1. Field of the Invention
The present invention relates generally to the maintenance of seawalls disposed between bodies of water and retained earth and, more particularly, to methods and apparatus for maintaining seawalls using anchoring devices to strengthen the seawalls to resist potential damage and/or repair actual damage in the seawalls.
2. Discussion of the Related Art
Seawalls are commonly disposed between bodies of water and earth to provide physical boundaries between the bodies of water and the earth and to support or retain the earth by resisting the pressure of the retained earth against the seawalls. Seawalls can be used to separate earth from various types of bodies of water of various sizes and depths. Seawalls can be constructed in various ways and of various materials. Typically, seawalls have a vertical span or height sufficient for an upper end of the seawall to normally extend above the water with a lower end or toe portion of the seawall embedded in the earthen floor to extend below the body of water. The distance that a seawall extends above the water may vary depending on the height of the retained earth above the water and/or anticipated fluctuations in water level. The depth to which the embedded toe portion extends below the water may vary in accordance with the vertical span of the seawall and/or the depth of the body of water to provide sufficient support for the seawall to resist movement from the pressure of the retained earth against the seawall. Accordingly, seawalls are usually designed for a particular depth body of water. The thickness of seawalls may vary depending on site-specific loads and other engineering parameters. One representative type of seawall comprises concrete panels about ten to fifteen feet high, about four feet wide and about three to five inches thick disposed in side by side abutment to form a continuous wall.
Since the earth exerts greater pressure against seawalls than the water, seawalls are oftentimes damaged or destabilized during their lifetimes as evidenced, for example, by movement, displacement, shifting, cracking and/or misalignment of the seawalls. Sometimes seawalls are placed at risk for damage or instability due to a change in conditions occurring subsequent to installation of the seawalls. For instance, if a body of water is dredged resulting in a greater depth body of water and a lesser depth of penetration for the toe portion of an existing seawall, the lesser depth of penetration for the toe portion may no longer be sufficient for the seawall to support the pressure of the retained earth such that the seawall is susceptible to damage or instability. In some cases, the height of the retained earth on the earth facing side of an existing seawall may be increased, causing increased pressure of retained earth against the seawall by which the seawall may be damaged or destabilized. In addition to the pressures of retained earth, seawalls may be damaged or destabilized directly or indirectly due to other conditions including collisions or other impacts, corrosion, environmental factors, and age. Since removal and replacement of damaged and/or unstable seawalls involves significant cost and disruption, it is preferable to strengthen existing seawalls to repair and/or avoid damage or instability.
It has been proposed to strengthen seawalls to resist movement using anchors or tie rods in conjunction with cementitious material as represented by U.S. Pat. No. 1,270,659 to Ravier, U.S. Pat. No. 4,480,945 to Schnabel, Jr., U.S. Pat. No. 4,711,604, to Heimsoth et al., and U.S. Pat. No. 4,728,225 to Brandl et al. U.S. Pat. No. 3,371,494 to Lagerstrom, U.S. Pat. No. 4,253,781 to Fischer et al., and U.S. Pat. No. 4,911,582 to Pierce, Jr. et al. disclose the use of anchors or tie rods in conjunction with cementitious material to restrain structural walls other than seawalls. Helical anchors for building constructions are represented by U.S. Pat. No. 4,499,698 to Hoyt et al., U.S. Pat. No. 5,011,366 to Hamilton, et al., U.S. Pat. No. 5,120,163 to Holdeman et al., U.S. Pat. No. 5,139,368 and U.S. Pat. No. 5,171,107 to Hamilton et al., U.S. Pat. No. 5,213,448 to Seider et al., and U.S. Pat. No. 5,927,905 to van Halteren.
Prior apparatus and methods for repairing and/or strengthening seawalls and other retaining walls have various disadvantages including complicated structure and installation steps, major disruption, the need for excavating and/or disturbing the earth, partial or complete demolition of existing walls, the need to temporarily hold back or contain water during installation, the need to install additional and/or replacement wall structure, the use of cementitious material to assist in anchoring, the need for backfill, and the inability to execute installation from a body of water. Prior apparatus and methods which require earth-side access are untenable where homes or other buildings are situated close to seawalls making it undesirable and even prohibitive to disturb the earth on the earth facing sides of the seawalls and/or to conduct seawall maintenance from the earth facing sides. Prior apparatus and methods for repairing and/or strengthening seawalls and other retaining walls using anchors or tie rods generally lack the ability to rigidly interconnect a plurality of spaced anchors or tie rods installed in a wall to maintain the spacing between the anchors or tie rods in a desired direction. Furthermore, prior apparatus and methods for repairing and/or maintaining seawalls and other retaining walls using anchors or tie rods do not allow a plurality of spaced anchors or tie rods installed in a wall to be adjustably interconnected to adjust the spacing between the anchors or tie rods. Prior apparatus and methods for repairing and/or strengthening seawalls and other retaining walls do not contemplate closing openings in the walls by adjustably moving the walls between interconnected anchors or tie rods installed in the walls on opposite sides of the openings.
