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"Membran polipropilen adalah membran mikrofiltrasi dengan sifat hidrofobik yaitu takut dengan air. Untuk menghasilkan kinerja yang baik maka membran ini harus diubah menjadi hidrofilik dengan merendamnya dalam propan. Selain itu untuk mendapatkan kinerja membran yang optimum maka dibutuhkan kondisi operasi yang optimum. Dengan tekanan yang tinggi akan dihasilkan fluks atau jumlah penneat yang tinggi namun kemumian yang rendah karena menurunnya selektivitas membran.Untuk mengatasi masalah utama dalam proses yaitu laju fouling dan polarisasi konsentrasi sorta tluks yang rendah perlu ditentukan desain alat pross mikrofiltrasi yang tepat Serta tekanan dan waktu perendaman yang optimum untuk digunakan dalam proses pemurnian air danau dengan teknologi membran menggunakan membran polipropilen hollow fiber sehingga diharapkan fluks membran dan faktor separasi bemilai tinggi.Sistem proses mikrofiltrasi yang dipilih adalah Sistem resirkulasi untuk mengurangi efek laju fouling dan polarisasi konsentrasi yang tinggi, modul ho/low fiber untuk meningkatkan fluks pemmeat dengan luas permukaan uang besar dan aliran cross flow untuk penyapuan akumulasi zat terlarut pada permukaan membran dan mencegah fouling serta polarisasi konsentrasi.Hasil penelitian menunjukkan bahwa semakin lama waktu perendaman maka semakin turun fluks permeat namun persen rejksi semakin meningkat. Semakin tinggi tekanan maka Huks permeat bertambah narnun person rejeksi menurun. Waktu perendaman membran dalam propanol yang optimum adalah I0 menit. Sedangkan tekanan optimum yang dipilih yaitu 0.1316 bar untuk menghasilkan fluks yang tinggi namun persen rejeksi yang cukup baik."

"Telah dilakukan modifikasi serat polipropilen dengan asam akrilat supaya dapat dipergunakan untuk penukar kation. Penelitian ini bertujuan untuk mendapatkan serat yang dapat menukar ion logam dalam larutan ;dengan kapasitas tinggi.Kopolimerisasi cangkok asam akrilat pada serat polipropilen dilakukan dengan metode peroksidasi menggunakan sinar dari sumber Co-60. Pengaruh beberapa faktor terhadap kadar pencangkokan dipelajari dengan memvariasikan dosis total iradiasil, temperatur dan waktu pencangkokan serta konsentrasi monomer. Variasi laju dosis dilakukan untuk mengetahui kecepatan pencangkokan. Terjadinya pencangkokan asam akrilat pada serat polipropilen diamati pada spektrum infra merah, dan kestabilan termal serat polipropilen sebelum dan sesudah pencangkokan (PP-g-AAc) diamati dengan Thermogravimetric Analysis (TGA). Rapasitas penukaran serat PP-g-AAc terhadap ion logam dalam larutan diperiksa dengan Atomic Absorption Spectrofotometer (AAS).Hasil yang diperoleh menunjukkan bahwa makin tinggi dosis total dan konsentrasi monomer makin tinggi kadar pencangkokan. Dari variasi temperatur dan waktu pencangkokan diperoleh energi pengaktivan pencangkokan asam akrilat pada serat polipropilen sebesar 5,031 kcal/mol. Pengamatan terhadap hubungan laju dosis dengan kecepatan pencangkokan diperoleh persamaan RP = C I0,8 yang berarti pada reaksi pencangkokan di samping terjadi kopolimer cangkok terjadi pula homopolimer asampoll akrilat. Pengamatan pada spektra infra merah membuktikan terjadinya pencangkokan pada bagian amorf serat. Serat PP-g-AAc yang dihasilkan mempunyai kapasitas penukaran untuk ion Cu2+ adalah sebesar 3,14 mek/g.

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Graft copolymerization of acrylic acid onto polypropylene fiber (PP) has been studied by preirradiation technique using co" gamma rays source. The preirradiated PP was treated with acrylic acid solution and heated at various temperature and period under nitrogen atmosphere. The percentage of grafting was determined and evaluated as function of total dose, reaction time, temperature and monomer concentration. The rate of grafting was studied as the function of dose rate. The grafted PP was characterized by IR spectroscopy TGA (Thermogravimetry Analysis) and the exchange capacity towards Cu(II).

