The aim of studying and bibliography

The main aim of study: Acquiring knowledge on the methods of evaluation of the practical properties of polymer materials.

The general information about the module: The module takes place in the sixth semester, includes 15 hours of lecture and15hours laboratory. The module ends with a final test.

Teaching materials: Instrukcje do ćwiczeń laboratoryjnych

others: Normy przedmiotowe

Bibliography required to complete the module

Bibliography used during lectures

1	Broniewski T., Kapko J., Płaczek W., Thomalla J.	Metody badań i ocena właściwości tworzyw sztucznych	WNT Warszawa.	2000
2	Przygodzki W.	Metody fizyczne badań polimerów	PWN Warszawa .	1990
3	Hunt J., James M. J.	Polymer characterisation	Blackie London.	1993
4	Rabek J.F.	Współczesna wiedza o polimerach T. 1	PWN Warszawa .	2017
5	Rabek J.F.	Współczesna wiedza o polimerach T. 2	PWN Warszawa .	2017

Bibliography used during classes/laboratories/others

1	Dogadkin B. A.	Chemia elastomerów	WNT Warszawa.	1976
2	Żuchowska D.	Polimery konstrukcyjne: wprowadzenie do technologii i stosowania	WNT Warzsawa.	2000
3	Rabek J.F.	Współczesna wiedza o polimerach T. 1	PWN Warszawa.	2017
4	Rabek J.F.	Współczesna wiedza o polimerach T. 2	PWN Warszawa .	2017

Bibliography to self-study

1

Artykuły w czasopismach chemicznych i polimerowych, tj. POLIMERY, PRZEMYSŁ CHEMICZNY

.

Basic requirements in category knowledge/skills/social competences

Formal requirements: Registration for the sixth semester.

Basic requirements in category knowledge: Has knowledge on instrumental and chemical analysis, basic polymer chemistry and technology, and processing of polymers and plastics.

Basic requirements in category skills: Has a laboratory skill in instrumental analysis and skill at performing calculations and interpretation of results.

Basic requirements in category social competences: Knows safety and fire protection regulation in chemical laboratory. Capable of working in team and individually.

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
01	Has the basic knowledge on the properties of polymeric materials, methods for their preparation/processing and methods of characterization their basic properties.	lecture	written test	K_W03++ K_U08+	P6S_UW P6S_WG
02	Has the basic knowledge on the practical application of polymeric materials depending on their properties.	lecture	written test	K_W07+ K_U08+ K_K01+	P6S_KK P6S_UW P6S_WG
03	Knows the methods used for assessing of the practical properties of polymer materials, in particular physical, strength (static and dynamic), thermal, flammability, electrical, magnetic, acoustic and optical properties.	lecture	written test	K_W07+ K_U19+	P6S_UU P6S_WG
04	Knows the software used to operate the selected measuring devices used to testing of evaluation of the practical properties of polymer materials.	laboratory exercises	oral test, written report	K_U02++ K_U06++	P6S_UW
05	Can propose testing methods to the study of selected practical properties of polymer material.	laboratory exercises	oral test, written report	K_W07+ K_K01+	P6S_KK P6S_WG
06	Can take measurements using the selected equipment, which allows the assessment of the practical properties of polymer material.	laboratory exercises	oral test, written report	K_U08+ K_K01+	P6S_KK P6S_UW

Attention: Depending on the epidemic situation, verification of the achieved learning outcomes specified in the study program, in particular credits and examinations at the end of specific classes, can be implemented remotely (real-time meetings).

