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    • 专利摘要:
    Robotic exoskeleton with self-adjusting sliding elbow support for human arm. The invention relates to a robotic exoskeleton that allows the user to move comfortably and perform medical therapies, assisted orthotic forces, activities related to sports practices or specialized training that require sequences of movements, daily tasks, or services of firemen, police, military, etc. Assisted in force by the exo-skeleton. The system consists of a vest (1), to which are attached the exo-arm (8), the exo-forearm (7), a support structure (2, 3, 4, 5), with sliding parts (5)., 31) and hinges (10) actuated, which allows to track the displacements of the shoulder with respect to the body and offers a solid mobile support point in addition to a passive weight compensation system using spindles (22), with power actuators (9) that allow to move the articulated arm in a controlled manner. The device also comprises an autonomous power supply system (11) and a control unit. (Machine-translation by Google Translate, not legally binding)
    公开号:ES2544890A1
    申请号:ES201430287
    申请日:2014-03-04
    公开日:2015-09-04
    发明作者:Roque Saltaren Pazmiño;Jesús VARELA SANZ;Javier;LÓPEZ LÓPEZ
    申请人:Universidad Politecnica de Madrid;
    IPC主号:
    专利说明:

    ROBOTIZED EXO SKELETON WITH SELF-ADJUSTABLE SLIDE ELBOW SUPPORT FOR HUMAN ARM
    DESCRIPTION
     5
    OBJECT OF THE INVENTION

    The present invention is encompassed within the field of rehabilitation medicine, sports training equipment, military robotics and assistance robots. Specifically, the invention relates to the design of an exoskeleton that can be superimposed on the arm of a person to provide assistance in rehabilitation, sports training, military applications or daily life, as an aid to move the arms, according to patterns of movement destined to achieve their rehabilitation, training, the execution of the specific movements of a discipline, or the most frequent daily movements. It is also appropriate for military, or civilian use in groups such as police or firefighters that may require strength and body protection.

    The object of the invention is to provide a robotic exoskeleton to allow its use in different applications, with great mobility, with the arrangement of only 20 five actuators, achieving a correct monitoring of the movement of the shoulder and the displacements of the elbow on the support structure which makes it possible to exert great forces.

     25
    BACKGROUND OF THE INVENTION

    At present, the rehabilitation robots that exist in the international market are of great weight and size and are anchored to a chair, the floor or a wall. Its appearance is that of an industrial robot next to the user who is usually sitting. The patient cannot move.

    Existing exoskeleton-type robots essentially engage in three functions: increase arm strength, rehabilitate or control other devices. Most known models have large mechanical structures and 35
    They have large power actuators to move them. Some are full body robots to support the weight of the robot. The versions that only cover the upper part of the body are normally the “master element” that allows a “slave robot” to be controlled and are only usable by healthy people and for this purpose.
     5
    The main deficiencies or disadvantages and unresolved problems of these models are:
    - Large volume: It makes mobility difficult in human environments and prevents taking it home or using it in daily user activities.
    - Heavy weight: A heavy exoskeleton is not suitable for patients who have 10 weak muscles or older people and is uncomfortable for the rest.
    - Industrial appearance: A big robot scares. It also stigmatizes its user. Its appearance precludes its daily use in the environments in which the person usually moves.
    - Complexity: High precision elements, expensive materials, and complex mechanisms prevent domestic application. The challenge is to achieve an effective and simple solution.
    - Shoulder joint: Almost all robotic systems treat the shoulder as a spherical joint of three degrees of freedom, but in reality their behavior is not this. The shoulder does not maintain a fixed position or an axis or center of the fixed rotation. It moves up - down and forward - behind, thus changing the center of rotation during movements.
    - None is able to follow the movement of the arm and forearm accompanying and without forcing it. This is of special interest in patients with pain and in military, firefighters, etc., who may require arm protection 25 while moving in a hostile environment.

    Existing exoskeletons are structures that are located near the arm, without wrapping it or accompanying it in its movement, as they are not able to follow its movements. The fundamental reason is the complexity of the movement of the majority of human joints, and in particular that of the shoulder that has 6 degrees of freedom (3 position and 3 orientation) and conditions the movement of the remaining parts of the arm.

    By raising the arm, the shoulder produces not only an increase in the angle between the body and the arm, but also vertical displacement of the joint and at certain times deviation from the axis of rotation of the joint. This type of displacements of the axis of rotation of the shoulder occurs in the three dimensions of the space so that the movement of the shoulder has 6 degrees of freedom and not three as it might seem at first sight.

    For this reason, if you wanted to make an exoskeleton that holds the arm and forearm or that wraps them, you would have to solve a problem in the shoulder joint. In the present design, the issue is addressed by giving extra mobility to the elbow that is dependent on the articulation of the human shoulder, to indirectly solve the problem generated by the latter.

    First of all it is necessary to clarify why it is interesting to wrap the arm and forearm and then the alternatives that could be valid to achieve it. Some of the 15 reasons are:

    - To distribute the mechanical efforts by the arm: For example, in rehabilitation of a shoulder, arm or forearm with pain. Wrap arm and forearm allows to accommodate the painful arm on properly padded supports 20 and prevents joint tensions. It also helps distribute the forces of the drives over the entire contact surface of the arm with the exoskeleton. In military equipment it would make the use more comfortable and allow a longer time of use. 25
    - To achieve greater precision in the movement: Existing systems do not involve the arm and forearm, among other reasons, because they are not able to follow their movement. If the arm could be wrapped without traction or tension, movement control would be much better. This advantage would have special value in rehabilitation 30 and in training of specific movements (sport, surgery, ...).
    - To protect the arm: an exoskeleton used to replace or complement the strength of its user, could additionally act as armor (military use), bullet protection (police), or fire retardant
    (civil-fire use), etc. if you are able to reasonably follow limb movements without forcing it.

