ITTV940060A1 - METHOD AND EQUIPMENT FOR THE AUTOMATION OF CUTTING START IN SAWS FOR STONE MATERIAL. - Google Patents

Abstract

To start the sawing of an irregular or rough block of stone, with a saw, both frame and disk, in order to avoid any sudden contact of one or more blades with protrusions of the block, which can lead to breakage of the or of the blades, a method is used consisting of revealing a characteristic sound generated at the beginning of the contact of a blade with the stone block, this sound clearly distinguishing itself from the background noise generated by the simple movement of the cutting complex without contact between the o the blades and the stone block. For the detection of this characteristic sound, an acoustic detector (64) that hears the sounds produced and is equipped with capable equipment (100) is used, at a time foreseen close to the contact of the blade or blades with the stone block. to distinguish the sounds produced by the saw not in contact with the block from those produced by the same in contact with the block, for example based on the difference in sound level characteristic of the two cases and to choose maneuvers to approach and engage the saw with the block such to prevent damage to the same saw.

Description

The present invention relates to a method for automating the start-of-cutting maneuvers of simple or multiplex saws, both disc and frame, for stone material and equipment that performs the same method.

It is known that when it is necessary to start the sawing of an irregularly shaped stone block, the problem arises of making the first contact of a blade or a minority of blades, in the case of a group of the same housed parallel in a sawing frame, less violent. or traumatic as possible to avoid overexertion breaking of the or some of the same blades.

A manual method has already existed for a long time which consists in approaching the blade of a disc saw or in lowering a frame equipped with saw blades at relatively high speed to bring the blades as close as possible to the same stone block. when a blade comes into contact with a protrusion of the stone block, activate carrying means on the lamas of abrasive materials and liquid coolants to facilitate the cutting of the stone material and lower the disc or frame at a constant speed connected to the nature of the stone material of the or e of the lam used.

Obviously, such a manual procedure is very laborious, with considerable time costs, because each cautious maneuver must necessarily be long, requires expert operators and is not free from accidental errors leading to more less significant damage to the blades.

An object of the present invention is to provide a method for bringing into contact a disc blade or a plurality of blades contained in a sawing frame with a block of stone in any case irregular, without any particular supervision of operators, at speeds much higher than those obtainable with direct visual surveillance, avoiding as much as possible traumatic stresses to the blade (s).

Another object is to provide a method which causes a sawing cycle started with the contact of the blade or blades described above to continue until the end of the same cycle.

A further purpose is to create an equipment that carries out the above methods by realizing the start of counting the blade (s) with the stone block and taking the necessary measurements in order to avoid damage to the blade (s).

The aforementioned purposes are achieved by a method consisting in detecting the sound emitted by a sawing machine by taking advantage of a considerable difference in level between the sound emitted by non-contact movements of one or more blades with a block of cutting stone and the sound emitted by movement with contact of blades with the same block, characterized by the fact of using acoustic detection means capable of measuring the level of sound emitted by the machine, of evaluating the level of said sound and of emitting an intervention signal when this level exceeds a predetermined threshold. serving to activate means that prevent the continuation of the advancement of the blade or blades towards the block to be sawed until means are activated, such as slowed descent of blades and introduction of coolants / lubricants and abrasives, which allow a sawing without traumatic effects on the blades.

In particular, in the case of a sawing machine with a frame which can move alternately carrying a plurality of blades, it is: acoustically the sawing machine, and especially its blade frame, from the external environment, acoustic detection means capable of measuring the level of sound emitted by the machine, the level of said sound is evaluated and an intervention signal is emitted when this level exceeds a predetermined threshold.

More particularly, the acoustic detection means are exposed in an acoustically insulated environment, enclosing the sawing machine, only for a limited time around the moment in which one or more blades come into first contact with the stone block and are withdrawn in a substantially airtight case once they have detected a sound level above the predetermined threshold.

Preferably, the operation of the acoustic detection means is controlled by placing an artificial source of sounds in the acoustically isolated environment in some position adjacent to the blade frame and exposing said acoustic detection means to the same environment, obtaining an approval signal or an alarm depending on whether the acoustic detection means emit or a signal indicating correct perception of the sounds of the artificial source.

In addition, the acoustic detection is followed by frequency band limitation to take into consideration a frequency band of the acoustic signals in which there is a maximum difference in level between the acoustic signals due to the movement of the blade frame alone and those due to the engagement of at least a lam with the stone block.