From the results the activation energy calculated is 5,031 kcal/mol. The rate of grafting follow the equation of Rp = CI0'8 which is indicate that the grafting mechanism should through bimolecular mechanism. IR spectra shows that the monomer grafted on the amorf part of PP. The exchange capacity of PP-g-AAc prepared for Cu(II) is 3,14 meq/g.;Graft copolymerization of acrylic acid onto polypropylene fiber (PP) has been studied by preirradiation technique using co" gamma rays source. The preirradiated PP was treated with acrylic acid solution and heated at various temperature and period under nitrogen atmosphere. The percentage of grafting was determined and evaluated as function of total dose, reaction time, temperature and monomer concentration. The rate of grafting was studied as the function of dose rate. The grafted PP was characterized by IR spectroscopy TGA (Thermogravimetry Analysis) and the exchange capacity towards Cu(II).

From the results the activation energy calculated is 5,031 kcal/mol. The rate of grafting follow the equation of Rp = CI0'8 which is indicate that the grafting mechanism should through bimolecular mechanism. IR spectra shows that the monomer grafted on the amorf part of PP. The exchange capacity of PP-g-AAc prepared for Cu(II) is 3,14 meq/g."

"Penelitian fotodegradasi pada polipropilen dilakukan pada sampel polipropilen tape yang dikenai radiasi UV dari sinar matahari dan dari alat xenotest. Penelitian dilakukan di Pulogadung pada Nopember 1996 hingga pertengahan Juni 1997. Xenotest 450 dioperasikan pada suhu 55 ± 2° C, relatif humidity 55 ± 5 %, hujan 18 menit, kering 102 menit. Variasi penambahan penstabil UV adalah 0 %, 0,05 %, 0,075 %. Sampel yang telah mengalami radiasi UV kemudian dianalisa tenacity, breaking elongation, spektrum ultra violet dan spektrum infra merahnya.Hasil yang diperoleh menunjukkan bahwa radiasi UV menyebabkan penurunan tenacity dan breaking elongation. Tenacity dan breaking elongation menurun sebanding dengan bertambahnya waktu radiasi. Penurunan tenacity dan breaking elongation ini dihambat dengan penambahan penstabil UV ke dalam polipropilen. Dengan semakin besarnya kandungan penstabil UV dalam polipropilen maka penurunan tenacity dan breaking elongation semakin dihambat. Dari spektrum infra merah pada polipropilen yang mengalami degradasi terjadi peningkatan serapan gugus karbonil pada bilangan gelombang 1825-1675 cm-1. Dari hasil spektrum ultra violet dapat dikatakan bahwa penstabil UV berfungsi sebagai penangkap radikal bebas yaitu radikal nitroksil menangkap radikal alkil membentuk hidroksilamin ether."

"Penelitian mengenai nanokomposit polimer telah menjadi penelitian yang banyak dilakukan dalam ilmu kimia polimer dan material selama belakangan ini. Telah berhasil dilakukan fabrikasi nanokomposit dengan matriks polipropilen dan lempung Pacitan sebagai nanofiller dengan menggunakan metode melt intercalation. Campuran terdiri dari polipropilen (PP), organoclay dari Pacitan (OCP), maleicanhydride (MA) dan diphenylamine (DPA). Struktur nanokomposit dikarakterisasi menggunakan X-ray diffractometer (XRD) dan transmission electron microscopy (TEM). Hasilnya menunjukkan terjadinya interkalasi clay Pacitan yang menyebabkan pelebaran jarak galeri lapisan silikat. Uji mekanik menunjukkan nanokomposit memiliki modulus tarik dan lentur lebih tinggi, tapi kekuatan tarik dan lentur lebih rendah dibandingkan PP-OCP0 dan harga literatur PP murni. Modulus tarik yang paling tinggi dimiliki oleh nanokomposit dengan kandungan organoclay sebanyak 7 wt%. Sifat termal PP-OCP0 dan PP-OCP7 diuji menggunakan alat Heat deflection temperature (HDT). Hasilnya menujukkan bahwa nilai HDT PP-OCP7 lebih rendah dari nilai HDT PP-OCP0.

