1. Field of the Invention
The present invention relates generally to stringed musical instruments, and more particularly to stringed instruments that maintain relative tune during string tension adjustments.
2. Description of the Related Art
Stringed musical instruments create music when strings of the instrument vibrate at wave frequencies corresponding to desired musical notes. Such strings typically are held at a relatively high tension, and the musical note emitted by the string is a function of the vibration frequency, length, tension, material and density of the string. The natural frequency of the vibrating string is described by the following wave equation:
f=(½L)(T/d)1/2
In this equation, f is the natural frequency of vibration, T is the tension on the string, d is the density of the string (in mass per unit length), and L is the length of the relevant portion of the string. Stringed musical instruments typically include a plurality of musical strings arranged generally parallel to one another. Preferably, the strings are configured to emit different notes when caused to vibrate. During use, the musician may vary the frequency of the string by pressing down on the string at a certain point in order to vary the effective length of the string, thus correspondingly changing the natural vibration frequency. The emitted musical note changes with the change in vibration frequency. As indicated by the equation, the vibration frequency is inversely proportional to the length of the vibrating portion of the string; thus, as the musician effectively shortens the string, the frequency of vibration increases, and thus the pitch of the emitted musical note correspondingly increases.
Each string of a stringed musical instrument typically is tensioned in relative tune to the other strings in order to facilitate predictable playing of chords and scales. This state, commonly referred to as being “in tune,” means that the natural frequency of the strings vary from one another by a predetermined interval. For example, conventional tuning of a guitar is such that the string at the lowest frequency is tuned to E, and subsequent strings are tuned to A, D, G, B and E. As such, each string is five half steps (the smallest frequency individually used in the standard 12-tone scale) higher than the previous string, except the G to B interval which is 4 steps. Adding all of the intervals, there are 24 half steps, which is two octaves (12 half steps being one octave).
An octave is the musical interval at which the frequency of the upper note is exactly twice that of the lower note. The frequency of vibration of the low E string and the high E string of a guitar are such that the emitted musical notes are two octaves away from each other. As indicated by the equation, a frequency may be doubled by halving the length of a musical string when the tension and density of the string are held constant. Different approaches are used, depending on which factors are desired and kept constant. For example, in order for the low E string and the high E string to be two octaves apart in a guitar in which the string lengths are equal, the tension on the high E string must be 16 times that of the low E string, or the density of the high E string must be 1/16 that of the low E string, or a combination of tension and density differences must create a factor of 16 so that when the square root of the term T/d is taken the result is 4, which indicates quadrupling of frequency in accordance with a two octave interval.
In conventional musical instruments, such as guitars, the tension of the strings relative to one another does not vary dramatically, mostly because of practical concerns. For example, too much tension may cause a string to be especially subject to breakage; too little tension may result in a string being so slack that it may contact the instrument body or interfere with other strings when vibrating during play. Accordingly, typically the density (mass per unit length) of the strings varies widely between strings in order to obtain a set of strings having the desired natural frequencies. For guitars, strings are sold in sets of six, with each string being weighted to produce its particular desired frequency within desired tension ranges.
Typically, guitar strings are fixed to the guitar at one end and attached to rotatable tuning knobs at the other end so that each string may be tightened with a suitable tension. Each string typically has its own knob (also called a tuning key). Stringing a guitar involves affixing one end of each guitar string to a mount on the body of the guitar, aligning the string in its place across the neck, and tightening and tuning the string by connecting it to its corresponding tuning key. Such stringing can be a time-consuming process.
Tuning a guitar is performed by turning each knob so as to tighten or slacken the string until the desired frequency is obtained. Tuning stringed instruments such as guitars can be time-consuming and difficult. Typically, a guitarist first correctly tunes the lower E string, and then progressively tunes the adjacent strings. For example, the E string is shortened (by pushing it against the guitar neck) to a position that produces an A note, and the adjacent A string is tuned by ear to match the A note as played on the E string. The D string adjacent to the A string is similarly tuned relative to the A string, as are the rest of the G, B and E strings progressively tuned relative to the adjacent strings. Such tuning by ear is typically very difficult for beginners and for those without a good sense of musical tones. Also, such tuning requires a reference note to start, and such reference note is usually provided by a different instrument, and it has a different timbre than does a guitar, thus further complicating tuning.
A piano typically contains about 220 strings. Typically, piano tuning is accomplished in much the same manner as a guitar tuning, and all 220 strings are adjusted relative to one another.
