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The Engineering Technologist· :, : ,i ;, By F. H. BABET" ,. (18th Annual Technical ]lIeeting, The Pet"ole",,, Society of CIM, Banff, Albel·ta, ;IIay, 1967) Downloaded from http://onepetro.org/jcpt/article-pdf/7/01/17/2166819/petsoc-68-01-03.pdf by guest on 24 September 2021
" ABSTRACT Some of the engineering tech HIGH SCI'JXIL HIGH SCHOOL The engineering technologist can be nologies are designed with three ,,","Troll ""m,,, ''''''''''I'''''''''' utilized to relieve the engineer of different programs (Figu,re 1) _ many of the tasks which the latter Students graduating from an artic may regard as being mundane. This ulated' vooational higb-sohool pro 'j paper describes the training of en gineering technologists. points out gram enter directl}" to year UB" at their capabilities and suggests areas NAlT. This is the standal'd two in which they can be effective in re year post-high-school technology ducing'-the engineering work load. program. Students who have fol f .. lowed the academic high-school UI D = program have had no vocational courses. These students may enter INTRODUCTION NAIT after completing either grade XI 01' grade XII. If they en l~ THE ENGINEERING TECHNOLOGIST ter the three-year program, they SOCIETY OF ALBERTA defines a receive instruction in some grade technologist as an individual who XII subjects and in tbe equivalent has completed two years of·post of the high-scbool vocational sub high-school education and has had jects in year "A". They then enter [J two or more years of related ex year "B" at the same level as those Figure 1.-E1lgineeri7lg Technology perience. This is quite similar to students 'who graduated from the Prog1'ams the requirements for registration vocational high schools. Students under otber departments within the as a Professional Engineer_ The who enter NAIT witb a 55 per cent Technology Division of the school. ·formation of the Engineering academic high-school average may NAIT is organized into four Technologist Society was initiated enroll in the year HAB". This is a divisions: Technology, Business and guided hy members of the As longer, accelerated year in which and Vocational Education, Exten '.'., ..,::'" sociation of Professional Engi students receive instruction equiva sion, and Industrial. The scope of ,.~ . neers. lent to the vocational subject mat this presentation does not allow de ter offered in year "A" and year tailed discussion of the latter three ENTRANCE REQUIREMENTS "B". Year "e" is common to all divisions, but it should be pointed students in the course. out that there are many courses of Entrance to most of the two-~~ear fered in these divisions which pro post-high-school engineering tech ORGANIZATION OF NAIT duce graduates which could prove nolog:y programs can be obtained to be assets to many oil and gas in by stndents who have a high-scbool At the time of writing, NAIT dustry activities. A few examples offered a total of 27 technology ) diploma with a uB" standing in of the courses and corresponding \. Matbematics 30 or 32, and credit courses. \Vhen the school opened in employee classifications which 1962, there were 16 technologies_ .' in Physics 30 or 32 or Chemistry could be of interest to petroleum f-~-~:~' 30. Tbese requirements vary slight New programs are designed and of ! industry recruiters are: Data Pro ~;, ., I b~ from program to program, de fered as industrial demand dic cessing (machine operators and , pendent upon the kind of engineer tates_ The technologies from which programmers), Chemistry (labora 1, the oil and gas industry draws the I ing technology which the entrant tOr)' analysts), and Heavy Duty ~f~ wisbes to study. The physics and bulk of its technological employees (gas plant operators). .~. ~ ! chemistry courses offered at NAIT, are those known as the Engineer wbich follow the grade XII courses ing Sciences Technologies. ·These on similar subjects, are designed to include Civil, Instrumentation, *At time of writing - Head. hold the interest of those students Drafting, Architectural, Snrveying, Gas Teohnology, No,"then, Albe·,.ta wbo bave grade XII credit and si Materials, Plastics and Gas_ The re ["",t. of Technology, Edmonton, multaneously impart new knowl mainder of the 27 technologies are Alta. edge to the students who are en~ Now employed as - Gas En lA vocational high-school program de countering the subject matter for signed specifically for entrance to a ginee,', Shell Canark Ltd., Calga;ry, the first time. pal'ticula-r technology course. Alta.
