Modeling Energy Creation with Lagging Charge and a Quasi-Sinusoidal Variance in Capacitance

The law of conservation of energy has not been disproven. However, an inability to disprove this law is not proof of its validity. This article introduces a model, with the use of Ansys and MapleSim simulations, of how to create energy with a lagging current and a quasi-sinusoidal variance in a stator’s capacitance. That is, the stator’s mean capacitance is larger than its median, so that the top half of its waveform is larger than its bottom half. The device has two capacitive stators that are connected to a dc voltage, and a rotor with conductive segments, which incur electrostatic induction from the stator’s charge. The stator and dc voltage are connected in series with an electrical load and an oversized inductor. Upon rotation, a quasi-sinusoidal variance in the stator’s capacitance is established by the cyclical change in electrostatic induction within the segments. This variance in the stator’s capacitance, in combination with the oversized inductor, forms a lagging stator current. In turn, the stator charge’s corresponding peaks occur once while the stator’s capacitance is slowly decreasing, and once while the stator’s capacitance is quickly increasing. Therefore, a greater amount of torque is produced onto the rotor as the stator’s capacitance is increasing than when it is decreasing. This lagging current creates 6.58 W of mechanical average power, 10.77 W of electrical average power, and 1.11 W average power within its dc voltage source. This model provides evidence that energy can be created in opposition to the law of conservation energy.