Assessment Of Carbon Monoxide (Co) Level In Monitoring Industrial And Residential Area
(Case Study Of Enugu Metropolis Monitoring Industrial And Residential Area)
The assessment of carbon monoxide (CO) levels is a crucial aspect of monitoring both industrial and residential areas to ensure environmental safety. Carbon monoxide, a colorless and odorless gas, poses significant risks to human health and the environment. In industrial settings, the continuous monitoring of CO levels is imperative due to the potential for emissions from combustion processes. This is particularly relevant in facilities where fossil fuels are utilized, such as power plants or manufacturing units. Simultaneously, in residential areas, sources like faulty heating systems or improperly ventilated stoves can contribute to elevated CO levels. Integrating advanced monitoring systems that employ cutting-edge sensors and real-time data analysis is essential for promptly identifying and addressing potential threats. Implementing stringent regulations and fostering public awareness regarding the sources and dangers of carbon monoxide enhances the overall safety of both industrial and residential spaces, promoting a healthier and secure living environment.
Air pollutions pollutant showed that the extent of spreading depends on the motor
vehicle traffic population of the area. This pollution strongly generated through
combustion of fossil fuels presents difficult environmental challenge to societies as
it could degrade the environment and affect human health and quality of life.
Vehicular emissions are major contributors to air pollution in urban areas as they
contain harmful gases. The levels of carbon monoxide has been investigated in two
locations of Enugu metropolis (high traffic ‟old park‟ and low traffic „caritas
university‟), in order to determine its pollution status with regards to air. EL-USB-
CO analyzer used for the analysis indicated variations in the levels of CO for the
period of study. The results obtained revealed that the concentrations of CO in high
traffic (HT) area is higher than that of low traffic (LT) and is unacceptable
compared with the Federal Environmental Protection agency (FEPA) Nigeria set
limit. The dispersion pattern of the suggests that vehicular emission contributes to
the levels of carbon monoxide in the environment.
Title page
Certification
Dedication
Acknowledgement
Table of content
Abstract
CHAPTER ONE
1.0 Introduction 1
1.1 Statement of problem 3
1.2 Aim 4
1.2Objectives 4
1.3 Research Hypothesis 4
1.4 Scope of Study 5
1.5 Significance of Study 5
CHAPTER TWO
2.0 Literature Review 7
2.1 Measurement and Monitoring of Co 13
2.2 Sources of Carbon monoxide 19
2.3 Properties of Carbon monoxide 20
2.4 Production of Carbon monoxide 22
2.5 Importance of Carbon monoxide 23
2.6 Effects of Carbon monoxide in human health 25
2.7 Epidemiological effects of Carbon monoxide 26
2.8 Impacts of Carbon monoxide 29
2.9 Local Studies 31
CHAPTER THREE
3.0 materials and Methods 34
CHAPTER FOUR
4.0 Result and Discussion 35
4.1 List of Tables 35
4.2 Test of Hypothesis 42
4.3 List of Graphs 48
CHAPTER FIVE
5.1 Conclusion and recommendation 56
Bibliography 57
Appendix 61
INTRODUCTION
Air pollution is associated with increasing cases of many adverse health effects,
e.g. mortality, respiratory diseases and cancer. The chemical composition of
ambient air is very complex and depends on many different factors, traffic
generated air pollution being a major source in large cities. This is especially true
in the developing world, mainly due to the high proportion of old, poorly
maintained vehicles, the abundance of two stroke vehicles and the poor fuel quality
(Baumbach et al., 1995; Gwilliam 2003). All these factors contribute to one of the
major air pollutant in urban areas; carbon monoxide (CO).
CO is a poisonous, colorless, inevitable gas that has neither taste nor smell. It is
formed when carbon burns with too little air (incomplete combustion) (Smith and
Scott, 2002). Carbon monoxide (CO), also called Carbonious oxide or Carbon (II)
Oxide and is slightly lighter than air. CO is a deadly, colorless, odorless, poisonous
gas, produced by the incomplete burning of various fuels, including coal, wood,
charcoal, oil, kerosene, propane, and natural gas. Products and equipments and
machines powered by internal combustion engines such as portable generators,
cars, lawn mowers, and power washers also produce CO. It has a high affinity for
hemoglobin in blood and displaces O2 to form carboxyl hemoglobin (COHb).
This can cause dizziness, headaches and eventually death. Tobacco smoke, gas
fires, burning candles are also common sources of CO in indoor air. Internal
combustion engines are responsible for most of the CO in outdoor air (Smith and
Scott, 2002). The ambient concentration of CO is measured in parts per million
(ppm). Most of the studies on air pollution and exposure to air pollutants have been
conducted in developed countries, i.e. Western Europe and the USA (Šišvić and
Fugaš, 1987, Cernuschi et. al., 1998; and Chiara et. al., 2005). There is limited
information on exposure to air pollutants in developing tropical countries, but
some studies have been carried out in sub-Saharan Africa (Baumbach et. al., 1995;
Fanou et. al., 2005; Lindѐn e.t al., 2007).
The population in Enugu city, the economic and administrative capital of Enugu
state, has increased rapidly in the last decade (about one million inhabitants), and
in since there is no reliable public transport system, air pollution has worsened
because of an increasing number of old second-hand cars and of taxi motorbikes
(Keke-NAPEP). Petroleum products used are also of poor quality, due to the
importation of sub-standard products into the country. No data on health effect of
air pollution in Enugu city is available to the researcher, but it is anticipated that air
pollution could become a major public health problem if adequate mitigation
measures are not taken at this time. Exposure to air pollution is normally assessed
by environmental monitoring; using either fixed monitoring stations or personal air
collecting instruments.
