HORSE-RIDER PROTECTION SYSTEM COMPRISING AN AIRBAG WAISTCOAT CONNECTED TO A SENSOR THAT SENSES FALLING OF THE HORSE

Abstract

A system for protecting a rider on his/her horse, including an airbag vest intended to be worn by the rider and including at least one inflatable sheath, a gas generator, a gas cartridge and an electronic unit connected to the gas generator and allowing triggering the inflation of the sheath, the system further includes a motion sensor intended to be installed on the horse, for example on the saddle, and configured to detect a fall of the horse, the motion sensor being connected to the electronic unit so as to trigger the inflation of the sheath in case of detection of a fall of the horse, so as to mitigate a potential crushing of the rider by the horse.

Claims

1. A system for protecting a rider on a horse likely to of falling on him/her, comprising an airbag vest to be worn by the rider, said vest having at least one inflatable sheath, a gas generator, a gas cartridge and an electronic unit connected to the gas generator and allowing triggering the inflation of the sheath, characterised in that it comprises a motion sensor intended to be installed on the horse and configured to detect a fall thereof by detecting an overpass of a limit angle which corresponds to an abnormal orientation of the horse, and in that said motion sensor is connected to the electronic unit so as to trigger the inflation of the sheath in case of detection of a fall of the horse.

2. The protection system according to claim 1, wherein the motion sensor is configured to detect a fall of the horse by measuring an angular position of said horse according to at least one axis.

3. The protection system according to claim 2, wherein the motion sensor is configured to detect a fall of the horse when the value of an angle of lateral or longitudinal inclination is larger than a predetermined limit value.

4. The protection system according to claim 1, wherein the motion sensor comprises a gyrometer and an accelerometer.

5. The protection system according to claim 1, wherein the motion sensor-is connected to the electronic unit-via a radio-frequency wireless link.

6. The protection system according to claim 1, wherein the airbag vest further comprises a cable intended to be detachably connected to the horse, said cable triggering the inflation of the sheath as it detaches from the vest.

7. The protection system according to claim 1, further comprising automatic activation means configured to activate the motion sensor ) only when the latter is installed on the horse.

8. The protection system according to claim 1, characterised in that it further comprises a motion sensor installed on the airbag vest while being connected to the electronic unit and configured to detect a fall of the rider.

9. The protection system according to claim 8, wherein the airbag vest does not comprise a cable intended to be connected to the horse-and to trigger the inflation of the sheath.

10. The protection system according to claim 1, further comprising a saddle on which the motion sensor-is installed.

11. The protection system according to claim 10, wherein the motion sensor is fastened at the rear of the saddle, in particular at the level of the cantle of said saddle.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0037] The figures are given for merely illustrative purposes for a better understanding of the disclosure without limiting its scope. The different elements are schematically illustrated and are not necessarily plotted to the same scale. In all figures, identical or equivalent elements bear the same reference numeral.

[0038] Thus, is illustrated in:

[0039] FIG. 1: a protective system for a rider according to the disclosure;

[0040] FIG. 2: an airbag vest according to the disclosure;

[0041] FIG. 3: the protection system wherein the airbag vest is triggered by detachment of the cable;

[0042] FIG. 4: the protection system wherein the airbag vest is triggered by detection of a fall of the horse.

DETAILED DESCRIPTION

[0043] It should be noted that some technical elements well-known to a person skilled in the art are reminded herein to avoid any insufficiency or ambiguity in understanding of the present description.

[0044] In the aspect described hereinafter, reference is made to a protection system comprising an airbag vest connected to a fall sensor, intended primarily for equestrian sports to protect riders in the event of a fall. This non-limiting example is given for a better understanding of the disclosure and does not exclude the use of the protection system by any other sportsman or occasional user using any movable vehicle (horse, motorbike, snowmobile, etc.) insofar as the movable vehicle might fall on the user in the event of an accident.

[0045] In the present description, the expression airbag vest refers to a garment cut into a vest, for protecting a user, in particular a rider, comprising one or more inflatable sheath(s) that could be activated by pyrotechnic triggering, for example; an object is said connected when it is equipped with means able to communicate, in a standalone manner, with other objects connected by a wired link and/or over a wireless network.

[0046] FIG. 1 shows a protection system 100 equipping a rider 200 and his/her horse 300, and comprising an airbag vest 20 intended to be worn by the rider and a motion sensor 30 fastened on a saddle 40 and connected via a wireless link to the airbag vest 20 to control triggering thereof.

[0047] Indeed, the airbag 20 is equipped with an inner inflatable sheath which inflates when the motion sensor 30 detects an unavoidable fall of the horse 300 corresponding to an extreme angular position that the horse cannot recover, to restore balance thereof, because of its anatomy and more particularly of its locomotor apparel.

[0048] Thus, when the rider 200 remains hooked to the horse 300 which is falling on its back, for example, the airbag vest 20 is triggered to make up a protection which will dampen the impact and will limit the effects on the rider.

[0049] Of course, when in his/her fall, the rider 200 is ejected off the horse 300, the airbag vest 20 is triggered, in a conventional manner, thanks to a cable 24 connecting said vest to the saddle 40.

[0050] This situation is shown in FIG. 3 wherein a distance D is indicated and corresponds to an activation, or triggering distance of the gas generator and therefore of the airbag. As long as the distance between the fastening points of the cable 24 on the airbag 20 and on the saddle 40 remains shorter than the activation distance D, the cable is not detached from the vest and the airbag is not triggered. The activation distance D should be sufficient so as not to constrain the normal movements of the rider 200 on his/her horse 300 during the practice of his/her discipline.

