Retractable handle arrangement

Abstract

A retractable handle arrangement comprising a handle comprising a first end and a second end and being movable between stowed and deployed positions; the handle being pivotally mounted about a handle pivot axis disposed between the first and second ends; an operating member extending from the handle; a first lever arm for moving the handle from the stowed position to the deployed position; a second lever arm for operating a release mechanism in response to movement of the handle from the deployed position to an operative position; and a drive mechanism; wherein the drive mechanism is coupled to the first lever arm and operable, in use, to cause the first lever arm to operatively engage with the operating member to move the handle from the stowed position to the deployed position; and wherein the operating member is arranged to operatively engage with the second lever arm when the handle is moved from the deployed position to an operative position.

Claims

1. A retractable handle arrangement comprising: a handle comprising a first end and a second end and being movable between stowed and deployed positions; the handle comprising a longitudinal axis extending between the first and second ends and being pivotally mounted about a handle pivot axis disposed between the first and second ends such that the pivot axis is arranged transversely to the longitudinal axis; an operating member extending from the handle; a first lever arm for pivotally moving the handle about the pivot axis from the stowed position to the deployed position; a second lever arm for operating a release mechanism in response to movement of the handle about the pivot axis from the deployed position to an operative position; and a drive mechanism; wherein the drive mechanism is coupled to the first lever arm and operable, in use, to cause the first lever arm to abut the operating member to move the handle from the stowed position to the deployed position; and wherein the operating member is arranged to abut the second lever arm when the handle is moved from the deployed position to an operative position.

2. A retractable handle arrangement according to claim 1, wherein the first lever arm is pivotally mounted about a first lever pivot axis on a first side of the operating member.

3. A retractable handle arrangement according to claim 1, wherein the second lever arm is pivotally mounted about a second lever pivot axis on a second side of the operating member.

4. A retractable handle arrangement according to claim 1, wherein the operating member extends substantially perpendicularly to the handle.

5. A retractable handle arrangement according to claim 1, wherein the drive mechanism comprises a motor and transmission means for coupling the motor to the first lever arm.

6. A retractable handle arrangement according to claim 1, comprising a return spring arranged so as to bias the handle toward the stowed position.

7. A retractable handle arrangement according to claim 1, comprising a return spring arranged so as to bias the second lever arm toward a latched position.

8. A retractable handle arrangement according to claim 1, comprising: a sensor for detecting a force applied to the handle when in the deployed position, which force is directed so as to urge the handle into the stowed position; wherein upon detecting the force the drive mechanism is configured to move the handle from the deployed position to the stowed position.

9. A retractable handle arrangement according to claim 1, wherein the handle pivot axis extends through and is disposed within the handle.

10. A retractable handle arrangement according to claim 1, wherein the handle is coupled to the drive mechanism such that the handle may be moved from the stowed position to the deployed position manually, independently of the drive mechanism.

11. A retractable handle arrangement according to claim 1, wherein the handle arrangement comprises a key barrel for receiving a key blade, wherein the key barrel is disposed behind the handle such that the handle conceals the key barrel in the stowed position.

12. A retractable handle arrangement according to claim 11, the handle pivot axis being arranged such that the key barrel remains substantially behind the handle in the stowed position and the key barrel and handle are disposed in the same plane which plane is substantially perpendicular to a plane comprising the handle pivot axis.

13. A retractable handle arrangement according to claim 1, comprising: a sensor for detecting a force applied to the handle when in the stowed position, which force is directed so as to urge the handle into the deployed position; wherein upon detecting the force the handle arrangement is arranged to move the handle from the stowed position to the deployed position.

14. A retractable handle arrangement according to claim 1, comprising: a sensor for detecting a force applied to the handle when in the stowed position, which force is directed so as to urge the handle inwardly in a direction away from the deployed position; wherein upon detecting the force the handle arrangement is arranged to move the handle from the stowed position to the deployed position.

15. A vehicle having a plurality of doors or other closures each of which comprises a retractable handle arrangement according to claim 1, wherein a control unit is coupled to all of the handle arrangements provided on the vehicle.

