Influence of Potassium on Growth, Yield, Water Relation and Chlorophyll Content of Greeengram [Vigna radiate (L.) Wilczek] in Inceptisols

Background: Mung bean (Vigna radiata L.) is an important edible bean in the human diet worldwide. However, its growth, development, and yield may be restricted or limited by insufficient or unbalanced nitrogen (N), phosphorus (P) and potassium (K) fertilization. Under intensive cropping systems, large amounts of K are removed, leading to serious depletion of soil K reserves. Therefore this study was conducted to generate the high yield and to improve yield components via effective and balanced fertilization.Methods: In this field experimentation during 2014-2016 different levels of potassium through soil application and foliar spray were studied. Three locations were selected on the basis dominance of the crops under rainfed condition.Result: In the present experimentation there was a significant effect of potash levels on plant height, number of pods per plant, 100-grain weight and grain yield. Significantly the highest grain yield (1120 kg ha-1) was recorded with 20 kg K2O ha-1, which was at par with 30 kg K2O ha-1. However, the grain yield with 20 kg K2O ha-1 was reported statistically equivalent yield with two foliar spray of muriate of potash (KCL) at flowering and pod filling stage. The pigments responsible for photosynthesis such as chlorophyll was favourably influenced by soil and foliar application of potassium. The K use efficiency parameters of AE, AR, ENUE and VCR were relatively high with potash application @ 20 kg ha-1 thereafter it declines. The positive balance of K is highly predominant in almost all the potassium applied plots which imply that the use of K fertilizers is optimal.

Phylogenetic analysis and In silico Screening of drug targets for ACE2 in Human and Spike Glycoprotein in Sars-CoV-2 for control of COVID19

Coronaviruses are the large group of infectious viruses that affect the respiratory tract and damages lungs. Large part to early Chinese efforts to genome sequencing of Sars-CoV-2, the virus that causes the Covid-19 disease, shared in early January 2020. The sequences from Wuhan seafood market pneumonia virus had different point mutations and are showing non-conserved patterns in between sequences from different regions of world. The present experimentation has shown that bioactive compounds like Nimbin present in Neem plant and Amlaic acid present in Amla are shown as best in the control COVID19. The bioactive compounds like Vitexin present in Bermuda grass and Curcumin present in turmeric powder were also shown good results. Hence usage of Neem, Amla, Bermuda grass and turmeric can boosts immunity and control COVID19. In anti-viral compounds, Remdesivir was found best and effective drug. Lopinavir also find effective drug next to Remdesivir. Hence in higher conditions, combination of remdesivir and lopinavir may be the best way of treatment for COVID19 patients. As antiviral compounds have side effects, Nimbin, Amlaic acid, Vitexin or Curcumin may be better molecules in the treatment of COVID19.

Performance Evaluation and Drying Kinetics for Solar Drying of Hygroscopic Crops in Vacuum Tube Assisted Hybrid Dryer

The present experimentation work discloses drying of hygroscopic crops under the new concept of solar-assisted greenhouse type dryer integrated with evacuated tube water heating system to control and maintain the temperature of the greenhouse environment according to the regulated flowrate of heated water in the drying trays. The dryer consists of an evacuated tube solar collector, flow regulating device and drying bed with provision for the flow of heated water. The power supply for forced circulation of solar-heated water inside the copper tube as well as the greenhouse environment air is maintained by solar photovoltaic (PV) modules. The dryer is tested for drying two hygroscopic crops namely coriander and fenugreek. The drying performance of the hybrid system is evaluated in terms of mass reduction and its derived influence on moisture content and drying rate. The derived parameters are compared with the corresponding evaluations under open sun drying. The rise in the greenhouse environment temperature and the crop surface temperature at hourly intervals as compared to the ambient condition were used as parameters for the thermal performance of the dryer. The drying curve for change in mass shows complete drying time for coriander and fenugreek reduced by 3.5 and 2.5 h, respectively, for present sample sizes. The most suitable mathematical model was also regressed using matlab followed by the development of a neural network for more precise prediction of moisture ratio (MR) for present hybrid drying.

Assessment of diesel engine characteristics fuelled by Jatropha with tamarind seed oil biodiesel

The present experimentation is carried out on a diesel engine using biodiesel as a fuel. The combination of lemongrass and tamarind seed methyl ester has replaced the diesel at various percentages. This investigation used three blends of biodiesels i.e. 10% of mixed methyl ester and 90% of pure diesel (B10) similarly B20, and B30. From the obtained results it was observed the enhanced brake thermal efficiency (BTE) for biodiesel blends as compared to the diesel. The blend B20 shows enhanced BTE than other samples, being around 20% higher than the diesel. The biodiesel blends show a reduction in HC and CO emissions and enhancement in CO2 and NOX emissions than the diesel. The highest heat release rate observed for B20 at a crank angle of 355° is 68.77 J/deg.

Evaluation of noise levels in areas and departments of the upper Technological Institute of Guasave

The present experimentation is the evaluation of noise levels in laboratories, classrooms and departments of a Higher Education Institution. Its objective is to identify and evaluate the working conditions to which workers and students are exposed when performing tasks. The study was conducted based on the official Mexican Standard NOM 011-STPS-2001 "Conditions of safety and hygiene in workplaces where noise is generated". Using a TES 1353S sound level meter for 4 weeks, evaluating 16 zones, in 2 periods. As a result, it was obtained that 6 of the 16 zones evaluated exceed the maximum permissible exposure limits. And recording discomfort and lack of concentration in the activities to be carried out on workers and students. As a recommendation, the implementation of periodic medical examinations and personal protective equipment for the personnel, in addition to the evaluation of noise levels in the preventive maintenance of the institution.to make the activities more comprehensive.

