US3745958A - Control of towed barges - Google Patents
Control of towed barges Download PDFInfo
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- US3745958A US3745958A US00238097A US3745958DA US3745958A US 3745958 A US3745958 A US 3745958A US 00238097 A US00238097 A US 00238097A US 3745958D A US3745958D A US 3745958DA US 3745958 A US3745958 A US 3745958A
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- barge
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- tugboat
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B63—SHIPS OR OTHER WATERBORNE VESSELS; RELATED EQUIPMENT
- B63B—SHIPS OR OTHER WATERBORNE VESSELS; EQUIPMENT FOR SHIPPING
- B63B21/00—Tying-up; Shifting, towing, or pushing equipment; Anchoring
- B63B21/56—Towing or pushing equipment
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- the present invention relates to a system providing automatic steering ogi fiiiibafg'es'by'femplpyin gTtid Wife activated upon departureGrTftowed vessls l 'gitiiat j bba F'fiflfiifie turned to zero angularity relative the barge centerline to impose a minimum drag with the barge in proper alignment to obtain increased speed as permitted by barges constructed with a ship shaped prow.
- the effect of heavy seas on such a formed barge is further diminished by incorporating a surge suppressor in the connection of the pair of hawsers extending from a dual drum towing winch on the tugboat to the barge.
- ther object is to minimize power requirements so as to obtain speeds that will enable barges to become competitive with ships on long hauls.
- the barge is formed with a ship shaped bow extending high above the deck to disperse waves tending to shatter deck cargo.
- Another object is to sustain the time gain from increased sea speeds by arranging a close-coupling of barge to the tugboat to facilitate movement through restrictive channels and expedite mooring the barge to the dock.
- a still further object is to provide an efficient tow of a train of barges. with the facility to disengage any rearmost barge of the tandem tow to becomea separate tow to intermediate destinations before the tenn-inus is reached.
- the present invention is comprised ,of a tugboat fitted with a dual drum winch from which extends a pair of hawsers for connection to a barge with ship shaped pointed prow and stern mounted rudders.
- a pivotally mounted beamwith ends extended to the barge sides provides for the equalized loading of hawsers connected thereto imparting draft for the barge.
- An elongated flexible member is arranged to transmit forces imposed on the beam as torque needed to activate rudder angularity commensurate with deviation of the barge off the tugboat course.
- Said deviation is monitored and controlled by an automatic means aboard the tugboat-responding to changes in the hawser departure from the tugboat; to actuate the towing winch motor and/or brake to provide a shortened length of that hawser in leading position with respect the direction of said deviation from normal hawser departure.
- the unequal hawser lengths effects the beam angularity respective the barge centerline for a resulting rudder angulan'ty committed through the interconnected elongated member.
- a train of barges are similarly arranged in tandem tow, depending on the serial connection .by pairsof wires extended between each two barges to repeat the beam udder angularity effect established for the first barge.
- a modified version depends upon the fitting of only the last barge of a train with the beam-rudder mechanism. The tugboat towing winch is manipulated.
- FIG. 1 is a plan view schematically illustrating the connection of vessels not in longitudinal alignment, de-
- FIG. 2 is a plan view schematically illustrating the close-coupled connection of vessels during traverse through restrictive channels and preparatory to mooring the barge to a dock;
- FIG. 3 is a plan view schematically illustrating the tandem tow of similar barges fitted with the beamrudder mechanism.
- An auxiliary tugboat is shown in phantom view as an optional arrangement in utilitarian position to supplement propulsion of the train of barges;
- FIG. 4 is a planview schematically illustrating an alternate tandem tow in which only the rear barge is fatted with the beam-rudder mechanism.
