ADAPTIVE LOAD-LIMITING STEERING COLUMN FOR VEHICLES

The telescopic steering column with actuators and a controllable coupling device addresses high force activation and extended travel needs, enhancing safety and adaptability in collision scenarios.

FR3169840A1Pending Publication Date: 2026-06-19AUTOLIV DEV AB

Patent Information

Authority / Receiving Office
FR · FR
Patent Type
Applications
Current Assignee / Owner
AUTOLIV DEV AB
Filing Date
2024-12-17
Publication Date
2026-06-19

AI Technical Summary

Technical Problem

Current steering column designs face challenges in activating load-limiting mechanisms at high forces, which are undesirable in low-severity collisions, and struggle to accommodate extended travel requirements for automated driving vehicles, particularly with existing plastic deformation mechanisms becoming cumbersome.

Method used

A telescopic steering column with actuators and a controllable coupling device that allows reversible movement and adaptive load limiting, incorporating a clutch system and brake mechanism to adjust braking force based on collision severity and occupant characteristics.

Benefits of technology

The system provides improved safety by enabling adaptive load limiting and extended travel, optimizing protection in various collision scenarios while maintaining normal functionality and reducing unnecessary damage.

✦ Generated by Eureka AI based on patent content.

Smart Images

  • Figure 00000000_0000_ABST
    Figure 00000000_0000_ABST
Patent Text Reader

Abstract

This disclosure provides a steering column for a vehicle, comprising a telescopic structure having a moving part and a reference part to be fixed to the vehicle. The steering column includes a first actuator (30) for driving the moving part (10) relative to the reference part (20), preferably in a translational direction. A controllable and reversible coupling device (50) is disposed between the first actuator (30) and the moving part (10). A second actuator (40) controls the coupling device (50). A third actuator (60) is provided to brake the moving part (10) if the second actuator (40) has been actuated. The steering column allows for adaptive load limiting and improved occupant safety in various collision scenarios. Figure for the abstract: Fig. 1
Need to check novelty before this filing date? Find Prior Art

Description

Title of the invention: LOAD-LIMITING ADAPTIVE STEERING COLUMN FOR VEHICLES Technical field of the invention

[0001] This disclosure relates to steering columns for vehicles, and more particularly to an adaptive steering column, a method of operation of such a steering column, and a vehicle incorporating the steering column, designed to improve occupant safety. State of the art

[0002] Steering columns are essential components of vehicles, providing a mechanical link between the steering wheel and the steering mechanism. Traditional steering columns generally incorporate load-limiting features to improve occupant safety during collisions. These load-limiting mechanisms often use deformable elements within telescopic shafts, such as plastic deformation, bending, tearing, or shearing elements, or separate mechanical modules like bending bars.

[0003] Current steering column designs face several challenges. The load-limiting methods employed are generally irreversible and typically activate during moderate to high-severity accidents. The minimum force required for activation is generally high, often exceeding 2 kN and reaching up to 8 kN. To prevent undesirable damage due to misuse, shear pins are commonly used, with breaking forces of approximately 3500 N. However, this high minimum force is undesirable in many situations, particularly during low-severity events, typically when airbag deployment is not required.

[0004] On the other hand, the emergence of automated driving vehicles has introduced new requirements for steering columns. These include the need for increased longitudinal travel, from a common value of 100 mm to a new target of 250 mm, to accommodate designs with, for example, retractable steering wheels. This extended travel requirement poses challenges for existing plastic deformation load-limiting mechanisms, such as bending bars, which become cumbersome when adapted to longer travel distances.

[0005] Low-speed collisions, although frequent, present a significant challenge for current steering column designs. In these scenarios, airbag deployment may not occur, leaving the seat belt as the primary safety barrier. means of restraining occupants. However, the high initial forces required to activate current load-limiting mechanisms may not provide optimal protection during these low-severity impacts.

[0006] It has been recognized that an adaptive and dynamic steering column system is necessary to overcome one or more of these problems. Description of the invention

[0007] A steering column for a vehicle may include a telescopic structure having a moving part and a reference part to be fixed to the vehicle. The steering column may include a first actuator for driving the moving part relative to the reference part, which may be in a translational manner. The telescopic structure could also be described as a sliding structure or a translational structure. In some aspects, the first actuator may include an electric motor. The first actuator may be irreversible when a load is applied to the moving part in certain implementations.

