1. Technical Field
This disclosure relates to subterranean structures, particularly vertical access passages to generally underground facilities, such as septic tanks and pump chambers, the vertical access passages sometimes being referred to as manholes. The present disclosure particularly to elements used in the construction of the walls of such subterranean structures, which are sometimes referred to as risers and covers therefore. The disclosure more particularly relates to cylindrical plastic structures made of a plurality of curved segments that are interlocking and stackable, and to a cover that can be locked to a variety of risers of various types.
2. Background Information
There have been previous attempts to construct the walls of manholes and other subterranean structures using a plurality of curved segments. In U.S. Pat. No. 4,751,799, a liner segment is formed in a vacuum forming operation from a heated plastic sheet, which is drawn against the surface of a suitably formed mold member to form certain prescribed outwardly extending projections. A plurality of such liner sections are then joined together using simple lap joints and placed within another mold assembly with an optional inner support and with the liner sections being spaced from the mold assembly. Concrete or other casting material is the poured into the space between the liner sections and the mold assembly with the outwardly extending projections of the liner acting to bond the liner to the casting. Other patents disclosing similar liners are U.S. Pat. Nos. 5,081,802; 5,236,298; 5,303,518; 5,383,311; 5,901,506; and 6,206,609. In all these disclosures, the liner forms a corrosion barrier for the structure, but does not have sufficient strength to constitute the only structural component of the riser.
Other liner segments can also be found, for example, in Hume U.S. Pat. No. 5,608,998, which use the liner segments to rehabilitate an existing, leaking manhole structure. The liner segments are rigid or semi-rigid plastic, and preferably corrugated, panels joined together laterally with an adhesive in a simple lap joint. A plurality of the liner segments are assembled within an existing manhole with a lower end of each ring including a channel or lip that captures the upper end of the next lower ring. Each liner segment of Hume is disclosed to include an integral L-shaped channel which is adapted to receive the opposite end of an identical panel that has no special end structure thereby permitting the panel assembly to be cut to fit a specific manhole perimeter without special forming tools. Once the liner is in place, a bonding layer of polymer foam or other material is injected between the pre-existing manhole structure and the newly formed liner. While the liner has sufficient strength to be self supporting, there is a continuing reliance on the physical strength of the pre-existing leaking manhole to provide some of the structural strength for the structure of the riser as a whole. In the event of a significant structural failure of the pre-existing leaking manhole, the simple overlapping end structure of the liner may be insufficient to prevent the manhole from collapsing inward.
Another structure formed of segments joined end to end is found in U.S. Pat. No. 4,310,372, which discloses couplings and well screens formed of three identical molded pieces joined edge to edge along longitudinal edges by C-shaped clamps slipped onto or snapped over outwardly protruding portions of the joined structure. The edges of each of the three molded pieces include various triangular ridges and grooves forming confronting, but not interlocking, surfaces, which are intended to be solvent welded together. The solvent welds in conjunction with the additional locking means provided by the C-shaped clamps hold the assembled sections together.
One-piece molded plastic structures that are intended for subterranean placement in a variety of fluid containment systems are disclosed in U.S. Pat. Nos. 5,257,652; 5,333,490; 5,361,799; 5,423,447; 5,833,392; 5,988,944; 6,059,208; and 6,189,717. All of the disclosed structures rely substantially entirely on the strength of the plastic materials forming the structures to resist the forces that might be applied by the surrounding soils. Further, it is known to stack structurally self sufficient component formations from U.S. Pat. Nos. 5,617,679 and 5,852,901. While all these structures use the inherent advantages of the various disclosed polymers and plastics to achieve certain desirable results, all these structures are bulky to transport.
Underground reinforced plastic enclosures made of a plurality curved segments that are more easily transported are disclosed in U.S. Pat. Nos. 3,974,599 and 4,089,139. In the earlier of these two disclosures, the curved segments take the form of semi-cylindrical portions having confronting longitudinal edges including outwardly projecting flanges. The flanges are coupled together with bolts and nuts to form the cylindrical members from the semi-cylindrical portions. In the later of these two disclosures, a number of the curved segments, preferably three, are coupled together to form each ring of the structure. Each of the segments includes vertical side edges that are configured to provide an engaging relationship between the laterally adjacent segments. In particular, one of the vertical side edges is disclosed to include a notch formed by the inner surface of the wall segment and an intersecting inclined wall portion. The other vertical side edge includes a projecting tongue having one surface aligned approximately with the inner surface of the remainder of the wall segment and another surface angled at about the same angle as the intersecting inclined wall portion. The projecting tongue can be seen as a wedge that is adhesively secured in the notch to join adjacent segments together to form a ring, but this amounts to no more than an improved lap joint structure having increased adhesive surface area.
