Dr. Ali Heidary Moghada | friction stir spot welding | Best Researcher Award

Posted on by Welding Conference

Dr. Ali Heidary Moghada | friction stir spot welding | Best Researcher Award

Educational and Skill Assistant at Islamic Azad University, Iran

πŸ‘¨β€πŸŽ“ Dr. Ali Heidary Moghada is a seasoned professional with nearly two decades of global experience in higher education and business. As the Director of the UAEU (CBE) Off-Campus Site in Abu Dhabi, he currently serves as the MBA program coordinator, overseeing industry-oriented post-graduate programs and the Executive Education Unit.

πŸ† In 2014, during his tenure as the College Dean of EIC – Abu Dhabi, the institution earned the prestigious Award of Educational Innovation from the Worldwide Hospitality Award in Paris. His leadership extended to successful reauthorization, re-licensure, and re-accreditation projects for all programs under the Commission of Academic Accreditation (CAA-MoE).

Professional Profiles:

Education:

The user’s educational background includes a Ph.D. in Advanced Materials Engineering and Metallurgy from the University of Tehran, Iran, in 1151 (Persian calendar, which corresponds to approximately 2012 in the Gregorian calendar). They also hold a Master’s degree in Materials Engineering and Metallurgy with a focus on Metal Extraction from Isfahan University of Technology, Iran, in 1106, and a Bachelor’s degree in Industrial Metallurgy from Shiraz University, Iran, in 1104.

 

Research projects:

The projects detailed include the construction of various devices such as sintering machines, strength testing machines, coke testing machines, jaminie testing machines, granulators, and palletizers for use in laboratories focused on metal extraction and thermal operations. These projects were executed by Ali Heidari Moghadam at the Islamic Azad University, Dezful Branch, resulting in the construction of a Box Glove device for laboratory use. Additionally, Morteza Shemayanian led a project at the Isfahan Iron Melt Company investigating the effect of initial particle size on sintering processes’ quality. Another project at the same company, led by Ali Heidari Moghadam, studied the impact of adding coke time on the initial load of the sintering process. Meisam Haji Lori oversaw projects at the Petrochemical Arvand Company, focusing on recycling used gamma-alumina catalysts and studying the effects of temperature and time of acidification on the process. Furthermore, a project at the Islamic Azad University, Dezful Branch, led by Vahid Khoramshahi, involved the design and construction of a gas sensor test device. Lastly, Ali Heidari Moghadam headed a project at the Khuzestan Gas Company, examining the tensile strength and hardness of carbon steel in the HAZ area and investigating the effect of welding speed on these properties. Additionally, there are two rows discussing completed research projects that have reached technology and projects with innovative and innovative features, focusing on the commercialization of knowledge-based companies and the construction and examination of zirconium-cobalt-rare earth alloys for use in vacuum chambers, both conducted at the Iran Scientific and Industrial Research Organization.

Β Innovative:

Manshoor Sanat, located at Dezful Growth Center in the Khuzestan Science and Technology Park (4931 4939), specializes in the technical manufacturing of lightweight polymer composite parts designed to serve as corrosion-resistant and flame-resistant structures for the oil industry. Their expertise lies in creating advanced materials that can withstand the harsh conditions often encountered in the oil and gas sector, providing durable solutions for infrastructure within this industry.

In addition to their expertise in composite material manufacturing, Manshoor Sanat is also involved in the construction and examination of composite reinforcement properties using the filament winding method. This process involves winding continuous fibers around a rotating mandrel in a precise pattern to create strong and lightweight composite structures. Their work in this area contributes to the development of innovative and efficient manufacturing techniques for composite materials, ensuring high-quality products for various industrial applications.

