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Kerala Agricultural University, Thrissur
The history of agricultural education in Kerala can be traced back to the year 1896 when a scheme was evolved in the erstwhile Travancore State to train a few young men in scientific agriculture at the Demonstration Farm, Karamana, Thiruvananthapuram, presently, the Cropping Systems Research Centre under Kerala Agricultural University. Agriculture was introduced as an optional subject in the middle school classes in the State in 1922 when an Agricultural Middle School was started at Aluva, Ernakulam District. The popularity and usefulness of this school led to the starting of similar institutions at Kottarakkara and Konni in 1928 and 1931 respectively.
Agriculture was later introduced as an optional subject for Intermediate Course in 1953. In 1955, the erstwhile Government of Travancore-Cochin started the Agricultural College and Research Institute at Vellayani, Thiruvananthapuram and the College of Veterinary and Animal Sciences at Mannuthy, Thrissur for imparting higher education in agricultural and veterinary sciences, respectively. These institutions were brought under the direct administrative control of the Department of Agriculture and the Department of Animal Husbandry, respectively. With the formation of Kerala State in 1956, these two colleges were affiliated to the University of Kerala. The post-graduate programmes leading to M.Sc. (Ag), M.V.Sc. and Ph.D. degrees were started in 1961, 1962 and 1965 respectively.
On the recommendation of the Second National Education Commission (1964-66) headed by Dr. D.S. Kothari, the then Chairman of the University Grants Commission, one Agricultural University in each State was established. The State Agricultural Universities (SAUs) were established in India as an integral part of the National Agricultural Research System to give the much needed impetus to Agriculture Education and Research in the Country. As a result the Kerala Agricultural University (KAU) was established on 24th February 1971 by virtue of the Act 33 of 1971 and started functioning on 1st February 1972. The Kerala Agricultural University is the 15th in the series of the SAUs.
In accordance with the provisions of KAU Act of 1971, the Agricultural College and Research Institute at Vellayani, and the College of Veterinary and Animal Sciences, Mannuthy, were brought under the Kerala Agricultural University. In addition, twenty one agricultural and animal husbandry research stations were also transferred to the KAU for taking up research and extension programmes on various crops, animals, birds, etc.
During 2011, Kerala Agricultural University was trifurcated into Kerala Veterinary and Animal Sciences University (KVASU), Kerala University of Fisheries and Ocean Studies (KUFOS) and Kerala Agricultural University (KAU).
Now the University has seven colleges (four Agriculture, one Agricultural Engineering, one Forestry, one Co-operation Banking & Management), six RARSs, seven KVKs, 15 Research Stations and 16 Research and Extension Units under the faculties of Agriculture, Agricultural Engineering and Forestry. In addition, one Academy on Climate Change Adaptation and one Institute of Agricultural Technology offering M.Sc. (Integrated) Climate Change Adaptation and Diploma in Agricultural Sciences respectively are also functioning in Kerala Agricultural University.
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ThesisItem Open Access Developing and testing of a collector-cum-storage types solar water heater for domestic use(Department of Farm Power Machinery and Energy, Kelappaji College of Agricultural Engineering and Technology, Tavanur, 2000) Bijukumar, K; KAU; Mohammad, C PThe present study was undertaken to desi~n and develop a collector-cum-storage type solar water heater of 30 litre capacity to supply hot water for domestic use. Five solar water heaters with different absorber plate positions were constructed. The storage tanks with dimensions of 67 xIl7 x 10 cm were made by using fibre glass, and the top of these storage tanks were covered using single plain glass plates of 71 x 51 x 0.4 cm size. The position of the absorber plate was varied by changing the width of the spacers (4 nos. at an angle of 400 with the side aluminium sheet), which connects bottom aluminium plate and top absorber plate. The absorber plate was of 65 x 45 cm size. The top face of the absorber plate was painted black to absorb maximum solar. radiation. The absorber plate positions were lcm, 3cm, 5cm, 7cm and 9cm from the top glass cover plate and were designated as SWHl 0, SWH30, SWH5.0, SWH7.0 and SWH9.0 respectively. The absorber plate position was optimized by testing the solar water heaters under two different test conditions. Solar water heater II (SWH3.0) outperforms other solar water heaters under the two test conditions. Maximum outlet temperature of 64°C af 3pm and maximum efficiency of 55.72% also at 3pm were observed in solar water heater 11. So it is optimized that the position of the absorber plate should be at 3cm from . the top glass plate. The solar warer heater can easily be handled by a single person since the weight is only 9.5kg. The operating cost per unit of thermal energy obtained