[0051] FIG. 2 shows, according to one aspect, the airbag vest 20 which may be worn alone or with a jacket above such as a riding competition jacket. The airbag 20 may also be removably or permanently integrated into a jacket.

[0052] The airbag vest 20 mainly comprises an inflatable sheath, not visible in the figure but which is located in a suitable pocket sewn in the vest, a pyrotechnically-triggered gas generator 21, a gas cartridge 22 connected to the gas generator, an electronic board 23 and the cable 24 connecting said board to the saddle 40.

[0053] Thus, when a rider 200 wearing the airbag vest 20, with the cable 24 attached, is ejected far enough from the saddle 40 so that the cable 24 is detached, this detachment triggers the inflation of the sheath integrated into the vest via the gas generator 21 which strikes the gas cartridge 22 to release the gas and inflate said sheath.

[0054] Of course, the inflation of the sheath may be chemically triggered, for example by means of a propellant like in automotive airbags.

[0055] Complementarily, when the horse 300 falls and the rider remains on the saddle 40, thereby preventing the cable 24 from detaching from the vest 20, the motion sensor 30 triggers the inflation of the sheath by detecting an overpass of a limit angle which corresponds to an abnormal orientation of the horse and the start of an unavoidable fall.

[0056] FIG. 4 illustrates such a fall.

[0057] Indeed, the motion sensor 30 allows measuring the movement of the saddle 40 on which it is fastened, according to several axes, so as to enable detection of abnormal angular positions of the horse before fall thereof.

[0058] The motion sensor 30 may be a miniature inertial measurement unit IMU (Inertial Measurement Unit in English). Such a unit generally consists of a combination of sensors, so-called proprioceptive sensors, directly measuring the movements of the movable vehicle on which said unit is fastened, herein the saddle 40 and therefore the horse 300 while assuming that the relative movement of the saddle with respect to the horse remains negligible. Such sensors are accelerometers and gyrometers. For miniaturisation reasons, these sensors are for example designed according to the microelectromechanical systems (MEMS) technology.

[0059] Preferably, the motion sensor 30 includes a gyrometer, an accelerometer and, optionally, a magnetometer.

[0060] The motion sensor 30 may be provided with an integrated computer in the form of a microcontroller, performing successive integrations of the measured angular accelerations to obtain the components of the angular velocity vector as well as the angular position. Thus, the analysis of the angular position according to two measurement axes allows deducing the orientation of the saddle 40 and therefore that of the horse 300 on which said saddle is installed, and to detect angle overpasses thanks to suitably calibrated specific algorithms.

[0061] In addition, to reduce its energy consumption, the motion sensor 30 remains on standby as long as the cable 24 has not been locked between the vest 20 and the saddle 40.

[0062] For example, the motion sensor 30 is a so-called 6-axis accelerometer and gyrometer module, with a wide programmable operating range.

[0063] The motion sensor 30 is connected to the electronic board 23 which is provided with a wireless communication module, for example a radio-frequency wireless communication module, coupled to an emitter/receiver antenna.

[0064] Preferably, the wireless communication module emits on an ISM (Industrial, Scientific and Medical) frequency band, in particular on the LoRa or Sigfox networks which are particularly suitable to short ranges and to low-consumption connected objects.

[0065] Thus, the antenna may be of the printed circuit type (PCB) and directly integrated into the electronic board 23.

[0066] The electronic board 23 and the motion sensor 30 comprise suitable electric power supply devices, which could comprise an energy recovery system (solar, mechanical, etc.) and/or a battery such as a lithium-ion battery.

[0067] The motion sensor 30 is configured to detect a fall and signal it to the electronic unit 23 if an angle of longitudinal or lateral inclination of the horse exceeds a predetermined limit value.

[0068] For example, the limit value of the angle of longitudinal inclination, which corresponds to the inclination of the horse with respect to the vertical, is at least equal to 90 in absolute value.

[0069] For example, the limit value of the angle of lateral inclination, which corresponds to the inclination of the horse with respect to a horizontal plane, is at least equal to 70 in absolute value.

[0070] According to an alternative aspect which is not shown, the protection system does not comprise a triggering cable connecting the airbag vest to the saddle, and comprises an additional motion sensor installed directly on the airbag vest and connected to the electronic board of the latter to detect the fall of the rider. Thus, the additional motion sensor allows analysing the kinematics of the rider and detecting the fall of the latter, either by comparing an instantaneous acceleration of the rider with an instantaneous acceleration of the horse (measured by the motion sensor fastened to the saddle), according to the same axis and at the same time point, or based on a machine learning model calibrated on data obtained by other riders during their falls.

[0071] In other words, to detect a fall in the rider, the additional motion sensor may function alone or in combination with the motion sensor of the horse. In the latter case, the motion sensor of the horse serves as a reference frame. Indeed, during a fall by ejection, the difference in acceleration, in algebraic value, between the rider and the horse is necessarily significant.

[0072] For example, the motion sensor of the rider may be integrated into the airbag vest in an electronic case comprising the electronic board.

[0073] It arises from the present description that some elements of the protection system may be replaced by equivalent elements yet without departing from the scope of the disclosure. For example, the protection system may comprise several motion sensors installed at different locations of the saddle, or directly on the horse in which case they would be made in the form of patches. Also, the protection system may comprise height sensors fastened on the front hoofs of the horse to detect a limit height necessarily causing a fall of the horse on his back.

[0074] What is claimed is: