The invention relates to a protein hydrolysate and a process for making such protein hydrolysate. In particular the invention relates to a collagen hydrolysate and a process for making such collagen hydrolysate. Further the invention relates to a food, pet food, cosmetic, pharmaceutical or technical application comprising the protein hydrolysate of the present invention and further food, pet food, cosmetic, pharmaceutical or technical constituents.

A device and method of thermal-driven water treatment to fully separate water and solute using a heat source such concentrated solar thermal energy are disclosed herein. The claimed device is integrated to a multi-effect-distillation water treatment system to achieve high energy efficiency and 100% water extraction using high temperature solar thermal energy. In the disclosed water treatment system, water for reclamation is sprayed into droplets which fall into hot, dry air and creates very effective convective heat transfer between water droplets and hot airflow. During the heat transfer process, water is vaporized for pure water collection while the crystallized solute from the reclamation water to the bottom for collection.

A device and method of thermal-driven water treatment to fully separate water and solute using a heat source such concentrated solar thermal energy are disclosed herein. The claimed device is integrated to a multi-effect-distillation water treatment system to achieve high energy efficiency and 100% water extraction using high temperature solar thermal energy. In the disclosed water treatment system, water for reclamation is sprayed into droplets which fall into hot, dry air and creates very effective convective heat transfer between water droplets and hot airflow. During the heat transfer process, water is vaporized for pure water collection while the crystallized solute from the reclamation water to the bottom for collection.

An apparatus is described. The apparatus comprises a liquid dispenser comprising a liquid outlet, the liquid dispenser being configured to generate a droplet stream. The apparatus also comprises a first fluid flow device configured to generate a confinement fluid flow for confining a trajectory of the droplet stream therein, the first fluid flow device comprising an outlet arranged to allow the droplet stream to exit therefrom, wherein the fluid outlet is arranged within the confinement fluid flow device. Furthermore, the apparatus comprises a second fluid flow device configured to generate a reaction fluid flow for reacting with droplets in the droplet stream, wherein the outlet of the first fluid flow device is arranged within the second fluid flow device. A method is also described.

An apparatus is described. The apparatus comprises a liquid dispenser comprising a liquid outlet, the liquid dispenser being configured to generate a droplet stream. The apparatus also comprises a first fluid flow device configured to generate a confinement fluid flow for confining a trajectory of the droplet stream therein, the first fluid flow device comprising an outlet arranged to allow the droplet stream to exit therefrom, wherein the fluid outlet is arranged within the confinement fluid flow device. Furthermore, the apparatus comprises a second fluid flow device configured to generate a reaction fluid flow for reacting with droplets in the droplet stream, wherein the outlet of the first fluid flow device is arranged within the second fluid flow device. A method is also described.

A spray drying process and apparatus for drying a spray dryable liquid composition to a spray dried powder is described, in which the spray dryable liquid composition contains no carrier. The spray dryable liquid composition is processed at a solids concentration not exceeding 80% by weight, based on total weight of the spray dryable liquid composition, being atomized to generate an atomized spray of liquid particles of the spray dryable liquid composition into a spray drying chamber, in which the atomized spray is contacted with a stream of drying fluid flowed at temperature not exceeding 100 C. into the spray drying chamber, to form the spray dried powder.

A spray drying process and apparatus for drying a spray dryable liquid composition to a spray dried powder is described, in which the spray dryable liquid composition contains no carrier. The spray dryable liquid composition is processed at a solids concentration not exceeding 80% by weight, based on total weight of the spray dryable liquid composition, being atomized to generate an atomized spray of liquid particles of the spray dryable liquid composition into a spray drying chamber, in which the atomized spray is contacted with a stream of drying fluid flowed at temperature not exceeding 100 C. into the spray drying chamber, to form the spray dried powder.

A spray drier system is provided for spray drying a liquid sample such as blood plasma. The spray drier system may include a spray drier device adapted to couple with a spray drier assembly. The assembly may include an enclosure mounted to a frame. The assembly may receive a flow of drying gas which is directed by the enclosure shape towards a spray drying head mounted within the enclosure to the frame. Flows of a liquid sample may be further received by the head, which aerosolizes the liquid sample. Aerosolized liquid sample and drying air may be mixed within a drying chamber of the enclosure to produce dried sample and humid air. The dried sample and humid air may also be separated in a collection chamber of the enclosure, with the humid air exhausted from the enclosure.

A spray drier system is provided for spray drying a liquid sample such as blood plasma. The spray drier system may include a spray drier device adapted to couple with a spray drier assembly. The assembly may include an enclosure mounted to a frame. The assembly may receive a flow of drying gas which is directed by the enclosure shape towards a spray drying head mounted within the enclosure to the frame. Flows of a liquid sample may be further received by the head, which aerosolizes the liquid sample. Aerosolized liquid sample and drying air may be mixed within a drying chamber of the enclosure to produce dried sample and humid air. The dried sample and humid air may also be separated in a collection chamber of the enclosure, with the humid air exhausted from the enclosure.

A sea water harvesting process includes the steps of collecting sea water, filtering the sea water, passing the filtered sea water through a high-pressure reverse osmosis membrane to separate the sea water into de-salinated water and concentrated sea water, delivering the concentrated sea water to an evaporator, heating the concentrated sea water in the evaporator under vacuum to produce calcium sulphate, sea salt and a super-concentrated sea water. Downstream of the evaporator the super-concentrated sea water is heated to produce a concentrated mineral liquor containing sea minerals in a concentration of about 42%.