The present application is a U.S. national stage application under 35 U.S.C. § 371 of PCT Application No. PCT/GB2020/052447 filed Oct. 5, 2020, which claims priority to United Kingdom Patent Application No. 1914298.3 filed Oct. 3, 2019, United Kingdom Patent Application No. 1916642.0 filed Nov. 15, 2019, and PCT Patent Application No. PCT/GB2020/052434 filed Oct. 2, 2020. The disclosures of the aforementioned priority applications are incorporated herein by reference in their entireties.
The present invention relates to tools for use in the tuning of instruments, particularly pianos.
Chordophones are musical instruments which make sound by way of vibrating strings. The strings of chordophone instruments can be vibrated by being either plucked, bowed, or hammered. Hammered chordophones include pianofortes; plucked chordophones include guitars; and bowed chordophones include violins.
Pianofortes, commonly referred to as pianos, have keyboards comprising different keys which are triggered to generate a range of musical notes. When the keys of the keyboard are depressed, up to three different strings are simultaneously struck with hammers to induce vibration of the strings resulting in production of a sound. When the key is released, the hammers move away from the strings and dampers are applied to the opposite side of the strings to stop the vibration.
The strings of a piano are made of piano wire, often manufactured from iron or high-carbon steel. Qualities of the strings, such as the length, tension and thickness all affect the sound produced when vibration of the strings is triggered by means of the hammers. In order to alter the pitch of the sound made by the string, and to keep the piano in tune, the tension of these strings must be adjusted periodically. At one end of each string, the string is wound around a tuning pin. These tuning pins are fixed into a pinboard and can be rotated to alter the tension of the strings and thereby the pitch of the sound made by the strings when vibration is induced.
When a piano tuner tunes a piano, they must gauge in which strings the tension requires altering, typically by listening for out of tune notes or by detecting out of tune notes by an electronic tuner. Once the strings that require alteration of tension have been identified, a tuning lever (a piano lever in the case of a piano) is fitted to the protruding end of the corresponding tuning pin and is used as a lever to rotate the tuning pin in the appropriate direction to either loosen or tighten the corresponding string attached to that tuning pin. Whilst the tuning pin is being rotated by the piano tuner using the tuning lever, the piano key associated with string in question is played until the string has the desired pitch. The tuning lever is then removed from the piano pin leaving the piano pin in a position such that the desired tension is imparted to the string.
Piano tuning pins are situated in a board of hard wood often referred to as the “pinblock”. The pinblock holds the tuning pins in place and the friction between the tuning pins and the pinblock generally prevents the tuning pins from moving keeping the strings at a desired tension. Over time, the holes in the pinblock in which the tuning pins are located can become enlarged. This is due to repeated movement of the tuning pin in the pinblock during tuning and warping of the wood that the pinblock is made from due to changes in temperature and exposure to moisture/humidity. Such enlargement also sometimes occurs on a new piano when a tuning pin is warped.
As a tight fit of the tuning pin in the pinblock is necessary for holding a tuning pin in place to maintain the required tension in the string, enlarged pinblock holes cause the instrument to “de-tune” more rapidly than normal. Specifically, when the friction between the pinblock and the pin becomes weaker than the tension in the string, the tension in the string can result in the rotation of the tuning pin in the pinblock, in turn causing the attached string to loosen.
Moreover, enlarged pinblock holes make it more difficult to tune a piano. As described above, during tuning, a piano tuning pin is rotated with a tuning lever to achieve the desired tension in the string. However, when the desired tension has been applied via the tuning lever, as soon as the tuning lever has been removed, piano pins situated in enlarged holes have a tendency to move due to the friction between the pinblock and the pin not being sufficient to overcome the force imparted on the pin by the tension in the string, thereby immediately detuning the string being tuned.
Several solutions to this problem exist to inhibit the movement of tuning pins in pinblock holes. In one such solution, the loose tuning pin is removed from the hole in the pinblock and fitted with a sheath. The addition of the sheath to the tuning pin enlarges the effective circumference of the tuning pin, ensuring that the tuning pin has a tighter fit in the hole in the pinblock when reinserted. This solution requires that the tuning pin, once fitted with the sheath, be hammered back into the pinblock. This is often undesirable, particularly when tuning antique or valuable instruments as the hammering can cause unintentional damage to the instrument. The vibrations caused by hammering in the tuning pin can also cause other tuning pins to move within the pinblock and result in the unwanted alteration of tension in other strings. The unwanted alteration of the tension of these strings subsequently needs to be corrected. This can be very time consuming if a loose tuning pin is only identified partway through the tuning process as the whole tuning process may have to begin again.
