restricted i) arab republic undp/egy/81/007...
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Restricted UNDP/EGY/73/041 (Phase I) UNDP/EGY/81/007 (Phase II) Terminal Report
ARAB REPUBLIC OF EGYPT
Centre for Advancement of Postgraduate Studies in Engineering Sciences, Cairo University (Phase I) Centre of Engineering Research and Training, Cairo University (Phase II)
Project Findings and Recommendations
Serial No. FM R/SC/OPS/84/229( UN DP)
United Nations Educational, United Nations Scientific and Cultural Development Organization Programme
Paris, 1984
ARAB REPUBLIC OF EGYPT
Centre for Advancement of Postgraduate Studies in Engineering Sciences, Cairo University (Phase I)
Centre of Engineering Research and Training, h Cairo University (Phase 11)
Project Findings and Recommendations
Report prepared for the .Government of the Arab Republic of Egypt by the United Nations Educational, Scientific and Cultural Organization
for the United Nations Development Programme (UNDP)
. (Unesco) acting as Executing Agency
United Nations Educational, Scientific and Cultural Organization
United Nations Development Programme
UNDTJ/EGY/73/041 (Phase I) u~~~/~cY/81/007 (Phase 11) Terminal Report FMR/ SC/Q PS/ 84/ 2 2 9 ( UND P ) 25 June 1984 @ Unesco 1984 Printed in France
TABLE OF CONTENTS
Paragraphs
I. INTRODUCTION
Project Backgroud
11. PROJECT OBJECTIVES
A. OBJIZCTIW OF PHASE I OF THE PROJECT Bo OBJECTIVES OF PHASE I1 OF THE PROJECT
111. MAIN ACTIVITIES AND OUTPUT
IT. THE CEFTRE AM> INDUSTRY CO4PERATION
v. ACHIEYEMENT OF IMMEDIATE OBJECTIVES
VI. RECOMMENDATIONS
APPENDICES
APPEM)IX A - Unesco Egperts and Consultants APPENDIX B - Counterpart Staff APPEmDIX C - Study TOUS
(1 - 6) 1 - 6
(7 - 9) 7
8 - 9
(11 - 20) (21 - 24) (25 - 30)
APPWIX D - Intensive Short Courses for Ehgineers from Industry APPENDIX E - Long-term Courses Offered in the Postgraduate Propamme
ZGY/73/041 (Phase I) - Centre for Advancement of Postgraduate Studies in Ehgineering Sciences, Cairo University
Centre of Engineering Research and Training, Cairo University
%Y/81/007 (Phase 11) -
TERMINAL REPORT
I. INTRODUCTION
Pro,ject Background
1. To assure wellqalified teachers at the postgraduate level and to maintain the quality of research, the law in the Arab Republic of Egypt (A.R.E) requires university professors to have postgraduate degrees. However, due to lack of research facilities in the universities, it has in the past been difficult to obtain such a degree, with the result that the number of qualified teachers was limited and the ratio of students to teachers was inordinately high. To overcome this, the Government provided a large number of' fellowships to train graduates abroad. Yet, apart from the heavy drain on the country's hard currency reserve, this programme was not totally satisfactory. Consequently, the Government decided to upgrade both university research facilities and the postgraduate programme.
2. committed it self, the Government decided that every technical training institution in the country should support this effort. It also decided that the postgraduate programme at the Ehgineering Faculty of Cairo University should be oriented towards the solution of industrial problems. Co-operation between universities and industries had previously been unsuccessful €or two reasons. One was that the A.R.E*s major industries worked under licence agreements with foreign parent firms and thus these was little chance they would perform industrial research locally. The Government wanted these industries to be independent after these agreemen% expired and wanted the country to be prepared to tackle its own industrial problems in order to increase industrial production. The other reason for poor industry/university co-operat ion was the universities' lack of qualified teachers, researchers and modern facilities.
Keeping in mind the vast industrialization to which the A.R.E. has
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30 A request for Technical Assistance was, therefore, submitted to UNDP in 1973, to overcome these bottlenecks. The project document for Phase I, "Centre for Advancement of Postgraduate Studies in Ehgineering Sciences, Cairo University", was drawn up and signed by UNDP and the Government on 23 September 1974 and by Unesco, as Executing Agency, on 25 November 1974. equipment, study tour programmes and experts. The Government was to provide L.E. 872,140 in kind, in the form of space for the project, national faculty and staff and L.E. 52,000, in cash, for the renovation work and remuneration of those who would participate in the project. Activities began in October 1975 with the appointment of the Chief Technical Adviser, an expert in heat transfer and national professors in heat transfer, combustion, fluid mechanics and solid mechanics. The gzoject was to be an autanomoua .body under the supervision of Cairo University's Vice-President for postgraduate studies and research. The objectives were to upgrade the postgraduate programme, orient the research towards industrial or practical problems and institutionalize the relations with industry.
