In order to address the low soil breaking rate, poor soil covering performance, and low working efficiency of the existing 3MT-1.8 and PMT-75 grapevine burying machines, two types of improved burying machines, namely the 3MTLJ-1.8 and 3MTXP-1.8, were developed in consideration of the local Ningxia soil conditions. Field experimental results indicated that the soil breaking rate of the 3MTLJ-1.8 machine was 71.44%, and its soil sampling volume increased by approximately 30% compared to that of the 3MT-1.8 machine. It was verified that the self-developed 3MTLJ-1.8 machine can be used in the southern regions of Ningxia. Furthermore, the soil sampling volume of the 3MTXP-1.8 burying machine was 0.24 m3/m, and its soil breaking rate increased by more than 41.42% compared to the standard required volume. The 3MTXP-1.8 machine can be used in the northern areas of Ningxia, where the soil hardness is higher. The results can provide a reference for the development and popularization of grapevine burying machines in Ningxia.
Keywords: grapevine burying machine, improvement, soil sampling performance, soil covering performance, soil breaking rate
DOI: 10.25165/j.ijabe.20181102.2927

Citation: Yang S M, She H Y, Yang S C, Zhu X J, Chen Y, Li J H, et al. Design and experimental validation of improved grapevine burying machine. Int J Agric & Biol Eng, 2018; 11(2): 95–100.

grapevine burying machine, improvement, soil sampling performance, soil covering performance, soil breaking rate

Zhao R L, He W L. Situation and development measures of grape production mechanization in Ningxia. Chinese Agricultural Mechanization, 2012; 6: 15–18. (in Chinese)

Wisniewski M, Gusta L V. The biology of cold hardiness: Adaptive strategies. Environ Exp Bot, 2014; 106: 1–3.

Spayd S E. Wine-grape cold injury assessment in post-bud break period. HortScience, 2007; 42(4):795–796.

Bucur G M, Dejeu L. Research on frost injury of new Romanian grapevine cultivars in the winter 2014-2015. Agriculture and Agricultural Science Procedia, 2016; 10: 233–237.

Dami I E, Ennahli S, Zhang Y. Assessment of winter injury in grape cultivars and pruning strategies following a freezing stress event. American journal of enology and viticulture, 2012; 63(1): 106–111.

Molitor D, Caffarra A, Sinigoj P, Pertot I, Hoffmann L, Junk J. Late frost damage risk for viticulture under future climate conditions: a case study for the Luxembourgish winegrowing region. Australian Journal of Grape and Wine Research, 2014; 20(1): 160–168.

Frioni T, Green A, Emling J E, Zhuang S, Palliotti A, Sivilotti P, Sabbatini P. Impact of spring freeze on yield, vine performance and fruit quality of Vitis interspecific hybrid Marquette. Scientia Horticulturae, 2017; 219: 302–309.

Zabadal T J, Dami I E, Goffinet M C, Martinson T E. Winter injury to grapevines and methods of protection. Chien M L: Michigan State University Extension; 2007.

Hu Y G, Wu W Y, De Melo-Abreu J P, Shapland T M, Zhang H, Snyder R

L. Comparative experiments and effectiveness evaluation on vertical blowing fans (VBF) for frost protection. Int J Agric & Biol Eng, 2015; 8(5): 36–42.

Londo J P, Kovaleski A P. Characterization of wild North American grapevine cold hardiness using differential thermal analysis. American Journal of Enology and Viticulture, 2017; 68 (2): 203–212.

Ker K. Ontario’s experience with wind machines for winter injury protection of grapevines and tender fruit. In: Proc. of Inst. For Continental Climate Viticulture and Enology—Understanding and preventing freeze damage in vineyards, 2007; pp.75–78.

Zhang Y, Dami I. Improving freezing tolerance of ‘chambourcin’ grapevines with exogenous abscisic acid. Hortscience, 2012; 47(12): 1750–1757.

Loseke B A, Read P E, Blankenship E E. Preventing spring freeze injury on grapevines using multiple applications of Amigo Oil and naphthaleneacetic acid. Scientia Horticulturae, 2015; 193: 294–300.

