The present invention generally relates to power tools having an impact mechanism.
U.S. Pat. Nos. 7,395,873, 7,053,325, 7,428,934, 7,124,839 and Japanese publications JP 6-182674, JP 7-148669, JP 2001-88051 and JP 2001-88052 disclose various types of power tools having an impact mechanism. While such tools can be effective for their intended purpose, there remains a need in the art for an improved impact mechanism and an improved power tool with an impact mechanism.
This section provides a general summary of some aspects of the present disclosure and is not a comprehensive listing or detailing of either the full scope of the disclosure or all of the features described therein.
In one form, the present teachings provide a power tool with a housing, a motor, a transmission, a spindle and an impact mechanism. The motor has an output shaft that drives the transmission. The transmission has a plurality of planet gears, a planet carrier journally supporting the planet gears for rotation about an axis, and a ring gear that is in meshing engagement with the planet gears. The impact mechanism has a plurality of anvil lugs, an impactor and an impactor spring. The anvil lugs are coupled to the ring gear and are not engaged by the planet gears. The impactor is mounted to pivot about the spindle and has a plurality of hammer lugs. The impactor spring biases the impactor toward the ring gear to cause the hammer lugs to engage the anvil lugs.
In another form, the present teachings provide power tool with a motor, a spindle, a transmission, a rotary impact mechanism and an adjustment mechanism. The transmission is driven by the motor and has a transmission output. The rotary impact mechanism cooperates with the transmission to drive the spindle. The rotary impact mechanism includes a plurality of anvil lugs, an impactor, and a spring. The impactor is movable axially and pivotally on the spindle and includes a plurality of hammer lugs. The spring biases the impactor in a predetermined axial direction to cause the hammer lugs to engage the anvil lugs. The rotary impact mechanism is operable in a direct drive mode in which the hammer lugs and the anvil lugs remain engaged to one another and a rotary impact mode in which the impactor reciprocates and pivots to permit the hammer lugs to repetitively engage and disengage the anvil lugs and thereby generate a rotary impulse. The adjustment mechanism is configured to set a switching torque at which the rotary impact mechanism will switch between the direct drive mode and the rotary impact mode.
In yet another form, the present teachings provide a power tool having a motor, a transmission, a shaft and an impact mechanism. The transmission is driven by an output shaft of the motor and includes a planetary stage with a ring gear and a planetary stage output member. The shaft coupled to the planetary stage output member. The impact mechanism has a first set of impacting lugs, an impactor and an impactor spring. The first set of impacting lugs are fixed to the ring gear. The impactor is rotatably mounted on the shaft and includes a second set of impacting lugs. The impactor spring biases the impactor toward the ring gear to cause the second impacting lugs to engage the first impacting lugs. The impact mechanism is operable in a first mode in which the second impacting lugs repetitively cam over the first impacting lugs to urge the impactor axially away from the ring gear in response to application of a reaction torque to the ring gear that exceeds a predetermined threshold and thereafter re-engage the first impacting lugs to create a torsional impulse that is applied to the ring gear and which is greater in magnitude than the predetermined threshold. The impact mechanism is also being operable in a second mode in which the second impacting lugs are not permitted to cam over and disengage the first impacting lugs irrespective of the magnitude of the reaction torque applied to the ring gear.
In yet another form, the present teachings provide a power tool having a motor, a shaft, a transmission, a rotary impact mechanism, a housing, which houses the transmission and the rotary impact mechanism, and an adjustment mechanism. The transmission is driven by an output shaft of the motor. The rotary impact mechanism cooperates with the transmission to drive the shaft. The rotary impact mechanism includes a first set of impacting lugs, an impactor and an impactor spring. The impactor being rotatably mounted on the shaft and includes a second set of impacting lugs. The impactor spring biases the impactor in a direction toward the first set of impacting lugs to cause the second impacting lugs to engage the first impacting lugs. The impact mechanism is operable in a first mode in which the second impacting lugs repetitively cam over the first impacting lugs to urge the impactor axially away from the first impacting lugs in response to application of a trip torque and thereafter axially toward the first impacting lugs to re-engage the first impacting lugs and create a torsional impulse that is applied to the shaft. The adjustment mechanism is configured for setting the trip torque at one of a plurality of predetermined levels and includes an adjusting member that is mounted for rotation for rotation on the housing about the shaft, the adjustment member forming at least a portion of an exterior surface of the power tool.
