FR2677155A1 - Motor car simulator - Google Patents

Abstract

The simulator of the invention includes a first carriage (3) moving longitudinally, on which a second carriage (7) moves transversely, which, via a device with 3 DEG of freedom (10, 11, 13), supports a platform (12) which itself, by means of a vibrating platform (14), supports a vehicle (2), a projection sphere (25) and projectors (27).

Description

AUTOMOTIVE CAR SIMULATOR
The present invention relates to a motor car simulator.

 Motor car simulators are known which simulate only the visual aspect of driving these cars, and which can only be suitable for elementary driving training.

 To simulate other phenomena and physical quantities, such as vehicle movements, the behavior of its suspension components, in particular with a view to improving road handling and increasing comfort under difficult conditions (winding roads , roads in poor condition ...), as well as to better adapt roads and engineering structures to driving (profile of access roads to bridges or highways, visibility and legibility of road signs on curved and / or sloping roads, ...), it must also be possible to simulate the different movements of the car (roll, pitch, laces, in addition to movements in X, Y and Z).

In order to simulate vehicle movements, suspended platforms are generally used, the movements of which, generally at six degrees of freedom, are controlled by hydraulic cylinders. These platforms support a driver's cab and an image projection system, the screen of which is generally a portion of a sphere. These simulators are well suited to simulating aircraft, but cannot be used for simulating motor cars, since these simulators can only simulate movements in X (longitudinal) and Y (transverse) of small amplitude (l meter). or less) and of relatively low frequency, which is sufficient to simulate the behavior of aircraft, while for application to motor cars, the platform should be able to be animated by movements
X and Y of relatively large amplitude (several meters) in order to produce feelings of positive and negative accelerations with strong gradient, and so that the oscillatory movements of the platform can be of higher frequency.

Recently, we have known simulators intended for motor cars and having a mobile platform. In the first case (Daimler Benz), the platform is mounted on jacks giving it six degrees of freedom. This known platform therefore has the aforementioned drawbacks of platforms for aircraft cabins. In a second case (Swedish VTI), the platform animation device moves it linearly according to a Y (transverse) movement only, and angularly according to two degrees of freedom. Soon, it should be able to produce vertical vibrations. However, to make the movements of a motor vehicle as realistic as possible, large amplitude movements must be printed on the platform.
X, Y and Z independent between them, as well as angular movements in laces, roll and pitch as independent as possible between them, and finally vibratory movements in
X, Y and Z independent of each other, which these last two known simulators do not allow.

 The present invention relates to a motor vehicle simulator whose platform can be animated with all of the aforementioned movements, each of these movements being as independent as possible from the others, simulator whose movement deflections are of reasonable values (3 to 5 m maximum for the largest of them) while ensuring virtually all the movements that a moving motor vehicle can undergo in reality, and this, as realistically as possible, the control of these movements being as simple as possible, the simulator being as inexpensive as possible.

 The simulator according to the invention comprises a platform supporting, by means of a device vibrating at least one degree of freedom with movements of low amplitude and high frequency, a driving position comprising a vehicle, the platform being supported by an animation device essentially comprising two parts: a lower part producing rectilinear movements in X and Y, and an upper part producing angular movements with at least two degrees of freedom, all the movements being independent of each other, this simulator comprising a projection device and a projection screen. Preferably, the projection screen is integral with the platform.

 The present invention will be better understood on reading the detailed description of an embodiment, taken by way of nonlimiting example and illustrated by the appended drawing, in which: - Figure 1 is a perspective view, with parts broken away , of a simulator according to the invention, and - Figures 2 and 3 are respectively a side view and a top view of a vibrating platform that can be used in the simulator of Figure 1.

The invention is described below with reference to a particular motor vehicle, but it is understood that it can be applied to other types of road vehicles: trucks, coaches,
The simulator of the invention comprises a set of slides or rails 1 fixed on the ground or on a stable support and ensuring the longitudinal movement (in X) of the test vehicle 2, that is to say that these rails I are arranged parallel to the longitudinal axis of the vehicle 2. In the example shown in the drawing, these rails 1 are three in number, but it is understood that their number may be different. Preferably, the vehicle 2 is a real vehicle.

 On the rails 1, a mobile carriage 3 is mounted. The longitudinal stroke (in Y) of the carriage 3 on the rails I is limited by stops 4. This stroke is for example between 3 and 5 m approximately. The carriage 3 is formed of a rectangular chassis actuated by jacks 5, for example hydraulic, which move it on the rails 1 and on which are fixed two transverse rails 6, that is to say perpendicular to the rails 1. Good of course, the carriage 3 is as light as possible (to reduce the total mass in motion), while being sufficiently solid and rigid to support the elements described below without deforming or vibrating.

 On the thresholds 6, a second mobile carriage 7 is mounted, which for example has a substantially triangular shape. The movements of the carriage 7 on the rails 6 are controlled by jacks 8, and its stroke is limited by stops 9. This stroke is for example around 3 m.

 On the carriage 7 is rigidly fixed a tripod 10 supporting, by means of a ball joint 11 a platform 12. The platform 12 is driven by angular movements in roll, laces and pitch, practically independent of each other, under the control at least three hydraulic cylinders referenced 13 as a whole.

 The platform 12 supports a vibrating device 14. Preferably, as shown in FIGS. 2 and 3, the device 14 is of the type with six degrees of freedom (movements, independent of each other, linear in X, Y, Z and angular in roll , pitch and laces). The device 14 produces movements of small amplitude (for example 10 to 20 centimeters for linear movements and a few degrees for angular movements) and of relatively high frequency (up to approximately 120 Hz).

