Methods and apparatuses for drying electronic devices are disclosed. Embodiments include methods and apparatuses that heat and decrease pressure within the electronic device. Some embodiments increase and decrease pressure while adding heat energy, such as by using a heated platen in contact with the electronic device or by supplying a gas (e.g., air), which may be heated, into the interior of the electronic device. Embodiments include heating the gas supplied into the interior of the electronic device with pump used to decrease pressure within the electronic device and/or a separate heater. Still other embodiments include controlling the temperature of the gas supplied into the electronic device. Still further embodiments automatically control, such as by using an electronic processor, some or all aspects of the drying of the electronic device.

A vacuum drying device and a related method thereof are provided. The device includes a box body, where a bottom end of the box body is provided with a base, and a top end of the box body is communicated with a vacuumizing pipeline. A lifting mechanism is arranged in the base, and a top end of the lifting mechanism is fixedly connected with a table top. A plurality of drying mechanisms are arranged on the table top, and top ends of the drying mechanisms are fixedly connected with a take-up mechanism. The take-up mechanism is connected with a powder collecting mechanism, the take-up mechanism is fixedly connected with the box body, and the take-up mechanism is connected to a wire collecting mechanism. The wire collecting mechanism is connected to a powder collecting mechanism, and the wire collecting mechanism is fixedly connected to the vacuumizing pipeline.

Methods and apparatuses for drying electronic devices are disclosed. Embodiments include methods and apparatuses that heat and decrease pressure within the electronic device. Some embodiments increase and decrease pressure while adding heat energy, such as by using a heated platen in contact with the electronic device or by supplying a gas (e.g., air), which may be heated, into the interior of the electronic device. Embodiments include heating the gas supplied into the interior of the electronic device with pump used to decrease pressure within the electronic device and/or a separate heater. Still other embodiments include controlling the temperature of the gas supplied into the electronic device. Still further embodiments automatically control, such as by using an electronic processor, some or all aspects of the drying of the electronic device.

A razor drying device for drying razors includes a housing having a top, a base, a back, a front, a left side and a right side defining an interior space within the housing. A wall and a divider are coupled to and positioned within the interior space of the housing, defining respectively a compartment and a chamber. A motor, power module and a processor are coupled to and positioned in the compartment. The motor has a shaft with a terminus extending through the wall. A fan is coupled to the terminus. The power module and the processor are operationally to each other and to the motor. The chamber has a screen for a bottom. The device has a tray, removable from the housing through a complimentary opening in the front. A plurality of inlets is positioned in the back of the housing and in the wall.

A blender has a mixing chamber for reception of materials to be blended. A mixing screw is mounted at a bottom of the mixing chamber for mixing materials within the mixing chamber and delivering mixed materials to an outlet feeding a processing line. Heaters are mounted within the mixing chamber for drying blend material in the mixing chamber.

Methods and apparatuses for drying electronic devices are disclosed. Embodiments include methods and apparatuses that heat and decrease pressure within the electronic device. Some embodiments increase and decrease pressure while adding heat energy, such as by using a heated platen in contact with the electronic device or by supplying a gas (e.g., air), which may be heated, into the interior of the electronic device. Embodiments include heating the gas supplied into the interior of the electronic device with pump used to decrease pressure within the electronic device and/or a separate heater. Still other embodiments include controlling the temperature of the gas supplied into the electronic device. Still further embodiments automatically control, such as by using an electronic processor, some or all aspects of the drying of the electronic device.

Methods and apparatuses for drying electronic devices are disclosed. Embodiments include methods and apparatuses that heat and decrease pressure within the electronic device. Some embodiments increase and decrease pressure while adding heat energy, such as by using a heated platen in contact with the electronic device or by supplying a gas (e.g., air), which may be heated, into the interior of the electronic device. Embodiments include heating the gas supplied into the interior of the electronic device with pump used to decrease pressure within the electronic device and/or a separate heater. Still other embodiments include controlling the temperature of the gas supplied into the electronic device. Still further embodiments automatically control, such as by using an electronic processor, some or all aspects of the drying of the electronic device.

Methods and apparatuses for drying electronic devices are disclosed. Embodiments include methods and apparatuses that heat and decrease pressure within the electronic device. Some embodiments increase and decrease pressure while adding heat energy, such as by using a heated platen in contact with the electronic device or by supplying a gas (e.g., air), which may be heated, into the interior of the electronic device. Embodiments include heating the gas supplied into the interior of the electronic device with pump used to decrease pressure within the electronic device and/or a separate heater. Still other embodiments include controlling the temperature of the gas supplied into the electronic device. Still further embodiments automatically control, such as by using an electronic processor, some or all aspects of the drying of the electronic device.

The purpose of the present invention is to provide an indirect heat drying method and a refined-coal production method, with which the stability of carrier-gas pressure balance can be improved when using indirect heat dryers to dry particulate matter. This indirect heat drying method for particulate matter uses two indirect heat dryers, and is provided with: a step (A) in which particulate matter is dried in a first indirect heat dryer; and a step (B) in which the particulate matter is further dried in a second indirect heat dryer to obtain dried particulate matter. The indirect heat drying method for particulate matter is characterized by being further provided with a step (C) in which first microparticles included in a carrier gas discharged from the first indirect heat dryer are recovered and mixed with the particulate matter supplied to step (B); and a step (D) in which second microparticles included in a carrier gas discharged from the second indirect heat dryer are recovered and mixed with the dried particulate matter obtained in step (B).

A razor drying device for drying razors includes a housing having a top, a base, a back, a front, a left side and a right side defining an interior space within the housing. A wall and a divider are coupled to and positioned within the interior space of the housing, defining respectively a compartment and a chamber. A motor, power module and a processor are coupled to and positioned in the compartment. The motor has a shaft with a terminus extending through the wall. A fan is coupled to the terminus. The power module and the processor are operationally to each other and to the motor. The chamber has a screen for a bottom. The device has a tray, removable from the housing through a complimentary opening in the front. A plurality of inlets is positioned in the back of the housing and in the wall.