Karta przedmiotu

Machines theory and technical mechanics

Some basic information about the module

Cycle of education:

2022/2023

The name of the faculty organization unit:

The faculty Chemistry

The name of the field of study:

Chemical and process engineering

The area of study:

technical sciences

The profile of studing:

The level of study:

first degree study

Type of study:

full time

discipline specialities :

Hydrogen technologies, Processing of polymer materials , Product design and engineering of pro-ecological processes

The degree after graduating from university:

Bachelor of Science (BSc)

The name of the module department :

Department of Chemical Engineering and Process Control

The code of the module:

268

The module status:

mandatory for teaching programme Hydrogen technologies, Processing of polymer materials , Product design and engineering of pro-ecological processes

The position in the studies teaching programme:

sem: 1, 2 / W60 C30 P15 / 7 ECTS / Z,Z

The language of the lecture:

Polish

The name of the coordinator 1:

Grzegorz Poplewski, PhD, Eng.

office hours of the coordinator:

środa 8:45 - 10:15, czwartek 10:15 - 11:00, piątek 9:30 - 10:15

The name of the coordinator 2:

Marcin Chutkowski, PhD, Eng.

office hours of the coordinator:

4 godziny tygodniowo, wtorki 10-12, piątki 10-12

semester 1:

Izabela Poplewska, PhD, Eng.

The aim of studying and bibliography

The main aim of study:
In the 1st semester of the course, the student should master the basic knowledge and ability to solve problems of statics solid rigid and materials strength. In the second semester of the course a student obtains knowledge of standards and standardization, law regulations applying to design and construction, basic constructive materials, machines theory and machine parts common in chemical equipment

The general information about the module:
The module is realized in the first and second semester. The 1st semester includes 30 hours of lectures and 30 hours of practice, the 2nd semester 30 hours of lectures and 15 hours of the project. Both the 1st and in the 2nd semester ends with credit. Drawings used in the didactic process were made in AutoCAD and Autodesk Inventor Professional.

Teaching materials:
Prezentacje z prowadzonych wykładów dostępne poprzez stony domowe koordynatorów

Bibliography required to complete the module

Bibliography used during lectures
1	W. Siuta	Mechanika techniczna : podręcznik dla technikum	WSiP.	1995
2	J. Misiak	Mechanika Techniczna. Statyka i wytrzymałość materiałów T1	WNT, Warszawa.	2014
3	W. Lewandowski	Maszynoznawstwo chemiczne	Fundacja Poszanowania Energii w Gdańsku.	1998
4	J. Pikoń	Podstawy konstrukcji aparatury chemicznej	PWN.	1979
5	L. Dobrzański	Podstawy nauki o materiałach i metaloznawstwo	WNT.	2004
6	-	Warunki Urzędu Dozoru Technicznego	UDT.	2005
7	W. Biały	Maszynoznawstwo dla niemechaników	Pracownia Komputerowa Jacka Skalmierskiego.	2010
8	G. Poplewski, M. Chutkowski	Mechanika techniczna i maszynoznawstwo	Oficyna wydwnicza PRz, Rzeszów.	2014

Bibliography used during classes/laboratories/others
1	W. Siuta, S. Rososiński, Kozak Bogusław	Zbiór zadań z mechaniki technicznej	WSiP, Warszawa.	2007
2	J. Bandrowski, M. Palica	Materiały pomocnicze do ćwiczeń i projektów z inzynierii chemicznej	Wydawnictwo Politechniki Śląskiej.	2005
3	G. Filipczak, L. Troniewski, S. Witczak	Tablice do obliczeń projektowo-konstrukcyjnych aparatury procesowej	Wydawnictwo Politechniki Opolskiej.	1997
4	-	Polskie Normy	-.	-
5	-	Warunki Urzędu Dozoru Technicznego	UDT.	2005
6	G. Poplewski, M. Chutkowski	Mechanika techniczna i maszynoznawstwo	Oficyna Wydawnicza PRz, Rzeszów.	2014
7	M. Palica, J. Raczek, H. Merta	Pomoce projektowe z inżynierii chemicznej i procesowej	Wydwnictwo PŚ, Gliwice.	2010

