Apples are still manually harvested by workers using ladders and buckets. Though it is known that manual apple harvest would probably lead to occupational injuries (e.g., back, neck, and shoulder strains), there has been little research that focuses on identifying the awkward activities/postures of pickers during the harvest process. After categorizing apple harvest work into 12 activities, this study used the method of Rapid Upper Limb Assessment (RULA) to identify awkward postures/activities that occurred during apple harvest. Awkward activities confirmed include descending a ladder, dumping apples, picking high and low apples on a ladder as well as on the ground, and moving a ladder, with potential reasons for each awkward activity provided. Meanwhile, it was demonstrated that pickers spent approximately 64% of working time under awkward postures that would lead to occupational diseases. In addition, this study analyzed picker harvest efficiency in terms of general and detail manners. The general mode assessed harvest activity in terms of picking and non-picking, with results showing that pickers averagely spent 76% (±7%) of harvest time in picking apples. Further analysis evaluated picking activities in terms of reaching, detaching, and transporting apples, with results showing that pickers spent averagely 30% (±6%) of time in detaching apples, which is the value time during apple harvest. Furthermore, valuable picking time ratio was obtained as the multiplication of picking time ratio and detaching time ratio. With a valuable ratio of 22% (±5%), it theoretically demonstrated the low harvest efficiency of the traditional harvest method. Since a majority of the awkward activities and the low efficiency were because of the ladders/buckets, using a harvest-assist unit may be a potential solution. Additionally, more efforts should be spent on the development of innovative mechanism to replace worker in placing attached apples to the bucket. Once the time for transporting apples is eliminated, the time for reaching apples is also removed, indicating the harvest efficiency would be improved significantly.
Keywords: rapid upper limb assessment, awkward postures, apple harvest, safety, ergonomic analysis, harvest efficiency analysis
DOI: 10.25165/j.ijabe.20191202.4567

Citation: Zhang Z, Wang Y J, Zhang Z H, Li D P, Wu Z Z, Bai R, et al. Ergonomic and efficiency analysis of conventional apple harvest process. Int J Agric & Biol Eng, 2019; 12(2): 210–217.

rapid upper limb assessment, awkward postures, apple harvest, safety, ergonomic analysis, harvest efficiency analysis

Lu R, Zhang Z, Pothula A K. Innovative technology for apple harvest and in-field sorting. Fruit Qtly, 2017; 25(2): 11–14.

He L, Schupp J. Sensing and automation in pruning of apple trees: A Review. Agronomy, 2018; 8(10): 211.

Zhao D A, Lv J D, Ji W, Zhang Y, Chen Y. Design and control of an apple harvesting robot. Biosyst. Eng., 2011; 110(2): 112–122.

Shamshiri R, Ishak W, Ismail W. Nonlinear tracking control of a two link oil palm harvesting robot manipulator. Int J Agric & Biol Eng, 2012; 5(2): 1–11.

Baeten, J. Donne, K., Boedrij, S., Beckers, W., Claesen, E. Autonomous fruit picking machine: A robotic apple harvester. In Springer Tracts in Advanced Robotics, 2008; 42: 531–539.

Shamshiri R R, Weltzien C, Hameed I A, Yule I J, Grift T E, Balasundram Chowdhary G. Research and development in agricultural robotics: A perspective of digital farming. Int J Agric & Biol Eng, 2018; 11(4): 1–14.

Shamshiri R R, Hameed I A, Karkee M, Weltzien C. Robotic Harvesting of Fruiting Vegetables: A Simulation Approach in V-REP, ROS and MATLAB. In Automation in Agriculture-Securing Food Supplies for Future Generations. InTech, 2018.

Shamshiri R R, Hameed I A, Pitonakova L, Weltzien C, Balasundram S K, Yule I J, et al. Simulation software and virtual environments for acceleration of agricultural robotics: Features highlights and performance comparison. Int J Agric & Biol Eng, 2018; 11(4): 15–31.

Lehnert C, English A, McCool C, Tow A W, Perez T. Autonomous sweet pepper harvesting for protected cropping systems. IEEE Robot. Autom. Lett., 2017; 2(2): 872–879.

