Mechanics of Solids and Fluids

Equip students with the foundational knowledge of solid mechanics and fluid dynamics, key principles in engineering applications. This course focuses on understanding the behavior of solid materials under stress and strain, as well as the movement of fluids within various engineering systems. Students will explore how these principles interact to optimize structural designs and fluid-based systems.

Learning Objectives

At the end of this simulation, you will be able to:

Apply concepts of stress, strain, and elasticity to analyze the mechanical behavior of solid materials under different loading conditions.
Use virtual simulations to calculate and interpret material deformation, understanding the limits of plastic and elastic deformation in engineering materials.
Utilize principles of fluid dynamics to analyze flow behaviors, pressure variations, and turbulence in fluid systems such as pipes, ducts, and open channels.
Apply mechanical and fluid system optimization techniques to improve structural designs and fluid flow efficiency in engineering applications.
Use virtual labs and simulations to identify and solve problems related to stress, strain, fluid flow, and system performance in practical engineering scenarios.
Assess the performance of materials and fluid systems under varying conditions, providing recommendations for improvements based on simulation results.

How do virtual labs work?

Enhance students' involvement in science by immersing them in interactive learning scenarios. Create simulations for experiments, provide hands-on training in laboratory techniques, and convey theoretical concepts through captivating visual experiences to improve their overall long-term learning outcomes.

Access web-based simulations that are compatible with laptops, Chromebooks, tablets, and iPads, eliminating the need for software installation.
Incorporate a teacher dashboard for automated grading and monitoring of student progress.
Utilize embedded quizzes to assist students in mastering scientific content.
Comprehensive repository of educational materials, including learning resources, lab reports, videos, theory pages, graphics, and more.

Microcontroller and Embedded Systems Programming

The Microcontroller and Embedded Systems module provides virtual environments (e.g., Arduino, Raspberry Pi) where students can design, simulate, and test embedded systems. Through interactive exercises, students learn to interface sensors, actuators, and communication modules, while writing and debugging code to control devices effectively.

Drug Delivery Systems and Microfluidics

Empower students to master the design and function of drug delivery systems with a focus on microfluidic devices for precise medication administration. Through immersive simulations, students will design and test microfluidic devices, optimizing fluid dynamics and dosage control for various medical conditions.

Vibration Analysis and Mechanical Resonance

This XR simulation enables students to analyze vibration patterns and mechanical resonance in rotating and reciprocating systems. They will interact with virtual scenarios where they can examine vibration frequencies, amplitudes, and damping within mechanical structures. The simulation guides students through detecting resonance, identifying sources of vibration, and implementing solutions to reduce noise and wear. Real-time feedback will focus on vibration analysis, system stability, and reliability, providing students with the skills to ensure the durability and optimal performance of mechanical systems.

Control Systems and Automation

This XR simulation trains students in designing and implementing control systems for automated mechanical processes. It provides virtual scenarios where students can program control systems, such as PID controllers, to regulate critical variables like temperature, speed, and pressure in automated systems. Interactive lessons cover feedback loops, sensors, and actuators used in automated machinery, with real-time feedback on the stability, precision, and response times of the control systems.

Advanced Machining Techniques (5-Axis Machining, EDM)

Explore XR-driven simulations of advanced machining techniques such as 5-axis machining and Electrical Discharge Machining (EDM). Students will virtually operate 5-axis machining centers to perform multi-axis operations on intricate parts and use EDM to machine hard materials with high precision. These simulations provide valuable hands-on experience in mastering advanced manufacturing processes. Feedback on part complexity, machining accuracy, and process optimization helps refine skills.

Weld Joint Preparation and Fit-Up

The Weld Joint Preparation and Fit-Up simulation provides hands-on virtual training in preparing materials and achieving proper joint alignment before welding. Through XR-enabled immersive scenarios, participants practice critical pre-welding tasks and receive real-time feedback to ensure precision and quality.

LMS Integration

imaginX seamlessly integrates with leading LMS (Learning Management Systems), enabling educators to track student performance and allowing students to maintain their work records. It is compatible with popular platforms such as Canvas, Blackboard, Moodle, Google Classroom, Schoology, Sakai, Brightspace/D2L, and can also be used independently of an LMS.