A liquid mixing device and a liquid mixing method are provided, which can suppress air from being mixed into liquids to generate air bubbles, and the structure is easy to clean, so that a high-quality mixed liquid can be obtained. The liquid mixing device is suitable for mixing multiple liquids and includes a stirring chamber; a supply portion, disposed on an inner surface of the stirring chamber to supply the liquids into the stirring chamber; a stirring component, disposed in the stirring chamber to stir the liquids supplied into the stirring chamber; and an opposing plate, disposed on the stirring component and disposed opposite to the supply portion.

The present disclosure discloses a high-temperature aerogel heat insulation coating, preparation equipment and a use method for the preparation equipmen. A supporting leg frame is arranged on the outer side wall of the reaction tank; a storage cavity is formed in the upper outer box; a dispersing shaft is arranged in the storage cavity; dispersing blades are installed on the dispersing shaft; a dispersing motor and a material guiding pipe are arranged outside the upper outer box; an unloading mechanism is arranged under the reaction tank; and an exhaust hole and a feeding hole are formed in the outer part of the reaction tank.

In one embodiment, the present system describes a system wherein a first fluid is within a tank. An intermittent mixer is used for agitating the first fluid within the tank. At least one data acquisition device within the tank is capable of measuring at least one characteristic within the first fluid. In the embodiment, at least one data analyzer is capable of receiving the characteristics within the first fluid, comparing the characteristics within the first fluid to the characteristics of a second fluid, generating a data packet which contains a calculated operational speed and an operational time needed for the intermittent mixer to agitate the first fluid to obtain the characteristics of the second fluid and transmitting the data packet to the intermittent mixer. In this system the intermittent mixer is capable of altering the first fluid within the tank into the second fluid.

The present invention relates to a fluid treatment chamber with a self-cleaning rotary sight window. The proposed rotary sight window includes a stationary frame (10); a transparent stationary panel (11) attached to the stationary frame by a leak-tight joint (41); a rotary frame (20) connected to the stationary frame (10) by a rotary joint (40); a transparent rotary panel (21) attached to the rotary frame (20) by a joint, the transparent rotary panel (21) being arranged opposite and spaced apart from the transparent stationary panel (11) by an intermediate chamber (1); and a motor (30) connected to the transparent rotary panel (21) or to the rotary frame (20), wherein the joint between the transparent rotary panel (21) and the rotary frame (20) is an interference joint (43) attached by a dimensional interference fit.

The present invention relates to a fluid treatment chamber with a self-cleaning rotary sight window. The proposed rotary sight window includes a stationary frame (10); a transparent stationary panel (11) attached to the stationary frame by a leak-tight joint (41); a rotary frame (20) connected to the stationary frame (10) by a rotary joint (40); a transparent rotary panel (21) attached to the rotary frame (20) by a joint, the transparent rotary panel (21) being arranged opposite and spaced apart from the transparent stationary panel (11) by an intermediate chamber (1); and a motor (30) connected to the transparent rotary panel (21) or to the rotary frame (20), wherein the joint between the transparent rotary panel (21) and the rotary frame (20) is an interference joint (43) attached by a dimensional interference fit.

A stream of seed may be maintained at a metered flow rate through multiple stages of a treatment process. These multiple stages include dispensing, first application of fluid, second application of fluid, and seed transport. Seed transport may be accomplished through a conveyor configured to maintain the metered flow rate while providing static mixing, drying, and conditioning of the treated seed. The metered stream of seed may be treated within a first treatment applicator where a first wet treatment is applied, transferred through the incline conveyor, and treated again within a second treatment applicator where a second wet treatment is applied. Overtreating in multiple stages may layer consecutive seed treatments around the treated seed. A predetermined amount of seed treatment may be applied to the coated seed based on the metered flow rate established. Maintaining the metered flow rate through multiple stages eliminates the need for multiple metering steps.

A system for bone cement includes a vial holder configured for receiving a vial and including a holding structure for maintaining the vial in the vial holder. The vial includes a monomer component for bone cement. A holder chamber is configured to receive and secure the vial holder. The vial holder is advanced toward a vial-breaking device for breaking the vial and releasing its contents into the holder chamber past the elastomeric seal. Once the vial holder is advanced further the elastomeric seal is deformed to form a seal and prevent fumes produced from escaping from the device.

A static mixing tip includes a static mixer, a housing and a body. A head space is between the housing and the static mixer, a sealing lip on the base of the static mixer seals between the base of the static mixer and the housing, and a venting element is on the sealing lip of the static mixer or the housing. The venting element provides gas flow communication between sides of the sealing lip, and a gaseous connection between the head space and an exterior ambient atmosphere such that gases trapped in the head space between the housing and the static mixer can escape during normal operation and operation of the static mixing tip.

An inference system for monitoring a cementitious mixture for three-dimensional printing is provided. The inference system includes an ambient condition sensor, a temperature sensor, a moisture sensor and an image capturing device. The inference system also includes a controller coupled to the ambient condition sensor, the temperature sensor, the moisture sensor, and the image capturing device. The controller receives sensed ambient conditions, a temperature signal, and a moisture content signal. The controller receives an image feed of a portion of a cementitious mixture. The controller also receives signals indicative of a motor speed and a motor torque associated with a mixing container. The controller builds a model and determines a material suitability of the cementitious mixture using the model based on the received ambient conditions, the temperature signal, the moisture content signal, the image feed, the motor speed, and the motor torque and determines one or more corrective actions.

An inference system for monitoring a cementitious mixture for three-dimensional printing is provided. The inference system includes an ambient condition sensor, a temperature sensor, a moisture sensor and an image capturing device. The inference system also includes a controller coupled to the ambient condition sensor, the temperature sensor, the moisture sensor, and the image capturing device. The controller receives sensed ambient conditions, a temperature signal, and a moisture content signal. The controller receives an image feed of a portion of a cementitious mixture. The controller also receives signals indicative of a motor speed and a motor torque associated with a mixing container. The controller builds a model and determines a material suitability of the cementitious mixture using the model based on the received ambient conditions, the temperature signal, the moisture content signal, the image feed, the motor speed, and the motor torque and determines one or more corrective actions.