The present invention relates, in general, to liquid and vapor seals.
Resilient seals are frequently used with translating or rotating parts to prevent liquid and/or vapor leakage around the translating or rotating parts while they are moving or when they are in a static, rest state.
A typical prior art seal configuration for a moving member, such as a translating or reciprocating rod or shaft, is shown in
Depending upon the material used to form the seal, as well as the cycle frequency of movement of the rod, the seal can be subject to deterioration resulting in eventual breakdown of the seal and loss of contact with the rod thereby allowing undesirable leakage of liquid or vapor from one side of the seal to the other.
It will be desirable to provide a seal configuration which minimizes this problem.
An apparatus is disclosed for sealing a rod translating between first and second positions. The apparatus includes a small diameter portion and a large diameter portion on a rod defining at least one first or two first and second longitudinally spaced walls extending between the smaller diameter portion of the rod and the larger diameter portion of the rod. A seal is mounted in a fixed position relative to the rod. The seal has an inner diameter greater than the smaller diameter portion of the rod such that the seal is disposed in a non-contacting position relative to the smaller diameter portion of the rod during translation of the rod between the first and second positions. The seal is configured for sealing engagement with one of the first and second walls on the rod when the rod translates to one of the first and second positions.
In one aspect, the seal has a circular cross section sealing engagement portion and the small diameter portion in the rod defines a circular small diameter portion.
In one aspect, the first and second walls on the rod are substantially perpendicular to the longitudinal extent or axis of the rod.
In another aspect, the first and second walls of the rod are disposed at non-perpendicular or obtuse angles relative to the small/diameter portion of the rod.
In a specific implementation, a vehicle fuel door lock apparatus and a seal apparatus are disclosed for positively locking a movable fuel door on fuel door housing in the vehicle. The apparatus includes a movable rod reciprocatingly extending through an aperture in fuel lid housing and adapted for movement between first and second opposed end positions of travel. The rod has an outer diameter along a major extent of the rod. The seal apparatus includes a small diameter portion and a large diameter portion on the rod forming opposed walls between the small diameter portion of the rod and the large diameter portion of the rod.
A seal is fixedly disposed relative to the small diameter portion of the rod. The seal has an inner diameter greater than the small diameter portion of the rod such that the seal is disengaged from the small diameter portion of the rod during translation movements of the rod between the first and second end travel positions, but is positioned to sealingly engage the one of first and second walls at the first and second end positions of travel of the rod.
In one aspect, the seal has a circular cross section sealing engagement portion and the small diameter portion in the rod defines a circular small diameter portion.
In one aspect, the first and second walls on the rod are substantially perpendicular to the small diameter portion of the rod.
In another aspect, the first and second walls on the rod are disposed at non-perpendicular or obtuse angles relative to the small diameter portion of the rod.
In one aspect, a tubular extension extends from the fuel lid housing and defines a through bore opening to an interior of the fuel lid housing. The rod reciprocatingly extending through the bore in the tubular extension and the seal is fixedly coupled to the tubular extension such the inner diameter of the seal is spaced from the small diameter portion of the rod.
In another aspect, a stationary holder fixedly positions the seal adjacent to the aperture in the fuel lid housing to dispose the inner diameter of the seal within the reduced diameter portion of the rod.
The various features, advantages and other uses of the present invention will become more apparent by referring to the following detailed description and drawing in which:
Referring now to the drawing, and to
In the seal structure 10, the rod 12 is connected to a suitable actuator, not shown, which drives the rod in a translating or reciprocating manner to the right to a first end limit of travel as shown in
The seal 14 is formed of any suitable resilient material, such as rubber, synthetic compositions, etc. It will also be understood that the seal 14 will typically be mounted in a holder or structure surrounding the rod 12.
