Refine your search
Collections
Co-Authors
A B C D E F G H I J K L M N O P Q R S T U V W X Y Z All
Ranghaswami, M. V.
- Conjunctive Use of Surface and Ground Water for Irrigation with Special Reference to Pap Basin, Tamil Nadu
Abstract Views :286 |
PDF Views:0
Authors
Affiliations
1 Department of Agricultural Engineering, Agricultural college, (A.N.G.R.A.U.), Mahanandi A. P., IN
2 Deparment of Soil and Water Conservation Engineering, Tamil Nadu Agricultural University, Coimbatore T.N., IN
3 Water Technology Centre, Tamil Nadu Agricultural University, Coimbatore T.N., IN
1 Department of Agricultural Engineering, Agricultural college, (A.N.G.R.A.U.), Mahanandi A. P., IN
2 Deparment of Soil and Water Conservation Engineering, Tamil Nadu Agricultural University, Coimbatore T.N., IN
3 Water Technology Centre, Tamil Nadu Agricultural University, Coimbatore T.N., IN
Source
International Journal of Agricultural Engineering, Vol 6, No 1 (2013), Pagination: 20–27Abstract
The concept of conjunctive use of water resources requires judicious planning and policy implementation to utilize the surface and groundwater resources. The concept of integrated hydro-systems management was recognized by the practioners' since early 1970's. Earlier, studies on conjunctive use mostly focused when situations such as water logging and salinization problems were caused by intensive irrigation in many canal commands. But shortages of surface water supplies also necessitated the development of groundwater in many canal commands. In such situation, groundwater can be used along with surface water supplies in a profitable way. The present study was carried out in Parambikulam- Aliyar - Palar basin, Coimbatore, Tamil Nadu, where the command area is divided into two zones which receive the canal supply once in alternate years. The water demand and available water resources in the study area were evaluated considering surface water and groundwater and rainfall. The aquifer response and recharge due to rainfall in the PAP basin were studied. The efficiency of canal water delivery system in 4(L) distributory and evaluation of the conjunctive use of available water resources and its optimal allocation with the objective of obtaining maximum net benefits in 4(L) distributory of the Pollachi canal were studied. This paper presents a simple economic- engineering optimization model to explore the possibilities of conjunctive use of surface and groundwater using linear programming, and to arrive at an optimal cropping pattern for optimal utilization of water for maximizing net benefits.Keywords
Linear Programming, Conjunctive Use, Surface And Groundwater Resources, Water Allocation, Cropping Pattern- Moisture Dynamics and Water Use Efficiency as Influenced by Different Methods and Levels of Irrigation for Vegetable Crop under Salt-affected Soils
Abstract Views :241 |
PDF Views:0
Authors
Affiliations
1 Department of Soil and Water Engineering, College of Agricultural Engineering, Raichur karnataka, IN
2 College of Agricultural Engineering, University of Agricultural Sciences, Raichur karnataka, IN
3 Department of Soil and Water Conservation Engineering, Agricultural Engineering College and Research Institute, (T.N.A.U.) Coimbatore T.N., IN
4 Department of Soil and Water Conservation Engineering, Agricultural Engineering College and Research Institute, (T.N.A.U.) Coimbatore T.N.
1 Department of Soil and Water Engineering, College of Agricultural Engineering, Raichur karnataka, IN
2 College of Agricultural Engineering, University of Agricultural Sciences, Raichur karnataka, IN
3 Department of Soil and Water Conservation Engineering, Agricultural Engineering College and Research Institute, (T.N.A.U.) Coimbatore T.N., IN
4 Department of Soil and Water Conservation Engineering, Agricultural Engineering College and Research Institute, (T.N.A.U.) Coimbatore T.N.
