STUDY OF HYBRID FIBER REACTIVE POWDER CONCRETE CHARACTERISTICS WITH VARIATIONS OF MICRO POLYPROPYLENE FIBER AND STEEL FIBER CONTENT
The main principle in improving the performance of RPC is to use cement or pozzolanic material to strengthen the Interfacial Transition Zone (ITZ) between the mortar matrix and the fine aggregate by reducing the w/c ratio, eliminating coarse aggregate in the mixture, and application of heat durin...
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id-itb.:807532024-03-07T08:41:02ZSTUDY OF HYBRID FIBER REACTIVE POWDER CONCRETE CHARACTERISTICS WITH VARIATIONS OF MICRO POLYPROPYLENE FIBER AND STEEL FIBER CONTENT Trisakti Paiding Lewa, Shandy Teknik sipil Indonesia Theses Reactive Powder Concrete, Interfacial Transition Zone, Workabilty, Compressive Strength, Flexural Strength, Direct Tensile Strength, Fracture Energy INSTITUT TEKNOLOGI BANDUNG https://digilib.itb.ac.id/gdl/view/80753 The main principle in improving the performance of RPC is to use cement or pozzolanic material to strengthen the Interfacial Transition Zone (ITZ) between the mortar matrix and the fine aggregate by reducing the w/c ratio, eliminating coarse aggregate in the mixture, and application of heat during curing. However, by eliminating coarse aggregate in the RPC mixture, the interlocking effect does not occur which can dissipate the cracks that occur during failure. This can make RPC behavior very brittle. To replace the function of coarse aggregate in crack dissipation, the use of fiber is added to create a multiple crack bridging effect This study focuses on the effect of adding micro polypropylene fiber to the behavior of RPC mixtures containing 1% Steel Fiber. Variations in addition of micro polypropylene fiber ranged from 0.06% to 0.1% of the volume fraction. The tests carried out were fresh concrete tests (slump flow, J-Ring test, and slump loss) and hard concrete tests (Compressive Strength, Flexural Strength, Direct Tensile Strength, and Fracture Energy). The addition of steel fiber with a concentration of 1% can cause a decrease in workability. Mixtures containing 1% Steel Fiber and added Micro Polypropylene Fiber with a volume fraction of 0.06% - 0.1% can cause a significant decrease in workability due to a large aspect ratio and can cause additional friction in the mixture. The decrease caused by the addition of fiber ranged from 2.87% - 15.83%. The compressive strength of RPC did not increase significantly when added fiber to the mixed matrix. However, the application of Hot Water Treatment during the treatment process will increase the RPC compressive strength from 90.1 MPa to 114.5 MPa (2% - 19%). The increase due to the addition of micro polypropylene fiber (MPF) to the SF1 mixture increased the flexural strength by 7.16 MPa to 15.62MPa (42% - 59%) for Normal Curing and 6.33 MPa to 15.09 MPa (36% - 38%) for Hot Water Treatment. The increase due to the addition of MPF to the SF1 mixture increased the tensile strength by 1.95 MPa to 4.26 MPa (19% - 43%) for Normal Curing and 2.63 MPa to 4.87 MPa (7% - 44%) for Hot Water Treatment. Fracture energy also increases when MPF is added to SF1 by 0.149 N/mm to 2.33 N/mm (9 – 16 times) for Normal Curing and 0.153 N/mm up to 2.94 N/mm (15 – 19 times) for Hot Water Treatment. text |
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Teknik sipil Trisakti Paiding Lewa, Shandy STUDY OF HYBRID FIBER REACTIVE POWDER CONCRETE CHARACTERISTICS WITH VARIATIONS OF MICRO POLYPROPYLENE FIBER AND STEEL FIBER CONTENT |
| description |
The main principle in improving the performance of RPC is to use cement or pozzolanic
material to strengthen the Interfacial Transition Zone (ITZ) between the mortar matrix
and the fine aggregate by reducing the w/c ratio, eliminating coarse aggregate in the
mixture, and application of heat during curing. However, by eliminating coarse
aggregate in the RPC mixture, the interlocking effect does not occur which can dissipate
the cracks that occur during failure. This can make RPC behavior very brittle. To
replace the function of coarse aggregate in crack dissipation, the use of fiber is added
to create a multiple crack bridging effect This study focuses on the effect of adding
micro polypropylene fiber to the behavior of RPC mixtures containing 1% Steel Fiber.
