Field of the Invention
This invention relates to a tuned or tunable boring tool for suppressing vibrations caused in machining processes and, more particularly, to a tuned or tunable boring tool that utilizes a dynamic vibration absorber tuned for reducing vibration of a vibrating boring bar at multiple natural frequencies or vibration modes.
Description of Related Art
During a metalworking operation, there is relative motion between a workpiece and a cutting tool being urged against the workpiece. Specifically, the surface finish left on the workpiece by a previous pass of the cutting tool creates variation in chip thickness that, in turn, creates fluctuation of the cutting force magnitude. The relative motion between the workpiece and the tool is magnified by this fluctuation of the cutting force and may lead to an unstable condition known as chatter. Chatter is an example of self-excited vibration. As a result of this vibration, a poor quality surface finish and an out-of-tolerance finished workpiece may be produced.
Chatter may be especially problematic when the cutting tool is coupled to an elongated boring bar. A boring bar is essentially a cantilevered member which is anchored at one end and attached to the cutting tool at the other end. Boring bars are conventionally formed from a metal material, such as carbon steel. To reduce vibrations of the boring bars, cutting parameters such as speed and depth of cut may be reduced, decreasing the metal removal rate. However, this approach interferes with production output leading to low productivity.
Numerous attempts to eliminate boring bar vibration are known. One method for reducing vibration is using a boring bar fabricated from a stiffer material, such as carbide (e.g., tungsten carbide). However, carbide boring bars are more expensive than conventional steel bars. Furthermore, with carbide boring bars, although chatter and vibration are reduced by the inherently high stiffness of the carbide bar, vibration may still build to an unacceptable level. Additionally, carbide is fairly brittle and a minor impact upon the boring bar during use or setup may inadvertently damage the bar. A carbide boring bar extending between a steel adapter and steel tip portion is disclosed in U.S. Pat. No. 6,935,816 to Lee et al.
Another attempt to reduce vibration in boring bars is by attaching a dynamic vibration absorber mechanism to or within the boring bar. The dynamic vibration absorber may be sized during manufacturing to vibrate at a particular predetermined frequency to cancel vibration of the cantilevered bar. The dynamic vibration absorber may also include various mechanisms for tuning the bar, for particular applications.
A dynamic vibration absorber for use in a tunable boring bar, comprised of a cylindrical mass of a high-density material supported on resilient bushings, is disclosed in U.S. Pat. No. 3,774,730. When optimally tuned, the mass oscillates in response to vibration produced in the boring bar to cancel out vibration. The absorber may be tuned to accommodate the boring bar for the changes in the length of the boring bar and the weight of the cutting tool connected at the end of the bar. Such an adjustment is made by longitudinally urging pressure plates at opposing ends of the cylindrical mass, thereby compressing the rubber bushings against the mass, which alters the force of the rubber supports against the mass. Generally, the process of tuning the boring bar is easier for boring bars having higher natural frequencies where smaller tuning masses can be applied. Therefore, shorter and stiffer bars are typically easier to tune than longer, more flexible bars.
Tunable boring bars are typically formed from materials that can be machined, such as carbon steel, so that the bar can be fitted to accommodate the vibration absorption mechanism. Therefore, tunable boring bars generally are not made from stiffer materials, such as carbide, which cannot be machined through conventional means. In addition to tunable boring bars, some boring bars are designed with internal vibration absorber mechanisms that are not tunable. These anti-vibration bars will be referred to as AVB bars.
For both tunable and AVB bars, the dynamic vibration absorber is configured to cancel or minimize vibration of the bar at the first natural frequency of the bar, referred to hereinafter as the first mode. However, when vibration of the first mode of the boring bar is effectively canceled or minimized, the second natural frequency, referred to hereinafter as the second mode, may become dominant and cause chatter during cutting, even in light duty applications. The above-described tunable boring bars and AVB bars do not address vibration of the second mode or higher order modes.