Source
International Journal of Agricultural Engineering, Vol 6, No 1 (2013), Pagination: 82–92Abstract
The study was conducted at the Agricultural Research Station, Gangavati, University of Agricultural Sciences, Gangavathi in northern Karnataka, India during Rabi/summer, 2007-08 and 2008-09 with beetischolar_main (Beta vulgaris) as the test crop. Under the drip irrigation, the soil moisture content was the highest and maintained almost steadily near the field capacity throughout the cropping period at all distances away from the dripper. The maximum moisture content near the dripper was reduced to the extent of 15 and 19 per cent at a distance of 60 cm away horizontally and vertically downwards, respectively, from the dripper during 2007-08 in case of drip irrigation at 0.6 ET in salinity level-I, against16 and 20 per cent during 2008-09. The soil moisture content at particular distance from the point of application increased with increase in depth of applied water and it decreased with distance from the point of application (R2= 0.83 to 0.92). The maximum water use efficiency of 6.74 and 6.23 kg m-3 was achieved in drip irrigation at 0.6 ET under salinity level-I and the lowest water use efficiency of 2.78 and 2.40 kg m-3 was recorded in drip irrigation at 1.4 ETin salinity level-III during 2007-08 and 2008-09, respectively. Among the surface irrigation levels, the highest water use efficiency of 4.25 kg m-3 at 1.0 ET and 3.32 kg m-3 in 0.8 ET was recorded in salinity level-I during 2007-08 and 2008-09, respectively.Keywords
Drip, Surface Irrigation, Irrigation, Vegetable, Beetischolar_main, Soil Salinity, Moisture Distribution, Water Use Efficiency- Irrigation Management Strategies for Cultivation of Beetischolar_main (beta Vulgaris) under Saline Vertisols
Abstract Views :205 |
PDF Views:0
Authors
Affiliations
1 Department of Soil and Water Engineering, College of Agricultural Engineering, University of Agricultural Sciences, Raichur karnataka, IN
2 College of Agricultural Engineering, University of Agricultural Sciences, Raichur karnataka, IN
3 Department of Soil and Water Conservation Engineering, Agricultural Engineering College and Research Institute, (T.N.A.U.) Coimbatore T.N., IN
1 Department of Soil and Water Engineering, College of Agricultural Engineering, University of Agricultural Sciences, Raichur karnataka, IN
2 College of Agricultural Engineering, University of Agricultural Sciences, Raichur karnataka, IN
3 Department of Soil and Water Conservation Engineering, Agricultural Engineering College and Research Institute, (T.N.A.U.) Coimbatore T.N., IN
Source
International Journal of Agricultural Engineering, Vol 6, No 1 (2013), Pagination: 201–207Abstract
The experiments were conducted with beetischolar_main (Beta vulgaris) as test crop in saline vertisols of Tungabhadra Project command area in Northern Karnataka, India during 2007-'08 and 2008-'09 in strip plot design with three soil salinity levels (Electrical conductivity, EC - 1.3, 2.7 and 4.3 dS m-1) in main plots and five drip irrigation levels (Evapotranspiration , ET- 0.6, 0.8, 1.0, 1.2 and 1.4 ) with three surface irrigation levels (0.8, 1.0 and 1.2 ET) in sub-plots adopting three replications. There was significant difference in tuber yield owing to different irrigation regimes by various levels of drip and surface irrigation methods. The highest tuber yield of 19.43 t ha-1 was recorded by drip irrigation at 1.2 ET followed by drip irrigation at 1.4 ET (18.28 t ha-1) as against the lowest tuber yield of 9.98 t ha-1 in surface irrigation scheduled at 0.8 ET during 2007-'08. Similarly, the highest tuber yield of 18.91 t ha-1 in drip irrigation at 1.2 ET and the least yield of 9.6 t ha-1 in the surface irrigation scheduled at 0.8 ET were registered during 2008-'09. The different levels of salinity had marked influence on tuber yield during both the years. Significantly the highest tuber yield of 18.23 t ha-1 and the lowest tuber yield of 11.0 t ha-1 were recorded, respectively in salinity levels- I and III during 2007-'08. Similarly, during 2008-'09 significantly the maximum tuber yield of 17.89 t ha-1 in salinity level-I and the least of 10.5 t ha-1 in salinity level-III were observed.Keywords
Irrigation, Drip, Surface Irrigation, Irrigation Levels, Salinity, Saline Soil, Beetischolar_main, Vegat- Nutrient Dynamics as Influenced by Different Levels of Drip and Surface Irrigation Methods in the Rhizosphere of Beetischolar_main Crop under Saline Vertisols
Abstract Views :353 |
PDF Views:0
Authors
Affiliations
1 Department of Agricultural Engineering, College of Agriculture, Hanumanamatti, Haveri (Karnataka), IN
2 Department of Soil and Water Conservation Engineering, Agricultural Engineering College and Research Institute (T.N.A.U.), Coimbatore (T.N.), IN
3 College of Agricultural Engineering, Raichur (Karnataka), IN
4 Krishi Vigyan Kendra, Chitradurga (Karnataka), IN
1 Department of Agricultural Engineering, College of Agriculture, Hanumanamatti, Haveri (Karnataka), IN
2 Department of Soil and Water Conservation Engineering, Agricultural Engineering College and Research Institute (T.N.A.U.), Coimbatore (T.N.), IN
3 College of Agricultural Engineering, Raichur (Karnataka), IN
4 Krishi Vigyan Kendra, Chitradurga (Karnataka), IN
Source
International Journal of Agricultural Engineering, Vol 7, No 2 (2014), Pagination: 299-306Abstract
A study was conducted at the Agricultural Research Station, Gangavati, in northern Karnataka, India during Rabi/summer, 2007-'08 and 2008-'09 with beetischolar_main (Beta vulgaris) as the test crop in saline vertisol. During both the year and irrespective of the soil salinity levels slightly higher nitrogen was observed at 15 cm away from the dripper point compared to either at the dripper point or distances beyond 15 cm from the dripper point. The magnitude of available nutrients decreased vertically with increase in soil depth. The drip irrigation scheduled at 1.2 ET resulted in the maximum tuber yields of 19.43 and 18.91 t ha-1 during 2007-'08 and 2008-'09, respectively. Among the salinity levels, the highest tuber yield of 18.23 and 17.89 t ha-1 were recorded in salinity level-I, respectively. Whereas among the surface irrigation levels, irrigation at 1.2 ET recorded the highest tuber yields of 12.2 and 11.84 t ha-1, respectively.Keywords
Drip, Surface Irrigation, Vegetable, Beetischolar_main, Soil Salinity, Potassium Distribution.References
- Ahlwaalia, M.S., Singh, Baldev and Gill, B.S. (1993). Drip irrigation system - its hydraulic performance and influence on tomato and cauliflower crops. J. Water Mgmt., 1(1): 6-9.