Technology, January-March, 1968, Montreal 17 }[any of the general public be gineers and some carryon an active example, could enter the employ of lieve that a technical institute is a consulting practice. the gas processing industry, the trade school. This is not the case petro-chemical manufacturing in in Alberta. Training in the 26 ap CURRICULUM dustry or the pulp and paper indus prenticeable trades is performed on hS. A technologist, on the other the Institute campus within the In Rach year of a two- or thl'ee hand. would find it ver:r difficult dustrial Division, but they are en year technology program consists to utilize his knOWledge of gas be tirely different kinds of courses of three 10- to 12-week quarters. haviour in the production problems than those which are being dis The pass mark for each course is of paper manufacturing. As an il cussed in this presentation_ 50 per cent, and supplemental e:t lustration of the degree of special amin<.ltions may be '\\Titten_ A stu To be certain that the teehnol ization pl"esent in the techllolog~' dent must pass efl.ch of the quar ogy graduates are satisfying the curriculae, Gas Technolog}r stu ter subject courses taken at N AIT needs of industry. ear.h program dents l"eceive 440 hours of instruc to obtain a diploma, has an advisory committee. This tion in gas processing alit of a total A typical technology course is group meets once a year to review of 1800 hours of instruction in fl the Gas Technology course, in the curriculum, graduate success two-.vear cOUrse. which the students take mathemat and other criteria pertinent to the As a further illustration of the ics, chemistry, physics, drafting, maintenanc.e of a technology pl-O relationship between the education english, surveying, statics, strength gram which is cognizant of the lat of engineers and technDlogi~ts, and of materials, computer program Downloaded from http://onepetro.org/jcpt/article-pdf/7/01/17/2166819/petsoc-68-01-03.pdf by guest on 24 September 2021 est industrial developments and re the ~pecific abilities of technolo rning, thermodynamics, instrumen quirements. A typical technology gists, Gas Technology students are tation and, of course, gas technol advisory committee consists of required to estimate the required ogy. The weight in the gas tech chief engineel"s, department man capital investment of 3 complete nology program i~ on chemistry agers or production superintend gas pL'ocessing plant during their and the gas processing subjeds. ent,:.; of six or seven of the more last quarter of the program. This The course content is under con pl"(lminent companies in the indus project inc.ludes the determination stant revision to keep abreast of tI-y which employ the majority of of the processes required to pro the technology's graduates. industrial development.s. For ex duce specific products, size esti ample, a course in computer pro mates of all equipment sLlch as ves gramming was added to the Gas sels. pumps, exchangers and utili THE PLANT AND STAF'F Technology curriculum when it was ties. and finally the calculation of found that many of the graduates The Institute is situat~d on a the total estimated cost of cOllstruc were involved in computer utiliZll :~G-acre space. 20 acres of which ing the plant. tion in their industrial positions as was under roof at the time of writ The Instit.ute is operated as much engineering technologisbL ing. Additions to the facilities are as po~sible in an industrial setting. being made constantly in an at F£gnre 2 illustrates the differ This is necessitated by the fact thnt tempt to meet the educatlonal re ence between the educational train students mus.t, in the short period quirements of students and indus ing of a teehnologist and that of of two years. progress from hig-h try. Capital investment for the an engineer. An engineer, in at school graduates to immediately plant ayerages one million dollars tending university for four years, employable engineering technolo per aCl-e of floor spaee for build studies in depth the same subjects gists. In most instances, company ings and equipment. This capital that a technologist studies at a training progl·ams for technolo was shared, initially, 75 per cent more shallow level. The engineer's gists are relatively short compared by the federal government and 25 area of education covers the whole to those required fOf engineers. p~r cent by the provincial govern of Figure 2; that of the technolo This is becHllse of theil' spc ment, under the pH.visions of the gist covets only the left half of the c.ialized training in a particular F't'de1·al Focationul a:nd Technical figure. This arrangement is neces technologJ'. The training pl'ogrnm l~'du..cation Act. Each technology has sitated bl' the fact that the tech is also reduced by virtue of the fuct laboratory facilities whieh vary in nologist must work in the same that most students spend three to value from $50.000 to $250.000. subject area as the engineer, but four months working in industrj! The majority of the staff at the not usually at the same relatively between their first and second year Institute hold Bachelors or Masters high level. The technologist must of Institute education. degrees in their field and have had be capable of understanding the basic principles to which the engi an average of at least five years PROGRAM PURPOSE of industrial experience. Some of neer will often refer. Consider, for the staff hold Ph.D. degrees, not example, a heat exchange calcula 'I'he main purpose of the tech· ably in the chemistry section. 