Sailor
Community Member
I just witnessed a phenomena that totally wrecked my understanding of how dissolved solids exist and are measured in water. I’m hoping that someone here can explain exactly what, how, and why I’m seeing what I’m seeing, and that is, the TDS value of water coming out of a deionization canister rising as much as 50 times the TDS value of water going into it (as shown in the attached video).
My reverse osmosis system uses 3 separate deionization canisters, each with its own purpose. Water exits the membrane, passes through the cation resin, then the anion resin, and finally a mixed resin bed. There’s a TDS sensor downstream from the membrane and another downstream from the cation resin, so you can see the direct effect the cation resin has on the water chemistry.
Before we go further, let’s stipulate what a TDS meter measures, and what it does not. A TDS meter measures the quantity, not the quality or type of dissolved solids in water. A TDS meter senses the conductivity of the water and returns a value based on the sum of all the ions in the water. That’s it. It measures ions. It does not necessarily measure pesticides, chemicals, residues, or any other non-ionic pollutants that might be contaminating the water.
Note that the tap water here in the Phoenix area runs at about 500-600 TDS. Note also that upon startup, it takes about a minute or two to purge stale water from the system after it had been sitting idle for a day or so and begin to display stable TDS values at various points in the plumbing. Water passes through the sediment filter and dual carbon block elements and enters the membrane still north of 500 TDS, then exits the membrane initially at about 200 TDS, but drops to and stabilizes at about 6 to 8 TDS within the first minute.
Okay, here’s the crazy part. Water exits the membrane at about 6-8 TDS and flows into the cation resin. For the first minute or so, water exiting the cation resin holds steady at about 28 ppm on the TDS meter, but then rises precipitously to as much as 450 TDS before retuning to a stable 28 TDS about a minute later.
Question #1: Water enters the membrane at a very high TDS, but comes out at about 6 to 8 TDS. It appears that the membrane is physically removing minerals, separating dissolved solids and/or suspended solids from the product water and disposing them via the waste water. Is that what’s happening at this stage in the RO system?
Question #2: Water leaving the membrane and entering the cation resin is virtually free of dissolved solids. There is only a relatively small number of ions in the water. Then, suddenly, the TDS meter reads triple digits before stabilizing at a value still 4 times higher than the incoming value. It appears that the cation resin is creating new ions out of thin air! How does this happen?
I can see how the cation resin might affect the pH of the water, rapidly altering the H+ ion concentration, which would indeed impact the TDS reading. Is it really that simple? So when I see the TDS value climbing through 400 it’s not because the cation resin is creating calcium or magnesium ions from non-ionic Ca or Mg atoms that somehow got through the membrane; instead it’s flooding the system with hydrogen ions, a process that I assume would be reversed when the water passes through the anion resin canister downstream.
Questions #3 & #4: Am I on the right track here, or totally out to lunch? More importantly, is this rising TDS phenomenon something to worry about, or not? After all, at the end of the day, the product water comes out at zero TDS.
Here's the video. Note that there's more information in the description section if you click the link to watch the video on YouTube rather than the embedded clip here.
My reverse osmosis system uses 3 separate deionization canisters, each with its own purpose. Water exits the membrane, passes through the cation resin, then the anion resin, and finally a mixed resin bed. There’s a TDS sensor downstream from the membrane and another downstream from the cation resin, so you can see the direct effect the cation resin has on the water chemistry.
Before we go further, let’s stipulate what a TDS meter measures, and what it does not. A TDS meter measures the quantity, not the quality or type of dissolved solids in water. A TDS meter senses the conductivity of the water and returns a value based on the sum of all the ions in the water. That’s it. It measures ions. It does not necessarily measure pesticides, chemicals, residues, or any other non-ionic pollutants that might be contaminating the water.
Note that the tap water here in the Phoenix area runs at about 500-600 TDS. Note also that upon startup, it takes about a minute or two to purge stale water from the system after it had been sitting idle for a day or so and begin to display stable TDS values at various points in the plumbing. Water passes through the sediment filter and dual carbon block elements and enters the membrane still north of 500 TDS, then exits the membrane initially at about 200 TDS, but drops to and stabilizes at about 6 to 8 TDS within the first minute.
Okay, here’s the crazy part. Water exits the membrane at about 6-8 TDS and flows into the cation resin. For the first minute or so, water exiting the cation resin holds steady at about 28 ppm on the TDS meter, but then rises precipitously to as much as 450 TDS before retuning to a stable 28 TDS about a minute later.
Question #1: Water enters the membrane at a very high TDS, but comes out at about 6 to 8 TDS. It appears that the membrane is physically removing minerals, separating dissolved solids and/or suspended solids from the product water and disposing them via the waste water. Is that what’s happening at this stage in the RO system?
Question #2: Water leaving the membrane and entering the cation resin is virtually free of dissolved solids. There is only a relatively small number of ions in the water. Then, suddenly, the TDS meter reads triple digits before stabilizing at a value still 4 times higher than the incoming value. It appears that the cation resin is creating new ions out of thin air! How does this happen?
I can see how the cation resin might affect the pH of the water, rapidly altering the H+ ion concentration, which would indeed impact the TDS reading. Is it really that simple? So when I see the TDS value climbing through 400 it’s not because the cation resin is creating calcium or magnesium ions from non-ionic Ca or Mg atoms that somehow got through the membrane; instead it’s flooding the system with hydrogen ions, a process that I assume would be reversed when the water passes through the anion resin canister downstream.
Questions #3 & #4: Am I on the right track here, or totally out to lunch? More importantly, is this rising TDS phenomenon something to worry about, or not? After all, at the end of the day, the product water comes out at zero TDS.
Here's the video. Note that there's more information in the description section if you click the link to watch the video on YouTube rather than the embedded clip here.
