This research was conducted during three winter seasons (2015-2016), (2016-2017) and (2017-2018) at Ras Sudr Research Station, South of Sinai Governorate, this region suffers from the problems of increasing salinity in soil and irrigation water, in addition to the high level of ground water. Therefore, the cultivation on wide ridges (raised-bed soil) was used for good soil leaching by storing large quantities of irrigation water in these wide ridges and easy drainage it from both sides of the ridges to the adjacent furrows. The wide ridges are considered one of the methods of remedy the rise in ground water level by raising the agricultural soil to a higher level, which helps to move the roots of plants away from the ground water level and to drain the irrigation water through the ridges sides to the adjacent furrows, which does not cause an increase in the ground water level. Also, conservation tillage (no-tillage) reducing the effect of salinity. So that a prototype of combined machine was manufactured which consisted of two units, the first unit to build ridges with the possibility to change the both of width and height of ridges. The second unit to sow wheat seeds on the ridges. The research treatments consisted of two tillage systems (traditional tillage system (TT) and conservation tillage system (CT) i.e., no-tillage), three ridge widths (50cm, 70cm and 90cm) and four ridge heights (0cm, 20cm, 35cm and 50 cm) where, the treatment of (0cm) was indicated to control treatment (flat soil). Also, the effect of three agriculture seasons was studied. Some parameters were measured or estimated as the following; actual field capacity (AFC), field efficiency (FE)), energy requirements (ER), pulling force (PF), fuel consumption rate (FCR), bulk density (BD), average infiltration rate (AIR), soil salinity (SS), water stored in the effective root zone (WS), water consumptive use in root zone (WC), water application efficiency (WA), wheat grain yield (WGY), water productivity (WP) and specific cost of production (SC). When using (CT) system and the largest cross section area of the ridges (90cm width x 50cm height) with continued application of this system for three consecutive seasons achieved the highest values of: (AFC=0.39 ha/h), (FE=93%), (WS=5773 m3/ha), (WC=4834 m3/ha), (WA=89%), (WGY=8.7 Mg/ha) and (WP=1.8 Mg/m3), in addition this treatment achieved the lowest values for both (SS=6.17 ds/m) and (SC=216 L.E/Mg) compared to the other treatments.
| Published in | International Journal of Applied Agricultural Sciences (Volume 7, Issue 1) |
| DOI | 10.11648/j.ijaas.20210701.12 |
| Page(s) | 16-37 |
| Creative Commons |
This is an Open Access article, distributed under the terms of the Creative Commons Attribution 4.0 International License (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted use, distribution and reproduction in any medium or format, provided the original work is properly cited. |
| Copyright |
Copyright © The Author(s), 2024. Published by Science Publishing Group |
Conservation Tillage, Irrigation Water Consumption, Raised-bed Soil, Wheat Crop, Wide Ridges
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APA Style
Adil Abd Elsamia Meselhy, Mohamed Fathy Abou Youssef, Ahmed El-Kot. (2021). Manufacturing of Machine for Planting on Wide Ridges Without Tillage in Desert Soils. International Journal of Applied Agricultural Sciences, 7(1), 16-37. https://doi.org/10.11648/j.ijaas.20210701.12
ACS Style
Adil Abd Elsamia Meselhy; Mohamed Fathy Abou Youssef; Ahmed El-Kot. Manufacturing of Machine for Planting on Wide Ridges Without Tillage in Desert Soils. Int. J. Appl. Agric. Sci. 2021, 7(1), 16-37. doi: 10.11648/j.ijaas.20210701.12
AMA Style
Adil Abd Elsamia Meselhy, Mohamed Fathy Abou Youssef, Ahmed El-Kot. Manufacturing of Machine for Planting on Wide Ridges Without Tillage in Desert Soils. Int J Appl Agric Sci. 2021;7(1):16-37. doi: 10.11648/j.ijaas.20210701.12
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Download@article{10.11648/j.ijaas.20210701.12,
author = {Adil Abd Elsamia Meselhy and Mohamed Fathy Abou Youssef and Ahmed El-Kot},
title = {Manufacturing of Machine for Planting on Wide Ridges Without Tillage in Desert Soils},
journal = {International Journal of Applied Agricultural Sciences},
volume = {7},
number = {1},
pages = {16-37},
doi = {10.11648/j.ijaas.20210701.12},
url = {https://doi.org/10.11648/j.ijaas.20210701.12},
eprint = {https://article.sciencepublishinggroup.com/pdf/10.11648.j.ijaas.20210701.12},
