The present invention relates generally to power tools, and more specifically to fan assemblies for power tools such as fastener drivers.
Many power tools (e.g., fastener drivers, miter saws, etc.), operate via intermittent, relatively short periods of motor activation interrupted by relatively longer periods of motor deactivation. Such power tools often include fan assemblies rotated by the motor to provide cooling airflow and ventilation for various components of the power tool. Such fan assemblies are typically fixed to a motor shaft to co-rotate with the motor shaft and thus cannot generate cooling airflow during periods of motor deactivation.
The present invention provides, in one aspect, a power tool that includes a motor having a motor shaft that rotates about a motor axis in a first rotational direction, and a fan assembly attachable to the motor shaft for rotation in the first rotational direction. The fan assembly includes a fan body and a bearing. The bearing includes a race that is rotatably affixed to the fan body. The race is freely rotatable relative to the motor shaft in the first rotational direction, and fixed against rotation relative to the motor shaft in a second rotational direction opposite the first rotational direction.
In some embodiments, the fan assembly further includes a flywheel rotatably affixed to the fan body.
In some embodiments, the race is rotatably affixed to the flywheel.
In some embodiments, the bearing is a first bearing and the race is a first race, and the fan assembly further includes a second bearing having a second race that is rotatably affixed to the fan body.
In some embodiments, the second race is freely rotatable relative to the motor shaft in each of the first and second rotational directions.
In some embodiments, the power tool further includes an energy storage device coupled to the motor shaft and to the fan assembly, the energy storage device being configured to supply torque to the fan assembly upon deactivation of the electric motor.
In some embodiments, the power tool further includes an air compression and storage device coupled to the motor shaft, the air compression and storage device being configured to supply an airflow to cool the electric motor upon deactivation of the electric motor.
In some embodiments, the power tool further includes an auxiliary fan configured to supply an airflow to cool the electric motor upon deactivation of the electric motor.
The present invention provides, in another aspect, a method of cooling an electric motor configured for use in a power tool, the electric motor having a motor shaft rotatable about a motor axis, and the power tool further including a fan assembly attachable to the motor shaft. The method includes a step of activating the electric motor to supply a torque to the motor shaft. The method also includes a step of rotating the motor shaft and the fan assembly about the motor axis, the fan assembly generating an airflow to cool the electric motor. The method also includes a step of deactivating the electric motor to stall rotation of the motor shaft. The fan assembly continues to rotate about the motor axis to generate the airflow after rotation of the motor shaft has ceased.
In some embodiments, the power tool further includes an energy storage device coupled to the motor shaft and to the fan assembly. The method also includes a step of, before the step of deactivating the electric motor, supplying torque from the electric motor to the energy storage device to store energy therein. The method also includes the step of, after the step of deactivating the electric motor, supplying torque from the energy storage device to the fan assembly to rotate the fan assembly about the motor axis.
In some embodiments, the power tool further includes an air compression and storage device coupled to the motor shaft. The method also includes a step of, before the step of deactivating the electric motor, supplying torque form the electric motor to the air compression and storage device to compress and store air therein. The method also includes a step of, after the step of deactivating the electric motor, releasing the air from the air compression and storage device to generate a secondary airflow to cool the electric motor.
In some embodiments, the power tool further includes a power source and an auxiliary fan electrically coupled to the power source. The method also includes a step of, after the step of deactivating the electric motor, supplying electrical power from the power source to the auxiliary fan to generate a secondary airflow to cool the electric motor.
The present invention provides, in another aspect, a power tool including a motor having a motor shaft that rotates about a motor axis in a first rotational direction. The power tool also includes a fan assembly attachable to the motor shaft for rotation in the first rotational direction. The fan assembly includes a fan body, and a flywheel rotatably affixed to the fan body. The fan body and the flywheel are freely rotatable relative to the motor shaft in the first rotational direction, and fixed against rotation relative to the motor shaft in a second rotational direction opposite the first rotational direction.
In some embodiments, the fan assembly further includes a bearing having a race that is rotatably affixed to the flywheel, the race being freely rotatable relative to the motor shaft in the first rotational direction, and fixed against rotation relative to the motor shaft in the second rotational direction.
In some embodiments, the bearing further includes a cage that supports a plurality of rollers.
In some embodiments, the bearing is a first bearing and the race is a first race, and the fan assembly further includes a second bearing having a second race that is rotatably affixed to the flywheel.
In some embodiments, the second race is freely rotatable relative to the motor shaft in each of the first and second rotational directions.
In some embodiments, the power tool further includes an energy storage device coupled to the motor shaft and to the fan assembly, the energy storage device being configured to supply torque to the fan assembly upon deactivation of the electric motor.
In some embodiments, the power tool further includes an air compression and storage device coupled to the motor shaft, the air compression and storage device being configured to supply an airflow to cool the electric motor upon deactivation of the electric motor.