As shown in
As shown in
The inner diameter 16 of the seal 14 is greater than the small diameter portion 22 of the notch 21 such that the inner diameter 16 of the seal 14 does not contact the small diameter portion 22 of the notch 21 during translatory movement of the rod 12 to the right as shown in
The small diameter portion 20 has a substantially constant outer diameter 22. Opposite ends 30 and 32 of the notch 20 form walls or shoulders which act as seats for the seal 14 in the extreme first and second end limit of travel positions of the rod 12 shown in
In the aspect of the seal structure 10 shown in
It can be seen in
Likewise, as shown in
It will be understood that during all intermediate positions of the seal 14 with respect to the notch 20 during translation of the rod 12 between the extreme left and extreme right positions, the clearance 26 between the inner diameter 16 of the seal 14 and the small diameter portion 22 in the notch 21, as shown in
Referring now to
In this alternate configuration of the seal structure 10, the walls 40 and 42 of the notch 21 are disposed at substantially non-perpendicular angles with respect to the linear small diameter 22 of the notch 21. For example, the walls 40 and 42 of the notch 20 are disposed at obtuse angles with respect to the linear small diameter portion 22 of the notch 21. Despite the angular configuration of the walls 40 and 42 of the notch 21, the seal 14 can still sealingly engage either wall 40 or 42 in the leftmost and rightmost end limit of travel of the rod 12 shown in
Like the previous aspect, the inner diameter 16 of the seal 14, as shown in
An implementation of the above-described seal structures is depicted in
A lock apparatus 82 includes an elongated rod 84 having a striker 86 formed at one end. The striker 86 is configured for engaging an aperture or suitable structure on the inside of the fuel door, not shown, to engage and pull the fuel door to a locked position relative to the housing 80. The rod 84 is driven in a translating or reciprocating manner by an actuator 86 in the form of an electric motor having a bi-directional translating output shaft 88 coupled to the rod 84.
A seal structure 90 is mounted on a tubular extension of the fuel door housing 80 to provide sealing between the interior of the fuel door housing 80 and the exterior ambient environment of the fuel door housing 80 due to the passage of the translating rod 84 through a bore in the extension of the fuel door housing 80.
Further details of the seal structure 90 are shown in the enlarged view of
The catch members 96 engage apertures 98 in a cap 100 to enable to the cap 100 to be mounted over the tubular extension 92 and capture a seal member 110 between the interior of the cap 100 and the end portion of the tubular extension 92. The cap 100 fixedly holds a seal member 100 in place relative to the rod 84.
In this example, the seal member 110 has an annular, circular diameter, ring-like end portion 112 and an integral, angularly formed mounting portion 114 which seats in between adjacent portions of the cap 100 and the end of the tubular extension 92.
As shown in
An alternate seal structure 130 is shown in
In this aspect, the fuel door housing 80 does not include a tubular extension 92. Rather, a holder 138 mounted to suitable stationary structure surrounding the fuel door housing 80 or connected to the fuel door housing 80 itself, has an end portion 140 complimentary to the shape of the mounting portion 136 of the seal member 132 to fixedly receive and hold the seal member 132 in the desired position relative to the notch 120 in the rod 84.
In fueling operations, the fuel door, not shown, is opened and closed manually by a user, but is connected to a push-push rod, also not shown, such that a slight tap on a closed fuel door releases the fuel door a small fuel amount from the fuel lid or surrounding edges of the fuel lid housing. The user can then grasp the edge of the fuel lid or door to fully open the door for fueling operations. At the completion of fueling operations, the user firmly closes the door in the fuel lid housing opening.
A signal is provided to the fuel rod actuator or motor 81, shown in
At the completion of fueling operations, the user manually closes the fuel door to engage the push-push rod. At the very next time the vehicle doors are locked, such as after the driver re-enters the vehicle, closes the door and starts the vehicle ignition, the vehicle body ECU sends a signal to the fuel rod motor 81 causing the rod 84 to extend and engage the striker to hold the fuel door in the fully locked position.
Referring now to
In this aspect, two separate seals 160 and 162 or a single unitary seal with two separate seal lobes 160 and 162, are mounted in the suitable holder 164 such that the end portions or lobes 160, 162 of a single seal member are held in the fixed position relative to the translating rod 150, but are spaced from the smaller diameter portion 152 on the rod 150 during all translational movements of the rod 150 as shown in
In
As the rod translates from the leftmost or second end travel position shown in