Login| Sign Up| Help| Contact|

Patent Searching and Data


Title:
GEARSHIFT HANDLE ASSEMBLY
Document Type and Number:
WIPO Patent Application WO/2005/036032
Kind Code:
A1
Abstract:
A gearshift handle assembly (10) has a gearshift handle (14) and an actuator (18) for releasing the gearshift handle (14) for movement between a plurality of gear positions. The actuator (18) has a housing (22). A sleeve (26) is disposed between the actuator (18) and the housing. The sleeve (26) is made of a material that has a coefficient of friction lower than the coefficient of friction of the material of the housing (22).

Inventors:
JARJOURA TAMMER (US)
SPENCER BRYON A (US)
CURTIN EMILY (US)
BEATTIE CALUM (CA)
Application Number:
PCT/US2004/024647
Publication Date:
April 21, 2005
Filing Date:
July 30, 2004
Export Citation:
Click for automatic bibliography generation   Help
Assignee:
KEY SAFETY SYSTEMS INC (US)
JARJOURA TAMMER (US)
SPENCER BRYON A (US)
CURTIN EMILY (US)
BEATTIE CALUM (CA)
International Classes:
F16H59/02; (IPC1-7): F16H59/04; G05G1/06
Foreign References:
US4896556A1990-01-30
US5372051A1994-12-13
US5179870A1993-01-19
US5501120A1996-03-26
US5247849A1993-09-28
US5289735A1994-03-01
Attorney, Agent or Firm:
Drayer, Lonnie R. (Inc. 5300 Allen K. Breed Highwa, Lakeland FL, US)
Download PDF:
Claims:
CLAIMS :
1. A gearshift handle assembly (10) comprising : a gearshift handle (14); an actuator (18) for releasing the gearshift handle (14) for movement between a plurality of gear positions ; a housing (22) for the actuator (18), the housing (22) comprising a material having a coefficient of friction (C2) ; and a sleeve (26) disposed between the actuator (18) and the housing (22), the sleeve (26) comprising a material having a coefficient of friction (Cl) that is lower than the coefficient of friction (C2) of the material comprising the housing (22).
2. A gearshift handle assembly (10) as described in Claim 1 wherein the actuator (18) has a first flat surface (30) and the sleeve (26) has a second flat surface (34), the first flat surface (30) being in contact with the second flat surface (34).
3. A gearshift handle assembly (10) as described in Claim 2 including a lubricant disposed between the first flat surface (30) and the second flat surface (34).
4. A gearshift handle assembly (10) as described in Claim 1 wherein the sleeve (26) has a first crosssection of a first shape (42) to match a second shape of a second crosssection (46) of the housing (22), the first shape matching the second shape to prevent movement of the sleeve (26) within the housing (22).
5. A gearshift handle assembly (10) as described in Claim 1 including a shift lock mechanism (50) in communication with the actuator (18), the shift lock mechanism (50) preventing movement of the gearshift handle (14) between the plurality of gear positions.
6. A gearshift handle assembly (10) as described in Claim 5 including a motiontransmitting member disposed between the actuator (18) and the shift lock mechanism (50).
7. A gearshift handle assembly (10) as described in Claim 1 including a button (60) in contact with the actuator (18).
8. A gearshift handle assembly (10) as described in Claim 7 wherein the button (60) comprises a first sloped surface (64) in contact with a second sloped surface (68) on the actuator (18).
Description:
GEARSHIFT HANDLE ASSEMBLY This invention relates to an actuator for a gearshift handle assembly.

A gearshift handle for an automatic transmission permits a driver to change the gears of a vehicle transmission by moving the gearshift handle between various positions. Typically, the gearshift handle is locked in a particular gear position until unlocked by the driver. The driver unlocks the gearshift handle by pressing a release button either at the front of the gearshift handle or on its'side, which, in turn, causes an actuator in the gearshift handle to release the gearshift handle from a shift lock mechanism.

Problems may arise with the actuator that unlocks the gearshift handle.

The gearshift handle, which houses the actuator, is generally made from plastic and fiberglass. These materials have a high coefficient of friction and cause the actuator to experience a fair amount of friction when moved.

Manufacturers have sought to overcome this problem by placing lubricant between the actuator and the gearshift handle. During frequent use the lubricant tends to migrate from the area of contact between the actuator and the gearshift handle.

For a side actuating gearshift handle, manufacturers have sought to reduce the effort of unlocking the gearshift handle by employing a cam as an actuator. To unlock the gearshift handle, the driver presses a release button to cause pivotal movement of the cam. The cam moves an unlocking member along a linear path. The pivoting action of the cam tends to force the unlocking member to move in a pivoting fashion as well. On occasion, this type of movement may cause a backlash through the release button.

Manufacturers have sought to eliminate this problem by creating a notch in the cam to prevent the unlocking member from moving radially relatively to the cam. This solution is time consuming to implement.

A need therefore exists for a gearshift handle assembly that provides smooth and inexpensive actuation of a shift lock mechanism.

The present invention comprises a gearshift handle and an actuator for releasing the gearshift handle for movement between various gear positions.

The actuator has a housing that is disposed within the gearshift handle. In contrast to prior art gearshift handle assemblies, the inventive gearshift handle assembly employs a sleeve between the actuator and its housing.

The sleeve has a coefficient of friction less than the coefficient of friction of the housing or the gearshift handle. In this way, the actuator may slide on the sleeve with less frictional resistance than prior art gearshift handle assemblies.

Figure 1 illustrates a gearshift handle assembly of a first embodiment of the invention, showing actuator and sleeve.