On occasion, a guitarist may desire to change the pitch of his instrument in order to play a particular song. This can be accomplished by using a device known as a capo, which wraps around the neck of the guitar and can effectively shorten the length of all of the guitar strings, thus increasing the frequency and correspondingly increasing the emitted pitch of all of the strings, while maintaining the strings in relative tune. However, this operation relatively shortens the neck of the guitar, which may be undesired. Also, the guitarist must change the position of his fingers along the neck to play chords and such. Thus, it can be desired to completely retune the guitar to a higher pitch. This typically necessitates retuning the low E string, then the A, D and so on, which is difficult and time consuming. It is thus impractical to retune a typical guitar during a playing session.
Accordingly, there is a need in the art for a stringed musical instrument that is relatively quick and easy to string. There is also a need for a stringed musical instrument in which the strings can be easily placed into relative tune and maintained in relative tune. Additionally, there is a need for a stringed musical instrument in which the strings can be easily placed into absolute tune and maintained in such absolute tune over time. Further, there is a need in the art for a musical instrument in which the emitted pitch of the strings can be easily changed while generally maintaining a relative tune between the strings.
In accordance with one embodiment, a stringed musical instrument is provided, comprising a musical string and a string mounting system. The musical string comprises a first elongate segment and a second elongate segment, the first and second segments being connected to one another. The mounting system is configured so that harmonic vibrations in the first segment are substantially isolated from the second segment.
In another embodiment, the mounting system is configured to maintain the first and second segments at substantially the same string tension. In yet another embodiment, the mounting system comprises a pivot, and the musical string is at least partially wrapped about the pivot so that a direction of the string changes at the pivot. In one embodiment, string tension is communicated across the pivot so that portions of the musical string on either side of the pivot are at substantially the same tension.
In further embodiments, a first end of the string is attached to an anchor and a second end of the string is attached to a tensioner, and the tensioner is adapted to change the tension in the string. In a still further embodiment, the musical string is arranged in a continuous loop.
In yet another embodiment, the mounting system and vibration separators are configured to maintain the first and second segments at substantially the same string tension. In still a further embodiment, the first and second segments have a different mass per unit length. In still another embodiment, the string mounting system is configured to maintain the tension of the first string segment at a substantially constant ratio to the tension of the second string segment.
In accordance with still another embodiment, the present invention provides a stringed musical instrument. The instrument comprises a plurality of musical string segments, each string segment having a harmonic frequency corresponding to a string tension and a string length. Vibration of the string segment at the harmonic frequency emits sound at a corresponding musical note, and the plurality of string segments are tuned so that each of the segments emits a different musical note in accordance with a relative tuning pattern. A string mounting system is configured to hold each string segment at a desired tension. A string tension adjustment system is configured to simultaneously change the tension of each of the plurality of string segments in a manner so that the emitted musical notes of the string segments change with the changing tension, but the relative tuning pattern of the notes emitted by the respective string segments remains substantially the same.
In another embodiment, the tension adjustment system is configured so that actuation of the adjustment system changes the tension in one of the segments to a greater degree than in another of the segments.
In accordance with a still further embodiment of the invention, a musical string system is provided, comprising a plurality of string segments joined end-to-end so that each of the string segments is at substantially the same tension. The system is configured so that each string segment has a different harmonic frequency at the tension.
In accordance with yet another embodiment, a stringed musical instrument is provided. The instrument comprises a composite string and a string mounting system. The composite string comprises a first elongate segment and a second elongate segment that are joined end-to-end. The second segment is more pliable in bending than the first segment. The string mounting system has a pivot member. The second segment is at least partially wrapped about the pivot member so that the direction of the composite string changes at the pivot.
In another embodiment a vibration separator defines a playing zone and a mount zone, and string vibrations are isolated by the vibration separator between the playing zone and mount zone. In a further embodiment, the pivot member is disposed in the mount zone. In yet a further embodiment, the first segment extends through the playing zone, and the second segment is disposed in the mount zone.
In one embodiment, the pivot member comprises a tuning knob. In another embodiment, the pivot member comprises a pulley. In a further embodiment, substantially no tension in the composite string is applied to bending the second segment about the pulley.
In yet another embodiment, the first and second segments are selectively detachable from one another. In other embodiments, the second segment has a width and a thickness, and the width is greater than the thickness such as in a belt. In still other embodiments, the second segment comprises a plurality of filaments.
