DE3830783C1 - Acoustic signal transmitter, particularly chime signal transmitter, for motor vehicles - Google Patents

Abstract

In this signal transmitter, having an electroacoustic sound transducer and an electric clock generator which supplies the sound transducer with an essentially square wave electric signal having a constant frequency and pulse width and variable amplitude, the frequency of the signal of the clock generator is greater than the resonant frequency of the sound transducer in order to generate simply and inexpensively high volumes with small constructional size. Furthermore, the pulse width of the signal of the clock generator is narrower than half the period of the signal. Finally, the sound transducer is associated with a Helmholz resonator, the resonant frequency of which is approximately equal to twice the frequency of the electrical signal.

Description

The invention relates to an acoustic signal generator, in particular gong signal generator for motor vehicles, with a electro-acoustic transducer and with an electric Clock generator that connects the sound transducer with an essential rectangular electrical signal with constant frequency and pulse width, but more variable Amplitude, supplied.

From DE-OS 31 47 364 such an acoustic Signal generator for generating a bell or one Gongsignal known. The pulse width of the generated there electrical signal is about half that Period of the electrical signal. The frequency of the electrical signal is in the listening area and corresponds to Frequency of the generated by the acoustic signal generator acoustic signal.

However, the known acoustic signal generator has disadvantages. If the electroacoustic transducer with a electrical signal supplied, the frequency of the frequency the acoustic signal generated by the acoustic signal generator Signal corresponds, so this frequency is often very far from the resonance frequency of the acoustic transducer. The has the disadvantage that the production is comparatively high Volume an electrical signal of great power is required or that a correspondingly large electro-acoustic transducer is required. This can, especially when used in motor vehicles, there primarily as a warning signal generator in the area of Dashboards or roof control units create difficulties lead when housing the acoustic signal generator.

When operating the known acoustic signal generator in the resonance frequency of the transducer  Difficulties arise because even slight deviations from the Too strong frequency of the generated electrical signal Volume fluctuations can lead. In addition, one Change the frequency of the known acoustic Signal generator only by changing the frequency of the generated electrical signal possible.

The invention has the task of an acoustic signal generator to create that is easy and inexpensive to manufacture, which can generate large volumes with a small size, and at which the frequency of the acoustic signal generated is changeable in many ways.

This object is achieved in that the Frequency of the clock generator signal is greater than that Resonance frequency of the transducer that the pulse width of the Signals of the clock generator is less than half Period of the signal that the transducer on Helmholtz resonator is assigned and that the Resonance frequency of the Helmholtz resonator is approximately equal to that is twice the frequency of the electrical signal.

The fact that the frequency of the electrical signal of the Clock generator is greater than the resonance frequency of the Sound transducers are the requirements for Constant frequency of the generated electrical signal lower than the previous one because of the electroacoustic transducers not with his Resonance frequency is operated. Because the pulse width of the clock generator signal is less than half Period of the signal takes place in addition to the excitation of the electroacoustic transducer with the frequency of the Clock generator a particularly strong excitation, the frequency of the electroacoustic transducer, that of the first Harmonic of the sound produced corresponds. This first Harmonic frequency is twice that Frequency of the clock generator electrical signal corresponds. In that a Helmholtz resonator is provided  is assigned to the electroacoustic sound transducer is the electroacoustic efficiency of the acoustic signal generator according to the invention in the field of Resonance frequency of the Helmholtz resonator compared to the Previously increased. That is, given a electrical power of the electrical signal is at the Resonance frequency of the Helmholtz resonator the volume of the acoustic signal generator according to the invention is particularly large. According to the resonance frequency of the Helmholtz resonator approximately twice the frequency of the electrical signal selected. That means the resonance frequency the Helmholtz resonator corresponds to the frequency of the first Harmonic of the sound generated by the acoustic signal generator.

By means of these measures according to the invention, it is therefore possible with the acoustic signal generator according to the invention To produce sound that is derived from the fundamental tone of the Frequency of the electrical signal corresponds and above all composed of the first overtone, the generated Volume of the overtone generated by the Helmholtz resonator according to the invention by tuning the Resonance frequency of the Helmholtz resonator and through the pulse width of the electrical signal selected according to the invention is selected with a particularly high volume. Through the particularly large volume of the first overtone objectively the acoustic signal generator according to the invention generated volume compared to the previously known. In addition, the physiology of the human Hearing causes the warning effect of the acoustic Signal generator, especially when used as a warning gong, significantly improved compared to the previous one.

The acoustic signal generator according to the invention has the previously known the advantage that as an additional part only the Helmholtz resonator is required, which is simple and is inexpensive to manufacture. By using the Helmholtz resonator according to the invention can be a comparatively small electro-acoustic transducer  can be used, although with the invention Acoustic signal generators can generate large volumes. There is also a change in the timbre of the acoustic Signal not only by changing the frequency of the electrical signal but also by changing the Resonance frequency of the Helmholtz resonator possible.

Further advantageous refinements and developments of acoustic signal generator result from the Subclaims.

To disturb the function of the acoustic according to the invention Exclude signal generator during operation, it is advantageous to the frequency of the electrical signal of the Clock generator to choose about 20% larger than that Resonance frequency of the electroacoustic sound transducer.

It is particularly advantageous to adjust the pulse width of the electrical signal of the clock generator approximately equal to one Quarter of the period of the electrical signal choose because in this case the first overtone of the acoustic signal compared to the fundamental in electro-acoustic transducer produced particularly strong becomes.

The electroacoustic sound transducer used can advantageously be an electromagnetic sound transducer, the is characterized by a pronounced resonance frequency and whose resonance frequency is usually below Frequencies of the acoustic signal is that by the acoustic signal generator according to the invention are generated should. In this context, one can e.g. B. one choose an electromagnetic transducer whose Resonance frequency is about 700 Hz.

The Helmholtz resonator can be by housing parts and Acoustic transducer can be limited space through an opening is connected to the environment. It is advantageous between  a channel is arranged in the opening and in the Helmholtz resonator, for easy tuning of the Helmholtz resonator in its cross section and length can be changed, without having to change the housing dimensions. In In this context, the opening, especially as multiple slots are formed, being by change the number of slots and by changing the Passage area of the slots also a vote of Resonance frequency of the Helmholtz resonator can take place without that the channel or the housing parts would have to be changed. Finally, in this context, the channel and / or the slots as parts of the housing parts, in particular form together in one piece to the Manufacturing and assembly effort to manufacture the to reduce the Helmholtz resonator according to the invention.

If a gong signal or a bell signal is to be generated, which is characterized by a constant pitch and timbre and by a decaying amplitude of the acoustic signal distinguished, it is advantageous if a pulse generator is specified, which controls a pulse shaper, the one second electrical signal with rapidly increasing and slowly falling edge generated and if a modulator is provided that the first electrical signal with the second electrical signal modulated and the Sound transducer with a third modulated electrical Signal supplied. Through these measures, the above described characteristic gong sound with hard attack and slow decay easily and inexpensively.

An embodiment of the acoustic Signal generator is shown in the drawings and will explained in more detail below with reference to the drawing.

Show it:

Fig. 1 is a schematic representation of the mechanical parts of the acoustic signal generator according to the invention,

Fig. 2 is a schematic representation of the electrical parts of the acoustic signal generator according to the invention,

Fig. 3 is a graph in which the volume is plotted against the frequency of the acoustic signal generator according to the invention and

Fig. 4 different voltage-time diagrams in which the electrical signals and the superimposition of the electrical signals are shown schematically.

In Fig. 1, an electroacoustic sound transducer, which is designed as an electromagnetic sound transducer or loudspeaker ( L ), is arranged in a corresponding recess in a first housing part ( G 1 ) and with a cover cap ( AK ) which is connected to the first housing part ( G 1 ) is locked, fixed in this recess. The first housing part ( G 1 ) is essentially open downward in FIG. 1 and is essentially covered in this open side by a second housing part ( G 2 ). A web of the first housing part ( G 1 ) and the wall of the second housing part ( G 2 ) pointing upwards in FIG. 1 form a sound-conducting channel ( K ) which ends in slots ( S ), ie slot-shaped openings in the second housing part.

