ITBO20110203A1 - BRIDGE FOR ROPE MUSICAL INSTRUMENTS - Google Patents

Description

DESCRIPTION

of the patent for Industrial Invention entitled:

â € œBRIDGE FOR STRING MUSICAL INSTRUMENTSâ €

The present invention relates to a bridge for stringed musical instruments. One of the peculiarities of the present invention relates to the possibility of simultaneously adjusting the distance between the strings. In fact, as is well known, the need to produce electric basses with string spacing according to the customer's needs is increasingly felt (this is especially true for lutherie instruments). Currently the manufacturers of electric basses produce instruments with different fixed spacing and without any possibility of adjusting the pitch between contiguous strings. It is evident that in case of pickup change it is necessary to adapt the spacing of the strings so that each string is associated with the magnet or magnets of the corresponding pickup.

In particular, the present invention finds advantageous, but not exclusive application in electric basses, to which the following description will make explicit reference without thereby losing generality.

As is known, a generic electric guitar, and in particular an electric bass, comprises a main body and a neck. The strings extend along the surface of the neck from the tuners placed on the headstock to the locking on the bridge at the other end of the main body.

A nut supports the strings at the bottom of the neck on the headstock side, while the bridge supports the same strings at the other end in order to allow the strings themselves to be stretched so that they can vibrate to generate the desired sounds.

In this type of electric guitar the intonation of the guitar is obtained more or less by wrapping one end of each string on the corresponding shaft of the tuning mechanism, in order to control the tension applied to the string itself.

There are several ways to modify:

- the mutual distance between the strings;

- the distance between the nut and the bridge, a distance that is called â € œdiapasonâ € in jargon; note that the length of the tuning fork in general differs from string to string to take into account the diameter of each string; And

- the height of the strings with respect to the surface of the neck, in order to prevent the strings from rubbing on the neck and / or on the frets during their vibrations for some reason.

For example, one of the most adopted systems to regulate the distance between the strings consists in interchanging a bridge with another naturally of different spacing between the strings. Consequently, it is necessary to have several bridges each with a fixed but always fixed spacing. There are also bridges defined by single elements on the market that must be mounted directly on the instrument with a certain spacing that is no longer adjustable.

Therefore, the object of the present invention is to provide a bridge for stringed musical instruments which is free from the drawbacks described above and, at the same time, is easy and economical to make.

According to the present invention, therefore, a bridge for stringed musical instruments is produced according to what is claimed in claim 1 or in any of the claims directly or indirectly dependent on claim 1.

For a better understanding of the present invention, two preferred embodiments are now described, purely by way of non-limiting examples and with reference to the attached drawings, in which:

Figure 1 illustrates a three-dimensional assembly of a first embodiment of a bridge for stringed musical instruments made according to the teachings of the present invention;

Figure 2 shows an exploded view of the assembly of Figure 1;

Figure 3 shows a partially sectioned plan of the assembly of Figure 1;

- figure 4 shows a section A-A taken on the plan of figure 3;

- figure 5 shows a section B-B taken on the plan of figure 3;

Figure 6 shows in plan a first configuration of some elements belonging to the bridge for stringed instruments of Figure 1;

Figure 7 is a plan view of a second configuration of some elements belonging to the bridge for stringed instruments of Figure 1;

figure 8 shows an exploded view of a second embodiment of the bridge for stringed instruments object of the present invention;

- figure 9 shows in plan a first configuration of some elements belonging to the bridge for stringed instruments of figure 8; And

Figure 10 is a plan view of a second configuration of some elements belonging to the bridge for stringed instruments of Figure 8.

In Figures 1, 2, the number 10 indicates, as a whole, a bridge for stringed instruments made according to the teachings of the present invention.

In this case, bridge 10 is suitable for receiving four strings (STR1), (STR2), (STR3), (STR4) (figure 1) for example for a four-string electric bass.

As shown in particular in Figure 2, the bridge 10 comprises an external frame 20 with a frame to which a base plate 21 is fixed by means of two screws 151 and relative centering pins 152 so as to allow perfect alignment of the external frame 20 with the same base 21. Once all the components have been assembled, the bridge 10, in turn, is locked onto the main body (not shown) for example of an electric bass guitar.

As shown in particular in Figure 2, the external fixed frame 20 is substantially rectangular in shape and comprises two sides 20A *, 20A ** which are longer than two transverse sides 20B. It should be noted that both transverse sides 20B are crossed by a through hole 22 of axis (X) for purposes which will be specified more fully in the following. Of course, the frame 20 could be of different shapes and for example with a circular peripheral development.

Side 20A **, which is the furthest away from the nut (not shown) has four shaped recesses 23, 24, 25, 26.