Li T, Kang J, Zhao W Y, Sun W, Zhang F W, Zhang J L, et al. Design of a new grape vine overwintering burying machine. Acta Agriculturae Boreali-Occidentalis Sinica, 2013; 22(8): 151–156.

Li T, Kang J, Wu J M, Sun W, Lv X M. The present situation of grape vine burying machine and the development of related mechanization technology in China. Journal of Agricultural Mechanization Research, 2013; 10(10): 218–221. (in Chinese)

Liu Z J, Yang X J, Liu L J, Jia Z H, Zhang T. Grape vine winter buried soil machine design. Journal of Agricultural Mechanization Research, 2012; 2(2): 113–115. (in Chinese)

Evans R G. The art of protecting grapevines from low temperature injury. Proc. ASEV 50th Anniversary Annual Mtg., Seattle WA, 2000; pp.60–72.

Spring P E B. Cold injury to winegrapes and protection strategies and methods. Hortscience, 2008; 43(6): 1652–1662.

Meng H W, Li J J, Kan Z. Development of PM-1200 suspended grape vine burying machine. Journal of Agricultural Mechanization Research, 2012; 6: 53–55. (in Chinese)

Lu H Y. The present situation and development of the technology of grape vines. Agricultural Machinery, 2013; (12): 174–175. (in Chinese)

Ning S C. Selection and operation technology of grape vine burying machine. China Agricultural Mechanization Herald, 2012; 5: 1–2. (in Chinese)

You J, Hu J, Guo H, Yang W Z. Development of a new type grape vine burying machine. Agricultural Engineering, 2014; 5(3): 100–103. (in

Chinese)

Zhao R L, Wang L, Tan Z B. Design and development of the grape vine burying machine. Journal of Agricultural Mechanization Research, 2012; 12(12): 115–119. (in Chinese)

Zhang H Q. Development of 3MT-5.0 grape vine burying machine. Agricultural Science & Technology and Equipment，2013; 11(11): 44–46. (in Chinese)

Zhang J, Li X B. 1MP-500 multi-function grape vine machine. Xinjiang Agricultural Mechanization, 2008; 1: 37. (in Chinese)

Liu Z G. Technology of grape vine burying machine. Agricultural Technology and Equipment, 2007; 8: 23. (in Chinese)

Pang J J, Ning S C, Li Y X. MT200-2 grape vine burying machine and operation technical key points. Xinjiang Agricultural Mechanization, 2006; 2: 70–71. (in Chinese)

You J, Guo H, Hu J, Yang W Z. Review of grape vine burying machine. Agricultural Engineering, 2013; 3(2): 8–10. (in Chinese)

Wang Z Q, Hao Z Q, Liu F Z. Grape overwintering machine development and trend of management machinery. Agricultural Technology and Equipment, 2014; 6B: 4–6. (in Chinese)

Pang J J, Gou H M, Ning S C. Grape mechanization buried rattan technology and its development in China. Sino-overseas Grapevine & Wine, 2008; 3: 32–33. (in Chinese)

Liu Z J. Design and research on grape vine machine. Beijing: Chinese Academy of Agricultural Mechanization Sciences, 2011; 7: 1–9. (in Chinese)

DB64/T 915-2013, Local standards and technical indicators of grape vine burying machine. Quality and Technical Supervision in Ningxia Hui Autonomous Region, 2013. (in Chinese)

Li T, Kang J, Sun W, Zhao W Y, Wang D, Zhang J L, et al. Design and test on a new grape vine over-winter burying machine. Agricultural Research in the Arid Areas, 2013; 31(4): 249–256. (in Chinese)

Shang S Q, Wang D W, Lu G Y. Current situation and development trend of grape mechanization production. China Agricultural Mechanization Herald, 2014; 5(7): 7–9. (in Chinese)

Sun P F. Design and performance research of the shovel and throw type grape vine burying machine. Agricultural University of Hebei, 2014. (in Chinese)

Ding W M. Agricultural Machines. Beijing: China Agriculture Press, 2011. (in Chinese)