EUR
en
Looking for a challenging role to utilize my engineering skills that can contribute to the company’s growth as well as enhance my knowledge by exploring new things.
BSc Mechanical Engineering | 2021 – Present
FSC pre-Engineering | 2019 – 2021
Matric | 2019 – 2021
ASME UET KSK | Oct 2022 – Present Deputy Director (Oct 2022 - Jun 2023)
Director (Oct 2023 - Present)
Simulation and numerical analysis of thermal properties during heat exchange of nanofluids and hot water in a counter flow heat exchanger. 2023 – 2024
Description:
This project aims is to design and simulation of shell and tube counter flow heat exchanger by using SolidWorks 2022. The primary objective is to explore the thermal properties exhibited during the heat exchange process involving nanofluids and hot water. In the initial phase of the study, the focus is on the calculation of the heat transfer rate. The experimentation Begin with the baseline scenario, involving the heat transfer rate when the heat exchanger utilizes the aqueous solution of lithium bromide. Subsequently, the investigation advances to a more complex scenario by introducing 0.1% copper oxide into the nanofluid at an initial temperature of 25°C. When lithium bromide and hot water is used it is found that LiBr temperature is rising and hot water temperature is decreasing and heat transfer rate has been shown within the simulation. In second phase, copper oxide as a nanoparticle is added at a controlled temperature to understand how such additives may influence the overall heat transfer efficiency. 0.1% amount of CuO has been added into the aqueous solution of lithium bromide and heat transfer rate has been increased that improves the overall heat transfer efficiency of heat exchanger.
Design and Simulation of Centrifugal Pump using SOLIDWORKS and investigating the effect of various parameters on Pressure Generation. 2022 – 2023
Description:
The main objectives of the project were to create a detailed 3D model of the centrifugal pump and analyze its performance under various conditions. Using SOLIDWORKS, I meticulously designed a 3D model of the centrifugal pump, considering factors such as geometry, dimensions, and material properties. Once the design phase was complete, I moved on to simulating the pump's performance. I explored a wide range of volume flow rates, pressure ratios, and velocities to understand how these factors affected the pump's efficiency and effectiveness. I was able to analyze fluid flow patterns and pressure distributions within the pump. One specific aspect of the project involved investigating the impact of the number of blades on the pump's performance. Through extensive simulations, I analyzed how variations in the number of blades affected the pump's efficiency, pressure generation, and overall performance. This analysis provided valuable insights into the optimal design parameters for achieving the desired pump performance
Application of Boyle's and Charles law in Internal Combustion Engine 2022 – 2023
Description:
The project aimed to explore how Boyle's and Charles' laws impact internal combustion engines. Boyle's law, focusing on pressure and volume, helped optimize intake systems. During the intake stroke, volume increase led to pressure decrease, aiding fuel-air intake. Charles' law, relating to temperature and volume, analyzed temperature changes during compression. Decreased volume raised temperature, enhancing combustion. Understanding these laws allowed us to design efficient cooling systems and optimize combustion. We examined parameters like engine speed, compression ratio, and fuel properties, studying their effects on pressure, temperature, and volume changes. This insight informed the design, leading to improved engine performance and efficiency
Bookmark
Daniel Féau processes personal data in order to optimise communication with our sales leads, our future clients and our established clients.
This site is protected by reCAPTCHA and the Google Privacy Policy and Terms of Service apply.