- An auxiliary tugboat is shown in phantom view as an optional arrangement in utilitarian position to provide a reverse pull to the train sufficient to oppose the force of a following sea affecting the proper trailing of barges;' V
- FIG. 5 is a side elevational view of the towed barge illustrating the'bow configurationand extension of the prow above the deck to protect deck cargo;
- HO. 6 is a plan view illustrating the towed barge and the inventive beam-rudder mechanism with draft transmitting connected means thereto;
- FIG. 7 is a sectional plan view of the pivotal beam contained within a watertight tunnel incorporated in the barge;
- FIG. 11 is an elevational view schematically illustrating a means to lock rudders to a fixedposition
- FIG. 12 is a plan view schematically illustrating a means to automatically actuate the towing winch on the tugboat in' response to deviation of a towed barge off a tugboat course;
- FIG. 13 is an elevational view illustrating a portable means to effect the safe transfer of a man to and from tugboat and barge;
- FIG. 14 is an enlarged elevational view of the closecoupled arrangement between the tugboat and barge;
- FIG. 15 is a portion of the plan view, partly in section, taken from the plane 15-15 of FIG. 14; 7
- FIG. 16 is a portion of the plan view showing the disposition of rudders and the appendages supporting them.
- FIG. 17 is a portion of an elevational view to depict an alternate rudder arrangement.
- the tugboat 10 (hereafter referredto as boat 10) is in tow of barge 11 shown off course with corresponding angular displacement of rudders 12.
- a dual drum towing winch 13 aboard boat 10 provides for the storage and pay-out of a pair of hawsers l4 and 15,
- H6. 3 the inclusion of another barge 11 to form a train is representative of two or more identically fittcd barges with the beamrudder mechanism in tandem tow.
- a smaller auxiliary tugboat 23 similar to boat 10 is shown in phantom view to have a utilitarian first position to supplement the draft of the train and thereafter assumes a second position typified'in H6. 2 wherein the last barge of the several represented to be in HS. 3 has been disconnected for tow to an intermediate destination being passed on the voyage to the terminus.
- each one is oper able to be steered (as subsequently disclosed) whether in the train or individually maneuvered.
- the boat 10 Bin tow of a train of barges with only the last one in the tandem tow being of the type represented by barge 1 1, whereas barge 24 is representative of one or more other barges in the train not fitted with the pivotal beam, rudder or other drag device but rather have bare hulls offering least resistance to tow.
- Stern barge 11 is relied on to provide steerage as subsequently covered.
- Auxiliary tugboat 23 is shown in a third utilitarian position to provide needed drag to the train-in-opposition to forces of following seas affecting the trailing of barges in tandem tow. In FIG. 3 the auxiliary tugboat 23 may also be reconnected to provide the stern drag cited, conveyed through wires 29, normally slack, connected between barges 11.
- a ship shape pointed prow 22 is advocated for barges destined for higher speeds.
- This representation of the form to extend high above the deck provides for wave dispersal from deck cargo 27 and minimizes slamming and tendencies to nose under waves by providing a more gradually increased buoyant capacity commensurate with the degree of keel submersion.
- the pointed prow also eliminates one need for the forward guides specified in Ref. A, therein indifferent to barge form with a stand to support that guide from the bow of any barge.
- the pointed prow provides sufficient latitude to accommodate angular deviation of two hawsers oppositely connected to the beam ends.
- the pivotal beam 17 is contained within a tunnel. 30 installed below deck 26 to extend with open ends at the barge sides to retain the watertight integrity of the hull.
- the rudders l2 are actuated by the elongated flexible member 31 extending aft of the end connections 32 at the ends of the beam 17, caused to rotate by the hawsers 14 and 15 as subsequently discussed.
- Sheave segments 33 situated below deck 26 in compartment 34 immediately above stern rudders 12, contain the elon-v gated flexible member to a tension state to convey linear movement of end connections 32 coincident with pivotal movement of beam I7 to rotate the rudders by a torque transfer means 35.
- Watertight tubes 36 extend between tunnel 30 and compartment 34 to contain a portibn of the flexible member 31 extending aft. Said tubes 36 are provided with flared entrances 37 at the tunnel to accommodate deviation of the connection 32 with rotation of the beam.
- Non-return valves 39 of conventional form included with tubes 36', intercept water admitted at entrances 37 for discharge through the barge sides to the seas.
- The'two hawsers 14 and 15 replace the single hawser and bridle of Ref. A.
- the barge 11 has veered off to port of the boat 10 in which case monitoring means 40, subsequently discussed with regards FIG. 12, activates control of the dual drums of towing winch 13; so as to make hawser 15 shorter than hawser 14. This will produce a slight clockwise rotation (viewed looking down in FIG. 1) of beam 17 still attempting to retain equalized tension in the two hawsers.