UNDP ageed to provide US$ 640,000 for
h
4. A long time was taken in deciding whether the equipment received, should be installed in. existing laboratories or at a central place. building took longer than expected. Due to a financial crisis in 1976, UNDP had to
~ reduce its contribution and as a result the required equipment could not be procured on schedule. In addition, the number of participating experts was reduced and short-term consultants were engaged for periods of a month or less, and for very specific purposes.
The project had many initial problems.
After this had been settled the modification of the allotted
These problems meant that it was not possible to attain all the . objectives as laid down in the original project document by the end of the prescribed period of four years and ten months. until. the end of 1981. graduate programme was upgraded by the combined efforts of visiting consultants and national professors. engineers from industry. started in the Centre. contribution was US$ 933,424 and the Government's cash contribution amounted to L.E, 92,379. importance for research and training had been fully recograized, the project could achieve its long-term objectives, further technical assistance in the form of a Second Phase was recommended and subsequently approved.
5. Research and Training, Cairo University) was signed on 28 January 1982 by the Government and Unesco and on 28 February 1982 by UNDP. of activity, with a total UNDP input of US$ 446,700 and a Government contribution of L.E. 45,000 in cash and L.E. 32,000 in kind. subsequent-ly and at the end of Phase I1 bTmDP had contributed US$ 399,968 and the Government L.E. 43,550 in cash.
Hence, the project was extended During the extension equipment was installed and the post-
Intensive short courses were developed and offered for Three contracted industrial. research projects were
By the endb of Phase I of the project, the total UNDP
As it appeared likely that, given time and once the Centre's
The project document for Phase I1 (EGY/81/007 - Centre of Ehgineering It provided for two years
These figures were modified
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60 During Phase I1 consolidation of the central research facilities took place with more modern equipment to cater for postgraduate work and industrial consulting. More industrially-oriented research projects were begun as master and doctoral degree theses, Well-planned short courses were offered to engineers from industry. Some of the contracted industrial research projects were completed and more contracted research projects were started, During an evaluation meeting in this period, it was observed that the unit system of operation did not help to attract more industrial projects, while much time was consumed in completing contracts due to industry's administrative procedures. To overcome these diffi- culties, administrative changes were made in the operation of the Centre and the
Centre started obtaining consulting projects from other funding agencies such as the Academy of Scientific Research and Technology and US AID, to establish good contacts with local industries through short courses and contracted consulting projects. As a result of these two principal activities, the Centre is now able to continue its activities without any external support,
1
6 Board membership was modified to include high-level Government authorities. The
The Centre was able
11. PROJECT OEJECTIVES
A. OBJECTIVES OF PHASE I OF THE PROJECT (EGY/73/041)
7. graduate Studies in Engineering Sciences", had the following long-range and immediate objectives:
The project EGY/73/041, designated as Ventre for Advancement of' Post-
Long-range objectives :
To train postgraduates in engineering sciences with an industrial orientation in order to supply the demand of the research and develop- ment laboratories of industrial organizations of the A.R.E. and other Arab States, The project would also develop research and testing laboratories which could expediently and efficiently solve industrial problems of local industries. Thus, close co-operation with national industry for the application and adaptation of modern technology would be established,
Immediate objectives :
(i) To train graduate engineering science students in industrial and applied research for masters' degrees in their respective disciplines and eventually doctoral degrees so that they could qualify for positions in universities in the A.R.E. and other Arab States.
(ii) To install and operate training and research laboratories in heat transfer, combustion, fluid mechanics and solid mechanics in the Faculty of Engineering at Cairo University, laboratories should cater to the needs of postgraduate research and industrial consulting.
These
. . . . . . . . .
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(iii) To survey the needs of national industry in order to identify problems adversely affecting its development, and to propose and implement programmes for the solution of these problems with the support of the industrial sector.
