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Effects Of Silica Aerogel Produced From Boron Wastes To Compressive Strength And Thermal Performance Of Environmentally Friendly Bricks

Yıl 2023, , 24 - 32, 27.09.2023
https://doi.org/10.46810/tdfd.1256442

Öz

In this study, the aim is to inspect the effects of silica aerogel produced from boron waster to compressive strength and thermal performance of bricks. Firstly, silica aerogel was produced by using boron waste obtained from Turkey/Eskişehir/Kırka region. After, silica aerogel produced was mixed into the brick in different proportions, and was baked in 900 °C and 1000 °C to create mixed brick samples. Finally, samples produced was experimented with compressive strength and thermal conductivity coefficient and SEM images were taken. As a result, the increase of aerogel amount caused decrease in compressive strength and thermal conductivity coefficient values in both temperatures. It was observed that amorphous structure increased with the increase of silica aerogel and partial holes and cracks emerged in SEM images. Additionally, when compressive strength was used as basis, it was determined that AB1 sample could be used as holder, while AB2, AB3 and AB4 samples could be used as coating or back filling material in traditional structures. Use of wastes which contain silica such as boron waste in aerogel production is thought to be an appropriate solution for waste disposal.

Kaynakça

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Bor Atıklarından Üretilen Silika Aerojelin Çevre Dostu Tuğlaların Basınç Dayanımına ve Isıl Performansına Etkileri

Yıl 2023, , 24 - 32, 27.09.2023
https://doi.org/10.46810/tdfd.1256442

Öz

Bu çalışmada, bor atıklarından üretilen silika aerojelin tuğlanın basınç dayanımı ve ısıl performansına etkisinin incelenmesi amaçlanmıştır. Çalışma üç aşamada gerçekleştirilmiştir. İlk aşamada Türkiye/Eskişehir/Kırka bölgesinden temin edilen bor atığı kullanılarak silika aerojel üretimi yapılmıştır. İkinci aşamada, üretilen silika aerojel hacimce farklı oranlarda (%0 (REF), %15 (AB1), %25 (AB2), %35 (AB3), %45 (AB4)) tuğla bünyesine ikame edilmiş, 900 oC ve 1000 oC pişirilerek katkılı tuğla numuneleri üretilmiştir. Üçüncü ve son aşamada ise, üretilen numunelere basınç dayanımı ve ısı iletim katsayısı tayini deneyleri uygulanmıştır. Ayrıca numunelerin içyapısının incelenmesi amacıyla SEM görüntüleri alınmıştır. Sonuç olarak; her iki sıcaklıkta da aerojel miktarının artması ile basınç dayanımı ve ısı iletim katsayısı değerinde azalma meydana gelmiştir. SEM görüntülerinde silika aerojel miktarının artmasıyla amorf yapının artığı ve yer yer boşluklar ve çatlaklar oluştuğu görülmüştür. Ayrıca basınç dayanımı baz alındığında; üretilen numunelerden AB1 numunesi taşıyıcı olarak kullanılabileceği, AB2, AB3 ve AB4 numunelerinin ise kaplama veya geleneksel yapılarda duvar dolgu malzemesi olarak kullanılabileceği tespit edilmiştir. Bor atığı gibi silis içeren atıkların aerojel üretiminde kullanılmaları atıkların bertaraf edilmesi için uygun bir çözüm yolu olacağı düşünülmektedir.

