An automatic vacuum drying device comprises a drying oven, a heating device used to heat the drying oven, a vacuum extraction device used to evacuate the drying oven, a nitrogen input device used to input nitrogen into the drying oven, and a transporting device located inside the drying oven and used to transport materials, two first openings are located at two opposite sides of the drying oven, an automatic sealing door is mounted on at least one of the first openings, the automatic sealing door includes a first door plank and a second door plank parallel to the first door plank, an elevator structure is located between the first door plank and the second door plank, the elevator structure is used to lift the first door plank and the second door plank. The automatic vacuum drying devices can form an automatic vacuum drying production line conveniently, and the automatic vacuum drying production line has high degree of automation, and high processing efficiency, such that it is possible to drastically improve the vacuum drying efficiency.

An acoustic energy-transfer system includes: an acoustic chest arranged circumferentially around a container configured to receive a material to be processed; and an ultrasonic transducer arranged circumferentially inside the acoustic chest, the ultrasonic transducer defining an acoustic slot extending through the ultrasonic transducer, the acoustic slot angled with respect to a central axis of the acoustic chest.

An acoustic energy-transfer system includes: an acoustic chest arranged circumferentially around a container configured to receive a material to be processed; and an ultrasonic transducer arranged circumferentially inside the acoustic chest, the ultrasonic transducer defining an acoustic slot extending through the ultrasonic transducer, the acoustic slot angled with respect to a central axis of the acoustic chest.

Technologies for controlling food dehydration in a low-oxygen environment include a control device and an enclosed drying chamber. The control device receives sensor data from environmental sensors disposed within the drying chamber. A concentration of oxygen within the drying chamber is determined based on the received sensor data. The control device controls a valve to selectively feed an amount of a combustible gas to a burner assembly disposed within the drying chamber. The burner assembly is ignited by the control device and a flame is produced. The flame depletes the concentration of oxygen within the drying chamber to an initial oxygen concentration level. The control device controls another valve to feed an amount of non-reactive gas into the drying chamber to flush the drying chamber and further deplete the concentration of oxygen within the drying chamber to a lower oxygen concentration level. Other embodiments are described and claimed.

The invention is based on a star-shaped rotation dryer (1) for segmenting a fluidizing chamber 4) into process compartments (11), whereby the star-shaped rotation dryer (1) is pivot mounted and features dividing wall (9) or similar for the conveyance of solid particles along a conveyance path, whereby a flow-receiving base (10) is detachably mounted below the star-shaped rotation dryer (1); the invention further relates to a method of spray-coating solid particles for the purpose of agglomeration, coating, layering, spray granulation or pelletization, whereby the retention time spectrum of the solid particles inside the fluid-bed apparatus (2) has a margin of at least 1:3 (alternatively tRTD903 tRTD10).

Disclosed is a method, apparatus and system of drying wet toner particles which includes the use of cooling fluid. The method also includes introducing a heated drying gas into a toner drying chamber to create a circulating flow of drying gas.

The disclosure provides a method of forming an acoustical panel base mat, including providing a green board including an alkyl ether sulfate surfactant, wherein the green board includes from about 10 to about 40 wt. % solids, and dewatering the green board slurry to form a dewatered green board, wherein the dewatering comprises supplying hot air and applying a vacuum to the green board.

The disclosure provides a method of forming an acoustical panel base mat, including providing a green board including an alkyl ether sulfate surfactant, wherein the green board includes from about 10 to about 40 wt. % solids, and dewatering the green board slurry to form a dewatered green board, wherein the dewatering comprises supplying hot air and applying a vacuum to the green board.

A coat drying device dries a wet-coated film that is coated on a continuously transported coating object having first and second parts, where the second part has a greater heat capacity than the first part. The coat drying device includes a heat source and a heat source moving device. The heat source provides thermal energy primarily to a coating surface of a second part. The heat source moving device moves the heat source to the second part such that a spacing between the second part and the heat source is maintained within a predetermined range.

The present invention relates to a water drying control system for refined cotton. The system comprises a pressing machine and a heat exchanger, a back end part of the pressing machine is provided with a discharge opening, and the system further comprises a control box, a main flap valve, a main drying pipe, a first drying cup, a second drying cup, a first cyclone separator, a first flap valve, a first draught fan, a third drying cup, a fourth drying cup, a second cyclone separator, a second flap valve, a second draught fan, a first infrared ray moisture transducer, a second infrared ray moisture transducer and a third infrared ray moisture transducer. Hot air can be supplemented to change the drying intensity and control the moisture content of the refined cotton of each stage in a reasonable scope, so as to effectively increase the performance.