RU2602371C1 - "multi locking" tuning pin for string musical instrument - Google Patents

Abstract

FIELD: music.

SUBSTANCE: invention relates to string musical instrument tuning pin, which has a body, a worm pair for rotation of the rod, on which the string is wound, and a support bushing connected to the pin body with a threaded connection, which the rod lies on under the string tension force, herewith the pin rod in the place of winding the string has arc-like working bearing surfaces for the string arranged along the circumference with angular intervals, and the support bushing has a hole for the rod, where the support bushing hole cross-section is formed by lateral sides of regular parallelepiped and has an additional support bushing located between the tuning pin support bushing and the pin body.

EFFECT: technical result is easier tuning of the musical instrument and maintaining the musical instrument tuning scale.

1 cl, 5 dwg

Description

The invention relates to stringed musical instruments, for example, an electric guitar having a tremolo mechanism, and allows for a longer fixation of the system, prevents the detuning of a musical instrument while playing it and when using the tremolo mechanism.

Known for the string of a musical instrument, in which the pin on which the string is wound has a circular cross-section at the place of winding the string and rests on the support sleeve at one point. U.S. Patent 4,945,800.

Known peg string musical instrument, the pin of which has a cross-section at the place of winding the string, made in the form of a conjugated rounded working section, and a straight guide section and rests on the support sleeve at one point. Patent of the Russian Federation 2053575, cl. G10C 3/10.

Known for the string of a musical instrument, in which the pin, on which the string is wound, rests on the support sleeve at one point. The design of the stake allows you to twist the string during its replacement. U.S. Patent 5,847,295, cl. G10D 3/14, CL U.S. 84/305.

Known for the string of a musical instrument, the pin of which has the ability to move along its axis and has one fulcrum on the support sleeve. RF patent No. 2364955, cl. G10D

In FIG. 1 shows an electric guitar having a tremolo mechanism 2, strings 11, tuning pegs 4, front nut 3.

In FIG. 2 shows a plan of the proposed spike, where 8 pin spike, 11 string, 5 guitar neck tree, 6 spike body, 7 pinion gear, 9 upper pin support sleeve 8, 10 washer, 12 spike handle for adjusting the string tension. Additional support sleeve 30. In FIG. 3 shows a section разрез-A on the proposed peg. The support sleeve 9 with the inner hole, the cross section of which is made by a square, for the location of the pin 8 in it, takes the string tension to two support points 21, the technical clearance between the pin and the support sleeve is shown at position 22. Pos 20 shows the offset of the shaft pin under the action of the tension force strings 11.

In FIG. 4 shows a top view of the pin of the proposed stake with a cruciform part of the axis on which the string is wound.

In FIG. 5 shows an additional support sleeve.

The proposed stick for a stringed musical instrument, FIG. 2, 3, 4, has a rotating pin 8 on which the string 11 is wound. Pin 8 has a cylindrical surface located inside the shaft body and the support sleeve, and a cross-shaped part on which the string is wound. 11. When the string is wound on pin 8 and tuned, the force generated by the string causes pin 8 of peg 4 to rest on the support sleeve 9, which rests on the additional support sleeve 30. The additional support sleeve transfers the tension force of the string to the guitar neck tree. The proposed supporting sleeve 9 has a hole in which the pin 8 is located. The hole of the sleeve 9 has a cross section formed by the sides of a regular parallelepiped. Geometrically, the cross section of the support sleeve bore is, for example, the square described around the imaginary standard circumference of the support sleeve bore. This hole with a cross section in the form of, for example, a square allows the round part of the pin 8 to be located with structural gaps between the round surface of the pin 8 and the opening planes of the support sleeve 9. A structural gap is necessary to unload the worm pair of the shaft and compensate for errors in the ring production. When pulling the string, the pin will bend slightly, choosing a constructive gap, and lean on two points of the support sleeve, these two support points will be on the top of the support sleeve. The support sleeve 9 is attached to the body of the shaft threaded connection. The elasticity of the neck tree, on which the pegs are mounted, allows the support sleeve to be twisted with the necessary effort and at the same time find the position of the support sleeve when the cylindrical part of the pin 8 rests on two support points 21 of FIG. 3 of the supporting sleeve 9. The proposed spike has a pin on which a string is wound, consisting of a cylindrical section and a section allowing the string to be wound on the working sections of the pin in the form of arcs 23 of FIG. 4. The cross section of the pin at the place of winding the string can be in the form of a cross-shaped or star-shaped (three-pointed, five-pointed, six-pointed).