Therefore, conventional tunable boring bars and AVB bars, as are known in the prior art, may not produce satisfactory performance for boring bars with narrower diameters or longer lengths. This limitation is problematic since, for certain cutting applications, narrow, long-length boring bars are particularly desirable. Therefore, there is a need for a tuned or tunable boring bar that can be optimized to cancel or minimize vibration of the boring bar at both the first mode and subsequent modes of vibration.
A tuned or tunable boring tool including a dynamic vibration absorber for minimizing or canceling vibration of a vibrating boring tool at multiple natural frequencies or modes is provided. The tuned or tunable boring tool includes a boring bar having a distal portion configured to support a tool, a proximal portion configured for attachment to a support structure of a metalworking machine, and a tubular body extending between the proximal portion and the distal portion, having an elongated cavity therein. The boring tool further includes a dynamic vibration absorber inserted within the elongated cavity of the boring bar. The dynamic vibration absorber includes a mass that vibrates in conjunction with vibration of the boring bar. The mass has a proximal end, positioned adjacent to the proximal portion of the boring bar, and a distal end, positioned adjacent to the distal portion of the boring bar. The dynamic vibration absorber further includes at least one proximal support positioned adjacent to and supporting the proximal end of the mass and at least one distal support positioned adjacent to and supporting the distal end of the mass. The at least one proximal support and at least one distal support have different stiffnesses.
According to another aspect of the invention, a method of forming a tuned or tunable boring tool is provided. The method includes the step of providing a boring bar having a distal portion configured to support a tool, a proximal portion configured for attachment to a support structure of a metalworking machine, and a tubular body extending between the proximal portion and the distal portion, having an elongated cavity therein. The method further includes the step of providing a tuned or tunable vibration absorber. The vibration absorber includes a mass that vibrates in conjunction with vibration of the boring bar. The mass has a proximal end, positioned adjacent to the proximal portion of the boring bar, and a distal end, positioned adjacent to the distal portion of the boring bar. The vibration absorber further includes at least one proximal support, which is resilient, positioned adjacent to and supporting the proximal end of the mass, wherein the at least one proximal resilient support has a stiffness, and at least one distal resilient support, which is resilient, positioned adjacent to and supporting the distal end of the mass, wherein the at least one distal support has a stiffness. The stiffness of the proximal support is different from the stiffness of the distal support. The method further includes the steps of: mounting the vibration absorber into the cavity of the boring bar; mounting a cutting tool to the distal end of the boring bar; and securing the proximal end of the boring bar to a mounting structure of a metalworking machine.
Some of the advantages and features of the preferred embodiments of the invention have been summarized hereinabove. These embodiments, along with other potential embodiments of the device, will become apparent to those skilled in the art when referencing the following drawings in conjunction with the detailed descriptions as they relate to the figures.
For purposes of the description hereinafter, spatial orientation terms, if used, shall relate to the referenced embodiment as it is oriented in the accompanying drawing figures or otherwise described in the following detailed description. However, it is to be understood that the embodiments described hereinafter may assume many alternative variations and embodiments. It is also to be understood that the specific devices illustrated in the accompanying drawing figures and described herein are simply exemplary and should not be considered as limiting.
The present invention is directed to a vibration absorber configured for use with a tuned or tunable boring tool. The vibration absorber is a dynamic vibration absorber that oscillates in response to vibration of the boring bar. To facilitate discussion, a boring tool 2, including the vibration absorber and boring bar, as is known in the prior art, will now be described.
With reference to
As discussed herein, use of the boring bar 10 on a workpiece in a metalworking operation will produce vibrations that may deteriorate the surface finish and dimensional tolerance of the workpiece. For this reason, the boring tool 2 is provided with a vibration absorber, such as a tunable dynamic vibration absorber 24, that dampens the vibrations generated in the boring bar 10.