16. A vehicle according to claim 15 wherein the control unit is arranged to determine whether to move one or all of the handle arrangements from the deployed position to the stowed position based upon a parameter of the force applied to one or more of the handles when in the deployed position and control the drive mechanism of each handle arrangement accordingly.

17. A vehicle according to claim 15, wherein the vehicle comprises a locking mechanism on each of the doors or other closures, and further wherein the control unit is arranged to activate the locking mechanism so as to lock one or all of the doors or other closures based upon a parameter of the force applied to one of the handles.

18. A vehicle according to claim 17, wherein the parameter is one of the following: duration of the force; magnitude of the force; direction of the force; and number of times force is applied.

19. A vehicle having a handle arrangement as claimed in claim 1.

20. A vehicle according to claim 19 comprising one or more doors and wherein a handle acts as a lock status indicator for each individual door.

21. A retractable handle arrangement according to claim 1, wherein the handle pivot axis is arranged substantially perpendicularly to the longitudinal axis.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

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

(2) FIG. 1 is a perspective view from above of part of the exterior of a vehicle door fitted with a door handle arrangement in accordance with an embodiment of the present invention, the door handle being shown in a stowed state;

(3) FIG. 2 is a front plan view of the mechanism of the door handle arrangement of FIG. 1, with the door handle in the slowed state;

(4) FIG. 3 is rear plan view of the mechanism of the door handle arrangement of FIG. 1, with the door handle in a stowed state;

(5) FIG. 4 is top plan view of the mechanism of the door handle arrangement of FIG. 1, with the door handle in the deployed state;

(6) FIG. 5 is rear plan view of the mechanism of the doer handle arrangement of FIG. 1, with the door handle in the deployed state;

(7) FIG. 6 is perspective view from below of the mechanism of the door handle arrangement of FIG. 1, with the door handle in the deployed state;

(8) FIG. 7 is a top plan view of the mechanism of the door handle arrangement of FIG. 1, with the door handle in the operative state;

(9) FIG. 8 is rear plan view of the mechanism of the door handle arrangement of FIG. 1, with the door handle in the operative state;

(10) FIG. 9 is perspective view from below of the mechanism of the door handle arrangement of FIG. 1, with the door handle in the deployed state; and

(11) FIG. 10 shows schematically an embodiment of a system for controlling the operation of the retractable handle arrangement of FIG. 1.

DETAILED DESCRIPTION

(12) Detailed descriptions of specific embodiments of a handle arrangement, a method and a vehicle of the present invention are disclosed herein. It will be understood that the disclosed embodiments are merely examples of the way in which certain aspects of the invention can be implemented and do not represent an exhaustive list of all of the ways the invention may be embodied. Indeed, it will be understood that the handle arrangement, method and the vehicle described herein may be embodied in various and alternative forms. The figures are not necessarily to scale and some features may be exaggerated or minimised to show details of particular components. Well-known components, materials or methods are not necessarily described in great detail in order to avoid obscuring the present disclosure. Any specific structural and functional details disclosed herein are not to be interpreted as limiting, but merely as a basis for the claims and as a representative basis for teaching one skilled in the art to variously employ the invention.

(13) Referring to FIG. 1 in a door handle arrangement 1 of one embodiment of the invention, a flush-mounted door handle 10 is retractable with respect to a door of a vehicle. A painted door skin 12 is shown here to represent the door. The retractable handle arrangement 1 provides a handle 10 which is operable to be deployed automatically, or manually, in response to a user interaction; the handle 10 is deployed to a deployed position from a stowed condition. Once in a deployed position, or at least partially deployed position, the handle 10 is operable to be moved to an operative position to release a door latch. When the handle 10 is in the deployed position the door is unlocked.

(14) The door skin 12 is penetrated by a horizontally-extending slot 14 that receives the handle 10 as a close fit. The outer surface 18 of the handle 10 is shaped to match the slot 14 and lies flush with the surrounding door skin 12 when the handle 10 is stowed as shown in FIG. 1. The shape of the slot 14 and of the outer surface 16 of the handle 10 is chosen for aesthetic reasons and is largely immaterial in terms of function.

(15) Whilst shown in a contrasting tone for clarity in the drawings, at least the outer surface 16 of the handle 10, and possibly the entire handle 10, is painted in the same colour as the vehicle body. Other finishes may, of course, be chosen instead, again for aesthetic reasons.

