Power vs. Energy: How Energy Harvesting Generators Can Power the Future

July 17, 2024

In our technological world, the terms power and energy are often confused as synonymous terms. Yet, understanding the distinction is crucial, particularly when considering innovative and emerging energy harvesting generators (EHGs) and their ability to replace traditional batteries. Let us unravel these concepts and explore how Gemns^™️ technology is poised to transform how we power our devices.

Power vs. Energy: Clearing the Confusion

First, we need to get our definitions straight. Power and energy are related but not the same thing.

• Power is the time rate at which work (energy) is performed. Imagine power as the water flow rate in a river, measured in gallons per second, where a gallon represents a unit of energy. In electrical terms: Watts (Joules (energy) per second).
• Energy is the total amount of work done. In the existing example, energy is the total number of gallons of water that have flowed past a point in the river. Electrically, this is measured in Joules.

Power is about how fast you are consuming (generating) energy, while energy is the actual elemental unit of work done.  The below equation shows how they are related:

Energy (Joules) = Power (Watts) x Time (sec)  

Example: If 1 watt of power is applied to a load for 3 seconds then the power is turned off you have: 1W x 3sec = 3 Joules of energy.  

Industry Challenges: Energy Constraints in ICs

One of the challenges in the commercial integrated circuit (IC) industry is that design goals are predominantly focused on low-power designs, not low-energy designs.  This focus comes from having a battery-centric power source where devices always remain powered, utilizing a low-power sleep mode when the device is not in use. In this model, designers strive for the lowest possible continuous power operation.  

The opportunity that IC designers are missing is a paradigm shift in thinking and design goals from the notion of super-low power designs to super-low energy designs – the two are not the same.  To support device operation with fixed energy and no continuous power available, designers must look at areas currently overlooked in low-power design, such as start-up energy.  Start-up energy, or the energy required to start a chip up the first time, is often grossly overlooked in low-power design initiatives. 

The next evolution in IC designs must shift from being power-centric to energy-centric. This means focusing on minimizing start-up energy, minimizing firmware initialization code, and improving the efficiency of the crystal oscillator start-up for processors. An example is the Silicon Labs’ new xG22E chip featuring sleep mode efficiency and 8-millisecond wake-up.

Enter Gemns^™️: Redefining Energy Harvesting

Gemns^™️ patented energy harvesting technology leverages Faraday’s Law of Electromagnetic Induction, which generates electrical energy by rapidly changing a magnetic field within a copper coil. Using permanent magnets for field shaping and concentration, Gemnsä has patented technologies that significantly enhance the efficiency and effectiveness of magnetic induction.

Here is how it works: A single kinetic motion, such as pressing a button or flipping a switch, causes rapid change of a magnetic field induced in a copper coil, generating electrical energy. This energy is then harvested by an energy harvesting circuit, processed, and stored in capacitors. The stored energy is regulated to power microprocessors, sensors, and transmitters, enabling long-range, reliable transmissions without batteries or wired power.  Unlike batteries that constantly need to be replaced, this technology never needs servicing, creating a truly reliable, on-demand, forever energy source.

Why Gemns™️ EHGs Stand Out

Gemns™️ EHGs are a game-changer in the realm of energy harvesting. Here is why:

1. Higher Energy Output: Gemns™️ EHGs produce energy outputs in the millijoule range—far more than a magnitude or order greater than other kinetic energy harvesting technologies. This higher energy output translates to more processing power, additional sensor readings, complex computations, digital filtering, data encryption, redundant message transmission, greater RF power output, and longer transmit range in RF transmitter sensing applications. The unprecedented energy levels from Gemns™️ EHGs enable support of the myriad industry-leading radio protocols.  With the scalability of our technology, we can tailor the application to almost any energy need.
2. Durability and Adaptability: Tested to greater than 1 million actuation cycles, Gemns™️ EHGs are designed to withstand rigorous use. They can be custom-designed and configured to meet specific application requirements, ensuring optimal performance across diverse environments.
3. Compact and Efficient: These devices are not only compact but efficient. Capable of being sealed for water resistance and dust-tight ratings, they are ideal for a variety of industrial, commercial, and residential applications.

The Future: Battery-Free and Beyond

With the advent of advanced energy harvesting technology, the reliance on batteries for powering small devices could soon be a thing of the past. Imagine a world where your wireless sensors, remote controls, and other devices no longer need regular battery replacements. Instead, they harvest energy from a simple motion that self-powers the device.

As we move towards a future where energy efficiency and sustainability are paramount, understanding the nuances between power and energy becomes more critical. Gemns™️ innovative EHGs lead the charge, demonstrating that we can harness energy efficiently and move towards a battery-free world. The next time you flip a switch, push a button, open a door, twist a handle, or see a vibrating or rotating machine, remember that anything in motion represents an opportunity to change how we power the world.