The present disclosure provides a smart clothes drying device and a smart clothes drying method. The smart clothes drying device includes a light intensity sensor, an integrated controller, an umbrella and at least one clothes hanger. The light intensity sensor is to sense light intensity and output a light intensity signal. The integrated controller is to receive the light intensity signal and control opening or closing of the umbrella according to a comparison result of comparing the light intensity signal with a closing light intensity threshold or an opening light intensity threshold in such a manner that the integrated controller controls opening the umbrella when the light intensity signal is greater than the opening light intensity threshold, and the integrated controller controls closing the umbrella when the light intensity signal is less than the closing light intensity threshold.

The present disclosure provides a smart clothes drying device and a smart clothes drying method. The smart clothes drying device includes a light intensity sensor, an integrated controller, an umbrella and at least one clothes hanger. The light intensity sensor is to sense light intensity and output a light intensity signal. The integrated controller is to receive the light intensity signal and control opening or closing of the umbrella according to a comparison result of comparing the light intensity signal with a closing light intensity threshold or an opening light intensity threshold in such a manner that the integrated controller controls opening the umbrella when the light intensity signal is greater than the opening light intensity threshold, and the integrated controller controls closing the umbrella when the light intensity signal is less than the closing light intensity threshold.

A grain aeration system facilitates thorough and efficient aeration of grain within a grain bin. The system includes a grain bin having a top vent and a bottom vent. A stand is positioned within the grain bin. A duct includes a loop section supported on the stand and an extension extending from the loop section out through the bottom vent in the grain bin. The duct has a duct wall and a plurality of perforations extending through the duct wall. A blower drives air flow out of the bottom vent creating air flow into the grain bin through the top vent and into the duct wherein the blower is configured to aerate grain positioned within the grain bin.

A bale dryer including a support frame, at least one air intake manifold movably coupled to the support frame for supplying heated air, a bale retainer coupled to the support frame and configured for retaining at least one bale in a fixed position vertically spaced from the at least one air intake manifold, and an actuator coupled to the at least one air intake manifold and configured to move the at least one air intake manifold between a retracted positon and an extended positon.

The present disclosure relates to a Radix Codcnopsitis Pilosulas sorting and threading machine that rapidly sorts and automatically threads a Radix Codcnopsitis Pilosulas into a string. The Radix Codcnopsitis Pilosulas sorting and threading machine includes a bottom plate, a support leg, a mounting frame, an N-shaped frame, a feeding hopper, a baffle, a first roller, a first conveyor belt, a drive motor, a deep groove ball bearing and a spindle, where the mounting frame is fixedly mounted on the bottom plate through the support leg, the N-shaped frame is mounted on an upper left side of the mounting frame, the feeding hopper is mounted in the top of the mounting frame, two first rollers are rotatably mounted on an upper part of the mounting frame, and a first roller on the right is higher than a first roller on the left.

The present disclosure relates to a Radix Codcnopsitis Pilosulas sorting and threading machine that rapidly sorts and automatically threads a Radix Codcnopsitis Pilosulas into a string. The Radix Codcnopsitis Pilosulas sorting and threading machine includes a bottom plate, a support leg, a mounting frame, an N-shaped frame, a feeding hopper, a baffle, a first roller, a first conveyor belt, a drive motor, a deep groove ball bearing and a spindle, where the mounting frame is fixedly mounted on the bottom plate through the support leg, the N-shaped frame is mounted on an upper left side of the mounting frame, the feeding hopper is mounted in the top of the mounting frame, two first rollers are rotatably mounted on an upper part of the mounting frame, and a first roller on the right is higher than a first roller on the left.

An apparatus for connecting a heater to a grain bin aeration fan features a multi-piece adapter device having a connection adapter with inlets for receiving flexible ducts from a heater. The connection adapter can be used on its own to directly interface with a grain bin aeration fan of a first size, or can be used in combination with a cooperative sizing adapter to adjust an effective outlet size of the adapter to better fit a grain bin aeration fan of a different second size. An ambient air intake in the connection adapter entrains ambient air into the heated air stream.

A method of drying frac sand without heat is comprised of constructing a drainage system and placing sand on top of a perforated top layer thereon. The drainage system has multiple layers through which liquid passes to dewater sand resting thereon. At the bottom of the drainage system, perforated collection pipes, at least partially surrounded by rocks, collect and carry the liquid to a collection pond for reuse. A cellular confinement layer has sections of panels which, upon expansion, have cells filled with rocks. A woven monofilament geotextile fabric layer comprising woven monofilament geotextile fabric sheets sewn together has sized openings which allow fluid, but prevent sand from passing through the openings. The top layer comprises high density polyethylene perforated sheets welded together. A watertight liner sits below the collection pipes and the cellular confinement layer. Protective layers above and below the watertight liner prevent rocks from damaging same.

A method of drying frac sand without heat is comprised of constructing a drainage system and placing sand on top of a perforated top layer thereon. The drainage system has multiple layers through which liquid passes to dewater sand resting thereon. At the bottom of the drainage system, perforated collection pipes, at least partially surrounded by rocks, collect and carry the liquid to a collection pond for reuse. A cellular confinement layer has sections of panels which, upon expansion, have cells filled with rocks. A woven monofilament geotextile fabric layer comprising woven monofilament geotextile fabric sheets sewn together has sized openings which allow fluid, but prevent sand from passing through the openings. The top layer comprises high density polyethylene perforated sheets welded together. A watertight liner sits below the collection pipes and the cellular confinement layer. Protective layers above and below the watertight liner prevent rocks from damaging same.

An infrared (IR) light source drying apparatus (10, 100, 120) is disclosed as including a body (123), an airflow output device (14, 104, 122) for outputting an airflow from the body, and an IR lamp (108, 124) for emitting an IR light ray, the apparatus being without any heating element in the path of movement of the airflow through the body. The airflow outputted by the drying apparatus (10, 100, 120) and directed towards a target (T) is at the ambient temperature, and serves to cool the target. The present invention can provide waterproof functions when drying the target, operate with batteries and use significantly less power for powering the drying apparatus.