An alternative solution to inhibit the movement of tuning pins is the application of a liquid treatment to the pinblock. The liquid treatment causes the wood surrounding the hole in the pinblock to expand resulting in tighter fit between the tuning pin and the hole in the pinblock when the tuning pin is reapplied to the pinblock. This solution is not always appropriate, particularly when dealing with antique and valuable instruments as it may result in permanent, and undesirable changes to the way instrument sounds. This solution often also entails hammering of the tuning pin into the pinblock following the application of the liquid, resulting in the same problems as outlined above.
It is an aim of certain embodiments of the invention to mitigate the above problems by providing a tool for use during tuning of an instrument such as a piano that inhibits movement of tuning pins that are fitted in loose pin block holes and that at least partly overcomes the problems set out above.
The tool is named “Pin-Gripper”.
In accordance with a first aspect of the invention, there is provided a tool for fitting to a tuning pin of an instrument for inhibiting movement of the tuning pin. The tool comprises a tuning pin engaging portion comprising a through hole for engaging a tuning pin and one or more flexible resilient arms extending from the tuning pin engaging portion. The one or more flexible resilient arms configured, in use, to engage with other tuning pins adjacent to the tuning pin, and/or with the strings attached thereto, to inhibit movement of the tuning pin.
Optionally, the through hole is configured to engage with a piano tuning pin.
Optionally, the tool comprises a plurality of flexible resilient arms.
Optionally, the plurality of arms comprises at least two flexible resilient arms.
Optionally, each flexible resilient arm comprises a hook, each hook configured, in use, to engage with an adjacent string attached to an adjacent tuning pin.
Optionally, each flexible resilient arm comprises a resilient bend configured to engage with an adjacent tuning pin.
Optionally, each hook is tilted up from a plane of the flexible resilient arm.
Optionally, a first flexible resilient arm is a first length, and a second flexible resilient arm is a second length, said second length longer than the first length, the hook of said first flexible resilient arm configured, in use, to engage with a first string attached to the tuning pin to which the tool is engaged, and a said second string configured to engage with a second string attached to an adjacent tuning pin.
Optionally, the first flexible resilient arm is substantially 4 cm in length and the second flexible resilient arm is substantially 8 cm in length.
Optionally, the tuning pin engaging portion is provided by at least one coil of wire.
Optionally, the tuning pin engaging portion and plurality of flexible resilient arms are formed from a single length of wire.
Optionally, the through hole is tapered.
Optionally, the through hole has a substantially square, hexagonal, circular, or elliptical cross-section.
Optionally, the through hole is configured such that when fitted to a tuning pin, a suitable length of the tuning pin protrudes from the tool to allow a tuning lever to engage with the protruding section of the tuning pin.
Optionally, the flexible resilient arms further comprise a coiled region.
Optionally, the tuning pin engaging portion is formed from a main body and the flexible resilient arms extend outwards from the main body.
Optionally, a recess is provided surrounding the through hole on the tuning pin engaging portion configured to receive an insert, said insert comprising a further through hole for receiving a tuning pin.
Optionally, the tuning pin engaging portion further comprises grip screw extending into the through hole.
Optionally, the tuning pin engaging portion and plurality of flexible resilient arms comprise two single lengths of wire Optionally, the tuning pin tool further comprises a stabilising member.
Optionally, the stabilising member comprises: a plate having a central hole configured to receive a tuning pin and; at least one attachment means for attaching the stabilising member to the tuning pin tool.
Optionally, the one or more flexible resilient arms comprise metal wire.
Optionally, the metal wire is copper wire.
In accordance with a second aspect of the invention, there is provided a method of tuning an instrument string of an instrument, said method comprising: fitting a tool according to the first aspect to a first tuning pin of the instrument; placing a tuning lever on the first tuning pin and tuning a string connected to the tuning pin; tuning the string with the tuning lever; positioning the one or more arms of the tool to engage with further tuning pins adjacent to the first tuning pin, and/or with the strings attached thereto, to inhibit movement of the tuning pin when the tuning lever is removed, and removing the tuning lever.
