The disclosure relates to a support mechanism for a vehicle closure panel. More particularly the disclosure relates to a prop rod system for use with a vehicle hood, trunk, liftgate, or tailgate.
Numerous motor vehicles employ a hingable closure panel disposed in a region between the passenger compartment and the forward bumper of the motor vehicle, or between the passenger compartment and the rearward bumper of the motor vehicle. The hingable closure panel provides a mechanism for accessing the underlying engine or storage compartment.
Some closure panels employ a prop rod or other mechanism to hold the closure panel in an open position. Such mechanisms may include a traditional prop arm or conventional pneumatic or gas-charged struts.
A support mechanism for a closure panel of a vehicle body, such as a hood, rear hatch closure panel, trunk, liftgate, tailgate, or the like is provided. The closure panel is moveable with respect to the vehicle body from a first position to a second position. The support mechanism secures the closure panel in the second position. The support mechanism may be a hood prop rod system or the like.
The support mechanism includes a connection rod assembly and a counterbalancing device. The connection rod assembly includes a connection rod and a connection rod base structure. The connection rod is pivotally connected to the closure panel at a first attachment point and pivotally connected to the connection rod base structure at a second attachment point. The connection rod base structure is configured to move linearly with respect to the first attachment point.
The counterbalancing device includes at least one guide block and at least one resistance member. The counterbalancing device may also include at least one spring element.
The at least one guide block is coupled to the connection rod base structure for movement therewith. The at least one guide block engages the at least one resistance member creating an interaction therebetween. The interaction between the at least one guide block and the at least one resistance member creates a resistance force sufficient to counter balance the closure panel as the connection rod base structure moves linearly with respect to the first attachment point.
The speed at which the closure panel moves between the first position and the second position is defined by the interaction between the at least one guide block the at least one resistance member.
The at least one spring element is biasingly positioned with respect to the at least one resistance member. Each spring element defines at least one detent along the length of each resistance member to bias the at least one resistance member against the at least one guide block. The counterbalancing force applied by the support mechanism against the weight of the closure panel increases as the connection rod base structure and the guide blocks move along the length of the at least one resistance member compressing the at least one spring element as the connection rod base structure and the at least one guide block approach the at least one detent. Each detent defines a predetermined location defining the second position of the closure panel.
The above features and advantages, and other features and advantages, of the present invention are readily apparent from the following detailed description of some of the best modes and other embodiments for carrying out the invention, as defined in the appended claims, when taken in connection with the accompanying drawings.
Referring to the figures, wherein like reference numbers correspond to like or similar components throughout the several views, a support mechanism 101 for a closure panel 102 of a vehicle body 103 is provided.
Referring to
The support mechanism 101 is designed to act as a hold open device for a vehicle closure panel 102, as well as a counterbalancing device to reduce and regulate the speed at which the closure panel 102 is moved between a first position 105 and a predetermined location along angles θ1 and θ2, comprising a second position 106.
The first position 105 of the vehicle closure panel 102 may be a closed position. The second position 106 may be an open position. The open position may be any open position, such as, but not limited to, a full-open position 117 and a service position 114. In the full-open position 117 the closure panel 102 may extend, relative to the vehicle body 103 along angle θ1. In the service position 114 the closure panel 102 may extend, relative to the vehicle body 103, along angle θ2 respectively. In the service position 114, the value of angle θ2 is greater than the value of angle θ1 when the closure panel 102 is in the full-open position 117. A user input force F is necessary to initiate movement of the closure panel 102 from the first position 105 to the second position 106 and/or from the second position 106 to the first position 105.
The support mechanism 101 includes: a connection rod assembly 119 and a counterbalancing device 112. The connection rod assembly 119 includes a connection rod 107 and a connection rod base structure 113. The connection rod 107 may have a first end 108 and a second end 109. The connection rod 107 may be pivotally connected to the closure panel 102 at the first end 108 at a first attachment point 110. The connection rod 107 may be operatively connected, by a pin connection, integral formation, or slidably connected at its second end 109 to the connection rod base structure 113 at a second attachment point 111.
The connection rod base structure 113 may be slidable within a guide track 124 formed in the vehicle body 103 within the vehicle underhood 125 (shown in
Referring to
The at least one guide block 115a, 115b may be coupled to the connection rod base structure 113 and is configured to be moveable therewith. The connection rod base structure 113 and the at least one guide block 115a, 115b are moveable together along a length of the at least one resistance member 120a, 120b. The at least one guide block 115a, 115b is formed of a first material; the first material may be a frictional material. The first material may be any rigid material such as a polymeric material, metallic material, ceramic material, or the like.
The at least one resistance member 120a, 120b may run along the length of the guide track 124 and extend from a first end 123a, 123b to a second end 128a, 128b. Each resistance member 120a, 120b may be formed as a dual or single band. The at least one resistance member 120a, 120b may be formed of a second material; the second material may be a frictional material. The second material may be a strong but flexible polymer or metallic material such as steel or nylon.
The at least one resistance member 120a, 120b may be operatively connected at each of the first end 123a, 123b and second end 128a, 128b to an end plate 121, 127. The at least one resistance member 120a, 120 may move or oscillate along its length between the first end 123a, 123b.
