Your search keyword '"Manavalla, Sreekanth"' showing total 12 results

1. Exergetic investigation of the influence of injector location in HCCI engines utilizing DEE as pilot fuel and biogas as primary fuel

Author

Aditya Sai Samavedam, Prasshanth C.V., Manavalla Sreekanth, T.M. Yunus Khan, Naif Almakayeel, and Feroskhan M

Subjects

Homogeneous charge compression ignition engine (HCCI engine), Biogas, Diethyl ether, Pilot fuel, Injector location, Science (General), Q1-390, Social sciences (General), H1-99

Abstract

To address the global demand for sustainable energy, integrating biogas into internal combustion engines is becoming more important. Homogeneous Charge Compression Ignition (HCCI) engines, known for high efficiency and low emissions, offer a promising solution. This study investigates the optimal injector location for using biogas in HCCI engines, with diethyl ether (DEE) as the pilot fuel, evaluating three positions: (i) at the port, (ii) 6 cm away (Manifold 1), and (iii) 10 cm away (Manifold 2). Through experiments and simulations, the impact of injector location on engine performance is analyzed across various parameters, including methane fractions, engine loads, and exhaust gas compositions. Results show that port injection achieves the highest first law and exergy efficiencies but increases emissions of hydrocarbons (HC), carbon monoxide (CO), and smoke. At 15 Nm load, Manifold 1 shows a 27.34 % reduction in exergy efficiency compared to port injection, while Manifold 2 exhibits an 18.49 % decrease at higher loads. Despite lower efficiencies, Manifold 1 effectively reduces harmful emissions. The study also considers exergo-economic and sustainability aspects, highlighting that while port injection is optimal for efficiency, Manifold 1 excels in minimizing HC and CO emissions, with a 50 % reduction in HC and 71.43 % reduction in CO emissions at 15 Nm load compared to port injection. Manifold 2 achieves the lowest smoke emissions across all loads. This investigation provides crucial insights into optimizing HCCI engines for biogas utilization, emphasizing injector location, fuel composition, and operating parameters to enhance performance and reduce environmental impact.

Published

2024

2. Performance and emission characteristics of biogas fuelled dual fuel engine with waste plastic oil as secondary fuel

Author

Palanivelrajan, A.R., primary, Manimaran, R., additional, Manavalla, Sreekanth, additional, Yunus Khan, T.M., additional, Almakayeel, Naif, additional, and Feroskhan, M., additional

Published

2024

3. System Design, Optimization and 2nd Law Analysis of a 100 MWe Double Reheat s-CO2 Power Plant at Full Load and Part Loads

Author

Manavalla, Sreekanth, primary, M., Feroskhan, additional, Daniel, Joseph, additional, Ramasamy, Sivakumar, additional, Yunus Khan, T. M., additional, Baig, Rahmath Ulla, additional, Almakayeel, Naif, additional, and Voddin Tirumalapur, Bhanu Kiran, additional

Published

2023

4. System Design, Optimization and 2nd Law Analysis of a 100 MWe Double Reheat s-CO 2 Power Plant at Full Load and Part Loads.

Author

Manavalla, Sreekanth, M., Feroskhan, Daniel, Joseph, Ramasamy, Sivakumar, Yunus Khan, T. M., Baig, Rahmath Ulla, Almakayeel, Naif, and Voddin Tirumalapur, Bhanu Kiran

Abstract

Super-critical Carbon dioxide (s-CO2) power plants are considered to be efficient and environmentally friendly compared to the traditional Rankine cycle-based steam power plants and Brayton cycle-based gas turbine power plants. In this work, the system design of a coal-fired 100 MWe double reheat s-CO2 power plant is presented. The system is also optimized for efficiency with turbine inlet pressures and the recompression ratio as the variables. The components needed, mass flow rates of various streams and their pressures at various locations in the system have been established. The plant has been studied based on 1st and 2nd laws at full load and at part loads of 80%, 60% and 40%. Operating parameters such as mass flow rate, pressure and temperature have considerably changed in comparison to full load operation. It was also observed that the 1st law efficiency is 53.96%, 53.93%, 52.63% and 50% while the 2nd law efficiency is 51.88%, 51.86%, 50.61% and 48.1% at 100%, 80%, 60% and 40% loads, respectively. The power plant demonstrated good performance even at part loads, especially at 80% load, while the performance deteriorated at lower loads. At full load, the highest amount of exergy destruction is found in the main heater (36.6%) and re-heaters (23.2% and 19.6%) followed by the high-temperature recuperator (5.7%) and cooler (4.1%). Similar trends were observed for the part load operation. It has been found that the recompression ratio should be kept high (>0.5) at lower loads in order to match the performance at higher loads. Combustion and heat exchange due to finite temperature differences are the main causes of exergy destruction, followed by pressure drop. [ABSTRACT FROM AUTHOR]

Published

2023

5. A Comprehensive Study of the Effects of Various Operating Parameters on a Biogas-Diesel Dual Fuel Engine

Author

Feroskhan, M., primary, Ismail, Saleel, additional, Natarajan, Gobinath, additional, Manavalla, Sreekanth, additional, Khan, T. M. Yunus, additional, Khadar, Shaik Dawood Abdul, additional, and Ali, Mohammed Azam, additional

Published

2023

6. Design and Experimental Studies of a Funnel Solar Cooker with Phase Change Material

Author

Chauhan, Kartikey, primary, Daniel, Joseph, additional, Manavalla, Sreekanth, additional, and Jayaraju, Priyadarshini, additional

