The present invention is directed to locking covers for vault openings. More particularly, the present invention is directed to a novel cover for existing subgrade vault openings.
Traditional vaults for holding or storing construction equipment and materials (e.g., voltage wires for street lamps) do not have locking mechanisms and are easily broken into. These vaults are subject to burglars who steal the expensive construction materials and devices costing municipalities and states millions of dollars per year. The present invention meets the need for securing these existing subgrade vaults against theft without the need for reconstructing the vault itself.
In one embodiment of the present invention, a locking cover apparatus for covering a vault having side walls is comprised of: a cover having a plurality of through holes; a plurality of threaded locking security bolts for placement in the plurality of through holes; a plurality of locking latch components, each having a latch portion and a threaded opening for accepting one of the threaded locking security bolts; a plurality of locking mounting brackets, each having a flange portion at a top portion of each mounting bracket, wherein each of the locking mounting brackets is adapted to attach to one (or two) of the side walls of the vault; wherein each of the locking latch components is configured to rotate when the threaded locking security bolt for each of the locking latch components is rotated, and wherein the cover is locked from removal from the vault when each of the latch portions of the locking latch components is under one of the flange portions.
The foregoing and other features and advantages of the present invention will be apparent from the following more detailed description of the particular embodiments, as illustrated in the accompanying drawings.
The following detailed description of the example embodiments refers to the accompanying figures that form a part thereof. The detailed description provides explanations by way of exemplary embodiments. It is to be understood that other embodiments may be used having mechanical and electrical changes that incorporate the scope of the present invention without departing from the spirit of the invention.
In addition to the features mentioned above, other aspects of the present invention will be readily apparent from the following descriptions of the drawings and exemplary embodiments, wherein like reference numerals across the several views refer to identical or equivalent features, and wherein:
A tread plate 2 is preferably constructed from a non-skid, ADA approved surface. For example, the cover can be made from stainless steel, aluminum, cold rolled steel or various other materials. The cover can also be made with various types, patterns, thicknesses and materials. For example, the cover can be constructed of a shatterproof material. In one embodiment, the entire cover and all hardware is made of non-corroding materials that cannot be cut into or compromised by an oxyacetylene torch. The cover can also be configured to meets HS20 loading requirements.
Through holes in the cover 3 provide clearance to permit the diameter of the locking bolt head to pass through, and become recessed below, the cover surface. The locking security bolts 4 are preferably high-security locking bolts (e.g., supplied by McGard Co.).
Locking lifting bolts 5 are similar to the locking security bolts described above, but are used to conceal two threaded locations which, when the bolts are removed, expose threads which are used for insertion of eyehook lifting rings 8 for use in removal and installation of the cover. When these two bolts are installed, the appearance of two additional locking locations and an illusion of greater security is provided.
Bolt covers 7 are preferably placed on top of the bolts to keep dirt, debris, water, etc. away from the locking security bolts and to prevent corrosion. Unlike existing covers, the cover of the present invention is preferably impenetrable to wildlife and insects such as bees, wasps, snakes, mice, rats, etc., providing a safer environment for workers as well as protecting the conduit and components inside from damage.
There are four counterbored spacers 10, each having a through hole to allow the locking bolts to pass through. The counterbore allows for part of the locking bolt head to be recessed below the ½″ cover plate so that none of the locking bolt heads extend above the top surface of the cover.
Lifting bolt spacers 11, similar to the counterbored spacers, are preferably used and the center holes are threaded to accommodate two of the locking security bolts, or lifting rings, as needed. The cover preferably provides an impervious and smooth installation, with no holes or access as in existing units. The locking mechanism is preferably fully recessed and inaccessible by any conventional tool.
Locking flags (or latches) 12 are mechanically and operationally connected to the locking security bolts so that when the threaded locking security bolts are rotated clockwise, the locking flags rotate and hit the stop pin 25 on the corner locking flange weldment and then move up and towards and clamp against the top flange 20. The flag portion (or latch portion) of the locking flag locks the cover in place when placed under the top flange portion of the corner locking flange weldment. In the preferred embodiment, the locking flag has an internal threaded portion that is matched to the locking security bolts. As the locking security bolts are turned, the locking flags rotate. Once the locking flag hits the stop pin, further rotational movement of the locking flag is prevented, however, as the locking security bolt is turned, the locking flag will continue to move upward on the bolt. This latching mechanism does not require adjustment or setting as it automatically stops when tight, unlike other systems. Double jam nuts 13 are used in one embodiment, which are tightened against one another and prevent the locking flags from unthreading and disengaging from the locking security bolt.
