Method, system, and apparatus for drying materials used in additive manufacturing and, more particularly, drying systems which are capable of rapidly drying polymers by alternating heating, and low-pressure cycles without affecting material properties.

A dehydrator apparatus for dehydrating biological material. The apparatus includes an external housing, and a vessel supported within said external housing and spanning in a longitudinal direction thereof in elevated relation from a bottom of the housing. A loading inlet feeds into said vessel from outside the housing for admission of biological material. An air intake feeds into the housing to deliver heated air thereto from a hot air source, and air routing components within the external housing guide the heated air into heat exchange relationship with the vessel itself, and also into heating and aerating exposure to contents of said vessel. An agitator is installed in operable relation to the vessel to agitate the material fed thereinto via the material inlet. An exhaust outlet exhausts the heated air from the housing after having heated and aerated the vessel and its contents.

The present disclosure relates to a drying apparatus for a powder raw material for manufacturing a secondary cell with an electric heater. In an embodiment of the present disclosure, a plurality of independently controlled heaters are mounted on a main body of an apparatus in which a plurality of heating regions are defined, and the temperature deviation of the internal chamber can reduce by providing the amount of heat supplied to each heating region through the control of the plurality of heaters. The main body of the apparatus includes a cylindrical portion in which the powder raw material is accommodated and sidewalls on both sides of the cylindrical portion, and by installing heaters on the cylindrical portion and the sidewalls, respectively, the entire region defining the main body of the apparatus can be evenly heated.

A dehydrator apparatus for dehydrating biological material. The apparatus includes an external housing, and a vessel supported within said external housing and spanning in a longitudinal direction thereof in elevated relation from a bottom of the housing. A loading inlet feeds into said vessel from outside the housing for admission of biological material. An air intake feeds into the housing to deliver heated air thereto from a hot air source, and air routing components within the external housing guide the heated air into heat exchange relationship with the vessel itself, and also into heating and aerating exposure to contents of said vessel. An agitator is installed in operable relation to the vessel to agitate the material fed thereinto via the material inlet. An exhaust outlet exhausts the heated air from the housing after having heated and aerated the vessel and its contents.

Apparatus for drying Spent Ion-Exchange Resins (SIER), which can intensify the SIER drying process, reduce power consumption, and accelerate discharge of SIER when the drying process is completed. The apparatus comprises a sealed cylindrical body, and a blow-down choke installed in an upper part of the sealed cylindrical body and a nozzle to feed the spent ion-exchange resins is installed inside the body, and a nozzle to retrieve dried ion-exchange resins is installed in its bottom part and equipped with a locking device. An external heater is provided for the body, and a drive shaft that is installed in alignment inside the body, capable of rotation, and equipped with a stirrer. A lower part of the drive shaft with lower screw winding is installed in alignment inside the nozzle to retrieve dried ion-exchange resins. The nozzle to retrieve dried ion-exchange resins is equipped with a water draining device.

Provided is a device for granulating, agglomerating, pelletising, drying and/or coating, the device including a swirl chamber, a distribution chamber, wherein the swirl chamber is separated from the distribution chamber by a base and wherein a powder to be granulated or a powder mixture to be granulated is presented in the swirl chamber, the device further including at least one agitator for thoroughly mixing the powder to be granulated or the powder mixture to be granulated and at least one addition device for a liquid, wherein the base is designed in several parts and at least one base part is horizontally and/or vertically displaceable, with the result that that the base becomes a distributor plate. Also provided is a method for granulating, agglomerating, pelletising, drying and/or coating using such a device and a base suitable for use as a distributor plate in a convective drying apparatus.

Methods and devices for agitating material. In some embodiments, an agitator is positioned in a receptacle to agitate material therein. The agitator may include a shaft, an arm extending from the shaft, and at least one knife extending from the arm. In some embodiments, the agitator may further include one or more agitator elements operably connected to at least one knife.

A hemp biomass drying assembly that is disposed within a structure and having a central lift assembly, a rotatable tine assembly, an auger assembly, and a track drive assembly that are all connected to a control system to activate and operate all assemblies. The drying assembly has multiple modes of operation that include a spreading mode, a leveling mode, and stirring mode, and an unloading mode.

The herein described invention is a Negative Pressure Drying Apparatus. The preferred embodiment of the Negative Pressure Drying Apparatus is designed for drying saturated baseballs; however, the Negative Pressure Drying Apparatus could be used to dry most any article that would fit within the drying receptacle. The Negative Pressure uses mechanical means of moving air, generally an outward blowing fan mounted to a first end of a drying receptacle, which is comprised of a plurality of intake holes at a second end of the drying receptacle. The outward blowing fan creates negative pressure within the drying receptacle due to the output of the fan exceeding the intake of air through the intake holes. The negative pressure within the drying receptacle accelerates drying by drawing moisture out of the saturated articles.

The herein described invention is a Negative Pressure Drying Apparatus. The preferred embodiment of the Negative Pressure Drying Apparatus is designed for drying saturated baseballs; however, the Negative Pressure Drying Apparatus could be used to dry most any article that would fit within the drying receptacle. The Negative Pressure uses mechanical means of moving air, generally an outward blowing fan mounted to a first end of a drying receptacle, which is comprised of a plurality of intake holes at a second end of the drying receptacle. The outward blowing fan creates negative pressure within the drying receptacle due to the output of the fan exceeding the intake of air through the intake holes. The negative pressure within the drying receptacle accelerates drying by drawing moisture out of the saturated articles.