The tunable dynamic vibration absorber 24 is mounted in the central cavity 12 of the body 18. The vibration absorber 24 includes a generally cylindrical mass 50 having a proximal end 57 and a distal end 62. Each end 57,62 has an outwardly facing conical surface 58, 61. A proximal resilient support 65 and a distal resilient support 70 circumscribe the conical surface 58 on the proximal end 57 and the conical surface 61 on the distal end 62, respectively, of the absorber mass 50. The supports 65, 70 may be annular, such as o-rings, or partially annular structures.
Throughout the specification, reference will be made to support 65 and support 70, as well as variation thereof. In all cases it should be understood that each of these is a resilient support formed from a resilient material, such as a natural or synthetic elastomer. A proximal pressure plate 75 and a distal pressure plate 80 are positioned within the central cavity 12 adjacent to the end portions 57, 62 of the absorber mass 50. The proximal pressure plate 75 has an inwardly facing conical surface 77 while the distal pressure plate 80 also has an inwardly facing conical surface 82. Each pressure plate 75,80 surrounds the respective support 65,70 such that the inwardly facing conical surfaces 77,82 of the pressure plates 75, 80 urge each support 65,70 against the respective conical surface 58,61 of the proximal end 57 and the distal end 62 of the absorber mass 50.
Each pressure plate 75, 80 is at least laterally supported within the cavity 12. As illustrated in
The proximal pressure plate 75 is movable within the central cavity 12 along the longitudinal axis X. A positioning member, such as an adjusting screw 85, may be used to adjust the compression of the supports 65,70 against the absorber mass 50. The adjusting screw 85 extends through a bore 90 from the outer surface of the boring bar 10 to contact the proximal pressure plate 75. The adjusting screw 85 is threadably mated with the bore 90 such that the rotation of the adjusting screw 85 at a screw head 87 urges a contact end of the adjusting screw 85 against or away from the proximal pressure plate 75, thereby displacing the proximal pressure plate 75 along the longitudinal axis X to increase or decrease the compression of the supports 65,70. To tune the subject boring bar 10, an operator monitors the vibration of the boring bar 10 and tightens or loosens the adjusting screw 85, thereby adjusting the force of the supports 65,70 against the absorber mass 50. Alternatively, it is also possible to predefine the amount of compression on the supports 65,70 against the absorber mass 50 necessary to minimize vibration under different tool conditions. In this manner, a machine operator may adjust the compressive force of the supports 65,70 to predetermined levels for tuning.
Alternate mechanisms for tuning the dynamic vibration absorber of the boring tool 2 are also known. For example, with reference to
Having generally described the structure and operation of a boring tool 2 and dynamic vibration absorber 24 as is known in the prior art, the dynamic vibration absorber of the present invention will now be described in detail.
With reference to
Pressure plates 75,80 move along the longitudinal axis X to compress the supports 165,170 against the mass 150. As in previously described dynamic absorbers known in the prior art, adjusting the position of the pressure plates 75, 80 adjusts the compression of the supports 165,170 against the mass 150. Adjusting the compression of the supports 165,170 changes the vibration frequency of the mass 150 to cancel or minimize vibration of the first mode of the boring bar 110.
In some embodiments, the mass 150 may be surrounded by various dampening materials to further optimize dampening of the first mode. For example, as illustrated in
Briefly stated, the first mode of vibration for a cantilever, such as a boring bar, is simple wherein the free end of the cantilever essentially oscillates back and forth. This first mode of vibration has the greatest influence upon displacement of the bar and it is this motion that prior art anti-vibration bars have addressed. However, the second mode of vibration may also be significant and the second mode motion is more complex with a stationary node part way along the length of the vibrating bar. The inventor has discovered that by introducing resilient supports 165, 170, each with different stiffnesses, the vibration characteristics of the mass 150 may be altered to reduce or eliminate the displacement of the bar caused by the second mode of vibration which was previously imparted to the bar when the stiffnesses of the resilient supports were equal. Therefore, in addition to canceling or minimizing vibration of the first mode, the supports 165, 170 of the dynamic vibration absorber 124 are configured so that movement of the mass 150 also cancels or minimizes the second mode of the vibrating bar 110. To achieve this the mass 150 and supports 165,170 are configured so that, during vibration, the displacement of the proximal end 157 of the mass 150 is greater than the displacement of the distal end 162 of the mass 150. To obtain this result, the distal support 170 is formed and positioned to restrict motion of the mass 150 more than the proximal support 165.