- the displaced rudder responding with beam movement will transmit a torque, exerted by water-reaction against it, through the torque transfer means to add tension force to the port side of the elongated flexible member 31.
- This will cause an extra elastic stretch in the port wire with a resulting decreased stretch in the starboard side wire.
- This will be reflected as'an increased load on the port hawser and decreased 7 load on the starboard hawser, negligible differences with streamlined balanced rudders.
- the hawsers are relieved from suddenly applied loads by terminating the hawser wires as in FIG. 6 with a length of chain 41 as the connecting means 16 to increase sag and mass to be displaced before the hawsers become taut; to effect a gradually applied load.
- a torsion bar 42 has been incorporated within beam 17 to be twisted by the lever arm extension 43 providing an indirect connection 16 of the hawsers and beam.
- the torsion bar is anchored to the beam at the inboard ends 44 and journal 45 at the outboard ends of the beam provide support for the twisted bar.
- Slide bearings 46 and 47 guide the rotative movement of the beam within the tunnel to assure proper alignment of beam 17 with the pivot axis 48 bolted through the tunnel 30 to permit the assembly of the beam therein. Shoulder guards 50 extend. beyond the barge sides at the tunnel openings-to protect the extending beam ends.
- the hawsers may be connected directly to the lever arms 43 thereby serving as the connecting means 6.
- a shortened chain length 41 terminal of the hawsers are incorporated with the torsion bar as an additional suppressant as was applied without the torsion. bar.
- the elongated flexible member 31 is sectionalized to provide an improved application of a wire bent at the sheave segments 33'.
- two smaller sized wires 51 with superior bending characteristics are devised by means of a conventional equalizer thimble 52 to share the load equally of the one wire connected to it by socket 53.
- Two such equalized pairs 51 are required at a sheave segment; 510 a pair immediate to the wire from the beam and 51b a pair immediate to its counterpart for the oppositely disposed sheave on the barge.
- Pair 51a fit to grooves 54 formed in the periphery of the sheave segment and extended in wrap thereto for anchoring at 55a.
- pair 51b fit grooves 56 for anchoring at 55b with the two pairs interlaced and linkedtogether through the common anchorage.
- Torque transfer means 35 is comprised of a housing 56 to contain and support the sheave segment shaft 57, the extension into chamber 34 of rudder port 58 and mating gears 60, 61 mounted respectively to shaft 57 and post 58.
- Gears 6:) and 63 provide an angular ratio between the rotation of the sheave segment and rudder, but more importantly provide the correct directional rotation of the rudder in response to hawser steering effort.
- the toggle joint forces plungers 65 arranged for guided engagement through housing 56 to the mesh with teeth of a gear.
- the rudders may-be locked with zero angularity with respect the barge centerline for minimum .drag (resistance) and zero lift (steering thrust) as when backing the barge; or with the rudders locked 90 from said centerline then serve to brake against motion of the barge respective its centerline as when mooring the barge to a dock.
- the monitoring means 40 is suitably mounted on boat 10 to control towing winch 13 with deviation off course of the towed barge as indicated by the abnormal departure of hawsers from the boat stern 21.
- one of the dual drums is made to haul-in while the other pays-out the wire hawser.
- Other arrangements are optional to the need. as for instance only one wire may be shortened or lengthened respective the other wire left fixed in length for the existing conditions.
- a pair of pivotal arms are selec tively disengaged by clamp means 71; so that manual control of the towing winch can be manipulated as from the pilot house when the vessels are closecoupled.
- Port drum 72 and starboard drum 73 are held to position by brakes 74 (spring lockedrsolenoid released).
- Motors 75 are indicative of whatever means is I employed to selectively power individual drums.
- hawsers l4 and 15 are at a deflected angle to 14' and 15. This therefore causes switch 77 to activate the port motor and starboardsolenoid brake release.
- Refinements not shown in FIG. 12 would include limit switches to interrupt corrective control to permit response of the barge to assume a changed position.