The proposed spike also has an additional support sleeve 30 of FIG. 5, which assumes the load of the stretched string. An additional sleeve fills the cavity between the inner diameter of the hole in the neck tree for installing the peg and the outer surface of the pedestal sleeve.

The proposed stick is mounted on the head of the neck. The peg fastening on the guitar neck is carried out by the support sleeve 9 with external thread, the washer 10 and the body of the peg 6, which allows you to finish fastening the peg in the position of the support sleeve when the peg pin rests on two points 21 (Fig. 3) of the support sleeve.

The proposed stake works as follows. Rotating the worm with the handle 12, FIG. 2, the gear of the worm pair rotates, and with it the pin of the spike 8. String 11 of FIG. 2, pulling, creates lateral force on the pin 8. The pin 8, at the end of the guitar tuning, will lean on two points 21 of the support sleeve 9, which, in turn, will lean on the additional support sleeve, and in the lower part on the gear of the worm pair. Two support points of the support sleeve give the pin additional stability, which helps to preserve the structure of the musical instrument. When the string is pulled, the flat working surfaces of the support sleeve 9 are in contact with the outer cylindrical surface of the pin, and the working part of the pin on which the string is wound is wrapped by the string, touching the working surfaces of the pin in the form of arcs 23 of FIG. 4, and in the interval between the working sections, the string is positioned linearly 24 of FIG. 4. The shape of the wound section of the string on the pin is created in the form of arcuate and rectilinear sections. This prevents the wound sections of the string from moving relative to the pin. The strings when playing the guitar and when using the tremolo mechanism then stretch more than the tuning position or lose tension, and the use of the proposed pick helps to preserve the structure of the musical instrument. In addition, in the proposed design of the pier, the working sections of the pin on which the string rests have an obtuse angle created by the arc of the working section of the pin and the structural cavity in which the string is located in a straight line. This creates an additional obstacle to the movement of the wound section of the string relative to the pin.

In the modern language of musicians and manufacturers of spikes having strong kinks of a string in the place of string winding on a pin, spikes are called "locks". In Russia, it is firmly rooted to call such spikes "Locking spikes." In connection with this, the proposed stab of a string musical instrument makes sense to call it “Multibloc String Musical Instrument.” Multilocity creates two points of support for the pin on the supporting sleeve, an additional supporting sleeve and the shape of the working portion of the pin on which the string is wound in the form of alternating arcuate sections and gaps between the arcuate sections of the working section of the pin.

If the peg of a string musical instrument does not have a pin, a support sleeve and an additional support sleeve of the proposed design, then the string at the place of winding on the pin will slip at the moment of changing the string tension by the tremolo mechanism. Also, during the tuning of a musical instrument, a pin resting on a support sleeve with a circular cross section at one point will move, changing the position of one support point on the support sleeve of the stake during tuning of the instrument, which makes tuning difficult and causes the musical instrument to malfunction while playing on it and the use of the tremolo mechanism, and the pin itself can skew the entire spike under the action of the string tension force. The diameter of the pin is smaller than the inner diameter of a conventional pedestal support sleeve. The difference in diameters is a constructive necessity in order to reduce the friction force during rotation of the pin and not to create critical loads on the worm pair of the shaft and the shaft body itself.

Claims (1)

A peg of a string musical instrument having a body, a worm pair for rotating the pin onto which the string is wound, and a support sleeve connected to the peg body by a threaded connection on which the pin rests under the action of the string tension force, characterized in that the pin pin in the place of winding the string has arched working supporting surfaces for the string, located along a circle line with angular gaps, and the support sleeve of the stake has an opening for a pin, where the cross section of the opening of the supporting sleeve is formed on the sides of the right parallelepiped and has an additional bearing bush located between the bearing sleeve and the housing chopping chopping.

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