Subterranean openings such as vertical manholes desirably have features to prevent entry by unauthorized personnel. One such entry prevention system consists merely of a cover that desirably is locked to the side structure defining the subterranean opening. Examples of such locking covers are to be found in U.S. Pat. Nos. 897,046; 4,015,373; 4,101,154; 4,523,407; 4,964,755; 5,628,152; 5,845,442; 5,979,117; 5,987,824; and 6,584,734. Many such locking covers require a specific orientation with respect to the side structure of the subterranean opening to permit an interlocking engagement of the locking element with specific mating structures in the side structure. Some locking structures are adapted to have an outer portion that simply protrudes under a flange or ledge, but still requires manipulation of more or less complex mechanisms to achieve the necessary outward protrusion of the outer portion.
Another such entry prevention system shown in U.S. Pat. No. 5,265,974 comprises a safety net situated below the cover of a manhole type access opening. The safety net assembly has at least two rigid rods of a length sufficient to span the access opening. Each rod is supported at both ends by a support coupled to the manhole so that at least one of the rods is movable from one side of the access opening to an opposite side. A web or net is securely attached to all the rods to travel with any movement of the rods from one side of the access opening to the opposite side. The web or net has openings sufficiently small to prevent the entry of unauthorized personnel. When unlocked, the rods can be moved between a secured position and an open position.
There remains a need for a reinforced plastic enclosure suited for subterranean use as a structurally defining portion of a manhole that is constructed from a plurality of easily transported curved segments that includes vertical side edges having specific structural features that will lock adjacent segments together without a required use of any adhesive or separate fasteners. There is an additional need for a lockable lid that will cooperatively engage a top opening of a subterranean structure defined by the assembled segments. There is a further need for a security device that will inhibit accidental entry into a subterranean structure defined by the assembled segments.
Accordingly, a subterranean structure can be formed from a plurality of wall elements in the form of easily transported curved segments. Each curved segment can be viewed as being cylindrically curved about a vertical axis and having an inside surface and an outside surface. Each segment has vertical side edges and horizontal top and bottom ends. A first vertical side edge includes a protruding mating element that is vertically tapered. The second vertical side edge has a slot that is also vertically tapered. The vertical side edges include confronting surfaces adapted to be brought into abutting relationship in interlocking engagement when assembled with adjacent segments of similar construction. The vertically tapered protruding mating element and slot have surfaces designed to pull the confronting surfaces together as the tapered elements become increasingly mechanically engaged through vertical relative movement of the adjacent edges. The protruding mating element can take the form of a dovetail extending continuously along the first vertical side edge with the dovetail including a distal portion having a width of continuously varying dimension to achieve the vertical taper. The corresponding slot on the second vertical side edge is then also dovetailed and of varying width so that relative vertical relative displacement of two adjacent segments causes the adjacent confronting surfaces to be drawn together.
To assemble the curved segments into a ring, the protruding mating element of one segment is slipped into the vertically tapered slot of an adjacent segment until the top and bottom ends of the adjacent segments are aligned. The preceding operation is repeated with additional segments until sufficient segments are joined together horizontally to complete a ring except for a last adjacent pair of vertical side edges. The segments of the ring are then vertically warped by a distance sufficient to align one end of the protruding mating element of the last adjacent pair of vertical side edges with an opposite end of the adjacent tapered slot. To complete the ring, the aligned protruding mating element and tapered slot are then slipped together while un-warping the joined segments forming the remainder of the ring until the top and bottom ends of all the segments are aligned.
The rings can include a lap portion on either the upper or lower end so that once some rings are assembled, the rings can be stacked one upon another to form a manhole or other subterranean structure of desired vertical height, the lap portion assuring a self centering of the stacked rings. The assembly and stacking of the rings to form the subterranean structure can be achieved without tools, adhesives, or separate fasteners. Of course, various fasteners, adhesives or cements can be used with such structures, if desired. Additionally, each of the segments can include features that permit locking engagement with a closure to prevent unauthorized entry into the subterranean structure, and can include various security devices that will inhibit accidental entry into the subterranean structure defined by the assembled segments. Further, the assembled segments can be combined with a closure to prevent unauthorized entry into the subterranean structure, and can be combined with suitable security devices that will inhibit accidental entry into the subterranean structure defined by the assembled segments.
A locking cover intended to restrict entry into the subterranean structure can include a plate having an upper surface and a lower surface. The locking cover can include an outer depending flange that extends downward from an outer perimeter of the plate. An inner depending flange can extend downward from the lower surface. The outer and inner depending flanges are spaced from each other to receive an upper horizontal end of a riser. A locking element in the nature of a flexible spider having a center portion and a plurality of radially extending legs can be coupled to the lower surface of the cover. The spider can have three or more legs that can flex with respect to the cover to allow radial movement of outer ends of the legs sufficient to lockingly engage a feature adjacent to the upper horizontal end of the riser. The legs of the locking element can be fixed to each other, and can be for differing lengths.
