Solidworks

Solidworks, one of the most widely used in the market and is owned by Dassault Systems. Our Solidworks assignment help experts will help you in sizing and modelling of parts. It is popularity is attributed to its usage and relatively lower price compared to other software in this category.

Creo Parametric 4.0

Before rebranding it was known as Pro-E, it is part of the PTC suit, it shines when it comes to parametric design.

Solid edge & Siemens NX

It is a product from the Siemens, it quality is way ahead of Solidworks. Synchronous Technology where you can modify an individual part with ease at the assembly level. The NX package does come with CAM package.

CATIA

Catia can be described as Product Lifecycle Management software that is a complete set. The tools include CAM, CEA, CAD, CFD and advanced Ergonomics as opposed to Solidworks where you have to source third party software such as solid-CAM It is widely adopted in the Aerospace industry.

Autodesk Inventor

Inventor is a product from Autodesk, it is common among students because of a free license for the students. It works the same as Solidworks.

AutoCAD

AutoCAD by Autodesk, is the most popular in many industries and higher learning institutions. It can be used in 3D design though limited. These is attributed to:

• i.   It eases of use and availability of the learning materials
• ii. Has huge capabilities across major engineering fields
• iii. It is productive is unmatched when it comes to use of the command-line

On top of designing Mechanical Engineering assignment experts can further enhance your model by use of rendering software such as Keyshot and V-ray.

FEA and Simulation tools

Mechanical Engineering Assignment Help does include use of software for Finite Element Analysis. The most common ones include Ansys, Hypermesh, labView, Matlab, Cosmol, and Abaqus.

MATLAB

It is one of the most needed software as an engineer. It can be regarded as a general purpose piece of software. It requires modelling of data to solve complex mathematical and engineering problems. However as good as it sounds you have to write the code on your own. MATLAB is used across many engineering fields, where Chemical Engineering Assignment Help and Electrical Engineering Assignment Help may be needed.At engineeringtut.com we are ready to help you achieve higher grades and stress free academic life.

Ansys

Ansys is a general purpose software used in a number of engineering applications. Our Mechanical Engineering assignment help experts use it in projects of fluid dynamics, structures, physics, electromagnetism and heat transfer. It provides a virtual environment with which one can make 3D simulations replicating real life environment. In some cases, our experts import models from CAD software such as Solidworks, the mesh it after defining the loads. The results are viewed as graphical or numerical. Ansys workbench is a powerful and complex platform with a sole purpose of integrating the parametric CAD systems with simulation technologies. The power can be attributed to powerful algorithmic solver from Ansys.

LabView

LabView is a logic based simulation system. It finds its use in the testing of applications that require testing, measuring and control with a rapid and easy access to hardware and data insights. It finds its use in engineering control and instrumentation which is part of our Mechanical Engineering Assignment Help. Labview helps in the design of industrial equipment, design, develop and simulation of design systems with actuators and sensors. Also it is a greate piece of hardware in the design of wireless communication systems.

Cambridge Engineering Selector (CES) EduPack

Used in material and process selection in manufucturing and material selection

Ms Excel

This is one of the most important software as an engineering student. It helps in computation of complex structured data (in tables) with much ease. It has inbuilt formulae for easy computation. Also helps in presentation of tabular data into graphs. Its full power can be demonstrated by use of commands also by use of code.

Mechanical Engineering Assignment Help services Topics

Material science and engineering

Material science is one of the most researched areas in engineering related fields. Material science explains the relationship between a material structure and its properties. There are six major classes of materials: Biomaterials,Ceramics,Composites, Polymers, Metals and Semiconductrors

Classification of this materials is based on the chemical make up, the atomic structure, physical and engineering properties. A material electrical, mechanical, optical, thermal, deteriorative and magnetic properties are dependent on the chemical and physical structure of a material.

Our Mechanical Engineering Assignment Help experts have a solid years of experience having worked materials processing and manufacturing industry. Aluminum is one of the materials that is widely used in the thermal, electrical applications, transportation systems and construction materials. All this is attributed to its superior electrical and thermal properties, low cost and its relatively low density.

