Hasil Pencarian  ::  Simpan CSV :: Kembali

Hasil Pencarian

Ditemukan 149637 dokumen yang sesuai dengan query
cover
Diah Kusumantara
Pengaruh faktor air semen terhadap campuran 50% semen portland dan 50% abu sekam padi = Water cement factor influence in 50% cement mix with 50 % rice husk ash
"Sifat mekanis pasta semen yang terdiri dari kuat tekan, kuat tarik, porositas dan modulus elastisitas merupakan sifat utama yang sangat penting dalam pengunaan sebagai bahan konstruksi. Seiring dengan perkembangan, penambahan bahan additif untuk mendapatkan sifat mekanis beton pada saat ini begitu banyak variasinya, salah satunya adalah dengan penambahan kadar silica yang terkandung dalam abu sekam padi. Abu sekam padi yang diperoleh dari pembakaran kulit padi pada tungku bersuhu 400 - 800 0 C digunakan sebagai bahan pozolan karena memenuhi syarat SK-SNI-1989-F, yaitu mengandung SiO2 yang tinggi sebesar 93,44%. Dari hasil pengujian, untuk pasta semen campuran dengan penambahan abu sekam padi maka didapat kuat tekan pasta semen campuran abu sekam padi tertinggi berada di FAS 0,7 yaitu pada nilai kuat tekan f c? = 26,5 Mpa atau penurunan sebesar 71,86 % dari kuat tekan pasta normal dan kuat tarik pasta semen campuran abu sekam padi tertinggi berada di FAS 0,7 yaitu pada nilai kuat tarik f ct = 0,653 Mpa atau penurunan sebesar 37,57 % dari kuat tarik pasta normal. Penelitian ini dilakukan dengan kuat tekan dan kuat tarik pada pasta semen campuran abu sekam dengan FAS 0.60, 0.70 dan 0.80.
Primary property of cement pasta consist of stress, strain, porosity and modulus of elasticity which is importants in construction material, as its development in property, additive mixture is added to change the property, until this day, one of its variation is by adding silica which existed in rice husk ash. Rice husk ash obtainable from the burning of rice coarse in furnace heated 400 ' 1000 0 C used as pozolan-like material as it fulfill the requirement within SK-SNI-1989-F, consisting of high SiO2 (93,44%). From the research test (mixing pasta cement with rish ash) we acquire a maximum stress strength within 0,7 water cement ratio that is f c? = 26,5 Mpa or a downgrade of 71,86 % from normal pasta stress strength and maximum strain strength within 0,7 water cement ratio that is f ct = 0,653 Mpa or a downgrade of 37,57 % from normal pasta strain strength. The reasearch was done by doing stressing and straining, using water cement factor 0,6, 0,7, and 0,8."
Depok: Fakultas Teknik Universitas Indonesia, 2009
S50518
UI - Skripsi Open  Universitas Indonesia Library
cover
Pretysesar Nurul Hikmah
Analisis Perbandingan Kuat Tekan Mortar Geopolimer Berbahan Abu Sekam Padi Dan Zeolit Dengan Alkali Aktivator Terhadap Mortar Berbahan Semen Portland = Comparative Analysis Of Compressive Strength Of Geopolymer Mortar Made From Rice Husk Ash And Zeolite With Alkaline Activator Against Portland Cement Mortar
"Menurut survey Badan Pusat Statistik di Indonesia diketahui telah terjadi pertumbuhan nilai konstruksi di Kalimantan Timur (lokasi baru Ibu Kota Negara) sebesar 6,60% dari tahun 2019-2020. Semakin tinggi nilai konstruksi maka semakin tinggi pula permintaan bahan bangunan, contohnya seperti mortar semen portland. Akan tetapi, terdapat dampak buruk dalam pemakaian semen portland yang secara terus-menerus yaitu terjadinya pemanasan global karena adanya emisi gas CO yang tinggi. Untuk mengurangi dampak buruk tersebut diperlukanlah bahan pengganti semen yang lebih ramah lingkungan seperti material geopolimer. Dalam pembentukan mortar geopolimer dibutuhkan bahan utama yang mengandung kadar Si dan Al yang tinggi seperti ASP dan zeolit, serta perlu adanya alkali aktivator seperti NaOH dan NaSiO yang berperan sebagai larutan pengikat unsur Si dan Al dalam reaksi geopolimerisasi. Ada perlakuan khusus pada studi ini untuk menjaga kualitas mortar geopolimer ASP-Zeolit yang terbentuk yaitu metode dengan oven di suhu 60°C selama 24 jam. Pada studi ini dilakukan pembentukan mortar geopolimer dengan lima variasi komposisi penyusun mortar geopolimer antara lain 100%ASP; 90%ASP-10%Zeolit; 70%ASP-30%Zeolit; 50%ASP-50%Zeolit; dan 100%Zeolit, untuk mengetahui pengaruh kadar prekursor terhadap nilai kuat tekan mortar tersebut serta membandingkan nilai kuat tekan mortar geopolimer dengan kuat tekan mortar semen portland. Hasil penelitian ini menunjukkan adanya kandungan Si yang tinggi dalam bahan penyusun mortar geopolimer akan meningkatkan nilai kuat tekannya seperti mortar geopolimer 100%ASP, tetapi nilai kuat tekan mortar geopolimer ASP-Zeolit masih dibawah nilai kuat tekan mortar semen portland.
