FR2921628A1 - Terrestrial vehicle for e.g. three-wheel motor scooter, has axles with connection unit that inclines wheels while moving wheels along opposed horizontal directions, by inclination of frame around axis - Google Patents

Abstract

The vehicle has a frame (2) connected to right and left rear wheels (8, 9) and right and left front wheels (12, 13) via deformable parallelogram type rear and front variable geometry axles (7, 11), where the wheels are transversely spaced on both sides of an longitudinal axis (AL). The axles have a connection unit that inclines the wheels while moving the wheels along the opposed horizontal directions, by the inclination of the frame around the axis.

Description

BACKGROUND OF THE INVENTION The invention relates to a machine adapted to move on a floor, comprising at least two laterally opposed ground contact members, and carrying a reclining frame about a longitudinal axis substantially corresponding to the direction of movement of this craft. BACKGROUND OF THE INVENTION Such a machine corresponds for example to the three-wheeled scooter disclosed in the patent application EP1561612 in the name of Piaggio, which comprises a rear wheel and a front axle carrying two steered wheels. OBJECT OF THE INVENTION The invention proposes an alternative engine architecture comprising two lateral contact members on the ground such as wheels, notably offering improved road handling. SUMMARY OF THE INVENTION To this end, the subject of the invention is a terrestrial machine, comprising a chassis with a longitudinal axis and members of contact with the ground, at least one axle through which the chassis is connected to two contact members. with the ground transversely spaced apart on either side of the longitudinal axis, characterized in that said axle constitutes connecting means by which an inclination of the frame about its longitudinal axis correspondingly tilts the contact members on the ground. while moving them in opposite horizontal directions. With this solution, the positions of the contact members on the ground relative to the vehicle frame vary according to the inclination of the chassis, so that their positions adapt according to the curvature of the vehicle trajectory for improve road holding. The invention also relates to a machine as defined above, wherein the connecting means are shaped so that an inclination of the frame causes a horizontal translation towards the front of the ground contact member to which the chassis tilts. The invention also relates to a machine as defined above, wherein the axle comprises at least two transversely movable cross members and two lateral supports each intended to be secured to a contact member on the ground, each lateral support being hinged to one end of a crossmember, each crossmember having its central part hinged to the chassis, the crossmembers forming with the lateral supports a variable geometry variable geometry axle of the deformable parallelogram type, and in which the axle is arranged to deform parallel to a transverse plane having an orientation corresponding to that of a rising slope with respect to the direction of advancement of the machine. The invention also relates to a machine as defined above, comprising an axle including a central support on which are articulated sleepers, and wherein the central support is rigidly secured to the frame. The invention also relates to a machine as defined above, comprising a rear axle having its central support rigidly secured to a fixed part of the frame. The invention also relates to a machine as defined above, comprising a front axle having its central support rigidly secured to a directional mobile part of the chassis. The invention also relates to a machine as defined above, comprising an axle provided with a locking member which can be in a locked state prohibiting any deformation of the axle with variable geometry that team. The invention also relates to a machine as defined above, comprising an in-terposed suspension system between each lateral support and each lateral body contact with the ground. BRIEF DESCRIPTION OF THE FIGURES - FIG. 1 is a perspective view of the structure of a machine according to the invention; - Figure 2 is a perspective view of the rear axle of the machine according to the invention shown alone; - Figure 3 is a perspective view of the front axle of the machine according to the invention shown alone; - Figure 4 is a rear view of the structure of the machine according to the invention when its frame is inclined; - Figure 5 is a top view of the structure of the machine according to the invention when its frame is inclined; - Figure 6 is a top view of the structure of the machine according to the invention when its direction is oriented obliquely while its rear axle is blocked. DETAILED DESCRIPTION OF THE INVENTION The vehicle according to the invention, the structure of which is represented in FIG. 1 being marked by 1, comprises a chassis 2 including a so-called fixed or rear part marked by 3, and a movable or front part by 4, corresponding to a steering column rigidly secured to a handlebar 6. A rear axle marked by 7, bearing a right rear wheel 8 and a left rear wheel 9 is probed at the fixed rear portion 3 of the frame. A front 4 axle 11 carrying a right front wheel 12 and a left front wheel 13 is in turn maintained at the chassis by the movable front portion 4 of this frame. The rear frame 7 which is visible in more detail in FIG. 2 is of the articulated type. It comprises two lateral supports 14 and 15 intended to be secured to unrepresented wheels, as well as four crosspieces bearing the references 16 to 19, and a central support 21.

The two lateral supports 14 and 15 are connected to each other by the four crosspieces 16-19 which are here bars extending parallel to each other by occupying positions corresponding to four edges of a parallelepiped.

Each end of the crossbar is hinged to a lateral support via a link of fixed pivot type, and each cross member is articulated on the central support 21 by another pivot connection. The pivot links are marked 16g-19g for the left lateral support 14, 16d-19d for the right lateral support 15, and 16c-19c for the central support 21. The four links pivot of the central support are situated at the vertices of a square situated in a longitudinal vertical plane. The same goes for the pi-vot links of each lateral support. As visible in the figures, these twelve pivot links are oriented along parallel axes. In the example of the figures, these axes are oriented in such a way that, when viewed from the left, when the chassis of the vehicle is not inclined, ie when it is situated in a vertical plane, it is extend parallel to a vertical longitudinal plane of the vehicle by being inclined at +45 degrees with respect to the longitudinal axis AL of the vehi- cle.

The rear axle 7 is thus deformable parallel to an inclined plane which is normal to the axes of these pivot links, that is to say with respect to a transverse plane inclined at +45 degrees with respect to a vertical plane s'. extending transversely to the machine. This plane can still be defined as passing through the centers of two pivot links of the same cross beam of the axle while being inclined +45 degrees with respect to the vertical when seen from the left of the vehicle. The front axle 11 which is shown alone in FIG. 3 is also articulated, it has a general structure quite similar to that of the rear axle 7. It comprises two lateral supports 22 and 23 connected one to the other. four crossbars marked 24-27 and a central support 28. The four cross members are hinged on the lateral supports and on the central support by pivot connections marked 24d-27d and 24g-27g with regard to the right supports and left, and 24c-27c with respect to the central support 28. Just as in the case of the rear axle, the axes of these twelve pivot links are parallel to each other. The front axle is secured to the steering column of the chassis 2, that is to say to its moving part before 4, by its central support 28, instead of being secured to a fixed part of the chassis as it is the case for the rear axle. This central support 28 is thus able to rotate about an axis indicated by AR in FIG. 1. This axis AR, which coincides with the steering column 4, is inclined with respect to the vertical angle of said hunting angle. This hunting angle which is non-zero is the angle formed by the axis AR and a vertical axis intercepting the axis AR when the frame is straight, that is to say when it is inscribed in a longitudinal vertical plane. In the example illustrated in the figures, the steering column 4 is inclined towards the rear. In other words, in lateral view, the upper end of the column 4 is shifted toward the rear of the vehicle relative to the lower end of this column 4. The hunting angle has a value of the order from ten to fifteen degrees.

The assembly formed by the handlebar 6 and the steering column 4 constitutes the directional member of the frame 2. This assembly forms with the central support 28 a rigid whole capable of pivoting about the oblique axis AR to orient the vehicle.

In the structure shown in the figures, the central support 28 is secured to the steering column 4, so that the angle between the axis of orientation of each pivot connection, the axis AR is +45 when the vehicle is seen from the left.

Thus, the axes of the pivot links of the front axle 11 extend parallel to a vertical longitudinal plane of the vehicle by being inclined with respect to the longitudinal axis AL of a value corresponding to +45 degrees less the angle of hunting, this being valid when the frame is vertical while the handlebar 6 is right for the vehicle to follow a straight path. The front axle 11 is thus deformable parallel to a plane normal to the axes of its pivot connections, that is to say with respect to a transverse plane inclined with a value corresponding to +45 degrees less the hunting angle relative to a vertical plane extending transversely to the front axle, when the assembly is seen from the left. 7 This inclined plane can also be defined as passing through two pivot links of the same crossbar of the front axle while being inclined by a value corresponding to the hunting angle increased by +45 degrees relative to the horizontal , ie on the ground. In order to facilitate handling of the machine, particularly at low speed, at least one of the articulated axles is equipped with a locking member that can be in a locked state to make the axle dimensionally stable.

The locking member of the rear axle 7 which is marked 29 in FIG. 3 comprises a deformable parallelogram including first and second so-called short links 31 and 32, opposite and parallel to each other, as well as a so-called long link 33.

The two short links are located on either side of the central support 28, each having one end connected to the crossmember 16 by a pivot connection of the same orientation as the other pivot links constituting the axle, these two pivot links being equidistant. The long link 33 has its two ends respectively connected to the other ends of the short links, by pivot links of the same orientation as the other pivot links. It is linked by its center to the upper amount of the support 28, by a fifth pivot connection, of the same orientation. Thus, the assembly formed by the crosspiece 16, the rod 33 and the rods 31 and 32 constitutes a deformable parallelogram, located in the plane of the crosspieces 16 and 19, which deforms in the same manner as the whole of the axle 7 when it is requested. The long link 33 carries a half braking disc, and the support 28 carries at its upper post a brake caliper, not visible in the figures, adapted to grip this half disc to make the assembly uncomfortable. 16, 31, 32 and 33, and thereby the axle 7. The front axle also comprises a locking member, identified by 36, similar to the locking member 29 of the rear axle, but which is mounted at the lower front cross member 25 of the axle instead of being mounted at the front upper cross member 16, as in the case of the rear axle. Thus, when the locking member of the front axle or the rear axle is controlled to go into a locked state, the half-brake disc that it comprises is gripped by the stirrup that it has, this which makes the corresponding axle geometrically indeformable. These locking members are advantageously locked when the vehicle is traveling at low speed, to lock the chassis 2 in a vertical position, so as to avoid a significant angle of the chassis of the machine, at low speed.

This vehicle is a quadricycle similar to a four-wheeled motorcycle, whose chassis is able to bow in turns. It can thus be provided with a motor driving transmission members to the wheels that can be integrated in the space delimited by the crosspieces of the rear axle, and / or the front axle. Each wheel is secured to a lateral support, for example by means of a suspension system not shown in the figures.

As the front axle and the rear axle are deformable parallelograms in oblique planes, they allow a lateral inclination of the chassis 2, ie a rotation of this chassis around the axis AL, which substantially coincides with the tangent to the trajectory of the vehicle at a given moment. This inclination of the chassis, of the roll type which is represented in FIG. 4, causes the wheels to tilt relative to the vertical, which thus remain parallel to the plane of the chassis, while being both kept in contact with the ground. The front wheels are inclined relative to the vertical, while having a direction conditioned by the orientation given to the handlebar 6 of the machine.

Given the inclination of the deformation plane of the parallelogram of the front axle and the rear axle, the inclination of the frame 2 also causes a translation of the wheels of each axle, which appears clearly in the top view of Figure 5.

More particularly, at the rear axle, the wheel on the side towards which the chassis tilts translate towards the front of the vehicle, while the wheel on the opposite side is translated towards the rear of the vehicle. gear.

These substantially longitudinal translations of the wheels are caused by the fact that each axle is a deformable parallelogram which is mounted on the frame so as to deform parallel to an oblique plane relative to the ground.

The front wheels are translated in a similar way to the rear wheels, when the chassis tilts, the wheel to which the frame is inclined then translating forward, and the opposite wheel then translating to the rear, as visible in Figure 5.

Specifically, when the vehicle takes a turn, the chassis tilts towards the inside of the turn, just like that of a motorcycle, and given the variable geometry of the axles, this inclination translates the inner wheels to the turn towards the before, and the outer wheels at the bend towards the rear of the machine. This translation of the wheels increases the distance separating the most forward wheel from the center of gravity of the machine, as well as the distance separating the wheel furthest from the center of gravity of the machine.

The increase of these magnitudes improves the curve of the road as it increases the amplitude of the torque applied by the ground to the vehicle, which facilitates the holding of the vehicle in the curved paths. The axle lock also makes it easier to handle the machine at low speeds and at a standstill, giving it great maneuverability. Indeed, when one or the other of the axles is locked, the handlebar can be strongly rotate to benefit from a very small turning radius, without risk of falling since the chassis is then kept straight. The user of the machine can then for example sneak easily between cars in use in the city, enjoying a very small turning radius, without risking a large corner angle as would be the case with a motorcycle. This situation is represented in FIG. 6: the rear locking device is locked, so that the chassis occupies an upright position, that is vertical regardless of the orientation given to its handlebar 6. When the vehicle is immobilized , one or the other or both locking members can be locked when the corresponding parallelogram is in the upright position, not deformed, to park the vehicle without having to use a stand, as in the case of a motorcycle.

The invention finds applications to multiple types of gear. In particular, it is adapted to equip the front axle of a snowmobile, the ground link members then being skids or skis held by an axle of the same general architecture as the front axle indicated by 11 in the figures, this axle is also connected to a steering column of the snowmobile. It is also suitable for a three-wheeled scooter, the front axle of such a scooter then being equipped with an inclined deformable parallelogram type axle such as the axle 11.

Claims (8)

1. Machine (1) terrestrial, comprising a frame (2) with a longitudinal axis (AL) and ground engaging members (8, 9, 12, 13), at least one axle through which the frame is connected to two ground contact members (8, 9, 12, 13) transversely spaced apart on either side of the longitudinal axis (AL), characterized in that said axle (7, 11) constitutes connecting means by which inclination of the frame (2) about its longitudinal axis (AL) correspondingly tilts the ground contact members (8, 9, 11, 12) while translating them in opposite horizontal directions. 2. Machine (1) according to claim 1, wherein the connecting means (7, 11) are shaped so that an inclination of the frame (2) causes a horizontal translation towards the front of the contact member on the ground (8, 9, 11, 12) to which the frame (2) inclines. 3. Machine according to claim 2, provided with an axle (7; 11) comprising at least two transversely movable crosspieces (16-19; 24-27) and two lateral supports (14, 15; 22, 23) each intended for to be secured to a contact member on the ground, each lateral support (14, 15; 22, 23) being articulated on one end of a cross member (16-19; 24-27), each cross-member (16-19; 27) having its central part articulated with respect to the frame (2), the crosspieces (16-19; 24-27) forming with the lateral supports (14, 15; 22, 23) a variable geometry-type axle of deformable parallelogram type, and in which the axle is arranged to deform parallel to a transverse plane having an orientation corresponding to that of a rising slope with respect to the direction of advancement of the machine. 4. Machine according to claim 3, comprising an axle (7; 11) including a central support (21; 28) on which are articulated the sleepers (16-19; 24-27), and wherein the central support (21; 28) is rigidly secured to the frame (2). 5. Machine according to claim 4, comprising a rear axle (7) having its central support (21) rigidly secured to a fixed part (3) of the frame (2). 6. Machine according to claim 4 or 5, comprising a front axle (11) having its central support (28) rigidly secured to a directional mobile part (4) of the frame (2). 7. Machine according to one of claims 3 to 6, comprising an axle (7; 11) provided with a locking member (29; 36) can be in a locked state prohibiting any deformation of the axle geometry va- riable (7; 11) that he equips. 8. Machine according to one of the preceding claims, comprising a suspension system interposed between each lateral support (14, 15; 22, 23) and each lateral member of contact with the ground (8, 9; 12, 13).