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Flexure-based piezo stages can provide positioning at the sub-nanometer or sub-micrometer scale, which is especially valuable in fields such as microscopy. They can make rapid adjustments and settle at a desired position quickly, making them suitable for dynamic applications. They have minimal wear and friction because they operate without traditional mechanical guidance like bearings, resulting in excellent long-term stability and longevity. Since flexure-based piezos don’t rely on lubrication, they are ideal for applications where contamination or cleanliness is a concern. These devices are not friction-based, like “Stick/Slip” or “Walking” piezos, meaning performance and reliability are dramatically increased. See our product offering and video! https://lnkd.in/gsMgQ3ca

Want to learn everything you need to know about thermal interface materials, and how to use them to keep your electronics cool and running at their best? Check out these new videos from Leader Tech Inc: https://lnkd.in/gTJvKPiC #LeaderTech #EMI #EMIShielding

The first high voltage ignition system with magneto (center) and the first spark plug Bosch (right) invented  in 1902 by the german engineer Honold (right). In the picture there is other primitive spark plug.

The science behind Venturi: With a pressure blower injecting air at high velocity and pressure, the Venturi effect kicks in, inducing airflow upstream. This creates consistent, trouble-free material conveyance with ample velocity in the conveying ducts. Learn more ➡️ https://ow.ly/ujb950RYxGW

🧪 The fascinating world of vacuum flow types in a nutshell! 🌬️✨ 🔸 Viscous Flow: Dominates at high pressures, molecules collide frequently. 🏃♂️🏃♀️ 🔸 Molecular Flow: At low pressures, molecules move freely without collisions. 🚀🌌 🔸 Transition Flow: A mix of viscous and molecular, happening at intermediate pressures. ⚖️🔄 Understanding these flow types is crucial for optimizing vacuum system performance and ensuring efficient operations. 📈🔧 Pfeiffer Vacuum created an interesting video series explaining difference aspects of Vacuum flows: 📽 https://lnkd.in/dG_qK7s6 #VacuumTechnology #Engineering #FlowDynamics #ScienceInsights

💡 𝗪𝗵𝗶𝘁𝗲 𝗽𝗮𝗽𝗲𝗿 | 𝗜𝗻𝗿𝘂𝗻𝗻𝗲𝗿 𝗺𝗼𝘁𝗼𝗿 𝘃𝘀 𝗢𝘂𝘁𝗿𝘂𝗻𝗻𝗲𝗿 𝗺𝗼𝘁𝗼𝗿 Which torque motor is right for your application? Each type has its advantages and disadvantages for different applications. This paper explores the performance, thermal resistance, and mounting of both inrunner and outrunner motors. ⬇️ Download our white paper here> https://lnkd.in/gKRbivmi

🧲 Exciting Innovation in Liquid Magnetic Filtration Technology! 🚀High-strength neodymium magnets can capture fine iron starting from 1 µ! 🧲 I am thrilled to share a game-changing solution for liquid mixtures – the Pipeline Magnetic Filter MSP-S OCTOPUS by Sollau. 🔍💧 This cutting-edge technology sets a new standard for efficiency and precision in liquid separation, making it an indispensable tool for various industries. 🌟 Key Features: ✅ Superior Magnetic Separation: MSP-S ensures highly effective removal of magnetic particles from liquid mixtures, enhancing the purity of your end product. ✅ Versatile Applications: From chemical processing to food and beverage industries, MSP-S caters to a wide range of applications, contributing to seamless production processes. ✅ Easy Integration: Designed with user convenience in mind, this separator seamlessly integrates into existing pipelines, minimizing downtime and maximizing productivity.   ❗ CONTACT US FOR A FREE ON-SITE CONSULTATION❗ How will be the pipeline magnet cleaned? Ferromagnetic particles are trapped on magnetic rods being in contact with the separated material. Cleaning the finger magnet is very easy and quick. It is performed in several steps: 1.     Release the fast clamp 2.     Pulling the magnetic component out of the separator body 3.     Removing the magnetic cores from the stainless steel protective tubes (metal particles fall off) 4.    Reverse assembly   💡 Imagine the impact on your production efficiency and product quality! The MSP-S is a testament to Sollau's commitment to innovation and excellence. Please contact me or my colleagues for more information or technical advice: ☎️ Petr Zbranek - EN ☎️ Kamil Kornel - EN ☎️ Martin Bedřich - DE ☎️ Panák Zsuzsanna - HU ☎️ Jakub Ezechýl - CZ ☎️ David Čabla - CZ #LiquidSeparation #Innovation #Sollau #Magneticseparation #Magneticfiltration #Magnet Let's revolutionize the way we handle liquid mixtures! Share your thoughts and experiences with liquid separation technology in the comments below. 👇 Together, we shape the future of industrial processes! 🌐💙

