RU2554273C1 - Acoustic system - Google Patents

Abstract

FIELD: physics.

SUBSTANCE: acoustic system comprises low-frequency, high-frequency and mid-frequency radiators; inputs of the system are intended for connecting an amplifier, capacitors from the first through the sixteenth, resistors from the first through the sixth and an inductor. The first lead of the low-frequency radiator is connected through parallel-connected inductor and third capacitor to the positive input of the system, and the second lead of the low-frequency radiator is connected to the negative input of the system. The low-frequency radiator is connected in parallel to series-connected first and second capacitors, series-connected fifth resistor and thirteenth capacitor, as well as the twelfth capacitor. The first lead of the high-frequency radiator is connected through the fifteenth capacitor to the positive input of the system; the second lead of the high-frequency radiator is connected to the negative input of the system; the first lead of the mid-frequency radiator is connected through the sixth resistor to the positive input of the system; the second lead of the mid-frequency radiator is connected to the negative input of the system; the mid-frequency radiator is connected in parallel to the fourteenth capacitor.

EFFECT: high sound quality.

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Description

The invention relates to electronic equipment, in particular, is intended for use in acoustic systems.

The most important indicator of the quality of acoustic systems (AS) is their ability to reproduce without distortion the entire dynamic range of real music signals.

Known stereo speaker system according to the author's USSR Certificate No. 1764188, containing two medium-high frequency speakers and one low-frequency speaker, including two medium-high frequency speaker heads and one low-frequency speaker head, a low-frequency transformer, two capacitors, one of the capacitors being connected in parallel with the head of the speaker low frequencies, two input terminals of the first and second channels, connected with the outputs of two medium-sized loudspeaker heads high frequencies, common bus. In order to simplify the design and reduce signal power loss, the first output of the primary winding of the low-frequency transformer is connected to the terminal of the first channel, and the second output is connected to the bus and connected through the capacitor to the inputs of the first and second heads of the mid-frequency speakers, the first output of the secondary winding of the low-frequency transformer is connected to the terminal the second channel, and the second output is connected to the input of the head, a low-frequency speaker, the output of which is connected to a common bus. When signals 5 are received at inputs 1, 2 from a stereo low-frequency amplifier, the signals from input 2 are simultaneously input to the low-pass filter formed by the capacitor 3 and the leakage inductance of the low-frequency transformer 4 (the inductance of the windings of the low-frequency transformer becomes equal to the leakage inductance as a result of shunting the windings very low output impedance of stereo low-frequency amplifier 15) and at the input of the loudspeaker 8 medium-high frequencies, a filter element which is a capacitor 5. The low-frequency signals are filtered and reproduced by the head 20 of the loudspeaker 6, and the medium-high frequency signals are filtered and reproduced by the loudspeaker 8. At the same time, the signals from input 1 are fed to the winding of the low-frequency transformer 4 and to the input of the medium-high-frequency loudspeaker 8, the filter element of which is the capacitor 5 .

The low-frequency signals are transformed into the secondary winding, filtered by the same filter (capacitor 3 and the leakage inductance of the low-frequency transformer 4) and reproduced by the head of the loudspeaker 6 (signal path - parallel connection of the capacitor 3 and the loudspeaker head 6 - output impedance of the low-frequency amplifier channel - dissipation inductance) , i.e. on the head of the loudspeaker 6 there is a mixture of low-frequency signals from both channels of a stereo low-frequency amplifier. The signals of medium-high frequencies from input 1 are filtered by a medium-high-frequency filter, the element of which is a capacitor 5, and are reproduced by a medium-high-frequency loudspeaker 7. This eliminates the introduction of an additional inductance into the low-pass filter circuit, introducing additional signal power losses, and thereby increases the efficiency of the dynamic speaker and the speaker system as a whole and simplifies the filter circuit. In addition, the use of one capacitor as an element of medium-high-frequency filters for both medium-high-frequency loudspeakers instead of two (each for the corresponding medium-high-frequency loudspeaker) also simplifies the stereo speaker system. In the end result, this technical solution reduces the overall dimensions of the speaker system.

A disadvantage of the known speaker system is insufficient noise immunity, insufficient frequency range; insufficient quality of reproduced sound.

The known acoustic system adopted for the prototype, from a source published on the Internet at: http://www.radiolamps.ru/articles/acoustics/acoustic_8.html.

