The present disclosure relates to the field of devices for applying tension to a wire or string, and more specifically to devices that keep such tension at or near constant as the wire stretches or contracts over a limited range.
Various products and applications benefit from holding a wire or string at a near-constant, predictable tension over time and in a variety of environmental conditions. Notably, stringed musical instruments create music by vibrating strings held at tension. If the string is at the correct tension for the given instrument, it will vibrate at a desired frequency corresponding to the desired note. However, musical strings tend to stretch or contract over time and/or due to environmental factors such as temperature, humidity or the like. Such stretching or contracting typically results in the tension in the string changing, and the string thus vibrating at a different frequency than the desired frequency. This can result in the string going out of tune-emitting a note that is aurally different than the desired note. Typical stringed musical instruments tend to go out of tune fairly quickly, and musicians often find themselves spending substantial time tuning their instruments, even in the midst of performances.
The appearance of a musician's instrument looks is often seen as an expression of the artist, and thus musicians tend to desire that their instrument's componentry be non-obtrusive so as not to dominate the appearance. Also, certain instruments, particularly acoustic instruments, can be sensitive to componentry placed in certain portions of the instrument. Further, componentry should avoid possibly interfering with a musician during play.
There is a need in the art for a method and apparatus for mounting a string of a stringed musical instrument in a manner so that the string remains at a near-constant tension even if the string stretches or contracts over time and/or due to environmental factors.
There is also a need in the art for such a method and apparatus that is relatively small and easy to install in certain stringed instruments without substantially altering sound of the instrument, altering its appearance, or interfering with playability.
In accordance with one embodiment, the present invention provides a constant tension device. The device includes a primary spring attached to a carrier so as to apply a primary spring force. The primary spring force applied to the carrier changes in accordance with a first function as the carrier moves relative to the primary spring along an axis. A wire or string is attached to the carrier and extends along the axis so that an axial force applied to the carrier is applied to the wire or string. A secondary spring has a first end attached to the carrier so as to apply a secondary spring force to the carrier. The secondary spring force is directed transverse to the axis and has an axial component that is applied to the carrier in a direction along the axis. The secondary spring force is configured so that the axial component of the secondary spring force varies in accordance with a second function as the carrier moves relative to the primary spring along the axis. A net axial force applied to the carrier comprises the sum of the primary spring force and the axial component of the secondary spring force.
In one such embodiment a stringed musical instrument comprises such a constant tension device, and the wire or string is a musical string having a first end attached to the carrier and a second end fixed relative to the carrier. The secondary spring is chosen so that as the carrier moves longitudinally along the axis the axial component of the secondary spring force changes in accordance with the secondary spring rate function, and the secondary spring rate function approximates and opposes the primary spring rate function so that the net axial force applied to the carrier stays within about 1.2% of a preferred tension per each millimeter of longitudinal movement. In another embodiment the secondary spring is chosen so that as the carrier moves longitudinally along the axis the axial component of the secondary spring force has a magnitude approximating the change in primary spring force applied to the carrier so that the net axial force applied to the carrier stays within about 0.6% of a preferred tension per each millimeter of longitudinal movement.
In another embodiment a second end of the secondary spring is fixed relative to the carrier, and a secondary spring angle is defined between a line normal to the axis and a line of action of the secondary spring. The carrier has an operational range defined as a distance along the axis between opposing first and second axial positions, the carrier being between the first and second axial positions. Some embodiments additionally comprise a first stop at the first axial position of the operational range, the first stop preventing the carrier from moving in a first direction past the first axial position. Some such embodiments additionally comprise a second stop at the second axial position of the operational range, the second stop preventing the carrier from moving in a second direction past the second axial position.
In other embodiments, the operational range corresponds to a change in the secondary spring angle up to 10°.
In one embodiment, the secondary spring force is directed in a direction normal to the axis at a point within the operational range. In additional embodiments the operational range is defined within a range in which the secondary spring angle is between ±5°.