(iv) To establish, in co-ordination with other scientific indus- trial projects assisted. by UNDP in- th-e A.R.E., a programme to make better h o r n the services offered. by the Centre at Cairo University.
B.
The project EGY/81/007, designated as "Centre for Ehgineering Research
OBJECTIVES OF PHASE I1 OF THE PROJECT (EGY/81/007)
8. and Training", had the following long-range and immediate obj'ectives:
Long-range objectives :
To improve and increase industrial productivity through manpower development.
Immediate ob j ectives :
(i) To consolidate research facilities in heat transfer, combustion, fluid mechanics and solid mechanics.
(ii)
(iii) To increase productivity in selected industries.
(iv)
(v)
To carry out industrially-oriented research projects.
To train engineers from industry to sxLt industrial needs.
To strengthen links between the Centre and other similar centres in the A.R.E. and abroad.
9. establishing links With local industry.
The project thus had the dual purpose of institution-building and
111. MAIN ACTIVITIES AND OUTPUT f
10. carried out:
To attain the objectives of this project, the following activities were i
(a) Central research facilities were developed for research in heat transfer, combustion, fluid mechanics and solid mechanics at a cost of US$ 566,000. research and industrial consulting. Modern equipment was installed in the laboratories as follows:
These facilities are now used for both postgraduate
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Heat transfer laboratory: potentiometers, wattmeters, power -variacs, precision pyranometer, scaling digital voltmeter, helium-neon gas laser and data logger.
Internal combustion laboratory: high-speed camera, peak pressure indi- cator, heat pipes, quartz windows, oscilloscopes, stroboscope, window glasses , Schlieren apparatus, pressure transducers, diesel smooheter, temperature measuring units, electronic measuring units and dynamometer .
2 Continuous combustion laboratory: infra-red gas analyser for CO, CO and oxygen analysers, micromanometers, sulphur oxide analyser and ceramic tubes.
Fluid mechanics laboratory: 300 Kw compressor unit, rotameters, optical bench, lenses, hotwire anemometer, pressure probes, stereo-microscope, micromanometers, 5-hole pitot tubes, special measuring devices, venturi tubes, solarimeter, torsion dynamomet&, rnultimeters, projection micro- manometers and sound-level meter.
Solid mechanics laboratory:.vibration-testing analysing recording units, ion plating unit, polariscope, demonstration polariscope, strain- measuring unit, ultrasonic flaw detector and hydraulic power unit.
All these laboratories are now being well used for postgraduate research and industrial consulting.
(b) A small library was established with about 100 modern technical books and eleven advanced technical journals which are referred to constantly by postgraduate students.
(c) Two experts and 20 short-term consultants were assigned to this project and completed the efforts of national professors in fulfilling project activities, The experts offered long-term courses as part of the postgraduate programme in radiating heat transfer, gas dynamics, mechanical vibrations and applied mechanical vibrations, with the objective of improving the course content foy industrial applications. in most of the courses.
This -trend is now continuing
(d) Five postgraduate courses were developed with the objective of upgrading them with more industrial applications. This trend is continuing in most of the postgraduate courses.
(e) Twenty-four intensive short courses (one month each) were developed Some of these and resulted in the training of about 750 engineers.
courses were requested by high-level enginews from industry to suit their needs.
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(f) Forty-two study tour programmes were organized for Faculty members participating in the project to Visit research institutions, labora- tories and industries in Europe and the United States of America.
conferences/ s eminm s
(9) A conference on mechanical power engineering was held in February 1977, and a Cairo University conference on mechanical design and production was held in December 1979, for which the Centre provided finanaal support. These conferences were the first of their kind and now are held once every two years, A one-day seminar was held on 2 August 1978, in the course of which the Egyptian sector of the Combustion Institute was established.
(h) About 50 industrially-oriented research projects were conducted as masters' and doctoral theses, using the Centre's central research facilities. employment in the A.R.E. universities and in industry,
The 50 students who participated are well-suited for
(i) The following industrial research and development projects were undertaken:
- rational utilization of fuel in industry and reduction of the ill effects of excess sulphur in local fuels; - testing of facilities for diesel engines; - design modification of diesel engines; - minimization of wear in the cylinders of railway diesel
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engines ; - minimization of wear in phosphate pumps; - optimization of the design of railway coaches; - noise reduction in window-type air-conditionen, PV. THE CENTXE AND INDUSTRY CO-OPERATION
A, INDUSTRIAL PROBLEMS
Several industries in and around Cero were visited by the Director and 11, his colleagues, the experts and consultants to survey the problems facing industry. Five problems were identified and contracts were signed between the Centre and the industries concerned to solve these problems. tants were also involved in solving industrial problems financed by other agencies such as the Academy of Scientific Research and Technology and US AID. foll.owing is a brief description of these industrial problem.
i
Members of the Centre and consul-
The
. . .
