EP1713646B1 - Liquid jet writing tool - Google Patents

Description

The present invention relates to liquid jet writing instruments such as ink.

More particularly, the invention concerns, among these writing instruments, those which comply with the preamble of claim 1.

In known writing instruments of this type, the tubular element generally comprises a feeler having a first end intended to come into contact with the support during writing, and a second end connected to a mechanism for detecting movement of the probe. in contact with the support. This detection mechanism is connected to the processing unit to enable activation of the liquid projection system. Thus, when the user holds the writing instrument in his hand and brings it closer to the support, the probe comes into contact with the surface of the support, which enables the detection mechanism to send a signal to the reader. processing unit to enable liquid projection activation. The documents US 2003/118394 and US 5,501,535 describe such a writing instrument.

Therefore, although the writing head, namely the liquid projection head, no longer needs to be at contact of the support, it is however imperative that the probe of the writing instrument is, meanwhile, in contact with the support to be able to start the projection of liquid. Nevertheless, the projection of liquid on the support is solely related to the fact that the probe is or not in contact with the support, the projection of liquid then being constant and fixed at a predetermined flow as long as the probe is in contact with the support. Therefore, if the writing instrument is moved at high speed on the support, the projection of liquid may be insufficient for a suitable completion of a continuous line. Similarly, when the user moves the writing instrument with a low speed, the projection of liquid can then be too important thus preventing the realization of a suitable feature.

The present invention aims to overcome the technical problems mentioned above, by providing a reliable writing instrument, simple and provides optimum writing comfort for the user.

For this purpose, the subject of the invention is a writing instrument according to claim 1.

With these provisions, the user of the instrument simply controls the activation of the ink projection by bringing the instrument to a suitable distance from the support while transmitting a movement that will be detected by the writing instrument. to vary the frequency and / or the amplitude of the electrical signals controlling the activation of the liquid projection system. This activation of the liquid projection can therefore be stopped by the user, either by immobilizing his hand and thus the instrument, or by removing the writing instrument or more accurately the liquid projection head of the support. This writing instrument therefore makes it possible to cause a controlled projection of liquid as a function of the speed of movement of the instrument under optimal conditions which are close to the writing conditions known hitherto with conventional writing instruments such as than ballpoint pens or felt pens.

Preferred embodiments of the invention are described in the dependent claims.

Other features and advantages of the invention will become apparent from the following description of several of its embodiments, given by way of non-limiting example, with reference to the accompanying drawings.

• la figure 1 est une vue schématique en coupe de l'instrument d'écriture selon un premier mode de réalisation de l'invention ;
• la figure 2 est un schéma bloc des différents éléments constituants l'instrument d'écriture conforme au premier mode de réalisation ;
• la figure 3 est un schéma bloc représentant schématiquement les moyens de détection de mouvement de l'instrument d'écriture selon un premier exemple (non revendiqué) pour faciliter la compréhension de l'invention; et
• la figure 4 est un schéma bloc représentant schématiquement les moyens de détection de mouvement de l'instrument d'écriture selon un second exemple (non revendiqué) pour faciliter la compréhension de l'invention.

On the drawings:

• the figure 1 is a schematic sectional view of the writing instrument according to a first embodiment of the invention;
• the figure 2 is a block diagram of the various elements constituting the writing instrument according to the first embodiment;
• the figure 3 is a block diagram schematically showing the motion detection means of the writing instrument according to a first example (not claimed) to facilitate the understanding of the invention; and
• the figure 4 is a block diagram schematically showing the motion detection means of the writing instrument according to a second example (not claimed) to facilitate the understanding of the invention.

In the different figures, the same references designate identical or similar elements.

The figure 1 represents a writing instrument 1 which comprises a substantially tubular element 2 which extends between a first end 2a and a second end 2b. This tubular element 2 has an inner wall 21 delimiting a hollow interior space, and an outer wall 22 intended to be handled by a user.

The hollow interior space delimited by the inner wall 21 of the tubular element 2 comprises a liquid reservoir 3 and a projection system 4 of said liquid directly associated with the reservoir 3. The liquid reservoir 3 is removably mounted in the hollow interior space of the tubular element 2 so as to be replaced after depletion of said liquid by another tank. The liquid contained in this reservoir may, depending on the use of the instrument, be formed by ink, or by an ink-eraser or ink-masking liquid when the instrument is used as a corrector or by glue when said instrument is used as an applicator or glue sprayer. The projection system 4 is formed by a liquid projection head 41 directly connected by a channel 31 to the liquid reservoir 3, and by an electrical signal generator 42 intended to control the activation or not of said projection head 41.

