Effluent Impact On Water Quality
(A Case Study Of Aba River In Aba North L.G.A.Of Abia State)
The impact of effluent on water quality is profound and encompasses various dimensions, including environmental, ecological, and public health aspects. Effluent, originating from industrial, agricultural, or municipal sources, contains a diverse array of contaminants, such as heavy metals, organic pollutants, nutrients, and pathogens, which can significantly degrade water quality. These pollutants often disrupt aquatic ecosystems, leading to biodiversity loss, habitat degradation, and impaired water functionality. Moreover, the discharge of untreated or inadequately treated effluent into water bodies poses serious risks to human health, as it can introduce pathogens and toxins into drinking water sources, resulting in waterborne diseases and other adverse health effects. Addressing the challenges posed by effluent requires holistic management approaches, including stringent regulation, adoption of advanced treatment technologies, and promotion of sustainable practices to mitigate pollution and safeguard water resources for present and future generations.
This project work was aimed at determining the effect of effluent on Aba River. This became pertinent owing to the fact that companies discharge their effluent into the river without treatment. Four different samples were collected from four locations and analyzed, which include Upstream Sample (A), Unilever Effluent (B), Nigeria Breweries Effluent (C), and Down Stream Sample (D).
The results obtained indicated that there is industrial input of metals like Iron, Copper, Zinc, Calcium and non metals like Sulphate, Phosphate, Chloride, and Carbonate. This parameters were higher when compared with WHO’s standard.
The microbiological analysis showed that the river is highly polluted.
Finally conclusions were drawn and recommendations made.
Title Page
Approval Page
Dedication
Acknowledgement
Abstract
Table of Content
CHAPTER ONE
Introduction 1-2
1.1 Statement of the Problem 3
1.2 Aims and Objective 3
1.3 Area of Study 4
1.4 Significance of the Study 4
1.5 Definition of Terms 4-6
CHAPTER TWO
Literature Review 7-11
2.1 Historical need and Development of Drinking
Water Quality 11-12
2.2 Water Characteristic 12-16
2.3 Waste Water Characteristics 16-17
2.4 Water Pollution 17-18
2.4.1 Water-Borne-Diseases 18
2.4.2 Water-Washed-Diseases 19
2.4.3 Water-Based-Diseases 19
2.4.4 Water-Related Diseases 19-20
2.5 Drinking Water Quality Standards and Goals 20
2.5.1 Primary Drinking Water Standard 21
2.5.2 Secondary Drinking Water Standard 21-22
2.5.3 How Standards are Set 22-23
CHAPTER THREE
3.0 Sampling Procedure 24-25
3.1 Data Collection 25
3.2 Parameters Analysed 25-26
3.2.1 Apparatus/Reagents 26-27
3.3 Methods used in The Experiment 27-36
3.4 Practical Results 36
3.4.1 Temperature 36
3.4.2 Colour 36
3.4.3 pH 37
3.4.4 Odour 37
3.4.5 Calculating for Hardness in the Samples 37-38
3.4.6 Calculating Alkalinity 39-40
3.4.7 Total Dissolved Solid (TDS) 40-41
3.4.8 Dissolved Oxygen 42-43
3.4.9 Metals (Cations) 43
3.5 Non Metals (Anions) 44
3.5.1 Comparing The parameters with WHO’s Standard 44
3.5.2 Dissolved Oxygen Curve 45
CHAPTER FOUR
4.0 Data Presentation 46
4.1 Parameters 46-47
4.2 Analysis of Physical Parameters 47
4.3 Analysis of Chemical Parameters 48
4.1 Analysis of Microbiological Parameters 48
CHAPTER FIVE
5.1 Conclusion 49-50
5.2 Recommendation 50-51
Reference 52
INTRODUCTION
1.1 WHAT IS CONCRETE
Concrete is an artificial engineering material made from a mixture of Portland cement, water, fine and course aggregates, and a small amount of air. It is the most widely used construction material in the world.
Concrete is the only major building material that can be delivered to the job site in a plastic state. this unique quality makes concrete desirable as a building material because it can be molded to virtually any form or shape. Concrete provides a wide latitude in surface textures and colours and can be used to construct a wide variety of structures, such as highways, and streets, bridges, dams, barge buildings, airport runways, irrigation structures, breakwaters, piers and docks, sidewalks, soles and farm buildings, homes and even barges and ships.
Other desirable qualities of concrete as a building material are its strength, economy, and durability. Depending on the mixture of material used, concrete will support, in compression, 700 or more kg/sq cm (10,000 or more 1b/sq in). the ensile strength of concrete is much lower, but by using properly designed still reinforcing, structural members can be made that are as strong in tension as they are in compression. The durability of concrete is evidenced by the fact that concrete columns built by the Egyptians more than 3000 years ago are still standing.
There are however, many different types of concrete, the names of some are distinguished by the types, sizes and densities of aggregates e.g. eight weight, normal weight or heavy weight. Concrete are similar in composition to mortar, which are used to bond unit masonry. Mortars however, are normally made with sand as a hole aggregates.
