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Peculiarities of heat exchange in dough under rotary rollers action

НазваPeculiarities of heat exchange in dough under rotary rollers action
Назва англійськоюPeculiarities of heat exchange in dough under rotary rollers action
АвториVolodymyr Piddubnyy, Lyudmila Kahanets-havrylko, Viktor Fedoriv, Viktor Senchishin, Ihor Stadnyk
ПринадлежністьNational University of Trade and Economy, Kyiv, Ukraine Uzhhorod trade and economic professional college of the State trade and economic university, Uzhgorod, Ukraine Podilsky State University, Kamianets-Podilskyi, Ukraine Ternopil Ivan Puluj National Technical University, Ternopil, Ukraine
Бібліографічний описPeculiarities of heat exchange in dough under rotary rollers action / Volodymyr Piddubnyy, Lyudmila Kahanets-havrylko, Viktor Fedoriv, Viktor Senchishin, Ihor Stadnyk // Scientific Journal of TNTU. — Tern.: TNTU, 2023. — Vol 109. — No 1. — P. 43–53.
Bibliographic description:Piddubnyy V., Kahanets-havrylko L., Fedoriv V., Senchishin V., Stadnyk I. (2023) Peculiarities of heat exchange in dough under rotary rollers action. Scientific Journal of TNTU (Tern.), vol 109, no 1, pp. 43–53.
DOI: https://doi.org/10.33108/visnyk_tntu2023.01.043
УДК

664.643

Ключові слова

dough, injection, heat conductivity, heat spread, heat flow, roller, phase, medium.

Any impact of mechanical action on a viscous medium contributes to the transformation of a volumetric spongy-reticular solid structure into a gluten skeleton, as it defines the elastic and viscous characteristics of the medium and it is important in gas dispersion in a liquid. Thus, the aim of the study under consideration was to determine the relationship between the working surface of the working body and the amount of heat Q transferring per unit of time from the roller wall to the medium. The problem of the development of a generalized model of a working process of rollers’ action on the medium has been solved due to the study under discussion. The problem is aimed at obtaining the structural, expenditure, and energy characteristics, as well as at determining the ways of increasing the efficiency of such class of machines operation under deformation modes conditions. Some peculiar features of the compression area have been taken into consideration in cases when the temperature pressure value by the angle of rotation varies constantly. It was proved, that the heat-transfer coefficient value  can be calculated quite approximately as it is necessary to take into account an available area influencing the heat exchange and the movement speed on the working dough roller surface in the injection area.  Some temperature state variations of the dough in bagels production during its compressing, injection, and transportation have been determined. It was admitted, that the impact of the liquid phase temperature of the working medium  is determined by the value of its kinematic viscosity . The temperature variations were determined by means of thermal imaging of a pilot plant.

ISSN:2522-4433
Перелік літератури
  1. Paul Byrne, Redouane Ghoubali (2019), Exergy analysis of heat pumps for simultaneous heating and cooling. Applied Thermal Engineering. Volume 149. 2019. P. 414–424.
  2. Z. Y. Xu, R. Z. Wang, Chun Yang (2019), Perspectives for low-temperature waste heat recovery. Energy. Volume 176. 2019. P. 1037–1043.
  3. Musale S. V., Chavan U. D. and Kotecha P. M. (2021) International Journal of Advances in Engineering and Management (IJAEM). Volume 3. Issue 8. P. 1028–1044.
  4. Igor Stadnyk, Volodymyr Piddubnuy, Olena Eremeeva, Halyna Karpyk (2018) Features of heat transfer in the environment when it is sprayed with rotary rollers. Potravinarstvo Slovak Journal of Food Sciences. Vol. 12. 2018. No. 1. P. 824–835.
  5. Savenkova T. V., Soldatova E. A., Misteneva S. Y., Taleysnik M. A. (2019). Technological properties of flour and their effect on quality indicators of sugar cookies. Food Systems. 2 (2). Р. 13–19.
  6. Shishkin A., Sadygova M., Belova M., Kirillova T. (2020). Mathematical model of resource-saving production technology of baked goods with amaranth flour. Journal of Engineering Studies and Research. 26 (3). Р. 195–203.
  7. Sokolenko A. I., Mazaraki A. A., Piddubniy V. A. ta in. Energetichni transformatsii i energozberezhennya v harchovih tehnologiyah: monografiya. K.: Feniks, 2012. 484 р.
  8. Naschokin V. V. Tehnicheskaya termodinamika i teploperedacha. M.: Vyisshaya shkola, 1980. 469 р.
  9. Pankiv Yu. Yu., Stadnik I. Ya., Vasiliv V. P., Kos T. S. Dinamika mizhfazovoyi vzaemodiyi mizh komponentami pri peremIshuvannI. Zb. naukovih prats Institutu prodovolchih resursIv NAAN. Prodovolchi resursi. 2020. Tom 8. No. 15. Р. 174–184.
  10. Sokolenko A. I., Shevchenko O. Yu., Piddubniy V. A. Intensifikatsiya masoobminnih protsesiv v harchovih tehnologiyah. K.: Lyuksar, 2008. 443 р.
References:
  1. Paul ByrneRedouane Ghoubali (2019), Exergy analysis of heat pumps for simultaneous heating and cooling. Applied Thermal EngineeringVolume 149. 2019. P. 414–424.
  2. Z. Y. Xu, R. Z. Wang, Chun Yang (2019), Perspectives for low-temperature waste heat recovery. EnergyVolume 176. 2019. P. 1037–1043.
  3. Musale S. V., Chavan U. D. and Kotecha P. M. (2021) International Journal of Advances in Engineering and Management (IJAEM). Volume 3. Issue 8. P. 1028–1044.
  4. Igor Stadnyk, Volodymyr Piddubnuy, Olena Eremeeva, Halyna Karpyk (2018) Features of heat transfer in the environment when it is sprayed with rotary rollers. Potravinarstvo Slovak Journal of Food Sciences. Vol. 12. 2018. No. 1. P. 824–835.
  5. Savenkova T. V., Soldatova E. A., Misteneva S. Y., Taleysnik M. A. (2019). Technological properties of flour and their effect on quality indicators of sugar cookies. Food Systems. 2 (2). Р. 13–19.
  6. Shishkin A., Sadygova M., Belova M., Kirillova T. (2020). Mathematical model of resource-saving production technology of baked goods with amaranth flour. Journal of Engineering Studies and Research. 26 (3). Р. 195–203.
  7. Sokolenko A. I., Mazaraki A. A., Piddubniy V. A. ta in. Energetichni transformatsii i energozberezhennya v harchovih tehnologiyah: monografiya. K.: Feniks, 2012. 484 р.
  8. Naschokin V. V. Tehnicheskaya termodinamika i teploperedacha. M.: Vyisshaya shkola, 1980. 469 р.
  9. Pankiv Yu. Yu., Stadnik I. Ya., Vasiliv V. P., Kos T. S. Dinamika mizhfazovoyi vzaemodiyi mizh komponentami pri peremIshuvannI. Zb. naukovih prats Institutu prodovolchih resursIv NAAN. Prodovolchi resursi. 2020. Tom 8. No. 15. Р. 174–184.
  10. Sokolenko A. I., Shevchenko O. Yu., Piddubniy V. A. Intensifikatsiya masoobminnih protsesiv v harchovih tehnologiyah. K.: Lyuksar, 2008. 443 р.
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