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The Electric Power Research Institute (EPRI) recently published a document titled "High-Altitude Electromagnetic Pulse Hardening Pilot Projects: Status and Future Research." This document highlights a 3-year study on the potential impacts of high-altitude electromagnetic pulse (HEMP) on the electric transmission system. APELC is prominently featured in the EPRI article for our 2m RS105 system, a prime example of radiated susceptibility testing for grid components against the HEMP E1 waveform. Our systems have played a vital role in supporting EPRI's HEMP testing endeavors. The work conducted by EPRI, leveraging APELC's equipment, is of utmost importance in safeguarding the power and utility infrastructure of our nation. By providing practical recommendations and guidelines for shielding and safeguarding the grid, EPRI empowers utility customers to effectively mitigate the threats posed by high-altitude nuclear events. Learn more about our EMP Test System in use at EPRI in our latest blog: https://bit.ly/3KcmtXD

An electromagnetic pulse, or EMP, is a burst of electromagnetic radiation that can disrupt or damage electronic devices. EMPs can be caused by natural phenomena such as solar flares or by human-made devices such as nuclear weapons. Many people are curious about how solar power systems would fare in the event of an EMP. In this blog, we will explore whether or not solar power would work after an EMP and what steps can be taken to protect solar power systems. Can Solar Power Systems Survive an EMP? Solar power systems are made up of a variety of electronic components, including solar panels, inverters, and charge controllers. While solar panels themselves are not vulnerable to EMPs, the electronic components in the system can be damaged by the high-energy burst of electromagnetic radiation. However, the likelihood of an EMP damaging a solar power system is relatively low. Solar power systems are designed to withstand a certain amount of electromagnetic interference, and the likelihood of an EMP strong enough to completely destroy a solar power system is relatively low. What Can be Done to Protect Solar Power Systems? There are several steps that can be taken to protect solar power systems from the effects of an EMP. One option is to install surge protectors on the solar power system’s electronic components. Surge protectors can help absorb the excess energy from an EMP and prevent it from damaging the system. Another option is to install a Faraday cage around the solar power system. A Faraday cage is a metallic enclosure that can protect electronic devices from electromagnetic radiation. By enclosing the solar power system in a Faraday cage, the system can be protected from the effects of an EMP. Conclusion While there is some risk of damage to solar power systems in the event of an EMP, the likelihood of a complete system failure is relatively low. By taking steps to protect the system’s electronic components, such as installing surge protectors or a Faraday cage, solar power systems can be made more resilient in the event of an EMP. As solar power becomes more prevalent as a source of energy, it is important to consider the potential risks and take steps to protect these valuable systems. Read more - https://lnkd.in/dGgdns_h . . . #SOLARIZEUSA #SolarEnergy #RenewableEnergy #GreenEnergy #CleanEnergy #SolarPower #SolarPanels #Solartechnology #SolarIndustry #GoSolar

An electromagnetic pulse, or EMP, is a burst of electromagnetic radiation that can disrupt or damage electronic devices. EMPs can be caused by natural phenomena such as solar flares or by human-made devices such as nuclear weapons. Many people are curious about how solar power systems would fare in the event of an EMP. In this blog, we will explore whether or not solar power would work after an EMP and what steps can be taken to protect solar power systems. Can Solar Power Systems Survive an EMP? Solar power systems are made up of a variety of electronic components, including solar panels, inverters, and charge controllers. While solar panels themselves are not vulnerable to EMPs, the electronic components in the system can be damaged by the high-energy burst of electromagnetic radiation. However, the likelihood of an EMP damaging a solar power system is relatively low. Solar power systems are designed to withstand a certain amount of electromagnetic interference, and the likelihood of an EMP strong enough to completely destroy a solar power system is relatively low. What Can be Done to Protect Solar Power Systems? There are several steps that can be taken to protect solar power systems from the effects of an EMP. One option is to install surge protectors on the solar power system’s electronic components. Surge protectors can help absorb the excess energy from an EMP and prevent it from damaging the system. Another option is to install a Faraday cage around the solar power system. A Faraday cage is a metallic enclosure that can protect electronic devices from electromagnetic radiation. By enclosing the solar power system in a Faraday cage, the system can be protected from the effects of an EMP. Conclusion While there is some risk of damage to solar power systems in the event of an EMP, the likelihood of a complete system failure is relatively low. By taking steps to protect the system’s electronic components, such as installing surge protectors or a Faraday cage, solar power systems can be made more resilient in the event of an EMP. As solar power becomes more prevalent as a source of energy, it is important to consider the potential risks and take steps to protect these valuable systems. Read more - https://lnkd.in/dGgdns_h . . . #SOLARIZEUSA #SolarEnergy #RenewableEnergy #GreenEnergy #CleanEnergy #SolarPower #SolarPanels #Solartechnology #SolarIndustry #GoSolar