Steel is arguably the most used metal, its processing cost reducing thanks to the advances in steel processing which is even competing in terms of cost with the plastics in car bodies in the automotive industry. Steel is also used in the manufacture of machinery, heavy equipment and as reinforcement members. Alloys exhibit superior performance; a good example is stainless steel which is a steel alloy that has been specifically developed to be used in corrosive environments. Many other alloys have been developed for high temperature such as the gas turbines. Also there exists a category of special metals which are used in soft core magnets that are used in electric transformers and in electric motors. Our Mechanical Engineering Assignment Help experts will help you do research alloy development and material selection for a particular engineering application.

Ceramics is another important area in material science, their applications include areas where mechanical and chemical stability with low thermal conductivity is required. Some of the applications include: industrial furnaces and ovens, nose cone for the space shuttles. Our Mechanical Engineering assignment help experts use tools such CES Edupack for material selection or any other tool that the student specifies.

Microstructure and surface characterization

Microstructure analysis and surface characterization is core to mechanical engineering and entails: (TEM) transmission electron microscopy , (SEM) scanning electron microscopy, surface profilometry, diffraction techniques, energy dispersive spectroscopy (EDX) among other techniques.

• • Optical microscopy
• • Surface optical profilometry, Surface chemical analysis
• • Nano indentation
• • Transmission electron microscopy
• • Scanning electron microscopy
• • Crystallography & Electron diffraction
• • Energy Dispersive spectroscopy
• • Electro backscatter diffraction
• • Tomography
• • XRD, XPS, and scientific report analysis

Microstructure and mechanical properties

Microstructure- atomic structure dictates the mechanical properties of a material

• • Relationship between microstructure and mechanical properties
• • Explaining how strengthening occurs at microstructural level and how it is related to mechanical properties required of an alloy
• • Bonding and interatomic forces
• • Atoms, electrons, molecules and atomic structure
• • Structure imperfections and defects of solids
• • Microstructure and alloy design: phase diagrams; precipitation hardening and thermal processing
• • Kinetics in materials and process of kinetics
• • Mechanical properties: strain, stress, elasticity, tensile properties, strengthening mechanisms, grain growth, recovery and recrystallization
• • Failure of e: fatigue, creep, fracture and impact toughness; ductile, fracture and brittle failure.
• • Non-metals and their properties and their applications : glasses and ceramics; their structure and bonding; polymerization, thermosets and thermoplastics; cross linking; composites
• • Correct failure analysis using correct fracture mechanics
• • Bonding of non-materials including ceramics and polymers
• • Engineering materials and their applications

Composite design

Our experts will help you solve problems on mechanics of fiber-reinforced polymer materials and structure. Core composite design and mechanics encompasses 2D modelling; 3D continuum mechanics for anisotropic; laminate theory; structural modelling of composite plates and beams, damage and failure prediction. Our experts will help you do assignment and projects on deformation of failure of composite materials and structures and applications.

• • Properties, design, analysis and manufacture of composite materials
• • Application of composites
• • Type and properties of fibers & polymer resin materials:
• • Processing and manufacturing methods: mechanical properties
• • Failure and fracture
• • Laminae and laminates
• • Sandwich structures
• • Composite materials: thermosettings, matrix, fibers
• • Mechanics and Design: anisotropic materials, elastic behavior of lamina; mechanics of lamina, multidirectional lamina, structural analysis of lamina, stress and failure analysis, sandwitch structures, joining methods in composites.
• • Manufacture: resin infusion, molding, filament winding
• • Case study: automotive, aerospace, marine, energy etc.

Application of surface engineering include: power generation, oil and gas, marine, biomedical and aerospace sectors. Surface engineering entails assessment of micromechanical failure modes

Manufacturing and materials

There is a relationship between material properties, design and manufacturing processing. Some of the common manufacturing processes include: welding, casting, forming, 3D printing, cutting and composite manufacturing.

  Introduction and manufacturing process selection for design

• • Manufacturing process and shape it can produce
• • Product design specification
• • Selection of manufacturing process
• • Case study of product selection
• • Cambridge Engineering Selector (CES) EduPack use and its relevance to data and material selection and manufacturing

  Casting processes

• • Production of liquid metal and solidification
• • Metal casting in relation to: properties, design, economics, structure, quality, fusion and solidification

  Joining Process

Welding processes in relation to; design of joints, defects, quality, cost and service performance. Relationship between microstructure and weld properties.