The syllabus of the module

Sem.	TK	The content	realized in	MEK
6	TK01	Characteristic of the basic physical properties of polymeric materials: density, porosity, solubility, moisture content, absorbability, etc.	W01-W02	MEK01
6	TK02	Classification of the polymer materials taking into account methods of processing and the practical applications.	W03-W04	MEK02
6	TK03	Determination of strength properties (static and dynamic) of polymeric materials. Thermal properties and flamability of plastics. Determination of temperature of phase transition (glass transition, melting, crystallization). Testing method of heat resistance. Aassessment of thermal resistance under prolonged loud. Methods of evaluation of aging and chemical resistance. Determination of electric, magnetic, acustic, optical properties of polymeric materials. Analysis of polymer morphology.	W05-W15	MEK03
6	TK04	Learning computer software used to operate the equipments used during laboratory lessons and to interpret obtained results.	L01-L03	MEK04
6	TK05	Preparation of samples for analysis.	L01-L03	MEK05
6	TK06	Thermal analysis of plastics – determination of glass transition temperature and degree of crystallinity by DSC. The analysis of the reactivity of the epoxy resins by differential scanning calorimetry (DSC). Dynamic mechanical analysis DMA of selected polymer materials.	L01-L03	MEK06

The student's effort

The type of classes	The work before classes	The participation in classes	The work after classes
Lecture (sem. 6)		contact hours: 15.00 hours/sem.	complementing/reading through notes: 1.00 hours/sem. Studying the recommended bibliography: 3.00 hours/sem.
Laboratory (sem. 6)	The preparation for a Laboratory: 3.00 hours/sem. The preparation for a test: 3.00 hours/sem.	contact hours: 15.00 hours/sem.	Finishing/Making the report: 3.00 hours/sem.
Advice (sem. 6)	The preparation for Advice: 1.00 hours/sem.	The participation in Advice: 2.00 hours/sem.
Credit (sem. 6)	The preparation for a Credit: 8.00 hours/sem.	The written credit: 1.00 hours/sem. The oral 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	Mark of the written test from the lectures – W1. The test mark depends on the score gained: 50,1-60%: 3.0 60,1-70%: 3.5
Laboratory	Student must perform all of the planed experiments, prepare and pass written reports, pass tests from theoretical information connected with laboratory lessons.Average mark from test, written report from each exercise, taking into account the observations of performance of each exercise – W2.
The final grade	Final mark: W = w 0,5 W1 + w 0,5 W2; w - weighting factor: w = 1,0 first term, w = 0,9 second term, w = 0,8 third term.