Preferably, the frequency band is limited to a maximum frequency of 3200 Hz.

Most preferably, the frequency band is limited to a maximum frequency of 1600 Hz.

More preferably, the frequency band is limited to a maximum frequency of 800 Hz.

Most preferably, the frequency band is limited to a maximum frequency of 200 Hz.

In particular, when the acoustic detection means emit a signal whose level exceeds the predetermined threshold, they activate memory means which remain activated until an external deactivation signal arrives.

In addition, the activation of said memory means activates a start cycle of sawing contained in control means completing the equipment realizing the present automatic cutting start method.

In particular, the part of the method realized by said control means, after the activation of the memory means, comprises a lifting of the blade holder frame until the blades are disengaged from the stone block, withdrawal in hermetic case of the acoustic detection means and enabling to one cutting cycle.

More specifically, the cutting cycle includes starting a pump for the mixture of coolant and abrasive liquid, distribution of the mixture to zones corresponding to the blades, beginning of the cutting down or down of the blade holder frame at a predetermined speed and checking the completion of the related cycle. cutting.

An apparatus for carrying out the method of the present invention essentially comprises a microphone housed in a casing of the type which can be closed in a substantially hermetic manner and provided with means for making said microphone exit and withdraw with respect to said casing, the microphone being connected to an input of means amplifiers that carry the signal at a sufficient amplitude for subsequent processing, the output of the amplifier means is connected to a first low-pass filter which eliminates all signals having a frequency higher than the maximum allowed frequency, the output of the low-pass filter is connected to rectifier means which emit a continuous signal of single polarity and the rectifier means are connected to smoothing means in the form of a low-pass filter which transforms the single polarity signal into a signal of sufficient duration to exclude signals due to transient disturbances , the output of the smoothed out means is connected to a comparator circuit voltage which compares a signal coming out of said smoothing means with a predeterminable voltage level giving a high output when the level of the signal coming out of the smoothed means exceeds the predeterminable voltage level and the output of the voltage comparator is connected to memory activated by the high output of said voltage comparator and maintaining the activation even when said high output disappears until the arrival of a deactivation signal coming from the outside and said memory means connected to a programmable logic controller which automatic execution of a start of cut so that the activation of the memory leads to command the maneuvers controlled by the programmable logic controller.

In particular, these memory means consist of an R-S flip-flop.

In addition, the aforementioned apparatus implementing the method of the present invention comprises an additional section for verifying the operation of the microphone formed by a coincidence logic circuit which receives the output of the voltage comparator on its first input and on a second input thereof. the output of an operation signaling means of an artificial sound source so that the combination of the operation signaling of the artificial sound source with no output from the voltage comparator leads to operating an alarm signal generator.

In particular, the coincidence circuit is an NGR logic gate and the alarm signal generator is a power circuit for the operation of signaling devices such as horns, warning lights or both.

Alternatively, the coincidence circuit is a logic gate ANE and the alarm signal generator is a power circuit for driving alarms such as horns, warning lights or both.

The characteristics of the present invention are set forth with particularities in the claims forming the concluding part of the present description. However, other characteristics and advantages will appear more evident from the following description of an example of its embodiment, concerning only a sawing machine with an alternatively movable frame, since the transposition to different types of sawing machines is obvious, given for illustrative and non-limiting purposes. , accompanied by the attached drawings, in which:

Figure 1 is a partial perspective view of an external casing, or hood, mainly presiding over the soundproofing of an alternative stone sawing machine according to the present invention comprising, connected to one of its walls, a case for storing a microphone used in the detection according to the present invention, of the level of sounds within the same soundproofing enclosure;

Figure 2 is a schematic sectional view of the same housing showing its opening and closing means and means for removing and withdrawing the same microphone;

- figure 3 is a block diagram of an example of embodiment of a circuit suitable for discriminating the microphone outputs to distinguish between sounds due to the movement of an unengaged camera frame and sounds due to the movement of a camera frame with at least one blade engaged in an action of sawing a block of stone and also to perform a functional check of the same microphone;

- figure 4 is an assembly of two diagrams showing the spectral composition of the sounds present under the same soundproofing cap illustrating how, up to certain frequencies, there is a possibility of distinguishing, on the basis of the amplitude, the sounds due to a simple movement of a saw without engagement of its blades and those due to movement with engagement of at least one blade; And

Figure 5 is a flow chart of the procedures performed by an equipment according to the present invention from the beginning of the lowering of a blade holder frame to the completion of the segmentation of a stone block.

