FR2573559A1 - Control system for impact frequency of vibrating armature - Google Patents

Abstract

The system obtains from the resonant frequency of the membrane (13) an electrical pulse sequence of the same frequency which is then used to generate a control frequency for the current flowing in an excitation coil (18) belonging to the vibrating armature (20). The pulse sequence obtained from the resonant frequency of the membrane is produced by a transducer responding to the membrane's movement, pref. a piezoelectric transducer mounted directly on the membrane or on a projection from it. Alternatively a piezoelectric acceleration sensor may be mounted on the casing of the horn (12).

Description

"Method for contactless frequency control
driving the oscillating armature of an electro horn
magnetic ".

State of the art
The invention starts from a method for the contactless control of the driving frequency of the oscillating armature, fixed to a membrane, of an electromagnetic horn, as a function of the displacement of the membrane.

 A horn operating according to this method is for example known in the document FR-PS 1 428 483.

In this case, a self-oscillating amplifier, tuned to the natural resonance of the moving parts of the horn, controls the supply of the excitation winding and therefore the driving frequency of the oscillating armature in natural resonance. An alternating voltage obtained simultaneously from the displacement of the membrane by induction, by capacitive or else piezoelectric effect, is introduced in phase coincidence in the resonance circuit of the amplifier to serve as possible differences between the electric frequency d oscillation and the effective mechanical frequency of resonant frequency of the oscillating electric circuit.

 From document DE-OS 25 57 711, it is also known to couple by means of a compensation member to the control input of a flip-flop circuit a detector, which during the excitation of the oscillating armature delivers a voltage pulse to an iron core, this rocker circuit blocking for a predefined switching time a device for interrupting the excitation current of the armature coil upon the appearance of a pulse from the detector.

 Document DE-OS 24 48 685 describes a contactless switch circuit for an electromagnetic horn, the membrane mechanically connected to the oscillating armature oscillates freely at its own resonance and which, to excite the oscillation, establishes or cuts the circuit d excitation for the armature winding as a function of two momentary positions of the oscillating armature with respect to its iron core, these two momentary positions, determining the switching processes of the oscillating armature, being detected by an inductive sensor and being converted by modulation of an auxiliary oscillation into a control signal for the switch circuit.

Such circuits for the contactless control of the driving frequency of the oscillating armature are certainly a little more expensive than the conventional switch circuit of a contact switch connected in series with the excitation coil of the oscillating armature of this type. which is called the hammer of
Wagner. However, such a conventional contact switch is subject to disturbances, in particular due to the considerable wear to which it is subjected. But precisely in the case of horns, great importance must be attached to a safe mode of operation and a long service life, especially to the neutralization of the disturbing mechanical source. By using contactless control devices such as are described above, the life of the horn, whose constitution is otherwise unchanged, can be multi
folded.

 In addition to a longer service life, care should be taken in the case of an electromagnetic horn to ensure the purity of the acoustic signal obtained; This signal is produced by the periodic impact of the oscillating armature on an iron core. Therefore, the membrane connected to the armature and the oscillating disc are caused to perform their own oscillations. The periodic succession of the impact of the oscillating armature determines the basic frequency of the signal (300 to 500 Hz). The frequency of the sound is defined by the natural frequency of the membrane or of the oscillating disc. It is at an order of magnitude of about 3000 Hz. If the natural frequency of the membrane or of the oscillating disc is an integer multiple of the basic frequency, the sound of the horn is pure. To guarantee this, it was hitherto necessary to adapt on each individual horn during manufacture the base frequency to the natural frequency of the oscillating disc and the membrane by modification of the stiffness of the spring of the oscillating armature. This adjustment process is time consuming and involves additional costs.

 The object of the invention is to remedy these drawbacks and the invention provides for this purpose that from the natural frequency of the membrane, a succession of electrical pulses of the same frequency is obtained, this succession of pulses being exploited to obtain a control frequency subdivided into a ratio of whole numbers for the supply of an excitation coil of the oscillating armature.

Advantages of the invention
The method according to the invention for the contactless control of the driving frequency of the oscillating armature, on the other hand, has the advantage that there is no longer any need for an additional adjustment of the base frequency to obtain the purity horn signal sound, because the control frequency for the power supply of the excitation coil of the oscillating armature is obtained from the natural frequency of the diaphragm or from the oscillating disc. pulses produced by the membrane to obtain a control frequency subdivided according to an entire ratio for the oscillating armature, can be produced with a relatively simple electrical circuit which operates by switching corresponding to the type of operation of a mechanical contact switch and which consequently presents little loss and operational safety
Other characteristics of the invention make it possible to envisage other advantageous forms of improvements in the horn, characterized in that, starting from the natural frequency of the membrane, a succession of electrical pulses of the same frequency is obtained, this succession of pulses being used to obtain a control frequency subdivided into a ratio of whole numbers for the supply of an excitation coil of the oscillating armature; the succession of electrical pulses obtained from the frequency proper of the membrane is produced by a converter reacting to the movement of the membrane, preferably a piezoelectric converter; the converter is arranged on the diaphragm itself, preferably on an internal face of this diaphragm facing the horn housing; the converter, taking the form of a perforated disc, is disposed on an extension of the oscillating armature, preferably between the membrane and an oscillating disc connected to the latter; an acceleration sensor, preferably made of a piezoelectric material, is used as a converter and is anchored on. the horn boot; the succession of electrical pulses obtained from the natural frequency of the membrane is stored in an operating circuit comprising a preselection counter and a trigger stage, and delivering the control pulses for supplying the b -obin of excitation of the oscillating armature; the succession of electrical pulses obtained from the natural frequency of the membrane controls a signal switch connected upstream of the operating circuit, this switch being connected to the output of a frequency generator connected to the power supply circuit. horn current.

