DE102018216633A1 - An adjustment system - Google Patents

Abstract

An actuator system (3) for a moveable vehicle seat assembly (17, 19), the system comprising: an actuator (60) controllable to move at least one component (39) of the seat assembly (17, 19) between a first position and a first position second position, and a spring (74, 76) configured to bias the at least one component (39) away from the second position.

Description

TECHNICAL AREA

The present disclosure relates to a positioning system. More particularly, but not exclusively, the present invention relates to an actuator system in a retractable seat assembly for use in the passenger compartment of a vehicle, such as a saloon vehicle or sport utility vehicle (SUV). Aspects of the invention relate to a control system, a retractable seat assembly and a vehicle having a control system and / or a retractable seat assembly.

STATE OF THE ART

The large space available in a standard off-road vehicle (standard SUV) allows a user to adjust the seating distribution in the SUV to either carry more passengers or accommodate a larger load. However, the seats used in luxury SUVs and more generally in luxury vehicles are often larger and heavier than those used in standard passenger cars because they are optimized for comfort rather than versatility.

Additional functionality may be required for the seats of a luxury vehicle. For example, it may be desirable for a rear seat to be reclined to provide more comfort to seated passengers. To accomplish this, individual components of the seat may be movable relative to a bulkhead (or partition) that separates a seating area from a cargo compartment of the vehicle. The partition itself can be folded forwards to increase the capacity of the cargo space.

The movement of both the seat and the divider wall may be driven by a system of motors that may be installed within the structure of the seat assembly. Consequently, the ability to adjust the seats in luxury SUVs is often compromised due to the increased weight and size of the seat assembly. In particular, some electric motors may not be able to provide sufficient torque to move the components of the assembly between their retracted and unfolded positions. It is therefore desirable to assist in any way the movement of the retractable seat assembly, and the present invention has been developed against this background.

BRIEF SUMMARY OF THE INVENTION

In accordance with one aspect of the present invention, there is provided a movable vehicle seat assembly positioning system, the system comprising: an actuator controllable to move at least one component of the seat assembly between a first position and a second position and a spring configured is to bias the at least one component away from the second position.

Advantageously, the actuator and the spring cooperate to control the movement of the component. In particular, the assistance provided by the spring allows the actuator performance to remain nearly constant as the component moves between the unfolded and retracted positions. By modulating the power of the actuator, the spring allows the actuator to run smoother, creating a more comfortable and relaxed environment for the passengers sitting in the vehicle. The modulation of the actuator power also extends its life.

The spring may be configured to bias the at least one component toward the second position. In embodiments, the spring may be configured to bias the at least one component into both the first position and the second position. In embodiments, the spring may be configured to bias the at least one component away from the first position under tension and to bias the at least one component away from the second position under pressure.

The spring may be configured to terminate the biasing of the at least one component at a third position that may be located between the first position and the second position. The third position may define a neutral position in which the spring is configured to exert no biasing force on the at least one component remote from either the first or the second position. Alternatively, the first or second position may be located between the third position and the other of the first and second positions.

The spring may be configured to disengage from the at least one component at the third position. Advantageously, the spring may be configured to selectively engage the at least one component such that it applies torque only during a predetermined portion of the movement of the component between the first and second positions.

The spring may include a first end configured to engage another component of the seat assembly, the at least one component being movable relative to the further component, and a second end being configured for releasable engagement with the at least one component , The first end may provide a point of attachment against which the spring can be biased.

The second end may include a flange, wherein the flange is configured to engage and / or disengage a protruding member of the at least one component. Advantageously, the spring may be configured to disengage the at least one component once it has released all of its potential energy. The spring will therefore resist the subsequent movement of the at least one component no resistance.

The spring may be a coil spring. Advantageously, the coil spring is configurable to store a large potential energy while conveniently accommodated in a small volume at the fulcrum of the seat assembly, thereby reducing packaging limitations of the control system.

The adjusting system may include a second spring configured to bias the at least one component away from the first position. Advantageously, the first and second springs may cooperate to control movement of the component between the first and second positions.

The second spring may be configured to terminate the biasing of the at least one component at a fourth position that may be between the first position and the second position.

The fourth position may be between the second position and the third position.

The fourth position substantially coincides with the third position insofar as the third and fourth positions together define a transfer position at which the component can transition between the first and second springs. A single transfer position allows a smooth transition between the first and second springs and minimizes movement of the component for which the actuator must move the component without assistance.

The third and fourth positions may define a transfer area or a transfer position, and the first component may be disposed at a right angle to a seat cushion of the seat assembly. In other words, the component is substantially orthogonal to the seat cushion of the seat assembly when the component is in the transfer position. When in the handover area, the first component may be in a substantially vertical area / position.

The second spring may include: a first end configured to engage with another component of the seat assembly, the at least one component being movable relative to the further component, and a second end configured to releasably engage the at least one component is.

The second end may include a flange, wherein the flange is configured to engage and / or disengage a protruding member of the at least one component.

The first and second springs are configured to releasably engage the same protruding member. Advantageously, the seat assembly may be provided with a single protruding member by which it can be brought into position by both the first and second springs, thereby reducing the complexity of the mechanism.

The second spring may be a coil spring. A coil spring can conveniently store a large amount of potential energy while requiring little space in the seat assembly.

The second spring may be disposed side by side with the first spring, and a drill axis of the first spring may be aligned with a drill axis of the second spring, thereby reducing the space occupied by the actuator system in the seat assembly. The drill axis of the first spring may be defined as a rotation axis, and the drill axis of the second spring may also be defined as a rotation axis of the second spring.