Accordingly, there is a need for apparatus and methods for maintaining seawalls by repairing and/or strengthening the seawalls utilizing anchoring devices having anchoring members installed from the water facing sides of the seawalls to extend through the seawalls into the retained earth and retaining members secured to the anchoring members along the water facing sides of the seawalls without the need for excavation and/or disturbance of the earth, removal of existing seawalls or seawall portions and/or the installation of additional seawalls or seawall portions, and without the need for backfill, cementitious material and water containment while having simplified structure and installation steps. There is also a need for apparatus and methods for maintaining seawalls by which at least a pair of spaced anchoring members extending through a seawall may be rigidly secured in interconnected relation to maintain the spacing between the interconnected anchoring members. Another need exists for apparatus and methods for maintaining seawalls by which at least a pair of spaced anchoring members extending through a seawall may be adjustably interconnected to adjust the spacing between the interconnected anchoring members. A need further exists for apparatus and methods for maintaining seawalls by which anchoring members installed in a seawall on opposite sides of an opening in the seawall may be interconnectedly drawn toward one another to close the opening.
Accordingly, it is an object of the present invention to overcome the aforementioned disadvantages of prior apparatus and methods for maintaining seawalls.
Another object of the present invention is to strengthen a seawall utilizing one or more anchoring devices each including an anchoring member having a shaft installed to extend through the seawall from a water facing side thereof and an anchor anchored in earth on an earth facing side of the seawall, and a retaining member secured on the shaft along the water facing side of the seawall.
It is also an object of the present invention to restrain a seawall against movement due to pressure of retained earth on an earth facing side of the seawall by compressing the seawall between a retaining member secured on a shaft of an anchoring member extending through the seawall and an anchor of the anchoring member embedded in the retained earth.
The present invention has as an additional object to adjustably compress a seawall between an anchor of an anchoring member embedded in retained earth on an earth facing side of the seawall and a retaining member disposed along a water facing side of the seawall by adjustably securing the retaining member along a shaft of the anchoring member carrying the anchor and extending through the seawall at a selected non-perpendicular angle.
It is a further object of the present invention to tension an anchoring member longitudinally between an anchor of the anchoring member embedded in retained earth on an earth facing side of a seawall and a retaining member adjustably secured in a selected longitudinal portion along the length of a shaft of the anchoring member extending from the anchor through the seawall at an acute angle with the seawall.
Moreover, it is an object of the present invention to rigidly interconnect at least a pair of anchoring members extending through a seawall at spaced locations to fix the separation distance between the anchoring members.
Yet another object of the present invention is to rigidly interconnect a first anchoring member extending through a seawall to more than one other anchoring members extending through the seawall at spaced locations from the first anchoring member to fix the separation distances between the first anchoring member and the more than one other anchoring members.
It is an additional object of the present invention to adjustably interconnect at least a pair of anchoring members extending through a seawall at spaced locations to adjust the separation distance between the anchoring members and maintain the adjusted separation distance.
The present invention has as a further object to adjustably interconnect a first anchoring member extending through a seawall to more than one other anchoring members extending through the seawall at spaced locations from the first anchoring member to adjust the separation distances between the first anchoring member and the more than one other anchoring members and maintain the adjusted separation distances.
Additionally, it is an object of the present invention to interconnectedly secure a plurality of anchoring members extending through a seawall at spaced locations to one another via connecting members secured on the anchoring members along a water facing side of the seawall.
Another object of the present invention is to close an opening in a seawall by compressing the seawall between anchoring members extending through the seawall on opposite sides of the opening.
Yet a further object of the present invention is to compress a seawall with a desired compressive force between anchoring members extending through the seawall at laterally spaced locations.
The aforesaid objects are achieved individually and in combination, and it is not intended that the present invention be construed as requiring two or more of the objects to be combined unless expressly required by the claims attached hereto.
