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Screening for Sexually Transmitted Infections in Adolescents with Genitourinary Complaints: Is There a Still Role for Endocervical Gram Stains?
Subah Nanda, Amanda Schoonover, Jasman Kaur, Annie Vu, Erica Tavares, Angela Zamarripa, Christian Kolacki, Lindsey Ouellette and Jeffrey Jones
Abstract

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Engineering Group Mini Review 記事ID: igmin252

Issues of Manufacturability of Roller Machines

Mechanical Engineering Affiliation

Affiliation

    Institute of Mechanics and Seismic Stability of Structures named after M.T.Urazbaev, Uzbekistan Academy of Sciences, Tashkent, Uzbekistan

要約

Issues of maintenance of manufacture adaptability are considered in the article on an example of roller squeezing machines; recommendations to increase the manufacture adaptability of designs are offered. The geometry and kinematics of the attachment points of the base plate of a vertical-type squeezing roller machine are considered.

数字

参考文献

    1. Donya DV, Leonov AA. Engineering rheology: textbook. Kemerovo Technological Institute of Food Industry; Kemerovo: 2008; 123. Available from: https://sng1lib.org/book/3010942/fc93e8
    2. Attenburrow EA. The rheology of leather: a review. J Soc Leather Technol Chem. 1993;77(4):107-11. Available from: https://www.researchgate.net/publication/269572329_The_Rheology_of_Leather_-_A_Review
    3. Rymkevich PP, Gorshkov AS. Nonlinear Kelvin-Voigt model. Vestn Vyssh Uchebn Zaved Legk Prom. 2022;55(1):8-12. doi:10.46418/0021-3489_2022_55_01_02.
    4. Golovina VV, Rymkevich PP, Vagner VI. Application of nonlinear rheological models to the description and explanation of non-classical behavior of longitudinal free low-amplitude vibrations in polymer yarns. Vestn Vyssh Uchebn Zaved Legk Prom. 2022;55(1):13-18. doi:10.46418/0021-3489_2022_55_01_03.
    5. Ward AG. The mechanical properties of leather. Rheol Acta. 1974;13:103-12. doi:10.1007/BF01526892.
    6. Furashova SL, Gorbachik VE, Skokov PI. Using model methods to describe the stress relaxation of footwear materials. Bull Kazan Technol Univ. 2007;(6). Available from: https://cyberleninka.ru/article/n/ispolzovanie-modelnyh-metodov-dlya-opisaniya-relaksatsii-napryazheniy-obuvnyh-materialov (accessed 2024 Jan 16).
    7. Li Z, Paudecerf D, Yang J. Mechanical behaviour of natural cow leather in tension. Acta Mechanica Solida Sinica. 2009;22(1):37-44. doi:10.1016/S0894-9166(09)60088-4.
    8. Tikhonova NV, Abdullin IS, Makhotkina LY, Zhukovskaya TV, Yusupova AR. Study of the deformation characteristics of a multilayer shoe upper blank material after plasma exposure. Bull Kazan Technol Univ. 2014;(2). Available from: https://cyberleninka.ru/article/n/issledovanie-deformatsionnyh-harakteristik-mnogosloynogo-materiala-zagotovki-verha-obuvi-posle-plazmennogo-vozdeystviya (accessed 2024 Jan 16).
    9. Amanov A, Bahadirov G, Amanov T, Tsoy G, Nabiev A. Determination of Strain Properties of the Leather Semi-Finished Product and Moisture-Removing Materials of Compression Rolls. Materials (Basel). 2019 Nov 4;12(21):3620. doi: 10.3390/ma12213620. PMID: 31689954; PMCID: PMC6862193.
    10. Amanov AT, Bahadirov GA, Amanov TY, Tsoy GN, Nabiev AM. The improvement of the rheological model of leather. Int J Adv Sci Eng Inf Technol. 2023;13(1):321-8. doi:10.18517/ijaseit.13.1.17360.
    11. Filin AP. Applied mechanics of a deformable rigid body. Moscow: Main Editorial Office of Physical and Mathematical Literature of the "Nauka" Publishing House; 1975; 832.
    12. Khusanov IN, Tsoy GN, Khusanova UI. Method for determining the rheological parameter during the deformation of a material. Patent UZ No. IAP 05761; Publ. Bulletin No. 2, 2019 Feb 28.
    13. Burmistrov AG. A device for determining the relaxation properties of leather and similar flexible materials. RF Patent No. 2210753; Publ. 2003 Aug 20, Bulletin No. 23.
    14. Burmistrov AG, Kocherov AV, Grodsky DM. On the accuracy of approximation of relaxation functions on the "RELAX" installation. Thematic collection of scientific works of MGUDT. 2007;262-4.
