The present invention relates to systems and methods for facilitating accessing of lock and/or dam gate assemblies and related components (including, for example, tainter gates) for purposes of allowing installation, replacement, repairing, or other actions to be taken in relation thereto, and more particularly relates to bulkhead systems (including components and arrangements thereof) and related methods for achieving one or more of such objectives.
It is often desired that installation, replacement. repairing, and/or other actions be performed in relation to fainter and other lock and dam-type gate assemblies and related components. In some circumstances, it is desired that such actions be performed even though it is not possible or not desirable (due to cost concerns, etc.) for the water typically present around such lock and dam-type gate assemblies to be diverted and drained away from those gate assemblies and related components. It is known that, in at least some such circumstances, the desired actions to be performed in relation to a gate assembly (or associated components) can be performed even though water is still present at or near the upstream end of the gate assembly, by providing a blocking structure or “bulkhead” (or bulkhead structure) at or near the upstream end of those gate assemblies, By providing such a bulkhead structure, even though the water is present at or near the upstream end of the gate assembly, the water is dammed up and prevented from flowing downstream of the bulkhead structure, and thus downstream portions or components of the gate assembly become dry and accessible. so that the desired actions can be taken in relation to those downstream portions or components.
Notwithstanding, the potential effectiveness of utilizing bulkhead systems in at least some such circumstances, conventional bulkhead systems are often cumbersome and/or difficult to implement, and/or costly to utilize. Therefore, it would be desirable to provide an improved bulkhead system and/or method that could be developed that would facilitate the performing of installation, replacement, repairing, and/or other actions ill relation to gate assemblies and/or associated components in manner(s) that were enhanced relative to conventional bulkhead systems in terms of ease of use or implementation, cost, and/or one or more other considerations.
In at least one example embodiment, the present invention relates to a bulkhead system for preventing or limiting water flow. The bulkhead system includes a bulkhead assembly baying a first end and a second end, the bulkhead assembly including first and second bulkhead sections that each extend between the first and second ends, that are positioned adjacent to one another along a horizontal or substantially horizontal interface surface, and that are arranged so that the first bulkhead section is positioned vertically above the second bulkhead section. Each of the first and second bulkhead sections includes as respective cavity that is configured to receive ballast, the bulkhead sections being capable of varying degrees of floatation or submerging depending upon amounts of the ballast that are received in the cavities. The bulkhead system also includes first and second side assemblies that are respectively positioned adjacent to the first and second ends of the bulkhead assembly and that are configured respectively to span respective distances outward from the respective first and second ends so that the overall bulkhead system will extend fully between opposed side structures of as darn when implemented in relation thereto. Each of the side assemblies includes a respective first structural member that extends outward away from the bulkhead assembly from a respective first location along the respective end of the bulkhead assembly adjacent to which the respective side assembly is positioned, and also each of the side assemblies includes a respective brace member that extends outward away from as respective second location along the bulkhead assembly adjacent to which the respective side assembly is positioned, up to a respective further location along the respective first structural member of the respective side assembly. The bulkhead system further includes a plurality of seal structures configured to establish a watertight or substantially watertight interfacing of the bulkhead system with respect to the dam when implemented in relation thereto.
In at least one additional example embodiment, the present invention relates to a method of implementing a bulkhead system in relation to a dam so as to prevent or limit a flow of water past the dam. The method includes providing a plurality of bulkhead sections assembled together as a bulkhead assembly, where each or the bulkhead sections includes a respective internal cavity that is configured to receive a respective amount of ballast therewithin, and coupling first and second side assemblies to first and second ends of the bulkhead assembly so as to form the bulkhead system. The method also includes causing a first of the bulkhead sections to receive the respective amount of ballast therewithin, receiving water pressure at an upstream surface of the bulkhead assembly such that the bulkhead system is forced against the dam and substantially sealed in relation thereto, and operating to counteract the water pressure and thereby prevent or limit the flow of water past the dam, where the operating is performed at least in part by one or more brace members of the side assemblies of the bulkhead system.
In at least one further example embodiment, the present invention relates to a method of implementing a bulkhead system in relation to a dam so as to prevent or limit a flow of water past the dam. The method includes assembling a plurality of bulkhead sections together as a bulkhead assembly, where each of the bulkhead sections includes a respective internal cavity that is configured to receive a respective amount of ballast therewithin, and further assembling first and second side assemblies to first and second ends of the bulkhead assembly and to one another so as to form the bulkhead system, where the further assembling of the side assemblies to one another includes coupling the side assemblies by way of one or more rods. Additionally, the method includes floating the bulkhead system to a first location proximate the dam causing a first of the bulkhead sections to receive the respective amount of ballast therewithin so as to result in tipping of the bulkhead assembly as the first bulkhead section becomes increasingly submerged relative to a remainder of the bulkhead assembly, and additionally causing a second of the bulkhead sections to receive the respective amount of ballast therewithin so as to result in further submerging of the bulkhead assembly. The method further includes receiving water pressure at an upstream surface of the bulkhead assembly such that the bulkhead system is forced against the dam and substantially sealed in relation thereto, and operating to counteract the water pressure and thereby prevent or limit the flow of water past the dam, where the operating is performed at least in part by one or more brace members of the side assemblies of the bulkhead system.
Notwithstanding the above examples, the present invention is intended to encompass a variety of other embodiments including for example other embodiments as are described in further detail below as well as other embodiments that are within the scope of the claims set forth herein.
Embodiments of the disclosure are disclosed with reference to the accompanying drawings and are for illustrative purposes only. The disclosure is not limited in its application to the details of construction or the arrangement of the components illustrated in the drawings. The disclosure is capable of other embodiments or of being practiced. or carried out in other various ways. In the drawings:
Referring to
As shown in
Referring particularly to
As also shown, it is the second (lower) bulkhead section 118 of the bulkhead assembly 106 that in the present example is in contact with an upper edge 18 of the monolith 16. More particularly, in this example, a seal component 111 along or proximate to the bottom of the downstream side surface 120 of the second (lower) bulkhead section 118 particularly is in contact with the upper edge 18 of the monolith 16 such that a watertight seal is formed between the monolith and the bulkhead assembly 106. AS for
Turning to
By comparison with
Referring again to
With respect to the first structural steel member 124 of the present embodiment in particular, when the second side assembly 110 is implemented in relation to the bulkhead assembly 106 and the dam 2 as shown in
Further as shown in more detail in
Although in the present embodiment, the first structural steel member 124 includes the walls 193, 194, 195, 196 defining the single internal tubular cavity and the two side pockets, in other embodiments other types of members can be employed that have different structural features. For example, in another embodiment, there can be present more than two connection walls such that more than one internal tubular cavity is present, and/or depending upon the placement of connection walls one or both of the side pockets can be absent or the side pockets can be different in size relative to one another. Also, although the present embodiment includes the stiffeners 197, in other embodiments such stiffeners need not be present (and also in other embodiments such stiffeners can be spaced differently than as shown).
Further as shown in
The respective structural gussets 132 are also respectively positioned at different respective vertical levels along the first structural steel member 124 that coincide with the respective vertical levels at which are positioned the respective support struts 142. As shown, the respective structural gussets 132 are respectively coupled to the respective support struts 142 and extend diagonally outward away from the respective support struts 142 (that is, in a direction away from the bulkhead assembly 106 when the second side assembly 110 is assembled thereto), from respective locations 134 that are along a common vertical axis, so as to be ultimately connected with the front wall 193 of the first structural steel member 124. Thus, when the second side assembly 110 is assembled in relation to the bulkhead assembly 106, the support struts 142 are between that bulkhead assembly and respective ones of the structural gussets 132, as well as between that bulkhead assembly and the first structural steel member 124 (albeit depending upon the embodiment the vertical side edges 130 or portions thereof can also be in direct contact with the bulkhead assembly 106). Further, when the bulkhead system 100 is implemented in relation to the dam 2, the structural gussets 132 extend outward diagonally away from the bulkhead assembly 106 toward the second pier 12, generally in a downstream direction.
As for the additional formations 191, as shown in
Still referring to
In the present embodiment, each of the second structural steel members 126 includes a respective primary rectangular portion 150, a respective angular buttress portion 152 and a respective further angular portion 154. As is evident from
Additionally, the respective angular buttress portions 152 are right triangular formations that are formed integrally with respect to (or mounted on) the respective inner side edges 158 of the respective primary rectangular portions 150 and jut inwardly relative to the inner side edges (that is, toward the center of the bulkhead assembly 106 when the second side assembly 110 is assembled thereto). Each of the respective angular buttress portions 152 is particularly configured so that a respective front edge 157 of each of the buttress portions extends perpendicularly relative to the inner side edge 158 of the corresponding rectangular portion 150, and is configured to contact one of the downstream side surfaces 120 of the bulkhead assembly 106 (see
Further as shown, each of the second structural steel members 126 additionally includes one or more of the further angular portions 154.
In contrast to the angular buttress portions 152, which include the front edges 157 intended to interface to the bulkhead assembly 106, the further angular portions 154 are not intended to contact or directly support the bulkhead assembly 106. Rather, each of the further angular portions 154 is configured to support a respective first end 174 of a respective threaded rod 176 that extends between that further angular portion of the second structural steel member 126 of the second side assembly 110 and a complementary (mirror image) further angular portion of a complementary (mirror image) second structural steel member of the first side assembly 108, which supports a respective second end 178 (visible in
It should be further appreciated from close inspection of
As for the third structural steel member 128, this member is located adjacent to the first structural steel member 124, along the rear wall 194 thereof (and thus downstream of the first structural steel member), and also is located adjacent to the second structural steel members 126, on outer side edges 159 of the primary rectangular portions 150 thereof opposite the inner side edges 158 thereof (which as noted above are configured to contact the second end. surface 114 of the bulkhead assembly 106). The third structural steel member 128, in contrast to the second structural steel members 126, is a member that extends the same vertical length as the first structural steel member 124, and the third structural steel member 128 is mounted to (or otherwise coupled to or in contact with) the first structural steel member 124 in such a manner that the junction therebetween is sealed in a watertight manner. The third structural steel member 128 in the present embodiment includes a rectangular tubular member 127 with an internal vertically-extending cavity, albeit in other embodiments the third structural steel member can instead include another vertically extending structure such as a structure having a C-shaped cross-section, where one edge of the C is mounted to the first structural steel member 124 and the other end of the C is in contact with the second structural steel members 126.
The third structural steel member 128 is the particular portion of the second side assembly 110 that allows for sealing of that side assembly to the second pier 12 and concrete monolith 16 of the dam 2. In particular, the third structural steel member 128 in addition to the vertically-extending rectangular tubular member 127 also includes the seal component 122 already mentioned above (see
Further as shown in
In view of the above, therefore, the bulkhead system 100 when implemented in relation to portions of the dam 2 provides a watertight seal (cr, perhaps if imperfectly implemented, a substantially watertight seal) so as to prevent water upstream of the bulkhead system from proceeding into the region downstream of the bulkhead system, due to the watertight seals established between the bulkhead system and the dam. More particularly, the additional seal component 140 of the second side assembly 110 seals that side assembly in relation to the second pier 12, as corresponding (complementary or mirror image) additional seal component of the first side assembly 108 seals that side assembly in relation to the first pier 10, the seal components 122 of the two side assemblies 108, 110 seal the base regions of those side assemblies in relation to the concrete monolith 16, and the seal component 111 seals the bulkhead assembly 106 in relation to the concrete monolith 16.
