The claimed invention relates generally to a blade guard for use with a power tool that is used in association with a debris evacuation system, and more particularly, but not by way of limitation, to a blade guard for use with a portable, handheld power tool suited to cutting substrates that generate significant amounts of airborne particulates when cut.
Portable handheld power tools are often used for a variety of construction tasks. Such tools often employ an electrical motor and an operational mechanism, such as a rotatable blade, to cut, drill, plane or otherwise operate upon a workpiece.
While operable, such tools have nevertheless been found to have limited utility in certain types of applications. For example, using a conventional power tool (e.g. a circular saw) to cut certain types of substrates, such as concrete board or drywall, can generate significant amounts of dust or other airborne particulates. The dust and particulate matter that is created while cutting substrates is problematic for several reasons. Initially, the dust and other particulate matter often creates a large mess that must be cleaned up after the work is complete at the jobsite. The cleaning process not only takes time, but because the airborne dust does not immediately settle on surfaces at the worksite, it is not often possible to immediately clean a work area after a substrate is cut. Further, many types of concrete board includes respirable crystalline silica, which may be a cause of cancer, silicosis, and has been linked to other diseases with accumulated and extended intake of airborne dust while breathing.
To avoid issues relating to the generation of such particulates, users often employ hand actuated cutting devices, such as manual saws or shears, in an effort to cut such substrates. While operable, these and other manual methods are time consuming and inefficient, and can produce less than optimal cut geometries, accuracy and finish.
There is accordingly a continued need for improvements in the manner in which certain types of materials prone to generate particulates can be processed by a user in a fast and efficient manner without the limitations set forth above. It is to these and other improvements that preferred embodiments of the present invention are generally directed.
A first representative embodiment of the disclosure includes a blade guard used in association with a debris evacuation system disposed upon a power tool having a cutting blade. The blade guard includes a generally arcuate body fixed to a housing of the power tool, the body surrounding a portion of the cutting blade. A plenum is provided that is at least partially disposed in concert with the body and fixably disposed thereon. The plenum includes an arcuate portion disposed substantially coaxially with the cutting blade.
A second representative embodiment of the disclosure includes a blade guard used in association with a debris evacuation system that is configured to surround a rotatable cutting blade. The blade guard includes an arcuate body mounted to surround a portion of an outer circumferential edge of the cutting blade, wherein the arcuate body is fixed with respect to the rotatable blade. A plenum is disposed upon the body and is configured to provide fluid communication between a cutting zone within the body and a suction source. An aperture is defined in the body proximate the cutting blade, the aperture is disposed proximate a location where the cutting blade exits a workpiece being cut.
a is the view of the power tool of
Preferred embodiments of the present invention are generally directed to an apparatus a blade guard used in association with a cutting tool having a debris evacuation system for collecting debris during cutting of a substrate. The cutting tool may be used to cut substrates such as fiber cement board, wood or wood products, composite decking boards, medium density fiberboard (MDF), rock or natural or engineered mineral based materials (e.g. granite), metal, plaster, fiber glass, and other similar materials that create significant dust and debris when cut.
The tool may be a portable hand tool with a motor, an impeller and a cutting blade. The impeller is axially mounted to a first end of the motor, and the cutting blade is transversely mounted to a second end of the motor opposite the first end. Preferably, the impeller and the cutting blade are concurrently rotated by the motor at different, respective first and second rotational rates. The impeller is further configured to direct and urge particulates generated by the cutting blade to a debris collection assembly.
A first representative embodiment of a blade guard used in associate with a tool having a debris evacuation system is depicted in
The blade guard 950 further defines a plenum 953 that is disposed coaxially around the blade guard 950, but segregated from a cutting volume 931 disposed within the inner volume of the blade guard 950 by an arcuate wall 954. The plenum 953 is fluidly connected with the cutting volume 931 of the blade guard 950 through an aperture 958. The aperture 958 is disposed in the portion of the blade guard 950 located above the base plate 903 proximate the forward end of the slot 903a. The blade guard 950 may be formed integrally with the housing 902 in at least a portion rearward of the blade guard 950. In some embodiments, the fixed blade guard 950 (and plenum 953) are integral with the housing as well.
The plenum 953 follows an arcuate path around at least a majority of the blade guard 950, in a coaxial relationship with the cutting blade 930. The plenum 953 extends outward from the blade guard 950 and toward the debris evacuation system at a point proximate a rear portion of the blade guard 950. The extending portion of the plenum 953 may be formed monolithically with the blade guard 950, or in other embodiments, may be a tubular structure that is connected to a plenum outlet feature in the blade guard 950. With this configuration, the upper blade guard 950 directs the flow (F) of debris from the forward end of the blade 930, where a majority of debris originates, around an outer edge of the blade 930, towards a rear end of the tool 900, and directly into a remote container, therefore substantially avoiding contact between the operator and the debris.
In some embodiments, the blade guard 950 (including the plenum 953) is constructed from two clamshell halves that define the outer volume thereof. The two clamshell halves of material that form the plenum 953 are connected (or abutted) together at an upper seam 955 and a lower seam 954, which each form the respective upper surface and lower surface of the plenum 953, respectively. As best shown in
The aperture 958 and blade guard 950 are each disposed such that a portion of the cutting blade 930 directly above the forward end of the slot in the base plate 903 extends through the aperture 958 and into the plenum 953. In some embodiments, one or more teeth 930a of the cutting blade 930 extend through the aperture 958 and into the plenum 953. In some embodiments, the aperture 958 and plenum 953 are configured such that a tangent line T extending from the outer circumference of the cutting blade 930 disposed just below the base plate 903 extends through the aperture 958 and into the plenum 953.