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The study of polymer nanocomposites has been an active research field in polymer chemistry and materials science for the past decade. Nanocomposites which consist of polypropylene as matrix and Pacitan clay nanofiller have been successfully prepared by a melt intercalation method. The compound consisted of polypropylene (PP), Pacitan organoclay (OCP), maleicanhydride (MA), and diphenylamine (DPA). The structure of nanocomposites was investigated using an X-ray diffractometer (XRD) and transmission electron microscopy (TEM). The results show that an intercalation of silicate layers was occurred. The intercalation caused the silicate layer distance expansed and PP was able to move into the gallery. The results of mechanical test show that the nanocomposites have higher tensile and flexural moduli, but lower tensile and flexural strengths compared to PP-OCP0 and theoretical value of pristine PP. The PP-OCP7 sample has best mechanical properties. Sample of PP-OCP0 and PP-OCP7 were thermal tested by using a heat deflection temperature (HDT) machine. The HDT results show that PP-OCP7 has a lower HDT value than the PP-OCP0."

"Penelitian ini menyajikan model tegangan dan regangan dalam tekan pada spesimen beton terkekang dan tidak terkekang di dalam tekan yang menggunakan plastik Polypropilene sebagai pengganti agregat kasar. Hasil test tekan pada berbagai spesimen kolom pendek akan dikaji dan di analisa pada karakteristik tegangan-regangan, efek dari penulangan kekangan, dan peningkatan kemampuan gaya tekannya. Berdasarkan hasil test, tulangan kekang meningkatkan kuat tekan, serta daktilitas penampang. Identifikasi parametrik terhadap berbagai persamaan umum dari beton normal yang sudah ada digunakan terhadap hasil eksperimen untuk mendapatkan nilai parameter baru koefisien kekangan  k1 dan k2 yang sesuai untuk beton ringan. Diagram tegangan-regangan untuk spesimen beton ringan kolom lingkaran dan persegi dari hasil eksperimen dibandingkan dengan diagram tegangan-regangan untuk beton normal yang umum dipakai, hasilnya menunjukkan kesesuaian yang baik.

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Plastic production in the world ramped up to 322 million tons annual in 2015 with growth rate of 8.4% annually resulting large amount of plastic waste in nature. These plastic wastes are almost non-degradable in nature and polluting the environment in land and the sea. The use of recycled plastic aggregate for coarse aggregate in concrete is part of efforts to reduce environmental pollution by processing plastic grain in to coarse aggregate to substitute nature aggregate for light concrete. This study presents the analysis of concrete stress and strain model under compression of unconfined and confined concrete using Polypropilene plastic as substitution for coarse aggregate. To improve bonding between plastic aggregate and cement paste, this plastic aggregate is then coated with sands by placing and mixing the plastic aggregate with sands into a heater rotating cylinder. Test results of various specimens of short column will be reviewed and analysed in the stress and strain characteristics, effect of steel confinement, and performance improvement in compression. Based on experiment results, steel confinement increases compressive strength and ductility of the section. Parametric identification on established stress-strain model for normal concrete is used on the experimental results to obtain the new parameter values for confinement coefficient k1 and k2 that are suitable for this lightweight concrete. The stress-strain diagram for lightweight concrete of cylinder and square column specimen as resulted from experiment compared to the established stress-strain diagram used for normal concrete, the result indicates good agreement."

"[Polipropilena (PP) kopolimer impak merupakan salah satu jenis PP yangcukup banyak digunakan. PP kopolimer impak dibuat dengan penambahan etilena yang mengakibatkan penurunan kristalinitas PP. Usaha yang dilakukan untuk memperbaiki sifat kristalinitas PP yaitu dengan menambahkan agen nukleasi. Pada penelitian ini PP ditambahkan agen nukleasi serat ijuk yang mendapatkan perlakuan alkali, dilanjutkan dengan oksidasi menggunakan katalis yang bertujuan untuk mempercepat waktu kristalisasi PP. Serat ijuk ditambahkan sebanyak 10% volum. Morfologi, kandungan kimia dan kristalinitas serat ijuk dikarakterisasi dengan menggunakan FESEM (Field Emission Scanning Electron Microscope), FTIR (Fourier Transmission Infra Red), XRD (X-Ray Diffraction). Terbukti bahwa telah terjadi perubahan diameter dan morfologi serat ijuk menjadi mikrofibril setelah perlakuan alkali yang dilanjutkan dengan oksidasi menggunakan katalis. Hal tersebut menunjukkan telah terjadi penggerusan permukaan serat ijuk yaitu dengan menurunnya kadar lignin dan hemiselulosa yang merupakan pengikat antara lignin dan selulosa. Hasil karakterisasi XRD menunjukkan kristalinitas serat ijuk yang tidak diberi perlakuan adalah 42% sedangkan yang mendapat perlakuan NaOH 2% selama 1 jam dilanjutkan oksidasi menggunakan NaClO 5% selama 5 jam dan katalis KMnO4 0,01 N selama 15 menit menunjukkan kristalinitas sebesar 60,75%. Untuk mengerahuiefek serat ijuk sebagai agen nukleasi dilakukan uji DSC (Differential Scanning Calorimetry) pada sampel campuran PP-serat ijuk. Hasil DSC menunjukkan ada perubahan kecepatan kristalisasi PP-serat ijuk yang menunjukkan efek serat ijuk sebagai agen nukleasi. Pada kecepatan pendinginan 10 ° C/menit, PP murni memiliki waktu kristalisasi 1,2 detik, PP-serat tanpa perlakuan memiliki waktu kristalisasi 1 detik sedangkan PP-serat ijuk dengan perlakuan NaOH 2% selama 1 jam dilanjutkan oksidasi menggunakan NaClO 5% selama 5 jam dan katalisKMnO4 0,01 N selama 15 menit memiliki waktu kristalisasi 0,9 detik.;Polypropylene (PP) copolymer impact is one type of PP is quite widely used. PP impact copolymer is made by adding ethylene which resulted in a decrease in crystallinity PP. Efforts are being made to improve the properties of PP crystallinity by adding a nucleating agent. In this study PP nucleating agent added “Ijuk” fibers that get alkali treatment, followed by oxidation using a catalyst which aims to accelerate the crystallization of PP time. “Ijuk” fibers was added as much as 10% volume. Morphology, chemistry and crystallinity of “Ijuk”fibers were characterized by using FESEM (Field Emission Scanning Electron Microscope), FTIR (Fourier Transmission Infra Red), XRD (X-Ray Diffraction). It was proved that there has been a change in fiber diameter and morphology of fibers into microfibrils after alkali treatment followed by oxidation using a catalyst. It showed that there has been annihilation of surface fibers with reduced levels of lignin and hemicellulose which is a binder between lignin and cellulose. XRD characterization result indicated the fiber crystallinity untreated fibers was 42% while with treatment 2% NaOH for 1 hour followed oxidation using NaClO 5% for 5 hours and the catalyst KMnO4 0.01 N for 15 minutes showed crystallinity of 60.75%. To determine “Ijuk” fiber as nucleating agents, the sample of PP-fiber mixture was tested by DSC (Differential Scanning Calorimetry). DSC results showed change in rate of crystallization of PP-fiber fibers that indicate the effects of “Ijuk” fiber as a nucleating agent. In the cooling rate of 10 ° C / min, pure PP has a crystallization time of 1.2 seconds, the PPfibers without treatment had a crystallization time of 1 second while the PP-fiber fibers with 2% NaOH treatment for 1 hour followed oxidation using NaClO 5% for 5 hour and 0.01 N KMnO4 catalyst for 15 minutes had a crystallization time of 0.9 seconds., Polypropylene (PP) copolymer impact is one type of PP is quite widelyused. PP impact copolymer is made by adding ethylene which resulted in adecrease in crystallinity PP. Efforts are being made to improve the properties ofPP crystallinity by adding a nucleating agent. In this study PP nucleating agentadded “Ijuk” fibers that get alkali treatment, followed by oxidation using acatalyst which aims to accelerate the crystallization of PP time. “Ijuk” fibers wasadded as much as 10% volume. Morphology, chemistry and crystallinity of “Ijuk”fibers were characterized by using FESEM (Field Emission Scanning ElectronMicroscope), FTIR (Fourier Transmission Infra Red), XRD (X-Ray Diffraction). Itwas proved that there has been a change in fiber diameter and morphology offibers into microfibrils after alkali treatment followed by oxidation using acatalyst. It showed that there has been annihilation of surface fibers with reducedlevels of lignin and hemicellulose which is a binder between lignin and cellulose.XRD characterization result indicated the fiber crystallinity untreated fibers was42% while with treatment 2% NaOH for 1 hour followed oxidation using NaClO5% for 5 hours and the catalyst KMnO4 0.01 N for 15 minutes showedcrystallinity of 60.75%. To determine “Ijuk” fiber as nucleating agents, thesample of PP-fiber mixture was tested by DSC (Differential ScanningCalorimetry). DSC results showed change in rate of crystallization of PP-fiberfibers that indicate the effects of “Ijuk” fiber as a nucleating agent. In the coolingrate of 10 ° C / min, pure PP has a crystallization time of 1.2 seconds, the PPfiberswithout treatment had a crystallization time of 1 second while the PP-fiberfibers with 2% NaOH treatment for 1 hour followed oxidation using NaClO 5%for 5 hour and 0.01 N KMnO4 catalyst for 15 minutes had a crystallization time of0.9 seconds.]"

