Hostname: page-component-8448b6f56d-m8qmq Total loading time: 0 Render date: 2024-04-25T05:51:00.225Z Has data issue: false hasContentIssue false
  • English
  • Français

Tillage, seeding and fertilizer application technologies

Published online by Cambridge University Press:  30 October 2009

Dale E. Wilkins
Dale E. Wilkins
Affiliation:
Agricultural Engineer, USDA-Agricultural Research Service, Columbia Plateau Conservation Research Center, EO. Box 370, Pendleton, OR 97801.
Get access

Abstract

Tillage, seeding and fertilizing implements for rainfed cereal production with a winter precipitation pattern have unique functional requirements. In designing and developing implements for these systems, soil and water conservation principles are critical and must be integrated into the total production system. Plant diseases, insects, weeds, environmental degradation, crop yield, crop quality and economics all may be influenced by tillage, seeding and fe rtilizing implements. Advances have been made in implements f or improved residue management, stand establishment and crop fertilization that leave more crop residue on the surface for soil and water conservation. However, they alter the seed and root zones, often resulting in uncontrolled pests, reduced yields, or increased production costs. Research is needed to integrate production implements into ecosystem management through automatic control systems for improved tillage, se eding and fertilizing. These systems should include field history mapping, real-time soil sens ors, and models to link data bases with equipment functions.

Keywords

conservationplantingequipmentdiseaseerosioncrop residue
Type
Selected Papers from the U.S.-Middle East Conference on Sustainable Dryland Agriculture
Information
American Journal of Alternative Agriculture , Volume 11 , Issue 2-3 , September 1996 , pp. 83 - 88
Copyright
Copyright © Cambridge University Press 1996