In other embodiments, the blade guard 950 may be constructed from two or more clamshell halves at various seams. The blade guard 950 may include a lower portion that defines a portion of the blade guard 950 directly above and proximate to the outer circumferential edge of the cutting blade 930. The lower portion includes an opening, which defines an aperture, similar to aperture 958, which is disposed just above the base plate 903 proximate to the front end of the cutting blade 930. The aperture allows for fluid communication from the cutting zone to the plenum 953 therethrough. In this embodiment, like aperture 958 discussed herein, a portion of the outer circumferential edge of the cutting blade 930 may extend through the aperture and into the plenum 953.
In one embodiment, the hand held rotary tool 900 includes a housing 902 that supports and fixes a motor 910 with a motor shaft 912 extending therefrom, a torque transmission system (not shown) is disposed between the motor shaft 912 and output shaft 918 to transfer torque therebetween. An output shaft 918 engages an output of the transmission and a cutting blade 930 is removeably received upon the output shaft 918. The cutting blade 930 is generally circular and includes a plurality of cutting teeth 930a. The cutting blade 930 may be formed of a polychrystaline diamond construction, though other materials such as carbide can readily be used. A 5⅜ inch diameter multi-tooth blade is a particularly advantageous size, although other sizes including larger diameters of around 7 inches or more, and smaller diameters of around 4 inches or less, can also be used as desired. For example, in some embodiments a 5.0 inch blade may be used. The blade may be configured with carbide teeth or with other materials. Further, the cutting blade 930 may be fabricated or worked with various known techniques to improve or affect the hardness, strength, ability to retain a sharp edge of the cutting blade 930.
A portion of the cutting blade 930 extends through a slot 903a in a base plate 903 that is fixed (either movably fixed or rigidly mounted) to the housing 902 and is the surface upon which the tool 900 contacts the substrate or work piece to be cut. In some embodiments, the base plate 903 may be pivotable about the housing 902 such that the cutting depth may be adjusted by modifying the amount of the cutting blade 930 extending below the slot 903a.
The motor 910 may be an alternating current (AC) motor. The motor 910 is preferably supplied with alternating current (AC) power via cord and user activated on-off switch disposed upon the housing. The motor 910 can alternatively be supplied by direct current (DC) power such as from an associated battery pack. Although not shown, a user activated switch can be incorporated with the handle so that pressure is required from the hand of a user to activate the motor. In some embodiments, the motor 910 control system may include an interlock that requires a second switch or button to be pressed to initially start the motor 910. The second operator may be ergonomically operable with a second hand to prevent spurious and unintended operations of the motor 910. The interlock may be configured such that the second operator may be released after the motor 910 starts to allow the tool to be held by two hands during use. A handle may be provided on the housing 902 to allow the user to move and operate the tool with a single hand.
The motor 910 is aligned within the housing 902 such that an axis of rotation 910c of the motor shaft 912 is substantially perpendicular to an axis of rotation of the output shaft 918 and the cutting blade 930. The transmission may be a set of substantially perpendicular input and output 916a, 916b bevel gears (
The plenum 953 is fluidly connected to a volute 942 of an impeller 940. The impeller 940 may be fixed to a second end 912b of the motor shaft 912 (i.e. the end of the motor shaft opposite from the transmission 914). The impeller 940 may provide for forced flow across the motor 910 to remove heat therefrom, as well as providing for flow of air and entrained dust and debris from through the plenum 953. The impeller 940 may include multiple sets of blades. Activation of the motor 910 preferably results in concurrent operation of both the cutting blade 930 and the impeller 940. This simultaneous activation advantageously results in substantially immediate application of the vacuum pressure to the blade guard 950 by or before the cutting blade 930 reaches operational speed.
In this embodiment, the impeller 940 rotates at the same rotational velocity as the motor shaft 912 due to the direct connection therebetween. In other embodiments, the impeller 940 may be indirectly connected to the motor shaft 912 with a transmission therebetween, which allows the rotational velocity of the impeller 940 to be different from the motor shaft 912, as well as the orientation of the impeller 940 to be modified as desired for the tool's design. The impeller is enclosed by a housing that includes an inlet portion 944 that is fluidly connected with the plenum 953 and a cylindrical main portion 945 that surrounds the rotatable impeller blades. The main portion 945 is configured to closely neighbor the impeller blades to minimize flow across the tips of the blades, which would reduce the efficiency of the impeller 940.
As shown in
A discharge 943 may be provided from the impeller 940. In some embodiments the discharge 943 is disposed in an orientation and direction tangential to the tips of the impeller 940 blades. The discharge may include a downstream rotatable joint that allows the discharge 943 piping and connection to be aligned at any desired angle with respect to the housing and/or the motor shaft 912. The discharge 943 includes a threaded or other suitable connection structure to receive a hose thereto (either directly, or through a secondary fitting) to allow the evacuated dust and debris to flow to a remote collection point.
In some embodiments, a lower blade guard 960 may be provided that is movably mounted to the blade guard 950 or other portions of the housing 902 to enclose the cutting blade 930 disposed below the base plate 903. The lower blade guard 960 is translatably movable in a path coaxial with the rotational axis of the cutting blade 930 to allow the lower blade guard 960 to be withdrawn from below the base plate 903 when the cutting blade 930 engages a work piece disposed below the base plate 903. Because the plenum 953 fluidly communicates with the cutting volume 931 at a position proximate the forward portion of the cutting blade 930 extending through the slot in the base plate 903, the flow of dust and debris from the cutting volume 930 flows (as aided by the impeller 940) regardless of the position of the lower blade guard 960.