In the example considered here, the projection head 41 is a piezoelectric projection head which comprises a projection nozzle 43 disposed at the end 2a of the tubular element 2. This end 2a of the tubular element can be constituted by a tip directly fitted on the inner wall 22 of the central portion of the tubular element 2. This nozzle 2 has an end orifice in which is disposed the nozzle 43 of the projection head 41. This nozzle of projection 43 may be fixedly mounted on the tip 2a or retractably by means of a suitable mechanism to accommodate said nozzle inside the nozzle avoiding thus any risk of deterioration of said nozzle in case of non-use of the writing instrument. The projection head 41 comprises, in a manner known per se, a piezoelectric element adapted to deform when it is subjected to the electrical signals coming from the generator 42, thus creating microdroplets 7 at the level of the projection nozzle 43 and which are projected on the support 8.

The liquid projection system 4 may also be formed by a substrate, for example glass, on which is reported at least one heating resistive element positioned at at least one small channel containing a small amount of ink from 3. Thus, when an electrical signal is generated by the generator 41 on the resistive element, it instantly rises in temperature thereby creating a vapor bubble in the ink, which bubble expels a thin droplet 7 of liquid on the support 8.

The writing instrument also comprises a processing unit 6 intended to activate the electrical signal generator 42 (or electrical pulsation) to enable the projection nozzle 43 of the projection system to project the droplets 7 remotely onto the support 8 The hollow interior space of the tubular element 2 also comprises at its end 2b a power supply source formed, for example, by a battery, or even two rechargeable batteries or not, allowing by means of a switch 11 powering up the various electrical elements forming the writing instrument. This switch 11 may be replaced by any means of activation actuable by the user of the instrument, and in particular by means of detecting the grip of the tubular element 2 by the user such as, for example , a capacitive sensor arranged at level of the outer wall 22 of the tubular element 2 and for detecting a pressure when the user grasps the instrument.

The end 2b of the tubular element 2 may for example be in the form of a cap removably mounted on the central portion of said tubular element 2 to allow the replacement of the two used batteries 10 with new batteries.

The tubular element 2 also comprises at its end 2a control means 12 for controlling the distance between the projection head 41 and the support 8. These control means 12 may be formed by a probe connected to a detector itself. even connected to the processing unit 6. In the example considered here, the control means are formed by measuring means 12 for measuring, without any physical contact of the writing instrument on the support 8, the distance between the projection head 41 and the support 8. More exactly, the measuring means 12 are adapted to measure the distance between the projection nozzle 43 and the support 8.

In this embodiment, the measuring means 12 are constituted by an optical system 13 which comprises, for example, an infrared LED 13a which sends an incident light beam FI towards the support 8 so as to create a light spot on said support 8 and a beam of reflected light FR which will then be analyzed by a photodiode 13b so as to calculate the angle of inclination of the incident beam FI relative to the support 8.

Since the distance between the photodiode 13b and the infrared LED 13a is known and the inclination angle of the incident light beam F1 is calculated, it is then sufficient to calculate, by simple trigonometric relations, the distance that separates the infrared LED. of the support 8. This photodiode can be formed by a S6560 photodiode marketed under the trademark HAMAMATSU.

According to another variant embodiment, the optical system 13 may also comprise means for transmitting a conical light beam whose axis of symmetry merges with the longitudinal axis of the tubular element 2. The optical system then comprises a sensor adapted to calculate the radius of the light spot formed by the conical beam on the support 8. The radius of the light spot being proportional to the distance between the emission means of the conical beam of the support 8, it is then possible to determine linearly the distance between the transmitting means and the support. Similarly, if the axis of symmetry of the conical beam is inclined relative to the support, the light spot created on the support will no longer be circular but ellipsoidal, and the sensor will also be adapted to measure the length of the small axis of the ellipsoidal spot so to determine the distance between the transmission means of the conical beam of the support. Indeed, in this case and whatever the inclination of the writing instrument, the length of the small axis of the ellipsoidal spot is only proportional to the distance between the transmission means of the support, only the length of the large axis of the ellipsoidal spot being proportional to the inclination of the conical beam.

According to an alternative embodiment, the measuring means 12 may also be constituted by an acoustic sonic probe. In this case, the distance measured between the nozzle 43 and the support 8 corresponds to the smallest distance separating said nozzle 43 from the support 8 and this, independently of the inclination of the writing instrument with respect to the support 8.

As can be seen in reference to figures 1 and 2 , the optical system 13 which forms the measuring means 12 is directly connected directly to the processing unit 6 which stores in memory the measurement made by the optical system 13. The processing unit can also be adapted to control the optical system 13 to perform repeated measurement operations in specified time intervals. These time intervals could for example be between 1 ms and 0.1 seconds.

The tubular element 2 also comprises motion detection means which, according to the first embodiment of the invention shown in FIGS. figures 1 and 2 , are formed by an accelerometer. This accelerometer 14 is directly connected to the processing unit and can be placed anywhere within said tubular element. For example, the accelerometer may be disposed at the end 2b of the tubular element so as to undergo the movements having the greatest amplitude when the user uses the writing instrument.

The operation of the writing instrument will now be described with reference to figures 1 and 2 .

When the user wishes to use the writing instrument 1 to write on a support 2, he first puts the various electrical elements of said pencil in tension by actuating the switch 11.

The user then brings the end of the writing instrument closer to the support 8, so that the measuring means formed by the optical system 13 calculate automatically and without physical contact with the support 8 the distance that separates the nozzle in the same way, the movement of the writing instrument towards the support 8 is detected by the accelerometer 14 which sends a detection signal directly to the processing unit 6.

This processing unit 6 is adapted to control the activation of the liquid projection system 4 and therefore the projection of droplets 7 on the support 8 only when the accelerometer 14 detects a movement of the writing instrument and when the measuring means 12 formed by the optical system 13 determine that the distance between the spray nozzle 43 and the support 8 is less than a predetermined maximum value.

This predetermined maximum value may for example be indicative of the order of 1 cm.

Thus, when the measuring means 12 determine that the distance between the nozzle 43 and the support 8 is greater than the predetermined maximum value and that the accelerometer detects a movement of the writing instrument, the processing unit 6 does not will not control the activation of the projection system and no droplets will be projected onto the support 8.

Similarly, the processing unit 6 will not control the projection of droplets when the writing instrument is not in motion even if the nozzle 43 is at a suitable distance from the support, that is to say at a distance less than the predetermined maximum value.

The accelerometer therefore sends in real time all the acceleration and deceleration measurements to the processing unit 6 according to the movements that the user applies to the writing instrument. The processing unit 6 can then, according to measurements made using the accelerometer, control the electrical signal generator 42 so as to vary the frequency and / or the amplitude of the electrical signals directly sent to the head of liquid projection 41, thereby varying proportionally the size and / or the frequency of projection of the droplets 7 on the support 8.

For example, if the user quickly moves the writing instrument during its use, the accelerometer then sends the processing unit the measurement of the acceleration so that said processing unit 6 controls an increase in the frequency of the electrical signals so as to increase the frequency of projection of the droplets 7. This makes a line as continuous as possible on the support 8, thus avoiding the realization of a pattern or a discontinuous line consisting of a succession of droplets more or less spaced apart.

Conversely, when the accelerometer measures a deceleration, the processing unit 6 can then proportionally decrease the frequency of the electrical signals in order to reduce the droplet projection frequency 7. This reduction in the droplet projection frequency 7 allows to avoid excessive intake of liquid for the realization of a pattern when the writing instrument is moved at low speed.

According to a first example (not claimed) represented on the figure 3 , the motion detection means are formed by the optical system 13 and the processing unit 6 which determines speeds or ranges of movement speed of the projection head 41 relative to the support 8 as a function of the measurements made by the optical system 13.

More particularly, according to this first example, the optical system 13 may also include an infrared LED 13a which will for example be modulated by means of a modulator 50 so as to reduce the possibility of interference with other light sources. In this way the infrared LED 13a emits an incident light beam FI towards the support 8 to create a spot light on said support and a beam of reflected light FR which will then be analyzed by a photodiode 13b. For this purpose, the reflected light beam FR or the reflected signal is detected and measured using a photodiode to eliminate the effects of interference so as to make the measurements more reliable.

Thus, according to this first example, it is proposed that the optical system 13 in cooperation with the control unit 6 be used to provide both an estimate of the distance that separates the projection head 41 from the support 8 but also to estimate the speed of displacement of this projection head 41 relative to the support 8. In this case, the optical system 13 or more precisely the infrared LED 13a and the corresponding photodiode 13b are arranged at the level of the projection head 41 so that that the optical system can see or observe a small area of the support 8 which is relatively close to the area on which the droplets of liquid will be affixed without being exactly superimposed with this area on which the liquid droplets 7 will be affixed. This system requires that the viewing area of the optical system 13 on the support is relatively small so that it may be useful to use lens systems to focus the different light beams and reflected on the area of the light. smaller possible so as to retain the components of the reflected signal relating to the speed of movement of the writing instrument relative to the support 8.

The infrared LED 13a is for example modulated so as to save the power used and in order to filter the most effectively possible background noise. A typical modulation frequency may for example be in a range of 25 to 30 kHz or even above, avoiding the frequency band between 38 and 40 KHz which is often used for example by infrared remote control systems of televisions.

The photodiode 13b, as we can see on the figure 3 as for it, detects the signal reflected directly from the surface of the support 8, and this signal is amplified by means of a preamplifier 23 coupled in an alternative mode. This preamplifier 23 has a bandwidth frequency response which is centered around the infrared modulation frequency so as to allow elimination of unwanted signals. In practice, different amplification steps coupled in alternate mode may be necessary. Nevertheless, these different amplification stages coupled in alternative mode can be located after the demodulator 24 directly located downstream of the preamplifier 23.

The alternating signal obtained by means of the preamplifier 23 is then demodulated by the demodulator 24. Additional resistive components can also be added so as to alter the charging and discharging time constants as a function of the frequency response of the detected signals.

The demodulated alternating signal is then sent to a low-pass filter 25 so as to determine the amplitude of the demodulated signal which is representative of the distance separating the optical system 13 from the support 8. The low-pass filter makes it possible to reduce the noise. unwanted by smoothing the signal slightly. A higher cut-off frequency of between 50 and 100 Hz may for example be suitable for this low-pass filter.

The demodulated signal is also amplified again in alternative mode so as to extract the data relative to the speed of displacement of the writing instrument relative to the support 8. Indeed, when the writing instrument is stationary relative to the support 8, the amplitude of the demodulated signal remains constant and no additional alternative component is superimposed on the demodulated signal. However, when the writing instrument is moved relative to the support 8, the demodulated signal changes amplitude in relation to the changes in distance between the writing instrument and the medium 8 but also in relation to the local changes. reflectivity of the paper. Depending on the optical system chosen, these amplitude changes of the demodulated signal may be relative to the support 8, to the surface texture of this support 8, to visible marks or also to lines already made by means of a projection of droplets of liquid on the support. In a conventional manner, when the writing instrument is moved relative to the support 8, additional alternating components are added to the amplitude of the demodulated signal with an order of magnitude of a few KHz as a function of the speed of movement of the writing instrument with respect to the support 8.

Thus, the frequency components embedded in the demodulated signal are representative of the speed of displacement of the writing instrument relative to the support 8. These additional frequency components which can be likened to a noise embedded in the demodulated signal and which is representative of the speed of the writing instrument can be analyzed in different ways. For example by means of three filters 26, 27 and 28 each having a predetermined bandwidth so as to extract three different speed ranges, namely a first range of slow speeds V1 of the writing instrument relative to the support 8, a second range of average speeds V2 and a third high speed range V3.

Other digital processing of the signals picked up by means of the photodiode 13b can be used as for example zero crossing detectors.

Thus, when the writing instrument is stationary relative to the support 8, no noise relating to the displacement and speed of the writing instrument is present in the demodulated signal. Conversely, when the writing instrument is moved without contact relative to the support 8, a noise is automatically generated in the demodulated signal and this depending on the type of surface of the support 8, and this noise is trying to increase in size. frequency when the writing instrument is moved more and more rapidly relative to the support 8.

According to an alternative embodiment, the optical system 13 may also comprise two photodiodes 13b which are arranged to observe two adjacent regions inside the light spot obtained by means of the infrared LED 13a on the support 8. The electronic circuit used then compares the signals received from the two photodiodes 13b so as to generate an output signal when there is a significant difference between the two demodulated signals obtained. The different output signals thus produced can be analyzed and, for a given area, the frequency of these signals will then reflect the speed of movement of the writing system relative to the support 8.

Furthermore, according to an alternative embodiment, the optical system 13 may not be provided with lenses but with collimators for example made by means of an optically black tube at both ends of which are reported discs having openings of very small diameter.

The infrared LED 13a can also be replaced by an infrared laser diode.

According to an alternative embodiment, the processing unit 6 can also be adapted to stop the activation of the liquid projection system when the spray nozzle 43 is too close to the support 8 to allow the liquid droplets 7 to be suitably projected on the support. In this case, the processing unit 6 will control the activation of the liquid projection system only if the motion detection means 14 or 13 detect a movement of the writing instrument relative to the support and if the optical system 13 determines that the distance between the spray nozzle 43 and the support 8 is within a range delimited by a predetermined minimum value and a predetermined maximum value.

Similarly, to allow a better user writing comfort, the processing unit 6 can be adapted to activate communication means 16 intended to emit an alert signal when, on the one hand, the optical system 13 determines that the distance between the ink projection head 41 and the support 8 is at least less than a predetermined maximum value, and that secondly, the accelerometer 14 or the optical system 13 in relation to the unit 6 does not detect any movement of the projection head 41 relative to the support 8 for a predetermined time interval. These communication means 16 may, for example, be in the form of a visible light signal emitter or an audible acoustic signal emitter, thus enabling the user to know that the liquid projection head 41 or, more exactly, the nozzle of projection 43 is at a suitable distance from the support to enable activation of the generator 42 of electrical signals and that even accidental movement of the writing instrument is likely to cause the activation of the projection system 4 and thus the projection of liquid droplets on the support 8.

Similarly, to allow a better user writing comfort, the processing unit 6 can be adapted to activate the communication means 16 to emit an alert signal when the liquid projection system 4 has not has not been activated for a given time interval (for example 30 seconds or a minute) and that the measuring means 12 detect that the distance is again adequate between the projection head 41 and the support 8 and that the detection means of movement 14 or 13, 6 again detect a movement of the writing instrument. In this case, the processing unit activates the communication means during, for example, a maximum of two seconds to warn the user that the liquid projection is imminent, and after this maximum time interval of two seconds, the processing unit 6 then activates the liquid projection system 4.

In the case where the measuring means 12 are formed by an acoustic sonic probe, the tubular element 2 can also be provided, at its end 2a, means for emitting a visible light spot on the support 8 , this light spot being intended to represent the point of impact of the droplets 7 on the support.

The figure 4 represents a second (not claimed) example of the motion detection means which are formed here by the optical system 13 and the processing unit 6 which will then be adapted to reduce the frequency and / or the amplitude of the electrical signals controlling the activation of the projection head 41 when the optical system 13 detects the presence of liquid 7 on the support 8, which is then representative of a decrease in the speed of movement of the writing system as a whole relative to the support 8. More exactly as can be seen in this figure 4 the optical system is always formed by an infrared LED 13a as well as a corresponding photodiode 13b which will be equipped with a system of lenses or collimators so as to allow both the determination of the distance which separates the projection head 41 of the support 8 but also to examine the area of the support 8 on which are intended to be applied the droplets 7. The optical system, or more exactly the LED 13a and the photodiode 13b must be arranged relative to the projection head 41 of such that the incident light beam F1 as well as the reflected light beam FR are precisely focused on the area on which the droplets 7 are intended to be applied. The signals obtained from the photodiode 13b are then processed by means of a preamplifier and a phase detector 29 so as to send the information to the processing unit 6 which will command one turns, on the one hand, the control circuit or the electrical signal generator 42 supplying the projection head 41, and on the other hand, the control circuit of the infrared LED 13a.

The processing unit 6 is adapted to allow ejection of droplets 7 from the projection head 41 with a maximum frequency when the distance between the projection head 41 and the support 8 is in a suitable range and the system optical 13 does not detect the presence of liquid 7 on the support 8. In this case the processing unit 6 controls the ejection of droplets 7 on the support 8 as shown in FIG. figure 4 .

If the writing instrument remains stationary relative to the support 8, the optical system 13 then automatically detects the presence of liquid on the support 8 so that the processing unit 6 controls the significant decrease or the stop according to the case of the projection of droplets 7 on the support. As soon as the writing instrument is moved, the optical system 13 is found in front of a clean zone of the support 8 so that the processing unit 6 controls the ejection of droplets at a maximum frequency. Conversely, as soon as the speed of the writing instrument decreases relative to the support 8, the optical system 13 is then able to detect the presence of droplets at the right of the projection head 41 so that the unit processing 6 will then automatically control the decrease of the frequency and / or amplitude of the electrical signals sent by the signal generator 42 to the projection head 41.