    15. Burmistrov AG. Machines and devices for the production of leather and fur. Moscow: Kolos S; 2006; 384.
    16. Leather processing & tanning technology handbook. 2011. NIIR Board of Consultants & Engineers. ISBN 10: 8190568590. Available from: https://books.google.com.hk/books?id=hbKkCwAAQBAJ
    17. Renaud M, Rueff M, Rocaboy A. Mechanical behaviour of saturated wood under compression. Wood Sci Technol. 1996.
    18. Ward AG. The mechanical properties of leather. Rheol Acta. 1974.
    19. Santos RJ, Agostini DL, Cabrera FC, Budemberg ER, Job AE. Recycling leather waste: preparing and studying the microstructure, mechanical, and rheological properties of leather waste/rubber composite. Polym Compos. 2015.
    20. Amanov AT, Bahadirov GA, Nabiev AM. A study on the pressure mechanism improvement of a roller-type machine working bodies. Materials (Basel). 2023.
    21. Amanov AT, Bahadirov GA, Tsoy GN, Nabiev AM. Improvement of the process of mechanical dehydration of five-layer semi-finished wet leather products. Leather Rev. 2021.
    22. Amanov AT, Bahadirov GA, Tsoy GN, Nabiev AM. Effect of multilayer processing of semi-finished leather products. Int J Mech Eng Robot Res. 2022.
    23. Bahadirov G, Musirov M, Nabiev A. Determination of rational parameters of a device for leather feeding to the machining area. East Eur J Enterp Technol. 2023;2(1(122)):62–72. doi:10.15587/1729-4061.2023.277393.
    24. Bahadirov GA, Umarov AA, Nabiev AM, Tsoy GN. Experimental determination of the non-homogeneity of the physical parameters of a leather semi-finished product. E3S Web Conf. 2023;389:01028. doi:10.1051/e3sconf/202338901028.
    25. Bahadirov GA, Tsoy GN, Nabiev AM. The effect of roller pressure and feed rate on hides squeezing. E3S Web Conf. 2023;402:00016. doi:10.1051/e3sconf/202340210016.
    26. Amanov TY, Baubekov SD, Tsoy GN, Nabiev AM. Device for providing pressure force between working bodies of roller technological machines. Mod High-Tech Technol. 2023;9. Available from: https://top-technologies.ru/ru/article/view?id=37151
    27. Xia Y, Wei S, Deng Y, Jin Y. A new enriched method for extended finite element modeling of fluid flow in fractured reservoirs. Comput Geotech.
    28. Bandara S, Soga K. Corrigendum to: Coupling of soil deformation and pore fluid flow using material point method. Comput Geotech. 2015;63(1):199-214. doi:10.1016/j.compgeo.2014.12.007.
    29. Xiao Y, Tang Z, Hong X, Chen S. Application of normalized SPH method to inviscid fluid flows with large deformation of free surface. Comput Fluids.
    30. Wang H, Tan Z, Kuang S, Yu A. Numerical modeling and analysis of particle-fluid flow and wall erosion in centrifugal slurry pumps under different solid concentrations. Powder Technol.
    31. Shi B, Wei J, Zhang Y. A novel experimental facility for measuring internal flow of solid-liquid two-phase flow in a centrifugal pump by PIV. Int J Multiph Flow. 2017.
    32. Peng G, Huang X, Zhou L, Zhou G, Zhou H. Solid-liquid two-phase flow and wear analysis in a large-scale centrifugal slurry pump. Eng Fail Anal. 2021.
    33. Tarodiya R, Levy A. Surface erosion due to particle-surface interactions: A review. Powder Technol. 2021.
    34. Onem E. Quality properties of leather produced in water and supercritical fluid (SCF) media. J CO2 Util. 2018.
    35. Krishnamoorthy G, Sadulla S, Sehgal PK, Mandal AB. Green chemistry approaches to leather tanning process for making chrome-free leather by unnatural amino acids. J Hazard Mater. 2012.
    36. Sayegh MA, Rouzineau D, Meyer M, Cid E, Alix P, Dalmazzone C, Roesler J. Impact of physico-chemical properties on falling liquid films flow over flat and corrugated surfaces. Int J Multiph Flow. 2022.
    37. Khan R, Kumar R, Ma Z. Experimental investigations on the performance characteristics of plastic surfaces for developing low flow falling film liquid desiccant regenerators. Sol Energy. 2022.
