BlueSens gas sensor GmbH’s Post

#MeetTheMachine Tandem Off Gas Analyzer allows for real-time data acquisition of CO2 and O2 concentration in the gas exhaust from bioreactors. Using IR absorption and electrochemical measurements, Tandem is compatible with different manufacturers. https://hubs.la/Q02qVllH0 #Biotechnology

🔧 Rocksensor RF3200 Coriolis Mass Flow Meter : Unmatched Precision for Liquids, Gases & Slurries The RF3200 series delivers mass flow measurement with up to 0.1% accuracy—perfect for oils, chemicals, beverages, food slurries, natural gas, biogas, hydrogen, and more. 🌟 Key Benefits: ✔️ Highly Accurate: ±0.001g/cm³ density & up to 0.1% mass flow accuracy ✔️ Instantaneous & Totalized Flow: Track flow and totalized values ✔️ Integrated/Remote Display Options: Flexible for your setup ✔️ Display Parameters: Mass flow rate, volume flow rate, temperature, and density ✔️ No External Influences: Unaffected by temperature, pressure, viscosity, etc. ✔️ Easy Installation: Compact design with no straight pipe runs required ✔️ Versatile: Ideal for Cryogenic, High Pressure, & Sanitary needs Get reliable, repeatable flow data—contact us today! 📞 #CoriolisFlowMeter #MassFlowMeter #FlowMeasurement #IndustrialFlow #PrecisionFlow #LiquidFlow #GasFlow #SlurryFlow #FlowAccuracy #CoriolisTechnology #FlowMetering #OilFlow #ChemicalFlow #BeverageFlow #FoodSlurries #HydrogenFlow #NaturalGas #Biogas #FlowInstrumentation #SanitaryFlowMeter #CryogenicFlow #HighPressureFlow #EasyInstallation #FlowData #FlowMeasurementSolutions #Rocksensor

This week we're delving into the importance of using deionized water in your Hydrogen generators. What is DI water? Why do you need it? How do you select the best supply? Read our blog and get the answer to all of this and more. #WeArePEAK #HydrogenGenerator #DeionizedWater #GC #GCMS #GasChromatography

Application of flat plate SCR denitration catalyst Most large and medium-sized boilers use selective catalytic reduction (SCR) denitration technology for flue gas denitration. This is currently the most mature flue gas denitration technology, and its core lies in the SCR denitration catalyst. However, the research on flue gas denitration technology in my country was carried out relatively late. The early SCR denitration catalyst formulas and production lines were purchased from European, American and Japanese technologies. In recent years, a large number of environmental protection companies have developed a variety of denitration catalysts through the introduction of digestion and absorption. However, most of the SCR catalysts currently on the market are medium-temperature SCR denitration catalysts, and their optimal operating temperature range is 300-420°C. Below or above this temperature range, the catalyst denitration activity begins to decline, and reversible/irreversible events occur. Poisoning and inactivation  #scrcatalyst #catalyst

Precision-engineered and assembled to the highest quality standards: HISELECT® membranes are highly robust even under harsh conditions, offering excellent chemical resistance and high temperature tolerance. They can be integrated into hydrogen applications to recover hydrogen from ammonia synthesis purge gases or for the removal of hydrogen from process gases in refineries and synthesis gas operations, for example. Watch how the technology works in the video below: #LindeEngineering #HISELECT #Hydrogen

ARE YOU FAMILIAR WITH CRYOGENIC 🌬️ CONDENSATION FOR VOC RECOVERY FROM GAS PHASES? In industrial settings, controlling air pollution is crucial, especially in operations that involve volatile organic compounds (VOCs). One method for managing these compounds is cryogenic condensation. This process involves using extremely low temperatures to condense solvent vapors from gas streams. ❄️ Cryogenic condensation utilizes liquid nitrogen due to its properties: 📌 Low boiling point at -196°C. 📌 Non-toxic, ensuring safety in industrial environments. 📌 Non-corrosive, prolonging equipment life. 📌 Non-flammable, enhancing operational safety. This makes it a preferred choice in various industries to minimize unwanted reactions and enhance safety by providing an inert atmosphere during the process. A particularly efficient configuration for this technique is the Closed-Cycle Inert Gas Condensation, detailed with several schemes in a report by The Environmental Technology Best Practice Programme. This system is well known in several applications, involves continuously recirculating a fixed volume of nitrogen through the condensation unit, allowing for high solvent vapor concentrations. Here are some key aspects: 🎯 High Solvent Capacity: Supports up to 40% volume for volume (v/v) solvent concentrations in the nitrogen stream. 🎯 Efficient Recovery Module: Utilizes a series of heat exchangers to cool and condense the solvent vapors effectively. 🎯 Cost-Effective: Generally lower capital and operating costs due to the closed system and efficient solvent recovery. Using an inert atmosphere not only ensures safety by maintaining less than 5% oxygen in the oven vent stream but can also improve energy efficiency by up to 90%. Such systems are designed to accommodate large fluctuations in solvent concentration and airflow, making them versatile for various industrial applications. For those in industries like coating, where solvent-laden gas is common, adopting cryogenic systems could significantly optimize VOC recovery processes and enhance environmental compliance. 🔎 More info about cryogenic technologies on: https://lnkd.in/dkRD7Ey6 #VOCRecovery #IndustrialSafety #CryogenicCondensation 🔗 Check out this report in the image and comment below

