FR2938383A1 - Magnetic connector for connecting e.g. multimedia appliance and removable man machine interface, has connector part connected electrically and mechanically to another connector part by magnetic attraction of magnets or magnetic materials - Google Patents

Abstract

The connector has a connector part (110) mechanically integrated into an electronic device (150) and provided with a set of magnets (100, 115, 120). The magnets are electrically connected to the electronic device. Another connector part (105) is mechanically integrated into another electronic device (170) and provided with another set of magnets (130, 135, 140). The latter connector part is connected electrically and mechanically to the former connector part by magnetic attraction of the magnets or magnetic materials when the two sets of the magnets are placed in contact with each other.

Description

The present invention relates to a magnetic connector for electronic devices, for example for connecting an electronic device and an associated removable human-machine interface. Most connectors for current removable electronic devices offer mechanical male-female mechanical connection. A first disadvantage of this type of connector is the wear of the mechanical parts due to the friction of the electrical contacts between them during their insertion and their removal. A second disadvantage is the addition of a removable mechanical system to maintain devices which increases the costs of the devices. Other connectors utilize spring-loaded electrical contacts 20 to minimize the insertion and disinsertion of the devices between them. The major disadvantage of this type of connector is the wear of the springs which in aging no longer plays their role and the electrical contacts are no longer between the devices. In addition, it is necessary to add a removable mechanical system to maintain devices. An object of the present invention is to be able to easily connect and disconnect, without the use of a mechanical fastening system and without the risk of injury, electronic devices removable between them so as to replace or remove them momentarily (for example a multimedia device with detachable facade) or transport them separately (eg car radio with detachable facade). The present invention thus makes it possible to reduce the number of mechanical fastening and connection elements in an electronic device, thereby reducing the assembly time and reducing the cost of the device. The present invention aims a connector for electronic devices, characterized in that it comprises: - a first part of the connector, mechanically integrated with a first electronic device, and comprising at least one magnet electrically connected to said first electronic device, - a second part the connector, mechanically integrated with a second electronic device, and comprising at least one magnet or at least one magnetic material electrically connected to said second electronic device, said second part of said connector being adapted to be electrically and mechanically connected to the first part of the connector by means of the magnetic attraction of their magnets or their magnet and their magnetic material, when the two magnets or the magnet and the magnetic material are in contact. By virtue of these arrangements, said magnets or said magnets and magnetic materials, when assembled, maintain physical contact with each other, thanks to the magnetic attraction, thus making it possible both to establish a mechanical hold between the two. electronic devices and to freely move electrical signals from one electronic device to another. According to particular features, said magnetic contacts (magnets or magnet and magnetic material) can be used to transport a power supply between the two parts of the connector. Thanks to these arrangements, a first device can supply a second device with energy. According to particular features, a magnetic contact of each part of the connector can be used to carry information between the two parts of the connector. Thanks to these provisions, the devices can communicate with each other. According to particular features, two magnetic contacts of each part of the connector can serve both to carry energy and information between the two parts of the connector. Thanks to these arrangements, only two magnetic contacts per connector part are necessary to transport the energy and the information which makes it possible to facilitate the connection between said magnetic elements. According to particular characteristics, a first part of the connector has magnets having different poles. According to particular features, a second portion of the connector has magnets having poles inverted with respect to said magnets of said first portion of the connector. Thanks to these arrangements, the magnets of the two parts of the connector attract each other and come into mechanical contact but have only one direction of connection. According to particular features, a first part of the connector has a permanent magnet. According to particular features, a second portion of the connector has a magnetic field detector.

With these provisions, the first electronic device may or may not allow the transport of energy and / or information between the two parts of the connector when the magnetic field detector detects or not the magnetic field of said permanent magnet. This allows, for example, not to damage the electronic devices during a polarity reversal or when projecting a metal element on the magnetic elements. According to particular characteristics, electromagnets are arranged on either side of the connector. According to particular characteristics, said electromagnets are activated during the presence of a power supply.