- Antony, E. and Singandhupe, R.B. (2004). Impact of drip and surface irrigation on growth, yield and WUE of capsicum. J. Agric. Water Mgmt., 65: 121–132.
- Aujla, M.S.,Thind, H.S. and Buttar, G.S. (2005). Cotton yield and water use efficiency at various levels of water and nitrogen through drip irrigation under two methods of planting. J. Agric. Water Mgmt., 71: 167–179.
- Cassel, Sharmasarkar F., Sharmasarkar, S., Miller, S.D., Vance, G.F. and Zhang, R (2001). Assessment of drip and flood irrigation on water and fertilizer use efficiencies for sugarbeets. J. Agric. Water Mgmt., 46: 241-251.
- Hartz, T.K., Johnstone, P.R., Francis, D.M. and Miyao, E.M. (2005). Processing tomato yield and fruit quality improved with potassium fertigation. J. Hort Sci., 40: 1862-1867.
- Rajak, Daleshwar, Manjunatha, M.V., Rajakumar, G.R., Hebbara, M. and Minhas, P.S. (2006). Comparative effects of drip irrigation and furrow irrigation on the yield and water productivity of cotton (Gossypium hirsutum L.) in saline and waterlogged vertisols. Agric. Water Mgmt., 83 : 30-36.
- Manjunatha, M.V., Rajkumar, G.R., Hebbara, M. and Ravishankar, G. (2004). Effect of drip and surface irrigation on yield and water production efficiency of Brinjal (Solanum melongena) in saline vetisols. Indian J. Agric. Sci., 74(11):583-587.
- Moolman, J.H. (1998). Effect of spatial variability on the estimation of the soluble salt content in a drip irrigated saline loam soil. Agric. Water Mgmt., 15(4) : 361-376.
- Ravi, B., Sujatha, S. and Balasimha, D. (2007). Impact of drip fertigation on productivity of arecanut (Areca catechu L.). Agric. Water Mgmt., 90: 101-111.
- Reddy, Mallikarjun, Ayyanagowdar, M.S., Nemichandrappa, M., Sirajuddin, Momin, Umarfarooque, Horaginamani, M. and Ravichandran, M. (2011). Influence of drip irrigation methods on growth and yield of onion at Raichur region. Indian J. Natural Sci., 8(2) : 580-587.
- Sharma, R.C., Singh, Ranbir, Singh, Y.P. and Singh, Gurubachan (2006). Sodic soils of shivrin experimental farm: Site characteristics, reclaimability and use potential for different land uses. Central Soil Salinity Research Institute Bulletin 1/2006, pp. 1-32, Karnal, India.
- Singh, A.K., Chakraborty, D., Mishra, P. and Singh, D.K. (2002). Nitrogen and potassium dynamics in fertigation systems.17th WCSS, 14-21 August 2002, Thailand.
- Siyal, A.A., Siyal, A.G. and Abro, Z.A. (2002). Salt-affected soils, their identification and reclamation. Pakistan J. Appl. Sci., 2(5): 537-540.
- Tiwari, K.N., Singh, Ajay and Mal, P.K. (2003). Effect of drip irrigation on yield of cabbage (Brassica oleracea L.var. capitata) under mulch and non-mulch conditions. Agric. Water Mgmt., 58:19- 28.
- Tognetti, R., Palladino, M., Minnocci, A., Delfine, S. and Alvino, A. (2003). The response of sugar beet to drip and low-pressure sprinkler irrigation in southern Italy. J. Agric. Water Mgmt., 60: 135-155.
- Tripathi, P.C., Sankar, V. and Lawande, K.E. (2010). Influence of micro-irrigation methods on growth, yield and storage of Rabi onion. Indian J. Hort., 67(1) : 61-65.