NL1021177C1 - Wave transformer has vertical direction control and is placed in front of acoustic drive device, in front of output mouth or compression driver or in front of diaphragm - Google Patents

Abstract

The wave transformer has a vertical direction control and is placed in front of an acoustic drive device, in front of the output mouth of a compression driver or in front of a diaphragm. The transformer has a housing and a channel, a circular inlet opening and a rectangular outlet opening. The housing encloses a through passage between the inlet opening and the outlet opening in order to conduct the acoustic waves along a pair of rapidly expanding horizontal walls. The transformer has two identical shell halves (1,1'). The channel is exclusively formed by right and left side walls, upper and lower walls. The maximum width of the channel between the inlet and outlet openings is equal to or smaller than the inlet opening. The shell halves have installation flanges (2,2').

Description

SOUND WAVE TRANSFORMER

The invention relates generally to the optimization of acoustic coupling of adjacent acoustic drive devices, over their full spectrum, by means of a specific sound wave transformer. This (sound) wave transformer is intended to convert a flat, circular, isophasic wave surface that is created at the mouth opening of a compression driver into a flat, rectangular, isophasic wave surface. A concatenation of a plurality of rectangular, planar wave surfaces formed in this way forms a planar, isophasic band from which a coherent, cylindrical propagating wave surface can arise. A plurality of acoustic drive devices which are coupled in this way with the aid of said wave transformer will thus generate a coherent cylindrical wave surface.

In order to achieve this coupling effect, the vertical beam angle of such wave transformers must be very small (0-5 degrees), so that undesired mutual interference phenomena are minimized. To be able to couple correctly, it is also important that the distance between the wave transformer outputs is minimal.

It is known that a hoom can only offer directional control downwards to frequencies, the wavelength being comparable to the size of the mouth mouth. It is also known that with diverging steam walls, where the distance IS between these walls is equal to or greater than the wavelength that is guided through the walls, if the deviation is reduced in the meantime, this can lead to annoying reflections. This can partly be explained by the fact that the wave surface propagates at the same speed in all directions and will consequently assume a convex shape through the deflecting walls, which manifests itself when the convex wall narrows in reflection of the convex wave surface against the hoom wall.

The wave transformer of the invention consists of a circular flat input and a rectangular flat output between which a passage is designed such that the time interval for propagating the acoustic wave between the input and the output, for all possible paths that the wave can traverse, is substantially is equal. As a result, the wave will manifest as a flat rectangular wave surface from the wave transformer.

The wave transformer is positioned in front of an acoustic drive (compression driver) on the longitudinal axis of the wave propagation direction and includes a channel that expands longitudinally. Said channel forms a passage for the flat wave surface, which arises at the circular output of the said driving device, to a rectangular opening, in such a way that said wave surface manifests itself almost flat out of said rectangular opening of the wave transformer

A crucial aspect of the invention is that the obtained passage from the circular entrance to the rectangular exit is obtained by exclusively using two shell halves and without using one or more internal bodies, such as frequently used phase plugs, which attach to the housing. be connected.

BRIEF DESCRIPTION OF THE DRAWINGS

The invention will be described with reference to a number of copied drawings which are given as a non-limiting example of a wave transformer in which reference numbering is used to indicate corresponding parts through the different views, wherein:

FIG. 1 is a perspective view of the wave transformer.

FIG. 2 is a perspective view of one wave transformer half 40 FIG. 3 is a vertical axial section along I-I in FIG. 5.

FIG. 4 is a horizontal axial section along U-Π in Figure 5.

FIG. 5 is a rear view of the wave transformer

FIG. 6 is a front view of the wave transformer

FIG. 7 is a perspective view of a plurality of aligned wave transformers.

45, A, ·· · 2

DESCRIPTION OF THE INTENDED HOUSING

It is an object of the present invention to provide a throw transformer which provides a passage by means of two shell halves with a predetermined shape of walls and without using internal bodies.

The throw transformer is adapted to be positioned in front of the output of an acoustic drive device.

Said shell halves each have a rear side and a front side and wherein the walls between said rear side and front side describe half of a passage. In the first part (I, Fig. 4) the shape of the said passage goes from a semi-circular shape to a rectangular shape. In the second phase (II, Fig. 4), the shape of said wall of the shell half gradually changes into a spherical recess which abruptly changes on the longitudinal axis into a spherical bulge in such a way that when placing both shell halves on top of each other at least one channel is created between said spherical bulge and said spherical recess. Subsequently, in the third phase (III, Fig. 4), the shape of the passage in said half of the scale is described by a shallow rectangular recess with a width that is at least narrower than half the wavelength of the highest frequency transmitted by said throw transformer should be guided. The area of said rectangular recess perpendicular to the longitudinal axis expands with the horizontally located walls determining the vertical spread of the throw transformer by the angle (β) between these horizontal walls. Both shell halves joined together form a housing with a circular opening on said rear side connected via at least one internal channel to said rectangular exit opening on the front side.