The tool 900 is configured to be used with a remote collection and filtration apparatus 1000 (
The filtration apparatus 1000 may be formed as a cap 1001, best shown in
The base plate 102 supports a motor 106 via support brackets 108, 110. An impeller assembly 112 is mounted to a first end of the motor 106. A cutting blade assembly 114 is mounted to a second end of the motor 106 opposite the first by way of a gear assembly 116.
As shown in
As further shown in the schematic depiction of
The motor 106 preferably includes a central shaft 128 that includes a longitudinal axis U (
The gear assembly 116 is mounted to a second end of the central shaft 128 and is includes a selected gear reduction rate. In some embodiments, bevel gears with perpendicular shafts therefrom may be used. In other embodiments, spur or helical gears with parallel shafts therefrom may be used. The gear reduction ratio can be any suitable value and will depend upon and be proportional to the rotation rate of the central shaft 128. One preferred gear reduction rate is on the order of about 3.5:1. In other embodiments, reduction ratios of 2:1, 3:1, or other suitable reduction ratios may be used. Preferably, the blade 118 operates within the range of from about 7500 rpm to about 11,000 rpm, although this is not necessarily required. Although a number of gearbox configurations can be utilized, a transverse gear arrangement is preferably utilized such as generally represented in
More specifically,
In this way, both the impeller 130 and the cutting blade 118 are driven by the same motor assembly, but at different respective rates. Preferably, the impeller 130 rotates at a rate that is substantially greater than the rate of the cutting blade 118, although such is not necessarily required. In other embodiments, the cutting blade 118 may rotate at a higher speed than the impeller 130.
While the gear assembly 116 is preferably characterized as a gear reduction assembly, such is not necessarily required. In alternative embodiments, the gear assembly 116 can be configured to produce an increase in speed rather than a reduction in speed. It is also not necessarily required that the gear assembly 116 be located between the motor and the cutting blade 118. For example, in further alternative embodiments the blade 118 is rotated at the base rotational rate of the shaft 128, and the gear assembly 116 is disposed between the shaft 128 and the impeller 130. Various other alternatives will readily occur to the skilled artisan upon review of the present disclosure and are included within the scope of the present discussion.
The cutting blade assembly 114 further preferably includes a cover assembly 146 in which the blade 118 is rotated. The cover assembly 146 preferably forms a channel, or plenum 148 that extends across a top portion of the blade 118 and which terminates in an outlet port 150. The port 150, in turn, is arranged to be in fluidic communication with the conduit 132 (see e.g.,
Preferably, the blade 118 extends all the way through the substrate 142 and a selected distance DI below the substrate 142, as generally depicted in
As shown in
The assembly 200 includes a cutting blade 204 configured to operate upon the substrate 202 to remove particulate material therefrom. Preferably, the cutting blade 204 is characterized as a substantially disk-shaped blade which is rotated at a high rotational rate during operation. The cutting blade 204 preferably comprises one or more radially extending teeth 204a. The cutting blade 204 is preferably rotated by a motor in a first rotational direction 206.
A base, or shoe 208 preferably rests upon the substrate 202 and is guided therealong by the user during the cutting operation via a suitable handle 288. The handle 288 is configured to be gripped by the user to allow the tool 200 to be moved and operated with a hand of the user. In some embodiments, the handle 288 can be configured to be moved and operated by a single hand of the user. The cutting blade 204 preferably extends through an aperture (not shown) of the base plate 208 to access the substrate 202. As discussed in the embodiment above, the distance D1 that the cutting blade extends below the base 208 and therefore the substrate 202 should be as long as possible to minimize the amount of dust and debris created when cutting the substrate 202 and to facilitate the direction and urging of the dust and debris created to the ports 214, 216 discussed below.
The assembly 200 further preferably comprises a cover assembly 210 in which the cutting blade 204 is rotated. The cover assembly 210 forms a channel, or plenum 212 that extends across a top portion of the cutting blade 204. A first port 214 is preferably arranged as shown adjacent a leading edge of the cutting blade 204, and a second port 216 is preferably arranged adjacent a trailing edge of the cutting blade 204. The ports 214, 216 preferably bound opposing ends of the plenum 212 as shown.
Vacuum (suction pressure) is preferably applied to the respective ports 214, 216 via conduits, or legs 218 and 220. The vacuum is preferably generated by an impeller or other pressure source (
As shown in
The first, or leading edge port 214 is preferably positioned so that particulates (debris) generated by the interaction between the cutting blade 204 and the substrate 202 are substantially directed and urged toward and through the port 214. The dimensional and axial orientation of the port 214, and the cutting depth of the cutting blade 204, are preferably arranged to enhance the flow of debris exiting the kerf area into the port 214. As discussed in the above embodiment, a maximum cutting depth of the cutting blade 204 is preferred to minimize the amount of dust and debris created and/or the removal of any dust or debris through the conduits 218, 220 and through the impeller.
It is contemplated that the assembly 200 will be configured so that a substantial portion of the generated debris will be drawn through the first port 214. That is, the debris will be directed and urged upwardly along a tangential path that tends to direct and urge the flow of such debris toward and into the leading edge port 214. Upwardly directed debris not drawn into the leading edge port 214 will generally advance along the plenum 212 and through the second, trailing edge port 216. In this way, substantially all of the particulate, dust, and debris generated by the cutting operation can be captured and removed from the work area.
The motor 230 preferably includes a motor shaft 232 that is rotated at a base rotational rate. This rate can be any suitable value, such as at or above around 20,000 revolutions per minute (rpm). In another preferred embodiment, the rotational rate of the shaft 232 is at about 37,000 rpm.
