ICEI - 2023 (Volume 11 – Issue 05)

Influence Of Mineral Admixtures In Cement Concrete To Develop Light Weight Structures

DOI : 10.17577/IJERTCONV11IS05093

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Maruthi T, Nayana P, Rajashekar T D, Sameeksha S R, Ramya R H, 2023, Influence Of Mineral Admixtures In Cement Concrete To Develop Light Weight Structures, INTERNATIONAL JOURNAL OF ENGINEERING RESEARCH & TECHNOLOGY (IJERT) Volume 11, Issue 05 (ICEI – 2023),

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Influence Of Mineral Admixtures In Cement Concrete To Develop Light Weight Structures

Maruthi T

Department of Civil Engineering Jain Institute of Technology, Davanagere

Karnataka, India

Nayana P Department of Civil Engineering

Jain Institute of Technology, Davanagere Karnataka, India

Sameeksha S R Department of Civil Engineering

Jain Institute of Technology, Davanagere Karnataka, India

Rajashekar T D Department of Civil Engineering

Jain Institute of Technology, Davanagere Karnataka, India

Ramya R H Department of Civil Engineering

Jain Institute of Technology, Davanagere Karnataka, India

Abstract. Concrete is second most important consumption in the world. Commonly concrete is composed with cement and fine aggregates and coarse aggregates.. In this study, We found that aluminium powder and betel nut fibre can be used as substitutes for cement and coarse aggregates in a strong concrete mix that is combined in a 1:3 ratio. We deduced from the aforementioned experimental checks and results that the best alternative to cement was concrete built with 0%, 0.25%, 0.50%, 0.75%, and 1.0% Aluminium Powder and 0.25%, 0.50% Betel Nut Fibre as additions. The Compressive Strength of Concrete Mixing of M1 to M5 For 0.25% of Betel Nut Fiber for 7,14, and 28 Days of Curing, In Which M3 Concrte Mix gives the Optiumum Percentage of 0.25% Betel Nut Fiber. And the compressive strength of Concrete Mixing of M6 to M10 For 0.5% of Betel Nut Fiber for 7,14, and 28 Days of Curing, In Which M8 Concrte Mix gives the Optiumum Percentage of 0.5% Betel Nut Fiber.

Keywords Aluminium powder, Optimum %,Betel nut fiber etc..,

  1. INTRODUCTION

    One of the most important components of construction materials is concrete. The concrete building industries are growing rapidly today. There has been an increase in demand for building structures, infrastructure, and airports globally in recent years. The development of lightweight concrete in the building industry has helped to solve various issues caused by the large dead load of conventional concrete. By boosting the mix volume and lowering the structure's dead load, lightweight concrete acts as an intensifying agent. Lightweight concrete has a lower weight than traditional concrete.

      1. Cement

        In this paper we have used cement OPC 43 Grade (Ultratech cement).

      2. Fine aggregates

        Fine aggregate is used 4.75 mm Indian standers sieve passed M-sand is used in the preparation of specimen.

      3. Aluminium powder

        Light-weight aerated concrete is produced by making LAC involves the addition of the gas-forming admixture like aluminium powder to a wet mortor mixture.

        Fig ; 1 Aluminium powder

      4. AGRO WSTE BETEL NUT(ARECA CATECHU) Due to different amounts of cellulose, hemicellulose, lign, and moisture, it was discovered that the maturity of the BNH fibre influences its thermal stability. The BNH fibres' length and diameter decreased and their density rose as the maturity of the fibre increased.

    Fig 2 Agro Waste Betel Nut

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  2. MATERIALS AND METHODOLOGY

    1. MATERIALS

      In this project, M-43 Grade concrete is given; the proportions for mixing are determined by the M-43 Grade mix design. This experimental investigation makes use of the materials listed. Binding materials

      • Cement

      • Aluminium powder

      • Fine Aggregate

      • Agro wste betel nut(areca catechu)

    2. METHODOLOGY

2.2.1 The construction process uses the following protocol.

Fig 3 flow chart

    1. Experimental studies

      1. Mixing scheme

        For this test, we used concrete of grade M-43. The blend layout is successfully completed as being consistent.

        Table 1: Betel Nut Fiber @0.25 Percent Used

        Table 2: Betel Nut Fiber @ 0.5 Percent Used

      2. Mixing of Concrete:

        Cement, sand, aluminium powder, rice husk ash, and betel nuts are precisely weighed before being dry-mixed to achieve a uniform tint. Before adding to the mixture, proper additive and cement mixing has been ensured. Once the ingredients have been dispersed evenly, the mix can be used. Water was added to the mixture, and thorough mixing was made.

        Fig 3 Mixing of Concrete

      3. Casting of Specimens

        The steam can only reach a maximum temperature of 72°C, and it can cure in regular quatar for 14 days. The specimen is then taken out of the water, dried for 24 hours, and cleaned (to remove surface moisture).11 to 14 hours of steam curing are spent at a proper humidity level of about 90%.Concrete can be preserved against moisture loss necessary for hydration and maintained within the specified temperature range via curing. A curing procedure entails keeping the concrete damp or moist until the concrete has fully hydrated and reached its strength.

        Fig 4 Curing of Concrete (Moulds)

      4. Specimen testing

The well-known checking out machine (UTM) exanimates the cubes after the last touch of a specific amount of curing time.

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Fig 5 Testing machine

RESULTS AND DISCUSSION

    1. TEST ON FRESH CONCRETE

      1. Slump Cone Test

      2. Vee Bee Consistometer

      3. Compaction Factor

      1. Slump Cone Test:

        Table 3: Slump cone test reading

      2. Vee Bee Consistometer Test

        Table 4: Vee-Bee test reading

      3. Compaction Factor Test

        Table 5: Compaction Factor Test

        TESTS ON FRESH CONCRETE

        1. Slump cone test

        2. Compaction factor test

        3. Vee-bee consistometer test

  1. Slump cone test

    Table 5: Slump cone test results

    % Replacement of Aluminum powder

    Slump value in mm

    0%

    15

    0.25%

    13

    0.50%

    12

    0.75%

    10

    1.0%

    9

  2. Compaction factor test

    Table 6: Compaction factor test results

    % Replacement of Aluminum powder

    Compaction factor test

    0%

    0.754

    0.25%

    0.741

    0.50%

    0.735

    0.75%

    0.731

    1.0%

    0.700

  3. Vee-Bee consistometer

    Table 7: Vee Bee consistometer test results

    % Replacement of Aluminum powder

    Vee bee degree in seconds

    0%

    35

    0.25%

    38

    0.50%

    40

    0.75%

    44

    1.0%

    47

    TESTS ON HARDEN CONCRETE

    Table 12: Compression test for 28 days of curing @

    Sl No.

    % Replacement of Aluminum powder

    Load in kN

    Compression strength in N/mm2

    Average strength in N/mm2

    M1

    0%

    1000

    44.44

    43.99

    1010

    44.88

    960

    42.66

    M2

    0.25%

    980

    43.55

    43.18

    970

    43.11

    965

    42.88

    M3

    0.5%

    1020

    45.33

    45.7

    1030

    45.77

    1035

    46.0

    M4

    0.75%

    900

    40.0

    41.11

    950

    42.22

    925

    41.11

    M5

    1%

    850

    37.77

    38.29

    860

    38.22

    875

    38.88

    0.25 Betel Nut Fiber

    535

    Graph 5: Graphical representation of compression strength test for 28 days of curing

    Table 13: Compression test for 28 days of curing

    Sl No.

    % Replacement of Aluminum powder

    Load in kN

    Compression strength in N/mm2

    Average strength in N/mm2

    M6

    0%

    1045

    46.44

    47.18

    1060

    47.11

    1080

    48.0

    M7

    0.25%

    1040

    46.22

    46.0

    1035

    46.0

    1020

    45.33

    M8

    0.5%

    1080

    48.0

    47.77

    1075

    47.77

    1070

    47.55

    M9

    0.75%

    950

    42.22

    42.0

    935

    41.55

    930

    41.33

    M10

    1%

    900

    40.0

    40.0

    910

    40.44

    890

    39.55

    @ 0.50 Betel Nut Fiber

    Table 18: split tensile strength test for 28 days of curing @ 0.25 Betel Nut Fiber

    Sl no.

