The Myron L CS51 Conductivity Cell delivers lab-grade conductivity measurement with a 10-foot cable for flexible installation in tanks, process lines, or submersion applications. Built with 316 stainless steel and Teflon wetted materials, this general-purpose probe handles up to 20,000 µS/ppm with integrated temperature compensation for reliable accuracy.
SPECIFICATIONS
Myron L CS51 Technical Details
| Model Number | CS51 |
| Cable Length | 10 ft. / 3 meters |
| Measurement Range | Up to 20,000 µS/ppm |
| Wetted Materials | 316 stainless steel, Teflon |
| Process Connection | 3/4" NPT bored-through swage fitting |
| Pressure Rating | 100 psi at 100°C |
| Temperature Compensation | Integral element, automatic |
| Seal Design | Double EPR O-ring configuration |
INSTALLATION & USE
How to Install the CS51 Cell
- Thread the 3/4" NPT swage fitting into your process line, tank wall, or standpipe. Apply thread sealant rated for your process temperature.
- Insert the CS51 probe through the fitting until seated. The double O-ring design creates a chemical-resistant seal without additional sealing compound.
- Route the 10 ft. cable to your Myron L meter or controller. Avoid sharp bends or pinch points along the cable run.
- For submersion configuration, reverse the swage fitting and mount to a standpipe. Ensure the probe tip is fully submerged during measurement.
- Verify electrical connection and allow time for temperature equilibration before calibration or measurement begins.
COMPATIBILITY
Works With Myron L Meters
The CS51 conductivity cell is designed for use with Myron L water quality meters and controllers that accept conductivity input. The integral temperature element enables automatic temperature compensation when connected to compatible meters. Field replaceable design allows for quick swap-outs without process shutdown. Suitable for general-purpose water quality monitoring in industrial, agricultural, and commercial applications where conductivity measurement up to 20,000 µS/ppm is required.
🔧 Pro Tip: The dual O-ring seal design puts the outer ring in contact with your process fluid while the inner ring stays protected. If you're working with aggressive chemicals, inspect the outer O-ring periodically and replace before it reaches the inner seal for maximum reliability.