Each shaped recess 23, 24, 25, 26, in turn, provides for a relative narrowing shoulder 23A, 24A, 25A, 26A, on which, in use, the relative rope (STR1), (STR2), (STR3 ), (STR4) (figure 1).

In a known way, one end of each string (STR1), (STR2), (STR3), (STR4) which is located in correspondence of bridge 10 is provided with a respective eyelet (OCH1), (OCH2), (OCH3), (OCH4), which, in use, remains locked in the respective shaped recess 23, 24, 25, 26 (see below).

In other words, for example, the terminal part of the string (STR1) rests on the relative narrowing shoulder 23A, while the relative eyelet (OCH1) is received in the respective shaped recess 23. When the string (STR1) is pulled by the shaft of the tuning mechanism (not shown) the eyelet (OCH1) is locked in the respective recess 23.

The same observations apply to the other strings (STR2), (STR3), (STR4).

Furthermore, side 20A ** provides four through holes 43, 44, 45, 46 for purposes that will be clarified below.

The free space inside the external frame 20 is occupied by four movable internal frames 51, 52, 53, 54, placed side by side, one for each string (STR1), (STR2), (STR3), (STR4).

The movable inner frame 51 is identical to the movable inner frame 52, while the movable inner frame 53 is identical to the movable inner frame 54. Furthermore, the pair of movable inner frames 54, 53 is so to speak â € “specular” with respect to the pair of movable internal frames 51, 52.

For these reasons, by now describing in detail the mobile internal frame 51, both the mobile internal frame 52 will be described, which as we have said is identical to the internal monili frame 51, which, taking into account the orientation of some elements, also the others two movable internal frames 53, 54, which are identical to each other.

Again with reference to Figure 2, the movable internal frame 51 is substantially rectangular in shape. A separating wall 51A divides the internal frame 51 into a first hollow section 61 and into a second hollow section 62. The first hollow section 61 is crossed by the aforementioned through hole 22 of axis (X), while the second hollow section 62 provides a slot 62A and a through hole 62B close thereto. The through hole 62B has an axis (Y1) substantially perpendicular to the aforementioned axis ((X). On the separating wall 51A there is a notch 51B in correspondence with the axis (Y1).

As we have said, similar considerations could be made for the other three internal frames 52, 53, 54. However, these considerations are not made in order not to burden the present description.

The first hollow section 61 is designed in such a way as to accommodate a nut screw element 71 inside, while in the second section 62, in use, there are a driving element 81, and a respective saddle 91 coupled together by a respective coupling dovetail (CR). The second hollow section 62 includes further dragging means 82, 83 and 84 and respective saddles 92, 93 and 94, so that the description of the coupling between the element 81 and the corresponding saddle 91 also applies to the coupling between elements 82, 83 and 84 and the corresponding saddles 92, 93 and 94.

As shown again in figure 2, the driving element 81 is in turn crossed by a threaded through hole 81A, whose axis, in use, is precisely the aforementioned axis (Y1). In turn, the saddle 91 has a threaded through hole 91A, with axis (Z1). Note that the (Z1) axis is substantially perpendicular to the plane identified by the (X) and (Y1) axes.

A fundamental element of the present invention is constituted by the multi-threaded screw with variable pitch 100.

The screw 100, which can be rotated by means of an Allen key (not shown) is housed in the through hole 22 of axis (X), and is coupled simultaneously with the threads (or with the teeth) present in the nut elements 71, 72 , 73, 74. In fact, for this purpose the multi-threaded screw with variable pitch 100 is provided with a first left-hand threaded section 101, in engagement with the thread (or with the teeth) of the nut element 71, followed by a second left-hand threaded section 102 coupled with the nut screw element 72.

Note that in the case shown in figure 2 the pitch of the first left-hand threaded section 101 is triple the pitch of the second left-hand threaded section 102. Similarly, on the other hand, the screw 100 provides a third right-hand threaded section 104 and a fourth right-hand threaded portion 103, each threaded portion being coupled, respectively, with the nut element 74 and with the nut element 73. Also in this case the pitch of the third right-hand threaded section 104 is triple the pitch of the second right-hand threaded section 103.

This means that a complete turn of the screw 100 will correspond to a displacement according to an arrow (F1) of three linear units of the nut screw element 71, with a displacement (always according to the arrow (F1) of a linear unit of the element nut 72. There will therefore be a relative displacement of the nut element 71 by two linear units with respect to the nut element 72.