Some of the advantages of the present invention are that the anchoring devices are installed from the water facing sides of seawalls without the need for excavating or disturbing the earth, removing existing seawalls or seawall portions, adding additional seawalls or seawall portions, water containment, and backfill; the anchoring devices are installed using procedures conducted from the body of water such that the earth facing sides of the seawalls need not be interfered with; the need for cementitious material is eliminated; the anchors can have various configurations including helical formations, arm formations and/or expandable/collapsible formations; any type of earth anchor can be used on the anchoring members; the apparatus and methods of the present invention can be employed on various types of seawalls made of various materials and having various dimensions; the apparatus and methods of the present invention may be used for various aspects of seawall maintenance including the repair of damaged seawalls and as a preventative to avoid damage to existing seawalls not already damaged; the apparatus and methods of the present invention may be used to repair or avoid various types of actual or potential damage to seawalls including movement, shifting or displacement of seawalls, cracked or separated seawalls and misalignment of seawall panels; the apparatus and methods of the present invention may be used for various stages of disrepair in seawalls; depending on the extent of deviation from original specifications, a seawall may be restored to original specifications with a single adjustment performed upon installation of one or more anchoring devices or with multiple incremental adjustments performed dynamically over time following installation of one or more anchoring devices; the apparatus and methods of the present invention may be implemented in accordance with site-specific conditions and engineering requirements; the apparatus and methods of the present invention are particularly advantageous for use where earth-side access is restricted or not viable and/or where replacement of a seawall would entail negative consequences; installation of the anchoring devices may be accomplished using conventional machinery and tools; the number of and locations for the anchoring members installed in a seawall may vary in accordance with individual requirements; the anchoring members may be interlocked in various lateral directions including vertical, horizontal and/or any other angular lateral direction on the seawalls; pairs of anchoring members may be forcefully drawn toward one another in various lateral directions including vertical, horizontal and/or any other angular lateral direction on the seawalls; the shafts of the anchoring members extend through passages formed through the seawalls to facilitate installation; where the cross-sectional sizes of the passages are larger than the cross-sectional sizes of the shafts therethrough, the excess cross-sectional area of the passages not occupied by the shafts may be filled in various ways; ferrules or other structural members may be disposed on the shafts and introduced in the passages with an interference fit to fill the excess cross-sectional area not occupied by the shafts, to support the shafts in the passages and/or to center the shafts in the passages; the retaining members can be designed in various ways for securement on the shafts parallel or non-parallel to the water facing sides of the seawalls; various types of securing members may be used to secure the retaining members on the shafts of the anchoring members; the retaining members may have abutment surfaces configured to abut the water facing sides of the seawalls; various inserts can be inserted or interposed between the retaining members and the water facing sides of the seawalls; the retaining members distribute forces or pressures on the seawalls; the anchoring members can be interlocked by interlocking the retaining members therefor; the retaining members of any two anchoring members can be rigidly interlocked using a fixed length connecting member having opposing ends secured to the retaining members of the two anchoring members, respectively; the retaining members of any two anchoring members can be adjustably interlocked using an adjustable length connecting member having opposing ends secured to the retaining members of the two anchoring members, respectively; the apparatus and methods of the present invention can be used to strengthen existing seawalls for which the depth of penetration of the toe portions is reduced, such as following deepening of the bodies of water on the water facing sides of the seawalls; and the apparatus and methods of the present invention can be used to strengthen existing seawalls for which the height of retained earth is increased on the earth facing sides of the seawalls.
These and other objects, advantages and benefits are realized with the present invention as generally characterized in an apparatus for maintaining a seawall disposed between a body of water and retained earth, the apparatus comprising at least two anchoring devices for being installed on the seawall at spaced locations and a connecting member for rigidly interconnecting the anchoring devices to fix or maintain the separation distance between the anchoring devices. The apparatus may comprise first and second anchoring devices or any number of anchoring devices. Each anchoring device includes an anchoring member and a retaining member. Each anchoring member may comprise a longitudinally extending shaft carrying an anchor having a configuration to anchor the anchoring member in the retained earth. The anchor may comprise any type of earth anchor having various anchor formations including a helical formation, an arm formation and/or a collapsible expandable formation. Each retaining member may comprise a flange having a bore hole therethrough for receiving an end of the shaft of the corresponding anchoring member by which the retaining member is movable longitudinally along the shaft. Each retaining member may have an abutment surface for abutment with a water facing side of the seawall, and the retaining members and the abutment surfaces may have various configurations. Any of the anchoring devices may further include an insert for being interposed between the retaining member and the water facing side of the seawall. Any of the anchoring devices may further comprise a filler for being disposed around the shaft of the anchoring device to fill the passage in the seawall through which the shaft extends when the anchoring device is installed on the seawall. Each retaining member may be secured on the corresponding shaft in various ways using one or more securing structures formed separately from or as part of the retaining member. Securing structures formed separately from the retaining member may comprise a securing member of the anchoring device, and the securing member may include a nut for threadedly engaging the end of the shaft extending from the bore hole of the retaining member. Securing structure formed as part of the retaining member may include a thread along the bore hole for threadedly engaging the end of the shaft.
Each anchoring member is inserted in a passage formed through the seawall and is advanced in the passage into the retained earth to anchor the anchor in the retained earth a distance spaced from an earth facing side of the seawall. The end of each anchoring member extends from the passage along the water facing side of the seawall, and the retaining member is secured on the end of the anchoring member extending from the passage. The retaining members apply compressive force against the seawall by virtue of the seawall and retained earth being compressed between the retaining members and the anchors and by virtue of the anchoring members being tensioned between the retaining members and the anchors. The connecting member rigidly interconnects the ends of the anchoring members to fix or maintain the separation distance between the anchoring members, and the connecting members may be attached to the retaining members of the anchoring devices. The length of the connecting member between the interconnected anchoring members or devices may be fixed or may be adjustable to permit the separation distance between the anchoring members or devices to be selectively adjusted.