- the monitoring means centerline- 78 may be realigned. for the duration of that persistent force to establish agreement in departure as a temporary normal condition, thus the rudders would then be retained. at some angular set respective the barge centerline.
- a boom 18- is shown to extend from the stern of barge 11 to provide an overhung end above the boat It) brought to a safe distance astern of the barge to effect the transfer of a man therebetween as needed to manipulate appurtenances especially having to do with mooring the barge to a dock as is customarily required.
- the pivotally mounted boom 80 contains a track 81 to receive a trolley 82 placed there by a man with a pole on the boat.
- a stirrup 83 fixed to a line 84 reeved over a sheave 85 mounted on the trolley provides footing for a man to be raised by other men haul-- ing on line 84 until a stay 86 can be hooked into the trolley by the raised marnself-haul along the boom to a drop laddcrpermits the man to board the barge, whereupon the pivotally mounted boom 80 is hauled inboard of the barge;
- kithe spreader bar 18 is shown to be pivotally mounted to the stern 21 of boat 10 by a universal joint'90 and extends to the prow 25 of barge 11 in em gagement with one of a series of protrusions 91 that provide an end support of bar 18 in an approximately mean horizontal position with the two vessels respond- 'sist in the lift of the bar 18 from storage on boat 10 by means of winch '94 for an initial connection with universal joint 90; thereafter to provide the support of the extended bar to effect engagement to the barge prow. Shortening of the hawsers draws the vessels to a limited close spacing when the spring loadedtelescopic feature 95 becomes seated to provide a solid compression column.
- FIGS.- 14 and 15 taken together shows the spring assembly 95 at both ends to indicate this combinationor onfy one end so titted.
- the vessels assume a position whereby the ends of bar 18 are not at the mean position as above the compression of the spring feature 95 extends the reach between ends to retain thebar integrity as a toggle connection.
- the winch means 94 is slacked off only enough not to interfere in the play of the bar, but remains connected-in to reassume support of the bar as needed and to remove the bar when interfering with other operations.
- the chains 41 are connected to pad-eyes fitted to the sides of barges 24 without rudders. These chains extend forward with special chain links 97 for connection to wires 29 paid-off reels 20 mounted to the stern of the adjacent barge.
- the rearmost barge 11 with pivotal beam and rudders depend upon conveyance of steering effort of hawsers to be transmitted through each barge 24 slightly aslant resulting fromthe propulsion force being transmitted principally through the shorter of the two hawsers.
- FIG. 16 the disposition of the rudders are shown supported by streamline appendages fixed to the stern of the barge.
- the rudder is shown disposed so asto be operable through 90 from the neutral when the braking ability of the rudder is to be required as previously disclosed.
- a pivotally mounted beam extends athwartship to the sides of the barge with beam end arrangement for connection to said hawsers; and, dgbgam to rudder interconnectingmeags tgarsmfls pi opiglsibhffbmyed through the pivotal beam to a misaligned barge relative the tugboat to activative corrective rudder angularity; 31 i n3; messiah?ll fl a fissstitadsaesssetiem -iwsrfly ls.
- an elong'ated flexible member having'the respective ends thereof secured to the opposite ends of said beam and an intermediate portion formed in tension transmitting engagement with a torque transfer means connected with said rudders; and, 2. a monitoring means selectively adapted to sense the change in angularityof hawser departure off 7 the tug stern, occasioned by deviation in alignment of vessels, actuates control of the towing winch to establish a differential between the pair of hawser lengths, therewith adjusting said beam to athwaitship angularity commensurate with corrective rudder angularity to reinstate vessels alignment and directional heading.- 2.
- An improved steering imparting draft connection between vessels according to claim 1, wherein said steering connection means further comprises:
- a watertight tunnel extends athwartship with open ends at sides of the barge to establish the pivotal mount and accommodate a limited rotative movement of said beam in response to the said differential between hawsers;
- grooves formed in the periphery of said sheave segments accommodate the seating of segmental lengths of said intermediate portion with ends fixed thereto to provide opposite extensions as continuations of the elongated flexible member;
- tubular members comprises: 7
- a non-return trap connected to and intermittent the length of said tubular member intercepts coninboard discontinuousportion fixed to the beam adjacent to the pivotal axis thereof and opposite ends extending beyond the barge side to terminate with a lever arm 'angularly disposed therewith to twist the torsion bar commensurate with the force imposed by the tension in the hawser transmitted to the distal end of the lever arm;
- journal means provide support and accommodate said twist of the torsion bar relative the pivotal beam;
- bearing means accommodate free guided rotative movement of the pivotal beam within the tunnel;
- An improved steering imparting draft connection between vessels according to claim 4 wherein said beam end arrangement incorporates a length of chain as an extension of the hawser with connection to the I said distal end of the lever arm.