    As for the possible ways to wrap or accompany the arm or forearm movement, two solutions seem reasonable: 5

    - Separate the exoskeleton by the shoulder into two parts: one corresponding to the arm and another that is attached to the body. The movement of both should be independent to leave the shoulder free to perform their natural movements. 10
    - Keeping the arm of the exoskeleton attached to the body by the shoulder, but giving it the ability to move it needs, for which it is necessary to give the arm-body joint the degrees of freedom that the shoulder requires. This can be achieved by moving part of the complexity of the shoulder to the arm and elbow. This allows the arm and elbow to be able to move radially to follow the movements of the shoulder. In addition, the rotation of the shoulder is transferred to the elbow structure which in turn moves with the arm self-adjusting according to the elevation and advance of the shoulder in each case. This solution has certain advantages such as allowing the shoulder to be followed and facilitating the protection of the arm and forearm, without forcing the joints and providing a mobile and firm support point to the arm, which, in turn, allows the application of great forces to the exoskeleton ,. No one has used this system so far.
     25
    In 1995 Marc D. Taylor patented (US5,417,643, reference [2]) a rudimentary support for the arm anchored to a chair in which the user was placed that allowed to perform lifting and rotation exercises of the arm for rehabilitation purposes. Since then there has been a clear tendency in the design of rehabilitation robots to place the patient in a fixed or wheelchair and place it next to the robot that will move his arm. 30 These types of robots, which we will call “fixed robots,” correspond to designs such as the one disclosed in US6,007,500 [8] of 1999, the one disclosed in reference [9] of 2003, the ARMin, ARMin II, ARMin III from the University of Zurich [3] of 2007, or the TSAI robot of the National University of Taiwan [4] of 2010.
     35
    In 1998, Mark E. Rosheim filed one of the first patents of modern exoskeleton, US5,845,540-B1 [6]. It is a master-slave system in which a human operator places the exoskeleton on the body and uses it as a master joystick to operate a slave robot. To this type, “Master-slave exoskeletons”, correspond to the one disclosed in patent 5,845,540 [5] patented in 2001 by the 5 Seoul Institute of Science and Technology and the model patented by Schiele, Andre Visentin, Gianfranco, EP1364755-B1 [ 1], presented two years later for space applications.

    Motorika's ReoTherapy ReoGo product [11] of 2009 is a large 10-size joystick that reaches from the ground to the height of a person sitting in a wheelchair. The user moves the lever and a computer program shows on a screen the movement of a point that represents his hand. It proposes objectives that the user must achieve by motivating him through the computer game to execute movements. This equipment is not exoskeletal or by table. Its only relationship with the exoskeleton presented is its medical application.

    The 2005 Intelligent automation Inc MacARM [12] is a fixed cage-type robot. The patient lies on a stretcher inside and cables from the corners of the cage move his arm through the space for rehabilitation purposes. twenty
    The inventions [15] and [16] are related to the "System for bilateral training" which consists of a large inclined platform that is fixed on a table or flat surface. The patient grabs cranks and they move the patient's hands in sliding movements forward and backward. The system is not portable, nor exoskeletal. It corresponds to the "fixed robot" type. 25

    The reference patent [1], EP1364755-B1, of 2003 is an arm exoskeleton with 16 degrees of freedom designed for space applications, conceived as a master system to give orders to a slave robot for maintenance work in space, returning a feedback of forces (type joystick) that contributes 30 to handle the slave robot with comfort. It has complex mechanisms such as the telescopic actuation unit, a high number of actuators, adjustable prestressing systems and many cables running through the exoskeleton to control the numerous joints. Its design is not well adapted for other applications such as rehabilitation, training, or use by people with motor weakness. 35
    For these applications a light system is required, which can achieve great mobility. Patent EP1364755-B1, is designed to be moved by a human arm and not to move the arm, so that the system is not adapted to support the weight of the arm and move it.
     5
    Patent application PCT / ES2009 / 070305 entitled "Robotic arm for control of arm movement" [10] belongs to the group of "fixed robots" in a particular version that places the patient on a hospital bed. The robot is anchored to the ceiling and takes the arm by its part furthest from the body. Like all fixed robots, they are not suitable to accompany a patient who moves. 10

    The RUPERT exoskeleton [19] of which there are already three versions, is an exoskeleton operated by pneumatic systems, with four degrees of freedom, one on the shoulder, two on the elbow and one on the wrist. The main weaknesses of this solution are that it does not carry gravity compensation, which only has a degree of freedom in the shoulder, which makes it impossible to follow this joint in a normal range of movements and the presence of pneumatic action that forces connect to an external source of pressurized air, which reduces its independence and mobility and makes it noisy and difficult to hide from view.
     twenty
    Reference US7,862,524-B2 [7] is an exoskeleton for the arm for shoulder rehabilitation purposes consisting of powerful power actuators and bulky "harmonic drive" type actuators located directly at the junctions of the links that compose the structure. By design it is a heavy system, and that logically needs the actuators to be large, which cannot be hidden and generates significant weights and inertia that complicate the control of arm movement. It is distinguished from virtually all previous models by having a torso-shoulder joint that does not appear in any other model. This is an important step in solving the problem of the shoulder, but only considers the displacement of the shoulder in the frontal plane and mainly in the vertical plane, which constitutes an incomplete solution.

    Until today there are no known low-cost models, nor models of reduced weight with force to move the arm of the patient, nor portable rehabilitation systems that can be taken to the home itself, nor portable exoskeletons with passive compensation of 35
    gravity, neither systems that adapt well to the mobility of the shoulder, or that follow the arm and forearm in their movements, nor exoskeletons of sports training that allow practicing movements to perfect the execution of them.