Optionally, the method further comprises fitting a positioning piece onto the tuning pin before the fitting of the tool wherein the tool is positioned on top of the positioning piece.
Optionally, the method further comprises fitting a sheath onto the tuning pin before the fitting of the tool wherein the through hole of the tuning pin is positioned over said sheath.
Optionally, the instrument is a piano.
Optionally, the method further comprises the step of positioning hooks located on the flexible resilient arms of the tuning pin tool over the strings attached to neighbouring tuning pins.
In accordance with embodiments of the invention, a tuning pin tool is provided for inhibiting movement of a tuning pin during and after it has been tuned, for example, with a tuning lever. Tuning pin tools in accordance with embodiments of the invention, comprise a portion configured to engage a tuning pin and one or more flexible resilient arms extending from this portion.
The arms are configured such that they can be positioned to engage with adjacent tuning pins and/or strings attached to these tuning pins such that they inhibit movement of the tuning pin arising, for example, due to the rotational force applied to the tuning pin due to the tension in the string not being overcome by friction between the tuning pin and the material in which the tuning pin is mounted.
Use of such tools provides a method of inhibiting the movement of tuning pins in a pinblock that arises due to enlarged pinblock holes. Such a method does not require the use of liquid treatments and does not require loose tuning pins to be hammered.
Advantageously, such tuning pin tools can be left in-situ in and instrument, thereby prolonging the time that the corresponding strings are likely to remain in tune.
Advantageously, in certain embodiments, the tool comprises a tapered through hole ensuring the tool can be tightly fitted to a tuning pin
Various further features and aspects of the invention are defined in the claims.
Embodiments of the present invention will now be described by way of example only with reference to the accompanying drawings where like parts are provided with corresponding reference numerals and in which:
The pinblock 101 is typically situated behind a cast iron plate in an upright piano or underneath a cast iron plate in a grand piano. Tuning pins 102 are inserted in corresponding holes in the pinblock 101. Friction between the tuning pins 102 and the holes in which they are inserted generally inhibits movement of the tuning pins 102 unless manipulated with a tuning lever.
Typically, the pinblock 101 of a piano is manufactured from multiple layers of cross-laminated hardwood that has been glued and compressed. The holes in the pinblock are typically configured to have a slightly smaller diameter than that of the tuning pin 102 to be inserted into the hole to ensure a tight fit.
Piano tuning pins 102 are typically manufactured from steel and are substantially cylindrical at one end and have a substantially square or hexagonal cross-section at the opposite end shaped to be engaged by a tuning lever.
The substantially cylindrical end of a tuning pin 102 is typically at least partially threaded and is inserted into a hole in a pinblock 101. Threading on the substantially cylindrical end of the tuning pin further increases the friction between the tuning pin 102 and the hole in the pinblock 101. Piano strings are typically fitted to a piano relative to the orientation of the threading so that rotation of a tuning pin to tighten the string drives the tuning pin further into the pinboard.
The opposite end of the tuning pin 102 with the square or hexagonal cross-section protrudes out of the pinblock 101 and is such that it can be engaged by a tuning lever. In the middle of the tuning pin 102 there is a small through hole through which piano wire is threaded.
The soundboard 103 is a large thin wooden board typically constructed from multiple strips of wood that have been glued together. The soundboard 103 holds the bridge 104 which is also typically constructed from multiple layers of cross-laminated hardwood that has been glued and compressed. The soundboard 103 acts as an amplifier of the sound and the role of the bridge 104 is to connect the source of the sound (the strings 105) to the amplifier (the soundboard 103).
On the bridge 104, are multiple bridge pins 106. The bridge pins are small metal pins which hold the strings 105 in position on the bridge. Each string 105 is held in place by two bridge pins 106. The soundboard 103 also holds multiple hitch pins 107, the hitch pins 107 hold the strings at the distal end.
Piano strings are made from piano wire. To fit a string to a piano, first a length of piano wire is inserted through the tuning pin through hole. The piano wire is then coiled around the tuning pin two or three times and a protruding end of piano wire is bent inwards thereby holding it in place.