According to a survey conducted by Indonesia's Central Statistics Agency, East Kalimantan (the new location for the State Capital of Indonesia) saw a 6,60% increase in construction value between 2019 and 2020. The higher the construction value, the higher the demand for building materials, such as portland cement mortar. However, there are negative impacts in the continuous use of portland cement which causes a global warming effect due to high CO2 gas emissions. To reduce these negative impacts, a more environmentally friendly cement substitute material, such as geopolymer material, is needed. In the formation of geopolymer mortar, the main ingredients that contain high levels of Si and Al are needed, such as RHA and zeolite, as well as the need for alkaline activators such as NaOH and Na2SiO3 which act as a binding solution for Si and Al elements in the geopolymerization reaction. There is special treatment in this study to maintain the quality of RHA-Zeolite geopolymer mortar that is formed namely curing oven at 60°C for 24 hours. In this study, geopolymer mortar was formed with five variations of geopolymer mortar composition, including 100% RHA; 90% RHA-10% Zeolite; 70% RHA-30% Zeolite; 50% RHA-50% Zeolite; and 100% Zeolite, to determine the effect of precursor content on the compressive strength of the mortar and to compare the compressive strength of this geopolymer mortar with the compressive strength of portland cement mortar. The results of this study indicate that a high Si content in the RHA-Zeolite geopolymer mortar will increase its compressive strength like 100% RHA geopolymer mortar, but the compressive strength of RHA-Zeolite geopolymer mortar is still below the compressive strength of portland cement mortar."
Depok: Fakultas Teknik Universitas Indonesia, 2023
S-pdf
UI - Skripsi Membership  Universitas Indonesia Library
cover
Moh. Azhar
Rekayasa material abu sekam padi dan batu apung pada beton ringan untuk meningkatkan kekuatan mekanik semen portland komposit = Lightweight concrete containing rice husk ash and pumice materials to improve the mechanical strength of portland cement composites
"[ABSTRAK
Telah dilakukan penelitian pembuatan beton ringan atau lightweight
concrete (LWC) menggunakan batu apug (BA) dan abu sekam padi (ASP).
Sampel beton ringan yang dibuat mengandung BA dengan fraksi berbeda, adapun
material semen, pasir, dan abu sekam padi volumenya dijaga tetap. Terdapat dua
parameter utama yang menentukan sifat mekanik sampel LWC masing-masing
adalah densitas sampel dan rasio air/semen (w/c). Sifat mekanik yang paling
utama dari LWC adalah kekuatan tekan. Pada campuran dengan fraksi volume
batu apung terbesar (100%) menghasilkan densitas dan kekuatan tekan paling
rendah masing-masing sebesar (1389,6 kg/m3 dan 11,1 MPa). Diketahui bahwa
makin rendah fraksi batu apung dalam sampel beton makin tinggi nilai densitas
dan kekuatan tekannya, disebabkan oleh tingginya nilai fraksi pori baik pori
terbuka maupun pori tertutup dalam sampel beton. Observasi terhadap fotomikro
SEM batu apung menunjukkan bahwa terdapat sejumlah besar pori dengan bentuk
memanjang ke bagian dalam dari permukaan sampel beton. Pori hadir dengan
kerapatan jumlah pori relatif besar serta dengan ukuran yang bervariasi. Fakta ini
menjelaskan mengapa batu apung besifat ringan karena memiliki densitas massa
yang rendah. Pola difraksi sinar X sampel beton ringan memperlihatkan dominasi
fasa kristalin diidentifikasi sebagai fasa quartz (SiO2). Namun dapat dipastikan
sampel beton ringan terdiri dari fasa campuran antara fasa kristalin dan dengan
sedikit fasa amorph.
Fotomikro SEM beton ringan menunjukkan bahwa senyawa Kalsium Silikat
Hidrat (CSH) mulai tumbuh pada waktu awal proses hidrasi dan terus
berkembang sampai umur beton mencapai umur hidrasi 28 hari yang ditandai
dengan sifat fisik yang padat dan peningkatan kekuatan beton. Dapat dipastikan
bahwa senyawa CSH ini memiliki peranan penting terhadap pengaturan sifat
mekanik seperti kekuatan tekan. Penelitian ini menyimpulkan bahwa batu apung
dan abu sekam padi adalah material berbasis silika amorph yang memiliki densitas
lebih rendah terutama dibandingkan dengan material pembentuk beton lainnya.
Baik densitas dan kekuatan tekan sampel beton ringan ditentukan oleh rasio antara
batu apung dan abu sekam padi. Ditemukan rasio terkecil BA/ASP yaitu 8
menghasilkan nilai densitas dan kekuatan tekan optimal, masing-masing pada usia
beton 28 hari sebesar 1891 kg/m3 dan 23 MPa. Komposisi beton ringan yang
terbaik 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 nilai
rasio antara kuat tekan dan densitas tertinggi adalah 1285.;
ABSTRACT
Research studies on the manufacture of lightweight concrete (LWC) using
pumice and rice husk ash (RHA) materials have been done. LWC samples were
made 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 main
parameters that determine the mechanical properties of LWC which are density
and the water and cement ratio (w/c ratio). The main mechanical properties of
LWC sample is the power press. Samples with the largest volume fraction of
pumice (100%) resulted in lightest density (1389.6 kg/m3) and the smallest
strength of LWC (11.1 MPa). It was found that, the lower the mass fraction of
pumice in LWC samples, the higher the density values and compressive strength
were obtained. This was caused by the high mas fraction value of pores, which
were both open and closed pores. Scanning electron micorscopy (SEM) images
for the pumice showed that the there are a large number of regular and structured
pores extending deep inside the surface of the sample. It was observed that pores
present with pore size does not vary significantly but with the density of the
relatively large number of pores, indicating pumice has a low mass density. The
XRD pattern of the lightweight concrete samples indicated that the samples were
dominated by crystalline phases in which the quartz (SiO2) is the main phase and
a small fraction of amorphous phase was also obtained.
