Statuss(Aktīvs) | Izdruka | Arhīvs(0) | Studiju plāns Vecais plāns | Kursu katalogs | Vēsture |
Course title | Engineering Graphics |
Course code | LauZ2039 |
Credit points (ECTS) | 4.5 |
Total Hours in Course | 121.5 |
Number of hours for laboratory classes | 48 |
Independent study hours | 72 |
Date of course confirmation | 19/10/2011 |
Responsible Unit | Institute of Mechanics and Design |
Course developers | |
Dr. sc. ing., Imants Nulle Mg. sc. ing., lekt. Mareks Šmits |
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There is no prerequisite knowledge required for this course | |
Replaced course | |
LauZ4140 [GLAU4140] Engineergraphics VidEB012 [GVIEB012] Engineering Graphics |
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Course abstract | |
The aim of the study course is to create and develop geometrical logic, spatial thinking and imagination. The basic method used in course framework is the graphical method. The students get thought to draft and read drawings what is the international graphical method and means of expression of constructive thought. | |
Learning outcomes and their assessment | |
1) Knowledge - understands the projection method, view, and section view creation principles. Familiar with the drawings related standards (ISO, LVS, GOST, etc.). Knows the type of items and the relevant working documents and the execution sequence. Knows how to explain the drawing and add dimensions and annotations of threads, surface finish and material. Knowledge is appreciated in tests and laboratory works.
2) Skills – knows to create part working drawings, axonometric views, perform drawings of dismountable and rigid assemblies and text documentation for it, as well as read assembly drawings and detailing them according LVS, EN, ISO, GOST, etc. standards. AutoCad Mechanical software is used to perform these tasks. Skills are appreciated in tests and laboratory works. 3) Competence – ability to apply professional knowledge and skills of Engineering graphics in practical work and studies. Competence is appreciated in tests and laboratory works. |
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Course Content(Calendar) | |
1. Create Sheet format, Title block, Template file with AutoCad Mechanical. – 3h
2. Geometrical constructions. Views. Section views. – 3h 3. Geometrical constructions. Views. Section views. – 3h 4. Creating drawing of a prismatic part. Constructing an axonometric view in Isometric Drafting mode. Adding dimensions and surface texture. – 3h 5. Casting part drawing. Axonometric view. Tolerances. Threads in part drawings. – 3h 6. Casting part drawing. Axonometric view. Tolerances. Threads in part drawings. – 3h 7. Assembly drawings. Adding Balloons. Bill of materials. Parts list. Fasteners from AutoCad Mechanical library. – 3h 8. Assembly drawings. Adding Balloons. Bill of materials. Parts list. Fasteners from AutoCad Mechanical library. – 3h 9. Test. Part drawing. – 3h 10. Welded assembly drawing. Parts list. Welding symbols. Balloons. Axonometric view. – 3h 11. Welded assembly drawing. Parts list. Welding symbols. Balloons. Axonometric view. – 3h 12. Detailing of assembly drawings. – 3h 13. Detailing of assembly drawings. – 3h 14. Detailing of assembly drawings. – 3h 15. Detailing of assembly drawings. – 3h 16. Test - details drawing. – 3h |
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Requirements for awarding credit points | |
Students receive a final mark if they have successfully completed the tasks assigned in laboratory works and have passed 2 tests.
The tasks performed in the laboratory works have to be presented. Presentation includes short oral report of each finished task as well as answers to the questions about the theoretical aspects of this topic. In the first test drawing of parts is required, but the second one a detailing of assembly drawing is done. Theoretical knowledge is assessed as a test. |
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Description of the organization and tasks of students’ independent work | |
Part drawing with offset and revolved sectional views.
Construction line of intersection of surface in part drawing. Drawing of threaded parts. |
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Criteria for Evaluating Learning Outcomes | |
A student will get a successful mark on the test work if at least 50% of the tasks are properly solved. The student receives high marks if the tasks performed in the laboratory and independent works are completed, well-designed and the student is able to answer the questions. | |
Compulsory reading | |
1. I.Nulle, J.Čukurs. Inženiergrafika. Metodiskais materiāls E-studijām. 2014. 101 lpp.
2. Dukulis I. Pamati darbā ar AutoCAD 2018: mācību e-grāmata. Jelgava, 2018. 178 lpp. 3. Čukurs J., Viļumsone I., Nulle I. Inženiergrafika: mācību grāmata. Mašīnbūves rasēšana. Rīga: RaKa, 2007. 258 lpp. 4. Čukurs J., Nulle I., Dobelis M. Inženiergrafika: mācību grāmata. Jelgava: LLU, 2008. 416 lpp. |
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Further reading | |
1. Čukurs J., Vronskis O. Tehniskā grafika: mācību grāmata. Rīga: RaKa, 2008. 265 lpp.
2. Auzukalns J., Dobelis M., Fjodorova G., u.c. Inženiergrafika: mācību grāmata. Rīga: RTU, 2008. 3. Čukurs J., Vronskis O. Tehniskā grafika: Grafisko darba uzdevumu krājums. Rīga: RaKa, 2010. |
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Notes | |
The study course is included in the compulsory part of the 2nd level professional higher education study program "Machine Design and Manufacturing" of the Faculty of Engineering. 1st study year 2nd semester. |