In accordance with still a further embodiment, the present invention provides a stringed musical instrument comprising a composite string and a string mounting system. The composite string comprises a plurality of musical string segments and a plurality of bending string segments. A bending segment is interposed between adjacent musical segments. The string mounting system has a plurality of pivots. The composite string is at least partially wrapped about the pivots so that a direction of the composite string changes at each pivot. The mounting system is configured so that the bending segments engage the pivots and the musical segments do not engage the pivots. Each musical string segment has a harmonic frequency corresponding to a string tension and a string length so that vibration of the musical string segment at the harmonic frequency emits sound at a corresponding musical note. Each bending segment is more pliable in bending than the adjacent musical segments. The string mounting system is configured to hold each string segment at a desired tension so that the plurality of musical string segments are tuned so that each of the musical segments emits a different musical note in accordance with a relative tuning pattern when the composite string is held at a tension. A string tension adjustment system is configured to simultaneously change the tension of each of the plurality of string segments in a manner so that the emitted musical notes of the musical string segments change with the changing tension, but the relative tuning pattern of the notes emitted by the respective musical string segments remains substantially the same.
a schematically illustrates a musical string mounting arrangement in accordance with yet another embodiment.
a shows an embodiment of an irising tension adjustment pulley.
b is a cross section of the embodiment of
a-c illustrate yet another embodiment of a string mounting system having a structure for fine tuning strings, shown in different arrangements.
The following description presents embodiments illustrating aspects of the present invention. It is to be understood that various types of musical instruments can be constructed using aspects and principles as described herein, and embodiments are not to be limited to the illustrated and/or specifically-discussed examples, but may selectively employ various aspects and/or principles disclosed in this application.
With first reference to
In the illustrated embodiment, the string is divided into six generally parallel segments 40a-f between rotatable pulleys 34. Preferably, the pulleys 34 are each adapted to rotate about an axis 42, and thus evenly distribute tension throughout the entire string 32. As such, each of the segments 40a-f is at substantially the same tension. Further, the pulleys 34 preferably isolate vibrations in each segment from other segments. Preferably the segments 40a-f are substantially the same length. Since the length and tension are substantially the same, and since the segments are comprised of a single string 32 which, in the illustrated embodiment, has a substantially constant density, the frequency of vibration of each string segment 40a-f is substantially the same.
In additional embodiments, the frequency of vibration of the respective segments can be varied by making certain adjustments. For example, the position of the pulleys 34 can be arranged such that the length of different segments 40a-f varies, thus resulting in different frequencies. Additionally, in additional illustrated embodiments, string segments may have different density such as, for example, by adding a winding of additional musical string about the respective string segment. In one embodiment, each segment 40a-f of the continuous string 32 is treated and/or modified to have a different density. As such, even though each of the string segments is under the same tension, each vibrates at a different frequency because of the difference in density and/or other treatment. It is to be understood that such densities can be customized as desired by the musician. Thus, the embodiment of
In the embodiment illustrated in
Suitable tension communicating pivots may include rotating pulleys, as in the illustrated embodiment, but may also include other structures such as a ball bearing, wheel, gear, and/or a peg or bar having a low friction surface such as a polished surface or a Teflon coating. It is also to be understood that, in certain circumstances, a pivot structure, at which a string is partially wrapped to change the direction of the string, may be specifically adapted not to communicate a tension thereacross. For example, certain surface coatings or treatments on a peg, bar or the like may increase friction so as to prevent or resist movement of a string over the surface of the pivot, and thus prevent communication of tension across the pivot. However, for purposes of this specification, reference to a “pivot” refers to a tension communicating pivot unless specifically described as otherwise.
With reference next to
In the illustrated embodiment, a pair of vibration separator portions 70 are provided. Each vibration separator portion 70 comprises a separator mount 72 on which a separator body 74 is rotatably mounted. The illustrated separator bodies 74 comprise generally cylindrical rollers, each having a shaped groove 76 or notch that acts as a saddle to hold the string 52 in a desired alignment. The separators 70 are adapted to communicate tension thereacross, but to substantially isolate vibrations from crossing the separators 70.
With continued reference to
With reference also to
With reference next to
With particular reference next to
Although the embodiment illustrated in
With reference next to
In the embodiment illustrated in
For example, with reference next to
Preferably, the density and/or other properties of adjoining string segments is chosen so as to accommodate a desired relative tune between adjacent string portions. For example, in the embodiment illustrated in
In the embodiment just discussed, all of the string portions 172a-f are in relative tune to one another, regardless of the overall pitch of the strings. As discussed above, the first, or bass, string of a guitar typically is tuned to E, and the rest of the strings are tuned relative to the first string. Such can be the case in the illustrated embodiment. If the string is tightened so that the first string portion 172a emits an E, then all of the strings portions 172a-f are in relative tune (and conventional tune) to the first string portion 172a, and thus all string portions of the guitar are tuned quickly and easily by tuning only one of the portions. If a musician wishes to change the pitch of the guitar, the musician may simply increase the tension of the composite musical string 142. As tension increases, all of the string portions 172a-f simultaneously increase in tension, and thus emit a higher musical note. However, the string portions will remain in relative tune, with the same number of half steps between notes emitted by the string portions 172a-f. Thus, to increase the pitch of his guitar, the musician simply tightens the tension on the string 142, simultaneously increasing the pitch of the strings, yet maintaining the instrument in relative tune.