In some embodiments a guitar includes such a constant tension device mounted to one of a headstock or a bridge of the guitar. A guitar string has a first end attached to the carrier and a second end attached to the other of the headstock and the bridge of the guitar. A tension in the guitar string is equal to the axial force applied to the carrier.
In some such embodiments, the carrier is movable to a position at which the guitar string is held at a perfect tune tension, and as the guitar string elongates the axial force applied to the carrier by the primary spring decreases and the axial component of force applied to the carrier by the secondary spring increases in the direction the carrier moves as the guitar string elongates.
In yet another embodiment of a guitar, a second end of the secondary spring is fixed relative to the carrier, and a secondary spring angle is defined between a line normal to the axis and a line of action of the secondary spring. The carrier has an operational range defined as a distance along the axis corresponding to a change in the secondary spring angle of up to 10°. The primary spring has a primary spring rate and the secondary spring has an axial spring rate component that opposes the primary spring rate so that a change in tension in the guitar string within the operational range corresponds to a range of 10 cents or less of frequency.
In additional embodiments the secondary spring comprises a pair of springs acting on opposite sides of the carrier, second ends of the secondary springs being fixed relative to the carrier. In some such embodiments the secondary springs can be rigidly connected to the carrier and to a fixed secondary spring mount.
In some embodiments the secondary springs comprise a flat sheet deflected in compression. In additional embodiments, the flat sheet is rigidly connected to the connector and a fixed secondary spring mount. In further embodiments, a plurality of the flat sheets are spaced apart from one another.
In still further embodiments, the pair of springs comprise deflected bars.
Some such embodiments additionally comprise a connector between each deflected bar and the carrier. In some embodiments the connector comprises an elongate bar. In other embodiments the connector comprises a ball bearing.
In accordance with yet another embodiment, a constant tension device is provided. The device includes a carrier configured to be movable along an axis and a wire or string attached to the carrier and extending along the axis so that an axial force applied to the carrier is communicated to the wire or string. A target tension is defined as a desired tension for the wire or spring. A spring has a first end attached to the carrier and a second end attached to a spring mount that is fixed relative to the carrier so that the spring applies a spring force to the carrier. A spring angle is defined between a line normal to the axis and a line of action of the spring. The spring force is directed transverse to the axis and has an axial force component and an axial spring rate that are communicated to the carrier in a direction along the axis. The spring is selected so that the axial force component equals the target tension when the spring angle is a zero rate angle at which the axial spring rate of the spring is zero.
In another embodiment, when the spring angle is greater than the zero rate angle the axial spring rate is one of negative or positive, and when the spring angle is less than the zero rate angle the axial spring rate is the other of negative or positive.
The following description presents embodiments illustrating inventive aspects that are employed in a plurality of embodiments. It is to be understood that embodiments may exist that are not explicitly discussed herein, but which may employ one or more of the principles described herein. Also, these principles are primarily discussed in the context of stringed musical instruments. However, it is to be understood that the principles described herein can have other applications such as sporting goods, industrial and/or architectural applications in which it may be desired to apply a near-constant force to an item that may move over an operational range and/or employ spring arrangements that can exhibit positive spring rates.
This disclosure describes embodiments of a device that can apply a near-constant tension to a string, wire or the like even as that string, wire or the like changes in length over a range of distance. Notably, Applicant's U.S. Pat. No. 7,855,440, which is incorporated herein by reference in its entirety, teaches similar but distinct principles for achieving a near-constant tension in a wire or string as the wire or string expands and/or contracts.
With initial reference to
Over time, the wire 32 may stretch or contract.
