ES1058429U - Pulse instrument such as a guitar with modulation plate. (Machine-translation by Google Translate, not legally binding) - Google Patents

Abstract

Pulse instrument, such as a guitar with modulation plate (1), with a soundboard (3), which has an upper table or soundboard (2) and a mast (4) fixed to the soundboard (3), as well as with several strings (5) that can be tensioned and that run between the sound box (3) and the mast (4), the strings (5) being fixed by their first end (6) on the upper table (2) of the resonance box (3) in a joint support and support bridge (7), and by its second end (8) fixed to the mast (4), characterized in that the support and support bridge (7) ) is located on a modulation plate (9) made in the upper table (2), the modulation plate (9) having a thickness greater than that of the upper table (2). (Machine-translation by Google Translate, not legally binding)

Description

Pulse instrument, such as a guitar with modulation plate.

The present invention relates to an instrument pulse, such as a guitar, with a soundboard which presents a top board (harmonic cover) and a mast or neck attached to the soundboard, as well as several strings that they can be tensioned between the soundboard and the mast, being fixed the ropes by its first end on the upper board of the soundboard in a common support and support bridge, and They are fixed by its second end on the neck.

This kind of pulse instruments is found impaired in terms of acoustic volume in orchestras with arc instruments, in which the tone is generated from a long and persistent vibration impulse, since in the pulse instruments only a brief impulse is produced by being pressed only briefly.

In the patent CH 135 499 C a state is described of the technique quite far. This state of the art refers exclusively to bow instruments, and as for this invention It results from another type. In bow instruments, the strings go fixed or forwarded on a clamping line and on a bridge support, as physically independent components, serving the support bridge for the return of the ropes in the direction of the clamp, resting on the upper table of The soundboard. The holding line itself is located in the area of the edge of the soundboard and generally  positively hug the edge area to transmit tension from the strings to the soundboard. According to the known publication, in all kinds of bow instruments, exclusively the support bridge that guides the ropes must be fixed on the soundboard of the instrument by means of a base or modulation plate of another material, to perfect the sound of the strings of the instrument. The basis for the bridge support can present the shape of a circular, oval insert, rectangular, elongated or otherwise.

A state of the art closest to the invention, with a resonance plate for both instruments pulse-like arc, which should produce improved acoustic quality compared to solid wood resonance plates of Traditional manufacturing, is described in DE 201 13 495 U1. This publication is known to build by minus one of the two resonance plates of the soundboard in a fiber composite construction, consisting of the resonance plate of a core plate and a coating of long fibers embedded in a support material, provided at least in the area of one of the two outer faces of the plate core. The core plate presents within the area limited by the  resonance plate contour at least one empty surrounded through the material areas of the core plate. Is empty supposes a maximum of 80% of the total volume of the core plate filled by the material.

The measures proposed in the publications before described, however, have not resulted in increased radiation Acoustic pulse instrument.

For this reason, the invention was proposed as aim to improve the acoustic radiation emitted by pulse instruments, in terms of acoustic volume and quality of sound.

This objective is resolved in accordance with the invention when the support and support bridge is located on a modulation plate made in the table above, presenting the modulation plate a thickness less than the table higher.

In the pulse and arc instruments, the sound is generated by the vibrating string and is amplified by the box of resonance. To this end, the soundboard should present a relatively large mass, so that the soundboard represent a system of inertia. Instead, according to the invention, the modulation plate, which is excited by the ropes through the support and support bridge, it vibrates due to its lower oscillating mass, thus achieving a clean separation of the sounds The transmission of the vibrations of the strings to the modulation plate, which occurs almost without losses, only it is possible to be arranged the common bridge of support and support on the modulation plate.

A reduced oscillating mass and behavior favorable vibration can be achieved effectively thanks to the reduced thickness of the modulation plate compared to the upper table or with respect to the whole soundboard. The upper table generally has a thickness of 2.5 mm, while the modulation plate must have, according to a preferred form of the invention, a thickness of 0.8 to 1.6 mm. They have obtained particularly good acoustic results with a Modulation plate thickness of 1.4 mm. Plate thickness of modulation you can choose everything constant regardless of the material thickness of the upper table.