[0008] The steering column may further include a controllable and reversible coupling device disposed between the first actuator and the moving part. Thus, the column can be made retractable in the event of a collision or the detection of an imminent collision, even at low speeds and therefore with low stress on the column, without breaking any parts that would require subsequent replacement. A second actuator may be provided to control the coupling device, preferably reversibly. In some cases, the coupling device may include a clutch device including a toothed clutch, and / or a load limiter (a force limiter, a torque limiter, etc.) including elastic means or springs cooperating with a friction brake. The second actuator may include a solenoid for engaging and disengaging the toothed clutch and / or the load limiter.In all cases, the moving part can be translated more easily (generally when a force of less than 1000N is applied) after or during the actuation of the second actuator than without actuation of the second actuator. In other words, the coupling device is designed to withstand all driving conditions or requirements (including no translation of the moving part when a force of approximately 3500N is applied) and to release the moving part when the second actuator is actuation so that it can be translated when a force of less than 1000N is applied.

[0009] Furthermore, the steering column may incorporate a third actuator to brake or clamp the moving part, particularly if the second actuator has been actuated or is about to be actuated. In some implementations, the third actuator may include a brake caliper for clamping onto a rail (or guide rack) of a rail / gear system. The brake caliper may be actuated by various means, such as a pyrotechnic device, a pneumatic system including at least one pressure generator, or a spring-loaded mechanism released by a solenoid. In some aspects, the pyrotechnic device may include several independently controlled igniters to provide different levels of braking force and / or to provide different actuation moments.

[0010] The steering column may also include a control unit configured to actuate the second actuator to disengage the coupling device in response to the detection of a collision or imminent collision, and optionally to actuate the third actuator to apply a braking force to the moving part. The braking force may be selected or adjusted based on factors such as the severity of the collision or imminent collision, occupant characteristics, and / or occupant position. The overall system may include sensors and detectors to assess factors such as the severity of the collision or imminent collision, occupant characteristics, and / or occupant position.

[0011] One method of operating the steering column may involve detecting a collision or an imminent collision, which may be of a severity not requiring the deployment of an airbag. The method may include actuation of the second actuator to control the coupling device, which may involve energizing a solenoid to disengage a clutch, a toothed clutch, and / or a load limiter between the first actuator and the moving part. The method may optionally include actuation of the third actuator to brake the moving part if the second actuator has been actuated, which may involve activating a pyrotechnic device to apply a braking force to the moving part.The method may further include the selection or adjustment of a braking force to be applied by the third actuator based on factors such as the severity of the collision, the characteristics of the occupant, and the position of the occupant.

[0012] The steering column as described can be incorporated into a vehicle, offering improved safety features and adaptable steering control in various driving conditions. Description of the figures

[0013] Other features and advantages of the present invention will become more apparent upon reading the following detailed description of embodiment(s) of the invention given by way of non-limiting example(s) and illustrated by the accompanying drawings, in which:

[0014] [Fig-1] illustrates a perspective view of a steering column for a vehicle, according to aspects of this disclosure;

[0015] [Fig.2] illustrates a cross-sectional view of a steering column assembly, according to a method of implementing this disclosure;

[0016] [Fig.3] illustrates a cross-sectional view of a braking mechanism for a column of direction, according to aspects of this disclosure.

[0017] Detailed description of embodiment(s)

[0018] A steering column 100 for a vehicle, as illustrated in [Fig. 1], is provided. The steering column 100 comprises a telescopic structure having a movable part 10 and a reference part 20. The reference part 20 is configured to be fixed to the vehicle.

[0019] The movable part 10 includes, in particular, a steering wheel 11, an outer shell 12, and a guide rack 13, the steering wheel 11 being rotatably mounted relative to the outer shell 12 (or about an axis that can be defined by the outer shell) to steer the vehicle. The reference part 20 includes, in particular, a mounting plate 21 and an outer housing 22 fixed together, as well as an articulated chain 23. The mounting plate 21 is configured to fix the steering column 100 to the vehicle structure. In the illustrated example, a mounting plate 21 with bolts is provided, but other solutions are possible.

[0020] The steering column 100 includes a first actuator 30 for driving the moving part 10 relative to the reference part 20. The first actuator 30 is configured to provide a translational movement of the moving part 10 relative to the reference part 20.

