DE3607252A1 - Individual-string holder for stringed instruments - Google Patents

Abstract

The invention relates to an individual-string holder for stringed instruments, in which the tensile force of the string (11) is absorbed with the aid of a spring (14) which engages on a lever system, e.g. a one-armed lever (13). The string (11) engages at another point of the lever system. For different lever angles, a force which can be adjusted to the tensile force of the string (11) and is constantly equal in the opposite direction thereto is modified by the spring (14). <IMAGE>

Description

The invention relates to a single tailpiece for Stringed instruments according to the preamble of the claim 1.

Such tailpieces, in which the tensile force of a string is caught with the help of a spring, z. B. from the DE-PS 6 83 057 known. This tailpiece, there for one The guitar described has one with one for each string Coil spring attached to the guitar screwed in a screw rod on the other side the string is hooked into. With this tailpiece each string is tuned as usual with the help of tuning pegs voted. There is an adjusting ring on the screw rods a mark provided according to the mood of the respective string shifted so far on the screw rod will mark that with an instrument-fixed Mark coincides.

If caused by external interference, especially temperature fluctuations or mechanical actions, a change of the mood thus established, it can be restored by the fact that the two mentioned Mark again by turning the tuning pegs Be brought under cover. Herewith receives the spring again the original length with which for the right mood required tension on the string exactly compensated becomes.

A tailpiece is known from DE-PS 8 09 008, at which also has a spring in the longitudinal tension of the strings lies, which preferably from a to the tensile force of the Strings prestressed compression spring, their counter bearing is attached to the tailpiece.

The purpose pursued with this tailpiece is it, the sound and the response of steel strings String instruments to those of old Italian instruments align with gut strings. Through the compression springs  the stiffness of the metal strings on a matched to the gut strings Measure reduced. In addition, there is no need similar to gut strings that are otherwise used for metal strings indispensable fine tuner.

However, the prerequisite for the desired goals is that the compressive force of the springs matches the tensile force exactly the respective string is tuned and also with - albeit minor - changes in length of the string z. B. as a result of temperature fluctuations does not change. Should also Strings are stretched, their tensile strength varies to the spring force of the springs used so far, so the springs must also be replaced. Should also go played with a different tuning of the strings when this is determined by the springs, the mentioned fine tuning effect lost, d. H. this tailpiece works no different than the one described above.

In the well-known tailpieces, in which a spring for Recording the string tension used can be a change the set mood usually only through time consuming and, especially when the musician performs, annoying retuning can be corrected.

The invention has for its object a tailpiece to constructively improve the type in question so that a string once tuned despite external Interference influences automatically adjusted in a certain range becomes so that their pitch is audible and corresponding measurably remains the same.

This object is according to the invention by the characterizing Part of claim 1 specified features solved.

There is a significant difference to known tailpieces in that according to the invention the string on a the lever system connected to the instrument.  A spring also acts on this lever system can be easily adjusted so that by the lever system exerts torque at all lever positions into one of the tensile strengths of the string when correct Counteracting the same force is converted. Such compensation follows simple mathematical ones Law and can by simple lever systems, e.g. B. a or multi-armed levers, and simple springs with approximately linear characteristic can be easily realized, e.g. B. a conventional leg spring, a tension or a compression spring in screw form etc.

The tailpiece is preferred behind the bridge of the stringed instrument arranged. A particularly cheap embodiment arises when the triangle resulting from the Point of contact of the string on the bridge, the point of attack of the String formed on the lever and the fulcrum of the lever is an approximately isosceles triangle with the tip is in the fulcrum of the lever.

With a tailpiece according to the invention that is once set string tension even with external interference automatically kept constant so far that the pitch of the struck string audible and measurable accordingly remains the same.

If the tailpiece is in the usual way behind the bridge arranged of the stringed instrument, so by the automatic readjustment precludes the generation of a vibrato. In order to enable such a manual tone shaping, it would be possible not to leave the tailpiece behind that Bridge, but near the saddle of the stringed instrument to arrange. With this arrangement, pulling and sliding the gripper finger in the direction of the string Vibrato intensifies because of the tensile force between Gripper finger and the instrument-fixed clamping point is changed on the dock. A toner boost to create a Vibratos by pulling at right angles to the tensioned string however does not occur.  

A much better solution is that during normal To lock the tailpiece or to block. In the locked position, everyone can desired manual tone shaping. The automatic Reconciliation is of course then blocked by the Tailpiece overridden. By briefly unlocking it of the tailpiece, however, the string can work automatically again be retuned.

