C/M Electric + Air Flow

 

THE SHIELD

C/M Electric + Air Flow

THE LARGEST ENERGY BREAKTHROUGH ON EARTH 

EV Electric Generation. Ev Electric Flow + Air Flow + Conversion 

Dr Sydney Nicola Bennett's self-refilling Air Compression concepts refill as they go & once engaged continually regenerate usable Energy for storage or use perpetually for all Stationary & Motion applications 

The largest Energy breakthrough in history on earth 

1988-1993 / 1994-1995 & patented, copyrighted & trademarked between 1996-2001 in 100-170 of 195 countries as initially created at 75 Catharine Dr in East Ferris Township in Ontario Canada behind the Freshmart

Innovations since leading up to 2024-2025 involve real world larger scale applications adapted internationally for safe Zero Emisisons Energy through S.B.G of CIG In-House Brands & partners 

Proper.

https://youtube.com/shorts/Ka_QrEL57k4?si=0TgqjntYTi3Kv1Sh

ELECTRIC FLOW 

To speed up the flow of electricity, you can increase the voltage or decrease the resistance within the circuit. This is based on Ohm's law, which states that current is directly proportional to voltage and inversely proportional to resistance. Increasing the voltage or decreasing the resistance will result in a faster flow of electrons, effectively increasing the current. 

Here's a more detailed explanation:

• Voltage:

Voltage is the electrical potential difference that drives the flow of electrons. Increasing the voltage essentially pushes the electrons with more force, causing them to move faster through the conductor. 

• Resistance:

Resistance is the opposition to the flow of current. Reducing resistance allows electrons to move more freely, increasing the speed at which they travel through the circuit. 

• Current:

The flow of electrons is called current. By either increasing voltage or decreasing resistance, you can increase the current and thus the speed at which electricity flows. 
Methods to increase current (and therefore speed):

• Increase voltage: Use a higher voltage power source. 

• Reduce resistance:

• Use a larger diameter wire, which has lower resistance. 

• Use a conductor with lower resistivity. 

• Minimize the length of the wire, as longer wires have higher resistance. 

• Reduce impedance: Impedance is the resistance to alternating current (AC). Reducing impedance also allows for faster current flow. 

Understanding the basics of electricity by thinking of it as water

The fundamental laws of electricity are mathematically complex. But using water as an analogy offers an easy way to gain a basic understanding.

Electricity 101 – Voltage, Current, and Resistance

The three most basic components of electricity are voltage, current, and resistance.

• VOLTAGE is like the pressure that pushes water through the hose. It is measured in volts (V).

• CURRENT is like the diameter of the hose. The wider it is, the more water will flow through. It is measured in amps (I or A).

• RESISTANCE is like sand in the hose that slows down the water flow. It is measured in ohms (R or Ω).

Voltage, current, and resistance are all related. If you change one of them in a circuit, the others will change, too. Specifically, voltage is equal to current multiplied by resistance (V = I x R). Thinking about water, if you add sand into the hose and keep the pressure the same, it’s like reducing the diameter of the hose… less water will flow.

Electricity 201 – DC, AC, Batteries, and Transformers

How does electricity work in electronics and the grid?

DIRECT CURRENT or DC is similar to the normal flow of water in a hose – it flows in one direction, from the source to the end. Historically, DC was originally championed by Thomas Edison in the famous Current Wars of the late 1800s. DC lost the war for the grid but it has found an even more exciting role in modern electronics like computers, phones, and televisions.

ALTERNATING CURRENT or AC is like the water flowing back and forth within the hose many times per second. The water analogy breaks down a little here but AC is easily created by electric generators (also called alternators). Nikola Tesla and George Westinghouse championed AC over DC and they eventually prevailed. AC is now the global standard for delivering electricity to homes and buildings via the grid.

BATTERIES can be thought of as water pumps that circulate water through a hose that travels in a closed loop back to the battery. There are many metrics used for the capacity of batteries and not all are immediately logical. They include amp-hours and kilowatt hours. Batteries can only generate DC power.

TRANSFORMERS are like holding your thumb partially over the end of the hose to get the water to spray farther. The water volume (power) remains the same but the pressure (voltage) increases as the diameter (current) decreases. This is exactly what transformers do for overhead powerlines. The electricity can travel farther with fewer losses because the resistance (sand) doesn’t impede the electricity (water) when the current is lower (smaller diameter hose). Transformers only work with AC. The ability to move electricity over long distances is the main reason AC beat out DC a century ago.

Electricity 301 – Power and Energy

Now, let’s keep using the hose analogy to dive into the murkier waters of circuits (pun intended, sorry).

POWER is like the volume of water that is flowing from the hose, given a specific pressure and diameter. Electric power is measured in watts (W). And larger systems are measured in kilowatts (1 KW = 1000 watts) or megawatts (1 MW = 1,000,000 watts).

ENERGY is like measuring the volume of water that has flowed through the hose over a period of time, like filling a 5 gallon bucket in a minute. Electric energy is often confused with electric power but they are two different things – power measures capacity and energy measures delivery. Electric energy is measured in watt hours (wh) but most people are more familiar with the measurement on their electric bills, kilowatt hours (1 kWh = 1,000 watt hours). Electric utilities work at a larger scale and will commonly use megawatt hours (1 MWh = 1,000 kWh).

https://www.freeingenergy.com/understanding-the-basics-of-electricity-by-thinking-of-it-as-water/

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