Considering first figure 1, it can be seen that an alternating movement machine for sawing stones comprises an external soundproofing hood 12 showing protruding support columns 14-20 and housing mechanisms for lowering (lowering) a blade holder frame (not shown in the figure ) and also of the main uprights 22-28 supporting soundproofing panels forming the same hood 12. In particular, the soundproofing hood 12 formed by upper extreme panels 30 and 32, by upper central panels 34 and 36, by extreme lateral panels 38 and 40 , by central side panels, such as panel 42, and by panels 44, 46 and 48 casing for a connecting rod for the actuation of the same sawing machine.

A case 30 is fixed to one of the central side panels, such as panel 42, from which a connection cable 52 exits.

Considering subsequently Figure 2, it can be seen that the aforementioned housing 30, from which the connection cable 3 exits, comprises a containment hood 34 fixed by means of a flang 56 and a plurality of bolts 58 to a wall 60 of the above soundproof hood lined internally with sound-absorbing panels 62. The containment hood 54 defines a protected space which serves to house a relatively delicate organ such as a microphone 64 connected by means of a flexible cable 66 with a through connector 68 which carries a connector 70 coupled to the outside for the connection cable 52 The same microphone 64 is fixed by means of a bracket 72 to a rod 74 connected to a movable piston 76 of a pneumatic actuator cylinder 78 which, by means of a bracket 80, is fixed to the same wall 60, the cylinder 78 being equipped with inlets 82 and 84 for actuator cylinder 78 control fluid, such as compressed air. In front of the microphone 64 there is a door 86, sliding like a slide, for closing a corresponding opening in the wall 60 of the soundproofing hood which is connected by means of a bracket 88 to a rod 90 moved by a piston sliding inside a pneumatic cylinder 94 provided of inputs 96 and 9 for control compressed air.

As can be understood intuitively, the pneumatic cylinder 7 serves to evert and withdraw the microphone 64 from and within the containment hood 54 and the pneumatic cylinder 94 serves to move the sliding door 86 to open and close the corresponding opening connecting the inside the soundproofing hood, possibly in the vicinity of a saw blade, with the containment hood 54 to allow the microphone output 64 just for the time sufficient to check operation and to perceive the sounds produced by the blade holder frame s in the absence of in the presence of contact of at least one blade with a stone block.

Figure 3 illustrates a diagnosis discrimination circuit 100 which enables the microphone 64, when introduced under the hood 12, to distinguish between sounds emitted by a blade holder frame without blades in contact and with blades in contact with the stone block and in figure 4 the spectral composition of the sounds present under the hood in the absence and in the presence of contact illustrates the principle that can be used for the present invention.

The circuit of Figure 3 also comprises means for diagnosing functionality of the microphone 64.

By examining in particular Figure 3, it can be seen that the circuit 10 comprises a first amplifier 102 which brings the level of the signals coming from the microphone 64 to values such as to be easily processed, a low-pass filter 104 which in the present embodiment cuts all signals having a frequency higher than 200 Hz, a rectifier / detector 106 which makes the signals coming from filter 104 of unique polarity, a smoothing filter 108 which makes the DC component of the detected signal prevail and eliminates any short-term transient disturbances, so intense from having passed the low-pass filter 104, which could lead to erroneous signals. The output of the smoothing filter 108 is connected to a non-inverting input of an operational amplifier 110 operating voltage comparator whose inverting input is connected to a potentiometer 112 fed by a stabilized direct voltage V ^, as could be a supply voltage for the same discriminator and diagnostic circuit 100, to determine a voltage level with which the signal coming from the smoothing filter 108 and present on its non-inverting input is compared. As is obvious, the voltage comparator 110 produces a high output signal when the level of the signal on its non-inverting input is higher than that on its inverting input and produces a low output signal when the level of the signal on its non-inverting input is less than that on its inverting input. The output of the voltage comparator 110 passes through a two-position switch formed by two sections of which the one indicated by 114a in position I puts the same output in communication with a write input 116 S (set) of a flip-flop R-S 118 of which one of its normal output Q is connected by means of a conductor 120 to an input of a programmed logic controller (PLC) 122. The same conductor 120 is also connected to an input of a power amplifier 124 which drives alarm 126, such as a pilot lamp, a buzzer, or the like, have the task of informing that an automaton procedure for starting the cut has been started. The same flip-flop R-S 118 is also provided with a cancellation input 128 R (reset) to which the cancellation signal is presented at the end of an automatic cutting start procedure. For example, this cancellation signal could be constituted by a high level signal (+ V ^) applied to the input 128 by means of a relay contact 130 controlled by the same controller 122 through a circuit symbolized by a simple connection 132.