The locking cover can include a central opening to receive a key for unlocking the locking element. The central opening can be a simple cylindrical opening in the center of the locking cover. The key can be an axially symmetric rod having a lower portion dimensioned to be received in the central opening of the locking cover and a shoulder of a greater dimension. The length of the lower portion can be dimensioned to assure the unlocking of the locking element when the shoulder is in contact with the cover upper surface. The key can also include a tapered portion between the lower portion and the shoulder allowing lateral displacement of the key relative to the central opening of the cover. A handle can be provided at one end of the key facilitating lateral displacement of the key in relation to the locking cover to engage the key in an unlocking position.
Other features and advantages of these structures will become apparent to those skilled in the art from the following discussion of a preferred embodiment illustrated in the accompanying drawings.
The segment 10 also has vertical side edges 24 and 26, which are discussed in more detail below. The vertical side edges 24 and 26 can be braced by gussets 28 extending between an outer portion of the vertical side edge and the surface 12 of wall 16. The outer surface 12 can also include a plurality of dimples 30 that are designed to act as a centering device facilitating the drilling of a hole in the wall 16 to allow various equipments to be mounted to the wall 16. The inside surface 14 can also include dimples 30 as well as one or more planar regions 31, shown in
An adjacent pair of the segments 10 can be joined together as shown in
It can be seen from
One mechanism for facilitating the junction of the vertical side edges 24 and 26 is shown in
The engagement of the tapered protruding element 40 into the tapered slot 32 requires that two adjacent segments 10 be vertically moved relative to each other. While the tapered protruding element 40 and tapered slot 32 are shown in
A method for the assembly of a plurality of the curved segments 10 into a ring 50 is illustrated in
While
The vertical orientation of the interlocking mating element 40 and tapered slot 32, as distinguished from a horizontal orientation commonly used in many prior art structures, insures that the same type of warping action is necessary to separate one segment 10 from another. Unlike the assembly motions of many prior art devices, this warping action is unlikely to occur as a result of earth movement adjacent to an assembled riser that has been installed in a subterranean environment. As a result, a riser constructed with the present invention has an added margin of strength and security that is not provided by other structures.
The segments 10 can be made from a wide range of polymers including, without limitation, PC, PVC, DHPP, HDPE and ABS. The polymers desirably have the required properties of strength, stability, impact resistance, and bondable using non-toxic cements that are generally available in the trade. A suitable polymer is, for example, Cycolac® GPX3800 available from GE Plastics. Cycolac® GPX3800 is an ABS plastic having a typical tensile strength of 5400 psi, flexural strength of 9600 psi, and an Izod impact resistance of 8.4 at 73° F.
The modular design of the riser segments 10 conserves shipping and storage space as shown in
An access chamber, riser, or other subterranean structure 54 can be assembled from a stacked series of rings 50 formed from the segments 10 as shown in
With each succeeding ring 50, the downwardly extending lap portion 23 of the upper ring can be positioned to surround the junction of the now contiguous horizontal upper and lower surfaces 20 and 22, to assist in centering the rings 50 one on the other, and to deflect moisture away from the horizontal surface junction. Again, a suitable bonding agent can be employed between the abutting surfaces 20 and 22, if desired, but is not necessary to complete a structure of the present invention. A suitable cover plate 62, such as a standard cast iron manhole cover, can be added to restrict access to the subterranean structure 54. The cover plate 62 can be secured to the horizontal upper surface 20 of the uppermost ring 50 by suitable fasteners 63 as are typically used in the trade. Appropriate back fill 66 can be added to surround the rings to aid in stabilization of the manhole 54 with respect to the structure 56.
A locking cover 80 is shown in
A distal end 106 of each leg 100 is adapted to protrude into the groove 21 on the inner surface 14 of the riser segments 10 to lock the cover 80 in place. Alternatively, a ring of material such as polyethylene or epdm rubber that is sufficiently soft to engage the ends 106 of the legs 100 can be placed as a lining adjacent to the upper horizontal end 20 of the riser. The spider 96 shown in
Another alternative form for the spider 96 is shown in
A central opening 114 can be provided in the locking cover 80 to provide access for a key 110. A preferred key 110 is seen in
While particular embodiments of the invention have been shown and described with reference to the drawings, it is recognized that variations and modifications thereof will occur to those skilled in the art. It is therefore intended that the foregoing detailed description be regarded as illustrative rather than limiting, and that the following claims, including all equivalents, are intended to define the spirit and scope of this invention.
This application is a divisional application of application Ser. No. 11/515/626 filed on Sep. 5, 2006, now U.S. Pat. No. 7,966,786 which is a continuation-in-part of application Ser. No. 10/607,225 filed Jun. 26, 2003, now abandoned each of which is hereby incorporated by reference.
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Number | Date | Country | |
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20100242377 A1 | Sep 2010 | US |
Number | Date | Country | |
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Parent | 11515626 | Sep 2006 | US |
Child | 12814173 | US |
Number | Date | Country | |
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Parent | 10607225 | Jun 2003 | US |
Child | 11515626 | US |