Qureshi W S, Payne A, Walsh K B, Linker R, Cohen O, Dailey M N. Machine vision for counting fruit on mango tree canopies. Precision Agriculture, 2017; 18(2): 224–244.

Mehta S S, Burks T F. Vision-based control of robotic manipulator for citrus harvesting. Comput. Electron. Agric., 2014; 102: 146–158.

Wang L L, Zhao B, Fan J W, Hu X A, Wei S, Li Y S, et al. Development of a tomato harvesting robot used in greenhouse. Int J Agric & Biol Eng, 2017; 10(4): 140–149.

Zhang Z, Heinemann P H, Liu J, Baugher T A, Schupp J R. The development of mechanical apple harvesting technology: A review. Transactions of the ASABE, 2016; 59(5): 1165–1180.

Pothula A, Zhang Z, Lu R. Design features and bruise evaluation of an apple harvest and infield presorting machine. Trans. ASABE, 2018; 61(3): 1135–1144.

Silwal A, Davidson J R, Karkee M, Mo C, Zhang Q, Lewis K. Design, integration, and field evaluation of a robotic apple harvester. Journal of Field Robotics, 2017; 34(6): 1140–1159.

Davidson J R, Silwal A, Hohimer C J, Karkee M, Mo C, Zhang Q. Proof-of-concept of a robotic apple harvester. IEEE/RSJ International Conference on Intelligent Robots and Systems (IROS), 2016; pp.634–639.

He L, Schupp J. Sensing and automation in pruning of apple trees: A review. Agronomy, 2018; 8(10): 211.

Zhang Z, Heinemann P, Liu J, Schupp J, Baugher T. Design, fabrication, and testing of a low-cost apple harvest-assist device. ASABE Paper No. 141839738. St. Joseph, MI: ASABE, 2014.

Zhang Z, Pothula A, Lu R. Development and preliminary evaluation of a new bin filler for apple harvesting and infield sorting machine. Trans. ASABE, 2017; 60(6): 1839–1849.

Zhang Z. Design, test, and improvement of a low-cost apple harvest-assist unit. PhD diss. State College, PA: Pennsylvania State University, Department of Agricultural and Biological Engineering, 2015.

Zhang Z, Heinemann P, Liu J, Schupp J, Baugher T. Brush mechanism for distributing apples in a low-cost apple harvest-assist unit. Appl. Eng. in Agric., 2017; 33(2): 195–201.

Feng J, Zeng L, He L. Apple fruit recognition algorithm based on multi-spectral dynamic image analysis. Sensors, 2019; 19(4): 949.

Zhang Z, Zhang Z, Wang X, Liu H, Wang Y, Wang W. Models for economic evaluation of multi-purpose apple harvest platform and software development. I Int J Agric & Biol Eng, 2019; 12(1): 74–83.

Earle-Richardson G, Jenkins P L, Fulmer S, Mason C, Burdick P, May J J. An ergonomic intervention to reduce back strain among apple harvest workers in New York State. Applied Ergonomics, 2005; 36, 327–334.

Fathallah F. A. Musculoskeletal disorders in labor-intensive agriculture. Applied ergonomics, 2010; 41(6): 738–743.

Sakakibara H, Miyao M, Kondo T, Yamad S. Overhead work and shoulder-neck pain in orchard farmers harvesting pears and apples. Ergonomics, 1995; 38(4): 700–706.

Bernard B. (1997). Musculoskeletal disorders and workplace factors: A critical review of epidemiologic evidence for work−related musculoskeletal disorders of the neck, upper extremity, and low back. Cincinnati, Ohio: National Institute for Occupational Safety and Health.

Proto A R, Zimbalatti G. Risk Assessment of Repetitive Movements in the Citrus Fruit Industry. Journal of Agricultural Safety and Health, 2010; 16(4): 219–228.

Earle-Richardson G, Fulmer S, Jenkins P, Mason C, Bresee C, May J. Ergonomic analysis of New York apple harvest work using a Posture-Activities-Tools-Handling (PATH) work sampling approach. Journal of Agricultural Safety and Health, 2004; 10(3): 163–176.

Fulmer S, Punnett L, Slingerland D T, Earle-Richardson G. Ergonomic exposures in apple harvesting: Preliminary observations. American Journal of Industrial Medicine Supplement, 2002; 2: 3–9.