- said 2 beam end arrangement comprises:
- a locking means fixes the rudder to selected angularity respective the barge centerline to oppose forces transmitted by.the hawser or sea effect to the rudders;
- rudder angularity extends'from zero angle with minimum drag to a angle with maximum drag resisting directional movement parallel to the barge centerline.
- a tugboat with at least two barges in-tandem tow having rudders mounted to the stern of at least the last of the train of barges;
- a pair of hawsers paid-out from a dual drum towing winch aboard the tugboat extends aft for connection to towing means of the first barge of the train;
- a pivotally mounted beam extends athwartship to the sides of the barge fitted with rudders to provide said towing chain connecting means;
- tugboat propulsion forces transmitted by said pair of hawsers altered to have varying lengths are conveyed throughout the train to affect the pivotal beam angularity thereby producing corresponding corrective rudder angularity effected by beamrudder interconnecting means to maintain train alignment in response to said altered hawsers.
- the said pair of equal length wires extend from reels mounted to the stern of a barge for extension aft with length depending upon interval of barge spacing for connection to the adjacent tow chain.
- the train further comprises:
- an auxiliary tugboat employed for utilitarian purposes serves as a supplementary power means when situated to lead in the tow of the connected vessels;
- said auxiliary tugboat servesas a controlleddrag when situated at the end of the train to offset following seas effort to destroy the train progress;
- auxiliary tug serves to shuttle barges as a sepa- 10.
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Abstract
Connected vessels arranged to be towed in the course of a tugboat are dependent upon corrective steering by rudders activated by draft forces transmitted to a pivotal beam on the barge from a pair of hawsers paid-off from the tugboat with an adjusted difference in length to rotate the beam correspondingly. Draft forces and condition responsive steering are serially transmitted to successive barges in tandem tow with surge suppressors incorporated into the interconnections.
Description
114-253. XR 39745 1958 SR Unlififl males rawm e? I ,958
Nelson 7 I 1973 I 1 1 CONTROL OF TOWED BARGES 3,469,552 9 1969 114 235 [76} Inventor: A t r Jo Ne son, 330 Shasta 323,639 v8/18115 Cowden 114/236 i San Mateo Cahf' Primary Examiner-Milton Buchler [22] Filed: Mar. 27, 1972 I 7 Assistant Examiner-E. R. Kazenske 211 Appl. No.: 238,097 v 57 ABSTRACT 52 11.8. c1. 114/236 Cmmecled vessels arranged be 511 1111. (:1 B631) 21/00 are dePe"92!E-QPQMWXQCQLQEFBHE1l- 1 4/162. 5/61 7 otal beam on the barge from a pair of hawsers paid-off from the tugboat with an adjusted difference in lerigth {516] v Refe'rences (med to rotate the beam correspondingly. DIZ1I KQEQNLIELM UNXTED STATES PATENTS 'conditio ruesponsive steering are seriany trar1 rnifled to 3,336,895 8/1967 Nelson 114/236 i t djmo the interconnections. 1 3,611.977 10/1971 Mosvold 114/236 W 612,539 10/1898 Bowick .L 114/236 14 Claims, 17 Drawing Figures CONTROL OF TOWED BARGES Reference: This application relates to my US. Pat. No. 3,336,895, dated 8-22-67, entitled, Yaw Control of Towed Barges," hereafter noted as Ref. A.