In another form the present teachings provide a method for installing a self-drilling, self-tapping (SDST) screw to a workpiece. The method includes: driving the SDST screw with a rotary power tool with a continuous rotary motion against a first side of the workpiece to form a hole in the workpiece; operating the rotary power tool with rotating impacting motion to complete the formation of the hole through a second, opposite side of the workpiece, to rotate the SDST screw to form at least one thread in the workpiece or both; and operating the power tool with continuous rotary motion to tighten the SDST screw to the workpiece.
In a further form the present teachings provide a power tool that includes a motor, an output spindle, a transmission and an impact mechanism. The transmission and the impact mechanism cooperate to drive the output spindle in a continuous rotation mode and in a rotary impacting mode. A trip torque for changing between the continuous rotation mode and the rotary impacting mode occurs when a continuous torque greater than or equal to 0.5 Nm and less than or equal to 2 Nm is applied to the output spindle. In the rotary impacting mode torque spikes greater than or equal to 0.2 J and less than or equal to 5.0 J are cyclically applied to the output spindle.
Further areas of applicability will become apparent from the description provided herein. It should be understood that the description and specific examples in this summary are intended for purposes of illustration only and are not intended to limit the scope of the present disclosure, its application and/or uses in any way.
The drawings described herein are for illustrative purposes only and are not intended to limit the scope of the present disclosure in any way. The drawings are illustrative of selected teachings of the present disclosure and do not illustrate all possible implementations. Similar or identical elements are given consistent identifying numerals throughout the various figures.
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The impact mechanism 18 can include a rotary shaft 70, an anvil 72, an impactor 74, a cam mechanism 76 and an impactor spring 78. The rotary shaft 70 can be coupled to the output of the transmission 16 (i.e., the planet carrier 52 in the example provided) for rotation about the axis 58. In the particular example provided, the rotary shaft 70 is unitarily formed with the carrier structure 60 and the output spindle 20, but it will be appreciated that two or more of these components could be separately formed and assembled together. The anvil 72 can comprise a set of anvil lugs 80 that can be coupled to the ring gear 56 in an appropriate manner, such as on a side or end that faces the impactor 74 or on the circumference of the ring gear 56. Although the set of anvil lugs 80 is depicted in the accompanying illustrations as comprising two discrete lugs that are formed on a flange F that extends axially from the ring gear 56, it will be appreciated that the set of anvil lugs 80 could comprise a single lug or a multiplicity of lugs in the alternative and/or that the lug(s) could extend radially inwardly or outwardly from the ring gear 56. The anvil lugs 80 are coupled to the ring gear 56 and are not engaged by the planet gears 54.
The impactor 74 can be an annular structure that can be mounted co-axially on the rotary shaft 70. The impactor 74 can include a set of hammer lugs 82 that can extend rearwardly toward the ring gear 56. Although the set of hammer lugs 82 is depicted in the accompanying illustrations as comprising two discrete lugs, it will be appreciated that the set of hammer lugs 82 could comprise a single lug or a multiplicity of lugs in the alternative and that the quantity of lugs in the set of hammer lugs 82 need not be equal to the quantity of lugs in the set of anvil lugs 80. Aside from contact with the set of anvil lugs 80 that are coupled to the ring gear 56, the impactor 74 is not configured to engage other elements of the transmission 16 and does not meshingly engage any geared element(s) of the transmission 16.
