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"Penelitian ini bertujuan untuk menganalisis permeabilitas, kuat lentur (fr), cepat rambat gelombang (v), serta perkembangan cepat rambat gelombang pada sampel roller compacted concrete (RCC), beton konvensional dengan portland slag cement (PSC), dan beton konvensional dengan portland composite cement (PCC). Penelitian ini dilakukan menggunakan metode observasi laboratorium meliputi pengujian permeabilitas untuk menentukan ketahanan beton terhadap penetrasi air, pengujian kuat lentur untuk menentukan ketahanan beton terhadap gaya lentur, serta pengujian cepat rambat gelombang dengan metode non-destruktif yaitu pengujian ultrasonic velocity pulse (UPV). Hasil penelitian didapatkan koefisien permeabilitas beton RCC sebesar 27.865×10-6 cm/s; koefisien permeabilitas beton konvensional PSC sebesar 1.037×10-6 cm/s; dan koefisien permeabilitas beton konvensional PCC sebesar 9.739×10-6 cm/s menunjukkan bahwa semakin rendah permeabilitas beton, maka semakin baik kemampuannya dalam menahan tekanan air. Hasil penelitian didapatkan kuat lentur beton RCC dengan target fc’ 15 MPa sebesar 0.70 MPa; kuat lentur beton konvensional PSC dengan target fc’ 30 MPa sebesar 4.17 MPa; dan kuat lentur beton konvensional PCC dengan target fc’ 30 MPa sebesar 4.02 MPa menunjukkan bahwa kuat lentur meningkat seiring dengan peningkatan mutu beton. Hasil penelitian beton umur 28 hari didapatkan cepat rambat gelombang beton RCC sebesar 3365.67 m/s; cepat rambat gelombang beton konvensional PSC sebesar 4627.48 m/s; dan cepat rambat gelombang beton konvensional PCC sebesar 4702.41 m/s menunjukkan bahwa semakin tinggi cepat rambat gelombangnya maka menyatakan bahwa beton semakin padat dan semakin sedikit porositas beton. Dalam penelitian ini ditemukan adanya korelasi antara kuat lentur dan kecepatan rambat gelombang dengan persamaan empiris pada beton RCC yaitu fr = 0.0002v; persamaan empiris pada beton konvensional dengan PSC yaitu fr = 0.0009v; dan persamaan empiris pada beton konvensional dengan PCC yaitu fr = 0.0009v.

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This research aims to analyse the permeability, flexural strength (fr), ultrasonic pulse velocity (v) and ultrasonic pulse velocity evolution of roller compacted concrete (RCC), conventional Portland Slag Cement (PSC) and onventional Portland Composite Cement (PCC) samples. This research was carried out using laboratory observation methods, including permeability testing to determine the resistance of concrete to water penetration, flexural strength testing to determine the resistance of concrete to bending forces, and ultrasonic pulse velocity testing using a non-destructive method, namely ultrasonic pulse velocity (UPV) testing. The results showed that the permeability coefficient of RCC concrete was 27.865×10-6 cm/s, the permeability coefficient of conventional PCC concrete was 1.037×10-6 cm/s, and the permeability coefficient of conventional PCC concrete was 9.739×10-6 cm/s, indicating that the lower the permeability of concrete, the better its ability to resist water pressure. The results obtained flexural strength of RCC concrete with target fc' 15 MPa of 0.70 MPa; flexural strength of PSC conventional concrete with target fc' 30 MPa of 4.17 MPa; and flexural strength of PCC conventional concrete with target fc' 30 MPa of 4.02 MPa show that flexural strength increases with increasing concrete quality. The results of 28-day-old concrete research obtained ultrasonic pulse velocity of RCC concrete of 3365.67 m/s; ultrasonic pulse velocity of PSC conventional concrete of 4627.48 m/s; and ultrasonic pulse velocity of PCC conventional concrete of 4702.41 m/s show that the higher the wave propagation speed, it states that the denser the concrete and the less porosity of concrete. In this study it was found that there is a correlation between flexural strength and ultrasonic pulse velocity with the empirical equation for RCC concrete, fr = 0.0002v; the empirical equation for conventional concrete with PSC, fr = 0.0009v; and the empirical equation for conventional concrete with PCC, fr = 0.0009v."