The coil direction of the second spring is opposite to the coil direction of the first spring, so that the first and second springs may be configured to apply opposite torques to the common protruding element.

The first spring may be configured to store more energy than the second spring so that it is configured to support the weight of the seat component when positioned in a folded position.

The actuator may include an electric motor. The power of the electric motor can be comfortable be controlled by its power supply is precisely controlled. Thus, the electric motor provides improved control over the movement of the seat assembly.

The electric motor may be configured to receive substantially constant power as it moves the at least one component between the first position and the second position.

The first spring may be disposed adjacent the second spring so that it can conveniently apply torque to a common protruding element. In addition, by locating the springs adjacent to each other, it is possible to configure them to occupy a reduced footprint within the seat assembly.

The first component may comprise a partition wall of the movable seat assembly.

• einen Stellantrieb, der steuerbar ist, um eine erste Komponente der Sitzbaugruppe relativ zu einer zweiten Komponente der Sitzbaugruppe schwenkbar zu bewegen, wobei die erste Komponente eine Sitzlehne umfasst und der Stellantrieb angeordnet ist, um die erste Komponente um eine Schwenkachse relativ zu der zweiten Komponente zwischen einer ersten Position und einer zweiten Position zu schwenken;
• eine erste Feder, die konfiguriert ist, um die erste Komponente von der zweiten Position weg vorzuspannen; und
• eine zweite Feder, die konfiguriert ist, um die erste Komponente von der ersten Position weg vorzuspannen;
• wobei die erste Feder konfiguriert ist, um das Vorspannen der ersten Komponente an einer dritten Position zu beenden, wobei die dritte Position zwischen der ersten Position und der zweiten Position ist;
• wobei die zweite Feder konfiguriert ist, um das Vorspannen der ersten Komponente an einer vierten Position zu beenden, wobei die vierte Position zwischen der ersten Position und der zweiten Position ist.

In accordance with another aspect of the invention, a positioning system for a movable vehicle seat assembly is provided, the system comprising:

• an actuator controllable to pivotally move a first component of the seat assembly relative to a second component of the seat assembly, the first component including a seat back and the actuator arranged to move the first component about a pivot axis relative to the second component to pivot a first position and a second position;
• a first spring configured to bias the first component away from the second position; and
• a second spring configured to bias the first component away from the first position;
• wherein the first spring is configured to terminate the biasing of the first component at a third position, the third position being between the first position and the second position;
• wherein the second spring is configured to terminate the biasing of the first component at a fourth position, wherein the fourth position is between the first position and the second position.

According to a further aspect of the invention, there is provided a movable seat assembly comprising a first component, a second component and a positioning system according to any one of the preceding paragraphs, wherein the actuator of the control system is controllable to move the first component between a first position and a second position relative to the second component.

The first component may be pivotally connected to the second component of the movable seat assembly and arranged to pivot about a pivot axis relative to the second component.

The spring may be near the pivot axis. The actuator may be near the pivot axis.

The first position may define a collapsed position of the first component and the second position may define an unfolded position of the first component.

The seat assembly may include a locking mechanism arranged to secure the first component in the unfolded position, and the first spring is configured to eject the first component from the locking mechanism.

The seat assembly may include a second spring of the control system, wherein the second spring is configured to bias the first component away from the folded position.

The second spring may be configured to substantially equalize the weight of the first component when the first component is disposed in the unfolded position. Thus, the amount of torque required by the actuator to move the seat component away from the folded position is minimized, thereby allowing a smaller, less heavy actuator to be used.

The first component may comprise a partition wall of the movable seat assembly. In alternative embodiments, the first component may include a backrest of the movable seat assembly.

According to a further aspect of the invention, a vehicle is provided which comprises a positioning system according to one of the preceding paragraphs and / or a movable seat assembly according to one of the preceding paragraphs.

According to another aspect of the invention, there is provided a movable vehicle seat assembly positioning system, the system comprising: an actuator controllable to pivotally move a first component of the seat assembly relative to a second component of the seat assembly, the first component having a first component Seat back comprises, and the actuator is arranged to pivot the first component about a pivot axis relative to the second component between a first position and a second position; and a first spring configured to bias the first component away from the second position; and a second spring configured to bias the first component away from the first position; wherein the first spring is configured to terminate the biasing of the first component at a third position, the third position being between the first position and the second position; wherein the second spring is configured to terminate the biasing of the first component at a fourth position, wherein the fourth position is between the first position and the second position.

It is expressly intended, within the scope of this application, that the various aspects, embodiments, examples, and alternatives presented in the preceding paragraphs, claims, and / or description and drawings, and in particular, their individual features, be independent of each other or can be considered in any combination with each other. This means that all embodiments and / or features of any embodiment can be combined in any manner and / or in any combination, provided that these features are not incompatible. The Applicant reserves the right to change any claim originally filed or to submit any new claim, including the right to change any originally filed claim to be subject to any feature of any other claim and / or is integrated into such a claim, even if it has not previously been claimed in this way.

list of figures

• 1 eine Draufsicht auf ein Luxusfahrzeug mit einer hinteren Sitzanordnung ist, die zur Verwendung in Ausführungsformen der Erfindung geeignet ist;
• 2 eine perspektivische Ansicht der hinteren Sitzanordnung von 1 ist, die in einer aufgeklappten Konfiguration angeordnet ist;
• 3 2 entspricht, jedoch die hintere Sitzanordnung in einer eingeklappten Konfiguration zeigt;
• 4 eine perspektivische Ansicht der hinteren Sitzanordnung von 2 ist, die ein Stellsystem gemäß einer Ausführungsform der Erfindung zeigt;
• 5 eine perspektivische Ansicht einer Feder des in 4 gezeigten Stellsystems ist;
• 6 eine perspektivische Ansicht einer Getriebeanordnung des in 4 gezeigten Stellsystems ist;
• 7a bis 7c eine Komponente der hinteren Sitzanordnung von 2 mittels einer Reihe von Stufen einer Einklappsequenz der Komponente zeigen; und
• 8a bis 8c den 7a bis 7c entsprechen, jedoch eine Aufklappsequenz der Komponente zeigen.

