EP3148920A1

EP3148920A1 - Tool intended for raising a vehicle

Info

Publication number: EP3148920A1
Application number: EP15725630.6A
Authority: EP
Inventors: Vincent CLERC
Original assignee: SoftBank Robotics Europe SAS
Current assignee: Aldebaran SAS
Priority date: 2014-05-30
Filing date: 2015-06-01
Publication date: 2017-04-05
Anticipated expiration: 2035-06-01
Also published as: WO2015181392A1; US20170144875A1; JP2017527504A; CN106715318A; SG11201609421UA; MX2016015686A; RU2648539C1; CA2950644A1; NZ726259A; ES2692413T3; AU2015265832A1; KR20170021803A; JP6393413B2; EP3148920B1; FR3021643A1; KR101889209B1; DK3148920T3; AU2015265832B2

Abstract

The invention relates to a tool (20) intended for raising a vehicle (14) relative to a reference plane (21) on which the vehicle (14) is intended to move. According to the invention, the tool (20) is made up of an integral part having an arm (23) extending essentially according to a main axis (24), intended to be placed between the vehicle (14) and the reference plane (21) and to be operated by an operator substantially in a rotation movement around the main axis (24) of the arm (23). In one section of the arm (23), perpendicular to the main axis (24) and extending along the main axis (24), two overall distances D1 and D2 are defined which are angularly offset relative to one another. The first distance D1 is smaller than the second distance D2, the distance D1 being intended for being smaller than a distance D separating the vehicle (10) from the reference plane (21) and the distance D2 being intended for being greater than the distance D.

Description

Tools for lifting a vehicle

The invention relates to a tool for lifting a vehicle with respect to a reference plane on which the vehicle is intended to move.

Many tools called jacks exist, especially in the automotive field. A jack, supplied with the vehicle, allows in particular to change a wheel, for example in case of puncture. A widely used model of jack conventionally comprises several movable arms in rotation relative to each other. The arms are arranged in the shape of a diamond and a horizontally arranged screw system makes it possible to modify the length of one of the diagonals of the rhombus. The length of the other diagonal moves in the opposite direction and can lift the vehicle from the ground. This type of jack requires a relatively long maneuvering time.

More important tools have been developed for use in the workshop. For example, there are tools comprising a hydraulic or pneumatic cylinder and allowing the vehicle to be lifted directly or by means of an angle gear system. This type of tool is much more bulky and much more expensive than an onboard jack.

In general, the known tools have many moving parts that weigh down the tools, make it complex and expensive and can also be a source of failure.

The invention aims to overcome all or part of the problems mentioned above by providing a much simpler tool for lifting a vehicle. In operation the tool according to the invention is monobloc, that is to say without moving parts.

For this purpose, the subject of the invention is a tool intended to lift a vehicle with respect to a reference plane on which the vehicle is intended to move, characterized in that it is formed of a single piece having a branch extending essentially along a main axis, intended to be placed between the vehicle and the reference plane and to be maneuvered by an operator substantially in a rotational movement about the main axis of the branch, and that in a section of the branch perpendicular to the main axis and extending along the main axis, two distances D1 and D2 are defined angularly offset from one another and in that the first distance D1 is smaller than the second distance D2, the distance D1 being intended to be less than a distance D separating the vehicle from the reference plane and the distance D2 being intended to be greater than the distance D.

In an advantageous embodiment, the tooling comprises a removable handle of the branch and allowing in a mounted position the rotation of the branch about its main axis. The handle and the branch comprise magnetic elements cooperating with each other to hold the handle and the branch in a disassembled position.

The invention will be better understood and other advantages will appear on reading the detailed description of an embodiment given by way of example, a description illustrated by the attached drawing in which:

FIG. 1 represents an example of a robot that can be lifted by a tool according to the invention;

FIGS. 2a and 2b show an exemplary tool according to the invention and arranged with respect to the base of the robot of FIG. 1;

Figure 3 shows in section the tooling of Figures 2a and 2b; FIG. 4 represents a curve showing the pace of the progression of a current distance d of a section of the tooling as a function of an angle of rotation of the tooling;

Figures 5a and 5b show the tool equipped with a handle; Figures 6 and 7 show the tool alone, Figure 6 in the operative position and Figure 7 in the folded position.

For the sake of clarity, the same elements will bear the same references in the different figures.

The tool according to the invention can be implemented for any vehicle moving relative to a reference plane such as the ground. The vehicle can move for example by means of wheel or articulated legs. The vehicle comprises a flat lower surface parallel to the reference plane and tooling allows to lift this surface by drawing on the reference plane.

The invention finds particular utility for lifting a humanoid robot 10 as shown in FIG. The tool according to the invention can of course be used for other types of vehicles.

The robot 10 comprises a head 1, a torso 2, two arms 3, two hands 4 and a skirt 7 to lower the center of gravity of the robot and thus obtain good stability.

The robot 10 comprises several articulations allowing the relative movement of the different members of the robot 10 in order to reproduce the human morphology and its movements. The robot 10 comprises, for example, a hinge 11 between the torso 2 and each of the arms 3. The hinge 11 is motorized around two axes of rotation to enable the arm 3 to be moved relative to the torso 2 in the manner of displacements. possible by a shoulder of a human being.

The skirt 7 comprises a first hinge 12 resembling a knee, between a leg 7a and a thigh 7b. A second articulation 13 resembling a hip is mounted between the torso 2 and the thigh 7b. These two joints 12 and 13 are motorized pivot links about an axis of rotation. The axis of rotation Xa of the hinge 12 and the axis of rotation Xb of the hinge 13 are substantially parallel to an axis connecting the two shoulders of the robot, for tilting the robot forward or towards the back.

The skirt 7 comprises at its base a tripod 14 for moving the robot 10. The tripod 14 comprises three wheels 15, 1 6 and 17 articulated relative to the tripod. An exemplary wheel that can be implemented is described in the patent application published under No. FR 2 989 935 and filed in the name of the applicant. The wheels 15, 16 and 17 are motorized and move the robot 10 in all directions of the reference plane.

Figures 2a and 2b shows in section in a vertical plane the tripod 14 and a tool 20 for lifting it relative to the reference plane 21 horizontal. The tripod 14 has a lower horizontal surface 22 parallel to the reference plane 21. Tooling 20 is intended for take support on the reference plane 21 to lift the surface 22 and therefore the entire robot 10. The tool 20 allows to lift one of the wheels relative to the reference plane 21. The tool 20 is slid under the tripod 14 by an operator between the reference plane 21 and the surface 22 in the vicinity of one of the wheels, for example the wheel 15 as shown in Figures 2a and 2b. Tooling 20 is formed of a single piece having a branch 23 extending substantially along a main axis 24 perpendicular to the plane of Figures 2a and 2b. The tooling 20 is intended to be operated by the operator substantially in a rotational movement about the main axis 24 of the branch 23.

In Figure 2a, the wheels 15, 1 6 and 17 are all in contact with the reference plane 21 and in Figure 2b, the wheel 15 is raised. Between the two figures, the branch 23 has been turned around its main axis 24 by about 90 °.

Figure 3 shows a branch section 23 in a plane perpendicular to its main axis 24. In order to lift the tripod 14, the branch 23 has a particular shape. More specifically, in a section of the branch 23 perpendicular to the main axis 24, two distances D1 and D2 are defined angularly offset from one another. The first distance D1 is less than the second distance D2. The distances D1 and D2 are defined as a function of a distance D separating the reference plane 21 from the surface 22 when the three wheels are placed on the reference plane 21. This distance D represents the ground clearance of the robot 10. The distance D is perpendicular to the reference plane 21. The distance D1 is smaller than the distance D and the distance D2 is greater than the distance D. Thus the operator can introduce the branch 23 under the surface 22 while keeping the distance D1 substantially perpendicular to the reference plane 21. The difference between the two distances D1 and D allows free sliding of the branch 23 under the robot 10. By rotating the branch 23 around its main axis 24, the operator brings the distance D2 perpendicular to the reference plane 21 . The distance D2 is greater than the ground clearance, the robot 10 is raised at the point of contact between the branch 23 and the surface 22. The section of the branch 23 in which one finds the distances D1 and D2 extends along the main axis 24 for a length sufficient to lift the robot 10.

The angular offset between the two overall distances D1 and D2 can be any while remaining less than 180 °. In the example shown, the distances D1 and D2 are substantially perpendicular to each other.

Advantageously, in order to improve the stability of the robot 10 when it is lifted, when the operator lifts the robot 10, during the rotation of the branch 23, it is possible to make the robot 10 pass through a high point then to make it go down slightly beyond this high point to avoid that the robot 10 does not fall back on its wheels itself. For this purpose, in the section of the branch where the distances D1 and D2 are defined, a third overall distance Dmax is defined, angularly offset from the distance D1 more weakly than the distance D2. The distance Dmax is greater than the distance D2.

The angles of offset between the distances are visible in Figure 3. An angle am separates the axes of the distances D1 and Dmax and an angle a2 separates the axes of the distances D1 and D2.

It is still possible to improve the stability of the robot 10 in the raised position. For this purpose, the section of the branch 23 has two plane surfaces 27 and 28 distant from the second distance D2. The flat surface 28 is intended to come into contact with the reference plane 21 and the flat surface 27 is intended to come into contact with the surface 22 of the robot 10.

FIG. 4 represents a curve showing the pace of the progression of a current distance d as a function of the angle of rotation a of the branch 23. For a zero angle, the distance D1 is found to be smaller than the distance D. The distance d is increasing between a zero angle and the angle am. The distance d is decreasing between the angles am and a2. Finally, the distance d is increasing beyond the angle a2. This new growth is due to the presence of the two flat surfaces 27 and 28. The stability of the robot in the raised position is obtained when the distance d reaches a minimum, in this case the distance D2, obtained for the angle a2. The branch 23 may terminate at one of its ends by a shape allowing its driving in rotation about its main axis 24. It may be a square or hexagonal section on which the operator can have a key d 'training. Alternatively, the tooling 20 comprises a handle 30 allowing in an operational position, the rotation of the branch 23 about its main axis 24. Advantageously, the handle 30 extends substantially perpendicular to the branch 23. The handle 30 allows the operator to rotate the branch 23 about its main axis 24.

The tool 20 comprising the branch 23 and the handle 30 is visible in FIGS. 5a and 5b. In FIG. 5a, the branch 23 can slide freely under the surface 22 of the robot 10. The distance D1 is perpendicular to the reference plane 21. The tool 20 is in the position of Figure 2a. In Figure 5b, the tool 20 is in the position of Figure 2b. The distance D2 is perpendicular to the reference plane 21. Between the positions of the tooling 20 of FIGS. 5a and 5b, the operator has turned the branch of the angle a2 while maneuvering the handle 30.

Advantageously, in the position of FIG. 5b, the handle 30 rests on the reference plane 21. Planar surfaces 27 and 28 may be dispensed with. The curve shown in FIG. 4 may decrease beyond the angle α 1 and this decay may continue beyond the angle α 2. The stability position of the tool 20 is then ensured when the handle 30 rests on the reference plane 21. The decrease of the current distance d is interrupted when the handle 30 comes into contact with the reference plane 21.

In use, the tool 20 comes into contact with both the reference plane 21 and the planar surface 22. The branch 23 rotating around its main axis 24, tangential efforts occur at the contacts. These efforts can be translated either by a movement of the robot 10 parallel to the reference plane 21 or by sliding at one of the contacts. The movement of the robot 10 relative to the reference plane 21 is undesirable. It is possible to arrange the tooling 20 to limit the risk of movement and advantageously to choose the contact that can slip. For this purpose, with respect to a plane 32 containing the main axis 24, outer surfaces 33 and 34 of the branch 23 located on either side of the plane 32 have different coefficients of friction. The lowest coefficient of friction is chosen for the surface at which sliding is desired.

The reference plane 21 may have different natures. This is the ground and the operator can decide to lift the robot 10 on different types of soil. By against the surface 22 for the robot 10 and the surface 34 for the branch 23 are better controlled. It can be chosen that the surface having the highest coefficient of friction is intended to come into contact with the robot 10, in this case the surface 34, and the surface having the lowest coefficient of friction is intended to come into contact with the reference plane in this case the surface 33. It may for example cover the surface 34, a rubber pad or a silicone-based material. The surface 33 may be covered with a pad in a material having a good glide such as polytetrafluoroethylene (PTFE).

Advantageously, the handle 30 is removable from the branch 23 to allow easier storage of the tool 20. Figures 6 and 7 show the tool 20 alone. FIG. 6 shows the handle 30 assembled to the branch 23 in an operational relative position, also called the mounted position for lifting the robot 10, and FIG. 7 represents the handle 30 in a folded position still called the disassembled position with respect to the branch 23. In the position of Figure 7, the handle 30 extends parallel to the main axis 24 of the branch 23. The tool 20 advantageously comprises means for holding the handle relative to the tool in the folded position. In order to limit the bulk, these holding means may be formed by one or more permanent magnets 40 and 42 disposed in the handle 30. The branch 23 then comprise an inclusion of one or more magnetic elements 41, and 43 each formed by a ferromagnetic material or by a permanent magnet arranged to achieve mutual attraction of the handle 30 and the branch 23 in the folded position. More generally, the handle 30 and the branch 23 comprise magnetic elements 40 to 43 cooperating with each other to hold the handle 30 and the branch 23 in the folded position.

It can be provided in the robot 10 a sleeve for sliding the folded assembly.

An example of forms for driving the branch 23 by the handle 20 is visible in Figure 7. The branch 23 may comprise a male square 36 and the handle 30 may comprise a female square 37 for cooperating with the square 36 for the rotation drive of the branch 23. The square 36 extends along the main axis 24 and the insertion of the male square 36 into the female square 37 is in translation along the main axis 24. The two squares can each comprise a corresponding cutaway allowing a keying in the relative functional position of the handle 30 relative to the branch 23. The holding in position of the handle 30 in the operative position relative to the branch 23 can be done by means of elements magnetic elements (ferromagnetic element or permanent magnet) arranged in the squares 36 and 37. Advantageously, one of the magnetic elements makes it possible both to hold the handle 30 and the branch 23 in a e folded position and in a functional position. For example the magnetic element 40 disposed in the handle 30 can cooperate with a magnetic element 44 disposed in the square 36 in the operative position. The magnetic element 40 then performs a dual function, cooperating either with the magnetic element 41 in the folded position or with the magnetic element 44 in the operative position.

Claims

1. Tool (20) for lifting a vehicle (10) with respect to a reference plane (21) on which the vehicle (10) is intended to move, the tool being formed of a one-piece piece having a branch (23) ) extending substantially along a main axis (24), intended to be placed between the vehicle (10) and the reference plane (21) and to be maneuvered by an operator substantially in a rotational movement about the axis (24) of the branch (23), in a section of the branch (23) perpendicular to the main axis (23) and extending along the main axis (24), two distances are defined overall D1 and D2 angularly offset from each other the first distance D1 being smaller than the second distance D2, the distance D1 being intended to be less than a distance D separating the vehicle (10) from the reference plane (21) and the distance D2 being intended to be greater than the distance D, the out comprising a handle (30) removable from the branch (23) and allowing, in a mounted position, the rotation of the branch (23) about its main axis (24), characterized in that the handle (30) and the branch (23) comprise magnetic elements (40, 41, 42, 43) cooperating with one another to hold the handle (30) and the branch (23) in a disassembled position.

2. Tooling according to claim 1, characterized in that the two overall distances D1 and D2 are substantially perpendicular to each other.

3. Tooling according to one of the preceding claims, characterized in that in the section of the branch (23) is defined a third overall distance Dmax, angularly offset from the distance D1 more weakly than the distance D2 and that the distance Dmax is greater than the distance D2.

4. Tooling according to one of the preceding claims, characterized in that the section of the branch (23) has two planar surfaces (27, 28) distant from the second distance D2.

5. Tooling according to one of the preceding claims, characterized in that relative to a plane (32) containing the main axis (24), outer surfaces (33, 34) of the branch (23) located on the side and other of the plane (32) have different coefficients of friction.

6. Tooling according to claim 5, characterized in that the surface (34) having the highest coefficient of friction is intended to come into contact with the vehicle (10) and the surface (33) having the lowest coefficient of friction. is intended to come into contact with the reference plane (21).

7. Tooling according to one of the preceding claims, characterized in that the handle (30) in the mounted position extends substantially perpendicular to the branch (23).

8. Tooling according to one of the preceding claims, characterized in that one of the magnetic elements (40) allows both to maintain the handle (30) and the branch (23) in the disassembled position and in the mounted position.