DOI : 10.17577/IJERTCONV12IS03059- Open Access
- Authors : Ms. D. Kowsalya, Raghul.N, Anjaly Thomas, Gunasekaran.M, Shahna Sherin. A
- Paper ID : IJERTCONV12IS03059
- Volume & Issue : Volume 12, Issue 03 (March 2023)
- Published (First Online): 23-05-2024
- ISSN (Online) : 2278-0181
- Publisher Name : IJERT
- License:
This work is licensed under a Creative Commons Attribution 4.0 International License
An Experimental Study on Partial Replacement of Cement by Using Sawdust Ash in Concrete
MS. D. KOWSALYAa,
RAGHUL.Nb, ANJALY THOMASb, GUNASEKARAN.Mb, SHAHNA SHERIN. Ab
aAssistant Professor, Department of civil Engineering,
Shree Venkateshwara Hi-Tech Engineering College, Gobichettipalayam, Erode- 638455,
India
bUG Scholar, BE Civil Enginering, Department of Civil Engineering, Shree Venkateshwara Hi-Tech Engineering College, Gobichettipalayam, Erode- 638452, India
ABSTRACT
Sawdust is used in the manufacture of charcoal briquettes. For using sawdust ash (SDA) as a construction material was experimentally investigated. Sawdust was burnt and the ash sieved using a 90-micron sieve. The setting time and mechanical properties depended upon the proportion and characteristic of raw material and water to binder ratio. In this study, replacement of OPC by 5%, 10 %, and 15%, by sawdust ash is proposed.
This mix design of concrete for M grade is done. Experimental investigation is carried out on concrete cubes, cylinder and prism specimens. To replace this cement with saw dust ash various tests are performed on the quality and various mechanical properties strengths like compression strength, split tensile strength will be assessed for all the
mixes. Based on the strength properties of SA concrete optimum mix will be found.
keyword: saw dust ash, M25 mix design, compressive strength, split tensile strength
INTRODUCTION
General
Concrete is one of the most widely used construction material in the world. It is composed of coarse aggregate, fine aggregate, cement and water. It has been in used for over a century in all construction works. A new material in the field of concrete technology has been developed during the recent past with the ongoing demand of industries to meet the functional, strength economical and durability requirement.
In India, the production is 50 million m3 of logs in 2015. In the wood production
industry about 15 – 20 % waste is generated from total production although the reutilization of wood waste has been practiced.
Scope
study covers compressive experimental laboratory examination on This the partial replacement of Portland cement with sawdust.Sawdust is a pollozonic material that can serve as partial replacement to cement due to siliceous.Aluminous material which, in themselves, posses little or no cementitious value but which will, in finely divided from and in the presence of waterReact chemically with calcium hydroxide at ordinary temperature to form compounds possessing cementitious properties
Advantages
Dry sawdust or planer shavings properly packed in the walls and attics of building afford excellent heat insulation. During construction the brickwork had been back- plastered and a space which had been left between the brick and the tiles was filled with sawdust insulation Combining sawdust with water, and freezing creates a better insulating barrier in an ice capsule
METHODOLOGY
Title selection Study literature
Collection of materials Materials testing
Mix design
Replacement of cement with sawdust ash 5% , 10% , 15%
Curing of specimen Testing of specimens
Comparison of result
STUDY ON MATERIALS
Cement
It constitutes only about 20 percent of the total volume of concrete mix; it is theactiveportionofbindingmediumandisthe onlyscientificallycontrolledingredient of concreteThe OPC is classified into three grades, namely 33 Grade, 43 Grade, 53Gradedependingupon the strength of 28days.
M Sand
Manufactured sand (M-Sand) is an additional of river sand for concrete structures. Manufactured sand is created as rigid granite stone by crushing.The crushed sand is of cubical form with grounded boundaries, washed and
classified as a building material. The extent of manufactured sand (M- Sand) is a reduced amount of 4.75 mm.
Coarse aggregate
Crushed graves or stone obtained by crushing of gravel or hardstone.Uncrushed gravel or stone resulting from the naturaldisintegration of rock.Partiallycrushedgravelobtainedasprod uctofblendingofabovetwotypes.
Sawdust ash
Sawdust is an organic waste resulting from the mechanical milling or processing of timber (wood) into various shapes and sizes. The dust is usually used as domestic fuel. Dry sawdust concrete weighs only 30% as much as normal weight concrete and its insulating properties approximate those of wood. Sawdust has been used in concrete for at least 30 years, but not widely.
Water
Water is the key ingredient, which when mixed with cement, forms a paste that binds the aggregate together.The water causes the hardening of concrete through a process called hydration.
CHARACTERISTICSOF MATERIALS
Cement
| Characteristics | ValuespecifiedbyIS |
| SpecificGravity | 3.13 |
| Standardconsistency(%) | 33 % |
| InitialSettingTime | 30 (minutes) |
| FinalSetting Time | 600 (minutes) |
M Sand
| Characteristics | Value specified
by IS |
| Bulk density | 1.78 Kg/m³ |
| Fineness modulus | 2.10 |
| Specific gravity | 2.34 |
| Characteristics | Value specified
by IS |
| Size | 20mm |
| Shape | Angular |
| Specific Gravity | 2.74 |
Coarse aggregate
| Moisture content | 10.8 |
| Apparent specific
gravity |
0.14 |
| Porosity % | 84 |
| Water retention | 50 |
TESTING
COMPRESSIVE STRENGTH FOR SAW DUST ASH
Compressive strength after 7 days for cube
| S.