One or more embodiments of the invention will now be described, by way of example only, with reference to the accompanying drawings, in which:

• 1 Figure 12 is a plan view of a luxury vehicle with a rear seat assembly suitable for use in embodiments of the invention;
• 2 a perspective view of the rear seat assembly of 1 is arranged in an unfolded configuration;
• 3 2 but shows the rear seat assembly in a folded configuration;
• 4 a perspective view of the rear seat assembly of 2 which shows a positioning system according to an embodiment of the invention;
• 5 a perspective view of a spring of in 4 shown adjusting system is;
• 6 a perspective view of a gear arrangement of in 4 shown adjusting system is;
• 7a to 7c a component of the rear seat assembly of 2 by means of a series of stages of a folding sequence of the component; and
• 8a to 8c the 7a to 7c but show a pop-up sequence of the component.

DETAILED DESCRIPTION

Embodiments of the invention relate to a device for moving the components of a motorized seat assembly for a vehicle. Due to the weight of the components, the device includes a spring to help move the components between a collapsed and an unfolded position.

Before considering these embodiments in detail, a seat assembly to which such embodiments are applicable will be described with reference to FIGS 1 to 4 to put the invention into context.

1 shows in plan view and in simplified form a luxury vehicle 6 with a rear seat assembly (or assembly) 1 and a control system 3 for controlling the movement of components of the rear seat assembly 1 according to embodiments of the invention. The rear seat arrangement 1 is in a passenger compartment 2 of the vehicle 6 arranged and a cargo space 4 is behind the seating arrangement 1 Are defined. 2 shows the rear part of the passenger compartment 2 and the cargo space 4 in perspective view.

In the following description, the terms "forward" and "backward" are used to refer to positions or locations of features relative to the vehicle 6 to describe. For example, the term "forward" refers to locations or positions toward or near the front of the vehicle 6 and the term "backward" refers to locations or positions toward or closer to the rear of the vehicle 6 ,

As most clearly in 2 shown is the passenger compartment 2 from the hold 4 through a partition 8th or a separation separated, the extending transversely between the opposite sides of the vehicle 6 extends. The cargo space 4 is commonly referred to as a "trunk", "luggage space" or "cargo space" of a vehicle. Luggage and other items are typically in the hold 4 loaded by a hinged flap or door (not shown) at the rear of the vehicle 6 is opened to access the cargo space 4 to enable. The partition 8th has a first surface 10 and a second surface 12 on. If the partition 8th in an unfolded or upright configuration, as in 2 shown, define their first surface 10 and the second surface 12 one facing forward and one facing rearward surface of the partition 8th ,

The rear part of the passenger compartment 2 contains the seating arrangement 1 , which is shown in a standard configuration, with the first surface 10 the partition 8th the passenger compartment 2 is facing and the second surface 12 the cargo space 4 in 2 is facing. The 1 to 3 will now be described together.

The seating arrangement 1 includes a first seat 18 , a second seat 16 and a separating section having a central seat 20 defined, with the central seat 20 between the first seat 18 and the second seat 16 is arranged. With particular reference to the 2 and 3 Each seat includes a seat cushion 22 , a seat back (or backrest) 24 , a headrest 26 and a calf pad 27 , The seat backrests 24 are adjacent to the first surface 10 the partition 8th arranged. The central seat 20 includes a central upholstery 28 and a backrest that is pivotable as an armrest 30 to act.

The seating arrangement 1 is referred to in the art as 40-20-40 pitch: the first seat 18 covers 40% of the seating surface of the seating arrangement 1 , the central seat 20 includes 20% of the seating surface of the seating arrangement 1 and the second seat 16 covers 40% of the seating surface of the seating arrangement 1 ,

The seating arrangement 1 is in 3 shown in a configuration in which a part of the seat assembly 1 is folded. The partition 8th is asymmetrical in a first partition wall section 17a and a second partition wall section 19a divided. Accordingly, the seat assembly 1 in a first seat assembly 17 and a second seat assembly 19 divided as in 2 shown. The first seat assembly 17 includes the first seat 18 , the central seat 20 and the armrest 30 and the first partition wall section 17a , The second seat assembly 19 includes the second seat 16 and the second partition wall section 19a , In the example shown, the seat assembly 1 a 40-20-40 division, meaning that the first partition section 17a and the second partition section 19a typically have a 60-40 pitch. In this way, the first and second partition wall sections define 17a . 19a each main and secondary sections of the partition 8th ,

The first, second and central seat 18 . 16 . 20 are arranged so that the seat backs 24 and the armrest 30 one axis at a time 33 that are right across the vehicle 6 parallel to the plane of the partition 8th extends, can fold forward. The partition 8th is also arranged so that it interacts with the seats 18 . 16 . 20 works forwards.