The present invention is also generally characterized in a method of maintaining a seawall disposed between a body of water and retained earth involving the steps of forming a passage through the seawall to extend downwardly at an acute angle from a water facing side of the seawall to an earth facing side of the seawall, inserting an anchoring member through the passage from the water facing side and into the retained earth on the earth facing side, advancing the anchoring member into the retained earth to anchor an anchor of the anchoring member in the retained earth at a distance spaced from the earth facing side of the seawall with a longitudinally extending shaft of the anchoring member which carries the anchor extending through the passage along the water facing side of the seawall, and securing a retaining member on an end of the shaft extending from the passage on the water facing side of the seawall to apply compressive force against the water facing side of the seawall to resist displacement of the seawall due to pressure of the retained earth. The method may be performed entirely from a vessel deployed on the body of water without the need for excavation or disturbance of the earth or for earth-side access. Any number of anchoring devices may be installed on the seawall so that the compressive force applied to the seawall is sufficient to strengthen the seawall to resist displacement without the need for cementitious materials for anchoring. The passage may be formed in the seawall by drilling, for example, using a directional drilling machine or any other suitable machinery deployed on the body of water. Advancement of the anchoring member into the retained earth may involve moving the anchoring member into the retained earth longitudinally and/or rotationally. Securing the retaining member on the end of the shaft may involve rotating a securing member on the shaft into compressive engagement with the retaining member with the shaft extending through a bore hole of the retaining member. The method may involve interposing an insert between the retaining member and the water facing side of the seawall. The method may further involve filling the passage around the shaft extending therethrough. Advancement of the anchoring member into the retained earth may involve advancing the anchoring member with the anchor in a collapsed position and moving the anchor from the collapsed position to an expanded position to anchor the anchoring member in the retained earth. The method may comprise periodically adjusting the compressive force of the retaining member against the seawall.
The present invention is further generally characterized in a method of maintaining a seawall disposed between a body of water and retained earth involving installing a first anchoring member on the seawall at a first location, installing a second anchoring member on the seawall at a second location, spaced from the first location, and rigidly interconnecting the anchoring members to maintain the separation distance between the anchoring members. The anchoring members may be installed to extend through the thickness of the seawall with an anchor of each anchoring member anchored in the retained earth at a distance spaced from an earth facing side of the seawall and with an end of each anchoring member extending from a water facing side of the seawall. Installation of the anchoring members may involve securing first and second retaining members on the ends of the first and second anchoring members, respectively, and the first and second anchoring members may be rigidly interconnected by rigidly interconnecting the first and second retaining members. Securement of the retaining members on the anchoring members may involve compressing the seawall and retained earth between the retaining members and the anchors, and the method may involve periodically adjusting the compressive force of the retaining members against the seawall. Rigidly interconnecting the first and second anchoring members may involve adjusting the separation distance between the first and second anchoring members. The method may involve installing the first anchoring member on one side of an opening in the seawall, installing the second anchoring member on an opposite side of the opening, with the step of rigidly interconnecting the first and second anchoring members including drawing the first and second anchoring members toward one another to adjust the separation distance between the anchoring members an amount sufficient to close the opening and maintaining the adjusted separation distance between the first and second anchoring members after the opening is closed. The method may be used to close openings formed by separated cracks or seams in the seawall. The method may involve drawing a pair of interconnected anchoring members together in various directions including vertical and horizontal directions. The method may involve periodically adjusting the separation distance between the anchoring members.
In one representative seawall, the panels 16 are made of concrete and have a height of about ten to fifteen feet, a width of about four feet and a thickness of about three to five inches. The seawall 10 can be constructed in various alternative ways including, for example, as bulkheads, pilings and/or piers, and of various materials including, for example, steel, wood and concrete. The seawall 10 can have various dimensions. Body of water 12 may be any type of body of water including, for example, oceans, harbors, channels, sounds, rivers and lakes. The retained earth 14 may comprise one or more constituents including, for example, dirt, sand, rock and shells. One representative composition for retained earth 14 is an aggregate of sand and shell. Site-specific conditions may be determined using standard engineering tests and/or calculations, such as soil analysis, from which the force or pressure on seawall 10 from earth 14 can be determined.