Bibliography to self-study
1	J. Misiak	Zadania z mechaniki ogólnej. Statyka cz. I	WNT.	2014
2	J. Misiak	Mechanika Ogólna. Statyka i kinematyka T1	WNT.	2014
3	A. Dudek, S. Łaczek	Zbiornik ciśnieniowy spawany	Wydawnictwo Politechniki Krakowskiej.	2006

Basic requirements in category knowledge/skills/social competences

Formal requirements:
registration for the semester

Basic requirements in category knowledge:
mathematics and mechanics at a basic level

Basic requirements in category skills:
solving skills and analysis of simple problems

Basic requirements in category social competences:
ability to cooperate during the clasess, good manners

Module outcomes

MEK	The student who completed the module	Types of classes / teaching methods leading to achieving a given outcome of teaching	Methods of verifying every mentioned outcome of teaching	Relationships with KEK	Relationships with PRK
MEK01	The student understands the need for standardization of products and processes and is able to use the basic rules and regulations in the design of chemical equipment	lecture, designing in small groups	written test, presentation of the prepared desing	K-W04+++ K-U04++ K-U06+++ K-U17+ K-U18+ K-U19++ K-K02++	P6S-KO P6S-UO P6S-UU P6S-UW P6S-WG
MEK02	The student has a basic knowledge of construction materials used in the construction of chemical apparatus and knows the criteria for construction materials selection	lecture, designing in small groups	written test, presentation of the prepared design	K-W04++ K-U04+ K-U06++ K-U17+ K-U18+ K-U19++ K-K02+	P6S-KO P6S-UO P6S-UU P6S-UW P6S-WG
MEK03	The student has a basic knowledge of machines theory including machine parts, shafts and axles, bearings, brakes, clutches and drives	lecture	written test	K-W04+++ K-U04+ K-U06+ K-K02+	P6S-KO P6S-UW P6S-WG
MEK04	The student has a basic knowledge of common chemical equipment parts such as bodies (shells), heads, short ends, seals, covers and manhole openings, pipelines and their components, flow control elements (valves), vessel accessories	lecture, designing in small groups	written test, presentation of the prepared design	K-W04+++ K-U04+++ K-U06++ K-U17+ K-U18++ K-U19+ K-K02+	P6S-KO P6S-UO P6S-UU P6S-UW P6S-WG
MEK05	Student knows and understands the basic concepts and the quantities of statics and strength of materials.	lectures, classes	written test	K-U06+++ K-U19++ K-K02+	P6S-KO P6S-UU P6S-UW
MEK06	Student is able to apply the acquired knowledge and solve the basic problems of statics and strength of materials.	lectures, classes	test	K-W04+ K-U06+++ K-U18+ K-U19++ K-K02+	P6S-KO P6S-UO P6S-UU P6S-UW P6S-WG

The syllabus of the module

Sem.	TK	The content	realized in	MEK
1	TK01	Basic terms and concepts of mechanics.	W01, C01	MEK03 MEK06
1	TK02	Flat, convergent arrangement of forces.	W02, C02	MEK05 MEK06
1	TK03	Moment of force.	W03, C03	MEK05 MEK06
1	TK04	Reduction and equilibrium of planar systems forces converging and arbitrary.	W02, W04, C02, C04	MEK05 MEK06
1	TK05	The sliding and rolling friction.	W05, C05	MEK05 MEK06
1	TK06	The center of gravity.	W04, C04	MEK05 MEK06
1	TK07	The moment of inertia.	W11, C11	MEK05 MEK06
1	TK08	Basic terms and concepts of the strength of materials.	W07, C07	MEK02 MEK06
1	TK09	Mechanical properties of construction materials.	W07, W08	MEK02
1	TK10	Basic cases of stress: compressive, tensile, shear, torsion, bending, buckling, complex strength.	W09-W15, C09-C15	MEK05 MEK06
1	TK11	Plane trusses	W05	MEK05 MEK06
2	TK01	General rules of designing and construction of chemical apparatus	W01-W04, P01	MEK01
2	TK02	Standards and standardization, law regulations by Polish Office of Technical Inspection (UDT)	W01-W06, P01-P15	MEK01
2	TK03	Basic constructive materials used in construction of chemical apparatus: steels and iron-base alloys, other metallic materials, plastics, glass and ceramics, wood. Criteria and rules of constructive material selection.	W07-W12	MEK02 MEK05
2	TK04	Machines review and basic machine parts of general purpose: joints, shafts and axles, bearings, couplings, brakes, gears and drives together with their calculation and selection rules	W13-W20	MEK03
2	TK05	Basic chemical apparatus parts: bodies (shells), heads, connector pipes, openings, vessel accessories, pipelines and their parts, seals and valves together with their calculation and selection rules	W21-W30, P01-P15	MEK04

