GEMM
Gravity Energy Motion Machine
Published 06/02/2025
The GEM.M system represents an innovative approach to land-based energy generation, leveraging the principles of mechanical inertia, gravity, and pulsed energy within a controlled environment to produce electricity. The core concept involves a significant mass weight, which moves from a height to initiate motion, utilizing gravity to its advantage. This mass is attached to an arm, rotating around a central axis at an angular velocity. The system's design is such that the mass's motion drives generators. This setup not only mimics the idea of perpetual motion but does so in a manner that complies with thermodynamic laws by relying on an external power source for initial start-up and to maintain operation through periodic energy pulses.
One of the unique aspects of GEM.M is its potential for energy efficiency and cost-effectiveness. Initially, the construction and maintenance of each system were estimated at $15 million, but with scaling, this cost could be reduced significantly. This economic model positions GEM.M as a competitive alternative to traditional energy sources, especially when considering the lifecycle costs of coal or nuclear power stations. The system aims for a minimal efficiency loss, with an initial projection of a 15% reduction due to friction, air resistance, and pulse technology inefficiencies. However, with the integration of a spring system, this loss could be minimized, potentially improving efficiency to around 92%. This spring system introduces an oscillatory motion, storing potential energy and modulating torque, which contributes to energy recycling within the system, reducing the need for external energy inputs.
The design philosophy of GEM.M also includes a cleanroom environment, which is crucial for maintaining the efficiency of the system by minimizing external contaminants, reducing air resistance, and managing noise pollution through specialized fabrication within the warehouse. This controlled setting enhances the system's performance by creating conditions that are optimal for mechanical operation, reducing energy losses that would occur in a typical industrial setting. The integration of energy harvesting concepts, like piezoelectric or electromagnetic methods, further enhances the system's efficiency by capturing energy that would otherwise be lost, aligning with Australia's push towards sustainable energy solutions.
In terms of scalability and integration, GEM.M is envisioned to work where 300 systems could theoretically replace the output of one coal power station, integrating seamlessly into city simulations or industrial complexes. This would not only contribute to renewable energy targets but also offer a sustainable, low-emission alternative to traditional power generation methods. The system's design allows for energy sharing between units, where two operational units could provide the necessary energy to start a third, promoting an internal energy distribution for efficiency.
This technology, with its focus on efficiency, cost reduction, and environmental friendliness, could indeed become a pivotal player in our journey towards zero emissions and sustainable energy production.
This means that 1 system (3 units per system) would produce the same energy as a 3MW wind turbine annually.
This image depicts a conceptual design of a motion machine,
which is theoretically meant to operate with an energy pulse
input.
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GEM.M system is unique in that it combines rotational inertia,
gravity, pulsed energy assistance, and continuous motion
into a single system.
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Inertia, gravity, pulsed energy, and continuous motion work
together in the GEM.M system. the system is theoretical
but it could be brought closer to reality with research and development.
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Let's break down how these might interact in a theoretical design:
Inertia and Gravity: Inertia is the property of an object to resist
changes in its state of motion. When combined with gravity, an object
in motion could theoretically maintain some movement due to its
inertia, but it would still face energy losses from friction and air
resistance. Gravity could provide a continuous force, like in a
pendulum, but even pendulums eventually stop due to these losses.
Pulse Electronic Device: Assuming this device could manage the energy
flow in a precise manner, it might help in optimizing the transfer of
kinetic energy (from the movement caused by gravity and inertia) into
another form. However, this device would still need an external energy
source to operate. The pulse electronic device plays a crucial role in the operation of the GEM.M system, acting as a control mechanism to optimize energy transfer within the machine. As the system moves through its rotational cycle, the pulse device precisely times short bursts of electrical energy to counteract losses from friction and resistance, ensuring continuous motion. This pulse assists in maintaining the system’s kinetic energy, much like how a cyclist provides periodic pedaling to sustain movement without requiring constant exertion. By synchronizing with the system's natural inertia and gravitational forces, the pulse electronic device enhances efficiency, allowing the GEM.M system to generate and return energy effectively within an optimized cycle.
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In summary, while inertia, gravity, and a pulse electronic device
could theoretically be combined to create a system where natural
movement powers a turbine, this system would not be perpetual. It
would need to be part of a larger energy ecosystem where energy input
(like lifting the weight back up to start the cycle again) is
provided, or where the system is designed to work within the
constraints of energy conservation.
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The idea involves creating a system where interconnected setups
use grid energy initially to start the process, and then leverage
gravity, gears, and other mechanical means to generate and return
energy to the grid. This concept is interesting and aligns with energy
harvesting and regeneration principles in engineering.
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Power Calculation for 2.5 rad/s
Given Values
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Mass (mmm) = 3000 kg
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Arm length (rrr) = 15 m
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Gravity (ggg) = 9.81 m/s²
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Angular velocity (ω\omegaω) = 2.5 rad/s
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Power formula: P=rmgωP = rmg\omegaP=rmgω
Power Output for One Unit
P=(15 m)(3000 kg)(9.81 m/s2)(2.5 rad/s)P = (15 \text{ m}) (3000 \text{ kg}) (9.81 \text{ m/s}^2) (2.5 \text{ rad/s})P=(15 m)(3000 kg)(9.81 m/s2)(2.5 rad/s) P=1,103,625 W=1.1 MWP = 1,103,625 \text{ W} = 1.1 \text{ MW}P=1,103,625 W=1.1 MW
Power Output for One System (3 Units)
Psystem=1.1 MW×3=3.31 MWP_{\text{system}} = 1.1 \text{ MW} \times 3 = 3.31 \text{ MW}Psystem​=1.1 MW×3=3.31 MW
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Comparison with Large-Scale Power Generation​
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Coal Power Plant (~1000 MW): You would need ~302 systems (each with 3 units) to match a 1000 MW coal plant.
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Wind Turbine (~3 MW each): One GEM.M system (3 units) is similar in output to a single large wind turbine at 2.5 rad/s.
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Hydropower Plant (~500 MW): You would need ~151 GEM.M systems to match a medium hydroelectric dam.
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Central Axis
Comparison with Modern Energy Production:
Wind Turbines As mentioned earlier, a single modern wind turbine with
a capacity of 3 MW can produce an average of about 1,050 kW.
Solar Farms A utility-scale solar farm might have a capacity in the
hundreds of megawatts.
Coal/Nuclear/Gas Power Plants These large thermal power plants often
have capacities in the gigawatt range. A 1 GW coal plant, as we
calculated, would produce 500,000 kW on average
Efficiency in Energy Conversion: Modern generators and converters are
highly efficient. Engineering could focus on optimizing the conversion
from mechanical to electrical energy, possibly pushing efficiency
beyond the 80% we've assumed.
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ChatGPT AI IMAGE
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The Gravity Energy Motion Machine (GEM.M) is an innovative energy system that works by combining gravity, inertia, rotational motion, and a pulsed energy boost. Imagine pushing a swing—once it starts moving, it keeps going because of inertia, which is an object's natural tendency to stay in motion. The GEM.M unit starts with a small amount of external energy to get it spinning. Then, gravity and inertia help keep it moving with minimal extra effort. A pulse electronic device provides occasional energy boosts to counteract friction and prevent slowdowns. This continuous motion is converted into electricity, making the GEM.M system a promising alternative energy source. With three units working together, a single system produces power comparable to a wind turbine, offering a sustainable and efficient way to generate energy.
CRAIG BRIAN PETER COYLE
Founder | INTREPID ARTS AUSTRALIA
Diversified Investment Solutions
