gerhard_za
Mechanical
- May 8, 2022
- 6
Hi all,
I am brand new to this forum. I have been working in the water treatment industry for many years as a project manager. Of late, I have been forced into the process engineering side of the game and realise that there are a lot of critical aspects of water, especially reverse osmosis, that I desperately need to build expertise in. I am hoping you folk could lend a friendly hand!
The background is that there is a network of laboratories that require deionized water. I took on the challenge to supply them with a more robust system that is a bit more industrial than they're used to, but in favour of availability, with less intervention required.
I settled on using 4040 tap water RO membranes as they are by far the most common. 4021 and 2540 are less common and don't cost much less. I could not use a large multistage type pump as it is too bulky and noisy for the small lab environments. Thus I settled on 800GPD diaphragm pumps which give ±4LPM at ±5Bar. Feedwater TDS is <300PPM in 95% of cases so we do carbon and 5micron pre-treatment and push it through the RO directly. Then it runs through a mixed bed resin to remove the remaining ions. These plants are small and there are many (almost 200). So doing antiscalant with affordable dosing pumps require dilution and too frequent replacement thereof.
I have two questions (for now)
1) A typical 4040 membrane can give 2400GPD which is much less than my pump's 800GPD. I am only getting about 1200GPD from my setup with some back pressure but with lower conductivities they do fine. My initial reasoning was that more surface area allows for longer life but I also read that I actually need to apply more pressure to get better rejection. But higher pressure at low TDS input water means permeate flows in excess of 50% of feed water (and they claim on a single pass you should be looking at 17% to 30% recover).
*What am I missing in terms of planning for membrane life? DO I need to go smaller on the membrane so the pressure increases from the same pump? But increased pressure also introduces higher probability of scale formation?
2) As mentioned, the antiscalant or SMBS dosing is not an option. I don't have the space and have to settle for shorter lifetimes on RO membranes (regarding them as more of a consumable, due to extra hardware and consumable cost more or less surpassing the cost of a new one on an annual basis).
*Have any of you had experience with the Siliphos crystal balls or similar which I can throw into a cartridge and allow to dissolve on the way into the membrane? Is this suitable? Will it have more pros than cons? Their main ingredient is P204 or P205 (
I hope some of you have the time to read this and offer some advice. I am in a tight spot to make almost 200 systems in the field cheaper to maintain and prolonging membrane life in a small setup is key.
Kind regards
Gerhard from South Africa
I am brand new to this forum. I have been working in the water treatment industry for many years as a project manager. Of late, I have been forced into the process engineering side of the game and realise that there are a lot of critical aspects of water, especially reverse osmosis, that I desperately need to build expertise in. I am hoping you folk could lend a friendly hand!
The background is that there is a network of laboratories that require deionized water. I took on the challenge to supply them with a more robust system that is a bit more industrial than they're used to, but in favour of availability, with less intervention required.
I settled on using 4040 tap water RO membranes as they are by far the most common. 4021 and 2540 are less common and don't cost much less. I could not use a large multistage type pump as it is too bulky and noisy for the small lab environments. Thus I settled on 800GPD diaphragm pumps which give ±4LPM at ±5Bar. Feedwater TDS is <300PPM in 95% of cases so we do carbon and 5micron pre-treatment and push it through the RO directly. Then it runs through a mixed bed resin to remove the remaining ions. These plants are small and there are many (almost 200). So doing antiscalant with affordable dosing pumps require dilution and too frequent replacement thereof.
I have two questions (for now)
1) A typical 4040 membrane can give 2400GPD which is much less than my pump's 800GPD. I am only getting about 1200GPD from my setup with some back pressure but with lower conductivities they do fine. My initial reasoning was that more surface area allows for longer life but I also read that I actually need to apply more pressure to get better rejection. But higher pressure at low TDS input water means permeate flows in excess of 50% of feed water (and they claim on a single pass you should be looking at 17% to 30% recover).
*What am I missing in terms of planning for membrane life? DO I need to go smaller on the membrane so the pressure increases from the same pump? But increased pressure also introduces higher probability of scale formation?
2) As mentioned, the antiscalant or SMBS dosing is not an option. I don't have the space and have to settle for shorter lifetimes on RO membranes (regarding them as more of a consumable, due to extra hardware and consumable cost more or less surpassing the cost of a new one on an annual basis).
*Have any of you had experience with the Siliphos crystal balls or similar which I can throw into a cartridge and allow to dissolve on the way into the membrane? Is this suitable? Will it have more pros than cons? Their main ingredient is P204 or P205 (
I hope some of you have the time to read this and offer some advice. I am in a tight spot to make almost 200 systems in the field cheaper to maintain and prolonging membrane life in a small setup is key.
Kind regards
Gerhard from South Africa
