The following content is specified for search engines and not for reason of understanding the concept of our technology.

We pass impulses through a reflectional symmetry and convert the emerging kinetic energy into electricity.

How our technology works?

1. We have a Symmetrical Condition (equilibrium)

a) Individually rotating heavy disks (high mass moment of inertia) are interlinked with springs.
b) At rest these springs are in a state of partial pre-compression.
c) The level of pre-compression dictates the inner stability of the arrangement.

2. We have an Asymmetrical Condition (mechanical chain-reaction)

a) Rapid acceleration on the first disk loads the first few springs and initiates an overlapping chain-reaction until the symmetry is back in its pre-compressed equilibrium.
b) The kinetic energy during the whole chain-reaction over time is greater than the rapid acceleration on the first element.

3. Realization

The model is idealized by using spiral springs, where the loading force is applied to the center. The compression energy is released on the outer circumference.

4. Benefits
These special asymmetrical conditions create angular velocity that is higher than the reflectional symmetry needed to regain the equilibrium (requires a minimum number of elements). The symmetry is not limited in a sense of rotational transformation and receives the benefit that a surplus on kinetic energy is present and can be transformed to electricity, hydrogen or fuel cells.

Our technology will open a realistic economic future to all hydrogen and fuel cell applications as the current environmental and economic costs to obtain these forms of fuels are immensely high due to the burning of fossil fuel.

Conclusion: Proofed by several demonstration models our results demand an aggressive development process.

 

Terawatt aims to access the energy mix and gain a market positioning by differentiating itself as a new way of generating electricity, harnessing the kinetic energy of a self compensating mechanical impulse.

Our Company is a company dedicated to the holding and managing of license rights and patent rights, research and development of prototypes, production and trading of goods of all types as of the inter session from finance and trade businesses.
We are developing a unique technology that is secured under different and up to date International Patents.

Tests on CP1 proves concept to "Generate Energy"

We are currently modifying and extending the unit to show a more differentiated energy balance.

TERAWATT, a Cheap, Fuel-less and Self-sustainable Energy Source

Elements are interlinked with springs. The specific layout permits self compensating equalization. To prevent any recoil, we use backstopping clutches. To collect the energy we use overrunning clutches.
Example : If the pre compression of each torsion spring is 500 N, the allowed torque of each applied generator is 200 N to achieve a fluent self-compensation of arranged elements.

The disks can only rotate in one direction (applied backstopping clutches). The rest tension (extended balanced condition) of each spring is higher than the friction in the arrangement (included tightening torque from generator on collector axis).

Concept Model DSS 1:Target of our first prototype was to establish:

• The right amount of disks
  
• The right weight of each disk (a perfect mass moment of inertia in accordance with the tension of springs results in a high defined impulse)
  
• The right rest tension of applied springs (in accordance with the friction in the arrangement and tightening torque of generator)
  
• The right amount of degrees and speed of the repeated burst on first Element.
• We established several basic tests in real world.
• We entered these results into numeric simulations.
  
  The outcome has lead us to realize a prototype and overcome Old Believes. A burst on one side of the stack causes all elements, one after the other, to turn forward.

TERAWATT ENERGY SOLUTION

Result after each impulse: The position of each disk to each other is exactly equal to its starting position. Each disk has been rotated one after the other (caused by its specific mass moment of inertia) in the new position predetermined by the first element burst. Reverse rotation is impossible by reason of backstopping clutches.

Following equipment must be understood or known to understand the function of our product.

Clutches:

• Clutch Functions (Overrunning clutch, Backstopping clutch)
• Overrunning Clutch (Design Styles)
• Principles of Operation) Big Applications

Brakes:

• Small Applications
• Big Applications
• High Resolution
• Interactive Wire Fusion

TERAWATT unit section

A certain amount in mass moment of inertia (specific weight of each disk) causes the absorption of the full charge in the respective springs.

• The disks in the stack are positioned at rest symmetrically to each other.
  
• Once disturbed (by bursting impulse on first element after DSS Loader) the elements (disks) constrain themselves forward until prior symmetric position is again reestablished.
  
• As the rest tension of each spring is calculated to be higher than the total friction, friction will only slow down the entire impulse but will not prevent that each spring will reestablish its extended prior state again and again after each initiated impulse.
  
• General rule: the rest tension between two interlinked elements should be 60% higher than
  the total torque in and on the system (friction on backstopping clutches, friction on overrunning clutches, tightening torque on generator etc.).

Pre-compressed Spring This charge, as it is never “0” Newton drives through the arrangement and extents the initial burst until it arrives at the
end of the stack.

Calculating additional Elements As mass x time x distance = energy, the driven impulse will always surpass the critical point,
where the total available momentum in all disks is higher then the momentum necessary to cause the burst. In order to surpass the critical point, we need a definite number of disks.

In order to gain energy out of the impulse, additional disks are added.

The total number of these added disks must be carefully calculated (depending on design and size of a specific system)
in order to obtain maximum efficiency.

Requirements

The functioning of the unit is guaranteed as long as the Tightening Torque in the System (TTS)*
does not exceed 50% of the Permanent Available Momentum (PAM)**.
*elements and generator
**average performance of interactive force between each element

Calculation of PAM (example):
If the spring is pre-compressed to 500 N and its maximum load is 1000 N, PAM = 750 N.
As PAM =750 N, TTS smaller equal 375 N. In general:

• RT (Rest Tension) should be 50% of maximum load of spring.
• PAM is the average performance of interactive force between each element.
• TS should not exceed 50% of PAM.
  

Dynamic Simulation proves Concept Through this applied resistance the impulse is in fact decelerated by 50% but nevertheless
the burst drives evenly through the whole arrangement and leaves a consistent momentum.

Dynamic Simulation proves Concept

Through this applied resistance the impulse is in fact decelerated by 50% but nevertheless
the burst drives evenly through the whole arrangement and leaves a consistent momentum.

• dynamic simulation1
• dynamic simulation2
  
  
  see also: Energy Flow of big power station

TERAWATT energy system The repeated process represents a New alternative Energy Source until the springs are depleted, than recycled and replaced.

Lifetime:

• Base Unit
  50-100 years

• Converters and Generators
  20-50 years

• Backstopping Clutches
  Sprockets need replacement after 10-15 years.

• Overrunning Clutches
  Sprockets need replacement after 10-15 years.
• Springs
  Depending on Alloy 10-15 years.

• Bearings 10-20 years