Spring Cleaning Sale: Exclusive Deals on Used Telemark Equipment
Spring is in the air, and that means it’s time to clear out the old and make way for the new! IES, your trusted distributor of Telemark vacuum deposition equipment, is excited to share that Telemark is offering exclusive discounts on a wide selection of nearly new and used equipment. This is the perfect opportunity to upgrade your tools, enhance your operations, and save big on industry-leading technology.
Whether you're looking to replace outdated equipment, expand your production capabilities, or invest in high-performance tools without paying full price, this sale has something for you. But don’t wait—these deals are only available while supplies last!
Thermal mass flow measurement instruments are typically separated into two main categories: Mass Flow Meters and Mass Flow Controllers. It’s estimated that over 90% of mass flow measurement instruments sold are mass flow controllers. So, it’s no surprise that most mass flow application conversations focus on mass flow controllers. Notwithstanding, there are still numerous applications for which mass flow meters are critical.
The following are common applications for mass flow meters (also known as thermal mass flow meters):
Bruker Corporation announced the launch of the VERTEX NEO Platform with its first product, the VERTEX NEO R. This release marks a continuation of providing high-end Fourier-Transform Infrared (FTIR) instrumentation for unparalleled and disturbance-free academic and industrial research and development. The VERTEX NEO R, the successor of the VERTEX 70v, combines significant advancement in high-end FTIR research instrumentation with Bruker’s proven MultiTect detector technology. It also features Bruker’s first unique Vacuum ATR accessory.
Gaskets and Expansion Joints for Semiconductor Manufacturing
Solve your most complex sealing challenges with Garlock’s portfolio of best-in-class solutions.
Target your Semiconductor manufacturing challenges with Garlock's wide range of fluid sealing products, including Pump Diaphragms, Expansion Joints, Gaskets, and more. Ensure product quality and purity in sensitive applications, including
End effectors for the semiconductor industry are designed with specialized technical features and components to ensure that they can safely and efficiently handle delicate electronic components such as silicon wafers, integrated circuits, and microchips. Here are some of the technical features and components that are commonly found in end effectors for the semiconductor industry:
Material selection: End effectors used in the semiconductor industry are typically made from materials that are non-contaminating, such as stainless steel or aluminum. This is important to prevent any particles or impurities from being introduced into the manufacturing process.
Cleanroom compatibility: End effectors for the semiconductor industry are specially designed to be compatible with cleanroom environments. This means that they are designed to minimize the generation and shedding of particles,
Isolation/Poppet Valve – Low-Cost Protection Against System Failure
A vacuum isolation or poppet valve is a type of valve designed to isolate a section of a vacuum system from the rest of the system. Under normal operation they are kept in an option position. With loss of power or signal the valve will immediately close protecting the vacuum system from expensive repairs and decontamination.
What can happen?
When there is some sort of vacuum system failure, the phenomena known as backstreaming. Depending on the actual system configuration, if a pump fails or is underperforming, instead of pumping out the system the flow reverses pulling back everything from the vacuum line into the chamber.
ATC has formally announced their new G Series, with an exceptionally low GWP (Global Warming Potential). This latest technology release from ATC maintains powerful and precise performance while lowering environmental impact. Read more on the latest releases below.
Electrochemical fuel cells are a transformative innovation in sustainable energy, offering the potential to replace combustion engines with cleaner, more efficient systems. Among the various fuels explored for these systems, hydrogen (H₂) has become the focus of research. This is thanks to its high energy density and environmental benefits. But while hydrogen fuel cells promise zero emissions and high energy output, their success depends on overcoming challenges related to fuel purity, emissions control, and system efficiency.
Addressing these challenges requires precision tools that provide real-time insights into the behavior and composition of gases within fuel cells. Gas analysers are indispensable in this regard, enabling researchers to push the boundaries of hydrogen technology and make sustainable energy a practical reality.
Particle Filter Material Choice for Raman and FTIR Microscopy
The filter material to analyze particulate matter with Raman or FTIR microspectroscopy plays a vital role. Their simple task is to filter liquids to isolate solids onto filters – but as soon as you introduce spectroscopic methods, the requirements on the filter increase drastically. But let’s start at the beginning: Which filters are at our disposal, and how do we select the right one for our needs? Do we have to ask the Mirror on the wall from the Snow White fairy tail? No, of course not! The answers are compiled for you below.
Filter materials for FTIR and Raman
For FTIR analysis, the choice between measuring individual particles (with a low particle count) or the entire filter (with a high particle count) guides our filter selection. Nitrocellulose and Glassfiber filters are good options when
Volker Metzger, Watlow, Germany, discusses the challenges and opportunities of lowering carbon emissions in the oil and gas industry through electrification.
The necessity for electrification in industrial processes has intensified as the world aims to fulfill the objectives set by international agreements on climate change. Many traditional industries, such as oil and gas, still rely on gas burners or steam rather than electric heaters. However, electrification plays a key role in advancing thermal systems within industry and lowering greenhouse gas emissions (GHG).
Trends in industrial electrification
The global shift towards decarbonisation, driven by regulatory pressures and sustainability goals, is pushing the oil and gas industry to transition from fossil fuel-based heating systems to electric heating systems. This trend is evident in the implementation of electric heaters in various oil and gas operations, including refineries, petrochemical
