Investigation On The Characteristics Of Cornstalk Ash Blended Cement
Exploring the intricacies of Cornstalk Ash Blended Cement involves delving into the unique attributes of this innovative construction material. Comprising a blend of Portland cement and cornstalk ash, this composite material harnesses the advantageous properties of both components. Cornstalk ash, derived from agricultural waste, not only serves as a sustainable alternative but also contributes to the enhancement of certain key properties in the resulting cement. The investigation encompasses an in-depth analysis of the physical, chemical, and mechanical characteristics of the Cornstalk Ash Blended Cement. It is imperative to scrutinize factors such as compressive strength, durability, and setting time to comprehend the material’s performance under varying conditions. Additionally, the research investigates the environmental impact and feasibility of widespread utilization, addressing concerns related to sustainability and resource optimization in the construction industry. This comprehensive examination strives to shed light on the viability and potential applications of Cornstalk Ash Blended Cement within the realm of contemporary construction practices.
Analysis of investigation on the characteristics of cornstalk blended ash cement was carried out based on the interest of coming out with a good pozzolanic material with all required cement properties. Hence,the supposed competitive demand relationship between cement products in construction works has been majorly wined by cement and this makes people to depend mostly on it despite the increase in price and some with inadequate properties.
In an attempt to reuse and convert agro wastes into useful materials for the construction industry, this research considered the application of corn stalk ash (CSA) as partial replacement for ordinary Portland cement (OPC) in the production of concrete cubes.
The study investigated the oxide composition of CSA to ascertain its suitability as a pozzolanic material. Some properties of cement with CSA as a replacement for OPC were examined.
The results showed that CSA is not a good pozzolana as it does not satisfy the requirement for use as a pozzolana according to ASTM C618(2005). The compressive
strength of the specimens with replacement levels at 10% and 20% cured for periods of 7–28 days was lower at early curing time but improved significantly at later age.10% replacement level did not show increased strength compared to 20% CSA at 28 days curing period. Density decreased withincreasing ash content, water absorption rate increased with increased CSA contents, while abrasionresistance increased with increasing amount of CSA substitutions. The test results revealed that
CSA concrete cubes can attain higher strength than the conventional ones at longer curing periods,due to its pozzolanic reactions.
Title page
Certification
Dedication
Acknowledgement
Abstract
Table of Contents
List of Tables
List of Figures
CHAPTER ONE:
INTRODUCTION
i. Background to the study
ii. Problem statement
iii. Aim of the study
iv. Objectives of the study
v. Justification
vi. Scope
CHAPTER TWO:
LITERATURE REVIEW
2.0.Introduction
2.1.Corn and Corn Cultivation
2.2.Corn and Corn Stalk
2.3.Chemical Composition of Corn Stalk
2.4.Corn Stalk Ash blended Cement and Construction Industry
2.5.Brief description of Cement
2.6.Chemical Properties of Cement
2.7.Lafarge Cement
2.8.The Need for Corn Stalk Ash Blended Cement
2.9.Empirical Study
CHAPTER THREE :
METHODOLOGY
3.1.Experiment Site
3.2.Compressive Strength
3.3.Chemical Analysis
3.4.Physical Analysis
CHAPTER FOUR:
RESULTS AND DISCUSSION
CHAPTER FIVE:
CONCLUSION AND RECOMMENDATION
5.0.Conclusion
5.1.Recommendation
REFERENCES
APPENDIX
Appendix A: Getting Corn Stalk from Field
AppendixB: Corn Stalk blended Ash
AppendixC: Crushing Machine
AppendixD: Concrete Cubes after 28days Curing
AppendixE: Alpan Machine
AppendixF: Surface Area Machine
AppendixG: Burning of Corn Stalk into Ash
INTRODUCTION
vii. Background to the study
