WO2016051081A1 - Exoskeleton having a centered tool holder, and method for using such an exoskeleton - Google Patents

Abstract

The invention relates to a lower member exoskeleton (1), including: two articulated legs (2, 3) arranged such as to be coupled with the lower members of a user; a member (4) for providing a connection between the upper ends (5, 6) of the legs to which it is articulated, said member being positionable on the pelvis of the user and entirely located in front (7) of the articulated legs in the walking direction; and an articulated arm (8) for holding a tool (9), said arm being attached to the connecting member (4). The articulated legs are arranged such as to be entirely attached onto the front of the legs of the user. The exoskeleton comprises means for actuating the articulated legs on the basis of the movements of the user. The articulated arm is attached to the connecting member such as to be centered or substantially centered relative to the member (4), within or substantially within the sagittal plane (10) of the user.

Description

 EXOSQUELET WITH CENTER TOOL DOOR AND METHOD OF USING SUCH EXOSQUELET

The present invention relates to an exoskeleton of lower limbs with a tool holder, comprising two articulated legs arranged to be coupled to the lower limbs of a user, a connecting member between the upper ends of the legs to which it is articulated, adapted to be positioned at the of the user 's pelvis and means for actuating the articulated legs according to the movements of the user.

 It also relates to a method of using such an exoskeleton.

 It finds a particularly important, although not exclusive, application in the field of the use of tools with high hardness, in particular because of the major efforts to provide at the level of the tool itself in the horizontal plane.

 It can thus be used to advantage in the building and public works sector, the automotive industry, aeronautics or any other type of industry requiring the use and therefore the assistance to work of tools such as: that and not limited to rakes, perforators, jackhammers or any tools whose handling generates significant horizontal forces.

 Currently, exoskeletons for the use of known tools are generally provided for the upper limbs.

In the rarer case the use of lower exoskeletons, these put this Once again, a tool holder is attached to the exoskeleton at the right end of one leg.

 This solution reproduces in fact a typical type of operation for humans, ie with a right-handed or left-handed architecture depending on the user.

 Such solutions have disadvantages.

Indeed, insofar as they are precisely close to an operation corresponding to that of the man without exoskeleton, they are thus directly linked to an arm or to one side of the exoskeleton.

 It is therefore more difficult and time consuming to equip with the exoskeleton and the man's gestures are limited to those authorized by the latter (impossible for the user provided with the exoskeleton to drink or scratch, for example ).

 In the case of an architecture with an arm attached to the right of the end of a leg, the eccentricity of the tool relative to the man also limits the areas achievable with the tool and makes uncomfortable the handling of the tool.

 In general, the exoskeletons of the prior art are provided essentially for generating vertical forces against gravity.

The invention among others has an idea opposite to the teaching of the prior art and the practice of exoskeletons, including (but not exclusively) by accepting a centering on the front of the tool taken only or essentially centrally at the hips or the size of the user especially and for example in the lower part of the lower exoskeleton. Unexpectedly, this architecture makes it easier to generate horizontal forces, that is to say the components of which project essentially in a horizontal plane.

 Indeed, to generate horizontal forces we will here exploit the weight of the user. So that the direction of the effort projected in the horizontal plane does not create a lever arm and therefore a couple difficult to counter, we will make sure that it is directed towards the center of gravity of the whole user more exoskeleton.

 For this purpose, the present invention aims at providing an exoskeleton and a method of using such an exoskeleton that better responds than those previously known to the requirements of the practice, in particular in that it will allow manipulation and / or use. of the tool centrally relative to the exoskeleton, in the sagittal plane of the man, and in his field of vision, leaving the arms of the latter free of their movements.

 Sagittal plane means the vertical plane of symmetry of the skeleton of the user.

 It also presents the following advantages:

The architecture of the exoskeleton is simplified by proposing a single tool holder while the tool will be able to be handled with both hands.

 The workspace is close to that of the unattended man using a two-handed tool.

- The arms of the man are not linked to the tool, and therefore remain free for basic gestures.

The tool can be used transparently by a right-handed or left-handed person, while Previous solutions required fixing the tool to the right or left. Likewise, no adjustment is necessary between the operators according to their size.

- The tool holder is completely in the field of view of the operator who can thus limit the interference.

 The tool holder does not add additional lateral extra thicknesses to the exoskeleton.

- The tool holder does not hinder movements related to the force work, such as cleaning the tool.