"Penelitian ini dilakukan untuk mengevaluasi hasil pengujian kuat tekan beton inti dan Ultrasonic Pulse Velocity (UPV) pada sampel Roller Compacted Concrete dan beton konvensional dengan penggunaan Semen Portland Slah (PSC) dan Semen Portland Komposit (PCC) yang akan digunakan dalam proyek bendungan. Hal ini untuk memenuhi kebutuhan data yang sesuai dalam ACI 228.1R-19 terkait adanya data penelitian untuk setiap proyek yang dilakukan. Penelitian ini dilakukan dengan eksperimental laboratorium yang melibatkan uji destruktif (kuat tekan) dan non destruktif (UPV). Penelitian telah mengungkapkan bahwa kuat tekan beton inti dan cepat rambat UPV memiliki korelasi yang tinggi dimana semakin tinggi cepat rambatnya akan memberikan kuat tekan beton inti yang lebih tinggi juga. Persamaan empiris yang didapatkan pada penelitian ini adalah fc’(x) = 1.1665x pada Roller Compacted Concrete, fc’(x) = 6.1484x pada beton konvensional dengan semen PSC, dan fc’(x) = 6.9937x pada beton konvensional dengan semen PCC.

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This research was conducted to examine the results of core concrete compressive strength and Ultrasonic Pulse Velocity (UPV) tests on Roller Compacted Concrete samples and conventional concrete using Portland Slah Cement (PSC) and Composite Portland Cement (PCC) which will be used in solidification projects. This is to fulfill the appropriate data requirements in ACI 228.1R-19 regarding the existence of research data for each project carried out. This research was carried out in an experimental laboratory involving destructive (compressive strength) and non-destructive (UPV) tests. Research has revealed that the compressive strength of core concrete and the creep speed of UPV have a high correlation, where the higher the creep speed, the higher the compressive strength of the core concrete too. The empirical equation obtained in this research is fc’(x) = 1.1665x in Roller Compacted Concrete, fc’(x) = 6.1484x in conventional concrete with PSC cement, and fc’(x) = 6.9937x in conventional concrete with cement PCC."

"Roller Compacted Concrete (RCC) telah menjadi material pilihan dalam berbagai aplikasi konstruksi karena keunggulannya dalam hal kekuatan, durabilitas, dan efisiensi biaya. RCC termasuk ke dalam no-slump concrete yang memiliki konsistensi kering dan dipadatkan menggunakan alat berat seperti roller, sehingga memberikan karakteristik unik dibandingkan dengan beton konvensional. Penelitian ini bertujuan untuk mengetahui korelasi antara hasil pengujian kuat tekan dan UPV sampel silinder RCC dengan pemanfaatan 60% fly ash dan semen tipe PCC. Metode yang digunakan dalam peneltian ini adalah pengujian destruktif untuk kuat tekan beton dan pengujian non destruktif untuk UPV. Hasil dari penelitian ini adalah nilai kuat tekan sampel RCC yang meningkat seiring pertambahan cepat rambat gelombang. Sampel RCC yang diuji sampai umur 28 hari nilai kuat tekannya 2.84 MPa dan belum memenuhi target kuat tekan fc’ 15 MPa. Dari grafik hubungan kuat tekan dan cepat rambat sampel RCC didapatkan persamaan fc'(v) = 0.3392e^(0.5951v).

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Roller Compacted Concrete (RCC) has become the material of choice in various construction applications due to its advantages in terms of strength, durability, and cost efficiency. RCC is classified as no-slump concrete, having a dry consistency and compacted using heavy equipment such as rollers, thus providing unique characteristics compared to conventional concrete. This study aims to determine the correlation between the results of compressive strength and UPV testing of RCC cylinder samples with the utilization of 60% fly ash and PCC type cement. The method used in this research is destructive testing for concrete compressive strength and non-destructive testing for UPV. The result of this research is the compressive strength value of RCC samples which increases as the wave propagation speed increases. RCC samples tested until the age of 28 days the compressive strength value is 2.84 MPa and has not met the target compressive strength fc' 15 MPa. From the graph of the relationship between compressive strength and propagation speed of the RCC sample, the equation is obtained fc'(v) = 0.3392e^(0.5951v)."