'Man3' tion. The engineer would be taught nology programs at NAIT is to of the instructors and administra to determine design coefficients produce n technologist who is nl tors are registered professional en- which take into account each of the most immediatelY employable as an individual resistances encountered assistant to an engineer. Norma in the flow of heat from the hot to Iy. the technologist is JloL in com the cold medium, such as fluid film, petition with engineer~, although scale, tube watl, etc. The technolo some of the top technology gradu gist, although he is made aware of ates appear to be capable of han these parameters, is also taught to dling higher level responsibilities, design on the basis of an over-all Further to this observation heat exchange coefficient, depend many technologists are presently ent upon the conditions present. writing the professional engineer o 1 , , 4 The technologies are more spe ing examinations. n:AJlS OF mm:.I."_'lQ! cialized than are engineering An articulated program is no'\' Figure 2.--Educatiollul TrailLlng. courses. A chemical engineer, for being attempted by the University
18 The Journal af Canadian Petroleum ------~-,.~-~--'-- '.' - .: . :~- ---
-, , of Alberta and other universities (4) supervise construction acth"i CONCLUSION throughout Canada and -the United tiesj States wherein top teChnology (5) assist in the preparation of In conclusion. the engineering -, graduates are admitted to the sec recommendation reports and shortage problem, which has been ond year of engineering. No re-· plant performance tests; and widely publicized during the past suIts of this trial are available at (6) sllp~rvi::je field operations. few years, can, in part: be solved r· present. - by the effective utilization of qual The Institute programs do not The technologist can relieve the ified technologists. This creates engi~ ,- compete with university programs; engineer of many of the mundane another problem, in that the they complement them, in that they engineering tasks. In many in neer must now become a small produce graduates who can work stances, the technologist will be scale manager. He must be capable with engineers to increase the challenged by working out solu of organizing and directing the ac over-all efficiency of any engineer tions to problems which may only tions o,f one or more engineeJ.:ing ing section of an industrial organ bore an engineer. With the proper technologists. Ideally, the engineer ization. The aim of technical utilization of technologists, the en should now be able to (1) define a institutes is to produce a first-rate gineer should he left with more problem, (2) determine all of the technologist, not a second-rate en time for creative thought, organ possible alternate solution methods gineer. ization of efforts and new plans of (3) analyze the solutions prOvided Downloaded from http://onepetro.org/jcpt/article-pdf/7/01/17/2166819/petsoc-68-01-03.pdf by guest on 24 September 2021 action. The foremost user of tech by the technologist and, finally (4) supply his supervisor with the UTILIZATION OF TECHNOLOGISTS nologists in Alberta is aiming for one technologist for each engineer. justified best possible solution to A technologist can utilize the In the United States! some organ the problenL pl-inciples and theories ,,,hieh have izations are aiming for as many as been developed by engineers, but four technologists per engineer. he is not normally concerned with Technologists, as with engineers, the development of new theories or must be challenged by their work. techniques - this is the role of the Otherwise, they become bored and engineer_ The division line between begin looking for more responsible the capabilities of engineers and positions in the industry. Every technologists is not that definite man likes to utilize his education bu~ the foregoing relationship usu~ and training - technologists are ally prevails. no exception_ Of the 15 Gas Tech In the gas indllstrJr, technologists nologists who graduated in 1965__ can be used, in some cases after a onl)' 6 are in the employ of the short training period, to: campan]" with whom the}r accept (1) conduct and calculate AOFP ed employment subsequent to grad determinations; uation. These companies have rec Fred H. Babet was born in Edmonton ognized the value of technologists and attended high sc~oo[ in Calgary. " (2) perform gas plant design cal .,~ culations including vessel siz and are utilizing them to the mu He then entered the University of Okla homa, graduating with 0 B.Sc. in pe -.' ing, flash calculations, absorb tual benefit and satisfaction of both employee and employer_ troleum engineering in 1957. After er calculations, heat exchanger groduotion, and until 19621 he was em sizing and almost any other During the past three years, the ployed by British American Oil as a pro duction engineer. From 1962 to 1967 mathematical manipulation starting salary of Gas Technolog}r he was in government service as head which may be encountered in graduates has averaged 85 per cent of gas technology at the Northern Al the design of processing of the starting salaries paid to en berto Institute of Technology in Edmon plants; gineering graduates. The gradu ton. He is nOW gas engineer, special projects, with Shell Canada Limited in (3) perform economic investiga ates of other technologies at NAIT Calgary. tions such as cost reduction or have enjoyed a similar degree of corrosion programs; industrial acceptance.
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Technology, January_March, 1968, Montreal 19