The embodiment discussed above in connection with
With reference next to
In the illustrated embodiment, a first one of the pulleys 202 is linearly movable. More specifically, preferably an axis 204 of the first pulley 202 is mounted on a track or the like so that the pulley 202 can be selectively linearly moved. When the pulley 202 is moved outwardly, away from the playing zone 194, the tension in the composite string 190 is increased, and vice versa.
With additional reference to
It is to be understood that other suitable structures may be employed for linearly moving the pulley axle 204. For example, in another embodiment, a rack and pinion-type gearing arrangement may be employed. Further, it is contemplated that other structures, including structures that may employ ratcheting or the like, may be suitably used.
With reference next to
The composite string 252 is routed through an array 258 of rotatable pulleys 260 that function to maintain a substantially uniform tension distributed throughout the composite string 252. Each pulley 260 preferably rotates about an axis 262. A first set 264 and a second set 266 of vibration separators are provided to define a playing zone 270 that is vibrationally separated from first and second mounting zones 272, 274. In the illustrated embodiment, each of the vibration separators 266 comprises a substantially cylindrical body 276 that is adapted to rotate about a generally vertical axis 278. It is contemplated, however, that other structures may be used as desired for vibration separators. Additionally, the illustrated string mounting system 250 includes six string portions 280a-f in the playing zone 270, and is thus especially suitable for use on a guitar as in the embodiment of
In the embodiment illustrated in
Preferably, the tension adjustment pulley 284 provides a macro, or rough, tuning adjustment to allow a musician to quickly tune the string system 250 at or very near a desired tuning pitch. In the illustrated embodiment, a fine tuning member 286 is also provided. The illustrated fine tuning member 286 comprises a rotatable pulley that engages the composite string 252, and which is linearly and incrementally movable into and out of engagement with the string 252 so as to selectively deflect the string 252, thus increasing or decreasing tension in the string 252.
Preferably, the fine adjustment pulley 286 is smaller than the macro adjustment pulley 284, and generally is less engaged with the string 252 than is the macro adjustment pulley 284. For example, in the illustrated embodiment the string 252 is wound about 180 degrees of the macro adjustment pulley 284, but the fine tuning adjustment pulley 286 makes less contact with the musical string 252. As such, linear movement of the fine tuning adjustment pulley 286 has less of an effect on string tension than does the same amount of linear movement of the macro adjustment pulley 284. Accordingly, after a rough tuning has been achieved a musician may use the fine tuning pulley 286 to dial in a perfect tune of the instrument more easily than can be accomplished with the macro adjustment pulley 284. Of course, in additional embodiments, only a single adjustment pulley may be employed.
When low-quality or even typical-quality musical strings are employed, it is anticipated that there will be significant manufacturing variations in the density of string segments. For example, the density of a string segment may not be tightly controlled during manufacturing, resulting in variations in the actual vibration frequency of the string at a specified tension. Thus, string segments may not emit the exact tone anticipated at a specified string tension and length. Potentially, due to such variations, the string segments may not be in a desired relative tune when all are held at the same tension; however, they likely will be quite close to relative tune.
With continued reference to
Movable vibration separators may employ adjustment structure similar to the device discussed above in connection with
In another embodiment, the linearly movable pulley 284 is connected to a spring member so that the pulley is biased toward tightening the string 252 (away from the playing zone 270 in the arrangement illustrated in
Applicant has noted that a relatively small “stretch” of a musical string on a typical guitar may cause reduced string tension that results in the string segment going out of tune. For example, elongation of a musical string even by less than ⅛ inch may cause an audible change in its tone. Thus, preferably the spring is chosen to exert a relatively constant force over a displacement range of about 1/8 inch. A relatively constant force includes a range of forces over which there is no audible tone change in the associated string. Thus, in this embodiment, once the string is in tune, it will stay in tune even if it stretches a small amount. Also, this embodiment enables automatic tune of the instrument. For example, once the string 252 is tightened sufficient to engage the spring within the range of constant force, the spring will ensure correct string tension.
In another embodiment, the second end of the spring is attached to an adjustment member, so that by actuating the adjustment member, the linear displacement of the spring can be varied significantly and, thus, the force/tension that the spring exerts on the string can be adjusted by adjusting the spring displacement.
The principle discussed above can also be employed in connection with other embodiments. For example, each individual string of a multi-string musical instrument could include a spring-loaded string mount. Also, a first end of a multi-segment musical string could be attached to a spring-loaded string mount, or both ends of such a string could be attached to a spring-loaded string mount.