Similarly, with one turn of the same screw 100, the nut element 74 moves according to the arrow (F2) (opposite the arrow (F1)) by three linear units, while the nut element 73 moves at the same time by one unit linear (always according to the arrow (F2)). Since the nut element 72 has moved by one unit according to the arrow (F1), and the nut element 73 has also translated by one unit but in the direction identified by the arrow (F2), ultimately also the two lead screw elements 72, 73 have moved by two linear units with respect to each other.

In this way all four nut elements 71, 72, 73, 74 move by two linear units with respect to each other at each complete turn of the screw 100. It is obvious that the direction (arrow (F2 )) of the displacements of the nut elements 74 and 73 is opposite to that of the displacements of the nut elements 71, 72 (arrow (F1)) due to the fact that the threaded portions 104, 103 are right-handed, while the threaded portions 101, 102 they are left-handed.

Always referring to the movable internal frame 51 for convenience (but the same observations apply to the movable internal frames 52, 53, 54), it can be noted that the displacement according to the arrow (F1) of the nut element 71 involves a similar translation of the The entire internal movable frame 51 (dragged by the nut screw element 71 housed, as mentioned, in the first hollow section 61) and all the other elements contained in this internal movable frame 51. In this case, in addition to the aforementioned nut element 71, translate both the driving element 81 and the saddle 91 coupled to it by means of the relative dovetail (CR). Therefore the string (STR1) also moves (always according to the arrow (F1)).

Figure 6 illustrates the condition in which the four movable internal frames 51, 52, 53, 54 are placed side by side and therefore the distance between the strings (STR1), (STR2), STR3), (STR4) is minimal. On the other hand, Figure 7 shows the situation in which each movable internal frame 51, 52, 53, 54 assumes the maximum distance from the contiguous one / s. The latter is obviously the case when the musician wishes to have the maximum distance between the strings (STR1), (STR2), STR3), (STR4). It is also obvious that it is possible to have all the intermediate situations placed between the two extreme positions illustrated in figures 6, 7 by graduating the rotation of the screw 100.

Normally in a four-string bass the minimum distance between the strings (STR1), (STR2), STR3), (STR4) (see figure 6) is 17 mm, while in the configuration illustrated in figure 7 the maximum distance between the strings strings (STR1), (STR2), STR3), (STR4) is 20 mm. Therefore, by means of the system illustrated here, in a four-string bass the distance between the strings (STR1), (STR2), STR3), (STR4) themselves can vary from a minimum of 16.5 mm to a maximum of 20, 5 mm thus increasing the range of spacings obtainable.

As previously mentioned, in addition to the aforementioned distance between the strings (STR1), (STR2), STR3), (STR4) it is also possible to vary the tuning fork of each string.

In fact, the through hole 62B is crossed by a screw 111, which is screwed into the threaded through hole 81A made, as we have said, in the driving element 81. By rotating the screw 111 in one direction or another it is possible to make the driving element 81 and the saddle 91 coupled to it move in a direction (F3) (figure 2). Moving the saddle 91 on which the string (STR1) rests according to the arrow (F3) means varying the tuning fork of the string (STR1) itself. It is obvious that this last displacement is possible only because there is a certain play between the drag element 81 and the saddle 91, on the one hand, and the walls of the second section 62, on the one hand. other.

A third and final adjustment that can be performed in the bridge 10 object of the present invention is that which concerns the height of each string (STR1), (STR2), STR3), (STR4) with respect to the base 21.

In fact, for this purpose, a respective threaded dowel 121 (of axis (Z1)) is screwed into the threaded through hole 91A made in the saddle 91 (Figure 2). By screwing or unscrewing the threaded dowel 121, it is possible to move the saddle 91 alone, up or down depending on the direction of rotation of the threaded dowel 121 (which slides vertically on the corresponding driving element 81 thanks to the existence of the respective coupling dovetail (CR)) according to an arrow (F4) with a consequent raising / lowering of the point of contact of the string (STR1) with the respective saddle 91. In this way, as has been said, it is possible to vary the € ™ height of the rope (STR1) from the base 21.

According to a further embodiment of the present invention illustrated in figures 8, 9, 10, in which the corresponding elements are indicated with the same numbers and abbreviations of figures 1-7, the screw 100 has a fifth section 105 without thread which passes through idle through a fifth fixed internal frame 55. This fixed internal frame 55 will therefore always remain stationary and integral with the base 21, while the other movable internal frames 101, 102, 103, 104 will move according to the mechanism illustrated in relation to the first embodiment according to figures 1-7.

The main advantage of the bridge object of the present invention is represented by the fact that through a single screw it is possible to carry out all the adjustments of the mutual distance between the strings of an instrument at the same time without having to replace the bridge itself and therefore make other fixing holes on the body of the instrument, at the same time, in case of replacement of the pickups (not shown) it will be possible to easily proceed with the adjustment of the spacing of the strings (in these cases of modest size, typically between a few tenths of a millimeter and reveals necessary to make the string coincide with the pickup magnet.