The force or pressure exerted on seawall 10 by retained earth 14 is ordinarily greater than the force exerted on seawall 10 by body of water 12 such that the seawall may become damaged or unstable. Damage or instability of seawall 10 may be evidenced by movement, displacement or shifting of seawall 10 from its upright vertical orientation, by openings in the seawall due to cracks in individual seawall panels 16 or separation of adjacent seawall panels 16, and/or by misalignment of seawall panels or cracked portions of panels. Various other conditions may contribute to or cause damage or instability in seawall 10 including collisions or other impacts with the seawall, corrosion and age. Where body of water 12 is deepened after construction of seawall 10, the increased depth of body of water 12 results in a reduced penetration depth for toe portion 20 below earthen floor 22 as shown by dotted line 22 in
An anchoring device 32 according to the present invention is illustrated in
Shaft 38 is depicted with a circular cross-section that is uniform or constant along the length of the shaft; however, the cross-section of the shaft can be non-uniform or non-constant along its length. The anchor 44 may be carried on shaft 38 close to or along forward end 40 as shown in
The retaining member 36 may be designed in various ways to be secured on the rearward end 42 of shaft 38 via securing structure formed separately from or as part of the retaining member. The retaining member 36 includes a flange 52 having a forward abutment surface 54 and a bore hole 56 extending through the flange at an angle to the abutment surface. The flange 52 is depicted as being planar with planar abutment surface 54 for abutment with the planar water facing side 24 of seawall 10. It should be appreciated, however, that the abutment surface and/or the flange can have various non-planar configurations and can have various perimetrical configurations including a square perimetrical configuration as shown in
A method for maintaining seawall 10 using anchoring device 32 is performed from body of water 12 without the need for excavating or disturbing retained earth 14 or earthen floor 22 and without the need for earth-side access to seawall 10. As shown in
In accordance with the method of the present invention, the drive shaft 72 carrying drill bit 74 is positioned at the preselected angle A to the seawall 10, and the drive shaft 72 is rotatably driven while being advanced or moved forwardly in a longitudinal or axial direction to form a passage 76 extending entirely through the thickness of seawall 10 from the water facing side 24 to the earth facing side 26 as shown in
Once the passage 76 has been formed in seawall 10, the drive shaft 72 is coupled or connected with the shaft 38 of anchoring member 34 in coaxial relation or alignment. Coupling or connection of the drive shaft 72 with the shaft 38 may be performed above the water on or from the vessel 64. The drive shaft 72 having the anchoring member 34 coupled or connected thereto is positioned at angle A to seawall 10, and the drive shaft 72 is again advanced in a longitudinal or axial direction to introduce the anchoring member 34, forward end 40 first, into and through the passage 76 from the water facing side 24 to the earth facing side 26 of the seawall 10. The drive shaft 72 is rotated while continuing to be advanced in the longitudinal or axial direction to rotate and advance the anchoring member 34 into the retained earth 14. The configuration of forward end 40 and anchor 44 of anchoring member 34 facilitate advancement of the anchoring member in earth 14. The anchoring member 34 is advanced a preselected or predetermined distance into earth 14 such that anchor 44 is embedded in earth 14 at a preselected or predetermined distance from the earth facing side 26 of seawall 10. The configuration of anchor 44 embedded in earth 14 resists withdrawal of the anchoring member 34 from the earth 14. The shaft 38 of anchoring member 34 extends through the passage 76, and the externally threaded rearward end 42 of shaft 38 extends from the passage 46 on the water facing side 24 of seawall 10. As shown in
Where the seawall 10 is made of a material capable of being cut or penetrated by anchor 44 being driven through passage 76, the cross-sectional size of passage 76 may be made no larger than necessary to accommodate the cross-section of shaft 38 extending therethrough. However, the cross-sectional size of passage 76 may be made larger than necessary to accommodate the cross-section of shaft 38, and may be made large enough to accommodate the cross-section of anchor 44. As described below, anchors may be used which have collapsed positions presenting a relatively small or narrow cross-section and expanded positions presenting a relatively large or wide cross-section as described below, and the passage 76 may be made no larger than necessary to accommodate the cross-section of the anchor in the collapsed position. Where an annular or other gap is presented in passage 76 around shaft 38 due to the cross-sectional size of the passage being larger than the cross-section of the shaft 38 extending therethrough, this gap can be filled with any suitable filler as explained further below. Accordingly, the anchoring device 32 may further comprise a filler, such as the sleeve 153 described below and as shown in
The retaining member 36 is secured on the rearward end 42 of shaft 38 along the water facing side 24 of seawall 10 with a predetermined torque to obtain a predetermined tension in anchoring member 34 and a predetermined compression against seawall 10. The rearward end 42 of shaft 38 is inserted in the bore hole 56 of retaining member 36 with the abutment surface 54 of the retaining member facing the water facing side 24 of seawall 10. Where the retaining member 36 is provided with securing structure 62, the retaining member 36 is rotated relative to the shaft 38 in a first rotational direction with the thread 50 on the rearward end 42 in threaded engagement with the thread of bore hole 56. Rotation of the retaining member 36 relative to the shaft 38 in the first rotational direction causes forward advancement of the retaining member 36 longitudinally along the shaft 38 toward seawall 10. The retaining member 36 is rotated relative to the shaft 38 in the first rotational direction to a predetermined torque with the abutment surface 54 in abutment with the water facing side 24 of seawall 10 to obtain a predetermined tension in anchoring member 34 and a predetermined compression against seawall 10. The retaining member 36 is secured on the shaft 38 in the longitudinal position corresponding to the predetermined torque, compression and tension due to engagement of thread 50 with the securing structure 62.
