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Arezou Yavarianfar looks at what operators, suppliers and developers of heat networks need to be aware in the evolving regulatory landscape, with new requirements coming in under the #EnergyAct2023 in Building Magazine (£). https://lnkd.in/ect8PGxW

Madhusudhan Rapole, Managing Director, Oorja Energy Engineering Services, discusses "A Pathway to Affordable & Low Energy Cooling" 📽️ Click here to watch the full video: https://lnkd.in/dySUP_5Q #Technologies #Technology #IndustryAnalysis #management #Innovation #MarketReport #thermalcontrolmagazine

Advancements in Water Electrolysis Technology: A Comparative Analysis Water electrolysis technology offers diverse options, each with distinct advantages and limitations. #AlkalineElectrolysis stands as the oldest and most established method, boasting cost-effectiveness and high gas purity. In contrast, #PEM_Electrolysis excels in efficiency and environmental friendliness, though it carries higher costs. Meanwhile, #SOE presents promising advancements with exceptional efficiency and thermal stability, despite being in a relatively nascent stage. Understanding the nuances of these electrolysis methods is crucial for harnessing #Hydrogen as a clean energy carrier efficiently. #CleanEnergy #HydrogenEconomy #Electrolysis #GreenHydrogen #SustainableEnergy #EnergyStorage #RenewableEnergy #TechInnovation #EnergyEfficiency

Helios TCS® Demonstrates Substantial Energy And Cost Savings For District Cooling System At Duke University Duke University has long been committed to sustainability, optimizing its infrastructure to enhance energy efficiency and reduce environmental impact. One of its major initiatives has been the adoption of the Helios Automatic Tube Cleaning System®. This cutting-edge system was installed in Duke’s district cooling system to combat the chronic issue of fouling in the chiller tubes, which negatively impacted the energy efficiency and operational reliability of the plant. One of the most striking benefits of the Helios system has been the dramatic reduction in energy consumption. Since the system’s installation, Duke University has saved nearly 7 million kilowatt-hours of electricity annually, a significant figure that underscores the extent of the system’s impact. Learn more at: https://bit.ly/3YB0ql8 #heatexchangers, #heatexchanger, #sustainability, #districtcooling, #chillers, #commercialHVAC, #hvac, #HeatingAndAirConditioning, #HVACSystem, #EnergyEfficiency, #EnergyEfficientProducts, #HVACsolutions, #HeliosTCS, #TritonDebrisStrainer

"The future belongs to those who believe in the beauty of their dreams." - Eleanor Roosevelt #utilityservices #energyefficient #sustainability #renewableenergy #infrastructure #customercare #electricity #gas #water #wastewater #smartgrid #innovation #technology #safexcavation #costeffective #minimallyinvasive #versatile #durability #hydroexcavation #hydrovac #vacuum excavation #excavation

Heat recovery systems are essential for industries aiming to improve energy efficiency and cut costs. These systems capture waste heat generated from processes like manufacturing and power generation, repurposing it for useful applications. Common uses of recovered heat include preheating incoming materials and providing space heating, which reduces the energy needed for operations. Waste heat can also support district heating systems, optimizing energy consumption and lowering emissions. Advanced technologies like organic Rankine cycle (ORC) systems convert low-grade heat into electricity, enhancing overall efficiency. As regulatory pressures increase and energy costs rise, investing in heat recovery systems becomes increasingly strategic. By reusing waste heat, industries can significantly reduce energy consumption, lower expenses, and foster sustainability, paving the way for a more energy-efficient future. Ongoing advancements in heat recovery technologies promise to enhance their effectiveness across various sectors. #hexagon_engineering_ltd #development_in_heat_recovery

