CS244103B2 - Baffle with cardioid response - Google Patents

Abstract

A loudspeaker cabinet yielding a desired directive characteristic has a speaker (Z) mounted in its front face. The enclosed volume of the cabinet (Co) communicates with the cabinet exterior through a rear plate matrix which consists of a thick plate with a rectilinear array of through holes. The rectilinear array of holes (M2) is backed by a layer of acoustic damping material (R2). In order to achieve the desired directive characteristic the overall dimension of the array should optically be equal to twice the cabinet depth (d), however it may be as small as (d/2) a half the cabinet depth (d).

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a baffle having a cardioid shape having a dynamic loudspeaker having a rotating coil and comprising a known phase-changing RC member, which member is connected to a dynamic loudspeaker diaphragm, external acoustic field.

Nowadays, directed electroacoustic meters are increasingly being used. Not only sound receivers - microphones, but especially baffles are equipped with such an alkaline network - acoustic elements that at low kim turns ensure that they direct the system, especially in those cases where the inverter dimensions are. less than the wave length. Directional inverters have more advantages than non-directional inverters. These include those that tend to be susceptible, possess the choice of sound direction, the noise of the reflected sound waves, and the clarity of speech.

The baffle for high frequencies can be provided in the necessary dimensions, i.e. the baffle corresponds to the wavelength, with the orientation itself and does not need to be performed separately. At middle frequencies and even more at low frequencies, the wavelength is so great that immortalization using a baffle of current dimensions cannot be reached. To obtain an antero-posterior with a 9-10 dB @ 10 dB at 10 Hz, we can easily conclude that a baffle of dimension 2 meth. A baffle having a cardioid directional echo-hammock may allow the antero-posterior dimmer to be considerably smaller in size, while giving rise to some of the problems associated with the use of such baffles. One of these problems is the decrease in acoustic pressure versus sound pressure in a cardinal baffle.

Ο ^ ΙΙ ^ ι! the shape of the directional chaoKOetistiOy breaks when the wave length is comparable to the acoustic path length of the baffle, that is, when

These disturbances reported in the literature have been reviewed. When the known arrangement of the cerciditis shape was measured according to its directional chaos and etiquette, slacks, frequency independent, disturbing effects were detected.

This problem is solved by providing a capsule with a magnetic resistive according to the invention which provides a straight line pressure-frequency tics so as to utilize the functional bandwidth and ensure that the directional directionality is uniform. It was found that the cause of these problems is that the cabinet with ^ гПШ! chaaaaOtistics has dimensions of building elements comparable to the wavelength, which is not desirable. In addition, it has been found that these undesirable phenomena can be avoided by a suitable spatial arrangement of the acoustic slit system that leads to the external acoustic field of the baffle with a carburetor and using another slit system.

The invention is characterized in that the first cavity connected to the back of the loudspeaker diaphragm via an acoustic slit system, characterized by a first acoustic resistance and / or a first acoustic mass, is connected directly to the external acoustic field and / or the second cavity, the second cavity being via a second acoustic slit system, rejecting the second acoustic resistance and / or the second acoustic mass, connected to the external acoustic field such that the openings leading to the external acoustic field are located at the rear or side wall, near its edges and the distance between the holes are greater than half the depth of the baffle, preferably twice the depth of the baffle.

The baffle depth is охШ1пХ 1.2 times greater and at least 0.4 times greater than the width of the front baffle wall.

The baffle according to the invention, which produces an undistorted frequency and directional characteristic, is formed by a first acoustic slot system, which is located on

The apertures of the first acoustic slot system have the same geometrical arrangement as the apertures of the second acoustic slot system formed at the rear of the baffle.

The first acoustic system has at least two openings that are connected by at least two. cylindrical bodies having a second acoustic slit system, the second acoustic slit system having at least one opening which opens either directly or through a second acoustic resistor into the external acoustic field, wherein the cylindrical bodies are partially inserted into the space first cavities and / or are partially extended into the external acoustic field ·

Cylindrical bodies are filled with ma (^ t ^: Lál ^ ¢ ^ e ₎ which attenuates the sound.

Time constant d ^ c. k ^ Ra is determined ^and on the first acoustic ^resistivity rvního acousto & ého slotted system, and second acoustic resistance of the acoustic system and the second depth of the baffle meets the condition:

d / c = Jt ^ C] + RgCC + Cg) ·

Time constant d / c. which is determined by the first acoustic mass of the first acoustic slit system and the depth of the baffles, satisfies the following conditions:

^{1) 2} (Mg Mg ₊ Cg).

