The present disclosure relates to hopper barges and, more particularly, to a device for retrofitting a hopper barge with a pumping system.
Dredging is defined as the underwater removal of soil, such as sand, gravel, and rocks, and its transport from one place to another. A hopper barge is a marine vessel that is employed in dredging operations, and is primarily used to carry materials like rocks, gravel, sand, and rubbish, from one location to another for dumping.
An important use of such barges is in the bulk transfer of materials used for land reclamation projects. Such projects require the transport of large volumes of aggregates, i.e., sand, silt, and the like, that are dredged at one location, loaded onto the barges, and discharged at a site where land is being reclaimed.
One known type of hopper barge is known as the “split barge.” The split barge has a hull that selectively divides longitudinally between the end bulkheads. The vessel consists of two major parts, i.e., port and starboard halves. These halves are mostly symmetrical in design and are also hinged at the deck and operated by hydraulic cylinders. When the halves are closed, the hopper barge may be filled with materials for bulk transfer to another location. When the hopper barge is split opened, the contents of the hopper barge are dumped rapidly at the location of the hopper barge.
On many occasions, there is a need to dump the contents of the hopper barge onto a beach or disposal area on land, as opposed to dumping the contents of the hopper barge through the split opening of the hull. However, most hopper barges are not equipped to empty in this way. Retrofitting split-type hopper barges by installing pumping systems has heretofore been complicated, requiring significant changes to the structure of the barge. Such retrofitting operations are also time-consuming and expensive.
Further, even hopper barges that are already equipped with pumping systems are inefficient. It is difficult to empty the contents of these known barges even with pumps.
There is a continuing need for a sluiceway device and method of utilizing a hopper barge for pumping contents to a disposal area such as a beach. Desirably, the sluiceway device allows the hopper barge to be fully emptied in a more efficient manner than existing systems.
In concordance with the instant disclosure, a sluiceway device and method of utilizing a hopper barge for pumping contents to a disposal area such as a beach, and which allows the hopper barge to be fully emptied in a more efficient manner than existing systems, is surprisingly discovered.
In one embodiment, a sluiceway device for a hopper barge includes an elongate main body defining a discharge channel. The elongate main body is configured to be disposed atop an inner surface of a hull of the hopper barge. The elongate main body is further configured to receive dredging material placed in the hopper barge. The elongate main body has a plurality of openings formed therein. There is a plurality of doors disposed adjacent the openings and configured to selectively seal and unseal the openings. Further, a discharge pump is in communication with the discharge channel. The discharge pump is configured to pump the dredging material from the discharge channel to a disposal area outside of the hopper barge.
In another embodiment, a sluiceway device for a hopper barge includes an elongate main body defining a discharge channel. The elongate main body is disposed atop an inner surface of a hull of the hopper barge. The elongate main body is further configured to receive dredging material placed in the hopper barge. The elongate main body has a plurality of openings formed therein. There is a plurality of doors disposed adjacent the openings and configured to selectively seal and unseal the openings. Further, a discharge pump is in communication with the discharge channel. The discharge pump is configured to pump the dredging material from the discharge channel to a disposal area outside of the hopper barge.
In a further embodiment, a method for operating the sluiceway device including providing a hopper barge and a sluiceway device with at least one opening. The sluiceway device has an elongate main body defining a discharge channel. The elongate main body is configured to be disposed atop an inner surface of a hull of the hopper barge. The elongate main body is configured to receive dredging material placed in the hopper barge. The main body has a plurality of openings formed therein. There is a plurality of doors disposed adjacent the openings and configured to selectively seal and unseal the openings. There is a discharge pump in communication with the discharge channel. The discharge pump is configured to pump the dredging material from the discharge channel to a disposal area outside of and spaced apart from the hopper barge. The method further includes filling the hopper barge with dredging material, opening the at least one opening to permit the dredging material to fall into the discharge channel, and pumping water into the discharge channel. The dredging material and water from the discharge channel are pumped from the hopper barge.
The drawings described herein are for illustration purposes only and are not intended to limit the scope of the present disclosure in any way. The above, as well as other advantages of the present disclosure, will become readily apparent to those skilled in the art from the following detailed description, particularly when considered in the light of the drawings described hereafter.
The following description is merely exemplary in nature and is not intended to limit the present disclosure, application, or uses. In respect of the methods disclosed, the order of the steps presented is exemplary in nature, and thus, is not necessary or critical unless otherwise disclosed.