 The implementation of the tool does not hinder the initial mobilities of the exoskeleton, for example the seizure of an object on the ground (squatting position of the exoskeleton).

 It will also be possible to slip on the exoskeleton already fitted with the tool from the back of the tool in a simple and fast manner.

 Finally, although reducing (by design of the connecting member between the legs of the exoskeleton) the field of vision towards the front of the user, the invention allows a better apprehension of the space by the 'user.

 The perception and efforts of the user are thus very little different from those he experiences when using without equipment.

The invention also allows greater safety, the tool is not likely to be dropped or fall on the user in case of movement with 1 exoskeleton. For this purpose, the invention proposes in particular a lower limb exoskeleton comprising two articulated legs arranged to be coupled to the lower limbs of a user, a connecting member between the upper ends of the legs to which it is articulated, adapted to be positioned at the level of the pelvis of the user and entirely located at the front of said legs articulated in the direction of travel and an articulated arm tool holder, fixed to the connecting member,

 characterized in that the articulated legs are arranged to be fixed and / or located entirely on the front of the user's legs,

 in that it comprises means for actuating the articulated legs according to the movements of the user, and in that the articulated arm is fixed to said connecting member centrally or substantially centered with respect to the organ, in the plane or substantially in the sagittal plane of the user.

 Such a relative arrangement of the articulated legs of the connecting member and the centered position of the attachment of the tool holder makes it possible to resume in a simple manner without excessive motorization the torque generated by the work of the user with the tool.

 Thus the generation of horizontal forces by the tool is no longer a problem difficult to solve except to require additional actuation of the exoskeleton.

In advantageous embodiments, one or more of the following provisions are also and / or in addition: the exoskeleton comprises means for detecting the supports of the exoskeleton on the ground, the articulated arm comprising force-amplifying means for handling the tool and means for blocking the operation of the articulated arm as a function of the support on the the soil of exoskeleton members and pre-established instructions;

 - The connecting member comprises a bearing abutment and / or fixing a tool carried by the tool holder. The power of the legs of the exoskeleton can then be used to increase the efficiency of the tool used;

 - The connecting member comprises a transverse bar on which is fixed the articulated arm and the articulated arm comprising a first articulation in horizontal rotation for scanning a working area in front of the exoskeleton;

 the articulated arm comprises a first rod for fixing the first articulation below the transverse bar;

 the articulated arm comprises a series of three pivots connected respectively to one another by second and third connecting rods and arranged to allow flexion / extension of the arm in a vertical plane and its inclination with respect to a horizontal plane;

 - The articulated arm further comprises a longitudinal pivot of lateral orientation of the tool relative to the rest of the articulated arm;

- The arm comprises a first longitudinal handle for fixing and / or handling of the tool by a first hand of the user, provided with a force sensor; - The arm is equipped with a second handle fixed lower on the arm, handling thereof with a second hand of the user, to facilitate a horizontal rotational movement;

 the connecting member is equipped with means of illumination towards the front of the exoskeleton and / or with a protective canopy of the user.

 The invention also provides a method of using a lower limb exoskeleton with a tool carrier provided with a tool, said exoskeleton comprising a connecting member of two articulated legs adapted to be positioned at the pelvis of the user, characterized in that, the member being entirely located at the front of the legs articulated in the direction of travel and comprising an articulated arm carrying tool, fixed to the connecting member centrally with respect to the member, said arm being provided with force amplifying means and comprising a first longitudinal handle of the tool by a first hand of the user, said handle being provided with a force sensor,

we block the articulated arm (in nominal),

when it is detected whether the support on the ground of the members of the exoskeleton is in accordance with previously established instructions, it is possible to switch to force amplification mode of the tool carrier,

it is detected whether the user intends to exert a force on the tool by said force sensor, and when the detection is positive, said tool is used, the direction of the force provided by the articulated arm being identical to that observed on the first handle. The invention will be better understood on reading the following description of embodiments given below by way of non-limiting examples.

 The description refers to the accompanying drawings in which:

 Figure 1 is a front side perspective view of an exoskeleton according to one embodiment of the invention.

 Figure 2 shows a side view of the exoskeleton of Figure 1.

 Figure 3 is a top view of the exoskeleton of Figure 1.

 FIGS. 4A to 4D illustrate four stages of use of an exoskeleton according to an embodiment of the invention, with the link bar respectively lowered, before threading, and then in use by the user.