Figure 2 is an exploded view of the gearshift handle of Figure 1, highlighting actuator and sleeve.

Figure 3 illustrates the sleeve of Figures 1 and 2 with lubricant.

Figure 4 illustrates the housing of Figures 1 and 2.

Figure 5 illustrates a second embodiment of the invention, a side actuation gearshift handle assembly.

Figure 6 illustrates the actuator of Figure 5.

Figure 7 is a cross-sectional view of the actuator of Figures 5 and 6 in its housing.

Figure 1 is a cross-sectional view of a gearshift handle assembly 10 in accordance with the present invention. Like prior art gearshift handle assemblies, the inventive gearshift handle assembly 10 has a gearshift handle 14 that allows a driver to shift a vehicle transmission through its various gears.

The gearshift handle 14 is prevented from moving from one gearshift position to another gearshift position by a shift lock mechanism 50, here shown schematically.

To release the gearshift handle 14 for movement between the various gearshift positions, a driver presses a button 60 in the direction indicated by arrow C. The button 60 has a first sloped surface 64, such as a rounded or inclined surface, which also moves in the direction indicated by arrow C to contact a second sloped surface 68, here another rounded or inclined surface, of an actuator 18. The actuator 18 is housed in a housing 22, which may be a separate part or be part of the gearshift handle 14. The actuator 18 then moves in the direction indicated by arrow A and transmits its motion to a motion transmitting member 54 to release the shift lock mechanism 50.

Following movement of the gearshift handle 14 to its proper gearshift position, the motion transmitting member 54 and the actuator 18 move in the direction indicated by arrow B and return the button 60 to its original position along the direction indicated by arrow D.

In contrast to prior art gearshift handle assemblies, the inventive gearshift handle assembly 10 employs a sleeve 26 located between the actuator 18 and the housing 22. The sleeve 26 comprises a material having a lower coefficient of friction Cl than the coefficient of friction C2 of the material comprising the housing 22. The sleeve 26 thus offers a low amount of frictional resistance to the actuator 18 within the housing 22.

As shown in Figure 2, the actuator 18 has a first flat surface 30 that fits on top of a second flat surface 34 of the sleeve 26. Accordingly, the first flat surface 30 slides on the second flat surface 34. To further reduce friction between the actuator 18 and the sleeve 26, a lubricant is placed on the sleeve 26 at a location 38 to allow the actuator 18 to slide on the sleeve 26 more smoothly. Because the lubricant is placed between the first flat surface 30 and the second flat surface 34, movement of the actuator 18 on the sleeve 26 causes the lubricant to spread evenly over the flat surfaces 30,34 rather than in one particular area. In this way, the sleeve 26 prevents the migration of lubricant away from the area of contact between the actuator 18 and the sleeve 26.

As shown in Figure 3, the sleeve 26 has first cross-section 42 of a particular shape to match, as shown in Figure 4, the shape of the second cross-section 46 of the housing 22. The second cross-section 46 has shoulders 48. By having shoulders 48, the sleeve 26 is prevented from rotating within the housing 22 and is, in fact, locked in place against rotational movement within the housing 22.

Figures 5-7 illustrate a side actuation shift assembly. The inventive gearshift handle assembly has a gearshift handle 104. The gearshift handle 104 moves between gearshift positions along a first axis X. As in the previous embodiment, the gearshift handle assembly is prevented from moving between gear positions by a shift lock mechanism 150. Unlike a front actuation gearshift handle assembly, the side actuation gearshift assembly uses an actuator 108 that unlocks the gearshift handle 104 by moving along a second axis Y that is transverse to the first axis X.

To release the gearshift handle 104 for movement, a driver presses a button 102 in the direction indicated by arrow E along the Y axis, which is an axis transverse to the X axis, to contact the actuator 108. The actuator 108 comprises a first member 124, which extends along the Y axis within a first portion 116 of the housing 112, as well as a second member 128, which extends along the Z axis, which an axis transverse to both the X and Y axes, within a second portion 120 of the housing 112. Movement of the button 102 forces movement of the first member 124 in the direction indicated by arrow E.

As shown in Figure 6, the first member 124 has a first sloped surface 132, such as a rounded or inclined surface. The second member 128 has a second sloped surface 136, such as a rounded or inclined surface.

Movement of the first member 124 in the direction indicated by arrow E causes the first sloped surface 132 to contact the second sloped surface 136.

Motion is transmitted from the first member 124 along the direction indicated by arrow E to the second member 128 along the direction indicated by arrow A, along the Z axis, through the first sloped surface 132 and second sloped surface 136. The second member 128 moves a motion transmitting member 154 to release the shift lock mechanism 150 in the direction indicated by arrow A. Once the gearshift position has been changed, the motion transmitting member 154 returns along the direction indicated by arrow B to its original position. The motion transmitting member 154 moves the second member 128 in this same direction, which ultimately causes the first member 124 and button 102 to return to their original positions along the direction indicated by arrow F. In this way, motion may be transmitted along two different paths with little resistance. This return and release function can be as known in the prior art. In contrast to prior art side actuation gearshift handle assemblies, the inventive gearshift handle assembly eliminates the cam as well as its pivoting action. The inventive gearshift handle assembly eliminates the backlash associated with prior art side actuation gearshift handle assemblies.

The first member 124 is provided with protrusion 140, as shown in Figures 6 and 7. As shown in Figure 7, a first portion 116 of the housing 112 is provided with a groove 144 to receive a protrusion 140. In this way, the first member 124 is prevented from rotating within the first portion 116 of the housing 112.




 
Previous Patent: MANUAL ACTUATING MECHANISMS

Next Patent: ROTARY SHAFT SEAL