A method and system for drying an active part of an electric transformer, by continuously determining a moisture content in the solid insulations during vapor phase drying in a drying oven and stopping this drying when an equilibrium moisture content is reached. Then, continuously determining a moisture content in the solid insulations during the retightening and geometric adjustment phase of the active part outside the drying oven and continuing with the determination of moisture content during vacuum drying once the active part is inside the hermetically sealed tank, and stopping vacuum drying when an equilibrium moisture content is reached in the solid insulations. The determination of moisture content and equilibrium moisture content is carried out by applying the diffusion equation.

A motor assembly for a laundry treating appliance, the motor assembly including an impeller housing, a compressor housing disposed within the impeller housing, a compressor motor disposed within the compressor housing, an impeller mechanically coupled to the compressor motor and disposed within the impeller housing, and a cover for the impeller housing.

An energy efficient a drying system and process using heated, dry air. The system includes an air inlet, a heat pump evaporator unit, a heat pump condenser unit, a drying unit, a heat exchanger unit, a fan, and air channels for transport of airflow from the air inlet through the system. The fan causes air to flow into the air inlet through the heat pump evaporator unit and to maintain an airflow through the system. The heat pump evaporator unit is configured to use a refrigerant to absorb heat from air that flows into the system through the heat pump evaporator unit. The heat pump condenser unit is configured to release the heat absorbed at the evaporator to the airflow. The heat exchanger unit is arranged to transfer heat from the airflow leaving the drying unit to the cold, dehumidified air flowing from the heat pump evaporator unit.

Provided herein is a method of drying an electrode assembly of lithium-ion battery, comprising drying the electrode assembly in two successive stages under vacuum at elevated temperature; filling the oven with hot, dry air or inert gas; repeating the steps of vacuum drying and gas filling several times. The method disclosed herein is particularly suitable for drying electrode assemblies using aqueous binders.

Vacuum rotary automatic dryers for fruits, vegetables, grains, herbs, medicines and granulate, is composed of the box frame (5), the loading conveyor (6) and the hopper (7), whereby on the box frame (5) in the upper horizontal sector is the shaft (18), mounted to which the frame (8) is attached, in which a cylinder (4) is mounted with the cover (32), which rotates around its axis using an electric motor (11). In the cylinder (4) are small cylinders (1) inserted in which the products for drying are loaded. In the process of loading the products, cylinder (4) with the cylinders (1) is placed in a vertical position, and then, in the drying process, it is rotated into a horizontal position by a pneumatic cylinder (19). Low-pressure in smaller cylinders (1) is achieved using a vacuum pump (2), and the warm water is fed through a swivel joint (25) through a hollow shaft (9) in the central tube (26) and the space of cylinder (4) and flows around the outer surface of small cylinders (1). The area under the cover (32) and in small cylinders (1) is connected with the circulating pump (21) which pushes water while washing the products through a vacuum distributer (20) filling about of useful volume. Through the PLC controller (22) cycles of washing and drying of the product, as well as washing of small cylinders (1), take place automatically. In accordance with the idea of the invention, the vacuum is achieved only in small cylinders (1), which reduces the dimensions and quantity of materials for the construction of dryers, as well as the energy consumption, because the design allows the evaporation with low-pressure below 50 millibars and a heating temperature below 40 C. The product quality is also improved because of the slight movement of the products prevents them from sticking to the inner walls of the smaller cylinders (1) and the walls of the augers (3,41) and thus prevents damage to the membrane, which is especially important when drying fruits. The invention also allows, that in the same device, washing of products before drying and washing of small cylinders (1) and augers (3, 41) after unloading of dried products, which is very important, because hand washing with existing dryers significantly increases the time between two drying cycles. The invention also allows that the space for the products, i.e. in smaller cylinders (1), is fed with chemical solutions in liquid or gaseous state using a circulating pump (21), e.g. i

Provided herein is a method of drying electrode assembly of lithium-ion battery, comprising the steps of vacuum drying the electrode assembly in an oven at elevated temperature; filling the oven with hot, dry air or inert gas; repeating the steps of vacuum drying and gas filling 2 or more times. The method disclosed herein can provide the electrode assembly having a water content of less than 20 ppm.

An apparatus and method for microwave vacuum-drying of organic materials, such as food products. The apparatus has a microwave vacuum chamber 20, a loading module 36 to load containers 38 of the organic material into the vacuum chamber, a rotatable cylindrical cage 64 in the vacuum chamber for rotating the containers, a piston 114 for moving the rotating containers through the vacuum chamber, and means for unloading the containers of dehydrated material from the vacuum chamber. The apparatus may include an equilibration chamber 150 for cooling the dehydrated material under reduced pressure, and a transfer module 42 to transfer the containers from the vacuum chamber to the equilibration chamber. The apparatus has a microwave transparent window 54 for transmission of radiation into the vacuum chamber, and a gas jet 58, 60, 62 for blowing a stream of gas, such as air or nitrogen, into the vacuum chamber adjacent to the window.

Methods for drying cannabis in continuous throughput-type and batch-type microwave vacuum drying apparatus. One method uses a vacuum chamber having a plurality of adjacent drying zones. The cannabis is conveyed through each of the zones while exposing it to microwave radiation. Each of the drying zones has a microwave power level different from that of an adjacent drying zone, the microwave power levels of zones varying from each other in a non-linear arrangement from the first zone to the last zone. In a batch method, cannabis is loaded into a vacuum chamber, the pressure is reduced, and the cannabis is irradiated with microwave radiation at a first power level. The surface temperature of the cannabis is measured and when the temperature exceeds a specified temperature for a time period greater than a first time period, the power level is reduced to a lower power level for a second time period. The methods of drying maximize the retention of terpenes in the cannabis.

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.

A system (2) for extruding and drying an extruded honeycomb body (14) which has channels (18) that extend in a longitudinal direction (L) and which channels (18) are each bounded by first channel walls (20a) that extend in a first direction (A) which is transverse relative to the longitudinal direction (L), and by second channel walls (20b) that extend in a second direction (B) in which is also transverse relative to the longitudinal direction (L) comprises: (i) an extruder (16) having an extrusion head (17) for producing the honeycomb body (14) by extrusion; (ii) a microwave oven (4) comprising an arrangement of a plurality of microwave radiators (6), each microwave radiator being for irradiating the honeycomb body with a directional microwave beam in an irradiation direction (S); and (iii) a feed unit (12) adjoining the extruder (16) for transferring the honeycomb body from the extruder (16) into the microwave oven (4), wherein either: (a) the extrusion head (17) of the extruder is oriented in such a way that during operation of the system the orientation position of the extruded honeycomb body (14) resulting from the extrusion when transferred into the microwave oven (4) is such that the irradiation direction (S) of each microwave radiator (6) is oriented at a predefined irradiation angle (a) which is not zero relative to each of the two transverse directions (A, B) of the first and second channel walls (20a, 20b); GBor (b) the system (2) is designed to sense the orientation of the first and/or second channel walls (20a, 20b) of the honeycomb body produced by the extruder and to move the honeycomb body and/or a microwave radiator (6) into a set point orientation such that the irradiation direction (S) of each microwave radiator (6) is oriented at a predefined irradiation angle (a) which is not zero relative to each of the two transverse directions (A, B) of the first and second channel walls (20a, 20b).