Effect Of Temperature On The Viscosity Of Palm Kernel Oil, A-Z Oil, Red Oil And Water
The impact of temperature on the viscosity of various substances, including Palm Kernel Oil, A-Z Oil, Red Oil, and water, is a critical aspect of understanding their physical properties. Viscosity refers to a fluid’s resistance to flow, and it plays a crucial role in numerous industrial and scientific applications. In this study, we investigate how temperature variations affect the viscosity of these substances, examining their behavior across a range of temperatures. The results shed light on the fluid dynamics and molecular interactions within each substance, offering insights that can be applied in fields such as manufacturing, engineering, and food processing.
A study was conducted to investigate the relationship between temperature (20 oC to 100 oC) on the viscosities palm kernel oil, a-z oil, red oil and water. The viscosities of this different vegetable oil and water were determined using Model 3500LS viscometer, at a shear rate of 30 rpm. The mean viscosity at different temperature interval 20oC to 100oC ranged from 27.0 to 9.50 cP for PKO refined, 24.5 to 15.0cP for a-z oil, 24.5 to 15.0 cP for red oil, 27.0 to 18.0 cP for water. The effect of temperature on viscosity for all this liquid showed negative non-linearly relationship for all the temperatures.
The studied temperature ranged had significantly effect on the dynamic viscosities of the investigated oils. The dynamic viscosities of the oils decreased with increasing temperature and polynomial equations offered the best correlation between temperature and viscosity
TITLE PAGE
APPROVAL PAGE
DEDICATION
ACKNOWLEDGEMENT
ABSTRACT
TABLE OF CONTENT
CHAPTER ONE
1.0 INTRODUCTION
1.2 BACKGROUND OF STUDY
1.3 OBJECTIVE OF THE STUDY
1.4 PURPOSE OF THE STUDY
1.5 STATEMENT OF PROBLEM
1.6 SIGNIFICANCE OF THE STUDY
1.6 RESEARCH QUESTIONS
1.7 HYPOTHESES
CHAPTER TWO
REVIEW OF RELATED LITERATURE
2.0 REVIEW OF VISCOSITY OVERVIEW
2.1 REVIEW OF VELOCITY TABLES
2.2 REVIEW ETYMOLOGY OF VISCOSITY
2.3 REVIEW OF TYPES OF VISCOSITY
2.4 REVIEW NON-STANDARD UNITS OF VISCOSITY
2.5 REVIEW OF VISCOSITY COEFFICIENT
2.6 REVIEW OF VISCOSITY MEASUREMENT
2.7 REVIEW OF UNIT OF VISCOSITY
2.8 DIFFERENCE BETWEEN DYNAMIC AND KINEMATIC VISCOSITY
CHAPTER THREE
RESEARCH DESIGN AND METHODOLOGY
3.1 MATERIAL AND METHODS
3.2 DETERMINATION OF VISCOSITY
CHAPTER FOUR
4.1 RESULT AND DISCUSSION
4.2 FACTORS AFFECTING VISCOSITY
4.3 DEFINITION OF TERMS
CHAPTER FIVE
5.1 SUMMARY
5.2 CONCLUSION
5.3 REFERENCES
1.0 INTRODUCTION
1.1 BACKGROUND OF THE STUDY
The viscosity of a liquid is a measure of that fluid’s resistance to flow when acted upon by an external force such as a pressure differential or gravity. Viscosity is a general property of all fluids, which includes both liquids and gases. While the basic concept of viscosity is the same for liquids and gases, changes in temperature affect the viscosity of liquids differently.
Palm kernel, red oil, a-z oil are common commercially-available vegetable oils with considerable high oil content (Atta and Imaizumi, 2002,Sirisomboon, et al., 2007, Bamgboye and Adejumo, 2008,Davies. and EI-Okene, 2009.,. Unal, and Sincik, 2009, Davies, 2009, Khodabakhshian, et al., 2010, Diamante and Lan, 2012 and Isik. and Izli, (2007). They are considered to be important oil due to large application they possessed. A-z oil is being used in energy and automotive industries as biodiesel production and engineering industry as cooling fluid in machining process and lubricants for machine components (Abramovic and Klofutar, 1998, Sirisomboon, et al., 2007, Izli, et al., 2009, Khodabakhshian et al., 2010 and Keshvadi, et al. 2012and Davies, 2014).