According to this second example shown on the figure 4 the liquid used or the ink used may have appropriate reflectivity properties with respect to the optical system 13 so that each liquid droplet 7 affixed to the support 8 is automatically detected by said optical system 13.

Claims (10)

1. Writing instrument comprising a substantially tubular element (2) that extends between a first end (2a) and a second end (2b) and that is designed to be held by a user, said tubular element (2) containing:

   - a reservoir (3) of liquid;

   - a liquid spray system (4) comprising a liquid spray head (41) connected to the reservoir (3) of liquid, the spray head (41) being designed to spray the liquid onto a medium (8) from a distance;

   - a processor unit (6) serving to activate the liquid spray system (4) so as to enable the spray head (41) to spray the liquid onto the medium (8) from a distance (8);

   - monitor means (12) for monitoring the distance between the spray head (41) and the medium (8), the monitor means (12) being connected to the processor unit (6);

   - movement detector means (14; 13,6) for detecting movement of the spray head (41), the movement detector means (14; 3, 6) being connected to the processor unit (6);

   the processor unit (6) being adapted to activate the liquid spray system (4) when at least the monitor means (12) determine that the distance between the spray head (41) and the medium (8) is appropriate; characterized in that the processor unit (6) is adapted to cause the frequency and/or the amplitude of electrical signals for activating the liquid spray system (4) to vary as a function of the movement detected by the movement detector means (14; 13,6);
   in that the movement detector means are formed by an accelerometer; and
   in that the monitor means (12) are formed by measurement means (12) for measuring the distance between the spray head (41) and the medium (8), and the processor unit (6) is adapted to activate the liquid spray system (4) when firstly the measurement means (12) determine that the distance between the spray head (41) and the medium (8) is less than a predetermined maximum value, and secondly the movement detector means (14; 13,6) detect movement.
2. Instrument according to claim 1, in which the measurement means (12) are adapted to measure the distance between the spray head (41) and the medium (8) without physical contact between the writing instrument (1) and said medium (8).
3. Instrument according to anyone of claims 1 or 2, in which the processor unit (6) is adapted to activate the liquid spray system (4) when firstly the measurement means (12) determine that the distance between the spray head (41) and the medium (8) lies in the range defined by a predetermined minimum value and by said predetermined maximum value, and when secondly the movement detector means detect movement of the tubular element (2).
4. Instrument according to anyone of the preceding claims, in which the measurement means (12) comprise an optical system (13) serving to measure the distance between the spray head and the medium.
5. Instrument according to anyone of claims 1 to 3, in which the measurement means (12) comprise an ultrasound acoustic probe serving to measure the distance between the spray head (41) and the medium (8).
6. Instrument according to anyone of the preceding claims, in which the tubular element (2) contains an electrical power source (10) and switch means (11) connected to the electrical power source (10), said switch means (11) being actuatable by the user in order to switch on the liquid spray system (4), the processor unit (6), the monitor means (12) and the accelerometer (14).
7. Instrument according to anyone of the preceding claims, in which the tubular element (2) contains emitter means for emitting a visible light spot onto the medium in order to represent the point of impact of the liquid sprayed onto the medium (8).
8. Instrument according to anyone of the preceding claims, in which the liquid spray head (41) comprises at least one nozzle (43) for spraying droplets (7) of liquid, and the spray system (4) further comprises an electrical signal generator (42) for generating electrical signals for activating said at least one nozzle (43) of the spray head (41).
9. Instrument according to anyone of claims 2 to 12, in which the processor unit (6) is adapted to activate communication means (16) serving to emit a warning signal to the user when firstly the measurement means (12) determine that the distance between the spray head (41) and the medium (8) is less than a predetermined maximum value, and when secondly the movement detector means do not detect any movement of the tubular element (2) for a predetermined time interval.
10. Instrument according to anyone of the preceding claims , in which, when the liquid spray system (4) has not been activated for a first time interval, the processor unit (6) is adapted to activate, for a second time interval, communication means (16) serving to emit an alarm signal, and then to activate the liquid spray system (4) when the measurement means (12) determine that the distance between the spray head (41) and the medium (8) is once again less than the predetermined maximum value, and when the movement detector means detect, once again, movement of the tubular element (2).

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