• 专利附录
  • 专利说明
  • 权利要求
  • 类似技术
  • 同族专利
  • 引用文献
  • 法律状态
  • 优先权
    • 专利摘要:
    Telehandled robotic vehicle, being of the type that have rolling means and an articulated arm topped with a clip and that is tele-commanded to carry out different risk operations, by means of a control suitcase, so that the vehicle comprises: two sets of wheels, one on each side, each driven by corresponding engines; two caterpillar games, one on each side inside the wheel sets; a first articulated arm mounted on a turret 360º; a second articulated and rotating arm with respect to a vertical mounting axis and a double articulation means for assembling the turret for its displacement with respect to the longitudinal axis of the vehicle, so that with the two sets of wheels and the two sets of tracks it is it moves through all kinds of terrains and with the combined movements of the two articulated arms it holds and manipulates the objects under examination. (Machine-translation by Google Translate, not legally binding)
    公开号:ES2540598A1
    申请号:ES201331685
    申请日:2013-11-19
    公开日:2015-07-10
    发明作者:César SALLEN ROSELLÓ
    申请人:Proytecsa Security SL;
    IPC主号:
    专利说明:

    DESCRIPTION
    Remote controlled robotic vehicle.
    OBJECT OF THE INVENTION
    The following invention, as expressed in the statement of the present specification, refers to a remote-controlled robotic vehicle, which is of the type of robotic vehicles whose essential object is the detection, recognition and deactivation of explosive devices or involving situations of danger to society.
    In this way, the remote-controlled robotic vehicle object of the invention combines a displacement system based on two side wheel trains and two tracks in order to facilitate its movement through smooth terrain and by any other type of irregular or slippery terrain.
    Likewise, when the remote-controlled robotic vehicle object of the invention is provided with a pair of articulated arms, it is allowed that with one of the arms it can hold an object and with the other arm it can examine it.
    SCOPE.
    This report describes a remote-controlled robotic vehicle, which has an average size capable of handling objects weighing up to 200 kilos, and is of special application for police, military or even civil intervention missions in missions that involve a certain risk. .
    Thus, the remote-controlled robotic vehicle is applicable when actions aimed at attacks on society structures such as the placement or alleged placement of explosive devices, “dirty” bombs, attacks with chemical gases, biological material or dispersion of radioactive elements are presented. .
    Likewise, the remote-controlled robotic vehicle can perform autonomous surveillance missions in perimeters, borders, industries or places where autonomous surveillance can be useful.
    BACKGROUND OF THE INVENTION
    Conventionally, when you have to manipulate explosive devices or perform risky operations, even more so, when human lives are at risk, robots that are remotely operated by means of a control console are used.
    In this way, among the existing robots for the manipulation of explosive devices, we can mention the one that comprises an articulated arm, according to a single section, and without the possibility of turning according to a horizontal plane, that is, only, it has movement according to a vertical plane and limited by its only articulated section.
    Also, these types of robots have a series of control elements, such as vision camera and proximity sensors.
    Likewise, we can consider the patent documents ES 2 241 490 and ES 1 073 757, so that in document ES 2 241 490 a “self-propelled robot for handling explosive charges” is described, which comprises means of displacement defined by two track trains of track of track adjustable in width and incorporating an articulated arm, according to four sections, finished in a clamp, with the first section in the form of fork driven by a pair of cylinders and in its folded the body of clamp is through the couple of branches of the first section.
    On the other hand, in document ES 1 073 757 a “Remote control robot for special operations” is described, being of the type of robots used to carry out risky operations and having a tread, a telescopic arm finished off in a caliper and remote control and function means, so that the robot incorporates a turret, 360º swivel, equipped with at least one thermal chamber and whose turret is integral with an arm consisting of a series of segments in number of six, rotatably joined together and actuated by hydraulic cylinders, the arm having at least one chamber and at least one deterrent weapon.
    Starting from this type of constitution, each articulation of the arms is directly controlled by the operator, which implies that in order to bring the clamp closer to an object with a desired position and angle, the operator must act independently and successively on each articulated movement until finally achieve the desired position, which requires skill and time in the operation.
    In addition, the control of hydraulic clamp forces is practically impossible and, even more so, when it comes to delicate objects, which is inconvenient.
