Effect of Random Inclusion of Polypropylene Fibers on Strength Characteristics of Cohesive Soil

Abstract Effects of stabilization with cement on mechanical properties of cohesive soil - sandy- -silty clay. Ground improvement as a result of stabilization with cement has its impact on soft soils such as sandy clay in engineering constructions. Stabilized soils are also used in foundation design, where improvement of mechanical properties is needed. Because of these reasons, knowledge of physical and mechanical properties is needed. The relationship stress - strain of soils stabilized with cement is often unclear and strength characteristics need to be clear. In this paper results of physical and mechanical properties soil stabilized with cement are presented

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Improvement of strength characteristics for sandy soils by polypropylene fibers (PPF)

Journal of Physics Conference Series ◽

10.1088/1742-6596/1895/1/012016 ◽

2021 ◽

Vol 1895 (1) ◽

pp. 012016

Author(s):

Noor A Al-Saray ◽

Qassun S Shafiqu ◽

Mohammed A Ibrahim

Keyword(s):

Sandy Soils ◽

Strength Characteristics ◽

Polypropylene Fibers

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Deformation and strength characteristics of cohesive soil obtained by consolidated constant volume direct shear test.

Doboku Gakkai Ronbunshu ◽

10.2208/jscej.2001.673_15 ◽

2001 ◽

pp. 15-26

Author(s):

Toshihiro OGINO ◽

Toshiyuki MITACHI ◽

Satoru SHIBUYA ◽

Hiroshi OIKAWA

Keyword(s):

Direct Shear Test ◽

Shear Test ◽

Cohesive Soil ◽

Constant Volume ◽

Strength Characteristics ◽

Direct Shear ◽

Deformation And Strength Characteristics

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STRESS-STRAIN BEHAVIOR OF HIGH-STRENGTH CONCRETE REINFORCED WITH POLYPROPYLENE FIBERS

Problemy sovremennogo betona i zhelezobetona ◽

10.35579/2076-6033-2020-12-09 ◽

2020 ◽

Author(s):

Г.Д. Ляхевич ◽

В.А. Гречухин ◽

С. Мотамеди

Keyword(s):