    The only exception is the patent [20] of the same authors: Roque Saltaren and Jesús 5 Varela. This design addressed the problem by separating, by means of a parallel structure, the exoskeleton of the arm from the exoskeleton of the body, in order to follow the movement of the shoulder.
    REFERENCES 10
    [1] Patent EP1364755-B1. Title: “Exoskeleton for a human arm, Particularly for space applications.” BOPI Publication (OEMP): ES2334780-T3. Authors: Andre Schiele; Gianfranco Visentin.
    [2] US Patent Number 5,417,643. “Continuous passive motion exercise device” Inventor: Marc D. Taylor, Columbus, Ohio. Assigned to: Danninger Medical 15 Technology, Inc, Columbus Ohio.
    [3] “ARMin-Exoskeleton for Arm Therapy in Stroke Patients” Tobias Nef, Matjaz Mihelj, Gabriela Kiefer, Christina Perndl, Roland Müller, Robert Riener, member IEEE. University Zurich, Switzerland 2007
    [4] TSAI - OCT 2010] “An Articulated Rehabilitation Robot for Upper Limb 20 Physiotherapy and Training. B.-C. Tsai, W.-W. Wang, L-C. Fu and J.-S. Lai National Taiwan University Hospital, National Taiwan University, Taiwan.
    [5] Patent No: US 6,301,526 B1. "Master device having force reflection function". Inventors: Mun Sang Kim, Soo Yong Lee, Chong won Lee of the Institute of Science and Technology, Seoul (KR) 25
    [6] U.S. 5,845,540 "Robotic Manipulator" Inventor Mark E. Rosheim, St Paul, Minn. By “Ross-Hime Designs, Incorporated, St. Paul, Minn.
    [7] Patent Number US 7,862,524 B2 "Portable arm exoskeleton for shoulder rehabilitation". Inventors: Craig R. Carignan, Michael Scott Liszka. Jan. 4, 2011.
    [8] U.S. Patent 6,007,500 "Shoulder, rotator cuff, and elbow stretching machine". 30 Inventor John J. Quintinskie, Jr. 31025 5th Ave. South, Federal Way, Wash 98003.Dec. 28,1999.
     [9] "Upper extremity exoskeleton structure and method". Inventors: Vladimir Zemlyakov, Haverhill MA (US); Patrick McDonough, Kensington, NH (US). Jun. 26,2003 35
    [10] Patent application PCT / ES2009 / 070305 "Robotic arm for control of arm movement". Inventors: Jose María Sabater Navarro, Eduardo Fernandez Jover, Nicolas Manuel García Aracil, Jose María Azorín Poveda, Carlos Perez Vidal. 11 March 2010.
    [11] ReoTherapy ReoGo by Motorika. Comercial product. 5
    [12] "Development of the MACARM - a Novel Cable Robot for Upper Limb Neurorehabilitation". David Mayhew, Benjamin Bachrach, W. Zev Rymer, and Randall F. Beer. Proceedings of the 2005 IEEE
    [13] European patent application EP02075669 "Gear locomotion device". Inventor: Amit Goffer by ARGO Medical Tech. 2002 10
    [14] International patent application PCT / CH2002 / 000255 "Device for reeducation and / or training of the lower limbs of the person". Inventors: Roland Brodard, Raymond Clavel for the Fondation Suisse for les Cybertheses.
    [15] “Dynamic orthotic device for monitoring, diagnosis and suppression of pathological tremor.” Inventors: Jose Luis Pons Rovira, Eduardo Rocon de Lima, 15 Andre Ruiz Olaya, Ramón Ceres Ruiz, Leopoldo Calderón Estevez, Juan Manuel Belda - Lois, Javier Sanchez Lacuesta, Ricard Barbera Guillem, Jaime Prat Pastor. C.S.I.C. Institute of Biomechanics of Valencia. 2008
    [16] "Cartesian travel mechanism with single transmission and double drive". Inventors: Jose Miguel Sanchez Soler, Miguel Ángel Abad Martín-20 Camuas, Artemio Paya Vicens. 2006.
    [17] PAT US 2001 / 001,222 "Device for bilateral training" Jill Whitall, Sandy McCombe-Waller, David Grant.
    [18] PAT US 2006 / 0.194.677 "Bilateral arm trainer and method of use". Jill Whitall, Sandy McCombe-Waller, David Grant. Continued request for 2002 25 PCT / US01 / 001222
    [19] "Design and Control of RUPERT: A device for Robotic Upper Extremity Repetitive Therapy". Thomas G. Sugar, Jiping He, Edward J. Koeneman, James B. Koeneman, Richard Herman, H. Huang, Robert S. Shultz, D.E. Herring, J. Wanberg, Sivakumar Balasubramanian, Pete Swenson, Jeffrey A. Ward. IEEE Transactions on neural 30 systems and rehabilitation engineering vol 15. N-3 Sept 2007.
    [20] Roque Saltarén and Jesús Varela: “Wearable robotic exoskeleton for human arm” patent number: P201131435

    35
    DESCRIPTION OF THE INVENTION

    The present invention relates to a robotic exoskeleton with a support structure with sliding elbow that allows it to follow the complex movement of the shoulder, and to be able to accompany the movements of the arm and forearm by wrapping them and self-adjusting during the movement. The system offers a rigid joint between arm and body, which makes it possible to have a support system that is solid enough to allow a large amount of force. The exoskeleton is placed superimposed on the human trunk and arms and can be used routinely to provide strength to the user or for specific applications of rehabilitation, teaching of some activity, or military uses.

    The present invention solves the problems of the state of the art listed above by means of a sliding component structure that takes into account the degrees of freedom of rotation of the shoulder and the additional ones due to the displacement 15 of the point of rotation of the shoulder in the three dimensions of the space ( frontal, sagittal and transverse plane).

    It also solves the displacements of the support point of the elbow with respect to the structure that supports the weight of the arm and its load. When raising the arm it is observed that the human elbow gradually moves away, although not linearly, from any structure parallel to the arm that is attached to the body and tries to follow its movement. The difference in elbow tracking is more noticeable if the structure is below or above the arm, but also occurs if it is at the same height as this. If a structure surrounds the user's arm and elbow, it would attempt to cross the armor in the highest positions, damaging the arm or armor or significantly limiting the realizable movement.

