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工程与应用科学

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德克萨斯大学奥斯汀分校

   硕士生项目

MS in Mechanical Engineering

标准考试成绩要求

TOFEL:79

IELTS:6.5

学年学制

36 hours of coursework

学年学费

$1,629 per credit hour

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录取要求

Every master’s degree program assumes that participants have a general college education through the baccalaureate level. Accordingly, to enter a master’s degree program a student must hold a baccalaureate degree from a regionally accredited United States institution or proof of equivalent training outside the United States. He or she must also have taken at least twelve semester hours of upper-division undergraduate coursework in the area of the proposed graduate major or must have the consent of the graduate dean. Some areas may require more undergraduate preparation. Students who lack adequate preparation may be admitted to a graduate program on the condition that they complete additional preparatory coursework designated by the graduate adviser. These courses are in addition to the thirty semester hours or more required for the master’s degree itself.

申请材料清单

Register for the appropriate course in your last semester.

Submit a completed Program of Work form that has been approved by your supervising professor. Submit the completed form to the Academic Advising Office, ETC 5.224. Your Graduation Application will not be approved online until the Program of Work has been reviewed and approved by the Graduate Office. Note: There is no need to get the Graduate Adviser's signature before bringing your MS Program of Work to the Academic Advising Office, ETC 5.224. Your form will be signed by the Graduate Adviser after the Graduate Coordinator reviews it.

Submit the Master's Graduation Application electronically before the semester deadline.

Students completing a thesis or report are required to submit a printed copy of the following pages to the Graduate School, Main 101, by 3 p.m. on the relevant deadline listed here. All paperwork must be submitted together in one packet:

A signature page (with signatures of your supervising committee as listed on your Master’s Graduation Application form) ALL committee members must sign the signature page - no proxy signatures allowed;

A copy of your Copyright Tutorial certification email;

A Statement on Research with Human Participants form;

A Statement of Research in Restricted Regions form; and

Any requests to Delay Publication.

Submit the forms whether you used human participants or conducted research in a restricted region or not. If you did use human participants, attach a copy of the IRB approval letter or waiver or exemption notification of the form. If you traveled to a restricted region, attach a copy of your IOC approval letter(s).

If you cannot deliver the required pages in person, they may be mailed to arrive by the deadline. We recommend that you use a guaranteed method of delivery.

Send them to:

The University of Texas at Austin

Dean of Graduate Studies

110 Inner Campus Drive, Stop G0400

Austin, TX 78712-1710

Students may submit their thesis or report electronically or in a traditional bound version. Either format requires an additional printed copy of the following pages to be submitted separately from your thesis or report.

a title page

a signature page (with original signatures of your supervising committee as listed on your Master's Graduation Application form)

an Abstract

Submit your Thesis or Report by deadline.

Complete the Exit Survey.

There is no minimum score required by ME and we do not require any special subject tests.

Keep in mind that this score cannot be waived under any circumstances and that the scores are only valid for five (5) years.

For more information on test scores see the Graduate School.

Average GRE scores for recently admitted ME graduate students:

GRE V: 590 (GRE General Test) 159 (Revised GRE Test)

GRE Q: 770 (GRE General Test) 163 (Revised GRE Test)

Average GRE scores for recently admitted ORIE graduate students:

GRE V: 570 (GRE General Test) 160 (Revised GRE Test)

GRE Q: 770 (GRE General Test) 163 (Revised GRE Test)

The Graduate School requires:

A score of 550 (paper test), 213 (computer based test), or 79 (internet based test) on the Test of English as a Foreign Language (TOEFL)

OR

A 6.5 on the Academic Examination of the International English Language Testing System (IELTS).

Scores above the minimum do not guarantee admission and please keep in mind that TOEFL scores are only valid for 2 years following the test date. Our program does not accept expired test scores.

Preferred TOEFL for ME/ORIE department: 90 or above on (iBT)

Average TOEFL score for ME/ORIE admits: 106 (iBT)

截止申请时间:

秋季:12月1日 春季:10月1日

专业介绍

Mechanical engineers design, build and analyze motor vehicles, aircraft, heating and cooling systems, watercraft, manufacturing plants, industrial equipment and machinery, robotics, medical devices, alternative energy and more. Mechanical engineering is an incredibly broad field, offering a variety of opportunities in the engineering, technology and other industries.