An electromagnetic pulse, or EMP, is a burst of electromagnetic radiation that can disrupt or damage electronic devices. EMPs can be caused by natural phenomena such as solar flares or by human-made devices such as nuclear weapons. Many people are curious about how solar power systems would fare in the event of an EMP. In this blog, we will explore whether or not solar power would work after an EMP and what steps can be taken to protect solar power systems. Can Solar Power Systems Survive an EMP? Solar power systems are made up of a variety of electronic components, including solar panels, inverters, and charge controllers. While solar panels themselves are not vulnerable to EMPs, the electronic components in the system can be damaged by the high-energy burst of electromagnetic radiation. However, the likelihood of an EMP damaging a solar power system is relatively low. Solar power systems are designed to withstand a certain amount of electromagnetic interference, and the likelihood of an EMP strong enough to completely destroy a solar power system is relatively low. What Can be Done to Protect Solar Power Systems? There are several steps that can be taken to protect solar power systems from the effects of an EMP. One option is to install surge protectors on the solar power system’s electronic components. Surge protectors can help absorb the excess energy from an EMP and prevent it from damaging the system. Another option is to install a Faraday cage around the solar power system. A Faraday cage is a metallic enclosure that can protect electronic devices from electromagnetic radiation. By enclosing the solar power system in a Faraday cage, the system can be protected from the effects of an EMP. Conclusion While there is some risk of damage to solar power systems in the event of an EMP, the likelihood of a complete system failure is relatively low. By taking steps to protect the system’s electronic components, such as installing surge protectors or a Faraday cage, solar power systems can be made more resilient in the event of an EMP. As solar power becomes more prevalent as a source of energy, it is important to consider the potential risks and take steps to protect these valuable systems. Read more - https://lnkd.in/dGgdns_h . . . #SOLARIZEUSA #SolarEnergy #RenewableEnergy #GreenEnergy #CleanEnergy #SolarPower #SolarPanels #Solartechnology #SolarIndustry #GoSolar

https://lnkd.in/ezTFXW6r HTS materials are materials that exhibit superconductivity at temperatures significantly higher than those required by conventional superconductors. Unlike traditional superconductors, which must be cooled to near absolute zero to function (-273.15 °C), HTS materials become superconductive at relatively higher temperatures, though still below 0 °C. The term "high temperature" is a relative term, as these materials typically become superconductive above the boiling point of liquid nitrogen (-195.79 °C), making them more practical, resilient, and cost-effective for various applications. As the HTS market scales, and material costs come down, HTS could new ways to think about energy storage, industrial heating, aviation, wind turbines, and medical diagnostics. Superconducting magnetic-energy storage (SMES) systems offer efficient, long-term energy storage for power grids. HTS induction heaters can significantly reduce energy consumption and emissions in metal processing. In aviation, HTS materials could lead to lighter, more efficient electric propulsion systems. For wind turbines, using HTS windings instead of traditional magnets can increase efficiency and reduce weight. In medical diagnostics, HTS technology could make MRI machines more compact and efficient. HTS has the potential to revolutionize industries by improving efficiency, reducing environmental impact, and enabling new technologies. https://lnkd.in/d_QXYxvX

Energy monitoring helps to identify optimisation potential, control the process better, and make improvements measurable. One of the largest consumers of electricity are often compressors, feeding the compressed air network. The ideal solution for such applications is the OPTISWIRL 4200 #vortex #flowmeter with integrated pressure and temperature compensation, as well as optional #FAD (free air delivery) software. Here it is shown measuring compressed air in a glass packaging plant, but compressors are literally used across all industries. In #Nuclear #PowerPlants, for example, compressed air is needed for emergency shutdown systems, to operate control rod drive mechanisms, or to power tools and equipment. Learn more about vortex flow measurement and free air delivery measurement right here: https://lnkd.in/dhzqvzy #powergeneration #energyefficiency #energymanagement #energyindustry #energy #powerplant #powerindustry #powerdistribution #processinstrumentation #processcontrol #NuclearIndustry #NuclearSafety