SEM images of lightweight concrete samples showed that the structure of
Calcium Silicate Hydrates (CSH) started growing at the beginning of hydration
time 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 as
compressive strength. The study concluded that the pumice and rice husk ash is
are amorphous silica-based material which has a lower density compared to other
concrete forming material such as cement and sands. Both density and light
weight concrete compressive strength are determined by the ratio between pumice
and rice husk ash, in which the smallest ratio 8 resulted in the largest density and
compressive strength, which are 1890.5 kg/m3 and 23.2 MPa respectively at the
age of 28 days. The study concluded that the best composition for lightweight
concrete 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 between
compressive strength and density of 1285.;Research studies on the manufacture of lightweight concrete (LWC) using
pumice and rice husk ash (RHA) materials have been done. LWC samples were
made 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 main
parameters that determine the mechanical properties of LWC which are density
and the water and cement ratio (w/c ratio). The main mechanical properties of
LWC sample is the power press. Samples with the largest volume fraction of
pumice (100%) resulted in lightest density (1389.6 kg/m3) and the smallest
strength of LWC (11.1 MPa). It was found that, the lower the mass fraction of
pumice in LWC samples, the higher the density values and compressive strength
were obtained. This was caused by the high mas fraction value of pores, which
were both open and closed pores. Scanning electron micorscopy (SEM) images
for the pumice showed that the there are a large number of regular and structured
pores extending deep inside the surface of the sample. It was observed that pores
present with pore size does not vary significantly but with the density of the
relatively large number of pores, indicating pumice has a low mass density. The
XRD pattern of the lightweight concrete samples indicated that the samples were
dominated by crystalline phases in which the quartz (SiO2) is the main phase and
a small fraction of amorphous phase was also obtained.
SEM images of lightweight concrete samples showed that the structure of
Calcium Silicate Hydrates (CSH) started growing at the beginning of hydration
time 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 as
compressive strength. The study concluded that the pumice and rice husk ash is
are amorphous silica-based material which has a lower density compared to other
concrete forming material such as cement and sands. Both density and light
weight concrete compressive strength are determined by the ratio between pumice
and rice husk ash, in which the smallest ratio 8 resulted in the largest density and
compressive strength, which are 1890.5 kg/m3 and 23.2 MPa respectively at the
age of 28 days. The study concluded that the best composition for lightweight
concrete 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 between
compressive strength and density of 1285., Research studies on the manufacture of lightweight concrete (LWC) using
pumice and rice husk ash (RHA) materials have been done. LWC samples were
made 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 main
parameters that determine the mechanical properties of LWC which are density
and the water and cement ratio (w/c ratio). The main mechanical properties of
LWC sample is the power press. Samples with the largest volume fraction of
pumice (100%) resulted in lightest density (1389.6 kg/m3) and the smallest
strength of LWC (11.1 MPa). It was found that, the lower the mass fraction of
pumice in LWC samples, the higher the density values and compressive strength
were obtained. This was caused by the high mas fraction value of pores, which
were both open and closed pores. Scanning electron micorscopy (SEM) images
for the pumice showed that the there are a large number of regular and structured
pores extending deep inside the surface of the sample. It was observed that pores
present with pore size does not vary significantly but with the density of the
relatively large number of pores, indicating pumice has a low mass density. The
XRD pattern of the lightweight concrete samples indicated that the samples were
dominated by crystalline phases in which the quartz (SiO2) is the main phase and
a small fraction of amorphous phase was also obtained.
SEM images of lightweight concrete samples showed that the structure of
Calcium Silicate Hydrates (CSH) started growing at the beginning of hydration
time 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 as
compressive strength. The study concluded that the pumice and rice husk ash is
are amorphous silica-based material which has a lower density compared to other
concrete forming material such as cement and sands. Both density and light
weight concrete compressive strength are determined by the ratio between pumice
and rice husk ash, in which the smallest ratio 8 resulted in the largest density and
compressive strength, which are 1890.5 kg/m3 and 23.2 MPa respectively at the
age of 28 days. The study concluded that the best composition for lightweight
concrete 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 between
compressive strength and density of 1285.]"
2015
D2054
UI - Disertasi Membership  Universitas Indonesia Library
cover
Bangun, Gideon Oktavian
Kuat Tarik Langsung, Kuat Lentur, Susut dan Density Mortar Campuran Semen Abu Sekam Padi dan Precious Slag Ball Dengan Perbandingan 30% : 20% : 50%
"Penelitian awal mortar dengan campuran semen, abu sekam padi (ASP) dan precious slag ball (PSB) dengan perbandingan 30% PCC, 20% ASP dan 50% PSB di uji beberapa sifat mekanisnya yaitu kuat tarik langsung, kuat tarik lentur, susut dan density. Pengujian di lakukan dengan mengikuti standar pengujian Kuat Tarik Langsung ASTM-C-307-03, Kuat Lentur ASTM-C-348-02, Susut ASTM-C-490-00, Density ASTM-D-720-00. Dari penelitian diharapkan campuran ini dapat menghasilkan mortar dengan sifat mekanis yang memenuhi standar SNI atau ASTM.