The cam mechanism 76 can be configured to permit limited rotational and axial movement of the impactor 74 relative to the gear case 32 (
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It will also be appreciated that the torque adjustment mechanism 22 may be configured with a setting at which the hammer lugs 82 (
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It will also be appreciated that the torque adjustment mechanism 22 can permit the user to select a desired trip torque from a plurality of predetermined trip torques (through rotation of the torque adjustment collar 106). In some situations it may be desirable to initially seat a threaded fastener (not shown) to a desired torque while operating the rotary power tool 10 (
It will be appreciated that other methods and mechanisms may be employed to lock the rotary power tool 10 (
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The motor assembly 14a can be any type of motor (e.g., electric, pneumatic, hydraulic) and can provide rotary power to the transmission 16a. The transmission 16a can be any type of transmission and can include one or more reduction stages and a transmission output member. In the particular example provided, the transmission 16a is a single-stage, single speed planetary transmission and the transmission output member is a planet carrier 52a. The output spindle 20a can be coupled for rotation with the planet carrier 52a.
The impact mechanism 18a can include a set of anvil lugs 80a, an impactor 74a, a torsion spring 1000, a thrust bearing 1002 and an impactor spring 78a. The anvil lugs 80a can be coupled to a forward annular face 1010 of a ring gear 56a that is associated with the transmission 16a. The impactor 74a can be supported for rotation on the output spindle 20a and can include a set of hammer lugs 82a that are configured to engage the anvil lugs 80a. It will be appreciated that the anvil lugs 80a and the hammer lugs 82a can be configured in a manner that is similar to the anvil lugs 80 and the hammer lugs 82 discussed above and illustrated in
The torque adjustment mechanism 22a can include a torque adjustment collar 106′, an apply device 108′ and an adjustment nut 1030. The adjustment collar 106′ can be mounted for rotation on the housing assembly 12a and can include a plurality of longitudinally extending grooves 1032 that are circumferentially spaced about its interior surface. The apply device 108′ comprises a plurality of legs 110a and an annular plate 112a in the example provided. The legs 110a can extend between the adjustment nut 1030 and the annular plate 112a, while the annular plate 112a can abut the impactor spring 78a on a side opposite the thrust bearing 1002. The adjustment nut 1030 can include a threaded aperture 1040 and a plurality of tabs 1042 that can be received into the grooves 1032 in the torque adjustment collar 106′. The threaded aperture 1040 can be threadably engaged to corresponding threads 1048 formed on the housing assembly 12a. Accordingly, it will be appreciated that rotation of the torque adjustment collar 106′ can cause corresponding rotation and translation of the adjustment nut 1030 to thereby change the amount by which the impactor spring 78a is compressed.
The impact mechanism 18a can be operated in a first mode in which the impact mechanism 18a does not produce a rotationally impacting output. In this mode the torque adjustment collar 106′ is positioned relative to the housing assembly 12a to compress the impactor spring 78a to a point at which the anvil lugs 80a and the hammer lugs 82a remain engaged to one another and the impactor 74a does not rotate. To counteract the force transmitted through the impactor 74a to the ring gear 56a, a second thrust bearing 1050 can be disposed between the ring gear 56a and the housing assembly 12a.
The impact mechanism 18a can also be operated in a second mode in which the impact mechanism 18a produces a rotationally impacting output. In this mode the torque adjustment collar 106′ is positioned relative to the housing assembly 12a to compress the impactor spring 78a to a point that achieves a desired trip torque; at this point, the impactor spring 78a can be further compressed so as to permit the hammer lugs 82a to disengage the anvil lugs 80a during operation of the impact mechanism 18a. As will be appreciated, disengagement of the anvil lugs 80a and the hammer lugs 82a involves the movement of the impactor 74a and the thrust bearing 1002 in a direction away from the ring gear 56a so as to further compress the impactor spring 78a. As torque is transmitted to the output spindle 20a during operation of the rotary power tool 10a, a torque reaction acts on the ring gear 56a, causing it and the impactor 74a to rotate in a second rotational direction opposite the first rotational direction. Rotation of the impactor 74a in the second rotational direction loads the torsion spring 1000. When the trip torque is exceeded, the hammer lugs 82a will ride or cam over the anvil lugs 80a so that the impactor 74a disengages the ring gear 56a. At this time, the ring gear 56a is permitted to rotate in the second rotational direction, the torsion spring 1000 will urge the impactor 74a in the first rotational direction and the impactor spring 78a will urge the impactor 74a rearwardly to re-engage the ring gear 56a. The hammer lugs 82a impact against the anvil lugs 80a when the impactor 74a re-engages the ring gear 56a to produce a torsional pulse that is applied to the ring gear 56a to drive the ring gear 56a in the first rotational direction. It is believed that the impactor 74a will have sufficient energy not only to stop the ring gear 56a as it rotates in the second rotational direction, but also to drive it in the first rotational direction so that the torque output from the transmission 16a is a function of the torque that is input to the transmission 16a from the motor assembly 14a.