With reference next to
At relatively low angles of α, such as from about 0-20°, more preferably 0-15°, still more preferably 0-10° and most preferably 0-5° , sina is a substantially linear function. As noted above, −kx is a totally linear function, in which the primary spring rate k is a constant, and the function is negative. Thus, over such relatively low angles of α, a secondary spring force Fs can be chosen so that over an operating range of deflection (x), the value of a function k(s)x is approximated by Fs(sina), and a secondary axial spring rate k(s) changes with a and the spring rate function is positive. As such, over the operating range shown in
Table 1 below presents a spreadsheet that demonstrates a real-life scenario of performance of one embodiment having structure as depicted in
In the scenario depicted in Table 1, the tension Fp initially in primary spring (Spring 1)—and thus the preferred tension Tp in the wire—is 10 lb., and the initial length L1 of the primary spring 40 is 1.4 in. The spreadsheet simulates an application such as a guitar in which the springs apply the tension to a guitar string, and over time the guitar string stretches (here over a range of travel of 0.0625 in.). The spreadsheet shows the state of the springs and tension in the wire/guitar string at various points along the 0.0625 range of travel.
As shown in
In the scenario depicted in Table 1, over a string stretch of 0.0625 in., secondary spring 60 (Spring 2) rotates almost 12 degrees, and the total tension in the wire (Tw) varies from the preferred (initial) tension Tp by at most about 0.4%. Such a variance would result in minimal, if any, audible changes in guitar string tune.
It is to be understood that various lengths, spring rates, etc. can be selected for the primary and secondary springs in order to vary specific results, but the principle remains that the secondary spring is chosen to approximate the linear change in tension applied by the primary spring as the primary spring moves linearly and the secondary spring (or at least the line of action of the secondary spring) changes such that the rate of change of the axially-directed component force approximately negates the rate of change of the primary spring force.
With reference next to
In the embodiment illustrated in
In Table 2 below, an example is presented in which the springs 60 are initially arranged so that α=60°, and the at-rest length of the springs is 2.0 in. The example spring has a spring rate k of 90 lb./in. and the width w between the fixed spring mounts 68 is 2.0 in., so that each fixed spring mount is 1.0 in. from the axis. Table 2 shows how various aspects of this arrangement change as the carrier 50 moves linearly along the axis as demonstrated in
With specific reference next to
With reference next to
With continued reference to
More specifically, in the embodiment depicted in
In view of Table 3, over a range of α=−4° to 4°, the net axial spring rate ka averages about −1.15 lb./in. Over a range of a range of α=−5° to 4°, the net axial spring rate averages about −1.37 lb./in. Over a range of α=−5° to 5°, the net axial spring rate averages about −1.69 lb./in.
With reference next to
With reference next to
As shown in
In some embodiments the curved surfaces 96, 98 can be arcuate about a fixed radius of curvature. In other embodiments the curved surfaces can have a varying radius of curvature along their lengths in order to generate a camming effect. The camming affect can be selected so as to help the associated secondary spring better approximate the linear −kx function of the primary spring by, for example, using the camming surface to create a lever arm so as to create a mechanical advantage compensating for incremental variations in the axial spring rate at particular values of α.
The carrier 50 employed in this or others of the embodiments disclosed herein can be supported in any desired manner. In some preferred embodiments it is suspended above a surface, held in place by the tension supplied by the primary spring and borne by the attached wire or string. In other embodiments it slides over the surface. In still other embodiments it is supported on the surface by a linear bearing.
In a preferred embodiment, and with reference next to
With additional reference to
In some guitar-based embodiments a user may tension the string via the tuning peg 106 sufficient so that the carrier 50 is immediately adjacent the second stop 122 (on the string side of the carrier). As such, if the user desires to “bend” notes during play, the carrier 50 will engage the second stop, preventing the carrier 50 from moving further to compensate for the user pulling on the string 32, and thus allowing the user to increase the tension in the string, resulting in a “bent” note.
With reference next to
With reference next to
With reference next to
In the embodiment illustrated in
The frame width of 0.66 in. and the selected spring rate in the embodiment of
In the embodiments discussed above in connection with
With reference next to
With additional reference to
As noted above, embodiments of tension devices having features as described herein can be incorporated into stringed instruments such as guitars. Embodiments can function as, and be placed as, the bridge of a guitar or other stringed instrument. In other embodiments, constant-tension devices such as discussed herein can be placed on the headstock of a guitar (electric or acoustic), violin, cello or other stringed instrument, thus keeping the components spaced from the body of the instrument. Notably, suitable stringed instruments for incorporating tension devices as discussed herein also include pianos, mandolins, steel guitars, and others.