(16) Referring to FIGS. 2, 3 and 4, the retractable handle arrangement 1 comprises a mechanism 18 which is operable to move the handle 10 between the stowed state (herein also referred to as a stowed condition and stowed position) and a deployed state (herein also referred to as a deployed condition and deployed position), as will be described in more detail later.

(17) The handle 10 is provided in a housing 3, the housing 3 having an aperture for receiving the handle 10. A sealing element 4 is provided to form a seal between the handle 10 and the housing 3 and/or the door skin 12. The handle 10 is an elongate member having first and second ends 20, 22. Pivot means 24 is disposed proximate to the first end 20 and defines an axis about which the handle 10 is rotatable, when the handle 10 moves between the stowed and deployed states. In some embodiments a return spring 26 is provided on the pivot means 24 so as to bias the handle 10 toward the stowed position. An operating member 28 projects perpendicularly from an inner surface of the handle 10, which inner surface is disposed opposite the outer surface 16. The operating member 28 is disposed at substantially the same distance along the length of the handle 10 from the first end 20 as the pivot means 24.

(18) The mechanism 18 comprises a motor 30 which is coupled to transmission means 32. The transmission means 32 comprises a piston 34 and a lever arm 38. The piston 34 may be surrounded by an expandable sealing member 36 to prevent or reduce ingress of dirt or moisture into the motor 30, the sealing member 36 may also serve to retain a lubricant such as grease. The piston 34 may be coupled to the motor 30 by a rack, crank mechanism or cam, when a rack is employed a pinion gear or worm gear may be used to drive the rack linearly. The advantage of employing a earn mechanism is that the force and the speed with which the piston 34 is extended or retracted can be controlled or modulated. In alternative embodiments the lever arm 38 may be coupled directly to a cam mechanism. GB1110487.4, and PCT/EP2012/062040, in the name of the same applicant and titled RETRACTABLE HANDLE ARRANGEMENT FOR A DOOR OR THE LIKE, the contents of which are incorporated herein in their entirety, discloses such a cam mechanism, suitable for pivotally moving lever arm 38.

(19) The lever arm 38 has first and second ends 44, 46 and is pivotally mounted about a lever axis 40 which is at least substantially perpendicular to the direction of travel of the piston 34. The lever axis 40 is disposed toward the second end 46, substantially at or proximate the second end 486 of the lever arm 38. The piston 34 abuts a first surface of the lever arm 38 substantially at or proximate the first end 44 of the lever arm 38. The operating member 28 of the handle 10 abuts the lever arm 38 between the lever axis 40 and the first end 44 of the lever arm 38. The operating member 28 of the handle 10 abuts the lever arm 38 on a second surface of the lever arm 38 opposing the first surface; the point of contact between the operating member 28 of the handle 10 and the lever arm 38 is disposed towards the second end 46 of the lever arm 38.

(20) The lever arm 38 is biased against the piston 34 by a return spring 17, as shown in FIG. 4, such that the lever arm 38 is biased to return to a stowed position. In some embodiments the return spring 17 is configured and arranged to engage with the operating member 28 and biases the operating member 28 against the lever arm 38 such that both the lever arm 38 and operating member 28 are biased to return to a stowed position by the return spring 17.

(21) The retractable handle arrangement 1 comprises a second lever arm 42; second lever arm 42 is disposed on an opposing side of the operating member 28 to that of the lever arm 38. The second lever arm 42 has first and second ends 43, 47 and is pivotally mounted about a lever axis 41 which is substantially perpendicular to the direction of travel of the piston 34. The lever axis 41 is disposed toward the second end 47, substantially at or proximate the second end 47, of the lever arm 42.

