Disclosed herein is a solar thermal osmosis desalination system comprising a forward osmosis subsystem and a reverse osmosis subsystem where the forward osmosis subsystem is configured to receive solar thermal heat and generate power that can be used to operate the reverse osmosis subsystem.

There is described a method for producing 3-hydroxypropanal, the method comprising: culturing an Acetobacter lovaniensis bacterium in a growth medium containing phosphate at a level which is more than 1 g/liter and nitrate at a level which is more than 0.1 g/liter, wherein culturing of the bacterium produces the 3-hydroxypropanal. The 3-hydroxypropanal can be separated from the growth medium or, when the microorganism has converted some or all of the 3-hydroxypropanal to 3-hydroxypropionic acid and/or a 3-hydroxypropionate ester, it may be separated as 3-hydroxypropionic acid or a 3-hydroxypropionate ester. The separated product can be converted into other chemicals such as an ester of 3-hydroxypropionic acid, 3-hydroxypropionic acid, 3 -hydroxypropionate salts (including ammonium, sodium and calcium 3-hydroxypropionate), acrylic acid, acrylates, acrylamide, acrylonitrile, acrolein and 1,3 propanediol.

The present invention relates to separation of desired target products from biological, plant, and waste-type material, wherein the desired target products include renewable fuels such as ethanol, biobutanol, and biodiesel, wherein the separation is conducted with a cross-flow filtration system having the ability to separate desired products from both non-viscous and viscous medium.

The present invention relates to separation of desired target products from biological, plant, and waste-type material, wherein the desired target products include renewable fuels such as ethanol, biobutanol, and biodiesel, wherein the separation is conducted with a cross-flow filtration system having the ability to separate desired products from both non-viscous and viscous medium.

A membrane distillation arrangement (100) comprising: at least two dividers (120), each divider (120) having a top (122) and a base (124) and at least one side (126) which extends between the top (122) and the base (124); at least one transfer element (132) selected from a membrane, heat transfer component or combination thereof, each transfer element (132) having a top (134) and a base (136), each transfer element (132) being supported between two dividers (120); a plurality of perimeter seals (130), at least one perimeter seal (130) extending around the perimeter of the top (134) or the base (136) of each transfer element (132), each perimeter seal (130) forming a substantially fluid tight seal and a fluid flow space (140, 141) between the respective top (134) or base (136) of each transfer element (132) and a respective adjacent face of a divider (120). Each divider (120) includes at least one side inlet (114) and at least one side outlet (116), each side inlet (114) and side outlet (116) extending into the at least one side of each divider (120), and being in fluid communication with the respective fluid flow space (140, 141) formed between the adjacent transfer element (32) and the respective adjacent face of a divider (120).

A process produces salt by way of strong brine concentration after sea water desalination by using a two-way circulation method and bromine extraction. The process includes the following steps: A, preparing fresh water and strong brine from sea water in a high-pressure reverse osmosis unit by using a reverse osmosis method, wherein the concentration of the prepared strong brine is 70000 to 80000 PPM; and B, performing fresh and concentrated separation on the strong brine with the concentration of 70000 to 80000 PPM in a two-way circulation manner by using a concentration difference method till the strong brine is crystallized.

A process produces salt by way of strong brine concentration after sea water desalination by using a two-way circulation method and bromine extraction. The process includes the following steps: A, preparing fresh water and strong brine from sea water in a high-pressure reverse osmosis unit by using a reverse osmosis method, wherein the concentration of the prepared strong brine is 70000 to 80000 PPM; and B, performing fresh and concentrated separation on the strong brine with the concentration of 70000 to 80000 PPM in a two-way circulation manner by using a concentration difference method till the strong brine is crystallized.

The method of recycling brine from a multi-stage flash desalination plant recycles the high-salinity, high-temperature brine output from a multi-stage flash desalination plant to produce diluted brine suitable for reinjection back into the multi-stage flash desalination plant as a makeup stream. The high-salinity, high-temperature brine output from the multi-stage flash desalination plant is diluted with water extracted from treated wastewater effluent output from a wastewater treatment plant, thus providing further recycling of the treated wastewater effluent. Following osmotic transfer of the diluting water from the treated wastewater effluent to produce the diluted brine, the remaining concentrated treated wastewater effluent passes through a secondary filtration system to yield a solid product and a volume of permeate water. The volume of permeate water may be further mixed with the diluted brine.

The method of recycling brine from a multi-stage flash desalination plant recycles the high-salinity, high-temperature brine output from a multi-stage flash desalination plant to produce diluted brine suitable for reinjection back into the multi-stage flash desalination plant as a makeup stream. The high-salinity, high-temperature brine output from the multi-stage flash desalination plant is diluted with water extracted from treated wastewater effluent output from a wastewater treatment plant, thus providing further recycling of the treated wastewater effluent. Following osmotic transfer of the diluting water from the treated wastewater effluent to produce the diluted brine, the remaining concentrated treated wastewater effluent passes through a secondary filtration system to yield a solid product and a volume of permeate water. The volume of permeate water may be further mixed with the diluted brine.

A water distillation system including a reservoir unit configured to reserve a second liquid of higher concentration than the first liquid; a pipe including a first end communicated with the first liquid and a second end communicated with the second liquid in the reservoir unit; a semipermeable membrane fitted on the pipe to separate the first liquid and the second liquid, so that the first liquid is mixed into the second liquid through the semipermeable membrane and led to the reservoir unit by osmotic action; and a distillation unit configured to distill the second liquid in the reservoir unit by solar energy.