BACKGROUND OF THE INVENTION '1. Field of the invention The present invention relates to a system providing automatic steering ogi fiiiibafg'es'by'femplpyin gTtid Wife activated upon departureGrTftowed vessls l 'gitiiat j bba F'fiflfiifie turned to zero angularity relative the barge centerline to impose a minimum drag with the barge in proper alignment to obtain increased speed as permitted by barges constructed with a ship shaped prow. The effect of heavy seas on such a formed barge is further diminished by incorporating a surge suppressor in the connection of the pair of hawsers extending from a dual drum towing winch on the tugboat to the barge.
2. Description of the prior art v The present method to tow barges is the result of a gradual modification of original ideas. The bulk of these barges employ a molded or spoon shaped bow with boxy stems to accommodate fixed skegs in an'effort to stabilize against an-erratic course. Such barges pound into waves, ship water aboard to the detriment of deck cargo, still yaw badly while at the same time demand extraordinary power, to progressat comparativel-y slow speed. The uncontrolled tow suffers damage 0 in many collisions. self-destruction due to slamming t Otherdevices introduced to improve control have been intricate requiring elaborate maintenance practices, most often omitted with a resulting premature failure. Such problems and other like ones are overcome in the present invention; specifically relying on the type of A primary object is to pr o videa steering means for @wedyessels that definitely contrfcildagainstwande fiiig,
ise t.iiyjibet i b9tr ric i ther object is to minimize power requirements so as to obtain speeds that will enable barges to become competitive with ships on long hauls. For high speed performance the barge is formed with a ship shaped bow extending high above the deck to disperse waves tending to shatter deck cargo.
Another object is to sustain the time gain from increased sea speeds by arranging a close-coupling of barge to the tugboat to facilitate movement through restrictive channels and expedite mooring the barge to the dock.
A still further object is to provide an efficient tow of a train of barges. with the facility to disengage any rearmost barge of the tandem tow to becomea separate tow to intermediate destinations before the tenn-inus is reached.
Another object is to provide apparatus that will minimizc damage to equipment, and avoid danger to SUMMARY OF THE INVENTION 65 The present invention is comprised ,of a tugboat fitted with a dual drum winch from which extends a pair of hawsers for connection to a barge with ship shaped pointed prow and stern mounted rudders. A pivotally mounted beamwith ends extended to the barge sides provides for the equalized loading of hawsers connected thereto imparting draft for the barge. An elongated flexible member is arranged to transmit forces imposed on the beam as torque needed to activate rudder angularity commensurate with deviation of the barge off the tugboat course. Said deviation is monitored and controlled by an automatic means aboard the tugboat-responding to changes in the hawser departure from the tugboat; to actuate the towing winch motor and/or brake to provide a shortened length of that hawser in leading position with respect the direction of said deviation from normal hawser departure. The unequal hawser lengths effects the beam angularity respective the barge centerline for a resulting rudder angulan'ty committed through the interconnected elongated member.
A train of barges are similarly arranged in tandem tow, depending on the serial connection .by pairsof wires extended between each two barges to repeat the beam udder angularity effect established for the first barge. A modified version depends upon the fitting of only the last barge of a train with the beam-rudder mechanism. The tugboat towing winch is manipulated.
when vessels are close-hauled to utilize the barge rud-' ders as assistance in maneuveringthrough restricted channels and when mooring to docks of limited accommodation. To realize the effectiveness of the steering apparatus the barges are specified as to conformation and appurtenances to cope with heavy seas at increased speeds and constraining means provide for tugboat 5 safety.
BRIEF DESCRIPTION OF DRAWINGS FIG. 1 is a plan view schematically illustrating the connection of vessels not in longitudinal alignment, de-
0 picting the resulting angularity of beam and rudder to produce corrective steerag'e for the barge;
FIG. 2 is a plan view schematically illustrating the close-coupled connection of vessels during traverse through restrictive channels and preparatory to mooring the barge to a dock;
FIG. 3 is a plan view schematically illustrating the tandem tow of similar barges fitted with the beamrudder mechanism. An auxiliary tugboat is shown in phantom view as an optional arrangement in utilitarian position to supplement propulsion of the train of barges;
FIG. 4 is a planview schematically illustrating an alternate tandem tow in which only the rear barge is fatted with the beam-rudder mechanism. An auxiliary tugboat is shown in phantom view as an optional arrangement in utilitarian position to provide a reverse pull to the train sufficient to oppose the force of a following sea affecting the proper trailing of barges;' V
FIG. 5 is a side elevational view of the towed barge illustrating the'bow configurationand extension of the prow above the deck to protect deck cargo;
HO. 6 is a plan view illustrating the towed barge and the inventive beam-rudder mechanism with draft transmitting connected means thereto;
FIG. 7 is a sectional plan view of the pivotal beam contained within a watertight tunnel incorporated in the barge;
. -10 of FIG. 9;'
FIG. 11 is an elevational view schematically illustrating a means to lock rudders to a fixedposition;
FIG. 12 is a plan view schematically illustrating a means to automatically actuate the towing winch on the tugboat in' response to deviation of a towed barge off a tugboat course;
FIG. 13 is an elevational view illustrating a portable means to effect the safe transfer of a man to and from tugboat and barge;
FIG. 14 is an enlarged elevational view of the closecoupled arrangement between the tugboat and barge;
FIG. 15 is a portion of the plan view, partly in section, taken from the plane 15-15 of FIG. 14; 7
FIG. 16 is a portion of the plan view showing the disposition of rudders and the appendages supporting them; and,
FIG. 17 is a portion of an elevational view to depict an alternate rudder arrangement.
DESCRlPTlON I. General arrangement Ref. A lays claim to the method of utilizing a propulsion force to provide draft for a towed barge fitted with rudders adopted to reduce the needed propulsion force; also applied to automatically activate the rudders to provide barge steerage to follow the tugboat course. The principle relies on the use of an athwartship pivotal beam on the barge with ends connected by means of a bridle to a hawser paid-out from the tugboat. A tensioned wire with ends also tied to the beam extends rearward on the barge and formed so as to respond linearly'with the change in beam end position relative the barge rotated about the beam axis. This linear movement is transmitted as a torque to rotate the rudder to a predetermined angular magnitude to pro vide steerage in compliance with the barge characteris-.
tie in waters plied. This principle is applied with modified details to provide a fuller utilization of the accrued advantages in the present application, as follows.
. in FIG. 1, the tugboat 10 (hereafter referredto as boat 10) is in tow of barge 11 shown off course with corresponding angular displacement of rudders 12. A dual drum towing winch 13 aboard boat 10 provides for the storage and pay-out of a pair of hawsers l4 and 15,
each terminating with connecting means i'fifr ir jbihing to the ends of pivotal beam 17. This arrangement is cmingan individual barge to a dock. V
in H6. 3 the inclusion of another barge 11 to form a train is representative of two or more identically fittcd barges with the beamrudder mechanism in tandem tow. A smaller auxiliary tugboat 23 similar to boat 10 is shown in phantom view to have a utilitarian first position to supplement the draft of the train and thereafter assumes a second position typified'in H6. 2 wherein the last barge of the several represented to be in HS. 3 has been disconnected for tow to an intermediate destination being passed on the voyage to the terminus. By including only identical barges 11, each one is oper able to be steered (as subsequently disclosed) whether in the train or individually maneuvered.
In FIG. 4 the boat 10 Bin tow of a train of barges with only the last one in the tandem tow being of the type represented by barge 1 1, whereas barge 24 is representative of one or more other barges in the train not fitted with the pivotal beam, rudder or other drag device but rather have bare hulls offering least resistance to tow. Stern barge 11 is relied on to provide steerage as subsequently covered. Auxiliary tugboat 23 is shown in a third utilitarian position to provide needed drag to the train-in-opposition to forces of following seas affecting the trailing of barges in tandem tow. In FIG. 3 the auxiliary tugboat 23 may also be reconnected to provide the stern drag cited, conveyed through wires 29, normally slack, connected between barges 11. I
ln FlGS. 5 and 6 a ship shape pointed prow 22 is advocated for barges destined for higher speeds. This representation of the form to extend high above the deck provides for wave dispersal from deck cargo 27 and minimizes slamming and tendencies to nose under waves by providing a more gradually increased buoyant capacity commensurate with the degree of keel submersion. The pointed prow also eliminates one need for the forward guides specified in Ref. A, therein indifferent to barge form with a stand to support that guide from the bow of any barge. The pointed prow provides sufficient latitude to accommodate angular deviation of two hawsers oppositely connected to the beam ends.