The fitting of a piano string is explained further with reference to
A string 105a, once threaded through a tuning pin 102a, is then extended over the sound bridge 104, where it is held in place by being inserted between a first pair of bridge pins 106a. The piano wire is then bent around a hitch pin 107. The length of piano wire between the first tuning pin 102a and the hitch pin 107, forms a first string 105a. The piano wire then extends from the hitch pin 107 to a second tuning pin 102b, so as to form a second string 105b, running substantially in parallel with the first string 105a.
The length of piano wire forming the second string 105b also passes over the bridge 104 and between a second pair of bridge pins 106b. The length of piano wire forming the second string 105b terminates at a second tuning pin 102b, where the length of piano wire is inserted through a through hole in the second tuning pin 102b and coiled around the second tuning pin 102b so as to form two or three coils.
Once the strings are fitted in place in a piano they are tuned. To tune each string, a tuning lever is used to rotate the tuning pins 102 and thereby tighten or loosen the strings 105 to which the tuning pins 102 are attached. Rotation of a tuning pin 102 in a first direction results in the tightening of the corresponding string (and thus increasing the pitch produced when the string is played) and rotation of a tuning pin 102 in a second direction results in the loosening of the corresponding string (and thus decreasing the pitch produced when the string is played).
As described above, enlarged pinblock holes make it more difficult to tune a piano because once a tuning lever has been used to apply the desired tension to a piano string by rotating a tuning pin and the tuning lever is removed from the tuning pin, the tuning pin is prone to move, thereby detuning the string that has just been tuned.
The tuning pin tool 200 comprises a main body which forms a tuning pin engaging portion 202 which typically comprises a suitable material such as steel, brass, chrome, or hardened plastic.
The tuning pin engaging portion 202 shown in
In the embodiment depicted in
Located centrally within the tuning pin engaging portion 202 is a through hole 201. The through hole 201 has a cross-section configured to receive the exposed portion of a piano tuning pin that has been inserted in a pinblock (the exposed portion being the portion that is engaged by the tuning lever).
In certain embodiments, the through-hole 201 is configured specially for tuning pins the exposed-in-use ends of which have a substantially square cross-section. In such embodiments, the through hole 201 has a cross-section that is substantially square.
In other embodiments, for tuning pins that have a substantially hexagonal cross-section for the end that is exposed in use, the through hole has a cross-section that is substantially hexagonal. This is depicted schematically in
In further embodiments, the through hole may have a cross-section configured to engage with different types of tuning pins, e.g. tuning pins that have a substantially hexagonal cross-section or have a substantially square cross-section. Such a cross-section may be “star” shaped. This is depicted schematically in
The through hole 201 is typically sized so that its diameter allows it to fit over, and slide down, the exposed part of a tuning pin. The thickness of a typical tuning pin increases down its length as the cross-section changes from being configured to engage with a tuning lever (e.g. square or hexagonal) to circular. The through hole 201 is typically sized so that as it is pushed down the length of the piano pin, it will engage with the tuning pin as it gets thicker thereby resulting in a secure friction fit between the piano pin and the tool.
To aid the formation of this secure friction fit, the through-hole may be tapered slightly. That is, an aperture on one face of the tuning pin engaging portion 202 has an area larger slightly larger than the aperture on the opposite face of the tuning pin engaging portion 204b.
The tuning pin tool 200 further comprises a plurality of flexible resilient arms 203 extending outwards from the tuning pin engaging portion 202. The flexible resilient arms 203 are thin, elongate projections made from flexible resilient material such as copper wire or steel wire. The flexible resilient arms 203 can be attached to the tuning pin engaging portion 202 by any suitable technique, for example the flexible resilient arms 203 may be fixed to the tuning pin engaging portion 202 by means of soldering. Alternatively, the flexible resilient arms 203 may be fixed to the tuning pin engaging portion 202 by fitting into holes on the body of the tuning pin engaging portion 202. In another example, one length of flexible resilient material may extend through a hole in the body of the tuning pin engaging portion 202 forming two flexible resilient arms 203 protruding from opposite areas of the body of the tuning pin engaging portion 202.
The flexible resilient arms 403 are comprised of the two ends of the wire. Each flexible resilient arm 403 comprises a recess 406 configured to securely fit around a neighbouring piano pin.