With reference next to
In the illustrated embodiment, each of the pulleys 260, 284 comprises an outer periphery having teeth 290. The teeth 290 preferably are arranged so as to not interfere with the string 252 on the pulley 260, 284. A latch 292 is provided adjacent each pulley, and is adapted to selectively engage the teeth 290 so as to prevent the pulley 260, 284 from rotating. Preferably, the latch 292 is spring loaded so that, once triggered, it will stay in place. Fine tuning members 294, 296 are provided at or adjacent each tensioned string segment 254a-f between pulleys 260, 284. A first type of fine tuning member 294 closely resembles the fine tuning pulley 286 discussed above in connection with
In the illustrated embodiment, the string system 288 is first drawn to a desired tension by the adjustment pulley 284 so as to tune a desired one of the string portions 180a, such as, for example, the low E string of a guitar. Preferably, the other string portions 180a-f are adapted to be appropriately tuned to the other strings of a typical guitar, but due to manufacturing variations, such as wide tolerances, may not be precisely in appropriate relative tune at the tension at which the low E string segment is in tune. The latches 292 are then triggered to maintain each of the string portions 280a-f in its macro tuned tension, and to vibrationally and tensionally isolate the string portions 280a-f between the pulleys 260, 284 from one another. Preferably, the pulleys have a relatively high friction surface so that the string 252 does not move across the pulleys, and thus tension is not communicated across the pulleys 260, 284 when they are prevented from rotating. The musician then adjusts the fine tuning members 294, 296 to vary the tension in the string portions 280a-f as needed to fine tune each string portion as desired to ensure correct relative tune.
It is to be understood that other structural arrangements may be employed to accomplish the purposes described above in connection with
In the embodiments discussed above in connection with
The embodiment illustrated in
Preferably, the cam type fine tuning members 296 have a neutral position at which the cam is capable of either increasing or decreasing string tension. For example, in the embodiment illustrated in
With reference next to
The tension adjustment pulley 310 illustrated in
In operation, as the bolt 324 is rotated, the bolt threads engage the nut threads so as to linearly move the nut and associated arms 334 upwardly and downwardly. A string seat 340 is defined between the top and bottom arm portions 336, 338 and at the surface 320 of the pulley member 312. The location of the string seat 340 changes as the arms 334 are moved up and down over the surface 320 of the pulley 312. The effective diameter of the tension adjustment pulley 310 is defined by the diameter of the pulley member 312 at the string seat 340. As the bolt 324 is rotated to move the string holder device 330 upwardly, the effective diameter of the pulley member 312 is decreased, and vice versa.
An irising tension adjustment pulley 310 such as the embodiment discussed above in connection with
With reference next to
b illustrates an embodiment in which the first string segment 360 is drawn about one of the pegs 364. In this embodiment, the string 360 is deflected from its default path, and the path is lengthened, thus increasing the tension of the string 352.
In the arrangements illustrated in
In the illustrated embodiment, the pegs 364 are fixedly mounted to the musical instrument. In another embodiment, an array of detents or holes are provided on the instrument, and pegs are removably fit into the holes. In a still further embodiment, the pegs 364 are retractable, and remain in a retracted state within the musical instrument until selectively deployed as desired by the user. Such retractable pegs may be spring loaded for easy deployment. Still further embodiments may employ pegs having a surface treatment with a substantially high polish and/or a coating such as a Teflon coating in order for the string to easily slide across the low friction surface of the peg, and thus communicate tension across both sides of the peg. Alternatively, pegs may have a high friction surface treatment and/or coating so as to resist movement of the string across the pegs and thus to not communicate tension across the peg.
With reference next to
In the illustrated embodiment, the first radius R1 is different from the second radius R2. As such, when the tuning key 400 is twisted to increase or decrease the tension in the second string segment 396, tension will also be affected in the first string segment 380; however, the tension in the first and second string segments 380, 396 will differ in accordance with a relative relationship. More specifically, when the pulley 372 is at an equilibrium condition in which the composite pulley 372 does not rotate, each of the first and second string segments 380, 396 will be applying a force, or tension, sufficient to create a moment of inertia of equal and opposite magnitude on the pulley 372, and the tension in the string segments 380, 396 will be related to each other in accordance with the mathematical relationship T1R1=T2R2, where T1 is the tension in the first string segment 380, R1 is the radius of the first pulley member 374, T2 is the tension in the second string segment 396, and R2 is the radius of the second pulley member 376. As such, the tension in the string segments 380, 396 will always differ in accordance with a mathematical relationship based upon the relative radii of the pulley members 374, 376, for example, T1=(R2/R1) T2.
In another embodiment, a composite pulley is provided which, like the embodiment shown in
With reference next to
A pitch adjustment system is adapted to increase or decrease the tension in each subsystem 422 simultaneously so as to change the pitch or key of the entire string system 420. The illustrated pitch adjustment system 450 comprises a pitch adjustment knob 452 about which a plurality of main adjustment wires 454 are at least partially wound.