Whereas, concrete contain much larger aggregates and this usually have greater strength. As a result, concrete have a much wider range of structural application, including pavements, footings, pipes, unit majoring, walls, dams and tanks. Because ordinary concrete is much weaker in tension than in compression, it is usually prestressed or reinforced with a much stronger material, such as steel, to resort tension.
There are various methods employed for carting ordering concrete. For very small projects, sacks of prepared mixes may be purchased and mixed on the site with water, usually a drem-type, portable, mechanical mixer.
For large projects, mix ingredient are weighed separately and deposited in a stationary batch mixer or a continuous mixer. Concrete mixed or agitated in a truck is called ready mixed concrete. In general, concrete is placed and consolidation is forms by hand tamping or pudding around reinforcing steel or by spreading at or near vertical surface. Another technique vibration or mechanical pudding, which is the most satisfactory one for achieving proper consolidation.
CONSTITUENT OF CONCRETE
The two major components of concretes are cement parts and inert materials. The cement parts consists of Portland cement, water, and some air either in the form of naturally entrapped air voids or minute, intentionally entrained air bubbles. The inert materials are usually composed of fire aggregate, which is a material such as sand, and course aggregate, which is a material such as gravel, crushed stone, or slag. In general, fire aggregate particular are smaller than 6.4mm (.25mm) in size, and course aggregates a particles are large than 6.4mm (.025mm). Depending on the thickness of structure to be built, the size is used, when Portland cement is mixed with water, the components of the cement react to form a cementing medium. In properly mixed concrete, each particles of sand and course aggregates is completely surrounded and coated by this paste, and all spaces between the particular are filled with it. As the cement part sets and hardens, it binds the aggregates into a solid mass.
Under normal conditions, concrete grows stronger as it grows older. The chemical reactions between cement and water that cause the parts to harden and bind the aggregates together require time. The reactions take place very rapidly at first and then slowly over a long period of time.
1.2 SALT WATER (SEA WATER)
Sea water has a salinity of about 3.5%. in that about 78% is sodium chloride and 15% is chloride and sulphate of magnesium. Sea water also contain small quantities of sodium and potassium salts. This can react with reactive aggregates in the same manner as alkalizes in cement. Therefore, sea water should not be used even for Pcc if aggregates are known to be potentially alkalie reactive. It is reported that the use of sea water for mixing concrete does not appreciately reduce the strength of concrete although it may lead to corrosion of reinforcement in certain cases. Research workers are unanimous in their opinion, that sea water can be used in un-reinforced concrete or mass concrete sea water slightly accelerates the early strength of concrete. But it reduces the 28day strength of concrete by about 10 to 15percent.
However, this loss of strength could be made up by redesigning the mix. Water containing large quantities of chlorides in sea water may cause efflorescence and persistent dampness. When the appearance of concrete is important, sea water may be avoided.
Granite, limestone, sand stone, or basaltic rock are crushed for use principally as concrete aggregate or road stone.
ADVANTAGES OF CONCRETE
Under normal conditions, concrete grows stronger as it grows older. It is the most widely used material (construction) in the world, because it is the only major building material that can be delivered to the job site in a plastic state.
Concrete can be molded into different form or shape due to its unique quality. Other qualities of concrete as a building material are its strength, durability, and economy, depending on the mixture of material used.
Concrete provides a wide latitude in surface texture and colours and can be used to construct a wide variety of structures, such as highways and street bridges, dams, large buildings, airport runways, irrigation structures, breakwaters, piers and docks, sidewalks, silos and farm buildings, home and even barges and ships.
DISADVANTAGES OF CONCRETE
• Ordinary concrete are much weaker in tension, than in compression.
• Concrete is a bottle material and presses very low tensile strength, limiting ductility and little resistance to cracking
• Internal micro cracks as inherent present in the concrete and its poor tensile strength propagates such micro cracks and eventually leading to bottle failure of concrete.
• Concrete containing micro silica is vulnerable to plastic shrinkage, cracking and therefore, sheet or mat curing should be considered.
1.3 OBJECTIVES AND PURPOSE OF STUDY
The purpose of the study is to know the adverse negative effect the water (salt) may have on concrete.
Water is an important ingredient of concrete as it actively participates in the chemical reaction with cement. Since it helps to form the strength giving cement gal, the quantity and quality of water is required to be looked into very carefully. Sea water has a salinity of about 3.5percent, in that , about 78% is sodium chloride and 15% is chloride and sulphate of magnesium. It is said that the use of salt water (sea) for mixing concrete does not appreciably reduce the strength of concrete through it may lead to corrosion of reinforcement in certain cases. The aim of the experiment is to prove whether or not, if the sea water can reduce the strength of concrete.
1.4 SCOPE AND LIMITATION OF STUDY
A popular yard-stick to the suitability of water for mixing concrete is that, if water is fit for drinking, it is fit for making concrete. This does not appear to be a true statement for all conditions. Some water containing imparities may be suitable for other purpose, but not for the mixture of concrete.
