Mechanical Engineering Schools

Professions in mechanical engineering are challenging and rewarding, and Mechanical Engineering Schools can provide the education needed to succeed in the field. Offering a full spectrum of education in modern technology, Mechanical Engineering Schools teach the design and production of mechanical systems vital to modern societal needs. They help undergraduate and graduate students develop vital skills to meet the design and production challenges of mechanical engineering professions.

The mechanical engineering discipline is among the oldest in the engineering field. Mechanical Engineer in Schools prepare students for the responsibilities of developing product specifications and preparing detailed drawings; for ensuring the safety and performance of product design; for finding creative solutions to practical and technological problems; and for testing and evaluation of all product components and product efficacy.

Students in Mechanical Engineering Schools will study calculus, biology, physics, fluid mechanics, technical writing, and computer aided design (CAD) using computer software products. Mechanical Engineering Schools also instruct in performing research, product design and development, manufacturing, testing, operation, and maintenance.

Mechanical Engineering Schools provide programs of study for Associate of Science (AS), Bachelor of Science (BS), Master of Science (MS), and Doctorate (PhD), degrees in mechanical engineering. The curriculum emphasizes energy sciences and technologies, applied mechanics, thermal sciences, and design in their curriculums.

Bachelor of Science (BS) degrees from Mechanical Engineering Schools are designed to give students comprehensive backgrounds for occupations in various areas of engineering. Degree programs require academic courses in liberal arts and sciences, acquired scientific knowledge, and product design and development. Undergraduate programs require four years of preparation in academic programs to fulfill requirements of degree curriculums. Length of graduate programs can vary somewhat, depending on the specific school and students' goals.

MS and PhD degrees from Mechanical Engineering Schools require advanced levels of study in research and a thesis. Graduate degrees from Mechanical Engineering Schools provide high levels of preparation for performing responsibilities in advance positions in the workplace. MS and PhD degrees from Mechanical Engineering Schools will prepare graduates for positions in management and sales, where engineering backgrounds facilitate detailed dialogue of technical aspects of product design, use, planning, implementation, and installation.

Degrees from Mechanical Engineering Schools apply to almost any type of occupational field. Mechanical engineers work in manufacturing, in private engineering firms, in industrial plants, for government agencies, in architectural design, in laboratories, and on construction sites.

If you would like to learn more about Mechanical Engineering Schools and Online Mechanical Engineering Schools, you can find more in-depth information and resources on our website.

DISCLAIMER: Above is a GENERAL OVERVIEW and may or may not reflect specific practices, courses and/or services associated with ANY ONE particular school(s) that is or is not advertised on SchoolsGalore.com

Copyright 2006 - All Rights Reserved Michael Bustamante, in association with Media Positive Communications, Inc. for SchoolsGalore.com

Michael Bustamante is a staff writer for Media Positive Communications, Inc. in association with SchoolsGalore.com. Visit our Traditional School Directory and find Colleges, Universities, Vocational Schools, and Online Schools at SchoolsGalore.com, your educational resource to locate schools.

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What is a tachometer?

A tachometer is an instrument designed to measure the speed of an object or substance. The word is formed from Greek roots: tachos, meaning speed, and metron, meaning measure. The traditional tachometer is laid out as a dial, with a needle indicating the current reading and marking safe and dangerous levels. Recently, digital tachometers giving a direct numeric output have become more common.

In its most familiar form, a tachometer measures the speed at which a mechanical device is rotating. A common example is the tachometer found on automobile dashboards. In this application, the tachometer measures the revolutions per minute (RPMs) of the engine drive shaft. It is important to monitor engine RPMs, as running the engine at excessively high rates can drastically shorten engine life.

A tachometer used in this application can be built in multiple ways. It may be a small generator attached to the engine drive shaft, where the RPM measurement is scaled to the electric current generated by the device. Alternately, it may simply measure the rate at which the ignition system sends sparks to the engine.

The traditional tachometer requires physical contact between the instrument and the device being measured. In applications where this is not feasible for technical or safety reasons, it may be possible to use a laser tachometer to take measurements from a distance. A laser tachometer works by pulsing a tight beam of light against the rotating element. The rotating element will have a reflective spot, and the tachometer measures the rate at which the light beam is reflected back. A laser tachometer can be a permanent part of the system, or it can be handheld for occasional spot measurements.

A tachometer can even find uses in medicine. By placing a small, turbine-like device in an artery or vein, a doctor can use a tachometer to infer the rate of blood flow from the speed at which the turbine spins. This can be used to diagnose circulatory problems such as clogged arteries. This device is known as a haematachometer.

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