The present invention relates, in general, to sliding doors, and more particularly to doors suitable for cold storage rooms.
Sliding doors typically move horizontally or vertically and parallel to the wall to which they are attached along a track system. In some applications, the door may move away from the wall on a track system once it has cleared the opening as in an overhead door or a vertical door that is tilted out from the wall. The door panel may be manually or automatically moved from its blocking position to an unblocking position. Some door openings may use multiple leaves to cover the opening. In horizontal applications, the leaves will move in opposite directions to clear the opening more quickly. In some instances, the amount of overhead track required to extend beyond the door opening is reduced by having the door panel vertically divided into a number of over-lapped, vertically-separated leaves that take up less horizontal space when moved to the unblocking position.
Cold storage lockers are often accessed through a door opening closed by a sliding door. The panels for this purpose are typically transparent vinyl sheets, minimally insulated flexible panels or foam filled rigid panels. The transparent vinyl sheets are selected to reduce the likelihood of damage to the door. In particular, such doors are used in an institutional (e.g., warehouse) setting wherein palletized cargo is moved in and out of a cold storage locker by forklift. Since this panel is transparent, it also allows forklift operators to see what is on the other side of the door before it is opened. Although providing damage resistance, these types of panels have a very low insulation value and are too flexible to provide an effective air seal between the environments on either side of the opening. Because of the properties of the material, the transparent vinyl sheets may develop a warp that prevents a good seal. Air pressure differentials will cause leakage due to the lack of a compressive seal between the door panels and the door frame. This will allow a significant amount of warm moist air to enter the cold storage locker and/or refrigerated air to be lost into an unrefrigerated space. Consequently, such door systems are less efficient to operate and can lead to ice accumulation in the cold storage locker.
Rigid door panels are often used, especially in the United States, in order to reduce the operating costs of a cold storage locker. The rigid panel provides a consistent surface to seal to the door frame. The thickness of the rigid door panel is selected to provide a specific amount of insulation. Since the panel is rigid, a constraint can be applied to the edges that are parallel to the direction of travel to seal the door against the gasket the full width of the panel perpendicular to the direction of travel. On a horizontal sliding door, the constraint is a floor-mounted device that presses against the door when it is closed. Typically, these devices are rollers that are bolted to the floor and, since they are rigidly mounted, they can be damaged or broken when the door is impacted and/or they cause damage to the panel during an impact. Elimination of the need for these items would reduce the amount of damage to a rigid panel during an impact. Rigid door panels do provide very good environmental separation; however, the panels become susceptible to differential air pressure defeating the air seal.
Vertical sliding doors, similar to the familiar residential garage door, are supported on both vertical sides. However, these doors can also suffer to a degree from a poor seal at the top lateral and/or bottom lateral edges, especially for a wide doorway. It would be desirable to also provide a way to urge these non-tracked edges into sealing contact with the door front.
Attempts have been made to provide a damage resistant door panel for a sliding door system that also provides sufficient insulation. Resilient door panels have been suggested which have sufficient thickness to insulate like a rigid door panel, but yield to a degree when impacted by a forklift. While the panel itself achieves a degree of insulation, the insulation capability of the overall door system suffers from poor sealing between panels and poor sealing between a panel and the door frame. The stiffness of each door panel is much less than that of a rigid panel so sealing across the full gasket width perpendicular to the direction of travel is very difficult.
Thus, approaches to seal the door known in rigid doors are not applicable. In U.S. Pat. No. 3,039,153, a shank is projected from the door frame that has a head that engages a medial slot in a plate attached to a sliding door panel. This binder assembly is disclosed as for maintaining a close seal for a fire door that slides close to the door frame. However, the binding assembly resides within the sealing area of the door frame and the door panel, forcing some spacing therebetween that must be overcome by other sealing components. Moreover, the binder assembly is incapable of overcoming any significant spacing of the door panel from the door frame. However, for a refrigerated door intended to translate quickly and to reduce damage due to impact, it is not desirable that the door panel necessarily translate closely to the door frame to allow engagement of such a binder assembly. Thus, such a planar binding assembly may not reliably engage upon door closure.
Consequently, a significant need exists for an improved sealing system for sliding doors that maintains a good air seal to the door frame. It would be desirable in some instances that the improved sealing system be releasable and easily resets. This will minimize damage of rigid panels and will improve the seal of flexible panels.