Further embodiments of the invention emerge from the subclaims forth. The invention is based on the drawing explained in more detail. In this represent:

Figure 1 is a diagram for explaining the forces acting on a tailpiece according to the invention.

Fig. 2 is a side view of a first embodiment of a string holder according to the invention;

Fig. 3 is a plan view of the tailpiece shown in Fig. 2;

Fig. 4 is a plan view of a tailpiece which is slightly modified compared to the embodiment in Fig. 3;

Fig. 5 to 9 show further embodiments of the invention.

In Fig. 1, a string 1 is shown schematically, which is guided at point C over an indicated web 2 and is suspended at an end point B of a lever 3 with the length c . The lever 3 is rotatable about the point A fixed to the instrument. The string tension F 1 has a component F 2 perpendicular to the lever 3 .

F 2 = F 1 × sin β ,

where β is the angle between the string 1 and the lever 3 . The sine of this angle can also be expressed by the ratio of h and c , where h is the perpendicular to the string 1 starting from the point of rotation A and c , as mentioned, the length of the lever 3 . A spring 4 , shown here schematically as a leg spring, acts on the lever 3 and is adjusted so that a force F 3 which is the same as the component F 2 but counteracts it is generated at the attachment point B. The spring 4 ideally has a characteristic curve which is adapted to the ratio of h and c at different angles β , that is to say depends on the sine of this angle. In practice, the sine dependency can be completely replaced by a linear dependency that is adapted to the sine curve.

Changes the tensile force F 1 of the string z. B. by temperature influences, the angle β and the effective lever arm h would change accordingly, this change being largely linearly proportional to the angle β for the practical areas. With a correctly dimensioned and preloaded spring 4 with a linear characteristic, whose force F 3 in point B can be adjusted by moving its effective point of attack on lever 3 , the string tension F 1 is kept constant to such an extent that the pitch of the string is audible and remains measurably the same.

In Fig. 1, the points B, C and A form an isosceles triangle, the outside angle CAB is denoted by α . In this case, β is α / 2.

In Fig. 2, a tailpiece 10 is shown, the z. B. is suitable for an electric bass. The tailpiece 10 has a one-armed lever 13 which is mounted behind the web 12 on the ceiling of the instrument 15 so as to be pivotable about a shaft 16 . A string 11 guided over the bridge 12 is suspended from the lever at a suspension point 17 . This suspension point 17 is connected to a carriage 18 which is displaceable on a spindle 19 along the lever 13 . The position of the slide is set using a knurled screw 20 . A double leg spring 14 is wound around the shaft 16 of the tailpiece 10 , one spring end of which is supported on the instrument base 15 and the other end of which is supported on the upper side of the lever 13 . The spring force of the leg spring 14 is approximately matched to the tensile force of the string 11 .

For clarification, points A, B and C corresponding to FIG. 1 are again shown in FIG. 2. In order to adapt the torque generated by the leg spring on the lever to the tensile force of the string, the slide 18 is adjusted with the attachment point 17 with the knurled screw 20 . The adjustment of this point of attack is equivalent to the adjustment of the point of application of a tension or compression spring on the lever of the tailpiece. In both cases, the string tension is ultimately adjusted.

If the pretension of the leg spring 14 should decrease over time, it can be readjusted by an adjusting screw 21 which is fastened in the instrument base 15 and acts on the spring end resting thereon.

In the embodiment according to FIG. 3, the spring turns of the leg spring 14 enclose the shaft 16 on both sides of the lever 13 . It is also possible according to FIG. 4 to integrate the spring windings in the lever designated there with 13 a . The tailpiece 10 a together with the leg spring 14 a then only has the width of this lever 13 a . The exemplary embodiments according to FIGS. 3 and 4 do not differ otherwise; in Fig. 3 and 4, identical parts are provided with the same reference numerals to which has been added in Fig. 4 of the lower case letter a. A detailed description is therefore unnecessary.

The tailpieces shown in FIGS. 3 and 4 can be locked in their respective positions by a counter bearing 22 , which acts on an axial projection 23 of the knurled screw 20 . In the embodiment according to FIG. 4, it is also possible to lock the lever 13 a by axially pressing along the shaft 16 a . This can either be done with individual pressing elements or by arranging several string holders next to each other on a common shaft and bracing them axially for locking. In any case, the axial bracing must be able to be easily released in order to enable independent adjustment quickly.

In Fig. 5, 108 is a square tube with thread in the lower part that runs on spindle 110 , 101 is a string with suspension ball 109, 102 is a bridge, 107 is a bearing in the lever on shaft 106, 105 is the guitar body, 104 is a spring (here compression spring ), would also be possible as a tension spring in the ( F ) direction shown or as a leg spring around shaft 106 .

