Load:

1. komponenta
Lecture type  Total 
Lectures 
30 
Exercises 
30 
* Load is given in academic hour (1 academic hour = 45 minutes)

Description:

COURSE GOALS: Introduction to technical standards, basics of Descriptive Geometry, axonometric representation, orthogonal projection and cross section.
LEARNING OUTCOMES AT THE LEVEL OF THE PROGRAMME:
1. KNOWLEDGE AND UNDERSTANDING
1.3. demonstrate a thorough knowledge and understanding of basic concepts in techniques
2. APPLYING KNOWLEDGE AND UNDERSTANDING
2.2. identify and describe important aspects of techniques and their applications
3. MAKING JUDGMENTS
3.2. develop clear and measurable learning outcomes and objectives in teaching based on curriculum goal
3.3. reflect on and evaluate their own practice of teaching
4. COMMUNICATION SKILLS
4.1. communicate effectively with pupils and colleagues
5. LEARNING SKILLS
5.1. search for and use professional literature as well as any other sources of relevant information
LEARNING OUTCOMES SPECIFIC FOR THE COURSE:
Upon passing the course on Technical Documentation 1 the student will be able to:
1. enumerate basic standards in the field of technical drawings and recollect numerical quantities of the most important elements introduced;
2. analyse and decompose complex body to primitive bodies and make proper freehand isometric sketch of the complex body;
3. graphically solve basic metrical problems (plane to plane section, point to plane distance, line perpendicular to plane);
4. graphically produce true cross section area of a primitive body sectioned with projection plane of the first or the second kind.
5. make or recognize a cross section of a simple body with a given plane.
COURSE DESCRIPTION:
1. Introduction, accessories for Technical Drawing
2. Technical standards and standardisation: lines, lettering, paper sizes, scales.
3. Technical standards and standardisation: lines, lettering, paper sizes, scales.
4. Introduction to Descriptive Geometry. Basics: projection of a point, line segment, line.
5. Determining true length of a line segment generally positioned in space. Determining adjacent angle between a line and a plane.
6. Projecting planes. Lines parallel to plane trace. Lines perpendicular to plane trace.
7. Rotating planes about plane's trace. Side view.
8. Cross section of a body with a general plane.
9. Determining true cross section area.
10. Basic terms and definitions of a projection according to ISO 128.
11. Basic terms and definitions of a projection according to ISO 128.
12. Section kinds.
13. Application of sections.
14. Axonometric representation.
15. Isometric representation.
Exercises and seminars are following lectures by content.
REQUIREMENTS FOR STUDENTS:
Students must attend lectures and exercises, solve home assignments, make at least 10 freehand isometric drawings of a given objects, solve at least 50 percent of two written preliminary exams each, solve one design assignment and complete the exercise book (projections and isometric representation).
GRADING AND ASSESSING THE WORK OF STUDENTS:
Grading and assessing the work of students during the semesters:
* Two written preliminary exams
* Home works (prerequisite)
* Freehand isometric drawings
* Exercise book
Grading at the end of semester:
* Oral presentation of a design assignment (20 percent of the final grade)
Contributions to the final grade:
* 50 percent of the grade is carried by the results of the two written exams
* 10 percent of the grade is carried by the average result for 5 freehand isometric drawings
* 20 percent of the grade is carried by the result of design assignment and oral presentation
* 20 percent of the grade is carried by the result of the exercise book
Final grade "excellent" can not be awarded if any of the partial grades is equal to "sufficient".

Literature:

 Z. Herold: Inženjerska grafika, Inženjerski priručnik, Školska knjiga, Zagreb, 1994.
M. Opalić, M. Kljajin, S. Sebastijanović: Tehničko crtanje, Zrinski d.d., Čakovec, 2003.
Z. Herold, D. Žeželj: Inženjerska grafika  Metodička vježbenica, FSB, Zagreb, 2005.
 Koludrović: Tehničko crtanje u slici s kompjuterskim aplikacijama, Autorska naknada Koludrović Ć. I. R., Rijeka, 1997.
K. Horvatić Baldasar, I. Babić: Nacrtna geometrija, Sand d.o.o., Zagreb 2001.