Earle-Richardson G, Jenkins P L, Freivalds A, Burdick P, Park S, Lee C, et al. Laboratory evaluation of belt usage with apple buckets. American Journal of Industrial Medicine, 2006; 49: 23–29.

Earle-Richardson G, Jenkins P L, Strogzta D, Bell E M, May J J. Development and initial assessment of objective fatigue measures for apple harvest work. Applied Ergonomics, 2006; 37: 719–727.

Freivalds A, Park S, Lee C, Earle-Richardson G, Mason C, May J J. Effect of belt/bucket interface in apple harvesting. International Journal of Industrial Ergonomics, 2006; 36(11): 1005–1010.

McAtamney L, Corlett E N. RULA : a survey method for the investigation of work-related upper limb disorders. Applied Ergonomics, 1993; 24(2): 91–99.

Dockrell S, O’Grady E, Bennett K, Mullarkey C, Mc Connell R, Ruddy R, Flannery C. An investigation of the reliability of Rapid Upper Limb Assessment (RULA) as a method of assessment of children’s computing posture. Applied Ergonomics, 2012; 43: 632–636.

Chen J D, Falkmer T, Parsons R, Buzzard J, Ciccarelli M. Impact of experience when using the Rapid Upper Limb Assessment to assess postural risk in children using information and communication technologies. Applied Ergonomics, 2014; 45(3): 398–405.

Rahman C M. Study and analysis of work postures of workers working in a ceramic industry through rapid upper limb assessment (RULA). International Journal of Engineering, 2014; 5(3): 8269.

Garcia P P N S, Polli G S, Campos J A. Working postures of dental students: ergonomic analysis using the Ovako Working Analysis System and rapid upper limb assessment. Med Lav, 2013; 104(6): 440–447.

Zhang Z, Zhang Z H, Wang W, Liu H, Sun Z. The role of a new harvest platform in alleviation of apple workers’ occupational injuries during harvest. Journal of Agricultural Safety and Health, 2019; 25(1): 11–24.

Zhang Z, Pothula A K, Lu R. Economic analysis of a self-propelled apple harvest and in-field sorting machine for the apple industry. ASABE Paper No. 2456644. St. Joseph, MI: ASABE, 2016.

Zhang Z, Pothula A K, Lu R. Development of a new bin filler for apple harvesting and infield sorting with a review of existing technologies. ASABE Paper No. 1700662, St. Joseph, MI: ASABE, 2017.

Zhang Z, Luo Y, Robinson D. Reducing Food Poverty and Vulnerability

among the Rural Elderly with Chronic Diseases: The Role of the New Rural Pension Scheme in China. International journal of environmental research and public health, 2018; 15(6): 1253.

Zhang Z, Robinson D, Hite D. Racial Residential Segregation: Measuring Location Choice Attributes of Environmental Quality and Self-Segregation. Sustainability, 2018; 10(4): 1114.

Zhang Z, Pothula A, Lu R. Improvements and evaluation of an infield bin filler for apple bruising and distributions. Trans. ASABE, 2019; 62(2): 271–280.

Taylor F W. The principles of scientific management. Harper, 1914.

Gilbreth F B. Scientific management in the hospital. Modern Hospital, 1914; 3: 321–324.

Baumgart A, Neuhauser D. Frank and Lillian Gilbreth: Scientific management in the operating room. Quality and Safety in Health Care, 2009; 18(5): 413–415.

Hendrich A, Chow M P, Skierczynski B A, Lu Z. A 36-hospital time and motion study: how do medical-surgical nurses spend their time? The Permanente Journal, 2008; 12(3): 25.

Lan S, Wang X, Ma L. Optimization of assembly line based on work study. IE&EM'09. 16th International Conference on Industrial Engineering and Engineering Management, IEEE, 2009; pp.813–816.

Duran C, Cetindere A, Aksu Y E. Productivity improvement by work and time study technique for earth energy-glass manufacturing company. Procedia Economics and Finance, 2015; 26: 109–113.

Moktadir M A, Ahmed S, Zohra F T, Sultana R. Productivity improvement by work study technique: a case on leather products industry of Bangladesh. Ind. Eng. Manag., 2017; 6: 1–11.