Publications:

Effect of pin geometry, rotational speed, and dwell time of tool in dissimilar joints of low-carbon galvanized steel and aluminum 6061-T6 by friction stir spot welding

Facile solution-based synthesis of impurity-free hydroxyapatite nanocrystals at ambient conditions

Tetragonality enhancement in BaTiO3Β by mechanical activation of the starting BaCO3Β and TiO2Β powders: Characterization of the contribution of the mechanical activation and postmilling calcination phenomena

Obtaining the highly pure barium titanate nanocrystals by a new approach

Effect of re elements on the sorption properties of nanocrystalline Zr-Co getters prepared by mechanical alloying

Electron Beam Welding & Processing Friction Stir

Posted on by Welding Conference

Introduction of Electron Beam Welding & Processing Friction Stir Welding

Research in Electron Beam Welding (EBW) and Friction Stir Welding (FSW) represents the forefront of advanced materials joining techniques, offering unique solutions in the manufacturing and aerospace industries.

Microstructure and Property Optimization in Electron Beam Welding:

Researchers delve into the intricate microstructural changes induced by Electron Beam Welding, aiming to optimize properties such as hardness and toughness. Understanding the relationship between welding parameters and material characteristics is vital for ensuring the reliability of welds in critical applications.

Additive Manufacturing Applications of Electron Beam Processing:

In this subfield, researchers explore how Electron Beam Processing can be harnessed for additive manufacturing. By selectively melting or sintering materials layer by layer, this approach opens avenues for producing complex components with improved structural integrity and tailored material properties.

Tool Design and Material Flow in Friction Stir Welding:

Friction Stir Welding relies on a rotating tool to join materials in the solid state. Research in this area focuses on optimizing tool design and understanding material flow during the process. The goal is to enhance the weld quality, particularly in challenging materials such as high-strength alloys and composites.

Hybrid Welding Processes: Electron Beam and Friction Stir Welding Integration:

This subtopic explores the synergy between Electron Beam Welding and Friction Stir Welding, aiming to combine their strengths in a hybrid approach. Researchers investigate the integration of these processes to capitalize on their complementary features, achieving enhanced weld properties and expanding the scope of applications.

Environmental Impact and Sustainability in Electron Beam and Friction Stir Welding:

Researchers delve into the environmental aspects of both Electron Beam and Friction Stir Welding, evaluating their energy efficiency and carbon footprint. This subfield aims to develop sustainable practices, optimizing processes for reduced energy consumption and waste generation while maintaining high-quality welds.

Electron Beam Welding & Processing Friction Stir Welding

Posted on by Welding Conference

Introduction of Electron Beam Welding & Processing Friction Stir Welding

Research in Electron Beam Welding (EBW) and Friction Stir Welding (FSW) represents the forefront of advanced materials joining techniques, offering unique solutions in the manufacturing and aerospace industries.

Microstructure and Property Optimization in Electron Beam Welding:

Researchers delve into the intricate microstructural changes induced by Electron Beam Welding, aiming to optimize properties such as hardness and toughness. Understanding the relationship between welding parameters and material characteristics is vital for ensuring the reliability of welds in critical applications.

Additive Manufacturing Applications of Electron Beam Processing:

In this subfield, researchers explore how Electron Beam Processing can be harnessed for additive manufacturing. By selectively melting or sintering materials layer by layer, this approach opens avenues for producing complex components with improved structural integrity and tailored material properties.

Tool Design and Material Flow in Friction Stir Welding:

Friction Stir Welding relies on a rotating tool to join materials in the solid state. Research in this area focuses on optimizing tool design and understanding material flow during the process. The goal is to enhance the weld quality, particularly in challenging materials such as high-strength alloys and composites.

Hybrid Welding Processes: Electron Beam and Friction Stir Welding Integration:

This subtopic explores the synergy between Electron Beam Welding and Friction Stir Welding, aiming to combine their strengths in a hybrid approach. Researchers investigate the integration of these processes to capitalize on their complementary features, achieving enhanced weld properties and expanding the scope of applications.

Environmental Impact and Sustainability in Electron Beam and Friction Stir Welding:

Researchers delve into the environmental aspects of both Electron Beam and Friction Stir Welding, evaluating their energy efficiency and carbon footprint. This subfield aims to develop sustainable practices, optimizing processes for reduced energy consumption and waste generation while maintaining high-quality welds.