Additionally it should be noted that, in the present embodiment, the bulkhead system 100 is particularly strengthened/reinforced in several manners so as to resist the forces of water along its upstream side that are unbalanced by similar forces on its downstream side when the bulkhead system is fully implemented in relation to the dam 2. First, the structural gussets 132 serve to strengthen the side assemblies 108, 110 to resist forces/torques experienced by those side assemblies due to their positioning between the bulkhead assembly 106 and the piers 10, 12. Second, tension provided by the threaded rods 176 acting upon both of the side assemblies 108, 110 by way of the second structural steel portions 126 also serves to strengthen the overall bulkhead system 100 and to prevent (or resist) bending/bowing of the center regions of the bulkhead system relative to its sides proximate the piers 10, 12.
As already noted, in the present embodiment, the bulkhead assembly 106 includes two bulkhead sections, namely, the first and second (respectively, upper and lower) bulkhead sections 116 and 118. In view of this, the present embodiment includes not merely one but rather four of the threaded rods 176 located at different vertical levels along the bulkhead assembly 106, with two (the upper two) of the threaded rods being associated with the first bulkhead section 116 and the other (lower) two of the threaded rods being associated with the second bulkhead section 118. Notwithstanding the use of two bulkhead sections and four threaded rods in the present embodiment, in other embodiments there can be more or less than two bulkhead sections and more or less than four threaded rods (and more or less than two threaded rods per bulkhead section).
It is further envisioned that the above-described embodiment of the bulkhead system 100 (as well as a variety of other similar embodiments of bulkhead systems) can be implemented/installed/assembled in relation to the piers 10, 12 and the monolith 16 of the dam 2 in a particular manner. To begin with, it should be understood that each of the bulkhead sections 116, 118 in the present embodiment is a submersible bulkhead (or barge) section having a sealable interior cavity 109 (as shown in phantom in
Given such a design of bulkhead sections such as the bulkhead sections 116, 118, the process of implementing the bulkhead system 100 can be performed in a manner as shown by a flow chart 300 in
It should be appreciated that, when emptied or substantially emptied of water, each of the bulkhead sections 116, 118 and thus the bulkhead assembly 106 will float within a waterway. Further, in the present embodiment, the bulkhead assembly 100 comprising those bulkhead sections 116, 118 (and the bulkhead assembly 106) will float within a waterway. Given this to be the ease, the bulkhead system 100 (including the bulkhead sections 116, 118/bulkhead assembly 106) can therefore be easily floated toward and moved into location relative to the piers 10, 12. Thus, at a step 308, the bulkhead assembly 106 achieved at the step 302 (and indeed the bulkhead system 100 overall) is floated to a location proximate to the piers 10, 12 (and concrete monolith 16) of the dam 2 with respect to which the bulkhead system 100 is to be installed.
Once the bulkhead system 100 including the bulkhead assembly 106 is in position near the dam 2, then at a step 310 one or more of the bulkhead sections is/are individually filled with ballast (water) as appropriate to submerge the overall bulkhead assembly (and thus the bulkhead system) in the desired manner. This filling process can depend upon a variety of circumstances, the operational conditions, and/or the number of characteristics of bulkhead section(s) that are employed in the bulkhead system 100/bulkhead assembly 106. For example, in the present embodiment involving the two bulkhead sections 116 and 118, the step 110 can involve performing of a first substep 312 at which the second bulkhead section 118 is first filled with water (e.g., water is pumped in) so that the overall bulkhead assembly 106 is tipped and the second bulkhead section particularly becomes submerged. Then once the second (lower) bulkhead section 118 is fully ballasted, to second substep 313 is performed at which the first bulkhead section 116 is also filled with water (with the pumping being switched) as appropriate and partly submerged to a desired level (with a portion of the bulkhead assembly 106 remaining above the water line). The substeps 312 and 313 are shown with dashed lines to indicate that this manner of performing the step 310 is optional and. that the step 310 can be performed in a variety of other manners as well (for example, in another scenario, the first bulkhead section 116 need not be filled at all with ballast).
