YSI 3254 Glass Fill Conductivity Cell
- YSI 3254 includes built-in temperature sensor for automatic temperature compensation
- Cells are calibrated according to OIML recommendations 56 and 58
- 2-electrode conductivity cell
|603254||3254 glass fill cell with built-in temperature sensor, cell constant = 1.0/cm-1, 4 ft. cable|
|Usually ships in 3-5 days|
|086511||3140 platinizing solution, for use with 3200 & 3400 series cells, 2 oz.|
- Model: YSI 3254
- Cell Type: Fill
- Cell Constant: 1.0/cm-1
- Constant: 100/m
- Material: Pyrex 7740
- Length: 135mm
- Max OD: 19mm
- Chamber ID: 11mm
- Chamber Depth: 83mm
- Chamber Volume: 5mL
In The News
UPDATE : Fondriest Environmental is offering their expertise in conductivity through their new online knowledge base. This resource provides an updated and comprehensive look at conductivity and why it is important to water quality. To learn more, check out: Conductivity, Salinity and TDS .
Salinity and conductivity measure the water's ability to conduct electricity, which provides a measure of what is dissolved in water. In the SWMP data, a higher conductivity value indicates that there are more chemicals dissolved in the water.
Conductivity measures the water's ability to conduct electricity. It is the opposite of resistance. Pure, distilled water is a poor conductor of electricity.Read More
In Saskatoon, Saskatchewan, pollution and runoff from storms and snowmelt are getting the close look they deserve, and there’s much more to examine.
Weather, from heavy spring storms to long months of snow and freezing temperatures, makes the polluting potential of runoff and snowmelt greater than and different from warmer climate cities, said Garry Codling in an email. In Saskatoon, potentially harmful elements in runoff can exceed the guidelines for runoff set by the Canadian government.Read More
Appalachia may be as closely associated with mining as it is to anything else. That close relationship will leave its mark on the area’s streams long after the last mine closes.
A nine-year study recently published in Science of the Total Environment shows that long after mining activity stops and the land is left to heal, streams and stream life are slow to recover.
“We could be really fine point and say that some of them seem to be recovering very, very slowly,” said Carl Zipper, professor emeritus of environmental science at Virginia Tech University . Most of the streams studied didn’t show signs of recovery.Read More