Each resistance member 120a, 120b is configured to interact with the at least one guide block 115a, 115b as the at least one guide block 115a, 115b, coupled to the connection rod base structure 113, moves along the length of the at least one resistance member 120a, 120b between the first end 123a, 123b and the second end 128a, 128b, such that the guide block 115a, 115b engages with the at least one resistance member 120a, 120b creating an interaction therebetween.
The interaction between the at least one resistance member 120a, 120b and the at least one guide block 115a, 115b creates a resistance force sufficient to counterbalance the weight of and reduce the speed of the closure panel 102 as the closure panel 102 is moved between a first position 105 and a second position 106. The resistance force may be one or more of a mechanical resistance force and a frictional resistance force. The speed at which the closure panel 102 moves between the first position 105 and the second position 106 is defined by the interaction between the first material of the at least one guide block 115a, 115b and the second material of the at least one resistance member 120a, 120b.
The at least one spring element 122a, 122b may be formed of an elastomeric material. The at least one spring element 122a, 122b may be biasingly positioned with respect to the at least one resistance member 120a, 120b. For example, the at least one spring member 122a, 122b may be placed proximate to one of the resistance member first end 123a, 123b and the resistance member second end 128a, 128b.
The at least one spring element 122a, 122b is configured to bias the at least one resistance member 120a, 120b to increase the counterbalancing force applied against the weight of the closure panel 102. The at least one spring element 122a, 122b is compressed by the connection rod base structure 113 and the at least one guide block 115a, 115b, as the connection rod base structure 113 and guide blocks 115a, 115b move along the length of the at least one resistance member 120a, 120b and the closure panel 102 moves between a first position 105 and a second position 106.
Multiple spring elements 122a, 122b may be placed along the length of the at least one resistance member 120a, 120b. Each spring element 122a, 122b defines a detent 126. The detent 126 being a defined position where one mechanical part is held in relation to another and is releasable by a user applied force F. The compressed spring element 122a, 122b biases the at least one resistance member 120a, 120b such that the resistance force, created by the interaction between the at least one guide block 115a, 115b and the at least one resistance member 120a, 120b, increases as the connection rod base structure 113 and the at least one guide block 115a, 115b approach the at least one detent 126.
Each detent 126 defines a predetermined location which defines the second position 106 (show in
As shown in
In the first example embodiment, the support mechanism 101 further includes two spring elements 122a, 122b defining two detents 126 and two guide blocks 115a, 115b. The guide blocks 115a, 115b are disposed within the connection rod base structure 113 and disposed about the resistance members 120a, 120b, such that each of the guide blocks 115a, 115b are directly engaged with the second side 132a, 132b of one of the respective resistance members 120a, 120b.
The spring elements 122a, 122b are disposed within the gap 118 between the resistance members 120a, 120b and are located proximate the resistance member first ends 123a, 123b and the resistance member second ends 128a, 128b. Each of the spring elements 122a, 122b defines a detent 126 to secure the closure panel 102 in a predetermined position. While two spring elements 122a, 122b are shown, in each of the respective figures, by way of illustration, it is to be understood that the support mechanism 101 may include any number of spring elements 122a, 122b placed strategically along the length of the resistance members 120a, 120b.
In the configuration shown in
The detents 126 define the first position 105, shown in
As shown in
Each of the spring elements 122a, 122b are disposed within the guide track 124 between one of the opposing walls 134 and the second side 132a, 132b of one of the at least two resistance members 120a, 120b. The spring elements 122a, 122b are located proximate each of the resistance member first ends 123a, 123b and the resistance member second ends 128a, 128b. Each of the spring elements 122a, 122b defines a detent 126 to secure the closure panel 102 in a predetermined position. While two spring elements 122a, 122b are shown, in each of the respective figures, by way of illustration, it is to be understood that the support mechanism 101 may include any number of spring elements 122a, 122b placed strategically along the length of the resistance members 120a, 120b.
In the configuration shown in
One detent 126 defines the first position 105, shown in
The support mechanism 101 described herein is operable to reduce the speed at which the closure panel 102 travels between a first position 105 and a second position 106. The speed at which the closure panel 102 moves between the first position 105 and the second position 106 is defined by the interaction between the at least one guide block 115a, 115b formed of a first material and the at least one resistance member 120a, 120b formed of a second material.
The support mechanism 101 utilizes simple structure, which need not include pneumatic or gas-strut elements. The elimination of pneumatic elements allows the counterbalancing device 112 to act as a linear spring to provide a smooth power output and controlled movement of the closure panel 102 between the first position 105 and second position 106 in a multitude of temperatures and environmental conditions. This speed control of the closure panel 102 limits the amount of over travel of the closure panel 102 that may result from an uncontrolled movement between the first position 105 and the second position 106.
The detailed description and the drawings or figures are supportive and descriptive of the invention, but the scope of the invention is defined solely by the claims. While some of the best modes and other embodiments for carrying out the claimed invention have been described in detail, various alternative designs and embodiments exist for practicing the invention defined in the appended claims.