Thanks to these provisions, the user can not remove the connector without cutting the power supply, the electronic device is thus protected. According to particular features, a first electronic device can be an electronic device. According to particular features, a second electronic device may be a man-machine interface. With these provisions, the user can easily connect interfaces and replace or replace them with other human-machine interfaces having the same type of magnetic connector. According to particular features, a first device has a plurality of magnetic connectors. Thanks to these provisions, the user can place several devices having magnetic connectors on said first device. Other advantages, aims and particular features of the present invention will emerge from the description which follows, made for an explanatory and in no way limiting purpose with reference to the appended drawings in which: FIG. 1 represents, schematically, a first embodiment In a particular embodiment of the connector object of the present invention in disassembled position, each of the parts having its front view, - Figure 2 shows, schematically, in profile and in section, in a first view, the two parts of the assembled connector and represented in a first particular embodiment of the connector object of the present invention, - Figure 3 shows schematically in profile and in section, a second particular embodiment of the connector, unassembled, object of the present invention, - the FIG. 4 schematically represents, in profile and in section, a third particular embodiment of the connector. , unassembled, object of the present invention and - Figure 5 shows schematically in profile and in section, a fourth particular embodiment of the connector, unassembled object of the present invention. The present invention relates to a magnetic connector for electronic devices. In these embodiments illustrated in Figures 1 to 6, it takes the form of an oval, however, the present invention is not limited to a particular form of connector but instead extends to various geometric shapes such as rectangular , square, round or polygonal. Figure 1 schematically shows two electronic devices 150 and 170, partially shown and unassembled, each incorporating a portion 110 and 105 of the magnetic connector object of the present invention, each of the connector parts being viewed from the front. A first part 110 of said connector is observed, three magnets 100, 115 and 120 arranged in the form of a triangle, each of said magnets positioned at one of the vertices of said triangle, and having different magnetic poles. This position in triangle allows on the one hand to create a natural polarizer and on the other hand to enhance the mechanical attraction of the magnetic elements between them during disassembly. Also shown in this figure, a second portion 105 of said connector incorporating three other magnets 130, 135 and 140 having magnetic poles opposite those of the magnets of the first part of the connector so that they can be magnetically attracted to each other during assembling said devices through said connector portions. In variants, the magnets of one of the parts of the connector are replaced by magnetic materials. In variants, when the clutter on the faces of the connectors does not allow to place them in a triangle, the magnets are positioned in a straight line.

In variants, the magnets are positioned to create geometric shapes. This variant makes it possible to optimize the magnetic attraction of the connector as a function of the shape of the device and the number of magnetic contacts. In variants, the number of magnets can be changed. This variant makes it possible to optimize the number of magnets on the connector for cost or space reasons or to increase the number of magnets in order to transfer more electrical signals.

Figure 2 shows schematically the two electronic devices 150 and 170 partially illustrated in Figure 1 incorporating the two parts 110 and 105 of the connector, assembled, each of the parts seen in profile and in section. The three magnets 100, 115 and 120 of said first portion of said connector and the three magnets 130, 135 and 140 of said second portion of said connector shown in the first figure are distinguished in profile and in section. It is clearly seen that when the two parts of the connector are assembled, the magnets 100, 115 and 120 of the first part 110 of the connector are found in mechanical contact with the magnets 130, 135 and 140 of the second part 105 of the connector. It is also observed that said magnets of each part are electrically connected, via the electrical wires 250, 215 and 295 for the first part of said connector and via the electrical wires 260, 290 and 270 for the second part of said connector. , to their respective electronic equipment 230, 240, 235 and 255. All the elements allows in particular to pass the electrical signals from one electronic device to another.

On said first part 110 of the connector, the magnets 100 and 115 are connected to a power supply device 230, respectively to the positive potential and to the ground of said power supply device via two electrical wires 250 and 215. The magnet 120 is connected to it, by means of an electric wire 295, to a management and data storage element 240 of microcontroller type, powered by the power supply device 230. On a second part 105 of the connector, the magnets 130 and 135 are used to transmit to the power supply device 235 the power required for the operation of said second electronic device 170, via the electrical wires 260 and 290, respectively representing the positive potential and the mass. Said power supply from said power supply device of said first part of the connector when said magnet 130 and 135 are in mechanical contact with the magnets 100 and 115. The magnet 140 is connected to it by means of a wire electrical 270 to a microcontroller-type data management and management member 255, thus allowing the transfer of information, in the form of digital electrical signals, between the two management and storage members of the connector via the interface magnet 120 and electrical wire 295 when the magnet 120 is in contact with the magnet 140. The transfer of single-wire information can be done, for example, via the PBUS protocol (proprietary protocols allowing the transmission of signals with a single electric wire). In variants, only two magnets can be used on each part of the connector to carry both power and information from one electronic device to another.

Alternatively, one can use several contacts, a portion for the power supply and the rest for the transfer of information. This variant makes it possible to transfer information in both directions via type I2C, SSI (proprietary protocols), RS232 or parallel protocols.

FIG. 3 represents schematically two unassembled electronic devices comprising the same elements as the electronic devices illustrated in FIG. 2, except for a magnet 420 positioned on the second part 105 of the connector but not electrically connected to the second electronic device. 170 and having the same magnetic pole as the opposite magnet 100 located on the first portion 110 of the connector, and a sensor 450 positioned on the first portion 110 of the connector. Said sensor 450 being adapted to detect the presence of magnetic fields. Said sensor 450 is positioned in front of the magnet 420 when the two parts 110 and 105 of the connector are in contact, the magnet 420 and the sensor 450 are then in contact, thus allowing the magnetic field of said magnet 420 to be detected. by the sensor 450. Therefore, the first electronic device 150 can then allow the transfer of electrical signals to the second device, these signals can be, for example, the power supply. In the case where the two parts of the connector were connected in the wrong direction, the sensor 450 would not detect the magnet 420, having the consequence of prohibiting the transfer of electrical signals between the electronic devices 150 and 170. The sensor 450 can be of the ILS or Hall Effect type (registered trademarks). This particular embodiment of the connector object of the present invention makes it possible to avoid any short circuits caused by metal elements placed on the magnets when the two parts of said connector are disassembled. FIG. 4 schematically represents two electronic devices, not assembled, comprising the same elements as the electronic devices illustrated in FIG. 2, except for the two magnetic materials 600 and 620 situated on either side of the electrical contacts of the first part. the connector as well as two electromagnets 630 and 660 located opposite said magnetic materials when the two parts are assembled. Said electromagnets 630 and 660 are powered by the device 235 via the electrical wires 620, 640, 670 and 685. The function of the electromagnets is to keep the devices strongly in contact so that the user can not disassemble the connector voluntarily or involuntarily when the devices are powered. In variants, one can use a manual switch to cut the effect of the electromagnet. Alternatively, the positions of the electromagnets and the magnetic materials can be reversed.

Alternatively, electromagnets may be used instead of magnetic elements 600 and 620 to enhance the magnetic attraction. FIG. 5 schematically represents two electronic devices 745 and 770 connected to a single electronic device 750 via two magnetic connectors 705 and 715 in assembled positions, the assembly being seen in profile and in section. It is observed that the two parts 710 and 725 of the connectors of the first electronic device 750 are identical so that the electronic device 745 can be connected in place of the electronic device 770 and vice versa. Both connectors are electrically connected to their respective electronic equipment.

Alternatively, the electronic device 750 has a plurality of identical magnetic connectors. 20 25 30 35 1. 5 10 15 2. 3. 4. 5. 6. 7. 8. 9.35

Claims (1)

REVENDICATIONS1. A connector for electrically and mechanically connecting two electronic devices, comprising: - a first part of the connector, mechanically integrated with a first electronic device, and comprising at least one magnet electrically connected to said first electronic device, - a second part of the connector, mechanically integrated to a second electronic device, and comprising at least one magnet or at least one magnetic material electrically connected to said second electronic device, said second part of said connector being adapted to be electrically and mechanically connected to the first part of the connector by virtue of the magnetic attraction their magnets or their magnet and their magnetic material, when the two magnets or the magnet and the magnetic material are in contact. Connector according to claim 1, characterized in that the magnets and the magnetic materials are adapted to transmit electrical signals. Connector according to claim 2, characterized in that said electrical signals can be information and / or a power supply. Connector according to one of claims 1 to 3, characterized in that at least one of the magnets of a first part of the connector does not have the same magnetic pole as the other magnets of said first part. Connector according to claim 4, characterized in that at least one of the magnets face magnetic key. Connector according to one of claims 1 to 5, characterized in that a first portion of the connector connected to the first device has a magnet not electrically connected to said first device. The connector of claim 6, characterized in that a second portion of the connector has a magnetic field sensing system positioned opposite the magnet of the first device when the connector is assembled. Connector according to one of claims 6 and 7, characterized in that the detection system is adapted to detect the presence of the magnet when the connector is assembled. Connector according to claims 6 to 8, characterized in that the electronic device connected to the magnetic field detection system allows the passage of electrical signals between the two parts of the connector if said field detection system detects the presence of the magnet. 10. Connector according to one of the preceding claims, characterized in that electromagnets are placed on either side of the connector. Connector according to claim 10, characterized in that magnetic materials are placed in front of said electromagnets when the two parts of the connector are assembled. Connector according to one of claims 10 to 11, characterized in that the electromagnets can strongly maintain the connection between the two parts of the connector in the presence of a power supply. Connector according to one of the preceding claims, characterized in that a first device is an electronic device. Connector according to one of claims 1 to 13, characterized in that a second device is a man-machine interface. Connector according to one of the preceding claims, characterized in that the electronic devices have a plurality of connectors. 30