With particular reference to 2 It should be noted that the seat backs 24 of the first and second seats 16 . 18 from the partition 8th the seating arrangement 1 are separated so that they are independent of the dividing wall 8th can be moved. Providing a partition 8th that are independent of the seats 18 . 16 . 20 is foldable, increases the versatility of the seating arrangement 1 , For example, this configuration allows the bulkhead as a basis for the movement of the seat backs 24 can be used, which is helpful in view of their relatively large size and their relatively high weight, resulting from the increased comfort that they should offer. This arrangement also allows the partition 8th continue the cargo space 4 from the passenger compartment 2 separates while the positions of the seat backs 24 be set. It is understood that in the 1 to 3 shown rear seat assembly 1 an example of a seating arrangement with which embodiments of the invention can be used. Alternative embodiments are configured for use with seat assemblies in which the bulkhead 8th and the seat back 24 are firmly mounted to a single component of the seat assembly 1 to form so that the dividing wall 8th and the seat back 24 can only be moved as a single unit.

In the configuration of in 3 shown seat arrangement 1 is the first seat 18 in a folded configuration, leaving its seat back 24 on her corresponding seat cushion 22 rests. The first partition wall section 17a the partition 8th ie the second seat assembly 17 , is in a standard unfolded configuration. In this configuration, the corresponding second partition wall section 19a folded forward to on the top of the seat back 24 to lie, leaving the first surface 10 the second partition wall section 19a generally the floor of the passenger compartment 2 is facing and the second surface 12 of the second section of the partition 8th generally the roof of the passenger compartment 2 is facing. The collapsed configuration of the first seat 18 allows it, that a long load 32 from the vehicle 6 is promoted while the second seat 16 and the central seat 20 Transport passengers.

Although not shown here, it will be apparent to those skilled in the art that the seat assembly 1 can be arranged so that both the first and the second partition wall section 17a . 19a are arranged in a folded configuration, in which both the seat backs 24 as well as the armrest 30 around the folding axis 33 folded forward so that every seat back 24 and the armrest 30 with their corresponding upholstery 22 . 28 engages. In this fully folded configuration, both the first and second sections of the divider wall are 8th folded forward to the top of the seat backrests 24 and the armrest 30 to lie, leaving the first surface 10 the partition 8th generally the floor of the passenger compartment 2 facing, and the second surface 12 generally the roof of the passenger compartment 2 is facing. The fully folded configuration allows for a greater load from the vehicle 6 will be carried.

4 shows the seat assembly 1 with the pad and padding removed to show the underlying support structure. The seating arrangement 1 is in 4 shown in a configuration where the armrests 24 the first and second seat assemblies 17 . 19 from the partition 8th are spaced. Each partition section 17a . 19a includes an upper support structure 38 and a bulkhead bracket 40 whereas the seat backs 24 each a seat back support structure 24a include, which pivotally with the partition wall bracket 40 is connected so that they are relative to the partition wall 8th can move.

Each moveable seat assembly also includes a support structure 34 , which is configured to the assembly with the chassis of the vehicle 1 connect to. In particular, the partition wall bracket 40 each assembly with the support structure 34 through a pair of hinged joints 54 connected, which are arranged on opposite sides of each seat assembly. The hinged joints 54 define a pivot axis 33 each seat assembly surrounding the partition 8th is pivoted.

With particular reference to the second seat assembly 19 connects a first pivoting joint 54a the partition wall bracket 40 with a first arm 34a the carrying structure 34 , and a second pivotal connection 54b connects the partition wall bracket 40 with a second arm 34b the carrying structure 34 , where the first arm 34a in relation to the inside cabin of the vehicle, inward of the second arm 34b is arranged. In this way, the first and second pivotal joints define 54 in each case an inner and an outer pivotable joint 54a . 54b the seat assembly. By this arrangement, the partition wall 8th swiveling with the carrying structure 34 the second seat assembly 19 connected and it is arranged to be in use around the pivot axis 33 relative to the support structure 34 to pan.

The seating arrangement 1 further includes a pair of detents 70 on the sides of the partition 8th towards the upper corners of the seating arrangement 1 are attached. The rest 70 are configured to engage a locking mechanism (not shown) attached to a vehicle cabin structure (not shown). The locking mechanism is operable, the partition 8th in place in the unfolded position. This ensures that every partition 8th is securely held when the seat assembly 1 in the unfolded position, thereby providing a secure basis for the movement of other components of the seat assembly, including, for example, the seat backs 24 , It also acts to minimize vibration and therefore noise resulting from the movement of the partitions 8th revealed while the vehicle 1 is in motion.

Each moveable seat assembly includes a positioning system 3 , which is arranged to control the movements of the assembly between the unfolded (standard) configuration and the folded-in configuration. Every positioning system 3 includes an actuator 60 which is controllable to a first component 39 the seat assembly between a first and a second position relative to a second component 41 to move the seat assembly. The control system 3 also includes a spring assembly 72 that is configured to work with the actuator 6 to work to the first component 39 relative to the second component 41 to move.

According to the embodiment described herein, the partition wall defines 8th the moving first component 39 and defines the support structure 34 the second component 41 , The first and second positions of the first component 39 correspond respectively to the folded and unfolded configuration of the seat assembly. In alternative embodiments, the actuator may 60 be configured to other components of the seat assembly, such as the seat back 24 , to move. Likewise, the first and second positions of the moveable component may correspond to any number of suitable arrangements of the seat assembly.

The actuator 60 and the spring arrangement 72 are near one of the couple of swivel joints 54 the seat assembly arranged. In the in 4 shown exemplary arrangement is the actuator 60 each seat assembly near the inner pivoting joint 54a each respective seat assembly arranged. However, it is clear to the person skilled in the art that the actuator 60 near the outer hinged joint 54b or at any other suitable location within each seat assembly.

Every actuator 60 is configured to apply appropriate forces to the bulkhead 8th exercise to move them between the folded and the unfolded position. In particular, the actuator comprises 60 a partition drive operating on an inwardly facing surface 41 the partition wall bracket 40 each seat assembly is mounted. Accordingly, the partition wall drive moves with the partition wall 8th when it passes between the folded and the unfolded position. This also allows the divider drive to be conveniently housed within the frame of the seat assembly to accommodate packaging limitations of the control system 3 to reduce.

With reference to the 5 and 6 are components of the control system 3 disposed within the structure of each seat assembly, as described in more detail below.

As most clearly in 6 shown is the partition drive (which in this view behind the bulkhead bracket 40 is hidden) with an axis 61 connected by an access hole 63 in the partition wall bracket 40 protrudes and with a drive gear 62 or pinion is connected. The drive gear 62 engages in an intermediate gear 64 at a transversely facing surface 43 the partition wall bracket 40 is appropriate. The intermediate gear 64 also stands with a driven gear 66 engaged, which is a portion of the inner arm 34a the seat assembly structure 34 forms, so that the driven gear remains stationary when the partition 8th moved between the folded and unfolded position. The center axis of the driven gear 66 is on the pivot axis 33 the first seat assembly 19 aligned. The drive gear 62 , the intermediate gear 64 and the drive gear 66 define a gear arrangement of the control system 3 ,

During operation of the actuator 60 the partition wall drive drives the drive gear 62 which, in turn, the intermediate gear 64 drives. When the driven gear 66 is fixed, crosses the intermediate gear 64 when turning the path of the portion of the driven gear 66 with which the intermediate gear 64 engages, which in turn causes the partition 8th is moved. In this way, define the driven gear 66 and the intermediate gear 64 a rack drive type arrangement in which the driven gear 66 defines a curved "rack" along which the intermediate gear 64 runs when the dividing wall 8th in motion. A leadership arrangement 67 Make sure that the rack and pinion remain in alignment when the divider wall 8th moved between the folded and unfolded position.

The leadership arrangement 67 includes a guide channel 68 that is in the body of the driven gear 66 is arranged. The guide channel 68 takes a guide pin 69 the leadership arrangement 67 on, from the outward-facing surface 43 the partition wall bracket 40 protrudes and is configured to extend along the guide channel 68 moves when the partition wall 8th relative to the seat assembly structure 34 emotional. The extreme ends of the canal 68 that limits the movement of the guide pin 69 define correspond to the unfolded and folded position of the partition 8th , In this way, the guide channel and the pin 68 . 69 configured to advantageously prevent the idler gear 64 over any end of the driven gear 66 is pushed out during the operation of the control system 3 acts as a rack. For example, in 6 the arrangement of the control system 3 the partition 8th , which is in the unfolded position. In this configuration, the idler gear is 64 at the extreme end of the driven gear 66 positioned when the guide pin 69 at the extreme end of the guide channel 68 is arranged.

As most clearly in 5 shown is the spring assembly 72 on the inner hinged connection 54a the first seat assembly 19 arranged. The spring arrangement 72 includes a first coil spring 74 and a second coil spring 76 , Each spring is configured to function as a torsion spring formed from a strip of elastic material wound along its length to form a coil. In embodiments, the coil springs are formed of stainless steel. However, it will be apparent to those skilled in the art that the springs may be formed of any engineering material having suitable elastic properties.

Each coil spring includes a first end 74a . 76a and a second end 74b . 76b , The first end 74a . 76a is configured to be firm with the seat assembly structure 34 engaged while the second end 74b . 76b is configured so that it is detachable in the partition 8th intervenes. In this way, each coil spring is on the seat assembly structure 34 attached, but may be free in terms of partition wall 8th move. As will be explained in more detail below, the first spring is 74 configured to be the partition 8th biased away from the folded position while the second spring 76 designed to be the dividing wall 8th to bias away from the unfolded position. Advantageously, the first and the second spring 74 . 76 configured to the actuator 60 when moving the partition 8th between the folded and unfolded position. The second spring 76 is also configured to latch the latch 70 the partition 8th from the locking mechanism ejects when the catch 70 is released by the locking of the locking mechanism.

As in 5 Shown is the winding of the first spring 74 in an opposite direction to the winding of the second spring 76 executed.

The first end 74a . 76a each spiral spring 74 . 76 is stuck to a pin 35 the seat assembly structure 34 appropriate. The first end 74a . 76a includes a hollow sleeve 75 , where the sleeve 75 axially aligned with the coil of the spring and shaped to conform to the shape of the pin 35 is adjusted. The sleeve 75 is arranged so that the springs 74 . 76 sliding on a shaft of the pin 35 can be mounted so that the springs 74 . 76 sitting next to each other and in coaxial alignment with each other. In this way, the second spring 76 Side by side with the first spring 74 arranged such that an axis of rotation of the first spring 74 on a rotation axis of the second spring 76 is aligned.

As most clearly in 6 can be seen, the pin protrudes 35 the partition 8th orthogonal to the transversely facing surface of the inner arm 34a out, leaving the pin 35 at the pivot axis 33 the first seat assembly 19 is aligned. The pin 35 has a cross section in the form of a rectangle with rounded short sides. Accordingly, the shaft of the pin 35 two opposite rounded edges and two opposite flat edges. Due to this arrangement, the sleeve can 75 every spring 74 . 76 not in relation to the pin 35 Turn when torque is applied to the second end of the spring 74 . 76 is created.

The second end 74b . 76b each spiral spring 74 . 76 includes a curved flange 77 that is configured with a protruding element 78 the partition 8th in and out of engagement when the partition 8th is moved between the folded and unfolded position. Every spring 74 . 76 is configured to withstand the force generated by the protruding element 78 is exercised on them. In particular, each flange 77 configured so that the outer surface of each spring 74 . 76 a resistance to the protruding element 78 exerts when the spring 74 . 76 around the cone 35 rotates.