The same circuit 100 also has a section 134 for diagnosing the functionality of the microphone 64 to allow checking, before starting an automatic start-up procedure, that the microphone 64 is fully functional. This check must absolutely be done because a failure that renders the microphone unusable would have very damaging consequences for the blades because it would not allow you to notice the first contact of a blade with the stone block and therefore you must avoid any start of the procedure if the microphone does not work. . The said diagnosis section 134 is formed by a coincidence circuit 136, which in the present case is a NOR gate, equipped with two inputs 138 and 140 d which the first connects to a position II of the switch 114a section and the second connects through a resistor R at the voltage V ^ and to a switch section 114b which can be positioned between a position I, corresponding to discrimination, and a position II, corresponding to diagnosis on a microphone, where it is connected to ground. The output 142 of the NOR gate 136 enters an amplifier 144 which drives a warning device 146 in the form of a pilot lamp or a buzzer.

To fully understand the function of the diagnosis section 134, it must be remembered that an artificial source of sound is installed under the soundproofing hood 12 (such as for example an emitter formed by a sheet suitably struck by a mechanical actuator with an electric motor controlled by a signal d diagnosis). When it is desired to ascertain the functionality of the microphone 64, it is commanded to exit the case SO, the two switch sections 114a and 114b are brought to position II and the artificial sound source is put into operation.

If the microphone 64 worked correctly, the output of the voltage comparator 110 would remain high, causing the input 138 of the NOR gate 136 to remain high, so that its output 142 remains low and preventing the actuation of the horn 146 through the '144 driver amplifier.

If, on the other hand, the microphone 64 does not work correctly by emitting a signal that is too weak or no signal, the output of the voltage comparator 110 would remain low, causing the input 138 of the NOR gate 136 to remain low which, having already low Γί input 140 when the switch 114b is in the Π position, its output 142 is high, activating the driver amplifier 144 and, consequently, the horn 146. Obviously, in addition to the activation of the horn 146, other means can also be provided for definitively integrates the operation of the logic controller program] 122 if the diagnosis section 134 indicates a malfunction of the microphone 64.

The difference between the sound emitted by a blade holder frame with the in contact with a stone block and blades out of contact is illustrated by the graph in figure 4 in which the curve marked with solid squares indicates the sound pressure level, as a function of frequency, expressed in dB, for the sound emitted by a frame having at least one blade in contact with the stone block, while the cu marked by empty squares indicates the pressure level are a function of the frequency, also expressed in dB, for the sound eme from the same frame without blades in contact with the stone block From an examination of the two curves it can be seen that for sound frequencies of 25 4000 Hz the two curves remain clearly distinct with differences between sound pressure levels between at least 7 and 10 dB. C means that for ordinary types of microphones, such as dynam microphones based on the principle of a moving coil within a magnetic field whose output signal can be estimated proportional to the square root of the sound pressure, differences in output voltages between 3.5 and 5 dB, so the voltage levels emitted by those microphones will be 2.23 to 3.16 times greater for associated sounds / blades in contact than those associated with non-contacting blades. output signal can be estimated directly proportional to the same sound pressure, differences in output voltages including t 7 and 10 dB would be expected, therefore the voltage levels emitted by this second type of microphone would be from 5 to 10 times greater for associated sounds of blades in contact compared to those associated with blades not in contact However, piezoelectric microphones are particularly sensitive to humid and highly contaminated environments such as q uelli of a sawing loom for which, despite the ability to better distinguish differences in sound level, they are not necessarily to be preferred.

Furthermore, to effectively exploit the difference in level between sound with contact and sound without contact, avoiding any contribution of disturbances from extraneous sources, a frequency range is chosen in which the two sound levels are clearly distinct with differences that never fall below a 7 dB. For example, a choice that has proved to be excellent limits the maximum allowed frequency to 200 Hz. This limitation makes it possible to have two distinctly distinct output levels but makes piezoelectric microphones very unattractive because, due to their nature which makes them equivalent to a voltage generator connected in series to a capacitor not too high (at most of the order of a few nanofarads), are not particularly suitable for reproducing signals with a frequency lower than 100 Hz, making the sounds detected under the hood not very usable. soundproofing. Therefore, with frequency limitation up to 200 Hz, the use of dynamic type microphones should be considered preferable.

