Posts Tagged ‘design’

Celazole PBI (Polybenzimidazole) is an impressively high performing engineering plastic, offering the highest mechanical properties compared to any other unfilled thermoplastic over 400° F. It is an ideal plastic for elevated heat bushings, valve seats, and connectors. This material is very hard and has amazing ultrasonic transparency, making it a superb option for probe tip lenses in ultrasonic measuring equipment and other similar parts.

Also referred to as Duratron PBI, Celazole is an unreinforced material that is exceptionally “clean” when it comes to ionic impurity, and it doesn’t outgas, with the exception of water. It is a superior thermal insulator. While other plastics in melt stick to other materials, this does not happen with polybenzimidazole, as such it makes it ideal for a number of applications.

Examples of applications that Celazole is commonly used for include, but are not necessarily limited to:

• Seals and wear surfaces
• Valve and pump seats
• Handling parts and fixtures for plastics and glass manufacturing
• Replacement for metal for aerospace components
• Structural and wear parts for manufacturing involving Semiconductor and Electronics

High performance engineering machinable shapes, such as Celazole, are perfect design starting points, lessen weight, and expand the length of time before maintenance or replacement is required. This reduces the overall expense though the increase in process uptime, making this innovative plastic exceptionally valuable.

From stress analysis of machine components (using finite element packages), to numerical descriptions of the artist-drawn shapes of new gadgets (using CAD packages), to the use of numbers associated with the mundane jobs of production, inspection, and statistical quality assurance(using statistical packages), to the economically critical planning problem of what material to buy in what amount from where (using optimization packages), and so on, applied mathematics is everywhere in the everyday world of software applications in routine engineering.

From calculations of heat and mass flow in steam power plants and car radiators, to calculations of air flow in cooling fans, to calculations of molten metal flowing and mixing in weld pools, applied mathematics turns the wheels of engineering analysis and design.From reliability in electrical power system grids to traffic in networks (both tar roads and optical fibres), mathematics crosses boundaries in a way no other technical subject can.

The applications mentioned above are the subjects of many books. Yet, they collectively fail to convey the excitement that engineering applications of mathematics can have. There is more to the story than a list of applications. some ways those more interesting are online tutoring. With Online math tutoring you’ll get math answers by submitting your math problems. some Precalculus help that we got from online tutoring is very useful. you can also get something like statistics help or even chemistry help. this is a fun and good way to learn engineering mathematics.

Engineering colleges must be more effective and visible partners within the broader university community. This partnership should be enhanced for non-classroom activities as well as for formal research and education. Engineering colleges, their faculty and students have much to offer the broader campus community. For example, engineers can provide the real-world context to show non-engineering students the applications of the mathematical and scientific concepts they are learning. Engineering educators and their colleagues in science can also provide leadership in helping their campuses initiate computer networking and make effective use of the information super highway. Industry can help foster this cross-campus interaction by bringing multifaceted problems to the university that require the talents of several disciplines to solve. Industry representatives who sit on university advisory boards should also stress this approach in their recommendations to the institution.

Conversely, engineering education programs have much to gain from other disciplines. New insights can be provided, for example, by chemistry in developing environmentally friendly technologies, by political science in teaching the value of issues advocacy, by art in designing new consumer products, by business in aiding the understanding of international trade issues, and by law in treating intellectual property rights. Both engineering students and faculty would benefit from such interdisciplinary collaboration.

Engineers working with other colleagues across the university can also promote technological literacy for all students. Engineering colleges should accept responsibility for providing technical literacy programs to liberal arts students. Activities can include developing and teaching courses that provide laboratory or design experience for non-engineers, examine the history of science and technology, or discuss the interaction of technology and society.

At the same time, student participation in university-wide activities, such as student government, professional societies, athletics, and performing arts can help them develop the leadership and communications skills that are an important part of an engineering education.

Engineering deans should actively encourage their faculty members to participate in research, educational and leadership activities beyond the engineering college. Industrial advisory board members should stress cross-campus interaction in their recommendations to the college. Activities should include connections with such units as the schools of business, medicine, arts, sciences, and education.

Engineering deans and faculty should actively encourage students to participate in university-wide activities. These activities can include participation in student government, student professional societies, athletics, performing arts, debate, study abroad, and similar activities. The aim is to promote leadership and communications skills as well as a sense of the integration of engineering into the broader world.

Engineering deans should take responsibility for helping non-engineering majors on their campuses better understand the importance and relevance of technology in their lives, and seek to better equip those students to prosper in an increasingly technological world. Engineering schools may develop specific courses, seminars, guest lectureships, and cross-campus projects. Use payday loan for better loans management

One of the first distinctions that must be made is between science and engineering. It is not a simple distinction because the two are so interdependent and intertwined, but whatever difference there is needs to be considered.

Science is the study of “natural” phenomena. It is the collection of theories, models, laws, and facts about the physical world and the methods used to create this collection. Physics, chemistry, biology, geology, etc. try to understand, describe, and explain the physical world that would exist even if there were no humans. It is creative in building theories, models, and explanations, but not in creating the phenomena that it studies. Science has its own philosophy with an epistemology, esthetics, and logic. It has its own technology in order to carry out its investigations, build its tools, and pursue its goals. Science has its organizations, culture, and methods of inquiry. It has its “scientific method” which has served as a model (for better or for worse) in many other disciplines.