Depending on the dimensions of the plate modulation can influence the frequency range during the Pulse instrument manufacturing. A modulation plate large allows to generate serious sounds, and with a plate of Modulation of small geometric dimensions can be performed treble tones Therefore, the dimensions of the plate modulation is a compromise solution with a view to the range of frequencies with which in the future you can play with the pulse instrument, which should cover a range of 800 Hz to 15,000 Hz.

In an advantageous embodiment, the plate Modulation has a convex domed shape. Unlike the bow instruments, in the pulse instruments the strings go fixed at one end on the upper table of the box resonance, and they are not simply supported. For this reason, about the modulation plate not only acts a tightening force perpendicular on this but also a tipping moment resulting from the tension of the strings exerted on the bridge of support and support, which must be supported by the modulation. This tipping moment results in the side of the force transmission to the support and support bridge occurs an increase in the clamping force exerted on the plate modulation, and on the opposite side, to a tensile force additional. With a usual initial string tension of 500 Newton and with the usual lever ratios, resulting from the height of the point of attack of the ropes on the support and support bridge, it produce on the modulation plate some efforts that, in the in case the modulation plate is too sized thin can lead to the sinking of the support and support bridge in that. This problem can be also solve with a thicker plate material modulation, but this would reduce acoustic properties positive modulation plate Thanks to the convex bulging of the modulation plate, the forces are transmitted outwards through the side flanks of the convex bulge, so that the modulation plate can be made relatively thin, and with it the acoustic properties and the sound radiation

The modulation plate can preferably go pasted on the table above. In this way a union is obtained of the material, with a uniform and large surface incorporation between the modulation plate and the upper table. Alternatively, the modulation plate can also be attached to the lid higher.

As building materials for the plate Modulation are preferably considered wood or plastic. Whether use wood, it should be a solid wood, such as fir or other coniferous wood.

It has also been convenient to provide the plate of modulation by its inferior face of a bracing. East bracing gives greater rigidity to the modulation plate, but with a mass smaller than that of a solid modulation plate than in its set was thicker.

The bracing can be done in the form of grid, the shape of the grid being especially convenient, rectangular. It is understood by rectangular grid several bracings that intersect and that cut each other forming an angle of approximately 90 °.

The grid preferably comprises several bridges, with the bridges in its central zone being the thickest, finishing thinner on both sides. As material for bridges is especially suitable raft wood. The bridges are stuck all over their surface on the underside of The modulation plate. The bridges preferably end at the edge area of the modulation plate, and do not overlap it, with what which simplifies the placement of the modulation plate.

Bridges can carry a coating of a carbon fiber layer The carbon fiber layer will be preferably applied on the face away from the plate modulation. The thickness of the carbon fiber layer can be constant over the entire length of the bridge.

The bridges are conveniently oriented forming angle to the grain of the wood of the plate modulation and / or the grain of the upper table. In this way, it manages to give rigidity to the modulation plate also in a direction in which the wood material presents by nature less resistance

On the pulse instruments with a table wood top, the wood of the top board can have the oriented grain parallel to the grain of a modulation plate made of wood. The wood for the top board is also preferably a coniferous wood, in particular wood of fir tree. The modulation plate can be made of it wood. Since the mechanical load capacity and therefore also the behavior of wood vibrations depends on the orientation of the grain, that is, of the orientation of the fibers of wood, grain orientation of the modulation plate should match the grain orientation of the table higher. When the grain is interrupted between the upper table and the modulation plate produces a marked improvement in acoustic properties

The invention is described below with greater detail using a set of five drawing figures. The Figures show the following:

Figure 1: Front perspective view of a guitar with modulation plate;

Figure 2: Longitudinal section through the guitar through the A-A line of the figure two;

Figure 3: view according to figure 2, with the plate of modulation stuck on the upper table;

Figure 4: view according to figure 2, with a plate convex modulation;

Figure 5: Front view in enlarged perspective of a soundboard with modulation plate, and

Figure 6: section through a plate convex modulation with bracing.