In certain embodiments, the tuning pin tool 400 may be provided with a stabilising member 407. The stabilising member 407 may be a plate, for example a thin metal plate, with a central hole for receiving the tuning pin 409. The stabilising member has a means for attaching to the tuning pin tool such as attachment hooks 408.
In certain embodiments, a plurality of tuning pin tools 400 may be fitted to a single tuning pin 400.
The flexible resilient arms 503 are formed from the two ends of the wire and each further form a recess 506, configured to fit to a neighbouring tuning pin. The tuning pin tool 500 is not provided with a stabilising member.
The first connecting point 602a further comprises two securing grips 605a, 605b, formed from a length of wire reaching around the connecting point 602a and wound together to secure the connecting point 602a. The second connecting point 602b also comprises two corresponding securing grips 605c, 605d.
The tuning pin tool shown in
When in use, the tuning pin tool 700 is fitted over a tuning pin with the grip screw 706 positioned so that it does not extend into the through hole 701 of the pin engaging portion 702. When the tuning pin tool 700 is correctly positioned on the tuning pin. The grip screw 706 is then rotated in the internally threaded hole 707 such that the grip screw 706 extends into the through hole 701 of the tuning pin engaging portion 702 until it contacts the tuning pin. In this way, the grip screw 706 is urged against the tuning pin such that a secure fit between the tuning pin and the tuning pin engaging portion 702 is provided.
In use, the insert 810 is positioned in the recess 809 on the tuning pin engaging portion 802. The tuning pin tool 800 and insert 810 are then positioned on the tuning pin such that, the face of the tuning pin engaging portion 802 holding the insert is placed over the tuning pin first (i.e. faces towards the pinboard). The insert 810 is configured to fit tightly into the recess 809 on the tuning pin engaging portion 802 such that it will not readily separate from the tuning pin engaging portion 802 when it is positioned over the tuning pin.
A section of a pinboard 901 is shown in which a tuning pin 902 is inserted and which is attached to a piano string 905 as described above.
During a typical tuning process, a piano tuner will identify tuning pins that are loose within the pin block. This is usually done by feeling or tapping each tuning pin.
If the piano tuner identifies that the tuning pin 902 is loose, as shown in
The piano tuner then turns the tuning lever 904 to rotate the tuning pin 902 to change the tension in the piano string 905 so that the piano string 905 generates the desired pitch when played.
When this has been done, to ensure that the tuning pin does not change position when the tuning lever 904 is removed, the piano tuner positions the flexible resilient arms 906 of the tuning pin tool 903 so that they engage with the protruding parts of adjacent tuning pins. The piano tuner can readily position the flexible resilient arms 906 because the arms 906 are flexible and resilient. Typically, the flexible resilient arms are appropriately positioned so that they impart a force on the tuning pin tool that inhibits rotational movement of the tuning pin engaging portion of the tool in a given direction. Typically, this is in the opposite direction to the rotational force imparted on the tuning pin due to tension in the piano string.
Accordingly, when the tuning lever 904 is removed, even if the through hole 907 in which the tuning pin 902 is inserted has become enlarged, rotational movement of the tuning pin 902 is inhibited thereby reducing the chance that the piano string 905 de-tunes.
In certain embodiments of the present invention, a positioning piece may be fitted to the tuning pin before the tuning pin tool to ensure the tuning pin tool is positioned on the tuning pin such that it will not come into contact with the piano string.
A section of a pinboard 1001 is shown in which a tuning pin 1002 is inserted and which is attached to a piano string 1005 as described above. In
In certain embodiments of the present invention, a sheath may be fitted to the tuning pin before the tuning pin tool to ensure the tuning pin tool is positioned on the tuning pin such that the tuning pin tool does not contact the strings. In certain embodiments where a tuning pin is substantially narrower than the through hole in the tuning pin engaging portion, a sheath may be fitted to the tuning pin such that a tighter fit is provided between the tuning pin and the tuning pin tool.
A section of a pinboard 1101 is shown in which a tuning pin 1102 is inserted and which is attached to a piano string 1105, as described above. In
Tension in the piano string generally imparts an anti-clockwise rotational force on the tuning pin 1202. In a tuning pin that is tightly fitted in a non-enlarged pinboard hole, this force is resisted by the friction between the tuning pin and the pinboard hole. However, in an enlarged hole, the friction is reduced which may lead to the tuning pin rotating in the direction of this force during a tuning process once the tuning lever has been removed.
