THE EFFECTS OF SUGAR CANE BAGASSE ASH AS SUPPLEMENTARY CEMENTITIOUS MATERIAL IN PRODUCTION OF CONCRETE
ABSTRACT
Sugarcane Bagasse is the fibrous residue leftover when sugarcane is squeezed for its juice. Bagasse ash is obtained by subjecting Bagasse to calcinations using furnace. This work is aimed tat using Bagasse Ash as a replacement in the production of concrete.
The bagassewas collected from dumped in a marketin Kano and thereafter sun-drie to eliminate any trace of moisture. It was then taken to the blast furnace for calcinations(controlled burning) at a temperature of 1250OC for 25minutes.The ash was then weighed and sieved with a 90μm standard sieve and the quantity retained on the sieve (black carbon) was weighed and discarded. The ash collected was investigated and its chemical compositions were obtained. Normal Consistency and Setting time for Cement and bagasse ash were determined. The concrete was batched using mix ratio 1:2:4 and the cement was replaced in varying percentages of 5%, 10%, 15%, 20% and 25% using Bagasse ash.Thereafter, the concrete was cured for 7, 14, 21, and 28days and its properties both in fresh and harden state were determined.
The result for Normal consistency of cement was achieved at 35% of water cement ratio (140ml of water added) which is equal to 34mm penetration.While Normal consistency for Bagasse ash was achieved at 33% of water Sugarcane Bagasse Ash (SCBA )ratio (132mls of water added) which is equal to 35mm penetration. Hence, the cement and bagasse ash are satisfactory for normal consistency of 34 to 35% range of specification.The Slump of the concrete shows a slight reduction as the bagasse ash content increases. Also, the results of the compressive strength of concrete at 20% replacement has highest compressive strength of 19.94N/mm2 at 28 days.
TABLE OF CONTENT
Titled page
Certification ii
Dedication iii
Acknowledgment iv
Abstract v
Table of content vi
List of Table vii
List of Figure viii
CHAPTER ONE: PREAMBLE
1.1 Preamble 1
1.2 Statement of problem 2
1.3 Aims and Objective 4
1.4 Justification 4
1.5 Scope of the study 5
CHAPTER TWO: LITERATURE REVIEW
2.1 Concrete 6
2.2 Properties of Concrete 7
2.2.1 Fresh properties 7
2.2.2 Hardened properties 7
2.3 Components of Concrete 7
2.3.1 Ordinary Portland Cement 7
2.3.2 Aggregates
2.3.3 Water 8
2.3.4 Admixtures 8
2.4 Cement 8
2.4.1 Types of cement 9
2.4.1.1 Portland cement 9
2.4.1.2 Portland pozzolana cement 11
2.4.2 Physical Properties of cement 12
2.4.2.1 Fineness 13
2.4.2.2 Consistency of cement paste 13
2.4.2.3 Setting time 14
2.5 Pozzolans 14
2.6 Cementitious Material 15
2.6.1 Fly ash 16
2.6.2 Lime stone 18
2.6.3 Condensed Silica Fume 18
2.7 Bagasse 19
2.8 Previous Work Done 20
CHAPTER THREE: METHODOLOGY
3.1 Material Sourcing 25
3.1.1 Bagasse Ash 25
3.1.2 Cement 25
3.1.3 Aggregate 25
3.1.3.1 Fine Aggregates 26
3.1.3.2 Coarse aggregate 26
3.2 Research Procedure 26
3.2.1 Production of Bagasse Ash 27
3.2.2 Characterization of Bagasse Ash 28
3.2.3 Test on Bagasse ash and cement 28
3.2.3.1 Finesses Test 28
3.2.3.2 Normal Consistency Test 29
3.2.3.3 Setting time test (Initial and Final) 30
3.2.4 Test on aggregate 31
3.2.4.1 Sieve Analysis 31
3.2.4.2 Specific gravity and absorption capacity 32
3.2.4.3 Moisture content 33
3.2.5 Preparation of Concrete Specimens and Mixing Procedure 34
CHAPTER FOUR: RESULTS AND DISCUSSION
4.1 Characterization of Bagasse ash and cement 35