The first housing part ( G 1 ), the second housing part ( G 2 ) and the loudspeaker ( L ) form a space which acts as a Helmholtz resonator. The Helmholtz resonator ( R ) communicates with the environment via the sound guide channel ( K ) and the slots ( S ).

It can be seen in Fig. 1 that the arrangement of the Helmholtz resonator ( R ) of the sound guide channel ( K ) and the slots ( S ) was chosen such that on the one hand there is a small design because the sound guide channel ( K ) is essentially parallel to the plane the loudspeaker ( L ) is arranged and that, in particular when the acoustic signal transmitter according to the invention is installed in the motor vehicle, the sound guide channel is arranged such that an operator in the motor vehicle does not pass through the slots ( S ) into the interior of the Helmholtz resonator ( R ) and thus onto the membrane of the speaker ( L ) can look. In FIG. 2 , the same or equivalent device parts as in FIG. 1 are provided with the same reference numerals. There, a clock generator (TG) is shown, which a modulator (M) in such a conductively connected to a first input (E 1), that the modulator (M) via the first input (E 1) a first electrical signal (U 1) receives. Furthermore, a pulse generator ( IG ) is provided in FIG. 2, which starts a pulse shaper ( IF ) with the aid of a unique clock signal, which in turn is conductively connected to a second input ( E 2 ) of the modulator ( M ) and via this second input ( E 2 ) the modulator ( M ) determines a second electrical signal ( U 2 ). The loudspeaker ( L ) is controlled by an output ( A ) of the modulator ( M ) with a third electrical signal.

The electrical control of the acoustic signal generator according to the invention according to FIG. 2 is provided for generating a chime signal or bell signal.

In FIG. 3, the volume level (LST) is applied the signal generated by the acoustic signal transmitter acoustic signal versus frequency (F). In Fig. 3 it can be seen that at the resonance frequency ( FRL ) of the loudspeaker ( L ), which in this exemplary embodiment is approximately 700 Hz, a comparatively large volume is generated for a given electrical input power. The frequency ( FSG ) of the clock generator ( TG ), as shown in FIG. 3, lies above this resonance frequency, in the present exemplary embodiment at approximately 850 Hz. As the frequency increases at approximately 1700 Hz in the present exemplary embodiment, there is a further increase compared to the first increase stronger increase in volume for a given electrical input power for the loudspeaker ( L ) can be seen. This is the resonance frequency ( FRH ) of the Helmholtz resonator, which according to the invention corresponds to the frequency of the first harmonic of the signal generated by the clock generator ( FSO ).

It can be seen in FIG. 3 that may not be the comparatively low efficiency of the transducer during operation of the loudspeaker (L) at its resonant frequency (FRL) is utilized in the inventive acoustic signal transmitter, that by the novel provision of the corresponding tuned Helmholtz resonator, however, the volume of the first overtone generated by the loudspeaker ( L ) is particularly high at the resonance frequency of the Helmholtz resonator ( FRH ) or the frequency of the first overtone ( FSO ).

In FIG. 4, the same or equivalent parts are drawing as shown in Figs. 1 to 3 with the same reference numerals.

In Fig. 4a, the course of the first electrical signal is shown (U 1) over time (t). It can be seen that the first electrical signal ( U 1 ) is a square wave signal, the period of which ( T 2 ) is approximately 1.2 milliseconds at a frequency of 850 Hz. In the present exemplary embodiment, a pulse duration ( T 3 ) is 1/4 of the period ( T 2 ), that is to say approximately 0.3 milliseconds. This measure according to the invention results in a particularly strong excitation of the first overtone in the loudspeaker ( L ) compared to the fundamental.

In FIG. 4b, the course of the second electrical output signal is shown (U 2) over time (t). It can be seen that the second electrical signal ( U 2 ) has a very steep rising edge and a very slow falling edge. Furthermore, a gong duration ( T 1 ) is entered in FIG. 4b. This is the time period in which the gong signal is generated.

