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Mobility Rehabilitation - opis przedmiotu

Informacje ogólne
Nazwa przedmiotu Mobility Rehabilitation
Kod przedmiotu 06.9-WM-ER-IB-41_18
Wydział Wydział Mechaniczny
Kierunek WM - oferta ERASMUS
Profil -
Rodzaj studiów Program Erasmus
Semestr rozpoczęcia semestr zimowy 2023/2024
Informacje o przedmiocie
Semestr 1
Liczba punktów ECTS do zdobycia 4
Typ przedmiotu obowiązkowy
Język nauczania angielski
Sylabus opracował
Formy zajęć
Forma zajęć Liczba godzin w semestrze (stacjonarne) Liczba godzin w tygodniu (stacjonarne) Liczba godzin w semestrze (niestacjonarne) Liczba godzin w tygodniu (niestacjonarne) Forma zaliczenia
Wykład 30 2 - - Egzamin
Projekt 30 2 - - Zaliczenie na ocenę

Cel przedmiotu

The aim of the course is introduction to the rehabilitation engineering a specially to the construction of medical equipment, rehabilitation equipment of basic rehabilitation methods.

Wymagania wstępne

Physics, Mechanics and Strength of Materials, Electronics and Electrical engineering, Fundamentals of Engineering Design, Biomechanics, Sensors and Measurements,  Electronic Medical Apparatus 

Zakres tematyczny

Lecture:

1. Introduction to rehabilitation engineering, history of rehabilitation, basic definitions, phases of the rehabilitation process, role of rehabilitation engineering. (2 hours.)

2. Medical, social and vocational rehabilitation. (2 hours.)

3. Introduction to physiotherapy: basics of physiotherapy, therapeutic massage, climatotherapy, balneotherapy, kinesiotherapy. (4 hours)

4. Basics of kinesiotherapy - types of movements, types of exercises. (4 hours)

5. Orthotic equipment. foot orthoses, knee orthoses, hip joint orthoses, lower limb orthoses, lower limb orthotics. (4 hours)

6. Prosthetic equipment: upper limb prostheses, hand prostheses, forearm prostheses, muscle tension measurements, measurements of non-electrical quantities in medical diagnostics and control. (4 hours)

7. Lower limb prostheses, gait kinematics, locomotion, lower limb prosthetics, foot prostheses, dynamic foot prostheses, lower leg prostheses, thigh prostheses, hip prostheses, functional stimulation of the lower limbs (4 hours)

8. Standing and stabilizing equipment, standing frames, auxiliary equipment (2 hours)

9. Sensors in rehabilitation devices, selected rehabilitation devices (2 hours)

10. Modern solutions of intelligent rehabilitation devices. (2 hours.)

Project:

1. Device concept - Literature examples of solutions. Sketches with a description of the elements, their functions and methods of production. Assessment of the advantages and disadvantages of individual proposals. The final concept accepted for implementation. Construction assumptions. (4 hours)

2. 3D model – solid model of the solution, description of the structure and functions of individual elements. 3D view of the assembly and individual parts. Report on the interpenetration of elements. (6 hours)

3. Calculations of force distribution - Analysis of force distribution in the system in selected positions. Determination of forces and moments loading structural elements and nodes. Load diagrams of the designed system. Determining the reactions acting on structural elements as well as the load on the limb. Justification for the adopted burdens. Drive selection. (4 hours)

4. Strength calculations - Calculations of selected structural nodes containing views and load patterns. Indication of design changes forced by structural strength considerations. (4 hours)

5. Assessment of the solution in terms of ergonomics and rehabilitation - Assessment of the structure in terms of ergonomics. Checking whether the structure meets the design assumptions. Suggestions for therapeutic exercises using the device. (2 hours.)

6. Selection of materials - list of elements, semi-finished products, parts and components for purchase. Cost estimate including purchases (according to online prices) and costs estimated. (4 hours)

7. Technical documentation - technical drawings of parts and assemblies. (4 hours)

8. Manufacturing and assembly technology - Description of the technology of manufacturing the elements, description of the assembly procedure. Description of the startup process. (2 hours.)

Metody kształcenia

Conventional lecture, project method, discussion, work with a source document, work in group

Efekty uczenia się i metody weryfikacji osiągania efektów uczenia się

Opis efektu Symbole efektów Metody weryfikacji Forma zajęć

Warunki zaliczenia

Lecture: The condition for passing is obtaining a positive grade in a written exam.

Project: The condition for passing the course is obtaining a positive summative assessment, which consists of: formative assessment based on the assessment of the degree of implementation of individual stages of the project, assessment for presentation and assessment for answers to questions related to the project. The assessment is made individually for each group member.

The project will grade based on:

1. Implementation of an individual project in groups of 1-2 people
2. Submitting reports according to the agreed points of the project implementation schedule
3. Giving the presentation
4. Submission of final project documentation

The final grade is determined based on the arithmetic mean of the grades from the lecture and project.

Literatura podstawowa

 

  1. Powell, Wendy, Rehabilitation: Innovations and Challenges in the Use of Virtual Reality Technologies, New York : Nova Science Publishers, Inc. 2017
  2. Esposito, Salvatore M., Lagana, Raimondo, Rehabilitation : Practices, Psychology and Health, New York : Nova Science Publishers, Inc. 2012
  3. L.H.V. van der Woude, F. Hoekstra, S. de Groot, K.E. Bijker, R. Dekker, P.C.T. van Aanholt, F.J. Het, Rehabilitation: Mobility, Exercise and Sports, Amsterdam : IOS Press. 2010
  4. Chad A. Noggle, Raymond S. Dean,Mark T. Barisa, ABPPNeuropsychological Rehabilitation, New York : Springer Publishing Company. 2013
  5. Leisman Gerry, Merrick Joav, Neuroplasticity in Learning and Rehabilitation, New York : Nova Science Publishers, Inc. 2016

Literatura uzupełniająca

  1. R. Bartlet, Introduction to Sports Biomechanics - Analysing Human Movement Patterns, Routledge, 2007
  2. Susan B. O'Sullivan, Thomas J. Schmitz, George Fulk, Physical Rehabilitation, F.A. Davis Company, 2019
  3. Rory a Cooper, Douglas A. Hobson, Hisaichi Ohnabe, An Introduction to Rehabilitation Engineering, Taylor & Francis INC International Concepts, 2006
  4. Hoffman, Shirl J.; Knudson, Duane V., Introduction to Kinesiology 5th Edition With Web Study Guide, Human Kinetics Publishers, 2017
     

Uwagi


Zmodyfikowane przez dr hab. inż. Tomasz Klekiel, prof. UZ (ostatnia modyfikacja: 14-05-2024 12:16)