Draft Version # 27
The Culture of the Engineering Profession
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In the following document,
each article will be a separate topic within the various “Information
Categories”. Methods of organization
vary from document to document. In the United States Constitution, the Articles
are divided into Sections. The Charter of the United Nations tends to be
organized around the Chapters. The Universal Declaration of Human Rights tends
to be organized around the Articles. In this document, the “Information
Categories” will be divided into a variety of “Articles”. This is just one
possibility, and you are welcome to contribute your suggestions and input.
You are also
welcome to call Kenneth Freelain, P.E. at (301) 891 – 0496 if you care to
discuss this document over the telephone.
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Table of contents of “The
Culture of the Engineering Profession”
Section 1 – General overview and background information
Item 1.1; An explanation of the numbering system which is
used for the “Information Categories” and “Information Category numbers”
Item 1.2; A definite sign of evolution
Item 1.3; The functions of, and the reasons for the
existence of, “The Culture of the Engineering Profession”
Item 1.4; The distinction between a “professional culture”
and an “ethnic culture”
Item 1.5; Comparing the engineering profession to the
legal, medical, and dental professions
Article 1.5.1; Education
Article 1.5.2; Licensure
Article 1.5.3; Ambiguity in the name of the engineering
profession
Item
1.6; An alphabetical listing of some of the “Adverse Experiences of the
Engineering Profession”
Article
1.6.1; Aerospace Engineering (aeronautical engineering)
Article
1.6.2; Aerospace Engineering (astronautical engineering)
Article
1.6.3; Chemical Engineering
Article
1.6.4; Civil Engineering
Article
1.6.5; Electrical Engineering
Article
1.6.6; Marine Engineering
Article
1.6.7; Mechanical Engineering
Article
1.6.8; Mining Engineering
Article
1.6.9; Nuclear Engineering
Article
1.6.10; Petroleum Engineering
Article
1.6.11; Politics and the “Infrastructure Report Card” of the American Society
of Civil Engineers
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Section 2 – Descriptions of some specific disciplines and
technical specialties
Item 2.1; Aerospace Engineering (including both
Aeronautical Engineering and Astronautical Engineering)
Item 2.2; Chemical Engineering
Item 2,3; BioMedical Engineering
Item 2,3; BioMedical Engineering
Item 2.4; Civil Engineering
Item 2.5; Electrical and Electronics Engineering
Item 2.6; Mechanical Engineering
Item 2.7; Nuclear Engineering
Item 2.8; Other engineering disciplines which do not appear
in this document
Section 3 – Utilities, public works, and the infrastructure
Item 3.1; Public safety in
engineering and in utilities
Item
3.2; Reliability of the services of utilities
Item
3.3; The United States Army Corps of Engineers
Item 3.4; Public works
Section
4 – An Alphabetical Listing of Some of the Major Engineering Societies and
Professional Organizations
Item
4.1; American Institute of Aeronautics and Astronautics
Item
4.2; American Institute of Chemical Engineers
Item
4.3; American Nuclear Society
Item
4.4; American Society of Civil Engineers
Item
4.5; American Society of Mechanical Engineers
Item
4.6; Institute of Electrical and Electronics Engineers
Item
4.7; National Society of Professional Engineers
Item 4.8; Other
professional societies which do not appear in this document
Section
5 – Engineering employment
Item
5.1; Career One Stop, sponsored by the United
States Department of Labor
Item
5-2; Web sites which pertain to engineering employment
Section
6- Engineering Magazines and Technical Publications
6.1;
Overview
6.2;
An alphabetical listing of some of the major engineering magazines and
technical publications
6.2.1; Aerospace
America magazine
6.2.2; C.E.P. (or Chemical Engineering Progress) magazine
6.2.3; Civil Engineering
magazine
6.2.4; Mechanical
Engineering magazine
6.2.5; P.E.
(or Professional Engineer) magazine
6.2.6;
The Reporter magazine
6.2.7; Spectrum
magazine
The “Table of Contents” ends here, at the
following horizontal line.
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Section 1 - General overview and background information
Item 1.1; An explanation of the numbering system which is
used for the “Information Categories” and for the “Information Category
numbers”
The numbering
system which is used for the “Information Categories” is divided into three
separate parts, and each part is separated from the adjacent part by a “period”
(also known as a “decimal point”). An “Information Category number” is a number
for either a section, an item, or an article. The following format is used for
each “Information Category number”.
[Section
number].[Item number].[Article number]
So, for example, the information
category which had the number 1.6.5 would be found in Section number 1
(General overview and background information), under Item number 6 (A listing of some of the adverse experiences of the engineering
profession), Article
number 5 (Mining Engineering).
If an Information Category number
consists of only a section number and an item number (such as 1.1), then that
“item” has not been subdivided into “articles”. This means that “article
numbers” are not used subdivide the information within that particular “item”.
All of the “sections” have been
sub-divided into “items”, whereas only a few (but not all) of the “items” have
been sub-divided into “articles”.
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Item
1.2; A definite sign of evolution
Years ago, Pi Tau Sigma was established as a
national honorary mechanical engineering fraternity. At that time, the
overwhelming majority of engineers (and engineering students) were men. Of
course, the members of fraternities are exclusively males.
A recent visit to the University of Maryland’s
branch of Pi Tau Sigma, on the College Park campus, revealed the fact that Pi
Tau Sigma is no longer a fraternity. Instead, it has become an engineering
society, and it is now gender-neutral. The faculty adviser of Pi Tau Sigma was
a lady. Approximately 1/3 of all engineering students are now females.
This
was certainly a definite sign of evolution.
Item
1.3; The functions of, and the reasons for the existence of, “The Culture of
the Engineering Profession”
The document which is entitled “The Culture of
the Engineering Profession” serves the following purposes, and performs the
following functions, among others.
Function # 1 – To discourage any repetition of the worst
mistakes which have confronted the engineering profession---To see some
examples, please refer to the following “Listing of Adverse Experiences”
Function # 2 – To encourage repetition of the best, and the
major, successes of the engineering profession. There are many success stories
in the international history of the engineering profession
Function # 3 - To serve as a center of career information
about the engineering profession. Some of this material has been provided by
the United States Bureau of Labor Statistics
Function # 4 - To provide general information about
the engineering profession for people who are interested in doing relevant
research
Function # 5
–To contribute to the level of camaraderie which exists within the engineering
profession
Function # 6 – To improve the quality the esprit de
corps which exists within the engineering profession. In this context, the term
“esprit de corps” can be defined as “a sense of unity and of common interests and responsibilities, as developed among a group of
persons closely associated
in a task, cause, enterprise, etc.”
This
definition was found on the web site which uses the following URL. www.dictionary.com
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Item 1.4; The distinction between a “professional culture” and an “ethnic culture”__
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Item 1.4; The distinction between a “professional culture” and an “ethnic culture”__
If a profession has a “professional culture“,
then that culture should be readily available to, and accessible to, each
person who practices that particular profession.
On the other hand, an “ethnic culture” tends to
be primarily of interest to those people who belong to a certain ethnic group.
So, for example, French people are expected to
be more interested in the Eiffel Tower than anyone else. The Eiffel Tower is
part of the “ethnic culture” of France.
People from China are expected to be more
interested in the Great Wall of China than anyone else. The Great Wall of China
is part of the “ethnic culture” of China.
On
the other hand, in the United States, all of the professional engineers should
have an equal opportunity to interact with the professional “Culture of the
Engineering Profession”, regardless of whether they are French-American (or
Franco-American), or Chinese American, or of any other ancestry. A professional
culture should be readily accessible to each and every member of a given
profession, regardless of their ethnic background. The culture of any given
profession belongs to everyone who practices that particular profession, in
much the same way that a “public park”, “public street”, or “public sector
infrastructure facility” belongs to everyone. We may regard a “professional
culture” as being in the “public domain”, very much like a document which is
published by the government.
The
following ten (10) components of a “non-professional” culture provide examples
which are quite different from what one should expect to find within a
“professional culture”. The typical culture, or standard culture, is a “non-professional
culture” or a “popular culture”.
Ten (10) Examples of Some of the Components of a
Typical (or Standard)
“Non-Professional Culture”, or “Popular Culture”
The following ten (10) examples
represent some of the components of a typical (or standard) “non-professional
culture”, or “popular culture.” These examples are quite different from what a
person should expect to find in a “professional culture”.
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1] Clothing styles for men - (One
example might include a “fez”.) The fez,
as well as its equivalent, the tarboosh, is a felt hat of two types. It may
take the shape of a truncated cone made of red felt. It can also be a short
cylinder made of kilim fabric, both usually with a tassel attached to the top.