The average starting salary for Cockrell School students who go into mechanical engineering after graduation is $71,484. For more information on average mechanical engineering salaries across the country, visit EngineerSalary.com.

Mechanical Engineering Fields

Basic Engineering

Mechanical engineers deal with the mechanics of motion and the transfer of energy.

Applied Mechanics

Applied Mechanics looks at shock and vibration, dynamics and motion, and fracture and failure in components.

Fluids Engineering

There are mechanics involved in anything that flows — air, water, sand, oil, etc. Fluids engineers design and build systems that control or utilize flow, such as pumps, turbines, compressors, valves, pipelines and fluid systems in vehicles.

Heat Transfer

Heat moves in systems all around us, from computers, to automobiles, to ventilation systems. The field of heat transfer deals with combustion, power generation and transmission systems, process equipment, electronic devices, thermal controls in manufacturing, environmental controls, biotechnology, aerospace applications, transportation equipment and even cryogenics.

Bioengineering

Nearly every part of the human body may be described in mechanical terms. Bioengineering deals with artificial organs, biomechanics, biomaterials, bio-instrumentation, biotransport processes, human factors, medical devices, biomedical modeling and biological systems.

Tribology

Tribology deals with interacting surfaces in motion. It looks at friction, lubrication and wear. Any products which involves two surfaces rubbing against one another is the concern of a tribologist.

Energy Conversion

Our world is incredibly dependent on the conversion of energy into useful forms. A mechanical engineer is extremely important in this conversion.

Internal Combustion Engines

IC engines are not only used in automobiles, but are also used in aircrafts, marine vessels and even some stationary applications such as electric generators.

Fuels & Combustion Technologies

Some mechanical engineers specialize in fuels and combustion systems. In addition to working with combustion systems, they also deal with fuel processing, alternative fuels, fuel handling, transportation and storage.

Power Engineering

Mechanical engineers work in power engineering in the design and production of electricity-producing systems.

Energy Resources

In addition to working in the conversion of energy, mechanical engineers may also work in finding and developing new forms of energy.

Advanced Energy Systems

Mechanical engineers develop new energy systems such as power cycle devices, fuel cells, gas turbines and many others.

Solar Engineering

Mechanical engineers develop solar energy collectors and new and innovative ways to utilize solar energy.

Nuclear Engineering

Mechanical engineers may design and develop nuclear reactors and components, such as heat exchangers, radioactive waste systems and new fuel technologies.

Petroleum Engineering

The petroleum industry has been an important part of our lives for quite a while. Mechanical engineers work on oil and gas drilling and production, offshore and arctic operations, hydrocarbon processing, synfuels and coal technology, materials, equipment design and manufacture, fuel transport, new fuel technologies and pollution control.

Ocean, Offshore & Arctic Engineering

Much of our energy sources already comes from offshore sources. Mechanical engineers design and build ocean structures, systems, hyperbaric chambers, life support equipment, marine vehicles, submersibles and ROV's, propulsion systems, remote sensing systems, moorings and buoys, ship structures and ocean mining equipment.

Environment & Transportation

Getting from one place to another is something that affects every person every day of their lives. Mechanical engineers work to move us and our goods quickly and more efficiently. In addition, the effect that transportation, and other factors, have on the environment is something that concerns us all.

Aerospace & Automotive

Mechanical engineers design propulsion engines and structural component systems, crew and passenger accommodations and life support systems. They also develop the equipment used to build automotive, aircraft, marine and space vehicles.

Environmental Engineering

Environmental conditions normally deal with a mechanical process, the movement of heat, noise and pollutants through soil, water and air. Mechanical engineers can study the effects of these processes and work to reduce their impact on the environment.

Noise Control & Acoustics

ound is very much a mechanical phenomenon. It deals with the movement of vibrations through solids, liquids and gasses. A background in mechanical engineering can help to solve acoustical problems in noise control, industrial acoustics, and acoustic materials and structures.