The initiation automation procedure is particularly illustrated by the flow chart illustrated in FIG. 5 which can be used to produce a program to be loaded into an operation memory of the same programmed logic controller 122.

As can be seen from Figure 5, the flow chart begins with an ISO starting arrangement followed by a rapid lowering arrangement 1S2 of the blade holder frame. Subsequently, a 1S4 decision block verifies that the frame has reached a safe height. Before the arrival (answer NO) the rapid lowering of the frame continues, after the arrival (answer YES) it passes to a block 156 providing to start a flywheel of the sawing machine and to bring the frame step-by-step in rapid descent to a block of stone. Immediately afterwards, a block 15S is used to make the microphone 64 come out into the soundproofing hood 12 and to operate the artificial source of control sound. A decision block 160 checks whether the microphone is working. If it does not work (NO response), s stops the procedure and an alarm warning is issued. If it works (answer YES), it is verified with the decision block 164 whether the sound level is within a threshold set by the voltage comparator circuit 110 (Figure 3). If it is not (answer NO), the check is repeated while the step-by-step approach of the frame to the stone block continues. If it is (answer YES) a block 166 has a lifting of the blade holder frame to disengage it from the stone block and the microphone rites to remove it as quickly as possible from the extremely hostile and contaminated environment of the sawing machine. After this phase, a block 168 orders enabling for cutting, that is, it allows the blades carried by the frame to come into contact with the stone block to start sawing. As soon as cutting has been enabled, a block 170 is activated to pump a mixture of coolant (usually water containing abrasive particles (the so-called imaia) which provides an effective cutting action of the blades carried by the frame. . The same block 170 provides to give the tealio an optimal lowering speed for the execution of the same cut. Finally a decision block 172 verifies if the cut is complete, that is, if the sawing of the stone block has been completed. it is (answer NO), the procedure continues to return to block 170 for activating mixture pumping and cutting down. If it is (answer YES), the procedure ends up in block 174 which obviously removes a block of stone sawn from under the machine for sawing and eventually to replace the stone block with a new block to be sawn.

What has been described above illustrates a preferred example of embodiment of the present invention which is not to be considered absolutely in a limiting sense. So much so that from reading the aforementioned description, any expert in this particular technical branch may come to the mind of equivalent measures and solutions to be considered all protected herein according to a scope of protection defined by the following claims. For example, the coincidence circuit which in the diagnosis section 134 is represented by a NOR gate 136, could be constituted by an AND gate with the sole condition of using an inverse logic to the one used.

In the case of use of the present invention with disc saws rotating at very high speeds, the acoustic frequencies that the microphone should detect could be much higher (for example up to 10,000 Hz) and therefore it would be necessary to modify the low-pass filter 104 accordingly and could it would be more convenient to use a piezoelectric microphone instead of a dynamic microphone.

In the same way, the pneumatic cylinders 78 and 94 could be replaced by rotating electric motors driving racks or by electric motors of the so-called linear type.

Finally, the discriminator and diagnostic circuit 100 which has been shown here as constructed with analog components could be wholly or partly constructed with digital components.

Claims (19)