Kaynakça

  • [1] Becker PFB, Effting C, Schackow A. Lightweight thermal insulating coating mortars with aerogel, EPS, and vermiculite for energy conservation in buildings. Cem. Conc. Comp. 2022; 125(2022): 104283.
  • [2] Calisesi M. Aerogel Incorporated Plasters and Mortars, The Case Study of Precast Panels; Degree Course: Build. Eng. and Arch.; University of Bologna: Bologna, Italy, 2017.
  • [3] Stephan A, Athanassi A. Towards a more circular construction sector: Estimating and spatialising current and future non-structural material replacement flows to maintain urban building stocks. Res., Conser. & Recy., 2018; 119: 248–262.
  • [4] Cao VD, Pilehvar S, Salas-Bringas C, Szczotok AM, Rodriguez JF, Carmona M, Al-Manasir N, Kjoniksen AL. Microencapsulated phase change materials for enhancing the thermal performance of Portland cement concrete and geopolymer concrete for passive building applications. Ener. Conv. and Man. 2017; 133: 56e66.
  • [5] Lu Y, Liu Z, Li X, Yin XJ, Utomo HD. Development of water-based thermal insulation paints using silica aerogel made from incineration bottom ash. Energy & Build. 2022; 259, (2022): 111866.
  • [6] Buratti C, Moretti E, Belloni E, Agosti F. Development of Innovative Aerogel Based Plasters: Preliminary Thermal and Acoustic Performance Evaluation. Sustainability; 2014(6): 5839-5852.
  • [7] Berardi U, Akos L. Thermal bridges of metal fasteners for aerogel-enhanced blankets. Ener. & Build. 2019; 185 (2019): 307-315.
  • [8] Elshazli MT, Mudaqiq M, Xing T, Ibrahim A, Engin BJS, Yuand J. Experimental study of using Aerogel insulation for residential buildings. Adv. in Build. Ener. Res. 2022; 16(5): 569-588.
  • [9] Ganobjaka M, Brunner S, Wernery J. Aerogel materials for heritage buildings: Materials, properties and case studies. J. Cult. Her. 2020; 42(2020): 81–98.
  • [10] Lucchi E, Becherini F, Tuccio, MCD, Troi A, Frick J, Roberti F, Hermann C, Fairnington I, Mezzasalma G, Pockele L, Bernardi, A. Thermal performance evaluation and comfort assessment of advanced aerogel as blown-in insulation for historic buildings. Build. Env. 2017; 122 (2017): 258-268.
  • [11] Aste N, Leonforte F, Manfren M, Mazzon M. Thermal inertia and energy efficiency - parametric simulation assessment on a calibrated case study, App. Ener. 2015; 145 (2015): 111–123.
  • [12] Walker R, Pavia S. Thermal Performance of a selection of insulation materials suitable for historic buildings. Build. Env. 2015; 94(2015): 155e165.
  • [13] Fernando S, Gunasekara C, Law DW, Nasvic MCM, Setunge S, Dissanayake R. Engineering properties of waste-based alkali activated concrete brick containing low calcium fly ash and rice husk ash: A comparison with traditional Portland cement concrete brick. J. Build. Eng. 2022; 46 (2022): 103810.
  • [14] Mahdi SN, Dushyanth V, Babu R, Hossiney N, Abdullah MMAB. Strength and durability properties of geopolymer paver blocks made with fly ash and brick kiln rice husk ash. Case Stud. Const. Mat. 2022; 16(2022): e00800.
  • [15] Soharu A, Naveen BP, Sil A. Fly ash bricks development using concrete waste debris and self-healing bacteria. J. Mat. Cyc. Waste Manag. 2022, 35(2022): 1-12.
  • [16] Debnatha, NK, Boga S, Singha A, Majhi MR, Singh VK. Fabrication of low to high duty fireclay refractory bricks from lignite fly ash. Ceram. Int. Avai. 2022, 48(9): 12152-12160.
  • [17] Suganya STD, Krishnaraj L, Nakkeeran G. Evaluation of failure mode analysis and strength behavior of fly ash brick masonry prisms, Sust. Const. Mat. 2022; 107–121.
  • [18] Araf T, Islam MS, Shipon MFA. Suitability of waste slag as partial replacement of fine aggregate in making sustainable brick. Prooceding of 3rd International conference on Research and Innovation in Civil Engineering, Prague. (2022). ISBN: 978-984—35-1935-1.
  • [19] Abu-Jdayil B, Mourad AH, Hittini W, Hassan M, Hameedi S. Traditional, state of the art and renewable thermal building insulation materials: An overview. Const. and Build. Mat., 2019; 214: 709–735.
  • [20] Fricke J. Tillotson, T. Aerogels: Production, characterization, and applications. Thin Sol. Films. 1997; 297(1–2): 212–223.
  • [21] Mahadik DB, Lee YK, Chavan NK, Mahadik SA, Park HH. Monolithic and shrinkage free hydrophobic silica aerogels via new rapid supercritical extraction process. J. Sup. Fluids, 2016; 107: 84–91.
  • [22] Joo P, Yao Y, Teo N, Jana SC. Modular aerogel brick fabrication via 3D-printed molds. Additive Manufacturing, 2021; 46(2021): 102059.
  • [23] Baetens R, Jelle BP, Gustavsen A. Aerogel insulation for building applications: a state-of-the-art review. Ene. Build.. 2011; 43(4): 761e769.
  • [24] Jelle BP. Traditional, state-of-the-art and future thermal building insulation materials and solutions – Properties, requirements and possibilities. In Ener. Build., 2011; 43 (10): 2549-2563.
  • [25] Berardi U. Aerogel-enhanced systems for building energy retrofits: Insights from a case study, Ene. Build. 2018; 159(2018): 370-381.
  • [26] Ibrahim M, Biwole PH, Wurtz E, Achard, P. A study on the thermal performance of exterior walls covered with a recently patented silica-aerogel-based insulating coating. Building Environment, 2014; 81 (2014): 112-122.
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Toplam 87 adet kaynakça vardır.