4.1.1 Physical properties of cement and Bagasse ash Result 38
4.1.2 Chemical composition of sugarcane Bagasse Ash 38
4.2 Result on Sieve Analysis 40
4.2.1 Grain size distribution for Bagasse Ash and OPC Cement 40
4.2.2 Results for Sieve Analysis of Fine Aggregate 41
4.2.3 Result for Sieve Analysis of Coarse Aggregate 42
4.3 Workability Test (Slump Test) 44
4.4 Average compressive strength Result 45
CHAPTER FIVE: CONCLUSION AND RECOMMENDATION
5.1 Conclusion 47
5.2 Recommendation 47
Reference
LIST OF TABLE
Table 2.1 Typical composition of ordinary Portland cement 10
Table 2.2 Chemical Requirement for pozzolan 16
Table 3.2 Mix proportion for the concrete work 35
Table 4.1 Physical properties of cement and Bagasse ash 38
Table 4.2 Chemical composition of cement and SBA 39
Table 4.3 Grain Size distribution for bagasse ash and OPC Cement 40
Table 4.4 Sieve analysis results for fine aggregate 41
Table 4.5 Sieve analysis results for coarse aggregate 43
Table 4.6Concrete Slump Test 40
Table 4.6Average Compressive Strength 42
LIST OF FIGURE
Figure 3.1 Diagram of sugarcane Bagasse ash 26
Figure 4.1 Graph for gradation of Bagasse ash and cement 37
Figure 4.2 Graph for sieve analysis of fine aggregate 39
Figure 4.3 Graph for sieve analysis of coarse aggregate 41
Figure 4.4Concrete Slump Test 42
Figure 4.4.1 Average Compressive Strength 43
CHAPTER ONE
INTRODUCTION
1.1 Preamble
Concrete is the most commonly used construction material in the world. It is basically composed of two components: paste and aggregates. The paste which acts as binder contains cement, water and occasionally admixtures; the aggregate contains sand and gravel or crushed stone(Naik andMoriconi, 2003). The aggregate are relatively inert filler materials which occupy 70% to 80% of concrete and can therefore be expected to have influence on its properties( Mindess and Young, 2003).The infrastructural needs of developing countries have lead to huge increase in demand for Portland cement. According to BAU scenario, cement consumption will grow at high rate on world level in the year 2000-2030 ,the 1600 Metric tones of cement consumption in 2000 will increase almost two folds to 2880 Metric tons by 2030, implying an annual 2% grow rate (Nurdeen and Shahid, 2010).
Cement is one of the constituents of concrete and of very high technical benefits, but expensive and environmentally unfriendly material. (Naik and Moriconi, 2006). Therefore, requirements for economical and more environmental friendly cementing material have extended interest in other cementing materials that can be used as supplement for Ordinary Portland cement. Ground granulated furnace slag, fly ash etc have been used successfully for this purpose, Ordinary Portland Cement is frequently used as a major construction material in the country and the world at large. It is considered as a durable material of construction. However, the environmental issue is on the increasing side, as Portland cement is responsible for about 5%-8% global carbon dioxide (CO2) emissions due to it high demand(Jayminkumar and Raijiwala,2015). Researchers all over the worlds are searching out on ways of utilizing either industrial or agricultural waste as a source of raw material for industries. This waste utilization will not only aid the economy but will also bring about foreign exchange earnings and environmental pollution control.
