    2.College of Mechanical Engineering,North China University of Water Resources and Electric Power,Zhengzhou 450046,China
  • Received:2021-08-20 Online:2022-10-01 Published:2022-11-11
  • Contact: Fu-jun ZHOU E-mail:zhuguangqiang123@126.com;fjzhou@163.com

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Abstract:

Aiming at the problems of stem clamping and conveying, such as broken stems and blockages in the process of fresh corn harvesting, a bionic ear picking flexible clamping and conveying device with simple structure and stable clamping and conveying was designed. First, on the basis of analyzing the holding the stalk, bending and breaking the ears from top to bottom, researching the principle of bionic ear picking, the focus is on the operating parameters that affect the flexible stem clamping and conveying device. The grading test method is adopted for the device. The bench test was designed with a single factor, and it was obtained that the working efficiency was the best when the unit forward speed was 1.2 m/s and the cutter speed was 420 r/min. Secondly, fixing the two parameters unchanged and taking the speed of clamping conveyor belt, the inclination angle of clamping mechanism and the gap between clamping conveyor belt were taken as test factors, and the stem breaking rate and clamping accuracy were taken as test indexes, using the quadratic regression orthogonal rotation combination test method to carry out the bench test. The mathematical model of factors and indicators is established through Design-Expert8.0.6 software, and the factors are optimized after the constraints are added. The test results show that when the speed of the clamping conveyor belt is 342 r/min, the inclination angle of the clamping mechanism is 19°, and the clamping conveyor belt gap is 6.0 mm, the average value of stem broken rate is 0.46%, and the average value of clamping accuracy is 94.0%, which show a good working performance. Finally, a field verification experiment was carried out. The results show that the average stalk breaking rate was 0.55% and the average clamping accuracy rate was 93.0%, which were basically consistent with the optimized results. The device designed in this paper reduces the stalk breakage, has high stability, and meets the requirements for harvesting fresh corn ears.

Key words: agricultural mechanization engineering, fresh corn, bionic ear picking flexible clamping and conveying, experimental device, optimization analysis

CLC Number: 

  • S233.4

Fig.1

Device test bench structure diagram"

Fig.2

Structure of flexible clamping conveying"

Fig.3

Starting angle structural diagram"

Fig.4

A concave circular disc with a poking wheel"

Fig.5

Pull wheel"

Fig.6

Schematic diagram of clamping conveying mechanism"

Fig.7

Stem compression strength"

Fig.8

Shear load displacement test and curve"

Fig.9

Schematic diagram of divider"

Fig.10

Cutter diagram"

Table 1

Determination of parameters of Jingkenuo 2010"

参数项目均值参数项目均值
株高/mm2457籽粒含水率/%70
最低结穗高度/mm895果穗根部直径/mm45
果穗长度/mm189结穗位茎秆直径/mm36

Fig.11

Physical chart of test bed"

Table 2

Actual value and code of variable"

编码值因 素

夹持输送带

转速/(r·min-1

夹持机构

倾角/(°)

夹持输送带

间隙/mm

1.682664.82011.3
1563.1317.4910.08
041413.88.3
-1264.8710.116.52
-1.682163.27.65.3

Table 3

Experiment design and results"

编 号因素目标函数

夹持输送带转速

Z1/(°)

夹持机构倾角

Z2/(°)

夹持输送带间隙

Z3/(m·s-1

茎秆断茎率

Y1/%

夹持准确率

Y2/%

1264.8710.116.520.4794.11
2563.1310.116.520.2795.98
3264.8717.496.520.7292.45
4563.1317.496.520.7593.1
5264.8710.1110.080.4293.13
6563.1310.1110.080.5595.65
7264.8717.4910.080.1395.6
8563.1317.4910.080.6494.98
9163.213.88.30.3894.37
10664.813.88.30.7394.95
114147.68.30.2194.65
12414208.30.7593.68
1341413.85.30.5493.18
1441413.811.30.2193.68
1541413.88.30.2793.9
1641413.88.30.2293.87
1741413.88.30.1492.19
1841413.88.30.3792.89
1941413.88.30.4693.12
2041413.88.30.3192.43
2141413.88.30.2593.41
2241413.88.30.3192.76
2341413.88.30.2994.29

Table 4

Analysis of variance between cutting rate and stem breaking rate"

来源平方和自由度均方FP
模型0.68/0.659/60.076/0.119.15/12.090.0003***/<0.0001***
Z10.12/0.121/10.12/0.1214.44/13.400.0022***/0.0021***
Z20.18/0.181/10.18/0.1821.44/19.900.0005***/0.0004***
Z30.096/0.0961/10.096/0.09611.58/10.750.0047***/0.0047***
Z1Z20.12/0.121/10.12/0.1214.19/13.170.0024***/0.0023***
Z1Z30.0251/10.0253.050.1042
Z2Z30.00661/10.00660.800.3880
Z120.096/0.0961/10.096/0.09611.61/10.740.00471***/0.0047***
Z220.042/0.0421/10.042/0.0425.04/4.660.0427**/0.0464**
Z320.0031/10.0030.390.5440
残差0.11/0.1413/160.0082/0.0089
失拟项0.042/0.0775/80.0085/0.00971.03/1.180.4593/0.4092
纯误差0.065/0.0658/80.0082/0.0082
总和0.7922

Table 5

Analysis of variance of clamping accuracy"

来源平方和自由度均方FP
模型22.69/22.529/72.52/3.225.87/8.390.0023***/0.0003***
Z12.16/2.161/12.16/2.165.02/5.620.0431**/<0.0316**
Z22.66/2.661/12.66/2.666.19/6.920.0272**/0.0189**
Z31.50/1.501/11.50/1.503.50/3.910.0841*/0.0665*
Z1Z22.41/2.411/12.41/2.415.61/6.280.0340**/0.0242**
Z1Z30.0441/10.0440.100.7553
Z2Z35.07/5.071/15.07/5.0711.81/13.220.0044***/0.0024***
Z124.39/4.371/14.39/4.3710.21/11.400.0070***/0.0042***
Z124.42/4.411/14.41/4.4110.29/11.490.0069***/0.0040***
Z120.121/10.130.300.5918
残差5.58/5.7513/150.43/0.38
失拟项1.50/1.675/70.30/0.240.59/0.470.7099/0.8327
纯误差4.08/4.088/80.51/0.51
总和28.1722

Fig.12

Two-factor response surface for stem breaking rate"

Fig.13

Field experiment"

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