A plurality of proportional adjustment pulleys 460 are provided, one proportional adjustment pulley 460 corresponding to each main adjustment wire 454. Each proportional adjustment pulley 460 preferably comprises first and second concentrically arranged pulley members 462, 464 that are adapted to rotate with one another about an axis 466. The main adjustment wire 454 attaches to the first pulley member 462. A dedicated linear movement line 470 is attached at a first end 472 to an associated second pulley member 464. A second end 474 of each dedicated linear movement string 470 is attached to the axis 427 of a corresponding subsystem pulley 426.
Preferably, each subsystem pulley 426 is linearly movable, preferably along a line substantially parallel to a longitudinal axis of the strings 424 in the playing zone 440 of the instrument. As such, when the proportional adjustment pulley 460 is rotated, the linear movement line 470 causes the subsystem pulley 426 to move linearly, thus stretching or relaxing the associated string 424. The string 424 associated with the pulley 426 is governed by the equation F=−kx, where F is the force, or tension, in the string, “x” is the linear displacement of the string, and “k” is the spring constant of the spring. As such, as the pulley 426 is moved linearly, the tension in the corresponding string 424 increases or decreases based upon the displacement and the spring constant of the string. Preferably, the proportional pulleys 460 are each dimensioned to consider such material properties in order to maintain correct relative tune between strings 424.
The main adjustment wire 454 and linear movement line 470 preferably are constructed of a material, such as wire, string, or the like, that can be wound about a pulley, but may also communicate tension along its length.
In the illustrated embodiment, the first pulley member 462 and second pulley member 466 of each proportional pulley 460 have different radii. As such, a mathematical proportional relationship between the radii of the pulley members 462, 464 determines the change in tension of the string 424 in the corresponding string subsystem 422 that occurs upon rotating the pitch adjustment knob 452. Preferably, the pitch adjustment knob 452 is constructed so that, upon rotation, each main adjustment wire 454 travels substantially the same linear distance. However, due to the differing radii of the proportional pulleys 462, 464 corresponding to each of the subsystems 422, such linear travel of the main adjustment wires 454 results in a different, specially-configured tension adjustment for each string subsystem 422. These relative adjustments are determined by the proportional relationships of the radii of each proportional adjustment pulley 460 in combination with other factors such as the spring constant of the respective strings. As such, the tension of each string subsystem 422 is adjusted by rotating the pitch adjustment knob 452, and such tension adjustments between string subsystems are mathematically related so that the relative tuning between string subsystems 422 remains governed by such mathematical relationships, and each string subsystem remains in relative tune with the other subsystems. Accordingly, the relative radii of the first and second pulley members 462, 464 of each proportional pulley 460 are preferably chosen in consideration of properties (such as density and spring constant) of the associated string subsystem 422. In summary, rotating the pitch adjustment knob 452 will simultaneously adjust the pitch of the entire group of string subsystems 422 while maintaining a desired relative tune between subsystems 422.
In the embodiment illustrated in
As the force exerted on the pitch adjustment knob 452 is anticipated to be quite large, in the preferred embodiment, the pitch adjustment knob 452 preferably includes a ratcheting mechanism to selectively hold the knob at a desired tension. The ratcheting mechanism may be selectively disengaged by actuation of a latch, button, or the like.
In another embodiment, the knob 452 may be motorized so as to more easily adjust the string system. This may be especially helpful in embodiments that are more complex and involve more string subsystems than are presented in the illustrated embodiment. For example, a piano employing aspects of the embodiment discussed above in connection with
With reference next to
As best illustrated in
In the embodiment illustrated in
In an additional embodiment, the first end 494 of each string segment 492 is attached to the musical instrument at a tuning key which enables some measure of tightening of the string segment 492. The second end 496 of the string segment 492 is attached to the tightening knob 500 in a manner as discussed above in connection with
With reference next to
With continued reference to
In the illustrated embodiment, the tension adjustment post 562 is linearly movable in order to facilitate fine tuning adjustments. It is to be understood that, in other embodiments, the tuning adjustment post 562 need not be linearly movable, and other structures may be selectively employed for biasing a spring force in a desired direction of rotation of the pulley. Also, in another embodiment, a plurality of adjustment posts are provided. In one arrangement, a plurality of posts are arranged generally spaced apart in a row. In another arrangement, an array of posts is provided. Also, the spring member 564 may be chosen from a selection of spring members having various elastic properties in order to customize the relative tuning relationship between the segments 557, 559.
With reference next to
With continued reference to
A tension gauge such as the gauge 570 illustrated in
In the illustrated embodiment, the gauge 570 can function as a visual indicator of correct tune of the string, as the indicator 588 will be aligned with a corresponding mark of the scale 590. If the string tension changes due to string relaxation, environmental factors, or the like, the tension change will be indicated by the gauge 570, as the indicator 588 will have changed alignment. As such, a user may visually check the tune of his instrument by simply looking at the gauge rather than using a tuning apparatus. Accordingly, string tune can be checked and adjusted without having to actually play any string.