(22) In some embodiments, in the stowed condition the second lever arm 42 is spaced apart from the operating member 28, that is to say they are not in physical contact. When the handle 10 is deployed to the deployed position the operating member 28 is rotated such that it is substantially brought into contact, or at least close proximity, with a portion of the second lever arm 42. In alternative embodiments, the second lever arm 42 is biased against the operating member 28, by a return spring is when in the stowed condition; the return spring 19 facilitates returning the handle 10 to the stowed condition since the second lever arm 42 acts upon the operating member 28. In other embodiments the second Sever arm 42 is only biased against the operating member 28 when the handle 10 and hence the operating member 28 are moved from the deployed state to the operative condition. The retractable handle arrangement 1 may comprises an end stop which prevents the second lever arm 42 acting against the operating member 28 when returning from the deployed state to the stowed state.

(23) In the deployed position the operating member 28 of the handle 10 substantially abuts the second lever arm 42 between lever axis 41 and first end 43 of the lever arm 42. The point of contact where the operating member 28 of the handle 10 abuts second Sever arm 42 is disposed towards the second end 47 of the second lever arm 42.

(24) An aperture A1 is provided in the second lever arm 42; aperture A1 is disposed substantially at the first end 43 of the second lever arm 42. Aperture A1 is coupled to a coupling member 74 such as a Bowden cable (shown in FIG. 8) which coupling member 74 is coupled to a door latch (not shown).

(25) It will be appreciated that lever arm 38 forms a second class lever, whereas second lever arm 42 forms a third class lever.

(26) The retractable handle arrangement 1 comprises a plurality of micro-switches M1, M2, M3, M4. The micro-switches M1, M2, M3, M4, and switch 15, are electrically coupled to a control module 54 (see FIG. 10) by a wiring harness 7.

(27) Micro-switch M1 is mounted upon the lever arm 38 towards the first end 44; a spring mechanism 45 is mounted on the lever arm 38 and is disposed between the micro-switch M1 and the piston 34. When the handle 10 is in a deployed condition the micro-switch M1 is activated by a user exerting a force upon the handle 10 in a direction so as to push the handle towards the stowed condition. As a consequence the spring mechanism 45 is pushed against the end of piston 34 and in turn the spring mechanism is acts upon micro-switch M1. The spring mechanism 45 provides haptic feedback to the user to inform the user that the switch has been activated in some embodiments an audible click as the spring mechanism 45 returns to its unbiased condition may also provide feedback to the user. In response to activation of the micro-switch M1, the control module 54 is configured and arranged to instruct the handle arrangement 1 to return the handle 10 to the stowed position and to lock the door. In some embodiments the retractable handle arrangement may provide visual feedback in addition, or in the alternative, to aural or haptic feedback, for example by activating a light mounted on the retractable handle arrangement or elsewhere on the vehicle. In some embodiments the aural feedback may fake the form of an electronic beep or other noise, this may be generated by a security system mounted on the vehicle for example.

(28) Micro-switch M2 is a limit switch, and is activated by the lever arm 38 when the Sever arm 38 is driven to the deployed position. When the micro-switch M2 is activated the control module 54 is configured and arranged to instruct the motor 30 to stop extending the piston 34.

(29) Micro-switch M3 is a limit switch, and is activated by the lever arm 38 when the lever arm 38 is returned to the stowed position. When the micro-switch M3 is activated the control module 54 is configured and arranged to instruct the motor 30 to stop retracting the piston 34.

(30) Micro-switch M4 is optional, and may be used to activate a function as, or before, the handle 10 is moved from the deployed position to the operative position; for example micro-switch M4 may be provided on vehicles which comprise frameless door windows, (such windows generally extend into the vehicle body or frame to form a seal; in order to open the door it is necessary to withdraw the window from the vehicle body or frame, by at least partially retracting the window into the door). When the micro-switch M4 is activated the control module 54 is configured and arranged to instruct, to instruct the window system to retract the window into the door.

(31) In alternative embodiments the microswitch M4 may be omitted, the system may be programmed to detect a request for deployment of the door handle 10 to the deployed state and initiate movement of the door window to withdraw the window from the vehicle body or frame. Alternatively, upon receiving an instruction to deploy the handle 10, the system may be configured to send an instruction to an actuator provided for partially refracting or dropping the door window sufficient to allow the door to be opened. The same actuator may be used for deploying the handle and for partially retracting or dropping the door window sufficient to allow the door to be opened. In which case the window may be partially retracted or dropped automatically when the handle is deployed. In such embodiments if is envisaged that the door window would be retracted before the handle 10 reached fully deployed slate, thus reducing the likelihood of a user opening the door whilst the door window is raised up within the vehicle body or frame.