The invention overcomes the above-noted and other deficiencies of the prior art by providing a sliding door system that achieves a good seal to a door frame with a lateral keeper on a lateral edge of each door panel that is pulled into a camming surface on the door frame. Thereby, warping of the door panel or an air pressure differential is overcome that may prevent a good seal. Moreover, this lateral keeper advantageously improves both rigid door panels as well as resilient door panels.
In one aspect of the invention, a keeper mechanism includes a first engagement device that is on a trailing surface of a horizontally sliding door panel, one that is not supported by a door track, which thus may be spaced away from a trailing edge of a door frame. This first keeper projects toward the door frame within a recess of the door frame to engage a second keeper that projects toward the door panel within this recess from a sealing surface of the door frame. These keepers slidingly engage and cam against one another as the door panel closes to urge the door panel against the sealing surface of the door frame. Moreover, insofar as these first and second keepers interact within a recess accessed at a trailing edge of the door frame and door panel, this camming action may overcome a significant amount of spacing therebetween and avoid contact with the door panel itself during opening and closing. Thereby, the door panel resists material warping or air pressure differentials that would otherwise impair a good sealing contact.
These and other objects and advantages of the present invention shall be made apparent from the accompanying drawings and the description thereof.
The accompanying drawings, which are incorporated in and constitute a part of this specification, illustrate embodiments of the invention, and, together with the general description of the invention given above, and the detailed description of the embodiments given below, serve to explain the principles of the present invention.
A sliding door system achieves a good seal to a door frame with a lateral keeper on a trailing edge of a door panel that is pulled into a camming surface on the door frame for bi-parting doors. For single door panels, a camming surface is also provided on the leading edge of the panel and a keeper is provided on the door frame. The system mechanically pulls the door into the gasket overcoming leaks in the seal that can be created by warping of the door panel or an air pressure differential and advantageously improves the seal of both rigid door panels and resilient door panels.
The term “lateral” used herein refers to a door panel edge, in either a horizontally or vertically sliding door system, that is traverse to the direction of open and closing. A leading edge is a lateral edge that is foremost during closing and a trailing edge is rearmost during closing.
Turning to the Drawings wherein like numbers denote like components throughout the several views, in
Recessed back from a sealing surface 26 of the door frame 16, a camming surface, depicted as a keeper pin 28, is mounted laterally outward from a vertical portion 30 of the sealing surface 26. The keeper pin 28 is shown in greater detail in
Returning to
It will be appreciated that, alternatively, a camming surface may be incorporated into a door panel with a keeper affixed to a door frame. Furthermore, although the keeper pin 28 is recessed by having the sealing surface 26 spaced outward from the door frame 16, alternatively a keeper pin may be recessed into a channel (not shown) sized to receive a projecting portion of the keeper of the door panel so that the keeper of the door does not abrade the wall during opening and closing.
With particular reference to
In
With regard to
While the present invention has been illustrated by description of several embodiments and while the illustrative embodiments have been described in considerable detail, it is not the intention of the applicant to restrict or in any way limit the scope of the appended claims to such detail. Additional advantages and modifications may readily appear to those skilled in the art.
For example, in the illustrative embodiment, the keeper 34 is advantageously formed from a polymer in order to provide lubricity and the desired resiliency, and the keeper pin 28 is formed from metal for strength. However, either may be formed from a metal, a polymer, a composite material, etc.
As another example, it will be appreciated that the capability for disengaging in response to an impact force may be omitted in applications such as a rigid door panel, such as shown in
This application is a continuation in part of U.S. patent application Ser. No. 10/600,101, filed 20 Jun. 2003, now abandoned.
Number | Name | Date | Kind |
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400562 | Goelet | Apr 1889 | A |
1116728 | Posson | Nov 1914 | A |
1209733 | Lester | Dec 1916 | A |
1250816 | Dunderdale | Dec 1917 | A |
2937867 | Schweig | May 1960 | A |
3039153 | Dusing | Jun 1962 | A |
5899303 | Allen | May 1999 | A |
6098341 | Gebauer | Aug 2000 | A |
Number | Date | Country | |
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20050005524 A1 | Jan 2005 | US |
Number | Date | Country | |
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Parent | 10600101 | Jun 2003 | US |
Child | 10912860 | US |