Various blends of cement utilized in construction are portrayed by their physical properties. Some key parameters control the nature and quality of cement. The physical properties of good cement are based on; Fineness of cement, Soundness, Consistency, Strength, Setting time, Heat of hydration, Loss of ignition, Bulk density, Specific gravity (Relative density). In addition, cement has a very high cost in many developing countries like Nigeria and its usage cannot be sustained. The need for moderate structure materials in giving satisfactory lodging to people of the world has turned into the real worry of researchers.The expense of traditional structure materials keep on expanding as most of the populace keeps on falling beneath the destitution line. This consequently requires the look for elective neighborhood materials as aggregate or fractional swap for concrete (Adesanya and Raheem, 2009; Akinwumi and Aidomojie, 2015; Raheem &Adedokun 2017). The research has led to the discovery of the potentials of using industrial by-products and agricultural wastes as replacement of some cement materials.Agricultural and industrial wastes possess pozzolanic properties used in cement replacement.The application of agro and industrial wastes in the production of cement is an environmentally friendly method of disposal of large amounts of substances that would have constituted pollution to land, water and air. The agricultural and industrial wastes that possessed pozzolanic characteristics and which had been studied and applied as partial replacements for cement are Rice husk ash [6-9], Corn cob ash [4, 10-12], Waste burnt clay [13-14], Hair fibre [15] and Saw dust ash [16-17]. The saw dust ash (SDA) which has been proven to be a pozzolanic material was used as a partial substitution for OPC in this study. Many researchers have argued that concrete is one of the major materials used for radiation protection in facilities. The radiation protection feature of concrete depends on its components. Cement production is one of the important sources of carbon dioxide emission to the atmosphere. CO2,which is a greenhouse gas, contributes about 65% of global warming (Vijayakumar, 2013; Raheem &Adedokun 2017). The high energy demand as well as the emission of carbon dioxide, which caused global warming and depletion of limestone deposits are the major challenges associated with cement production.
In the recent years, there is great interest in replacing a long time used materials in concrete structure by new materials to produce cheaper, harder and durable concrete.Abdelrahman& El-Awney (2015).The raw materials for cement production are limestone (calcium), sand or clay (silicon), bauxite (aluminum) and iron ore, and may include shells, chalk, marl, shale, clay, blast furnace slag, slate. Chemical analysis of cement raw materials provides insight into the chemical properties of cement.
Corn, also known as maize, is one of the most successful cereal grasses of all time. It has been under human cultivation for over 10,000 years and has spread itself into every niche of commercial agriculture (Adesanya, & Raheem (2009). Maize crop started as a subsistence crop in Nigeria and has gradually risen to a commercial crop on which many agro-based industries depend on as raw materials (Iken, and Amusa, 2014).Corn stalk is a waste product obtained from maize plant, which is the major cereal crop produced in sub-Saharan Africa.Therefore, this research investigated the use of Corn stalk as a partial replacement for ordinary Portland cement in the production of concrete cubes. It includes the determination of the oxide,composition of the CSA, evaluation of the compressive strength, density, water absorption,crushing strength of the concrete and the abrasive resistance of the concrete cubes.
viii. Problem statement
A major challenge in the constructions in the world today is access to good and quality cements with right proportions of its physical properties.The high price of good cement with balance property ratio has made it difficult for people to acquire it, hereby leading to usage of poor quality cement which later affect the construction.This study examined the physical properties of ordinary cements alongside blended cornstalk ash and how it improved the physical properties without unnecessary increase in the cost for effective and standard construction.
ix. Aim of the study
The aim of this study is to investigate the characteristics of corn stalk blended cement as a partial replacement for ordinary portland cement.
x. Objectives of the study
The main aim of this study is to investigate the characteristics of corn stalk blended cement as a partial replacement for ordinary portland cement while the objectives of the study are:
• To ascertain the characterization of corn stalk ash.