The geometry of the walls of said channel is inter alia defined by the shortest possible path lengths along the walls between said entrance opening and said exit opening which are all substantially identical in length.

The vertical side wall of the shell half can take various forms and, after joining the two shell halves, run over a large part of the passage (phases II and III) almost parallel to each other. The vertical side walls make at least one flowing pendulum which has the greatest deviation at the level of the horizontal plane through the longitudinal axis and gradually runs to a straight path at the level of the horizontally expanding walls.

The throw transformer as shown in figure 1 consists of two identical scale halves, element 1 and Γ, which are rotated through 180 degrees relative to each other about the longitudinal axis. The shell parts have a mounting flange 2 and 2 "on the rear for mounting the acoustic drive device. Backs 3 and 3 'are arranged at the front, inter alia for stiffening the side wall. Filling plates 4 and 4 "and horizontal partitions S and 5" with cams are placed along the top and bottom for mutual connection of the wave transformers.

From the entrance of the throw transformer, the top and bottom wall expand directly with an angle a (Fig. 2-4). In the first phase (I) of the throw transformer, the passage narrowed in the horizontal plane. In the second phase (II), below and above the horizontal plane through the longitudinal axis, respectively, a mountain 6 and a valley 7. At the level of the horizontal plane through the longitudinal axis, the shape changes from mountain to valley and vice versa. The mountain of one scale half falls into the valley of the other scale half and forms a channel through the space that has been saved between them. This is followed by a third phase (III) in which the throw transformer has a shallow rectangular cut-out 8 and the bottom and top walls only expand slightly. The angle β that these walls make with respect to each other substantially determines the vertical spread of the throw transformer. The cut-out 9 forms the exit opening of the channel.

In the current throw transformer housing: A = 34mm, the diameter of the input opening (= diameter output of the compression driver).

o = 45 ’, the angle over phases I and II of the top and bottom wall.

40 β = ca.3 \ the angle over phase III from top and bottom wall, which also determines the vertical spread of the throw transformer.

b = 25 mm, the width of the exit L = 140 mm, the height of the exit

This dimensioning should not be seen as a limit, but is only given as an illustration with the example.

45 The throw transformer can be produced in an injection molded rigid material, such as metal, plastic. The identical shell parts are assembled by means of glue, heat welding or screws.

3

The shape of the housing, which is obtained by combining two shell parts, is such that the shortest possible path length along the wall from between the entrance opening and the exit opening are substantially of the same size. During use, the propagation time of the wave between entrance opening and exit opening is constant in all directions.

As a result, the wave transformer makes it possible to convert the flat isophasic circular wave surface presented by the acoustic drive device into a flat, isophasic, rectangular wave surface. The dimensioning of the rectangular output of the wave transformer is chosen such that several wave transformers can be placed consecutively under each other, so that a narrow band is created as an opening (Fig. 7).

The operation of the wave transformer is improved in a general sense as a function of the input frequency spectrum, in particular for frequencies having a wavelength of less than about 15 centimeters, equal to the height L of the output aperture. Other optimisations can be found in: 1. The width of the passage which should be less than the shortest wavelength in phase II and III.

2. Make α smaller than 30 *.

3. Make L greater than or equal to the longest wavelength.

4. Make i smaller than or equal to the shortest wavelength.

5. The difference between the shortest possible path lengths must not be more than a quarter of the shortest wavelength that is passed through the wave transformer.

The intended use for the wave transformer according to the invention can be found in applications for professional sound installations for auditoriums and open air situations where a large amount of loudspeakers are required.

Grouping a plurality of speakers with the wave transformer in the vertical direction as shown in Figure 7 has the effect of generating an isophasic, flat band from which a coherent cylindrical wave surface can arise. An optimum coupling between the acoustic drive devices is obtained in this way.

Although the invention has been described on the basis of certain methods, materials and bodies, it should be clear that the invention is not limited to what has been disclosed and is spreading over everything equivalent to the scope of the claims.