"Polipropilena (PP) merupakan polimer termoplastik yang banyak digunakan. PP memiliki densitas yang rendah, mudah diproses, dapat didaur ulang, dan relatif murah, tetapi kekuatan tariknya rendah. Penggabungan PP dengan serat kenaf dapat meningkatkan sifat mekanik PP. Namun, PP dan serat kenaf memiliki kompatibilitas yang rendah. Oleh karena itu, serat kenaf diberi perlakuan pemutihan dengan NaClO 1% selama 2 jam pada temperatur ruang. Serat dikarakterisasi dengan FTIR, FESEM, dan uji tarik. Pemutihan menurunkan kandungan hemiselulosa, lignin, dan zat pengotor pada permukaan serat serta meningkatkan kekuatan tarik serat. Proses pencampuran PP dan serat kenaf dilakukan dengan metode hot melt mixing. Pencampuran dilakukan dengan komposisi serat 5% hingga 25% fraksi massa, temperatur 170oC hingga 190oC, dan waktu 10 menit hingga 20 menit. Komposit dikarakterisasi dengan FESEM, uji tarik, dan STA. Penambahan serat 5% fraksi massa menghasilkan komposit dengan kekuatan tarik, kristalinitas, dan kestabilan termal yang paling tinggi. Temperatur pencampuran 190oC menghasilkan komposit dengan kekuatan tarik, kristalinitas, dan kestabilan termal yang paling tinggi. Waktu pencampuran 20 menit menghasilkan komposit dengan kekuatan tarik paling tinggi.

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PP is a thermoplastic polymer which is widely used. PP has low density, easily processed, can be recycled, and relatively inexpensive, but has low tensile strength. Synthesis PP with kenaf fiber can improve the mechanical properties of PP. However, PP and kenaf fiber have low compatibility. Therefore, kenaf fiber treated by bleaching with NaClO 1% for 2 hours in room temperature. Fiber characterized by FTIR, FESEM, and tensile test. Bleaching reduces hemicellulose, lignin, and impurities on the fiber surface and increase the tensile strength of fiber. PP and kenaf fiber mixing is done by hot melt mixing method. Mixing is done with fiber composition of 5% to 25% mass fraction, temperature of 170oC to 190oC, and time of 10 minutes to 20 minutes. Composites characterized by FESEM, tensile test, and STA. The addition 5% mass fraction of fiber results a composite with the highest tensile strength, crystallinity, and thermal stability. Mixing temperature of 190oC results a composite with the highest tensile strength, crystallinity, and thermal stability. Mixing time of 20 minutes results a composite with the highest tensile strength."