Variations in addition of micro polypropylene fiber ranged from 0.06% to 0.1% of the
volume fraction. The tests carried out were fresh concrete tests (slump flow, J-Ring test,
and slump loss) and hard concrete tests (Compressive Strength, Flexural Strength,
Direct Tensile Strength, and Fracture Energy).
The addition of steel fiber with a concentration of 1% can cause a decrease in
workability. Mixtures containing 1% Steel Fiber and added Micro Polypropylene Fiber
with a volume fraction of 0.06% - 0.1% can cause a significant decrease in workability
due to a large aspect ratio and can cause additional friction in the mixture. The
decrease caused by the addition of fiber ranged from 2.87% - 15.83%.
The compressive strength of RPC did not increase significantly when added fiber to the
mixed matrix. However, the application of Hot Water Treatment during the treatment
process will increase the RPC compressive strength from 90.1 MPa to 114.5 MPa (2%
- 19%). The increase due to the addition of micro polypropylene fiber (MPF) to the SF1
mixture increased the flexural strength by 7.16 MPa to 15.62MPa (42% - 59%) for
Normal Curing and 6.33 MPa to 15.09 MPa (36% - 38%) for Hot Water Treatment.
The increase due to the addition of MPF to the SF1 mixture increased the tensile
strength by 1.95 MPa to 4.26 MPa (19% - 43%) for Normal Curing and 2.63 MPa to
4.87 MPa (7% - 44%) for Hot Water Treatment. Fracture energy also increases when
MPF is added to SF1 by 0.149 N/mm to 2.33 N/mm (9 – 16 times) for Normal Curing
and 0.153 N/mm up to 2.94 N/mm (15 – 19 times) for Hot Water Treatment. |
| format |
Theses |
| author |
Trisakti Paiding Lewa, Shandy |
| author_facet |
Trisakti Paiding Lewa, Shandy |
| author_sort |
Trisakti Paiding Lewa, Shandy |
| title |
STUDY OF HYBRID FIBER REACTIVE POWDER CONCRETE CHARACTERISTICS WITH VARIATIONS OF MICRO POLYPROPYLENE FIBER AND STEEL FIBER CONTENT |
| title_short |
STUDY OF HYBRID FIBER REACTIVE POWDER CONCRETE CHARACTERISTICS WITH VARIATIONS OF MICRO POLYPROPYLENE FIBER AND STEEL FIBER CONTENT |
| title_full |
STUDY OF HYBRID FIBER REACTIVE POWDER CONCRETE CHARACTERISTICS WITH VARIATIONS OF MICRO POLYPROPYLENE FIBER AND STEEL FIBER CONTENT |
| title_fullStr |
STUDY OF HYBRID FIBER REACTIVE POWDER CONCRETE CHARACTERISTICS WITH VARIATIONS OF MICRO POLYPROPYLENE FIBER AND STEEL FIBER CONTENT |
| title_full_unstemmed |
STUDY OF HYBRID FIBER REACTIVE POWDER CONCRETE CHARACTERISTICS WITH VARIATIONS OF MICRO POLYPROPYLENE FIBER AND STEEL FIBER CONTENT |
| title_sort |
study of hybrid fiber reactive powder concrete characteristics with variations of micro polypropylene fiber and steel fiber content |
| url |
https://digilib.itb.ac.id/gdl/view/80753 |
| _version_ |
1822009278567809024 |