SU1658421A1 - Method of manufacturing loudspeaker diaphragm - Google Patents

Description

one

(21) 4717049 / 24-10

(22) 07/11/89

(46) 06.23.91. Bksh. K ° 23

(71) Oisico-Technical Institute. L.O.Ioffe

(72) G.V. Dreiden, Yu.II.Ostrovsky, N.O. Reingand, T.P.Romanova and I.V. Semenova

(53) 621.395 (088.8)

(56) Japanese Application K 56-48120, cl. H 04 R 7/08, 1981.

For Japan K 55-24563, cl. II 04 R 7/08, 1980.

(54) METHOD OF MANUFACTURING THE SPEAKER DIAPHRAGM

(57) The invention relates to acoustics. The goal is to expand the working range of the diaphragm to the high-frequency region by adjusting the amplitude-frequency characteristic. The method of making the diaphragm consists in calculating cell sizes from the frequencies corresponding to the minima of the adjustable amplitude-frequency characteristic, shaping the honeycomb from the cells of the sizes found, fixing the honeycomb between the skins. Moreover, when forming a honeycomb core, cells of each size are distributed over the area of this core evenly.

The invention relates to technical physics, in particular to acoustics and acoustic instrument making, and can be used to create dynamic loudspeaker heads.

The aim of the invention is to extend the working range of the diaphragm to the high-frequency region by adjusting the amplitude-frequency characteristic.

The method of manufacturing the diaphragm consists in calculating cell sizes based on frequencies corresponding to the minimums of the corrected amplitude-frequency characteristic, forming a honeycomb from cells of the sizes found, fixing the honeycomb between the casings. Moreover, when forming a honeycomb core, cells of each size are distributed uniformly over the area of this core.

Figure 1 shows a diagram of the diaphragm manufactured by the proposed method, where 1 is the plating, 2 is the honeycomb in Figure 2 are the amplitude-frequency characteristics of the diaphragm known (a) and proposed (b).

As is known, cellular diaphragms work as follows. Up to the first resonant frequency of the moving system, the diaphragm operates in the mode of in-phase oscillations. In this frequency range, the sound pressure characteristic has a smooth n monotonic character with very little distortion.

After the first resonant frequency, a nodal line appears at the edge of the diaphragm, which divides the diaphragm into two antiphase oscillations.

about

SP

oo

Ј

A further increase in frequency leads to the formation of two or more closed nodal lines. At the same time, rather pronounced peaks-dips appear on the amplitude-frequency characteristic, due to the fact that different parts of the diaphragm radiate in antiphase.

In the study of cellular diaphragm oscillations by the method of holographic interferometry, it was found that, starting from a certain frequency, along with oscillations of the diaphragm as a whole, oscillations of individual cells are also excited.

Considering a cell as a separate diaphragm, it is easy to show that the frequency at which the cell oscillations are maximum (the resonance of a single cell) is determined by its size. As is well known, the relationship between the resonant frequency and the size of the diaphragm (for the case of a circular diaphragm) is described by the relation

(Ut

PCV

}

(one)

where pt is the resonant frequency, and is the radius of the diaphragm; T - tension

P - superficial density; tym - the roots of the Bessel function. Obviously, with the same tension and surface density, the resonant frequencies of cells of different sizes will be uniquely determined by these sizes.

It was also established that, near the resonance frequency, the amplitude of cell oscillations is sufficiently large and can significantly exceed the amplitude of oscillations of the diaphragm as a whole. This means that near the resonant frequencies, cell oscillations make a significant contribution to the sound pressure.

Thus, selecting the cell sizes so that their resonant frequencies correspond to the position of dips in the amplitude-frequency characteristic of the diaphragm, it is possible to achieve a substantial smoothing of this characteristic and thereby expanding the working range of the diaphragm to the high-frequency region.

At the same time it is necessary that the cells of various sizes are evenly distributed over the area of the honeycomb. This is because

at high frequencies, when cell oscillations are excited, the diaphragm as a whole operates in antiphase mode

fluctuations, which means the presence of one or more nodal lines. Obviously, oscillations of cells located in the area of these nodal lines will not be excited. therefore

non-observance of the uniform arrangement of the cells (as it happens in the prototype) can lead to the fact that at the desired frequency most of the cells of the corresponding size will fall into

5, the nodal line region and their oscillations ps will be excited. A positive effect will not be achieved. The proposed method is carried out as follows.

0 Determine the amplitude-frequency characteristic of the cellular diaphragm operating in the desired frequency range, with known parameters (aperture size, cell size, surface density, tension). On the obtained amplitude-frequency characteristic, the values of the frequencies corresponding to the dips are determined. From these frequencies, the cell size is determined by the known formula, for which these frequencies will be resonant. A diaphragm of the same dimensions is made, with the same tension and density, forming a honeycomb of cells of calculated sizes, placing cells of different sizes evenly over the area of the filler.

The use of the proposed invention is promising in acoustic instrument making when creating dynamic loudspeaker heads used in technical, scientific and consumer radio equipment.

Claims (1)

Invention Formula A method of manufacturing a diaphragm of a loudspeaker, comprising forming a honeycomb core of. cells of different sizes and fastening 0 between the skins, characterized in that, in order to expand the working range of the diaphragm to the high-frequency region by correcting the amplitude-frequency characteristic, before forming the honeycomb core, the cell sizes are calculated from the frequency values corresponding to. the minimums of the adjustable ampli0 five 0 pz ioo zoo then ioo aoo that's 16000 (HZ) ; 1