1.1STATEMENT OF PROBLEM
The world is presently confronted with the twin crises of environmental
degradation and fossil fuel depletion. The uncontrolled use and overexploitation of
our natural resources have also triggered other environmental issues, which
hitherto were non-existent. Some of these environmental issues include global
warming (climate change) and air pollution. The aforementioned have been shown
to have very serious health implications. Presently, fossil fuel powered engines are
noted to account for over sixty percent of the hydrocarbon and nitrogen oxide
pollution which have very serious environmental and health implications,
especially in our urban areas and their surrounding communities. It is thus very
timely and pertinent within the Enugu city due to the growing use of automobiles
and diesel powered generators within the city.
CO is one of those gases that are released from these combustion processes and its
effect on our environment range from its contribution to the photochemical smog,
ground level ozone and depletion of available oxygen within the area. Its effect on
human health when its accepted threshold is exceeded include headache, irritation,
fatigue, loss of muscular coordination, loss of memory and in severe cases, death.
The effects of CO on health are most dangerous because it is both colorless and
odorless, and as such cannot be easily detected. But since these factors; that
contribute to its formation and possible increment in its concentration within the
city is present, it is necessary that a monitoring system of stations be set up to help
in the establishment and eventual monitoring of the gas so as to ensure the safety
and wellbeing of the lives of the people in the city.
1.2 AIM AND OBJECTIVES
1.2.1 Aim:
The aim of this project is to monitor CO levels within Enugu city using two cities
as our basis.
1.2.2 Objectives:
i. Identify possible „hotspots‟ for generation of CO gas within the city.
ii. Determine the distribution of CO gas within high traffic and low traffic
areas of the city.
iii. Determine the daily differences in the various sample stations.
1.3 RESEARCH HYPOTHESIS
HO: There is a significant difference between the carbon monoxide levels within
high traffic areas and low traffic areas.
1.4 SCOPE OF STUDY
The scope of this project covers studies of CO concentrations and distribution
within Enugu city comprising of such districts as Old Park (high traffic) and
Caritas University (low traffic). The project will examine the distribution of air
pollution situation within these areas of the city. Data will be collected and
analyzed for its relevance to the question of how CO disperses in the environment.
To this end, two stations are chosen, one a high traffic (Old Park) and a low traffic
area that is primarily residential and have low traffic flow (Caritas University). The
essence of choosing these stations is to give a general overview of what the air
quality is like within the city, with one station showing the residential profile while
the other shows the commercial profile. The study will focus on only Carbon
Monoxide (CO) gas. The gas will be measured for a nine hour period for one week
at a five minutes interval using carbon monoxide sensors.
1.5 SIGNIFICANCE OF THE STUDY
This study helps in the understanding and also the monitoring of carbon
monoxide in Enugu metropolis and this will help in knowing the level of carbon
monoxide being emitted in this area.
This study will also help in minimizing the level of carbon monoxide in the
environment and also provide a means of solving the problems since motor bikes
and vehicles serves as the case study and the major contributor of carbon-
monoxide in outdoor activities
Carbon Monoxide (Co) Level In Residential Area:
Carbon monoxide (CO) is a colorless, odorless gas that can be harmful when present in elevated levels. It is produced by incomplete combustion of carbon-containing fuels, such as wood, gasoline, natural gas, and oil. In residential areas, CO can be generated by various sources, including gas furnaces, stoves, fireplaces, water heaters, and vehicles in attached garages. To ensure the safety of residents, it’s important to monitor and control CO levels in residential areas.
Here are some key points related to carbon monoxide levels in residential areas:
CO Alarms: Every residential property should have carbon monoxide alarms installed, especially in areas where fuel-burning appliances are present. These alarms are designed to detect elevated CO levels and provide an audible warning when dangerous levels are reached.
Safe Levels: The U.S. Environmental Protection Agency (EPA) and other regulatory agencies have established guidelines for safe CO levels. Typically, concentrations of CO should not exceed 9 parts per million (ppm) for a continuous eight-hour exposure, or 35 ppm for a one-hour exposure. However, it’s important to follow local regulations and guidelines, which may vary.
Regular Maintenance: To prevent CO buildup, it’s crucial to maintain and service fuel-burning appliances and heating systems regularly. This includes cleaning, inspecting, and ensuring proper ventilation.
Ventilation: Adequate ventilation is key to preventing CO buildup. Make sure that all gas appliances are properly vented to the outside, and keep vents and chimneys free from obstructions.
Vehicle Exhaust: Never run a vehicle inside an enclosed space like a garage, as this can lead to the rapid buildup of CO. Always ensure that the exhaust from vehicles is vented outside.
Symptoms of CO Poisoning: Be aware of the symptoms of CO poisoning, which can include headaches, dizziness, weakness, nausea, vomiting, chest pain, and confusion. If you or anyone in your household experiences these symptoms, leave the area immediately and seek medical attention.
Emergency Response: If a carbon monoxide alarm goes off or you suspect CO exposure, take it seriously. Evacuate the premises, call 911, and wait for emergency responders to arrive. Do not re-enter the building until it has been deemed safe.
To specifically measure CO levels in your residential area, you would need a carbon monoxide detector or monitor. These devices are designed to provide real-time readings of CO concentrations and can help you identify potential sources of CO and take appropriate actions to mitigate risks.
Overall, maintaining awareness of carbon monoxide risks, following safety guidelines, and using CO alarms are crucial steps to ensure the safety of residents in a residential area.