withthe solar water heater was found to be 25 paise per kWh.ThesisItem Open Access Performance and ergonomic evaluation of direct pady seeder and mechanical rice transplanter in wet lands(Department of Farm Power Machinery and Energy, Kelappaji College of Agricultural Engineering and Technology, Tavanur, 2013) Rathod Sachin, Ravsu; KAU; Sureshkumar, P KAn experiment was conducted to evaluate the performance of the ‘Aiswarya’ 8 row direct seeder and ‘Mahindra PF455S’ 4 row walk behind mechanical transplanter with ‘Jyothi’ rice variety in wet lands from the ergonomic point of view. It conducted with selected male and female subjects in the age group of 25–35 years. The performance of these machines was compared with manual transplanting. The results show that the seed rate for direct seeder was very low with 37 kg ha-1 as compared to the mechanical transplanter (55 kg ha-1) and manual transplanting (72 kg ha-1). EFC found for direct seeder and mechanical transplanter was 0.11 ha h-1and 0.12 ha h-1 respectively. The field efficiency was found to be 69% for direct seeder and 74% for mechanical transplanter. Fuel consumption of the mechanical transplanter was found 3.7 l ha-1. The grain yield and straw yield in mechanical transplanting method was higher 2652 kg ha-1 and 3482 kg ha-1 as compared to 2265 kg ha-1 and 2885 kg ha-1 in the case of direct seeding. But in the case of manual transplanting, the yields were 2025 kg ha-1 and 2508 kg ha-1 respectively. The mean value of WHR and OCR with direct seeder was 145.5 beats min-1 and 0.95 l min-1 for male and 148.9 beats min-1 and 0.98 l min-1 for female. But in case of mechanical transplanter, the mean value of WHR and OCR was 131.6 beats min-1 and 0.80 l min-1 for male and 134.1 beats min-1 and 0.83 l min-1 for female. There was complete recovery of HR after 8 min with direct seeder and 6 min with mechanical transplanter. In case of direct seeder ODR, OSR, OER, BPDS values were given by male 6.5, 0, 6.0, 40.8 and by female 7.5, 0, 7.5, 45.6. The corresponding values for mechanical transplanter were 3.0, 1.5, 3.5, 36 by male and 3.5, 1.5, 5.0, 36. As per the grading of energy cost of work, direct seeder categorized as “very heavy type” and mechanical transplanter as “heavy type”. The 8 row direct seeder is not suitable for female subjects. A 4 row Mahindra walk behind mechanical transplanter could be used successfully not only to improve the yield but also to provide operator comfort as compared to the 8 row direct seeder.ThesisItem Open Access Simultation of the Effect of Land and Vegetation Management on Runoff and Sediment Yield From a Small Watershed- a case Study(Department of Land and Water Resources and Conservation Engineering, Kelappaji College of Agricultural Engineering and Technology,Thavanur, 2000) Vinod Kumar, P R; KAU; Xavier Jacob, KConservation of soil by sound measures forms one of the fundamental premises towards a sustained future. The management of land and vegetation has profound influence in conservation programme. To simulate the effect of land and vegetation management measures on runoff and sediment yield from a waterhed, a study was conducted at Development Unit – IX of Attapadi region, in Palghat district. The relationship between effective rainfall and sediment mobilized due to rain storm was established as; ES = 28.57 ER0.9385., where ES is the effective sediment mobilized in T/km2 and ER is the effective rainfall in cm. The Universal Soil Loss Equation (USLE) was applied on perstorm basis to estimate the soil erosion. The Modified – USLE (R) factor was used to represent the erosivity factor in the soil loss estimation. The topographic factor (LS) was computed using the USLE and Revised – USLE methods. This particular parameter computed with the USLE was more than that of the RUSLE. The amount of soil erosion predicted with the USLE were more than that of the RUSLE due to greater LS factor associated with the USLE method. However both methods provided an ‘r2’ value of 0.9724. The WEPP – model was applied to simulate the runoff and soil erosion processes during individual rainstorm events. The model provided reliable simulation of the erosion process, but the runoff values were under – predicted for all the simulated events. The hillslopes cultivated with tuber crops gave maximum erosion per unit area during the simulation. The reason could be assumed as the absence of sufficient ground and canopy cover in this areas, which possessed a loosened surface after harvesting. The lands left as barren after tree felling also had increased rates of erosion during the simulation, which could be due to the lack of vegetative protection. While the paddy field had lesser rates of erosion owing to the flatness of land and vegetation cover. The other areas yielded reduced rates of erosion due to good canopy cover as well as surface cover provided by closely growing vegetation.ThesisItem Open Access Development and evaluation of modified atmosphere packed passion fruit(Passiflora edulis)(Department of Post harvest technology and agricultural processingKelappaji College of Agricultural Engineering and Technology, Tavanur, 2012) Madhana Supriya, R; KAU; Sudheer, K PPassion fruit is a tropical fruit which is extensively used in juice