The tarboosh is of ancient Greek origin and the modern fez, which is similar,
owes much of its development and popularity to the Ottoman era.
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2] Clothing fashions for women - (One
example might include a sari or saree.) A sari (or saree) is an Indian
female garment that varies from “two to nine yards” in length and “two to four
feet” in breadth/width/height. The word "sari" or "saree"
may be used to refer to the fabric (a cotton sari), a draping style (a Gujrati
sari), or a weaving technique (an Ikat sari).
While the sari is typical to Indian traditional wear, it can also be worn by women in South-East Asian countries like Burma, Malaysia, the Philippines, and Singapore where a long rectangular piece of cloth is draped around the body. However, these varieties are different from the sari as they are wrapped around the lower-half of body as a skirt, worn with a shirt/blouse, resembling a sarong, as seen in the Burmese, Longyi, Phillipino, Tapis, etc. Saris are usually worn with one end of the cloth wrapped around the waist, and the other end draped over the shoulder. The sari, or types of sari-draping, can be seen in the traditional wear of many South Asian countries.
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While the sari is typical to Indian traditional wear, it can also be worn by women in South-East Asian countries like Burma, Malaysia, the Philippines, and Singapore where a long rectangular piece of cloth is draped around the body. However, these varieties are different from the sari as they are wrapped around the lower-half of body as a skirt, worn with a shirt/blouse, resembling a sarong, as seen in the Burmese, Longyi, Phillipino, Tapis, etc. Saris are usually worn with one end of the cloth wrapped around the waist, and the other end draped over the shoulder. The sari, or types of sari-draping, can be seen in the traditional wear of many South Asian countries.
_______________________________________________________________
3] Culinary
Gastronomy is the study of food and culture
with a particular focus on gourmet cuisine.
One example might be escargot, which is a
Gastronomy is the study of food and culture
with a particular focus on gourmet cuisine.
One example might be escargot, which is a
dish of cooked land snails, usually served as an
appetizer in France and in French restaurants.
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4] Weddings – The manner in which couples are
joined in marriage varies from society to society,
and from culture to culture. The marriage procession
above comes from the island of Sicily.
5] Funerals – The burial services for
people
who have died vary from culture to culture,
and from society to society.
who have died vary from culture to culture,
and from society to society.
( A HUGE FUNERAL PROCESSION ABOVE
IN TUNISIA FOR A MARTYRED PROTESTER )
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6] Dancing – Some dances are performed
by professionals, for audiences, such as the ballet. Other dances, such as the
“Twist”, may be performed by amateurs who have no professional training
whatsoever. The “Twist” was a dance inspired by rock and roll music. It became
the first worldwide popular dance of the early 1960s, enjoying immense
popularity among young people and drawing fire from critics who felt it was too
provocative. It also inspired other popular dances, as well.
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7] Music – Music may be “classical
music”, such as the music of Beethoven (German), Handel (Handel was born in
Germany, trained in Italy, and settled in Britain as a naturalized British
subject.), Bach (German), Tchaikovsky (Russian), and/or Brahms (Born in
Germany, Brahms spent much of his professional life in Austria.), etc. Most of
the “classical music” usually tends to be instrumental. However, sometimes
classical music can also include human voices.
( George Fredric Handel pictured above )
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On the other hand, music may be
“popular music”, such as the music of Elvis Presley, Bob Marley, the Beatles,
Michael Jackson, and other international stars that created a major impact upon
the world of music. Some of these musical leaders have also become movie stars.
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( Michael Jackson above)
8] Sports – Spectator sports include
immensely popular sports such as baseball and football. In addition, some other
sports, such as golf, swimming, track, soccer, etc., have also produced many
stars and heroes.
American football is known as “football” in the U.S.A. and ”gridiron”
in some other countries.
“Association football”, commonly known
as “football or soccer” in many other countries outside of the U.S.A., is
played by 250 million players in over 200 countries, making it the world's most
popular sport.
Sometimes the similarity of names
can cause a certain amount of confusion
regarding the two different types of “football”.
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can cause a certain amount of confusion
regarding the two different types of “football”.
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9] Performing Arts – This broad category includes opera, the theater, and the sort of performances which are featured in
Washington, D.C.’s John F. Kennedy Center for the Performing Arts. Usually,
most dance performances tend to be accompanied by music.
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9] Opera -
This section about opera was contributed by Mr. Donato Soranno, an
instructor of music at Montgomery College in Montgomery County, Maryland.
Mr. Soranno is also a professional musician, professional opera singer,
a TV producer of musical programs, and a recording artist.
The preceding section on opera was contributed
through the courtesy of Mr. Donato Soranno.
Opera originated over 400 years ago in Florence, Italy by the Florentine Camerata, a group of humanists, musicians, poets and intellectuals. The group's earliest meeting was in 1573 and the apex of influence for the Florentine Camerata group was between 1577 and 1582. Unifying the Camerata members was the belief that the art of music could be improved and that society could be improved as well. The Camerata stressed the importance of music exploring the feelings and emotions inherent in the words of the text. They believed that their new music should be a combination of music and words in which each served the other. The group's work resulted in the creation of a new art form, opera.
( Picture of Jacopo Peri below )
The first opera, DAFNE, was written in 1597 by Jacopo Peri. Throughout the various periods of Western classical music to the present time 2,556 operas were written by 775 composers. Opera incorporates all varieties of other art forms including music, costumes, sets, make-up, dance and visual arts. Opera, or "opera in music", is an art form in which singers and instrumentalists perform a dramatic work through music. The music is the main component of an opera and the opera tells the story through music.
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10] Fine Arts – These “visual arts” usually include paintings, sculpture, and “national landmarks” such as the “Taj Mahal” in India, the “Great Wall of China” in China, and the “Eiffel Tower” in France. One of the largest art museums in Washington, D.C. is called the National Gallery of Art, and it also features films and musical performances.
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11] The typical (or standard) “popular
culture” may also be called a “non-professional culture”. The term
“non-professional cultural” does not imply any type of a stigma.
A “non-professional culture” is quite
different from a “professional culture”, because a “professional culture” is
dedicated to a certain specific profession, and so it will tend to be of
interest to mainly a relatively limited number of people. Unlike a
“non-professional culture”, the “professional culture” will usually not attract
as much participation and/or interest from the general public.
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Item
1.5; Comparing the engineering profession to the legal, medical, and dental
professions
Some of the major professions will be compared
on the basis of education, licensing requirements, and ambiguity of the name
for that profession.
Article
1.5.1; Education – Law schools, medical
schools, and dental schools usually tend to require a bachelor’s degree in
order to gain admission to the first year, at the entry level, in those
schools. On the other hand, most engineering schools admit high school
graduates into their undergraduate programs. The engineer who graduates from an
engineering school with a Bachelor of Science degree in engineering can be
regarded as eligible for membership in the engineering profession.
Article
1.5.2; Licensure – Most states require
doctors, lawyers, and dentists to be licensed. On the other hand, most
engineers do not possess the license of the Professional Engineer, also known
as the P.E. license.
Article
1.5.3; Ambiguity of the name of the engineering profession – It is an established fact that many of the
people who are called “engineers” do not actually practice engineering at a
professional level. Some of the people who are called “engineers” are skilled
craftsmen who do not possess professional credentials. This confusion exists
because the word “engineer” has not been carefully defined, but there is no
such confusion over ambiguous definitions of the words “doctor”, “lawyer”,
and/or “dentist”.
The word “engineer” has two (2) different
meanings, or definitions.
Definition # 1 – “Engineer” is the word for
someone who practices a trade in which the members are skilled craftsmen who
perform technical duties.
Definition # 2 – “Engineer” is also the word for
someone who practices a profession in which the members apply science,
technology, and mathematics in order to solve a wide range of technical
problems in various branches of science and technology.
Item
1.6; An alphabetical listing of some of the “Adverse Experiences of the
Engineering Profession”
The engineering profession has overcome a large
number of adverse experiences, and some of those experiences have been listed
below, in this section. These experiences have been listed in alphabetical
order, based upon the name of the discipline to which that particular
experience was most closely related.
Article 1.6.1; Aerospace engineering
(Aeronautical engineering, to analyze the performance of an aircraft which
operated within the Earth’s atmosphere)
The Hindenburg disaster took place
on Thursday, May 6, 1937, as the German passenger airship LZ 129 Hindenburg caught fire and was destroyed during its
attempt to dock with its mooring mast at the Lakehurst Naval Air Station, which is located adjacent to the borough of Lakehurst, New Jersey. Of the 97 people on board [N 1] (36 passengers and 61 crewmen), there were 35 fatalities. There
was also one death of a ground crewman.
