Journal of Jilin University(Engineering and Technology Edition) ›› 2023, Vol. 53 ›› Issue (10): 2847-2855.doi: 10.13229/j.cnki.jdxbgxb.20211347

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On-line detection method of aggregate gradation based on image processing

Xin RONG1(),Hong-hai LIU1(),Zuo-yao YIN2,Hai-xiang LIN2,Qing-hua BIAN3   

  1. 1.Key Laboratory of Road Construction Technology and Equipment,Ministry of Education,Chang'an University,Xi'an 710064,China
    2.Fujian Tietuo Machinery Co. Ltd. ,Quanzhou 362000,China
    3.Research and Development Center of Transport Industry of Technologies for Materials and Equipments of Highway Construction and Maintenance,Gansu Road& Bridge Construction Group Co. ,Ltd. ,Lanzhou 730030,China
  • Received:2021-12-07 Online:2023-10-01 Published:2023-12-13
  • Contact: Hong-hai LIU E-mail:1414276521@qq.com;liuhonghai@chd.edu.cn

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Abstract:

In order to strictly control the grading accuracy of the continuous mixing equipment supply system, an online aggregate grading detection method based on image processing has been developed. By setting up an aggregate particle collection platform at the belt of the cold storage bin, part of the aggregate is sampled during the fall of the aggregate and the gradation situation at this time is analyzed. A watershed + Harris method is used to divide it and combine the results of 200 pictures to obtain the final synthetic gradation of the asphalt mixture. When the proportion of aggregate sampling is basically the same, the optimal sampling distance that the dividing plate should be adjusted to under different belt speeds is obtained by using EDEM software simulation. By comparing the results of the screening test and the image detection method,the correlation coefficient between the image method and the screening method detection result reached 0.998,which has a good detection effect.

Key words: road engineering, continuous mixing plant, image processing, aggregate grading, EDEM simulation

CLC Number: 

  • U416.2

Fig.1

State of aggregate on belt"

Fig.2

Process of aggregate falling"

Fig.3

Aggregate image acquisition platform"

Fig.4

Image processing flow"

Fig.5

11~17 mm grain image processing process"

Fig.6

Introduced aggregate conveying and dispersing device"

Fig.7

Scattered grid cells"

Fig.8

Number of particles in the grid unit and relationship between belt speed, distance of distributor plate and sampling ratio"

Table 1

Relationship between belt speed and distance of distributor plate for the same sampling ratio"

序号速度/(m?s-1分料板距离/m取样占比/%
11.00.1125.01
21.20.1224.44
31.40.1325.44
41.60.1426.02

Fig.9

Aggregate particle collection"

Fig.10

AC-13 different grades of aggregate test results"

Fig.11

AC-13 synthetic gradation sieving value and detection value"

Fig.12

SMA-16 different grade aggregate test results"

Fig.13

SMA-16 synthetic gradation sieving value anddetection value"

Table 2

AC-13 different grades of aggregate screening and detection gradation"

筛孔尺寸/mm4~7 mm筛分级配/%4~7 mm检测级配/%7~11 mm筛分级配/%7~11 mm检测级配/%11~17 mm筛分级配/%11~17 mm检测级配/%Ig
16.01001001001001001000
13.210010010010099.081000.92
9.510010099.510047.8549.522.17
4.7599.7210066.9569.241.142.624.06
2.3636.8139.241.263.320.611.245.11
1.182.644.120.861.930.60.82.75

Table 3

AC-13 synthetic gradation detection value"

筛孔尺寸/mm筛分试验/%图像检测方法/%Ig
16.01001000
13.292.2894.92.62
9.574.66761.34
4.7551.1450.11.04
2.3632.02330.98
1.1823.4622.90.56

Table 4

SMA-16 different grades of aggregate screening and detection gradation"

筛孔尺寸/mm

7~11 mm

筛分级配/%

7~11 mm

检测级配/%

11~17 mm筛分级配/%11~17 mm检测级配/%Ig
16.01001001001000
13.210010098.8999.991.1
9.599.8110064.8467.012.36
4.7572.4874.93.974.573.02
2.361.873.240.761.231.84
1.181.212.620.511.011.91

Table 5

SMA-16 synthetic grade detection value"

筛孔尺寸/mm筛分试验/%图像检测方法/%Ig
16.01001000
13.279.8184.114.3
9.556.7154.52.21
4.7528.629.130.53
2.3621.8221.60.22
1.1817.3118.230.92
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