 FIG. 5 is an example of a logic diagram for developing laws for controlling the operation of an exoskeleton according to the invention.

 In the rest of the description, the same reference numbers will be used to designate identical or similar elements.

 Figures 1, 2 and 3 respectively show in perspective, in side view and in plan view an exoskeleton 1 of lower limbs comprising two articulated legs 2 and 3 arranged to be coupled to the lower limbs of a user (not shown), a connecting member 4 between the upper ends 5 and 6 of the legs to which it is articulated in known manner in itself.

The connecting member 4 is arranged to be positioned at the level of the user's pelvis and comprises means for actuating the legs articulated according to movements of the user here again also known in themselves.

 According to the embodiment of the invention more particularly described here the connecting member 4 is entirely located at the front (arrow 7) of the user (not shown) in the direction of travel.

 It comprises an articulated arm 8 tool holder 9 fixed to the connecting member 4 centrally relative to the member 4, in the plane or substantially in the sagittal plane 10 of the user.

 The exoskeleton 1 comprises means 11 for detecting the support of the exoskeleton on the ground, for example formed by piezoelectric sensors.

 The sensors are connected via a wireless connection and / or wired passing inside the legs to a control device 12 comprising in known manner a microprocessor, storage means, calculation means arranged to react to the indications obtained by the sensors 11 for example located under the soles of the slippers 13 used by the user and located at the end of the articulated legs 2 and 3.

The exoskeleton 1 comprises force-amplifying means 14 constituted by electric cylinders (not shown in detail) for handling the tool 9 and locking means, for example consisting of electrically-controlled pawls 15 located at the various joints which will be described. hereinafter, blocking the operation of the articulated arm 8 according to information from the support on the ground members of the exoskeleton and instructions previously established and recorded in the calculator 12.

 Precisely and for example when it is detected a dissociation between the two values obtained by the sensors 11 located on the left foot and the right foot, which means that the exoskeleton is climbing a step and / or moving forward , the computer 12 blocks and closes the pawls 15 so that the arm is immobilized.

 In the embodiment described, the tool 9 is constituted by a rake 16 provided with a rod 17 and having at one end a sweeping brush 18 for example to spread a layer of fresh tar and on the other side of a end 19 arranged to be able to rest on a fulcrum 20 secured to the connecting member 4, so that the thrust of the legs of the exoskeleton can be used to increase the effectiveness of the rake.

 More precisely, the connecting member comprises a transverse bar 21 on which the articulated arm 8 is fixed, the latter comprising a first articulation 22 in horizontal rotation allowing a scanning of a working zone in front of the exoskeleton (arrow 23). first rod 24 fixing the first articulation 22 on the transverse bar 21, vertical allowing the attachment of said first hinge 22 below the transverse bar 21.

Attached to this first articulation in horizontal rotation 22, the arm then comprises a sequence of three pivots 25, 26 and 27 connected respectively to each other by second rods 28 and third rod 29 connecting pivots. The joints between pivots are thus arranged to allow flexion / extension of the arm in a vertical plane and its inclination relative to a horizontal plane in a manner known for this type of articulation.

 It further comprises a longitudinal pivot 30 of lateral orientation of the tool relative to the rest of the articulated arm.

 In the embodiment, the arm comprises a first longitudinal handle 31 for fixing the tool, for example, which can thus be grasped upstream by a hand of the user (not shown).

 This first longitudinal handle 31 comprises a force sensor 32 known in itself for example of the pressure sensitive electric piezo sensor type.

 The arm is further equipped with a second handle 33 fixed lower on the arm 34, handling thereof by a second user's hand to facilitate a horizontal rotational movement.

 Advantageously, the connecting member 4 comprises illumination means 35 of the exoskeleton and / or a canopy 38 for protecting the user (see mixed line in FIG. 2).

The legs 2, 3 are formed in known manner by horizontal transverse axes parallel or substantially parallel to the connecting member which allow the flexion / extension of the corresponding leg and also by horizontal axes and perpendicular to the transverse axes to allow the Passive adduction of the hips. The member 4 comprises a branch 39 substantially U-shaped whose parts or end bars 40 are connected to the hinge pins 41 and whose central bar 42 is located in front of the user's belly.

 The bar 42 is horizontal and is provided with the horizontal bar 21 also horizontal cantilevered with respect to the lifting polygon of the body of the user which coincides substantially with that determined by the legs and articulated legs of the exoskeleton.

 The bar 21 is arranged to carry the tool holder.

 The exoskeleton also has articulations 43 at the knees of the user, for example formed similarly to the joints at the hips (horizontal axes) and means 44 for actuating the articulated legs according to the movements of the user. , schematized in phantom in the figure, which will be detailed below.

 The embodiment of the exoskeleton 1 more particularly described here will now be described more specifically with reference to FIG.

 Each leg has a leg 45 and a tibia 46 identical in pairs.

 The thigh 45 comprises an internal metal tube 47 (mixed lines in the figure) for example titanium, on which is fixed a first cover 48 for example plastic.

The first cover 48, elongate with a substantially trapezoidal longitudinal section in the shape of a human thigh, provides an interior space around the tubing 47, space in which will be housed at least in part the actuating means.

 The knee joint is for example of the type formed by a horizontal axis 49.

 When the exoskeleton is at rest, the thigh and the tibia form an angle α greater than 140 ° for example 160 °.

 The actuating means comprise the means for actuating the knees, for example housed inside the first corresponding cover 48, and are respectively each formed by a DC electric motor powered by a corresponding removable battery located on each side on the rear part of the connecting member 4 and / or the upper part of the thighs 45.

 The motor is of a power adapted to generate a torque greater than 100 N.m. It is connected to an actuation piston known in itself, fixed on one side to the tubing 47 of the thigh and the other to a blade 50 (mixed line) forming the corresponding tibia.

More precisely, and in the embodiment described, the tibia is of slightly curved elongated shape (for example a radius of curvature of between 1 m and 2 m). It is formed by an internal blade, rigid enough to take up the load but also flexible enough to play the role of a damping spring, attached at its proximal end to the lower part of the tubing 47 by the hinge formed by an axis and at its distal end to the foot described below. The tibia comprises a blade cover, for example in the form of an open sheath of U-shaped cross-section. and side profile adapted to the respect of the aesthetics.

 The upper part of the tibia cover cooperates with the inner face of the first cover during rotation of the knee.

 The tubes 47 of the thigh and the blades 50 of the shins are for example made of titanium or any suitable material and sized to withstand moments greater than 400 Newton meter, for example 1,000 N.m.

 The lower end of the curved blade 50 is articulatedly connected 51 to a boot 52 fit to be threaded.

 The hinge 51 is of the bi-axis type for flexion / extension and abduction / adduction, in a manner known per se.

 The shoe 52 comprises for example a spatula support of the assembly and a foot retention strap of the user forming a stirrup with the spatula.

 Each leg of the exoskeleton further comprises a hinge at the upper end of each thigh, hingedly attached to the connecting member 4, of the type described with reference to FIG.

 This articulation allows in particular a rotation angle β substantially between 20 ° and 80 °, between the thigh and the connecting member 4, the latter also remaining horizontal.

Each leg further comprises an actuating motor of the type of the actuating motors of the knee, for actuating the joints at the hip, respectively placed at the end and fixed on the lateral bars of the U of the organ 7 of the liaison. As indicated above, the actuating motors are powered leg by leg, for example by electric batteries respectively fixed to the rear of the upper end of the corresponding thigh relative to the direction of travel.

 As indicated above, the transverse branch of the connecting member 4 is again globally U-shaped.

 It comprises two parallel bars 39 forming the branches of the U, parallelepipedal shape partially hollow to contain the actuating motors of the hip joints connected from one side to the upper thighs by the corresponding joints, and the other side to the central crossbar formed of a rigid horizontal beam.

 The horizontal beam is arranged to support the tool holder.

 The entire organ forms a user E space.

 The detection sensors are, for example, piezometric sensors connected to the calculation means 12 housed in the member 4 and send information relating to the forces on the tool carrier and / or the exoskeleton.

 The calculation means then generate a command based on the information received from the sensors and simultaneously transmit it almost simultaneously to the actuating means to compensate the load and / or provide the required effort.

To do this, the actuating means generate from this information a pair opposite the weight of the load or force on the ground by the scraping tool for example.

 In another embodiment, the actuating means comprise passive elements, arranged to generate a torque between the pelvis and the support leg or legs, opposite the torque generated by said determined weight of the load.

 A method of using an exoskeleton 1 according to one embodiment of the invention will now be described with reference to FIGS. 4A to 4D.

 The exoskeleton 1 comprises a tool holder 8 and a tool (rake 16).

 The connecting member 4 comprises means 60 for controlling actuating means.

 These control means consist of buttons

(not shown) known in themselves to those skilled in the art and related to the calculation means.

 The buttons are for example positioned in the rear part of the connecting member 4 or on its outer lateral faces.

 The user 61 being behind the exoskeleton 1, he grasps it and actuates the control means.

 These then control the actuating means to lift the connecting member 4.

 The actuation means then instruct the motors of the knee and the abdomen to rotate so as to increase the angles between, on the one hand, the connecting member and the thigh, and on the other hand , the thigh and the connecting organ.

In this way the slippers and the link member remaining horizontal, the distance between them is reduced. Then the user 61, if it has not already done (as shown in the figures) fixed and / or hooks the tool or binding tool holder and / or secures for example by clipping.

 Once raised (Figure 4C), the user 61 can then and without difficulty, place his feet 62 in the stirrups 63 of the slippers, by simply threading and close the belt strap, shoulder straps 64 or the back support for donning 1 exoskeleton 1 from the back of the articulated legs 65.

 Once the exoskeleton 1 has been coated, the user 61 exerts a movement by a normal step and activates the tool holder.

According to the embodiment of the invention more particularly described the exoskeleton 1 comprises means 66 for detecting movement of the user and / or 67 of the support on the feet and in particular angle detection means.

 These detection means comprise, in a manner known per se, and for example one or more gyroscopes for determining the value of the angle at a given instant, coupled to one or three-direction accelerometers to determine the speed and the angular acceleration.

 In the embodiment more particularly described here, the detecting means also comprise a magnetometer thus making it possible to deduce from the measurements of the Earth's magnetic field the direction of the gravitational field.

The corner detectors are adapted to continuously acquire the angles between the thighs and shins of the legs of the user as well as between the thighs and the hip, this detection being performed at a determined frequency.

 The detection means 66 also comprise a pressure sensor, known per se, for acquiring the belly pressure exerted on the transverse bar and / or on the flexible blade.

 So :

 a concomitant reduction on each leg of the angles between the thigh and the shin of the user is analyzed by the calculation means as being a descent command of the crossbar and a reduction of one of the angles abdomen / thigh or thigh / tibia on one of the legs and the detection of a belly pressure greater than a determined threshold is analyzed by the calculation means as being a running command.

 This information transmitted to the calculation means allow the regulation of the engines.

 During its journey, the user can stop and / or advance, and being accompanied by the exoskeleton, he can activate the tool.

 The tool is mounted on the connecting member 4, via the tool holder in the middle of the body.

 More precisely, the arm 67 is here connected to the exoskeleton 1 by a motorized ball joint 68, below the bar 11.

 The arm 67 is itself hinged, passively or not.

More particularly in the embodiment comprising a passive articulated arm, ie without own motorization, the horizontality of the connecting member 4 during operation allows a stable reference and a reduction of the cantilever. The horizontal maintenance of the connecting member 4 allows a fixed reference position for tools or articulated arms 67 attached thereto. This thus makes it possible to remain in a given position at equilibrium (for example empty) due to the stiffness of springs, the presence of counter torque, inertia and / or bonding friction.

 The fixity and horizontality of the member 4 relative to the direction of the gravitational field therefore allow a good balance, with compensation of the mass of the tool, and this for all of its operating conditions .

 As described above, the exoskeleton 1 comprises the control means 60 (calculation, actuation), fixed on the transverse bar 39 of the connecting member 4.

 The means 60 hereinafter also called calculator, determine a control law from, in particular, the position of the different parts of the exoskeleton 1, the actions of the user 61, the cantilever and possible disturbances.

 This control law, when the torque generated by the cantilever accentuated by the arm 67, is greater than a certain threshold and involves a risk of tilting of the exoskeleton 1, then determines the distance e between the leg 65 whose upper end is located to the right of mounting the arm 67 and the other leg 65, the advance of a shoe 63 relative to the other.

The calculation means 60 integrate the distance e, the model of the exoskeleton 1 and the direction of the gravitational field and determine whether the distance e is sufficient to ensure the balance of the exoskeleton 1 calculated as a function of the torque generated by the cantilever.

 That is, the distance e must be sufficient so that the force and / or displacement of the arm 67 do not generate a torque greater than that of the balance that the exoskeleton can withstand for the distance considered.