    On the other hand, we can also consider US 6113343 A patent documents; JP 2000326875 and DE 2409027 A1, so that in US 6113343 a robot for explosives deactivation is presented, which has a base structure for a manipulator arm constituted by a first 226 arm (constituted by a pair of transmission members 230 ) and a second arm 228 (also constituted by a pair of transmission members, that is, they really are pairs of arms) each with independent drive relative to the corresponding axis of rotation.
    JP 200032875 describes a link belt device for moving a work vehicle, whose vehicle can vary in width, for which each of the undercarriages incorporates a pair of elements, so that said solidarity pairs both undercarriages fit into respective tubular elements integral with the vehicle structure itself.
    Finally, in DE 2409027 a leveling blade is described, so that the leveling blade is adjustable in width in order to be able to travel by road, being adjustable by means of respective sliding ends.
    DESCRIPTION OF THE INVENTION
    This report describes a remote-controlled robotic vehicle, being of the type of robotic vehicles equipped with rolling means and an articulated arm topped by a caliper and which is remote-controlled to carry out different risk operations, by means of a control case with at least one screen and the control means of the robotic vehicle, so that:
    image 1 The robotic vehicle comprises:
    • two sets of wheels, one on each side, with three driving wheels each, each wheelset driven by corresponding motors;
    • two sets of caterpillar, one on each side on the inside of the wheelsets, to
    slightly higher than the wheelsets;
    • a first articulated hydraulic action arm mounted on a 360º rotating turret;
    • a second articulated arm of electric and rotary actuation with respect to a vertical axis of assembly, and;
    • double articulation means for mounting the first articulated arm with respect to the turret, the first articulated arm moving along its longitudinal axis.
    and whose robotic vehicle is remotely controlled by:
    image 1 a control equipment integrated in a suitcase comprising:
    • an image display screen sent by cameras mounted on the robotic vehicle;
    • a touch screen in horizontal position of interface with the operator, and;
    • an HMI interface device defined by a “game pad” game control.
    so that with the two sets of wheels and the two sets of caterpillar it travels through all types of terrain and with the combined movements of the two articulated arm holds and manipulates the objects under examination according to the orders given by the operator from the transportable control equipment.
    On the other hand, each set of driving side wheels is driven by an electric motor, having differential mode traction and providing steering and turns.
    The first articulated arm, in a practical execution, is defined by three sections and a first clamp, the third section being provided with a lateral rotation of ± 90 ° and the first clamp is endowed with an endless rotation.
    The weight manipulation capacity of the first articulated arm varies depending on the articulation positions thereof, so that the more it extends, the smaller its capacity.
    The second articulated arm is defined by three sections and a second clamp, the third section being provided with a 360 ° rotation with respect to the longitudinal axis and with an elevation / descent turn with respect to a transverse axis, while the second clamp is equipped of an endless twist.
    The first clamp of the first articulated arm, hydraulically operated, is equipped with a pressure sensor, associated with the supply of flow and pressure, being able to regulate and know the exact force exerted on the object to be manipulated
    Likewise, the force or pressure exerted by the second clamp of the second articulated arm is controlled by the electric current control of the motor that activates it.
    The control means of the robotic vehicle have a spatial calculation system and when the robotic vehicle control operator is selected the position of the corresponding clamp in front of the object to manipulate the articulated arm will make the precise and simultaneous movements of its different sections to position itself optimally for the manipulation of the object, carrying out said movements in a fast and precise way.
    The first clamp of the first articulated arm is provided with short-distance mechanical joints at its ends that associated with springs or internal springs thereof will be those that withstand the pressure exerted on the object to be manipulated.
    Likewise, electronic distance sensors are associated with the inner springs or springs of the first clamp of the first articulated arm.
    Thus, from a certain compression of the mechanical joints of the first clamp of the first articulated arm, a high-strength mechanical stop is produced, from which, the first clamp continues to compress outside the force detection range of the electronic sensors , and the hydraulic pressure sensor being the one that detects and provides the force exerted.
    The robotic vehicle incorporates inertial sensors, based on accelerometers associated to the driving axle of the wheelset, having its global positioning and being able to move autonomously according to the routes marked by the operator in the control equipment, and also incorporates obstacle sensors, allowing your route to overcome obstacles and return to the marked route.
    Likewise, the control team incorporates means for its internet connection for its control from anywhere and for its connection to mobile devices, from which it can be controlled.
    To complement the description that is going to be carried out below, and in order to help a better understanding of the characteristics of the invention, this descriptive report is accompanied by a set of drawings, whose figures are illustrative and not limiting , the most characteristic details of the invention are represented.
    BRIEF DESCRIPTION OF THE DESIGNS.
    Figure 1. Shows a side elevation view of the robotic vehicle with the first and second articulated arm folded in transport or rest position, being able to observe how the second and third section of the second articulated arm remain on the first section thereof, as well as the control equipment based on a suitcase that integrates the control elements.
    Figure 2. It shows a front view of the robotic vehicle of the previous figure, being able to observe the vertical axis of assembly of the second articulated arm.
    Figure 3. It shows a perspective view from the rear of the robotic vehicle, being able to observe a set of wheels and a track set on its internal part and the first and second folded articulated arms.
    Figure 4. It shows a side elevation view of the robotic vehicle with the first and second articulated arms in an extension position, being able to observe the 360º rotating turret with the double articulation of the first articulated arm for its displacement according to its longitudinal axis .
    Figure 5. It shows a front view of the robotic vehicle of the previous figure, being able to observe how the third section of the first articulated arm has been turned to the side.
    Figure 6. It shows a plan view of Figure 4, being able to observe the rotation of the third section of the first articulated arm towards one side.
    Figure 7. It shows a perspective view from the rear of the robotic vehicle of Figure 4, being able to observe the rotation of the third section of the first articulated arm towards one side, as well as the double articulation of the first articulated arm in the turret.
    Figure 8. Shows a side elevation view of the robotic vehicle of Figure 1, the first articulated arm being represented according to different extended positions and the second folded articulated arm.
    Figure 9. Shows a side view of the robotic vehicle of Figure 1, the first and second arm being articulated in the position of maximum frontal extension.
    Figures 10, 11 and 12 show a perspective view, in side elevation and a longitudinal section of the first clamp of the first articulated arm in its closed position.
    Figures 13, 14 and 15 show a perspective view, in side elevation and a longitudinal section of the first clamp of the first articulated arm in its open position.
    Figure. 16. Shows a plan view of the transmission of the movement to the two sets of wheels by corresponding engines.
    Figure 17. Shows a view of the axis of rotation of the turret that mounts the first articulated arm through a double joint.
    Figure 18. It shows a perspective view of the double joint that is fixed to the turret and in which the first articulated arm is mounted, so that only one of the joints is visible when the other is hidden.
    DESCRIPTION OF A PREFERRED EMBODIMENT.
    In view of the aforementioned figures and according to the numbering adopted we can see how the robotic vehicle 1 is equipped with two sets of wheels 2, one on each side, three wheels each, each wheelset being operated 2 by the corresponding engine and two track sets 3, one on each side inside the wheel sets 2, the track sets 3 being at a level slightly higher than the wheel sets 2, as shown in the figures 1 and 2 of the designs, so that both sets have a solidarity displacement and the main contact to the ground corresponds to the wheel set 2, with the two track sets 3 being in a slightly elevated position.
    Through this execution, a quiet and smooth movement is achieved by means of the wheel sets 2 on smooth or prepared terraces such as concrete or asphalt, while the track sets 3 will contact and transmit traction to the firm when the ground is irregular, from land. unprepared, slippery, sand or soft ground, and thus having the ability to overcome steps and drive continuously.
    The direction of the robotic vehicle is achieved through the use of electric motors 19 that act independently on the wheelsets 2, so that it allows traction in differential mode, providing direction or even turning on itself or its vertical axis central, as seen in figure 16 of the designs.
    All motion controls are performed using closed loop systems, as digital servosystems.
    Likewise, the robotic vehicle 1 incorporates a first articulated arm 4 of hydraulic action mounted on a turntable 6 rotating 360 ° through double articulation means 7, allowing its displacement with respect to the longitudinal axis of said first articulated arm 4 and a second articulated arm 5 of electric and rotary drive with respect to a vertical axis 8 of assembly.
    Thus, in figure 17 of the designs the axis of rotation 18 of the turret 6 is appreciated to allow its rotation according to 360 °, and in figure 18 of the designs the double joint 7 is appreciated through which the first articulated arm 4 in turret 6.
    To the robotic vehicle 1 is associated a control equipment integrated in a suitcase 9 comprising a display screen 12 of images sent by cameras mounted on the robotic vehicle 1, a touch screen 13 in horizontal position of interface with the operator and a device HMI interface defined by a gamepad control.
    In this way, it is that with the two sets of wheels 2 and the two sets of tracks 3 it travels through all types of terrain and with the combined movements of the first articulated arm 4 and the second articulated arm 5 hold and manipulate, with the first and second clamp, the objects under examination according to the orders given by the operator from the transportable control equipment, that is, from the suitcase 9 that integrates the components as a PC.
    The first articulated arm 4 is defined by three sections 4a, 4b and 4c, the third section 4c being provided with a lateral rotation of ± 90 ° and the first clamp 10 is provided with an endless rotation, so that the weight handling capacity This first articulated arm 4 varies depending on the articulation positions and the farther away the first clamp 10 from holding the objects to be handled, the less capacity it will have.
    Thus, the first articulated arm 4 will have the following movements:
    • rotation of turret 6 on its vertical central axis;
    • forward and backward movement of turret 6 using double articulated parallelogram 7 or double trapezoid;
    • first section elevation 4a;
    • lifting and folding the second section 4b;
    • lifting and folding third section 4c;
    • lateral rotation of + -90 degrees of the third section 4c;
    • rotation of the first continuous endless manipulator clamp 10, and:
    • opening and closing the first clamp 10.
    On the other hand, the second articulated arm 5 is defined by three sections 5a. 5b and 5c, the third section 5c being provided with a 360 ° rotation with respect to the longitudinal axis and the second clamp 11 is provided with an endless rotation.
    The second articulated arm 5 will have the following movements:
    • rotation on its vertical axis 8 at its base;
    • first section elevation 5a;
    • lifting and folding on itself of the second section 5b;
    • total rotation of 360º on its longitudinal axis of the third section 5c;
    • elevation and or rotation on the transverse axis of the third section 5c;
    • continuous rotation of the second clamp 11, and;
    • opening and closing of the second clamp 11.
    Figure 9 of the designs clearly shows the different sections that make up the first and second articulated arm, as well as the double joint 7 through which the first articulated arm 4 joins the turret 6.
    The first clamp 10 of the first articulated arm 4, hydraulically operated, is provided with a pressure sensor, associated with the supply of flow and pressure, being able to regulate and know the exact force exerted on the object to be manipulated, providing excellent control of the force exercised on the manipulated object.
    On the other hand, the force or pressure exerted by the second clamp 11 of the second articulated arm 5 is controlled by the electric current control of the motor that activates it.
    The control means of the robotic vehicle 1 have a spatial calculation system and when selecting the control operator of the robotic vehicle 1 the position of the corresponding clamp in front of the object to be manipulated the articulated arm will effect precise and simultaneous movements of its different sections to position optimally for the manipulation of the object.
    In addition, the first clamp 10 of the first articulated arm 4 incorporates a means of controlling the force exerted therein that allows to control forces of a few grams up to a kilogram, especially for handling very delicate objects.
    Until now, the control of forces of the order described by hydraulic elements was practically impossible.
    Thus, the first clip 10 has mechanical joints 14 of short travel at the ends 15 of the forming sheets thereof, so that the joint allows internal springs or springs 16 to be placed in the structure of the first clip 10 so that The first pressure made will be transmitted to the inner spring springs 15, maintaining these, by definition, the pressure on the object taken.
    Electronic distance sensors 17 by means of the magnetic "hall" effect principle allow to know the compression (in distance) of the inner spring or spring 16, thereby calculating the force exerted or maintained by them.
    From a certain compression or displacement of these joints, a high-strength mechanical stop is produced, from which, this first clamp 10 can continue to compress the object, outside the range of force detection provided by this design, and by striking up to strengths of the order of tons, being then the hydraulic pressure sensor who provides the data of exerted force.
    Said design, therefore allows to know and control with the same clamp and with excellent precision, forces from a few grams to a few tons.
    Likewise, the robotic vehicle 1 incorporates inertial sensors, based on accelerometers associated to the driving axle of the wheelset, having its global positioning and being able to move autonomously according to the routes marked by the operator in the control equipment.
    On the other hand, as we have already indicated, we can indicate that the electronic control system of the robotic vehicle 1, integrated in the transportable case 9, consists of a high capacity management unit with embedded PC architecture and local control boards for command of the elements.
    The energy source is provided by a group of electrical energy storage formed by Lithium Ion batteries, capable of providing energy for typical missions of up to 4 h.