"Roller Compacted Concrete (RCC) adalah beton yang memiliki keunggulan dalam hal kecepatan pelaksanaan, biaya produksi yang lebih rendah, serta penggunaan semen yang lebih rendah dibandingkan beton konvensional. RCC umumnya dimanfaatkan pada struktur bendungan dan perkerasan jalan, tetapi belum banyak diaplikasikan di Indonesia. Pada kasus bendungan, RCC dapat dikombinasikan dengan penggunaan beton konvensional untuk memberikan keuntungan yang lebih baik. Penelitian ini bertujuan untuk mengkaji korelasi hubungan antara hasil uji kuat tekan dan ultrasonic pulse velocity (UPV) pada sampel silinder beton konvensional dengan campuran Portland Slag Cement (PSC) dan Portland Composite Cement (PCC) dalam kasus konstruksi Bendungan Roller Compacted Concrete (RCC). Penelitian dilakukan dengan menggunakan metode eksperimental laboratorium, yang melibatkan pengujian destruktif berupa uji kuat tekan dan pengujian non-destruktif berupa uji UPV. Hasil penelitian ini menunjukkan bahwa hasil uji kuat tekan dan UPV memiliki korelasi yang positif dan bervariasi berdasarkan jenis campuran beton yang digunakan, yang dipengaruhi oleh faktor seperti komposisi material, rasio air-semen, kepadatan dan homogenitas campuran, serta metode pembuatan dan perawatan sampel beton.

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Roller Compacted Concrete (RCC) is concrete that has advantages in terms of speed of implementation, lower production costs, and lower cement usage compared to conventional concrete. RCC is generally used in dam structures and road pavements, but has not been widely applied in Indonesia. In the case of dams, RCC can be combined with the use of conventional concrete to provide better benefits. This research aims to examine the correlation between the results of compressive strength and ultrasonic pulse velocity (UPV) tests on conventional concrete cylinder samples mixed with Portland Slag Cement (PSC) and Portland Composite Cement (PCC) in the case of Roller Compacted Concrete (RCC) Dam construction. The research was carried out using laboratory experimental methods, which involved destructive testing in the form of compressive strength tests and non-destructive testing in the form of UPV tests. The results of this research show that the compressive strength and UPV test results have a positive correlation and vary based on the type of concrete mixture used, which is influenced by factors such as material composition, water-cement ratio, density and homogeneity of the mixture, as well as the method of making and caring for the concrete samples."

"Roller compacted concrete (RCC) adalah jenis beton yang menggunakan pasta semen yang sangat sedikit sehingga pemadatan harus dilakukan dengan roller. Studi ini dilakukan untuk mengetahui efek penambahan fly ash pada RCC dan perbandingannya dengan beton konvensional non-OPC. Penelitian ini utamanya fokus untuk mendapatkan kuat tarik belah dan modulus elastisitas dengan metode DIC. Terdapat tiga variasi campuran, terdiri dari RCC dengan semen Portland Composite Cement (PCC) “EZPRO”, beton konvensional dengan semen pozzolan jenis Ground Granulated Blast Furnace Slag (GGBS) “MaxStrength”, dan beton konvensional dengan semen EZPRO. Kuat tekan desain dari semen RCC adalah 15 MPa dan variasi beton konvensional MaxStrength dan EZPRO memiliki kuat tekan desain sebesar 30 MPa.

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Roller compacted concrete (RCC) is a type of concrete that uses very minimal amount of cement paste that it requires roller compactor. This study was conducted to determine the effect of adding fly ash to RCC (Roller Compacted Concrete) and its comparison with conventional non-OPC (Ordinary Portland Cement) concrete. The research is focused on obtaining the split tensile strength and modulus of elasticity using the DIC (Digital Image Correlation) method. There are three mix variations, consisting of RCC with Portland Composite Cement (PCC) "EZPRO," conventional concrete with Ground Granulated Blast Furnace Slag (GGBS) pozzolan cement "MaxStrength," and conventional concrete with EZPRO cement. The design compressive strength of RCC cement is 15 MPa, while the design compressive strength of the conventional MaxStrength and EZPRO concrete is 30 MPa."