The embodiment discussed above in connection with
In still another embodiment, a portion of the scale 590 may be movable, such as over a threaded connection. As such, once the associated string is appropriately tuned, the scale is “calibrated”, meaning a portion of the scale is moved so as to perfectly align with the indicator 588. Thus, it will be easier for the user to visually notice any movement or variation of the indicator 588 relative to the scale, because a change in the perfect alignment will be easily visible. Such a movement will indicate a change of tension in the string, which corresponds to a change of tune. Tuning of the string can also be easily accomplished by changing tension to once again achieve perfect alignment. As such, minute changes in tune can be visually detected and corrected even before they become audibly detectable.
With reference next to
With continued reference to
In a preferred embodiment, the musical string segments 620 are made of musical-quality string so as to emit a desired tone and note at tension. Preferably, the bending segments 630 are made of a material that is very strong longitudinally yet relatively pliable in bending. Preferably, the bending segments 630 are more pliable in bending than are the associated musical segments 620. Most preferably, the bending segments 630 bend readily about the pulleys 604 with little or no resistance. Tension in the composite string 602 thus is not dedicated to bending the string 602 about the pivots 604, but is instead dedicated to maintaining appropriate tune along the string system 600. Since little or no tension is stored in bending material about the pulleys 604, the tension on either side of pulleys 604 and throughout the composite string 602 can be maintained relatively consistent.
Most preferably, the musical string segments 620 stretch longitudinally more readily than the bending segments 630. As such, tensioning of the string system 600 is controlled by longitudinal stretching of the musical segments 620 rather than the bending segments 630.
In one embodiment, the bending segments 630 are made of a collection of filaments arranged in a braid or other structure that compiles or organizes the filaments together. In this specification the term “filament” is a broad term used in accordance with its normal meaning, and includes thin elongate structures such as natural or artificial fibers, fine wires, and the like. Filament materials can include, for example, steel, aluminum, or other metals and alloys, polymers such as nylon, carbon, aramid or glass fibers, and the like. Combinations of filament materials may also be employed.
In another embodiment, at least one of the bending segments is configured as a belt having a width greater than its thickness. In such an embodiment, the pulleys are configured to accommodate the wide belt, which bends readily but resists elongation. In one embodiment, the belt comprises a fabric- or fiber-reinforced rubber. In another embodiment the belt comprises a plurality of thin, elongate filaments reinforced by a fabric. In yet another embodiment, the belt comprises a thin ribbon of material. In a still further embodiment, a bending segment is made of a single elongate wire. In still another embodiment, the bending segment is biased with a curve so as to turn even more easily and with less resistance about the pulley 604.
In a preferred embodiment, the connectors 626 employ a ball-and-connector construction as discussed above in connection with
The string system 600 embodiment illustrated in
In yet another embodiment, a stringed instrument having tuning knobs for tensioning a string may employ one or more composite strings, each comprising a bending segment attached to a musical string segment. The bending segment is placed and adapted to wrap about the tuning knob, leaving the musical segment to remain generally straight. Since the bending segment is specifically adapted to easily wrap about the tuning knob, tuning of each composite string is easier for the user, and less or no string tension of the musical segment is dedicated toward tuning the instrument. As such, a bending segment may be suitable for embodiments with or without pulleys.
Variations of the embodiments discussed above can be used in connection with several types and varieties of stringed musical instruments. Such instruments may be conventional, such as a six-string guitar, or unconventional. For example, in one embodiment, a guitar may have stringed playing portions on opposing sides of the neck. In one such embodiment, a single or double (see
As discussed above, the natural vibrating frequency of a musical string is defined by the equation f=(½L)(T/d)1/2. In several embodiments disclosed herein, the natural frequencies of adjacent string segments are mathematically related. For example, the natural frequency of a first string segment, f1 may be related to that of a second string segment, f2 by an equation such as f2=K1f1, where K1 is a constant. Typically, K1 is defined by properties of the first string segment as compared to the second string segment, such as the density of material used to make the string segment, the effective length L, and even the tension T and/or spring constant k. Once this mathematical relationship is established, simultaneously adjusting the string segments such as for example by simultaneously increasing or decreasing the tension T of the segments, will change the natural frequencies of the segments, yet may maintain the mathematical relationship between segment natural frequencies. Thus, the string segments remain in relative tune. The same holds true in embodiments in which a mechanism such as a composite pulley defines relative proportional tension relationships between strings. In such embodiments, even though the tension in related string segments changes differently, the tension still changes according to a proportional mathematical relationship. Such proportional tension adjustments vary the pitch of the individual segments while maintaining the mathematical relationships of the emitted natural frequency.
