FR2988867A1 - METHOD FOR RECHARGING A MOBILE ROBOT, SUCH AS A MOTORIZED SUPPORT SUPPORTING A TOUCH TABLET, AND ASSOCIATED DEVICE - Google Patents

Abstract

Electric charging device of a mobile robot with a low degree of freedom, comprising a docking station, the robot comprising vision means on its front face, motorization means and control means, the docking station comprising a charging support provided to provide an electric charge of said robot, characterized in that the control means cooperate with the viewing means for controlling said motorization means so as to: (i) bring said mobile robot closer to said load support in a forward direction until reaching a first position of said robot on said load support and (ii) rotating said mobile robot on itself until reaching a second position of said robot to make it able to be electrically charged from said support charge.

Description

- 1 - "Method for reloading a mobile robot, such as a motorized support supporting a touch pad, and associated device" Technical Field The present invention relates to a method for charging a mobile robot, particularly of the type used as a motorized support of a touch pad . It also relates to a device for implementing this method, as well as a docking station and a mobile robot or associated motorized support.

Such a charging method and charger allows a user to supervise the return of a mobile robot or motorized support for tablet to a docking station. STATE OF THE PRIOR ART Charge stations for motorized supports having a body and a head such as robots arranged to receive a device comprising a camera, said device constituting the head of the robot. For example, the charging station proposed for the RovioTM robot is known. This robot acts as mobile IP camera because it is possible to control the machine not only locally but also remotely via the Internet. The robot is able to stream video and sound to see and hear everything that happens in a remote person using a simple Internet browser. The robot is also able to orient itself to find the charging station to recharge its batteries. A disadvantage of this charging station is that the return to the base is in reverse, which limits the control by the user who can therefore verify or control the proper approach of the charging station by the robot.

Another disadvantage of this device is the need for the charging station to surround the robot, which has the consequence that it is bulky if the latter is also. Other charging systems are known, such as the one proposed for the GostaïTM robot. Again, the return to the base is in reverse, - 2 - which limits the control by the user who can therefore verify or control the proper approach of the charging station by the robot. Another disadvantage of the charging device is that it is bulky. Indeed, the charging system is a sort of articulated fork of the order of 35 centimeters connecting to the rear of the robot. It is therefore a bulky system, which is not aesthetic and fragile because many shocks occur between the charging station and the motorized support before the support is positioned under load.

Thus, the charging devices according to the state of the art require the robot back to the base which is in reverse, which limits the control by the user who can not verify or control the right approach to the charging station by the robot. In addition, charging stations according to the state of the art are cumbersome.

Finally, these charging stations are fragile because many shocks occur between the stations and the motorized supports before they are positioned in a charging situation. Moreover, the charging stations for motorized supports according to the state of the art protect little or no access to the load pads which can be dangerous. The invention therefore aims to overcome all or part of the previous disadvantages of charging stations for motorized media such as robots.

An object of the invention is to provide a method and load device for motorized support having few degrees of freedom (the head can not rotate relative to a vertical axis independently of the body) and whose body is bulky enough to allow a permanent control by a user allowing the user to verify that the approach of the base is carried out correctly and to correct if necessary. Another object of the invention is to provide such a charging device which is less bulky, more aesthetic and less fragile than existing ones. Another object of the invention is to propose such a device that does not constrain a degree of freedom of the robot. Another object of the invention is to propose such a charging device whose access to the load pads is protected. DESCRIPTION OF THE INVENTION At least one of the abovementioned objectives is achieved with an electric charging device of a mobile robot with a small degree of freedom, comprising a docking station, said robot comprising means of vision on its front face. , motorization means and control means, said docking station comprising a load support provided to provide an electric charge of said robot, characterized in that the control means cooperate with the viewing means for controlling said motorization means so as to: (i) bring said moving robot toward said load carrier in the forward direction until reaching a first position of said robot on said load carrier and (ii) rotating said movable robot on itself up to reaching a second position of said robot to make it electrically chargeable from said load carrier.