[0021] A controllable and reversible coupling device 50 is disposed between the first actuator 30 and the moving part 10. The steering column 100 further includes a second actuator 40 to control the coupling device 50.

[0022] A third actuator 60 is provided to brake the moving part 10, in particular if the second actuator 40 has been actuated or is about to be actuated. The third actuator 60 is positioned and fixed on the outer housing 22.

[0023] The telescopic structure of the steering column 100 allows a longitudinal stroke of up to 250 mm, for example (other ranges of values ​​are possible). This extended stroke range adapts to various driving positions, manual and / or automatic, and improves the vehicle's safety characteristics.

[0024] The guide rack 13 extends from the outer shell 12 and passes through the outer casing 22, including positioning rings or bearings, thus providing anti-rotation and linear guidance, facilitating the telescopic movement of the moving part 10. The articulated chain 23 is located inside the outer casing 22 and can be used to manage internal components such as wiring during the telescopic movement of the steering column 100.

[0025] The steering column 100 comprises several internal components arranged inside the outer housing 22, as illustrated in [Fig. 2]. [Fig. 2] is a cross-sectional view through the first actuator 30. The outer shell 12 is positioned and guided inside the outer housing 22 and houses a central shaft 14. A guide rack 13 is located along one side of the assembly, providing a track for the telescopic movement of the movable part 10 of the steering column 100.

[0026] The first actuator 30 is positioned at the bottom left of the assembly shown in [Fig. 2]. The first actuator 30 comprises an electric motor 31, a worm gear 32, and a toothed wheel 33. The first actuator 30 is connected to a shaft and to the coupling device 50 having a freewheel 52 engaged with the guide rack 13. This arrangement forms a screw / wheel system that allows precise control of the telescopic movement of the moving part 10 relative to the reference part 20. The electric motor 31 drives the worm gear 32, which in turn cooperates with the toothed wheel 33 to convert the rotary motion into linear motion via the coupling device 50 having the freewheel 52 engaged with the guide rack 13.

[0027] Adjacent to the first actuator 30 is the second actuator 40, which controls the coupling device 50. The coupling device 50 comprises an internal shaft 53 supporting a movable gear 51 and the freewheel 52. The coupling device 50 can therefore form a clutch device with a toothed clutch. The second actuator 40 may include a solenoid for engaging and disengaging the toothed clutch.

[0028] Indeed, the movable gear 51 translates along the internal shaft 53 under the action of the second actuator 40, so as to engage or disengage the freewheel 52; the coupling is therefore reversible depending on whether the second actuator 40 is activated or not. When the movable gear 51 is engaged with the freewheel 52, the moving part 10 cannot move relative to the reference part 20 because the system (screw / wheel system) is irreversible (unless the first actuator is actuated). When the movable gear 51 is disengaged from the freewheel 52, upon actuating the second actuator 40, the moving part 10 can move relative to the reference part 20 because the screw / wheel system is bypassed or the moving part is decoupled or disconnected from the reference part 20.Of course, an elastic return element allows the movable toothed wheel 51 to be returned to the engaged position with the free wheel 52 (particularly when the actuator 40 is not powered).

[0029] In other words, the movable gear 51 and the freewheel 52 work together to engage or disengage the telescopic function of the steering column 100. When engaged, the movable gear 51 connects the first actuator 30 to the moving part 10, allowing controlled adjustment of the position of the steering wheel 11. When disengaged, during the actuation of the second actuator 40, the moving part 10 can move freely relative to the reference part 20, subject to the braking action of the third actuator 60.

[0030] The coupling device 50 can also function as a load or torque (or force) limiter so as to limit in a controlled manner the displacement of the moving part 10 relative to the reference part 20.

[0031] The guide rack 13 and the screw / wheel system of the first actuator 30 together form a rail / gear system which allows the translation of the moving part 10. This system allows a precise and controlled telescopic movement of the steering column 100.

[0032] The arrangement of these components inside the outer housing 22 provides a compact and efficient design for the steering column 100. The integration of the first actuator 30, the second actuator 40 and the coupling device 50 allows both manually controlled adjustment and automated control of the position of the steering column, while incorporating safety features for use during collision events.

[0033] The steering column 100 includes a third actuator 60 for braking the moving part 10 when the movable gear 51 and the freewheel 52 are disengaged or if the movable gear 51 and the freewheel 52 are about to be disengaged. Figure 3 illustrates a cross-sectional view of the braking mechanism of the steering column 100 along the guide rack 13. The third actuator 60 includes a brake caliper for clamping onto a rail of the rail / gear system, in particular the guide rack 13.

[0034] The third actuator 60 comprises a caliper body 61 which houses several components. The guide rack 13 is positioned inside the outer housing 22 and serves as the surface on which the braking force is applied. A brake pad 62 is arranged to make contact with the guide rack 13. Springs 63 are incorporated to provide initial or residual tension and to prevent noise / rattling.

[0035] The brake caliper can be actuated by various mechanisms. In one example, the brake caliper is actuated by a pyrotechnic device. The pyrotechnic device may include several independently controlled detonators to provide different levels of braking force and / or different timing of actuation. As illustrated in [Fig. 3], a first pyrotechnic device 64 and a second pyrotechnic device 65 are included (which may be identical or different, particularly in terms of pressurization capacity). When activated, these devices create pressure to push the brake pad 62 against the guide rack 13.

[0036] In another example, the brake caliper can be actuated by a pneumatic system comprising at least one pressure generator. The pneumatic system It can use a pyrotechnic gas generator to function as an air brake. Alternatively, the brake caliper can be actuated by a spring-loaded mechanism released by a solenoid or a pyrotechnic device.

[0037] A pressure valve 66 is integrated into the system to regulate the pressure generated by the pyrotechnic devices and / or prevent overpressure. The pressure valve 66 limits the maximum pressure in the system.

[0038] The third actuator 60 can be designed to be reversible, allowing the braking force to be released after activation. Braking is achieved by friction between the brake pad 62 and the guide rack 13.

[0039] In some examples, the third actuator 60 may include a push-pin design with spring washers (spring washers or helical springs). This design may incorporate preloaded springs that can be released either by a pyrotechnic actuator or by a solenoid, depending on the specific configuration. In the examples above, the third actuator 60 is of the released-before-actuation type (i.e., before actuation, there is no or virtually no braking force). In some examples, the third actuator 60 may be of the "braked" or "activated"-before-actuation type (i.e., before actuation, the braking force is at its maximum), and upon actuation, the braking force is decreased or reduced to allow controlled sliding of the moving part 10.

[0040] The arrangement of these components allows for variable braking force, which can be adjusted by selectively activating one or both pyrotechnic devices. Several pyrotechnic actuators can be individually controlled to provide different levels of braking force. This design allows the steering column 100 to provide adaptive load limiting based on various factors.

[0041] The steering column 100 may include a control unit (or the overall system or the vehicle may include the control unit) configured to manage the operation of the various actuators and devices during normal use and collision scenarios. As stated, the control unit may be integrated into the steering column 100 or may be a separate unit communicating with the steering column 100.

[0042] During normal operation, the control unit can receive inputs from the vehicle or driver systems to adjust the position of the steering wheel 11. The control unit can activate the first actuator 30, which includes the electric motor 31, the worm gear 32 and the toothed wheel 33, to drive the moving part 10 relative to the reference part 20. This allows for precise adjustment of the position of the steering wheel 11 to adapt to different drivers or driving positions or situations.

[0043] In the event of a collision or imminent collision, the control unit can be configured to actuate the second actuator 40 in order to disengage the coupling device 50 in response to the detection of a collision or imminent collision. This action allows the moving part 10 to move freely relative to the reference part 20, subject to the braking action of the third actuator 60.

[0044] The control unit can also be configured to actuate the third actuator 60 in order to apply a braking force to the moving part 10. The braking force is selected and adjusted according to at least one of the following: collision severity, occupant characteristics, and occupant position. This adaptive load-limiting function improves the safety performance of the steering column 100 by adapting the column's behavior to the specific circumstances of the collision.

[0045] In a scenario where a collision or imminent collision is detected with a severity not requiring the deployment of an airbag, the control unit can actuate the second actuator 40 to control the coupling device 50. This action can involve the disengagement of the movable toothed wheel 51 from the free wheel 52, allowing the movable part 10 to move independently of the first actuator 30.

[0046] The control unit may optionally actuate the third actuator 60 to brake the moving part 10 if the second actuator 40 has been actuated or if the second actuator 40 is about to be actuated. The third actuator 60 comprises the caliper body 61 with brake pads 62 that can clamp or pinch a rail of the steering column 100 to provide controlled resistance to the movement of the moving part 10.