(32) In the stowed state illustrated in FIGS. 1, 2 and 3, the outer surface 16 of the handle 10 lies flush with the surrounding door skin 12. The handle 10 may be automatically driven from its stowed state to its deployed state in response to various events. For example, this movement may be in response to an unlocking signal from a key authorised to unlock the vehicle or from a presence sensor that detects the presence of an authorised key in the immediate vicinity of the vehicle. Conversely, the handle 10 may be automatically driven, or biased to return, from its deployed state to its stowed state in response to a locking signal from a key authorised to lock the vehicle or from a presence sensor that determines that the authorised key has left the immediate vicinity of the vehicle. The handle 10 may also toggle between the stowed and deployed states in response to a further action from the user, for example pressing a switch (not shown in FIG. 1) on the vehicle door.

(33) Referring to FIGS. 4, 5 and 6, in its deployed state, the handle 10 is rotated about the pivot means 24 against the biasing force of the return spring 17 and/or return spring 26 such that the second end 22 of the handle protrudes torn the slot 14 (not shown in FIGS. 4, 5 and 6) by en amount sufficient to allow a user to put their fingers around the handle 10.

(34) In the embodiment of the invention shown in FIGS. 4, 5 and 6, the retractable handle arrangement 1 comprises a top cover portion 72 which extends substantially perpendicular to the inner surface along the length of the handle 10 and along a portion of the second end 22.

(35) The presence of the top cover portion 72 requires a user to grasp the handle 10 with an underhand grip in order to open the associated door. An advantage of this handle configuration over the bar-type handle described previously is that the fop cover portion 72 may prevent items, such as clothing, bag straps, etc. from becoming looped over the handle 10 when it is in the deployed state. Accordingly, such a handle offers an improved safety aspect.

(36) As explained previously, when the handle 10 is in the operative state, this causes the door to be opened. The operative state, as shown in FIGS. 7, 8 and 9 corresponds to a position in which the handle 10 is further rotated about the pivot means 24 beyond the deployed state.

(37) The operation of the retractable handle arrangement 1 will now be described in more detail.

(38) Referring to FIGS. 3, 4, and 5, with the handle 10 in the stowed state, the lever arm 38 and second lever arm 42 are disposed substantially vertically. The return spring 26 and/or return spring 17 acts to bias the handle 10 towards the stowed state. Accordingly, the operating member 28 of the handle 10 presses against the lever arm 38 which, in turn, causes the first end 44 of the lever arm 38 to press against the piston 34. In order to deploy the handle 10, the motor 30 is driven to extend the piston 34 such that the piston 34 is extended in the direction of arrow D1 as shown in FIG. 5.

(39) Referring to FIGS. 4, 5 and 6, extension of the piston 34 causes the lever arm 38 to be pivoted about the lever axis 40. The first end 44 of the lever arm 33 moves in the direction of the arrow D2, as shown in FIG. 5. The lever arm 38 presses against the operating member 28 of the handle 10 thereby-causing the handle 10 to rotate about its pivot means 24 in the direction of arrow D3, as shown in FIG. 4, until it reaches the deployed position at which point the micro-switch M3 is activated and the motor 30 stops.

(40) The motor 30 and lever arm 38 are selected so as to be sufficient to break through any ice, in the event that the handle 10 is subjected to wet and freezing conditions (the required force may be about 200 N).

(41) In order to retract the handle 10 from the deployed state back into the stowed state, the motor 30 is driven in reverse which, in turn, retracts the piston 34 in the direction opposite to arrow D1 in FIG. 5. The biasing force of the return spring 26 and or return spring 17 causes the handle 10 to move toward the stowed state. As the handle 10 retracts, the operating member 28 causes the lever arm 38 to rotate back to its initial position shown in FIG. 3. Accordingly, during retraction of the handle 10, although the motor 30 is driven, the mechanism 18 does not exert a closing force on the handle 10. This is advantageous because, in the event that a user is holding the handle 10 as it retracts, the force against the user's hand is limited to that of the return springs 26, 17.

