Potable water treatment - Revision history

Michel Lamontagne: /* Production rates */

2023-12-13T17:11:41Z

Production rates

Michel Lamontagne: /* Production rates */

2023-12-13T17:06:45Z

Production rates

Michel Lamontagne: /* Desalination */

2023-12-13T16:57:03Z

Desalination

Michel Lamontagne at 15:54, 13 December 2023

2023-12-13T15:54:44Z

Michel Lamontagne at 15:54, 13 December 2023

2023-12-13T15:54:12Z

Michel Lamontagne: /* Desalination */

2023-12-12T17:05:40Z

Desalination

Michel Lamontagne: /* Water treatment plant */

2023-12-12T16:58:24Z

Water treatment plant

Multivac at 10:21, 23 July 2020

2020-07-23T10:21:48Z

Michel Lamontagne: Added image

2019-11-24T02:44:41Z

Added image

Michel Lamontagne at 18:20, 24 July 2019

2019-07-24T18:20:29Z

@@ Line 33: / Line 33: @@
 ===Production rates===
-New water would add itself to the recycled water in the food production system, and compensate for losses due to water treatment required to remove dissolved salts and other contaminants.
+New water would add itself to the recycled water in the life support systems, and compensate for losses due to water treatment required to remove dissolved salts and other contaminants.
-Plants require large amounts of water to function correctly. In greenhouses, water irrigation requirements have a typical value of 10 to 16 l/m2 per day.  So even if an open system configuration was adopted, a desalination array would be able to compensate all the required water with a production area one tenth of the farm area.  If we plan for about 2% replacement of the water per cycle, then the desalination plant would need about 500 times less area that the food production area.
+Plants for food production and life support require large amounts of water to function correctly. In greenhouses, water irrigation requirements have a typical value of 10 to 16 l/m2 per day.  So even if an open system configuration was adopted, a desalination array would be able to compensate all the required water with a production area one tenth of the farm area.  If we plan for about 2% replacement of the water per cycle, then an evaporation based desalination plant would need about 500 times less area that the food production area.
 ==TSSE==

@@ Line 33: / Line 33: @@
 ===Production rates===
-This would add itself to the recycled water in the food production system, and compensate for losses due to water treatment required to remove dissolved salts and other contaminants.
+New water would add itself to the recycled water in the food production system, and compensate for losses due to water treatment required to remove dissolved salts and other contaminants.
 Plants require large amounts of water to function correctly. In greenhouses, water irrigation requirements have a typical value of 10 to 16 l/m2 per day.  So even if an open system configuration was adopted, a desalination array would be able to compensate all the required water with a production area one tenth of the farm area.  If we plan for about 2% replacement of the water per cycle, then the desalination plant would need about 500 times less area that the food production area.

@@ Line 26: / Line 26: @@
 ==Desalination==
 The energy requirements of desalination for water treatment is approximately 3-3.5 kWh (electrical) per cubic meter of water, given a saltwater input equal to Earth sea water and using reverse osmosis. (2)
 With the ~500W/m^2 sunlight intensity on Mars, an efficiency of 20-25% and a 20-25% capacity factor, a square meter of ground can produce 0.5kWh per day or sol. So each day, a solar array can desalinate enough seawater-like salty water on Mars to equal its own area up to 15-33cm deep (about 1 foot), or 150 to 300 l/m2 per day.
 This would add itself to the recycled water in the food production system, and compensate for losses due to water treatment required to remove dissolved salts and other contaminants.

@@ Line 26: / Line 26: @@
 ==Desalination==
-The energy requirements of desalination for water treatment is approximately 3-3.5 kWh (electrical) per cubic meter of water, given a saltwater input equal to Earth sea water and using reverse osmosis. (1)
+The energy requirements of desalination for water treatment is approximately 3-3.5 kWh (electrical) per cubic meter of water, given a saltwater input equal to Earth sea water and using reverse osmosis. (2)
 With the ~500W/m^2 sunlight intensity on Mars, an efficiency of 20-25% and a 20-25% capacity factor, a square meter of ground can produce 0.5kWh per day or sol. So each day, a solar array can desalinate enough seawater-like salty water on Mars to equal its own area up to 15-33cm deep (about 1 foot), or 150 to 300 l/m2 per day.
@@ Line 39: / Line 39: @@
 References
-(1) https://www.desware.net/Energy-Requirements-Desalination-Processes.aspx
+(2) https://www.desware.net/Energy-Requirements-Desalination-Processes.aspx

@@ Line 26: / Line 26: @@
 ==Desalination==
-The energy requirements of desalination for water treatment is approximately 1.5-3kWh per cubic meter of water, given a saltwater input. (reference)
+The energy requirements of desalination for water treatment is approximately 3-3.5 kWh (electrical) per cubic meter of water, given a saltwater input equal to Earth sea water and using reverse osmosis. (1)
 With the ~500W/m^2 sunlight intensity on Mars, an efficiency of 20-25% and a 20-25% capacity factor, a square meter of ground can produce 0.5kWh per day or sol. So each day, a solar array can desalinate enough seawater-like salty water on Mars to equal its own area up to 15-33cm deep (about 1 foot), or 150 to 300 l/m2 per day.
@@ Line 32: / Line 32: @@
 This would add itself to the recycled water in the food production system, and compensate for losses due to water treatment required to remove dissolved salts and other contaminants.
-Plants require large amounts of water to function correctly. In greenhouses, water irrigation requirements have a typical value of 10 to 16 l/m2 per day.  So even if an open system configuration was adopted, a desalination array would be able to compensate all the required water with a production area one tenth of the farm area.  If we plan for about 2% replacement of the water, then the desalination plant would need about 500 times less area that the food production area.
+Plants require large amounts of water to function correctly. In greenhouses, water irrigation requirements have a typical value of 10 to 16 l/m2 per day.  So even if an open system configuration was adopted, a desalination array would be able to compensate all the required water with a production area one tenth of the farm area.  If we plan for about 2% replacement of the water per cycle, then the desalination plant would need about 500 times less area that the food production area.
 ==TSSE==
 Temperature Swing Solvent Extraction(TSSE)<ref>https://academiccommons.columbia.edu/doi/10.7916/d8-exf1-nm75/download</ref>is a process for removing impurities from water using a solvent at various temperatures. It works on the basis that the amount of water that a solvent can hold changes with temperature, so by "swing"ing the temperature of the solvent, it can extract water from brine and deposit it elsewhere. This process is useful because it requires only low grade waste heat to run and easily produced industrial solvents, rather than needing high pressure pumps and custom membranes in a reverse osmosis system. The primary drawback is that without a final reverse osmosis step, the water may contain traces of solvent. A two phase system utilizing Diisopropylamine (DIPA) and diethyl ether (Eth) was suggested to resolve this issue, as the second Eth washing can remove the DIPA while being easy to remove due to the high vapor pressure and immiscibility of Eth.