"Industri konstruksi di Indonesia saat ini terus berkembang, sehingga konsumsi akan material pun kian bertambah. Salah satu material yang sangat banyak digunakan dan terus bertambah permintaannya pada konstruksi adalah semen, khususnya semen tipe 1 (Ordinary Portland Cement). Padahal dari tahun ke tahunnya produksi klinker, yaitu campuran utama pembuat semen, semakin menurun seiring bahan baku yang berkurang. Permasalahan ini coba dipecahkan oleh produsen semen dengan membuat berbagai semen dengan campuran bahan-bahan baru, seperti semen pozzolan, semen dengan silica fume, semen komposit dan lainnya.Portland Composite Cement (PCC) salah satu dari semen tadi merupakan produk yang saat ini telah beredar dan banyak digunakan. PCC dianggap memiliki karakter yang mirip, bahkan lebih baik dibandingkan dengan OPC. Akan tetapi, pada penggunaanya mix design untuk PCC masih sama dengan OPC. Selain itu, belum diketahui pasti karakteristik beton yang dihasilkan dengan menggunakan PCC.Penulisan ini bertujuan untuk mengetahui salah satu karakteristik beton dengan semen PCC yaitu kuat lentur (modulus of rupture) dan susut, dimana mix design yang digunakan tetap menggunakan aturan ACI yang berlaku bagi beton dengan OPC. Jika benar PCC mempunyai kualitas yang lebih baik dibanding OPC, seharusnya kuat lentur (modulus of rupture) juga lebih baik. Kekuatan lentur atau tarik beton akan dipengaruhi oleh perubahan volume, yang dapat mengakibatkan retak. Penggunaan material tambahan seperti fly ash, pozolan dan lainnya, akan mempengaruhi terhadap perubahan susut beton, dimana penggunaan fly ash seharusnya akan mengurangi penyusutan.Dari penelitian ini didapatkan bahwa kuat lentur beton PCC mengalami kenaikan yang lebih lambat dibanding beton OPC, trend yang dihasilkan berupa grafik logaritma yang setelah lewat 28 hari lambat laun menjadi asimtotis. Nilai kuat lentur beton PCC pada umur 28 hari dan setelahnya, lebih tinggi dibanding beton normal. Penggunaan PCC tidak terlalu berpengaruhi terhadap nilai susut beton dibanding beton normal.

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Indonesia construction industry growing fast, that is why the needs for construction material keep growing. One of them is cement that used a lot for many construction applications and its demand increase from time to time, especially for Ordinary Portland Cement (OPC). On the other side, clinker productivity had been decreasing every year. To solve this problem, cement producer making many variation of composite cement, such as, pozzolan cement, cement with silica fume, PCC, etc.Portland Composite Cement (PCC) is one of the product that used by many people and project. PCC have similar characteristic and even better quality than OPC. Even PCC used the same way with OPC, but the true characteristic of PCC not known yet.This research has objective to study flexural strength and shrinkage of concrete using PCC. If PCC has better quality, its flexural strength should be better than OPC. Flexural strength influenced by volume alteration that cause concrete crack. Fly ash in PCC has property that influencing concrete volume alteration. Fly ash should be able to reduce concrete shrinkage.The research shows that PCC concrete flexural strength increasing slower than OPC concrete. The graph of PCC concrete flexural strength increasing on logarithmic equation those after 28 days by degrees become asymptotic. The PCC concrete flexural strength after 28 days is higher than OPC concrete. Using PCC in concrete does not give significant effect for the concrete shrinkages."

"[ABSTRAKTelah dilakukan penelitian pembuatan beton ringan atau lightweightconcrete (LWC) menggunakan batu apug (BA) dan abu sekam padi (ASP).Sampel beton ringan yang dibuat mengandung BA dengan fraksi berbeda, adapunmaterial semen, pasir, dan abu sekam padi volumenya dijaga tetap. Terdapat duaparameter utama yang menentukan sifat mekanik sampel LWC masing-masingadalah densitas sampel dan rasio air/semen (w/c). Sifat mekanik yang palingutama dari LWC adalah kekuatan tekan. Pada campuran dengan fraksi volumebatu apung terbesar (100%) menghasilkan densitas dan kekuatan tekan palingrendah masing-masing sebesar (1389,6 kg/m3 dan 11,1 MPa). Diketahui bahwamakin rendah fraksi batu apung dalam sampel beton makin tinggi nilai densitasdan kekuatan tekannya, disebabkan oleh tingginya nilai fraksi pori baik poriterbuka maupun pori tertutup dalam sampel beton. Observasi terhadap fotomikroSEM batu apung menunjukkan bahwa terdapat sejumlah besar pori dengan bentukmemanjang ke bagian dalam dari permukaan sampel beton. Pori hadir dengankerapatan jumlah pori relatif besar serta dengan ukuran yang bervariasi. Fakta inimenjelaskan mengapa batu apung besifat ringan karena memiliki densitas massayang rendah. Pola difraksi sinar X sampel beton ringan memperlihatkan dominasifasa kristalin diidentifikasi sebagai fasa quartz (SiO2). Namun dapat dipastikansampel beton ringan terdiri dari fasa campuran antara fasa kristalin dan dengansedikit fasa amorph.Fotomikro SEM beton ringan menunjukkan bahwa senyawa Kalsium SilikatHidrat (CSH) mulai tumbuh pada waktu awal proses hidrasi dan terusberkembang sampai umur beton mencapai umur hidrasi 28 hari yang ditandaidengan sifat fisik yang padat dan peningkatan kekuatan beton. Dapat dipastikanbahwa senyawa CSH ini memiliki peranan penting terhadap pengaturan sifatmekanik seperti kekuatan tekan. Penelitian ini menyimpulkan bahwa batu apungdan abu sekam padi adalah material berbasis silika amorph yang memiliki densitaslebih rendah terutama dibandingkan dengan material pembentuk beton lainnya.Baik densitas dan kekuatan tekan sampel beton ringan ditentukan oleh rasio antarabatu apung dan abu sekam padi. Ditemukan rasio terkecil BA/ASP yaitu 8menghasilkan nilai densitas dan kekuatan tekan optimal, masing-masing pada usiabeton 28 hari sebesar 1891 kg/m3 dan 23 MPa. Komposisi beton ringan yangterbaik diperoleh dari hasil penelitian ini adalah komposisi campuran PCC (1,00) :Pasir (1,00) : ASP (0,05) : BA (0,50) dengan nilai Slump 8 cm ditandai oleh nilairasio antara kuat tekan dan densitas tertinggi adalah 1285.;