In
The sluiceway device 100 may include an elongate main body 102 having a plurality of openings 104, and a discharge pump 106. As shown in
The sluiceway device 100 may have an elongate main body 102, for example, as shown in
The elongate main body 102 of the sluiceway device 100 may also have an upper major surface 110 for receiving the dredging material 109 placed in the hopper barge 108. In operation, the upper major surface 110 of the sluiceway device 100 is used to selectively hold the dredging material 109 above the split hull until the sluiceway device 100 is operated to remove the dredging material 109, as will be described further herein.
With reference to
With reference to
The discharge pump 106, shown in
Advantageously, the elongate main body 102 may be removably secured to the bottom of the split hull of the hopper barge 108 with suitable mechanical fasteners 128, such as rails, brackets, and bolts, as non-limiting examples. This allows the sluiceway device 100 to be removed when not in use. One of ordinary skill in the art may select other suitable mechanical fasteners for securing the elongate main body 102 of the sluiceway device 100 within the hopper barge 108, as desired.
In certain embodiments of the present disclosure, the openings 104 may be sealed with doors 114 as shown in
Each of the doors 114, in operation, may be configured to be selectively opened. For example, the openings 104 may be operated in sequence from one end of the elongate main body 102 to another end of the elongate main body 102. This sequential operation of the openings 104 permits the dredging material 109 to fall into the discharge channel 112 in an orderly and predetermined manner further detailed hereinbelow.
As shown in
In particular, each of the hinged doors 114 may be connected to an actuating arm 117 of the at least one actuator 116. The actuating arm 117 may be pivotally attached to the hinged door 114 so that, when the actuating arm 117 is moved downwardly by the actuator 116, the hinged door 114 is likewise opened. This allows the dredging material above the hinged door 114 to fall into the discharge channel 112, for subsequent transport by the discharge pump 106 away from the hopper barge 108, as described further hereinbelow.
Various configurations of the discharge channel 112 are envisioned, and all are deemed to be within the scope of the present disclosure. As one non-limiting example, as shown in
In this example, and as depicted in
The angled walls 120 may also be connected by a bottom plate 124. The angled walls 120, the top plate 122, and the bottom plate 124 together provide the trapezoidal shape in cross-section. The hinged doors 114 that selectively seal the openings 104 are disposed on the top plate 122 of the elongate main body 102 in this particular embodiment.
In another example, shown in
In this example, the upper major surface 110 may be configured to receive and support the dredging material 109 when disposed in the hopper barge 108. The top plate 122 may be secured to the interior surface of the hull on opposing sides with connecting rails, brackets, and bolts 128, as non-limiting examples. One of ordinary skill in the art may select other suitable mechanical fasteners 128 for securing the top plate 122 to the hull of the hopper barge 108, as desired.
With continued reference to
In a further example, shown in
In this example, a top portion of the pipe 130 defines the upper major surface 110 of the sluiceway device 100. The top portion 130 may therefore be configured to receive and support the dredging material 109 when disposed in the hopper barge 108.
With continued reference to
Advantageously, this embodiment may utilize less space inside the hull of the hopper barge 108 in comparison to other embodiments contemplated by this disclosure. As such, this embodiment may then hold more dredging material 109 than a substantially similar sized hopper barge 108 fitted with a different embodiment of the sluiceway device 100.
In
As shown in
In a particular example, as shown in
In a most particular example, the hatch actuator 116′ includes a hydraulic motor 134′ with the gear 136′ and the chain 138′ located on top of the modular section. The chain 138′ may be attached to gear pins 140′ at the top of the hatch actuator 116′ and will open and/or close the semi-circular opening 104′ by rotating the revolving door 114′. These components may be completely encased by a metal casing 142′ for protection.
As shown in
As further depicted in
Advantageously, the lip 144′ provides support to the revolving doors 114′. In particular, the lip 144′ may militate against an undesirable bending, sagging, or breaking of the revolving doors 114′ due to a weight of the dredging material 109′ where the sluiceway device 100′ is in operation. Other suitable means including bracing for further supporting the revolving doors 114′ may also be employed.
