CEV415 Chemistry For Chemical Engineer UITM Assignment Sample Malaysia

CEV415 Chemistry for Chemical Engineer is a course offered by Universiti Teknologi MARA (UiTM). This course is designed to provide chemical engineering students with an in-depth understanding of the principles of chemistry and how they relate to chemical engineering processes. Through this course, students will learn about the fundamental principles of chemistry, such as chemical reactions, chemical thermodynamics, chemical kinetics, and chemical equilibrium.

In addition, students will also learn about the properties of matter, including the behavior of gases, liquids, and solids, as well as the different types of chemical bonding and their significance in chemical engineering. The course will also cover important topics such as acid-base chemistry, electrochemistry, and organic chemistry, providing students with a comprehensive understanding of the subject matter.

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In this section, we discuss some assignment objectives. These are:

Assignment Objective 1: Apply the basic principles of physical and hydrocarbon chemistry in solving chemical engineering problems.

Chemical engineering problems often involve the application of basic principles of physical and hydrocarbon chemistry to analyze and optimize industrial processes. Here are some examples of how these principles can be applied to solve chemical engineering problems:

1. Thermodynamics: Understanding the thermodynamic properties of substances and their behavior under different conditions is crucial in designing and optimizing chemical processes. For example, thermodynamics can be used to determine the optimal temperature and pressure for a reaction to take place or to predict the amount of energy required to separate a mixture of gases or liquids.
2. Kinetics: Chemical reactions can be analyzed using kinetic models that describe the rate of reaction and the factors that influence it, such as temperature, pressure, and the concentration of reactants. Kinetic models can be used to optimize reaction conditions, design reactors, and predict the yield of a reaction.
3. Transport phenomena: The study of transport phenomena, which includes the transport of mass, momentum, and energy, is essential in chemical engineering. For example, understanding the diffusion of chemicals across a membrane can be used to design more efficient separation processes, such as distillation or membrane filtration.
4. Organic chemistry: The principles of organic chemistry are important in the design and optimization of hydrocarbon-based processes, such as oil refining, petrochemical production, and polymer synthesis. Understanding the properties of different hydrocarbon molecules and their reactions with other compounds can be used to optimize the production of specific products.
5. Materials science: Chemical engineering often involves the design and development of new materials for specific applications. Materials science principles can be used to analyze the properties of different materials and to design new materials with specific properties, such as strength, durability, or conductivity.

Assignment Objective 2: Explain the solutions of complex engineering problems using the basic principles of physical and hydrocarbon chemistry.

To solve complex engineering problems, it is important to understand the basic principles of physical and hydrocarbon chemistry. Physical chemistry deals with the study of the properties and behavior of matter at the molecular and atomic level, while hydrocarbon chemistry deals with the chemistry of compounds containing hydrogen and carbon atoms, which are commonly found in fossil fuels.

When solving engineering problems, it is important to first identify the physical and chemical processes involved in the system under study. For example, in the design of a chemical plant, it is necessary to consider the physical and chemical properties of the reactants and products involved, such as their melting and boiling points, densities, and solubilities.

In hydrocarbon chemistry, it is important to understand the properties and behavior of hydrocarbons, including their ability to undergo reactions such as combustion, polymerization, and cracking. These reactions are crucial in the production of fuels and other products derived from hydrocarbons.

To solve engineering problems, it is often necessary to apply fundamental principles of thermodynamics, which describe the relationships between energy, work, and heat transfer in a system. Understanding the thermodynamic properties of a system can help engineers optimize processes to maximize efficiency and minimize waste.

In addition, knowledge of transport phenomena, such as mass transfer, heat transfer, and fluid dynamics, is essential in solving engineering problems related to processes involving fluids and gases.

Assignment Objective 3:Present solutions related to the chemical engineering in report and oral presentation.

Report:

Introduction:

Chemical engineering is a diverse field that encompasses various industries such as pharmaceuticals, petrochemicals, food and beverages, and environmental engineering. In this report, we will discuss some of the latest developments in chemical engineering and their applications.

Process Intensification:

Process intensification is an emerging field in chemical engineering that aims to increase the efficiency of chemical processes while reducing their environmental impact. One of the most promising technologies in this area is microreactors, which enable chemical reactions to take place in a small and controlled environment. This technology has several advantages, including better heat and mass transfer, improved reaction selectivity, and reduced waste production.

Renewable Energy:

Renewable energy is a critical area of research for chemical engineers, as it can help reduce greenhouse gas emissions and mitigate the effects of climate change. One of the most promising technologies in this area is the production of biofuels from biomass. Chemical engineers are developing new processes for converting biomass into biofuels, which can be used to power vehicles and generate electricity.

Carbon Capture:

Carbon capture is a process that involves capturing carbon dioxide from industrial processes and storing it underground to prevent it from entering the atmosphere. Chemical engineers are working on developing new and more efficient carbon capture technologies, such as solvent absorption and membrane separation. These technologies can help reduce the carbon footprint of industries and mitigate the effects of climate change.

Conclusion:

Chemical engineering is an ever-evolving field that plays a critical role in several industries. By developing new and more efficient technologies, chemical engineers can help reduce the environmental impact of industrial processes and contribute to a more sustainable future.

Oral Presentation:

Good morning, everyone. Today, I’m going to talk about some of the latest developments in chemical engineering and their applications.

Process intensification is an emerging field in chemical engineering that aims to increase the efficiency of chemical processes while reducing their environmental impact. One of the most promising technologies in this area is microreactors. Microreactors enable chemical reactions to take place in a small and controlled environment, which offers several advantages, including better heat and mass transfer, improved reaction selectivity, and reduced waste production.

Renewable energy is another critical area of research for chemical engineers. One of the most promising technologies in this area is the production of biofuels from biomass. Chemical engineers are developing new processes for converting biomass into biofuels, which can be used to power vehicles and generate electricity.

Carbon capture is a process that involves capturing carbon dioxide from industrial processes and storing it underground to prevent it from entering the atmosphere. Chemical engineers are working on developing new and more efficient carbon capture technologies, such as solvent absorption and membrane separation. These technologies can help reduce the carbon footprint of industries and mitigate the effects of climate change.

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