The flanges 77 be formed by the end of the spring 74 . 76 is folded in the opposite direction to the direction in which the coil of the spring has been wound. Accordingly, it is the outer surface of each spring 74 . 76 that is detachable with the protruding element 78 the partition 8th connected is.

According to the embodiment described herein, the flange is 74a the first spring 74 configured to work with the preceding element 78 to engage when the partition wall 8th moved away from the folded position and to the unfolded position, whereby the first spring 74 is charged. When the partition wall 8th moved away from the unfolded position and towards the folded position, the projecting element engages 78 in the flange 76a the second spring 76 one, making the second spring 76 is charged.

The flanges 77 are also configured to be the protruding element 78 disengage in a common disengaged position, wherein the disengagement between the folded and the unfolded position of the partition 8th is arranged. When the protruding element is in the disengaged position, no force is applied to the divider 8th through any of the two coil springs 74 . 76 exercised. The movement of the partition 8th and again the protruding element in one of the directions will cause one of the springs 74 . 76 is loaded, whereby a force is generated, which counteracts this movement.

That way are the flanges 77 configured to be the protruding element 78 effectively transfer when the partition 8th pivots between the unfolded and the folded position. Accordingly, the common disengagement position defines the first and second coil springs 74 . 76 a transfer position of the spring assembly 70 , In embodiments, the first and second springs have 74 . 76 each a different disengagement position, so that there is no single transfer position. Rather, the distance between the respective disengagement positions defines a "transfer area" in which the control of the movement of the partition wall 8th between the first and the second spring 74 . 76 is transmitted. In embodiments, the disengagement position of each spring may be separate so that no spring is arranged to engage the divider 8th to engage when moving across the transfer area. In this configuration, the movement of the partition wall 8th about the engagement area solely by the actuator 60 controlled. In alternative embodiments, the springs 74 . 76 be configured so that they simultaneously on the partition 8th act as it moves across the transfer area. For example, the first spring 74 Be configured so that it does not interfere with the divider 8th disengages until the second spring 76 started with her intervention. Accordingly, the springs 74 . 76 configured so that they at least partially work against each other when the partition 8th moved between the respective release positions.

For example, in 5 the protruding element 78 engaged with the flange 74a the first spring 74 shown when the partition 8th is arranged in the unfolded position. In this configuration, the first spring 74 by the force passing through the protruding element 78 is applied to them, charged counterclockwise. When the partition wall 8th moved away from the unfolded position and toward the folded position, the flange stops 74a at the point on, with the protruding element 78 to be engaged, on which the first spring 74 is completely discharged. Any further movement in the direction of the folded position begins with the loading of the second spring 76 ,

In this embodiment, the coil springs 74 . 76 also arranged so that the disengagement position of the partition 8th corresponds to a position in which the dividing wall 8th is arranged substantially in a vertical position. That is, the dividing wall 8th is in a substantially vertical position relative to the pivot axis 33 arranged, ie the center of gravity of the partition 8th is substantially vertical with the pivot axis 33 aligned.

The control system 3 also includes one or more switches (not shown) that support the divider drives 60 control, which in turn cause the movement of the respective components of the seat assemblies. Pressing a switch generates an electronic request signal representing the control system 3 activated to perform a relevant movement by a suitable operation of the electric motors.

The switches are located in a door closest to the respective seat assembly, allowing an occupant of the seat to enter control requests to actuate the relevant motor and thereby move the seat as desired. In embodiments, the switches may be disposed on any suitable interior surface of the vehicle, including, for example, an interior wall of the cargo space 4 for an occupant when opening a rear cargo door of the vehicle 6 is accessible.

The drives of the control system 3 communicating with a vehicle controller (not shown) configured to control the motors in response to input signals received from a human machine interface (MMS) of the vehicle. The MMS includes a touch screen device mounted in a dashboard of the vehicle. In alternative embodiments, the vehicle controller may be configured to receive input signals from a wirelessly connected device, such as an electronic key or a personal computer.

In order to enable the reader to understand the advantages associated with the control system of this embodiment, the operation of the control system becomes 3 with reference to the following 7a to 7c . 8a to 8c and the 9 described in more detail.

The 7a to 7c are side views of the second seat assembly 19 that the dividing wall 8th , the seat back 24 and the headrest 26 contain. Each of the 7a to 7c shows the second seat assembly 19 in successive stages of movement when the dividing wall 8th under the control of the control system 3 collapses.

In the first stage of the folding process, the in 7a is shown, is the partition 8th in the unfolded configuration. When activating the positioning system 3 by a suitable switch, which folds the seat assembly 19 controls, seizes the control system 3 appropriate action in the second stage by the partition 8th is moved to the vertical position on the way to the folded position, as in 7b shown. In the third stage, the in 7c shown is the partition 8th further pivoted forward beyond the vertical position to take the folded position. As already mentioned, that is in the 7a to 7c shown sequence is provided only as an example and many variations are possible.

The 8a to 8c show the reverse process, namely a pull-back sequence in which the partition 8th moved from a folded configuration into an unfolded configuration. In particular, the first stage of the in 8a withdrawal process shown the partition 8th in the folded configuration, in which they at the end of the folding process of 7a to 7c ends. Next, in the second stage, the partition wall 8th moved in the direction of the vertical position on its way to the unfolded position. In the third stage, the in 8c shown is the partition 8th pivoted to the rear to pass through a vertical position and return to the unfolded position.