Nilai modulus kehalusan ASP adalah 0,754 dan PSB adalah 1,054, Akibat penambahan ASP dalam campuran nilai FAS yang di dapat tinggi yaitu lebih dari berat semen, hal ini disebabkan air yang dibutuhkan lebih banyak untuk mencapai konsistensi normal. Untuk semen tipe 1 (Tiga Roda) Campuran PCC dan PSB memiliki nilai kuat tarik langsung 3,6385 MPa ; kuat tarik lentur 13,992 MPa ; susut 0,0061% dan density 2,811 g/cm3. Campuran PCC ASP dan PSB memiliki nilai kuat tarik langsung 0,8975 MPa ; kuat tarik lentur 2,3625 MPa ; susut 0,0077% dan density 1,848 g/cm3. Untuk semen Tipe 2 (Holcim) Campuran PCC dan PSB memiliki nilai kuat tarik langsung 2,8667 MPa ; kuat tarik lentur 14,3166 MPa ; susut 0,0061% dan density 2,781 g/cm3 . Campuran PCC ASP dan PSB memiliki nilai kuat tarik langsung 0,8684MPa ; kuat tarik lentur 2,7882 MPa ; susut 0,0073% dan density 1,907 g/cm3.
Mortar yang dihasilkan dengan menggunakan campuran PSB memiliki density tinggi sehingga nilai kuat tarik langsung dan tarik lentur lebih tinggi jika dihitung berdasarkan rumus yang ada di dalam SNI 03-2847-2002, sedangkan untuk mortar yang menggunakan campuran ASP dan PSB memiliki density lebih rendah dan dapat diklasifikasikan dalam mortar ringan dengan nilai 1,900 g/cm3 untuk itu menggunakan rumus perhitungan kuat tarik langsung dan tarik lentur untuk mortar ringan sesuai dengan SNI 03-2847-2002.
Initial studies with a mixture of mortar cement, rice husk ash (ASP) and precious slag ball (PSB) with a ratio of 30% PCC, 20% RHA and 50% PSB tested several mechanical properties of the direct tensile strength, flexural tensile strength, shrinkage and density. Tests done by following the testing standard ASTM Direct Tensile Strength C-307-03, Flexural Strength ASTM C-348-02, Shrinkage ASTM-C-490-00, Density ASTM D-720-00. This mixture of research is expected to produce mortar with mechanical properties that meet SNI or ASTM standards.
ASP fineness modulus value is 0.754 and the PSB is 1.054, a result of the addition of ASP in a mixture of values that FAS can be as high as more than the weight of cement, this is due to more water needed to achieve normal consistency. The first type of cement (Tiga Roda) mixture of PCC and the PSB has a value of direct tensile strength 3.6385 MPa; Flexural Tensile Strength 13.992 MPa; Shrinkage 0.0061% and Density 2.811 g/cm3. Mixture of PCC, ASP and the PSB has a value of direct tensile strength 0.8975 MPa; Flexural Tensile Strength 2.3625 MPa; Shrinkage 0.0077% and Density 1.848 g/cm3. For the second tipe of cement (Holcim) Mixed PCC and the PSB has a value of Direct Tensile Strength 2.8667 MPa; Flexural Tensile Strength 14.3166 MPa; Shrinkage 0.0061% and Density 2.781 g/cm3. Mixture of PCC, ASP and the PSB has a value of Direct Tensile Strength 0.8684 MPa; Flexural Tensile Strength 2.7882 MPa; Shrinkage 0.0073% and Density 1.907 g/cm3.
Mortar is produced by using a mixture of PSB, has a high density so that the value of the direct tensile strength and flexural tensile higher if calculated on a formula that is in the SNI 03-2847-2002, while for the mortar using a mix of ASP and the PSB has a lower density and can be classified in the lightweight mortar with a value of 1.900 g/cm3 for it using a formula calculating the direct tensile strength and tensile bending to light mortar according to the SNI 03-2847-2002."
Depok: Fakultas Teknik Universitas Indonesia, 2011
S-Pdf
UI - Skripsi Membership  Universitas Indonesia Library
cover
Gilang Wibowo Aji
Kuat tekan, density, absorpsi dan modulus elastisitas mortar campuran semen, abu sekam padi, dan precious slag ball dengan perbandingan 30%:20%:50%
"Sifat mekanik mortar yang terdiri dari Kuat Tekan, Densitas, Absorpsi dan Modulus Elastisitas merupakan sifat utama yang sangat penting bagi mortar dalam penggunaan sebagai bahan konstruksi. Seiring dengan sumber daya alam yang terus berkurang, maka bahan untuk membentuk mortar pun dapat diganti dengan bahan buangan limbah pertanian dan baja, yang secara kualitas tidak kalah dengan bahan pengganti agregat halus (pasir). Adapun bahan pengisi yang digunakan adalah abu sekam padi (ASP) dan precious slag ball (PSB). Penelitian ini terdiri dari 2 komposisi, yaitu komposisi 30% PCC dan 70% PSB dan komposisi 30% PCC, 20% ASP, dan 50% PSB dan memakai 2 type semen. Dari penelitian yang telah dilakukan, diperoleh mortar dengan kuat tekan komposisi 1: 79.074 MPa dan 79.960 MPa dan kuat tekan komposisi 2: 14.99 MPa dan 15.95 MPa, densitas komposisi 1: 2,811 gram/cm3 dan 2,781 gram/cmdan densitas komposisi 2: 1,848 gram/cm3 dan 1,907 gram/cm3, absorpsi komposisi 1: 7.2, 10.8, 27.76, 36 gram/100cm2 dan 8.8, 18, 36.4, 47.2 gram/100cm2, dan absorpsi komposisi 2: 12, 21.6, 61.6, 146 gram/100cm2 dan 16, 26.4, 86.72, 135.2 gram/100cm2, modulus elastisitas komposisi 1: 43592.44, 43592.44, 37134.33, 37292.94 MPa dan 39438.58, 39438.58, 33858.25, 33769.86 MPa, dan modulus elastisitas komposisi 2: 10321.9, 4423.7, 9144.2, 9350.1 MPa dan 11662.4, 4423.7, 10275.8, 9879.6 MPa. Nilai-nilai sifat mekanik yang telah memenuhi persyaratan ASTM C 579¬01, ASTM C 905-01, ASTM C 1403-00 dan ASTM C 580-02 diharapkan dapat meminimalisir bahkan meniadakan penggunaan pasir serta memaksimalkan penggunaan limbah yang ramah lingkungan.