abstract = {This research was conducted during three winter seasons (2015-2016), (2016-2017) and (2017-2018) at Ras Sudr Research Station, South of Sinai Governorate, this region suffers from the problems of increasing salinity in soil and irrigation water, in addition to the high level of ground water. Therefore, the cultivation on wide ridges (raised-bed soil) was used for good soil leaching by storing large quantities of irrigation water in these wide ridges and easy drainage it from both sides of the ridges to the adjacent furrows. The wide ridges are considered one of the methods of remedy the rise in ground water level by raising the agricultural soil to a higher level, which helps to move the roots of plants away from the ground water level and to drain the irrigation water through the ridges sides to the adjacent furrows, which does not cause an increase in the ground water level. Also, conservation tillage (no-tillage) reducing the effect of salinity. So that a prototype of combined machine was manufactured which consisted of two units, the first unit to build ridges with the possibility to change the both of width and height of ridges. The second unit to sow wheat seeds on the ridges. The research treatments consisted of two tillage systems (traditional tillage system (TT) and conservation tillage system (CT) i.e., no-tillage), three ridge widths (50cm, 70cm and 90cm) and four ridge heights (0cm, 20cm, 35cm and 50 cm) where, the treatment of (0cm) was indicated to control treatment (flat soil). Also, the effect of three agriculture seasons was studied. Some parameters were measured or estimated as the following; actual field capacity (AFC), field efficiency (FE)), energy requirements (ER), pulling force (PF), fuel consumption rate (FCR), bulk density (BD), average infiltration rate (AIR), soil salinity (SS), water stored in the effective root zone (WS), water consumptive use in root zone (WC), water application efficiency (WA), wheat grain yield (WGY), water productivity (WP) and specific cost of production (SC). When using (CT) system and the largest cross section area of the ridges (90cm width x 50cm height) with continued application of this system for three consecutive seasons achieved the highest values of: (AFC=0.39 ha/h), (FE=93%), (WS=5773 m3/ha), (WC=4834 m3/ha), (WA=89%), (WGY=8.7 Mg/ha) and (WP=1.8 Mg/m3), in addition this treatment achieved the lowest values for both (SS=6.17 ds/m) and (SC=216 L.E/Mg) compared to the other treatments.},
year = {2021}
}
TY - JOUR T1 - Manufacturing of Machine for Planting on Wide Ridges Without Tillage in Desert Soils AU - Adil Abd Elsamia Meselhy AU - Mohamed Fathy Abou Youssef AU - Ahmed El-Kot Y1 - 2021/01/15 PY - 2021 N1 - https://doi.org/10.11648/j.ijaas.20210701.12 DO - 10.11648/j.ijaas.20210701.12 T2 - International Journal of Applied Agricultural Sciences JF - International Journal of Applied Agricultural Sciences JO - International Journal of Applied Agricultural Sciences SP - 16 EP - 37 PB - Science Publishing Group SN - 2469-7885 UR - https://doi.org/10.11648/j.ijaas.20210701.12 AB - This research was conducted during three winter seasons (2015-2016), (2016-2017) and (2017-2018) at Ras Sudr Research Station, South of Sinai Governorate, this region suffers from the problems of increasing salinity in soil and irrigation water, in addition to the high level of ground water. Therefore, the cultivation on wide ridges (raised-bed soil) was used for good soil leaching by storing large quantities of irrigation water in these wide ridges and easy drainage it from both sides of the ridges to the adjacent furrows. The wide ridges are considered one of the methods of remedy the rise in ground water level by raising the agricultural soil to a higher level, which helps to move the roots of plants away from the ground water level and to drain the irrigation water through the ridges sides to the adjacent furrows, which does not cause an increase in the ground water level. Also, conservation tillage (no-tillage) reducing the effect of salinity. So that a prototype of combined machine was manufactured which consisted of two units, the first unit to build ridges with the possibility to change the both of width and height of ridges. The second unit to sow wheat seeds on the ridges. The research treatments consisted of two tillage systems (traditional tillage system (TT) and conservation tillage system (CT) i.e., no-tillage), three ridge widths (50cm, 70cm and 90cm) and four ridge heights (0cm, 20cm, 35cm and 50 cm) where, the treatment of (0cm) was indicated to control treatment (flat soil). Also, the effect of three agriculture seasons was studied. Some parameters were measured or estimated as the following; actual field capacity (AFC), field efficiency (FE)), energy requirements (ER), pulling force (PF), fuel consumption rate (FCR), bulk density (BD), average infiltration rate (AIR), soil salinity (SS), water stored in the effective root zone (WS), water consumptive use in root zone (WC), water application efficiency (WA), wheat grain yield (WGY), water productivity (WP) and specific cost of production (SC). When using (CT) system and the largest cross section area of the ridges (90cm width x 50cm height) with continued application of this system for three consecutive seasons achieved the highest values of: (AFC=0.39 ha/h), (FE=93%), (WS=5773 m3/ha), (WC=4834 m3/ha), (WA=89%), (WGY=8.7 Mg/ha) and (WP=1.8 Mg/m3), in addition this treatment achieved the lowest values for both (SS=6.17 ds/m) and (SC=216 L.E/Mg) compared to the other treatments. VL - 7 IS - 1 ER -
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