A fan system includes a fan having a controllable speed setting or power setting; an optical camera directed outward from the fan and which provides optical data; a controller configured to: communicate with the optical camera, receive the optical data, control rotating directions and the speed setting or the power setting of the fan; and a processor configured to: receive the optical data, identify, using a machine learning model, directions of one or more targets in relation to the fan using the received optical data of the optical camera, access a data bank, determine, using the data bank, the speed setting or the power setting of the fan, and communicate with the controller to control the rotating directions of the fan and the speed setting or power setting of the fan based on the identified directions of one or more targets in relation to the fan.

A blower includes a housing including a proximal opening and a distal opening that are co-axially aligned, a stator component provided to the housing, an impeller positioned between the proximal opening of the housing and the stator component, and a motor adapted to drive the impeller. The impeller includes a plurality of impeller blades. The stator component includes a plurality of air directing grooves along its exterior surface. The leading edge of the air directing grooves extend tangentially outwards from the outer tips of the impeller blades and are configured to collect the air exiting the impeller blades and direct it from a generally tangential direction to a generally radial direction by dividing the air from the impeller and directing the air along a curved path towards the distal opening so that airflow becomes substantially laminar.

A diagnostic apparatus for an electric drive object that generates a drive force in response to receiving electric power, the diagnostic apparatus includes a circuitry configured to: acquire time series force data associated with the drive force; identify a force oscillation level associated with the drive force based on the force data; set an oscillation threshold at a first level when the drive object operates at a first speed and set the threshold at a second level higher than the first level when the drive object operates at a second speed higher than the first speed; and identify an irregularity of the drive object in response to determining that the force oscillation level exceeds the oscillation threshold.

The disclosed technology generally relates to a compressor housing that includes a main housing portion and an end housing portion. The main housing portion is configured to house a compressor motor and an inlet housing. The inlet housing is configured to receive vapor refrigerant downstream of the compressor motor. The main housing portion and the end housing portion are configured to interface at a mating surface of the respective housing portions and define a volume. The end housing portion includes a sensor cavity extending into the volume toward an opening of the inlet housing.

A compressor according to an embodiment of the present disclosure vibrates a rotating shaft or changes an operating frequency of a motor, in response to a vibration frequency of a discharge passage falling outside a normal range.

Provided are a slim-type stator using a multilayer printed circuit board (PCB) capable of maximally generating torque in an opposite rotor and capable of increasing airflow, and a single-phase motor and a cooling fan using the same. The slim-type stator includes: a multilayer PCB; and a plurality of coil patterns formed on respective PCB layers of the multilayer PCB and connected via throughholes, wherein the multilayer PCB includes at least one protrusion corresponding to the plurality of coil patterns, and at least one recess disposed between the plurality of coil patterns.

An automotive vapor pump for pumping a pump gas having a fuel vapor. The automotive vapor pump includes a pump inlet opening, a pump outlet opening, an outlet volute, a pump outlet duct which is substantially tangential and which fluidically connects the outlet volute with the pump outlet opening, a centrifugal pumping wheel which pumps the pump gas from the pump inlet opening into the outlet volute and subsequently into the pump outlet duct, an electric motor which drives a pumping wheel, the electric motor including a static motor coil, a magnetic rotor body, and a motor driving electronics which drives the static motor coil, an electric connector plug which electrically connects the motor driving electronics with an external control unit, and an integrated pressure sensor which detects a fluidic pressure in the outlet volute or in the pump outlet duct.

An electric blower includes a motor including a rotor having a rotation shaft, a stator provided to surround the rotor, and a sensor mounted on the stator and facing the rotor, a moving blade mounted at one end side of the rotation shaft in an axial direction of the rotation shaft, a frame housing the stator and having a hole on a side facing to the moving blade, a first air path outside the frame, a second air path inside the frame, and an air guide member for guiding an airflow generated by the moving blade to the second air path.

A compressor system includes; a compression section that sucks and compresses gas; a rotor that includes the compression section; a gas bearing that supports the rotor; a dynamic-pressure generating gas supply system that supplies, to a gas supply port for dynamic pressure of the gas bearing, bleed gas from the gas pressurized by the compression section; and an external gas supply system for static pressure that supplies, to a gas supply port for static pressure of the gas bearing, external gas from outside of the compression section. The dynamic-pressure generating gas supply system and the external gas supply system for static pressure respectively include paths that are independent of each other to the gas bearing. The gas supply port for dynamic pressure and the gas supply port for static pressure are independent of each other.

A vacuum pump exhaust system and an exhausting method of the vacuum pump supply a purge gas to the vacuum pump such that an amount of the purge gas satisfies one of following conditions: an amount of the purge gas flowing at a higher velocity than a backflow velocity of gas exhausted by the vacuum pump on at least a part of a downstream side of the temperature sensor unit, and an amount of the purge gas having a pressure of one of an intermediate flow and a viscous flow around the temperature sensor unit. The exhaust system further includes a purge gas supply unit capable of controlling a flow rate of purge gas introduced into the vacuum pump. This configuration can prevent process gas from flowing backward so as to change the composition around the temperature sensor unit, thereby accurately measuring the temperature of the rotating portion.