 If the distance e is sufficient, the calculation means 60 generate an authorization instruction and the tool can be used.

 More specifically, the control means 60 of the arm 67 are not limited for the position of the arm 67 considered.

 If the distance e is insufficient, then the means

60 are locked, i.e. do not transmit the move instruction to arm 67 and / or legs 65.

 We will now describe a method for generating the control law of the various motors of the exoskeleton 1, also with particular reference to FIGS. 4A to 4D.

 The computer 60 includes a non-volatile memory (not shown). This memory includes structural parameter values of the exoskeleton 1.

The parameters taken into account are the dimensional parameters (length, mass, position of the centers of gravity, relative angles, etc.) of the different elements of the exoskeleton and in particular of thigh dimensions (m ₆ , l; m ₉ , 1 ₉ ). shins (m ₈ , ls; m, lu), branches of the connecting member (mi, li; m ₂ , 1 ₂ , m ₃ , 1 ₃ ), joints (m ₄ , m ₅ , ΙΓΙ7, mio), and spatulas (m.1, 1ι ₄ ;

 The computer also includes a virtual repository with its associated coordinate system whose origin A is for example in the middle of the segment connecting the joints at the upper end of each leg tube.

 The calculator also acquires as the parameter the angles between hip and thigh l, βΐ, thigh and tibia 0 (2, β2, tibia and slipper α3, β3, as well as the direction in the virtual repository of the gravitational field.

 He then reconstructs a virtual geometric model of the position of the exoskeleton 1 continuously or almost continuously.

Then from this handset model to information about the masses mi to m _u of the different elements 1 exoskeletal 1, the computer reconstructs the location of the centers of gravity of the connecting member CDG1, of CDG2 thighs, CDG3 , shins CDG4, CDG5.

 The computer thus obtains a continuous or almost continuous dynamic model of the geometry and the forces, moments and forces applied to the exoskeleton 1 (acceleration yi in particular) for example by barycentric calculation for a total mass M referred to the general center of gravity GMPCC.

The computer determines from these data and those of the weight of the loads and / or the tools or arms 67 and the geometry of their cantilever, on the one hand the controls of the motors of recovery efforts and displacement legs and secondly and in particular the threshold torque and thus the distance d of advance of one leg relative to the other.

More specifically, in operation and with reference to FIG. 5, the exoskeleton 1 operates a first acquisition (step 70) of the directional parameters of the gravitational field, i, βι; x _A , y _A , z _A ; CDGi yi etc. and deduces a geometric and dynamic model of the exoskeleton with calculation (step 71) of the total mass M referred to the general center of gravity (CDG _M ).

 The knowledge of the direction of the gravitational field and the angles i, βι makes it possible to calculate the contribution of each element of the exoskeleton 1 to the stability and / or to the overhang.

 More precisely, the knowledge of the position of the exoskeleton 1 with respect to the direction of the gravitational field makes it possible to refine / correct the control law.

 The commands generated by the user determining an acceleration γί in advance of the elements of the exoskeleton 1, noisy or not, calculate the torque exerted by the cantilever and compares it with the limit threshold also calculated, and determines whether an action of the control means is required by the user 61 or necessary to balance the exoskeleton 1 (step 72).

 If this is the case the actuating means 60 are then controlled (step 73) to exert the necessary counter-couples in advance of the leg 65 of the calculated distance d.

Then the computer makes a new acquisition (step 74) of the parameters with deduction then of a new geometric and dynamic model of The exoskeleton with updated re-calculation of the total mass M 'referred to the general center of gravity CDG _M (step 75).

 The control law then integrates the correction elements for equilibrium and instructs the actuating means 60 accordingly (step 76).

 As long as the motion or stability of the exoskeleton is not complete or ensured (test 77), steps 72 to 76 are repeated (line 78).

 In the case where it is desired to use a system for amplifying the force, it is checked whether the position of the exoskeleton is admissible (test 79). If so, it then goes into amplification mode (step 80) when press the button.

 Specifically, the tool system follows the following ordering principle:

 - The articulated arm is in transparent mode or locked in position when the lower limbs are in moving mode, ie to move from one work area to another (cycle from steps 72 to 76).

 If the position of the exoskeleton is in accordance with the safety instructions with regard to the posture of the exoskeleton (test 79), the exoskeleton authorizes the transition to the force-amplification mode during the support (step 80) on the exoskeleton. the button Amplification of effort. For example, both feet support the ground in any person, or the slope of the ground is less than 10 °, or both feet at the same level (and not a foot on one step and the other on the ground).