To resist this the flexible resilient arms 1203a, 1203b, 1203c, 1203d of the tool 1201 are selectively positioned to engage with adjacent tuning pins. In the example shown in
Once the tool 1201 has been thus positioned it can be left in place.
As will be understood, multiple tools in accordance with embodiments of the invention can be fitted to an instrument to inhibit the movement of tuning pins.
In the examples described above, the tool has been shown with four resilient arms. However, in other embodiments, tools with different numbers of arms can be provided.
The tuning pin tool 1500 is formed from a single piece of wire. A coil of the single piece of wire forms a tuning pin engaging portion 1502 which comprises a through hole 1501 configured to receive a tuning pin.
Extending from the tuning pin engaging portion 1502 are elongate lengths of wire forming flexible resilient arms 1503a, 1503b. Each flexible resilient arms 1503a, 1503b includes a resilient bend. The flexible resilient arms 1503a, 1503b extend from the coil forming the tuning pin engaging portion in substantially opposite directions and are of substantially the same length.
Each flexible resilient arm 1503a, 1503b is a continuation of one end of the single piece of wire. A hook 1504a, 1504b is located at the distal end of each flexible resilient arms 1503a, 1503b. The hooks 1504a, 1504b are configured to engage with the neighbouring piano strings.
In certain examples, the flexible resilient arms 1503a and 1503b are substantially 8 cm in length.
The tuning pin tool 1500 is positioned on a tuning pin 1600 of a pin board and the flexible resilient arms 1503a, 1503b are positioned around adjacent pins 1601, 1602 using the resilient bend in each flexible resilient arm 1503a, 1503b. As can be seen from
Each hook 1504a, 1504b is then hooked around an adjacent string 1603a, 1603b. Typically each hook 1504a, 1504b goes under then over each adjacent string 1603a, 1603b. Typically, the pivot point formed by the resilient bend engaging with the adjacent pin, gives rise to a force which urges each hook 1504a, 1504b against the string with which it is engaged.
As will be understood, the tuning pin tool, thus arranged, imparts a force on the tuning pin 1600 to inhibit its rotation.
In keeping with the embodiment describe with reference to
In contrast to the embodiment described with reference to
The tuning pin tool described with reference to
The tuning pin tool 1700 is positioned on a tuning pin 1800 of a pin board which is situated at the edge of the pin board. The hook 1704a of the shorter of the two flexible resilient arms 1703a is configured to engage with the string 1801 of the pin 1800 to which the tool 1701 is attached. The longer of the two flexible resilient arms 1703b is guided around the tuning pin 1800 to which the tuning pin tool 1700 is attached and the hook 1704b of this arm 1703b is then hooked around the string 1802 of an adjacent pin 1803.
As will be understood, the tuning pin tool 1800, thus arranged, imparts a force on the tuning pin 1800 to inhibit its rotation.
As described above, in certain embodiments of the invention, a hook is provided at the distal end of the flexible resilient arms of the tuning pin tool.
As can be seen from
In certain embodiments, this results in a hook with an angle relative to the plane of the flexible resilient arm 1902 of approximately 30 degrees.
Advantageously, as shown in
In the embodiments described, for example, with reference to
The skilled person will understand that the tuning pin tools arranged in accordance with the embodiments described with reference to
In the examples described with reference to
Tools in accordance with embodiments of the invention can be used with any suitable instrument comprising a plurality of adjacent tuning pins mounted to a pinboard. Examples include harpsichords, virginals, harps, and spinets.
Tuning pin tools in accordance with certain embodiments of the invention can be adapted for use with other stringed instruments such as violins and guitars in which the tuning pins are provided by tuning pegs.
In the embodiments described with reference to
Typically, the tuning pin engaging portion formed from the coil of wire in the embodiments described with reference to
Typically, the coil of wire forming the tuning pin engaging portion in the embodiments described with reference to
In certain embodiments, the coils of the coil of wire may form a spring-like configuration.