[0047] The braking force applied by the third actuator 60 can be selected based on at least one of the following: the severity of the collision, the characteristics of the occupant, and the occupant's position. For example, in the case of a minor collision and / or a short distance between the occupant and the steering wheel and / or an occupant in the 5th percentile (small build), the control unit can activate only the first pyrotechnic device 64 or only the second pyrotechnic device 65 to provide a lower braking force. In the case of a more severe collision and / or a large distance between the occupant and the steering wheel and / or an occupant in the 95th percentile (large build), the control unit can activate both the first pyrotechnic device 64 and the second pyrotechnic device 65 to provide a higher braking force.

[0048] The pressure valve 66 in the third actuator 60 helps regulate the pressure generated by the pyrotechnic devices, ensuring that the braking force remains within a safe and effective range. This adaptive braking system allows the steering column 100 to provide optimized occupant protection in a range of collision scenarios.

[0049] By integrating these control features, the 100 steering column offers improved safety performance while maintaining normal functionality for everyday use and allowing reversible sliding. The ability to adapt the steering column's behavior according to collision characteristics and occupant-related factors represents a significant advancement in the design of steering columns and vehicle safety systems.

[0050] The features of all the examples or embodiments described above can be combined to create additional examples or embodiments without losing the desired effect. It should be understood that the description of an embodiment or example provided above is given by way of example only, and that various modifications could be made by a person competent in the field. Moreover, a person competent in the field will recognize that many other modifications and combinations of various aspects are possible. Accordingly, the aspects described are intended to encompass all such alterations, modifications, and variations that fall within the scope of the invention. Industrial application

[0051] A steering column according to the present invention, and its manufacture, are capable of industrial application.

[0052] It will be understood that various modifications and / or improvements obvious to a person skilled in the art can be made to the different embodiments of the invention described in this description without departing from the scope of the invention.

[0053] In particular, the coupling device can be provided so as to couple or not the wheel 33 of the worm gear system with the internal shaft 53, the wheel 52 would then be mounted fixed (in anti-rotation) with the internal shaft 53.

Claims

Demands

1. Steering column (100) for a vehicle, comprising: a telescopic structure having a movable part (10) and a reference part (20) to be fixed to the vehicle; a first actuator (30) for driving the movable part (10) relative to the reference part (20), preferably in a translation; a controllable and reversible coupling device (50) disposed between the first actuator (30) and the movable part (10); and a second actuator (40) for controlling the coupling device (50) in a reversible manner.

2. Steering column (100) according to claim 1, further comprising a third actuator (60) to brake the moving part (10) if the second actuator (40) has been actuated or if the second actuator (40) is about to be actuated.

3. Steering column (100) according to claim 1 or 2, wherein the coupling device (50) comprises a clutch device including a toothed clutch, and / or the coupling device (50) comprises a load limiter.

4. Steering column (100) according to claim 3, wherein the second actuator (40) comprises a solenoid for engaging and disengaging the toothed clutch and / or the load limiter.

5. Steering column (100) according to claim 2, wherein the third actuator (60) includes a brake caliper (61) for clamping onto a rail (13) of a rail / gear system.

6. Steering column (100) according to claim 5, wherein the brake caliper (61) is actuated by a pyrotechnic device (64, 65), or by a pneumatic system comprising at least one pressure generator, or by a spring mechanism releaseable by a solenoid.

7. Steering column (100) according to claim 6, wherein the pyrotechnic device (64, 65) comprises several independently controlled detonators to provide different levels of braking force.

8. Steering column (100) according to any one of the preceding claims, further comprising a control unit configured to: actuate the second actuator (40) to disengage the coupling device (50) in response to the detection of a collision or imminent collision; and optionally actuate the third actuator (60) to apply a braking force to the moving part (10), where the braking force is selected or adjusted according to at least one of the following: collision severity, occupant characteristics and occupant position.

9. Method of operating a steering column (100), the method comprising: supplying the steering column (100) according to claim 1; detecting a collision or imminent collision, the collision or imminent collision preferably having a severity not requiring the deployment of an airbag, actuation of the second actuator (40) to control the coupling device (50).

10. Vehicle comprising the steering column (100) according to any one of claims 1 to 8.