ICEI - 2023 (Volume 11 – Issue 05)

Wollastonite Partial Replacement Of Cement : An Experimental Research

DOI : 10.17577/IJERTCONV11IS05070

Download Full-Text PDF Cite this Publication
Kiran Kumar M S, Sanjay H C, Sanjan K M, Rakshitha C, Yashaswini J, 2023, Wollastonite Partial Replacement Of Cement : An Experimental Research, INTERNATIONAL JOURNAL OF ENGINEERING RESEARCH & TECHNOLOGY (IJERT) Volume 11, Issue 05 (ICEI – 2023),

Text Only Version

Wollastonite Partial Replacement Of Cement : An Experimental Research

Wollastonite Partial Replacement of Cement

: An Experimental Research

Department of Civil Engineering, Jain institute of technology, Davangere, India

Abstract: Construction uses concrete because it is a strong and reliable binding substance. Cement production in India is second-to-none. The amount of raw materials needed to produce one tonne of cement is around 1.5 tonnes. Additional cementitious elements are utilised in the manufacturing of concrete in order to reduce the amount of cement required. One such naturally occurring mineral is wollastonite, which is produced when silica and limestone combine in hot mogmas. In the current work, concrete contains 0%, 5%, 10%, 15%, and 20% Wollastonite in place of cement. Wollastonite's impact on concrete's strength characteristics for the M30 grade mix is investigated. The Mix Design is determined using IS 10262:2019. To measure workability, the slump cone, compaction factor, and vee-bee consistometer are used. For various concrete mixtures. Strengths in compression, split tensile, and flexural are The outcomes of the various combination mixes are then contrasted with those of a standard concrete mix.

Keywords concrete, additional cementitious substance, wollastonite, workability, strengths in Compression, strengths in split tensile and strengths in flexural

  1. INTRODUCTION

    Water, aggregate, and cement make up the majority of concrete. After water, concrete is the second most consumed man-made resource worldwide. Concrete requires cement as a key component because it bonds the particles to create a sturdy building material. For each tonne of cement produced, raw materials are needed in the range of 1.5 tonnes. It causes environmental issues and emits 0.8 tonnes of CO2. In the manufacturing of concrete, additional cementitious ingredients are employed to cut down on cement use.

    Using additional cementitious substance and other: additives such as admixtures, minerals and fibres have made the research field active during last few decades. Concrete's weakness in tension could be remedied by adding metal, mineral, or synthetic fibres, although doing so raises the price of the material. To increase the robustness and endurance properties, Portland cement is largely replaced with mineral admixtures such as fly ash, silica fume, metakaolin, etc.. Among the admixtures, wollastonite is one of the substances that has not been thoroughly studied.

    Wollastonite

    An industrial mineral called wollastonite contains elements like calcium, silicon, and oxygen. Wollastonite has the molecular formula CaSiO3, and its roughly theoretical composition is composed of 48.28% CaO and 51.72% SiO2. Various metal ions, including those of aluminium, iron, magnesium, potassium, and sodium, may be present in trace or insignificant levels in natural wollastonite.

    Fig 1 wollastonite powder

  2. OBJECTIVES

    • To look into the new characteristics of wollastonite concrete..

    • Examine the solidified properties of concrete, like compressive strength, split elasticity, and flexural strength.

    • To determine the ideal amount of wollastonite.

  3. MATERIALS AND METHODOLOGY

    1. MATERIALS

      • OPC 43grade cement

      • Using river sand as a Fine Aggregate

      • Coarse aggregate made of crushed stone

      • Wollastonite

      • Water

    2. METHODOLOGY

    401

    SL

    .No

    Material property

    Test Results obtained

    1

    Specific gravity

    2.4

    2

    Fineness modulus (%)

    2.68

    3

    Density in Bulk (kg/m3)

    1600

    4

    Absorption of water (%)

    1.70

    The approach has been used to research the properties of wollastonite-incorporated materials both when they are soft and when they have hardened (in place of cement). The following process is part of the research work.

    According to the codal provisions of IS 10262:2019, the M30 grade mix design was created. In order to build different concrete mixtures, wollastonite content is modified to 0%, 5%, 10%, 15%, and 20% by weight of cement. The prepared mixes' propertiesboth while they are soft and when they have hardenedare examined.

    Following are the Tests conducted in laboratory for fresh and hardened concrete.

    For fresh Concrete

    • Slump cone test

    • Compaction factor test

    • VeeBee consistometer test

      For Hardened Concrete

    • Compressive Strength

    • Split Tensile strength

    • Flexural Strength test.

  4. RESULTS AND DISCUSSION

  • Basic Tests on Collected Materials

1. Tests on cement

SL

.No

Material property

Test Results obtained

1

Specific gravity

2.8

2

Fineness modulus (%)

7.60

3

Density in Bulk (kg/m3)

1660

4

Absorption of water (%)

0.65

  1. Tests on Coarse Aggregate

    s n

    Material property

    Test Results obtained

    1

    Fineness %

    4.8

    2

    Normal Consistency %

    33

    3

    Specific gravity

    3.2

    4

    Initial setting time(min)

    32

    5

    Final setting time(min)

    569

    6

    Compressive Strength (N/mm2) (7days)

    24

    (28days)

    42

  2. Tests on Wollastonite

SL .No

Material property

Test Results obtained

1

Specific gravity

2.9

  • Tests on Fresh Concrete

1. For fresh Concrete

The findings of the vee bee test and the slump compaction factor are displayed in Table 1 below.

2. Tests on Fine aggregate

Table 1.Workability Test Results

402

Percentage of cement replaced by wollastonite

Fresh properties tested

Slump (mm)

Compaction factor

Vee-Bee Degree(sec)

Nominal mix

85

0.84

6

5%

83

0.83

7

10%

80

0.81

7

15%

76

0.78

8

20%

74

0.76

9

85

83

80

76

74

Fig 2: Slump variation

0.84

0.83

0.81

0.78

0.76

Fig 3: Variation of Compaction facor

The graph shows how the importance of compaction factor varies. The graph shows that the compaction factor steadily decreases as the quantity of wollastonite increases, and that nominal mix yields the highest compaction factor.

7

8

9

6

7

Fig 4: Variation of Vee-Bee Degree (sec)

The graph shows the Vee Bee Time fluctuations. The graph shows that the Vee-bee progressively rises as the amount of wollastonite increases, reaching its maximum value at 20% wollastonite.

2. For Hardened Concrete

  1. Test of Compressive Strength

    Table 2 shows the overall findings of the Strength in compression.

    Percentage of cement replaced by wollastonite

    7 Days

    28 Days

    Strength in compression (N/mm2)

    Strength in compression (N/mm2)

    Nominal mix

    20.99

    37.2

    5%

    23.82

    38

    10%

    26.81

    39.74

    15%

    28.65

    44.23

    20%

    22.4

    41.28

    Table 2: Test Results for 7 Days and 28 Days of Overall Strength in compression

    403

    37.2

    39.74

    44.23

    20.99

    23.82

    26.81

    28.65

    22.4

    38

    41.28

    Fig 5: Variation of Strength in compression Test results

    Fig 6. Strength in compression test at lab

  2. Test of Split Tensile Strength

    The overall findings of the Tensile strength in splits test are listed in the following table 3.

    Percentage of cement replaced by wollastonite

    7 Days

    28 Days

    Tensile strength in split (N/mm2)

    Tensile strength in split (N/mm2)

    Nominal mix

    1.6

    3.03

    5%

    1.87

    3.14

    10%

    2.37

    3.38

    15%

    2.62

    3.98

    20%

    2.19

    3.69

    Table 3: Results for the overall Tensile strength in split at 7 and 28 days

    3.03

    1.6

    3.14

    1.87

    3.38

    2.37

    3.98

    2.62

    3.69

    2.19

    Fig 7: Variation of Tensile strength results

    Fig 8. Tensile strength at test

  3. Test of Flexural Strength

The results of the overall strength in flexural test are presented in Table 4 below.

404

Table 4: In general, Flexural Strength results for 7 days and 28 days

Percentage of cement replaced by wollastonite

7 Days

28 Days

Flexural strength (N/mm2)

Flexural strength (N/mm2)

Nominal mix

4.93

6.62

5%

5.2

7.33

10%

5.41

7.63

15%

6.43

8.16

20%

5.31

7.39

6.62

4.93

7.33

5.2

7.63

5.41

8.16

6.43

7.39

5.31

Fig 9: Variation of Flexural Strength Test results

Fig 10. Flexural Strength test at lab

5) CONCLUSION

  • In the slump cone test of fresh concrete, the lowest wollastonite percentage results in the largest slump, with workability steadily increasing as the proportion of wollastonite in the concrete rises. The maximum compaction is attained with 0% cement and 100% wollastonite, and as the wollastonite proportion in concrete rises, the compaction factor slowly declines.

  • After 7 and 28 days of curing, respectively, the specimens containing 15% wollastonite and 85% cement were viewed as stronger in compression and have compressive strengths of 28.65 and 44.23 higher than that of nominal mix concrete.

  • Wollastonite was used in place of cement in concrete to build strength in split. After 7 and 28 days of curing, respectively, for 15% wollastonite + 85% cement, the split tensile strength improved to 2.62 and 3.98 when compared to that of the nominal mix concrete.

  • When wollastonite is used in place of cement, good Strength in Flexure was attained. After 7 and 28 days of curing, respectively, for 15% wollastonite and 85% cement, the flexural strength was up to 6.43% and 8.16% more than that of the nominal mix concrete. After considering the aforementioned information, it

has been concluded that the ideal concrete design mix should consist of 15% wollastonite in place of cement.

[1]. Aman Sharma,Dr.A.k saxena (2021) study and durability of concrete made with wollastonite material International journal of research publication Vol,2 no.10,pp.318- 321,0ctober 2021

[2].Supriya Xavier Lopes, R S Chikkanagoudar(2020) Effect of Wollastonite as Partial Replacement of Cement on Mechanical and Durability Properties of Concrete International Research Journal of Engineering and Technology (IRJET) e-ISSN: 2395- 0056 Volume: 07

Issue: 08 | Aug 2020 www.irjet.net p-ISSN: 2395-0072

[3]. Zade S, Borkar M, Makode P, Motghare R, Sakharkar P, Dongre B and Bandhekar P (2019), To study the strength of concrete by adding wollastonite in it, IJARIIE, Vol. 5, No.2, pp. 693 69.

[4]. Dahiphale S, Khan K and Tikhe K (2018), Properties of concrete containing Wollastonite, International Journal of Engineering Research in Mechanical and CivilEngineering (IJERMCE)

405

[5]. Wahab M A, Latif I A, Mohamed K and Amira A (2017), The use of Wollastonite to enhance the mechanical properties of mortar mixes, Construction

[6]. Dey V, Kachala R, Bonakdar A and Mobasher B (2015), Mechanical properties of micro and sub-micron wollastonitefibers in cementitious composites, Construction and Building Materials, Vol. 82,pp. 351 359 [7]. Rana A, Kalla P and Singh S (2014), Mechanical and Durability Properties of Concrete containing Wollastonite, ICI journal, pp. 1 6.

406