Claims (15)

A wave transformer with (improved) vertical direction control which is placed in front of an acoustic drive device, for the outlet of a compression driver or for a diaphragm. Said wave transformer comprises a housing with at least one channel, the surface of the surface of which extends perpendicular to the walls of said at least one channel between the circular entrance opening and the rectangular exit opening. Said housing encloses a passage between said entrance aperture and said exit aperture adapted to guide the acoustic waves along a pair of rapidly expanding horizontal walls which are connected to a pair of gradually curved vertical walls of a predetermined shape resulting in a substantially constant path length along the walls of said wall. channel 10 between said entry opening and said exit opening. Said channel is exclusively formed by a left and a right side wall, an upper and a lower wall. A wave transformer as described in claim 1 wherein the maximum width of said channel between said entrance opening and exit opening is equal to or narrower than said entrance opening. 15 A wave transformer as described in claim 1 wherein said wave transformer transforms a circular, flat wave surface into a substantially rectangular, flat wave surface. 4. A wave transformer as described in claim 1 wherein said entrance aperture is substantially circular. 20 A wave transformer as defined in claim 1 wherein the deviation in length between any two of said substantially constant path lengths is never more than a quarter of the wavelength of the highest frequency to be passed through said wave transformer. A wave transformer adapted to be positioned in front of the output of an acoustic drive device comprising two identical scale halves, which together form a housing. Each of the said shell halves has a rear and a front and an assembly of both shell halves forms a housing with at least one channel between the entrance opening at the rear and the exit opening at the front. Said shell half comprises a hemispherical recess which abruptly changes on the longitudinal axis into a hemispherical bulge, in such a way that when placing both shell halves on top of each other a part of said channel is formed between said hemispherical bulge and said hemispherical bulge . Subsequently this shape changes into a shallow rectangular recess with a width narrower than half the wavelength of the highest frequency to be passed through the said wave transformer. The area of said rectangular recess perpendicular to the longitudinal axis of the wave transformer expands with the horizontally located walls determining the vertical spread of the wave transformer with the angle that these said horizontal walls make with respect to each other. The geometry of the walls of said channel are defined by the shortest possible path length along the wall between said entrance opening and said exit opening which are substantially identical in size in all directions. A wave transformer as described in claim 6 wherein said rear side of each said half shell 40 also includes a rear plate which extends outwardly perpendicular to the longitudinal axis from said entrance opening. Said back plate serves as the mounting flange for said acoustic drive device. 8. A wave transformer as described in claim 6 wherein said front of each said half of the shell also has a number of rigidity ribs. 45 1 0; "": 9. A wave transformer as described in claim 6 wherein said wave transformer has an axis between the center of said entrance aperture and the center of said exit aperture on which there are no internal body or bodies. A plurality of said wave transformers as described in Claims 6 to 9, adapted to be placed in a line, wherein each wave transformer provides a housing with an input opening on one side of said housing mounted on the output of an acoustic drive device and an outlet on the other side of said housing, said plurality of wave transformers positioned in such a manner that said substantially rectangular and planar exit aperture of each said wave transformer in the line of said plurality of wave transformers substantially in a vertical plane and are contiguous with each other. 11. An instrument to specifically target acoustic energy. Said energy, over a predetermined frequency spectrum, is received by said instrument as a circular planar wave surface and transmitted at the output aperture of said instrument as a substantially rectangular planar wave surface. The instrument 15 provides at least one passage running from the entrance aperture to the exit aperture, said passage having a predetermined geometry to transform said circular planar wave surface to said rectangular planar wave surface for all wavelengths in said predetermined frequency spectrum, wherein each said at least one passage is defined by a passage that has an internal surface that expands from said entrance opening to said exit opening. 20 12. An instrument as defined in claim 11 which also has the ability to align a plurality of said instruments to create a wave surface in the form of a narrow band, to subsequently produce a coherent cylindrical acoustic wave, which has a horizontal opening angle which is determined by the angle of the vertical walls to be placed at the said output opening of the wave transformer of the invention. An instrument as described in claim 11 wherein the geometry of said passage corresponds to a time interval for the energy propagation between said entrance aperture and said exit aperture, said passage being formed such that said time interval for the energy propagation between entrance aperture and 30 exit opening is almost identical. 14. An instrument as described in claim 11 in combination with an acoustic energy source. Said instrument has two ends, one end adapted to connect to said acoustic energy source and the other end comprising an exit opening which is substantially rectangular and flat, said energy source radiating a flat circular wave surface at its exit. An instrument as described in claim 11 wherein said energy source comprises a loudspeaker which houses a compression chamber.