The present disclosure further includes the method 200 for operating the sluice way device 100, 100′ for the barge 108, 108′, as shown in
The method 200 may have a first step 202 of providing the hopper barge 108, 108′. The hopper barge 108, 108′ may be a split hull type. However, one skilled in the art may select the hopper barge 108, 108′ with different hull types, including non-split designs, as desired.
A second step 204 in the method 200 may include providing the sluiceway device 100, 100′ with the at least one opening 104, 104′. As described hereinabove, the sluiceway device 100, 100′ includes the elongate main body 102, 102′ that defines the discharge channel 112, 112′. The elongate main body 112, 112′ has the upper major surface 110, 110′. There are the plurality of openings 104, 104′ spaced apart and disposed along the length of the upper major surface 110, 110′ These openings 104, 104′ may be selectively sealed with the hinged doors 114, as shown in
In one embodiment, the sluiceway device 100, 100′ may be provided separately from the hopper barge 108, 108′. The sluiceway device 100, 100′ may then be installed into the hopper barge 108, 108′. The sluiceway device 100, 100′ may be installed in a single piece. Where the sluiceway device 100, 100′ is a single piece, the sluiceway device 100, 100′ may be lowered into the hull of the hopper barge 108, 108′ using a crane, as a non-limiting example. The sluiceway device 100, 100′ may then be secured to the hull of the hopper barge 108, 108′ using fasteners.
In other embodiments, the sluiceway device 100, 100′ may also be installed in multiple, individual segments along the hull of the hopper barge 108, 108′. The individual segments are then connected, for example, by welding or mechanical fasteners, in order to form the completed sluiceway device 100, 100′.
In yet another embodiment, the sluiceway device 100, 100′ may be preinstalled with the hopper barge 108, 108′. In this embodiment, the sluiceway device 100, 100′ is fabricated within the hopper barge 108, 108′ during manufacture of the hopper barge 108, 108′. In this manner, the sluiceway device 100, 100′ may be provided as an integral part of the hopper barge 108, 108′ assembly.
The hopper barge 108, 108′ may also have the discharge pump 106, 106′. The discharge pump 106, 106′ may be previously installed on the hopper barge 108, 108′ in cases where a hopper barge 108, 108′ is being retrofitted with the sluiceway device 100, 100′. Alternatively, the discharge pump 106, 106′ may be installed as a separate component together with the installation of the sluiceway device 100, 100′, as either a single piece or in the multiple individual segments as described hereinabove. For example, the discharge pump 106, 106′ may be attached to the sluiceway device 100, 100′, or the discharge pump may be installed concurrently into the hull of the hopper barge 108, 108′ while the sluiceway device 100, 100′ is installed.
The method 200 then includes a third step 206 of filling the hopper barge 108, 108′ with dredging material 109, 109′. In this step 206, the sluiceway device 100, 100′ has been installed. The at least one opening 104, 104′ remains sealed by the door 114′, 114′ during the filling of the hopper barge 108, 108′.
The hopper barge 108, 108′ may be filled using conventional dredging methods. The dredging material 109, 109′ is supported by the upper major surface 110, 110′ of the elongate main body 102,102′ of the sluiceway device 100, 100′. The hopper barge 108, 108′ may then be transported to the disposal location for the dredging material 109, 109′. The filled hopper barge 108, 108′ is depicted in
A fourth step 208 of the method 200 then includes unsealing the at least one opening 104, 104′ to permit the dredging material 109, 109′ to fall into the discharge channel 112, 112′. The doors 114, 114′ of the openings 104, 104′ may be opened by the at least one actuator 116, 116′, for example, as described hereinabove with respect to
The method 200 may then include a fifth step 210 of pumping water into the discharge channel 112, 112′. Once the dredging material is in the discharge channel 112, 112′, additional pumps may be used to direct water into the discharge channel 112, 112′. The additional pumps may be provided with the hopper barge 108 or the additional pumps may be provided with the sluiceway device 100, 100′ and installed into the hull of the hopper barge 108, 108′. Advantageously, pumping water into the discharge channel 112, 112′ while discharge material 109, 109′ is present may allow the dredging material 109, 109′ to flow through the discharge channel 112, 112′ more efficiently than it could without the water being present.