Concept and Mechanics of Fine Finishing Circular Internal Surfaces Using Deployable Magneto-Elastic Abrasive Tool

Fine finishing of cylindrical internal surfaces without affecting geometric form is a critical requirement in several mechanical and aerospace applications. Although various methodologies using flexible abrasive media are reported for the same, many of them demand complex tooling and fixtures to be developed in tune with the internal dimensions to feed the abrasive media. The present paper investigates the feasibility of using magneto-elastic abrasive balls with the aid of a mechanically deployable tool for microfinishing of geometrically symmetric tubular specimens. The deployable tool used for the present experimentation is designed like an umbrella mechanism, with magnetic pads to hold the elastic abrasive balls, expandable for bore diameter ranges from 45 to 75 mm. The magnetic type elastic abrasive balls proposed in the form of mesoscale balls of diameter 3.5 ± 0.25 mm are capable of finishing the bore surface without altering its roundness. Effects of elastomeric medium, mechanics of material removal and generation of finished profile during the proposed technique have been discussed in detail, through a comprehensive mathematical model. Effect of various process variables on surface roughness was investigated experimentally using response surface methodology and the theoretical predictions were validated at optimum operating condition. Sixty-two percent reduction in average roughness on brass tubes of initial roughness 0.168 μm, with significant improvement in all the associated two-dimensional roughness parameters and without any deviation on roundness, was clearly demonstrating the potential of proposed methodology.

Simulation of Heat Flux Between Two Parallel Metal Plates With Thermic Fluid as a Media

Most of the house hold needs are served by either the electricity or the LPG gas.[1] All fuel supply from fossil fuels seems to be limited and can generate an acute shortage in the coming future. Availability of power will be a vital problem, to be faced by future generations. Harnessing the power from solar rays seems to be the most reliable path towards sustainability of energy. The use of solar energy in the form of photovoltaic has captured a firm base in markets. However thermal energy extraction seems to be a neglected area, which has a huge potential. Hence the present paper deals with the study of extraction of such solar thermal energy using thermic fluids. With this aim, the author has initiated a study to extract the heat from solar concentrated power (CSP) systems. This system will heat the thermic fluid due to thermal energy in solar rays. This hot fluid is then passed through a guided passages formed between two plates and is used for heating top and bottom surfaces of two metallic plates. These hot surfaces then can be used as source of energy for home and industrial purposes. However in the present experimentation work, the scope of work is limited to thermal heat handling through the plate surfaces. Hence the supply of thermal energy from CSP is equivalently replaced by electric heater/ gas burners and is not discussed in details. Different flow passages are considered for result generation. Computational Fluid Dynamics (CFD) using FLUENT as tool in ANSYS 14.5 software is used for studying and comparing the results. Mathematical model is generated using preselected option of passage. Further Experimental validation is sorted in the end to verify the above results with temperature of upto 150°C. Selection of heat transfer fluid is based on sustainable higher operating temeperature. Pressure drop across the oil passage has indicated the inherent energy losses of the system. With the use of flow control valve and hydraulic pump the flow through the passage is regulated. Thus the energy flow can be controlled with respect to the requirement of process being carried out at each of the top and bottom surface respectively.

OPTIMIZATION OF SPEED PARAMETERS IN BURNISHING OF SAMPLES FABRICATED BY FUSED DEPOSITION MODELING

Fused Deposition Modeling (FDM) is one of the best Rapid Prototyping Processes proved to be. Many researchers have produced a lot of work using the FDM process and many papers were published. Many researchers have concentrated on optimizing the parameters to obtain higher surface finish. Burnishing is one of the processes used to get higher surface finish on light metals. The present paper deals with the application of burnishing process on the samples fabricated with FDM. The burnishing process is applied on the samples at different speeds and the surface finish results are recorded in the present experimentation.

Investigating the Effect of Vulcanization in Tread Rubber Applications

Retreading has many potential applications in tyre manufacturing industry. There is a critical need for optimization of vulcanization processes used in tread manufacturing. Not much work hitherto has been reported for optimization of efficient sulphur vulcanization process of the tread manufacturing. The present experimentation work highlights approach to macro-model strength, elongation and hardness during vulcanization of rubber. Relationship between strength, elongation, hardness and other parameter has been deduced by using Taguchi L9 orthogonal array (OA). Results indicate that the hardness, elongation and strength of tread rubber while vulcanization depends significantly on the natural: synthetic rubber ratio (NR: SR), curing time and curing temperature of the rubber.

Drag Reduction of Filaments and Poroelastic Bodies by Non-Linear Deformation

Because of their flexibility, trees and other plants deform with great amplitude (reconfigure) when subjected to fluid flow. Hence the drag they encounter does not grow with the square of the flow velocity as it would on a classical bluff body, but rather in a less pronounced way. The reconfiguration of actual plants has been studied abundantly in wind tunnels and hydraulic canals, and recently a theoretical understanding of reconfiguration has been brought by combining modelling and experimentation on simple systems such as filaments and flat plates. These simple systems have a significant difference with actual plants in the fact that they are not porous: fluid only flows around them, not through them. We present experimentation and modelling of the reconfiguration of a simple poroelastic system. Proper scaling of the drag and the fluid loading allows comparing the reconfiguration regimes of porous systems to those of simple systems. It is found that in the large reconfiguration regime, the scaling of the drag with flow velocity is independent of the porosity for a range of parameter values.