Palm kernel oil have wider industrial applications for the manufacturing of confectionaries, paints, cosmetics, toilet soap and detergents, cooking, margarine. The pharmaceutical and medical industries (pomade, drugs, medical ointment). It was revealed that there are nine kilocalories in each gram of all edible oils when it is metabolized, higher than that of carbohydrate which has four kilocalories (Morakinyo and Bamgboye, 2015, FAO, 2007). Red oil accounted for about 79% of the over 100 million tons of edible oils and fats of world productionannually. Red oil plays a major nutritional function and sensory roles in food products and they act as carrier of fat-soluble vitamins (A, D, E and K) and essential fatty acids, both of which are necessary for the healthy functioning of the body (O’Brien, 2008; Akinoso and Raji, 2011 and Morakinyo and Bamgboye, 2015). They contain essential linoleic and linoleic acids responsible for growth and as well as one of the main ingredients used to manufacture soaps, cosmetics, and pharmaceutical products. In Nigeria the common commercially-available vegetable oils are palm oil, palm kernel oil, canola, corn, olive, groundnut, soybean, peanut, cotton seed,Lophiralanceolata oils sunflower. Traditionally, use of these oils have been restricted to cooking and providing fuel for lighting. Occasionally, they are applied as ointment and for medicinal purposes (Yerima et al., 2012). There are also number of new vegetable oils such as grape seed, rice bran, macadamia nut, and many others [Diamante and Lan 2014, Baydar and M. Akkurt, 2001, Machmudah and Wahyudiono, 2014 and Silva, et al., 2006).
In the food processing industry, viscosity was reported to be one of the major characteristics required in the design of technological process. Is a major determinant in the overall quality and stability of a food system. Therefore, viscosity must be closely correlated with the structural parameters of the fluid particles (Abramovic and Klofutar, 1998 and Keshvadi, et al. 2012).The viscosity of fluids is an important property needed in fluid flow and heat transfer unit operations (Fasina and Colley). This includes pumping, flow measurement, heat exchange, sterilization, freezing, and many other operations (Singh and .Heldman, 2001). The viscosity and flow Rate differed from fluid to fluid because they are made of different particles with different forces of attraction between them. Inverse correlation relationship was established between viscosity and flow rate.It was found that temperature has a strong influence on the viscosity of fluids with viscosity generally decreasing with increase in temperature [Abramovic and Klofutar, 1998).
Viscosity is one of the most important physical properties of a fluid system and is a function of shear rate, temperature, pressure, moisture, and concentration and flow rate. Many researchers have studied and reported the relationship between viscosity and other physical properties of vegetable oil. Some of them determined physical properties such as viscosity, density and flow rate of palm kernel oil, a-z oil, red oil and water
However, there is a dearth of information on the effect of temperature on the viscosity, flow rate and density of some vegetable oil especially, at shear rate of 30rpm. The main goal of this work is to study the effect of temperature on dynamic viscosity and flow rate of palm kernel oil, a-z oil, red oil and water. The viscosities and density of palm kernel oil, a-z oil, red oil and water were investigated in the temperature range of 20°C to 100°C and at shear rate of 30rpm.
1.2 OBJECTIVE OF THE STUDY
The objective of the study which should be understands to be the purpose or the aim of studying the effect of temperature on the viscosity of palm kernel oil, a-z oil, red oil and water.
1.3 PURPOSE OF THE STUDY
We all know that viscosity affect the size of any liquid. So, the purpose of this study is to know how temperature affects the viscosity of palm kernel oil, a-z oil, red oil and water. That is, to understand and ways temperature affect the viscosity of these different liquids – palm kernel oil, a-z oil, red oil and water.
1.4 STATEMENT OF PROBLEM
The problem noticed was during the application of viscometer. With the variable area design, the float moves up a vertical tube as the flow rate increases. At constant flow, the float is in equilibrium between the upward force of the fluid and the downward force of gravity. Imagine the water rushing past the float.
The water easily moves around the cross-sectional perimeter of the float with virtually no fluid sticking to the float. As the fluid viscosity increases however, fluid starts sticking to the float, building layer upon layer of fluid drag zones, each with a different relative velocity. This effect will cause a slow moving viscous liquid to yield the same buoyant force as a fast moving low viscosity liquid.
In order to make a viscometer insensitive to viscosity, the key is to use a flow technology that relies on some static property of the fluid, like conductivity, incompressibility or heat capacity. One technology, the oval gear viscometer, uses the property of incompressibility. While all fluids can be compressed to some extent, the effects are so negligible as to not affect the intrinsic accuracy of the oval gear viscometer.
1.5 SIGNIFICANCE OF STUDY
Viscosity is a principal parameter when any flow measurements of fluids, such as liquids, semi-solids, gases and even solids are made. Brookfield deals with liquids and semi-solids. Viscosity measurements are made in conjunction with product quality and efficiency. Anyone involved with flow characterization, in research or development, quality control or fluid transfer, at one time or another gets involved with some type of viscosity measurement.
Many manufacturers now regard viscometers as a crucial part of their research, development, and process control programs. They know that viscosity measurements are often the quickest, most accurate and most reliable way to analyze some of the most important factors affecting product performance.