𝗗𝗮𝘆 𝟯 𝗜𝗻𝘀𝗶𝗴𝗵𝘁: 𝗘𝗹𝗲𝗰𝘁𝗿𝗶𝗳𝗶𝗰𝗮𝘁𝗶𝗼𝗻 𝗽𝗲𝗻𝗲𝘁𝗿𝗮𝘁𝗶𝗼𝗻 𝗶𝗻 𝗲𝘃𝗲𝗿𝘆 𝗺𝗮𝗶𝗻 𝘀𝗲𝗰𝘁𝗼𝗿𝘀 Electrification is a key lever in decarbonization. As of 2021, 21% of global final energy consumption came from electricity. Examining this by sector, commercial and public services have the highest share of final energy consumption from electricity at 52%. The residential sector stands at 26%, while transport lags behind at only 1.3%. In the residential sector, most energy is used for space heating, predominantly fueled by fossil fuels. A widespread adoption of heat pumps for home heating would significantly increase electricity's share. Heat pumps are a mature and widely available technology that has proven effective even in Nordic countries, where they are paradoxically most popular. The commercial and public sectors are inherently dependent on electricity, primarily due to their low energy intensity and reliance on computers. Transport, however, remains the hardest sector to decarbonize. While electric vehicles (EVs) will increase electricity demand, decarbonizing cargo, ships, airplanes, and long-haul heavy-duty transport presents significant challenges. The industrial sector also has many opportunities to increase electricity use, yet it includes numerous energy-intensive processes that are difficult to electrify. For more insights, refer to the Ember Global Electricity Review 2024: https://lnkd.in/gKnGFWQd #Electrification #Decarbonization #EnergyConsumption #HeatPumps #ElectricVehicles #GlobalEnergyTrends #SustainableEnergy #EmberReport #EnergyTransition

🌍 [RE-WITCH explains] What is Thermal COP and why does it matter? Continuing our journey through the technologies powering RE-WITCH, it is time for Thermal COP – a key metric that measures the efficiency of our cooling and heating systems. 📊 What is Thermal COP? Thermal COP is a measure of how efficiently a cooling system uses heat to produce cooling energy. In RE-WITCH, our advanced thermal systems should achieve a high Thermal COP, enabling us to convert waste heat into useful energy for cooling with minimal energy input. This high efficiency is essential for reducing both energy costs and CO2 emissions in industrial processes. 🔍 Why Thermal COP Matters in RE-WITCH? By integrating hybrid systems like #adsorption and #absorption chillers, along with heat exchangers and thermal energy storage (#TES), RE-WITCH optimizes the use of low-grade waste heat from industries. Our absorption systems should reach a Thermal COP of up to 0.7 under optimal conditions, making them a game-changer for sustainable industrial cooling. This high efficiency also means that our systems use fewer resources compared to traditional cooling technologies 💡 With a focus on maximizing Thermal COP, RE-WITCH demonstrates the potential of thermally-driven cooling to provide both economic and environmental benefits. This metric is one of the many ways we’re advancing towards a more sustainable industrial future. 🚀 Stay tuned for more insights into how RE-WITCH is setting new standards in industrial energy efficiency! #ThermalCOP #EnergyEfficiency #WasteHeatRecovery #IndustrialCooling #REWITCH

Chroma 63800R Series Regenerative AC Loads offer a new energy-efficient and carbon-saving solution for AC EVSE testing, thanks to their high power density and efficient energy recovery capability. Traditional load banks not only have a large footprint but also convert consumed power into heat, leading to significant energy consumption and requiring cooling systems to prevent overheating. In contrast, the Chroma 63800R Series achieves energy recovery with an efficiency of up to 89%. For instance, when operating at full load +power, a single unit can save 116,946 kWh of electricity per year, which is equivalent to reducing 45,258 kg (99,777 lbs.) of carbon emissions. The 63800R comes equipped with comprehensive CC, CP, and CR load modes and complies with the standardized CCID/RCD leakage current requirements for AC EVSE testing. Lower energy costs and request a quote today: https://lnkd.in/gHUJXG9U #acloads #regenerative

PV modules endure extreme heat and high temperatures year-round during summer. Ensuring these modules withstand high temperatures throughout their lifecycle is essential for maintaining long-term, safe, and reliable output. Typically, these modules need to function outdoors for 30 years and face six major stresses: thermal, humidity, mechanical, chemical, radiation, and electrical. We have 🌞Exceptional Performance in Extreme Heat 🔋Reliable Output, Year After Year 🏅 Leading the Industry in Durability and Efficiency Trust DAS SOLAR for durable and high-performing photovoltaic modules that thrive even in extreme environments. https://lnkd.in/gM-fRFau #DASSolar #SolarPower #GreenEnergy #EcoFriendly #Innovation