(42) A user may initiate refraction of the handle 10 by pressing on the handle between the second end 22 and the pivot point 24 so as to activate the micro-switch M1.

(43) The speed at which the handle is deployed may be varied by adjusting the speed of the motor 30; this may be achieved by reducing the voltage supply to the motor 30. In some embodiments this is achieved by modulating the voltage supply with a signal effectively turning the voltage supply on and off thereby reducing the effective voltage across the motor 30. During en initial deployment phase, the handle 10 moves relatively slowly. In a second deployment phase, the voltage supply is increased. This results in the handle 10 being moved at a higher speed.

(44) In a further embodiment of the present invention, the voltage supply may be modulated such that there is a third deployment phase of the handle 10. In more detail, the voltage supply is decreased after the second deployment phase. Accordingly, after the handle 10 is moved quickly during the second phase, it slows down gradually during the third phase until it stops in the deployed state, thereby producing a pleasing aesthetic effect.

(45) It will be appreciated by those skilled in the art that, whilst the above description refers to initial, second and third deployment phases, the voltage supply may be modulated such that the transitions between each of the deployment phases are continuous.

(46) Referring to FIGS. 7, 8 and 9, in order to open the door a user operates the handle 10 by pivoting the handle 10 about the pivot means 24; the user pulls the second end 22 of the handle 10 in the direction indicated by direction arrow D4 until the handle 10 reaches an operative position. In doing so the operating member 28 rotates in the direction indicated by direction arrow D5 and engages with the second lever arm 42, pivotally moving the second lever arm 42 about the pivot axis 41 in the direction indicated by direction arrow D6. Thus the second lever arm 42 pulls the coupling member 74 thereby releasing the door latch. Coupling member 74 is mounted on the housing 3 by clips 8, 9. When the user releases the handle 10 the return spring 19 acts upon the second lever arm 42 to return the second lever 42 to the deployed position and in doing se the second lever 42 acts upon the operating member 28 to return the handle 10 to the deployed position. The operating member 28 return to the deployed position in which position the operating member 28 is in contact with the lever arm 38.

(47) Referring again to FIG. 2, the handle 10 may also comprise an unlock button 49 disposed on the outer surface 16 thereof, the unlock button 49 is coupled to a switch or sensor 15. The unlock button 49 may be touch sensitive buttons, i.e. capacitive sensors, or if may be a micro-switches. The full functionality of the unlock button 49 will be described in more detail later. However, the position of the unlock button 49 on the handle 10 is selected so as to be both intuitive for the user and to reduce the possibility of incorrect use of the handle arrangement 1.

(48) The unlock button 49 is disposed adjacent to the first end 20 of the handle 10. As mentioned previously when a user operates the handle 10 the users thumb will typically be at the first end 20. Thus, when a user presses the unlock button 49 with their thumb, which unlocks the associated door and causes the handle 10 to be moved into the deployed state, their hand is naturally positioned such that it is easy and convenient for them to grasp the deployed handle 10 and open the door by pulling it to the operative position.

(49) Furthermore, the unlock button 49 is advantageously positioned in the event that a user is required to deploy the handle 10 manually, for example, if there is a loss of power to the motor 30, in this case, as the user applies pressure to the unlock button 49, the associated door will be unlocked as before. Subsequently, as the user applies increased pressure on the unlock button 49, the handle 10 will be rotated about the pivot means 24 against the biasing force of the return spring 26. Once the second end 22 of the handle protrudes from the slot 14, the user can grasp the handle 10 and pull it to the operative state to open the door. Accordingly, the handle 10 can be manually deployed by a user simply applying pressure at the unlock button 49, without requiring any more complex actions which require a greater degree of dexterity. The user may deploy the handle 10 with a single hand, for example by application of a force to the handle 10 between the first end 20 and the pivot point 24 with a thumb of one hand and then subsequently grasping or pulling the handle 10 between the second end 22 and the pivot point 24 with one or more fingers of the same hand to operate the handle 10. The handle 10 may be moved from the stowed position of the deployed condition either manually or automatically.