One means for restricting motion of the distal end 162 of the mass 150 is by making the stiffness of the distal support 170 different from the stiffness of the proximal support 165. Since stiffness of a body is directly proportional to the modulus of elasticity of the body material, this result may be obtained by forming the distal support 170 from a material having a different modulus of elasticity than the material of the proximal support 165. Since stiffness is also related to shape and size, this result may also be obtained by using a proximal support 165 and a distal support 170 with different shapes and/or sizes.
With continued reference to
The stiffness of the supports 165,170 is chosen based on the amount of motion needed so that the mass 150 effectively counteracts or cancels the second mode vibration of the bar 110. In other embodiments, differences in the shape or size of the supports 165,170 may be used to obtain similar results. For example, the distal support 170 may have the shape of a circle while the proximal support 165 may be an oval to provide different stiffnesses.
In use, the vibration absorber 124 is inserted in the cavity 112 of the boring bar 110. The proximal end 116 of the boring bar 110 is mounted to a frame or support. A cutting tool 20 (shown in
In a second mode of vibration, in the region of the mass 150, the bar 110 may experience a relative rocking motion with respect to the proximal end 157 and the distal end 162 of the mass 150. As a result, the motion of the bar 110 is counteracted by the mass 150.
The vibration absorber 124 depicted in
With reference to
With reference to
So far the o-rings 166, 167 have been illustrated as being supported by single beveled surfaces between the pressure plates 75, 80 and the mass 150.
Having generally described the structure of the invented boring bar and dynamic vibration absorber, the performance benefits of a dynamic vibration absorber optimized to cancel or minimize vibration of the second mode will now be discussed. More specifically, the present inventor has recognized that when the primary or first mode of a cantilever beam, such as a boring bar, is effectively dampened by a dynamic vibration absorber, the vibration of the second mode may become more significant or even dominant. Since the total amplitude of vibration of the bar is the summation of the amplitude from several modes, it may also be necessary to address vibration of the bar at the second mode to reduce chatter and improve performance.
This principle is illustrated in
A graphical representation of the FRF or transfer function is illustrated in
The transfer function characterizes the dynamic response of a system in the frequency domain. It is a complex function that can be represented by real and imaginary components, or, alternatively, as amplitude and phase.
The minimum value of the real part of the transfer function (Re[G]min) can be used to predict the dynamic stability of the boring bar during machining. Similarly, the maximum chip width (or depth of cut) for stable cut can be calculated from the equation:
wherein
Ks is the material cutting coefficient, μ is the force orientation factor, and Re[G]min is the value of the negative peak of the real component of the FRF.
By increasing the depth of cut, the metal removal rate can be increased, maximizing productivity. Therefore, it is desirable that the absolute value of Re[G]min be minimized.
The absolute value of Re[G]min may be minimized by adjusting the static stiffness K of the bar. Stiffness is defined as the force required to bend or deform a material a particular amount
The dampening ratio is ζ, which is equal to
In the dampening ratio equation, Δω is the difference in frequency between the frequency at which the maximum and minimum amplitude occur, specifically the difference in frequency between when Re[G]max and Re[G]min occur. The natural frequency of the bar is ωn. As can be seen from the Re[G]min equation, increasing the dampening ratio ζ for a vibrating cantilevered beam reduces the absolute value of the frequency response (Re[G]min). Including materials within the vibrating bar that are capable of absorbing vibration energy, such as the vibration absorbing layer and high viscosity fluid discussed above, reduces the dampening ratio for the bar. In either case, reducing the absolute value of Re[G]min means that the amplitude of vibration of the first mode is effectively addressed. However, when a second order system for a vibrating cantilever beam is considered, the frequency response function includes two minimum values. As described above, the amplitude of the second mode is addressed by allowing the mass 150 of the dynamic vibration absorber 124 to oscillate such that the relative motion between the bar 110 and the mass 150 in the region of the mass 150 is a rocking motion.
