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User-friendly Auto Sash Controller Upgrades Announced
Laboratory fume cupboard operatives now have access to a newly upgraded auto sash controller, which enables them to operate the unit with greater ease and efficiency. The enhanced unit has been created in response to customer demand by UK-based world-leading specialist in electronic airflow controls and monitors, TEL.
Auto sash controllers automatically close fume cupboard hoods when they detect that there is no operator present, helping to minimise energy consumption. TEL’s research indicates that the installation of one of its controllers can save customers approximately £1000 in energy costs per fume cupboard per year.
TEL’s modified controller now features the Auto Stop function, automatically stopping the opening sash at the sash working height of 500mm (this may be adjusted subject to user preference to 400mm), ensuring a safe face velocity of 0.5m/second. The new capability precludes the need for users to fit their own stopping devices.
TEL’s upgraded auto sash controller also features a new, more easily navigated menu, which has been restructured into function groups, allowing users to quickly access specific functions without scrolling through all menu items.
TEL’s Director, Richard Eady, said: “TEL works in close partnership with fume cupboard manufacturers, contractors and users across the world and our priority is to develop products that meet their evolving requirements.
“With our newly upgraded auto sash controller, we are pleased to have once again responded to customer needs with a sustainable product that is now even more user-friendly.”
Established in 1969, TEL is a second-generation family firm. It was a pioneer in the manufacture of fume hood airflow controls and monitors critical to the respiratory protection of laboratory workers, enabling customers to comply with health and safety legislation.
Its products are used in hundreds of thousands of laboratories worldwide via an international supplier network spanning Europe, the US, Africa and Asia. TEL provides a full-service offer, including product and laboratory design consultation, product supply and installation, training and technical backup.
More information online:
ilmt.co/PL/KOvw 55257pr@reply-direct.com
Soil Moisture Sensors Aid Crop Production Techniques in Space
NASA has just landed its Perseverance rover on Mars but it will be some time before astronauts can visit the red planet. One challenge to overcome is how to keep astronauts nourished. Because vitamins and antioxidants in vegetables degrade over time, long-term missions will need fresh greens for the astronauts to eat. NASA is now funding research into growing crops in space.
Dr Oscar Monje, a research scientist at NASA’s Kennedy Space Center in Florida, said: “Growing plants in a space station is challenging because both space and power are limited. All the plant chambers built in the past 40 years focused on enabling space biology studies that catered on how to grow plants in space. But now we want to focus on space crop production.”
Monje said: “With the Advanced Plant Habitat (APH), you can load experiment profiles from the ground that control the light level, the spectral quality, the CO2
concentration, photoperiod of light and root zone moisture. The APH can be monitored in near-real time with minimal crew intervention for weeks at a time.”
The 5 cm tall APH root zone is divided into four independently controlled root modules, called quadrants. In each quadrant, media moisture is controlled based on matric potential using a pressure sensor. However, this does not capture vertical variations in volumetric moisture. Monje said: “Each quadrant is watered with a porous tube system that distributes water throughout the porous media that is mixed with slow-release fertiliser. In the 5 cm tall root zone at one g, most of the water is ponded at the bottom, and the top layer of media where the plants are germinating can become too dry. For these reasons, two small, rugged volumetric EC-5 moisture sensors, manufactured by Meter Group, were added to each quadrant to monitor moisture redistribution phenomena in microgravity. These sensors are insensitive to salinity and temperature effects. When watering in space, moisture redistribution occurs because capillary forces in microgravity distribute water evenly across the substrate and affect aeration.
“If you don’t water plants enough, they don’t grow fast enough, but if you give them too much water, then you inhibit O2 supply to roots and nutrient
uptake. So we’re using volumetric water content sensors in the APH root module at different levels to control the moisture.” Labcell is the sole UK distributor for Meter Group’s volumetric water content sensors and has demonstration instruments available. More information online:
ilmt.co/PL/RPO5
55173pr@reply-direct.com
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