A chemical mixer tool for use in a storage drum is described. The chemical mixer tool typically comprises a mixer housing assembly in which one end of a mixer shaft is secured, the distal end of the mixer shaft having at least one collapsible impeller assembly removably attached thereon. The chemical mixer tool is configured to be removably secured to the top portion of the storage drum, with the distal end of the mixing shaft extending into the interior of the storage drum.

The present invention: continuously measures pressure in real time by means of pressure detection sensors inside a vessel and inside chemical piping and quickly discharges air when abnormal pressure is generated, so as to stably supply a crude liquid through a fixed pressure-maintaining liquid supply part; checks a standard concentration after the crude liquid is mixed so as to re-transfer the mixed liquid to a mixing tank unit when the concentration thereof does not reach the reference concentration, thereby spraying the mixed liquid through a jet nozzle member; and shortens the mixing time of primarily mixed liquid so as to enable the mixed liquid to be mass-produced and a stable quality thereof to be ensured.

A chemical mixer tool for use in a storage drum is described. The chemical mixer tool typically comprises a mixer housing assembly in which one end of a mixer shaft is secured, the distal end of the mixer shaft having at least one collapsible impeller assembly removably attached thereon. The chemical mixer tool is configured to be removably secured to the top portion of the storage drum, with the distal end of the mixing shaft extending into the interior of the storage drum.

A container (100) within which a food product is to be processed. The container (100) includes: a hollow body (101) providing an interior chamber (110) to receive the product and within which the product is processed, the body (101) having a rim portion (104) surrounding a body top opening (106); a removable lid (107) sealingly associated with the rim portion (104) to close the top opening (106), the lid (107) having: a base (111) sealingly associated with the rim portion (104), the base (111) having a base opening (115) providing access to the chamber (110) and a sealing surface (157) surrounding the base opening (115), a removable valve assembly (112) located in the base opening (115) and sealingly associated with the base (111) to close the base opening (115), the valve assembly (112) including: a main part (122) associated with the base (111) to removably secure the valve assembly (112) in the base opening (115), a seal (123) mounted on the main part (122) and engaging the sealing surface (157), an air opening (131) in the main part (122) providing for air flow from the chamber (110) to exterior of the container (100), a valve (132) operatively associated with the air opening (131) to close the air opening (131) to at least inhibit air flow from exterior of the container (100) to said chamber (110) but permit air flow from the chamber (110) to the exterior, and wherein a cavity (156) is provided between the base (111) and main part (122), leading to said seal (123), with the cavity (156) including a first cavity portion (151) and a second cavity portion (153), with the first cavity portion (151) being configured relative to the second cavity portion (153) to at least partly dissipate kinetic energy of liquid being propelled from the interior (110) into the cavity (156).

The invention comprises a vacuum attachment with multiple ports which easily attaches to an open top container to remove concrete/mortar dust and particulates from the air when mixing concrete/mortar with water. The vacuum attached in configured to fit securely on a variety of containers of different sizes. Further, the vacuum attachment attaches easily to any standard vacuum machine. The vacuum attachment may have lateral segments which provide spacing for two curved portions which terminate in multiple ports. The curved portions may be positioned at the top of the container with the ports facing downward into the container. When a vacuum machine is attached and activated, the vacuum attachment is able to efficiently remove dust particles from the air inside the container. Multiple vacuum attachments may also be used simultaneously by connecting a Y splitter hose to each of the vacuum machine attachment ports of the vacuum attachments.

The invention relates to a method of making a personal care composition, the method comprising steps of: providing a mixer comprising a housing comprising a first fluid inlet, a second inlet, and a fluid outlet, the mixer further rotor rotatably connected with the housing, the rotor comprising blades positioned within the housing to define cells between neighboring blades and the housing; preparing a personal care chassis base comprising surfactants and water; preparing a microcapsule composition comprising microcapsules, and air; advancing personal care chassis base along a flow path from the first fluid inlet toward the fluid outlet; transferring the microcapsule composition from the second inlet to the flow path by rotating the rotor; directing air in the microcapsule composition from inside the cells toward the second inlet; combining the microcapsule composition with the personal care chassis base to form the personal care composition; and advancing the personal care composition from the outlet. The microcapsule composition may further comprise an aqueous carrier including, but not limited to, water. The personal care composition can be transported to a filling line and filled through a filling nozzle into a bottle.

A system for dissolving gases in water comprises a mixing chamber that holds gas and a container in fluid communication with the mixing chamber. In operation, the mixing chamber is flooded to purge the ambient air. A gas delivery system introduces gas into the mixing chamber to push the water out. A pump then pumps temperature and salinity-treated water into the mixing chamber, and a distributor sprays or disperses the water into the mixing chamber. An optional impingement plate and/or mixing medium trap gas bubbles and hold gas-saturated water within the mixing chamber. This produces a volume of substantially bubble-free, highly-saturated gas-infused water that is then released into the container to mix with the water contained therein. This system can be incorporated in aquariums, ice chests, buckets, and live wells found on boats, kayaks, trucks, and other transports.

A system for use with a gunite rig to capture airborne gunite type materials, particularly those containing silica, during the preparation of the gunite. In one respect, as the bags of silica-containing material are placed in the mixing section of the gunite rig and ripped open, airborne gunite dust is captured by a hood and suction system positioned above the mixer. Further, the mitigation system includes a plenum box and suction system positioned adjacent the mouth of a gunite pot to capture gunite dust generated as the mixed gunite material falls from a hopper into the gunite pot.

A state monitoring system for stirring-degassing processing that includes: a sensor unit and a computer, the sensor unit including a temperature sensor that determines a temperature of a processing target material and a first transmitter-receiver that transmits output values of the temperature sensor to the computer, the computer includes a second transmitter-receiver, an information recorder, and a processor, the second transmitter-receiver receives output values of the temperature sensor transmitted by the first transmitter-receiver. A phenomenon that may appear in output values of the temperature sensor during processing and content of post-comparison determination processing performed by the processor according to the phenomenon are associated in information that is recorded in the information recorder, and the processor compares information recorded in the information recorder and a specific phenomenon that has appeared in output values of the temperature sensor during processing, and performs post-comparison determination processing according to a result of the comparison.

The invention focuses on a device for sequentially introducing additives in a polymer granulate and the use of the device for mixing the polymer granulate with the additives. The device consisting of a mixer with housing, comprising at least one mixer shaft attached in helix arranged non-continuous conveying pattern shapes, being rotated by a drive for the transport, whereby the mixer in the housing featuring an inlet for the polymer granulate to be mixed and each of the several subsequent inlets for the additive is followed by an outlet for the polymer granulate mixed with the additive, so that two or several mixing zones being formed in the mixer and whereby at least between at two mixing zones on the surface of the mixing shaft one section featuring a continuous screw conveyor instead of the non-continuous conveying pattern shapes, the section not being penetrable for returning solids from the subsequent mixing zone.