FR2743750A1 - Determining quantity of ink present in reservoir of e.g. printer - Google Patents

Abstract

The ink-filled reservoir (112) has an electrode (120) in contact with the ink which excites it at a frequency exceeding 10MHz using an oscillator (117). The ink produces an electromagnetic signal in response. The response signal is picked up by a receiving antenna (116) and supplied to the principal processor (100) via a conversion unit (115). The relationship between these signals and the quantity of ink present is stored and enables the latter to by displayed (104). The signals used may relate to amplitude or preferably to phase difference between incident and secondary radiation.

Description

 The present invention relates generally to a method and a device for determining the quantity of product present in a reservoir, and more particularly for determining the quantity of ink present in the reservoir of an image transfer device.

 For image transfer devices, such as printers, which use inkjet technology, many devices and methods have been devised for determining the amount of ink.

 A first known type of detection uses the electrical characteristics of the ink by measuring the resistance of the latter between two electrodes.

 The document EP-AO 370 765 describes a device for detecting the quantity of ink present in a reservoir, comprising two electrodes placed in the channel connecting an ink ejection head to the ink reservoir as well as a means of detection of the electrical resistance between the two electrodes. The first electrode is located near the ejection head while the second is remote from the latter. A potential difference is applied between these two electrodes. The resistance of the ink present in the reservoir is measured. The result shows that the resistance measured increases non-linearly when the quantity of ink in the reservoir decreases.

Measuring a resistance between two electrodes does not allow precise measurement of the quantity of ink. Indeed, the variation in resistance of
The ink present in the reservoir, as a function of the variation in quantity of ink, is a complex relationship, exhibiting an inflection such that it approximates an all-or-nothing relationship.

 A second known type of detection uses the electrical characteristics of the ink by measuring its capacity.

 Document US-A4 700 754 describes a detection of the level of liquid ink in a flexible tank which shrinks as the level of ink decreases. The outer bottom wall is coated with a conductive layer constituting an electrode of a capacitor. The wall of the reservoir acts as a dielectric of the capacitor thus produced while the ink surface in contact with the lower wall constitutes the second face of the capacitor. A measuring electrode placed in the center of the reservoir connects the ink to a measuring device. When the ink level decreases, the ink surface facing the conductive layer coated on the wall decreases, so the value of the equivalent capacity also decreases. The fact that the reservoir is flexible allows the measuring electrode to remain in contact with the ink.

 This second type of detection is used for a cartridge having flexible walls and cannot be applied for rigid cartridges. Indeed, the contact between the measurement circuit and the ink can only be made if the upper wall, when it crashes, forces the measurement electrode to be in contact with the ink.

 On the other hand, this measurement of the ink level is only possible for liquid ink contained in a reservoir without spongy body.

 In addition, it is difficult to know the ink level if it is less than a level between the measurement electrode and the bottom wall.

Indeed, the measurement electrode cannot go down to the bottom of the tank. The measuring range is thus limited in the lower values.

 The present invention aims to remedy the drawbacks of the prior art by providing a device and a method for determining the quantity of product present in a tank which supplies with a satisfactory reliability the quantity of product in the largest measurement range, while being simple and economical to implement.

 During their work, the inventors have found that an electrical excitation of a product causes electromagnetic radiation of the latter, and that this radiation depends not only on the excitation signal, but also on the quantity of product. In this context, the invention consists in analyzing the radiation caused by an electrical excitation of the product.

To this end, the invention proposes a method for determining an amount of product present in a tank, characterized in that it comprises the steps of:
- apply a predetermined excitation signal to the product present in the tank, so that the product radiates an electromagnetic signal,
- picking up the electromagnetic signal radiated by the product with a means for picking up producing an electrical signal representative of the electromagnetic signal, and
- process the electrical signal to produce a signal representative of the quantity of product present in the tank.

 In general, the invention applies to any product, in particular a consumable product used in a given device.

 Preferably, the invention applies to ink contained in the reservoir of an image transfer device. By ink is meant here any liquid, solid, gaseous or powdery product intended to modify an optical or physical factor of the printing medium.

 The method according to the invention has not only the advantage of solving the technical problem stated above, but also of being adaptable to a large number of existing devices.

According to a first embodiment, simple and economical to implement, the step to treat comprises the steps of:
- detect the amplitude of the electrical signal, and
- produce the signal representative of the quantity of product from a value given by a calibration table as a function of the amplitude detected.

According to a second embodiment, less sensitive to possible external disturbances than the previous one, the step to treat comprises the steps of:
- detect a phase difference between the electrical signal and the excitation signal, and
- produce the signal representative of the quantity of product from a value given by a calibration table as a function of the detected phase difference.

 Advantageously, the method further comprises the step of displaying a representation of the amount of product present in the tank, or the step of transmitting the signal representative of the amount of product present in the tank to a remote device so that it displays a representation of the quantity of product present in the tank.

 This product being a consumable product used in a given device, the user knows at all times the quantity of product remaining in the tank and is thus able, for example, to decide to fill the tank before it is completely empty, or to replace the empty reservoir with a full reservoir, or alternatively to replace the cartridge comprising the reservoir, in the case of an ink cartridge.

In another aspect, the invention relates to a device for determining a quantity of product present in a tank, characterized in that it comprises:
a means for exciting the product present in the tank by a predetermined excitation signal, so that the product radiates an electromagnetic signal,
a means for picking up the electromagnetic signal and producing an electrical signal representative of the electromagnetic signal, and
a means for processing the electrical signal and producing a signal representative of the quantity of product present in the tank.

 The device according to the invention is particularly suitable for implementing the above method. The device according to the invention has advantages similar to those of the method described above.

 According to a first preferred characteristic, convenient to implement, the means for exciting is an electrode placed in contact with the product in the reservoir, and the means for picking up the electromagnetic signal is a metallic piece forming an antenna, such as a metallic ribbon, arranged outside the tank.

 According to a second preferred characteristic, the means for exciting is a metal part forming an antenna, such as a metal strip, placed outside the tank, and the means for picking up the electromagnetic signal is an electrode placed in contact with the product in the tank.

 Advantageously, the means for exciting and the means for picking up the electromagnetic signal are positioned relative to each other so that the product is located between them. Thus, the detection conditions are optimized.

 According to preferred features of the invention, the means for exciting is supplied by an oscillator connected to the means for exciting via a switch and the excitation signal is a high frequency alternating signal, preferably of frequency greater than 10 MHz.

 The inventors have determined that a frequency greater than 10 MHz optimizes the determination of the quantity of product.

 According to a first embodiment, simple and economical to implement, the means for processing comprises an envelope detector and an analog-digital converter for producing a digital signal representative of the amplitude of the electrical signal.

 According to a second embodiment, less sensitive to possible external disturbances than the previous one, the means for processing comprises a phase comparator and an analog-digital converter to produce a digital signal representative of the phase difference between the electrical signal and the signal of excitement.

 Advantageously, the device also comprises means for displaying a representation of the quantity of product in the tank.

The invention is adaptable for determining quantities of product in several tanks respectively; according to a first embodiment, the device is then characterized in that it comprises:
- for each reservoir, a said means for exciting the product which is present therein by a predetermined excitation signal, so that the product radiates an electromagnetic signal,
a common means for picking up the electromagnetic signal and producing an electrical signal representative of the electromagnetic signal, and
- a common means for processing the electrical signal and producing a signal representative of the quantity of product present in the tank.

According to a second embodiment, the device is characterized in that it comprises:
a common means for exciting the product in each of the reservoirs by a predetermined excitation signal, so that the product radiates an electromagnetic signal,
- for each tank, a said means for picking up the electromagnetic signal and producing an electrical signal representative of the electromagnetic signal, and
- a common means for processing the electrical signal and producing a signal representative of the quantity of product present in the tank.

 In another aspect, the invention provides a product reservoir, characterized in that it comprises a single electrode disposed in contact with the product in the reservoir.

 The reservoir is advantageously used either to produce an electromagnetic signal radiated by the product, thanks to the supply of the electrode by a predetermined excitation signal, in order to determine the quantity of product present in the reservoir, or to collect thanks to the electrode an electromagnetic signal caused by a predetermined excitation signal, in order to determine the quantity of product present in the tank.

 The reservoir is advantageously the ink reservoir of an image transfer device.

The characteristics and advantages of the present invention will appear more clearly on reading several embodiments illustrated by the attached drawings, in which:
FIG. 1 is a block diagram of an embodiment of an image transfer device according to the invention,
FIG. 2 is a simplified perspective view of part of the image transfer device according to the invention,
FIG. 3 is a simplified and schematic view of an ink tank included in the device of FIG. 1,
FIG. 4 is a block diagram of a first embodiment of a conversion circuit according to the invention, included in the device of FIG. 1,
FIG. 5 is an experimental curve representing measurements made thanks to the invention,
FIG. 6 is a block diagram of a second embodiment of the conversion circuit according to the invention, included in the device of FIG. 1, and
- Figure 7 is an algorithm for determining the amount of ink according to the invention.

 With reference to FIG. 1, the invention applies to an image transfer device 10 generally included in an image or data processing device 11. The following description more particularly refers to a printer with inkjet, but the image or data processing device 11 can also be, for example, a laser printer, or be included in a fax machine, or even a microcomputer. The organs other than those of the image transfer device 10 are well known to those skilled in the art and therefore are neither shown nor described.

 The image transfer device 10 receives data to be printed D1 via a parallel input / output port 107 connected to an interface circuit 106. The circuit 106 is connected to a control circuit ink ejection 110, which controls an ink cartridge 111, via an amplification circuit 114.

 The ink cartridge 111 is interchangeable and is mounted on a reciprocating translation carriage actuated by a motor 102. The ink cartridge 111 essentially comprises an ink tank 112 and a print head 113.

 The printer further comprises a main data processing circuit 100, associated with a read-only memory 103 and a random access memory 109. The read-only memory 103 contains the operating programs of the main processing circuit 100, while the random access memory 109 , also associated with the ink ejection control circuit 110, temporarily stores the data D1 received via the interface 106 as well as the data processed by the main processing circuit 100.

 The main processing circuit 100 is connected to a display 104, on which the main processing circuit 100 controls the display of messages representative of the operation of the printer. The main processing circuit 100 is connected to a keyboard 105, comprising at least one switch, by which the user can transmit operating commands to the printer.

 The main processing circuit 100 is also connected to the motor 102 via an amplification circuit 101. The motor 102 moves the carriage which carries the print cartridge 111. The motor 102 is for example a motor step by step.

 The printer described above is conventional and well known to those skilled in the art. It will therefore not be more detailed.

 According to the invention, the ink is excited by a predetermined electrical signal and the resulting electromagnetic radiation is analyzed to determine the amount of ink in the tank.

 Thus, according to the invention, the printer generally comprises a means 120 for exciting the product present in the tank by a predetermined excitation signal SE, so that the product radiates an electromagnetic signal, a means 116 for picking up the electromagnetic signal and producing an electrical signal representative of the electromagnetic signal, and means 115 for processing the electrical signal and producing a signal representative of the amount of product present in the tank.

 The means for exciting is an electrode 120 disposed in contact with the ink and the electromagnetic sensor is an antenna 116 located outside the tank. According to a variant described below, the means for exciting can be outside the tank and the means for picking up inside.

 The inventors have observed that the electrical characteristics of the transmitting antenna formed by the ink contained in the reservoir are variable as a function of the quantity of ink.

 The alternative excitation signal SE is predetermined, and has a frequency greater than or equal to 10 MHz, for example 18 MHz, supplied by an oscillator 117 via a switch 118 and an amplifier 119.

 The main processing circuit 100 is connected to the switch 118 to control it and thus authorize the transmission of the alternating signal between the oscillator 117 and the electrode 120.

 The electromagnetic sensor 116 is a receiving antenna which is connected to a conversion circuit 115, itself connected to the main processing circuit 100. The electromagnetic sensor 116 detects electromagnetic radiation emitted by the ink forming the transmitting antenna when it is excited by the excitation signal SE. The electromagnetic sensor 116 transforms the electromagnetic signals received into an electrical signal S1. The electromagnetic sensor 116 supplies the electrical signal S1 to the conversion circuit 115 which supplies in response a digital signal SN to the main processing circuit 100.

 As a variant, the main processing circuit is replaced by a processing circuit internal to a microcomputer, in particular if the image transfer device 10 is included in this microcomputer.

 Referring to Figure 2, the printing device conventionally comprises a carriage 60 for carrying the print cartridge 111. The carriage is driven in a reciprocating movement on a movement path formed by guide rails 67. The motor 102 drives the carriage 60 by means of a belt device 63. The path of movement of the print head 113 is parallel to a line on a printing medium, not shown, such as a sheet of paper. A flexible cable 62 connects the amplification circuit 114 to the ink cartridge 111.

 In the preferred embodiment of the invention, the electromagnetic sensor 116 is a metallic and elongated piece, such as a ribbon.

Its length is adapted to the frequency of the excitation signal SE. For example, for a frequency of 18 MHz, it has been found experimentally that the length of the electromagnetic sensor 116 is preferably 111 mm. The electromagnetic sensor 116 is bonded to a part of the structure of the printing device or to the carriage 60. As a variant, the electromagnetic sensor is on the tank, or even inside the tank.

 The electromagnetic sensor detects electromagnetic radiation emitted by the ink cartridge 111, or more precisely by the ink contained in the reservoir 112 when it is excited by the excitation signal SE.

 The cable 62 also connects the amplifier 119 to the electrode 120.

 Referring to Figure 3, the ink tank 112 schematically comprises a casing 30 of plastic material permeable to electromagnetic radiation. An orifice 32 is provided for the outlet of the ink. The envelope 30 is filled with a spongy body soaked in ink 31.

The invention also applies to other types of ink tank, in particular those not comprising a spongy body. The electrical characteristics of the transmitting antenna formed by the ink contained in the reservoir are variable depending on the amount of ink.

 The electrode 120 is located on an internal face of the envelope 30 so that it is in contact with the ink. In the embodiment illustrated in FIG. 3,1 'electrode 120 is a conductive layer arranged against an internal vertical wall of the envelope 30. As a variant, the electrode 120 is a metal plate or is placed on the bottom of the envelope 30.

 The electrode 120 transmits the high frequency excitation signal SE supplied by the oscillator 117 to the ink of the spongy body 31.

 Preferably, the electrode 120 and the receiving antenna 116 are positioned relative to each other so that during the measurement detailed below, the ink contained in the reservoir is located between the electrode 120 and the receiving antenna 116.

 Alternatively, the respective functions of the electrode 120 and the receiving antenna 116 are exchanged. The antenna 116 is a transmitting antenna which receives the excitation signal SE, as shown in dotted lines in FIG. 1.

The ink contained in the reservoir then acts as a receiving antenna.

The electrode 120 is a means for picking up the electromagnetic radiation caused by the excitation signal and transmitting the received signal to the conversion circuit 115, as shown in dotted lines in FIG. 1.

 The invention also applies to a printer having several ink tanks, such as a color printer. In this case, each of the reservoirs is equipped with a respective electrode 120, which is either a means for exciting, or a means for sensing. In the first case, the printer comprises a means for receiving common, and a means for treating common for all the tanks. In the second case, the printer comprises a means for exciting common, and a means for treating common for all the tanks. In both cases, the sharing of part of the resources allows an economic realization and use of the invention.

 According to FIG. 4, the first embodiment of the conversion circuit extracts the amplitude of the radiation emitted by the ink contained in the reservoir 112 in response to the excitation signal SE. The conversion circuit 115 comprises an amplifier 50 connected to an envelope detector 51. The envelope detector 51 is connected to an analog-digital converter 52, one output of which is connected to the processing circuit 100.

 The electromagnetic sensor 116 supplies the electrical signal S1 to the amplifier 50 which amplifies the electrical signal S1 in current and voltage so as to facilitate the following processing. The electrical signal S1 is a function of the electromagnetic radiation detected.

 The amplifier 50 supplies the amplified signal SA to the envelope detector 51 which determines the amplitude of the amplified signal.

 The signal S2 at the output of the envelope detector 51 is supplied to the converter 52. The converter 52 converts the analog signal S2 into the digital signal SN to transmit it to the processing circuit 100. A stored calibration or correspondence table TC in memory 103 respectively corresponds values of quantity of ink, for example expressed as a percentage of a maximum quantity, to the amplitudes of the digital signal SN supplied by the converter 52.

FIG. 5 is an experimental curve showing the results obtained with the invention. The quantity of ink ENC contained in the reservoir 112, expressed as a percentage of the maximum quantity, is on the abscissa and the voltage of the electrical signal SI, expressed in Volt, at the output of the electromagnetic sensor 116 is on the ordinate. The relationship between the variables ENC and
S1 is quasi-linear and a signal S1 of given voltage indicates with a good reliability a quantity of ink in all the range of quantity of ink.

With reference to FIG. 6, the second embodiment of the conversion circuit extracts the phase difference between the excitation signal SE and the signal emitted by the ink contained in the reservoir 112 in response to the excitation signal SE. The conversion circuit 115a comprises, from a first input, an amplifier 50a connected to a first input of a phase comparator 51a. A second input of the conversion circuit 115a is directly connected to a second input of the phase comparator 51a. The phase comparator 51a is for example produced by an OR circuit
EXCLUSIVE and is connected to a low-pass filter 52a in series with an analog-digital converter 53a, one output of which is an output of the conversion circuit Il Sa connected to the processing circuit 100.

The electromagnetic sensor 116 supplies the electrical signal S1 which is amplified by the amplifier 50a into the amplified signal SA. The signal SA is supplied to the phase comparator 51a. The phase comparator 51a receives on its second input the excitation signal SE and compares the phases of the signals
SA and SE. The result of the comparison is a signal SC supplied to the low-pass filter which filters it into a filtered signal SF. The signal SC is composed of 1 or 0 depending on the equality or the phase difference of the compared signals. The low-pass filter incorporates the SC signal. The signal SF is supplied to the analog-digital converter 53a which digitizes it into a digital signal SNa and delivers the digital signal SNa to the processing circuit 100. The processing circuit uses the signal SNa as the signal SN. A calibration or correspondence table TCa stored in memory 103 then contains values of ink quantities as a function of phase difference values.

 With reference to FIG. 7, an algorithm according to the invention is stored in the read-only memory 103 of the printing device. The algorithm comprises seven steps E70 to E76 which are run periodically for example before the printing of a document. The function of the algorithm is to determine the quantity of ink present in the ink tank 112.

 Step E70 consists in positioning the carriage 60 supporting the ink cartridge 111 at a determined position, facing the electromagnetic sensor 116. As already specified, the relative positions of the electrode 120 and the electromagnetic sensor 116 are such that the ink is between them.

 The algorithm then goes to step E71 during which the switch 118 is activated to authorize the passage of the high frequency signal generated by the oscillator 117 to the amplifier 119. The electrode 120 is supplied by the signal d excitement SE. This signal causes the ink contained in the spongy body 31 to emit electromagnetic radiation.

 This radiation is captured in step E72 by the antenna 116, which supplies the signal S1 to the conversion circuit 115 which in turn provides in step E73 the digital signal SN to the processing circuit 100. As a variant, the circuit 115a conversion provides the digital signal SNa to the processing circuit 100.

 Step E74 is the determination of the quantity of ink in the reservoir 112. Step E74 consists in searching in the correspondence table TC for the stored amplitude value or in the table TCa for the stored phase difference value, closest to the measured value SN or SNa, then extracting from the correspondence table TC or TCa the corresponding ink quantity value.

 Alternatively, the signals SN and SNa are both used to determine the amount of ink present in the ink tank 112 with greater precision.

 In step E75, a representation of the quantity of ink extracted is displayed on the display 104 for the user. The representation of the quantity of ink is displayed either in encrypted form or in the form of a diagram.

 As a variant, the value of the quantity of ink is transmitted to a remote device, such as a microcomputer, via the output port 107. The microcomputer then displays a representation of the quantity of ink for the user, in encrypted form or in diagram form.

 In step E76, the switch is deactivated so as to open the circuit between the oscillator 118 and the electrode 120. The latter is then no longer supplied by the excitation signal SE. The processing circuit 100 then proceeds to the conventional steps of operating the printer.

 In the case of a printer with several reservoirs, the electrodes of each reservoir are supplied successively or selectively by the excitation signal SE to determine the quantity of ink in each reservoir.

 Of course, the present invention is not limited to the embodiments described and shown, but encompasses, quite the contrary, any variant within the reach of ordinary skill in the art.

Claims (32)

Claims 1. Method for determining a quantity of product present in a tank, characterized in that it comprises the steps of:  - applying (E71) a predetermined excitation signal (SE) to the product present in the tank, so that the product radiates an electromagnetic signal,  - picking up (E72) the electromagnetic signal radiated by the product with a means for picking up producing an electrical signal representative of the electromagnetic signal, and  - process (E73, E74) the electrical signal to produce a signal representative of the quantity of product present in the tank. 2. Method according to claim 1, characterized in that the step of treating comprises the steps of:  - detect the amplitude of the electrical signal, and  - produce the signal representative of the quantity of product from a value given by a calibration table (TC) as a function of the amplitude detected. 3. Method according to claim 1, characterized in that the step of treating comprises the steps of:  - detect a phase difference between the electrical signal and the excitation signal, and  - produce the signal representative of the quantity of product from a value given by a calibration table (TCa) according to the detected phase difference. 4. Method according to any one of claims 1 to 3, characterized in that it further comprises the step (E75) of displaying a representation of the quantity of product present in the tank. 5. Method according to any one of claims 1 to 3, characterized in that it further comprises the step of transmitting the signal representative of the quantity of product present in the reservoir to a remote device so that it displays a representation of the quantity of product present in the tank. 6. Method according to any one of claims 1 to 5, characterized in that the product is ink. 7. Device for determining a quantity of product present in a tank (112), characterized in that it comprises:  a means (120) for exciting the product present in the tank by a predetermined excitation signal (SE), so that the product radiates an electromagnetic signal,  a means (116) for picking up the electromagnetic signal and producing an electrical signal representative of the electromagnetic signal, and  - a means (115) for processing the electrical signal and producing a signal representative of the quantity of product present in the tank. 8. Device according to claim 7, characterized in that the means for exciting is an electrode (120) disposed in contact with the product in the tank. 9. Device according to claim 7 or 8, characterized in that the means (116) for picking up the electromagnetic signal is a metal part forming an antenna, arranged outside the tank. 10. Device according to any one of claims 7 to 9, characterized in that the means (116) for picking up the electromagnetic signal is a metallic strip. 11. Device according to any one of claims 7 to 10, characterized in that it is intended to determine quantities of products present in several tanks, respectively, and in that it comprises:  - for each reservoir, a said means for exciting the product present therein by a predetermined excitation signal (SE), so that the product radiates an electromagnetic signal,  a common means for picking up the electromagnetic signal and producing an electrical signal representative of the electromagnetic signal, and  - a common means (115) for processing the electrical signal and producing a signal representative of the quantity of product present in the tank. 12. Device according to claim 7, characterized in that the means for exciting is a metal part forming an antenna, arranged outside the tank. 13. Device according to claim 7 or 12, characterized in that the means for exciting is a metal strip. 14. Device according to claim 13, characterized in that the means for picking up the electromagnetic signal is an electrode arranged in contact with the product in the reservoir. 15. Device according to any one of claims 12 to 14, characterized in that it is intended to determine quantities of products present in several tanks respectively and in that it comprises:  a common means for exciting the product in each of the reservoirs by a predetermined excitation signal (SE), so that the product radiates an electromagnetic signal,  - for each reservoir, a said means for picking up the electromagnetic signal and producing a signal. electrical representative of the electromagnetic signal, and  - a common means (115) for processing the electrical signal and producing a signal representative of the quantity of product present in the tank. 16. Device according to any one of claims 7 to 15, characterized in that the means for exciting (120) and the means for picking up (116) are positioned relative to each other so that the product is located between them. 17. Device according to any one of claims 7 to 16, characterized in that the means for exciting (120) is supplied by an oscillator (117) connected to the means for exciting via a switch (118). 18. Device according to any one of claims 7 to 17, characterized in that the excitation signal (SE) is an alternating high frequency signal. 19. Device according to any one of claims 7 to 18, characterized in that the excitation signal (SE) is an alternating signal of frequency greater than 10 MHz. 20. Device according to any one of claims 7 to 19, characterized in that the means (115) for processing comprises an envelope detector (51) and an analog-digital converter (52) for producing a digital signal (SN ) representative of the amplitude of the electrical signal. 21. Device according to any one of claims 7 to 19, characterized in that the means (115a) for processing comprises a phase comparator (51a) and an analog-digital converter (53a) for producing a digital signal (SNa) representative of the phase difference between the electrical signal and the excitation signal. 22. Device according to any one of claims 7 to 21, characterized in that it further comprises means (104) for displaying a representation of the quantity of product present in the tank. 23. Device according to any one of claims 7 to 22, characterized in that the product is ink. 24. Product tank, characterized in that it comprises a single electrode (120) disposed in contact with the product in the tank. 25. Use of the reservoir according to claim 24, to produce an electromagnetic signal radiated by the product, by supplying the electrode with a predetermined excitation signal (SE), in order to determine the quantity of product present in The reservoir. 26. Use of the reservoir according to claim 24, for picking up, by means of the electrode, an electromagnetic signal caused by a predetermined excitation signal (SE), in order to determine the quantity of product present in the reservoir. 27. Use of the reservoir according to any one of claims 24 to 26, in which the excitation signal has a frequency greater than 10 MHz. 28. Use of the reservoir according to any one of claims 24 to 27, with said product which is ink. 29. An image transfer device (10) comprising a device for determining an amount of product present in an ink tank (112), according to any one of claims 7 to 23. 30. Printer (11) comprising an image transfer device according to claim 29. 31. Fax machine (11) comprising an image transfer device according to claim 29. 32. A microcomputer (11) comprising an image transfer device according to claim 29.