    To achieve an armor type wrap, it is proposed to wrap the arm and forearm in the mentioned armor without joining it to the body by the shoulder area and mounting it 30 on some type of sliding guide that would be located under the arm and attached to the trunk. The arm slides freely on the rails during the variations of position, without risk of crossing the armor by the elbow and, at the same time, the guide can be supported in any position by a solid and resistant structure joined
    to the body that is easy to move externally and incorporates the necessary additional degrees of freedom. There is no known exoskeleton that addresses this problem.

    The existence of the sliding elbow and the support structure simplify the control, since the kinematics of the two parts is easily relatable. A single degree of freedom 5 links those two structures and is easily measurable or calculable.

    The main contributions of this design with respect to the documents described above are:
     10
    - have a "support structure" on which the arm can be firmly supported allowing the application of great forces on it, gaining in speed, power and control of the whole, without the user's arm suffering stress.
    - have a “sliding-elbow” system that, in addition to incorporating the support structure into the assembly, allows the arm and forearm to be monitored. The elbow is monitored in its displacements with respect to the support structure during the elevations and descents and during the advances or setbacks of the arm.
    - Provide, due to its design, in relation to the work area or route 20 realizable, especially on the horizontal plane (greater advance). Provided by the sliding support structure and the displaced hinge system, which extend the reach of the lifting and advancing actuators, while avoiding the collision of elements with the body. 25

    The system is applicable in the assistance to people with motor limitations, in functions of rehabilitation of the limbs or aid to the movement of these. It is also applicable in general activities that require control and coordination of movements such as: sports training (tennis, ping-pong, ...), 30 surgical medical training (teaching of surgery, laparoscopic applications, etc.), manipulations specialized in navigation control, characterized by the ability of the device to reproduce movements predetermined or controlled by an assistant through direct or remote operation and in applications of assistance in force and protection of the body (military, fire, police, ...). 35
    The exoskeleton object of the present invention has important technical characteristics that allow solving different problems, providing the following advantages over other models:

    - Correct shoulder tracking: Correct tracking of displacements and 5 turns of the shoulder in space with respect to the trunk of the human body (6 degrees of freedom) thus avoiding pain and discomfort to the user. It provides the 3 degrees of freedom corresponding to the orientation or rotation of the arm in space by means of consecutive rotation axes. The three additional degrees of freedom, due to the shifts of the shoulder in the frontal, transverse and sagittal planes, are provided by the sliding structure of the side that allows the elevation of the shoulder, and by the sliding structure of the arm that allows a radial movement of the arm adaptable to each position. It is thus possible to follow the movement of the shoulder in space without forcing it.
     fifteen
    - Elbow follow-up: Elbow follow-up in its movements on the support structure provided by the radial sliding joint that moves on said support structure that carries the elbow joint elements and shoulder rotation. When a support structure is placed under the arm and attached to the trunk, it is normal for the arm to slide outward from the support, as we raise it. If the elbow joint elements are incorporated at the end of the arm support, as all other exoskeletons do, the elbow only fits the exoskeleton joint for a single arm lift position. In all other positions it would not fit and would not serve to articulate the elbow, or would not allow the forearm to be wrapped. In most robots with force assistance, this problem is ignored. The exoskeleton of the arm is a support structure with rigid joints that do not accompany the movements of the shoulder and elbow. In this way, the exoskeleton is always close to the arm, but it does not move in parallel to it, nor can it wrap it or serve as support and protection in all postures. In the present design, the elements that provide flexion-extension of the elbow and rotation of the shoulder (arm) are incorporated on a mobile structure that accompanies the elbow at all times during its displacements, which we call "self-sliding elbow. adjustable".

    - Arm support: The human arm rests comfortably on a support with the 35
    that there is no friction because it accompanies its forward and reverse movements with respect to the support structure provided by the sliding system and the support structure.

    - Large useful work area: By design, it allows operation by maintaining a large useful working area. Other mechanisms of the state of the art limit the real work area by the size of its engines, or by its structures, which collide in certain postures or by the complex mechanisms that surround the arm or by the difficulty of maintaining the tensile force in all positions without adding additional actuators. Provided by the special configuration of the support structure 10.

    - Exoskeleton: Being the invention of an exoskeleton, it provides mobility to the user, allowing him to move freely through diverse environments (do the treatment at home, train anywhere, receive assistance to a disabled arm 15 in the street, use by firefighters in fire or rescue, etc, ...).

    - Lightness or reduction in weight and volume: It prevents the user from carrying weight on the arm and allows him to move freely through human environments. Provided by the small actuators and the sliding support structure that loads with the motors, 20 with the arm and with the load and adjusts to the movement of this occupying very little additional space. Everything contributes to its use in human environments such as buildings or streets.

    - Simplicity and low cost: It uses few elements that are also simple and light. 25 Prevents complicated prestressing systems and multi-guide systems for tension or cable tension maintenance. It also avoids shoulder tracking systems based on multiple degrees of freedom or large and heavy rigid parts that require precision and absence of gaps that make the system more expensive. No titanium or expensive materials are needed for effective construction. It can be done with 30 commonly used materials.

    - Ease of movement programming: Intuitive for doctors, therapists, trainers and users. Provided by a tracksuit jacket with two “Inertial Units” that the doctor, therapist or trainer can wear and records 35
    the movement that it performs with its own arm. The measures are recorded and after filtering can be delivered to the exoskeleton for execution.

    - Versatility: Provided by a programmable computer-type input card that allows simple reprogramming for multiple and different 5 movements and behaviors.

    - Comfort, fit to the body: Provided by padding, wide support areas and support points separated from the arm support, rigid and wide that withstand the pressures without transmitting efforts to the body. The efforts are distributed in 10 large areas, improving your comfort.

    - Reduction of consumption, increase of autonomy: By using engines of lower power, energy consumption is lower.
     fifteen
    Structurally, the robotic exoskeleton with self-adjusting sliding elbow support comprises:
    - A harness or vest-like structure that is placed on the trunk of the exoskeleton user and serves as a support and reference base for the rest of the system.
      twenty
    - an exo-arm in charge of supporting, and optionally protecting, the user's arm.

    - a support structure for the exo-arm responsible for holding and positioning the exo-arm and the user's arm in the desired position and orientation.
      25
    - an exo-forearm, attached to the exo-arm by the sliding elbow structure and responsible for supporting, and optionally protecting, the user's forearm;

    - an exo-wrist, optional, to support the user's wrist and allow its rotation or the sending of orders according to the application; 30

    - a sliding elbow structure attached to the exo-arm to allow rotation movements of the shoulder and flexion-extension of the elbow, and to ensure a good fit of the forearm to the exo-forearm;
      35
    - a plurality of power actuators to actuate the active sliding joints and parts of the exoskeleton. The actuators can be electric motors, pneumatic or hydraulic cylinders or any other means of actuation;

    - carrier means to be carried by the user and responsible for supporting the 5 power actuators, the electronics;

    In a preferred embodiment, the support structure, for the exo-arm and the sliding elbow, comprises at least the following elements:
     10
    - a “fixed support base” that will be attached to the harness and will serve as a support point for the entire exo-arm support structure.

    - a “mobile support base” that will be attached to the previous “fixed support base” by means of some hinge type element that provides at least a degree of freedom in the joint, 15 allowing its rotation with respect to a vertical axis located in the union of both bases. This will allow the arm to move forward and backward.

    - a "vertical sliding support base" which will be connected, by means of a sliding table or other element of this type, to a guide fixed to the "mobile support base", allowing the subsequent assembly to be lifted with respect to the previous structures. It provides a degree of freedom of elevation or descent of the axis of rotation of the shoulder.

    - a "radial sliding support base" that will be joined by a hinge or similar to the "vertical sliding support base", allowing for the exo-arm to have a support surface to which it will be joined by a sliding table that it will move along a guide fixed to the "radial sliding support base". It provides a degree of freedom of rotation in the hinge and another of radial displacement, that is, in almost any direction for the exo-arm and the user's arm. In practice, this element, when combined with the previous ones, allows the arm 3 degrees of freedom of rotation plus 30 degrees of freedom of movement of the shoulder. By joining the elbow joint and the exo-arm and both sliding on this structure, the desired degrees of freedom are achieved.

    - some guides with sliding table that will serve as a union between pieces to provide 35
    a degree of freedom of linear displacement where necessary. The connection between the mobile base and the vertical sliding base and the connection between the radial sliding base and the ex-arm have already been mentioned.

    - the exo-wrist is preferably formed by a cylindrical shaped handle 5 anchored to a "sliding forearm base" that slides with respect to the forearm structure by the sliding table mechanism and guide already explained, to adjust to the length of forearm required in each posture and the user's morphology.
     10
    Another preferred exo-wrist variant would be formed by a cylindrical handle attached to a semi-ring, which would be attached to the aforementioned "sliding forearm base by means of any bearing mechanism that allows the ring and handle to rotate making the wrist play.
     fifteen
    Both the exo-forearm and the exo-arm preferably comprise some type of wrap, in order to keep the user's arm protected and accommodated. It is not essential that you hold it. Its shape, mode of closure and restraint will depend on the application that will be given to the exoskeleton. It will have padding and fixings to hold the assembly and distribute the pressure throughout the arm. twenty

    The rotation of the arm on the shoulder can be achieved by means of an actuator located on the sliding elbow. The wrist rotation can be achieved by an actuator located in the exo-forearm. The rotation of the elbow can be achieved by means of an actuator located in the sliding elbow. 25

    The elbow joint preferably comprises:

    - two moving parts with a common axis of rotation, the first moving part will be part of the exo-forearm and the second moving part of the exo-arm; 30

    - stops to prevent the elbow from turning backwards beyond a limit position;

    - an actuator or a fixation to immobilize said joint in certain uses. 35
    The exoskeleton may comprise:

    - various "encoders" located in the rotational joints to determine the angle that relates the position of the first moving part with respect to the second moving part; 5

    - various linear displacement sensors to locate at points where there is a degree of freedom of movement actuated or not.

    - a variety of inertial sensors in the exo-arm and exo-forearm to determine their orientation;

    The carrier means preferably comprise a vest, and may additionally comprise a backpack or bag for hiding electronics and actuators.
     fifteen
    Power actuators can be selected from the following: linear actuators, rotational actuators or a combination of the above. In a preferred embodiment, the linear power actuators exert their traction on the point to be moved.
     twenty
    The exoskeleton may have data storage means, input means for selecting an operating mode of the exoskeleton and a control unit configured to, depending on said selection, select one of the following operating modes of the exoskeleton:
     25
    - trajectory recording mode, to record the movements made by the exoskeleton in the data storage media;

    - recorded path tracking mode, to select a desired path, previously recorded on the data storage media, and repeat said path automatically or allow the user to try to follow it and correct it when leaving it;

    - External sensor tracking mode, to allow control of exoskeleton movement through external sensors. 35
    - exercise mode: in which the exoskeleton responds to stimuli caused by its user and reacts by moving in a certain way. For example, medical exercises to gain arc of movement in which the user must make the initial effort and the exoskeleton will help him to continue it.
     5
    DESCRIPTION OF THE DRAWINGS

    To complement the description that will then be made and in order to help a better understanding of the characteristics of the invention, this descriptive report is attached, forming an integral part thereof, a set of 10 drawings where illustrative and non-limiting, the following has been represented:

    Figure 1: General front view of the exoskeleton.
     fifteen
    Figure 2: Rear view of the exoskeleton.