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Rational utilization of fuel in industry and reduction of ill-effects of sulphur in local fuels (contracted with the Ministry of Electricity and Power)
Combustion monitoring instruments (CO, CO and O2 analysers) are not 2 12. used in industry and it was observed that boilers and furnaces were operated at unnecessarily high excess air levels, with a consequent loss of overall efficiency. The wasted fuel represented on a national basis some 50 million pounds per year (in the opinion of the consultant who visited the project and some of the industries). To solve this problem, continual visits were made to power stations in and around Cairo to suggest methods to improve boiler efficiency and output by properly adjusting the air-fuel ratio. The procedure was first to stop any air leakage in the boiler body by a process of gas analysis so that all the air would be involved in burning fuel. When the air-fuel ratio was properly adjusted, the efficiency of the boiler was increased to its design value. increased the boiler's efficiency by 3077. The Dew Point Meter was used for exact adjustment of the air-fuel ratio, The effects of various additives to fuel were studied in special test rigs installed in the Continuous Combustion Laboratory so that ill-effects of sulphur present in local fuels could be minimized.
\
This process
13 As a result of this contracted research, both the output and the efficiency of one of the four Cairo power stations, Cairo South, were raised. The immediate outcome was that the Ministry of Electricity and Energy decided not to buy gas turbine generating units costing 30 million pounds, because they were no longer needed to meet the power demand,
Testing facilities for diesel engines (contracted with the Diesel Engine Factory, Helwan)
14 The Diesel Engine Factory was in need of facilities for routine testing of engines before they were sold. A list of specifications was prepared and the units bought and installed. Testing procedures and test sheets were prepared and the factory engineers trained in using the equipment. control in the factory. version was also required, Studies revealed that it was uneconomical to redesign the exkting engine, so a new version with supercharging was recommended.
This improved quality Be-design of the existing engine into a supercharged
Minimization of wear in the. cylinders- of railway diesel engines (contracted with the Egyptian Railway Authority)
'k 15. Wear in the cylinder liners of railway diesel engines was reported to be double that in the same engine types operating outside Egypt. A special tool was designed to measure the wear in the cylinder liners at different sections. About 120 cylinders were examined to define the wear area, Samples were prepared and examined under the microscope to differentiate between mechanical wear and corrosion wear. carbon residue and ash content. The effects of var-ious additives to fuel were
Complete analysis was carried out to define mainly sulphur, gwn,
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studied to miriimize corrosion wear. The filtering system was examined to minimize mechanical wear. All these findings helped to increase the life of diesel engines in railways.
Modification of diesel engine (contracted for Factory No . 909, ' Helwan) 16. Locally-produced diesel engines, with two flywheels, had problems concerning the governing system, lubrication and ribrations and thus could not compete with imported modern engines on the market. Some parts of this engine were redesigned and modified to minimize the above defects. The main modifica- tion was to have a single flywheel to save material and improve balancing. Vibration tests showed improvement in the new design and the factory agreed to produce this modified engine.
Minimization of wear in two-phase phosphate pumps (contracted with The Phosphate Company, Hamrawen)
17. The Phosphate Company uses centrifugal pumps for transferring phosphate between sections. High phosphate-to-water ratios, high pressure ratios and salt water are used. The pumps were experiencing severe wear under these difficult operating conditions, which increased maintenance costs and decreased productiv- ity. To minimize pump wear and consequently maintenance costs, a new screen system was designed using the cyclone principle to separate phosphate, which flows downward, while the water flows upward to the suction side of the pump. pressurized water will flow through the ejector, creating negative pressure to suck up the separated phosphate again. instruments and is undergoing tests of its effectiveness before its use is recommended to the factory.