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

1.Allmaras, R.R., and Dowdy, R. H.. 1985. Conservation tillage systems and their adoption in the United States. Soil and Tillage Research 5:197222.CrossRefGoogle Scholar
2.Allmaras, R.R., Gupta, S. C., Pikul, J. L. Jr., and Johnson, C. E.. 1979. Tillage and plant residue management for water erosion control on agricultural land in eastern Oregon. J. Soil and Water Conservation 34:785–90.Google Scholar
3.Amer. Soc. Agric. Engineers. 1989. Standard S477. Terminology for soil-en-gaging components for conservation-tillage planters, drills and seeders. In Hahn, R.H. and Rosentreter, E.E. (eds). ASAE Standards 1989. St. Joseph, Michigan, pp. 272277.Google Scholar
4.Babowicz, R.J., Hyde, G. H., and Simpson, J. B.. 1983. Fertilizer effects under simulated no-till conditions. Paper No. 83-1025. Amer. Soc. Agric. Engineers Microfiche Collection. St. Joseph, Michigan.Google Scholar
5.Baker, C.J., and Saxton, K. E.. 1988. The cross-slot conservation-tillage grain drill opener. Paper No. 88-1568. Amer. Soc. Agric. Engineers Microfiche Collection. St. Joseph, Michigan.Google Scholar
6.Baker, J.L., Colvin, T. S., Marley, S. J., and Dawelbeit, M.. 1989. A point-injector applicator to improve fertilizer management. Applied Engineering in Agric. 5:334338.CrossRefGoogle Scholar
7.Bolton, F.E., and Booster, D. E.. 1981. Strip-till planting dryland cereal production. Trans. Amer. Soc. Agric. Engineers 24:5962.CrossRefGoogle Scholar
8.Choi, C.H., and Erbach, D. C.. 1986. Cornstalk residue shearing by rolling coulters. Trans. Amer. Soc. Agric. Engineers 29:15301535.CrossRefGoogle Scholar
9.Cook, R.J., and Haglund, W. A.. 1991. Wheat yield depression associated with conservation tillage caused by root pathogens in the soil and not phytotoxins from the straw. Soil Biology and Biochemistry 23:11251132.CrossRefGoogle Scholar
10.Douglas, C.L. Jr., and Rickman, R. W.. 1992. Estimating crop residue decomposition from air temperature, initial nitrogen content, and residue placement. Soil Sci. Soc. Amer. J. 56:272278.CrossRefGoogle Scholar
11.Douglas, C.L. Jr., Rasmussen, E. E., and Allmaras, R. R.. 1989. Cutting height, yield level, and equipment modification effects on residue distribution by combines. Trans. Amer. Soc. Agric. Engineers 32:12581262.CrossRefGoogle Scholar
12.Douglas, C.L. Jr., Rickman, R. W., Klepper, B. L., and Zuzel, J. F.. 1992. Agroclimatic zones for dryland winter wheat producing areas of Idaho, Washington, and Oregon. Northwest Sci. 66(1):2634.Google Scholar
13.Erbach, D.E., Morrison, J. E., and Wilkins, D. E.. 1983. Equipment modification and innovation for conservation tillage. J. Soil and Water Conservation 38:182185.Google Scholar
14.Hammel, J.E., Papendick, R. J., and Campbell, O. S.. 1981. Fallow tillage effects on evaporation and seedzone water content in a dry summer climate. Soil Sci. Soc. Amer. J. 45:10161022.CrossRefGoogle Scholar
15.Hyde, G., Wilkins, D., Saxton, K. E., Hammel, J. E., Swanson, G., Hermanson, R., Dowding, E., Simpson, J., and Peterson, C.. 1987. Reduced tillage seeding equipment development. In Elliott, L. F., Cook, R.J., Molnau, M., Witters, R.E., and Young, D.L. (eds). STEEP—Conservation Concepts and Accomplishments. Washington State Univ., Pullman, pp. 4156.Google Scholar
16.Kenny, J.F. 1985. Infiltration enhancement in frozen soil by creation of surface-connected macroporosity. M.S. thesis. Dept. of Agric. Engineering, Washington State Univ., Pullman.Google Scholar
17.Koohestani, M., and Gregory, J. M.. 1985. Measurement of tillage parameters that affect residue cover. Paper No. 85-2045. Amer. Soc. Agric. Engineers Microfiche Collection. St. Joseph, Michigan.Google Scholar
18.Kraft, J.M., Wilkins, D. E., Ogg, A. G. Jr., Williams, L., and Willett, O. S.. 1991. Integrated pest management for green peas in the Blue Mountain Region. Pub. EB1599. Cooperative Extension, Washington State Univ., Pullman.Google Scholar
19.Mahler, R.L. 1985. The effect of soil moisture on the tolerance of wheat to different rates and sources of starter N fertilizer. In D. Hayes (ed). Proc. 36th Annual Northwest Fertilizer Conference., Salt Lake City, Utah, 16–17 July. Northwest Plant Food Assoc., Portland, Oregon, pp. 2331.Google Scholar
20.Mahler, R.L., Lutcher, L. K., and Everson, D. O.. 1989. Evaluation of factors affecting emergence of winter wheat planted with seed-banded nitrogen fertilizers. Soil Sci. Soc. Amer. J. 53:571575.CrossRefGoogle Scholar
21.McClellan, R.C. 1987. A comparison of soil seed zone moisture in conventional tilled fallow fields and chemical fallow fields in Whitman County. In Elliott, L.F., Cook, R.J., Molnau, M., Witters, R.E., and Young, D.L. (eds). STEEP—Conservation Concepts and Accomplishments. Washington State Univ., Pullman, pp. 607615.Google Scholar