    Figure 3: Detail of the sliding elbow structure (top view)

    Figure 4: Detail of the sliding elbow structure (bottom view) 20

    Figure 5: Exo-arm and exo-forearm assembly (simple exo-wrist).

    Figure 6: Detail of the support structure (previous view)
     25
    Figure 7: Detail of the exo-forearm and rotational exo-wrist.

    Figure 8: Exoskeleton in electric version with rotational wrist (front)

    Figure 9: Exoskeleton in electric version with rotational wrist (posterior) 30

    Figure 10: Sensor layout

    Figure 11: Exoskeleton placed on the body
     35
    PREFERRED EMBODIMENT OF THE INVENTION

    The robotic exoskeleton with self-adjusting sliding elbow support, has a configuration and appearance similar to a garment, so that it adapts naturally and ergonomically to the postures and movement of the person 5 who uses it, so that serve to provide the person with a complement of strength, movement aid and protection if necessary. The assembly of the invention is composed of clearly differentiable and functional parts, shown in Figures 1, 2 and 11, which are listed below:
     10
    - A properly padded harness or vest (1) that is dressed on the body (see figure 11), whose functionality is to serve as the basis for the control electronics (12) and power (9), power supply (11) , as well as the support structure (2,3,4 and 5) of the exo-arms (8) and exo-forearms (7) articulated robotic. fifteen

    - A system of motorized articulated links, forming the exo-arms (8) and exo-forearms (7), for being shod on the outside of the human arm (s) and forearm (s), with fasteners (32) and ( 50) conveniently located on each joint of the user's arm and 20 that serve to transmit the force of the robotic mechanism that helps movement.

    - A support structure (2,3,4,5) for exo-arms (8), exo-forearms (7) and self-adjusting sliding elbow (6) that serves as a solid support point for the arm assembly at the same time as It allows mobility in all directions and orientations you need.

    - A set of power drives, consisting of actuators (9) and power transmission elements (16) and anchor points (17) 30 necessary to perform the movements.

    - An autonomous power supply system (11), which can also be powered by connection to the power grid.
     35
    - A system or electronic control (12) of power and computer-based movement, in which reside the algorithms that implement procedures appropriate to the type of user and activity to be performed.

    - A set of sensors (64 to 73), represented in figure 10, which allow obtaining information about the state (position and movement) of the exoskeleton and acting on it. This includes potentiometers (64 a70) and (73) and the inertial sensors of type IMU (71) and (72) among others.

    The harness or vest (1), is constituted by layers of flexible and lightweight material 10 for the protection of the body, covered by a plastic layer (76), (figure 11) that provides rigidity, supporting the rest of the structure and preventing the vest from moving relative to the user's body. It could be superimposed on any outer fabric that provides a pleasant appearance or protection (thermal, bulletproof, ...). The rigid parts together with the padding contribute to distributing the 15 specific forces or forces on a surface and make the user practically not notice the pressures caused by the movement of the exo-arm (8) and exo-forearm (7). It also includes braces (74), (figure 11) with fastener elements (75), (figure 11) that help to adjust and fasten it to the body.
     twenty
    The support structure shown in Figure 6 is composed of the following elements:

    - A fixed structure (2) shaped so that it has a flat surface with holes that allow this piece to be fixed to the vest (1), adjusting it to 25 different body measurements. It also has fins (61) arranged towards the back of the body that allow anchoring auxiliary equipment such as the power supply (11) or control electronics (12). Towards the anterior zone it has small fins (62), which can be oriented perpendicularly to the main zone or not, which allow fixing about 30 hinges (10) that will join the support structure (2) to the next, the mobile structure (3). If they are arranged perpendicularly, space is gained to locate an actuator (9) and facilitates reaching backward and forward arm positions more in line with the actual range of motion of the joint.
    - The mobile structure (3) is essentially a flat plate that is fixed to the fixed structure (2) by the hinges (10) providing rotational mobility along a vertical axis, which will allow forward and reverse movement of the arm. This axis of rotation is operated by an actuator (9) that is fixed to the fixed structure (2), by means of a square (51). The actuator moves the power transmission means (45) and (46). The latter has a clamp shape and the precise measures to hold the mobile platform (3) moving it when necessary.

    - A vertical sliding structure (4) in platform functions is connected to the mobile structure (3) by means of a sliding table system (33), (figure 3) and the guide (52), (figure 6) that gives it the possibility of moving parallel to the mobile structure (3) in the vertical direction, providing the adjustment to the position of the shoulder, following its evolution during the movement. To achieve this adjustment, it could be left free in some applications with 15 healthy patients, but in general it will be necessary to operate it. Such is the case in rehabilitation patients or applications in which it is expected to withstand significant loads (military, firefighters, ...). To actuate it, an actuator (9) and a power transmission system consisting of:
     twenty
    or an endless screw (22),

    or a coupling (18) between axles that joins the actuator (9) to the worm (22),
     25
    or a support assembly (44) formed by a square anchored to the mobile structure (3) and a bearing, which support the weight of the load preventing the coupling (18) from doing so.

    or a nut pressure assembly (43) similar to that formed by the square 30 (25), the nut support (24) with its nut and the stop (23) that prevents the nut from leaving the assembly. This assembly slides along the thread of the worm (22) as the actuator (9) rotates it. Being attached to the vertical sliding structure (4), this is moving relative to the fixed structure (3). 35
    - An upper structure (5), connected to the vertical sliding structure (4) by means of a hinge (10) that allows the rotation between the two along an adjustable horizontal axis. This axis is operated by an actuator (9) and a power transmission system, similar to the one explained above, which joins the upper (5) and mobile structures (3) by means of anchor points (17) at both ends, and which is composed of: a shaft coupling (18), an endless screw (22), a support assembly (19,20,21), a nut pressure assembly (23), (24), (25 ), a guide (48), a sliding table (33), (figure 3) and a sliding structure (49).
     10
    The resulting movement, from this part, is a combination of rotation of the upper structure (5), around a horizontal axis, adjustable along a vertical axis, and movable in height, with respect to the fixed structure (2).