The
This screen system is fitted with
To optimize the design of railway coaches and to develop facilities to test coaches (financed by the Academy of Scientific Research and Technology to SEMAF Co., Helwan)
18. of modern design methodology and facilities to test the coach. In order to save material, stress analysis of various members in the side-frame and bottom-frames is to be carried out by the finite element method, using very accurate values for the section properties of these members. The number of sections of members that are exposed only to light stress can be reduced tu save material. The members of the side-frames have been classified according to the cross-sections. Very accurate formulae have been derived for their section properties, and computer programmes have been developed to calculate these properties. With the help of a mini-computes present in the Centre, all values of section properties have been calculated and tabulated to be used as data for finite element analysis. To develop facilities to test the coach, a list of major equipment needed has been prepared and enquiries have been sent to potential suppliers.
Railway coaches are produced at SEMAF on an overdesign basis due to lack
shape and size of their
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Reduction of noise in window-type air-conditioners (financed by the Academy of Scientific Research and Technology to Koldair Co., Giza)
19. To minimize noise levels in the window-type air-conditioners produced by Koldair Co., vibration tests were conducted on various parts of the unit. It was observed that the support systems of the fan motor and compressor units caused additional vibrations. additional stiffners, vibration tests showed a remarkable reduction, which in turn reduced noise levels. Tests on noise caused by fluid flow, in the piping system and by the air-conditioner supports are under way,
When these support systems were redesigned with
STUDY TOUR PROGRAMMES
20 . Forty-two study tour programmes were arranged to allow Faculty members participating in Centre activities to visit research institutions and industries in Europe and the United States. days to two months. These visits were very useful for Faculty members in helping them to improve postgraduate programmes, supervise and guide industrially- oriented postgraduate research theses and work on industrial consulting projects. They were also helpful in establishing contacts between the Centre axd organiza- tions abroad, for example, firms such as Bechtel, General Electric, General Motors, Sulzer and Steinmuller, and research laboratories such as Oak Ridge and JUlich Nuclear Laboratories, During these study tours, senior Faculty members also interviewed scientists who could visit the Centre as consultants to help in specific ways. design of coal power stations and coal slurry pipelines in the Sinai, and in establishing a coal research centre in Egypt,
The period of these programmes varied from 20
Study tour visits to leading companies helped materially in the
v. ACHIEVEMENT OF IIIIMEDIATE OBJECTIVES
21. have been achieved, as noted in Section I11 of this report.
All the immediate objectives laid down at the beginning of the project
22. With the provision of modern laboratories and the visits of experts and consultants, the postgraduate programme has been upgraded, postgraduate research theses have a greater orientation towards industrial applications, and staff members need not go abroad to obtain postgraduate degrees. Postgraduate students are now better suited to industrial work and university faculty positions in the A,R.E. and other Arab countries, The intensive short courses have increased the knowledge of engineers from industry and trained them for better service.
23 problems and a number of industries have had problems solved and production increased. to continue to tackle industrial problems through contracted research projects,
z The needs of national industries have been surveyed to identify their
With the experience gained, Faculty members are in a better position
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24 e in Egypt and abroad through the study tour programmes and the visits of short- term consultants.
Contacts have been established between this Centre and similar Centres
VI. RECOMMENDATIONS
25 The staff of the Centre, being university faculty members, work at the Centre only part-time. Additional contracts with industry could have been signed had some staff members been full-time Centre employees. The Centre therefore should have a core of permanent full-time staff, for example,the Director, Deputy Directors and General Secretary.
26 . The Centre has potential for growth and can be of great help to industry in research and training. Because some measures of autonomy compatible with the expected growth in size and output may be necessary, it is recommended that the Centre become an autonomous body.
27 * Intensive short courses must be designed and selected to satisfy the needs of industry. Thus, each course should be evaluated by a small committee with the help of data collected from participants from the industry involved.
28 maintenance and use of the new equipment installed in the various laboratories.
29 A system should be established in the Centre to ensure regular visits to industries to survey problems and initiate research and development projects to solve them by means of contracts.
More qualified technicians must be recruited to the Centre for the
30, The Centre should seek bilateral relations with funding bodies and organizations to provide funds for organizing study tours for faculty members participating in the Centre's activities. The library should be continuously supplied with books and technical journals.
b
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APPENDIX A
Unesco Experts and Consultants
Name of Expert/ Consult ant
country of Origin
Field of Duration of Contract Specialization From To
Experts
Michel Saad Yellappa C. Das
Consultants
G, Youngbluth J. Swithenbank K, Bammert
E. Lwnsdaine S.A.V. Swanson
S. Michelfelder
R.G,S, Skipper B. Braun V. Beglinger F.C. Lockwood Chung Hua Wu W. ,FrBhling N. Gasporovic
D.G. Teer W. Tabakoff K.P. Knoche S. Wittig C.H. SWdqviSt N. Afgan ROC, Baker
UoSoAm India
Yugoslavia
U.K.
