Oziq-ovqat va kimyo sanoatida innovasion texnologiyalarni joriy qilish

“Oziq-ovqat va kimyo sanoatida innovasion texnologiyalarni joriy qilish”

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• Foydalanilgan adabiyotlar

“Oziq-ovqat va kimyo sanoatida innovasion texnologiyalarni joriy qilish”  mavzusidagi respublika ilmiy-amaliy konferensiya materiallari. 2023 yil 2-3 iyun  325  Qayta ishlangan polikarbonatning morfologik xarakteristikalari silindrsimon zarrachalarni  aniqlandi, ularning o'lchamlari 1,5 mm dan 3,0 mm gacha, silliq va porloq sirt, shuningdek, qo'pol  tuzilishga ega; bunday xususiyatlar polikarbonatni betonga aralashtirish uchun javob beradi.  Kristallikka hurmat, diffraktsiya cho'qqilari polikarbonat va Rutil komponentlari bilan bog'liq; Bu  C 16 O 33  stokiometriyasini taklif qiladigan EDS tomonidan tasdiqlangan. Bundan tashqari, chiqindi polikarbonatning funktsional guruhlari FT-IR spektroskopiyasi  orqali aniqlandi. Kutilganidek, bosim kuchi qiymatlari va betonning muvozanat zichligi  polikarbonat zarrachalarining o'lchamlari va uning konsentratsiyasiga bog'liq; eng yuqori bosim  kuchi qiymatlari 3% kichikroq zarralar bo'lgan beton uchun olingan, bu qiymatlar polikarbonat  zarralari bo'lmagan betonga nisbatan 20% yuqori edi.  Kichikroq polikarbonat zarrachalari betonda kamroq bo'sh joy yaratadi va natijada bosim  kuchi oshadi. Bundan tashqari, qayta ishlangan polikarbonat konsentratsiyasi oshganda, betonning  muvozanat zichligi zarracha o'lchamidan qat'i nazar, pasayadi. Polikarbonatli beton ACI 213R  standartiga mos kelishi istiqbolli.  Foydalanilgan adabiyotlar  1- ACI 213R (2003), Guide for Structural Lightweight-Aggregate, Concrete American  Concrete Institute, Farmington Hills, Michigan, U.S.A. 2- ASTM (2014), ASTM C567/C567M-14 Standard Test Method for Determining Density of  Structural Lightweight Concrete, American Society for Testing and Materials, West  Conshohocken, Pennsylvania, U.S.A. ASTM (2015), ASTM C192/C192M-15 Standard Practice  for Making and Curing Concrete Test Specimens in the Laboratory, American Society for Testing  and Materials, West Conshohocken, Pennsylvania, U.S.A.  3- . Fort, J. Cerny, R. Carbon footprint analysis of calcined gypsum production in the Czech  Republic. J. Clean. Prod. 2018, 177, 795–802. [CrossRef] 4- Gartner, E.M. Cohesion and expansion in polycrystalline solids formed by hydration  reactions—The case of gypsum plasters. Cem. Concr. Res. 2009, 39, 289–295. [CrossRef] 5- Erbs, A.; Nagalli, A.; de Carvalho, K.Q.; Mymrin, V.; Passig, F.H.; Mazer, W. Properties  of recycled gypsum from gypsum plasterboards and commercial gypsum throughout recycling  cycles. J. Clean. Prod. 2018, 183, 1314–1322. [CrossRef] 6- GtoG Project. Available online: http://gypsumtogypsum.org/ (accessed on 24 April 2019). 7- Begliardo, H.; Sanchez, M.; Cecilia Panigatti, M.; Garrappa, S. Reuse of recovered  construction gyp-sum plaster: A study based on aptitude requirements of argentine and Chilean  standards. Rev. Constr. 2013, 12, 27–35.  8- Erbs, A.; Nagalli, A.; Mymrine, V.; Carvalho, K.Q. Determination of physical and  mechanical properties of recycled gypsum from the plasterboard sheets. Cerâmica 2015, 61, 482– 487. [CrossRef] 9- .Papailiopoulou.N.;Grigoropoulou.H.;Founti,M.Energyanalysisoftheeffectsofhigh- levelrein-corporation of post-consumer recycled gypsum in plasterboard manufacturing. Waste  Biomass Valorization 2017, 8, 1829–1839. [CrossRef] 10- . Jiménez-Rivero, A.; García-Navarro, J. Indicators to measure the management  performance of end-of-life gypsum:  Fromdeconstructiontoproductionofrecycledgypsum.  WasteBiomassValorization2016,7,913–927. [CrossRef] 11- .Jiménez-Rivero,A.;Sathre,R.;García avarro,J.Life cycle energy and material flowim  plication sofgypsum plasterboard recycling in the European Union. Resour. Conserv. Recycl.  2016, 108, 171–181. [CrossRef] Download 84.84 Kb. Do'stlaringiz bilan baham: