RESEARCH PAPER
Butt Welding of Round Drive Belts
1
Faculty of Machines and Transportation, Chair of Basics of Machine Design, Poznań University of Technology, ul. Piotrowo 3, 60-965 , Poznań, Poland
Submission date: 2017-09-27
Acceptance date: 2018-06-12
Online publication date: 2018-07-17
Publication date: 2018-06-01
Acta Mechanica et Automatica 2018;12(2):115-126
KEYWORDS
ABSTRACT
The on-going rapid development of industry encourages development of new production technologies and designing of machines that use inventive mechanical engineering solutions, a big demand for parts of such machines being a natural consequence. Polymeric power transmission belts are a good example of that. This paper proposes an improvement in the process of production of such belting. Their production includes cutting to length and splicing of elastic round belts to obtain endless belts of the specified length. This is the key phase of the whole production process. A number of splicing methods are available using different physical phenomena. One of them is butt welding technique. In this process heat is applied on the material through an additional heating element called the heat platen. The effect depends on several factors, including preparation of the work pieces. Due to its characteristics the process is often carried out by hand. The need for automated manufacturing was created by important factors associated with manufacturing on an industrial scale: cost, time and quality. The proposed butt welding machine, complete with a control system is an answer to this need. The practical benefits include improved repeatability of splices, time savings and less work load for the operator.
REFERENCES (24)
1.
Amanat N., James N. L., McKenzie D.R. (2010), Welding methods for joining thermoplastic polymers for the hermetic enclosure of medical devices, Medical engineering & Physics, Vol. 32, 690–699.
2.
Amancio-Filho S.T., dos Santos J.F. (2009), Joining of Polymers and Polymer-Metal Hybrid Structures: Recent Developments and Trends, Polymer Engineering and Science, 49(8), 1461–1476.
3.
Ashby M.F., Jones D.R.H. (1996), Engineering materials (in Polish), WNT, Warszawa.
5.
Casalino G., Ghorbel E. (2008), Numerical model of CO2 laser welding of thermoplastic polymers, Journal of Materials Processing Technology, 207, 63–71.
6.
Ciszewski A., Radomski T. (1989), Construction materials in machine design (in Polish), PWN, Warszawa.
7.
Cocard M., Grozav I., Iacob M., Caneparu A. (2009), Establishing the Optimum Welding Procedure for PE 100 Polyethylene Pipelines Using the Response Surface Design, Materiale Plastice, 46(4), 452–457.
8.
Domek G., Dudziak M. (2011), Energy Dissipation in Timing Belts Made From Composite Materials, Advanced Material Research, 189–193, 4414–4418.
9.
Domek G., Kołodziej A., Dudziak M., Woźniak T. (2016), Identification of the quality of timing belt pulleys, Procedia Engineering, 177, 275–280.
10.
Domek G., Malujda I. (2007), Modeling of timing belt construction, Proceedings in Applied Mathematics and Mechanics, 7, 45–46.
11.
Evers F., Schöppner V., Lakemeyer P. (2017), The influence on welding processes on the weld strength of flame-retardant materials, Weld World, 61, 161–170.
12.
Inoue T., Miyata R., Hirai S. (2016), Antagonistically Twisted Round Belt Actuator System for Robotic Joints, Journal of Robotics and Mechatronics, 28(6), 842 – 853.
13.
Jasiulek P. (2006), Joining of plastics by welding, glueing and laminating (in Polish), Wydawnictwo “KaBe”, Krosno.
14.
Klimpel A. (1999), Metals and thermoplastic polymers welding technology (in Polish), Wydawnictwo Politechniki Śląskiej, Gliwice.
15.
Klimpel A. (2000), Welding of termoplastics materials (in Polish), Wydawnictwo Politechniki Śląskiej, Gliwice.
16.
Kukla M., Tarkowski P., Malujda I., Talaśka K., Górecki J. (2016), Determination of the torque characteristics of a stepper motor, Procedia Engineering, 136, 375–379.
17.
Madej M., Ozimina D. (2010), Plastics and composite materials (in Polish), Wydawnictwo Politechniki Świętokrzyskiej, Kielce.
18.
Puszka A. (2006), Polyurethanes – sources, properties and modifications (in Polish), Zakład Chemii Polimerów, Wydział Chemii Uniwersytetu Marii Curie Skłodowskiej w Lublinie, Lublin.
19.
Rzasinski R., (2017), The algorithm of verification of welding process for plastic pipes, IOP Conference Series: Materials Science and Engineering, 227, 012113.
20.
Sikora R. (1993), Proceeding macromolecular materials (in Polish), Wydawnictwo ŻAK, Warszawa.
21.
Sreejeth M., Singh M., Kumar P. (2012), Monitoring, Control and Power Quality Issues of PLC Controlled Three-Phase AC Servomotor Drive, 2012 IEEE Fifth Power India Conference, 19-22 Dec. 2012, Murthal, India.
22.
Wanqing L., Changqing F., Xing Z., Youliang C., Rong Y., Donghong L. (2017), Morphology and thermal properties of polyurethane elastomer based on representative structural chain extenders, Thermochimica Acta, 653, 116–125.
23.
Yousepour A., Hojjari M., Immarigeon J-P. (2004), Fusion Bonding/Welding of Thermoplastic Composites, Journal of Thermoplastic Composite Materials, 17, 303–341.
| eISSN: | 2300-5319 |
| ISSN: | 1898-4088 |
We process personal data collected when visiting the website. The function of obtaining information about users and their behavior is carried out by voluntarily entered information in forms and saving cookies in end devices. Data, including cookies, are used to provide services, improve the user experience and to analyze the traffic in accordance with the Privacy policy. Data are also collected and processed by Google Analytics tool (more).
You can change cookies settings in your browser. Restricted use of cookies in the browser configuration may affect some functionalities of the website.
You can change cookies settings in your browser. Restricted use of cookies in the browser configuration may affect some functionalities of the website.