  Metal forming

• • Bulk and sheet deformation process
• • Sheet deformation processes: bending, stretch forming, shearing and deep drawing
• • Selection of production method in relationship to structure requirements, formability of materials.

  Cutting and machining processes

• • Tool material
• • Economics of tool wear
• • Cutting processes

  Powder Process

• • Characteristics, flow, compaction and production

  3D printing and additive manufacturing

• • Principles of additive manufacturing

  Composite and polymer processing

• • Material structure and properties
• • Casting and polymer manufacturing and casting processes
• • Adhesive bonding for composites and polymers

Surface Engineering ( corrosion engineering )

Surface engineering entails study of material selection with respect surface characteristics in the environment of use. Our experts will help you assignments on:

• • Stress field: residue and induced stress, Hertz
• • Stress field and wear interactions
• • Coating and surface properties
• • Wear mechanisms: wear-corrosion, erosion, lubricated wear
• • Erosion resistant coatings: chemical and physical Vapour deposition, weld overlay, high velocity Oxy-Fuel
• • Plating & nano-composite surfaces/coating
• • Corrosion resistance surfaces / high temperature
• • Surface modification: carburizing, nitriding, carbo-nitriding, ion- implantation, induction hardening.

Biomechanical | Biomedical Engineering

Biomechanical engineering focuses on application of engineering principles together with medical and biological sciences in the design, manufacture of health care devices and equipment used in healthcare. Some of the areas Mechanical Engineering assignment help experts cover include Bio-instrumentation, involving application of computers and electronics together with engineering principles to develop instruments for diagnosis in healthcare sector.

Biomaterials, studies the naturally occurring materials for use in implantation devices and other medical devices. engineeringtut.com assignment help also helps students to research and assignments in Biomechanics, which involves study of mechanics to solve medical and biological related problems. One of the common areas which our experts have worked on is Rehabilitation engineering entailing a combination of engineering principles with computers to assist patients to recover from cognitive and physical impairments.

Mechanics

engineeringtut experts will help you do your assignments on projects related to mechanics, static, dynamics on solid bodies and engineering materials in general.

Mechanics assignment help services include:

•   Static bodies
• • Constructing a free body diagram and use them to solve a mechanics problem
• • Calculating action and reaction forces of a static body
• • Stress and strain calculation due to bending and torsion
• • Calculate critical buckling loads in structs
• • Writing lab reports on beam experiments: interpret the experimental data to deduce material and structural behavior; making theoretical assumptions, comparing experimental and practical results
• • Solving stress and strain problems using the Mohr’s circle
•   Dynamic bodies
• • Derive particle and rigid body trajectory equations
• • Work with equations of motion for rigid bodies
• • Apply the principles of work, energy and momentum in regard to particles and rigid bodies
• • Analysis of vibrations for 1 and 2 degree of freedom system

Our mechanical assignment help online provides most vibrant assistance to engineering students in solving the following:

•  Static systems Analysis
• • Identify and distinct different forces acting on the structure
• • Calculating equilibrium of particles and rigid bodies while calculating action and reaction forces
• • Calculate and plot diagrams of internal forces & momentum of a static beam
• • Use of the bending theory to determine the bending deflection in beams
• • Calculating bending induced shear stress and distribution in a beam under load
• • Determining and calculating forces in a member due to torsion
•  Dynamic Systems Analysis
• • kinetics and kinematics of particles, work done by forces. The potential, kinetic energy and momentum of rigid bodies.
• • Conservation of momentum, energy for particles and rigid bodies, motion of systems in 2D and 3D.
• • Working with lumped mass, stiffness and damper models
• • Calculating vibrations in a 1-2-3 degree of freedom systems using appropriate functions

Engineering Design

Design and computing two interrelated as pertaining to mechanical engineering. In this coursework students are expected to demonstrate knowledge and understanding of:

Our experts will assist you on tasks pertaining, engineering design, use of computers design, manufacture and writing and implementing computer programs using languages such as C, C++, Java, Python, Assembly Language among others. Python language is particularly powerful in data processing and visualization a great tool for solving numerical problems and for computational modelling.