Sugarcane is an agricultural product from which Bagasse Ash is obtained after squeezing out the sugary water in the sugarcane and subjecting it to heat by incinerating the residue through control burning to form ash. (Patcharin et al.,2009). Bagasse is the fibrous residue leftover when sugarcane is squeezed for its juice (Osinubi and Stephen,2005). The Sugarcane Bagasse creates environmental nuisance due to poor disposal which in turn forms garbage heaps (Oyejobi and Lawal, 2014). According to(Barroso and Bareras, 2000) one ton of sugarcane can generate 280kg of Bagasse waste. In the Northern part of Nigeria there is high production of sugarcane due to the soil and weather condition which favorably supports the farming of sugarcane and consequently there is abundant generation of Sugarcane Bagasse/residue waste which cause economic as well as environmental related issue. To solving these issues, enormous effort have been towards the Bagasse ash waste management. But there are yet no adequate research about the usefulness of sugarcane residue in the country, very little value is being attached to Bagasse. The residue has been found to be used for primary fuel source and also, for paper production. However, incinerating it to ash and adopting it as a good pozzolan adds to its economic value.The advancement in technology and desire for safer environment has stimulated the sense of economic reuse and proper management of material earlier discarded as waste. According to( Oriola and Moses, 2010), industrial activities often lead to depletion of natural resources, a process that may result in the accumulation of by-product and/or waste material. It is need of time to rise to the use of cement replacement materials in the concrete which can reduce the significant amount of cement consumption due to the hazardous effect of CO2 to the environment. The incinerating of organic waste of sugarcane i.e. Bagasse Ash contains pozzolanic material, Therefore, it is highly recommended to conduct research on Bagasse and their impact on concrete behavior, and also be adopted has a suitable replacement of cement in concrete
1.2 Statement of Problem
The production of cement is one of the most environmental unfriendly processes due to the emission of carbondioxide gas (CO2) to the atmosphere. Portland cement is responsible for about 5%-8% global carbon dioxide (CO2) emissions constituting environmental problem or impact which may likely be on the increased due to exponential demand of Portland cement(Jayminkumar and Raijiwala,2015).
In addition to its negative environmental impact, cement is also one of the most expensive materials when compared to the other constituents of concrete. The problem of high cost of cement is also a major concern of the construction industry(Anum and Williams, 2003).
The Sugarcane Bagasse creates environmental nuisance due to poor disposal which in turn form garbage heaps, if left to rot, will breakdown and release greenhouse gases, particularly methane, which is 27 times more dangerous to the Ozone than carbon-dioxide.(Australia Clean Energy Council)
1.3 Aim and Objectives
The aim of this research work is to investigate the suitability and effectiveness of bagasse ash as a partial replacement of cement in concrete.
The objectives of this research work includes:
i. Characterization of Bagasse Ash and to see if it exhibits pozzolanic property
ii. Determinationof influence of varyingbagasse ash on properties of concrete both in fresh and hardened states
1.4Justification of the Study
The advancement in technology and desire for safer environment has stimulated the sense of economic reuse and proper management of material earlier discarded as waste. But there are yet no adequate research about the usefulness of sugarcane residue in the country, very little value is being attached to Bagasse. The residue has been found to be used for primary fuel source and also for paper production. However, incinerating it to ash and adopting it as a good pozolan adds to its economic value. This waste utilization will not only aid the economy but will also bring about foreign exchange earnings and environmental pollution control.
1.5 Scope of study
The research focuses on the determination of the suitability of Bagasse ash as a replacement for cement in concrete and construction works. The optimum percentage of bagasse ash required to provide the desired strength when cement was replaced by 0%, 5%, 10%,15%,and 20% sugarcane bagasse ash. Thereafter, the following testscompressive strength, Sieve analysis, density, consistency and setting time were carried out in order to evaluating the influence of bagasse ash on concrete.
CHAPTER TWO
LITERATURE REVIEW
2.1 Concrete
Concrete is an artificial engineering material made from a mix of cement, water, fine and coarse aggregate which contains a negligible amount of air void. (Adebayo,2012) defined concrete as a construction material produced by mixing a cementing material, fine aggregate, coarse aggregate and water in a designed or prescribes proportion (Duggal, 2008) define concrete as a material resulting from the combination of binders (cement and lime), fine aggregate (sharp sand and quarry dust), Coarse aggregate (granite or gravel), water and sometimes admixture (to produce concrete with special properties) which after setting and cured sufficiently, harden like stone due to chemical reaction taking place between water and binding materials.
Concrete is the most widely used construction material in the world (Idagu et al., 2016). It is the most utilized artificial material and only second to water as the most used material in the world. This makes concrete a material of structural importance (Fadele and Ata, 2016); (Ghabir, 2006); (Olutoge, 2012) stated that concrete is the impetus of infrastructural development of any nation. Durable properties of concrete include its strength, economy and durability. Concrete is generally a poor tensile member but good in compression. Its tensional strength can be increased by reinforcing it with steel bar thus becoming a “reinforced concrete” (Usman et al., 2012).
.