This provides a charging system that tolerates the initial positioning inaccuracies of the robot relative to its load pads, centering the robot on these load pads guiding it during its final rotation, and allowing the user to control permanently return to the base while ensuring a parking mode with the tablet facing away from the wall. Preferably, the load support may include stopping means of the mobile robot in its first position at the end of its approach phase, and in its second position at the end of its rotation on itself , the viewing means can be directed substantially opposite the abutment means. Advantageously, the load support may be provided with two load pads and the mobile robot may comprise a main body provided on its base with two wheels driven by the motorization means, the main body may comprise a substantially shaped element. discoidal and of diameter substantially equal to the distance between the two load pads, the element cooperating with the load pads to allow rotation of the mobile robot on itself. In a particular version, the main body may further comprise two electrical connection elements arranged to come into contact with the two load pads when the mobile robot is in the second position on the load support. Thus, there is a device which is secured from an electrical point of view. Advantageously, the load pads may each comprise a pushbutton arranged to be mechanically controlled by pressure exerted by the connecting elements when the mobile robot is in the second position on the load support, and thus conditioning the electric charge of the robot. mobile to a correct positioning of the robot on the load base. In a particular version, the load support may further include infrared emitting means and the main body of the mobile robot may further comprise infrared receiving means cooperating with the infrared emitting means to allow an approach of the mobile robot on the load support . Advantageously, the mobile robot can constitute a motorized support for a mobile computing equipment, such as a tablet.

According to another aspect of the invention, there is provided a method of charging a mobile robot with a low degree of freedom from a docking station, said robot comprising a vision equipment disposed on its front face. , a drive device and a control device, said docking station comprising a load support provided to provide an electric charge of said robot, characterized in that it comprises: (i) a step for controlling said motorization means of causing said moving robot to approach said load carrier in the forward direction until reaching a first position of said robot on said load carrier, and (ii) a step of controlling said motor means to rotate said carrier. mobile robot on itself until reaching a second position of said robot to make it able to be electrically charged from said load carrier.

DETAILED DESCRIPTION Other advantages and particularities of the invention will appear on reading the detailed description of implementations and a non-limiting embodiment, and the following appended drawings: FIG. 1 illustrates an example embodiment of 2A and 2B are respectively top and bottom views of the charging device of FIG. 1, FIG. 3 illustrates a first position of the motorized support on the docking station at the 4A and 4B are respectively top and bottom views of the charging device according to the invention during a rotation of the motorized support about the Z axis, relative to the 5A and 5B illustrate a second position of the motorized support on the docking station at the end of the rotation of the motorized support 200 around the axis Z, with respect to the docking station 300, and FIGS. 6A to 6D illustrate different configurations of use of the charging pads of the docking station. It is shown in Figure 1 a device 100 according to the invention comprising a motorized support 200 and a docking station 300. The motorized support 200 comprises wheels for moving on a surface. It further comprises a head 202 and a main body 204. The head 202 can not pivot relative to the body 204 along a vertical axis represented by the Z axis. The head 202 includes a camera (not shown) for filming the body. before the robot. Only one wheel 206 is shown in FIG. 1. The robot also includes infrared-6 receivers placed on the lower part of the body. Two of these receivers 208 and 210 are shown in the figure. The docking station 300 comprises a support 302 for supporting the motorized support 202. The support 302 is of substantially rectangular shape and has a small thickness along the Z axis. The docking station 300 further comprises load pads. 304 and 306 placed on one end of the home support. The docking station 300 also comprises a stop 306 placed on one end of the reception support 302, opposite to the load pads 304 and 306.

As illustrated in FIG. 1, the charging device 100 according to the invention allows the motorized support 200 having few degrees of freedom (the head can not rotate relative to a vertical axis independently of the body) and whose body is quite large, permanent control by a user using the camera placed on the head 202 of the motorized support 202, allowing it to verify that the approach of the docking station 300 is performed properly and correct this approach if necessary. The infrared receivers included in the lower part of the motorized support 200 make it possible to receive an infrared signal, to process it, and to obtain a precise final approach of the motorized support 200 on the docking station 300 which furthermore comprises an infrared transmitter ( not shown). Thus the device 100 is tolerant with respect to the initial positioning inaccuracies of the motorized support 200 on the docking station 300 with respect to its load pads.

It is shown in Figures 2A and 2B an element 212 placed under the motorized support 200 and in the center thereof. This element 212 has a disc shape whose diameter is equal to the distance separating the two load pads. This element 212 limits the advance of the motorized support 200 on the docking station 300. In addition, the disk shape of the element 212 allows the robot, once it has arrived in a first position described in FIG. 3, to then be able to rotate around the Z axis, while remaining centered with respect to the charging pads of the docking station 300. With reference to FIG. 3, the motorized support 200 is in a first position on the docking station 300 at the end of the guide of the motorized support towards it. The elements of Figure 1 are shown, except the load pads that are not visible.

The abutment 308 is on the side of a wall (not shown) of a part. In this first position, the camera placed on the head 202 of the motorized support 200 thus faces the wall. Note that the docking station 300 does not surround the motorized support 200 and therefore imposes no stress on it along the Z axis.

This allows the motorized support 200 to be able to pivot about this axis, as illustrated also in FIGS. 4A and 4B, on which are represented the same elements as FIGS. 2A and 2B, with the exception of the support 302 of the docking station. 300.

With reference to FIGS. 5A and 5B, the motorized support rotates about the Z axis until it is in a second position on the docking station 300 at the end of the rotation of the motorized support 200 around the Z axis The elements of FIGS. 4A and 4B are respectively represented therein, with the exception of the wheel 206 of the motorized support 200.

Figures 5A and 5B illustrate that the camera of the head 202 of the motorized support 200 is now no longer facing the wall as in Figure 3, but to a room that a user can monitor by means of the camera. The load of the motorized support 200 is performed in this second position, said load position. With reference to FIGS. 6A, 6B, 6C and 6D, the charge pads 304, 306 will now be described in more detail. FIG. 6A shows a solid view of a charging pad 304, 306. The charging pad comprises a pressing button 602 which is shown in the up position in FIG. 6A and in the down position in FIG. 6B. It is the weight of the load support, once placed in the second position, which lowers the press button. FIG. 6C shows a view by transparency of the inside of a charging pad 304, 306. FIG. 6D represents a view by transparency of the inside of such a charging pad when the press button is in low position. 6C and 6D illustrate a spring 604 operating in compression and leaving the press button 602 in the up position in the rest position. In the low position, the press button 602 comes into electrical contact with an electric wire 606 itself connected to a power supply 608. The motorized support 200 also comprises two electrical connection elements (not shown). These electrical elements are positioned to come into contact with the two load pads 304, 308 when the mobile robot 200 is in the second position on the load support 300. The load pads 304, 408 are then mechanically controlled by the pressure exerted by the connecting elements when the mobile robot 200 is in the second position on the load support 300 and conditions the electric charge of the mobile robot 200 to a correct positioning of the robot on the load base 300. Thus, the support of Charge 300 protects a user against dangerous electric shocks. Of course, the invention is not limited to the examples which have just been described and numerous adjustments can be made to these examples without departing from the scope of the invention.

Claims (8)

REVENDICATIONS1. An electric charging device for a mobile robot with a small degree of freedom, comprising a docking station, said robot comprising vision means on its front face, motorization means and control means, said docking station comprising a load support provided to provide an electric charge of said robot, characterized in that the control means cooperate with the viewing means for controlling said motorization means so as to: (iii) bring said mobile robot to approach said load support in a forward direction until reaching a first position of said robot on said load support and (iv) rotating said mobile robot on itself until reaching a second position of said robot to make it capable of being electrically charged from said support charge. 2. Device according to claim 1, characterized in that the load carrier comprises stopping means of the mobile robot in its first position at the end of its approach phase, and in that in its second position at the end of its rotation on itself, the viewing means are directed substantially opposite said abutment means. 3. Device according to claim 2, wherein the load support is provided with two load pads and the mobile robot comprises a main body provided on its base with two wheels driven by the motorization means, characterized in that said main body comprises an element (208) of substantially discoidal shape and of diameter substantially equal to the distance separating said two load pads, said element cooperating with said load pads to allow rotation of the mobile robot on itself. 4. Device according to claim 3, wherein the main body further comprises two electrical connection elements arranged to come into contact with the two load pads when the mobile robot is in the second position on the load support. 5. Device according to claim 4, characterized in that the load pads each comprise a push-button arranged to be mechanically controlled by pressure exerted by the connecting elements when the mobile robot is in the second position on the load support. , and thus conditioning the electric charge of said mobile robot to a correct positioning of said robot on the load base. 6. Device according to any one of claims 3 to 5, characterized in that the load carrier further comprises infrared emitting means and the main body of the mobile robot further comprises infrared receiving means cooperating with said infrared emitter means for allow an approach of said mobile robot on said load support. 7. Device according to any one of the preceding claims, characterized in that the mobile robot is a motorized support for a mobile computing equipment, such as a tablet. 8. A method of electrically charging a mobile robot with a small degree of freedom, from a docking station, said robot comprising a vision equipment disposed on its front face, a drive device and a control device, said docking station comprising a charging support provided to provide an electric charge of said robot, characterized in that it comprises: - (i) a step for controlling said motorization means so as to bring said mobile robot closer to said support medium; charging forward to reach a first position of said robot on said load support and (ii) a step for controlling said motorization means to rotate said mobile robot on itself until reaching a second position of said robot for make it capable of being electrically charged from said load carrier.