The disaster was the subject of spectacular newsreel coverage, photographs, and Herbert Morrison's recorded radio eyewitness report from the landing field, which was broadcast the
next day. A variety of hypotheses have been put forward for both the cause of ignition and the initial fuel for the ensuing fire. The incident shattered public confidence in
the giant, passenger-carrying rigid airship and marked the end of the airship era.[1]
At 8:45p.m. local
time, the Hindenburg caught fire and quickly became engulfed in flames.[3] Where the fire started is unknown;
several witnesses on the port side saw yellow-red flames first jump forward of
the top fin.
[3] Other witnesses on the port side noted
the fire actually began just ahead of the horizontal port fin, only then
followed by flames in front of the upper fin. One, with views of the starboard
side, saw flames beginning lower and farther aft, near cell 1. No. 2 Helmsman
Helmut Lau also testified seeing the flames spreading from cell 4 into
starboard. Although there were five newsreel cameramen and at least one
spectator known to be filming the landing, no camera was rolling when the fire
started.
Wherever it
started, the flames quickly spread forward. Instantly, a water tank and a fuel
tank burst out of the hull due to the shock of the blast. This shock also
caused a crack behind the passenger decks, and the rear of the structure
imploded. Buoyancy was lost on the stern of the ship, and the bow lurched
upwards while the ship's back broke; the falling stern stayed in trim.
A fire-damaged
9" duralumin cross brace from the frame of the Hindenburg
salvaged in May 1937 from the crash site at NAS Lakehurst, NJ.
As the tail of the Hindenburg
crashed into the ground, a burst of flame came out of the nose, killing nine of
the 12 crew members in the bow. There was still gas in the bow section of the
ship, so it continued to point upward as the stern collapsed down. The crack
behind the passenger decks collapsed inward, causing the gas cell to explode.
The scarlet lettering "Hindenburg" was erased by flames while the
airship's bow descended. The airship's gondola wheel touched the ground,
causing the bow to bounce up slightly as one final gas cell burned away. At
this point, most of the fabric on the hull had also burned away and the bow
finally crashed to the ground. Although the hydrogen had finished burning, the Hindenburg's
diesel fuel burned for several more hours.
The time that it
took for the airship to be destroyed has been disputed. Some observers believed
that it took 34 seconds, others said that it took 32 or 37 seconds. Since none
of the newsreel cameras were filming the airship when the fire started, the
time of the start can only be estimated from various eyewitness accounts. One
careful analysis of the flame spread by Addison Bain of NASA gives the flame front spread rate across
the fabric skin as about 49 ft/s (15 m/s), which would have resulted
in a total destruction time of about 16 seconds (245m / 15 m/s=16.3 s). Some of
the duralumin framework of the airship was salvaged and shipped back to
Germany, where it was recycled and used in the construction of military
aircraft for the Luftwaffe. So were the frames of the LZ
127 Graf
Zeppelin and LZ 130 Graf
Zeppelin II
when both were scrapped in 1940.[5]
The disaster is
well recorded due to the significant extent of newsreel coverage and photographs, as well as Herbert Morrison's eyewitness radio report for station WLS in Chicago, which was broadcast the next day. Heavy
publicity about the first transatlantic passenger flight of the year by
Zeppelin to the U.S.A. attracted a large number of journalists
to the landing. (The airship had already made one round trip from Germany to Brazil that year.)
Morrison's
broadcast remains one of the most famous in history. Parts of it were later
dubbed onto the newsreel footage, giving the impression that the
words and film were recorded together. His plaintive "Oh, the
humanity!" has been widely used in popular culture. Part of the poignancy
of his commentary is due to its being recorded at a slightly slower speed, so
that when it is played back at normal speed, it seems to have a faster delivery
and higher pitch. When corrected, his account is less frantic sounding, though
still impassioned.
The source of this article was the Wikipedia on-line encyclopedia.
The source of this article was the Wikipedia on-line encyclopedia.
Article
1.6.2; Aerospace engineering (Astronautical engineering, to analyze the
performance of a spacecraft which operated outside of the Earth’s atmosphere)
The Space
Shuttle Columbia disaster occurred on February 1, 2003, when,
shortly before it was scheduled to conclude its 28th mission, STS-107, the Space
Shuttle Columbia disintegrated over Texas and Louisiana as it reentered Earth's
atmosphere,
killing all seven crew members.
During launch,
a piece of foam insulation broke off from the Space
Shuttle external tank and struck the left wing. When the Shuttle
reentered the atmosphere, the damage allowed hot gases to penetrate and destroy
the internal wing structure, which rapidly caused the spacecraft to break up.[1]
Most previous
shuttle launches had seen similar, if more minor, damage from foam shedding,
but the risks were deemed acceptable.[2] After the launch, some
engineers suspected the damage, but NASA managers limited the
investigation, under the rationale that the Columbia crew could not have
fixed the problem.[3]
Mission STS-107 was the 113th Space
Shuttle launch. The mission was delayed 18 times[4] over the two years from
the planned launch date of January 11, 2001, to the actual launch date of
January 16, 2003. (It was preceded by STS-113.) The Columbia Accident
Investigation Board determined that this delay had nothing to do with the
catastrophic failure six months later.[4]
The Columbia
Accident Investigation Board's recommendations addressed both technical and
organizational issues. Space Shuttle flight operations were delayed for over
two years, similar to the delay following the Challenger
accident.
Construction of the International
Space Station
was put on hold, and for 29 months the station relied entirely on the Russian
Federal Space Agency for resupply until Shuttle flights resumed with STS-114 and 41 months for crew
rotation until STS-121. Major changes to
shuttle operations, after missions resumed, included a thorough on-orbit
inspection to determine how well the shuttle's thermal protection system had
endured the ascent, and keeping a designated rescue mission at the ready in
case irreparable damage was found. Missions were also restricted to flights to
the ISS (so that the crew could use it as a "safe haven" if need be),
except for one
final mission
to repair the Hubble
Space Telescope.
The source of
this article was the Wikipedia on-line encyclopedia.
Article 1.6.3; Chemical Engineering
The Bhopal
disaster, also referred to as the Bhopal gas tragedy, was a gas leak incident in India, considered the world's worst industrial
disaster.[1] It occurred on the
night of 2–3 December 1984 at the Union
Carbide India Limited (UCIL) pesticide plant in Bhopal, Madhya Pradesh. Over
500,000 people were exposed to methyl isocyanate gas and other
chemicals. The toxic substance made its way in and around the shanty towns
located near the plant.[2] Estimates vary on the
death toll. The official immediate death toll was 2,259. The government
of Madhya Pradesh confirmed a total of 3,787 deaths related to the gas
release.[3] Others estimate 8,000
died within two weeks and another 8,000 or more have since died from gas-related
diseases.[4][5] A government affidavit
in 2006 stated the leak caused 558,125 injuries including 38,478 temporary
partial injuries and approximately 3,900 severely and permanently disabling
injuries.[6]
UCIL was the
Indian subsidiary of Union
Carbide
Corporation (UCC), with Indian Government controlled banks and the Indian
public holding a 49.1 percent stake. In 1994, the Supreme Court of India
allowed UCC to sell its 50.9 percent interest in UCIL to Eveready
Industries India Limited (EIIL), which subsequently merged with McLeod
Russel (India) Ltd. Eveready Industries India, Limited, ended clean-up on the
site in 1998, when it terminated its 99-year lease and turned over control of
the site to the state government of Madhya Pradesh. Dow
Chemical Company purchased UCC in 2001, seventeen years after the disaster.
Civil and
criminal cases are pending in the District
Court
of Bhopal, India, involving UCC and Warren
Anderson,
UCC CEO at the time of the disaster.[7][8] In June 2010, seven
ex-employees, including the former UCIL chairman, were convicted in Bhopal of
causing death by negligence and sentenced to two years imprisonment and a fine
of about $2,000 each, the maximum punishment allowed by Indian law. An eighth former
employee was also convicted, but died before the judgment was passed.[1]
The source of this article was the Wikipedia on-line encyclopedia.
Article 1.6.4; Civil Engineering
The I–35W Mississippi River
Bridge (officially known simply as Bridge 9340) was an eight-lane steel truss
arch bridge which carried Interstate-35W across the Mississippi River in
Minneapolis, Minnesota. The bridge failed catastrophically during the evening
rush hour on August 1, 2007, collapsing into the river below. Thirteen (13)
people were killed and 145 people were injured.