    38. Nabiev AM. Combined extraction of liquid from wet leather semi-finished products. In: Proceedings of the 7th International Conference on Industrial Engineering. Lecture Notes in Mechanical Engineering. Springer, Cham; 2022. doi:10.1007/978-3-030-85233-7_59.
    39. Tsoy GN. Experimental determination of the influence of fibrous material on the dehydration of wet semi-finished leather products. In: Proceedings of the 7th International Conference on Industrial Engineering (ICIE 2021). Lecture Notes in Mechanical Engineering. Springer, Cham; 2022. doi:10.1007/978-3-030-85233-7_60.
    40. Bahadirov G, Tsoy G, Nabiev A. Study of the efficiency of squeezing moisture-saturated products. EUREKA: Phys Eng. 2022;1:86-96. doi:10.21303/2461-4262.2021.001606.
    41. Amanov AT, Bahadirov GA, Tsoy GN, Nabiev AM. A new method to wring water-saturated fibrous materials. Int J Mech Eng Robot Res. 2021;10(3):151-156. doi:10.18178/ijmerr.10.3.151-156.
    42. Bahadirov G, Sultanov T, Tsoy G, Nabiev A. Experimental dehydration of wet fibrous materials. In: Proceedings of the International Scientific Conference “Construction Mechanics, Hydraulics and Water Resources Engineering” (CONMECHYDRO - 2021); Tashkent, Uzbekistan. Edited by Bazarov D; E3S Web of Conferences, 2021; 264:04060. doi:10.1051/e3sconf/20212640406.
    43. Nabiev AM, Tsoy GN, Bahadirov GA. Conditions for vertical pulling of semi-finished leather products under driving rollers. E3S Web Conf. 2023;376:01073. doi:10.1051/e3sconf/202337601073.
    44. Umarov A, Nabiev A, Khusanov K, Shernaev A. Features of parameters of a pair of rolls. AIP Conf Proc. 2023;2821(1):030020. doi:10.1063/5.0159452.
    45. Nabiev AM, Tsoy GN, Bahadirov GA. Ensuring conditions for the squeezed fluid flowing from the skin along the conveyor of the technological machine. E3S Web Conf. 2023;458:02015. doi:10.1051/e3sconf/202345802015.
    46. Nabiev AM, Tsoy GN, Bahadirov GA. Device for determining permeability of tanning liquid. Int J Mod Manuf Technol. 2023;15(3):8. doi:10.54684/ijmmt.2023.15.3.8.
    47. Bahadirov GA, Tsoy GN, Nabiev AM. Equipment and technology for processing raw hides: Monograph. Novosibirsk: Publishing House LLC "SibAK"; 2023. 214. EDN BPGDBU.
    48. Bahadirov GA, Nabiev AM, Rakhimov FR, Musirov MU. Determination of the parameters of the chain conveying device of the roller machine. Izvestiya Vysshikh Uchebnykh Zavedenii, Seriya Tekhnologiya Tekstil'noi Promyshlennosti. 2023;5(407):168-174. doi:10.1186/s42825-019-0017-5.
    49. Rakhimov FR, Achilov GQ. Determination of the support reaction forces of the feeding mechanism of a multi-operation machine. AIP Conf Proc. Nandyal, India; 2023;2821:030021. doi:10.1063/5.0159449.
    50. Ershov SV, Suvorov IA, Kuznetsov VB, Nikiforova EN, Kalinin EN. Synthesis of a 3D model of a woven reinforcing structure of a textile composite using the methodology of numerical object-oriented modeling. Text Ind Technol. 2021;1(391):114-119. doi:10.47367/0021-3497_2021_1_114.
    51. Ershov SV, Kalinin EN. Modeling the process of squeezing fibrous materials in a roller pair with a dynamic loading mode. In: Proceedings of Physics of Fibrous Materials: Structure, Properties, Science-Intensive Technologies and Materials (SMARTEX); 2020;1:277-281. doi:10.47367/2413-6514_2020_1_277.
    52. Nabiev AM, Tsoy GN, Bahadirov GA, Umarov AA, Rakhimov FR, Musirov MU. Experimental determination of the breakaway force of working rolls when processing semi-finished products. BIO Web Conf. 2024;93:03007. doi:10.1051/bioconf/20249303007.
    53. Nabiev AM, Bahadirov GA, Tsoy GN. Technological modes of the process of two-layer pressing of wet leather. Int J Innov Eng Res. 2024;3(9):1-6. Available from: https://ijieronline.com/assets/img/issues/A030920240106.pdf.
    54. Bahadirov GA, Nabiev AM, Tsoy GN. Improvement of quality indices of leather fabrics of fur skins. BIO Web Conf. 2024;130:0015. doi:10.1051/bioconf/202413007015.
    55. Amanov TY, Baubekov SD, Tsoy GN, Nabiev AM. Device for providing pressure force between working bodies of roller technological machines. Mod High-Tech Technol. 2018;9:9-14.

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