    On the upper structure (5) a guide (29) on which a sliding table 15 (33), (figure 3), on which the radial sliding platform (31) will be anchored, is mounted (figure 3) that It is explained below and that completes the possibilities of rotation, displacement and orientation of the set.

    The exo-skeletal arm, formed by (6), (7) and (8) is a set that fits over the user's arm fixing it and matching the equivalent joints of both (wrist, elbow, shoulder). The exo-skeletal arm, shown in figures 5, 4, 3 and 7 is formed by several elements:

    - The radial sliding platform (31) is the base of the Exo-Arm (8) and can be seen in Figure 3. This platform slides on the guide (29) attached to the support structure formed by (2), (3), (4) and (5) and in combination with it provides all the necessary degrees of freedom. Its movement could be automated in combination with the movements of the rest of the joints and degrees of freedom, but it can be left free, if the arm or the forearm of the user is properly fixed to the corresponding exoskeleton part. This degree of freedom will absorb shoulder and arm movements. Numerous elements are coupled on this platform, which move in solidarity with it when the arm is moved.
    - The exo-forearm (7) is a set of parts that is coupled to the user's forearm and is essentially composed of a flat support (51), (figure 7) on which a guide (33) with its sliding table is installed (33 '), (figure 3) to which various elements that can be seen in figures 5 and 7 are coupled:
     5
    o The padded support support (50) for the forearm (figure 7) or some other means of securing the forearm.

    or some element of the "grip" or "exo-wrist" (59), (figure 7), "hand grip" (13) (figure 1). 10

    o The reason that these elements slide over the exo-forearm is not only to adapt to different lengths of the limb but to allow their accommodation depending on the different positions that the elbow can adopt and possible displacements of the arm with respect to the ex-arm. fifteen

    - The Exo-arm (8) is the assembly formed by the sliding platform (31) and a simple padded arm support (32), although it could be a more complex structure with the possibility of fixing and holding the arm well.
     twenty
    - The exo-elbow (6) is a piece attached to the radial sliding platform (31) by means of a hinge (10) that allows the elbow extension flexion movement along a horizontal axis. This degree of freedom would be insufficient if it were not combined with that of exo-forearm rotation (7) with respect to this structure, by means of the pulley (36) and the bearing (34), attached to the platform 25 (35) by means of plates (41) on both sides. These two turns of the exo-forearm and exo-elbow allow a complete mobility of the forearm in any position of the arm and also the rotation of the shoulder.

    - There are many solutions to act the articulation of the exo-elbow (6) with respect to the 30 exo-arm (8), or more specifically, the platform (35) with respect to the radial sliding platform (31), but a preferred solution, that we can see in figure 3, consists of an actuator (9) that is fixed to the radial sliding platform (31) by means of a square (47). The motor is attached to an endless screw (22) by means of a shaft coupling (18). A stop formed by the square (21), 35
    the bearing (20) and the fixing (19) that form the set of supports (19,20,21) already mentioned, prevents the coupling (18) from undergoing stretching and tension. On the piece (31) there is a guide (30) with its corresponding sliding table to which a platform (14) is attached that supports:
     5
    or the nut pressure element formed by a square, a nut support and its nut (23), (24) and (25) with the stop that prevents the nut from coming out.

    o The power transmission element (26) which, thanks to a groove 10 (27) in the form of an arc or a curve formed by segments, transmits the force in the most convenient way at each possible angle of elevation of the forearm. It is noteworthy that the power transmission assembly is arranged so that it does not trip over the guide (29) in any position of the forearm and the radial sliding platform (31). 15 Actuation electronics (38) also accompanies the group in its movements.

    - The power transmission element (28) is fixed to the sliding exo-elbow (35) and connects with the previous power transmission element (26) 20 by means of a rod (39) that slides through the groove (27). This element (28) can support the control electronics (38) and is arranged so that it does not collide with the guides (29) in its movement.

    - To operate the exo-forearm with respect to the exo-elbow a possible solution is 25 by means of an actuator (9) located in the exo-elbow that by means of a pulley (37) a toothed belt (“timing belt”) (77) moves to the toothed pulley (36) located under the exo-forearm (7). The pulley (36) moves a sensor that informs the position of the forearm. Another option would be to place a contact stop for a certain resting position and use the motor encoder to know the exo-forearm situation.

    Gravity compensation is achieved mechanically due to the worm system (22) that practically does not require force to maintain a given position. 35
    The computer control system (12) controls the execution of the movements by means of algorithms adapted to the application given to it:

    - Rehabilitation: algorithms to execute the movements indicated by the doctor or therapist. 5

    - Sport: algorithms to execute training movements.

    - Learning in surgery: algorithms to repeat the movements indicated by the teacher. 10

    - Daily assistance: algorithms for the most frequently used movements in daily life.

    - Resistance assistance: algorithms that allow to maintain an uncomfortable or exhausting posture for a long time with the minimum effort. For example, in the work of the workshop, changing parts that require having long raised arms, or lying under a car with strength with raised arms.
     twenty
    - Military applications or security or fire departments: In this application there should be a means to indicate to the algorithm the type of movement that you want to do at each moment, intuitively and naturally. A simple means could be by sensors located in the handgrip or hand grip (13) or rotations of the exo-wrist, shown in Figure 7, which would mark the intention of movement by pressure or displacement respectively. The algorithm must react accordingly by driving the motors.

    The algorithms present in the computer may have been programmed in many different ways, including programming, simulation, using a joystick, or external sensors arranged similar to the kinematics of the human body, etc.