The impeller 234 is mounted to a first end of the shaft 232 for rotation thereby to generate the vacuum (suction pressure) that is applied to ports 214, 216 due to the fluid connection therewith. The motor shaft 232 and the impeller 234 are each rotated about an axis S, shown in
A gear assembly 236 is preferably mounted to a second end of the shaft 232 and includes a selected gear reduction rate, such as on the order of at least 2:1. In some embodiments, bevel gears with perpendicular shafts therefrom may be used. In other embodiments, spur or helical gears with parallel shafts therefrom may be used. This provides a reduced rotation rate for the cutting blade 204 to a suitable value, such as (but not limited to) from about 7500 rpm to about 11,000 rpm, as desired. Other rotational rates higher or lower than this range can be readily used, such as a rate of about 5000 rpm. The optimum cutting blade 204 rotational rate will depend upon a number of factors such as the type of substrate 202 to be cut, the diameter of the cutting blade 204, and the cutting depth. The gear assembly 236 preferably supports the cutting blade 204 along a second axis R that is transverse or substantially perpendicular to the motor shaft axis S (
Activation of the motor 230 thus preferably results in concurrent operation of both the cutting blade 204 and the impeller 234. The preferred close proximity of the impeller 234 to the cutting blade 204 as depicted in
The impeller 234 may be housed within an impeller housing 238 with an inlet port 240 in fluidic communication with a distal end of the common conduit 224. The impeller housing 238 may be monolithically formed with the housing of the tool 200. An outlet port is generally depicted at 242 and this is preferably connectable to an extended conduit 244. The extended conduit 244 is preferably characterized as a flexible hose, such as a 1½ inch or 2 inch diameter rubber or plastic hose. The extended conduit 244 is preferably relatively long, such as on the order of about 30 feet in length, although other lengths and constructions can be used (e.g., 15 feet, etc.).
Using an extended conduit 244 in this fashion allows the particulates to be transported to an appropriate location away from the user's work area, while providing sufficient flow characteristics to efficiently transport the dust and debris along the length of the extended conduit 244. In a preferred embodiment, the extended conduit 244 terminates at a debris collection assembly 246, such as a large filter bag or canister. Alternatively, the end of the extended conduit 244 can be vented to the surrounding atmosphere.
The foregoing configuration advantageously allows a user to utilize a portable hand tool in a location in which the associated debris is highly undesirable (e.g., in a garage, within a residential or commercial structure) and the extended conduit 244 can be directed outside to exhaust the generated particles to the debris collection assembly 246, or the atmosphere. The collection assembly described in the above embodiment and shown in
In situations where the assembly 200 is configured to cut concrete boards, the cutting blade 204 may be formed of a polychrystaline diamond construction, though other materials such as carbide can readily be used. A 5⅜ inch diameter multi-tooth blade is a particularly advantageous size, although other sizes including larger diameters of around 7 inches or more, and smaller diameters of around 4 inches or less, can also be used as desired. For example, in some embodiments a 5.0 inch blade may be used. The blade may be configured with carbide teeth or with other materials or surface finishes. It will be appreciated that the multi-port arrangement discussed herein is particularly suitable for a hand held cutting tool such as disclosed in the embodiments discussed herein The close placement of the impeller to the ports 214, 216, as well as the relatively high rate of rotational speed of the impeller 234, generally provides enhanced collection from the earliest stages of tool assembly use. It will be readily appreciated that while the preferred placement of the impeller 234 opposite the cutting blade 204 as shown in
Similarly, the flow characteristics provided by this preferred impeller 234 arrangement advantageously allows the use of a distally located, large capacity debris collection system, including a system that accommodates debris from multiple sources. This provides an alternative to conventional systems that use local collection bags, HEPA filters, etc. that may be overwhelmed in situations where large amounts of particulate matter is generated during operation.
Turning now to
The motor 510 may be an AC motor powered by one or more phases of line current supplied to the motor 510 by an attached cord 590, or in alternate embodiments the motor 510 may be powered from a DC battery installed on the portable tool 500. The operation of the motor 510 and ultimately the rotation of the cutting blade 530 may be controlled by a trigger mounted on the housing 502. In some embodiments, the trigger includes an interlock that substantially prevents inadvertent operation of the saw 500.
As shown in
The saw blade 530 is substantially enclosed within a blade guard 550 that encloses a majority of the circumferential edge of the saw blade 530 and provides a physical barrier from a user inadvertently contacting the upper and side portions of the rotating saw blade 530. The blade guard 550 further provides an enclosure, or plenum to retain a significant portion of the dust and debris created while cutting a workpiece or substrate within the blade guard 550 and the housing 502 and therefore prevent the same dust and debris from being expelled radially from the saw blade to the environment.
In some embodiments, a lower blade guard 552 is provided that is movably mounted to the upper blade guard 550 or other portions of the housing 502 to substantially fully enclose the circumference of the saw blade 530 to prevent inadvertent contact with the saw blade 530. The lower blade guard 552 is disposed to be withdrawn from below the shoe 519 and the circumference of the saw blade 530 below the shoe 519 when the tool 500 is presented to cut a workpiece or a substrate. This lower blade guard can be utilized in the other embodiments disclosed herein.
An impeller 540 is disposed on the output shaft 518 between the output bevel gear 516 and the saw blade 530. The impeller 540 is configured to establish a large flow of air, dust, and debris through the impeller 540 due to the establishment of a pressure drop across the impeller 540. The impeller 540 is rotatably disposed within a fan housing 544 that is defined within the housing 502 and provides clearance for the impeller blades 541 to rotate with the impeller 540 and the output shaft 518, but substantially eliminate room between the outer circumferential edges of the impeller blades 541 and the fan housing 544 to substantially eliminate air (and dust and debris entrained therein) from bypassing the impeller 540. In some embodiments, the fan housing 544 may be monolithically formed with the housing 502. Further, the minimized space between the outer circumferential edges of the impeller blades 541 and the fan housing 544 substantially eliminates air flowing through the space in the opposite direction.