"[Pada penelitian ini, serat ijuk dihancurkan dan diayak ukuran 40 # setelah itu serat ijuk diberi perlakuan kimia dengan NaOH 2 % selama 1 jam, KMnO4 0,1 N selama 15 menit, dan NaClO 5 % selama 5 jam dengan tujuan mendapatkan selulosa kristalin. Setelah itu dilakukan proses pencampuran kering (hotmelt mixing) antara polipropilen dengan serat ijuk hasil perlakuan kimia dengan 7,5 % volum serat ijuk terhadap polipropilen dengan variabel temperatur 160°C, 165°C, dan 170°C dan variabel waktu pencampuran 15 menit dan 20 menit. Setelah itu dilakukan pengujian uji FTIR buat serat, sedangan buat komposit adalah uji tarik, uji STA, uji XRD, dan uji FE-SEM hal ini dilakukan untuk mendapatkan sifat kristalinitas dan mekanik dari komposit polipropilen ini. Hasil penelitian menunjukkan bahwa serat ijuk hasil perlakuaan lebih kristalin dari pada serat ijuk tanpa perlakukan, polipropilen dengan serat ijuk hasil perlakuaan kimia cukup kompatibel terhadap polipropilen, dari penelitian didapatkan sifat kristalinitas terbaik pada variabel 165°C selama 20 menit. Dan yang memiliki sifat kekuatan tarik paling baik adalah variabel 170°C selama 20 menit, sedangkan yang memiliki % elongasi paling baik adalah dengan variabel 160°C 20 menit.