 Particular features of the characteristics of the invention follow from the following description and from the drawings in which an exemplary embodiment of the invention is represented.

 - Figure 1 is a block diagram of the electrical connection of the horn.

 - Figure 2 is a longitudinal section of the horn.

Description of the exemplary embodiment
The horn 10 shown in FIG. 1 is intended to be used on a motor vehicle not shown and consequently includes a fixing element 11 carrying the housing 12 of the horn. This bolier 12 consists of a sheet having the same thickness everywhere, preferably a sheet of steel. It has a circular cross section and it is closed by a membrane 13. On the bottom 14, opposite the membrane 13, of the housing 12 is anchored a core 15 fixed to the circular transverses and which projects into the housing 12 and which is constituted of a material having a magnetic conductivity, preferably soft iron. The anchoring of the core 15 on the housing 12 is carried out by a threaded stud 16 connecting to the core, and which has a diameter less than that of the core and passes through the bottom 14 of the housing 12 as well as the fixing element 11. A nut 17 screwed onto the stud 16 holds the parts 11, 12 and 15 together.

On the core 15 is placed an excitation coil 18 which during operation attracts the membrane 13 against the core 15 at the rate of successive current pulses. To this end, the free front face of the core 15 is placed, by providing an air gap, opposite the stud-shaped end 19 of an oscillating frame fixed to the membrane 13. To fix the frame 20 to the membrane 13, this frame comprises a central riveting stud 21 with a smaller diameter, which passes through the membrane 13, a spacer disc 22 as well as an oscillating disc 25 mounted between washers 23, 24, and which holds together by a head of rivet 26 formed at its end the parts 13, 20, 22, 23, 24, 25.

 the excitation coil 18 is capable of being connected to a current source 28 via an electronic contactless control circuit. described in more detail below as well as by means of a connection cable 27 indicated only symbolically in FIG. 2.

 The electronic control circuit essentially consists of an operating circuit 29 with a preselection counter and a trigger stage for the succession of electrical pulses obtained from the natural frequency of the membrane 13, of a terminal stage 30 connected to its output and which is arranged at the same time as a switch 31 on the conductor 27 connecting the current source 26 to the excitation coil 18, of a frequency generator 32, the pulses of which when the switch is closed 31 are sent for a short time into the operating circuit 29 to excite the armature 20, and a signal switch disposed between the frequency generator 32 and the operating circuit 29, this switch suppressing the generator pulses after oscillation of the membrane and sending into the operating circuit 29, instead of the generator pulses, the succession of electrical pulses obtained from the oscillation of the membrane.

 The conditions for the purity of the sound of the acoustic signal produced by an electromagnetic horn make that the driving frequency of the oscillating armature 20 on the core 15 and the natural frequency of the membrane 13 or else of the oscillating disc 25 are in a ratio of numbers whole. The natural frequency of the membrane of the oscillating disc is predefined by their construction and can for example be situated at an order of magnitude of 3000 Hz. If this frequency is an integer multiple of the driving frequency of the oscillating armature 1, the sound of the horn is pure. To guarantee this result according to the additional adjustment operations, it is provided that a succession of electrical pulses is obtained from the natural frequency of the membrane or else of the oscillating disc, with the same frequency, this succession of pulses being used to obtain a control frequency subdivided according to an integer ratio for the supply of the excitation coil 18 of the oscillating armature 20. In the embodiment shown, the succession of pulses obtained from of the displacement of the membrane, as indicated previously, is introduced via the signal switch 33 in the operating circuit 29. If, for example, a report is desired t 1: 8 between the driving frequency of the oscillating armature 20 and the frequency of the membrane 13, then the preselection counter contained in the operating circuit 29 activates. for each eighth of oscillation of the membrane, the trip stage of the operating circuit, which in turn connects the terminal stage 30.

Thus, when the switch 31 is closed, a short pulse of current reaches the excitation coil 18 and causes the attraction of the oscillating armature 20 by the magnetic force and the impact of the armature on the core 15.

 To obtain from the oscillations of the membrane 13 or else of the oscillating disc 25 a succession of electric pulses of the same frequency, use is preferably made of converters, in particular piezoelectric converters, which react to changes in shape and which , for small dimensions, have the property that their load modifications can follow alternative stresses even at high frequencies. In the embodiment shown, a piezo-ceramic converter, in the form of a flat plate 34 is arranged on the internal face, facing towards the housing 12 of the horn, of the membrane 13 in the vicinity of the edge of the housing. The plate 34 can be fixed to the membrane by gluing. Below the plate 34, a small box 35 is fixed on the boot 12 of the horn in which are housed electronic components schematically represented in the diagram of the Figure 1. The voltage pulse obtained during the impact of the armature 19 on the core 15 by deformation of the membrane 13, is brought via the flexible conductor 36 to the signal switch 33 located in bolte 35.

 Instead of the converter 34 fixed to the membrane 13, one could also use a pressure converter arranged on the riveting stud 24 between the membrane 13 and the oscillating disc 25. This arrangement brings the advantage that the pressure converter does not need to be connected to the membrane. As a pressure converter, a perforated piezo-ceramic disc can be used in this case, which is placed instead of the spacer disc 22 between the membrane 13 and the washer 24. For the transmission of the voltage pulses delivered by this disc perforated with the control electronics housed in the boot 35, it is possible to use strip conductors placed against the internal face of the membrane 13.

 Another possibility of detecting the oscillations of the membrane 13 or of the oscillating disc 25 consists in using a piezoelectric acceleration sensor as a converter. Such an acceleration sensor 37, indicated by dotted lines in FIG. 2, the construction and operating mode of which are presumed to be known, is, in the embodiment shown, reported inside the housing 12 from the horn to a location which oscillates in synchronism with the membrane 13 when the switch 30 is closed.

 For switching on the horn 10, the switch 31 is closed. Therefore, the frequency generator 32 receives current and delivers a succession of pulses with a predefined constant frequency which can correspond to the oscillation frequency of the membrane 13 or of the oscillating disc 25. The pulses of the generator arrive by through the signal switch 33 to the operating circuit 29 which in turn controls the terminal stage 30 at the rate of the trigger pulses delivered by the circuit 29.

Thus, the horn's excitation coil 18 receives current and attracts the armature 20, so that the armature strikes the core 15 and triggers the proper oscillation of the membrane 13 and of the oscillating disc 25. From this oscillation its own, a succession of electrical pulses of the same frequency is obtained using the piezoelectric converter 34, this succession of pulses being introduced via the signal switch 33 in the operating circuit 29.

 The pulses generated by the converter 34 cause the signal switch 33 to be switched and the pulses leaving the frequency generator 32 to be blocked. Consequently, only the signals from the piezoelectric converter 34 are processed, the preselection counter receiving these pulses, from the operating circuit 29 authorizing, after n pulses respectively, the tripping of the terminal stage 30.

In this way, the basic sequence determined by the frequency of impact of the oscillating armature 20 on the core 15 is predefined by the natural frequency of the membrane 13 or else of the oscillating disc 25 and can by means of the circuit d 'Operation 29 be subdivided into any integer ratio with respect to the frequency of the membrane. The oscillator 32 can be produced in a very simple way because it only serves to activate for a short time the operating circuit 29 to initiate the oscillation of the membrane 13. As soon as this takes place and the signal switch 33 receives pulses from the piezoelectric converter 34, this switch switches and blocks the passage of the succession of pulses from the frequency generator 32.

 Horn constructions with various base frequencies can be performed with a single circuit when the base frequency is adjustable on the operating circuit. By an appropriate setting of the operating circuit trigger threshold, it is also possible not only to detect all the oscillations of the membrane but also all the intermediate steps of an amplitude, so that by the choice of the trigger threshold , the delay of the horn's magnetic circuit can be taken into account.

Claims (7)

 10) Method for the contactless control of the driving frequency of the oscillating armature, fixed to a membrane, of an electromagnetic horn, according to the displacement of the membrane, method characterized in that from the natural frequency of the membrane (13), a succession of electrical pulses of the same frequency is obtained, this succession of pulses being used to obtain a control frequency subdivided into a ratio of whole numbers for the supply of an excitation coil ( 18) of the oscillating armature (20).  20) Device for implementing the method according to claim 1, characterized in that the succession of electrical pulses obtained from the frequency proper of the membrane (13) is produced by a converter reacting to the displacement of the membrane, preferably a piezoelectric converter (34).  30) Device according to claim 2, characterized in that the converter (34) is disposed on the membrane (13) itself, preferably on an inner face of this membrane facing the housing (12) of the horn.  40) Device according to claim 2, characterized in that the converter, taking the form of a perforated disc, is arranged on an extension (21) of the oscillating armature (20), preferably between the membrane (13) and an oscillating disc (25) connected thereto.  50) Device according to claim 2, characterized in that an acceleration sensor <37), preferably made of a piezoelectric material, is used as a converter and is anchored on the horn (12) of the horn.  60) Device for implementing the method according to claim 1, characterized in that the succession of electrical pulses obtained from the natural frequency of the membrane (13) is stored in an operating circuit (29 ) comprising a preselection counter and a tripping stage, and delivering the control pulses for supplying the excitation coil (18) of the oscillating armature (20).  70) Device according to claim 6, characterized in that the succession of electrical pulses obtained from the natural frequency of the membrane (13) controls a signal switch (33) connected upstream of the operating circuit (29) , this switch being connected to the output of a frequency generator (32) connected to the current supply circuit of the horn (10).