Thorium reactors are essentially the answer. Another is deep water and shallow water tidal power, which is continuous during the day and night 24 hours a day. I first learned about tidal power while I was in engineer at NASA, I was the manager for Electronics development for robotics for two decades. I was reading embedded systems, journal about embedded systems, controllers for redundant Control Systems. of Deepwater, tidal power plants such as that off the coast of Scotland. That’s when I became interested in the concept. Most of the world’s population lives on the coastal areas so you have short grid lines, your tidal power stations are essentially underwater and out of view. Only periodic maintenance and repairs are required and the system continues to operate on its own, providing electricity, as tides go in and out 24 hours a day 365 days a year. For inland areas such as Denver, Phoenix, etc. you have thorium reactors, located close to the cities with redundant safety systems, so that you never have an issue. And therefore, you have short power grids as well for the security of the United States. As for vehicles, we re-tool over the next generation, all vehicles to runoff of natural gas, which allows the oil companies to simply transition over, they could provide a new pump right now to each station. Overtime, you transition away from oil as the use of fuel, and you can develop the technologies for electric cars. Furthermore, that buys time to build the infrastructure for power generation and shorter grids. Also, the development of sterling engines allows for external exothermic reactions, such as geothermal, solar, biodiesel, or anything else as possible backup alternatives. Do United States government has virtually no energy policy at all, at least one that doesn’t make sense, particularly right now under the Democrat party. It fails to take him to your account the effect on the economy by decisions they make. This just shows how single dimensioned and narrow their thought process is. What we need is a Trump administration with good advisors, I would gladly like to be on his staff, particularly with energy policy. https://lnkd.in/g6yDMsNy

From the Idaho National Lab that brought us the NERVA reactor, comes the new micro-reactor. #smr #reactor #inl #nuclearenergy #nuclearpower #powergeneration #idaho #USA #R&D #electricity #distributedgeneration #utilities #modular

Regarding electric motor analysis, one of the most powerful functions on the 𝗔𝗧𝟳 is the 𝗭-𝗙𝗶 𝗧𝗲𝘀𝘁 𝗠𝗼𝗱𝗲. The 𝗭-𝗙𝗶 𝗧𝗲𝘀𝘁 𝗠𝗼𝗱𝗲 is used on all types of AC motors (of any voltage), generators, and transformers. The low voltage tests automatically perform all the Static tests: DF/C, INS, impedance, induction, phase angle, current frequency response (I/F), and calculates a TVS. The Z-Fi test mode must be used on all medium or high voltage equipment (𝘨𝘳𝘦𝘢𝘵𝘦𝘳 𝘵𝘩𝘢𝘯 1,000𝘝) and should be used on installed equipment with no TVS™ Reference. The reason the Z-Fi test is used on motors with no prior TVS is because you want to determine the current health of the motor. Once you generate a TVS™ value you can begin to trend the data. In the Z-Fi test mode you do not perform a DYN (dynamic stator & rotor test) because the load or drive is attached to the motor and the test is not practical. 𝗖𝗮𝗻 𝘆𝗼𝘂 𝗽𝗲𝗿𝗳𝗼𝗿𝗺 𝗮 𝗗𝗬𝗡 𝘁𝗲𝘀𝘁 𝗶𝗻 𝘁𝗵𝗲 𝗭-𝗙𝗶 𝗺𝗼𝗱𝗲? A DYN test is not offered in the Z-Fi test mode. Think of it as a baseline to find out what the condition of the motor is without a reference test. This equipment is usually already installed without having the ability to rotate the motor shaft ( i.e. connected to gearbox, submersible, or a pump). #maintenance, #oil, #oilandgasindustry, #gas, #oilfield, #petroleum, #drilling, #electricity, #power, #electricmotors, #preventivemaintenance, #conditionmonitoring, #conditionbasedmaintenance, #offshorewind, #oilindustry, #onshore, #energyefficiency, #hydrogen, #reliablity, #fuel, #aviación, #hidrocaruros, #robótica, #nuclear, #industria, #eficienciaenergetica

These 10 charts are not the definitive explanation of the electric grid. Instead, these illustrations are designed to help us understand the thing we call the #electricgrid --- and the #sandbox we are all playing in.Rhythmos.io #utility #infrastructure. Enjoy the quick read. https://lnkd.in/gbJDzA2j