Ayrıntılar

Birincil Dil Türkçe
Konular Mühendislik
Bölüm Makaleler
Yazarlar

Arzu Çağlar 0000-0003-3928-8059

Erken Görünüm Tarihi 27 Eylül 2023
Yayımlanma Tarihi 27 Eylül 2023
Yayımlandığı Sayı Yıl 2023

Kaynak Göster

APA Çağlar, A. (2023). Bor Atıklarından Üretilen Silika Aerojelin Çevre Dostu Tuğlaların Basınç Dayanımına ve Isıl Performansına Etkileri. Türk Doğa Ve Fen Dergisi, 12(3), 24-32. https://doi.org/10.46810/tdfd.1256442
AMA Çağlar A. Bor Atıklarından Üretilen Silika Aerojelin Çevre Dostu Tuğlaların Basınç Dayanımına ve Isıl Performansına Etkileri. TDFD. Eylül 2023;12(3):24-32. doi:10.46810/tdfd.1256442
Chicago Çağlar, Arzu. “Bor Atıklarından Üretilen Silika Aerojelin Çevre Dostu Tuğlaların Basınç Dayanımına Ve Isıl Performansına Etkileri”. Türk Doğa Ve Fen Dergisi 12, sy. 3 (Eylül 2023): 24-32. https://doi.org/10.46810/tdfd.1256442.
EndNote Çağlar A (01 Eylül 2023) Bor Atıklarından Üretilen Silika Aerojelin Çevre Dostu Tuğlaların Basınç Dayanımına ve Isıl Performansına Etkileri. Türk Doğa ve Fen Dergisi 12 3 24–32.
IEEE A. Çağlar, “Bor Atıklarından Üretilen Silika Aerojelin Çevre Dostu Tuğlaların Basınç Dayanımına ve Isıl Performansına Etkileri”, TDFD, c. 12, sy. 3, ss. 24–32, 2023, doi: 10.46810/tdfd.1256442.
ISNAD Çağlar, Arzu. “Bor Atıklarından Üretilen Silika Aerojelin Çevre Dostu Tuğlaların Basınç Dayanımına Ve Isıl Performansına Etkileri”. Türk Doğa ve Fen Dergisi 12/3 (Eylül 2023), 24-32. https://doi.org/10.46810/tdfd.1256442.
JAMA Çağlar A. Bor Atıklarından Üretilen Silika Aerojelin Çevre Dostu Tuğlaların Basınç Dayanımına ve Isıl Performansına Etkileri. TDFD. 2023;12:24–32.
MLA Çağlar, Arzu. “Bor Atıklarından Üretilen Silika Aerojelin Çevre Dostu Tuğlaların Basınç Dayanımına Ve Isıl Performansına Etkileri”. Türk Doğa Ve Fen Dergisi, c. 12, sy. 3, 2023, ss. 24-32, doi:10.46810/tdfd.1256442.
Vancouver Çağlar A. Bor Atıklarından Üretilen Silika Aerojelin Çevre Dostu Tuğlaların Basınç Dayanımına ve Isıl Performansına Etkileri. TDFD. 2023;12(3):24-32.