The speaker system (AS), selected as the prototype, was designed to provide high fidelity sound reproduction with an extended dynamic range. Schematic diagram of the speaker system is presented in figure 1. As the low-frequency (LF emitters) emitters selected two heads 75GDN-3. The functions of mid-frequency emitters (mid-range emitters) are performed by two heads 20GDS-1-4. For the described AC from the positions of matching the return of the LF and MF links, parallel-connected heads with a series resistor in the separation filter circuit were selected to align the return with respect to the LF link. In the RF link (high frequency link), two 6GDV-4-8 heads work in series. They efficiently reproduce higher sound frequencies, starting from 3000 ... 3500 Hz, which simplifies their coordination with mid-range emitters. The most effective damping and distortion reduction of low-frequency emitters is achieved when the complex is covered by electromechanical feedback (EMOS). In this regard, the parameters of the separation filters AC (figure 1) were chosen not only for reasons of proper allocation of the bands, but also taking into account their influence on the effect of EMOS (capacitors C1-C2-C3, the inclusion of resistor R1). To further reduce distortion, dual low-frequency emitters allow. This method can be recommended as an improvement of the proposed design of the speakers, especially if the introduction of EMOS is difficult.

The disadvantage of the filter for the speaker system selected for the prototype is insufficient noise immunity, insufficient frequency range, insufficient quality of reproduced sound.

The technical result achieved by the claimed invention is to increase the accuracy of sound reproduction; speaker power; stability of technical characteristics.

The claimed result is achieved by the fact that the speaker system contains low-frequency, high-frequency and mid-frequency emitters connected to the positive and negative inputs of the system, the system inputs are used to connect an amplifier, first to sixteenth capacitors, first to sixth resistances and inductance, the first output of the low-frequency emitter through the connected in parallel, the inductance and the third capacitor are connected to the positive input of the system, the second output of the low-frequency emitter is connected with a negative input of the system, parallel to the low-frequency emitter are connected the first and second capacitors connected in series, the fifth resistance and the thirteenth capacitor connected in series, the twelfth capacitor connected, the fourth and fifth capacitors connected in series, connected in parallel with the sixteenth capacitor in turn , the common conclusion of the first and second capacitors through the third resistance connected in series, four the first resistance and the switch are connected to the positive input of the system, the ninth and eighth capacitors connected in series are connected on one side to the positive input of the system, and on the other hand, to the common terminal of the third and fourth resistances, the first resistance is connected to the positive input of the system on one side, and on the other hand, connected to a common terminal of the first and second capacitors, series-connected sixth and seventh capacitors are connected on one side to a common terminal of the third and fourth of the resistances, and on the other hand, with the common output of the first and second capacitors, the second resistance and the tenth capacitor connected in parallel are connected on the one hand with the common output of the eighth and ninth capacitors, and on the other hand with the common output of the sixth and seventh capacitors, the eleventh capacitor connected on the one hand with the common terminal of the sixth and seventh capacitors, and on the other hand with the first terminal of the low-frequency radiator, the first terminal of the high-frequency radiator through the fifteenth condensate connected to the positive input of the system, the second terminal of the high-frequency oscillator connected to the negative input of the system, the first terminal of the midrange transducer via the sixth resistance connected to the positive input of the system, a second terminal midrange emitter connected to the negative input of the system, the emitter connected in parallel midrange fourteenth capacitor.

The inventive speaker system includes a low-pass filter formed by connected in parallel with an inductance and a third capacitor, as well as connected in series by the first and second capacitors; a medium-pass filter formed by a sixth resistance and a fourteenth capacitor; high pass filter formed by the fifteenth capacitor.

These filters in the inventive system perform a standard function of dividing the signal by frequency.

In addition to the traditional technical solution associated with the use of filters for dividing the signal by frequency, the claimed speaker system contains a circuit designed to evenly distribute the loads on each emitter, as well as to equalize the frequency of the signal on each emitter.

The specified circuit is formed by the first, second, third, fourth resistances, fourth, fifth, sixth, seventh, eighth, ninth, tenth and eleventh capacitors.

The elemental composition of the claimed acoustic system and the nature of the connections between the elements provides a qualitative distribution of loads (respectively, frequencies) for each emitter of the system. A clear distribution of loads on each radiator eliminates the "clogging" of one radiator by the frequencies of another radiator.

A clear frequency distribution allows you to more accurately select the parametric characteristics of each element of the system, allows you to more accurately predict the quality of the system, because in the inventive system, as established by the author empirically, there is no influence of "alien" frequencies on each emitter. In addition, the inclusion of a load distribution scheme for each emitter allows (due to equalization of the signal in frequency) to more fully extract sound in the entire frequency range, i.e. make maximum use of the reserve.

The inventive speaker system is illustrated in the drawing.

Figure 2 presents a schematic diagram of the inventive speaker system.

