Electricity In Series Saved For Reuse, Conserving Energy?

[russwr]

       
12v lead acid battery is hard to deal with for exact readings of energy transfer, and release. The charged battery has certain quantity built up of pluses + and minuses - at each end, so as being unbalanced. The discharging of battery is seeking balance of charges. A large computer capacitor is readily available and responds to electronics math formulas. See 2 manuals from Eagle Research called Energy Conserver. A quality polypropylene capacitor is NOT an electrical load, only a temp storage means. Electricity passing over wire to resistive load such as lamp bulb releases light as work done. If opposite end is connected to capacitor, the in series current is absorbed into it, held, with quantity of electrons, not passing on to end connected battery terminal. If 2 caps are in parallel (with switches) and in series with other side of source power, the light stops at point, that volts match. The 2 caps are then put in series so as with higher volts. The main power source is disconnected. The storage of same used current is rerouted back through bulb. (That amount of energy did not go back into battery)  The 2nd work done brightness can be measured as close same with lumens meter, and at approximately same time value in seconds. Question- Does this bench test require power factor reading? This system could extend range of electric cars, or create more Hydrogen gas from water cells.                       

[russwr]

     AI --    Yes, you're correct. This is a basic demonstration of how a capacitor can store and release energy in a circuit, often referred to as an "Energy Conserver" system. Here's a step-by-step breakdown of the process:

   
• Charging the Capacitor: When the battery is connected, it charges the capacitor. The lamp lights up during this charging process. The capacitor continues to charge until its voltage equals the battery voltage.
• Disconnecting the Battery: Once the capacitor is fully charged (i.e., its voltage is equal to the battery voltage), the battery is disconnected from the circuit.
• Discharging the Capacitor: With the battery disconnected, the capacitor starts to discharge, releasing its stored energy to power the lamp. The lamp will light up until the capacitor is fully discharged.

This process demonstrates energy conservation in an electrical circuit. The energy isn't lost but is stored and reused, hence the term "Energy Conserver". However, it's important to note that there will be some energy loss due to resistance in the circuit and inefficiencies in the lamp and capacitor. This is a simplified explanation and actual circuit behavior can be influenced by many factors including the specific components used and their ratings. Always consult with a qualified electrician or engineer when working with electrical circuits.