Industrial Engineering
Industrial Engineering is concerned with the design, improvement, and
installation of integrated systems of people, materials, equipment, information, and
energy in the most efficient manner possible. Efficiency is one of an engineers
major concerns. Being able to complete the job, solve the problem, and put the
solution in process are all very important, but making the process efficient allows
less waste and more profit. It draws upon specialized knowledge and skill in the
mathematical, physical, and social sciences together with the principles and methods
of engineering analysis and design to specify, predict and evaluate the results to be
obtained from such systems. Their jobs are also concerned with performance,
reliability, cost efficiency, quality control, plant design, and management of human
resources. Materials engineering and computer engineering are two of the modern
examples of industrial engineering.
Industrial engineers have the challenge of incorporating today’s leading
technological advances with the production of them in manufacturing facilities.
Their purpose is to maximize output, while minimizing the costs for materials and
production. This is why industrial engineers must have knowledge of product
development, materials processing, optimization, queuing theory, production
techniques, and engineering economy. Industrial engineers must have adequate skills
in computer aided design and computer aided manufacturing. Robots are now
providing more assistance than ever for industrial engineers.
Industrial engineering can spread into a wide area of fields. An industrial
engineer’s knowledge is useful in designing better systems to care for patients in
hospitals, reduce air pollution, and for approaching large-scale challenges in
enterprises(usually with a team of other engineers.) Industrial engineers will work
with biological engineers to improve the environment, reduce wastes, and conserve
Why I Am Majoring In Industrial Distribution I gradually became interested in Industrial Distribution throughout my education career. When I was applying for college during my senior year of high school, I was having a difficult time deciding between the majors of Business and Engineering. Therefore, I applied to Computer Engineering and was put into Blinn TEAM. Since Blinn was more cost efficient, I declined that offer and applied directly to Blinn College. I completed all of my core classes at Blinn and applied to transfer into
A Comparison of the Laboratory and Industrial Processes When going through the process of fermentation in a laboratory they use certain methods to achieve their goals and some of the methods that they use are completely different from the ones that are used in the industry of fermentation. A fermenter is a container that maintains optimum conditions needed to grow a particular organism I will be using different criteria’s to compare the laboratory and industrial process of fermentation in this assignment; some of them are listed below: * Equipment Used * The Quantity of the Product * Method Used * Quality of the Product Before I get right on into the assignment I will firstly talk about penicillin is and what it is used for today in our society because penicillin will come up. Penicillin was discovered by Alexander Fleming in 1929 and penicillin is one of the earliest discovered and widely used antibiotic agents, derived from the penecillium mold and the use of penecillium did not begin until the 1940s. Penicillin kills bacteria by interfering with the ability to synthesis the cell wall and this will disallow it from splitting and reproducing and it will only lengthen longer Below are is a table that shows the most obvious differences in fermentation in a laboratory and fermentation in the scientific industry: Laboratory Fermentation: Industry Fermentation: It is a batch culture They use a Ph sensor The Ph level is not being controlled The equipment used is more expensive The temperature is not being measured They use a thermometer The yeast population isn’t been given O² They equip the fermenter with an exit gas and an exit liquid flow The food supply is not being replenished They also equip it with a antifoam and gas flow It also has a dissolved O² sensor Equipped with an Sparser In industry they have a fresh media feed
The Industrial Revolution was a booming age for the United States that, though it brought many improvements in technology, caused many controversial events to take place.. Through the story Life in the Iron-mills, Rebecca Harding Davis proves the negativity of the factories from the Industrial Revolution. She proves this from personification, symbolism/metaphors, and also visual imagery. Rebecca Harding Davis proves through her writing, that the effect of industrialism in not pretty.
The field of medical robotics is a relatively new area. The first known documented utilization of robotics in the medical field occurred in the year 1985. A robot aided in placing a needle in the correct position for a biopsy of a patient's brain. Although there is still much to explore and discover in the area of medical robotics, the advances steadily increase at a fast pace. Historically, robots have often been first introduced to automate or ameliorate discrete processes, such as painting a car or placing test probes on electronic circuits, but their greatest economic influence has often come indirectly as essential enablers of computer-integration of entire production or accommodation processes.
The Period of 1730-1850 was one of the most influential, if not the most influential period, of human advancement. This time gave us many of the basic things we see all around us today, from our current wealth based system to the use of unions. It gave us the engine, it gave us a global economy. The Industrial Revolution was, and is, incredibly important. In the space of 5 generations, man went from farming for his living to operating mammoth machines. Man went from an unorganized group of warring people to a global economy. The Industrial Revolution truly boosted humanity to its next step into the future.
It began as a muddy pool, which was the meaning of the city’s original name: Liuerpul. Liverpool, located in England, was found by King John during 1207. It was known for being a port town, which was used to send soldiers and supplies to the Irish Sea during the conquering of Ireland by England. As years passed, King John divided the land and allowed people to establish houses and to start living. Later, they were given more freedom to start their own organizations. Over the next centuries, population grew and fell constantly because of poverty and famine. The economy wasn’t stable enough to give the city a proud name. It was not until the years between 1760 and 1850, when a big era hit the city of Liverpool, called Industrial Revolution. It became a success because of new technology that was invented to increase the population and secure its safety. Liverpool's industrialization became a success because new ideas and inventions affected the size of population and development of Liverpool.