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: yes

1	J. Bieniaś; Ł. Byczyński; D. Czachor-Jadacka; M. Droździel-Jurkiewic; M. Kisiel; B. Mossety-Leszczak; G. Pietruszewska; M. Włodarska; W. Zając	Nonterminal liquid crystalline epoxy resins as structurally ordered low Tg thermosets with potential as smart polymers	2024
2	K. Awsiuk; N. Janiszewska; B. Mossety-Leszczak; J. Raczkowska; A. Strachota; B. Strachota; M. Walczak; A. Zioło	Synthesis and Morphology Characteristics of New Highly Branched Polycaprolactone PCL	2024
3	M. Kisiel; B. Mossety-Leszczak	The Effect of Nonterminal Liquid Crystalline Epoxy Resin Structure and Curing Agents on the Glass Transition of Polymer Networks	2024
4	M. Kisiel; B. Mossety-Leszczak; L. Okrasa; M. Włodarska	Modification of the Dielectric and Thermal Properties of Organic Frameworks Based on Nonterminal Epoxy Liquid Crystal with Silicon Dioxide and Titanium Dioxide	2024
5	M. Kisiel; B. Mossety-Leszczak; W. Zając	Advancements in The Cross-Linking and Morphology of Liquid Crystals	2024
6	Ł. Byczyński; D. Czachor-Jadacka; M. Kisiel; B. Mossety-Leszczak; B. Pilch-Pitera; K. Pojnar; M. Walczak; J. Wojturska	Poliuretanowy lakier proszkowy oraz sposób wytwarzania poliuretanowego lakieru proszkowego	2024
7	Ł. Byczyński; E. Ciszkowicz; D. Czachor-Jadacka; M. Kisiel; B. Mossety-Leszczak; B. Pilch-Pitera; M. Walczak; J. Wojturska	Wodna dyspersja kationomerów uretanowo-akrylowych, sposób wytwarzania wodnej dyspersji kationomerów uretanowo-akrylowych oraz sposób wytwarzania fotoutwardzalnej powłoki z wykorzystaniem tej wodnej dyspersji	2024
8	M. Kisiel; B. Mossety-Leszczak; L. Okrasa; M. Włodarska; W. Zając	Changes in molecular relaxations and network properties of a triaromatic liquid crystal epoxy resin with nonterminal functional groups	2023
9	J. Karaś; M. Kisiel; B. Mossety-Leszczak; B. Pilch-Pitera; M. Włodarska; W. Zając	The application of liquid crystalline epoxy resin for forming hybrid powder coatings	2022
10	K. Byś; J. Hodan; B. Mossety-Leszczak; E. Pavlova; A. Strachota; B. Strachota	Self-Healing and Super-Elastomeric PolyMEA-co-SMA Nanocomposites Crosslinked by Clay Platelets	2022
11	M. Kisiel; B. Mossety-Leszczak	Liquid Crystalline Polymers	2022
12	B. Mossety-Leszczak; M. Włodarska	DFT Studies of Selected Epoxies with Mesogenic Units–Impact of Molecular Structure on Electro-Optical Response	2021
13	K. Byś; B. Mossety-Leszczak; E. Pavlova; M. Steinhart; A. Strachota; B. Strachota; W. Zając	Novel Tough and Transparent Ultra-Extensible Nanocomposite Elastomers Based on Poly(2-methoxyethylacrylate) and Their Switching between Plasto-Elasticity and Viscoelasticity	2021
14	M. Kisiel; B. Mossety-Leszczak; A. Strachota; B. Strachota	Achieving structural anisotropy of liquid crystalline epoxy by manipulation with crosslinking parameters	2021
15	M. Kisiel; B. Mossety-Leszczak	Development in liquid crystalline epoxy resins and composites – A review	2020
16	M. Marchel; B. Mossety-Leszczak; M. Walczak	Maize (Zea mays) reaction in response to rubber rag additive into the soil	2020
17	S. Horodecka; D. Kaňková; B. Mossety-Leszczak; M. Netopilík; M. Šlouf; A. Strachota; B. Strachota; M. Vyroubalová; Z. Walterová; A. Zhigunov	Low-Temperature Meltable Elastomers Based on Linear Polydimethylsiloxane Chains Alpha, Omega-Terminated with Mesogenic Groups as Physical Crosslinkers: A Passive Smart Material with Potential as Viscoelastic Coupling. Part I: Synthesis and Phase Behavior	2020
18	S. Horodecka; D. Kaňková; B. Mossety-Leszczak; M. Netopilík; M. Šlouf; A. Strachota; M. Vyroubalová; A. Zhigunov	Meltable copolymeric elastomers based on polydimethylsiloxane with multiplets of pendant liquid-crystalline groups as physical crosslinker: A self-healing structural material with a potential for smart applications.	2020
19	S. Horodecka; M. Kisiel; B. Mossety-Leszczak; M. Šlouf; A. Strachota; B. Strachota	Low-Temperature-Meltable Elastomers Based on Linear Polydimethylsiloxane Chains Alpha, Omega-Terminated with Mesogenic Groups as Physical Crosslinker: A Passive Smart Material with Potential as Viscoelastic Coupling. Part II—Viscoelastic and Rheological Properties	2020
20	A. Frańczak; M. Kisiel; B. Mossety-Leszczak; D. Szczęch	Quantitative analysis of the polymeric blends	2019
21	N. Buszta; M. Kisiel; J. Lechowicz; B. Mossety-Leszczak; R. Ostatek; M. Włodarska	Analysis of curing reaction of liquid-crystalline epoxy compositions by using temperature-modulated DSC TOPEM (R)	2019