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.

Biomechanics and Motion Analysis

Explore the principles of biomechanics and motion analysis through immersive XR simulations. Students will analyze human movement, understand forces acting on the body, and assess the performance of musculoskeletal systems in dynamic environments, enhancing their ability to apply these concepts to health, sports, and rehabilitation.

Protein Engineering and Biochemistry

Train students in essential techniques for protein expression, purification, and analysis, with immersive XR experiences to explore biotechnology applications. Focus on recombinant protein expression, purification methods, and enzyme activity analysis, along with designing proteins with improved properties through interactive virtual labs.

Airflow and Duct Design Simulation

The Airflow and Duct Design Simulation trains students in calculating airflow requirements and designing ducts to ensure HVAC systems operate efficiently. The simulation features virtual tools for calculating airflow based on building dimensions and heating/cooling loads. Students engage in interactive duct design exercises, where they size ducts, select materials, and place vents for optimal airflow. Real-time feedback is provided on pressure loss, air distribution efficiency, and adherence to industry standards.

Spacecraft Design and Orbital Mechanics

Dive into the design and analysis of spacecraft for space missions, focusing on key components like propulsion, thermal control, and communication systems. Use virtual tools to create satellites, space probes, and crewed spacecraft while mastering the principles of orbital mechanics. Learn to calculate orbital trajectories, understand gravitational effects, and simulate spacecraft maneuvering in space. Receive feedback on mission planning, fuel efficiency, and spacecraft stability in various orbits to optimize space exploration projects.

Control System Design and Tuning

Explore the design, simulation, and tuning of control systems for mechanical and electrical applications. Through interactive simulations, students will design feedback control systems using PID (Proportional-Integral-Derivative) controllers to regulate variables such as speed, temperature, or position. Real-time feedback will help students evaluate control system stability, response times, and error minimization for optimal system performance.

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.