Systems and methods of flow testing different workpieces in an automated testing station are described. Each workpiece comprises a flow path from an inlet to an outlet and the automated testing station comprises first and second sealing heads for injecting gas into the inlets of workpieces and collecting gas from the outlets of workpieces. The method includes performing a flow test by moving the flow test heads toward the workpieces while at the same time priming a flow of gas from the first sealing heads to the second sealing heads, prior to engaging the workpiece.

Personal fan devices that are configured to transition between an open configuration for use and a closed configuration for storage or transport. A fan device includes noisemaking structure(s), such as a rattle and/or a clapper, disposed with the fan device. As the fan device is moved, the handle generates noise as a result of the noisemaking structure(s). A plurality of fan devices may be used to generate high-decibel noises at an event, such as a sporting event or a performance.

A dual window fan having a rectangular body adapted to engage a window, two fan heads pivotably engaging the body independently of each other about a vertical pivot axis from aiming directly outwardly normal to the body to aiming inwardly through a pivot angle of at least 225 angular degrees.

Methods and apparatus for blowing out birthday candles are presented. The apparatus may include a rotor comprising at least two blades and attachable to a wind-up launcher for imparting a rotational impulse to the rotor. Each blade of the rotor may include a blade scoop extending from a central hub of the rotor to an outer safety ring positioned around an outer circumference of the rotor and coupled to each of the central hub and the outer safety ring. The blade scoop may have a convex shaped leading edge. The blade may also include a blade overhang for pushing air from the blade scoop out from the rotor. The blade overhang may have a trailing edge positioned below the central hub, with a portion of the blade forming the trailing edge having a tangent that is angled between 30 and 60 degrees below a plane of the outer safety ring.

A blower includes a body, a motor, and a single fan configured to rotate in response to rotation of a motor shaft to discharge air through a discharge opening. The maximum rotational speed of the motor shaft is within a range of 50,000 rpm to 120,000 rpm. An area of the discharge opening is changeable by a user. The blower is configured to selectively operate in a first mode or in a second mode according to the area of the discharge opening. In the first mode, the maximum blowing force of the air discharged through the opening is within a range of 2.5 N to 5.0 N when the motor is driven at the maximum rotational speed. In the second mode, the maximum dynamic pressure of the air discharged is within a range of 30 kPa to 65 kPa when the motor is driven at the maximum rotational speed.

Provided is an electric blower configured to include a centrifugal impeller provided with an intermediate blade, which reduces pressure loss inside an air path on a large air volume side and achieves high efficiency. In the electric blower, a first rotor blade and a second rotor blade each include an inner circumferential edge facing a central portion of a hub and connecting an upper edge and a lower edge. The inner circumferential edge of the second rotor blade includes a first portion connected to the lower edge, a second portion connected to the upper edge, and a third portion. The third portion is located between the first portion and the second portion. Among the first portion, the second portion, and the third portion, the first portion is located closest to an outer circumferential portion of the hub in a direction along a surface portion.

A blower includes a motor, a plurality of fans coaxially arranged in multiple stages, a housing having an inlet opening and a discharge opening, and a battery mounting part to which a battery is removably mountable. A rotational speed of the motor is within a range of 50,000 rpm to 120,000 rpm. A diameter of each of the fans is within a range of 30 mm to 70 mm. An area of the discharge opening is within a range of not less than an area of a circle having a diameter of 2.5 mm and not more than an area of a circle having a diameter of 10 mm. A blowing force of air discharged through the discharge opening is within a range of 1 N to 3 N.

A blower includes a body, a motor, and a single fan configured to rotate in response to rotation of a motor shaft to discharge air through a discharge opening. The maximum rotational speed of the motor shaft is within a range of 50,000 rpm to 120,000 rpm. An area of the discharge opening is changeable by a user. The blower is configured to selectively operate in a first mode or in a second mode according to the area of the discharge opening. In the first mode, the maximum blowing force of the air discharged through the opening is within a range of 2.5 N to 5.0 N when the motor is driven at the maximum rotational speed. In the second mode, the maximum dynamic pressure of the air discharged is within a range of 30 kPa to 65 kPa when the motor is driven at the maximum rotational speed.

Methods and apparatus for blowing out birthday candles are presented. The apparatus may include a rotor comprising at least two blades and attachable to a wind-up launcher for imparting a rotational impulse to the rotor. Each blade of the rotor may include a blade scoop extending from a central hub of the rotor to an outer safety ring positioned around an outer circumference of the rotor and coupled to each of the central hub and the outer safety ring. The blade scoop may have a convex shaped leading edge. The blade may also include a blade overhang for pushing air from the blade scoop out from the rotor. The blade overhang may have a trailing edge positioned below the central hub, with a portion of the blade forming the trailing edge having a tangent that is angled between 30 and 60 degrees below a plane of the outer safety ring.

Systems and methods of flow testing different workpieces in an automated testing station are described. Each workpiece comprises a flow path from an inlet to an outlet and the automated testing station comprises first and second sealing heads for injecting gas into the inlets of workpieces and collecting gas from the outlets of workpieces. The method includes performing a flow test by moving the flow test heads toward the workpieces while at the same time priming a flow of gas from the first sealing heads to the second sealing heads, prior to engaging the workpiece.