Description
The Direct Acting Solenoid Valve with a brass body is a critical component designed for precise control in various industrial applications. Operating at a voltage of 12V DC, this normally closed valve effectively isolates flow, regulates pressure, and ensures the safe direction of media in systems such as manufacturing, mining, water treatment, and compressed air systems. With an orifice size of 3 and capable of handling media temperatures from -10 to 100 degrees Celsius, it operates efficiently under pressures of 0-10 bar for both air and fluid. Its durable construction, featuring Teflon components, provides excellent corrosion resistance and leak prevention, enhancing system safety and operational efficiency in process plants and pipelines.
Features
- Compact ⅛” size for versatile installation in tight spaces.
- 3mm orifice ensures efficient flow control for various applications.
- Operates effectively within a media temperature range of -10 to 100°C.
- 12V DC voltage for reliable performance in low-power systems.
- Normally Closed (N.C) function provides safety by preventing unintended flow.
- Handles air/fluid pressures up to 10 bar for robust operation.
- Vacuum capability of 27 inches Hg for effective suction applications.
- Durable brass body construction with Teflon sealing for enhanced longevity.
Applications
- Used in fluid handling systems for precise control of liquid flow in industrial applications.
- Ideal for compressed air systems, ensuring reliable operation in pneumatic machinery.
- Applied in water distribution networks to manage flow and prevent backflow in pipelines.
- Utilised in gas pipelines for safe and efficient control of gas flow under varying pressures.
- Commonly found in steam systems, regulating steam flow for heating processes.
- Employed in process control systems to automate the regulation of fluids in manufacturing.
- Serves as an equipment isolation valve, providing safety and maintenance capabilities in critical systems.
- Effective in vacuum applications, maintaining integrity in systems requiring low-pressure environments.