CLAIMS 1. Method for automation of start of cut consisting of ne! detect sound emitted by a sawing machine by taking advantage of a considerable difference in level between the sound emitted by movement without contact of one or more blades with a block of stone to be cut sound emitted by movement with contact of blades with the same block, characterized by the fact to use acoustic detection means capable of measuring the level of sound emitted by the machine, to evaluate the level of said sound and to emit an intervention signal when this level exceeds a predetermined threshold, the intervention serving to activate means that prevent the continuation of an advancement of the or of the blades towards the block to be sawed until means are activated, such as slowed down of the blades and introduction of coolants / lubricants and abrasives, which allow a sawing without traumatic effects on the blades. 2. Method for automating the start of cutting of multi-blade saws on frame as in claim 1, characterized by the fact of acoustically isolating the sawing machine, and in particular its blade holder cloth, from the external environment, of using means of acoustic detectors capable of measuring the level of sound emitted by the machine, of evaluating the level of said sound and of emitting an intervention signal when this level exceeds a predetermined threshold. 3. Method, as in claim 2, characterized in that acoustic detection means are exposed in an acoustically insulated environment, enclosing the sawing machine, only for a limited time around the moment in which one or more blades make the first contact with the block of stone and are withdrawn into a substantially airtight case once they have detected a sound level above the preset threshold. 4. Method, as in claim 3, characterized in that it controls the operation of the acoustic detection means by placing an artificial sound source in the acoustically isolated environment in some position adjacent to the blade frame and exposing said acoustic detection means to the same environment , obtaining an approval signal or an alarm signal according to whether or not the acoustic detection means emit a signal indicating correct perception of the sounds of the artificial source. S. Method, as per claims 1, 3 or 4, characterized in that the acoustic detection is followed by frequency band limitation to consider a frequency band of acoustic signals in which there is a maximum difference in level between the acoustic signals due to the movement of the blade holder frame alone, those due to the engagement of at least one blade with the stone block. or. Method, as in claim S, characterized in that the frequency band is limited to a maximum frequency of 10000 Hz 7. Method, as in claim 6, characterized in that the frequency band is limited to a maximum frequency of 3200 Hz. 8. Method, as in claim 7, characterized in that the frequency band is limited to a maximum frequency of 1600 Hz. 9. Method, as in claim 8, characterized in that 1; frequency band is limited to a maximum frequency of 800 Hz. 10. Method, as in claim 9, characterized in that the frequency band is limited to a maximum frequency of 200 Hz. 11. Method, as in claim 5, characterized in that when the acoustic detection means emit a signal whose level exceeds the predetermined threshold, they activate memory means which remain activated until an external deactivation signal arrives. 12. Method, as in claim 11, characterized by the fact that 3⁄4 the activation of said memory means activates a start cycle of sawing contained in control means completing the apparatus realizing the present start automation method cut. 13. Method, as in claim 12, characterized in that the part of the method made by said control means, after the activation of the memory means, comprises a lifting of the blade holder frame until the blades are disengaged from the stone block, withdrawn in hermetic housing of the acoustic detection means and enabling a cutting cycle. 14. Method, as in claim 13, characterized by the fact that the cutting cycle comprises starting of a pump for mixture of cooler and abrasive liquid, distribution of the mixture in areas corresponding to the blades, beginning of descent or descent of cutting of the blade holder frame preset speed and verification of the completion of the relative cutting cycle. 15. Apparatus for carrying out the method of claims from to 14 characterized in that it essentially comprises a microphone (64) housed in a casing (50) of a substantially hermetically sealed type and equipped with means (78) for causing and withdrawing said microphone ( 64) with respect to said housing (30), microphone (64) being connected to an input of amplifier means (102) which carry the signal to a sufficient amplitude for its processing, the output of the amplifier means is connected to a low-pass filter (104) which eliminates all signals of fre higher than the maximum allowed frequency, the output of the low-pass filter (104) is connected to rectifier means (106) which emits a continuous signal of single polarity and the rectifier means are connected to smoothing means (108) in the form of a low-pass filter which transform the signal of single polarity into a signal of sufficient duration to exclude signals due to transient disturbances the output of the me the smoothing means (108) is connected to a voltage comparator circuit (110) which compares a signal outgoing from said smoothing means (108) with a predeterminable voltage level giving a high output when the level of the signal outgoing from the half smoothing means (108 ) exceeds the predeterminable voltage level and the output of the voltage comparator (HO) is connected to memory means (118 activated by the high output of said voltage comparator circuit (110 and maintaining activation even when said output disappears) halt until the arrival of a deactivation signal (128) coming from the outside and said memory means (118) are connected to 3⁄4 programmable logic controller (122) which controls the automatic execution of a cutting start in a that the activation of the memory (118) leads to command the maneuvers controlled by the programmable logic controller (122). 16. Apparatus, as per claim 15, characterized in that these memory means (118) consist of a flip-flop R-S. 17. Apparatus, as per claim 15, characterized in that it comprises an additional section (1314) for checking the operation of the microphone (64) formed by a coincidence logic circuit which receives the output on its first input (138) d voltage comparator (110) and on a second input thereof (140 the output of an operating signaling means of an artificial sound source so that the combination of the operating signaling of the artificial sound source with no output from the voltage comparator (110) leads to actuate an alarm signal generator (146). 18. Apparatus, as in claim 17, characterized in that the coincidence circuit (138) is a NOR logic gate and the alarm signal generator is a power circuit (144) for the operation of signaling devices (146) such as horns, warning lights or both. 19. Apparatus, as in claim 17, characterized by the fact that the coincidence circuit (138) is an AND logic gate and the alarm signal generator is a power circuit (144) for activating signaling devices (146) such as horns, warning lights or both,