The “cent” is a logarithmic unit of measure used for musical intervals. More specifically, one cent is 1/100 of the difference in frequency from one note to the next in the 12-note chromatic scale. In this scale there are twelve notes in each octave, and each octave doubles the frequency so that 1200 cents doubles a frequency. As such, one cent is precisely equal to 2^( 1/1200) times a given frequency. Since frequency is proportional to the square root of tension, one cent is also equal to a tension change by 2^(( 1/1200)*2)=2^( 1/600) from one tension value to a tension value one cent away. 2^( 1/600)−1= 1/865 (0.001156). Thus, every change in tension by 1/865 (0.001156) equates to one cent different in frequency. Similarly, every change in tension by 1/86 (0.01156) equates to a ten cent difference in frequency, and every change in tension by 1/173 (0.00578) equates to a five cent difference in frequency.
In one embodiment, the operation range of the tension device configured to be used with a stringed musical instrument is selected to correspond to a change in frequency of ten cents or less per 1 mm of travel. In another embodiment, the operation range of tension device is selected to correspond to a change in frequency of five cents or less per 1 mm of travel. The actual length of the operation range can vary, but in some embodiments is up to about 1 mm of travel. In other embodiments, the operation range is up to about 1-1.5 mm of travel. In still further embodiments, the operation range is up to about 2 mm of travel.
With reference again to
To determine a maximum desired change in tension to define a desired operational range of, for example, 10 cents, a string tension is multiplied by the value of 10 cents change infrequency. For example, for a guitar string designed for a tension of about 10 pounds, a change in tension corresponding to ten cents of frequency is calculated as 10 lb.*(01156)=0.12 lb.
It is to be understood that components of any of the embodiments discussed above, and also including embodiments not explicitly discussed above, but which include features combined to form other embodiments employing principles discussed herein, can be selected so as to construct a tension device having an operating range suitable for stringed musical instruments.
The embodiments discussed above have disclosed structures with substantial specificity. This has provided a good context for disclosing and discussing inventive subject matter. However, it is to be understood that other embodiments may employ different specific structural shapes and interactions.
Although inventive subject matter has been disclosed in the context of certain preferred or illustrated embodiments and examples, it will be understood by those skilled in the art that the inventive subject matter extends beyond the specifically disclosed embodiments to other alternative embodiments and/or uses of the invention and obvious modifications and equivalents thereof. In addition, while a number of variations of the disclosed embodiments have been shown and described in detail, other modifications, which are within the scope of the inventive subject matter, will be readily apparent to those of skill in the art based upon this disclosure. It is also contemplated that various combinations or subcombinations of the specific features and aspects of the disclosed embodiments may be made and still fall within the scope of the inventive subject matter. Accordingly, it should be understood that various features and aspects of the disclosed embodiments can be combined with or substituted for one another in order to form varying modes of the disclosed inventive subject matter. Thus, it is intended that the scope of the inventive subject matter herein disclosed should not be limited by the particular disclosed embodiments described above, but should be determined only by a fair reading of the claims that follow.
This application is a continuation of U.S. application Ser. No. 14/476,619, filed Sep. 3, 2014, which is based on and claims the benefit of U.S. Application Nos. 61/873,295, which was filed on Sep. 3, 2013 and 61/875,593, which was filed on Sep. 9, 2013. All of these priority applications are hereby incorporated by reference in their entirety.
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Number | Date | Country | |
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20160225352 A1 | Aug 2016 | US |
Number | Date | Country | |
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Number | Date | Country | |
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Parent | 14476619 | Sep 2014 | US |
Child | 15092524 | US |