The source of this article was the Wikipedia on-line encyclopedia.
1.6.5; Electrical Engineering
The
initial concept for this document originated within the field of electrical
engineering. On August 30, 2010, the Maryland Public Service Commission held a
Pepco Reliability Hearing. Pepco is the shortened name for the Potomac Electric
Power Company, and many customers and elected officials complained about the
reliability of the electric power service which they were receiving from Pepco.
Pepco’s service area is in the Washington, D.C. metropolitan area.
One of the
people who testified was named Stanley Klein, and during this hearing, Stanley
Klein shared the following observation when he said, “The electric power
industry once had a culture in which reliability was its over-riding
goal………….We must do everything possible to restore the reliability-focused
culture that was once the hallmark of Pepco and the entire electric power
industry.”
Stanley
Klein was active with the Smart Grid Interoperability Panel, and there is a
huge demand for a culture of reliability in the electric power industry. People who would like some additional
information about this panel may visit the web site by using the following URL.
http://sgip.org/
Reliability is extremely important, and
valuable, in the electric power industry. Of course, electrical engineering is
the dominant profession within the electric power industry. However, it should
definitely be clear that other branches of engineering are also important to
the electric power industry. There can be no doubt about this fact!
In other words, the “Culture of the
Engineering Profession” is very closely related to the culture which Stanley Klein was talking
about!
However, the need for this type of culture extends far beyond the
service area of the Potomac Electric Power Company. It also extends far beyond the
field which we refer to as electrical engineering.
On July 11, 2011,
the Washington Post published an article which used the following heading, or
title.
Pepco ranks as ‘most hated’ company in nation
You may find this
article by using the following URL.
Regardless of whether a person loves or hates any particular
corporation, emotions such as “love” and/or “hate” do not fall within the realm
of “engineering”, or the “scope of the engineering profession”. Engineering
does not encompass emotions.
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( Photo of the Costa Concordia disaster above )
Article 1.6.6; Marine Engineering
The Costa Concordia disaster
Captain Francesco Schettino
Operator Costa Cruises
On board 4,252[1]
Passengers: 3,206[2]
Crew and personnel: 1,023[2]
Losses 32 dead, 64 injured
Salvage Fuel and oil extraction: March 2012
Righting: September 2013
The Costa Concordia (Call sign:
IBHD, IMO number: 9320544, MMSI number: 247158500) is an Italian cruise ship[p
1] which partially sank when it ran aground at Isola del Giglio,[p 2] Tuscany,
on 13 January 2012, with the loss of 32 lives.
The ship, carrying 4,252 people from
all over the world, was on the first leg of a cruise around the Mediterranean
Sea, starting from Civitavecchia in Lazio, when she hit a reef during an
unofficial near-shore salute to the local islanders.
To perform this maneuver, Captain
Francesco Schettino[p 3] deviated from the ship's computer-programmed route,
claiming that he was familiar with the local seabed.
The collision with the reef could be
heard onboard and caused a temporary power blackout when water flooded the
engine room. The captain, having lost control of the ship, did nothing to
contact the nearby harbour for help but tried to resume the original course it
was on prior to the U-turn back to Giglio. In the end, he had to order
evacuation when the ship grounded after an hour of listing and drifting.
Meanwhile, the harbour authorities were alerted by worried passengers, and
vessels were sent to the rescue. During a six-hour evacuation, most passengers
were brought ashore. The search for missing people continued for several
months, with all but two being accounted for. On 26 September 2013, one week
after the ship was uprighted, human remains were found on deck 4, which could
be the last two missing passengers not accounted for. The remains will be
subjected to DNA testing to determine their identity.[3][4][5]
Costa Concordia, operated by Costa
Cruises, is one of the largest ships ever to be abandoned and she dominated
international media in the days after the disaster. Schettino was arrested on
preliminary charges of manslaughter in connection with causing a shipwreck,
failing to assist 300 passengers, and failing to be the last to leave the
wreck.[6] He was later charged with failing to describe to maritime authorities
the scope of the disaster[7][8] and with abandoning incapacitated
passengers.[9] Costa Cruises offered compensation to passengers (to a limit of
€11,000 a person) to pay for all damages including the value of the cruise.
One-third of the passengers took this offer. The company also at first offered
to pay Captain Schettino's legal costs but later declined.
There were immediate fears of an
ecological disaster, as the partially submerged wreck was in danger of slipping
into much deeper water, with a risk of oil pollution that would have devastated
the popular tourist zone. This event was averted, with all the fuel and oil
being extracted safely by 24 March 2012. Costa Concordia has been officially
declared a "constructive total loss" by the insurance company, with
her salvage expected to be the biggest operation of its kind (the ship's
displacement is 50,000 tons).[10][11] On 16 September 2013, the parbuckle
salvage of the ship began.[12] The operation started late due to bad
weather,[13] and the wreck was set upright in the early hours of 17
September.[14] The ship is due to be refloated and towed away to be cut up for
scrap.[15]
The source of this article was the Wikipedia on-line encyclopedia.
Article 1.6.7; Mechanical Engineering
The Space Shuttle Challenger disaster occurred on
January 28, 1986, when Space Shuttle Challenger (mission STS-51-L) broke
apart 73 seconds into its flight, leading to the deaths of its seven crew
members. The spacecraft disintegrated over the Atlantic
Ocean, off the coast of central Florida at 11:38 EST (16:38 UTC). Disintegration of the entire vehicle began
after an O-ring seal in its right solid rocket booster (SRB) failed at liftoff. The O-ring
failure caused a breach in the SRB joint it sealed, allowing pressurized hot
gas from within the solid rocket motor to reach the outside and impinge upon
the adjacent SRB attachment hardware and external fuel tank. This led to the separation of the
right-hand SRBs aft attachment and the structural failure of the external tank. Aerodynamic forces
promptly broke up the orbiter.
The crew compartment and many other vehicle fragments were
eventually recovered from the ocean floor after a lengthy search and recovery
operation. Although the exact timing of the death of the crew is unknown,
several crew members are known to have survived the initial breakup of the
spacecraft. However, the shuttle had no escape system and the impact of the
crew compartment with the ocean surface was too violent to be survivable.
The source of this article was the Wikipedia on-line encyclopedia.
Article 1.6.8; Mining Engineering
The Upper Big Branch
Mine disaster occurred on April 5, 2010 roughly 1,000 feet (300 m)
underground in Raleigh County, West
Virginia at Massey Energy's Upper Big Branch coal mine located in Montcoal. Twenty-nine out of thirty-one miners at the
site were killed.[1] The explosion occurred at 3:27 pm.[2] The accident was the worst in the United States
since 1970, when 38 miners were killed at Finley Coal Company's No. 15 and 16 mines in Hyden, Kentucky.[3][4][5] A state funded independent investigation would
later find Massey Energy and the Mine Safety and Health
Administration (MSHA) directly
responsible for the blast.[6]
The MSHA released its final
report on December 6, 2011, concluding that flagrant safety violations
contributed to a coal dust explosion. It issued 369 citations at that time,
assessing $10.8 million in penalties.[7] Alpha Natural Resources, which had bought Massey Energy in 2011,
settled its corporate criminal liabilities with the U.S. Attorney for $209
million.[8] Investigation of possible personal criminal
liability continues,[8] with one former superintendent, Gary May, pleading guilty in March 2012, and "confess[ing] to conspiring to 'impede
the [MSHA]'s enforcement efforts'".
In April 2012, Coal
producer Alpha Natural Resources Inc. (ANR) (the then current owner) said it
will permanently close its Upper Big Branch mine in West Virginia.[9]
The source of this article
was the Wikipedia on-line encyclopedia.
Article 1.6.9; Nuclear
Engineering
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The Chernobyl disaster (Ukrainian: Чорнобильська
катастрофа, Chornobylska Katastrofa – Chornobyl
Catastrophe) was a catastrophic nuclear accident that occurred on 26 April 1986 at the Chernobyl Nuclear Power Plant in Ukraine (then officially the Ukrainian SSR),
which was under the direct jurisdiction of the central authorities of the Soviet Union. An
explosion and fire released large quantities of radioactive particles into the
atmosphere, which spread over much of the western USSR and Europe.
The Chernobyl disaster is widely considered to have been the
worst nuclear power plant accident in history, and is one of only two
classified as a level 7 event (the maximum classification) on the International Nuclear Event Scale (the other being the Fukushima Daiichi nuclear disaster in 2011).
The battle to contain the contamination and avert a greater catastrophe ultimately involved over 500,000 workers and cost an estimated 18 billion rubles. The official Soviet casualty count of 31 deaths has been disputed, and long-term effects such as cancers and deformities are still being accounted for.
The source of this article was the Wikipedia
on-line encyclopedia.
Article 1.6.10; Petroleum Engineering
The Deepwater Horizon
drilling rig explosion refers to the April 20, 2010 explosion and
subsequent fire on the Deepwater Horizon semi-submersible Mobile Offshore Drilling Unit (MODU), which was owned and operated by Transocean and drilling for BP in the Macondo Prospect oil field about 40 miles (60 km) southeast of the Louisiana coast. The explosion killed 11 workers and
injured 16 others. The explosion caused the Deepwater Horizon to burn
and sink, resulting in a massive offshore oil spill in the Gulf of Mexico, considered the largest accidental marine oil
spill in the world, and the largest environmental disaster in U.S. history.[2][3][4]
The source of this article was the Wikipedia
on-line encyclopedia.
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Article
1.6.11; Politics and the “Infrastructure Report Card” of the American Society
of Civil Engineers
During the 2009 “National
Engineers Week”, a representative of the International Definition television
program interviewed an elected official in Annapolis, Maryland, in Maryland’s
capitol building complex. At the state level in Maryland, the elected officials
who serve in the Maryland House of Delegates are called “delegates”. One
delegate (who will not be named in this document) was being interviewed on
camera, for television. However, the delegate (from Prince George’s County)
failed to analyze even one single issue which would be of interest to the
engineering profession. This type of an omission could only occur in an
environment in which (at least some of) the politicians fail to comprehend the
role of the engineering profession in the public sector. An improvement in this
state of affairs could become conceivable
if (at least some of) the leading politicians became better educated about
engineering as a profession, about the infrastructure, and about the
“Infrastructure Report Card” of the American Society of Civil Engineers. More
valuable and relevant information may obtained by going to the following web site.
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Section 2 – Descriptions of some specific
disciplines and technical specialties
Item 2.1; Aerospace Engineering
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Aerospace engineering is the primary branch of engineering concerned with the research, design,
development, construction, testing, science and technology of aircraft and spacecraft.[1] It is divided into two major and overlapping
branches: aeronautical engineering and astronautical engineering. The former deals with aircraft
that operate in Earth's atmosphere, and the latter with spacecraft that operate
outside it.
Aerospace engineering deals with the design,
construction, and study of the science behind the forces and physical properties
of aircraft, rockets, flying craft, and spacecraft. The field also
covers their aerodynamic characteristics and behaviors, airfoil, control surfaces, lift, drag, and other properties.
Aeronautical engineering was the original term for the field. As flight
technology advanced to include craft operating in outer space, the broader term "aerospace engineering" has largely replaced it in
common usage.[2] Aerospace engineering, particularly the
astronautics branch, is often referred to colloquially as "rocket science",[3] although this is a popular misnomer.
The source of
this article was the Wikipedia on-line encyclopedia.
To see some
information from the Bureau of Labor Statistics, readers should follow the link
which appears below.
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Item 2.2; Chemical Engineering
Chemical engineering is the branch of engineering that applies the physical sciences (e.g., chemistry and physics) and/or life sciences (e.g. biology, microbiology and biochemistry) together with mathematics and economics to processes that convert raw materials or chemicals into more useful or valuable forms. In
addition, modern chemical engineers are also concerned with pioneering valuable
materials and related techniques – which are often essential to related fields
such as nanotechnology, fuel cells and biomedical engineering.[1] Within chemical engineering, two broad
subgroups include 1) design, manufacture, and operation of plants and machinery
in industrial chemical and related processes ("chemical process
engineers"); and 2) development of new or adapted substances for products
ranging from foods and beverages to cosmetics to cleaners to pharmaceutical
ingredients, among many other products ("chemical product
engineers").
The source of
this article was the Wikipedia on-line encyclopedia.
To see some
information from the Bureau of Labor Statistics, readers should follow the link
which appears below.
http://www.bls.gov/ooh/architecture-and-engineering/chemical-engineers.htm
______________________________________________________________
______________________________________________________________
Item 2.3; Civil Engineering
Civil engineering is a professional engineering discipline that
deals with the design, construction, and maintenance of the physical and
naturally built environment, including works like roads, bridges, canals, dams,
and buildings. Civil engineering is the oldest engineering discipline after
military engineering, and it was defined to distinguish non-military
engineering from military engineering. It is traditionally broken into several
sub-disciplines including environmental engineering, geotechnical engineering, geophysics, geodesy, control engineering, structural engineering, biomechanics, nanotechnology, transportation engineering, earth science, atmospheric sciences, forensic engineering, municipal or urban engineering, water resources engineering, materials engineering, coastal engineering, surveying, and construction engineering. Civil engineering takes place on all levels:
in the public sector from municipal through to national governments, and in the
private sector from individual homeowners through to international companies.
The source of this article was the
Wikipedia on-line encyclopedia.
To see some
information from the Bureau of Labor Statistics, readers should follow the link
which appears below.
Item 2.4; Electrical and Electronics Engineering
Electrical engineering is a field of engineering that generally deals with the study and
application of electricity, electronics, and electromagnetism. This field first became an identifiable
occupation in the latter half of the 19th century after commercialization of the
electric telegraph, the telephone, and electric power distribution and use. It now covers a wide
range of subfields including electronics, digital computers, power engineering, telecommunications, control systems, RF engineering, and signal processing.
Electrical engineering may include electronic engineering. Where a distinction is made, usually outside
of the United States, electrical engineering is considered to deal with the
problems associated with systems such as electric power transmission and electrical machines, whereas electronic engineering deals with the
study of electronic systems including computers, communication systems, integrated circuits, and radar.[1]
From a different point-of-view, electrical
engineers are usually concerned with using electricity to transmit electric power, while electronic engineers are concerned with
using electricity to process information. The subdisciplines can overlap, for
example, in the growth of power electronics, and the study of behavior of large electrical
grids under the control of digital computers and electronics.
The source of
this article was the Wikipedia on-line encyclopedia.
To see some
information from the Bureau of Labor Statistics, readers should follow the link
which appears below.
Item 2.5; Mechanical
Engineering
Mechanical engineering is a discipline of engineering that applies the principles of physics and materials science for analysis, design, manufacturing, and maintenance of mechanical systems. It is the branch of engineering that involves the production and
usage of heat and mechanical power for the design,
production, and operation of machines and tools. It is one of the oldest and broadest engineering disciplines.
The engineering field requires an understanding
of core concepts including mechanics, kinematics, thermodynamics, materials science, structural analysis, and electricity. Mechanical engineers use these core principles
along with tools like computer-aided engineering and product lifecycle
management to design and analyze manufacturing plants, industrial equipment and machinery, heating and cooling systems, transport systems, aircraft, watercraft, robotics, weapons, medical devices, and others.
Mechanical engineering emerged as a field during
the industrial revolution in Europe in the 18th century. However, its
development can be traced back several thousand years around the world.
Mechanical engineering science emerged in the 19th century as a result of
developments in the field of physics. The field has continually evolved to incorporate advancements in
technology, and mechanical engineers today are pursuing developments in such
fields as composites, mechatronics, and nanotechnology. Mechanical engineering overlaps with aerospace engineering, metallurgical engineering, civil engineering, electrical engineering, petroleum engineering, manufacturing engineering, chemical engineering, and other engineering disciplines to varying
amounts. Mechanical engineers also work in the field of Biomedical engineering, specifically with biomechanics, transport phenomena, biomechatronics, bionanotechnology and modeling of biological systems, like soft
tissue mechanics.
The source of this article was the Wikipedia
on-line dictionary.
To see some
information from the Bureau of Labor Statistics, readers should follow the link
which appears below.
Item 2.6; Nuclear
engineering
Nuclear engineers research and develop the processes,
instruments, and systems used to get benefits from nuclear energy and
radiation. Many of these engineers find industrial and medical uses for
radioactive materials—for example, in equipment used in medical diagnosis and
treatment.
Nuclear engineers typically work in offices; however, their work
setting varies with the industry in which they are employed. For example, those
employed by power generation and supply companies work in power plants.
The source of the
preceding article was the Bureau of Labor Statistics web site, and in order to
refer to some additional relevant information from the Bureau of Labor
Statistics, readers should follow the link which appears below.
Readers may use the following link to find a Wikipedia article
on this topic.