A sixth step 212 of the method 206 may include a pumping of the dredging material 109, 106′ and water from the discharge channel 112, 112′ away from the hopper barge 108, 108′. After the water and dredging material 109, 109′ are pumped together in the discharge channel 112, 112′, the discharge pumps 106, 106′ may then be used to pump the dredging material 109, 109′ from the hopper barge 108, 108′. The discharge pumps 106, 106′ may pump the dredging material 109, 109′ onto a beach or any other suitable location for disposal of the dredging material. Advantageously, the discharge pumps 106, 106′ allow hopper barges 108, 108′ to transport dredging materials 109, 109′ to sites that were not previously available due to the limitations of split hull hopper barges 108, 108′.
In a particular embodiment, the elongate main body 102, 102′ of the sluiceway device 100, 100′ may have at least two openings 104, 104′. The at least two openings include a first opening 104, 104′ and a second opening 104, 104′. In this embodiment, the first opening 104, 104′ is unsealed first according to the method 200. Once the dredging material 109, 109′ at the first opening 104, 104′ is disposed in the discharge channel 112, 112′, then the second opening 104, 104′ is also unsealed in sequence.
More specifically, the first door 114, 114′ is opened, water is added to the discharge channel 112, 112′ and the discharge material 109, 109′ is pumped from the boat. The second door 114, 114′ is then opened, water is added to the discharge channel 112, 112′ and the dredging materials 109, 109′ are pumped from the hopper barge 108, 108′.
It should be appreciated that this ordered unsealing of the at least two openings 104, 104′ may be performed with as many openings 104, 104′ are present in the sluiceway device 100, 100′, and in any suitable order, within the scope of the disclosure.
In a most particular example, as shown in
In this embodiment, the doors 114, 114′ would be opened sequentially. The sequential opening of the doors 114, 114′ may include opening the door 114, 114′ nearest the end of the hopper barge 108, 108′ furthest from the discharge pumps 106, 106′. The doors 114, 114′ may then be opened in order moving towards the discharge pumps 106, 106′ until all of the doors 114, 114′ have been opened and substantially all the dredging material has been emptied from the hopper barge 108, 108′. It should be understood that one skilled in the art may open the plurality of doors 114, 114′ in any other order and according to any suitable timing, as desired.
Advantageously, the sluiceway device 100, 100′ of the present disclosure is especially useful for converting the hopper barge 108, 108′ into a vessel for pumping contents such as the dredging material 109, 109′ to a disposal area, such as a beach. The sluiceway device 100, 100′ is easily installed in a conventional split-type hopper barge 108, 108′. Thus, the sluiceway device 100, 100′ permits retrofitting of hopper barges 108, 108′ in a manner that is less complicated an inexpensive relative to earlier-known retrofitting methods in the art.
While certain representative embodiments and details have been shown for purposes of illustrating the invention, it will be apparent to those skilled in the art that various changes may be made without departing from the scope of the disclosure, which is further described in the following appended claims.
This application is a continuation of U.S. patent application Ser. No. 16/360,603, filed on Mar. 21, 2019, and issued as U.S. Pat. No. 10,486,778 on Nov. 26, 2019, which in turn claims the benefit of U.S. Provisional Application Ser. No. 62/660,624, filed on Apr. 20, 2018, and U.S. Provisional Application Ser. No. 62/646,082, filed on Mar. 21, 2018. The entire disclosures of the above applications are hereby incorporated herein by reference.
Number | Name | Date | Kind |
---|---|---|---|
1582433 | Roach | Apr 1926 | A |
1609179 | Marotte et al. | Nov 1926 | A |
3404484 | Klee | Oct 1968 | A |
3578222 | Pot | May 1971 | A |
4030435 | Sensibar | Jun 1977 | A |
4120409 | vander Werff | Oct 1978 | A |
4176885 | Alkema | Dec 1979 | A |
4253782 | Brakel | Mar 1981 | A |
4548147 | Roggeveen | Oct 1985 | A |
6390006 | Sridhar | May 2002 | B1 |
9365370 | Walker | Jun 2016 | B2 |
10486778 | Belesimo | Nov 2019 | B2 |
20080256870 | Nixon | Oct 2008 | A1 |
Number | Date | Country | |
---|---|---|---|
20200079478 A1 | Mar 2020 | US |
Number | Date | Country | |
---|---|---|---|
62660624 | Apr 2018 | US | |
62646082 | Mar 2018 | US |
Number | Date | Country | |
---|---|---|---|
Parent | 16360603 | Mar 2019 | US |
Child | 16685580 | US |