Heat Transfer Solid Mechanics
Combustion
Combus tion Fluid Mechanics
Solar Energy Bio-Engineering Combus tion Solar Energy Combus tion Combus ti on Combus tion Fluid Mechanics Nuclear Energy Fluid Mechanics
Solid Mechanics Fluid Mechanics
Heat Transfer Combus tion
Nuclear Energy
Heat Transfer Fluid Mechanics
31 08 75 01.09.77
12/02/78
22/09/78 02/11/79 21/03/80 23/03/80 13/04/80
14/12/80 o 2/02/a 1 22/11/81 19/12/81 28/12/81 15/03/a 2 07/1 o/a 2 04/10/82
1 7/1 o/8 2 14/1 l/a 2 2 2/11/a 2
01/04/ 78
25/04/80 2 6/ 10/8 0
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Counterpart Staff
Position
F.M. El-Mahallawy
Amin Mubarak
M.M. El-Kotb
Sobhi Abdel Salam
Mounir Hila1
A.S. Asfouri
E. Khalil
M.F. Elrifai
Mustafa Kame1
Saher Koussa
E. El-Mahdi .I
Sami Marcos
A. Fathy
M.A. Salamoni
-Sami Mihkail
Director of the Centre Professor of Heat Engines Dept. of Mechanical Power Engineering Deputy Director of the Centre Professor of Combustion Dept. of Mechanical Power Engineering Deputy Director of the Centre Professor of Fluid Mechanics Dept. of Mechanical Power Engineering General Secretary of the Centre Professor of Combustion Dept. of Mechanical Power Engineering Professor of Heat Transfer Dept. of Mechanical Power Engineering Professor of Heat Transfer Dept. of Mechanical.Power Engineering
Assistant Professor of Heat Transfer Dept. of Mechanical Power Engineering Assistant Professor of Heat Transfer Dept. of Mechanical Power Engineering Assistant Professor of Heat Transfer Dept. of Mechanical Power Engineering
Professor of Combustion Dept. of Mechanical Power Engineering Associate Professor of Combustion Dept. of Mechanical Power Engineering Assistant Professor of Combustion Dept. of Mechanical Power Engineering Assistant Professor of Fluid Mechanics Dept. of Mechanical Power Engineering Assistant Professor of Fluid Mechanics Dept. of Aeronautical Engineering Head Dept. of Mechanical Design & Production Head Dept. of Mechanical Power Ehgineering
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Appendix B cont'd
Name Position
M. El-Araby
Galal Hassan
G, Sherbiny
S. B a y o k
Professor of Controls Dept. of Mechanical Design & Production Assistant Professor of Solid Mechanics Dept, of Mechanical Design & Production Assistant Professor of Solid Mechanics Dept. of Mechanical Design &Production
Professor
h
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APPENDIX C
Study Tours
Name of Staff Member Area of Study Place of Study Period of Study From To
i K.H. Khalil F.M. El-Mahallawy
S.A. Farag Y.H. Kabil
S. Bayoumi
M.E. Moshen
Moshen Said
S.A. Farag
S.A. Farag
F.M. El-Mahallawy
MOM. El-XOtb
E. El-Mahdi
Amin Mubarak A. Fathy
M. El-Sherbiny
A.R. Ragab S.A. Farag Sahar Koussa
h
Sobhi Abdel Salam
Heat Transfer Combustion
Combustion
. Mech. System
Mech, System
Mech. System
Solid Mechanics Combus tion
Dynaxrli cs
Dynamics
Dynamics
Combus tion
Combustion
Combus tion
Combus ti on
Fluid Mechanics Fluid Mechanics
Solid Mechanics Solid Mechanics Combus ti on Combus tion
Heat Transfer
08/75
08/7 5 08/75
07/75
09/75
U.S.A. 08/75
Udinej Italy 10/78
F.R.Go, 08/79 Switzerland , France, U.K. Sweden, Denmark, 08/80 Switzerland & F.R.G. F.R.G. , France, 08/80
France, U.K. , 08/80
F.R.G., France, 08/80
FmRoGo 07/80
France, U.K., 07/8 0 Switzerland, Greece
UoKo
FoRoGo
U, Km
U.K. 07/80
Udine, Italy 09/8 0 U.S.A. 08/81
Denmark, U.K., 08/81 Netherlands
U.X. g F.R. G a p 09/8 1 Yugos 1 avi a
09/75
09/7 5 09/7 5 08/75
10/75
09/75
09/79
1 2/7 8
10/8 0
09/80
09/80
09/80
09/80
08/80
08/80
10/80
09/81
09/8 1
09/81
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Appendix C cont'd
Name of Staff Member Area of Study Place of Study Period of Study From To
09/81
08/81
03/8 1
08/81
a7/81
08/81
08/82
Q8/8 2
cS/8 2
07/82
07/8 2.