Item 2.7; Other engineering disciplines which do not appear
in this document
There are many
different engineering specialties, and they are all important. They do not all
appear here in this document because this is an early version of this draft.
Over a period of time, as more and more engineers and other writers contribute
their input, all disciplines can become included.
Section
3 – Utilities, public works, and the infrastructure
Item
3.1; Public safety in engineering and in utilities
Organizations such as the federal Department of
Transportation’s Office of Pipeline Safety interact with Public Service
Commissions and other regulatory bodies. The regulation of utilities,
protection of the public safety, and other non-profit concerns tend to fall
within the jurisdiction of engineers in the public sector.
Item 3.2; Reliability of the services of utilities
Some utilities
are publicly owned and operated, while others are privately owned and operated.
Regardless of the ownership, the customers expect (and deserve) to receive
electric power, natural gas, telephone service, and water and sewer service on
a reliable basis, and at a reasonable cost. Many of these concerns are
addressed by members of the engineering profession, so engineers should try
very hard to maximize the reliability of the services of all utilities.
Item 3.3; The United States Army Corps of Engineers
The U.S. Army Corps of Engineers has
approximately 37,000 dedicated civilians and soldiers delivering engineering
services to customers in more than 130 countries worldwide.
With environmental sustainability as a guiding
principle, this disciplined team is working diligently to strengthen national
security by building and maintaining America’s infrastructure and providing
military facilities where American service members train, work and live. The
Corps is involved with both civilian and military engineering projects. While
the Corps is researching and developing technology for military conflicts, the
Corps is also involved with peaceful domestic projects involving navigable
streams and rivers in the domestic United States. The Corps energizes the
economy by dredging America’s waterways to support the movement of critical
commodities and providing recreation opportunities at campgrounds, lakes and
marinas.
By devising hurricane and storm damage reduction
infrastructure, the Corps reduces risks from disasters.
The men and women of the United States Army
Corps of Engineers play a very special and unique role in the American
engineering profession. They are protecting and restoring the national
environment, and their projects include critical efforts in the Everglades, the
Louisiana coast, and along many of our nation’s major waterways. The
Corps is also cleaning sites contaminated with hazardous, toxic, or radioactive
wastes, and other material in an effort to protect the environment.
One of the web sites which features information
about the United States Army Corps of Engineers uses the following URL.
Item 3.4; Public works
Public works (or internal improvements historically
in the United States) are a broad category of infrastructure projects, financed and constructed by the government, for recreational, employment, and health and
safety uses in the greater community. They include public buildings (municipal buildings, schools, hospitals), transport infrastructure (roads, railroads, bridges, pipelines, canals, ports, airports), public spaces (public squares, parks, beaches), public services (water supply, sewage, electrical grid, dams), and other, usually long-term, physical assets and facilities. Though often interchangeable with public infrastructure and public capital, public works does not necessarily carry an
economic component, thereby being a broader term.
The
source of this article was the Wikipedia on-line dictionary.
Section
4 – An Alphabetical Listing of Some of the Major Engineering Societies and
Professional Organizations
Item
4.1; American Institute of Aeronautics and Astronautics (also called the AIAA)
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AIAA in
Brief
One Remarkable Fact Says
It All: Since 1963, members from
a single professional society have achieved virtually every milestone in modern
American flight. That society is the American Institute of Aeronautics and
Astronautics. With more than 35,000 individual members and 90
corporate members, AIAA is the world’s largest technical society dedicated to
the global aerospace profession. Created in 1963 by the merger of the two great
aerospace societies of the day, the American Rocket Society (founded in 1930 as
the American Interplanetary Society), and the Institute of the Aerospace
Sciences (established in 1933 as the Institute of the Aeronautical Sciences),
AIAA carries forth a proud tradition of more than 75 years of aerospace
leadership.
This is the place for everything, from exploring our history and purpose … to catching up on the latest news … Make sure you check out our prestigious Honors. Recognizing excellence is one the most important contributions we make. Welcome to the heart of aerospace. With 35,000 members, AIAA is the world’s largest professional society devoted to the progress of engineering and science in aviation, space, and defense. Serving this elite audience and its historic mission is our commitment and our privilege. Now we invite you to learn more about AIAA – and share in the vision and excitement of this inspiring industry.
This is the place for everything, from exploring our history and purpose … to catching up on the latest news … Make sure you check out our prestigious Honors. Recognizing excellence is one the most important contributions we make. Welcome to the heart of aerospace. With 35,000 members, AIAA is the world’s largest professional society devoted to the progress of engineering and science in aviation, space, and defense. Serving this elite audience and its historic mission is our commitment and our privilege. Now we invite you to learn more about AIAA – and share in the vision and excitement of this inspiring industry.
AIAA’s
Mission
AIAA’s mission is to address the professional needs and interests
of the past, current, and future aerospace workforce and to advance the state
of aerospace science, engineering, technology, operations, and policy to
benefit our global society.
You may learn more about the American Institute of Aeronautics and
Astronautics, or the AIAA, by visiting the web site which
uses the following URL.
www.aiaa.org
Item
4.2; The American Institute of Chemical Engineers, or the AIChe
The
AIChE is the world's leading organization for chemical engineering
professionals, with over 45,000 members from over 90 countries. AIChE has the
breadth of resources and expertise you need whether you are in core process
industries or emerging areas, such as nanobiotechnology.
As
a member, you can access information on recognized and promising chemical
engineering processes and methods. Connect with a global network of
intelligent, resourceful colleagues and their shared wisdom. Find learning
opportunities from recognized authorities. Move forward professionally with
AIChE and enrich the world we live in.
You may learn more about the American Institute of Chemical
Engineers, or the AIChE, by visiting the web site which uses the following URL.
Item 4.3; American Nuclear Society
The American
Nuclear Society is a not-for-profit, international, scientific and educational
organization. It was established by a group of individuals who recognized
the need to unify the professional activities within the diverse fields of
nuclear science and technology. December 11, 1954, marks the Society's
historic beginning at the National Academy of Sciences in Washington,
D.C. ANS has since developed a multifarious membership composed of
approximately 11,000 engineers, scientists, administrators, and educators
representing 1,600 plus corporations, educational institutions, and government
agencies. It is governed by four officers and a board of directors
elected by the membership.
Purpose: The core
purpose of ANS is to promote the awareness and understanding of the application
of nuclear science and technology.
Vision: ANS will be the recognized credible
advocate for advancing and promoting nuclear science and technology.
You may learn more about the American Nuclear Society, or
the ANS, by visiting the web site which uses the following URL.
www.ans.org
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Item 4.4; The American Society of Civil Engineers
When the twelve Founders gathered at the Croton
Aqueduct on November 5, 1852, and agreed to incorporate the American Society of
Civil Engineers and Architects, one can only wonder if they dreamed the
profound significance and long-lasting impact ASCE would have on the overall
development of society. They laid a foundation for what proves to be one of the
most prominent engineering societies in the world.
With projects such as the Croton Aqueduct in New York State, civil
engineers work to improve the lives of everyone.
Simply stated, civil engineers are creative, people-serving and
problem-solving leaders who make our lives easier to live from one day to the
next.
On June 16, 1981, the ASCE Metropolitan Section unveiled a plaque
on the site of ASCE's founding near the southwest corner of Chambers and Centre
Streets in City Hall Park. This plaque commemorates 1852 the meeting of this
small group of civil engineers that took place in the office of Alfred W.
Craven, then the eminent Chief Engineer of the Croton Aqueduct for the City of
New York. The Croton Aqueduct Department was located in the Rotunda Building,
which no longer exists.
As civil engineering begins a new millennium, the American Society
of Civil Engineers not only reflects on the profession's rich heritage, but
equipped with this knowledge, ASCE continues to develop flexible,
forward-thinking plans for the future of the society and the civil engineering
profession.
Today ASCE is a worldwide leader for excellence in civil
engineering. With a mission to advance professional knowledge and improve the
practice of civil engineering, ASCE is a focal point for the development and
transfer of research results, and technical policy and managerial information.
Through strategic emphasis in key areas, including infrastructure renewal and
development, policy leadership and professional development, ASCE delivers the
highest quality publications, programs and services to its worldwide membership,
demonstrating a daily commitment to sustaining the profession.
You may learn more about the American Society of Civil Engineers,
or the ASCE, by visiting the web site
which uses the following URL.
Item
4.5; The American Society of Mechanical Engineers
The ASME is a not-for-profit membership organization that enables
collaboration, knowledge sharing, career enrichment, and skills development
across all engineering disciplines, toward a goal of helping the global
engineering community develop solutions to benefit lives and livelihoods.