While the power tools 10, 10a have been illustrated and described thus far as employing an axially arranged motor/transmission/impact mechanism/output spindle configuration, it will be appreciated that the disclosure, in its broadest aspects, can extend to power tools having a motor/transmission/impact mechanism/output spindle configuration that is not arranged in an axial manner. One example is illustrated in
The motor assembly 14c can be received in the housing assembly 12c and disposed about an axis 1000. The transmission 16c can include a first stage 1002 and a second stage 1004. The first stage 1002 can include a first bevel gear 1006, which can be coupled for rotation with the output shaft 42c of the motor assembly 14c, and a second bevel gear 1008 that can be mounted to an intermediate shaft 1010. The intermediate shaft 1010 can be supported on a first end by a bearing 1012 that can be received in the gear case 32c and on a second end by the shaft 70c of the impact mechanism 18c. The second stage 1004 can be a planetary transmission stage with a sun gear 50c, a planet carrier 52c, a plurality of planet gears 54c, and a ring gear 56c. A retaining ring 1020 can be employed to inhibit rearward movement of the ring gear 52c toward the second bevel gear 1008.
The impact mechanism 18c can include a rotary shaft 70c, an anvil 72c, an impactor 74c, a cam mechanism 76c and an impactor spring 78c. The rotary shaft 70c can be coupled to the output of the transmission 16c (i.e., the planet carrier 52c in the example provided) for rotation about the axis 58c. In the particular example provided, the rotary shaft 70c is unitarily formed with a carrier structure 60c of the planet carrier 52c and the output spindle 20c, but it will be appreciated that two or more of these components could be separately formed and assembled together. The anvil 72c can comprise a set of anvil lugs 80c that can be coupled to the ring gear 56c on a side or end that faces the impactor 74c. The impactor 74c can be an annular structure that can be mounted co-axially on the rotary shaft 70c. The impactor 74c can include a set of hammer lugs 82c that can extend rearwardly toward the ring gear 56c. The cam mechanism 76c can be configured to permit limited rotational and axial movement of the impactor 74c relative to the gear case 32c. In the example provided, the cam mechanism 76c includes a pair of V-shaped cam grooves 86c that are formed into the impactor 74c about its exterior circumferential surface, a pair of cam balls 88c, which are received into respective ones of the cam grooves 86c, and an annular retention collar 90c that is disposed about the impactor 74c and which maintains the cam balls 88c in the cam grooves 86c. It will be appreciated, however, that any type of cam mechanism can be employed, including mating threads. The retention collar 90c can be non-rotatably coupled to the gear case 32c. A retaining ring 1030 can be coupled to the gear case 32c to inhibit axial movement of the retention collar 90c along the axis 58c. The impactor spring 78c can bias the impactor 74c rearwardly such that the cam balls 88c are received in the apex 100c of the V-shaped cam grooves 86c and radial flanks of the hammer lugs 82c are engaged to corresponding radial flanks on the anvil lugs 80c.
The torque adjustment mechanism 22c can be generally similar in construction and operation to the torque adjustment mechanisms 22 and 22a described above. Briefly, the torque adjustment mechanism 22c can include a torque adjustment collar 106c and an adjuster 108c. The torque adjustment collar 106c can be rotatably mounted on the gear case 32c but maintained in a stationary position along the axis 58c. The adjuster 108c can include an internally threaded adjustment nut 1040 that can be non-rotatably mounted on the gear case 32c and threadably engaged to the torque adjustment collar 106c. Accordingly, it will be appreciated that rotation of the torque adjustment collar 106c can cause corresponding translation of the adjustment nut 104 along the axis 58c. A thrust bearing 1050 can be disposed between the impactor spring 78c and the impactor 74c. Bearings 1052 can be mounted in the gear case 32c to support the planet carrier 52c, the shaft 70c and the output spindle 20c.