    Concrete Mix

    Load (KN)

    Split tensile Strength(N/mm2)

    Average Strength in N/mm2

    1

    M1

    198

    3.98

    4.50

    190

    3.00

    210

    3.12

    2

    M3

    269

    3.56

    5.20

    272

    3.12

    282

    3.19

    Graph 11: Graphical representation of split tensile strength

    Table 19: split tensile strength test for 28 days of curing @ 0.50 Betel Nut Fiber

    Sl no.

    Concrete Mix

    Load (KN)

    Split tensile Strength(N/mm2)

    Average Strength in N/mm2

    1

    M1

    223

    3.98

    5.12

    230

    4.00

    350

    4.12

    2

    M7

    369

    4.56

    5.86

    372

    4.12

    382

    4.19

    Graph 6: Graphical representation of compression strength test for 28 days of curing

    TEST ON SPLIT TENSILE STRENGTH

    Graph 9: Graphical representation of split tensile strength

    Graph 12: Graphical representation of split tensile strength

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    TEST ON FLEXURAL STRENGTH

    Table 22: flexural strength test for 28 days of curing @ 0.25 Betel Nut Fiber

    Sl no.

    Concrete Mix

    Load (KN)

    Flexural Strength(N/mm2)

    Average Strength in N/mm2

    1

    M1

    198

    3.98

    4.2

    190

    3.00

    210

    3.12

    2

    M3

    269

    3.56

    5.45

    272

    3.12

    282

    3.19

    Graph 15: Graphical representation of flexural strength test

    Sl no.

    Concrete Mix

    Load (KN)

    Flexural Strength(N/mm2)

    Average Strength in N/mm2

    1

    M1

    128

    2.98

    4.45

    130

    3.00

    150

    3.12

    2

    M7

    169

    3.56

    5.45

    172

    3.12

    182

    3.19

    Table 23: flexural strength testfor 28 days of curing @ 0.50 Betel Nut Fiber

    CONCLUSION

    In this study, we found that aluminium powder and betel nut fibre can be used as alternatives to cement and coarse aggregates, respectively, to create a robust concrete mix in a 1:3 ratio. We learned from the aforementioned experimental checks and results that the best alternative to concrete was manufactured with 0.25,%0.5% betel nut fibre and 0.0%,0.25%,0.50%,0.75%,1.0% aluminium powder in place of cement.as supplements

    • At 28 days after curing, ordinary concrete has a compressive strength of 43.99 kN/m2. It was discovered that adding 0.25% of betel nut enhanced strength by 3.74 kN/m2 in the partially replaced combination aluminium powder and betel nut fibre.

    • At 28 days after curing, ordinary concrete has a compressive strength of 47.18 kN/m2. The combined aluminium powder and betel nut fibre with partial replacement yields a strength of 49.77 kN/m2 and a 5.20 increase for every 0.50% of betel nut.

    • At 28 days after curing, ordinary concrete has a split tensile strength of 4.50 kN/m2. The strength is enhanced by 12.7 percent for every 0.25% of betel nut in the partially replaced combination aluminium powder and betel nut fibre, which is attained at 5.20 kN/m2.

    • At 28 days after curing, ordinary concrete has a Split Tensile strength of 5.12 kN/m2. The combination partially replaced aluminium powder and betel nut fibre obtained 5.86 kN/m2 and found to have a 13.46 percent increase in strength.

    • At 28 days after curing, the flexural strength of the test conventional concrete is 5.45 kN/m2. 4.20 kN/m2 of strength from the partially replaced mixture of betel nut fibre and aluminium powder was also discovered, with the strength increasing by 18.34 for every 0.25 percent betel nut.

    • Conventional concrete has a flaw strength of

4.45 kN/m2@ after 28 days of curing. The combined aluminium powder and betel nut fibre that has been substituted in part is obtained at kN/m2, and it is also discovered that the strength increases by 0.5% for betel nut.

REFERENCE

Graph 16: Graphical representation of flexural strength test

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[2]Mr. Otomo Rachact (2019),"Partial Replacement of coarse aggregate with waste glass in concrete productionJournal of Mechanical and Civil engineering (IMCE- Volume-16 me 3.May-June-2019 , www.iojournals.org/.

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pornkasem.jon@kmutt.ac.th,Received 30January 2018;

Accepted 24 May 2018; Published 21 June 2018

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