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ABSTRACTResearch studies on the manufacture of lightweight concrete (LWC) usingpumice and rice husk ash (RHA) materials have been done. LWC samples weremade of pumice materials with a different mass fraction, while the cement, sand,and rice husk ash materials were keep fixed. It was found that there are two mainparameters that determine the mechanical properties of LWC which are densityand the water and cement ratio (w/c ratio). The main mechanical properties ofLWC sample is the power press. Samples with the largest volume fraction ofpumice (100%) resulted in lightest density (1389.6 kg/m3) and the smalleststrength of LWC (11.1 MPa). It was found that, the lower the mass fraction ofpumice in LWC samples, the higher the density values and compressive strengthwere obtained. This was caused by the high mas fraction value of pores, whichwere both open and closed pores. Scanning electron micorscopy (SEM) imagesfor the pumice showed that the there are a large number of regular and structuredpores extending deep inside the surface of the sample. It was observed that porespresent with pore size does not vary significantly but with the density of therelatively large number of pores, indicating pumice has a low mass density. TheXRD pattern of the lightweight concrete samples indicated that the samples weredominated by crystalline phases in which the quartz (SiO2) is the main phase anda small fraction of amorphous phase was also obtained.SEM images of lightweight concrete samples showed that the structure ofCalcium Silicate Hydrates (CSH) started growing at the beginning of hydrationtime and continue to evolve into a more solid structure until the age of 28 days,where the compound has an important role to the mechanical properties such ascompressive strength. The study concluded that the pumice and rice husk ash isare amorphous silica-based material which has a lower density compared to otherconcrete forming material such as cement and sands. Both density and lightweight concrete compressive strength are determined by the ratio between pumiceand rice husk ash, in which the smallest ratio 8 resulted in the largest density andcompressive strength, which are 1890.5 kg/m3 and 23.2 MPa respectively at theage of 28 days. The study concluded that the best composition for lightweightconcrete samples was the following: PCC (1,00): Sand (1,00): ASP (0,05): BA(0,50) with a slump value of 8 cm resulted in the largest value of a ratio betweencompressive strength and density of 1285.;Research studies on the manufacture of lightweight concrete (LWC) usingpumice and rice husk ash (RHA) materials have been done. LWC samples weremade of pumice materials with a different mass fraction, while the cement, sand,and rice husk ash materials were keep fixed. It was found that there are two mainparameters that determine the mechanical properties of LWC which are densityand the water and cement ratio (w/c ratio). The main mechanical properties ofLWC sample is the power press. Samples with the largest volume fraction ofpumice (100%) resulted in lightest density (1389.6 kg/m3) and the smalleststrength of LWC (11.1 MPa). It was found that, the lower the mass fraction ofpumice in LWC samples, the higher the density values and compressive strengthwere obtained. This was caused by the high mas fraction value of pores, whichwere both open and closed pores. Scanning electron micorscopy (SEM) imagesfor the pumice showed that the there are a large number of regular and structuredpores extending deep inside the surface of the sample. It was observed that porespresent with pore size does not vary significantly but with the density of therelatively large number of pores, indicating pumice has a low mass density. TheXRD pattern of the lightweight concrete samples indicated that the samples weredominated by crystalline phases in which the quartz (SiO2) is the main phase anda small fraction of amorphous phase was also obtained.SEM images of lightweight concrete samples showed that the structure ofCalcium Silicate Hydrates (CSH) started growing at the beginning of hydrationtime and continue to evolve into a more solid structure until the age of 28 days,where the compound has an important role to the mechanical properties such ascompressive strength. The study concluded that the pumice and rice husk ash isare amorphous silica-based material which has a lower density compared to otherconcrete forming material such as cement and sands. Both density and lightweight concrete compressive strength are determined by the ratio between pumiceand rice husk ash, in which the smallest ratio 8 resulted in the largest density andcompressive strength, which are 1890.5 kg/m3 and 23.2 MPa respectively at theage of 28 days. The study concluded that the best composition for lightweightconcrete samples was the following: PCC (1,00): Sand (1,00): ASP (0,05): BA(0,50) with a slump value of 8 cm resulted in the largest value of a ratio betweencompressive strength and density of 1285., Research studies on the manufacture of lightweight concrete (LWC) usingpumice and rice husk ash (RHA) materials have been done. LWC samples weremade of pumice materials with a different mass fraction, while the cement, sand,and rice husk ash materials were keep fixed. It was found that there are two mainparameters that determine the mechanical properties of LWC which are densityand the water and cement ratio (w/c ratio). The main mechanical properties ofLWC sample is the power press. Samples with the largest volume fraction ofpumice (100%) resulted in lightest density (1389.6 kg/m3) and the smalleststrength of LWC (11.1 MPa). It was found that, the lower the mass fraction ofpumice in LWC samples, the higher the density values and compressive strengthwere obtained. This was caused by the high mas fraction value of pores, whichwere both open and closed pores. Scanning electron micorscopy (SEM) imagesfor the pumice showed that the there are a large number of regular and structuredpores extending deep inside the surface of the sample. It was observed that porespresent with pore size does not vary significantly but with the density of therelatively large number of pores, indicating pumice has a low mass density. TheXRD pattern of the lightweight concrete samples indicated that the samples weredominated by crystalline phases in which the quartz (SiO2) is the main phase anda small fraction of amorphous phase was also obtained.SEM images of lightweight concrete samples showed that the structure ofCalcium Silicate Hydrates (CSH) started growing at the beginning of hydrationtime and continue to evolve into a more solid structure until the age of 28 days,where the compound has an important role to the mechanical properties such ascompressive strength. The study concluded that the pumice and rice husk ash isare amorphous silica-based material which has a lower density compared to otherconcrete forming material such as cement and sands. Both density and lightweight concrete compressive strength are determined by the ratio between pumiceand rice husk ash, in which the smallest ratio 8 resulted in the largest density andcompressive strength, which are 1890.5 kg/m3 and 23.2 MPa respectively at theage of 28 days. The study concluded that the best composition for lightweightconcrete samples was the following: PCC (1,00): Sand (1,00): ASP (0,05): BA(0,50) with a slump value of 8 cm resulted in the largest value of a ratio betweencompressive strength and density of 1285.]"