(50) In an alternative embodiment the unlock button 49 may be located proximate to the second end 22, the user may deploy and operate the handle 10 with a single hand; the user may press the unlock button 49 with a thumb such that the handle 10 is deployed automatically, the user may subsequently grasp the handle 10 between the second end 22 and the pivot point 24 with one or more fingers of the same hand to operate the handle 10.

(51) In the embodiment illustrated in FIG. 2 the pivot point 24 is located closer to the first end 20 than to the second end 22, it is envisaged that the first end 20 would be disposed forwardmost with respect to the vehicle and a user when employing single handed operation would engage the handle 10 with an underhand grip in other words from below with their right hand.

(52) In other embodiments other configurations ere envisaged, for example, but not limited to, the pivot point 24 may be located closer to the first end 20 than to the second end 22 and the second end 22 may be disposed forwardmost, a user when employing single handed operation would engage the handle 10 with an overhand grip in other words from above with their right hand. Alternatively, the pivot point 24 may be located closer to the second end 22 than to the first end 20, it is envisaged that the first end 20 may be disposed forwardmost, a user when employing single handed operation would engage the handle 10 with an underhand grip in other words from below with their left hand. In a further alternative the pivot point 24 may be located closer to the second end 22 than to the first end 20, it is envisaged that the second end 22 may be disposed forwardmost with respect to the vehicle, a user when employing single handed operation would engage the handle 10 with an overhand grip in other words from above with their left hand.

(53) Furthermore, with the above described arrangement, the functions of the unlock button 49 will be intuitive to a user unfamiliar with the operation of the handle arrangement 1. In particular, the position of the unlock button 49 at the first end 20 of the handle 10 will be associated in the mind of the user with opening the door because pressure at this position on the handle 10 causes the handle 10 to move from the stowed to the deployed state. In order to operate the look function the user need only press the handle 10 towards the stowed position, the spring mechanism 45 allows a predefined degree of movement of the handle 10 during which movement the force transferred to the piston 34 and motor 30 is limited, thereby reducing the likelihood of damage to the piston 34, motor 30 and/or drive mechanism therebetween.

(54) Referring to FIG. 10, a system for controlling a retractable handle arrangement 1 of the kind described above comprises a control module 54 for controlling the mechanism 18 of each retractable handle arrangement 1 on a vehicle. Although only a single handle arrangement is shown in FIG. 7, it will be appreciated that each door of the vehicle may be provided with a retractable handle arrangement 1.

(55) The control module 54 is also coupled to a wireless communication module 50, a vehicle speed sensor 58, a vehicle alarm system 60, door lock and unlock controls in the vehicle cabin 62, a handle light 84 and a door ajar switch 66. The wireless communication module 56 is operable to receive signals from a vehicle key fob 68. The key fob 26 is provided with respective door lock and unlock buttons and means for transmitting respective lock and unlock signals to the wireless communication module 56 in response to a user pressing the relevant button. The wireless communication module 56 is also operable to detect the presence of a smart key 70 within a target distance from the vehicle (typically 1-2 m) to enable passive entry. Also, the drivers door of the vehicle can be mechanically locked or unlocked from outside the vehicle via a key barrel 50 optionally positioned underneath the driver's door handle. Thus, the key barrel 50 will be revealed any time the handle is moved to the deployed or operative state. The key barrel 50 is coupled to the door lock (or other function) of the vehicle by a coupling element 75 such as a Bowden cable mounted to one end of a lock lever 51. The key barrel 50 passes through an aperture in the housing 3; the lock lever 51 is mounted to an internal end of the key barrel 50.

(56) Each retractable handle arrangement 1 may comprise a light 64, such as an LED, for illuminating the handle 10 and its immediate surroundings so as to facilitate the opening of the doors in low-light conditions. In some embodiments the LED may be mounted to an inner surface of the handle 10 proximate a lower edge of the handle 10 and be configured to point downwardly, away from top cover portion 72. In yet other embodiments the LED is mounted in a different location as packaging space allows, a fibre optic cable or other suitable light channeling device is coupled atone end to the LED. The other end of the fibre optic cable is mounted to an inner surface of the handle 10 proximate a lower edge of the handle 10 and is configured to point downwardly, away from top cover portion 72. Each retractable handle arrangement 1 may also comprise a pair of limit switches for detecting when the handle 10 is in each of the stowed and deployed states.