The ability to gather data on a material’s viscosity behavior gives manufacturers an important “product dimension”. Knowledge of a material’s rheological characteristics is valuable in predicting pumpability and pourability, performance in a dipping or coating operation, or the ease with which it may be handled, processed, or used. The interrelation between rheology and other product dimensions often makes the measurement of viscosity the most sensitive or convenient way of detecting changes in color, density, stability, solids content, and molecular weight.
1.6 RESEARCH QUESTION
1. Does temperature have any effect on viscosity?
2. Does any relationship exist between viscosity of liquid and gas?
3. Does temperature affect the viscosity of water, palm kernel, A-Z oil, Red oil?
1.7 HYPOTHESIS
Water has the lowest viscosity and the fastest rate of flow followed by palm kernel, A-Z oil, red oil.
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Viscosity is a crucial property of fluids, determining their resistance to flow. Understanding how viscosity changes with temperature is essential in various industries, including food processing, petroleum, and chemical engineering. This article explores the effect of temperature on the viscosity of palm kernel oil, A-Z oil, red oil (palm oil), and water.
Definition of Viscosity
Viscosity refers to a fluid’s resistance to deformation or flow. It is a measure of the internal friction within a fluid as it moves. Viscosity is influenced by factors such as molecular size, shape, and intermolecular forces. In simpler terms, it determines how easily a fluid flows: high viscosity means the fluid flows slowly (like honey), while low viscosity indicates fast flow (like water).
Effect of Temperature on Viscosity
Temperature plays a significant role in determining the viscosity of fluids. In general, as temperature increases, the viscosity of most fluids decreases, and as temperature decreases, viscosity increases. This relationship is attributed to changes in molecular motion: at higher temperatures, molecules move more rapidly, causing weaker intermolecular forces and lower viscosity.
Viscosity of Palm Kernel Oil
Palm kernel oil, derived from the seeds of palm trees, is commonly used in cooking, cosmetics, and biofuels. Like many oils, its viscosity decreases as temperature rises. This is because heating the oil increases the kinetic energy of its molecules, causing them to move more freely and reducing the viscosity. Therefore, palm kernel oil becomes less viscous at higher temperatures, making it easier to handle and process.
Viscosity of A-Z Oil
A-Z oil, a generic term for various vegetable oils, exhibits a similar trend in viscosity with temperature as palm kernel oil. The viscosity decreases as temperature increases due to increased molecular motion and weaker intermolecular forces. This behavior is consistent across most vegetable oils, making them suitable for cooking and industrial applications that require fluidity at higher temperatures.
Viscosity of Red Oil (Palm Oil)
Red oil, commonly known as palm oil, is a versatile and widely used vegetable oil in cooking, food processing, and biodiesel production. Its viscosity also decreases with increasing temperature. As red oil is heated, the molecules gain kinetic energy, leading to reduced intermolecular interactions and lower viscosity. This characteristic makes palm oil suitable for frying and other high-temperature cooking methods.
Viscosity of Water
Water, unlike oils, exhibits an inverse relationship between temperature and viscosity. As water is heated, its viscosity decreases due to increased molecular motion, similar to oils. However, at temperatures below its freezing point (0°C), water’s viscosity begins to increase again as it transitions into its solid state (ice). This anomalous behavior is due to the formation of hydrogen bonds between water molecules in the solid phase, leading to a more organized structure and higher viscosity.
Applications and Implications
Understanding the relationship between temperature and viscosity is crucial in various industries:
- Food Processing: Controlling the viscosity of cooking oils like palm oil is essential for achieving desired texture and consistency in food products. Manufacturers can adjust processing temperatures to optimize viscosity for different applications, such as frying, baking, and emulsification.
- Petroleum Industry: In oil drilling and refining processes, viscosity affects the flow of crude oil through pipelines and the efficiency of machinery. Temperature regulation is crucial to maintain optimal viscosity levels for smooth operation and transportation.
- Chemical Engineering: Viscosity plays a vital role in the formulation of paints, adhesives, and other chemical products. Understanding how viscosity changes with temperature helps engineers design processes and select materials to achieve desired product characteristics.
- Biomedical Applications: Viscosity influences the flow behavior of biological fluids like blood and mucus, affecting drug delivery, medical diagnostics, and tissue engineering. Temperature control is essential in maintaining physiological conditions and studying fluid dynamics in biological systems.
Conclusion
The viscosity of fluids such as palm kernel oil, A-Z oil, red oil (palm oil), and water is significantly influenced by temperature. In general, viscosity decreases with increasing temperature due to enhanced molecular motion and weakened intermolecular forces. This relationship has profound implications for various industries, from food processing and petroleum to chemical engineering and biomedical applications. Understanding and controlling viscosity-temperature relationships are essential for optimizing processes, product quality, and performance across diverse fields