Rail Transportation

Mechanical engineers design, build and maintain rail systems which help move people and goods every day. New developments are being applied to develop a new generation of locomotives for freight, passenger and transit services.

Solid Waste Processing

Solid waste processing is an important part of environmental protection. Mechanical engineers develop solid waste processing facilities, and work in areas related to recycling, resource recovery and waste-to-energy biomass conversion.

Manufacturing

Mechanical engineers are critical in making a product become reality.

Manufacturing Engineering

About half of mechanical engineers work for a company that makes something, whether it be consumer goods, transportation or industrial equipment. The work is as varied as the products that are produced.

Materials Handling Engineering

Handling materials can be challenging when the material is costly, exotic or dangerous. Some mechanical engineers specialize in materials handling, transportation, handling equipment or hazard control technologies.

Plant Engineering & Maintenance

Manufacturing plants often need to be updated. Mechanical engineers are crucial in this process.

Process Industries

A process engineer changes materials from one form to another so that they can be used in new and interesting ways. A mechanical engineer will design and build the machines that heat, cool, liquefy, harden or soften substances.

Textile Engineering

Textile companies seek out mechanical engineers in the design and production of the machines and plants that handle fabrics, weave or knit fabrics, manufacture apparel and handle the finished products.

Materials & Structures

Mechanical engineers have to use a variety of different materials when making a product. The design and production of these materials is also an important process for a mechanical engineer.

Materials Engineering

A materials mechanical engineer focuses on properties of materials and their effect on design, fabrication, quality, and performance. They work to create materials which can be cast, forged, stamped, rolled, machined or welded.

Non-Destructive Evaluation

Nondestructive testing is necessary to determine the quality of a device without dismantling it. Mechanical engineers use x-rays, ultrasound, magnetic particle inspection, infrared and other techniques.

Pressure Vessels & Piping

Pressure vessels and piping are critical in many industries, and mechanical engineers develop materials that resist fatigue and fracture, plan the fabrication of equipment, perform inspections and tests, and design components.

Systems & Design

Most mechanical engineers work in the design and control of mechanical, electromechanical and fluid power systems. Design engineers take into account a truly wide number of factors in the course of their work, such as: product performance, cost, safety, manufacturability, serviceability, human factors, aesthetic appearance, durability, reliability, environmental impact and recyclability.

Dynamic Systems & Control

Dynamic systems need to be controlled. Typical applications of DSC include novel transducer designs, biomechanics at the cellular and human scale, dynamics and control of power and vehicle systems, and innovations in signal and information theory. These engineers are needed in a vast number of areas — aerospace and transportation, biomedical equipment, production machinery, energy and fluid power systems, expert systems and environmental systems.

Fluid Power Systems & Technology

Hydraulic and pneumatics systems are in everyday use. Mechanical engineers are needed to design and build these systems that could be used in automotive, aerospace, manufacturing, power industries and any situations that call for a flexible and precise application of power in large amounts.

Information Storage & Processing Systems

With the vast amounts of data that are stored in computer systems today, mechanical engineers are needed to design and manufacture the devices to store this data. They are normally involved in hard disk technologies, data storage and equipment, wear and lubrication in data storage devices, micro-sensors and controls.

Microelectromechanical Systems

Microelectromechanical systems combine computers with tiny mechanical devices such as sensors, valves, gears and actuators embedded in semiconductor chips. Mechanical engineers are needed for the design and development of these high-tech devices.

M.S. Mechanical Engineering Degree Options:

M.S. - Thesis: 24 hours of coursework + 2 semesters of Thesis

M.S. - Report: 30 hours of coursework + 1 semester of Report

M.S. - Coursework: 36 hours of coursework

Students generally follow the thesis option, which requires thirty semester hours of credit, including six hours in the thesis course. Students who are appointed as teaching assistants or research assistants are expected to choose the thesis option. The report option requires thirty-three semester hours, including three hours in the report course. The option without thesis or report requires thirty-six hours of course work. For all three options, at least eighteen hours (including the thesis or report, if any) should be in the major area; and at least six hours should be in a supporting area. The supporting courses may be in mechanical engineering but must represent a specialty distinct from the major courses. Some areas of study have required core courses.

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