 The device 14 comprises a platform 15 consisting of two longitudinal members and two crosspieces, forming a rectangle, and all hinged together (ball joints 15A). This platform 15 is slightly deformable (to simulate the deformations of the chassis of the real vehicle). It supports the vehicle 2 by adjustable blocks 15B placed under the side members of the car, substantially at the places provided for the jack for lifting the vehicle 2. The platform 15 rests on four vertical jacks 16. The bodies of the jacks 16 are connected by ball joint to the platform 12, and their rods are connected by ball joints to the platform 15, as close as possible to the point of attachment of the corresponding shock absorber of the vehicle 2. The stroke of approximately 20 cm of the rods of the jacks 16 makes it possible to reproduce in real size the vehicle suspension travel 2.

A horizontal cylinder 17 is rigidly fixed to the platform 12, and its rod is parallel to the longitudinal axis of the vehicle 2 and is connected by ball joint in the middle of a short side of the platform 15. Two other cylinders 18 are rigidly fixed to the platform 12. Their rods are horizontal and perpendicular to the longitudinal axis of the vehicle 2. These rods of the jacks 18 are connected by double ball joint to one of the long sides of the platform 15.

The attachment points of these double ball joints on the platform 15 are located between the corresponding wheels on the same side of the car, symmetrically with respect to the middle of the distance between these wheels. The described arrangement of the seven jacks 16 to 18 makes it possible to subject the vehicle 2 to rectilinear movements in X, Y and Z and to rotations along the three axes (roll, laces, pitch), independently of each other.

 The angular movements (roll, pitch, laces) of the platform 12 around the ball joint II (which is substantially vertical to the center of gravity of the platform 12) are controlled, independently of each other by jacks 13A to 13D. For this purpose, the four jacks 13A to 13D are provided at each of their ends with ball joints. On the side of the platform 7, the ball joints of the jacks 13A and 13B are fixed at points 19 and 20 which are symmetrical with respect to a vertical plane passing through the ball joint 11, and which are near the vertices of the triangle formed by this platform, vertices which are both above the same rail 6 (which is itself closest to the rear of the vehicle 2). The ball joints of the other two cylinders 13C, 13D are fixed, platform side 7, near a point 21 which is substantially vertical to the ball joint 11.

 On the side of the platform 12, the ball joints of the jacks 13A, 13B are fixed near a point 22 which is under the longitudinal axis of the vehicle 2, at the rear (relative to the vehicle) of the platform 12. The ball joints of the two other jacks 13C, 13D are fixed at points 23, 24 which are symmetrical with respect to the center of gravity (which must substantially coincide with a vertical passing through the ball joint 11) of the platform 12. For reasons of symmetry, we uses the two cylinders 13C, 13D, but from the kinematic point of view, one of them may suffice.

 On the platform 12, a projection screen 25 is fixed, which has the shape of a part of a sphere, the "roof" 26 of which is roughly flat. To the "ceiling" of this roof, a panoramic projection system 27 is fixed, for example of the type with several projectors.

 The animation device with three degrees of freedom, located between platforms 7 and 12, operates as follows. To ensure pure roll movements, the jacks 13A and 13B are locked in the desired angular pitch position (which can be either a horizontal position or a tilted position forwards or backwards (relative to the vehicle 2 The cylinders 13C and 13D are controlled in opposition so as to rotate the platform 12 around a fictitious axis passing through the center of the ball joint 11 and through a point close to point 22 and being located substantially halfway between the centers of upper ball joints of cylinders 13A, 13B.

 To control pure pitching movements, the cylinders 13C, 13D are blocked, and the same control is simultaneously applied to the cylinders 13A, 13B. The platform 12 then pivots around a fictitious axis passing through the center of the ball joint 11 and the centers of the upper ball joints of the jacks 13C, 13D.

 The movements of pure laces require a different command for each of the cylinders 13A to 13D: in one direction (clockwise, seen from above), the rod of the cylinder 13B must be taken out and the rod of 13A returned, and in the other direction, enter that of 13B and take out that of 13A. The rods of the cylinders 13C and 13D practically do not move. The rotation takes place around an axis passing through the center of the ball joint 11. If the platform 12 is horizontal at the start, it must remain so during this rotation, the axis of rotation in question then being vertical.

Claims (5)

 1. Simulator for a motor car, characterized in that it comprises a platform (12) supporting, by means of a vibrating device with at least one degree of freedom (15 to 18) with movements of low amplitude and high frequency a driving position comprising a vehicle (2), the platform being supported by an animation device essentially comprising two parts: a lower part producing rectilinear movements in X and Y (1 to 9), and an upper part ( 10, 11, 13) producing angular movements with at least two degrees of freedom, all the movements being independent of each other, this simulator comprising a projection device (27) and a projection screen (25).  2. Simulator according to claim 1, characterized in that the projection device (27) and the projection screen (25) are integral with the platform.  3. Simulator according to one of claims 1 or 2, characterized in that the vibrating device has six degrees of freedom practically independent of each other: linear in X, Y, Z and angular in roll, pitch and yaw.  4. Simulator according to one of the preceding claims, characterized in that the rectilinear movements in X of the lower part of the animation device are produced by a lower carriage (3) moving on rails (1) under the action of jacks (5), this carriage supporting transverse rails (6) on which Y moves a second carriage (7) under the action of jacks (8).  5. Simulator according to one of the preceding claims, characterized in that the upper part of the platform animation device (12) comprises a tripod (10) fixed on the second carriage and supporting by a ball joint (11) the platform, and at least three jacks (13) fixed by ball joints to the second carriage and to the platform.