- The exoskeleton is then in amplification mode, the arm remains in locked or transparent position as long as the operator does not indicate of intention on the force sensor (test 81). During an intention measurement, the direction of effort provided by the articulated arm is identical to that observed on the handgrip. The intensity of the effort is amplified (step 82) by an amplification coefficient greater than 1, for example 5 or 10. The instructions are calculated for example every minute.

 During the amplification mode, the position of the exoskeleton is checked so that it remains in compliance with the safety instructions. This check is done for example every five minutes

 As is obvious and as also follows from the above, the present invention is not limited to the embodiments more particularly described. On the contrary, it embraces all the variants and in particular those where the energies used are hydraulic and / or pneumatic rather than electric.

Claims

1. Exoskeleton (1) of lower limbs comprising two articulated legs (2, 3) arranged to be coupled to the lower limbs of a user, a member (4) connecting the upper ends (5, 6) of the legs to which he is articulated, adapted to be positioned at the level of the user's pelvis and fully located at the front (7) of said legs articulated in the direction of travel and an articulated arm (8) tool holder (9), fixed to the connecting member (4) characterized in that the articulated legs are arranged to be fixed and / or located entirely on the front of the legs of the user,

in that it comprises means for actuating the articulated legs according to the movements of the user, and in that the articulated arm is fixed to said connecting member in a centered or substantially centered manner relative to the body (4 ), in the plane or substantially in the sagittal plane (10) of the user.

 2. Exoskeleton according to claim 1, characterized in that it comprises means (11) for detecting the support of the exoskeleton on the ground, in that the articulated arm (8) comprises means (14) for force amplifiers for handling the tool (9) and in that it comprises means (15) for blocking the operation of the articulated arm as a function of the support on the ground of the members of the exoskeleton and previously established instructions.

Exoskeleton according to one of the preceding claims, characterized in that the connecting member (4) comprises a transverse bar (21) on which is fixed the articulated arm (8) and in that said articulated arm comprises a first articulation (22) in horizontal rotation allowing a scan of a zone of work (23) in front of the exoskeleton.

 4. Exoskeleton according to claim 3, characterized in that the articulated arm (8) comprises a first rod (24) for fixing said first joint below the transverse bar (21).

 5. Exoskeleton according to any one of the preceding claims, characterized in that the articulated arm (8) comprises a series of three pivots (25, 26, 27) connected respectively to each other by second and third rods (28, 29). linkages and arranged to allow flexion / extension of the arm in a vertical plane and its inclination with respect to a horizontal plane.

 6. Exoskeleton according to any one of the preceding claims, characterized in that the articulated arm (8) further comprises a longitudinal pivot (30) of lateral orientation of the tool relative to the rest of the articulated arm.

 7. Exoskeleton according to any one of the preceding claims, characterized in that the arm comprises a first longitudinal handle (31) for handling the tool by a first hand of the user, provided with a force sensor ( 32).

8. Exoskeleton according to any one of the preceding claims, characterized in that the connecting member (4) is equipped with a second handle (33) fixed lower (34) on the arm, for handling thereof. by a second hand of the user, to facilitate a horizontal rotational movement.

 9. Exoskeleton according to any one of the preceding claims, characterized in that the connecting member (4) is equipped with means (35) for illuminating towards the front of the exoskeleton and / or a canopy ( 38) of user protection.

 10. A method of using a tool (9) with an exoskeleton (1) of lower limbs comprising a member (4) connecting two articulated legs adapted to be positioned at the user's pelvis and entirely located at the front of the legs articulated in the direction of travel, said member comprising an articulated arm (8) carrying tool (9), fixed to the connecting member (4) characterized in that the arm is fixed centrally by relative to the member, is an effort amplifier and comprises a first longitudinal handle (31) for handling the tool by a first hand of the user, said handle being provided with a force sensor, it blocks the articulated arm (8),

when it is detected whether the support on the ground of the members of the exoskeleton is in accordance with previously established instructions, it is possible to switch to force amplification mode of the tool carrier,

it is detected whether the user intends to exert a force on the tool by said force sensor, and when the detection is positive, said tool (9) is used, the direction of the force provided by the arm articulated being identical to that observed on the first handle (31).