Yet another power tool constructed in accordance with the teachings of the present disclosure is shown in
The power tools constructed in accordance with the teachings of the present disclosure may be employed to install a self-drilling, self-tapping screw to a workpiece. Non-limiting examples of self-drilling, self-tapping screws are disclosed in U.S. Pat. Nos. 2,479,730; 3.044,341; 3,094,895; 3,463,045; 3,578,762; 3,738,218; 4,477,217; and 5,120,172. Moreover, one type of commercially available self-drilling, self-tapping screw is known in the art as a TEK screw. Those of skill in the art will appreciate that a self-drilling, self-tapping (SDST) screw commonly includes a body, which can have a drilling tip and a plurality of threads, and a head. The drilling tip can be configured to drill or form a hole in a workpiece as the screw is rotated. The threads can be configured to form one or more mating threads in the workpiece as the screw traverses axially into the workpiece. The head can be configured to receive rotary power to drive the screw to thereby form the hole and the threads, as well as to secure the head against the workpiece and optionally to generate tension in a portion of the body (i.e., a clamp force). A power tool constructed in accordance with the teachings of the present disclosure can be configured to drive the head of the SDST screw with a continuous rotary (i.e., non-impacting) motion against a first side of the workpiece to at least partly form a hole in the workpiece. The power tool can be operated to produce rotary impacting motion (which is imparted to the head of the SDST screw) to complete the hole through a second, opposite side of the workpiece and/or to form at least one thread in the workpiece. The power tool can be operated to produce a continuous rotary motion which is employed to drive the SDST screw such that the SDST screw is tightened to the workpiece. It will be appreciated that a power tool constructed in accordance with the teachings of the present disclosure can change between continuous rotary motion and rotating impacting motion automatically (i.e., without input from the operator or user of the tool) and that the automatic change-over can be based on a predetermined torsional output of the power tool (i.e., automatic change-over can occur at a predetermined trip torque). We have found, for example, that a trip torque of between 0.5 Nm and 2 Nm, and more particularly a trip torque of between 1 Nm and 1.5 Nm is particularly well suited for use in driving commercially-available TEK fasteners into sheet metal workpieces of the type that are commonly employed in HVAC systems and commercial construction (e.g., steel studs). We have also discovered that it is desirable that the impacting mechanism provide a relatively small torsional spike of between about 0.2 J to about 5.0 J and more preferably between about 0.5 J to about 2.5 J when the power tool is configured to drive TEK fasteners into sheet steel workpiece. More specifically, the combination of the aforementioned trip-torque and torsional spike cause the tool to operate substantially as a tool with a continuous rotating output that switches over briefly into an impacting mode to complete the formation of a hole in the sheet steel workpiece and/or to form threads in the sheet steel workpiece.
It will be appreciated that the above description is merely exemplary in nature and is not intended to limit the present disclosure, its application or uses. While specific examples have been described in the specification and illustrated in the drawings, it will be understood by those of ordinary skill in the art that various changes may be made and equivalents may be substituted for elements thereof without departing from the scope of the present disclosure as defined in the claims. Furthermore, the mixing and matching of features, elements and/or functions between various examples is expressly contemplated herein, even if not specifically shown or described, so that one of ordinary skill in the art would appreciate from this disclosure that features, elements and/or functions of one example may be incorporated into another example as appropriate, unless described otherwise, above. Moreover, many modifications may be made to adapt a particular situation or material to the teachings of the present disclosure without departing from the essential scope thereof. Therefore, it is intended that the present disclosure not be limited to the particular examples illustrated by the drawings and described in the specification as the best mode presently contemplated for carrying out the teachings of the present disclosure, but that the scope of the present disclosure will include any embodiments falling within the foregoing description and the appended claims.
This application claims the benefit and priority of U.S. Provisional Patent Application No. 61/174,143 filed Apr. 30, 2009. The entire disclosure of the above application is incorporated herein by reference.
Number | Date | Country | |
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61174143 | Apr 2009 | US |