ebm-papst’s Post

Thermal anomalies often precede failures in high-voltage systems. Therefore energy and utility companies rely on thermal imagers to assess the heating status of critical components like transformers and substations. Read how a major energy supplier from Germany uses testo 883 for preventive maintenance of power generation and distribution systems: https://lnkd.in/geAJGHyk #testo #testosmi #customerreference #thermography #energysector #preventivemaintenance

High-voltage systems are known to experience failures following the occurrence of thermal anomalies. Hence, energy and utility companies utilize thermal imagers to evaluate the heating conditions of crucial components such as transformers and substations, in order to avert potential issues. A German energy supplier has adopted the testo 883 for proactive maintenance of their power generation and distribution systems. Read on to discover how this customer reference applies thermography to the energy sector for preventive maintenance. Free download: bit.ly/3LVaAp9 #testo #testome #customerreference #thermography #energysector #preventivemaintenance

Tomorrow's AMA will be a really good one. We have gotten so many questions about transformer selection and configuration. Variability in voltage and current is one aspect but different applications between PV inverters and ESS inverters is another. In our prep calls the group had some really good insights that we weren't even aware of regarding different purposes of transformers for different sites. Join to listen to the conversation and ask questions of this great panel of experts from Hammond Power Solutions and Dynapower. #pvdesign #askmayfieldanything #pveducation #energystoragesystems #electricalknowledge

The world's most innovative family of medium-voltage mechanical #cable #connectors and #lugs is available in larger sizes of 400–800 mm². 🌟 Now the underground networks installations are safe and easy to do even where the largest conductor cross-sections are needed such as in distributed production – wind farms and solar power plants and electric vehicle public charging stations, to mention some. 👍 The entire selection of connectors and lugs covers now the range from 10 mm² to 800 mm². It is a real advantage that we can offer similar products for all common conductors – we have one technology, and one installation technique. Read more about the benefits of connectors and lugs and how they really minimize the probability for faulty installations! https://lnkd.in/dcDzAEB7 #ensto #BetterLifeWithElectricity #mechanical #cable #connector #lug #innovative #newgeneration #range #electricitydistribution

Don't miss tomorrow's AMA! Join Ryan Mayfield, Jeff Somerville from Hammond Power Solutions, and Medina Maric from Dynapower as they delve into transformer selection and configuration complexities. They'll discuss key considerations for behind-the-meter C&I PV and storage projects, including Delta or Wye transformer selection and inverter alignment. While transformers have been around for many decades, the bidirectional nature and variability in PV and ESS inverters, as well as existing site electrical variances, add much confusion to proper transformer configuration. Gain valuable insights and best practices from industry experts to optimize your installations. Bring your questions for this powerhouse expert panel! 🗨 ✔ Save your spot at the link below: https://lnkd.in/dGs8Xwur #AMA #Transformer #PVsystems #Delta #Wye #ESS #Solar #PVdesign #PVengineering #Inverters #energystoragesystems #pvtransformers

#snsinstitutions #snsdesignthinkers #designthinking STEAM TURBINE The steam turbine has been a crucial component in processes related to the generation of energy. As society is more and more involved in looking at how energy is created and the sustainability and efficiency of the process, addressing the question of ‘what is a steam turbine’ and how this technology can be improved becomes essential. Let us guide you through a quick but insightful guide into the steam turbine: what this component is, its functions and the developments in the steam turbine that are facilitating the efficiency improvements. Heat rates are also a valuable insight for operators. This metric connects power plants to thermal efficiency values, and compares the amount of heat capable of generating 1 kilowatt-hour (kWh) of power. It is inversely proportional to power plant efficiency, and is related to three key concepts: Electric Power Output, Operating Conditions and Plant Design. Heat rate improvements can take many shapes and forms, the focus on steam turbine performance being one of them. Again, this strategy looks into the power output of the turbine compared to the used resources to measure efficiency. Key developments in this area include incorporating Heat Recovery Steam Generator (HRSG) structures and Turbine Inlet Air Cooling (TIAC) solutions mixed with Thermal Energy Storage (TES), the latter being particularly crucial in locations with extreme weather conditions.

Liquid cooling technology has attracted much attention for its efficient and stable performance, a popular thermal management solution for industrial and commercial energy storage systems Liquid cooling technology is a technology that uses liquid as a heat transfer medium to take away the heat generated by the battery module and circulate the heat. Compared with traditional air cooling technology, liquid cooling technology has higher heat transfer efficiency and cooling capacity, and also helps to increase the energy density of the energy storage system. The liquid cooling system mainly consists of the following parts: 1. Coolant: used to absorb the heat generated by the battery module and carry it to the radiator. 2. Pump: used to drive coolant to circulate in the liquid cooling system. 3. Radiator: used to dissipate the heat carried by the coolant to the outside world to keep the temperature of the battery module stable. 4. Control valve and connecting pipeline: used to control the flow direction and flow rate of coolant, and connect various components. In the design process of a liquid cooling system, the following aspects need to be considered: 1. Selection of coolant: A liquid with high thermal conductivity, stability, and non-volatility should be selected as the coolant. Commonly used coolants include mineral oil, synthetic oil, etc. 2. Pump selection: A pump with high lift, large flow, and low energy consumption should be selected to ensure that the coolant circulates fully in the system. 3. Radiator design: The radiator should have the characteristics of high heat dissipation efficiency, low noise, and corrosion resistance. Common radiators include plate radiators, heat pipe radiators, etc. 4. Design of control valves and connecting pipelines: Control valves and connecting pipelines with stable performance and easy maintenance should be selected to ensure normal operation of the system. Advantages of Nowtech liquid-cooled energy storage systems: 1. Able to effectively control the temperature fluctuation of the battery modules does not exceed 3°C. 2. Enable the battery modules to have a longer cycle life. 3. Ensure the liquid cooling system operates stably, reliably, and is easy to maintain. Are you looking for a trusted lithium battery or BESS supplier? Please send your requirements to [email protected], and you will get the best solution from our professional team. #energystorage #BESS #lithiumbatteries #solarenergy #evcharging #solar #renewableenergy #microgrids #solarpower #EV #greenenergy #power