⚡ 𝗕𝗲𝗰𝗼𝗺𝗲 𝗮 𝗯𝗮𝘁𝘁𝗲𝗿𝘆 𝗲𝘅𝗽𝗲𝗿𝘁 𝘄𝗶𝘁𝗵 𝗔𝗻𝘁𝗼𝗻 𝗣𝗮𝗮𝗿 In «The Battery Experts» video series, Anthony Chalou, our Battery Market Development Manager, talks about the physical properties of battery materials. «In a lithium-ion battery cell, the particle size distribution of electrode material directly influences the power and energy density of the produced battery.» In this episode ➡️ https://loom.ly/kI-zHrk you will learn about the different measurement techniques DIA & DLS. 📚 𝗗𝗼𝘄𝗻𝗹𝗼𝗮𝗱 𝗼𝘂𝗿 𝗳𝗿𝗲𝗲 𝗲-𝗯𝗼𝗼𝗸 to learn how to improve your batteries through material characterization here: 👉🏻 https://loom.ly/tiAx2D8 #TheBatteryExperts #batteryanalysis

WAGO Spring Pressure Connection Technogy: Vibration Proof, Fast Wire Connection, Maintenance Free. Vibration Test: https://lnkd.in/dp8jJrPh #SpringConnection #WAGO #MaintenanceFree #AATF2025

How Does a Magnetizer Work? A magnetizer is a device that generates a strong magnetic field to impart magnetism to a ferromagnetic material. The working principle of a magnetizer is based on the principle that when a ferromagnetic material is placed in a changing magnetic field, its magnetic domains, which are small regions of aligned magnetic dipoles, experience a torque that tends to align them with the external field. 🚠 Continuous magnetizers use a continuously flowing alternating current (AC) to generate a magnetic field. The alternating current causes the magnetic field to reverse direction periodically, which helps to align the magnetic domains of the ferromagnetic material in a random direction. 🚟 Pulse magnetizers use a high-voltage pulse of electricity to generate a very strong magnetic field for a very short period of time. The strong magnetic field can impart a significant amount of magnetism to the ferromagnetic material in a short amount of time. The choice of magnetizer type depends on the specific application. Continuous magnetizers are typically used for applications where a moderate amount of magnetism is required, such as in refrigerator magnets or door stoppers. Pulse magnetizers are typically used for applications where a very strong magnet is required, such as in magnetic hoists or magnetic separators. To uncover its veil, here we post a more detailed explanation of the working principle of a pulse magnetizer: 🕐 The ferromagnetic material is placed in the path of the magnetic field. A high-voltage pulse of electricity is applied to the magnetizing coil. 🕑 The pulse of electricity generates a very strong magnetic field that collapses very quickly. The strong magnetic field aligns the magnetic domains of the ferromagnetic material in a random direction. 🕒 As the magnetic field collapses, the magnetic domains continue to precess for a short time, which helps to further align them. 🕓 The ferromagnetic material retains a significant amount of magnetism after the pulse is over. Please be noted that the amount of magnetism that is imparted to the ferromagnetic material depends on several factors, including the strength of the magnetic field, the duration of the pulse, and the properties of the ferromagnetic material. #Magnets #HangzhouVectorMagnets #Magnetism #Magnetizer #Magnetizing #Machine #PrNd #Permanentmagnets