Figure 1 shows in a front view in perspective a guitar (1) according to the invention, with a box of resonance (3) to which a mast (4) is attached. From the box of resonance (3) the strings (5) pass until the end of the mast (4). On the soundboard (3), the strings (5) go fixed by its first end (6) in a support and support bridge common (7). The tuning of the guitar is done through the pins (23), in which the second is housed respectively end (8) of the strings (5), and by which you can adjust the tension of each of the strings (5).

The soundboard (3) carries on the face bottom (26) a resonance background (24) that is not visible in the Figure 2 (see Figure 2) and a resonance side (25) perpendicular around its outer edge. On the face upper (27), the soundboard (3) is closed by a lid upper (harmonic cover) (2), with the exception of the tarraja (28).

Placed in the table above (2) you can see the modulation plate (9), on which the joint bridge is fixed of support and support (7). The modulation plate (9) is shaped oval, the support and support bridge (7) being located in a central area of the modulation plate (9).

Figure 2 shows the guitar (1) in a longitudinal section. The modulation plate (9) is made as a flat plate, and ends at the upper face (27) to make with the upper table (2). The thickness (10) of the modulation plate (9) is considerably less than the thickness (11) of the table upper (2).

The fixing of the modulation plate (9) is performed by means of a glued joint, for which it is saw first in the upper table (2) a hole in the area of the future modulation plate (9), and then it is milled around from the hole a peripheral recess (29a). The depth of it recess (29a) from the upper face (27) corresponds essentially with the thickness (10) of the modulation plate (9).

Figure 3 presents a guitar in it view than that of Figure 2, but in this case the plate modulation (9) is not stuck in a recess (29a), but is stuck directly over the top cover, along a surface of gluing (29b).

A guitar is represented in Figure 4 (1), also in longitudinal section. Unlike the way of embodiment depicted in Figure 1 and in Figure 3, the plate of modulation (9) is not made as a flat plate, but has a bulge (12) convex outward, the bulge convex (12) is uniform to all sides, and the bridge of support and support (7) is located in a central area, so that the clamping force acting in the direction of the box resonance (24) is transmitted to the flanks (30a), (30b), and by the support cone formed by the flanks (30a), (30b) the formation of a bridge or vault.

In Figure 4 they can also be seen in detail on a larger scale the thicknesses (10), (11) of the upper table (2) and of the modulation plate (9). The modulation plate (9) is attached firmly to the upper table (2) in peripheral direction in the recess 29a. Due to the convex bulge, the modulation plate (9) stands out from the table above (2).

Figure 5 shows in an enlarged front view in perspective a soundboard (3) with a plate of modulation (9) located in the upper table (2). By the face bottom (13) (see Figure 6) of the modulation plate (9) is indicates with a dashed line a bracing (14). The bracing (14) has a uniform grid shape (15), the grid (15) being formed by bridges (16a) in the direction longitudinal and bridges (16b) in the transverse direction. The bridges (16a), (16b) intersect at right angles and extend to the edge area of the modulation plate (9), without stand out from it.

On the guitar (1) represented in Figure 5, both the soundboard (3) with its upper table (2) and the Modulation plate (9), are made of wood. The grain of the upper table (2), indicated schematically by the reference (22), runs essentially parallel to the axial extent of the strings (5), like the grain (21) of the modulation plate of wood (9). The acoustic advantage of the guitar (1) object of the invention is also the result of fiber disruption of the wood, while the alignment of the streaks (21), (22).

Figure 6 schematically shows a plate of modulation (9) with a convex bulge and worn on the face bottom (13) of the modulation plate a bracing (14) in grid shape (15). In the view of Figure 6 you can see the bridge (16b) that runs along the entire width of the plate modulation (9). At discrete distances, the bridge (16b) is crossed by a total of five bridges (16a), which pass perpendicular to that one. The bridges (16a) have a construction identical to the bridges (16b). The maximum thickness (18) of the bridges (16a), (16b) is reached in the central area (17), where the bulging convex (12) also presents the maximum distance with respect to the upper table (2), which is not represented in Figure 5. The bridges (16a), (16b) are losing height evenly towards both sides, and end in a thin section (19). On the far side of the modulation plate, the bridges (16a), (16b) are coated of a layer of carbon fiber (20), which gives a resistance additional to the bracing (14), and with it to the whole of the modulation plate (9).

Legends

one

Guitar

two

Top table (top harmonica)

3

Box of resonance

4

Mast

5

Strings

6

First end of the rope

7

Clamping bridge and support for

8

Second end of rope

9

Plate modulation

10

Plate thickness modulation

eleven

Thickness of the board higher

12

Domed convex

13

Underside of the modulation plate

14

Bracing

fifteen

Grating

16th

Bridges in longitudinal direction

16b

Bridges in cross direction

17

Central zone of bridge

18

Thicker bridge

19

Thin part of bridge

twenty

Fiber layer carbon

twenty-one

Wood grain of the modulation plate

22

Wood grain from the table above

2. 3

Plug

24

Bottom of resonance

25

Cost of resonance

26

Underside of the sounding board

27

Upper face of the sounding board

28

Tarraja

29th

Step

29b

Surface of glued

30th,

30b Flanks of domed convex

Claims (13)

1. Pulse instrument, such as a guitar with a modulation plate (1), with a resonance box (3), which has a top board or harmonic cover (2) and a mast (4) attached to the resonance box (3), as well as with several strings (5) that can be tensioned and that pass between the soundboard (3) and the mast (4), the strings (5) being fixed at their first end (6) on the upper table (2) of the soundboard (3) in a joint support and support bridge (7), and by its second end (8) fixed to the mast (4), characterized in that the support and support bridge (7) ) is located on a modulation plate (9) made in the upper table (2), the modulation plate (9) having a thickness greater than that of the upper table (2). 2. Pulse instrument, such as a guitar with a modulation plate according to claim 1, characterized in that the modulation plate (9) has a thickness of 0.8 mm to 1.6 mm. 3. Pulse instrument, such as a guitar with a modulation plate, according to claim 1 or 2, characterized in that the modulation plate (9) is made with a convex bulge (12). 4. Pulse instrument, such as a guitar with a modulation plate, according to one of claims 1 to 3, characterized in that the modulation plate (9) is glued to the upper table (2). 5. Pulse instrument, such as a guitar with a modulation plate, according to one of claims 1 to 4, characterized in that the modulation plate (9) is made of wood. 6. Pulse instrument, such as a guitar with a modulation plate, according to one of claims 1 to 4, characterized in that the modulation plate (9) is made of plastic material. 7. A pulse instrument, such as a guitar with a modulation plate, according to one of claims 1 to 6, characterized in that the modulation plate (9) is provided with a lower bracing (14) on its underside (13). 8. Pulse instrument, such as a guitar with a modulation plate, according to claim 7, characterized in that the bracing (14) is made as a trellis (15). 9. Pulse instrument, such as a guitar with a modulation plate, according to claim 8, characterized in that the trellis (15) is rectangular. 10. Pulse instrument, such as a guitar with a modulation plate, according to one of claims 7 to 9, characterized in that the trellis (15) is formed by at least two bridges (16a, 16b), presenting the bridges (16a , 16b) its greater thickness (18) in the central zone (17), ending thinner (19) at both ends. 11. Pulse instrument, such as a guitar with a modulation plate, according to claim 10, characterized in that the at least two bridges (16a, 16b) are covered with a layer of carbon fiber (20). 12. Pulse instrument, such as a guitar with a modulation plate, according to claim 10 or 11, characterized in that the bridges (16a, 16b) have an angular orientation with respect to the grain (21) of the wood of the modulation plate (9) and / or the grain (22) of the upper table (2). 13. Pulse instrument, such as a guitar with a modulation plate, with an upper board (2) made of wood, according to one of claims 5 to 12, characterized in that the wood of the upper board (2) has its grain ( 22) oriented parallel to the grain (21) of the modulation plate (9) made of wood.