FR3021404A1 - SYSTEM COMPRISING A DOSIMETER AND A DOSIMETER LOADING DEVICE FOR CONTROLLING THE OPERATING MODE OF THE DOSIMETER - Google Patents

Abstract

The invention essentially relates to a system (100) comprising a dosimeter (110) measuring a quantity of ultraviolet radiation, said dosimeter being adapted to operate in a first and a second alternative mode of operation, the system further comprising a device (150) for loading the dosimeter (110), said device (150) comprising: control means (152) for operating the dosimeter, and connection means (154) compatible with connection means (114). ) of the dosimeter (110) for charging the dosimeter (110) when said device (150) is powered, said dosimeter (110) comprising: • means for detecting or not detecting (112) the device control means (152) (150), and • means (116) for selecting the first or second operating mode based on the detection or non-detection of the control means (152) of the device (150).

Description

BACKGROUND OF THE INVENTION The present invention relates to the field of dosimeters measuring the amount of ultraviolet radiation. More specifically, the invention relates to the field of operating modes control of a dosimeter. The invention applies to portable dosimeters, in particular and without limitation to portable dosimeters in the form of a jewel, for example a brooch or a pendant. In known manner, a portable dosimeter comprises an ultraviolet radiation sensor and a cover element (or shell) placed between the sensor and the outside of the dosimeter. In addition, the dosimeter may operate in two modes of operation, for example in an "active" mode in which the electronic elements of the dosimeter are activated, and a "standby" mode, in which some of these electronic elements are extinguished, which makes it possible to reduce the electrical consumption of the dosimeter. In order to select one of the two modes, the user presses a button of the dosimeter positioned on the cover element, this button forming a protuberance on the cover element. However, this button has several disadvantages. Indeed, the protruding form of this button involves a risk of undesired selection of a mode, for example when the user takes control of the dosimeter. In addition, this protruding shape makes the dosimeter fragile and involves a risk of degradation of the dosimeter. In addition, the realization of this button is complex and the end result of this unattractive achievement. One of the objectives of the invention to remedy at least one of these drawbacks. Another object of the invention is to provide a system and a method for improved operation of the dosimeter.

OBJECT AND SUMMARY OF THE INVENTION To this end, the present invention relates to a system comprising a dosimeter measuring a quantity of ultraviolet radiation, said dosimeter being adapted to operate in a first mode of operation and a second mode of alternative operation, the system comprising in addition a device for loading the dosimeter, this device comprising: means for controlling the operating mode of the dosimeter, and connection means compatible with connection means of the dosimeter for charging the dosimeter when said device is powered, said dosimeter comprising: - means for detecting or not detecting the control means of the device, and - means for selecting the first or the second mode of operation as a function of the detection or non-detection of the device control means. The invention is advantageous in that the change in operating mode of the dosimeter being achieved via the dosimeter loading device, it is possible to make a dosimeter having a button-free structure forming a protuberance on the cover element. Thus, the risk of undesired selection of a mode when the user takes over the dosimeter no longer exists, and the dosimeter is more solid. In addition, the aesthetics of the dosimeter is improved. Indeed, the outer face of the cover element can take any shape. In a particular embodiment, the control means of the device comprise the connection means of the device, and the detection or non-detection means of the device control means are adapted to detect the loading of the dosimeter by the device. In a particular embodiment, the control means of the device comprise a magnet generating a magnetic field, and the detection or non-detection means of the device control means comprise means adapted to detect the magnetic field generated by the device. 'magnet.

Thus, the detection of the control means can then take place even if the loading device is not powered. In a particular embodiment, the detection or non-detection means of the device control means comprise a presence sensor positioned at a dosimeter cavity, and the device control means comprise a shape element. complementary to the cavity. In a particular embodiment: the dosimeter comprises a Bluetooth communication interface, the first mode of operation is a "communication" mode in which the Bluetooth communication interface is active and coupled with a terminal, and the second mode of operation is a mode of "sensory", according to which the Bluetooth communication interface is active and not coupled with a terminal. The invention furthermore relates to a method for controlling modes of operation of a dosimeter, said method being implemented by a system as described above, said method comprising steps of: detection or non-detection of the means of control of the device, and - selection of the first or second operating mode according to the detection or non-detection of the device control means. BRIEF DESCRIPTION OF THE DRAWINGS Other features and advantages of the present invention will emerge from the description given below, with reference to the accompanying drawings which illustrate an embodiment having no limiting character. In the figures: FIG. 1 represents, schematically, the hardware architecture of a system according to one embodiment of the invention; FIG. 2 schematically represents a system according to a first variant of a first embodiment of the invention; - Figure 3 shows schematically a system according to a first variant of a second embodiment of the invention; FIG. 4 schematically represents a system according to a first variant of a third embodiment of the invention; FIG. 5 represents, in the form of a flowchart, the main steps of a method of controlling modes of operation of a dosimeter according to an exemplary embodiment of the invention; FIG. 6 represents, in the form of a flowchart, the main steps of a method of controlling modes of operation of a dosimeter according to a particular embodiment of the invention. For the sake of clarity, the elements shown in these figures are not to scale unless otherwise stated.

DETAILED DESCRIPTION OF SEVERAL EMBODIMENTS FIG. 1 schematically represents the hardware architecture of a system 100 according to one embodiment of the invention.

The system 100 comprises a dosimeter 110 measuring a quantity of ultraviolet radiation, this dosemeter 110 being adapted to operate according to at least a first alternative mode of operation and a second mode of operation. The system 100 further comprises a device 150 for loading the dosimeter 110. This charging device 150 comprises control means 152 of the operating mode of the dosimeter 110, making it possible to switch from the first mode of operation to the second mode of operation, or from the second mode of operation in the first mode of operation.

In addition, the charging device 150 comprises connection means 154 compatible with connection means 114 of the dosimeter 110 for charging the dosimeter 110 when the charging device 150 is powered. The dosimeter 110 comprises means 112 for detecting or not detecting the control means 152 of the device 150. The dosimeter further comprises means 116 for selecting the first or the second mode of operation as a function of the detection or non-detection. detection of the control means 152 of the device 150. Typically, the dosimeter 110 comprises at least one ultraviolet radiation sensor 226, 228 R. In one example, the dosimeter 110 comprises a sensor 226 of type A ultraviolet radiation (UVA) and a sensor 228 of type B ultraviolet radiation R (UVB). The dosimeter 110 may comprise a cover element 230 placed between said at least one sensor 226, 228 and the outside of the dosimeter 110 in order to protect said at least one sensor 226, 228. The dosimeter 210 may communicate with a terminal, via a wireless link. The terminal may be for example a mobile phone. In addition, the wireless link can be for example a Bluetooth link. For this purpose, the dosimeter comprises a communication interface 220. In a first example, the charging device 150 is a charging cable 310 having a first socket 312 intended to be connected to a power source in order to supply the cable In this first example, the connection means 154 of the device 150 comprise a second socket 320 intended to be connected to the dosimeter 110. This charging cable 310 typically comprises at least one connecting wire of conductive material, covered of an insulating material 314. The second socket 320 has a first pin 322 and a second pin 322. These pins 322 are connected to the at least one connection wire inside the second socket 320. In addition, these pins 322 form protuberances at the second receptacle 320. Alternatively, the second receptacle 320 has a different number of pins 322. Moreover, when the device 150 e loading is a charging cable 310 according to the first example, the connection means 114 of the dosimeter 110 comprise a receptacle 330 adapted to receive the second receptacle 320 of the device 150. The receptacle 330 of the connection means 114 of the dosimeter 110 comprises two cavities of complementary shape to the pins 322, these cavities being positioned so that when the second socket 320 of the device 150 is connected to the socket 330 of the dosimeter 110, each pin 322 of the second socket 320 is positioned inside a In the variant where the second socket 320 has a different number of pins 322, the socket 330 of the connection means 114 of the dosimeter 110 has the same number of cavities of complementary shape to the pins 322.

Thus, when the first socket of the device 150 is connected to the power source, and therefore when the charging cable 310 is powered by this power source, and when the second socket 320 of the device 150 is connected to the socket 330 of the dosimeter 110, a current flows from the energy source to the dosimeter 110 in order to charge the dosimeter 110.

The energy source may be the sector, a terminal connected to the mains, a cigarette lighter, a source of solar energy, or a source of wind energy. In a second example, the charging device 150 is a magnetic induction charger.

This magnetic induction charger has a socket intended to be connected to a power source to power the charger. In addition, in this second example, the connection means 154 of the device 150 comprise a transmission medium that can generate a magnetic field from the energy transmitted by the energy source when the charger is powered. The dosimeter 110 may be positioned on this transmission medium and thus may be charged by the magnetic field. When the charging device 150 is a magnetic induction charger according to this second example, the connection means 114 of the dosimeter 110 comprise a receiver adapted to convert the magnetic field received into electrical current. The energy source may be the sector, a terminal connected to the mains, a cigarette lighter, a source of solar energy, or a source of wind energy.

In a first embodiment, the control means 152 of the device 150 comprise the connection means 154 of the device 150. The means 112 for detecting or not detecting the control means 152 are then adapted to detect the loading of the dosimeter 110 by the device 150. FIG. 2 shows a first variant of the first embodiment, in which the loading device 150 is a loading cable 310 according to the first example of the loading device 150 described above.

In this first variant of the first embodiment, the control means 152 of the device 150 comprise the second socket 320 intended to be connected to the dosimeter 110. In addition, the detection or non-detection means 112 comprise the receptacle 330 of the dosimeter 110 adapted to receive the second socket 320 of the device 150. These means 112 are thus adapted to detect the electric current flowing from the power source to the dosimeter 110 when the first plug is connected to a power source and when the second plug 320 is connected to the socket 330 of the dosimeter 110, and therefore adapted to detect the charging of the dosimeter 110 by the device 150.

In a second variant of the first embodiment, the charging device 150 is a magnetic induction charger according to the second example of charging device 150 described above. In this second variant, the control means 152 of the device 150 thus comprise the transmission medium. In addition, the detection or non-detection means 112 comprise the receiver adapted to transform the magnetic field received into electrical current. These means 112 are thus adapted to detect the magnetic field or the electric current generated from the magnetic field, and therefore adapted to detect the loading of the dosimeter 110 by the device 150.

In a second embodiment, the control means 152 of the device 150 comprise a magnet 410 generating a magnetic field. In addition, the detection or non-detection means 112 comprise means 430 adapted to detect the magnetic field generated by the magnet 410. The detection of the control means 152 can then take place even if the charging device 150 is not not powered. FIG. 3 shows a first variant of the second embodiment, in which the charging device 150 is a charging cable 310 according to the first example of charging device 150 described above. In this first variant of the second embodiment, the magnet 410 is typically positioned inside a cavity 420 of the second socket 320. This cavity 420 can be positioned between the two pins 322. In addition, the magnet 410 may comprise an outer surface 412, this outer surface 412 flush with the surface of the second socket 320. In addition, the means 430 adapted to detect the magnetic field generated by the magnet 410 are positioned inside the socket 330 of the dosimeter 110. These means 430 are typically positioned between the two cavities 332 of said receptacle 330. Thus, when the second receptacle 320 is connected to the receptacle 330 of the dosimeter 110, the means 430 can detect the magnetic field generated by the magnet 410 In a second variant of the second embodiment, the charging device 150 is a magnetic induction charger according to the second example of a charging device 150. written above.

In a third embodiment, the detection or non-detection means 112 comprise a presence sensor 530 positioned at a cavity 532 of the dosimeter 110. In addition, the control means 152 of the device 150 comprise an element 510 of FIG. complementary shape to the cavity 532. The element 510 is typically made of metallic material. The presence sensor 530 is for example a button positioned at the bottom of the cavity 532. Thus, when the element 510 is inserted into the cavity 532, said element 510 exerts a pressure on the button, which allows the means 112 to detect the control means 152. The detection of the control means 152 can then take place even if the charging device 150 is not powered. FIG. 4 shows a first variant of the third embodiment, in which the charging device 150 is a charging cable 310 according to the first example of charging device 150 described above. According to this first variant of the third embodiment, the cavity 532 comprising the presence sensor 530 can be positioned on the receptacle 330 of the dosimeter 110. In addition, the element 510 can be positioned on the second receptacle 320 of the device 150. an example, the cavity 532 comprising the presence sensor 530 is positioned between the two cavities 332 of said receptacle 330, and the element 510 is positioned between the two pins 322 of the second receptacle 320 of the device 150. Alternatively, the element 510 may be one of the pins 322 of the second socket and the cavity 532 may be the cavity 332 corresponding to this pin 322. When the second socket 320 of the device 150 is inserted into the socket 330 of the dosimeter 110, the element 510 enters said cavity 532 and exerts a pressure on the button, which allows the means 112 to detect the control means 152. In a second variant of the third mode of realization The charging device 150 is a magnetic induction charger according to the second example of a charging device 150 described above. FIG. 5 represents, according to an embodiment of the invention, a method of controlling operating modes of a dosimeter 110, this method being implemented by the system 100. This method comprises a step S10 of detection or not detection, by the means 112, of the control means 152 of the device 150. This method comprises a step S15 for selecting, by the means 116, the first or the second operating mode as a function of the detection or the non-detection of the means In a particular embodiment illustrated in FIG. 6, the method comprises a step SO in which the dosimeter 110 operates according to the first mode of operation.

The method further comprises a step S5 for detecting the positioning of the dosimeter 110 against the device 150. When the charging device 150 is a charging cable 310 as described above in the first example of the charging device 150, the positioning is detected in step S5 when the second receptacle 320 of the device 150 is connected to the receptacle 330 of the dosimeter 110. When the charging device 150 is a magnetic induction charger as described above in the second example of a charging device 150 the positioning is detected in step S5 when the dosimeter 110 is positioned on the transmission medium. The method comprises a detection step S10.1, by the means 112, of the control means 152 of the device 150. When the control means 152 of the device 150 comprise the connection means 154 of the device 150, as described above in the first embodiment of the system 100, the control means 152 is detected in the step S10.1 when the dosimeter 110 is loaded by the device 150. More specifically, when the device 150 is a charging cable 310 and the control means 152 of the device 150 comprise the second socket 320, as described above in the first variant of the first embodiment of the system 100, the detection or non-detection step S10.1 comprises detection or non-detection by the means 112, electrical current flowing from the power source to the dosimeter 110 when the first plug is connected to a power source and when the second plug 320 is connected to the receptacle 330 of the dosimeter 110. In addition, when the charging device 150 is a magnetic induction charger and the control means 152 of the device 150 comprises the transmission medium, as described above in the second variant of the first embodiment of the system 100, the control means 152 are detected in the step S10.1 when when the magnetic field or the electric current generated from the magnetic field is detected. In addition, when the control means 152 of the device 150 comprise a magnet 410, as described above in the second embodiment of the system 100, the control means 152 are detected in step S10.1 when the field magnetic generated by the magnet 410 is detected. In addition, when the detection or non-detection means 112 comprise a presence sensor 530 positioned at a cavity 532 of the dosimeter 110, as described above in the third embodiment of the system 100, the means for control 152 are detected in step S10.1 when the element 510 is detected. When the control means 152 are detected in the step S10.1, the means 116 select, in the selection step S15.1, the second mode of operation. The method then comprises a step S20 of operation according to the second mode of operation.

The method may further comprise a step S10.2 of non-detection, by the means 112, of the control means 152 of the device 150. When the control means 152 are no longer detected in the step S10.2, the means 116 select, in a selection step S15.2, the first mode of operation. Steps SO, S5, S10.1, S15.1, S10.2 and S15.2 can then be repeated. In a variant, when the control means 152 are no longer detected in the step S10.2, the means 116 select, in a selection step S15.2, a third mode of operation. The steps S0, S5, S10.1, S15.1, S10.2 and S15.2 can then be repeated by replacing the first mode of operation with a third mode of operation. In a first variant of the particular embodiment illustrated in FIG. 6, the first mode of operation of the dosimeter 110 is a hibernation mode. In this hibernation mode, only the means 112 for detecting or not detecting the control means 152 of the device 150 are not extinguished. In addition, the second mode of operation of the dosimeter is a so-called "sensory" mode, wherein the dosimeter 110 comprises a Bluetooth communication interface 220 active but not yet coupled to a terminal. In this first variant, the dosimeter may comprise a third mode of operation called "on", in which the Bluetooth communication interface of the dosimeter 110 is not activated. In a second variant of the embodiment of the operating mode control method of a dosimeter 110, the first mode of operation of the dosimeter 110 is a so-called "communication" mode, in which the dosimeter 110 comprises a communication interface 220 Bluetooth active and able to communicate with the terminal to which it has been coupled.

In addition, the second mode of operation of the dosimeter is a mode called "sensory", in which the Bluetooth communication interface of the dosimeter 110 is active, but not yet coupled with a terminal.

Claims (6)

REVENDICATIONS1. A system (100) having a dosimeter (110) measuring a quantity of ultraviolet radiation, said dosimeter being adapted to operate in a first and second alternative modes of operation, the system further comprising a charging device (150) of the dosimeter (110), this device (150) comprising: - control means (152) of the operating mode of the dosimeter, and - connection means (154) compatible with connection means (114) of the dosimeter ( 110) for charging the dosimeter (110) when said device (150) is powered, said dosimeter (110) comprising: - detection or non-detection means (112) of the control means (152) of the device (150) and means (116) for selecting the first or second operating mode based on the detection or non-detection of the control means (152) of the device (150). 20 2. System according to claim 1, wherein: the control means (152) of the device (150) comprise the connection means (154) of the device (150), and the detection or non-detection means (112). ) control means (152) of the device (150) are adapted to detect the loading of the dosimeter (110) by the device (150). 3. System according to claim 1 or 2, wherein: the control means (152) of the device (150) comprise a magnet (410) generating a magnetic field, and the detection or non-detection means (112). control means (152) of the device (150) comprise means (430) adapted to detect the magnetic field generated by the magnet (410). 4. System according to claim 1, wherein: the detection or non-detection means (112) of the control means (152) of the device (150) comprise a presence sensor (530) positioned at a cavity (532) of the dosimeter (110), and - the control means (152) of the device (150) comprise a member (510) of complementary shape of the cavity (532). 15 5. System according to one of claims 1 to 4, wherein: - the dosimeter (110) comprises a communication interface (220) BI uetooth, - the first mode of operation is a mode of "communication" in which l Bluetooth communication interface (220) is active and coupled with a terminal, and - the second mode of operation is a "sensing" mode, in which the Bluetooth communication interface (220) is active and not coupled with a terminal. 25 6. A method of controlling operating modes of a dosimeter (110), said method being implemented by a system according to one of claims 1 to 5, said method comprising steps of: - detection or non-detection (S10 ) control means (152) of the device (150), and - selection (S15) of the first or second operating mode as a function of the detection or non-detection of the control means (152) of the device (150) .