Uncover the secrets behind transformer efficiency in our latest blog post! From multi-layer helical windings to aluminum windings, each plays a vital role in electrical distribution. Check out the blog here: https://lnkd.in/gEazcMZF For more insightful explorations into the world of transformers, stay tuned to our blog for valuable industry insights. #electricalengineering #transformerwindings #electricalInnovation #transformerinsights #transformer911 #transformers #electricalscrap #transformerrepair #transformermaintenance #transformerservice #electricity #power #DGA #FR3 #FR3fluid #energy #manufacturing #powerindustry #powertransformers #powertransformerrepair #powerdistribution

Liquid cooling technology has attracted much attention for its efficient and stable performance, a popular thermal management solution for industrial and commercial energy storage systems Liquid cooling technology is a technology that uses liquid as a heat transfer medium to take away the heat generated by the battery module and circulate the heat. Compared with traditional air cooling technology, liquid cooling technology has higher heat transfer efficiency and cooling capacity, and also helps to increase the energy density of the energy storage system. The liquid cooling system mainly consists of the following parts: 1. Coolant: used to absorb the heat generated by the battery module and carry it to the radiator. 2. Pump: used to drive coolant to circulate in the liquid cooling system. 3. Radiator: used to dissipate the heat carried by the coolant to the outside world to keep the temperature of the battery module stable. 4. Control valve and connecting pipeline: used to control the flow direction and flow rate of coolant, and connect various components. In the design process of a liquid cooling system, the following aspects need to be considered: 1. Selection of coolant: A liquid with high thermal conductivity, stability, and non-volatility should be selected as the coolant. Commonly used coolants include mineral oil, synthetic oil, etc. 2. Pump selection: A pump with high lift, large flow, and low energy consumption should be selected to ensure that the coolant circulates fully in the system. 3. Radiator design: The radiator should have the characteristics of high heat dissipation efficiency, low noise, and corrosion resistance. Common radiators include plate radiators, heat pipe radiators, etc. 4. Design of control valves and connecting pipelines: Control valves and connecting pipelines with stable performance and easy maintenance should be selected to ensure normal operation of the system. Advantages of Nowtech liquid-cooled energy storage systems: 1. Able to effectively control the temperature fluctuation of the battery modules does not exceed 3°C. 2. Enable the battery modules to have a longer cycle life. 3. Ensure the liquid cooling system operates stably, reliably, and is easy to maintain. Are you looking for a trusted lithium battery or BESS supplier? Please send your requirements to [email protected], and you will get the best solution from our professional team. #energystorage #BESS #lithiumbatteries #solarenergy #evcharging #solar #renewableenergy #microgrids #solarpower #EV #greenenergy #power

Liquid cooling technology has attracted much attention for its efficient and stable performance, a popular thermal management solution for industrial and commercial energy storage systems Liquid cooling technology is a technology that uses liquid as a heat transfer medium to take away the heat generated by the battery module and circulate the heat. Compared with traditional air cooling technology, liquid cooling technology has higher heat transfer efficiency and cooling capacity, and also helps to increase the energy density of the energy storage system. The liquid cooling system mainly consists of the following parts: 1. Coolant: used to absorb the heat generated by the battery module and carry it to the radiator. 2. Pump: used to drive coolant to circulate in the liquid cooling system. 3. Radiator: used to dissipate the heat carried by the coolant to the outside world to keep the temperature of the battery module stable. 4. Control valve and connecting pipeline: used to control the flow direction and flow rate of coolant, and connect various components. In the design process of a liquid cooling system, the following aspects need to be considered: 1. Selection of coolant: A liquid with high thermal conductivity, stability, and non-volatility should be selected as the coolant. Commonly used coolants include mineral oil, synthetic oil, etc. 2. Pump selection: A pump with high lift, large flow, and low energy consumption should be selected to ensure that the coolant circulates fully in the system. 3. Radiator design: The radiator should have the characteristics of high heat dissipation efficiency, low noise, and corrosion resistance. Common radiators include plate radiators, heat pipe radiators, etc. 4. Design of control valves and connecting pipelines: Control valves and connecting pipelines with stable performance and easy maintenance should be selected to ensure normal operation of the system. Advantages of Nowtech liquid-cooled energy storage systems: 1. Able to effectively control the temperature fluctuation of the battery modules does not exceed 3°C. 2. Enable the battery modules to have a longer cycle life. 3. Ensure the liquid cooling system operates stably, reliably, and is easy to maintain. Are you looking for a trusted lithium battery or BESS supplier? Please send your requirements to [email protected], and you will get the best solution from our professional team. #energystorage #BESS #lithiumbatteries #solarenergy #evcharging #solar #renewableenergy #microgrids #solarpower #EV #greenenergy #power