One of the most widely used technologies for removing acid gases from gas streams is absorption using aqueous amine solutions. While various configurations exist based on the specific amine, desired gas purity, pressure, composition, and other factors, the core process typically includes an absorber and a regenerator linked by a lean-rich heat exchanger for energy efficiency. The absorption process is exothermic, while solvent regeneration generally involves heating the solution in a reboiled stripping column. In some cases, a series of pressure reductions into flash drums can effectively strip the solvent for reuse in the absorber. Curious about the right tools for simulating your amine units? Read this article by Optimized Gas Treating, Inc. #ProTreat

💡 Measurement Accuracy: Inconsistencies in hydrogen purity and performance metrics impede sector growth. ⚙️ Electrolysis: Variability in electrolyzer performance validation challenges standardized reporting. 🛠️ Corrosion Analysis: Diverse environmental conditions complicate consistent corrosion measurement. 🔍 Purity Analysis: Need for uniform protocols in hydrogen gas purity assessments. 📊 Research Gaps: Identified gaps highlight the need for innovative measurement technologies. 📈 Future Outlook: Enhanced measurement standards crucial for industry advancement. For more insights, check out the full report. #Hydrogen #Energy #Decarbonization #MeasurementChallenges #RenewableEnergy #SustainableFuture 🌍

CO2 Removal From Gas Streams: Understanding the Role of Carbonate Solutions 🚨 The absorption of CO2 (carbon dioxide) using an aqueous solution of basic compounds is a commonly employed method in various industries for gas purification. Among the typical solutions utilized for this purpose are: -     Monoethanolamine (MEA) -     Methyldiethanolamine (MAE) -     Diethylenetriamine (DTA) -     Potassium carbonate (K2CO3) In the last case, an aqueous solution 💧containing potassium carbonate (K2CO3) and potassium bicarbonate (KHCO3) is introduced from the top of the absorber, while the gas stream enters in a countercurrent flow from the bottom. In recent studies, the modeling of such absorption processes has often been carried out using Aspen Plus software. However, these models have shown limitations, particularly in comparing calculations with experimental data, which has been somewhat fragmented. As a result, these calculations do not sufficiently account for the influence of physical characteristics on the CO2 content in the purified gas, leaving a gap in fully understanding the purification process. A 2020 study by Skurygin et al., published in a leading scientific journal 📖, introduces a comprehensive mathematical model that describes the process of potassium carbonate absorption in a packed absorber. This study delves into the essential heat and mass transfer equations, which are critical to understanding the CO2 absorption process. It characterizes substance concentrations and temperatures in both the liquid and gas phases along the absorber's height. Key Highlights: 📌 The heat and mass transfer coefficients within this model are calculated using the Onda formulas, providing a precise description of the CO2 equilibrium at the liquid-gas interface, as described by the Sechenov relation. 📌 A significant aspect of this model is its validation against experimental data. The accuracy of the model is further confirmed by comparing the predicted CO2 concentration along the absorber with additional experimental data not initially used in the model's development. 📚 Learn more about the latest trends in gas scrubbing technology by following this link: https://lnkd.in/eepgQ5n2 #CO2Removal #SustainableTechnology #GasTreatment 💡 Discover the article cited in this post through the link provided in the comments below

🌱 simulation of CO₂ capture from steam reforming flue gas using an MEA + PZ solvent system in ASPEN HYSYS! 🚀 This captured CO₂ will play a key role in methanol synthesis, showcasing a sustainable pathway for industrial integration. 🙏 A special thanks to my colleagues Abdallah Algendy and محمد صالح for their support and guidance. #Sustainability #CarbonCapture #MethanolSynthesis #AspenHYSYS #blueMethanol #ProcessDesign #Modelling