9 Figure 11 shows the results of a computer simulation used to model the relative forces exerted by the control system 3 be exercised when the dividing wall 8th moved between the folded and unfolded position. 9 also shows how the torque passing through the bulkhead 8th on the components of the control system 3 is exercised, changes when the partition 8th moved between the folded and unfolded position.

With reference to 9 The dot-dash line labeled "seat torque" corresponds to the torque passing through the bulkhead 8th is exercised when it moves between the unfolded and folded position. The maximum positive torque (+80 Nm) coincides with the position in which the partition wall 8th is folded, ie when it is positioned at +65 degrees from the vertical. The maximum, negative torque (-60 Nm) coincides with the position in which the partition 8th is unfolded, ie when it is located at -45 degrees to the vertical. The change of the partition 8th applied torque is graphically in the 7a to 7c and 8a to 8c represented by hatched block arrows. In 7b you can see that is the dividing wall 8th is in the vertical position and thus the weight of the seat assembly 19 no net torque around the pivoting joint 54a exercises. The size and position of the arrow represents the relative displacement of the center of gravity of the partition 8th when moving away from the vertical position.

Returning to 9 The open dashed line, labeled "Lowering spring torque", corresponds to the combined power of the first and second springs 74 . 76 when the dividing wall 8th moved from the unfolded to the folded position. The solid dashed line labeled "increase in spring torque" corresponds to the combined performance of the springs 74 . 76 when the dividing wall 8th moved from the folded to the unfolded position. Although both line charts the combined power of the first and second spring 74 . 76 It should be noted that the above element 78 from one spring to the other is "handed over" when the partition 8th swings through the vertical position. Therefore, the positive torque values represent that of the first spring 74 applied torque and the negative torque values represent that of the second spring 76 applied torque. The offset between the graphs "Increase" and "Decrease" shows energy losses associated with loading and unloading the springs 74 . 76 are connected.

That of the feathers 74 . 76 applied torque is graphically in the 7a to 7c and 8a to 8c represented by the dashed arrows. It can be seen that the springs in the "transfer position" no torque on the partition 8th exercise. Conversely, the maximum torque corresponds to that of the springs 74 . 76 is exercised, the unfolded and folded position in which one of the springs is fully loaded. As in 9 can be seen, the first spring acts 74 when the dividing wall 8th moved from the unfolded position to the retracted position, first against the torque of the partition 8th to help with the dividing wall 8th to bring in the vertical position. The partition 8th is then to the second spring 76 Pass that against the wall 8th applied torque acts to lower the partition 8th to withstand the folded position. The reverse order is observed when the partition wall 8th moved from the folded position to the unfolded position.

The partition 8th is pivoted clockwise +65 degrees from the vertical when it is in the folded position. In contrast, the partition wall 8th pivoted -45 degrees from the vertical counterclockwise when it assumes the unfolded position, as in 7a shown. A corresponding torque is applied to the respective coil spring in each position due to the size of a weight component of the partition 8th created by the hatched block arrows in the 7a to 7c and 8a to 8c is shown, which acts to the partition 8th to move. Consequently, the maximum torque that is applied to the first coil spring 74 greater than the maximum torque applied to the second coil spring 76 is created.

The coil of the first coil spring 74 includes two complete turns, while the coil of the second coil spring 76 includes three complete turns. This allows the second coil spring 76 stores more energy than the first coil spring 74 , Thus, the second coil spring 76 more effective the torque of the partition 8th Counteract that is greater in the folded position than in the unfolded. Once the partition 8th is arranged in the folded position, it can not alone by the torque of the second spring 76 be moved from the folded position. The mechanical resistance of the actuator 60 together with the gear assembly acts to the effect of the movement of the partition 8th so that it remains in the folded position until the actuator 60 configured to unfold the seat assembly. In alternative embodiments, the partition may be replaced by the actuator 60 be actively held in position with a holding current is supplied to prevent it from reversing.

In 9 you can see that the change of the springs 74 . 76 applied torque roughly reflects the change in torque passing through the bulkhead 8th on the control system 3 is exercised. In fact, the springs are 74 . 76 configured to provide greater torque than the bulkhead 8th exercise, so the actuator 60 a counter torque against the first and the second spring 74 . 76 must exercise, so the partition 8th each can reach the unfolded and folded position. This is the actuator 60 configured to each spring 74 . 76 to load by the dividing wall 8th is moved to the unfolded and unfolded position.

Referring again to 9 The open solid line, labeled "Actuator Torque Reduction", corresponds to the output of the actuator 60 when the dividing wall 8th moved from the unfolded position to the folded position. The solid dashed line, labeled "increase the actuator torque", corresponds to the actuator's performance 60 when the dividing wall 8th moved from the folded to the unfolded position. The change of the actuator 60 applied torque is graphically in the 7a to 7c and 8a to 8c represented by the arrows of the solid black line. With particular reference to the 7a to 7c supports the actuator 60 initially the first spring 74 to help create the dividing wall 8th to bring in the vertical position when the partition 8th moved from the unfolded position to the folded position. The initial tip in the performance of the actuator 60 , in the 9 is shown, corresponds to the lifting of the partition wall catch 70 from the locking mechanism. If the partition 8th swings through the transfer position, the actuator operates 60 with the weight of the partition 8th together to the second spring 76 to load while holding the partition 8th lowered into the folded position.