The forefront of the invention is the ability to obtain relatively uniform acoustic pressure amplitude and directional chharktttistits without ripple-independent ripple and distortion even when the sound wave length is more than twice the baffle depth. · Right ^thus be zístot ^d ^ el3í oubto enclosure than in hitherto known ^ ch řeSezní, pttčimž can achieve greater width Padma sinžit lower hraMc! portable bandwidth.

The information given about the sounder of the present invention is clearer, its clarity is improved, the sound reflectivity is increased, and the acoustic feedback is diminished.

The invention is described in detail based on the drawings, where Fig. 1 schemmaické representation used hitherto baffle, Fig. 2 measured chhaaatetiзtity sound pressure frequency uo sounding, which is shown in FIG. 1, FIG. 3 directional Cihar ¢ t ^k cleaned ( 4 shows a schematic diagram of the baffle according to the invention, FIG. 5 shows a diagram of the three-way substitution box of the baffle shown in FIG. 1, FIG. Fig. 7 Directional frequency (measured at a single frequency) baffle with tardioid chhaaatttistikos constructed according to the invention, Fig. 8 another embodiment of the baffle according to the invention, fig. FIG. 10 shows a fourth embodiment of a baffle according to the invention.

Fig. 1 is a schematic diagram of a baffle used with chaaaatetr.stitos. The loudspeaker, provided with a coil, is mounted on the front wall of the baffle, the width of which is. The dynamic loudspeaker J has a memorial having a diameter D and an acoustic impedance Z, blocked in the transmission band by the mass M.

A first cavity with an acoustic capacity 6 adjoins the rear wall of the dynamic loudspeaker. The first acoustic slit system 6, characterized by the first acoustic resistance R and the first acoustic mass M 1, flows into the external acoustic field. The depth of the cabinet is indicated by the letter d ,.

Fig. 2 shows the tonicity of the acoustic darkness of the loudspeaker from the same. At low frequencies (about 1000 Hz), the sound pressure level is 6 dB less than at high frequencies.

Fig. 1 shows the directional baffle of the baffle of Fig. IV It is apparent from the curves that the shape of the directional character, especially in the 2000 Hz range, is strongly distorted.

Fig. 4 shows one embodiment of a baffle according to the invention. The bynamic loudspeaker J is fixed to the front wall of the baffle having a width S. The dynamic loudspeaker diaphragm J has a diameter D and an acoustic impedance Z. A first cavity £ of acoustic capability Cq is attached to the back of the diaphragm. Between the first cavity 6 and the second cavity 2, a first acoustic slit system 6 is provided, which is realized by the first acoustic resistor R and the first acoustic mass. A second acoustic slotted system implemented by a second acoustic resistance. and the second acoustic mass Mg, blends into an external acoustic field.

The undistorted sound pressure-frequency characteristics and the undistorted directional characteristic are obtained by assuming that the distance mezi between the vertical slits is equal to twice the depth d of the gearbox, but at least half of it. The depth of the baffle is selected to be equal to the width S of the front wall.

It is preferred that the distances h, h between the extreme slits in the vertical and horizontal directions of the second acoustic slit system 2 are equal and equal to those of the first acoustic slit system 6, wherein the elements of the first acoustic slit system 6 may have different values and openings. (slits) may have different diameters.

Fig. 5 shows a substitute electrical diagram of the embodiment of Fig. 4. The impedance of the dynamic loudspeaker core J is indicated by Z, the impedance of the second sound passage 4.2 - this sound passage Z ^ actually means the impedance of the sound radiation of the slot system opening into the external sound space. . In order to obtain the precise cardioid directional character of the pike, which is generally desired, it is necessary that the time constant d / c associated with the acoustic bypass path d be anelogical to the resulting Siena time constant for phase change. Therefore, the following assumption applies:

D / c = H 3 C 4 + R 8 (C 1 + C 8).

In order to obtain or inaccurate the directional directional chaalaterity, we must depart from the equation. . Basic and practical tests have shown that inequalities apply to obtaining better acoustic mass values. For this inequality we have the following relationship:

and,

- (-)> M ( ^C + + Cg).

In practice, tulles obtained good results in the following inequalities:

Rj. ^ 2 and «Mg ·, often Kg = 0 and = 0.

Fig. 6 shows a directional brick and a clever dependency of acoustic. 4. The baffle of the baffle has the same dimensions as the baffle of FIG. 1. The dynamic loudspeaker 8 is similarly constructed.