A stiffener X brace 14 is attached to the cover in one embodiment. The brace is preferably a welded brace that provides additional strength and load-carrying capacity to the cover. It also acts as a stop for the locking flags during counterclockwise rotation of the locking security bolts allowing the flags to stop rotating and move away from the top flange as the bolt is turned. The brace also protects all of the cover components during removal, handling and shipping, since the components do not extend past the height of the brace.
In one embodiment of the invention (
In one embodiment (
In one embodiment of the invention, end support bars 17 are placed on the bottom of the cover. In this embodiment, because the cover rests upon ½″ thick top flanges, these ½″ thick spacer end bars provide additional support and load-carrying capacity. (The ½″ cover is spaced an additional ½″ up to fill the 1″ deep space of the existing vault opening (27).) (The lip of the vault (shown at 27) is 1″ from the opening of the vault in the embodiment shown (e.g.,
Side support bars 18 can also be used in addition to the end support bars. Additionally, the end and side support bars provide additional structural support should one or more of the corner locking flange weldments be eliminated due to potential interference with a conduit or other obstruction.
A top flange 20 is secured, by welding or another method, to the top of the mounting bracket for use in securing the locking latch components and locking the cover as previously described. In other words, once the locking flag is in the locked position under the top flange, the cover cannot be removed from above as the locking flag is secured in place by the top flange. The top flange overhangs the angle mounting bracket (by ⅞″ in one embodiment) and allows for positioning of the entire corner locking flange weldment onto the vault opening. In the preferred embodiment, no measuring or positioning of the corner locking flange weldment is necessary; it is self-fixturing.
Since no lip or flange exists in many existing, smooth-walled, concrete vaults, this provision allows the locking flags to rotate into position and pull tight against the top flange to secure the cover. The top flange also acts as a spacer (in one embodiment, the flange is ½″ thick allowing the ½″ lid to sit flush with the top of the existing vault opening). It is appreciated that different size top flanges may be used with various size vaults and/or covers.
The stop pin 25 acts as a stop for the locking flag. When the locking security bolts are rotated clockwise, the locking flag rotates until it comes in contact with the stop pin and cannot rotate further. Its motion then becomes linear and it rises until it comes into firm contact with the top flange securing the cover.
The angle mounting bracket is a component of the corner locking flange weldment that allows the component to be securely mounted to existing vault walls. In one embodiment, the angle mounting bracket has a radiused corner 22 to allow for installation against any potential existing debris in the vault opening which could impede installation. The bracket can also be shimmed to fit any wall that is not straight or that is tapered. The design allows for uneven and/or non-plumb conditions and structures which are out of square. The cover can be installed securely with as few as two of the corner locking flange weldments installed diagonally if conditions so require.
In one embodiment of the invention, the corner locking flange weldment is comprised of multiple ¼″ positioning holes 23 for insertion of fasteners into the vault wall (e.g., Hilti-type fasteners) to hold the corner locking flange component for final installation (acts like a second set of hands during installation).
In one embodiment, the corner locking flange weldment is comprised of multiple 9/16″ mounting holes 24 for securing anchors into the vault wall and for securing the corner locking flange weldment in place. The holes also act as a drill template for the main anchors. There is no measuring required.
In an alternative embodiment, the cover of the present invention can be unlocked from the inside, ensuring that no human can be inadvertently locked inside. For example, the cover can be configured so that the lock flags can be easily turned and unlocked from the inside of the vault. For example, in one embodiment of the invention, a safety wrench can be attached to a location on the bottom of the cover which can be used by a person to turn the locking flags to an unlocked position.
While certain embodiments of the present invention are described in detail above, the scope of the invention is not to be considered limited by such disclosure, and modifications are possible without departing from the spirit of the invention as evidenced by the following claims:
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Number | Date | Country | |
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20160258191 A1 | Sep 2016 | US |