(57) The operation of the control module 54 will now be described in more detail.

(58) When the vehicle is parked, each handle 10 is in the stowed state, i.e. flush with the door skin 12, when its associated door is locked, and each handle 10 is in the deployed slate when its associated door is unlocked. Deployment of the handle 10 is thus triggered by unlocking; and refraction of the handle 10 is triggered by locking.

(59) Looking and unlocking are triggered by either using the lock and unlock, buttons on the key fob 68 or by the passive entry unlock button 49 provided on each handle 10 and activating the micro-switch M1 by pushing the handle 10. Optionally, a lock button (not shown) may be provided en the handle, the lock button may be located en the outer surface 16 of the handle substantially at the point at which the handle 10 pivots. More specifically, for access via passive entry, the user carries the smart key 70 on their person. When the smart key 70 is within a target range of a particular door handle 10 (typically 1-2 m) and the door unlock button 49 is operated, the control module 54 is operable to verify the presence of the smart key 70, by virtue of a signal received via the wireless communication module 56, and the handles 10 of all unlocked doors are deployed. The user can then open an unlocked door by pulling the associated handle 10 from the deployed state to its operative position as shown in FIGS. 7, 8 and 9 thereby mechanically releasing the door latch. Each handle 10 returns to the slowed state when its associated door is locked. This may be achieved by a user pressing or pushing on the handle 10 or by means of a Cabin lock button 62 within the vehicle or the lock button on the key fob 68.

(60) In some embodiments deployment of the handle 10 from the stowed position to the deployed position may be initiated by a user pressing upon the handle between the second end 22 of the handle 10 and the pivot point 24 such that the second end 22 of the handle is urged inwardly of the door cavity so as to activate the microswitch M1 whilst the handle 10 is in the stowed position.

(61) Accordingly, the deployment position of each handle 10 acts as a lock status indicator for each individual door. One exception to this may be provided when the vehicle is in motion in which case all the handles 10 of all doors, whether locked or unlocked, are in the stowed state. The handles 10 on any unlocked doors may be retracted into the stowed state in the event that the vehicle exceeds a threshold speed, for example, 5 miles per hour, which may be determined by the vehicle speed sensor 58. The handles 10 of the unlocked doors will then remain in the stowed state for the duration of the vehicle's journey and are only re-deployed in the case that the vehicle is determined to be stationary and either; (i) one of the doors is opened from the inside (which can be determined by means of the door ajar switch 66 provided on each door); (ii) in the case that an unlocked door's handle unlock button 49 is operated by a person, even without the smart key 70 present (such as when picking up a passenger); or (iii) if the cabin unlock button 62 is pressed.

(62) Pressing the handle 10 once towards the vehicle to activate micro-switch M1, or pressing the optional lock button will centrally lock the vehicle and, if applicable, arm the vehicle alarm system 60. If the handle 10 or lock button is pressed a second time within a predetermined time period, e.g. 3 seconds, a deadlock will be activated. The handles 10 will be refracted to the stowed stale in response to the first press of the handle 10 or lock button. A global close may be affected by pressing and holding the handle 10 or lock button, be, this may automatically close any open windows, and, if applicable to the vehicle, deploy a retractable roof, etc.

(63) The handle light 64 will be switched on when the vehicle is unlocked and turned off when the vehicle is locked. If the vehicle is left in an unlocked state for more than a predetermined period of time, e.g. 20 seconds, the system is configure to cause the light 64 to turn off. Also, the light 64 will not be activated, or will be deactivated, when the ignition is on or fumed on.

(64) A user need not wait for a handle 10 to fully deploy after pressing the handle unlock button 49 before opening the door, provided the user is able to grasp the handle 10 as ii is being deployed sufficient to pull it to the operative state.

(65) It can be appreciated that various, changes may be made within the scope of the present invention, for example, in other embodiments of the invention it is envisaged that in an alternative embodiment of the invention, the handle 10 is a bar-type handle which can be grasped with either an underhand or an overhand grip. With such a bar-type handle, the user's thumb will typically be positioned toward the first end 20 of the handle 10, when pulling the handle from the deployed state to an operative state.