    On the exo-skeleton there are inertial sensors (71) and (72) IMU type (see figure 10) that report the position, speed and acceleration of the arm and the user's forearm, 35
    as well as its inclination and orientation. There are also sensors that can be “encoders” or potentiometers that allow to know the position and characteristics of the movement of each joint or degree of freedom of sliding of the exo-skeleton. Thus, the degree of advance is measured with the potentiometer (64), the elevation by means of (66) and elbow flexion between (68) and (69). The latter measures on the other hand the shoulder rotation. Also included are linear sensors such as the one that measures the elevation of the shoulder (65), or the one that measures the elevation of the arm (67) or the one that measures the advance of the radial sliding platform with respect to its guide, the (73). He (70) measures wrist rotation.  10 Example 1: Execution mode with electric motors

    In the embodiment by means of pneumatic or hydraulic cylinders, the mechanical assembly and the power transmission elements are simplified as indicated in Figures 1 and 2. In an embodiment based on electric motors, as shown in Figures 8 and 9, the Power transmission is slightly more complicated but provides gravity compensation with virtually no consumption.
    Example 2: 2-arm embodiment
     twenty
    This embodiment can be used to exercise with both arms in parallel or in coordination of movements, for example for sports use. The essential difference is that two exo-arms and the actuators needed to move both arms would be installed.  25
    权利要求:
    Claims (1)
    [1]

    1st.- Robotized exoskeleton with self-adjusting sliding elbow support for human arm, comprising:
     5
    - a handle with at least one semicircular support (59) and a handle or exo-wrist (13) to position the hand and mobilize the user's wrist or allow it to exert control over the exoskeleton;
    - an exo-forearm (7), attached to the exo-wrist and in charge of supporting the user's forearm 10;
    - an exo-arm (8) responsible for supporting the user's arm, attached to the exo-forearm (7) by means of a movable joint (6) to allow the user's elbow to rotate;
     fifteen
    - a joint of the exo-arm (8) with a sliding support structure (2,3,4,5) that allows movement of the arm with respect to the shoulder and from this respect to the body;
    - a plurality of power actuators (9) for operating the elements of the exoskeleton; twenty
    characterized in that it comprises:
    - a support structure (2,3,4,5), which joins the exo-arm (8) to the trunk allowing the sliding of the arm over it, responsible for providing the mobility of the arm and 25 of the shoulder with respect to the trunk making a follow-up of the shifts of the shoulder with respect to the body, allowing a permanent adjustment of the movement of the elbow with respect to the body, which comprises at least one vertical sliding structure (4) and a radial sliding platform (31) on which the articulation system will go of the elbow or exo-elbow (35). 30

    2nd.- Robotized exoskeleton with self-adjusting sliding elbow support for human arm, according to claim 1, characterized in that it includes a gravity compensation system comprising at least one of the following 35
    elements:
    - An actuated screw (22) that supports the arm based on the support structure of the ex-arm (8).
     5
    - a lower shock absorber that supports the arm based on the support structure of the exo-arm (8).
    3rd.- Robotized exoskeleton with self-adjusting sliding elbow support for human arm, according to any of the preceding claims, characterized in that the elbow articulation structure moves over the support structure and allows the user's forearm and elbow to be permanently adjusted to the exo-forearm (7) and exo-elbow (35) of the robot, regardless of the position of the shoulder, arm and elbow.
     fifteen
    4th.- Robotized exoskeleton with self-adjusting sliding elbow support for human arm, according to any of the preceding claims, characterized in that both the exo-forearm (7) and the ex-arm (8) comprise, to keep the user's arm held to the exoskeleton, a support piece in the shape of a hollow semi-cylinder that allows easy access to the arm, cushions that make the space comfortable and adjustable fasteners to hold the arm or forearm.
    5th.- Robotized exoskeleton with self-adjusting sliding elbow support for human arm, according to any of the preceding claims, characterized in that the rotation of the arm on the shoulder is carried out by means of an actuator located on the sliding elbow-25, which moves with this on the support structure.
    6th.- Robotic exoskeleton with self-adjusting sliding elbow support for human arm, according to any of the preceding claims, characterized in that the rotation of the wrist is carried out by means of the handle (13) fixed on a hollow half cylinder or exo-wrist (59 ) whose actuator is located in the exo-forearm (7).
    7.- Robotic exoskeleton with self-adjusting sliding elbow support for human arm, according to any of the preceding claims, characterized in that the
    Bend of the elbow is carried out by means of an actuator located in the sliding elbow that moves with it on the support structure.
    8.- Robotized exoskeleton with self-adjusting sliding elbow support for human arm, according to any of the preceding claims, characterized in that 5 comprises a series of sensors (64 to 73) that allow to know the position, speed and acceleration of each of the parts of the exo-skeleton, some of said sensors being able to materialize in “encoders” or potentiometers to measure the advance, the elevation and the flexion of the elbow, as well as the rotation of the shoulder, the elevation of the shoulder, the elevation of the arm, the advance of the radial sliding platform 10 with respect to its guide, the rotation of the wrist and the orientation of the arm and forearm.
    9.- Robotized exoskeleton with self-adjusting sliding elbow support for human arm, according to any of the preceding claims, characterized in that the 15 carrier means comprise a vest (1).
    10.- Robotic exoskeleton with self-adjusting sliding elbow support for human arm, according to any of the preceding claims, where the power actuators (9) can be linear, rotational or a combination thereof.

    11.- Robotized exoskeleton with self-adjusting sliding elbow support for human arm, according to any of the preceding claims, characterized by 25 having data storage means, input means for selecting an operating mode of the exoskeleton and a unit Control set to, depending on this selection, select one of the following modes of operation of the exoskeleton:
     30
    - trajectory recording mode, to record the movements made by the exoskeleton in the data storage media;
    - recorded path tracking mode, to select a desired path, previously recorded on the data storage media, and repeat 35
    said trajectory automatically or allow the user to try to follow it and correct it when leaving it;
    - External sensor tracking mode, to allow control of exoskeleton movement through external sensors. The external sensors can be managed by the user himself in force assistance applications or by a tutor or doctor who guides the movements of the student or patient respectively.
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    同族专利:
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    ES2544890B2|2016-05-09|
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