The fan housing 544 is preferably substantially sealed with the housing 502 to prevent air (or foreign particulate matter) from outside of the housing 502 from being drawing within the fan housing 544 and through a volute 540a of the impeller without first flowing in the vicinity of the saw blade 530. The fan housing 544 is disposed proximate the upper blade guard 550. An enclosed plenum 548 is defined between the internal volume of the upper blade guard 550 and the fan housing 544 to allow for fluid communication between the internal volume of the upper blade guard 550 and the fan housing 544. In some embodiments a forward aperture 554 is provided in the upper blade guard 550 in the vicinity of the leading edge 530a of the saw blade 530. In still other embodiments, a second aperture 554a may be provided in the upper blade guard 550 in the vicinity of the trailing edge 530b of the saw blade 530.
Each of the forward and rear apertures 554, 554a allow for fluid communication (including air and dust and debris created while the cutting blade 530 cuts a substrate) between the inner volume of the upper blade guard 550 and the fan housing 544 through the enclosed plenum 548. The enclosed plenum 548 may include one or more separate branches extending between respective apertures 554 in the upper blade guard 550 and the fan housing 544, the number of branches being equal to the number of apertures 554. The enclosed plenum 548 is disposed to direct and urge the air, dust, and debris from the internal volume of the upper blade guard 550 to the volute 540a of the impeller 540 to provide the maximum amount of suction within the upper blade guard 550 and remove the most dust and debris as possible.
In this embodiment, the rotational speed of the impeller 540 is the same as the saw blade 530. In some embodiments, the diameter of the impeller 540, and the corresponding length of the blades, or vanes 541 of the impeller 540 may be modified in order to alter the mass flow rate of air, dust, and debris through the impeller 540 for the rotational speed of the saw blade 530. As can be understood, larger vanes generally produce a larger mass flow rate of air, dust, and debris through the impeller 540 for the same rotational speed.
The impeller 540 and fan housing 544 includes a discharge port 543 that is aligned substantially perpendicularly to the rotational axis of the impeller 540 and the output shaft 518. In some embodiments, the discharge 543 is aligned substantially tangential to an outer circumferential edge of the impeller 540. The discharge 543 is aligned to receive air, dust, and debris that flows through the rotating impeller 540 and receives kinetic energy from the impeller blades 541 to ultimately flow tangentially or axially away from the impeller blades 541.
In some embodiments, the discharge 543 promotes flow to a storage container 546 that receives and retains the dust and debris entrained with the air flowing through the impeller 540 to prevent the same from being discharged to the environment, while allowing air to flow therethrough. The storage container 546 may be a bag that is removeably attachable to the discharge 543, which is configured to retain dust and debris, but allow air to flow therethrough. The storage container 546 may be retained on the discharge 543 with a threaded connection, a plurality of clips or tabs, or any suitable removable mechanical connection known in the art. In other embodiments, a rigid structure may be removeably connected to the discharge 543 that is configured with a plurality of apertures sized to allow air to flow therethrough, while retaining a substantial portion of the dust and debris entrained with the air. The rigid structure 546 may be removeably attached to the discharge 543 with a threaded connection, a plurality of tabs or clips, or with other mechanical structure known in the art. An extension hose providing fluid communication to a remote collection container (not shown but similar to the container 154 in
Another embodiment of a handheld rotary tool 600 is provided in
The motor 610 may be an AC motor powered by one or more phases of line current supplied to the motor 610 by an attached cord 690, or in alternate embodiments the motor 610 may be powered from a DC battery installed on the portable tool 600. The operation of the motor 610 and ultimately the rotation of the cutting blade 630 may be controlled by a trigger mounted on the housing 602. In some embodiments, the trigger includes an interlock that substantially prevents inadvertent operation of the saw 600.
The motor 610 is aligned within the housing 602 such that the motor shaft 612 is substantially parallel to a longitudinal axis W of the cutting blade 630. In other embodiments, the motor 610 may be disposed within the housing 602 such that the motor shaft 612 is substantially perpendicular or at an oblique angle with respect to a plane through the saw blade 630. In embodiments where the motor shaft 612 is parallel to the saw blade 630, the transmission member 614 may be a set of substantially perpendicular bevel gears 615, 616 that allow for both the change in direction of the torque from the motor 610 to the saw blade 630 and additionally a change in rotational speed of the output shaft 618 from the speed of the motor shaft 612. In some embodiments, meshed worm gears may be used for the transmission 614 to provide for a large reduction in rotational speed of the output shaft 618.
The cutting blade 630 is substantially enclosed within a blade guard 650 that encloses a majority of the circumferential edge of the cutting blade 630 and provides a physical barrier from a user inadvertently contacting the upper and side portions of the rotating saw blade 630. The blade guard 650 further provides an enclosure to retain a significant portion of the dust and debris created while cutting a workpiece or substrate within the blade guard 650 and the housing 602 and therefore prevent the same dust and debris from being expelled radially from the saw blade to the environment.
In some embodiments, a lower blade guard may be provided that is movably mounted to the upper blade guard 650 or other portions of the housing 602 to substantially fully enclose the circumference of the saw blade 630 to prevent inadvertent contact with the saw blade 630. The lower blade guard may be similar to lower blade guards 552 described and shown in the embodiment above.
An impeller 640 is rotatably driven by the output shaft 618 through a second transmission 619. The second transmission 619 may be a belt drive, which is rotatably mounted to respective pulleys 619b, 619c provided on the output shaft 618 and an impeller shaft 642, respectively. The transmission can be designed such that the impeller 640 rotates at a higher speed than the cutting blade 630. Providing the impeller 640 on a separate shaft from the motor and output shafts 612, 618 allows the impeller 640 to be provided remotely from the motor and cutting blade 630. This location allows for a more compact tool with the performance advantages of the tools described in the other embodiments herein.