Mechanical properties of mortar consisting of Compressive Strength, Density, Absorption and Modulus of Elasticity is the main character are very important for the mortar to be used as construction material. Along with the decreasing of natural resources, the material used for the mortar mix can be replaced by agricultural and steel waste materials, which is not inferior in replacing material for natural sand. The filler material used are rice husk ash (RHA) and precious slag ball (PSB). This study consisted of two mortar compositions, namely the composition of 30% PCC and 70% PSB and the composition of 30% PCC, 20% RHA, 50% PSB and two different products of a type of cement were used in this experimental study consisted of two type of composition. The research outcomes exhibited that the compressive strength of composition 1: 79 074 MPa and 79,960 MPa and compressive strength of composition 2: 14.99 MPa and 15.95 MPa, the density of composition 1: 2.811 and 2.781 gram/cm3 gram/cm3 and density of composition 2: 1.848 gram/cm3 and 1.907 gram/cm3, the absorption of composition 1: 7.2, 10.8, 27.76, 36 gram/100cm2 and 8.8, 18, 36.4, 47.2 gram/100cm2, and absorption of composition 2: 12, 21.6, 61.6, 146 gram/100cm2 and 16, 26.04, 86.72, 135.2 gram/100cm2, modulus elasticity of composition 1: 43592.44, 43592.44, 37134.33, 37292.94 and 39438.58 MPa, 39438.58, 33858.25, 33769.86 MPa, and modulus elasticity of composition 2: 10321.9, 4423.7, 9144.2, 9350.1 MPa and 11662.4, 4423.7, 10275.8, 9879.6 MPa. The values of mechanical properties that meet the requirements of ASTM C 579-01, ASTM C 905-01, ASTM C 1403-00 and ASTM C 580-02 is expected to minimize and even eliminate the use of sand and maximize the use of environmentally friendly waste."
Depok: Fakultas Teknik Universitas Indonesia, 2011
S870
UI - Skripsi Open  Universitas Indonesia Library
cover
Bastian Okto Bangkit Sentosa
Pengaruh faktor air semen terhadap kuat tekan, kuat tarik belah, dan kuat lentur beton normal menggunakan semen portland pozzolan = Influence of water cement ratio on compressive strength, splitting tensile strength and flexural strength of normal concrete using portland pozzolan cement
"Semen Portland Pozzolan (SPP) adalah suatu bahan perekat hidrolis yang dibuat dengan menggiling halus klinker semen Portland dengan pozzolan, atau suatu campuran yang merata antara bubuk semen Portland dan bubuk pozzolan selama penggilingan atau pencampuran. SPP untuk mencapai kekuatannya membutuhkan waktu relatif lebih lambat dibandingkan dengan semen Portland lainnya meskipun ultimate strenght yang dicapai SPP mungkin sama atau lebih besar dari yang terbuat dari semen Portland. Dalam penelitian ini, faktor air semen (FAS) yang digunakan bervariasi diantara 0,3; 0,35; 0,45; 0,55; 0,65; 0,75; dan 0,8 serta diamati pengaruhnya terhadap kuat tekan, kuat tarik belah dan kuat lentur pada beton menggunakan SPP. Pengujian kuat tekan, kuat tarik belah, dan kuat lentur dilakukan pada umur 7, 14 dan 28 hari.
Hasil pengujian diolah dengan dua metode yaitu metode rata-rata dan chi-square untuk membandingkan metode mana yang paling akurat. Kuat tekan, kuat tarik belah dan kuat lentur bertambah seiring dengan pertambahan umur beton pada semua FAS. Namun kenaikan FAS berbanding terbalik dengan kuat tekan, kuat tarik belah dan kuat lentur beton. Kenaikan kuat tekan akan diikuti dengan kenaikan kuat tarik belah dan kuat lenturnya sehingga kenaikan kuat tarik belah akan mengikuti kenaikan kuat lentur dan sebaliknya.
Pozzolan Portland Cement (PPC) is an hydraulic adhesive which made by grinding Portland cement clinker with Pozzolan, or an equal mixture of Portland cement powder and powder Pozzolan during milling or mixing. PPC to achieve the strength it took relatively more slowly than other portland cement, although the ultimate PPC strenght achieved equal or perhaps greater than that made from portland cement. In this research, water cement ratio which is used variation from 0,30 0,3; 0,35; 0,45; 0,55; 0,65; 0,75; and 0,8 also observed the influent of compressive strength, splitting tensile strength, and flexural strength concrete using SPP. Compressive strength, splitting tensile strength and flexural strength test is done on 7, 14, and 28 days.
The test result is processed by two methods which are average method and chi square method for comparing the best accuracy method. Compressive strength, splitting tensile strength, and flexural strength increase following concrete age on all water cement ratio. However, increasing water cement ratio is inversely with compressive strength, splitting tensile strength, and flexural strength. Increasing compressive strength will be followed by splitting tensile strength and flexural strength so that increasing splitting tensile strength will follow increasing flexural strength."
