Special Welding Technology (FSI-HSV-K)

The main objective of the course is to provide students with the theoretical foundations and methodology necessary for solving technologies of problems relating to the application of special welding technologies. Students will acquire knowledge necessary for a complex solution of special welding technology application.

Students will acquire knowledge of unconventional types of modern welding technologies, and will be able to apply these technologies to particular examples of special welding. They will be able to independently and creatively work on a welding procedure.

Students are expected to be familiar with the fundamentals of fusion and pressure welding technology, as well as with science of materials.

The special methods of fusion welding. The course deals with the technology of welding by high-power sources such as plasma, electron-beam and laser applications. It familiarises students with technological methods of thermal spraying and their industrial application. Special welding methods, stud welding. The special methods of pressure welding. Friction welding, explosion welding and diffusion welding. Metal 3D printing methods. Soldering of metals.

The course is taught through lectures which are focused on basic principles and theories of the individual sectors. The teaching is completed by practical laboratory exercises.

The course-unit credits award is based on attendance at seminars, correct elaboration of computational assignment and active participation in its processing.

The final exam will be composed of written and oral part.

It is classificated to the ECTS grading scale.

The attendance to the seminar is regularly checked and the participation in the lesson is recorded. The missed lesson a student will elaborate the complemental task.

1. Introduction. Importance, advantages and disadvantages of special welding methods. Special arc methods.


2. Summary of materials and their weldability


3. Friction welding, FSW and electromagnetic pulse


4. Laser, electron beam welding


5. Laser, plasma, water jet cutting


6. Hybrid welding and 3D printing of metal materials - WAAM


7. Adhesive bonding


8. Hybrid joining


9. Deformation in welding


10. Residual and internal stresses induced by welding


11. The possibility of measuring quantities during and after welding - temperature field, deformation, residual stress, macro/micro, hardness


12. Welding and limit states – statics, dynamics, fatigue


13. Welding and limit states – brittle fracture and creep

1. Advantages of special welding methods. Standard EN ISO 9013.


2. Plasma welding and cutting and others aplications.


3. Electron beam welding and other aplications.


4. Basic about laser beam welding and cutting, hardening and deposit welding.


5. Water-jet cutting and electromagnetic puls welding.


6. Hybrid welding, 3D metal printing.


7. Friction and friction stir (FSW) welding, ultrasonic welding.


8. Difusion welding. Cold pressure welding. Flow Drill.


9. Pressure stick welding. Spot-spin welding. High frequency welding.


10. Aluminotermic welding, explosion welding, electroslag welding.


11. Plastic welding.


12. Soldering and brazing and hybrid brazing.


13. Adhesive bonding and hybrid bonding.

1. Weldability of selected materials


2. Assessment of the quality of the weld joint, weldability


3. Plasma cutting


4. Electron beam welding - excursion


5. Laser welding - excursion


6. Welding of studs


7. Measurement and evaluation of roughness on laser burns


8. Welding of plastics


9. Hybrid joining


10. Flow drill


11. The possibility of measuring quantities during and after welding - temperature field, deformation, residual stress, macro/micro, hardness


12. Welding and limit states – statics, dynamics, fatigue


13. Welding and limit states – brittle fracture and creep