The present invention relates to a cable system such as a Bowden cable system and further relates to a vehicle seat with a cable system
Bowden cables, a type of flexible cable, are used to transmit mechanical force or energy by the movement of an inner cable relative to an outer housing (also known as a guide cable or a sheaf). Bowden cable systems are particularly used in automotive applications, such as to transmit an actuating force from an actuator to an actuatable device. Vehicle seats employ Bowden cables between release handles (the actuator) and release latch mechanisms or fittings (the actuatable device).
It is an object of the invention to provide a cable system, such as a Bowden cable system or cable system with Bowden cable type features, that transmits an actuating force and actuating motion from an actuator to an actuatable device to provide an actuating movement at the actuatable device to actuate the actuatable device and which includes a bypass input that changes the effect of the actuator, such that the actuating motion of the actuator does not provide an actuating movement at the actuatable device so as to not actuate the actuatable device.
According to the invention, a cable actuator system is provided comprising an actuating cable for connection to an actuator and to an actuatable device and a bypass assembly connected to the actuating cable. The bypass assembly comprises a bypass input with a first input position and a second input position. With the bypass input in the first input position the bypass assembly acts on the cable such that an actuating movement of the cable by the actuator moves the cable an actuating distance at the actuatable device to actuate the actuatable device. With the bypass input in the second input position the bypass assembly acts on the cable such that the actuating movement of the cable by the actuator does not move the cable the actuating distance at the actuatable device.
The actuating cable advantageously comprises an inner cable having an actuator end for connection to an actuator and an actuatable device end for connection to an actuatable device. The actuating cable also advantageously comprises an outer guide cable (sheaf). The bypass assembly may act on the actuating cable in the first input position by holding or maintaining a position of the outer guide cable (sheaf) while allowing the inner cable to pass through (or pass relative to) the bypass assembly and to move relative to the bypass assembly and to move relative to the outer guide cable (sheaf). The bypass assembly may act on the actuating cable in the second input position by releasing or allowing movement (such as limited movement) of the outer guide cable (sheaf) while allowing the inner cable to pass through (or pass relative to) the bypass assembly and to move relative to the bypass but with movement (at least limited movement) of the outer guide cable (sheaf) with the inner cable. The releasing of the outer guide cable (sheaf)—allowing some movement of the outer guide cable (sheaf)—creates what is termed a lost motion. This provides less relative movement between the guide cable (sheaf) and the actuator inner cable and results in insufficient motion of the inner cable at the recliner latch 29. This results in an actuating motion of the actuator, wherein some of this motion is lost to the actuatable device as the normal actuating motion of the actuator does not result in an actuation of the actuatable device.
The sheaf of the actuating cable advantageously has a sheaf bypass assembly end and an actuator end. The bypass assembly may comprise a bypass housing and a sheaf piston positioned for limited movement in the bypass assembly. The sheaf bypass assembly end is fixed to the sheaf piston. The bypass input comprises a locking arrangement fixing a position of the sheaf piston relative to the bypass housing in the first input position and releasing the sheaf piston in the second input position, to allow limited movement of the sheaf piston relative to the bypass housing.
The bypass assembly advantageously further comprises a biasing spring biasing the sheaf piston, with a biasing force, into the first input position for being locked by the locking arrangement. In the second input position the limited movement of the sheaf piston relative to the bypass housing is movement against the biasing force of the biasing spring. The biasing spring, the bypass housing and the sheaf piston element may be configured to establish the limited movement of the sheaf piston relative to the bypass housing against the biasing force of the biasing spring such that the limited movement is greater than the actuating distance movement of the cable at the actuatable device to actuate the actuatable device.