"Cangkang kelapa sawit merupakan limbah hasil sektor pertanian yang memiliki potensi produksi yang tinggi namun belum dimanfaatkan secara maksimal di Indonesia. Penggunaan cangkang kelapa sawit sebagai pengganti agregat kasar pada beton telah banyak dilakukan. Dengan berat isi yang cukup ringan, cangkang kelapa sawit dapat menghasilkan beton ringan dengan berat jenis ±1900 kg/m3. Portland Composite Cemen (PCC) merupakan semen umum yang digunakan dipasaran. Semen ini memiliki butiran yang lebih halus sehingga menghasilkan panas hidrasi yang lebih rendah. Pada penelitian ini akan dilakukan studi eksperimen pada balok yang menggunakan cangkang kelapa sawit dari berbagai campuran jenis dan semen PCC sebagai pengikatnya. Pengujian yang dilakukan adalah uji kerakteristik beton (uji kuat tekan, kuat tarik belah, kuat lentur, permeabilitas, dan susut) serta pengujian pembebanan terhadap balok berukuran 300 x 15 x 25 cm3 menggunakan four-point loading serta pengamatan dengan metode Digital Image Correlation (DIC). Analisis yang dilakukan meliputi respon struktur balok akibat pembebanan, pola retak yang dihasilkan, serta bukaan retak yang terjadi selama proses pembebanan dilakukan. Hasil eksperimen menunjukkan karakteristik beton yang kurang memuaskan dimana hanya diperoleh kuat tekan sebesar 12,41 MPa. Balok beton bertulang cangkang kelapa sawit pada penelitian ini mampu menerima beban hingga 7000 kg. Pola retak yang terbentuk sudah sesuai dengan pembebanan yang dilakukan dan evolusi dari pembukaan retak yang diamati dapat terlihat dengan baik menggunakan metode DIC. Bukaan retak yang dihasilkan berkisar antara 100-300 μm. Meskipun menghasilkan respon struktur yang cukup baik, balok beton bertulang cangkang kelapa sawit tidak dapat dijadikan sebagai komponen struktural karena kecilnya kuat tekan yang dihasilkan. Perlu dilakukan penelitian lebih lanjut terkait dengan penggunaan cangkang kelapa sawit sebagai pengganti agregat kasar dalam campuran beton untuk komponen non-struktural.

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Oil palm shells are agricultural waste with high production potential that has not been fully utilized in Indonesia. The use of oil palm shells as a replacement for coarse aggregates in concrete has been widely explored. With its relatively low density, oil palm shells can produce lightweight concrete with a density of approximately 1900 kg/m3. Portland Composite Cement (PCC) is a commonly used cement in the market. It has finer particles, resulting in lower hydration heat. This study aims to conduct experimental studies on beams using oil palm shells in various mixtures and PCC as the binder. The testing includes characterization of the concrete (compressive strength, splitting tensile strength, flexural strength, permeability, and shrinkage), as well as load testing on 300 x 15 x 25 cm3 beams using four-point loading and observation using Digital Image Correlation (DIC) method. The analysis includes studying the structural response of the beams under loading, crack patterns, and crack opening during the loading process. The experimental results indicate unsatisfactory characteristics of the concrete, as only a compressive strength of 12.41 MPa was obtained. The reinforced concrete beams with oil palm shells in this study can sustain loads up to 7000 kg. The crack patterns formed are consistent with the applied loading, and the evolution of crack opening can be well observed using the DIC method. The crack openings range from 100 to 300 μm. Although the beams exhibit satisfactory structural response, they cannot be used as structural components due to their low compressive strength. Further research is needed regarding the use of palm kernel shells as a substitute for coarse aggregate in concrete mixtures for non-structural components."