    The control of the robotic vehicle 1 is carried out remotely by means of the control equipment materialized in the suitcase 9 which includes:
    • a display screen 12 of images of the cameras of the robotic vehicle 1, of the conditions of use and complete telemetry;
    • a touch screen 13 in horizontal arrangement that takes functions of real interface with the operator, having menus, operating modes and all commands, and;
    • an HMI interface device consisting of an intuitive gamepad game controller through which the entire robotic vehicle is controlled.
    The data transmissions between the control case 9 and the robotic vehicle 1, are carried out through a digital radio link, with high security modulation and encryption and as an alternative use can be connected via a fiber optic cable line when the conditions or the operator make it necessary.
    Thus, the control center, based on suitcase 9, is fully transportable and has its own electric power through the use of state-of-the-art lithium batteries.
    The robotic vehicle 1 can have up to ten video cameras for visualization of the environment, both optical and fixed position as well as total control in movements and zoom, infrared lighting, infrared vision and thermal imaging camera.
    It can also have obstacle sensors both laser and ultrasonic action.
    In order to be able to move and make approximations to the desired place as well as for perimeter surveillance functions, the robotic vehicle 1 has global positioning technology (GPS or similar) and inertial sensors (accelerometers on its axes), so that it allows know both its position accurately and its variations relative to it, even without coverage of the global positioning satellite system.
    The operator interface allows to design routes on a plane, so that the vehicle, by means of the described systems, can move autonomously to the desired place or circulate in a mission of continuous surveillance. The obstacle sensors combined with the image recognition allow the robot to have the intelligence to overcome obstacles and trace light variations to the programmed route.
    The control of the robotic vehicle 1, formed by the suitcase 9 with its display and control elements, has the ability to connect to the global network, so that, from anywhere in the world you can either visualize the current mission or take Control of the entire system. Thus, it is very useful in training or even in the decision-making process in delicate missions, where such decisions can be taken from anywhere in the world.
    5 For practical purposes, said connectivity also allows a diagnosis of the states of the robotic vehicle so that it can be used as a technical intervention.
    The robotic vehicle has connectivity systems to new technologies, so that through the appropriate interface and application specially designed for it, the robotic vehicle can be controlled by the latest mobile devices
    10 generation, so that multiple operator interfaces can coexist giving or taking control of it.
    The robotic operator-vehicle communication method, by means of “quickstart” allows the vehicle to be controlled by means of the “gamepad” command without the use or start-up of the control center in the suitcase.
    15 This function is only valid for short distances and allows the deployment of the robotic vehicle from its transport to its preparation for the mission, while the team deploys its quota or starts up the main control system, being especially useful to reduce the times of acting in critical situations.
    twenty
    权利要求:
    Claims (1)
    [1]
    1ª.-TELECOMMANDED ROBOTIZED VEHICLE, being of the type of robotic vehicles equipped with rolling means and an articulated arm finished off in a caliper and which is remote-controlled to carry out different risk operations, by means of a control equipment, characterized by:
    image 1 the robotic vehicle (1) comprises:
    or two sets of wheels (2), one on each side, with three wheels each, each set of wheels (2) driven by corresponding motors (19);
    or two sets of tracks (3), one on each side on the inside of the wheelsets (2), at a level slightly higher than the wheelsets (2);
    or a first articulated arm (4) of hydraulic action mounted, by means of double articulation means (7), on a turret (6) rotating 360º by the central axis (18);
    or a second articulated arm (5) of electric and rotating actuation with respect to a vertical axis (8) for mounting, and;
    and whose robotic vehicle (1) is remotely controlled by:
    image 1 a control device integrated in a suitcase (9) comprising:
    • a display screen (12) of images sent by cameras mounted on the robotic vehicle;
    • a touch screen (13) in horizontal position of interface with the operator, and;
    • an HMI interface device defined by a “gamepad” game control.
    so that with the two sets of wheels (2) and the two sets of tracks (3) it travels through all types of terrain and with the combined movements of the two articulated arm (4) and (5) holds and manipulates the objects to examination according to the orders given by the operator from the control equipment, based on the suitcase (9), transportable.
    2nd.-TELECOMMANDED ROBOTIZED VEHICLE, according to the 1st claim, characterized in that each set of lateral wheels (2) is driven by an electric motor, having traction in differential mode and providing direction and turns.