• To determine of the effects of corn stalk ash on physical and mechanical properties of blended cement mortar.
xi. Justification
There were several motivations for this study. Although few studies have investigated on things related to the properties of cornstalk ash and other supposed waste of agricultural materials. To the best of my knowledge, there was no definite assurance of complete adequate physical properties in ordinary cement until now.Additionally, analyzing a good access and usage for construction will provide better constructions as well as reducing the number of collapse building in the world.Addition of blended corn stalk ash has further enhanced the physical properties generating a better result for construction at a lower price. In an attempt to reuse and convert agro wastes into useful materials for the construction industry, several research had been carried out on the application of corn stalk ash (CSA) as partial replacement for ordinary Portland cement. The study investigated the characteristics of corn stalk ash blended cement and ascertain its suitability as a pozzolanic material.
xii. Scope
This study centers on the characteristics of corn stalk ash blended cement. Base on the limitation of the study, this research investigated the use of Corn stalk as a partial replacement for ordinary Portland cement in the production of concrete cubes. It includes the determination of the oxide, composition of the CSA, evaluation of the compressive strength, density, water absorption, crushing strength of the concrete and the abrasive resistance of the concrete cubes.
SHARE PROJECT MATERIALS ON:
Investigation On The Characteristics Of Cornstalk Ash Blended Cement:
Investigating the characteristics of cornstalk ash blended cement involves studying the physical, chemical, and mechanical properties of the blended material. This type of research is crucial for understanding the potential benefits and limitations of using cornstalk ash as a supplementary cementitious material. Here is a guide on how you can conduct an investigation on the characteristics of cornstalk ash blended cement:
1. Literature Review:
- Review Existing Studies: Begin by reviewing existing literature on the use of agricultural waste (such as cornstalk ash) in cementitious materials. Understand the potential advantages, challenges, and the state of current research.
2. Material Collection and Preparation:
- Collect Cornstalk Ash: Collect cornstalks and process them to obtain ash. This usually involves burning the cornstalks and then grinding the resulting ash to a fine powder.
- Source Cement: Choose a standard Portland cement as the base material for blending.
3. Experimental Design:
- Mix Proportions: Design different mix proportions with varying percentages of cornstalk ash replacement for cement (e.g., 5%, 10%, 15%, etc.).
- Control Mix: Prepare a control mix without any cornstalk ash to serve as a reference.
4. Physical Properties:
- Density: Measure the density of the blended cement and compare it with the control mix.
- Fineness: Evaluate the fineness of the cornstalk ash and its impact on the overall fineness of the blended cement.
5. Chemical Properties:
- Chemical Composition: Analyze the chemical composition of both the cornstalk ash and the blended cement. This includes elements like silica, alumina, calcium oxide, etc.
- Mineralogical Analysis: Use techniques such as X-ray diffraction (XRD) to identify the mineral phases present in the blended cement.
6. Mechanical Properties:
- Compressive Strength: Conduct compressive strength tests on hardened concrete samples at different curing ages for both blended and control mixes.
- Tensile Strength: Evaluate the tensile strength and flexural strength of the blended cement.
7. Durability Testing:
- Permeability: Assess the permeability of the blended concrete to evaluate its resistance to water and aggressive substances.
- Freeze-Thaw Resistance: Subject the concrete to freeze-thaw cycles to determine its resistance to this common environmental stress.
8. Microstructural Analysis:
- SEM Analysis: Use scanning electron microscopy (SEM) to examine the microstructure of the blended cement and identify any changes compared to the control mix.
9. Economic and Environmental Impact:
- Cost Analysis: Evaluate the economic feasibility of using cornstalk ash in terms of production costs and potential cost savings.
- Environmental Impact: Consider the environmental benefits of using agricultural waste as a sustainable alternative.
10. Conclusion and Recommendations:
- Summarize Findings: Present a summary of the key findings regarding the characteristics of cornstalk ash blended cement.
- Recommendations: Provide recommendations for optimizing mix proportions based on the observed performance.
11. Documentation and Reporting:
- Document Procedures: Clearly document the procedures followed in the investigation.
- Prepare a Report: Compile the results and findings into a comprehensive research report.
12. Peer Review:
- Seek Feedback: Share your findings with peers, researchers, or experts in the field for feedback and validation.
By following these steps, you can conduct a thorough investigation into the characteristics of cornstalk ash blended cement, providing valuable insights into its potential as a sustainable and effective construction material.