In FIG. 4c, the course of the third electrical signal (U 3), which is obtained by modulation of the first electrical signal (U 1) with the second electrical signal (U 2), represented over time (t). It can be seen that the frequency and the pulse width of the third electrical signal correspond to the frequency and the pulse width of the first electrical signal. In contrast, the amplitude of the third electrical signal corresponds to the amplitude of the second electrical signal. This means that as time progresses, the amplitude of the third electrical signal ( U 3 ) decreases, so that the volume of the sound produced by the loudspeaker is reduced and the typical gong or bell sound with a hard attack and slow ringing results.

The acoustic signal generator according to the invention thus has the advantage over the prior art that it is not critical with regard to the frequency constancy of the clock generator ( TG ) because the loudspeaker ( L ) is not excited in its resonant frequency ( FRL ). The volume of the acoustic signal generated by the acoustic signal generator according to the invention is increased compared to the known at a predetermined electrical power of the third electrical signal ( U 3 ), because the first harmonic of the generated acoustic signal by the Helmholtz resonator and its tuning of the resonance frequency and by the choice of pulse width compared to the fundamental tone with increased volume.

Claims (10)

1. Acoustic signal generator, in particular gong signal generator for motor vehicles, with an electroacoustic sound transducer and with an electrical clock generator which supplies the sound transducer with an essentially rectangular electrical signal with a constant frequency and pulse width but variable amplitude, characterized in that the frequency ( FSG ) of the signal ( U 1 ) of the clock generator ( TG ) is greater than the resonance frequency ( FRL ) of the sound converter ( L ), that the pulse width ( T 3 ) of the signal ( U 1 ) of the clock generator ( TG ) is less than half the period ( T 2 ) of the signal ( U 1 ) that a Helmholtz resonator ( R ) is assigned to the sound transducer ( L ) and that the resonance frequency ( FRH ) of the Helmholtz resonator ( R ) is approximately equal to twice the frequency ( FSG ) of the electrical signal ( U 1 ) is. 2. Acoustic signal generator according to claim 1, characterized in that the frequency ( FSG ) of the signal ( U 1 ) of the clock generator ( TG ) is about 20% greater than the resonance frequency ( FRL ) of the electroacoustic sound transducer ( L ). 3. Acoustic signal generator according to claim 1, characterized in that the pulse width ( T 3 ) of the signal ( U 1 ) of the clock generator ( TG ) is approximately 1/4 of the period ( T 2 ) of the electrical signal ( U 1 ). 4. Acoustic signal generator according to claim 1, characterized in that the electroacoustic sound transducer ( L ) is an electromagnetic sound transducer. 5. Acoustic signal generator according to claim 4, characterized in that the resonance frequency of the electromagnetic sound transducer ( L ) is approximately 700 Hz. 6. Acoustic signal generator according to claim 1, characterized in that the Helmholtz resonator ( R ) is a housing parts ( G 1 , G 2 ) and the sound transducer ( L ) limited space, which is connected to the environment through an opening. 7. Acoustic signal generator according to claim 6, characterized in that a channel ( K ) is arranged between the opening and the Helmholtz resonator ( R ). 8. Acoustic signal generator according to claim 6, characterized in that the opening in particular a plurality of slots ( S ). 9. Acoustic signal generator according to claim 7 and / or claim 8, characterized in that the channel ( K ) and / or the slots ( S ) as parts of the housing parts ( G 1 , G 2 ) are in particular formed together in one piece. 10. Acoustic signal generator according to claim 1, characterized in that a pulse generator ( IG ) is provided which controls a pulse shaper ( IF ) which generates a second electrical signal ( U 2 ) with a rapidly rising and slowly falling edge and that a modulator ( M ) is provided which modulates the first electrical signal ( U 1 ) with the second electrical signal ( U 2 ) and which supplies the sound transducer ( L ) with the third modulated electrical signal ( U 3 ).