Conservation agriculture (CA) based production systems may help in achieving more sustainable intensification of cropping systems that use less labour and energy and have higher profit margins, in addition to soil conservation and environmental impact mitigation advantages. But these objectives can only be achieved when the right mechanization options, including appropriate crop establishment equipment, are in place to assist in timely field operations. An urgent need exists, therefore, to fine tune and re-adjust the existing two-wheel tractor (2WT) operated seed drills, with specific reference to the design of blade and furrow openers, while at the same time considering performance in different soil types and environments. To this end, experiments were conducted during 2013-2014 and 2014-2015 at two BARI Regional Agricultural Research Stations in Jamalpur and Barisal, Bangladesh, on a loam and clay loam soil, respectively, to evaluate five types of furrow opener for strip tillage. Shoe and modified shoe-type furrow openers were tested and compared with three inverted-T furrow openers with rake angles of 75°, 65° and 55°. The newly designed inverted-T furrow openers were narrower than the shoe-type openers; they also had a longer, hollow shanks and provided better options for adjustment to achieve the desired seeding depth and line spacing. Compared to shoe-type openers, better seeding depth, uniformity and higher degree of seed coverage were recorded with use of the inverted-T furrow opener with a 65° rake angle. This resulted in better seed coverage in the furrow, a higher emergence rate index, and the highest emergence percentage of maize and mung bean. Our research findings can be generalized to smallholder production systems on loam and clay loam soils where farmers utilize 2WT operated seed drills for crop establishment in both traditional and conservation agriculture-based planting systems.
Keywords: two-wheel tractor, strip tillage planter, inverted-T furrow opener, rake angle, conservation agriculture, emergence percentage
DOI: 10.25165/j.ijabe.20211403.5906

Citation: Hoque M A, Hossain M M, Ziauddin A T M, Krupnik T J, Gathala M K. Furrow design for improving crop establishment of two-wheel tractor operated strip tillage planters in loam and clay loam soils. Int J Agric & Biol Eng, 2021; 14(3): 130–139.

two-wheel tractor, strip tillage planter, inverted-T furrow opener, rake angle, conservation agriculture, emergence percentage

Mondal S M A, Biggs S D, Justice S E. Rural mechanization: A driver in agriculture change and rural development (eds). Institute for Inclusiveness Finance and Development, PKSF Bhawan, Agargoan-1207, Bangladesh, 2017. http://www.inm.org.bd.

Gurung T R, Kabir W, Bokhtiar S M (eds.). Mechanization for sustainable agricultural intensification in SAARC region. SAARC Agriculture Centre, Dhaka, Bangladesh, 2017; pp.302. http://www.sac.org.bd/archives/publications/Mechanization

Krupnik T J, Valle S S, McDonald A J, Justice S, Hossain I, Gathala M K. Made in Bangladesh: Scale-appropriate machinery for agriculture resource conservation. CIMMYT, Mexico, D.F. 2013; 126p.

Gathala M K, Laing A M, Tiwari T P, Timsina J, Islam S, Chowdhury A K, et al. Enabling smallholder farmers to increase productivity while achieving environmental and economic benefits: a meta-analysis of conservation agriculture-based sustainable intensification in the Eastern Gangetic Plains. Renewable and Sustainable Energy Reviews, 2020; 120: 109645.

Jat M L, Chakraborty D, Ladha J K, Rana S, Gathala M K, McDonald A, et al. Conservation agriculture for sustainable intensification in South Asia. Nature Sustainability, 2020; 3: 336–343. doi: 10.1038/s41893-020-0500-2.

Mondal R I, Begum F, Aziz A, Sharif S H. Crop sequences for increasing cropping intensity and productivity. SARC J. Agri., 2015; 13: 135–147.