Where the anchoring device 32 comprises securing member 62′, the rearward end 42 of shaft 38 is inserted in the bore hole 56, which may be provided without the internal thread, with the abutment surface 54 facing the water facing side 24. The retaining member 36 is advanced along the shaft 38 in the direction of the seawall, and the end of shaft 38 extending rearwardly from the bore hole 56 is inserted in the hole of securing member 62′ to threadedly engage the internal thread of the securing member 62′ with the external thread 50 of shaft 38. The securing member 62′ is rotated in a first rotational direction to advance the securing member 62′ forwardly along shaft 38 into compressive engagement with the retaining member 36. The securing member 62′ is rotated to a predetermined torque with the abutment surface of the retaining member 36 applying a predetermined compression against seawall 10. The securing member 62′ and the retaining member 36 are secured on shaft 38 in longitudinal positions corresponding to the predetermined torque, compression and tension, the securing member 62′ being held in place due to engagement of its thread with the thread of shaft 38.
When the anchoring device 32 is installed on seawall 10, the seawall 10 and earth 14 between the retaining member 36 and anchor 44 are compressed, and the anchoring member 34 is tensioned between retaining member 36 and anchor 44 to strengthen seawall 10 to resist displacement of the seawall in the direction of water 12. The predetermined torque, compression and tension are selected in accordance with site-specific conditions, the type and/or size of anchoring member, and engineering specifications. Since the central longitudinal axis of bore hole 56 and shaft 38 are disposed at angle A to the abutment surface 54, the abutment surface 54 is in face to face abutment or contact with the water facing side 24 of seawall 10 along plane P, with the central longitudinal axis of shaft 38 extending downwardly from the water facing side 24 to the earth facing side 26.
The retaining member 36 can be secured on the rearward end 42 of shaft 38 at various positions along the length of rearward end 42. Where the retaining member 36 is provided with securing structure 62, the torque, compression and tension can be increased by further rotating the retaining member 36 relative to the shaft 38 in the first rotational direction, and the torque, compression and tension can be decreased by rotating the retaining member 36 relative to shaft 38 in a second rotational direction, opposite the first rotational direction, to cause retraction or rearward movement of the retaining member 36 longitudinally along the shaft 38 in a direction away from seawall 10. When the securing member 62′ is used to secure the retaining member 36, the torque, compression and tension can be increased by further rotating the securing member 62′ in the first rotational direction, and the torque, compression and tension can be decreased by rotating the securing member 62′ in a second rotational direction, opposite the first rotational direction, to cause retraction or rearward movement of the securing member 62′ longitudinally along the shaft 38 in the direction away from seawall 10. Accordingly, torque, compression and tension adjustments are possible in the anchoring devices. The retaining member 36 and securing member 62′ could be rotated, advanced and retracted via drive shaft 72 using an appropriate connector or coupling to releasably couple or connect the retaining member 36 and/or securing member 62′ to the drive shaft 72. The retaining member 36 and securing member 62′ can be secured on the anchoring member 34 using any other suitable machinery or tools operated and controlled from the vessel 64.
Where seawall 10 is not already damaged or unstable, one or more anchoring devices 32 may be installed on seawall 10 to strengthen the seawall to resist potential damage or instability. The compressive force applied by the one or more anchoring devices 32 against seawall 10 via the intermediary of earth 14 enables the seawall 10 to resist deviation from original design specifications, such as displacement from its upright vertical orientation. Where seawall 10 has already deviated from its original design specifications and experienced actual damage or instability, such as displacement from its upright vertical orientation, the one or more anchoring devices 32 can be used to strengthen the seawall and repair the actual deviation or damage. As an example, dotted lines in
The filler 151 comprises a cylindrical ferrule or sleeve 153 having a lumen 155 extending axially therethrough. The lumen 155 has a cross-sectional diameter or size corresponding to the external cross-sectional diameter or size of the rearward end 142 of shaft 138 to receive the shaft 138 therethrough with a close fit. The sleeve 153 has an external diameter or cross-sectional size corresponding to the diameter or cross-sectional size of passage 76 formed in seawall 10 such that the sleeve 153 can be disposed in passage 76 with an interference fit. The sleeve 153 could be provided with engagement structure along lumen 155 for engaging the engagement structure of shaft 138, and such engagement structure may comprise a thread 159 for threaded engagement with the thread 150 on the rearward end of shaft 138.