The student's effort

The type of classes	The work before classes	The participation in classes	The work after classes
Lecture (sem. 1)	The preparation for a test: 5.00 hours/sem.	contact hours: 30.00 hours/sem.	complementing/reading through notes: 4.00 hours/sem. Studying the recommended bibliography: 3.00 hours/sem.
Class (sem. 1)	The preparation for a Class: 8.00 hours/sem. The preparation for a test: 4.00 hours/sem.	contact hours: 30.00 hours/sem.	Finishing/Studying tasks: 15.00 hours/sem.
Advice (sem. 1)		The participation in Advice: 3.00 hours/sem.
Credit (sem. 1)	The preparation for a Credit: 4.00 hours/sem.	The written credit: 2.00 hours/sem.
Lecture (sem. 2)	The preparation for a test: 10.00 hours/sem.	contact hours: 30.00 hours/sem.	complementing/reading through notes: 5.00 hours/sem. Studying the recommended bibliography: 2.00 hours/sem.
Project/Seminar (sem. 2)	The preparation for projects/seminars: 5.00 hours/sem.	contact hours: 15.00 hours/sem..	Doing the project/report/ Keeping records: 15.00 hours/sem.
Advice (sem. 2)		The participation in Advice: 2.00 hours/sem.
Credit (sem. 2)	The preparation for a Credit: 2.00 hours/sem.	The written credit: 1.00 hours/sem.

The way of giving the component module grades and the final grade

The type of classes	The way of giving the final grade
Lecture	writing test (mark OW)
Class	Classes - 2 written tests, answers obtained during the semester - (mark OC). Student receives 0-20 points for each written test. For each correct answer in the course the student gets: +1 point for the correct answer, -1 point for the wrong answer or no answer. Points for answers are added to the points from the colloquium from a given chapter. The number of points from a given chapter can not exceed 20 and can not be less than 10 points. To pass the education module, students must pass both written tests. During the semester students can get a maximum of 40 points. OC: <40-36> points - (5.0), (36-32> points - (4.5), (32-28> points - (4.0), (28-24> points - t (3.5), (24- 20> points - (3.0), (20-0> points - (2.0).
The final grade	The final mark (FM) is calculated according to the formula: FM = 0.3wOW+0.7wOC where: w - a factor related to the term credit or examination, w = 1,0 the first term,w = 0,9 the second term, w = 0,8 a third term. While rounding average, the following rules are apply: to 2,99 (2.0), 3,0 - 3,30 – dst (3,0); 3,31 - 3,75 – +dst (3,5); 3,76 - 4,25 – db (4,0); 4,26 - 4,70 – +db (4,5); from 4,71 – bdb (5,0).
Lecture	Student obtains 0 - 64 pts for written test of lecture theory
Project/Seminar	Student obtains 0 - 18pts for design procedure test and 0 - 18pts for design documentation. The total number of points cannot exceed 36pts.
The final grade	The final mark depends on the total number of points obtained by student from lecture test and project design: below 50 pts - (2.0), 50-59 pts - (3.0), 60-69 pts - (3.5), 70-79 pts - (4.0), 80-89 pts - (4.5), 90-100 pts - (5.0)

Sample problems

Required during the exam/when receiving the credit
(-)

Realized during classes/laboratories/projects
(-)

Others
(-)

Can a student use any teaching aids during the exam/when receiving the credit : no

The contents of the module are associated with the research profile no