Compressive Strength ◽

High Strength Concrete ◽

Polypropylene Fiber ◽

Three Dimensional ◽

High Strength ◽

Strength Characteristics ◽

Effect Of Temperature ◽

Polypropylene Fibers ◽

Strength Concrete ◽

Concrete Mix

Целью настоящего исследования является исследование влияния полипропиленовых волокон, вводимых в бетонную смесь, на прочностные характеристики и снижение эффекта взрывного откалывания в бетоне, при повышении температуры. Полипропиленовая фибраобразует в бетоне трехмерный армирующий каркас, который воспринимает растягивающие усилия. Ее применение повышает долговечность, снижает истираемость поверхности, повышает ударную вязкость, устраняет усадку, предупреждает образование трещин, повышает морозостойкость. Для приготовления бетонной смеси использовали следующие компоненты: цемент марки М-500, песок кварцевый, щебень, микрокремнезем, суперпластификатор, вода, полипропиленовая фибра. Водоцементное отношение в испытании составило от 0,23 до 0,32. С целью изучения влияния температуры на прочностные характеристики высокопрочного бетона приготовили 16 составов бетонной смеси. Образцы нагревали до температуры 800 °С при скорости нагрева около 20 °С в минуту. После достижения данной температуры образцы в течение 24 часов медленно остывали до комнатной температуры, после чего измерялось снижение их массы и остаточное сопротивление на сжатие. При нагревании образцов в интервале температур от 160 °С до 180 °С в бетоне с ППВ происходит образование каналов, по которым при дальнейшем нагревании выходит пар. Испытания показали, что в образцах с полипропиленовым волокном (ППВ) не наблюдается эффекта взрывного откалывания. Полипропиленовые волокна уменьшают потерю сопротивления, и устраняют хрупкое разрушение. В исследовании изучено влияние длины и количества ППВ на прочность бетона на сжатие. Использование полипропиленовых волокон повышает огнестойкость и хрупкость высокопрочного бетона, способствует его вязкому разрушению. Образцы бетона без ППВ после нагружения полностью разрушились, тогда, как образцы бетона с ППВ при аналогичной нагрузке сохранили свою геометрию. Введение волокна в высокопрочный бетон способствует повышению прочности на сжатие и термостойкости образцов. После расплавления волокон, образовались капилляры, через которые пар может выйти из массива бетона, предотвращая, таким образом, взрывное откалывание бетона. The purpose of this study is to study the effect of poly-propylene fibers introduced into the concrete mix on the strength characteristics and reduction of the effect of explosive chipping in concrete when the temperature increases. Polypropylene fiber forms a three-dimensional reinforcing frame in concrete that accepts tensile forces. Its use increases durability, reduces surface abrasion, increases impact strength, eliminates shrinkage, prevents the formation of cracks, and increases frost resistance. The following components were used to prepare the concrete mix: M-500 cement, quartz sand, crushed stone, microsilicon, superplasticizer, water, polypropylene fiber. The water-cement ratio in the test was from 0.23 to 0.32. In order to study the effect of temperature on the strength characteristics of high-strength concrete, 16 concrete mix compositions were prepared. The samples were heated to a temperature of 800 °C at a heating rate of about 20 °C per minute. After reaching this temperature, the samples were slowly cooled to room temperature for 24 hours, after which the decrease in their mass and residual compressive resistance were measured. When samples are heated in the temperature range from 160 °C to 180 °C in concrete with PPV, channels are formed through which steam escapes during further heating. Tests have shown that there is no explosive chipping effect in samples with polypropylene fiber (PPV). Polypropylene fibers reduce the loss of resistance, and eliminate brittle fracture. The study examined the effect of the length and amount of PPV on the compressive strength of concrete. The use of polypropylene fibers increases the fire resistance and brittleness of high-strength concrete, contributes to its viscous destruction. Samples of concrete without PPV after loading completely collapsed, while samples of concrete with PPV under a similar load retained their geometry. The introduction of fiber into high-strength concrete increases the compressive strength and heat resistance of samples. After melting the concrete, capillaries were formed through which steam can escape from the concrete mass, thus preventing explosive chipping of the concrete.

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Strength Characteristics of Cohesive Soil using Ricehusk Ash, Banana Fiber and Bamboo Fiber

International Journal of Engineering Research and ◽

10.17577/ijertv6is020297 ◽

2017 ◽

Vol V6 (02) ◽

Author(s):

Navami Chandran B ◽

Veena Vijayan L ◽

Keyword(s):

Cohesive Soil ◽

Bamboo Fiber ◽

Strength Characteristics ◽

Banana Fiber

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The Effect of the Type and Amount of Synthetic Fibers on the Effectiveness of Dispersed Reinforcement in Soil-Cements

Materials ◽

10.3390/ma13183917 ◽

2020 ◽

Vol 13 (18) ◽

pp. 3917

Author(s):

Krystian Brasse ◽

Tomasz Tracz ◽

Tomasz Zdeb

Keyword(s):

Cohesive Soil ◽

Modulus Of Rupture ◽

Polypropylene Fibers ◽

Cement Composites ◽

Test Results ◽

Bending Tests ◽

Synthetic Fibers ◽

Flexural Tensile Strength ◽

Soil Cement ◽

The Matrix

The paper deals with mechanical properties of soil-cement composites made with non-cohesive soil and reinforced with dispersed fibers. The research was carried out on the basis of three soil-cement matrices whose compositions varied in terms of the volumetric fraction of cement paste and the water-cement ratio. Two types of polypropylene fibers were used as dispersed reinforcement: single fibrillated-tapes polypropylene fibers (SFPF) and bundles of coiled fibrillated-tapes polypropylene fibers (BCFPF). The fibers varied in terms of their length and mass fraction. The objective of the study was to assess the effect of the addition of fibers to soil-cement composites on their flexural tensile strength and on their behavior in the post-critical state. The studies were carried out after 28 days of curing. Bending tests were carried out to determine post-critical stress values σCMODi, stress values at which the matrix is destroyed (limit of proportionality) σLOP, maximum stress values transferred by the fibers σMOR (modulus of rupture), and total fracture energy Gf,tot as well as compressive strength. The test results obtained, and their analysis, indicate the significant impact of the dispersed reinforcement used on the performance of such composites during bending.

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