1. Field of the Invention
The present invention relates to power tools driven by motors.
2. Description of the Related Art
Currently known circular saws have about eighty percent of their weight and volume in the motor. Thus, in order to significantly reduce the size and weight of a circular saw, the size and weight of the motor must be reduced. However, a smaller lighter motor may not have enough power to drive a circular saw with an acceptable level of performance.
Another problem is that the large overhang of the motor interferes with the use of a 2×4 size piece of lumber as an edge guide against the footplate. Thus, such an edge guide can be used only on the blade side of the footplate where there is no motor overhang. Although the depth of cut could be reduced to provide clearance for the edge guide, a full depth of cut could then not be achieved.
Most brushless DC (BLDC) motors (electronically commutated motors) available today are low voltage. Most power tools that utilize brushless DC motors are cordless tools using 12, 18, or 36 volt lithium ion batteries. Using low voltage brushless DC motors in a corded power tool requires a transformer to reduce the voltage from the power grid to a voltage level appropriate for the low voltage motor. However, high power transformers are large and heavy, so including a transformer into a corded power tool would negate the size and weight savings of the brushless DC motor. Some manufacturers have developed corded brushless DC tools with an external transformer. This method allows for a lightweight compact tool, but the tool must connect to a transformer box that converts the voltage. This setup is very similar to the power cords on laptop computers. However, the power consumption of a typical laptop is under 100 watts, and professional power tools can consume over 1,800 watts. The high power demands of power tools require transformers that are several times larger than a traditional laptop transformer.
The invention is directed to a circular saw in which a size ratio of the overhang of the motor in relation to the size of the footplate ((width of footplate+motor overhang length)/width of footplate) is 1.25 or below. The motor may have a thickness or length of 85 mm or less. Thus, without the motor overhanging the footplate, a 2×4 size piece of lumber may be used as an edge guide on either lateral side of the footplate.
Another embodiment is directed to a circular saw in which a size ratio of the extension of the motor beyond the upper guard ((radius of upper guard+motor extension beyond the upper guard)/radius of upper guard) is 1.25 or below. The motor may have a thickness or length of 85 mm or less. Thus, without the motor extension beyond the upper guard, the overall size of the tool can be reduced.
The present invention may provide a way to make a small motor work on a circular saw without sacrificing power. Thus, a compact tool may be provided that meets customer demand for small and lightweight circular saw.
In one embodiment, the invention incorporates a brushless DC motor to reduce the size and weight of the circular saw. The motor may be substantially cylindrically-shaped, and may have a ratio of diameter to length of about 0.6. The weight of the motor may be about 0.875 pound. However, the diameter to length ratio and the weight may be different in other embodiments.
Because of the reduction in the motor overhang, the invention may enable the use of a 2×4 inch size piece of lumber as an edge guide on either side of the footplate. Moreover, the edge guide may be used on the motor side in conjunction with a full depth of cut.
In one embodiment, the invention comprises a circular saw including a footplate coupled to a saw blade. The footplate has a width between two lateral edges in a direction perpendicular to the saw blade. A DC brushless motor is drivingly coupled to the saw blade and is disposed above the footplate. The motor has a rotational axis within forty five degrees of parallel to the width of the footplate. The motor extends towards one of the lateral edges of the footplate in the width direction. A distance by which the motor extends beyond the lateral edge in the width direction being less than twenty five percent of the width of the footplate.
In a further embodiment, the invention comprises a circular saw including a rotatable saw blade. An upper guard is coupled to the saw blade and covers an upper portion of the blade. The radius of the upper guard extends from the axis of the blade to the outermost surface of the upper guard. A DC brushless motor is drivingly coupled to the saw blade and is disposed above the footplate. The motor has a rotational axis within forty five degrees of parallel to the radius of the upper guard. The motor extends towards the outermost surface of the upper guard in the radial direction. A distance by which the motor extends beyond the outermost surface in the radial direction being less than twenty five percent of the radius of the upper guard.
In another embodiment, the invention comprises a circular saw including a saw blade coupled to a substantially planar footplate. The saw blade has a neutral position in which the saw blade is substantially perpendicular to the footplate. The blade is bevelable about an axis substantially coplanar with the blade and substantially parallel to the footplate. The blade is bevelable in each of two opposite directions from the neutral position. A DC brushless motor is drivingly coupled to the saw blade.