Among other things, submerging of the bulkhead assembly 106 involves positioning the bulkhead assembly so that it is positioned so that the downstream side surface 120 of the second bulkhead section 118 (or the seal component 111 associated therewith) is in contact with the concrete monolith 16 and so the bulkhead assembly 106/bulkhead system 100 is positioned so as to be centered between (or more-or-less centered between) the piers 10, 12 of the dam 2. Submerging can in sonic cases already render the bulkhead assembly 106/bulkhead system 100 fixed in relation to the dam 2 (or the monolith 16 thereof, or in relation to a riverbed or other fixture), albeit this need not be always the case. As represented by a further substep 314, in at least some circumstances the performing of the substep 313 does not result in the bulkhead assembly 106/bulkhead system 100 being fixed in place but rather, at the substep 314, further adjustment of the positioning of the bulkhead assembly can still occur after the submerging. Such further adjustment is possible, in at least some cases, because the bulkhead assembly 106/bulkhead system 100 is still floating even after being filled with ballast and therefore can still be floated further into the proper position. That is, once the bulkhead assembly 106/bulkhead system 100 is correctly ballasted, and floated above the dam 2 (tainter gate), the entire assembly is carefully aligned and pulled into place.
Once the step 310 has been fully performed, then the process of installation/implantation of the bulkhead system 100 is nearly complete. Since the bulkhead system 100 is properly positioned, the water downstream of the bulkhead system 100 drains away (e.g., the water between the bulkhead and the tanner gate is lowered) and the force of the water along the upstream surface of the bulkhead system provides forces that drive the bulkhead system 100 against the dam 2, compress the seals therebetween, and hold the bulkhead system in place, as represented by the step 315, at which the process is completed. The bulkhead system 100 at this time can be considered to be attached/coupled to the dam 2 albeit the attachment/coupling is merely due to the forcing of the bulkhead system 100 against the dam.
Once this has occurred, as represented by the step 316, the bulkhead system 100 then is fully operational so as to block or limit the flow of water past the bulkhead system, with such blocking/limiting operation including operation to counteract the force of the water pressure bearing on the bulkhead system 100. It should further be appreciated that the counteracting operation particularly includes operation of bracing, mechanisms provided in the bulkhead system, including for example both the structural gussets 132 and the angular buttress portions 152. Even though
Notwithstanding the ordering of the steps of the flow chart 300 discussed above, in alternate embodiments other processes with other and/or additional steps and/or other orderings of steps can be utilized to implement the bulkhead system 100 or other embodiments of bulkhead systems encompassed herein in relation to a structure such as the dam 2. For example, although in the embodiment of
Also, in some alternate embodiments, the side assemblies 108, 110 are not only attached/coupled to the bulkhead assembly 106 by way of fasteners (and to one another by way of the threaded rods 176) but also are attached/coupled to the piers 10, 12 by way of additional fasteners. Further, although not done in the present embodiment, it is possible for the assembling of the bulkhead sections (e.g., the assembling of the bulkhead sections 116, 118 in accordance with the step 302) to be deferred until such time as those bulkhead sections are floated proximate to the dam 2. Also, in the event that the bulkhead system only includes a single bulkhead (e.g., only one of the bulkhead sections 116 or 118), the step 302 involving assembly of multiple bulkhead sections can be dispensed with altogether.
