Unit 4003 Engineering Science I (J/651/0710) Assignment Brief 2026

Unit 4003 Engineering Science I Assignment Brief

Introduction

Engineering is a discipline that uses scientific theory to design, develop, or maintain structures, machines, systems, and processes. Engineers are therefore required to have a broad knowledge of the science that is applicable to the industry around them.

This unit introduces students to the fundamental laws and applications of the physical sciences within engineering and how to apply this knowledge to find solutions to a variety of engineering problems.

Among the topics included in this unit are: international system of units, interpreting data, static and dynamic fundamentals, fluid mechanics and thermodynamics, material properties and failure, A.C./D.C. circuit theories, and electromagnetic principles and properties.

On successful completion of this unit, students will be able to interpret and present qualitative and quantitative data using computer software, calculate unknown parameters within mechanical and electrical systems, explain a variety of material properties, and use electromagnetic theory in an applied context.

Learning Outcomes

By the end of this unit students will be able to:

LO1 Examine scientific data using both quantitative and qualitative methods

LO2 Apply the fundamentals of mechanical engineering systems

LO3 Explore the characteristics and properties of engineering materials

LO4 Analyse applications of A.C./D.C. circuit theorems, electromagnetic principles, and properties.

Essential Content

LO1 Examine scientific data using both quantitative and qualitative methods

Quantitative research methodologies and methods: 

Descriptive Research

Survey Research

Correlational Research

Quasi-experimental Research Design

Experimental Research

Relevant methodologies and methods.

Qualitative research methodologies and methods: 

Grounded theory

Ethnographic

Narrative research

Historical

Case studies

Phenomenology

Relevant methodologies and methods.

The scientific method: 

Question

Research

Hypothesis

Experiment

Data Analysis

Conclusion and Communication.

Interpreting data:

Investigation using the scientific method to gather appropriate data

Test procedures for physical (destructive and non-destructive) tests and statistical tests that might be used in gathering information

Summarising quantitative and qualitative data with appropriate graphical representations and appropriate use of an international system of units Exploring the usage of quantitative and qualitative data in engineering applications specific to occupation/sector (e.g., manufacturing, operations,  space systems, aeronautical engineering, etc.) Using software to analyse data

Using presentation software to present data to an audience.

LO2 Apply the fundamentals of mechanical engineering systems

Static and dynamic fundamentals:

Units, scalars and vectors, two-dimensional force systems, and moment (torque) and couple

Representing loaded components with space and free-body diagrams

Equilibrium in two dimensions, distributed forces, the centre of mass,  and centroids

Calculating support reactions of beams subjected to concentrated and distributed loads

Newton’s laws of motion, one-dimensional particle kinematics, one-dimensional particle kinetics, D’Alembert’s principle, and the principle of conservation of energy

Application of fundamentals and industrial case studies.

Fluid mechanics and thermodynamics:

Fluid definition and properties

Definition of pressure, hydrostatic pressure, and basic equations, manometry, application and calculations, Archimedes’ principle

Flow characteristics and definitions, introduction to ideal fluid flow

Continuity of volume and mass flow for an incompressible fluid

Bernoulli’s equation

Thermodynamic properties, temperature, the zeroth law of thermodynamic  and pressure, system and control volume, processes, and cycles

Energy and energy transfer, and heat and work transfer: definitions, units,  and sign convention

Ideal gas and equation of state, internal energy, enthalpy, and specific heats  of ideal gas

The first law of thermodynamics.

LO3 Explore the characteristics and properties of engineering materials

Engineering materials:

Material properties, classifications, and testing

Atomic structure of materials and the structure of metals, polymers,  and composites

Phase diagrams and analysis

Mechanical and electromagnetic properties of materials.

Material failure:

Destructive and non-destructive testing of materials

The effects of static, dynamic, and impact loading on a material Degradation of materials and hysteresis.

Material selection:

Desired application

Working conditions

Manufacturability and assembly considerations

Cost and availability

Environmental impact and sustainability Chemical and Physical properties.

LO4 Analyse applications of A.C./D.C. circuit theorems, electromagnetic principles, and properties

D.C. circuit theory:

Ohm law, Kirchhoff’s voltage and current laws

Voltage, current, resistance, power, and energy in D.C. networks composed of resistors, capacitors, and inductors.

Exploring circuit theorems (Thevenin, Norton, Mesh, Superposition, Maximum power transfer).

A.C. circuit theory:

Waveform characteristics in a single-phase A.C. circuit

Odd and even harmonics

VmaxSinω t ± α)

AC circuit analysis using Kirchhoff’s laws

RLC circuits; Impedance, reactance, admittance, phasors, Q factor, bandwidth, and resonance in RLC circuits.

Magnetism:

Characteristics of magnetic fields and electromagnetic force

The principles and applications of electromagnetic induction, self and mutual induction, solenoid, relay, transformer, motors, and generators

Single and three-phase power, AC and DC motor and control.

Learning Outcomes and Assessment Criteria

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