The inventive speaker system contains associated with the positive and negative inputs of the system low-frequency (LF), high-frequency (HF) and mid-frequency (MF) emitters, the system inputs are designed to connect an amplifier. The first output of the low-frequency emitter LF through a parallel connected inductance L and the third capacitor C3 is connected to the positive input of the system; the second output of the low-frequency radiator bass connected to the negative input of the system; parallel to the low-frequency radiator LF connected in series are the first C1 and second C2 capacitors connected in series with the fifth resistance R5 and the thirteenth capacitor C13, as well as the twelfth capacitor C12; parallel to the second capacitor C2, fourth capacitors C4 and fifth C5 are connected in series, parallel to which, in turn, is connected the sixteenth capacitor C16, the common output of the first and second capacitors (C1 and C2) through the third resistance R3 connected in series, the fourth resistance R4 and the switch Pr connected to the positive input of the system; the ninth C9 and the eighth C8 connected in series are connected on one side to the positive input of the system, and on the other hand, to the common terminal of the third R3 and fourth R4 resistances; the first resistance R1 is connected on one side to the positive input of the system, and on the other hand connected to a common terminal of the first C1 and second C2 capacitors; the sixth C6 and the seventh C7 connected in series are connected on one side to a common terminal of the third R3 and fourth R4 resistances, and on the other hand to a common terminal of the first C1 and second C2 capacitors; connected in parallel, the second resistance R2 and the tenth capacitor C10 are connected on one side to a common terminal of the eighth C8 and ninth C9 capacitors, and on the other hand to the common terminal of the sixth C6 and seventh C7 capacitors; the eleventh capacitor C11 is connected on one side to a common terminal of the sixth C6 and seventh C7 capacitors, and on the other hand, to the first terminal of the low-frequency low frequency radiator; the first output of the high-frequency radiator of the HF through the fifteenth capacitor C15 is connected to the positive input of the system, the second output of the high-frequency emitter of the HF is connected to the negative input of the system; the first output of the mid-frequency radiator midrange through the sixth resistance R6 is connected to the positive input of the system, the second output of the mid-frequency radiator midrange is connected to the negative input of the system; parallel to the mid-frequency radiator midrange connected fourteenth capacitor C14.

The low-pass filter is formed by a capacitor C3, an inductance L, capacitors C1 and C2; the mid-range filter is formed by capacitor C14 and resistance R6; The high-pass filter is formed by capacitor C15.

The load distribution scheme between the emitters is formed by capacitors C4-C13, C16; resistances R1-R5.

The system starts when the switch Pr. The signal from the amplifier goes to the inputs of the speaker system. In the filters of low frequencies, medium frequencies and high frequencies, the signal arriving at the input of the system is separated by frequencies. The load distribution scheme provides equalization of frequencies and voltages, and also ensures the retention of characteristics in predetermined parameters. If the voltage at the terminals of the capacitor C12 deviates from the specified parameters, the voltage is adjusted through the circuit consisting of the capacitor C13, as well as the resistance R5.

The author experimentally established that the claimed speaker system provides a clear frequency reproduction of sound in the frequency range from 30 to 21000 hertz, while well-known technical solutions provide sound reproduction in the frequency range from 50 to 16000 hertz.

The selection of the parameters of the circuit elements is carried out empirically until a sound balance is achieved in each frequency range, including taking into account the exclusion of the negative effect of static electricity on the capacitor plates.

Thus, the claimed speaker system allows due to the full use of the reserve system to reproduce sound in a wider frequency range than known systems; allows you to increase the efficiency of the system; increase the level of noise immunity; reduce the possibility of the influence of electromagnetic fields surrounding the system.

Claims (1)

An acoustic system containing low-frequency, high-frequency and mid-frequency emitters connected to the positive and negative inputs of the system, the inputs of the system are designed to connect an amplifier, first to sixteenth capacitors, first to sixth resistances and inductance, the first output of the low-frequency emitter through the inductance and the third capacitor connected in parallel connected to the positive input of the system, the second output of the low-frequency radiator is connected to the negative input of the system, in parallel a first and second capacitors connected in series, a fifth resistance and a thirteenth capacitor connected in series, and a twelfth capacitor connected in series with a low-frequency radiator, a fourth and fifth capacitors connected in series, connected in series with a sixteenth capacitor in parallel with which, in turn, a sixteenth capacitor is connected, a common terminal of the first and of the second capacitors through the third resistance, the fourth resistance and the connection switch connected in series nen with a positive input of the system, the ninth and eighth capacitors connected in series are connected on one side to the positive input of the system and, on the other hand, to the common terminal of the third and fourth resistances, the first resistance is connected to the positive input of the system on one side and connected to the other with a common terminal of the first and second capacitors, connected in series of the sixth and seventh capacitors are connected on one side with a common terminal of the third and fourth resistances, and on the other hand with a common terminal of the first and second capacitors, connected in parallel the second resistance and the tenth capacitor are connected on the one hand with a common terminal of the eighth and ninth capacitors, and on the other hand with a common terminal of the sixth and seventh capacitors, the eleventh capacitor is connected on one side with a common terminal of the sixth and the seventh capacitor, and on the other hand, with the first output of the low-frequency emitter, the first output of the high-frequency emitter through the fifteenth capacitor is connected to the positive input of the system s, the second terminal of the high-frequency oscillator connected to the negative input of the system, the first terminal of the midrange transducer via the sixth resistance connected to the positive input of the system, a second terminal midrange emitter connected to the negative input of the system, the emitter connected in parallel midrange fourteenth capacitor.

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