The charkker pike exhibits a lower tendency than the character of the orcice used hitherto, especially in the 1000 Hz band.

Na Лг. 7 shows the pebble nature of the baffle pike made according to FIG. 4.

The directional characteristic in the 2,000 Hz band is not S-shaped, but is a cardioid curve.

Fig. 8 shows another example of a baffle made according to the invention. The first acoustic slit system 4 is evenly distributed over the inner partition. Holes leading to the external acoustic field They are located on the shell. The depth of the baffle 8, the width S of the front wall, is simultaneously the diameter and the distance between the opposing slots jh are shown in the figure.

Fig. 9 shows a longer embodiment of the baffle according to the invention

The first acoustic slit system 6 is formed by a plurality of apertures and is provided by a first acoustic resistance ft or a first acoustic mass Mr, and is located on the interior side of the four cylindrical bodies 6.

The second cavity 2 is formed by four cavities within the four cylindrical bodies. The second acoustic slit system 6 is formed on the outer walls of the four cylindrical bodies 6, which are flush with the rear of the baffle. The cylindrical bodies 6 have inserted into the space of the first cavity 6 of the capaecto 8. If quadrilateral baffles are used, for similar horizontal and vertical meshes, the distance between the centers of the cylindrical bodies 6 in the horizontal direction h 'is equal to the fork-knife between the centers of the cylindrical bodies 6, in the vertical direction h.

FIG. 10 shows a further embodiment of a baffle. Two dynamic speakers 6 are built into the baffle. The second cavity 8 is formed by four. cavities within four cylindrical bodies 6, which are located in the first cavity 6, filled with cotton or foam, and pass through the baffle wall into the external acoustic field. The first acoustic slit system 6 realized by the first acoustic resistance R or the first acoustic mass 6 is located on the inside of the four cylindrical bodies 6. The second acoustic slit system 2 is realized by the second acoustic resistance Rg and the second acoustic mass Mg is on the outside of four empty cylindrical bodies <5. Here, too, between the centers of the cylindrical bodies 6 in the horizontal and vertical directions, it is advantageous for the tulle distances to be approximately equal.

with a dynamic loudspeaker having an oscillating member is connected to a diaphragm, wherein

Claims (7)

1. A cardioid characteristic coil and comprising an RC-member of the phase, the rear side of which is connected to an external acoustic field, characterized in that the first cavity (1), connected to the rear of the dynamic loudspeaker diaphragm (3) via a first acoustic slotted system (4) reacted with a first acoustic resistor (R) and / or a first acoustic mass (R) is connected either directly to the external acoustic field and / or the second cavity (2) ), the second cavity (2) being connected to the external acoustic field via the second acoustic slit system (5) via the second acoustic resistor (Rg) and / or the second acoustic mass (Mg) so that the openings leading to the external acoustic field are located on the rear or side wall, running along their sides and the distance between the holes (h) It is greater than half the depth (d) of the baffle, preferably twice the depth (d) of the baffle. 2. 1.2 times A baffle according to item 1, characterized in that its depth (d) is maximally greater and at least 0.4 times greater than the width (S) of the baffle front wall. A baffle according to claim 1 or 2, characterized in that the first acoustic slit system (4) is mounted on the wind bar, wherein the openings of the first acoustic slit system (4) have the same geometrical arrangement as the openings of the second acoustic slit system (5). ) on the back of the baffle. 3. 244103 6 4. Cancionic sounding devices according to claim 1 or 2, characterized in that the first acoustic slot system (4) has at least two openings which are connected via two cylindrical bodies (6) to the second acoustic slot system (5), wherein the second acoustic slit system (5) having at least one opening which flows either directly or through the second acoustic resistance (Rg) into the outer acist field, the cylindrical bodies (6) being partially inserted into the space of the first cavity (1) e / or partially they are extended into the external acoustic field. 5. A caardioid chiropractic device according to clause 4, characterized in that the cylindrical bodies (6) are filled with sound-absorbing material. 6. A baffle with kairSioid cheattristikos according to any one of claims 1 to 5, characterized in that the time constant (d / c), which is determined by the first acoustic resistance (R) of the first acoustic slot system (4) and the second acoustic resistance ( Rg) of the second acoustic slot system (5) and baffle depth (d) satisfies the condition: d / c * + Cg) * 7. Sounding elsewhere with a characteristic according to any of the above points, characterized in that the time root dance (d / c), which is determined by the first acoustic mass (M1) of the first tout system (4) and the depth ( (d) satisfies this condition W (J ^{) 2} > Mi ⁺ V ⁺