"Beton adalah material utama dalam industri konstruksi untuk struktur yang memerlukan daya dukung tinggi, namun kualitasnya dapat terpengaruh oleh lingkungan, terutama salinitas air laut yang dapat menyebabkan kerusakan melalui reaksi kimia dan fisika. Penelitian ini mengevaluasi pengaruh salinitas terhadap kekuatan beton yang menggunakan semen tipe PCC, yang memiliki emisi CO2 sebesar 32% lebih rendah dibandingkan OPC, dengan target mutu beton 41.4 MPa. Uji dilakukan untuk mengukur kuat tekan, kuat tarik, dan permeabilitas beton pada umur 7, 28, dan 42 hari dengan berbagai tingkat salinitas dan durasi curing. Hasil penelitian menunjukkan bahwa salinitas tidak secara signifikan mempengaruhi kuat tekan beton, namun ada perbedaan dalam kekuatan tarik dan permeabilitas tergantung pada kondisi salinitas. Beton PCC terbukti efektif pada salinitas rendah tetapi tidak cocok untuk paparan langsung oleh air laut dalam jangka panjang. Temuan ini menunjukkan bahwa PCC merupakan alternatif ramah lingkungan dengan kinerja yang memadai untuk aplikasi konstruksi di daerah rawan salinitas, namun memerlukan perhatian khusus untuk kondisi paparan air laut secara langsung.

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Concrete is a primary material in the construction industry for structures requiring high load-bearing capacity, but its quality can be affected by environmental factors, particularly the salinity of seawater, which can cause damage through chemical and physical reactions. This study evaluates the impact of salinity on the strength of concrete using Portland Composite Cement (PCC), which has 32% lower CO2 emissions compared to Ordinary Portland Cement (OPC), with a target strength of 41.4 MPa. Tests were conducted to measure compressive strength, tensile strength, and permeability of the concrete at 7, 28, and 42 days of age under various salinity levels and curing durations. The results show that salinity does not significantly affect the compressive strength of the concrete, though there are differences in tensile strength and permeability depending on salinity conditions. PCC concrete is found to be effective in low salinity environments but is not suitable for direct exposure to seawater over the long term. These findings suggest that PCC is an environmentally friendly alternative with adequate performance for construction applications in saline-prone areas, but requires special consideration for direct seawater exposure"

"Penelitian ini membahas tentang penggunaan Abu Sekam Padi (RHA) sebagai bahan subtitusi perekat semen dan penggunaan Limbah Adukan Beton (CSW) sebagai agregat halus untuk mengurangi penggunaan jumlah pasir pada beton. Penelitian dilakukan dengan membuat mortar dengan lima variasi campuran dengan jumlah CSW 30%, 40%, 50%, 60% dan 70% dengan penggunaan RHA tetap yaitu 8% dari total pemakaian semen. Sifat mekanis beton yang diuji meliputi: kuat tekan, densitas atau kerapatan, absorbsi atau penyerapan air dan uji susut. Pengujian kuat tekan dilakukan pada umur 3, 7, 14, 21, 28, 56 dan 90 hari. Untuk pengujian densitas dan absorbsi dilakukan pada umur 28 hari. Sedangkan untuk pengujian susut dilakukan pada umur 1-28 hari secara terus-menerus. Pada pengujian-pengujian yang sudah dilakukan, nilai optimum terjadi pada campuran dengan jumlah CSW 30%, karena memiliki nilai kuat tekan dan densitas paling tinggi, serta penyerapan air dan penyusutan yang paling rendah. Dari penelitian ini diharapkan mortar dengan campuran RHA dan CSW dapat diaplikasikan untuk pembuatan bahan konstruksi ramah lingkungan.

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The focus of this study is observing the use of Rice Husk Ash (RHA) as a subtitute of portland cement and Concrete Sludge Waste (CSW) to reduce of sand in concrete. Five compotitions are made in this study with precentages of CSW are 30%, 40%, 50%, 60% and 70% and fixed amount 8% of RHA. The concrete were tested in compressive strength test at the age of 3, 7, 14, 21, 28, 56 and 90 days. Density test and absorption test at the age of 28 days. And Shrinkage test at the age of 1-28 days. From the result of those tests obtained an optimum number of CSW 30% because has the biggest compressive strength and density, thelowestabsorption and percentage of shrinkage. From the result has been obtained, the concrete with RHA and CSW could be applied to building material."