07/82 0$/82
08/8 2
0 8/8 2
08/83
07/83
10/81
09/81
09/81 ( 1-13 )
@,I8 1 08/81
08/81 ( 10-3 1 ) 09/82
09/82
09/82
08/82
07/82 (11-30)
08/82
09/82
08/82 (2-21)
09/8 2 ,'
08/83 (4-25
08/83
Abdel Aziz Heat Transfer U.K., France, Netherlands
France
France U.K., FoRoG,,
U.K.
Elasf ouri , A .s. Sami Mihkail
Heat Transfer Fluid Mechanics
Sabry Baz Fluid Mechanics
Solid Mechanics M.A. Salamoni
M+ El-Araby
S.A. Farag
Solid Mechanics
Combustion U.K., F.R.G. F.R.G., France, SWi t zer land U.K., France, Net her lands
U.K. , Norway, F.R.G.
F.M. El-Mahallawy Combus tion
M.M. El-Kotb Combustion
Amin Mobarak M.A. Salamod M. E. El-Ar aby Sami Mourad Morcos
Fluid Mechanics
Solid Mechanics Solid Mechanics
Fluid Mechanics U.Kc, F.R.G. Sweden, Norway, Denmark, F.R.G.
France
U.K., F.R.G.,.
UoKe, F.RoG.9 A.W. El-Dib Heat Transfer
E, Khalil Heat Transfer
Combustion S.A. Farag
M.A..Bahim
G.D.R. Czechoslovakia Sweden Organiaat ion and
Admini st rat ion
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APPENDIX D
Intensive Short Courses for Ehgineers from Industry
Title of the Course Number of Period of the Course Participants From To
i
New Techniques in Engines Gas Liquid Pipeline Design & Installation Furnace and Combustion Technology Gas Turbines Gas Turbines Boilers Numerical Methods in Mechanical Design Application of Vibration &Control in Mechanical
Engine Testing Numerical Methods in Mechanical Design Oil and Gas Burners
Power Generation from New and Renewable Energy
Solar Ehergy Thermal Process Steam Generators Gas Turbines Selection and Maintenance of Pumps, Rns and Compressors
Numerical Technique in Mechanical Design
Design and Operation of Pipelines and Networks Combustion Technology Applied to Boilers and
New and Renewable Energy Resources Combustion of Natural Gas and Coal New and Renewable Eaergy Resources Fluid Systems in Water and Sanitary Drainage
Sys t ems
Sources
Industrial Furnaces
Schemes
21 29 28 15 40 38 18 18
42 18 60 43
32 28 35 28
26 65 25
42 14 25 82
02/79 04/79 04/79 12/79 03/8 0 03/80 04/8 0 11/80
12/80
01/ 8 2 0 5/8 1 0 5/8 1
09/8 2 10/8 2 11/8 2
11/8 2
12/8 2 1 2/8 2 06/83
06/8 3 06/83 09/8 3 10/8 3
03/79 05/79 05/79 12/79 0 3/8 0 04/80 04/80 1 2/8 0
01/81 02/81 C8/8 1 o a;/8 I.
09/82 10/8 2 11/8 2 11/82
12/8 2 12/8 2 08/83
0 8/8 3 0.8 /83 09/83 11/83
- 17 -
APPENDIX E
Long-Term Courses Offered in the Postgraduate Programme
Postgraduate Course Programme No. of Name of Expert Duration of Students Course
Radiation Heat Transfer 17 Michel Saad 19 7 5-7 6 Gas Dynamics 24 Michel Saad 197 5-7 6 Mechanical Vibrations 30 Yellappa C. Das 1977-78 Applied Mechanical Vibrations 10 Yellappa C. Das 19 7 7-7 8