The bracket 108 , which can be displaced along the lever by means of an internal left-hand thread by means of the adjusting screw 110, presses the string onto the surface of the lever or onto the straight line to the center of the shaft 6 (with a longitudinal groove) in order to avoid deviations in the case of large string diameters. By changing the lever C, the effect of the spring force of the spring 104 on the string tension is changed and the string is thus tuned. This largely eliminates the need to readjust the string length using mechanisms on the head of the instrument. The usual mechanics could thus be replaced by clamping devices (with a smaller adjustment device) that are already frequently used today in electric basses. In this way, the effective point of application of the string tension on lever C is continuously adjusted - not the suspension point.

In Fig. 6, 1 is a web. The string 2 is guided under the pressure roller 3 and suspended with its ball 4 in the lever 5 . This lever 5 bypasses the height of the bearing 10 or the lever 9 . The lever 5 is suspended movably about a bolt 6 in the direction of F ₁ and F ₂ . The bolt 6 is part of a block 7 . This can be continuously adjusted radially to the axis 11 by means of a knurled screw 8 by means of an internal thread, so that the bolt 6 always moves towards or away from the center of the axis 11 . The bolt 6 represents an indirect suspension point of the string 2. The bypass lever 5 achieves a low installation height, also exploiting the spring force of the spring 12 near the center of the shaft 11 and thus reducing the size of the lever 9 . The spring preload can be adjusted using the adjusting screw 13 (Allen key) with spring seat. The spring 12 is supported on the one hand on the adjusting screw 13 , which is passed through a thread of a base plate 14 , on the other hand on the lever 9 with a corresponding fit. A damping 15 serves to intercept the lever 9 z. B. in case of broken strings.

In Fig. 7 is a force diagram of the lever system is shown. F ₁ originally means the string force, now the spring tension, F ₂ originally the spring force moving the lever C in the direction of F ₂ , now the string tension, A is equivalent to the force of a linear spring with zero spring force at β equal to 90 °. So when c is equal to b (isosceles triangle)

a = p + q , p = q , a = 2 q
" q " related to " c " = √ c ² - h ²
c = 1 then q = √1- h ²
a = 2 q = 2 √1- k ²
h = sin β , a = √1- (sin β ) ² = 2 cos β

Since it is very difficult to realize a spring with spring force equal to 0 at β = 90 °, the spring must lie in a range between β equal to 90 ° and β = 0 ° with F ₀ . These positions, depending on β and labeled β ₀ , result in corresponding torque curves. This results in a usable constancy of ± 2.5 ° around the range of the respective maxima. Since β is now α / 2 (isosceles triangle), this means a constant torque on lever C over an angle of 10 °.

The structure according to FIG. 8 is to be understood exactly mirror-symmetrically to the previous system drawing. The string 1 generates a force F ₂ , which counteracts a torque acting on the drum 3 by the spring force 2 and compensates it. The spring force can be adjusted by screwing the set screw 9 into the spring gears. It would also be conceivable to grasp the spring windings (external thread) and thus shorten the acting spring (as when screwing in) to adjust the spring force. In any case, the same movement should (must) take place in parallel through a thread in the lever 4 in order not to change β ₀ . Otherwise, this system would turn out to be a little more difficult than that. The exact center of the tuning range - maxima of the torque curve - can be identified by a fixed marking. 10 is a hemisphere to allow β motions. It is better to have a threaded hole in lever 4 with a corresponding tolerance. By radially acting locking of all tuning levers, a vibrato effect can be achieved by moving the tuning levers together in the direction of F 3 or F 4. The lever 4 with the drum 3 can be supported by the constant spring pressure of the spring 2 on the housing 7 only by a tip support. 5 is the bridge, 6 is a pressure roller for the strings 1 and 11 is the string ball.

The tailpieces 201 ( FIG. 9) are mounted on a common shaft 202 and are axially pressed by a plate spring assembly 203 via a pressure piece 204 . Two locking pins 206 are slidably mounted in a sleeve 205 which is connected in a rotationally rigid manner to the shaft 202 and each engage in a link track 207 of a camshaft 208 . The camshaft is rotated by a vibrato lever 209 and carries a locking pin 211 on the guitar body 210 side. In the position shown, the tailpieces 201 are pressed axially. If the vibrato lever is turned through 90 °, the locking pin 211 slides into a hole 212 in the instrument body 210 without the lock being released, so that the rotational position of the shaft 202 is fixed. In this section, the link tracks 207 have partial tracks 213 directed perpendicular to the shaft 202 . When the vibrato lever 209 is pivoted further, the pins 206 slide outward in the sleeve 205 , so that the plate spring assembly 203 is relaxed and the tailpieces 201 are released. This means that self-voting is possible again.