22.McClellan, R.C., Nelson, T. L., and Sporcic, M. A.. 1987. Measurements of residue-to-grain ratio and relative amounts of straw, chaff, awns and grain yield of wheat and barley varieties common to Eastern Washington. In Elliott, L.F., Cook, R.J., Molnau, M., Witters, R.E., and Young, D.L. (eds). STEEP—Conservation Concepts and Accomplishments. Washington State Univ., Pullman, pp. 617624.Google Scholar
23.Miller, R.J., and Oldenstadt, D.. 1987. STEEP History and Objectives. In Elliott, L. F., Cook, R. J., Molnau, M., Witters, R. E., and Young, D. L. (eds). STEEP—Conservation Concepts and Accomplishments. Washington State Univ., Pullman, pp. 18.Google Scholar
24.Morrison, J.E. Jr., Allen, R. R., Wilkins, D. E., Powell, G. M., Glisso, R. D., Erbach, D. C., Herndon, L. P., Murray, D. L., Formanek, G. E., Pfost, D. L., Herron, M. M., and Baumert, D. J.. 1988. Conservation planter, drill and air-type seeder selection guideline. Applied Engineering in Agric. 4:300309.CrossRefGoogle Scholar
25.National Oceanic and Atmospheric Admin. 1991. Climatological Data Annual Summary, Oregon. Vol. 97 (13). Asheville, North Carolina.Google Scholar
26.Papendick, R.I., Young, D. L., McCool, O. K., and Krauss, H. A.. 1985a. Regional effects of soil erosion on crop productivity—the Palouse area of the Pacific Northwest. In Follett, R.E. and Stewart, B.A. (eds). Soil Erosion and Crop Productivity. Amer. Soc. Agronomy, Madison, Wisconsin, pp. 306319.Google Scholar
27.Papendick, R.I., Elliott, L. E., and Saxton, K. E.. 1985b. Paired rows push no-till grain yields up. Soil and Water Conservation 6(7):67. U.S. Dept. of Agric., Sou Conservation Service, Washington, D.C.Google Scholar
28.Payton, D.M., Hyde, G. M., and Simpson, J. B.. 1985. Equipment and methods for no-tillage wheat planting. Trans. Amer. Soc. Agric. Engineers 28:14191424, 1429.CrossRefGoogle Scholar
29.Peterson, C.L. 1991. A comparison of expert systems and simulation techniques for control of a fertilizer applicator. In Proc. 1991 Symposium, 16–17 December, Chicago, Illinois. Amer. Soc. Agric. Engineers, St. Joseph, Michigan, pp. 373378.Google Scholar
30.Peterson, C.L., Dowding, E. A., Hawley, K. N., and Harder, R. W.. 1983. The chisel-planter minimum tillage system. Trans. Amer. Soc. Agric. Engineers 26:378383, 388.CrossRefGoogle Scholar
31.Saxton, K.E., McCool, O. K., and Papendick, R. I.. 1981. Slot mulch for runoff and erosion control. J. Soil and Water Conservation 36:4447.Google Scholar
32.Smiley, R.W. 1992. Estimate of cultivated acres for agronomic zones in the Pacific Northwest. In 1992 Columbia Basin Agric. Research. Spec. Rep. 894. Oregon Agric. Exp. Sta., Corvallis. pp. 8687.Google Scholar
33.Smiley, R.W., and Wilkins, D. E.. 1993. Annual spring barley growth, yield and root rot in high- and low-residue tillage systems. J. Production Agric. 6:270275.CrossRefGoogle Scholar
34.Soil Conservation Service. 1988. Estimating surface residues after tillage. Agronomy Technical Note No. 22. U.S. Dept. of Agric., Portland, Oregon.Google Scholar
35.Tessier, S., Hyde, G. M., Papendick, R. I., and Saxton, K. E.. 1991. No-till seeders effects on seed zone properties and wheat emergence. Trans. Amer. Soc. Agric. Engineers 34:733739.CrossRefGoogle Scholar
36.Wilkins, D.E. 1988. Apparatus for placement of fertilizer below seed with minimum soil disturbance. U.S. Patent Number 4,765,263. Issued August 23.Google Scholar
37.Wilkins, D.E., and Haasch, H. A.. 1990. Performance of a deep furrow opener for placement of seed and fertilizer. In 1990 Columbia Basin Agric. Research. Spec. Rep. 860. Oregon Agric. Exp. Sta., Corvallis. pp. 5862.Google Scholar
38.Wilkins, D.E., and Kraft, J. M.. 1988. Managing crop residue and tillage pans for pea production. In Proc. 11th International Conference, International Soil Tillage Research Organization, Edinburgh, Scotland, July 1988. Bush Estate, Penicuik, Midlothian, Scotland, pp. 927930.Google Scholar
39.Wilkins, D.E., Muilenburg, G. A., Alunaras, R. R., and Johnson, C. E.. 1983. Grain-drill opener effects on wheat emergence. Trans. Amer. Soc. Agric. Engineers 26:651655, 660.CrossRefGoogle Scholar
40.Wilkins, D.E., Dowding, E. A., Hyde, G. M., Peterson, C. L., and Swanson, G. J.. 1987. Conservation tillage equipment for seeding. In Elliott, L.F., Cook, R.J., Molnau, M., Witters, R.E., and Young, D.L. (eds). STEEP—Conservation Concepts and Accomplishments. Washington State Univ., Pullman, pp. 571577.Google Scholar
41.Wilkins, D.E., Rasmussen, R. E., and Collins, H. C.. 1989. Straw to grain ratios of Stephens winter wheat. In 1989 Columbia Basin Agric. Research. Spec. Rep. 840. Oregon Agric. Exp. Sta., Corvallis. pp. 8086.Google Scholar
42.Wilkins, D.E., Bolton, F., and Saxton, K. 1992. Evaluating seeders for conservation tillage production of peas. Applied Engineering in Agric. 8:165170.CrossRefGoogle Scholar
43.Womac, A.R., and Tompkins, F. D.. 1990. Development of a probe-type liquid fertilizer injector. In Proc. Beltwide Cotton Prod. Research Conference. National Cotton Council of Amer., Memphis, Tennessee, pp. 125129.Google Scholar