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Learning Objectives

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

Explore the process of inspecting propellers and rotor blades for damage and wear.
Learn to align and balance propellers and rotor blades for optimal performance.
Understand and apply aerodynamic principles in propeller and rotor blade repair.
Identify and correct issues related to pitch adjustments for efficiency.
Evaluate the impact of repair and balancing techniques on power transmission and overall aircraft performance.

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.

Relevant Course Packages All Course Packages →

Electrical Circuits and Systems Simulation

Electrical Circuits and Systems Simulation provides students with the knowledge and skills to design, analyze, and troubleshoot electrical circuits, with a focus on mechatronic applications. Through interactive simulations of DC and AC circuits, students will work with components like resistors, capacitors, inductors, and diodes. Using virtual oscilloscope and multimeter tools, students will measure voltage, current, and resistance, while receiving real-time feedback on circuit functionality, power ratings, and potential faults.

Kinematics and Dynamics of Machines

Train students in analyzing the motion and dynamics of mechanical systems and linkages using immersive XR simulations. Students will interact with virtual models of mechanisms such as gears, cams, pulleys, and crankshafts to observe and study their movement. The simulation offers interactive lessons on calculating velocities, accelerations, forces, and torques within mechanical linkages, with real-time feedback. The system will help students understand how to evaluate and optimize the efficiency of machines, force transmission, and performance.

Cardiac Arrest and Advanced Life Support (ALS)

Prepare students for cardiac emergencies using Advanced Life Support (ALS) techniques through immersive XR simulations. Students will practice performing CPR, defibrillation, airway management, and administering emergency medications while learning to recognize and respond to various heart rhythms.

Thermal Stress Management and Warping Prevention Simulation

The Thermal Stress Management and Warping Prevention Simulation teaches students how to manage thermal stress and prevent material warping during the welding process. It includes virtual scenarios where temperature changes and thermal expansion are monitored while welding. Students engage in exercises to adjust their welding methods, preheat/postheat treatment, or apply clamping techniques to minimize warping. Feedback is given on thermal stress, material distortion, and the effectiveness of preventive measures to ensure high-quality welds.

Pumping Systems and Sump Pump Installation

Explore the installation and maintenance of pumping systems, including sump pumps, to prevent flooding. Virtual practice in setting up discharge lines, configuring float switches, and performing routine maintenance to ensure system reliability.

Structural Analysis and Design

This XR simulation teaches students the principles of structural analysis and the design of buildings, bridges, and other infrastructures. Virtual scenarios allow students to analyze the strength, stability, and behavior of structures under various loads (e.g., dead loads, live loads, wind loads, seismic loads). Students use interactive tools to design beams, columns, trusses, and frames, selecting materials like steel, concrete, and timber. The simulation provides feedback on stress distribution, load-bearing capacity, safety factors, and compliance with engineering standards, helping students make sound design decisions.

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.