Islam M A, Islam M J, Ali A M, Mahbubur R K A S M, Hossain M F, Moniruzzaman M. Transforming triple cropping system to four crops pattern: An approach of enhancing system productivity through intensifying land use system in Bangladesh. International Journal of Agronomy, 2018; 6: 7149835. doi: 10.1155/2018/7149835

Matin M A, Hossain M I, Gathala M K, Timsina J, Krupnik T J. Optimal design and setting of rotary strip-tiller blades to intensify dry season cropping in Asian wet clay soil conditions. Soil & Tillage Research, 2020. doi: 10.1016/j.still.2020.104854

Hoque M A, Miah M S. Evaluation of different tillage methods to assess BARI inclined plate planter. Agric Eng Int: CIGR Journal, 2015; 17(3): 128–137.

Hossain M I, Sarker M J U, Hoque M A. Status of conservation agriculture based tillage technology for crop production in Bangladesh. Bangladesh J. Agril. Res., 2015; 40(2): 235–248.

Licht M A, Al-Kaisi M. Strip-tillage effect on seedbed soil temperature and other soil physical properties. Soil and Till. Res., 2005; 80:233–249.

Hossain M I, Hossain I, Mamun M A A, Siddiquie N A, Rahman M M, Rahman M S. Two-wheel tractor operated strip tillage seeding equipment for dry land farming. International Journal of Energy Machinery, 2012; 5: 35–41.

Chaudhuri D. Performance evaluation of various types of furrow openers on seed drills-a review. J. Agric. Engng Res, 2001; 79(2): 125–137.

Zhang X C, Li H W, Du R C, Ma S C, He J, Wang Q J, et al. Effects of key design parameters of tine furrow opener on soil seedbed properties. Int J Agric & Biol Eng, 2016; 9(3): 67–80.

Altikat S, Celik A. The effects of tillage and intra-row compaction on seedbed properties and red lentil emergence under dry land conditions. Soil and Tillage Research, 2011; 114: 1–8.

Gregg E S, Colton J, Matin Md A, Krupink T J. Efficient and participatory design of scale-appropriate agricultural machinery workshops in developing countries: A case study in Bangladesh. Development Engineering, 2020; 5: 100046. doi: 10.1016/j.deveng. 2019.100046

Loon J V, Woltering L, Krupnik T J, Baudron F, Boa M, Govaerts, B. Scaling agricultural mechanization services in smallholder farming systems: Case studies from sub-Saharan Africa, South Asia, and Latin America. Agricultural Systems, 2020; 180: 102792. doi: 10.1016/ j.agsy.2020.102792

Deepak C. Performance evaluation of various types of furrow openers on seed drills: a review. Journal of agricultural engineering research, 2001; 79(2): 125–137.

Altuntas E, Ozgoz E, Taser O F, Tekelioglu O. Assessment of different types of furrow openers using a full automatic planter. Asian Journal of Plant Sciences, 2006; 5(3): 537–542.

Choudhary M A, Yu G P, Baker C J. Seed placement effects on seedling establishment in direct drilled fields. Soil and Tillage Research, 1985; 6(1): 79–83.

Choudhary M A. A new multicrop inverted-T seeder for upland crop establishment. AMA, 1988; 19(3): 37–42.

Sawant C, Kumar A, Mani I, Singh J K. Soil bin studies on the selection of furrow opener for conservation agriculture. Journal of Soil & Water Conservation, 2016; 15(2): 107–112.

Verma A K, Dewangan M L, Singh V V, Das V. Mechanical consideration for design and development of furrow openers for seed cum fertilizer drill. Agricultural Mechanization in Asia, Africa, and Latin America, 2007; 38: 74–78.

Altikat S, Celik A. Effects of different no-till seeders and tractor forward speeds on the soil physical properties and seed emergence of summer vetch and winter wheat. Tarim Bilimleri Dergisi – Journal of Agricultural

Sciences, 2012; 18: 21–30.

FAO. Manual on integrated soil management and conservation practices, FAO Land and Water Bulletin 8, Rome, Italy, 2000.

Baker C J, Saxton K E, Ritchie W R, Chamen W C T, Reicosk D C, Ribeiro W R, et al. No-tillage seeding in conservation agriculture, 2nd ed, FAO, CABI, Rome: Oxford shire, 2007.