The impeller 640 is configured to establish a large flow of air, dust, and debris included therewith through the impeller 640 due to the establishment of a pressure drop across the impeller 640. The impeller 640 is rotatably disposed within a fan housing 644 that is defined within the housing 602 and provides clearance for the impeller blades 641 to rotate with the impeller 640 and the output shaft 618, but substantially eliminate room between the outer circumferential edges of the impeller blades 641 and the fan housing 644 to substantially eliminate air (and dust and debris entrained therein) from bypassing the impeller 640. In some embodiments, the fan housing 644 may be monolithically formed with the housing 602. Further, the minimized space between the outer circumferential edges of the impeller blades 641 and the fan housing 644 substantially eliminates air flowing through the space in the opposite direction.
The fan housing 644 is preferably substantially sealed with the housing 602 to prevent air (or foreign particulate matter) from outside of the housing 602 from being drawn within the fan housing 644 and through a volute 640a of the impeller without first flowing in the vicinity of the cutting blade 630.
The fan housing 644 and impeller 640 may be disposed on the opposite side of the motor 610 from the cutting blade 630, as shown in
An enclosed plenum 648 is defined between the internal volume of the upper blade guard 650 and the fan housing 644 to allow for fluid communication between the internal volume of the upper blade guard 650 and the fan housing 644. In some embodiments a forward aperture 654 is provided in the upper blade guard 650 in the vicinity of the leading edge 630a of the cutting blade 630. In still other embodiments, a second aperture 654a may be provided in the upper blade guard 650 in the vicinity of the trailing edge 630b of the cutting blade 630.
Each of the forward and rear apertures 654, 654a allow for fluid communication (including air and dust and debris created while the cutting blade 630 cuts a substrate) between the inner volume of the upper blade guard 650 and the fan housing 644 through the enclosed plenum 648. The enclosed plenum 648 may include one or more separate branches extending between respective apertures 654 in the upper blade guard 650 and the fan housing 644, the number of branches being equal to the number of apertures 654. The enclosed plenum 648 is disposed to direct and urge the air, dust, and debris from the internal volume of the upper blade guard 650 to the volute 640a of the impeller 640 to provide the maximum amount of suction within the upper blade guard 650 and remove the most dust and debris as possible.
The impeller 640 and fan housing 644 includes a discharge 643 that is aligned substantially perpendicularly to the rotational axis of the impeller 640 and the output shaft 618. The discharge 643 is aligned to receive air, dust, and debris that flows through the rotating impeller 640 and receives kinetic energy from the impeller blades 641 to ultimately flow tangentially or axially away from the impeller blades 641.
In some embodiments, the discharge 643 promotes flow to a storage container that receives and retains the dust and debris entrained with the air flowing through the impeller 640 to prevent the same from being discharged to the environment, while allowing air to flow therethrough. The storage container may be similar to storage container 546 discussed above. In other embodiments, a hose 647 may be attached to the discharge 643 to allow the air, dust, and debris to be removed from the tool 600 to a remote location.
Turning now to
The motor 710 may be an AC motor powered by one or more phases of line current supplied to the motor 710 by an attached cord 790, or in alternate embodiments the motor 710 may be powered from a DC battery installed on the portable tool 700. The operation of the motor 710 and ultimately the rotation of the cutting blade 730 may be controlled by a trigger mounted on the housing 702 and specifically the handle. In some embodiments, the trigger includes an interlock that substantially prevents inadvertent operation of the saw 700.
The motor 710 is aligned within the housing 702 such that the motor shaft 712 is substantially parallel to a longitudinal axis X of the cutting blade 730. In other embodiments, the motor 710 may be disposed within the housing 702 such that the motor shaft 712 is substantially perpendicular or at an oblique angle with respect to a plane through the cutting blade 730. In embodiments where the motor shaft 712 is parallel to the cutting blade 730, the transmission member 714 may be a set of substantially perpendicular bevel gears 715, 716 that allow for both the change in direction of the torque from the motor 710 to the cutting blade 730 and additionally a change in rotational speed of the output shaft 718 from the speed of the motor shaft 712. In some embodiments, worm gears may be used for the transmission member to provide for a large change in rotational speed between the motor shaft 712 and the output shaft 718.
The cutting blade 730 is substantially enclosed within a blade guard 750 that encloses a majority of the circumferential edge of the cutting blade 730 and provides a physical barrier from a user inadvertently contacting the upper and side portions of the rotating cutting blade 730. The blade guard 750 further provides an enclosure to retain a significant portion of the dust and debris created while cutting a workpiece or substrate within the blade guard 750 and the housing 702 and therefore prevent the same dust and debris from being expelled radially from the cutting blade 730 to the environment.
In some embodiments, a lower blade guard (not shown, but similar to lower blade guard 552) is provided that is movably mounted to the upper blade guard 750 or other portions of the housing 702 to substantially fully enclose the circumference of the cutting blade 730 to prevent inadvertent contact with the cutting blade 730.
An impeller 740 is rotatably driven by the motor shaft 712 with a second transmission 719 located at the opposite end of the motor shaft 712 from the transmission 714. The second transmission 719 may be a meshed set of bevel gears, with a first input gear 719b on the motor shaft 712 and a second output gear 719c on an impeller shaft 742.
