Åmod Series
Vacuum Coating Systems
Our modular vacuum coating system configuration provides the flexibility to personally customize a thin film deposition system from a diverse list of standard options, enabling unique process applications on any competitive budget.
The Åmod's unique design provides the ability to integrate a glove box during on site installation.
Powerful process features have been designed into a compact system, making the Åmod a perfect solution in all laboratory scale research environments.
The compact footprint allows you to maximize the use of available lab space without sacrificing the advanced capabilities your research demands.
The Åmod is engineered for a wide variety of scientific and industrial fields, ranging from research and development to pre-production applications.
Each system is capable of multiple source co-deposition processes and can be configured with combinations of up to 6 thermal evaporation sources, 3 magnetron sputter sources, or 1 electron beam heated source. The system with also accommodate a single large diameter substrate or multiple small substrates with optional shadow masking.
Thermal Space Simulation
Our space simulation vacuum chambers combine temperature control and altitude simulation to test components and subassemblies for a variety of industries.
The vacuum chamber is fitted with a temperature controlled shroud assembly to simulate the thermal absorptivity of an outer space environment.
The thermal shroud is formed to match the shape of the vacuum chamber above a component mounting platen.
The platen has an array of tapped holes for clamping down test components to improve thermal conductivity.
Solar absorption end plates are located to either end of the shroud reducing unwanted radiant energy transfer.
The inside of the shroud is coated with a high absorptivity, low thermal emittance solar selective coating to account for component test radiation emissions.
To enhance process stability the shroud assembly is thermally isolated from the surrounding chamber walls.
The temperature is controlled on the shroud assembly by passing fluid through a tubing network that has been welded or brazed to the respective sections of the shroud.
Conventional fluid circulation systems will expose the shroud to a thermal cycle ranging from -60°C to 120°C without LN2. However with minimal modification the thermal shroud may be used with a liquid nitrogen system to achieve cryogenic temperatures.
Vacuum Industry Trade Show Schedule
Come see us at an upcoming vacuum industry trade show or conference near you!
Here are the show booths we are hosting in addition to conferences we plan to attend.
Society of Vacuum Coaters
Denver, Colorado
April 23-28, 2005
Booth Number: 419
Society for Information Display
Boston, Massachusetts
May 22-27, 2005
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