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In this work, palm fiber crushed and sieved size 40 # after the palm fiber chemically treated with 2% NaOH for 1 hour, 0.1 N KMnO4 for 15 minutes, and 5% NaClO for 5 hours in order to obtain crystalline cellulose. Once that is done the dry mixing (hotmelt mixing) between polypropylene and palm fiber chemical treatment results with 7.5% volume of the palm fiber and polypropylene with a variable temperature of 160°C, 165°C and 170°C and a variable time mixing 15 minutes and 20 minutes. After it was examined FTIR test for fiber, while the composite is made tensile test, STA test, XRD test and FE-SEM test this is done to obtain crystallinity and mechanical properties of polypropylene composites this. The results show that fiber perlakuaan results more crystalline fibers than untreated palm fiber, polypropylene and palm fiber chemistry results treatment compatible enough to polypropylene, crystallinity of the research showed the best properties on the variable 165 ° C for 20 minutes. And who has the most excellent tensile strength properties are variable 170 ° C for 20 minutes, while the best of % elongation is at a variable 160 ° C 20 minutes.;In this work, palm fiber crushed and sieved size 40 # after the palm fiber chemically treated with 2% NaOH for 1 hour, 0.1 N KMnO4 for 15 minutes, and 5% NaClO for 5 hours in order to obtain crystalline cellulose. Once that is done the dry mixing (hotmelt mixing) between polypropylene and palm fiber chemical treatment results with 7.5% volume of the palm fiber and polypropylene with a variable temperature of 160°C, 165°C and 170°C and a variable time mixing 15 minutes and 20 minutes. After it was examined FTIR test for fiber, while the composite is made tensile test, STA test, XRD test and FE-SEM test this is done to obtain crystallinity and mechanical properties of polypropylene composites this. The results show that fiber perlakuaan results more crystalline fibers than untreated palm fiber, polypropylene and palm fiber chemistry results treatment compatible enough to polypropylene, crystallinity of the research showed the best properties on the variable 165 ° C for 20 minutes. And who has the most excellent tensile strength properties are variable 170 ° C for 20 minutes, while the best of % elongation is at a variable 160 ° C 20 minutes.;In this work, palm fiber crushed and sieved size 40 # after the palm fiber chemically treated with 2% NaOH for 1 hour, 0.1 N KMnO4 for 15 minutes, and 5% NaClO for 5 hours in order to obtain crystalline cellulose. Once that is done the dry mixing (hotmelt mixing) between polypropylene and palm fiber chemical treatment results with 7.5% volume of the palm fiber and polypropylene with a variable temperature of 160°C, 165°C and 170°C and a variable time mixing 15 minutes and 20 minutes. After it was examined FTIR test for fiber, while the composite is made tensile test, STA test, XRD test and FE-SEM test this is done to obtain crystallinity and mechanical properties of polypropylene composites this. The results show that fiber perlakuaan results more crystalline fibers than untreated palm fiber, polypropylene and palm fiber chemistry results treatment compatible enough to polypropylene, crystallinity of the research showed the best properties on the variable 165 ° C for 20 minutes. And who has the most excellent tensile strength properties are variable 170 ° C for 20 minutes, while the best of % elongation is at a variable 160 ° C 20 minutes.;In this work, palm fiber crushed and sieved size 40 # after the palm fiber chemically treated with 2% NaOH for 1 hour, 0.1 N KMnO4 for 15 minutes, and 5% NaClO for 5 hours in order to obtain crystalline cellulose. Once that is done the dry mixing (hotmelt mixing) between polypropylene and palm fiber chemical treatment results with 7.5% volume of the palm fiber and polypropylene with a variable temperature of 160°C, 165°C and 170°C and a variable time mixing 15 minutes and 20 minutes. After it was examined FTIR test for fiber, while the composite is made tensile test, STA test, XRD test and FE-SEM test this is done to obtain crystallinity and mechanical properties of polypropylene composites this. The results show that fiber perlakuaan results more crystalline fibers than untreated palm fiber, polypropylene and palm fiber chemistry results treatment compatible enough to polypropylene, crystallinity of the research showed the best properties on the variable 165 ° C for 20 minutes. And who has the most excellent tensile strength properties are variable 170 ° C for 20 minutes, while the best of % elongation is at a variable 160 ° C 20 minutes.;In this work, palm fiber crushed and sieved size 40 # after the palm fiber chemically treated with 2% NaOH for 1 hour, 0.1 N KMnO4 for 15 minutes, and 5% NaClO for 5 hours in order to obtain crystalline cellulose. Once that is done the dry mixing (hotmelt mixing) between polypropylene and palm fiber chemical treatment results with 7.5% volume of the palm fiber and polypropylene with a variable temperature of 160°C, 165°C and 170°C and a variable time mixing 15 minutes and 20 minutes. After it was examined FTIR test for fiber, while the composite is made tensile test, STA test, XRD test and FE-SEM test this is done to obtain crystallinity and mechanical properties of polypropylene composites this. The results show that fiber perlakuaan results more crystalline fibers than untreated palm fiber, polypropylene and palm fiber chemistry results treatment compatible enough to polypropylene, crystallinity of the research showed the best properties on the variable 165 ° C for 20 minutes. And who has the most excellent tensile strength properties are variable 170 ° C for 20 minutes, while the best of % elongation is at a variable 160 ° C 20 minutes., In this work, palm fiber crushed and sieved size 40 # after the palm fiber chemically treated with 2% NaOH for 1 hour, 0.1 N KMnO4 for 15 minutes, and 5% NaClO for 5 hours in order to obtain crystalline cellulose. Once that is done the dry mixing (hotmelt mixing) between polypropylene and palm fiber chemical treatment results with 7.5% volume of the palm fiber and polypropylene with a variable temperature of 160°C, 165°C and 170°C and a variable time mixing 15 minutes and 20 minutes. After it was examined FTIR test for fiber, while the composite is made tensile test, STA test, XRD test and FE-SEM test this is done to obtain crystallinity and mechanical properties of polypropylene composites this. The results show that fiber perlakuaan results more crystalline fibers than untreated palm fiber, polypropylene and palm fiber chemistry results treatment compatible enough to polypropylene, crystallinity of the research showed the best properties on the variable 165 ° C for 20 minutes. And who has the most excellent tensile strength properties are variable 170 ° C for 20 minutes, while the best of % elongation is at a variable 160 ° C 20 minutes.]"

"Tesis ini membahas kemampuan mahasiswa magister Fakultas Teknik UI angkatan 2010 dalam mencari dan menggunakan software Abaqus secara efektif dalam konteks Simulasi Ikatan antar Material Polimer pada Proses Bi-Injection. Penelitian ini adalah penelitian kualitatif dengan simulasi software. Hasil penelitian menyarankan bahwa dalam proses bi-injection molding dengan material polypropylene perlu diperhatikan setting parameter temperature dalam proses bi-injection molding untuk mendukung keberhasilan ikatan antar material.

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The focus of this study is analysis bonding material polymer of bi-injection molding process. This research using Abaqus software for analysis the case and modeling it. The result of research give advices to setting temperature parameter to get better bonding of polypropylene in bi-injection molding process."