Some specification requires that if the water is not obtained from source that has proven satisfactory, the strength of concrete or mortar made with questionable water should be compared with similar concrete or mortar made with pure water. Sea water has a salinity of about 3.5percent, in that, about 78% is sodium chloride and 15% is chloride and sulphate of magnesium. It is reported that the use of sea water for mixing concrete does not appreciably reduce the strength of concrete although it may lead to corrosion of reinforcement in certain cases.
The purpose of the experiment is to prove the doubt of people whether or not if salt water has an effect on concrete.
1.5 DEFINITION OF TERMS
ACCELERATION:- There are substances that speeds up rate of a reaction, for photography, an accelerator speeds the action of a developer. For structural engineering, an accelerator speeds the setting of concrete. In the manufacture of plastics, an accelerator is used to speed up the curing of epoxy and other resion-type plastics.
GRAVEL:- Gravel, loose material consisting of rock or mineral fragments. Gravel fragments are larger than sand particles and smaller than boulders specifically, gravel particles are larger than 2mm (0.08m) in diameter and smaller than 256mm (10m) in diameter. Gravel is a constituents of concrete, which is used in construction.
Gravel is produced by the weathering and erosion of rocks, strong river currents or glaciers often transport gravel greats distances before it is disposited. Rock fragments in gravel that has been transported by water are worm and rounded, while theso carried by ice usually have sharp angular edges. The rock fragments in gravel transported by rivers also vary in sizeless than those transported by glaciers. Gravels are also found on beaches where there is strong wave actives are very round and smooth.
SAND:- Sand loose incoherent mass of mineral materials in a finely gramilar condition, usually consisting of quartz (silica) with a small proportion of mica, feldspar, magnetite, and other resistant minerals. It is the product of the chemical and mechanical disintegration of rocks under the influence of weathering and abrasion. When freshly formed, the particles are usually angular and sharply pointed, becoming smaller and more rounded by attrition by the wind or by water.
QUARRY AND QUARRYING
Quarry and quarrying, open excavation from which any useful stone is extracted for building and engineering purpose and the operations required to obtain rock in useful form from a quarry. The two principal branches of the industry are the so-called dimension-stone and crushed stone quarrying. In the firms, blocks of stones such as marble, are extracted in different shapes and sizes for different purposes. In the crushed-stone industry.
Effluent Impact On Water Quality:
Effluent, in the context of environmental science and water management, refers to any liquid waste or discharge that flows into a water body, such as rivers, lakes, or oceans, after being treated or coming from various sources like industrial processes, sewage treatment plants, or agricultural runoff. The impact of effluent on water quality can be significant and can have both short-term and long-term consequences for aquatic ecosystems and human health. Here are some of the key ways in which effluent can impact water quality:
Chemical Pollution: Effluents often contain a wide range of chemicals, including heavy metals, organic compounds, and nutrients (such as nitrogen and phosphorus). When discharged into water bodies, these chemicals can alter the chemical composition of the water, leading to contamination. For example, heavy metals like mercury and lead can accumulate in aquatic organisms, posing a threat to both wildlife and humans who consume contaminated fish.
Nutrient Loading: Effluents from sewage treatment plants and agricultural runoff can be rich in nutrients, especially nitrogen and phosphorus. Excessive nutrient loading can lead to eutrophication, a process in which aquatic ecosystems become overloaded with nutrients, causing excessive growth of algae and aquatic plants. This can lead to oxygen depletion, fish kills, and the disruption of the balance of the ecosystem.
Temperature Effects: Some industrial effluents discharge heated water into water bodies, which can raise the temperature of the receiving water. Elevated temperatures can reduce the solubility of oxygen in water, making it more difficult for aquatic organisms to breathe. It can also disrupt the natural habitat of cold-water species, potentially leading to their decline.
Biological Pollution: Effluents may contain bacteria, viruses, and pathogens from sewage and industrial processes. When released into water bodies, they can pose health risks to humans who come into contact with contaminated water or consume contaminated seafood.
Sedimentation: Effluents can carry suspended solids and sediments into water bodies, leading to increased turbidity. High levels of sedimentation can smother the habitat of aquatic organisms and reduce the amount of sunlight reaching underwater plants, affecting the overall health of the ecosystem.
Habitat Destruction: In addition to chemical and biological impacts, the physical discharge of effluents can alter the physical characteristics of the water body. For example, the construction and operation of sewage outfalls can disrupt the seabed and benthic habitats, affecting bottom-dwelling organisms and the overall ecosystem structure.
Cumulative Effects: The cumulative impact of multiple sources of effluent, including industrial, agricultural, and municipal discharges, can be particularly damaging to water quality. Even if individual discharges meet regulatory standards, their combined effects can still be harmful.
Efforts to mitigate the impact of effluent on water quality include improved wastewater treatment processes, stricter regulations and enforcement, better management practices in agriculture, and public awareness campaigns. Sustainable water management strategies aim to balance the needs of human activities with the preservation and protection of aquatic ecosystems.