A fan control system includes a control module, a first fan module and a second fan module. The control module provides a first control signal to the first fan module to adjust the rotation state of the first fan module. The first fan module provides a second control signal to the second fan module based on the first control signal to adjust the second fan module. The first fan module includes a first terminal and a second terminal. The second fan module includes a first terminal and a second terminal. The first terminal of the first fan module is electrically connected to the control module to receive the first control signal. The second terminal of the first fan module is electrically connected to the first terminal of the second fan module. The second terminal of the second fan module is electrically connected to a reference voltage.

A machine including: a main frame including at least one functional element and one control unit; an air compressor or water pump integrated in the main frame, including a frame in which are mounted a stator, a rotor interacting with the stator and including a shaft, at least one turbine carried by the shaft, a fluid-supply channel to the turbine, and an outlet channel for compressed fluid, the shaft being mounted rotatably on the frame about an axis by first and second bearings, including respectively first and second spherical elements provided on respective first and second ends of the shaft and centered relative to the axis of the shaft, and respective first and second housings provided in the frame centered relative to the axis of the shaft and to support the respective first and second spherical elements.

The present invention is to provide a fan, comprising a base and a nozzle mounted on the base. The nozzle has a first wall, a second wall arranged generally parallel to the first wall, and a partition wall located between the first wall and the second wall. The partition wall split the airflow outlet of the base to a first nozzle airflow outlet and a second nozzle airflow outlet. The first wall edge of the second wall is folded in an annularly curved or bent manner to form a first Coanda surface adjacent to the first nozzle airflow outlet and capable of producing the Coanda effect, and the partition wall is folded either inward in an opposite direction of an airflow direction or outward in the airflow direction in an annularly curved or bent manner to form a closed wall, the closed wall forming a second Coanda surface adjacent to the second nozzle airflow outlet and capable of producing the Coanda effect.

A ceiling fan structure has a mounting bracket unit, a down rod connected to the mounting bracket unit, a spindle connected below the down rod, a plurality of first fan blades arranged around the spindle and driven to rotate around the spindle, and a plurality of second fan blades. Each first fan blade forms an airflow guide ring. The second fan blade is located in the airflow guide ring. Each first fan blade has a first windward face. Each second fan blade has a second windward face opposite to the first windward face. When the first fan blades are rotated, airflows output by the first windward faces of the first fan blades act on the second windward faces of the second fan blades to push the second fan blades to rotate in a reverse direction relative to the respective first fan blades.

Methods, systems, and apparatus, including a housing defining a top surface, a bottom surface, and first and second side surfaces. Also included is a first rail extending from the first side surface and a second rail extending from the second surface such that when the first and second rails are slidably engaged with a third surface. A blower device is included that is axially disposed between the top and bottom surface, wherein a first end of the housing defines a first plenum outlet, the top surface defines a plenum inlet, the bottom surface defines a second plenum outlet that is positioned on a second side of the blower device and that fluidly couples the first plenum chamber to the second plenum chamber. Further, the second plenum chamber is formed by the first and second rails, the bottom surface and the third surface has a third plenum outlet.

Methods, systems, and apparatus, including a housing defining a top surface, a bottom surface, and first and second side surfaces. Also included is a first rail extending from the first side surface and a second rail extending from the second surface such that when the first and second rails are slidably engaged with a third surface. A blower device is included that is axially disposed between the top and bottom surface, wherein a first end of the housing defines a first plenum outlet, the top surface defines a plenum inlet, the bottom surface defines a second plenum outlet that is positioned on a second side of the blower device and that fluidly couples the first plenum chamber to the second plenum chamber. Further, the second plenum chamber is formed by the first and second rails, the bottom surface and the third surface has a third plenum outlet.

A method for pressure and temperature control of fluid in a series of cryogenic compressors. An actual speed for each compressor and an actual inlet pressure and actual inlet temperature at entry are determined. The maximum speed for each compressor and a desired inlet pressure for the first compressor is provided. A speed index for each compressor is determined from the maximum speed and actual speed of each compressor. A proportional value is determined from the deviation of the actual and desired inlet pressure. A priority value is determined from the smaller of the proportional value and the smallest speed index. A desired inlet temperature for the first compressor and a desired speed for each compressor are determined from the priority value. The actual inlet temperature is adjusted to the determined desired inlet temperature and the actual speed for each compressor is adjusted to the determined desired speed.

A method and system for testing a pumping device (9) with a control unit (91) in a gas-measuring system (1). The pumping device (9) is tested with the control unit (91), which is configured to test readiness of the pumping device (9) to operate. An initialization data set and an operating data set are used for the testing. An indicator of readiness of the pumping device (9) to operate is determined based on this.

Some embodiments of the present disclosure provide a method of dissipating process exhaust from a chamber. The method includes conveying the process exhaust from the chamber through an inner tube of a pipeline to abatement. The process exhaust has a first temperature while exiting the chamber, and a second temperature while exiting the pipeline. The method maintains an outer tube of the pipeline at a vacuum state by a pump such that the inner tube is substantially thermal isolated from the atmosphere outside the pipeline. The second temperature is negative offset from the first temperature within a predetermined value.

Some embodiments of the present disclosure provide a method of dissipating process exhaust from a chamber. The method includes conveying the process exhaust from the chamber through an inner tube of a pipeline to abatement. The process exhaust has a first temperature while exiting the chamber, and a second temperature while exiting the pipeline. The method maintains an outer tube of the pipeline at a vacuum state by a pump such that the inner tube is substantially thermal isolated from the atmosphere outside the pipeline. The second temperature is negative offset from the first temperature within a predetermined value.