The bypass input locking arrangement may further comprise an input unit housing portion connected to or forming a portion of the bypass housing. A lock element and a lock element spring are supported by the input unit housing portion. The lock element spring biases the lock element into a locked position with the sheaf piston in the first input position. The bypass input may further comprise an input cable, with an outer sheaf connected to the input unit housing portion and with an inner cable connected to the lock element. The bypass inner cable moves the lock element from a locked position corresponding to the first input position to an unlocked position corresponding to the second input position. The bypass housing may hold the lock biasing spring and also form a stop for piston at locked position. The bypass housing may hold the lock biasing spring in place above the lock element. The lock element may comprise metal lock pins supported by a lock body. The locking pins engage the piston to lock the piston in the position of the sheaf piston relative to the bypass housing corresponding to the first input position. The lock element releases the sheaf piston in the second input position, to allow limited movement of the sheaf piston relative to the bypass housing. The lock pins may engage the bypass housing for additional strength.
According to another aspect of the invention, a vehicle seat is provided. The vehicle seat comprises a seat base a backrest mounted to pivot relative to the seat base, an actuator moveable from a rest position to a release actuating position, a vehicle seat actuatable device and a cable actuator system. The cable actuator system comprises an actuating cable connected to the actuator and connected to the vehicle seat actuatable device and a bypass assembly connected to the actuating cable. The bypass assembly comprises a bypass input with a first input position and a second input position. With the bypass input in the first input position the bypass assembly acts on the cable such that an actuating movement of the cable by the actuator moves the cable an actuating distance at the vehicle seat actuatable device to actuate the vehicle seat actuatable device. With the bypass input in the second input position the bypass assembly acts on the cable such that the actuating movement of the cable by the actuator does not move the cable the actuating distance at the vehicle seat actuatable device.
A fitting with a release latch is advantageously connected to the backrest. The fitting with the release latch prevents the backrest from pivoting (in particular pivoting forward) relative to the seat base in a latched state and releases the backrest to pivot forward relative to the seat base in a released state. The actuator may be a release actuator operatively connected to the cable actuator system. The vehicle seat actuatable device may be the release latch of the fitting and may be operatively connected to the cable actuator system.
The seat base may be mounted to pivot up toward the backrest from a seat design position to a stadium position. The seat base may be operatively connected to the bypass input of the cable actuator system. Movement of the seat base from the design position to the stadium position changes the bypass input from the first input position to the second input position, such that movement of the release actuator from the rest position to the release actuating position does not release the release latch with the seat base in the stadium position. Movement of the seat base from the stadium position to the design position changes the bypass input from the second input position to the first input position, such that movement of the release actuator from the rest position to the release actuating position does release the release latch.
The features and object of the invention are born from the need to deactivate one or more actuating devices—release levers, release handles etc.—particularly with vehicle seats. This need particularly arises with a vehicle seat configuration with a seat cushion (seat base) that is also placed into a stadium position. In such a stadium position, the seat base pivots upward toward the backrest. This stadium position is a position corresponding to a seat that is not being used in a stadium or in a theater. Such a stadium position allows access past the seat, whereby users more easily pass the upwardly pivoted seat base. The vehicle seat configuration may also include a backrest which can be folded forward to a fold flat position. It is a further object of the invention to provide such a seat with a cable system with a release handle (actuator) that is to be used to release a latch in a fitting to fold the backrest forward and possibly move the seat base and backrest to a seat fold flat position. It was determined that it would be best if the user would not fold the backrest of the seat flat when the seat cushion is set to the stadium position.
The cable system features of the invention may be used with other seat and with other situations in which an actuator function is to be bypassed or not effective based on certain situations. The change in status (change in situation) is provided by a bypass input as described.
It is a further object of the invention to provide a cable system that allows the occupant or user to pull a release handle, or actuate an actuator, such that the actuator does not release the actuatable device—a release latch. Preventing the actuation may avoid some situation such as preventing a backrest from folding flat, if the seat cushion (seat base) is set to the stadium position.
The various features of novelty which characterize the invention are pointed out with particularity in the claims annexed to and forming a part of this disclosure. For a better understanding of the invention, its operating advantages and specific objects attained by its uses, reference is made to the accompanying drawings and descriptive matter in which a preferred embodiment of the invention is illustrated.