Depok: Fakultas Teknik Universitas Indonesia, 2010
S50594
UI - Skripsi Open  Universitas Indonesia Library
cover
Abdul Latief
Kuat tarik langsung, kuat tarik lentur, susut dan density mortar campuran semen, abu sekam padi, dan precious slag ball dengan persentase 30%; 30%; 40% = Tensile and flexural strength, length change and density of cement mortar containing rice husk ash and precious slag ball using a composition of 30% cement; 30% RHA; 40% PSB
"Pada penelitian ini dilakukan pengujian kuat tarik langsung, kuat tarik lentur, susut dan density dengan jumlah benda uji 250 buah.
Pada penelitian ini dipakai 2 tipe Portland Composite Cement (PCC), Precious Slag Ball (PSB) dan Abu Sekam Padi (ASP) dengan komposisi campuran : 30% PCC (Portland Composite Cement) ? 30% ASP (Abu Sekam Padi) ? 40% PSB (Precious Slag Ball).
Standar penelitian mengacu pada standar ASTM. Dari penelitian ini didapatkan kuat tarik langsung pada umur 28 hari sebesar 0.740 MPa untuk campuran PCC tipe 1 dan sebesar 0.641 MPa untuk campuran PCC tipe 2. Kuat tarik lentur pada umur 28 hari sebesar 1.750 MPa untuk campuran PCC tipe 1 dan sebesar 1.550 MPa untuk campuiran PCC tipe 2. Nilai susut sebesar 0.0092 untuk campuran PCC tipe 1 dan sebesar 0.0088 untuk campuran PCC tipe 2. Density Sebesar 1.579 gr/cm2 untuk campuran PCC tipe 1 dan sebesar 1.602 gr/cm2 untuk campuran tipe 2.
This research observing the tensile strength, flexural strength, length change and density of mortar cement done to 250 specimens.
In this research two resources of Portland Composite Cement (PCC) produced by 2 industries were used in mortar mixing composed with Precious Slag Ball (PSB) and Rice Husk Ash (RHA) in proportion of 30% PCC; 30% RHA; 40% PSB. The terms used in this research relating to ASTM standards.
The results from this research give value of tensile strength of 28 days type 1 and type 2 are 0.740 MPa and 0.641 MPa; Flexural strength of 28 days type 1 and type 2 are 1.750 MPa and 1.550 MPa; Shrinkage type 1 and type 2 are 0.0092 and 0.0088. Density type 1 and type 2 are 1.579 gr/cm2 and 1.602 gr/cm2."
Depok: Fakultas Teknik Universitas Indonesia, 2010
S1467
UI - Skripsi Open  Universitas Indonesia Library
cover
Andria Kuswadi
Efek Proses dan Rasio Campuran Cangkang Telur dan Silika Sekam Padi terhadap Pembentukan Semen Hidraulik Dikalsium Silikat = The Effect of Silica Rice Husk and Eggshell Mixture Process and Ratio to The Formation of Dicalcium Silicate Hydraulic Cement
"Latar Belakang: Pemanfaatan material limbah hayati cangkang telur sebagai sumber kalsium dan abu sekam padi sebagai sumber silika dapat digunakan sebagai substitusi komponen utama pada proses pembentukan semen Dikalsium Silikat.
Tujuan: Mengetahui efek proses dan rasio cangkang telur dan silika sekam padi terhadap jumlah prosentase kandungan dikalsium silikat.
Metode: Sebanyak 1 g bubuk cangkang telur hasil milling kering menggunakan alat High Energy Milling dan 1 g silika sekam padi dilakukan uji karakterisasi XRD Sintesis dikalsium silikat dilakukan dengan metode solid state menggunakan empat rasio mol campuran cangkang telur dan silika sekam padi (9,01:3,00) ; (2:1) ; (1,9:1) dan (1,8:1) yang di dapat dari hasil percobaan pendahuluan. Campuran homogen dari masing-masing sampel dilakukan dengan milling basah menggunakan alat High Energy Milling selama 1 jam (700 rpm) dan larutan pencampur HexanTM. Sintesis Dikalsium silikat menggunakan kalsinasi suhu 12000C selama 3 jam pada Muffle Furnace dan proses pendinginan dibiarkan hingga mencapai suhu ruangan tanpa perlakuan khusus tertentu. Semen dikalsium silikat yang terbentuk selanjut dilakukan uji karakterisasi dengan XRD. Data hasil penelitian di sajikan dalam bentuk deskriptif.
Hasil: Proses milling basah dengan rasio cangkang telur dan silika sekam padi 1,8 : 1 menghasilkan prosentase konten C2S ( 100% ) dengan 2 struktur kristalite (monoclinic dan orthorombic). Rasio 1,9:1 menghasilkan 96,22% C2S rasio 2:1 menghasilkan 94,54% C2S dan rasio 9,01: 3,00 menghasikan 71,6% C2S.
Kesimpulan: Proses milling basah dengan rasio cangkang telur dan silika sekam padi 1,8 : 1 pada suhu kalsinasi 12000C selama 3 jam,menghasilkan prosentase kandungan tertinggi ( 100% ) C2S pada semen hidraulik campuran cangkang telur dan silika sekam padi.
Background: Silica rice husk and eggshell waste are one of the calcium source that can be used as main component substitute in formation process of Dicalcium Silicate.
Objective: To Determine the effect of silica rice husk and eggshell mixture process and ratio to the percentage formation of dicalcium silicate hydraulic cement.
Methods: 1 gram of eggshell powder produced by dry milling using the High Energy Milling machine and 1 gram of silica rice husk were characterized tested with XRD (X-Ray Diffraction) Dicalcium silicate synthesis was made with solid state method using four mol ratio of the eggshell and silica rice husk mixture, which were (9,01:3,00) ; (2:1) ; (1,9:1) and (1,8:1) from the previous research. Homogenous mixture from each sample were proceed from the wet milling using High Energy Milling for 1 hour (700rpm) and HexanTM solution mixture. Dicalcium silicate synthesis using calcination temperature 12000C for 3 hours on Muffle Furnace and the cooling process were letting to the room temperature without any further treatment. Dicalcium silicate cement were formed using the characteristic test with XRD. The result was perform in descriptive.
Result: Wet milling process with ratio of eggshell and silica rise husk was 1,8 : 1 content percentage of C2S ( 100% ) with 2 crystallite structure (monoclinic and orthorhombic). Ratio 1,9 : 1 produce 96,22% of C2S, ratio 2:1 produce 94,54% of C2S dan ratio 9,01: 3,00 produce 71,6% of C2S.
Conclusion: Wet milling with ratio of eggshell and silica rise husk was (1,8:1), calcination temperature 12000C for 3 hours produce the highest percentage (100%) of C2S on hydraulic cement from eggshell and silica rise husk mixture."
Jakarta: Fakultas Kedokteran Gigi Universitas Indonesia, 2021
SP-pdf
UI - Tugas Akhir  Universitas Indonesia Library
cover
Rakhmawati Caesaria
Efek Antibakteri Semen Hidraulik Dikalsium Silikat Campuran Kalsium Cangkang Telur Dan Silika Sekam Padi Terhadap Viabilitas Biofilm Streptococcus Mutans = Antibacterial Effects of Hydraulic Cement Dicalcium Silicate Mixture of Eggshell Calcium and Rice Husk Silica on Viability of Streptococcus Mutans Biofilm
"Latar belakang : Semen dikalsium silikat campuran kalsium cangkang telur dan silika sekam padi (C2S CS) mempunyai sifat hidrofilik dan dapat bereaksi dengan air atau cairan pada suhu ruang/suhu tubuh. Semen dikalsium silikat apabila berekasi dengan air antara lain akan menghasilkan senyawa kalsium hidroksida. Dalam mekanisme antibakteri dari semen dikalsium silikat, ion hidroksil yang dilepaskan oleh kalsium hidroksida akan meningkatkan pH, menyebabkan terjadinya kerusakan membran sitoplasma bakteri, denaturasi protein dan kerusakan pada DNA bakteri 
Tujuan: Mengetahui kemampuan antibakteri dari semen C2S CS yang dilarutkan dengan berbagai konsentrasi (1:1, 1:2 dan 1:4) terhadap viabilitas biofilm S. mutans.
Metode: Terdapat 4 kelompok penelitian yang terdiri dari 3 kelompok perlakuan dan 1 kelompok Kontrol negatif. Menggunakan metode mikrodilusi, 3 kelompok perlakuan terdiri dari ekstrak semen C2S CS berbagai konsentrasi (1:1, 1:2 dan 1:4) lalu dipaparkan dengan biofilm S.mutans ATCC 25175. Kemudian ditentukan viabilitasnya melalui microplate reader dengan Panjang gelombang 570 nm dan juga pembacaaan visual. Nilai MIC ditentukan apabila terdapat penurunan pertumbuhan bakteri 
Hasil: terdapat perbedaan signifikan yang terjadi antara kelompok perlakuan dan kontrol (p< 0.05). viabilitas bakteri terendah pada konsentrasi 1:1 yaitu 18,92% dan tertinggai pada konsentrasi 1:4 46,52%. Nilai MIC didapatkan pada konsentrasi ekstrak 1:1, dengan penurunan jumlah viabilitas biofilm bakteri S mutans sebesar 81,1%. 
Kesimpulan: Konsentrasi ekstrak semen C2S CS yang secara signifikan mampu menurunkan viabilitas biofilm S.mutans adalah Konsentrasi 1:1.
Background : Cement dicalcium silicate a mixture of eggshell calcium and rice husk silica (C2S CS) has hydrophilic properties and can react with water or liquids at room temperature/body temperature. When dicalcium silicate cement reacts with water, among others, it will produce calcium hydroxide compounds. In the antibacterial mechanism of dicalcium silicate cement, hydroxyl ions released by calcium hydroxide will increase the pH, causing damage to the bacterial cytoplasmic membrane, protein denaturation and damage to bacterial DNA. 
Objective: To determine the antibacterial ability of C2S CS cement dissolved in various concentrations (1: 1, 1:2 and 1:4) on the biofilm viability of S. mutans. 
Methods: There were 4 groups consisting of 3 treatment groups and 1 negative control group. Using the microdilution method, 3 treatment groups consisting of C2S CS cement extracts of various concentrations (1:1, 1:2 and 1:4) were then exposed to S. mutans biofilm. Then the viability was determined through a microplate reader with a wavelength of 570 nm and visual reading. The MIC value was determined if there was a decrease in bacterial growth 80% compared to the control. 
Results: there were significant differences between the treatment and control groups (p < 0.05). The lowest bacterial viability was at a concentration of 1:1, namely 18.92% and the highest at a concentration of 1:4 46.52%. The MIC value was obtained at a concentration of 1:1 extract, with a decrease in the number of S. mutansbiofilm viability by 81.1%. 
Conclusion: The concentration of C2S CS cement extract which significantly reduced the viability of S. mutans biofilm was a concentration of 1:1."