As mentioned, attachment of the bulkhead sections 116, 118 to one another can be accomplished by way of any of a variety of types of fasteners, In some cases, the attachment of the bulkhead sections 116, 118 is achieved indirectly by virtue of attachment of the side assemblies to each of the bulkhead sections (that is, the side assemblies hold the bulkhead sections together). Additionally, attachment of the side assemblies 108, 110 to the bulkhead assembly 106 (with the bulkhead sections 116, 118) also can be accomplished by way of any of a variety of types of fasteners. In at least some embodiments, where FLEXIFLOAT® steel floats or modular (sectional) barges (e.g., the SERIES-50 QUADRA sectional barges mentioned above) are employed as the bulkhead sections 116, 118, the bulkhead sections are attached to one another and to the side assemblies 108, 110 by way of FLEXIFLOAT connectors that are also available from Robishaw Engineering, Inc. (mentioned above), where the FLEXIFLOAT connectors are or include complementary male and female connector elements that are formed on the interfacing. surfaces of the different sections/assemblies. The support struts 142 in particular can be, in at least some embodiments, such FLEXIFLOAT connectors that serve to connect the side assemblies 108, 110 to the bulkhead sections 116, 118 of the bulkhead assembly 106 (other FLEXIFLOAT connectors used to connect the bulkhead sections to one another arc not shown in the figures, but nevertheless can be understood to be present and integrated with those bulkhead sections as well). Additionally, although in softie embodiments the bulkhead system 100 is attached to the dam 2 (or to the piers 10, 12 thereof) by way of fastening mechanisms, in other embodiments (including the present embodiment) the bulkhead system 100 is held in position relative to the piers 10, 12 and the monolith 16 of the data simply due to the force of the water applied to the bulkhead system 100 tending to push that system downstream, in combination with the wedging of the bulkhead system in between the piers 10, 12 (as shown, each of the piers tends to have a concave shape such that downstream movement of the bulkhead system 100 tends to further lock the bulkhead system in between those piers as a result).
It should be appreciated that the present disclosure envisions and encompasses numerous embodiments having a variety of dimensions, features, and characteristics, and the sizes and configurations of the components employed in any given implementation will typically be suited to lit the dimensions and characteristics of the dam. In one embodiment corresponding to the bulkhead system 100 described above with respect to
In this example embodiment, the side assemblies (extensions) 108, 110 also connect to the bulkhead sections (barges) 116, 118 using the FLEXIFLOAT connections, which also reinforces the internal connection of the two bulkhead sections (barges) along the 40′ length at which those two bulkhead sections are connected to one another. Also in this embodiment, the first structural steel member 124 of each of the side assemblies (extensions) 108, 110 is formed by two 20-foot long HP 14×89 beams that are welded together to provide an approximately 28-inch wide. The stiffeners 197 discussed above are provided at the outer flanges and inner flanges of the welded beams that are positioned near the pier and near the support struts 142. Further in this embodiment, the rectangular tubular member 127 of the third structural steel member 128 of each of the side assemblies 108, 110 is formed by a 20-foot long 10×10 HSS steel tube, which is attached to the downstream side of the first structural steel member 124 (the welded beams). The additional seal component 140 can include a side plate plus, as mentioned above, the 2 inch by 8 inch cofferdam seal, both of which are attached to this steel tube so as to match the contour of the tanner gate pier. Also, a shorter piece of the 10×10 HSS tubing can be welded to the bottom of each of the side assemblies 108, 110 to constitute the seal component 122 that provides a seal against the bottom sill (concrete monolith 16) of the gate/pier.
In addition, seal material constituting the further seal component discussed above (not shown in the figures) is attached to the side plates and sill connections (e.g., to the seal components 122) to further provide a seal of the side assemblies 108, 110 in relation to the sill the concrete monolith 16) when installed. This seal material/further diet seal component can have various dimensions depending upon the embodiment including, for example, 2″ in thickness (or some other thickness) by 6″ in length, or other dimensions as dictated by the surface profile of the concrete to which it is to seal against (in general, when the surface of the concrete that the cofferdam is sealing. against has a rougher surface, then a thicker seal material is needed to conform to the rougher surface profile and vice-versa). A channel with seal material in one embodiment can be pulled up against the bottom of the bulkhead assembly 106 with threaded rod to seal the interior joint between the bulkhead sections (barges) 116, 118 of the bulkhead assembly 106. Seal material can also be placed along the top side of the barge (that is, along the side of the barge that is at the top when the barge is floating), at the portion of barge that will rest against the sill when the barge (bulkhead assembly 106) is submerged.
As mentioned above, the support struts 142 extending from the first structural steel members 124 of the side assemblies 108, 110 can be FLEXIFLOAT connectors. Further, the structural gussets 132 in the present embodiment serving as braces can be 36.5″ (in length)×6″×6″ HSS tubes that extend from the lower (forward or upstream) part of the support struts 142 up to the outer one of the two HP beams that form the first structural steel member 124 (that is, up to the portion of the front wall or forward surface 193 formed by that one of the HP beams that is closer to the pier when the bulkhead system is implemented), centered on the web. The additional formations 191 running along the first structural steel member 124 can be 4×4×¼″ angle section(s). In the embodiment where there arc multiple such additional formations 191 that extend along the first structural steel member 124 with the support struts 142 therebetween, the additional formations 191 between the support struts 142 can be 54 inches in vertical length, while the additional formation above the uppermost one of the support struts can be 26.5 inches long and additional formation below the lowermost one of the support struts can be 27.5 inches long.
Further, with respect to the second structural steel members 126, in the present embodiment the primary rectangular portions 150 of these four members (which form a secondary connection system) are formed by four short pieces of the HP 14×89 beams, which are welded vertically to the HP beams that form the first structural steel member 124 at the rear wall (surface) 194 thereof (and particularly to the inner one of the two HP beams that form that first structural steel member). Further, the angular buttress portions 152 in the present embodiment are 6×6×1/2″ (or alternatively ¾″) angle plates welded to the inner side edges 158 of the primary rectangular portions 150 formed by the aforementioned beams (that is, the edges along the bulkhead sections/barges). In the present embodiment, each of the angle buttress portions 152 of the tour second structural steel member 126 on each of the side assemblies 108, 110 also have 4½ inch gusset stiffeners at each of the four locations. Additionally, in the present embodiment the further angular portions 154 similarly can be formed by ½″-thick (or alternatively ¾″-thick) angle plates that are welded to the primary rectangular portions 150, and each of the threaded rods connecting the further angular portions on the two side assemblies 108, 110 can be a 1 ⅜″ diameter tie rod (150 kilopound per square inch or ksi) such as a DYWIDAG tie rod made from THREADBAR® structural steel as available from DYWIDAG-Systems International (or DSI) GmbH of Aschheim. Germany, also having a place of business at Bolingbrook, Ill.
As noted above, in at least some embodiments a piping system can be installed in the bulkhead sections (barges) that allows the second (lower) bulkhead section 118 to be filled with water, thus causing the bulkhead assembly 106 list to one side with all of the weight supported by the first (upper) bulkhead section 116 and creating a floating, upright bulkhead assembly. The first (upper) bulkhead section 116 can also be ballasted with water to adjust the height of the bulkhead assembly 106 in the water. The barge/bulkhead assembly 106 in at least sonic cases is partially submerged and adjusted for depth to match the gate/sill elevations and then floated into place. Additionally, in one example embodiment where a piping system is used, the piping system includes a water pipe and vent pipe on each end of each of the bulkhead sections (barge) 116, 118, and all of the piping is 3 inch black steel schedule 40 piping. The water inlet/outlet couplings and vent pipe couplings are welded flush to the tops of the bulkhead sections 116, 118 to allow the bulkhead sections to be used in other applications with the installation of a plug. The water couplers also have stand pipes that are installed near the lower edges (when submerged) of the bulkhead sections (barges) 116, 118 at a depth near the bottoms of the bulkhead sections or assembly to and in removal of the water during demobilization. The vent pipe couplers are installed near the upper edge of the bulkhead sections (barges) 116, 118. The piping also is completely removable for trucking purposes and is secured to the deck of the bulkhead sections/assembly by the couplers and standard pipe clamps that are welded to the deck, The upper ends of the water pipes are equipped with valves and quick connects for the water pumps. All of the pipes are equipped with valves to seal the entire system if needed.