Founded in 1880 by a small group of leading industrialists, ASME has grown
through the decades to include more than 130,000 members in 158 countries.
Thirty-thousand of these members are students.
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From college students and early-career engineers to project
managers, corporate executives, researchers and academic leaders, ASME's
members are as diverse as the engineering community itself. ASME serves this
wide-ranging technical community through quality programs in continuing
education, training and professional development, codes and standards,
research, conferences and publications, government relations and other forms of
outreach.
You may learn more about the American Society of Mechanical
Engineers, or the ASME, by visiting the web site which uses the following URL.
Item 4.6; The Institute of Electrical
and Electronics Engineers, or the IEEE
The IEEE is an association dedicated to advancing innovation and
technological excellence for the benefit of humanity. The IEEE is the
world’s largest technical professional society. It is designed to serve
professionals involved in all aspects of the electrical, electronic and computing
fields and related areas of science and technology that underlie modern
civilization.
IEEE’s roots, however, go back to 1884 when electricity was just beginning to become a major force in society. There was one major established electrical industry, the telegraph, which—beginning in the 1840s—had come to connect the world with a communications system faster than the speed of transportation. A second major area had only barely gotten underway—electric power and light, originating in Thomas Edison’s inventions and his pioneering Pearl Street Station in New York.
IEEE’s roots, however, go back to 1884 when electricity was just beginning to become a major force in society. There was one major established electrical industry, the telegraph, which—beginning in the 1840s—had come to connect the world with a communications system faster than the speed of transportation. A second major area had only barely gotten underway—electric power and light, originating in Thomas Edison’s inventions and his pioneering Pearl Street Station in New York.
.jpg)
Meaning of "I-E-E-E"
IEEE, pronounced "Eye-triple-E", stands for the
Institute of Electrical and Electronics Engineers. The association is chartered
under this name and it is the full legal name.
However, as the world's largest technical professional association, IEEE's membership has long been composed of engineers, scientists, and allied professionals. These include computer scientists, software developers, information technology professionals, physicists, medical doctors, and many others in addition to our electrical and electronics engineering core. For this reason the organization no longer goes by the full name, except on legal business documents, and is referred to simply as IEEE.
However, as the world's largest technical professional association, IEEE's membership has long been composed of engineers, scientists, and allied professionals. These include computer scientists, software developers, information technology professionals, physicists, medical doctors, and many others in addition to our electrical and electronics engineering core. For this reason the organization no longer goes by the full name, except on legal business documents, and is referred to simply as IEEE.
Foundation of the AIEE
In the spring of 1884, a small group of individuals in the
electrical professions met in New York. They formed a new organization to
support professionals in their nascent field and to aid them in their
efforts to apply innovation for the betterment of humanity—the American
Institute of Electrical Engineers, or AIEE for short. That October the AIEE
held its first technical meeting in Philadelphia, Pa. Many early leaders, such
as founding President Norvin Green of Western Union, came from telegraphy.
Others, such as Thomas Edison, came from power, while Alexander
Graham Bell represented the newer telephone industry. As electric power spread
rapidly across the land—enhanced by innovations such as Nikola Tesla’s AC
Induction Motor, long distance AC transmission and large-scale power plants,
and commercialized by industries such as Westinghouse and General Electric—the
AIEE became increasingly focused on electrical power and its ability to change
people’s lives through the unprecedented products and services it could
deliver. There was a secondary focus on wired communication, both the telegraph
and the telephone. Through technical meetings, publications, and promotion of
standards, the AIEE led the growth of the electrical engineering profession,
while through local sections and student branches, it brought its benefits to
engineers in widespread places.
Foundation of the IRE
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A new industry arose beginning with Guglielmo Marconi’s wireless
telegraphy experiments at the turn of the century. What was originally called
“wireless” became radio with the electrical amplification possibilities
inherent in the vacuum tubes which evolved from John Fleming’s diode and Lee de
Forest’s triode. With the new industry came a new society in 1912, the Institute
of Radio Engineers.
The IRE was modeled on the AIEE, but was devoted to radio, and
then increasingly to electronics. It, too, furthered its profession by linking
its members through publications, standards and conferences, and encouraging
them to advance their industries by promoting innovation and excellence in the
emerging new products and services.
The Societies converge and merge
Through the help of leadership from the two societies, and with
the applications of its members’ innovations to industry and electricity wove
its way—decade by decade—more deeply into every corner of life—television,
radar, transistors, computers. Increasingly, the interests of the societies
overlapped.
Membership in both societies grew, but beginning in the 1940s, the
IRE grew faster and in 1957 became the larger group. On 1 January 1963, The
AIEE and the IRE merged to form the Institute of Electrical and Electronics
Engineers, or IEEE. At its formation, the IEEE had 150,000 members, 140,000 of
whom were in the United States.
Growth and globalization
Over the decades that followed, with IEEE’s continued leadership,
the societal roles of the technologies under its aegis continued to spread
across the world, and reach into more and more areas of people’s lives. The
professional groups and technical boards of the predecessor institutions
evolved into IEEE Societies. By the early 21st Century, IEEE served its members
and their interests with 38 societies; 130 journals, transactions and
magazines; more 300 conferences annually; and 900 active standards.
Since that time, computers evolved from massive mainframes to
desktop appliances to portable devices, all part of a global network connected
by satellites and then by fiber optics. IEEE’s fields of interest expanded well
beyond electrical/electronic engineering and computing into areas such as
micro- and nanotechnology, ultrasonics, bioengineering, robotics, electronic
materials, and many others. Electronics became ubiquitous—from jet cockpits to
industrial robots to medical imaging.
As technologies and the industries that developed them
increasingly transcended national boundaries, IEEE kept pace, becoming a truly
global institution which used the innovations of the practitioners it
represented in order to enhance its own excellence in delivering products and
services to members, industries, and the public at large. Publications and
educational programs were delivered online, as were member services such as
renewal and elections. By 2010, IEEE had over 395,000 members in 160 countries.
Through its worldwide network of geographical units, publications, web
services, and conferences, IEEE remains the world's largest
technical professional association.
You may learn more about the Institute of Electrical and
Electronics Engineers, or the IEEE, by visiting the web site which uses the
following URL.
Item 4.7; The National Society of
Professional Engineers
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In 1934, a group of professional engineers
met in New York City to establish an organization dedicated to the
non-technical concerns of licensed professional engineers. The National Society
of Professional Engineers stands today as the only national organization
committed to addressing the professional concerns of licensed PEs across all disciplines.
You may learn more about the National Society of Professional
Engineers, or the NSPE, by visiting the web site which uses the following URL.
Item 4.8; Other professional societies
which do not appear in this document
There are many other professional engineering societies, and they
have not all been included in this early version of this document. As time goes
on, and as this document evolves, it will become more complete. Eventually,
this document will include all of the professional engineering societies, but
at the present time, it does not.
Section
5 – Engineering employment
Item 5-1; Career One Stop, sponsored by the U.
S. Department of Labor
The following link will
take you to a good web site for information about various professions and
careers.
Once you follow this link,
you may click “Architecture and Engineering” at the top of the list, and you
will find a wealth of information about careers in engineering.
Item 5-2; Web sites which pertain to engineering
employment
There are many web sites
which pertain to engineering employment. The following list itemizes ten (10)
of them, but many, many more can be found on the internet.
Section 6- Engineering magazines and other technical publications
This listing should not be regarded as complete. In its present form, in evolutionary terms, it is simply an early version of an alphabetical listing of some of the magazines which are presently published by some of the major engineering societies and technical organizations. Over a period of time, this list should grow. There are many good and reputable technical publications which are not published by any engineering societies at all.
6.2; An alphabetical listing of some of the major engineering magazines and technical publications
6.2.1; Aerospace America magazine – published by the American Institute of Aeronautics and Astronautics
6.2.2; C.E.P. (or Chemical Engineering Progress) magazine – published by the American Institute of Chemical Engineers
6.2.3; Civil Engineering magazine – published by the American Society of Civil Engineers
6.2.4; Mechanical Engineering magazine – published by the American Society of Mechanical Engineers
6.2.5; P.E. (or Professional Engineer) magazine – published by the National Society of Professional Engineers
6.2.6; The Reporter – published by the American Public Works Association
6.2.7; Spectrum magazine – published by the Institute of Electrical and Electronics Engineers
The Contemporary Culture of the Engineering Profession
is in accordance with
~ Engineering Tribute To
The Presidential Inauguration ~
which is shown and presented under the
~ Engineering Tribute To
The Presidential Inauguration ~
which is shown and presented under the
The e-mail address for the site is
internationaldefinition@yahoo.com
Also here is his
" Engineering Tribute to the
Presidential Inauguration " site.
www.engineeringtribute.blogspot.com
" Engineering Tribute to the
Presidential Inauguration " site.
www.engineeringtribute.blogspot.com
engineeringtribute1@gmail.com
Here are the station schedules and viewing
times for the shows described above in the
~ Engineering Tribute To The Presidential Inauguration ~
Viewed in Fairfax County, Virginia on
Fairfax Public Access
2929 Eskridge Road
Suite S
Fairfax, VA 22031
http://www.fcac.org/
( Channel 30 )
Tuesday 7:00 A.M.