In the drawings:
Referring to the drawings in particular,
The seat base pivots 15, of the respective link arms 11, connect the frame of the seat base 14, at each side, to the corresponding link arm 11. The backrest link arm pivots 17, of each link arm 11, connect the link arm 11 at each side, to the frame of the backrest 12. The configuration allows for a pivoting up of the seat base 14, from a design position as shown in
The invention provides the multiple states of the actuator (release handle) 16, while still employing a cable system. In particular, the release bypass system according to the invention uses an actuating cable—a Bowden cable (or similar)—with an inner cable 23 extending from the actuator (release handle 16) all the way to the vehicle seat actuatable device (recliner latch 29) and with one or more outer guide cable 22. The CRBA 20 is connected to the actuating cable. The inner cable 23 is physically both the first input and the output of the CRBA 20. However, depending upon the state of the second input, the output changes, given the same input. The inner cable 23 of the actuating cable connects both to the actuator (release handle 16) and to an vehicle seat actuatable device (recliner latch 29). The CRBA 20 comprises a bypass input, the second input of the CRBA 20, with a first input position and a second input position. With the bypass input in the first input position the bypass device 20 acts on the cable 22/23 such that an actuating movement of the cable (the inner cable 23) at the actuator 16 moves the cable (in particular the inner cable 23) an actuating distance at the vehicle seat actuatable device 29 to actuate the vehicle seat actuatable device 29. With the bypass input in the second input position, the bypass device 20 acts on the cable 22/23 such that the actuating movement of the cable (the inner cable) by the actuator does not move the cable (in particular the inner cable 23) the actuating distance at the actuatable device 29.
In the embodiment of the vehicle seat 10, the cable release bypass system includes the CRBA 20 cooperating with a cable including actuator inner cable 23, a release handle guide cable (sheaf) 22, with an end fixed to the CRBA 20, and with a recliner latch guide cable (sheaf) 26, with an end fixed to the CRBA 20 (
As can be seen in
As can be seen in the sectional views of
The bypass device housing 30 is connected to the bypass input unit housing 36 to support the lock element 50 and to support the lock spring 52. The lock spring 52 biases the lock element 50 into a locked position. As can be seen in
The lost motion (travel of piston 40) is greater than the travel of the seatback release handle. The piston spring force is lower than the spring force of the latch. The latch is normally released by the seatback release handle if the CRBA lock element is engaged. When the lock element is disengaged and the release handle is actuated, the piston can move (lost motion) instead of the latch, (lower spring force at piston). Since the piston travel is greater than the travel of the seatback release handle, the handle reaches its travel limit.
The various parts of the CRBA 20, such as the bypass device housing 30, the bypass input unit housing 36, the lock element 50 and the sheaf piston element 40 may be made of plastic. The springs 44 and 52, the fasteners 39 and 54, pins 51 and the mounting bracket 37 may be formed of metal. However variation are possible as to the materials and the shapes of the parts.
Although the cable release bypass system is shown used with a vehicle seat, the system may be used with other applications in which the actuation movement of the actuating cable is to be functionally bypassed, namely to prevent actuation in certain situations. The bypass function is triggered by the additional input. The system provides the additional input so as to change the effect of the first input on the output of the system. This is advantageously accomplished with the use of a cable that extends from the first input to the output. It is particularly advantageous that this system allows the actuator to be fully actuated, the release handle 16 may be fully moved, with this movement in the second input state not resulting in any actuation at the actuatable device. This bypass action is believed to be advantageous and may be preferable over a system in which the actuator is blocked and is prevented from any movement.
Although a vehicle seat is disclosed in which the additional input (the bypass input) is a function of the pivot position of the seat base/cushion (the design position or the stadium position) other applications may advantageously use the cable release bypass system according to the invention. With regard to vehicle seats the state of some other part or sets of parts of the seat may provide the additional input. The actuatable device may be related to features other than the backrest fixture latch. For example, the position of rails, or the locking thereof, of a longitudinal seat movement system may be controlled whereby the movement of the seat base, backrest or other parts may provide the additional input or may have the features with the actuatable device.
While specific embodiments of the invention have been shown and described in detail to illustrate the application of the principles of the invention, it will be understood that the invention may be embodied otherwise without departing from such principles.