@@ Line 24: / Line 24: @@
 ==Water treatment plant==
 The first water treatment plants will be packaged units provided from Earth.  These types of units are already produced on Earth for buildings and communities isolated from the larger centralized water treatment plants available for towns and cities.
 ==TSSE==
 Temperature Swing Solvent Extraction(TSSE)<ref>https://academiccommons.columbia.edu/doi/10.7916/d8-exf1-nm75/download</ref>is a process for removing impurities from water using a solvent at various temperatures. It works on the basis that the amount of water that a solvent can hold changes with temperature, so by "swing"ing the temperature of the solvent, it can extract water from brine and deposit it elsewhere. This process is useful because it requires only low grade waste heat to run and easily produced industrial solvents, rather than needing high pressure pumps and custom membranes in a reverse osmosis system. The primary drawback is that without a final reverse osmosis step, the water may contain traces of solvent. A two phase system utilizing Diisopropylamine (DIPA) and diethyl ether (Eth) was suggested to resolve this issue, as the second Eth washing can remove the DIPA while being easy to remove due to the high vapor pressure and immiscibility of Eth.

← Older revision		Revision as of 10:21, 23 July 2020
Line 24:		Line 24:
	==Water treatment plant==		==Water treatment plant==
	The first water treatment plants will be packaged units provided from Earth. These types of units are already produced on Earth for buildings and communities isolated from the larger centralized water treatment plants available for towns and cities.		The first water treatment plants will be packaged units provided from Earth. These types of units are already produced on Earth for buildings and communities isolated from the larger centralized water treatment plants available for towns and cities.
		+
		+	==TSSE==
		+	Temperature Swing Solvent Extraction(TSSE)<ref>https://academiccommons.columbia.edu/doi/10.7916/d8-exf1-nm75/download</ref>is a process for removing impurities from water using a solvent at various temperatures. It works on the basis that the amount of water that a solvent can hold changes with temperature, so by "swing"ing the temperature of the solvent, it can extract water from brine and deposit it elsewhere. This process is useful because it requires only low grade waste heat to run and easily produced industrial solvents, rather than needing high pressure pumps and custom membranes in a reverse osmosis system. The primary drawback is that without a final reverse osmosis step, the water may contain traces of solvent. A two phase system utilizing Diisopropylamine (DIPA) and diethyl ether (Eth) was suggested to resolve this issue, as the second Eth washing can remove the DIPA while being easy to remove due to the high vapor pressure and immiscibility of Eth.

@@ Line 1: / Line 1: @@
 Potable water treatment [[Settlement facilities|facilities]] are an essential requirement for a Martian settlement.  A number of the following processes may be required, depending on the source of the water.  Some industrial processes will produce clean water than can be used in a potable water system.  [[Waste water treatment]] facilities are very similar to water treatment facilities, but will treat more heavily contaminated water.  In a closed loop system, the cleaned waste water is returned to the potable water treatment system for re-use. The [[Settlement systems|water distribution system]] links the two ends of the water infrastructure.
-==Water treatment processes==
+==Martian water contaminants==
-Reverse osmosis
+Salts, sand and hydrated minerals. Minerals (Ca,Mg,Fe) Primary contaminants from the martian environment and secondary contaminants from human use.
-Sand filtration
+Water hardness. perchlorate.
-Chlorination
+==Water treatment processes==
-==Expected contaminants==
+*Reverse osmosis (perchlorates,Ca,Mg)
 ==Water treatment plant==
 The first water treatment plants will be packaged units provided from Earth.  These types of units are already produced on Earth for buildings and communities isolated from the larger centralized water treatment plants available for towns and cities.

← Older revision		Revision as of 18:20, 24 July 2019
Line 1:		Line 1:
−	Potable water treatment [[Settlement facilities\|facilities]] are an essential requirement for a Martian settlement. A number of the following processes may be required, depending on the source of the water. Some industrial processes will produce clean water than can be used in a potable water system. [[Waste water treatment]] facilities are very similar to water treatment facilities, but will treat more heavily contaminated water. In a closed loop system, the cleaned waste water is returned to the potable water treatment system for re-use.	+	Potable water treatment [[Settlement facilities\|facilities]] are an essential requirement for a Martian settlement. A number of the following processes may be required, depending on the source of the water. Some industrial processes will produce clean water than can be used in a potable water system. [[Waste water treatment]] facilities are very similar to water treatment facilities, but will treat more heavily contaminated water. In a closed loop system, the cleaned waste water is returned to the potable water treatment system for re-use. The [[Settlement systems\|water distribution system]] links the two ends of the water infrastructure.

	==Water treatment processes==		==Water treatment processes==