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Updated in [May 25th, 2023]
This course, Spray Theory, provides an overview of the physics of liquid atomization, spray formation and propagation. Students will be introduced to theoretical models pertaining to jet breakup and drop formation, as well as the application of multiphase models for studying spray transport. The course will also present an overview of the design aspects as they pertain to spray nozzle and atomizers and discuss potential applications in combustion systems. Theoretical modeling of drop formation and atomization, drop size distribution models, and spray applications will be discussed. Experimental evidence and techniques for interrogating sprays will also be presented.
[Applications]
After this course, students will be able to apply the theoretical models of jet breakup and drop formation to various applications, such as spray combustion and spray drying. They will also be able to understand the physical processes underlying each application and the design process for each application. Additionally, students will be able to use the stochastic description of the spray formation and propagation process to understand the physical origins of drop size distributions. Finally, students will be able to use the multiphase transport framework for studying spray propagation.
[Career Paths]
1. Spray Design Engineer: Spray design engineers are responsible for designing and developing spray nozzles and atomizers for various applications. They must have a strong understanding of the physics of liquid atomization, spray formation and propagation, and must be able to apply theoretical models to design and optimize spray systems. The development of new technologies and materials for spray systems is an important part of this role.
2. Spray Combustion Engineer: Spray combustion engineers are responsible for designing and developing combustion systems that use sprays. They must have a strong understanding of the physics of liquid atomization, spray formation and propagation, and must be able to apply theoretical models to design and optimize combustion systems. They must also be able to develop new technologies and materials for spray combustion systems.
3. Spray Drying Engineer: Spray drying engineers are responsible for designing and developing spray drying systems. They must have a strong understanding of the physics of liquid atomization, spray formation and propagation, and must be able to apply theoretical models to design and optimize spray drying systems. They must also be able to develop new technologies and materials for spray drying systems.
Developing Trends:
1. Spray Design Engineer: With the increasing demand for more efficient and cost-effective spray systems, there is a growing need for spray design engineers who can develop new technologies and materials for spray systems.
2. Spray Combustion Engineer: With the increasing demand for more efficient and cost-effective combustion systems, there is a growing need for spray combustion engineers who can develop new technologies and materials for spray combustion systems.
3. Spray Drying Engineer: With the increasing demand for more efficient and cost-effective spray drying systems, there is a growing need for spray drying engineers who can develop new technologies and materials for spray drying systems.
[Education Paths]
Recommended Degree Paths:
1. Mechanical Engineering: Mechanical engineering is a field of engineering that focuses on the design, development, and operation of mechanical systems. This field is rapidly evolving with the development of new technologies and materials, and the increasing use of computer-aided design and manufacturing. Mechanical engineers are involved in the design and development of a wide range of products, from medical devices to automobiles, and from aircraft to robots.
2. Aerospace Engineering: Aerospace engineering is a field of engineering that focuses on the design, development, and operation of aircraft and spacecraft. This field is rapidly evolving with the development of new technologies and materials, and the increasing use of computer-aided design and manufacturing. Aerospace engineers are involved in the design and development of a wide range of products, from aircraft to spacecraft, and from missiles to satellites.
3. Chemical Engineering: Chemical engineering is a field of engineering that focuses on the design, development, and operation of chemical processes. This field is rapidly evolving with the development of new technologies and materials, and the increasing use of computer-aided design and manufacturing. Chemical engineers are involved in the design and development of a wide range of products, from pharmaceuticals to fuels, and from food products to bioproducts.
4. Biomedical Engineering: Biomedical engineering is a field of engineering that focuses on the design, development, and operation of medical devices and systems. This field is rapidly evolving with the development of new technologies and materials, and the increasing use of computer-aided design and manufacturing. Biomedical engineers are involved in the design and development of a wide range of products, from prosthetics to implants, and from medical imaging systems to drug delivery systems.