Mobile QR Code QR CODE

Journal of the Korea Concrete Institute

ISO Journal TitleJ Korea Concr Inst.
  • SCOPUS
  • KCI Accredited Journal

Journal Search

  1. Home
  2. All Issues
  3. 2025-04 (Vol.37 No.2)
  4. 10.4334/JKCI.2025.37.2.125
Export citation EndNote
XML PDF INFO REF

References

1 
Alaskar, A., Alshannag, M., and Higazey, M. (2021) Mechanical Properties and Durability of High-Performance Concrete Internally Cured Using Lightweight Aggregates. Construction Building Materials 288, 122998.DOI
2 
ASTM C109/C109M (2020) Standard Test Method for Compressive Strength of Hydraulic Cement Mortars. West Conshohocken, PA; ASTM International.URL
3 
ASTM C332-17 (2017) Standard Specification for Lightweight Aggregates for Insulating Concrete. West Conshohocken, PA; ASTM International.URL
4 
ASTM C349-18 (2018) Standard Test Method for Compressive Strength of Hydraulic-Cement Mortars (Using Portions of Prisms Broken in Flexure). West Conshohocken, PA; ASTM International.URL
5 
ASTM D2583-13a (2022) Standard Test Method for Indentation Hardness of Rigid Plastics by Means of a Barcol Impressor. West Conshohocken, PA; ASTM International.URL
6 
Bentz, D. P. (2009) Influence of Internal Curing Using Lightweight Aggregates on Interfacial Transition Zone Percolation and Chloride Ingress in Mortars. Cement and Concrete Composites 31(5), 285-289.DOI
7 
Bentz, D. P., and Snyder, K. A. (1999) Protected Paste Volume in Concrete: Extension to Internal Curing Using Saturated Lightweight Fine Aggregate. Cement Concrete Research 29, 1863-1867.DOI
8 
Bentz, D. P., and Weiss, W. J. (2011) Internal Curing: A 2010 State-of-the-Art Review. US Department of Commerce, National Institute of Standards and Technology, 1-82.URL
9 
Chen, W., Dong, S., Liu, Y., Liang, Y., and Skoczylas, F. (2022) Effect of Waste Glass as Fine Aggregate on Properties of Mortar. Materials 15(23), 8499.DOI
10 
Gudipudi, B. R., Kola, N. R., Reddy, M. E., and Rao, K. M. (2020) Effect of Different pH Waters on Compressive Strength and Tensile Strength of Concrete. Solid State Technology 63(1s), 1719-1724.URL
11 
Jang, I. Y. (2020) Pretreatment Technology for Recycling Waste Glass. Magazine of RCR 15(4), 35-39. (In Korean)DOI
12 
Justs, J., Wyrzykowski, M., Bajare, D., and Lura, P. (2015) Internal Curing by Superabsorbent Polymers in Ultra-High Performance Concrete. Cement Concrete Research 76, 82-90.DOI
13 
Kang, S. H., and Lee, K. G. (2010) Bloating Mechanism of Artificial Lightweight Aggregate for Recycling the Waste Glass. Journal of the Korean Ceramic Society 47(5), 445. (In Korean)DOI
14 
KATS (2022) Cement–Test methods–Determination of Strength (KS L ISO679 4009). Seoul, Korea: Korea Agency for Technology and Standards (KATS), Korea Standard Association (KSA). 1-32. (In Korean)URL
15 
Kim, S. K., Jang, P. K., and Jang, I. Y. (2017) Material Bahavior and Strength Character of 150 MPa Ultra High Strength Concrete Using LCD Glass Powder as Fine Aggregate. Journal of the Korea Concrete Institute 29(6), 615-623. (In Korean)DOI
16 
Kim, S. S., Lee, J. B., Nam, B. R., and Park, K. P. (2009) Performance Evaluation of Artificial Lightweight Aggregate Mortar Manufactured with Waste Glass. Journal of the Korea Concrete Institute 21(2), 147-152. (In Korean)URL
17 
Lee, H. S., and Lee, H. (2020) Comminution Characteristics for Recycling Waste Glass Bottle. Resources Recycling 29(2), 28-36. (In Korean)DOI
18 
Park, S. B., Cho, C. W., and Kim, J. H. (2001) Experimental Study on Physical and Mechanical Properties of Concrete with Fine Waste Glass. Journal of the Korea Concrete Institute 13(2), 184-191. (In Korean)DOI
19 
Roufael, G., Beaucour, A. L., Eslami, J., Hoxha, D., and Noumowé, A. (2021) Influence of Lightweight Aggregates on the Physical and Mechanical Residual Properties of Concrete Subjected to High Temperatures. Construction and Building Materials 268, 121221.DOI
20 
Sharma, L., Taak, N., and Bhandari, M. (2021) Influence of Ultra-Lightweight Foamed Glass Aggregate on the Strength Aspects of Lightweight Concrete. Materials Today: Proceedings 45, 3240-3246.DOI
21 
Utepov, Y., Tulebekova, A., Aldungarova, A., Mkilima, T., Zharassov, S, Shakhmov, Z., Bazarbayev, D., Tolkynbayev, T., and Kaliyeva Z. (2022) Investigating the Influence of Initial Water pH on Concrete Strength Gain Using a Sensors and Sclerometric Test Combination. Infrastructures 7(12), 159.DOI
22 
Wyrzykowski, M., Assmann, A., Hesse, C., and Lura, P. (2020) Microstructure Development and Autogenous Shrinkage of Mortars with CSH Seeding and Internal Curing. Cement and Concrete Research 129, 105967.DOI
23 
Ziejewska, C., Grela, A., and Hebda, M. (2023) Influence of Waste Glass Particle Size on the Physico-Mechanical Properties and Porosity of Foamed Geopolymer Composites Based on Coal Fly Ash. Materials 16(5), 2044.DOI