Installation of anchoring device 132 on seawall 10 in a method of maintaining seawall 10 is similar to that described above for anchoring device 32. A passage 76 of appropriate size is formed through the thickness of seawall 10 at a selected angle for insertion of anchor 144 and shaft 138 therethrough with the anchor 144 maintained in the collapsed position. The anchoring member 134 is advanced into the retained earth14 the appropriate distance and anchor 144 is moved from the collapsed position to the expanded position whereby the anchor 144 is embedded in the retained earth 14 to resist withdrawal of anchoring member 134. The filler 151 is used to fill the annular gap present in passage 76 around the shaft 138 extending therethrough. Accordingly, the sleeve 153 is positioned on the rearward end 142 of shaft 138 which extends from the water facing side 24 of seawall 10 as accomplished by inserting the rearward end 142 in the lumen 155. The sleeve 153 is advanced longitudinally along the shaft 138 in the direction of seawall 10 so that the sleeve enters passage 76 with an interference fit and thereby fills the gap around shaft 138. The sleeve 153 also supports and centers the shaft 138 in the passage 76. Where the sleeve 153 is provided with thread 159, the sleeve is advanced by being rotated relative to the shaft 138 in a first rotational direction. The longitudinal position of the sleeve 153 along the shaft 138 may be maintained due to threaded engagement of thread 150 with thread 159. The drive shaft 72 of machine 70 or any other suitable machinery and/or tools can be used to position and advance the sleeve 153 on the shaft 138 from vessel 64. The sleeve 153 may be retracted or moved rearwardly along the shaft 138 for longitudinal adjustment and, where the sleeve is provided with thread 159, it may be rotated on shaft 138 in a second rotational direction, opposite the first rotational direction, to cause longitudinal rearward movement of the sleeve along the shaft 138 in a direction away from seawall 10. The sleeve 153 may be made of any suitable material including galvanized and stainless steels. Although filler 151 is depicted as a definitive structural component, it should be appreciated that the filler may comprise any suitable filler material with or without a definitive structural shape.
The retaining member 136 is secured on the portion of rearward end 142 which protrudes from sleeve 153 and the passage 76 on the water facing side of seawall 10 and is used to establish tension in anchoring member 134 and compression against seawall 10 as described above for retaining member 36. Tension in anchoring member 134 and compression against seawall 10 may be established using securing member 162′ as described for securing member 62′. Since the bore hole 156 of retaining member 136 is perpendicular to planar abutment surface 154, the abutment surface 154 is at an angle to the water facing side 24 of seawall 10 due to the downward angle of passage 76. Accordingly, the abutment surface 154 is not in face to face abutment with the water facing side 24, and there is a space presented between the abutment surface 154 and the water facing side 24. As shown in
Anchoring device 32 thusly is representative of an anchoring device in which the abutment surface of the anchoring device in contact with the water facing side of the seawall is formed in its entirety by the abutment surface of the retaining member. Anchoring device 132 is representative of an anchoring device in which the abutment surface of the anchoring device in contact with the water facing side of the seawall is formed in part by the abutment surface of the retaining member and in part by an abutment surface of an insert interposed between the retaining member and the water facing side. It should be appreciated that in the anchoring device 132, the abutment surface 154 of retaining member 136 itself can be designed with a configuration 154′ corresponding to the configuration resulting from the combination of abutment surfaces 154 and 163 as shown in
In a method of seawall maintenance using the apparatus of
Following installation of the first and second anchoring devices 232a and 232b, the method of seawall maintenance utilizing the apparatus of
Following installation of the first anchoring device 232a and the third anchoring device 232c, the second connecting member 271b is rigidly interconnected to the anchoring members 234 of the first and third anchoring devices by aligning the outer ends of slots 278 of the second connecting member 271b with the holes 267 in the aligned legs 265 of the first and third anchoring devices, respectively. Bolts 269 are inserted through each pair of aligned outer ends and holes 267 in the aligned legs 265 of the first and third anchoring devices and are secured in place via nuts, respectively. The first end of the second connecting member 271b is adjacent or in abutment with the retaining member 236 of the first anchoring device 232a and the second end of the second connecting member 271b is adjacent or in abutment with the retaining member 236 of the third anchoring device 232c to prevent movement of the first and third anchoring devices toward one another in the horizontal lateral direction. Movement of the first and third anchoring devices 232a and 232c away from one another in the horizontal lateral direction is also prevented due to engagement of bolts 269 with the closed outer ends of slots 278 of the second connecting member 271b.
Due to the rigid interlocking connection between the first and second anchoring devices 232a and 232b, separation, misalignment or other displacement of crack 283 is prevented. Due to the rigid interlocking connection between the first and third anchoring devices 232a and 232c, separation, misalignment or other displacement of seam 284 is prevented. It should be appreciated that the legs 265 can extend from the retaining members 236 in any desired lateral direction to fix or maintain a desired separation distance between a pair of interconnected anchoring devices in any desired lateral direction. Any suitable machinery and/or tools can be used to secure the connecting members to the anchoring devices in interconnected relation from vessel 64. The anchoring devices 232a, 232b and 232c can be inspected or checked periodically and torque, compression and tension adjustments can be made along with adjustments to the fasterners, as needed.
