A slurry mixing device includes an installation frame, a slurry mixing tank, a slurry feeding tank, a cooling mechanism and a slurry discharging mechanism. The slurry feeding tank is movably arranged under the slurry mixing tank, the cooling mechanism and the slurry discharging mechanism. A mass scale is arranged under the slurry feeding tank. A stirring cavity is formed in the slurry mixing tank, and a stirring paddle is arranged in the stirring cavity. A stirring motor is arranged on the slurry mixing tank. An outlet is arranged on the bottom of the stirring cavity. An oil bath cavity is formed between the slurry mixing tank and the stirring cavity. The cooling mechanism includes a lifting cylinder and a lifting base. The lifting base is provided with a rotating paddle and a rotating motor. The lifting cylinder is arranged on the installation frame.

A hydrothermal treatment device (3) is a hydrothermal treatment device (3) performing hydrothermal treatment by heating high-water-content biomass, the hydrothermal treatment device (3) including a treatment container (21) that stores sludge, a sludge supply unit (22) that supplies the sludge to inside of the treatment container (21) such that a space (S) is formed in a vertical upper part of the treatment container (21), a stirrer (23) that is provided within the treatment container (21) and stirs stored matter such that counter flows in an up/down direction occur, and a heat transfer tube (24) that is disposed in a horizontal direction within the treatment container (21) and heats the sludge with heat of vapor flowing within the heat transfer tube (24).

An apparatus configured for attaching to a conventional cooler and mixing the contents therein, the apparatus including a lid assembly integrated with a mixing assembly. The lid assembly includes a lid having both a hole and an opening to allow the addition of contents to the container and a cover that can be positioned over the opening and secured to the lid. The mixing assembly is integrated with the lid assembly through the hole and includes a centering guide positioned at the bottom of the container, a mixing paddle coupled to the top portion of the centering guide, and a handle operatively coupled to the mixing paddle through the hole. After contents are added to the container through the opening, the cover is positioned over the opening and securely coupled to the lid. The handle is operated to cause the mixing paddle to stir the contents of the container.

An agitator device for mixing materials, including a containment vessel defining an interior volume, a hollow shaft having an upper end, a lower end, and a central bore along its length, the lower end extending downwardly into the interior volume of the containment vessel, the hollow shaft being rotatable with respect to the containment vessel, and a takeout tube having an upper end and a lower end, wherein the takeout tube is disposed within the central bore of the hollow shaft so that the lower end of the takeout tube is in fluid communication with the interior volume of the containment vessel.

An isolation device for adipose-derived stromal vascular fraction is provided. More particularly the embodiments relates to novel systems, devices, methods and kits for adipose tissue collection and stromal vascular fractions isolation from collected adipose. The devices and systems are used in the field of healthcare/regenerative medicine.

Methods of production and apparatuses for production for stably producing healthy and functional platelets, and methods for determining operating conditions of an apparatus for producing platelets are provided. The present invention relates to methods of production comprising a step of culturing megakaryocytes in a platelet production medium C, wherein the step of culturing comprises a step of stirring a medium C in containers 1, 4 using stirring mechanisms 2, 5. In one method of production, the step of stirring comprises reciprocating stirring blades 21, 24 in the stirring mechanisms 2, 24 such that any of predetermined turbulent energy, shearing stresses, or Kolmogorov scale is produced, in the medium C. In another method of production, the step of stirring comprises pivoting a stirring blade 51 in the stirring mechanism 5 wherein a plurality of stationary members 53 is placed therearound in a bottom region 4e of the container 4 such that the step of stirring produces turbulence in the medium C. The present invention also relates to apparatuses for production for carrying out the method of production. The present invention also relates to a method for determining operating conditions of an apparatus for producing platelets.

Systems and methods have demonstrated the capability of rapidly cooling the contents of pods containing the ingredients for food and drinks.

A fine-bubble mixed liquid producing apparatus 1 includes a reservoir 4 and a bubble feeding means 6 for feeding bubbles to a liquid L stored in the reservoir 4, wherein the bubble feeding means 6 includes a rotary cylinder 20 having an emitting part 22 on the outer circumferential surface, the emitting part 22 for being rotationally driven by a drive means 10, a circulating means 40 for drawing out the liquid L stored in the reservoir 4 and feeding the liquid L from the emitting part 22 to the reservoir 4, and a gas-liquid mixing part 50 for mixing bubbles with the liquid L circulated by the circulating means 40. This apparatus enables a fine-bubble mixed liquid to be efficiently produced.

An industrial mixing machine comprises a mixing head and at least one attachment means for attaching a mixing container, which contains a material to be mixed and is open on the attachment side, to the mixing head to form a closed mixing receptacle. The mixing head is pivotably mounted in relation to a frame as part of a pivotable assembly in such a way that the closed mixing receptacle formed from mixing head and mixing container is pivotable in relation to the frame to carry out the mixing process. The mixing head has at least one mixing tool, which is seated on a drive shaft extending through the mixing head and rotationally driven thereby, having multiple radial blades. The radial blades have a cross-sectional geometry according to which, starting from its maximum thickness, the blade thickness decreases in the rotational direction toward the rear blade end. In the section of decreasing blade thickness, the blade lower side is pitched more strongly with respect to the horizontal in the rotational direction than the blade upper side. An imaginary straight line connecting the rear end of the radial blades to their respective front end facing in the rotational direction is inclined in relation to the horizontal in the same direction as the inclination of the blade lower side in the section of decreasing thickness.

Systems and methods have demonstrated the capability of rapidly cooling the contents of pods containing the ingredients for food and drinks.