Published

2022

7. Exergy Analysis of a CI Engine Operating on Ternary Biodiesel Blends

Author

Manavalla, Sreekanth, primary, Chaudhary, Abhishek, additional, Panchal, Shreyash Hemant, additional, Ismail, Saleel, additional, M, Feroskhan, additional, Khan, T. M. Yunus, additional, Javed, Syed, additional, and Ali, Mohammed Azam, additional

Published

2022

8. Exploring the Effects of DEE Pilot Injection on a Biogas-Fueled HCCI Engine at Different Injection Locations.

Author

Mishra, Nihal, Mitra, Shubham, Thapliyal, Abhishek, Mahajan, Aniket, Khan, T. M. Yunus, Manavalla, Sreekanth, Baig, Rahmath Ulla, Janvekar, Ayub Ahmed, and M, Feroskhan

Abstract

One of the popular ways to minimise the impact of emissions produced by engines is by enabling alternative fuels. Out of the many trending options for alternative fuels, biogas provides some unique advantages, such as being considered to be environmentally friendly, obeying the laws of renewable energy and generating the smallest carbon footprints. The two major drawbacks of traditional diesel engines are their high rate of NOx and significant amount of soot. The best candidates for overcoming these issues are HCCI engines; HCCI engines can provide better control over NOx generation and overall thermal efficiency can be improved to a greater level. These types of engines are compatible with both SI and CI. Now, to understand and analyse the behaviour of HCCI, the present work was focused on a modified single-cylinder CI engine. It was made to operate in HCCI mode by enabling the combination of biogas, along with diethyl ether (DEE), as a fuel mixture. To achieve better combustion, biogas was combined with air, while DEE acted as an ignition source, which can be introduced at three different locations. In total, the experiment was performed sixty times so as to achieve the best injection position. To obtain this information, other parameters, such as biogas flow rate, torque, methane fraction and DEE injection position, were also incorporated. The main results were consolidated by warping the output parameters such as brake thermal efficiency, equivalence ratio, air–fuel ratio, and brake-specific fuel consumption. Emission such as CO, HC, NOx, and smoke were taken into account. The results indicate that port injection provides higher thermal efficiency than manifold injections, while lower emissions were observed in manifold injections. [ABSTRACT FROM AUTHOR]

Published

2023

9. Numerical Analysis of E-Machine Cooling Using Phase Change Material

Author

Selvan, Jayakumar, primary and Manavalla, Sreekanth, additional

Published

2022

10. Optimization of CNC End Milling Process Parameters of Low-Carbon Mold Steel Using Response Surface Methodology and Grey Relational Analysis

Author

Suresh Kumar, R., primary, Senthil Kumar, S., additional, Murugan, K., additional, Guruprasad, B., additional, Manavalla, Sreekanth, additional, Madhu, S., additional, Hariprabhu, M., additional, Balamuralitharan, S., additional, and Venkatesa Prabhu, S., additional

Published

2021

11. XRD Peak Profile Analysis of SiC Reinforced Al2O3 Ceramic Composite Synthesized by Electrical Resistance Heating and Microwave Sintering: A Comparison

Author

Mohankumar, Madhan, primary, Praveen Kumar, S., additional, Guruprasad, B., additional, Manavalla, Sreekanth, additional, Isaac JoshuaRamesh Lalvani, Joshua Stephen Chellakumar, additional, Somasundaram, P. L., additional, Tamilarasu, P., additional, and Tanwar, Prakash Singh, additional

Published

2021

12. XRD Peak Profile Analysis of SiC Reinforced Al2O3 Ceramic Composite Synthesized by Electrical Resistance Heating and Microwave Sintering: A Comparison.

Author

Mohankumar, Madhan, Praveen Kumar, S., Guruprasad, B., Manavalla, Sreekanth, Isaac JoshuaRamesh Lalvani, Joshua Stephen Chellakumar, Somasundaram, P. L., Tamilarasu, P., and Tanwar, Prakash Singh

Subjects

SINTERING, MICROWAVE heating, RESISTANCE heating, MICROWAVE sintering, FIELD emission electron microscopy, X-ray powder diffraction, STRAINS & stresses (Mechanics)

Abstract

Al2O3 with 10 wt.% of SiC ceramic composite is synthesized at 1500°C by electrical resistance heating sintering with a holding time of 5 hours and microwave sintering methods with a holding time of 15 minutes. The samples generated by the two methods are characterized using powder X-ray diffraction and field emission scanning electron microscopy (FESEM). Experiments with both samples showed that the existence of the α-Al2O3 and β-SiC phases in both samples was verified by the findings of XRD pattern on both samples. Microstructure study illustrates that the Al2O3 matrix particles have spherical-like shape and their average matrix particle size is 67 ± 5 nm for electrical resistance heating sintered sample and 38 ± 5 nm for microwave sintered sample. The lattice strain and crystallite size of Al2O3 matrix were measured using Williamson–Hall (W-H) methods, which were achieved via the use of XRD peak broadening, based on a diffraction pattern. Three modified W-H models were used to compute other parameters, including strain (ε) and stress (σ), as well as energy density (u). These models were the uniform deformation model (UDM), the uniform deformation energy density model (UDEDM), and the uniform deformation stress model (UDSM). The average crystallite sizes of α-Al2O3 attained from these three models of Williamson–Hall (W–H) methods and FESEM analysis are correlated and found very close to each other. In all three models of the W-H technique, X-ray diffraction peak profile examination of electrical resistance heating-sintered and microwave-sintered Al2O3/10 wt. % SiC ceramic composite reveals that the microwave-sintered sample has finer crystallite size with less strain. [ABSTRACT FROM AUTHOR]

Published

2021