In an alternate embodiment shown in
The impeller 740 is configured to establish a large flow of air, dust, and debris included therewith through the impeller 740 due to the establishment of a pressure drop across the impeller 740. The impeller 740 is rotatably disposed within a fan housing 744 that is defined within the housing 702 and provides clearance for the impeller 740 to rotate, but substantially eliminate room between the outer circumferential edges of the impeller blades 741 and the fan housing 744 to substantially eliminate air (and dust and debris entrained therein) from bypassing the impeller 740. In some embodiments, the fan housing 744 may be monolithically formed with the housing 702. Further, the minimized space between the outer circumferential edges of the impeller blades 741 and the fan housing 744 substantially eliminates air flowing through the space in the opposite direction.
The fan housing 744 and impeller 740 may be disposed on the opposite side of the motor 710 from the cutting blade 730, as shown in
An enclosed plenum 748 is defined between the internal volume of the upper blade guard 750 and the fan housing 744 to allow for fluid communication between the internal volume of the upper blade guard 750 and the fan housing 744. In some embodiments a forward aperture 754 is provided in the upper blade guard 750 in the vicinity of the leading edge 730a of the cutting blade 730. In still other embodiments, a second aperture 754a may be provided in the upper blade guard 750 in the vicinity of the trailing edge 730b of the cutting blade 730.
Each of the forward and rear apertures 754, 754a allow for fluid communication (including air and dust and debris created while the cutting blade 730 cuts a substrate) between the inner volume of the upper blade guard 750 and the fan housing 744 through the enclosed plenum 748. The enclosed plenum 748 may include one or more separate branches extending between respective apertures 754 in the upper blade guard 750 and the fan housing 744, the number of branches being equal to the number of apertures 754. The enclosed plenum 748 is disposed to direct and urge the air, dust, and debris from the internal volume of the upper blade guard 750 to the volute 740a of the impeller 740 to provide the maximum amount of suction within the upper blade guard 750 and remove the most dust and debris as possible.
The impeller 740 and fan housing 744 includes a discharge 743 that is aligned substantially perpendicularly to the rotational axis of the impeller 740 and the output shaft 718. The discharge 743 is aligned to receive air, dust, and debris that flows through the rotating impeller 740 and receives kinetic energy from the impeller blades 741 to ultimately flow tangentially or axially away from the impeller blades 741.
In some embodiments, the discharge 743 promotes flow to a storage container (not shown but similar to storage container 546) that receives and retains the dust and debris entrained with the air flowing through the impeller 740 to prevent the same from being discharged to the environment, while allowing air to flow therethrough.
Another alternate embodiment of a handheld rotary tool 400 is discussed with reference to
The motor may be powered from one or more phases of AC line current supplied to the motor by an attached cord, or in alternate embodiments the motor may be powered from a DC battery (rechargeable or otherwise) installed on the portable tool 400. A handle 408 is disposed on the housing 402 to allow the user to carry and operate the tool 400 with a single hand. The operation of the motor and ultimately the rotation of the cutting blade 430 is controlled by a trigger 409 or other operational mechanism mounted on the handle 408 or on the housing 402. The handle 408 is provided on the housing 402 that is configured to allow the tool 400 to be transported or carried by a single hand of the user. In some embodiments, the trigger 409 includes an interlock that substantially prevents inadvertent operation of the saw 400. As shown in
In some embodiments, the transmission 414 may be a belt 424 that is disposed in tension around pulleys 414a, 414b that are disposed on the respective motor and impeller shafts 412, 418. In other embodiments, a plurality of spur or helical gears (not shown) may be meshingly engaged to transfer torque from the motor shaft 412 to the output shaft 418. In these embodiments, the relative sizes of the pulleys 414a, 414b or the input and output gears are designed to provide the desired rotational speed of the impeller shaft 418 based on a specific motor shaft 412 speed.
In some embodiments, an impeller 440 may be provided on either the motor shaft 412 or the output shaft 418 (as shown in
As with the embodiments discussed above, the cutting blade 430 is disposed within an upper guard 450 that is fixed to the housing 402 and provides a protective barrier against inadvertent contact with the majority of the circumference of the cutting blade 430 and substantially limiting the radial expulsion of debris and dust created when cutting a substrate in the radial or tangential direction from the circumference of the cutting blade 430 and the blade teeth. In some embodiments, a lower blade guard 452 is provided that is movably mounted to the upper blade guard 450 or other portions of the housing 402 to substantially fully enclose the circumference of the cutting blade 430 to prevent inadvertent contact with the cutting blade 430. The lower blade guard 452 is disposed to be withdrawn from below the shoe 419 and the circumference of the cutting blade 430 below the shoe 419 when the tool 400 is presented to cut a workpiece or a substrate.
The impeller 440 is disposed within a disk-like fan housing 444 that substantially encloses the impeller 440. The walls of the fan housing 444 are disposed with an inner diameter slightly larger than the diameter of the impeller blades 441, to reduce the area for air, dust, and debris flow that bypasses the impeller 440, and to reduce the area for potential reverse air flow past the impeller blades 441. The impeller 440 includes a suction port, or volute 440a that receives air, dust, and debris therethrough subsequently exits the impeller 440 and discharge 443 from the fan housing 444 that is disposed axially or tangentially from the impeller blades 441.
A suction plenum is disposed between the internal volume within the upper guard 450 and the fan housing 444 to allow for fluid communication between the two volumes. The suction plenum is constructed and disposed similar to suction plenums 548, 648, 748, discussed above. One or more apertures may be provided in the upper blade guard 450 to allow communication of air, dust, and debris from the cutting zone to the impeller 440. The apertures and assorted structure may be constructed similarly to the similar structure discussed and shown above.
In some embodiments, the discharge 443 is configured to receive a storage container or similar device that receives the discharge flow of air, dust, and debris from the impeller 440. The storage container may be similar in design and operation to the storage container 546, discussed above.