The Industrial Revolution during 1760 to 1820 in Great Britain was a burgeoning period. The revolution brought massive benefits and changes on socioeconomic and cultural conditions. Firstly, it pushed the development of socioeconomic, and also released a great amount of working opportunity. At second his extraordinary change made the communication and transportation more efficient. Lastly, this revolution it made the production of agriculture boost, and fewer workers were needed in farm work. The Great Britain Industrial Revolution assisted the growth of agriculture, communication, transportation and socioeconomic.
They should know how to communicate with those whom are operating the machinery to diagnose and fix the problem. Workers need to know how to problem solve using mathematical and mechanical skills. It is very important that an employee be able to order equipment and stay within their budget. In this job, the employer has to know how to prioritize their work and be punctual while thorough in repairing the equipment. An industrial machinery mechanics typical workday will require the employee to pick up, push, pull or carry heavy objects.
The most far-reaching, influential transformation of human culture since the advent of agriculture eight or ten thousand years ago, was the industrial revolution of eighteenth century Europe. The consequences of this revolution would change irrevocably human labor, consumption, family structure, social structure, and even the very soul and thoughts of the individual. This revolution involved more than technology; to be sure, there had been industrial "revolutions" throughout European history and non-European history. In Europe, for instance, the twelfth and thirteenth centuries saw an explosion of technological knowledge and a consequent change in production and labor. However, the industrial revolution was more than technology-impressive as this technology was. What drove the industrial revolution were profound social changes, as Europe moved from a primarily agricultural and rural economy to a capitalist and urban economy, from a household, family-based economy to an industry-based economy. This required rethinking social obligations and the structure of the family; the abandonment of the family economy, for instance, was the most dramatic change to the structure of the family that Europe had ever undergone-and we're still struggling with these changes. In 1750, the European economy was overwhelmingly an agricultural economy. The land was owned largely by wealthy and frequently aristocratic landowners; they leased the land to tenant farmers who paid for the land in real goods that they grew or produced. Most non-agricultural goods were produced by individual families that specialized in one set of skills: wagon-wheel manufacture, for instance. Most capitalist activity focused on mercantile activity rather than production; there was, however, a growing manufacturing industry growing up around the logic of mercantilism. The European economy, though, had become a global economy. In our efforts to try to explain why the Industrial Revolution took place, the globalization of the European economy is a compelling explanation. European trade and manufacture stretched to every continent except Antarctica; this vast increase in the market for European goods in part drove the conversion to an industrial, manufacturing economy. Why other nations didn't initially join this revolution is in part explained by the monopolistic control that the Europeans exerted...
Robots are used in factories and even in people’s homes. So what if the Terminator film series got it right? Human workers, who work in factories, machineries, mills, everyday human controlled jobs like cash registers operators, are being replaced by robotic automation. This is a major problem for the everyday employee. Jobs that were once held by human workers, are now being replaced every day by robot “workers”.
The first industrial robot, built in 1961, was a mechanical arm used to load presses. After the development of the computer and the CNC (Computer Numerical Control) in the 1970?s, the world saw great advances in the development of robotic control and the quality of robot manufacturing. As a result, there has been acceptance of the industrial robot world wide, improving the productivity and quality standards of industry (Hodges 3-5).
When designing products, they may start to just sketch out the idea and then after a couple of sketches, he or she will start to use a Computer-Aided drafting program. After a product has been built, they will preform a quality assurance check on the product. Bureau of Labor Statistics (2015) says, “Employment of mechanical engineers is projected to grow 5 percent from 2014 to 2024, about as fast as the average for all occupations. Mechanical engineers can work in many industries and on many types of projects”. As technology advances so will the number of engineering jobs in the workplace. If you have a mechanical engineering degree you are able to work in many environments from the rail industry to the aerospace
Like all engineers, architectural engineers apply the theories and principles of science and mathematics to research and develop economical solutions to technical problems. Their work is the link between scientific discoveries and commercial applications. Engineers design products, machinery to build those products, factories in which those products are made, and the systems that ensure the quality of the product and efficiency of the workforce and manufacturing process. Engineers design, plan, and supervise the construction of buildings, highways, and transit systems. They develop new materials that both improve the performance of products and help implement advances in technology. Engineering knowledge is applied to improving many things, including the quality of health care, the safety of food products, and the efficient operation of financial systems.
Throughout my lifetime, I have never had to think very much about the working world and everything that went with it. All through high school I took classes I liked or thought would be interesting to me, but never thought that all of those classes were preparing me for what was to come. Before I knew it, it was time to go to college. The four years of high school had flown by and now it was time to choose a major for college. I had never given much thought as to what I wanted to do for the rest of my life. The only real occupations that I had really gotten to experience were teaching, the jobs that my parents had, and others such as doctors, dentist, most of the occupations that everyone sees while they are growing up. When I finally decided on my major, I chose engineering, but I didn’t know if I would like it or not. The only prior knowledge I had about it was the fact that my grandfather was an electrical and chemical engineer, and that my parents and teachers said that I would be good at engineering. Recently I have been interested in civil engineering, but what does one do with such a degree? What opportunities are available to a person with a degree in civil engineering on the job market? The broad curriculum that covers many different fields of engineering make civil engineering a major that allows a person to work in nearly any field they wish.
Computer integrated manufacturing is a relatively new technology arising from the application of many computer science sub disciplines to support the manufacturing enterprise. The technology of CIM emphasizes that all aspects of manufacturing should be not only computerized as much as possible but also linked together via a computer communication network into an integrated whole. In short, CIM has the potential to enable manufacturers to build cheaper, higher-quality products and thus improve their competitiveness.