Finite Element Analysis in solid Mechanics

Finite Element Analysis (FEA) provides and understanding to analyze engineering problem using commercial software tools including: ANSYS, Solidworks FEA and Abaqus.

• • Lagrange equation of dynamics of mechanical systems
• • Minimum potential energy problems using Rayleigh-Ritz method
• • FE matrices and equations of motion in structural dynamics
• • Boundary layer application
• • Use of ANSYS and Abaqus
• • 1D and 2D finite element analysis

Computing (Programming)

Our experts will help you do assignments on programming in C, Python, Java, assembly language among others. In assignments and projects students are required to demonstrate knowledge and understanding of:

Elon Writes design and computing assignment help consists includes

1. Programming assignment help building blocks involving, data types: strings, numbers, lists, tuples, variables, functions, objects, loops, modules, files, exceptions and testing; modular programming design patterns; data processing, visualization and computational modelling using libraries such as matplotlib, scipy, numpy, iPython, Spyder, Scipy among others.
2. Computational modelling assignment help building blocks involving, data types: strings, numbers, lists, tuples, variables, functions, objects, loops, modules, files, exceptions and testing; modular programming design patterns; data processing, visualization and computational modelling using libraries such as matplotlib, scipy, numpy, iPython, Spyder, Scipy among others.
3. Python, C and C ++ programming assignment help: working with functions, sequences, lists, dictionaries etc.; file IO, High order functions. Root finding, integration, interpolation etc.

Our experts will help you do assignments on programming in C, Python, Java, assembly language among others. In assignments and projects students are required to demonstrate knowledge and understanding of:

• • C – programming language
• • Combining Python codes with C
• • Show understanding of interpreted language vs compiled language
• • Version control and GIT
• • Code generation and symbolic methods
• • Shell commands
• • Write, compile and learn C- programs
• • Connect to a Linux server

Fluid Mechanics

Is the study of flow and forces within fluids. Fluid mechanics in summary:

• • Conservation of energy, mass and momentum
• • Laminar and turbulent boundary layer
• • Compressible and non-compressible fluid flow
• • Turbulent flow
• • Turbomachinery of fluid mechanics
• • Potential flow theory

Our fluid mechanics experts will help you:

• • Solve one or two dimensional flow problems by applying appropriate boundary conditions with appropriate boundary conditions.
• • Predicting the type of flow using the dimensionless units
• • Solve assignments on one-dimensional isentropic and non-isentropic
• • Solve problems on turbulent flow
• • Solve turbomachinery flow homework
• • Apply CFD methods and appropriate software such as ANSYS and Abaqus to achieve the same

Contents of fluid mechanisms can be divided into the following sections:

Viscous flow theory and boundary layers

• • Types of boundary layers
• • Boundary layers integral properties: displacement and momentum thickness and shape factor
• • Power law approximations for turbulence boundary layers
• • Drag for laminar and turbulent flow

Potential flow

Uniform flow, rankine oval, circulation, Laplace equation, Rankine oval, lifting flow over circular cylinder, Kuttaa condition and Kutta-Joukowski theorem.

Turbomachinery

Pump theory, centrifugal/ axial flow pumps, wind turbine among others

Compressible flow, Turbulence and CFD

• • Reynolds number and conservation equations
• • Fluctuating, mean quantities and kinetic energy, concept of eddy viscosity

Applications of CFD

Application of CFD includes grid and geometry generation, use of solvers, turbulence models in CFD software and interpretation of data. Some problems in CFD requires coding skills.

Our experts will help you solve problems pertaining CFD analysis, application of software such as ANSYS and Abaqus and write a comprehensive report.

• • CFD basics: RANS , Navier- Stroke, Continuity equation, numeric techniques in CFD, data visualization, mesh and geometry
• • Two pase flow/ boundary layer theory
• • Numeric procedures in CFD
• • Geometry and grid generation: surface and curve generation; dynamic mesh.
• • CFD solver packages: pressure solvers such as SIMPLE, PISO for incompressible flows and their implementation in commercial packages; programming in CFD packages.
• • Turbulence modelling
• • Interpreting of CFD results

Thermodynamics Assignment Help

Thermodynamics is one of the core mechanical engineering subject which requires students to analyze, design power propulsion, cooling and heating systems using thermodynamic principles.

Our Thermodynamic assignment help experts will help you in tacking problems in:

• • Calculating changes in thermodynamic properties due to: throttling, mixing, heat exchange and combustion etc.
• • Performance of IC engines, steam and vapor cycles, gas turbines and combined cycles.
• • Analyzing, designing and improving IC, aero, auto engines, refrigeration and power plants
• • Thermodynamic properties for real fluids and their calculations
• • Economic and environmental factors driving energy technology

Lab report

• • Analyzing experimental data
• • Designing and use of computer in modelling
• • Draw appropriate plots for analysis and justification of design decisions

Thermodynamics topics:

• • Thermodynamic properties
• • Analysis of thermodynamic processes ( turbines, compressors, nozzles, heat exchangers )
• • Combustion mechanisms and chemical equilibrium
• • Applications of Internal combustion engines: performance parameters, thermodynamic analysis; improving performance
• • Gas turbine analysis, power generation( intercooling, recuperation, reheating blade cooling ), gas turbines
• • Vapour cycles: condensable fluids, use of charts, tables; Rankine and Carnot power cycles; Effects of steam pressure and temperature; boiler efficiency
• • Boilers cycles: steam generation in bio-mass and coal power plants
• • Refrigeration and Psychrometry: mixture of water, air and application to air conditioning

Electrical and Electronics Systems

Electricity powers the world, most modern mechanical systems are a mix of mechanical and electrical components including, robots, modern cars, digital cameras among other systems. Electrical engineering are important in other engineering including ship science, astronautic, acoustic, mechanical engineering among others. As a mechanical engineer; electrical engineering concepts are used extensively in instruments and control.

Our experts will help you :

• • Assignments on application of Faradays law of induction
• • Solve problems calculating magnetic forces
• • Analyze circuits: inductors, capacitors, resistors using techniques including loop equations
• • Analyze Wheatstone bridge circuits of temperature and strain gauges
• • Apply circuit analysis techniques: mechanical systems modelling dynamics, flow in pipe networks control and heat transfer.

Some of electrical and electronic systems topic students cover include:

• • Electricity: Coulomb’s law, electrostatic forces, current, power and voltage
• • Circuit elements: Faraday’s and ohm’s law
• • Circuit analysis (DC): constructing loop equation, Kirchhoff’s laws, superposition and Thevenin Theorem.
• • Transistors and diodes
• • Operational amplifiers
• • Digital electronics: Logic circuits (Karnaugh Maps), Boolean algebra, sequential logic
• • Apply circuit analysis techniques: mechanical systems modelling dynamics, flow in pipe networks control and heat transfer.
• • Circuit analysis (DC): analysis of ac circuits, filter circuits, power, reactive power and power factor
• • Measurement systems: strain gauges, displacement sensors, transducers, temperature sensors, converters and filters
• • Transformers and other electrical machines; magnetic force production, DC machines, Faraday’s law

Electronics, drives and control

This coursework requires a student to design electro – mechanical control systems for general stability and smooth operations. Our experts will guide you through writing a Lab report.

Electronics

• • Frequency response ( magnitude & phases ) of passive circuits and Laplace notation for system transfer function
• • Amplifiers and their characteristics: integrators, differentiators, amplifiers
• • Time and frequency domains for signals and circuits
• • Protection diodes and voltage regulation
• • Filter circuit design, analysis and damping effects
• • A to D conversion and vise versa; sampling and aliasing
• • Digital circuits: CMOS and interface circuits, microprocessors, relays and memories

Motors and Drives

• • Motor speed control
• • Electric machines and torque speed characteristics
• • Power switches and their controls
• • Variable speeds

Control

• • Linear systems theory: mathematical modelling, time domain analysis, design and performance measurement
• • S – domain system representation: Laplace transform and system transfer function
• • System poles and zeros, absolute and relative stability
• • Variable speeds
• • Final value theorem and steady-state error
• • Closed-loop system transfer function, PID control systems
• • Frequency response of linear systems

Computing

• • The Arduino microprocessor integrated development Environment
• • Sensor communication (ultrasonic, infra-red, GPS, accelerometer and pressure)
• • Digital – analog conversions
• • Control of servos and motors
• • Arduino real-time processing with Arduino microcontroller