A further alternative apparatus for seawall maintenance is shown in
In a method of seawall maintenance using the apparatus of
Anchoring device 332c is installed on panel 16b of seawall 10 at a third location on seawall 10 laterally spaced from and aligned in the horizontal lateral direction with the first location for anchoring device 332a. First anchoring device 332a and third anchoring device 332c are installed on opposite sides of a vertically extending seam 384 defined between the side edges of adjacent panels 16a and 16b, and the seam 384 has separated or opened to present an opening between the panels 16a and 16b. The retaining members 336 for anchoring devices 332a and 332c are positioned so that a leg 365 of first anchoring device 332a is aligned with a leg 365 of a third anchoring device 332c in the horizontal lateral direction traversing seam 384. The aligned legs 365 of the first and third anchoring devices extend toward each other from the flanges of their respective retaining members 336. Anchoring device 332d is installed on panel 16b at a fourth location on seawall 10 laterally spaced from and aligned in the horizontal lateral direction with the second location for anchoring device 332b. The second anchoring device 332b and the fourth anchoring device 332d are installed on opposite sides of the seam 384. The retaining members 336 for anchoring devices 332b and 332d are positioned so that a leg 365 of second anchoring device 332b is aligned with a leg 365 of fourth anchoring device 332d in the horizontal lateral direction traversing seam 384. The aligned legs 365 of the second and fourth anchoring devices 332b and 332d extend toward each other from the flanges of their respective retaining members 336. The third and fourth anchoring devices 332c and 332d are in vertical alignment with one another on seawall panel 16b.
A method of seawall maintenance utilizing the apparatus of
Following installation of the first anchoring device 332a and the third anchoring device 332c, the second connecting member 371b is interconnected to the anchoring members of the first and third anchoring devices 332a and 332c by aligning the eye formations of the second connecting member 371b with the holes in the aligned legs 365 of the first and third anchoring devices and securing the eye formations to the aligned legs 365 using bolts 369 and nuts as described for the first connecting member 371a. The housing 385 for the second connecting member 371b is rotated in the first rotational direction to retract the stems of the second connecting member into the housing thereby moving or drawing the anchoring members of the first and third anchoring devices 332a and 332c toward one another in the horizontal lateral direction to correspondingly draw panels 16a and 16b toward one another to close or reduce the size of the opening of seam 384 as shown in
With the methods of the present invention, compressive force may be applied against a seawall by one or more anchoring devices sufficient to prevent displacement of the seawall without the need for cementitious material to assist in anchoring. The methods of the present invention can be conducted entirely from a vessel located on the body of water without the need for excavation or disturbance of the earth, earth-side access to the seawall or underwater diving. The methods can be used to strengthen various types of seawalls to resist potential damage and to correct various types and stages of actual damage. The anchors can have various configurations to anchor the anchoring members in the retained earth, and the retaining members can have various configurations. The retaining members can be secured on the anchoring members in various ways including the use of securing members threaded onto the ends of the anchoring members. Where a gap is presented around the anchoring member in the passage through the seawall, various types of fillers can be used to fill the gap. The fillers can include structural components or filler materials not having a definitive structural shape. The retaining members may comprise flanges having various planar or non-planar configurations, and the abutment surfaces of the retaining members can have various configurations. The anchoring devices may include various inserts insertable between the retaining members and the water facing side of the seawall. The retaining members distribute force or pressure against the seawall to resist displacement thereof. Any number of anchoring devices can be installed in a seawall at various locations and in various arrangements. Any pair of anchoring devices can be rigidly interconnected to maintain a fixed separation distance between the anchoring devices. Any pair of anchoring devices may be interconnected using a connecting member which permits adjustment of the separation distance between the interconnected anchoring devices. Adjustable connecting members may be provided which permit the separation distance between interconnected anchoring devices to be increased and/or decreased. Anchoring devices can be installed on relatively movable portions of a seawall and adjustably interconnected to effect movement of the relatively movable portions and thereafter maintain the adjusted position of the relatively movable portions. Adjustably interconnected anchoring devices can be used to close various types of openings in seawalls including openings between seawall panel portions and between seawall panels. Adjustably interconnected anchoring devices can also be used to separate relatively movable portions of a seawall including relatively movable panels or panel portions. The type of anchoring device or devices utilized and the torque, compression and tension for the anchoring device or devices may be selected in accordance with site-specific conditions and engineering specifications. Following initial installation, the anchoring devices and apparatus of the present invention can be checked or inspected periodically and adjustments may be made as needed to maintain or obtain a desired torque, compression and/or tension. Deviations from original design specifications can be corrected in seawalls using the anchoring devices to apply the necessary corrective forces. A deviation from original design specifications can be corrected at one time in a single application of corrective force or forces using one or more devices, or may be corrected dynamically or incrementally over a period of time in multiple applications of corrective force or forces using one or more anchoring devices, much in the manner of orthodontia.
Inasmuch as the present invention is subject to many variations, modifications and changes in detail, it is intended that all subject matter discussed above or shown in the accompanying drawings be interpreted as illustrative only and not be taken in a limiting sense.