processing. The fruit is highly perishable and losses its quality immediately after the second day of harvest. The postharvest loss in quality and commercial value is due to the intense respiratory activity and significant moisture loss. Hence a study was undertaken to develop a wax applicator to extend the shelf life of passion fruit by adopting the postharvest technologies. A simple and efficient wax applicator with a capacity of 250 kg.hr-1 was developed based on the physical properties of the fruits. Various samples of the passion fruits were treated with bee wax and commercial wax packed in LDPE bags of 200 and 400 gauge. The effect on the shelf life extension of fruits was investigated individually and in combination of wax and LDPE bags. In the case of LDPE bags, different levels of perforations such as 0%, 0.5%, 1% and 2% were used. The samples were kept in ambient condition viz., 32 - 35°C and 70 - 80% RH and at cold conditions as 7ºC and 90% RH. The physicochemical characteristics of samples were tested periodically at an interval of 5 and 7 days, under ambient and cold storage conditions, respectively. The results obtained were subjected to statistical analysis. From the results it was revealed that the samples kept in non-perforated polythene covers were found to be better than those kept in perforated bags and in normal atmosphere. A maximum shelf life of 40 days was obtained for passion fruits at 7oC coated with commercial wax emulsion. Thus, commercial wax coating in combination with LDPE bags acted as a barrier against moisture loss and respiration rate of fruits. However, the fruits kept as control had lost consumer acceptability after the tenth day of study at cold condition and within two days at ambient storage conditions.ThesisItem Open Access Development of a powered decoraticator for producing white pepper from black pepper(Department of Post Harvest Technology and Agricultural Processing, Kelappaji College Agricultural Engineering and Technology, Tavanur, 2007) Chithra, G; KAU; Santhi Mary, MathewA powered black pepper decorticator for producing white pepper from black pepper was developed, tested and its performance evaluated. The major parts are grinding surfaces, feed hopper, cylindrical collecting tray, water distribution assembly, 0.5 hp motor and reduction gear of 5:1 gear ratio. The decortication of the pepper berries was performed by compressive and shearing forces between the grinding surfaces. The experiment was conducted at different soaking time, speed and grinding surfaces. A 2- factor, experiment in Completely Randomized Design (CRD) with speed and soaking time as factors were adopted. The maximum decorticating efficiency observed for MS Plate, rexin sheet, teflon and grinding stone were 46.10, 51.30, 47.50 and 61.52 at 17 h -71 rpm, 17 h -71 rpm, 18 h -57 rpm and 17 h- 71 rpm soaking time - speed combinations. The wholeness of kernels show a decreasing trend at higher speeds that is crushing of berries increases. Generally, the mechanical damage also shows the similar trend. The maximum overall decorticating efficiency for various surfaces were 37.38 of 17 h -71 rpm, 38.99 17h- 71rpm, 35.63 of 18h- 57rpm and 51.06 of 17h -71rpm. The study shows that the parameters of speed and soaking time have significant influence on decorticating efficiency, wholeness of kernels, mechanical damage and overall decorticating efficiency. The quality of white pepper obtained from grinding stone coupled with polyurethane was superior to those obtained by other surfaces. The overall decorticating efficiency of powered decorticator was found maximum (51.06 %) at 71 rpm and 17 hour soaking period. The capacity of the developed machine was 1.23 kg/h.ThesisItem Open Access Performance evaluation of micro-irrigation devices(Department of Land and Water Resources and Conservation Engineering, Kelappaji College of Agricultural Engineering and Technology, Tavanur, 2003) Jacob Bijo, Daniel; KAU; Vishnu, BSeveral micro-irrigation emitters were evaluated for their individual performance and were compared among themselves on the basis of different performance parameters, and the results were used to analyse the credibility of the claim of the manufacturers. The emitters were tested for their quality of the workmanship, uniformity of flow rate and for their distribution performance. A total of thirty micro-sprinklers (ten models in three replications) were evaluated. The distribution performance of each of the devices was described by different performance parameters. The performance parameters used for this purpose were uniformity coefficient, coefficient of variation, distribution characteristic etc. The distribution patterns (densograms) were drawn and carefully studied to analyse the nature of distribution performance of the emitters. The values of the performance parameters were used to grade the devices using different statistical and ranking tools. It is generally concluded that only the manufacturer data should not be taken into consideration while selecting the irrigation devices and from the farmers’ point of view it is safer to depend more on the technical information resulting from scientific investigations.ThesisItem Open Access Development and evaluation of a cassava (Manihot esculenta) storage cum packaging system(Department of post harvest technology and agricultural processing, Kelappaji College of Agricultural Engineering and Technology, Tavanur, 2014) Chinthana, D T; KAU; George, MathewCassava (Manihot esculenta) has its origins in South America. This tuber root crop has become the staple food of the economically weaker sections of these countries as this can be grown in most of the adverse climatic and in fertile soil condition. In India the major production today is still from Kerala followed by Tamil Nadu and Andra Pradesh where it is gaining commercial importance for the production of Sago and Starch. The shelf life of this crop starts deteriorating immediately after harvesting and becomes unmarketable within 2-3 days. Hence, this study was undertaken to develop a more practical and affordable method to increase the shelf life of cassava by keeping in mind the economically weaker sections of society worldwide. The method chosen was to store the fresh cassava roots in boxes made up of locally available materials such as (wood, plastic, plywood) and filled with easily available cheap filler materials which are within the reach of the common man. To maintain moist condition of the filler materials small quantity of water was sprinkled daily. The filler materials selected ranged from different types of soils like sand , clay and laterite soil, cheap synthetic materials like sponge and plastic cuttings, and easily available organic materials like cassava leaves, coir, saw dust and wooden shavings. For the present study, the size of the box was developed to house around 6 Kgs of the roots along with filler materials. Two locally available popular varieties of Cassava viz. M4 and Muttechi were chosen for the study. First experiment was carried out with M4 variety with nine different filler materials as explained above stored in nine wooden boxes. Quality parameters were studied periodically in a range 5 days. It was found that cassava could be stored for 40 days using wooden shavings as filler material followed by sawdust and coconut fibre for 35day. The second experiment was the repetition of the same study with another variety commonly known as Muttechi variety in Kerala. Quality parameters were studied periodically in a range 5 – 7 days. It was found that cassava could be stored for 37 days using wooden shavings as filler material followed by sawdust (32days) and coconut fibre 27days. First two experiments revealed that synthetic filler materials like sponge, plastic etc were harmful to their survival. Organic materials like cassava leaves, Sand as a filler material was good in the initial stages but could not support for longer durations. The above two experiments were conducted using wooden boxes. In order to find the impact of material of construction of box on the storage duration of cassava, a third study was done choosing three materials (wooden box, plastic box and plywood boxes). Nine boxes were used for the study (3 each for the same material). The best three filler materials coconut fibre, saw dust and wooden shavings out of nine filler materials used in first and second experiments were used in the third experiment R.H 75% and temperature was 32ºC. Results of third experiment showed that the storage box played an important role more than that of the filler materials, as the roots stored in plywood box with best of the three filler materials could not survive for more than 15 days Comparing all the quality parameters it was observed that cassava roots stored in wooden box with wooden shavings as filler materials with routine replenishing of moisture by adding small quantity of water was best suited for extending the shelf life of the cassava roots up to 37 days during winter and the results could be less during summer with the extended shelf life of around 15 days. The economic analysis of the storage system was conducted and it was found for storing 1kg of cassava in the developed storage system with wooden shavings as a filler material including labour charges was Rs. 4.62/-. Hence, it can be concluded that this simple method of extending the shelf life of cassava roots by storing them in wooden boxes with wooden shavings as filler material with retention of moisture in the boxes by sprinkling small quantity of water daily is very economical, successful and easy for quick transportation.ThesisItem Open Access Soil erosion studies under simulated rainfall conditions in a lateritic terrain(Department of Land and Water Resources and Conservation Engineering, Kelappaji College of Agricultural Engineering and Technology, Tavanur, 2014) Praveena, K K; KAU; Kurien, E KSoil erosion IS a complex phenomenon involving the detachment and transport of soil particles, storage and runoff of rainwater and infiltration. Soil erosion depends on several factors such as climate, soil type, topography, cropping and land management practices, the antecedent conditions and the size of the area under consideration. The present study was carried out in the lateritic terrain of KCAET campus, Tavanur, Malappuram District. This study was aimed at developing a rainfall simulator and studying the performance of the developed rainfall simulator, the effect of rainfall