No |
Mix Description | Compressive strength
(N/mm²) |
Average Compressive |
| 1 | CM | 11.70 | 12.1 |
| 12.5 | |||
| 2 | 5% | 13.2 | 13.58 |
| 13.94 | |||
| 3 | 10% | 14.89 | 14.41 |
| 13.94 | |||
| 4 | 15% | 11.73 | 12.67 |
| 13.62 |
Compressive strength after 28 days for cube
SAW DUST ASH
Sawdust ash
3
10%
22.32
28.72
24.62
21.41
23.25
26.67
4
15%
22.33
SPLIT TENSILE STRENGTH FOR
Table Split tensile strength of cylinder for 7 days
| Mix (%) | Split tensile
strength(N/mm2 ) after 7 days |
Average
compression strength |
|
| Specimen 1 | Specimen 2 | after 7 days</p | |
| CM | 2.42 | 2.82 | 2.26 |
| 5% | 2.72 | 2.96 | 2.84 |
| 10% | 3.92 | 3.98 | 3.95 |
| 15% | 3.69 | 3.23 | 3.45 |
| Mix (%) | Split tensile
strength(N/mm2 ) after 28 days |
Average
compression strength |
|
| Specimen 1 | Specimen 2 | after 28 days | |
| CM | 4.47 | 4.76 | 4.71 |
| 5% | 4.81 | 4.68 | 4.75 |
| 10% | 4.92 | 4.89 | 4.91 |
| 15% | 4.74 | 4.56 | 4.65 |
Split tensile strength of cylinder for 28 days
| S.
No |
Mix Description | Compressive
strength (N/mm²) |
Average Compressive |
| 1 | CM | 17.98 | 19.25 |
| 20.52 | |||
| 2 | 5% | 24.52 | 23.42 |
RESULT
COMPRESSIVE STRENGTH FOR SAW DUST ASH
20
15
10
7 days
5
0
0 0.05 0.1 0.15
Compressive strength after 7 days for concrete
30
25
20
15
10
5
0
28 days
0 0.05 0.1 0.15
Compressive strength after 28 days for concrete
SPLIT TENSILE STRENGTH FOR SAW DUST ASH
Split tensile strength of cylinder for 7 days
Split tensile strength of cylinder for 28 days
5
4.9
4.8
4.7
4.6
4.5
28 days
0 0.05 0.1 0.15
CONCLUSION
5
4
3
2
1
0
7 days
0 0.05 0.1 0.15
The compressive strength of conventional concrete at 28 days is 19.25 MPa and 10% sawdust ash concrete is 26.67 MPa, it shows the 10.34 % improvement form conventional concrete. For other present age of SDA (sawdust ash) the strength is below 20 MPa, thus optimum present age of SDA is 10%. The split tensile strength of conventional concrete for 28 days is found to be 4.71 MPa and that for 10% sawdust ash concrete is 4.91 MPa. It shows the 34.41% improvement from conventional concrete. The optimum use of sawdust ash is 10%. Finally, from the experimental analysis we have found that 15% replacement of sawdust ash with cement in cement concrete is beneficial replacement. And we go beyond this for further replacement in percentage of cement we will see decrease in strength of concrete.
REFERENCE
- N. R. Buenfeld and J.B. Newman. The permeability of concrete in marine environment. Magazine of concrete research, Vol. 36, 1984, pp. 67.
- S. Gopalakrishna, N. P. Raja mane, M. Neelamegam, J. A. Peter and and J. K. Dattatreya. Effect of partial replacement of cement with fly ash on the strength and durability of HPC. The Indian Concrete Journal, 2001, pp. 335-
341.
- P. K. Mehta. Performance tests for sulphate resistance and alkali silica reactivity of hydraulic cement. Durability of building components. ASTM STP 691, ASTM Philadelphia, 1980, pp. 336-345.
- F. Meland. Use of fly ash in cement to reduce alkali-silica reaction. Fly ash, silica fume, slag and natural pozzolana in concrete. Pro. 2nd Int. Conf: ACI pub. Sp-91, V.M. Malhotra, ed., American Concrete Institute (ACI), Detroit, Mich., 1986, pp. 591-608.
- C. Marthong. Effect of partial replacement of three grades of cement by fly ash on concrete properties. MTech Thesis, CivilEngineering Department, Institute of Technology- BHU, 2002, Varanasi, India.
- T. R. Naik and B. W. Ramme. Effects of highlime. Fly ash content on water
demand, time of set and compressive strength of concrete. ACI Materials Journal, 87, 1990, pp. 619-26.
- S. D. Nagrale, H. Hajare and P. R. Modak. Utilization of Rice Husk Ash. International Journal of Engineering Research and Applications (IJERA) Vol. 2(4), 2012, pp. 1- 5.
- F. F. Oyelade and O. Akintoye. Coconut Husk Ash as a Partial Replacement of Cement in Sandcrete Block Production. Pro. 11th Int. Conf. and 32nd Annual General Meeting of the Nigerian Institution of Agricultural Engineers. October 17 20, 2011, Ilorin, Nigeria.
- M. S. Shetty. Concrete Technology. S. Chand & Company Ltd., 2005, New Delhi.
10). S. A. Sumaila and O. F. Job. Properties of SDA-OPC concrete: A preliminary assessment. Journal of Environmental Science. Vol.3 (2), 1999, pp. 155-159.
11) F. F. Udoeyo and P. U. Dashibil. Sawdust Ash as Concrete Material. Journal of Materials in Civil Engineering. ASCE, Vol. 14(2): 2002, 173.