Analysis of the Effectiveness of Dry Ice Agglomeration in Crank Piston Pelletizeri

Górecki, J.; Talaśka, K.; Wałęsa, K.; Wilczyński, D.

Artykuł - szczegóły

Tytuł artykułu

Analysis of the Effectiveness of Dry Ice Agglomeration in Crank Piston Pelletizeri

Autorzy

Górecki J. , Talaśka K. , Wałęsa K. , Wilczyński D.

Wybrane pełne teksty z tego czasopisma

http://www.simr.pw.edu.pl/ipbm/Instytut-Podstaw-Budowy-Maszyn/Nauka/Machine-Dynamics-Research

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Warianty tytułu

Języki publikacji

Abstrakty

The article presents the results of the analysis of effectiveness of the force utilized in the process of agglomeration of dry ice in the crank-piston compaction technique. The analysis is a continuation of research intended to demonstrate the effectiveness of the system. The results will be used to formulate design recommendations that will be taken into consideration when designing machines for the agglomeration of crystallized carbon dioxide. Results presented in this article are the second part of the work aimed at describing the operation of the agglomerating machine which realizes the compaction process of dry ice utilizing the crank-piston technique.

Słowa kluczowe

crystallized carbon dioxide thickening power machine design dry ice

Wydawca

Oficyna Wydawnicza Politechniki Warszawskiej

Czasopismo

Machine Dynamics Research

Rocznik

2018

Tom

Vol. 42, No. 4

Strony

33--41

Opis fizyczny

Bibliogr. 21 poz., wykr.

Twórcy

autor

Górecki J.

Poznań University of Technology, Chair of Machine Design Basic

autor

Talaśka K.

Poznań University of Technology, Chair of Machine Design Basic

autor

Wałęsa K.

Poznań University of Technology, Chair of Machine Design Basic

autor

Wilczyński D.

Poznań University of Technology, Chair of Machine Design Basic

Bibliografia

1. Chen L., Zhang X., 2014: A review study of solid-gas sublimation flow refrigeration From basic mechanism to applications, International Journal of Refrigeration, vol. 40, pp. 61-83.
2. Dong S., Song B., Hansz B., et al., 2012: Modeling of dry ice blasting and its application in thermal spray, Material Research Innovations, vol. 16, pp. 61-66.
3. Drzymała Z., 1988: Podstawy inżynierii procesu zagęszczania i prasowania materiałów, Warszawa, PWN.
4. Górecki J., Malujda I., Talaśka K., 2013: Research on Densification of solid carbon dioxide, Journal of Mechanical and Transportation Engineering, 65 (4), p. 5-12.
5. Górecki J., Malujda I., Talaśka K., et al., 2016: Influence of the Value of Limit Densification Stress on the Quality of Pellets During the Aglomeration Process of CO2. Procedia Engineering, vol. 136, pp 269-274.
6. Górecki J., Malujda I., Talaśka K. 2016: Investigation of internal friction of agglomerated dry ice, Procedia Engineering, vol. 136, pp. 275-279.
7. Górecki J., 2017: Doctoral Thesis: Shaping of the geometrical parameters of the working assembly of the CO2 agglomeration machine using the modeling of the limit stress (in polish), Poznan University of Technology.
8. Górecki, J., Malujda, I., Talaśka, K., Wojtkowiak, D., 2017: Dry ice compaction in piston extrusion process, Acta mechanica et automatic, vol. 11/4, 313-316.
9. Górecki, J., Malujda, I., Talaśka, K., Wilczyński, D., Wojtkowiak, D., 2018: Influence of geometrical parameters of convergent sleeve on the value of limit stress, MATEC Web of Conferences, vol. 157: 05006, 050061-0500610.
10. Hejft R., Obodziński S., 2012: Ciśnieniowa aglomeracja materiałów roślinnych innowacje technologiczno-techniczne. Część I, Journal of Resarch and Applications In Agricultural Engineering, vol. 57 (1).
11. Li M., Liu W., Qing X., et al., 2016: Feasibility study of a new approach to removal of paint coatings in remanufacturing, Journal of Materials Processing Technology, vol 234, pp 102-112.
12. Liu Y., Maruyama H., Matusaka S., 2010: Agglomeration process of dry ice particles produced by expanding liquid carbon dioxide, Advanced Powder Technology, vol. 21, p. 652-657.
13. Mazzoldi A., Hill T., Colls J., 2008: CO2 transportation for carbon capture and storage: Sublimation of carbon dioxide form a dry ice bank, International Journal of greenhouse gas control’s, vol. 2, p. 210-2183.
14. Mikołajczak A., Krawczyk P., Stępień M., Badyda K., 2018: Preliminary specification of the dry ice blasting converging-divergent nozzle parameters basing on the standard (analytical) methods, Rynek Energii, vol. 4, 91-96.
15. Nowicka E., Machnicka A., 2015: Hygienization of surplus activated sludge by dry ice, Ecological Chemistry and Engineering, vol. 21, pp. 651-660.
16. Otto C., Zahn S., Rost F., et al., 2011: Physical Methods for Cleaning and Disinfection of Surface, Food Engineering Reviews, vol. 3, pp 171-188.
17. Spur G., Uhlmann E., Elbing F., 1999: Dry-ice blasting for cleaning: process, optimization and application, Wear, 1999, 233-235, p. 402-411..
18. Talaśka, K., 2018: Study of research and modelling of compaction processes of powder and shredded materials (in polish), Poznan University of Technology.
19. Witte A., Bobal M., David R., et al., 2017: Investigation of the potential of dry ice blasting for cleaning and disinfection in the food production environment, LWT- Food Science and Technology, vol. 75, pp. 735-741.
20. Vansant J., 2013: Carbon dioxide emission and merchant market in the European union. In Aresta M. (eds) Carbon Dioxide Recovery and Utilization, Springer Science & Business Media.
21. Yamaguchi H., Niu X., Sekimoto K., Neksa P., 2011: Investigation of dry ice blockage in an ultra-low temperature cascade refrigeration system using CO2 as a working fluid, International Journal of Refrigeration, vol. 34 pp. 466-475.

Typ dokumentu

Bibliografia

Identyfikator YADDA

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