Jat M L, Singla K, Kamboj B R, Sidhu H S, Manpreet S, Bana A, et al. Operational manual for Turbo Happy seeder-Technology for managing crop residues with environmental stewardship. International Maize and Wheat Improvement Center (CIMMYT), Indian Council of Agricultural Research (ICAR), New Delhi, India, 2013; 28p.

Solhjou A, Fielke J M, Desbiolles J M A. Soil translocation by narrow openers with various rake angles. Biosystems Engineering, 2012; 30: 1–9.

Afzalinia S, Khosravani A, Javadi A, Mohammadi D, Alavimanesh M S. Effect of tillage and planting methods on the soil properties, grain drill performance, and wheat yield. Journal of Agricultural Science and Technology, 2012; 21(5): 537–543.

Senapati P C, Mohapatra P K, Dikshit U N. Field evaluation of seeding devices for finger-millet. Agricultural Mechanization in Asia, Africa, and Latin America, 1992; 23(3): 21–24.

Bilbro J D, Wanjura D F. Soil crusts and cotton emergence relationships. Transactions of the ASAE, 1982; 25: 1484–1487.

Morris N L, Millerr P C H, Orson J H, Froud-Williams R. Soil disturbed using a strip tillage implement on a range of soil types and effects on sugar beet establishment. Soil Use and Management, 2007; 23: 428–436.

Karayel D, Ozmerzi A. Comparison of vertical and lateral seed distribution of furrow openers using a new criterion. Soil & Tillage Research, 2007; 95: 69–75

Desbiolles J, Rainbow R. Targeting the right seed environment in dry conditions, Mallee Sustainable Farming Inc. Waikerie Field Day booklet, 2002; 20: 15–20.

BARI. BARI technology hand book, Bangladesh Agricultural Research Institute, Gazipur, 2016.

Ozmerzi A, Karayel D, Topakci M. Effect of sowing depth on precision seeder uniformity. Biosystems Engineering, 2002; 82(2): 227–230.

Rosa U A, Wulfsohn D. Soil bin monorail for high-speed testing of narrow tillage tools. Biosystems Engineering, 2008; 99: 444–454.

Stout B A, Buchele W F, Snyder F W. Effects of soil compaction on seedling emergence in simulated field conditions. Agric. Eng., 1961; 42(87): 68–71.

Tessier S, Saxton K E, Papendick R I, Hyde G M. Zero-tillage furrow opener effects on seed environment and wheat emergence. Soil and Tillage Research, 1991; 21: 347–360.

Siddique K H M, Johansen C, Turner N C, Jeuffroy M, Hashem A, Sarkar D, et al. Innovations in agronomy for food legumes - a Review. Agronomy for Sustainable Development, 2012; 32: 45–64.

Karayel D, Šarauskis E. Effect of down force on the performance of no-till disc furrow openers for clay-loam and loamy soils. Agricultural Engineering Research papers, 2011; 43(3): 16–24.

Temesgen M, Rockstrom J, Savenije H H G, Hoogmoed W B. Assessment of strip tillage systems for maize production in semi-arid Ethiopia: effects on grain yield and water balance. Hydrol. Earth Syst. Sci. Discuss., 2007; 4: 2229–2271.

Du B, Bekele A, Morrison J J E. Drill furrow opener effects on wheat and sorghum establishment in no-till fields. Applied Engineering in Agriculture. American Society of Agricultural Engineers, 2004; 20(2): 179–185.

Altikat S, Celik A, Gozubuyuk Z. Effects of various no-till seeders and stubble conditions on sowing performance and seed emergence of common vetch. Soil & Tillage Research, 2013; 126: 72–77.

Amin M A. Govt takes Tk3, 198 crore farm mechanization project to support farmers. 2020. https://www.dhakatribune.com/business/ economy/2020/06/11/govt-takes-tk3-198-crore-farm-echanization-project- to-support-farmers

NAMP. National Agricultural Mechanization Policy. Ministry of Agriculture. Government of Peoples Republic of Bangladesh, 2020