Another embodiment of a handheld rotary tool 800 is provided in
The motor 810 may be an AC motor powered by one or more phases of line current supplied to the motor 810 by an attached cord, or in alternate embodiments the motor 810 may be powered from a DC battery installed on the portable tool 800. The operation of the motor 810 and ultimately the rotation of the cutting blade 830 may be controlled by a trigger mounted on the housing 802 or on a handle, discussed below. In some embodiments, the trigger includes an interlock that substantially prevents inadvertent operation of the saw 800. A handle may be provided on the housing 802 (similar in operation and configuration to handle 580 shown in
The motor 810 is aligned within the housing 802 such that an axis of rotation P of the motor shaft 812 is substantially parallel to an axis of rotation Q of the cutting blade 830. In other embodiments, the motor 810 may be disposed within the housing 802 such that the axis of rotation P of the motor shaft 812 is substantially perpendicular or at an oblique angle with respect to the axis of rotation Q of the cutting blade 830.
In embodiments where the motor shaft 812 is parallel to the cutting shaft 818, the transmission 814 between the two shafts may be a pinion gear 815 defined on the motor shaft 812 and a meshed spur gear 816 attached to the output shaft 818 as shown in
The cutting blade 830 is substantially enclosed within a blade guard 850 that encloses a majority of the circumferential edge of the cutting blade 830 and provides a physical barrier from a user inadvertently contacting the upper and side portions of the rotating cutting blade 830. The blade guard 850 further provides an enclosure, or plenum 853 to retain a significant portion of the dust and debris created while cutting a workpiece or substrate within the blade guard 850 and the housing 802 and therefore prevent the same dust and debris from being expelled radially from the cutting blade 830 to the environment.
The blade guard 850 additionally includes a port defined in the blade guard 850 that is connected to a conduit 860 that provides fluid communication between the plenum 853 and the first volute 840a and first set of blades 841 of the impeller 840, described below. The port and suction end of the conduit 860 may be disposed proximate the leading edge of the cutting blade 830, or at other locations within the blade guard 850. In some embodiments, a second port may be defined in the blade guard 850 and connected to a second conduit that is fluidly connected to the impeller 840, which may be disposed proximate a trailing edge of the cutting blade 830 or at other locations of the blade guard 850. Embodiments with two or more ports and two or more conduits are similar to the structure shown in
In some embodiments, a lower blade guard may be provided that is movably mounted to the upper blade guard 850 or other portions of the housing 802 to substantially fully enclose the circumference of the cutting blade 830 to prevent inadvertent contact with the cutting blade 830. The lower blade guard may be similar to lower blade guard 552 described and shown in the embodiment above.
An impeller 840 is rotatably driven by the motor shaft 812. As shown in
The impeller 840 is configured to establish two independent air flow paths through the tool, a first path M urging and directing air and dust and debris created by the cutting blade 830 when cutting a substrate to the impeller 840. The first path M extends from the blade housing 850 through the conduit 860 (or multiple conduits as discussed above) to the impeller 840 and then subsequently directs air discharged from the impeller 840 through a discharge port 843 on the housing 802. A second flow path N provided by the impeller 840 provides a flow of cooling air across the motor 810 to the impeller 840 and ultimately discharges the cooling air through an output vent 808 defined in the housing 802. Air flowing across the motor 810 enters through an input vent 807 defined on the housing 802, preferably disposed on the opposite side of the motor 810 from the impeller 840. Air leaving the impeller 840 (after flowing past the motor 810) ultimately flows out of the housing through the output vent 808 defined in the housing 802.
The impeller 840 is formed with a first set of blades 841 and a second set of blades 846, and a first volute 840a that provides fluid communication to the first set of blades 841 and a second volute 845 that provides fluid communication to the second set of blades 846. Each of the first and second sets of blades 841, 846 are disposed on opposite sides of the impeller 840, such that the first set of blades 841 and the first volute 840a receive air, dust, and debris that flows along path M from the plenum 853 and through the conduit 860, and the second set of blades 846 and the second volute 845 receive air that flows along path N past the motor 810.
The impeller 840 includes a ring 847 that extends circumferentially along the outer edge of the impeller 840 and separates the outer edges of the first and second sets of impeller blades 841, 846. The ring 847 rides within a channel 809 defined in the housing 802, which substantially eliminates fluid communication between opposing sides of the impeller 840, thereby substantially preventing the dust and debris entrained within the air flowing along the first flow path M from flowing to the vicinity of the motor 810.
The impeller 840 is rotatably disposed within a fan housing 844 that is attached to or monolithically formed with the housing 802. The cutting blade side of the fan housing 844 is preferably substantially sealed with the housing 802 to prevent air (or foreign particulate matter) from outside of the housing 802 from being drawn within the cutting blade side of the fan housing 844 and through a volute 840a of the impeller 840 without first flowing in the vicinity of the cutting blade 830.
The impeller 840 and fan housing 844 includes a discharge 843 that is aligned substantially perpendicularly to the rotational axis of the impeller 840. The discharge 843 is aligned to receive air, dust, and debris that flows through the first set of blades 841 of the rotating impeller 840 and receives kinetic energy therefrom to ultimately flow tangentially or axially away from the impeller blades 841.
It will now be appreciated that the various preferred embodiments discussed herein provide a number of advantages over the prior art. The disclosed tools may be configured to be lightweight, portable and easily manipulated by a user to cut any number of materials. Substrates that are prone to generate significant amounts of dust and other airborne particulates, such as concrete board or drywall, granite, ceramics, marble, tile or similar materials can be readily processed by the tool with a minimal amount of such particulates being released to the surrounding atmosphere.