The reverse order is observed when the partition wall 8th moved from the folded position to the unfolded position. In particular, when the partition 8th moved from the folded position to the unfolded position, supports the actuator 60 the second spring 76 to help with the dividing wall 8th to bring in the vertical position. If the partition 8th swings through the transfer position, the actuator operates 60 initially with the weight of the dividing wall 8th to the first spring 74 to load while holding the partition 8th moved to the unfolded position. When the catch 70 the partition 8th engages the locking mechanism, the actuator can 60 Apply a positive torque with the first spring 74 acts to ensure that the locking mechanism is the dividing wall 8th securely fastened in position.

Referring again to the diagram in FIG 9 run the hollow and solid dotted lines that represent the torque, each of the first and the second spring 74 . 76 is exercised by the same point on the x -Axis. The crossing point represents a single transfer position between the first and second springs 74 . 76 The chained line, which represents the seat torque, also crosses the x Axis at the same point of the graph. This represents the point at which the dividing wall 8th passes through the vertical. In the vertical position is the weight of the partition 8th Centered over the pivot so that no positive or negative torque is exerted on the hinge assembly. Therefore, the spring mechanism is configured so that its transfer position coincides with the point at which the partition wall 8th goes through the vertical position. In alternative embodiments, the spring mechanism may be arranged so that the transfer position occurs when the partition wall 8th is arranged substantially from the vertical position to the front or rear.

In summary, the positioning of the partition 8th between the unfolded and folded position by actuation of an actuator 60 in conjunction with a complementary spring arrangement 70 reached. The actuator 60 and the spring arrangement 70 work together to control the movement of the partition 8th to control. In particular, it allows by the spring arrangement 70 offered support that the performance of the actuator 60 remains almost constant when the dividing wall 8th moved between the unfolded and the folded position. By modulating the power of the actuator 60 allow the springs 74 . 76 that the actuator 60 quieter, thereby creating a more comfortable and relaxed environment for the passengers sitting in the vehicle cabin. The modulation of the power of the actuator also extends its life.

According to embodiments of the present invention, the positioning system comprises 3 also a seat back drive 25 for any movable seat assembly, as in 4 shown. Every seatback drive 25 is configured to apply appropriate forces to each of the seat backrests 24 to rotate around a seat back rotation axis. In this way, the seat backs 24 relative to the partition 8th each seat assembly pivoted so that they can be arranged in a number of seating configurations, including an extended position and a reclined position. In the extended position is an upper portion of the seat back in front of the partition 8th pivoted and in the reclined position, the upper portion of the seat back is in the direction of the partition wall 8th pivoted. In such embodiments, each adjustment system may 3 Also include a seat spring assembly that is configured to be a modulation of the seat back drives 24 Required power to allow for the movement of the seat backrests 24 to control. The seat back drives 25 are identical in this example with the dividing wall drives 60 although they may differ in other implementations, for example, when different levels of torque are required to seat backs 24 and the partition 8th to fold.

Claims (12)

A positioning system for a movable vehicle seat assembly, the system comprising: an actuator controllable to pivotally move a first component of the seat assembly relative to a second component of the seat assembly, the first component including a seat back and the actuator arranged to move the first component about a pivot axis relative to the second component to pivot a first position and a second position; a first spring configured to bias the first component away from the second position; and a second spring configured to bias the first component away from the first position; wherein the first spring is configured to terminate the biasing of the first component at a third position, the third position being between the first position and the second position; wherein the second spring is configured to terminate the biasing of the first component at a fourth position, wherein the fourth position is between the first position and the second position. Actuation system after Claim 1 wherein the first spring is configured to disengage the first component at the third position, the first spring optionally having a first end configured to engage the second component of the seat assembly and a second end configured. to releasably engage the first component, the second end optionally including a flange, wherein the flange is configured to engage and / or disengage a protruding member of the first component. Actuation system after Claim 1 or Claim 2 wherein at least one of the first and second springs is a coil spring; optionally, wherein the first spring and the second spring are wound in opposite directions; optionally, wherein the second spring is disposed side by side with the first spring and wherein a drill axis of the first spring is aligned with a drill axis of the second spring. Positioning system according to one of the preceding claims, wherein: the fourth position is between the first position and the third position; or the fourth position substantially coincides with the third position such that the third and fourth positions together define a transfer position in which the component is transferred between the first and second springs. A positioning system according to any one of the preceding claims, wherein the third and fourth positions define a transfer area and the first component is substantially orthogonal to a seat cushion of the seat assembly and / or wherein the first component is in a substantially vertical position when in the transfer area located. A positioning system according to any one of the preceding claims, wherein the second spring comprises: a first end adapted to engage the second component of the seat assembly and a second end adapted to releasably engage the first component, the second end being optional a flange, wherein the flange is configured to engage and / or disengage a protruding member of the first component, wherein the first and second springs are optionally configured to releasably engage the protruding member , A positioning system according to any one of the preceding claims, wherein the first spring is configured to store more energy than the second spring. A positioning system according to any one of the preceding claims, wherein the actuator comprises an electric motor and the electric motor is configured to receive substantially constant force as it moves the first component between the first position and the second position. A moveable seat assembly having a first component, a second component, and a positioning system according to any one of the preceding claims, wherein the first component includes a seat back and the actuator is controllable to move the first component between a first position and a second position relative to the second component to move. Movable seat assembly after Claim 8 wherein the first position defines a collapsed position of the first component and the second position defines an unfolded position of the first component, wherein the movable seat assembly optionally includes a latch mechanism arranged to secure the first component in the deployed position, and the first spring is configured to eject the first component from the locking mechanism. Movable seat assembly after Claim 10 wherein the second spring is configured to substantially equalize the weight of the first component when the first component is disposed in the unfolded position. Vehicle with a parking system according to one of Claims 1 to 7 and / or a movable seat assembly according to any one of Claims 8 to 11 ,

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