The ACEL Tunnel Project is dedicated to expanding human and machine capabilities by developing a groundbreaking kinetic launch system. Our goal is to facilitate the transfer of intelligence and resources to other planets and stars, ensuring the safety and evolution of both biological and silicon-based life forms.
Our technology leverages a coil gun mechanism within a vacuum-sealed tunnel to achieve efficient and cost-effective space launches. By accelerating payloads smoothly to Mach 20, we can safely transport biological and silicon-based payloads into orbit.
The coil gun mechanism uses electromagnetic fields to accelerate payloads. Unlike rail guns, which cause excessive friction and wear, our coil gun operates in a vacuum to reduce resistance and energy loss.
Dual EMF fields are employed to center the payload and propel it through the tunnel. The first field keeps the payload aligned, while the second pulses to generate the necessary acceleration.
Maintaining a vacuum along the 80km tunnel is crucial for reducing air resistance. Continuous vacuum pumps and a plasma shield at the tunnel exit ensure the vacuum is preserved, allowing for efficient energy transfer.
Our system reduces the cost of launching payloads to orbit to $1/kg, a 1000x improvement over traditional rocket launches. This cost-efficiency opens new opportunities for space exploration and resource management.
Students rotate through subjects in 20-minute sessions, followed by 10 minutes of testing, ensuring engagement and personalized learning.
Instead of waiting until 18-21 for full agency, this system maximizes memetic content upload, preparing graduates to contribute to humanity's acceleration.
Our project is structured in
progressive
phases to ensure technical feasibility and scalability.
Each
phase will build on the previous one, increasing the tunnel length and launch parameters.
Initial testing phase to validate the coil gun mechanism and vacuum conditions.
Scaling up to test sustained acceleration and EMF field stability.
Further testing to refine material science and energy transfer methods.
Final phase to achieve full operational capability, launching payloads to Mach 20.