In yet another embodiment, the invention comprises a circular saw including a rotatable saw blade. At least one fan blade is coupled to the saw blade such that the fan blade is rotatable with the saw blade. A DC brushless motor is drivingly coupled to the saw blade and to the at least one fan blade.
In a further embodiment, the invention comprises a circular saw including a rotatable saw blade. An upper guard is coupled to the saw blade and covers an upper portion of the blade. The upper guard includes a handle that is substantially coplanar with the blade. A DC brushless motor is drivingly coupled to the saw blade.
The above mentioned and other features and objects of this invention, and the manner of attaining them, will become more apparent and the invention itself will be better understood by reference to the following description of embodiments of the invention taken in conjunction with the accompanying drawings, wherein:
Corresponding reference characters indicate corresponding parts throughout the several views. Although the exemplification set out herein illustrates embodiments of the invention, in several forms, the embodiments disclosed below are not intended to be exhaustive or to be construed as limiting the scope of the invention to the precise forms disclosed.
The invention may enable the size and weight of the motor on a working device to be dramatically reduced. The device may be virtually any type of portable devices, handheld devices, stationery devices, cordless devices, corded devices and the like. For example, the devices may be bevel saws, miter saws, table saws, circular saws, reciprocating saws, jig saws, bandsaws, cold saws, cutters, impact drivers, angler grinders, drills, jointers, nail guns, sanders, trimmers, routers. Other types of power device possible. The invention may relate to a size ratio of the overhang of the motor in relation to the size of the footplate or upper guard. In one embodiment, the footplate ratio is approximately 1.25 or less ((width of footplate+motor overhang amount)/width of footplate). In another embodiment, the upper guard ratio is 1.25 or less ((radius of upper guard+motor extension beyond the upper guard)/radius of upper guard). These ratios form a bounded surface containing the optimal embodiments of motor overhang and extension. Further, the length of the motor may be 85 mm or less.
Referring now to the drawings, and particularly to
In order to eliminate the need for a transformer, with the associated disadvantages mentioned above, in one embodiment, motor 16 is in the form of a high voltage 120V+ (120 VAC, which may be about 170 VDC) brushless DC motor. Thus, there may be no need for a transformer, with the associated disadvantages of a transformer mentioned above. Such high voltage BLDC motors are not readily available on the market. In one embodiment, the difference between the high voltage BLDG motor of the present invention and a low voltage BLDG motor is in the windings. In one embodiment, the high voltage brushless DC motor does not require a transformer because the AC line voltage is directly rectified to DC current by a voltage rectifier and a current smoothing filter or capacitor.
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Footplate 118 may have a width 130 between two lateral edges 132a-b in a direction perpendicular to saw blade 112. In one embodiment, width 130 may be approximately 140 mm. DC brushless motor 116 is drivingly coupled to saw blade 112 and is disposed above footplate 118. Motor 116 may have a rotational axis 134 that is substantially parallel to width 130 of footplate 118. Motor 116 may extend beyond lateral edge 132a of footplate 118 by an overhang distance 136 in width direction 130. This overhang distance 136 (e.g., the distance by which motor 116 extends beyond lateral edge 132a in the direction of width 130) may be approximately between five and thirty percent of width distance 130 of footplate 118.
In one embodiment, motor 116 has an input voltage of over 40 volts, such as about 120-170 volts (120 VAC, which may be about 170 VDC), for example. Motor 116 may have a length or thickness 138 of 85 mm or less. In a specific embodiment, motor 116 has a weight of 0.875 pound, a diameter 140 of 40 mm, and a length 138 of 82 mm. However, the dimensions and the weight of the motor may be different in other embodiments. Motor 116 may be sealed in an air-tight manner such that sawdust and other debris cannot enter motor 116 during operation.