In some embodiments, the power tool further includes an auxiliary fan configured to supply an airflow to cool the electric motor upon deactivation of the electric motor.
Other features and aspects of the invention will become apparent by consideration of the following detailed description and accompanying drawings.
Before any embodiments of the invention are explained in detail, it is to be understood that the invention is not limited in its application to the details of construction and the arrangement of components set forth in the following description or illustrated in the following drawings. The invention is capable of other embodiments and of being practiced or of being carried out in various ways. Also, it is to be understood that the phraseology and terminology used herein is for the purpose of description and should not be regarded as limiting.
With reference to
With reference to
In operation, the lifting assembly 42 drives the piston 22 and the driver blade 26 to the ready position by energizing the motor 46. As the piston 22 and the driver blade 26 are driven to the ready position, the gas above the piston 22 and the gas within the storage chamber cylinder 30 is compressed. Once in the ready position, the piston 22 and the driver blade 26 are held in position until released by user activation of a trigger 48 (
With reference to
With reference to
With reference to
Referring to
The flywheel 98 couples to the fan body 94 and provides an inertial mass to increase a moment of inertia of the fan assembly 86 about the motor axis 90 during operation. In the illustrated embodiment, the first central bore 114 of the fan body 94 receives the second central portion 126 of the flywheel 98 by interference fit to secure the flywheel 98 to the fan body 94. In other embodiments (not shown), the flywheel 98 may be secured to the fan body 94 by other means (e.g., fasteners, adhesive, etc.) recognizable to one of ordinary skill.
The flywheel 98 receives the first bearing 102 into the second central bore 134 (e.g., by interference fit), and also receives the second bearing 106 into the third central bore 138 (e.g., by interference fit), so that an outer race 150 of each bearing 102, 106 is rotationally fixed to the flywheel 98. In other embodiments (not shown), the fan assembly 86 does not include the flywheel 98, and the first and second bearings 102, 106 are instead directly received by the first central bore 114 of the fan body 94. In the illustrated embodiment, the first bearing 102 further includes a cage 154 that supports a plurality of rollers. The rollers engage a rotating shaft, such as the motor shaft 74 of the motor 46. The second bearing 106 further includes an inner race 155 that receives and is rotationally affixed to the motor shaft 74.
In the illustrated embodiment, the first bearing 102 is a one-way bearing (e.g., a one-way needle bearing, a one-way sprag bearing, etc.) that is freely rotatable about the motor axis 90 in a first rotational direction, but which locks against rotation about the motor axis 90 in a second rotational direction opposite the first rotational direction. Specifically, the outer race 150 of the first bearing 102 is rotatable in the first rotational direction relative to motor shaft 74, but is fixed against rotation in the second rotational direction relative to the motor shaft 74. In contrast, the second bearing 106 is a two-way bearing (e.g., a plain bearing, a ball bearing, a roller bearing, etc.) that is freely rotatable about the motor axis 90 in each of the first and second directions.
In operation, with the fan assembly 86 coupled to the motor shaft 74 of the fastener driver 10, the motor 46 is activated to accelerate the motor shaft 74 in the first rotational direction. Because the first bearing 102 locks against rotation in the second rotational direction, the motor shaft 74 drives the fan assembly 86 to co-rotate in synchronization with the motor shaft 74 as the motor shaft 74 accelerates in the first rotational direction. As the fan assembly 86 accelerates, it accumulates rotational inertia and the fan body 94 generates airflow within the interior of the fastener driver 10. The fan assembly 86 continues to co-rotate with the rotating motor shaft 74 until the motor 46 is deactivated.
Upon deactivation of the motor 46, the motor shaft 74 begins to decelerate (i.e., due to internal frictional forces, an external load on the fastener driver 10, and/or motor controls which actively decelerate the motor shaft 46) and may eventually stop rotating completely. However, because the bearings 102, 106 permit the fan assembly 86 to rotate freely in the first direction relative to the motor shaft 74, the fan assembly 86 does not decelerate at the same rate as the motor shaft 74. Instead, the fan assembly 86 continues to rotate in the first rotational direction after the motor shaft 74 has stopped due to the rotational inertia of the fan assembly 86 (as amplified by the flywheel 98). In this way, the fan body 94 continues to rotate and generate cooling airflow for the motor 46 after the motor 46 is deactivated and the motor shaft 74 is stopped. The fan assembly 86 gradually decelerates (i.e., due to frictional forces generated in the bearings 102 and 106, the fan body 94, etc.) until the motor 46 is reactivated, and the process is repeated.
Various features of the invention are set forth in the following claims.
This application claims priority to U.S. Provisional Patent Application No. 62/658,183 filed on Apr. 16, 2018, the entire content of which is incorporated herein by reference.
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