If the vibrato lever 209 is pivoted about the shaft 209 in the locked position, vibrato can be generated in the usual way.

Vibrato can be used with all systems described of the vibrato lever are also generated in that this acts directly on the springs that the lever system in Keep balance with the string pulling forces.

Claims (18)

1. Individual string holder for string instruments, in which the tensile force of the string is absorbed by means of a spring, characterized in that the string holder ( 10 ) has a lever system ( 3, 13 ) rotatably mounted on the instrument, on which the string ( 1, 11 ) is suspended, and that the spring ( 4, 14 ) engages the lever system ( 3, 13 ) and that this generates a variable torque at different lever angles ( α, β ), which for the different lever angles by the lever system ( 3, 13 ) is converted into a force that is adjustable to the tensile force ( F 1 ) of the string ( 1, 11 ) and that is constantly the same in the opposite direction. 2. tailpiece according to claim 1, characterized in that the lever system is a one-armed lever ( 13, 13 a ). 3. tailpiece according to claim 1, characterized in that the lever system is a two-armed lever ( 13 b ). 4. Tailpiece according to one of the preceding claims, characterized in that the point of application of the spring ( 14 ) is adjustable for adjustment to the string tension ( F 1 ). 5. Tailpiece according to one of the preceding claims, characterized in that the point of application ( 17, 17 a ) of the string ( 11, 11 a ) is adjustable for adjustment to the string tension ( F 1 ). 6. tailpiece according to one of the preceding claims, characterized in that the spring preload is adjustable is. 7. tailpiece according to claim 2, characterized in that the one-armed lever on a with the instrument ( 15 ) connected shaft ( 16, 16 a ) is mounted that around this shaft ( 16, 16 a ) a leg spring ( 14, 14 a ) is located, which is supported on the one hand on the instrument ( 15 ) and on the other hand on the lever ( 13, 13 a ) that the lever ( 13, 13 a ) has a hanging device ( 17, 17 a ) for the string ( 11, 11 a ), and that the suspension device ( 17, 17 a ) along the lever ( 13, 13 a ) is adjustable. 8. tailpiece according to claim 7, characterized in that the suspension device ( 17, 71 a ) with a along the lever ( 13, 13 a ) displaceable carriage ( 18, 18 a ) is connected. 9. tailpiece according to one of the preceding claims, characterized in that the lever system ( 13, 13 a ) 13 b ) of the tailpiece ( 10, 10 a , 10 b ) can be locked in the respective position relative to the instrument and can be released again from this position . 10. tailpiece according to claim 9, characterized in that a common locking device ( 22; 36, 43 ) is provided for the tailpiece ( 10 ) of all strings ( 11 ) of the instrument. 11. Tailpiece according to claim 10, characterized in that the stepless pitch change, the common locking device ( 36, 43 ) via an operating lever ( 44 ) about an instrument-fixed shaft ( 16 b ) is pivotable. 12. tailpiece according to claim 9, 10 or 11, characterized in that all tailpieces ( 201 ) on a common shaft ( 202 ) are arranged freely rotatable and axially pressed together by an axially acting energy store ( 203 ) as a locking device. 13. Tailpiece according to claim 12, characterized in that the energy store has at least one plate spring assembly ( 203 ). 14. Tailpiece according to claim 12 or 13, characterized in that the energy store ( 203 ) can be actuated via a cam control acting axially to the shaft ( 202 ) for locking or releasing the tailpiece ( 201 ). 15. Tailpiece according to claim 14, characterized in that the cam control ( 207, 208, 206 ) has a slide track ( 207 ), in which locking pins ( 206 ) acting on the energy store ( 203 ) engage. 16. Tailpiece according to claim 15, characterized in that the cam control has a locking pin ( 211 ) which can be displaced perpendicularly to the shaft ( 202 ) and which in an intermediate position of the cam control ( 26, 27, 28 ) in which the tailpiece ( 201 ) is still locked are engaged in an instrument-fixed hole ( 212 ) to block the rotational position of the shaft ( 202 ). 17. Tailpiece according to one of claims 9 to 16, characterized in that a vibrato lever ( 209 ) is provided for locking and releasing the tailpiece. 18. Tailpiece according to one of the preceding claims, characterized in that a vibrato lever ( 209 ) acts on the spring (s) of the lever system.