Jakarta: Fakultas Kedokteran Gigi Universitas Indonesia, 2022
SP-pdf
UI - Tugas Akhir  Universitas Indonesia Library
cover
Maharina Diyah Pritawati
Sitotoksisitas Semen Hidraulik Dikalsium Silikat Campuran Kalsium Cangkang Telur Dan Silika Sekam Padi Terhadap Sel Fibroblas = Cytotoxicity of Hydraulic Cement Dicalcium Silicate Mixture of Eggshell Calcium and Rice Husk Silica on Fibroblast Cells
"Latar Belakang : Semen hidroulik dikalsium silikat campuran kalsium cangkang telur dan silika sekam padi saat ini sedang dikembangkan untuk material perawatan di bidang kedokteran gigi, diantaranya sebagai material kaping pulpa. Tujuan utama dari perawatan ini adalah untuk menjaga vitalitas jaringan pulpa. Material kaping pulpa diharapkan bersifat biokompatibel dan memiliki sitositotoksisitas rendah sehingga beberapa pengujian perlu dilakukan untuk menentukan layak atau tidaknya bahan tersebut agar tidak menimbulkan respon biologis merugikan, karena maerial ini akan ditempatkan dekat dengan pulpa. Dasar dari uji sitositotoksisitas adalah kemampuan sel untuk bertahan hidup karena adanya senyawa toksik yang diberikan.  
Tujuan : Mengetahui efek sitotoksisitas Semen hidroulik dikalsium silikat campuran kalsium cangkang telur dan silika sekam padi terhadap sel fibroblas.
Metode : Sel fibroblas NIH3T3 yang telah mengalami serum starvation selama 24 jam, diberikan media kultur semen hidraulik dikalsium silika campuran cangkang telur dan silika sekam padi dengan konsentrasi 1:1, 1:2, 1:4 dan DMEM sebagai kontrol negatif. Efek sitotoksisitas diuji pada 24 jam dan 48 jam menggunakan MTT Assay, hasil yang didapatkan dianalisis dengan uji statistik uji non parametrik Kruskal Wallis dilanjutkan dengan Post Hoc menggunakan Mann-Whitney untuk kelompok observasi 24 jam. Sedangkan pada observasi 48 jam didapatkan dianalisis dengan uji statistik uji parametrik One Way Annova dilanjutkan dengan Post Hoc menggunakan T-Test.
Hasil : Tidak terdapat perbedaan bermakna nilai viabilitas sel pada pemberian semen hidroulik dikalsium silikat campuran kalsium cangkang telur dan silika sekam padi berbagai konsentrasi (1:1, 1:2, 1:4) terhadap sel fibroblas NIH3T3 pada observasi waktu 24 jam, dengan rerata nilai viabilitas tertinggi pada konsentrasi 1:4. Pada observasi 48 jam, terdapat perbedaan bermakna nilai viabilitas sel pada pemberian Semen hidroulik dikalsium silikat campuran kalsium cangkang telur dan silika sekam padi berbagai konsentrasi (1:1, 1:2, 1:4) terhadap sel fibroblas NIH3T3, dengan rerata nilai viabilitas tertinggi kelompok perlakuan pada konsentrasi 1:4.
Kesimpulan : Semen hidroulik dikalsium silikat campuran kalsium cangkang telur dan silika sekam padi berbagai konsentrasi (1:1, 1:2, 1:4) tidak memiliki efek  sitotoksisitas terhadap sel fibroblas NIH3T3 pada observasi waktu 24 jam dan 48 jam. Nilai viabilitas sel fibroblas NIH3T3 tertinggi pada observasi waktu 24 jam dan 48 jam terdapat pada konsentrasi 1:4.
Background : Dicalcium silicate hydraulic cement, a mixture of eggshell calcium and rice husk silica, is currently being developed for treatment materials in dentistry, including pulp capping material. The main goal of this treatment is to maintain the vitality of the pulp tissue. The pulp capping material is expected to be biocompatible and have low cytotoxicity so that several tests need to be carried out to determine whether or not the material is feasible so as not to cause an adverse biological response, because this material will be placed close to the pulp. The basis of the cytotoxicity test is the ability of cells to survive in the presence of a given toxic compound.
Objective : To determine the cytotoxicity effect of hydraulic cement dicalcium silicate mixture of eggshell calcium and rice husk silica on fibroblast cells.
Methods : NIH3T3 fibroblast cells that had undergone serum starvation for 24 hours were given hydraulic cement culture media of dicalcium silica mixture of eggshell and rice husk silica with concentrations of 1:1, 1:2, 1:4 and DMEM as a negative control. The cytotoxicity effect was tested at 24 hours and 48 hours using MTT Assay, the results obtained were analyzed by statistical non-parametric Kruskal Wallis test followed by Post Hoc using Mann-Whitney for the 24-hour observation group. Meanw hile the 48-hour observation obtained was analyzed by statistical test One Way Annova parametric test followed by Post Hoc using T-Test.
Results: There was no significant difference in the value of cell viability in the administration of hydraulic cement dicalcium silicate mixture of eggshell calcium and rice husk silica at various concentrations (1:1, 1:2, 1:4) against NIH3T3 fibroblast cells at 24 hours of observation, with a mean the highest viability value at a concentration of 1:4. At 48 hours of observation, there was a significant difference in the value of cell viability in the administration of dicalcium silicate hydraulic cement, a mixture of eggshell calcium and rice husk silica at various concentrations (1:1, 1:2, 1:4) to NIH3T3 fibroblast cells, with the highest mean viability value. treatment group at a concentration of 1:4.
Conclusion : Dicalcium silicate hydraulic cement mixed with eggshell calcium and rice husk silica in various concentrations (1:1,1:2,1:4) did not have a cytotoxic effect on NIH3T3 fibroblast cells at 24 hours and 48 hours. The highest NIH3T3 fibroblast cell viability value at 24 hours and 48 hours was observed at a concentration of 1:4."
Jakarta: Fakultas Kedokteran Gigi Universitas Indonesia, 2022
TA-pdf
UI - Tugas Akhir  Universitas Indonesia Library
<<   1 2 3 4 5 6 7 8 9 10   >>