on soil loss, the effect of rainfall on runoff and developing a soil erosion model. A rainfall simulator was fabricated to study the erosion processes. Rainbird 12115118 Van Pop up sprinkler heads were used as the drop formers. The simulator evaluated for its performance. The soil was reddish brown and belonged to the textural class of sandy loam. It belonged to the Naduvattom series. The experimental set up consisted of three units viz., the runoff plot, the rainfall simulator and the runoff-sediment collection unit. Twelve runoff plots with twelve different slopes of 1.5, 2.0, 2.6, 3.0, 3.2, 4.0, 5.0, 6.0, 9.0, 10, 12 and 13 per cent in different locations, each plot with a size of2 x 1.5 m were prepared. The fabricated rainfall simulator could produce rainfall intensities varying from 8.16 to 8.80 ern/h. The uniformity of rainfall varied from 89.01 to 92.70 per cent and the average drop size varied from 1.5 to 2.8 mm. A relationship between supply pressure and intensity of rainfall as well as intensity and uniformity of rainfall was developed. Studies were conducted on soil loss and runoff at different land slopes under simulated rainfall conditions. The soil loss and runoff was found to increase with increase in rainfall intensity and land slopes and there were no much variations on runoff and soil loss at 6 to 10 per cent land slopes. A linear multiple regression analysis and 3D surface plot analysis was used to incorporate slope and rainfall intensities into a single prediction equation of soil loss and runoff using SPSS software and MATLAB package. The linear equations developed by the regression analysis are as follows: Q = 38.9451 - 11.606 S - 126.391 E = 124.356 1 - 0.807 S -951.420 (R2 = 0.649) (R 2 = 0.307) The quadratic equations developed by the 3D surface plot analysis are as follows: Q = 130.8 - 28.72 S + 48.12 1 + 2.11 S2 - 1.544 S 1 E = - 647.4 - 49.261 + 86.94 S - 0.3206 12 +6.296 S I As the variants explained were satisfactory enough to explain the runoff and soil loss, it may be concluded that the causative factors namely slope and intensity are bearing directive impact on soil erosion. A canonical analysis was worked out to determine the effect on runoff and soil loss by the vector of parameters u ing slope and intensity. Canonical R was computed and the same was 0.82034 and it is significant at 1 per cent level. Hence it may be concluded that the vector of process 'including slope and intensity as parameters together navigates the ultimate impact namely runoff and soil loss.ThesisItem Open Access Development of a filter system for roof water harvesting(Department of Land and Water Resources and Conservation Engineering, Kelappaji College of Agricultural Engineering and Technology, Tavanur, 2014) Shijila, Erikottil; KAU; Sathian, K KThis thesis work was undertaken to study the performance of modified mesh filter under rainfall. The mesh filter was modified with two other filters such as sand and charcoal filter and their combination study was conducted on artificial rainwater and evaluated the quality of filtered water. The two filters are fabricated with naturally available material such as above 1 mm size coarse sand and small pieces of burned coconut shell. These materials are freely available from surroundings and each material was filled in each PVC pipes of 25 cm length. From the first study four buildings are selected in the campus have different impurity levels that because of rain fall events, purposes or constructed material. It was found that there are small variations in the quality of harvested water but after filtration all results are same because filter was not depends on the roofing material and impurity level. The quality parameter like pH of the rainwater harvested after the filtration with mesh filter for all roofs met the USEPA secondary drinking water standard range of 6.5-8.5. The electrical conductivity, turbidity and suspended solids are also met the drinking water standards by WHO and the calculated average filter efficiency of mesh filter was 81.3 %. From the filter combination study the quality parameter such as pH, electrical conductivity, turbidity and suspended .,olids also examined through water quality analyzer of collected samples. As per the BIS 10500 of 2004 and WHO all the results are in the permissible range. The BOD test result was ranging from 44 to 92 mg/l and compared to inflow the filtered water has drastic reduction in the values. From the coliform test it was cleared that there were no colifirms (011 OOml) in the filtered water after 24 hour incubation period where as in inflow water coliforms were detected. It was found that there is a marked reductio'. .n the concentration of impurities, The reduction in im urities ranges from 84 to 86 % and the charcoal tilter has highest filtration rate of 9.42 m3/minlm2 compared to others. The results clearly. revealed that combined filters remove the impurities in a more efficient manner than of the mesh filter developed earlier. There is only minor difference between the both filters. The results clearly revealed that combined filters remove the impurities in a mo: e efficient manner than of the mesh filter developed earler. There is only minor difference between the both filters.
