Example embodiments relate to a device for heating a liquid and/or warming air, including a burner device and an air conveying device. The air conveying device conveys combustion air to the burner device. The air conveying device has a carrier housing, a movable fan wheel, an air inlet, and an air outlet. The carrier housing has a conveying channel which is connected to the air inlet and the air outlet. The fan wheel is arranged so as to be rotatable about a longitudinal axis of the air conveying device and has a blade structure. The air outlet is arranged in a central area of the air conveying device and extends through the fan wheel. The invention further relates to a side channel blower.

A blower is disclosed. The blower includes a fan configured to generate flow of air, a lower body providing an internal space in which the fan is installed, and having a suction hole through which air passes, an upper body positioned over the lower body and providing an internal space in which air discharged from the fan flows, a damper positioned behind the upper body, and a discharge port formed between an end of the upper body and an end of the damper, in which the upper body includes an opening formed at a rear end of the upper body and communicating with the internal space of the upper body, and the damper opens and closes the discharge port while moving in a front-rear direction behind the opening.

A blower is disclosed. The blower includes a fan configured to generate flow of air, a lower body providing an internal space in which the fan is installed, and having a suction hole through which air passes, an upper body positioned over the lower body and providing an internal space in which air discharged from the fan flows, a damper positioned behind the upper body, and a discharge port formed between an end of the upper body and an end of the damper, in which the upper body includes an opening formed at a rear end of the upper body and communicating with the internal space of the upper body, and the damper opens and closes the discharge port while moving in a front-rear direction behind the opening.

An exhaust gas turbocharger shaft has an impeller connected to the exhaust gas turbocharger shaft in a form-locking manner and is connected to a shaft nut provided on an outer shell surface of the exhaust gas turbocharger shaft. The shaft nut is inserted into a central bore of the impeller in such a way that the impeller forms a form-locking connection with the shaft nut in the radial direction and the circumferential direction.

An exhaust gas turbocharger shaft has an impeller connected to the exhaust gas turbocharger shaft in a form-locking manner and is connected to a shaft nut provided on an outer shell surface of the exhaust gas turbocharger shaft. The shaft nut is inserted into a central bore of the impeller in such a way that the impeller forms a form-locking connection with the shaft nut in the radial direction and the circumferential direction.

The present disclosure relates to a fan blade, including a wheel hub, a bottom plate and a plurality of blades. The plurality of blades encircle an outer peripheral side of the wheel hub at an interval; a separation distance is kept between each of the blades and the wheel hub; the wheel hub, the bottom plate and the blades enclose an annular groove; an air guide groove is formed between two adjacent blades; a first air inlet is formed in a side, away from the bottom plate, of the air guide groove; a second air inlet connected to the annular groove is formed in a side, close to the wheel hub, of the air guide groove; and an air outlet is formed in a side, away from the wheel hub, of the air guide groove.

The present disclosure relates to a fan blade, including a wheel hub, a bottom plate and a plurality of blades. The plurality of blades encircle an outer peripheral side of the wheel hub at an interval; a separation distance is kept between each of the blades and the wheel hub; the wheel hub, the bottom plate and the blades enclose an annular groove; an air guide groove is formed between two adjacent blades; a first air inlet is formed in a side, away from the bottom plate, of the air guide groove; a second air inlet connected to the annular groove is formed in a side, close to the wheel hub, of the air guide groove; and an air outlet is formed in a side, away from the wheel hub, of the air guide groove.

The present invention refers to a fan set that has at least one circular support (3) on which a bearing fastening ring (7) can be supported during the process of fastening the closing cover (9) on the bearing already pressed onto the shaft, facilitating the process of assembling the bearing fastening ring (7) and reducing the length of the motor. After the complete fastening of the bearing fastening ring (7), it stops touching the fan, which can rotate freely.

Improved cooling systems for handheld devices are disclosed. In some aspects, the cooling system may utilize air inlets disposed behind a guard to prevent debris or liquids from entering the handheld device and potentially causing damage to internal components of the handheld device. In aspects, a vents may be disposed on the guard to divert cooling air into a housing of the handheld device to cool internal components, such as the motor or a printed circuit board (PCB). In additional or alternative aspects, a motor mount may be provided that includes ribs defining air channels to divert or direct cooling air to components to be cooled. The air channels provided by the motor mount may enable the cooling air to reach portions of the internal components that may be distant from the air inlets of the housing.

Improved cooling systems for handheld devices are disclosed. In some aspects, the cooling system may utilize air inlets disposed behind a guard to prevent debris or liquids from entering the handheld device and potentially causing damage to internal components of the handheld device. In aspects, a vents may be disposed on the guard to divert cooling air into a housing of the handheld device to cool internal components, such as the motor or a printed circuit board (PCB). In additional or alternative aspects, a motor mount may be provided that includes ribs defining air channels to divert or direct cooling air to components to be cooled. The air channels provided by the motor mount may enable the cooling air to reach portions of the internal components that may be distant from the air inlets of the housing.