A harvester cleaning fan system having a cross flow fan rotor, an inlet, an outlet and an inlet cover. The rotor rotates about a fan axis and has vanes defining a cylindrical rotation volume. The inlet extends around the rotor from an inlet leading edge to an inlet trailing edge. The outlet extends from the inlet trailing edge to the inlet leading edge. The inlet cover is adjacent the inlet, radially spaced from the rotor, and extends from a cover leading edge to a cover trailing edge. The cover leading and trailing edges are between the inlet leading and trailing edges. A first inlet passage is between the cover leading edge and the inlet leading edge, and a second inlet passage is between the inlet trailing edge and the cover trailing edge. An agricultural vehicle having a cleaning fan is also provided.

A compressor 100 includes: a rotor 10 having a rotary shaft 11 rotating around an axis A, and an impeller 12 provided integrally with the rotary shaft 11; a casing 5 having a casing main body 51 which surrounds the rotor 10 and forms an annular inlet flow path F1 surrounding the axis A at a front stage of the impeller 12, and an inlet nozzle 52 which introduces a fluid into the inlet flow path F1 from an outer side in a radial direction Dr; an external pipe 2 connected to the inlet nozzle 52 to introduce the fluid from the outside to the inlet nozzle 52; and a cleaning liquid supply part 4 which is configured to supply a cleaning liquid from a plurality of locations in a circumferential direction of the external pipe 2 to an interior of the external pipe 2.

A compressor 100 includes: a rotor 10 having a rotary shaft 11 rotating around an axis A, and an impeller 12 provided integrally with the rotary shaft 11; a casing 5 having a casing main body 51 which surrounds the rotor 10 and forms an annular inlet flow path F1 surrounding the axis A at a front stage of the impeller 12, and an inlet nozzle 52 which introduces a fluid into the inlet flow path F1 from an outer side in a radial direction Dr; an external pipe 2 connected to the inlet nozzle 52 to introduce the fluid from the outside to the inlet nozzle 52; and a cleaning liquid supply part 4 which is configured to supply a cleaning liquid from a plurality of locations in a circumferential direction of the external pipe 2 to an interior of the external pipe 2.

A hydraulic ram used for maintaining pressure on pump packing. A pump packing closure mechanism is sized to extend around a shaft of a pump, and to close a space between the shaft of the pump and a housing. The closure mechanism presses against packing rings that surround the shaft of the pump. A hydraulic ram presses the closure mechanism against the packing rings.

A silicone bond coat composition having a viscosity of less than 1,600 centistokes is applied to substantially all external surfaces of the article and then cured. A liquid silicone elastomer outer coat composition comprising a high viscosity first liquid silicone elastomer formulation and a low viscosity second liquid silicone elastomer formulation is then applied and cured to provide a protected article having a complex shape. Optimal coatings result from a careful balancing of component viscosities. In an embodiment, the first formulation has a viscosity greater than 300,000 centistokes, and the second formulation has a viscosity less than 6,000 centistokes, and the liquid silicone elastomer outer coat composition comprises from about 60 to about 40 percent by weight of the first formulation and from about 40 to about 60 percent by weight of the second liquid silicone elastomer formulation.

An electric fan with a self-cleaning mode to energise rotating fan blades in alternate forward and reverse directions to create a vibration in order to shake built-up dust or dirt particles from the blades in a frequency at which the rotational direction is alternated set to a known or detected resonant frequency of the blades thereby excite resonant modes and maximise the amplitude of vibrations. The self-cleaning operation may be triggered by detection of excessive/abnormal loading on the motor. The fan may be operated in a vibration detecting mode over a range of rotational speeds to locate speeds that produce resonance, or to detect a fault with the fan. Motor reversal frequencies corresponding to resonance-inducing speeds may be used in the self-cleaning mode. The vibration detecting mode may be carried out while the at least one blade is rotated in a direction opposite to its normal operational rotational direction.

Some embodiments of an apparatus and system are described for a crossflow blower. An apparatus may comprise an enclosure having a first side and a second side where a portion of the first side is recessed in a direction of the second side. The enclosure may also comprise a first internal height between the first side and the second side and a second internal height between the recessed portion of the first side and the second side. The enclosure may also comprise a motor and a crossflow blower arranged to generate a flow of air between the first side and the second side in a direction substantially perpendicular to an axis of rotation of the crossflow blower. Other embodiments are described.

An air blower includes: a panel (3); a frame member (5) arranged to surround the panel (3) and having a blowout port (13a, 13b, 13c, 13d, 13e, 13f, 13g) of air formed therein; and a fan (11a, 11b, 11c, 11d, 11e, 11f, 30) that sends air to the blowout port (13a, 13b, 13c, 13d, 13e, 13f, 13g). The frame member (5) produces airflows that are blown out from at least three directions and collide with each other, thereby producing an air current going forward to the panel (3).

An air blower includes: a panel (3); a frame member (5) arranged to surround the panel (3) and having a blowout port (13a, 13b, 13c, 13d, 13e, 13f, 13g) of air formed therein; and a fan (11a, 11b, 11c, 11d, 11e, 11f, 30) that sends air to the blowout port (13a, 13b, 13c, 13d, 13e, 13f, 13g). The frame member (5) produces airflows that are blown out from at least three directions and collide with each other, thereby producing an air current going forward to the panel (3).

A fan assembly includes a radial blower unit configured to exhaust air radially from an inlet axis of the radial blower unit. The fan assembly also includes baffles each partially surrounding the radial blower unit. The baffles are rotatable between an open position and a closed position around respective pivot axes, and the baffles have respective centers of mass aligned with the respective pivot axes.