Saw blade 112 may have a neutral position or orientation as shown in the drawings in which saw blade 112 is substantially perpendicular to footplate 118. Blade 112 may be bevelable (i.e., can be beveled) about an axis 142 (
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In one embodiment, the present invention provides a dual bevel circular saw. Because of the small size and compactness of the BLDG motor, the circular saw may bevel from the vertical orientation in either direction. The beveling may be about a horizontal axis which may be perpendicular to the axis of rotation of the blade. Because of the large motor overhang in existing circular saws, known circular saws can bevel in only one direction. By reducing the motor overhang, the inventive circular saw is capable both of beveling towards the motor and reverse beveling away from the motor. With particular gearing and motor locations, a full reverse bevel beyond 45 degrees from the vertical orientation is possible.
In one embodiment, the present invention includes a step-up transformer. The circular saw or other type of power tool may be configured to selectively run on batteries or with a power cord. When connected to a power cord, the tool operates with power in a way similar to that of any other high voltage corded brushless DC (e.g., electronically commutated) tool. However, when the tool is operated on batteries, the power is limited in order to optimize the power output of the battery pack. The power tool may include a step-up transformer so that a battery pack is able to power the tool's high voltage brushless DC motor. Due to the limited power output of a battery pack, only a relatively small transformer may be called for. In contrast to a step-down transformer which would need to handle the maximum power level that the motor can handle, the step-up transformer only needs to handle the maximum battery output.
In one embodiment, the present invention includes a flywheel. The circular saw or other type of power tool may include a flywheel for storing energy needed to overcome a temporary increase in load or mechanical resistance. One difference between a brushless DC motor (e.g., electronically commutated motor) and an AC motor is that the BLDC motor has a lower rotating mass. The lower rotating mass may enable rapid startup and rapid braking of the power tool, but it may pose challenges when the power tool encounters pockets of dense material such as knots or inclusions in wood. With a traditional AC motor, the higher rotating mass releases kinetic energy to help overcome a momentary spike in resistance. However, the lighter brushless DC motor has less stored kinetic energy, and thus may operate with a disadvantage under these conditions. According to the present invention, this operating disadvantage may be overcome by the inclusion of a flywheel coupled to the motor. The flywheel may enable the power tool to store substantial kinetic energy with a minimal increase in weight. In one embodiment, the flywheel has very little mass other than a dense ring that is as far away from the flywheel's rotational axis as practical.
In one embodiment, the power tool includes a cooling fan that is also the hub of the flywheel. Thus, the brushless DC power tool may be cooled with device that is a combination of a flywheel and a fan. Thus, no additional space may be required for a separate flywheel, and yet the rotating mass that may compensate for the limited mass of the motor may still be provided.
In one embodiment, the location of the upper guard handle may be optimized by virtue of the location of the center of gravity of the saw with the lighter BLDC motor. In general, the ideal handle location for a circular saw may be inline (e.g., coplanar) with the blade. The reason that the ideal handle location may be inline with the blade is that applying manual force in a direction coplanar with the blade may reduce or eliminate the moment caused by applying manual force to an offset handle in a direction that is not coplanar with the blade. This moment can cause binding and reduced cutting efficiency. In known circular saws, handles may be offset from the plane of the saw blade in order to place the handle close to the center of gravity, and thereby provide greater stability. With brushless DC motors (e.g., electronically commutated motors), however, the lightness of the motor results in the center of gravity being closer to the blade. This location of the center of gravity closer to the blade may enable a user to easily handle a saw with the handle mounted inline with the blade.
In general, BLDC motors have maximum torque when stationary, and the torque decreases linearly with increasing rotational speed. Thus, by virtue of the high level of stationary torque, a blade driven by a BLDC motor is less likely to become bound or seized in a workpiece, such as a piece of wood, than is a blade that is conventionally driven by an AC motor.
A BLDC motor may be especially well suited for use in an environment with a lot of sawdust, such as the environment that a circular saw operates in. Because the windings of a BLDC motor may be supported by the housing, the winding may be cooled by conduction. Thus, no airflow inside the motor is required, and the motor may be sealed from outside contaminants.
While this invention has been described as having an exemplary design, the present invention may be further modified within the spirit and scope of this disclosure. This application is therefore intended to cover any variations, uses, or adaptations of the invention using its general principles.
Number | Date | Country | |
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61530053 | Sep 2011 | US |