Typically, tuning pin tools in accordance with embodiments of the invention comprises a plurality (two or more) flexible resilient arms. However, in certain embodiments, a tuning pin tool may be provided, corresponding to the tuning pin tool described with reference to
Tools in accordance with embodiments of the invention can be manufactured by any appropriate method. The skilled person would understand that such methods include but are not limited to 3D printing. Tuning pin tools in accordance with embodiments of the invention may be mass-manufactured by automated means or alternatively, manufactured by manual means. Embodiments in which the tuning pin tool is made from a single length of wire may be particularly easily manufactured at low cost.
The wire from which the tuning pin tools described with reference to
Advantageously, embodiments in which the tuning pin engaging portion of the tuning pin tool comprise a coil of wire (as described, for example, with reference to
In the examples shown in
All of the features disclosed in this specification (including any accompanying claims, abstract and drawings), and/or all of the steps of any method or process so disclosed, may be combined in any combination, except combinations where at least some of such features and/or steps are mutually exclusive. Each feature disclosed in this specification (including any accompanying claims, abstract and drawings) may be replaced by alternative features serving the same, equivalent or similar purpose, unless expressly stated otherwise. Thus, unless expressly stated otherwise, each feature disclosed is one example only of a generic series of equivalent or similar features. The invention is not restricted to the details of the foregoing embodiment(s). The invention extends to any novel one, or any novel combination, of the features disclosed in this specification (including any accompanying claims, abstract and drawings), or to any novel one, or any novel combination, of the steps of any method or process so disclosed.
With respect to the use of substantially any plural and/or singular terms herein, those having skill in the art can translate from the plural to the singular and/or from the singular to the plural as is appropriate to the context and/or application. The various singular/plural permutations may be expressly set forth herein for sake of clarity.
It will be understood by those within the art that, in general, terms used herein, and especially in the appended claims are generally intended as “open” terms (e.g., the term “including” or “comprising” should be interpreted as “including but not limited to,” the term “having” should be interpreted as “having at least,” the term “includes” should be interpreted as “includes but is not limited to,” etc.). It will be further understood by those within the art that if a specific number of an introduced claim recitation is intended, such an intent will be explicitly recited in the claim, and in the absence of such recitation no such intent is present. For example, as an aid to understanding, the following appended claims may contain usage of the introductory phrases “at least one” and “one or more” to introduce claim recitations. However, the use of such phrases should not be construed to imply that the introduction of a claim recitation by the indefinite articles “a” or “an” limits any particular claim containing such introduced claim recitation to embodiments containing only one such recitation, even when the same claim includes the introductory phrases “one or more” or “at least one” and indefinite articles such as “a” or “an” (e.g., “a” and/or “an” should be interpreted to mean “at least one” or “one or more”); the same holds true for the use of definite articles used to introduce claim recitations. In addition, even if a specific number of an introduced claim recitation is explicitly recited, those skilled in the art will recognize that such recitation should be interpreted to mean at least the recited number (e.g., the bare recitation of “two recitations,” without other modifiers, means at least two recitations, or two or more recitations).
It will be appreciated that various embodiments of the present disclosure have been described herein for purposes of illustration, and that various modifications may be made without departing from the scope of the present disclosure. Accordingly, the various embodiments disclosed herein are not intended to be limiting, with the true scope being indicated by the following claims.
Number | Date | Country | Kind |
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1914298 | Oct 2019 | GB | national |
1916642 | Nov 2019 | GB | national |
PCT/GB2020/052434 | Oct 2020 | WO | international |
Filing Document | Filing Date | Country | Kind |
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PCT/GB2020/052447 | 10/5/2020 | WO |
Publishing Document | Publishing Date | Country | Kind |
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WO2021/064429 | 4/8/2021 | WO | A |
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107391 | Lindsay | Sep 1870 | A |
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982425 | Gotterke | Jan 1911 | A |
1094653 | Hillcoat | Apr 1914 | A |
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3754494 | Ticehurst | Aug 1973 | A |
4509399 | McKibben | Apr 1985 | A |
5869780 | Lim | Feb 1999 | A |
11380289 | Jenson | Jul 2022 | B1 |
Number | Date | Country |
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246801 | Nov 1911 | DE |
2793936 | Nov 2000 | FR |
2587673 | Apr 2021 | GB |
WO-2021064429 | Apr 2021 | WO |
Number | Date | Country | |
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20240054977 A1 | Feb 2024 | US |