    3rd.-TELECOMMANDED ROBOTIZED VEHICLE, according to the 1st claim, characterized in that the two sets of wheels (2) and the two sets of tracks (3) have a simultaneous movement.
    4th.- TELECOMMANDED ROBOTIZED VEHICLE, according to the 1st claim, characterized in that the first articulated arm (4) is defined by three sections (4a, 4b and 4c), the third section (4c) being provided with a lateral rotation of ± 90º and a first clamp (10) clamp is provided with endless rotation.
    5th.- TELECOMMANDED ROBOTIZED VEHICLE, according to the 1st claim, characterized in that the weight handling capacity of the first articulated arm
    (4) varies depending on the articulation positions.
    eleven
    6th.-TELECOMMANDED ROBOTIZED VEHICLE, according to the first claim, characterized in that the second articulated arm (5) is defined by three sections (5a, 5b and 5c), the third section (5c) being provided with a 360 ° rotation with respect to the longitudinal axis and a second clamp (11) is provided with an endless rotation.
    7th.-TELECOMMANDED ROBOTIZED VEHICLE, according to the 1st claim, characterized in that the first clamp (10) of the first articulated arm (4), hydraulically operated, is provided with a pressure sensor, associated with the flow and pressure supply, being able to regulate and knowing the exact force exercises the object to be manipulated
    8th.-TELECOMMANDED ROBOTIZED VEHICLE, according to the 1st claim, characterized in that the force or pressure exerted by the second clamp (11) of the second articulated arm (5) is controlled by the electric current control of the motor that activates it.
    9th.-TELECOMMANDED ROBOTIZED VEHICLE, according to the 1st claim, characterized in that the control means of the robotic vehicle (1) have a spatial calculation system and when selecting the control operator of the robotic vehicle (1) the position of the corresponding clamp in front of the object to manipulate the articulated arm will make the precise and simultaneous movements of its different sections to position itself optimally for the manipulation of the object.
    10th.-TELECOMMANDED ROBOTIZED VEHICLE, according to the 1st claim, characterized in that the first clamp (10) of the first articulated arm (4) is provided with mechanical joints (14) of short distance at its ends (15) that associated with some springs or internal springs (16) thereof will be those that withstand the pressure exerted on the object to be handled, as they are small weights.
    11th.-TELECOMMANDED ROBOTIZED VEHICLE, according to the 1st and 9th claim, characterized in that electronic sensors (17) are associated with distance sensors (17) of the first clamp (10) of the first articulated arm (4) of the first articulated arm (4) .
    12th.-TELECOMMANDED ROBOTIZED VEHICLE, according to the 1st and 9th claims, characterized in that, from a certain compression of the mechanical joints, high-strength mechanical stop is produced, from which, the first clamp (10) continues to compress outside the range force detection of the electronic sensors (17), and the hydraulic pressure sensor, associated with the hydraulic circuit, which detects and provides the force exerted.
    13th.-TELECOMMANDED ROBOTIZED VEHICLE, according to the 1st claim, characterized in that the robotic vehicle (1) incorporates inertial sensors, based on accelerometers associated to the driving axle of the wheelset (2), having its global positioning and being able to move from autonomously according to the routes marked by the operator in the control equipment, based on the suitcase (9) that integrates the control means.
    14th.-TELECOMMANDED ROBOTIZED VEHICLE, according to the 1st claim, characterized in that the robotic vehicle (1) incorporates obstacle sensors.
    15th.-TELECOMMANDED ROBOTIZED VEHICLE, according to the 1st claim, characterized in that the control equipment, based on the suitcase (9) that integrates the control means, incorporates means for its internet connection for control from anywhere.
    12
    16th.-TELECOMMANDED ROBOTIZED VEHICLE, according to the 1st claim, characterized in that the control equipment, based on the suitcase (9) that integrates the control means, incorporates means for its connection to mobile devices.
    13
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    ES201331685A|ES2540598B1|2013-11-19|2013-11-19|Remote Control Robot Vehicle|ES201331685A| ES2540598B1|2013-11-19|2013-11-19|Remote Control Robot Vehicle|
    CN201480073570.1A| CN106170370B|2013-11-19|2014-04-22|Remote control robot vehicle|
    PCT/ES2014/070340| WO2015075283A1|2013-11-19|2014-04-22|Remotely controlled robotic vehicle|
    EP14864490.9A| EP3072641B1|2013-11-19|2014-04-22|Remotely controlled robotic vehicle|
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