Science is old. It was part of the original makeup of a university or college in the form of natural philosophy. It came out of antiquity, developed in the middle ages, blossomed in the renaissance, was the tool of the enlightenment, and came into its present maturity in modernity. Indeed, the history of science is, in some ways, a history of intellectual development. This is certainly only true in conjunction with many other strains of philosophical, economical, theological, and technological development, but science is a central player in that story. Science is often paired with the arts (and Humanities and Social Sciences) in the “College of Arts and Science” of a traditional university.

Engineering is the creation, maintenance, and development of things that have not existed in the natural world and that satisfy some human desire or need. A television set does not grow on a tree. It is the creation of human ingenuity that first fulfilled a fantasy of a human need and then went on to change the very society that created it. I use the term “things” because one should include computer programs, organizational paradigms, and mathematical algorithms in addition to cars, radios, plastics, and bridges.

Science is the study of what is and engineering is the creation of can be. Only recently has engineering developed the set of characteristics that make it a legitimate academic discipline. Earlier, engineering often was viewed only as the application of natural science. Now, engineering has developed its own engineering science for the study of human made things to supplement natural science which was developed to study natural phenomena. Parts of computer science are wonderful examples of that. Engineering has its own philosophy and methodology and its own economics. It even has its own National Academy.

We differentiate science and engineering, not because their difference is great, but because, in many ways, it is small. Science could not progress without technology, and engineering certainly could not flourish without science and mathematics.

A more illuminating comparison might be between the humanities and engineering. One might find more similarity in style (not content) between English literature and engineering than between science and engineering. Both literature and engineering are the study of human created artifacts. Both teach creation in the form of creative writing and engineering design. Both teach analysis in the form of literary criticism and engineering analysis. Both are intimately connected with the needs and desires of individuals and society. A similar analogy could be made between art and engineering looking at studio art, art criticism, and art history.

Most scientists (but not all) feel there is some unique objective truth behind the physical phenomena they are studying. Their goal is to find it and describe and explain it, and this truth is unique although the approaches and approximations to it are certainly not. In literature and engineering, the designed entity is not unique to the situation, but it is a creation of the particular writer or designer and perhaps unique to the creator.

The distinctions of this section are not as clean or clear as have been presented here. The boundary between science and engineering can be and often is murky. Many items of study in science are influenced if not literally created by people. This is obviously true in biology and the life sciences but also true in physics where certain elements in the periodic table do not exist in nature. Perhaps, therefore, the areas of pure science are very limited. On the other hand, since people are members of our natural system, an argument can be made that their products are as natural as anything else and, therefore, the areas of pure scientific study are very broad. Clearly engineering is constrained in what it can create by the laws of science as everything is. Nevertheless, there is a difference in spirit in the two disciplines worth trying to delineate.

When deciding on a particular degree course, many students are unaware of the vast opportunities that lie in the broad area of engineering. This problem arises since most people are unable to define exactly what type of work an engineer performs.

The engineering profession is not well understood by the general public, even in the United Kingdom, who tend to associate an engineer with somebody who services their car or mends their washing machine! However, this type of work is rarely performed by graduate engineers. A professional engineer lives in a high-tech, fast moving world where the competition is fierce and the stakes are high.

With a degree in engineering, you are far more likely to be involved in the research, design and development of new products and services. Engineers have designed and created most of the world in which we now live. The subject is fairly creative and aims to solve everyday problems in a cost effective and practical manner. While many see engineering as a very technical subject, in reality many engineers will develop considerable management experience and the ability to communicate well and motivate individuals is an important skill.

The financial realities of studying for a degree cannot be ignored. Engineering is one of the few University subjects where companies are actively looking to sponsor students throughout their degree programme. If sponsored, the company will normally give you money during the university terms, and this can help to make life a bit easier!. Most companies will also offer paid work experience during the long summer holidays, and this is a very useful way of experiencing the type of work opportunities engineering has to offer. Sponsorship also offers the chance of a job offer after you graduate.

Job prospects for graduates with a degree in electrical and electronic engineering have never been so exciting. The huge growth in areas such as telecommunications has resulted in a large demand for suitably qualified students. In the past, many students have not realised how many opportunities lie in engineering, and this had led to companies finding it extremely difficult to attract people with the skills and experience they require. In general, engineering offers very rewarding work, as well as the potential for personal development, world-wide travel and good pay.

An Electrical and Electronic Engineering degree opens the door on many possible careers. Whether you want to be a manager or a technical expert, a sales person or a computer programmer, most electronics companies will need and value your skills. If at the end of your degree you decide that your future does not lie in engineering, then your degree can still be used to apply for a wide range of alternative employment opportunities.

In conclusion, a good degree in Electrical and Electronic Engineering from a university with strong research in growth areas such as telecommunications, as well as strong links to the industry, is an excellent and flexible foundation for future success.