Claims (14)

CLAIMS 1. Bridge (10) for stringed musical instruments ((STR1), (STR2), STR3), (STR4), (STR5)); bridge (10) comprising: - a fixed external frame (20) containing inside it saddle means (81, 91; 82, 92; 83, 93; 84, 94; 85, 95) relating to each string ((STR1), (STR2), STR3), (STR4), (STR5)); said saddle means (81, 91; 82, 92; 83, 93; 84, 94, 85, 95) being able to be moved transversely ((F1), (F2)) with respect to said cords ((STR1), ( STR2), STR3), (STR4), (STR5)) in order to allow the adjustment of the mutual distance between the strings ((STR1), (STR2), STR3), (STR4) (STR5)) themselves; And - screw means (100) suitable for carrying out the transverse displacement ((F1), (F2)) of said saddle means (81, 91; 82, 92; 83, 93; 84, 94); bridge (10) characterized by the fact that each string ((STR1), (STR2), STR3), (STR4), (STR5)) rests on respective saddle means independent from each other, and by the fact that at least some of said saddle means (81, 91; 82, 92; 83, 93; 84, 94, 85, 95) are approached / removed from each other by means of a single screw (100) provided with threaded portions (101, 102, 103, 104) having, in general, different winding directions and different pitches. 2. Bridge (10), as claimed in claim 1, characterized by the fact that said external fixed frame (20) contains inside it a plurality of internal frames 51, 52, 53, 54, 55) placed side by side. ™ other, one for each string ((STR1), (STR2), (STR3), (STR4), (STR5)). Bridge (10), as claimed in claim 2, characterized in that at least some of said internal frames (51, 52, 53, 54) are transversely movable ((F1), (F2)) with respect to said fixed external frame (20). Bridge (10), as claimed in any one of the preceding claims, characterized in that said external fixed frame (20) is substantially rectangular in shape and comprises two sides (20A *, 20A **) longer than two transverse sides (20B); both transverse sides (20B) being crossed by a through hole (22) of axis (X). 5. Bridge (10), as claimed in claim 4, characterized in that said side (20A **), which is the furthest from the nut, has shaped recesses (23, 24, 25, 26, 27) ; each shaped recess (23, 24, 25, 26, 27) providing, in turn, a relative narrowing shoulder (23A, 24A, 25A, 26A, 27A) on which the relative rope ((STR1), (STR2) rests ), (STR3), (STR4), (STR5)). 6. Bridge (10), as claimed in any one of 3-5, characterized in that at least some of said internal frames (51, 52, 53, 54) comprise respective lead screw elements (71, 72, 73, 74) , which are meshed with corresponding threaded portions (101, 102, 103, 104) belonging to said single screw (100). Bridge (10), as claimed in claim 6, characterized in that each of said internal frames (51, 52, 53, 54, 55) further comprises a respective driving element (81, 82, 83, 84 , 85) coupled with a respective saddle (91, 92, 93, 94, 95) adapted to support a respective string ((STR1), (STR2), STR3), (STR4), (STR5)). Bridge (10), as claimed in claim 7, characterized in that said coupling is a dovetail coupling (CR). 9. Bridge (10), as claimed in any one of the preceding claims, characterized in that, in the case of a four-stringed instrument (STR1), (STR2), STR3), (STR4), said screw (100) Ã It has two left-hand threaded portions (101, 102) and two right-hand threaded portions (104, 103). Bridge (10), as claimed in any one of claims 1-8, characterized in that, in the case of a five-stringed instrument, said screw (100) is provided with two left-hand threaded portions (101, 102), two right-hand threaded portions (104, 103), and one portion (105) without thread. Bridge (10), as claimed in claim 9 or claim 10, characterized in that the pitch of two threaded portions (101, 104) is an integer multiple of the pitch of the other two threaded portions (102, 103). Bridge (10), as claimed in claim 11, characterized in that the pitch of said threaded portions (101, 104) is three times larger than the pitch of the other two threaded portions (102, 103). Bridge (10), as claimed in claim 7, characterized in that each driving element (81, 82, 83, 84, 85), coupled with a respective saddle (91, 92, 93, 94, 95), It is able to move in a direction (F3) such as to vary the tuning fork of the respective string ((STR1), (STR2), STR3), (STR4), (STR5)). 14. Bridge (10), as claimed in claim 7, characterized by the fact that each saddle (91, 92, 93, 94, 95) is able to move in a direction (F4) to vary the height of the respective chord ((STR1), (STR2), STR3), (STR4), (STR5)) with respect to a fixed element (21).