With reference to
Example 1 is a standard tunable boring bar, as is known in the prior art and as depicted in
Example 2 is a tunable boring bar that exemplifies features of the present disclosure. Specifically, the bar includes three o-rings. Two of the o-rings are positioned near the distal end of the mass. One o-ring is positioned at the proximal end of the mass. Each o-ring is the same stiffness. Example 2 is similar to the boring bar depicted in
Example 3 is another tunable boring bar that exemplifies features of the present disclosure. Specifically, the bar includes two o-rings, each with a different stiffness. The o-ring on the distal end of the mass is 2.09 times stiffer than the o-ring on the proximal end of the mass. Example 3 is similar to the boring bar depicted in
As shown in
While several embodiments of the invention are shown in the accompanying figures and described hereinabove in detail, other embodiments will be apparent to, and readily made by, those skilled in the art without departing from the scope and spirit of the invention. For example, it is to be understood that this disclosure contemplates that, to the extent possible, one or more features of any embodiment can be combined with one or more features of any other embodiment. Accordingly, the foregoing description is intended to be illustrative rather than restrictive.
Number | Name | Date | Kind |
---|---|---|---|
2051954 | Leland | Aug 1936 | A |
2591115 | Austin | Apr 1952 | A |
3164041 | Carlstedt | Jan 1965 | A |
3207009 | Carlstedt | Sep 1965 | A |
3207014 | Carlstedt | Sep 1965 | A |
3230833 | Shurtliff | Jan 1966 | A |
3242791 | Smith | Mar 1966 | A |
3447402 | Ray | Jun 1969 | A |
3559512 | Aggarwal | Feb 1971 | A |
3582226 | Shurtliff | Jun 1971 | A |
3598498 | Holmen | Aug 1971 | A |
3643546 | Richter et al. | Feb 1972 | A |
3774730 | Maddux | Nov 1973 | A |
3838936 | Andreassen et al. | Oct 1974 | A |
4553884 | Fitzgerald et al. | Nov 1985 | A |
4817003 | Nagase et al. | Mar 1989 | A |
5413318 | Andreassen | May 1995 | A |
5518347 | Cobb, Jr. | May 1996 | A |
5700116 | Cobb, Jr. | Dec 1997 | A |
5810528 | O'Connor et al. | Sep 1998 | A |
5924670 | Bailey | Jul 1999 | A |
6443673 | Etling et al. | Sep 2002 | B1 |
6619165 | Perkowski | Sep 2003 | B2 |
6935816 | Lee et al. | Aug 2005 | B2 |
7234379 | Claesson | Jun 2007 | B2 |
7661912 | Onozuka | Feb 2010 | B2 |
8308404 | Ostermann | Nov 2012 | B2 |
8734070 | De Souza Filho | May 2014 | B2 |
20030147707 | Perkowski | Aug 2003 | A1 |
20060275090 | Onozuka | Dec 2006 | A1 |
20090257838 | Ostermann | Oct 2009 | A1 |
20100096228 | Digernes et al. | Apr 2010 | A1 |
20120003055 | Sasaki | Jan 2012 | A1 |
Number | Date | Country |
---|---|---|
103433762 | Dec 2013 | CN |
1029675 | May 1966 | GB |
1179217 | Jan 1970 | GB |
1306157 | Feb 1973 | GB |
2322684 | Sep 1998 | GB |
2000308941 | Nov 2000 | JP |
2005186240 | Jul 2005 | JP |
2011011276 | Jan 2011 | JP |
663493 | May 1979 | SU |
1093435 | May 1984 | SU |
WO 2015082361 | Jun 2015 | WO |
WO 2015082362 | Jun 2015 | WO |
Number | Date | Country | |
---|---|---|---|
20150375305 A1 | Dec 2015 | US |