Additionally notwithstanding the above discussion, numerous other embodiments are possible and intended to be encompassed herein as well. For example, depending upon the embodiment, any of various numbers and configurations of sectional barges and end
appendages or extensions can be utilized. The particular numbers and/or configurations of such structures can be varied to address different dam pier geometries (in many cases without actually providing precise design information concerning those particular configurations). Although the bulkhead system configuration shown in
Thus, in view of the above discussion, it should be recognized that the present disclosure is intended to encompass numerous embodiments of bulkhead systems having one, two, three, or even more bulkhead sections as well as embodiments of bulkhead systems employing any of as variety different types of side/end assemblies or structures (including embodiments where no such side assemblies are utilized), and that such various embodiments can be implemented in a variety of circumstances and depending upon a variety of factors including, for example, the unique dam geometry in each situation that is encountered or endemic to a given region/situation. The present disclosure particularly is intended to encompass, among other things, bulkhead systems that are one or both of modular in nature, insofar as any of a variety of modular components can be assembled to form the system (e.g., one or more bulkhead sections as well as one or more side/end assemblies), as well as submersible (or partly submersible) insofar as one or more of the bulkhead sections or other system components can be filled with ballast causing those sections or other system components to become submerged.
It is specifically intended that the present invention not be limited to the embodiments and illustrations contained herein, but include modified forms of those embodiments including portions of the embodiments and combinations of elements of different embodiments as come within the scope of the following claims.
The present Application claims the benefit of U.S. provisional patent application no. 61/604,734 filed on Feb. 29, 2012 and entitled “Submersible Bulkhead System and Method of Operating Same”, which is hereby incorporated by reference herein.
Number | Name | Date | Kind |
---|---|---|---|
249024 | Dechant | Nov 1881 | A |
1567715 | De Witt | Dec 1925 | A |
1858664 | Friedel | May 1932 | A |
1918015 | Broome | Jul 1933 | A |
2055512 | Wallace | Sep 1936 | A |
2385341 | Bayley | Sep 1945 | A |
2683354 | Harza | Jul 1954 | A |
4439061 | Whipps | Mar 1984 | A |
4661014 | Aubert | Apr 1987 | A |
4729692 | Tucker | Mar 1988 | A |
5032038 | Lemperiere | Jul 1991 | A |
5118217 | Younes | Jun 1992 | A |
5195846 | Lemperiere | Mar 1993 | A |
5634742 | Mills | Jun 1997 | A |
5642963 | Obermeyer | Jul 1997 | A |
6004067 | Peppard | Dec 1999 | A |
6012872 | Perry et al. | Jan 2000 | A |
6450733 | Krill et al. | Sep 2002 | B1 |
7214003 | Lux, III | May 2007 | B1 |
7690865 | Stewart et al. | Apr 2010 | B1 |
7815397 | Dung | Oct 2010 | B1 |
8066449 | Lux, III | Nov 2011 | B2 |
20030082007 | Liou | May 2003 | A1 |
20080008529 | Lux, III | Jan 2008 | A1 |
20090252557 | Fisher | Oct 2009 | A1 |
Number | Date | Country |
---|---|---|
19649868 | Jun 1997 | DE |
0163292 | Dec 1985 | EP |
62156413 | Jul 1987 | JP |
Entry |
---|
Floating Bulkhead Gates, webpage of Steel-Fab, Inc., retrieved from url: http://web.archive.org/web/20100117193750/http://www.steel-fab-inc.com/gates-floatingbulkhead.html, dated (according to the Internet Archive “Wayback Machine”) Jan. 17, 2010, 1 page. |
Schematic Drawing sent from J.F. Brennan, Inc. to Robishaw Engineering, Inc. on Apr. 20, 2010, 1 page. |
Working Drawing from Robishaw Engineering, Inc. For Flexifloat S-50 Quadrafloat, dated Nov. 8, 1996, 1 page. |
Working Drawing from Robishaw Engineering, Inc. for Design Loads S-50 Series Connector System, dated Feb. 25, 2002, 1 page. |
Number | Date | Country | |
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61604734 | Feb 2012 | US |
Number | Date | Country | |
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Parent | 13780937 | Feb 2013 | US |
Child | 14513013 | US |