In accordance with some embodiments, musical string is constructed of wire manufactured according to very tight tolerances. For example, preferably a string that is adapted to be the high E string of a guitar has a nominal diameter of about 0.009 inches, and a diameter tolerance of less than 1%, more preferably less than 0.25%, and most preferably below 0.1%. As such, consistency of actual natural frequency of the string at a specified tension and effective length is achieved. For example, the guitar high E string nominally vibrates at 330 Hz. Applicant has determined that a string diameter that varies from the nominal diameter by +−0.25% will vibrate at between 329.175 and 330.825 Hz, which corresponds to about 1.65 beats per second. Adherence to 0.1% diameter tolerances will result in under 0.66 beats per second, which is an inaudible difference in tune. Preferably, manufacturing tolerances are such that the variation from nominal frequency generates a beat frequency of less than about 2 beats per second, more preferably less than about 1.65 beats per second, still more preferably less than about 1 beat per second, and most preferably about 0.66 beats per second or less.
Although this invention has been disclosed in the context of certain preferred embodiments and examples, it will be understood by those skilled in the art that the present invention 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 invention have been shown and described in detail, other modifications, which are within the scope of this invention, 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 embodiments may be made and still fall within the scope of the invention. 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 invention. For example, a tuning knob member as provided
This application claims the benefit of U.S. Provisional Application No. 60/698,027, which was filed on Jul. 11, 2005, The entirety of which is hereby incorporated by reference. The entirety of Applicant's copending U.S. application Ser. No. 11/356,486, which was filed on Feb. 17, 2006, is also hereby incorporated by reference.
Number | Name | Date | Kind |
---|---|---|---|
2614449 | Machalek | Oct 1952 | A |
3136198 | Smith et al. | Jun 1964 | A |
3583272 | Eurich | Jun 1971 | A |
3780612 | Robinson | Dec 1973 | A |
4020730 | Hill | May 1977 | A |
4130045 | Walker | Dec 1978 | A |
4137812 | Franzmann | Feb 1979 | A |
4138919 | Miller | Feb 1979 | A |
4170161 | Kaftan | Oct 1979 | A |
4348934 | Ogata | Sep 1982 | A |
4375180 | Scholz | Mar 1983 | A |
4656915 | Osuga | Apr 1987 | A |
4704935 | Franklin | Nov 1987 | A |
4760622 | Rohrman | Aug 1988 | A |
4777858 | Petschulat et al. | Oct 1988 | A |
4856404 | Hughes, Sr. | Aug 1989 | A |
4909126 | Skinn et al. | Mar 1990 | A |
4955275 | Gunn | Sep 1990 | A |
5040741 | Brown | Aug 1991 | A |
5080295 | Hongo et al. | Jan 1992 | A |
5097737 | Uhrig | Mar 1992 | A |
5173565 | Gunn | Dec 1992 | A |
5293804 | Myers | Mar 1994 | A |
5323680 | Miller et al. | Jun 1994 | A |
5343793 | Pattie | Sep 1994 | A |
5377926 | Min | Jan 1995 | A |
5390579 | Burgon | Feb 1995 | A |
5637820 | Wittman | Jun 1997 | A |
5734117 | Tanzella | Mar 1998 | A |
5756913 | Gilmore | May 1998 | A |
5824929 | Freeland et al. | Oct 1998 | A |
5859378 | Freeland et al. | Jan 1999 | A |
5883319 | Hebestreit et al. | Mar 1999 | A |
5886270 | Wynn | Mar 1999 | A |
RE36484 | Turner | Jan 2000 | E |
6069306 | Isvan et al. | May 2000 | A |
6437226 | Oudshoorn et al. | Aug 2002 | B2 |
6528709 | Hebestreit et al. | Mar 2003 | B2 |
6559369 | Gilmore | May 2003 | B1 |
6580021 | Barney | Jun 2003 | B2 |
6723904 | Dolan et al. | Apr 2004 | B1 |
20030094087 | Gregory | May 2003 | A1 |
20070006712 | Lyles | Jan 2007 | A1 |
20070214931 | Lyles | Sep 2007 | A1 |
20070214935 | Lyles | Sep 2007 | A1 |
20080196571 | Lyles | Aug 2008 | A1 |
Number | Date | Country |
---|---|---|
WO 0038172 | Jun 2000 | WO |
WO2007008785 | Jan 2007 | WO |
WO2007106600 | Sep 2007 | WO |
Number | Date | Country | |
---|---|---|---|
20070012161 A1 | Jan 2007 | US |
Number | Date | Country | |
---|---|---|---|
60698027 | Jul 2005 | US |