Saturday 4:00 P.M.
Also viewed in Montgomery County, Maryland on
Montgomery Public Access
(MY MC MEDIA)
http://www.mymcmedia.org/access-19/
Montgomery Community Television, Inc.
7548 Standish Place
Rockville, MD 20855
(301) 424-1730 phone
(301) 294-7476 fax
( Channel 19 )
Monday 10:00 A.M.
Thursday 8:30 P.M.
They will all be viewed under the 13 week
submission in which the station has for shows,
starting the week of September 22, 2014 until
December 22, 2014. Each of these programs will
be repeated for the coming scheduling period
between December 22, 2014 unto March 22, 2015.
Enjoy watching these shows on
~ Engineering Tribute To The Presidential Inauguration ~
under the show title of " International Definition ".
( IN HONOR & TRIBUTE TO PACHELBEL'S VERY WELL
ENGINEERED & ORCHESTRATED CANON in D , & AS
YOU SEE, FEEL & HEAR EACH & EVERYTHING WITHIN
THIS WONDROUS FANTASTIC UNIVERSE OF OURS . )
AND THUS YOU CAN NOT BUT HELP IN SEEING HOW
IN EVERYTHING, EVEN IN THOSE ENDEAVORS WE
HUMAN BEINGS CHOOSE AND CONTINUE TO DO, EVEN IN
OTHER FIELDS OF STUDY THAT THUS DO & ALWAYS HAVE
INTER-PLAYED WITH THE ENGINEERING PROFESSION.
FOR EVERYTHING IN LIFE MUST BE WELL " ENGINEERED" !
ENGINEERING TECHNOLOGY IN THE COMING FUTURE IS
NEEDED EVEN MORE SO IN THESE PRESENT TECHNICAL
TIMES. AND THUS IT IS STILL TO BE SEEN IF
TECHNOLOGICAL DEVELOPMENTS IN THE FUTURE
WILL BE ( UNLIKE OUR PRESENT TIME ) DEVELOPED TO
BE BETTER ENGINEERED AND BETTER MAINTAINED IN
THE UPCOMING UNCERTAIN DISTANT FUTURE THAT
STILL REMAINS AND AWAITS US ALL ? ! )
AND THUS YOU CAN NOT BUT HELP IN SEEING HOW
IN EVERYTHING, EVEN IN THOSE ENDEAVORS WE
HUMAN BEINGS CHOOSE AND CONTINUE TO DO, EVEN IN
OTHER FIELDS OF STUDY THAT THUS DO & ALWAYS HAVE
INTER-PLAYED WITH THE ENGINEERING PROFESSION.
FOR EVERYTHING IN LIFE MUST BE WELL " ENGINEERED" !
ENGINEERING TECHNOLOGY IN THE COMING FUTURE IS
NEEDED EVEN MORE SO IN THESE PRESENT TECHNICAL
TIMES. AND THUS IT IS STILL TO BE SEEN IF
TECHNOLOGICAL DEVELOPMENTS IN THE FUTURE
WILL BE ( UNLIKE OUR PRESENT TIME ) DEVELOPED TO
BE BETTER ENGINEERED AND BETTER MAINTAINED IN
THE UPCOMING UNCERTAIN DISTANT FUTURE THAT
STILL REMAINS AND AWAITS US ALL ? ! )
AN EPILOGUE TRIBUTE TO KENNETH W. FREELAIN
( Written & given forth in thanks & gratitude by Filippo Biondo )
( Picture above taken by Filippo Biondo of
Mr. Kenneth W. Freelain P.E. after helping him in a filming
of one of his weekly television shows at Catholic University )
Thus it's strangely curious, fascinatingly wondrous along
with philosophically adventure-filled how certain destined
meetings have a way of perhaps having & sharing the divine
knowledge and divine spirit to lift us up to new greater heights
of enlightenment much further beyond ourselves, be it by some
unknown but still secretly understood modus operandi which has it's
own certain way that distinguishes the distinct distance & calls out
to go but further beyond ourselves & our limited knowledge and to
achieve but an even greater form of excellence and new founded
definition of understanding, reason, enlightenment and moral conviction.
with philosophically adventure-filled how certain destined
meetings have a way of perhaps having & sharing the divine
knowledge and divine spirit to lift us up to new greater heights
of enlightenment much further beyond ourselves, be it by some
unknown but still secretly understood modus operandi which has it's
own certain way that distinguishes the distinct distance & calls out
to go but further beyond ourselves & our limited knowledge and to
achieve but an even greater form of excellence and new founded
definition of understanding, reason, enlightenment and moral conviction.
Thus to approach this excellent wondrous work of
Mr. Ken Freelain P.E., M.ASCE
from not only a historical & scientific point of view but from a
deep introspective philosophical point of view is thus to look
within & understand further the laws, statements & principals
that he has brought forth & expounded upon within his new
founded academic disciplines. So thus it has been a keenly
enlightening & a divinely awakening experience of mind & being.
Thus Mr. Kenneth W. Freelain P.E. along with his factual,
fantastic, interesting " Culture of the Engineering Profession "
brings a new and innovative reasoning "to believe in excellence"
& an open invitation to join us in exploring new, innovative,
enhanced ways of thinking, defining, behaving and reasoning.
Thus we strive to excel, to achieve and to solemnly believe in...
brings a new and innovative reasoning "to believe in excellence"
& an open invitation to join us in exploring new, innovative,
enhanced ways of thinking, defining, behaving and reasoning.
Thus we strive to excel, to achieve and to solemnly believe in...
(ONCE AGAIN IN CLOSING, THIS EPILOGUE WAS WRITTEN
BY FILIPPO BIONDO IN APPRECIATION AND IN TRIBUTE
TO HIS OUTSTANDING WORK & INNOVATIVE KNOWLEDGE.
( " THIS EPILOGUE ALSO WAS READ & GIVEN APPROVAL
BY KENNETH W. FREELAIN P.E., M. ASCE HIMSELF. " )
& THUS HIS WORK WILL CONTINUE ON INTO THE...
COMING FUTURE DISTANCE & BEYOND ! & INTO AREAS
& UNDERSTANDINGS BEYOND WHAT WE KNOW TODAY )
Thus Enter Into...
http://www.internationaldefinition.blogspot.com/
INTERNATIONAL DEFINITION
The Cultural Enrichment Committees in accordance with "International Definition" is a non-profit organization representing an advancement in scientific evolutionary definitions & new innovative terminologies. And thus through this newly founded academic discipline bring forth a series of thought provoking questions that need to be reasoned out and scientifically answered, for the enhancement & enrichment of all earth's diverse human beings.
Also Enter Into Kenneth W. Freelain P.E., M.ASCE
" Engineering Tribute To The Presidential Inauguration "
Info On "The Engineering Tribute"
The "Engineering Tribute to the Presidential Inauguration"
is the name of a ceremony which takes place in conjunction with the
inauguration of each President of the USA.
Because the "Engineering Tribute to the Presidential Inauguration"
takes place in conjunction with the inauguration of each American president, it occurs once every four (4) years, during those years
which follow the year of the Presidential Election.
Sometimes it lasts for more than one day, in order to allow
all of the speakers to be videotaped for television.
When such extensions of time are required, they are usually
necessary in order to provide flexibility in the schedules
of both the speakers and the television crews.
In its shortened form, the
"Engineering Tribute to the Presidential Inauguration"
is simply called the "Engineering Tribute".
is the name of a ceremony which takes place in conjunction with the
inauguration of each President of the USA.
Because the "Engineering Tribute to the Presidential Inauguration"
takes place in conjunction with the inauguration of each American president, it occurs once every four (4) years, during those years
Sometimes it lasts for more than one day, in order to allow
all of the speakers to be videotaped for television.
When such extensions of time are required, they are usually
necessary in order to provide flexibility in the schedules
of both the speakers and the television crews.
In its shortened form, the
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