For barges with deck cargo 27 as shown in FIG. 5, the pivotal beam 17 is contained within a tunnel. 30 installed below deck 26 to extend with open ends at the barge sides to retain the watertight integrity of the hull.
The rudders l2 are actuated by the elongated flexible member 31 extending aft of the end connections 32 at the ends of the beam 17, caused to rotate by the hawsers 14 and 15 as subsequently discussed. Sheave segments 33, situated below deck 26 in compartment 34 immediately above stern rudders 12, contain the elon-v gated flexible member to a tension state to convey linear movement of end connections 32 coincident with pivotal movement of beam I7 to rotate the rudders by a torque transfer means 35. Watertight tubes 36 extend between tunnel 30 and compartment 34 to contain a portibn of the flexible member 31 extending aft. Said tubes 36 are provided with flared entrances 37 at the tunnel to accommodate deviation of the connection 32 with rotation of the beam. Non-return valves 39, of conventional form included with tubes 36', intercept water admitted at entrances 37 for discharge through the barge sides to the seas.
2. Detailed disciosure The'two hawsers 14 and 15 replace the single hawser and bridle of Ref. A. As illustrated in FIG. 1, the barge 11 has veered off to port of the boat 10 in which case monitoring means 40, subsequently discussed with regards FIG. 12, activates control of the dual drums of towing winch 13; so as to make hawser 15 shorter than hawser 14. This will produce a slight clockwise rotation (viewed looking down in FIG. 1) of beam 17 still attempting to retain equalized tension in the two hawsers.
However, the displaced rudder responding with beam movement will transmit a torque, exerted by water-reaction against it, through the torque transfer means to add tension force to the port side of the elongated flexible member 31. This will cause an extra elastic stretch in the port wire with a resulting decreased stretch in the starboard side wire. This will be reflected as'an increased load on the port hawser and decreased 7 load on the starboard hawser, negligible differences with streamlined balanced rudders.
In transmitting draft forces the hawsers are relieved from suddenly applied loads by terminating the hawser wires as in FIG. 6 with a length of chain 41 as the connecting means 16 to increase sag and mass to be displaced before the hawsers become taut; to effect a gradually applied load. In FlGS. 7 and 8 a torsion bar 42 has been incorporated within beam 17 to be twisted by the lever arm extension 43 providing an indirect connection 16 of the hawsers and beam. The torsion bar is anchored to the beam at the inboard ends 44 and journal 45 at the outboard ends of the beam provide support for the twisted bar. Slide bearings 46 and 47 guide the rotative movement of the beam within the tunnel to assure proper alignment of beam 17 with the pivot axis 48 bolted through the tunnel 30 to permit the assembly of the beam therein. Shoulder guards 50 extend. beyond the barge sides at the tunnel openings-to protect the extending beam ends.
In moderate service the hawsers may be connected directly to the lever arms 43 thereby serving as the connecting means 6. merit of the lever arm 43 resulting from twist in the torsion bar 42 due to change in load supplements accompanying change in elastic stretch in the hawser to act as a combined surge suppressor. In severe service a shortened chain length 41 terminal of the hawsers are incorporated with the torsion bar as an additional suppressant as was applied without the torsion. bar.
In FIGS- 9 and 10 the elongated flexible member 31 is sectionalized to provide an improved application of a wire bent at the sheave segments 33'. Instead of contiming the size of wire connected tothe beam, two smaller sized wires 51 with superior bending characteristics are devised by means of a conventional equalizer thimble 52 to share the load equally of the one wire connected to it by socket 53. Two such equalized pairs 51 are required at a sheave segment; 510 a pair immediate to the wire from the beam and 51b a pair immediate to its counterpart for the oppositely disposed sheave on the barge. Pair 51a fit to grooves 54 formed in the periphery of the sheave segment and extended in wrap thereto for anchoring at 55a. Oppositely, pair 51b fit grooves 56 for anchoring at 55b with the two pairs interlaced and linkedtogether through the common anchorage.
The lock of the elongated flexible member 31 by this means produces fixed angular sheave rotation correspending with linear movement of wires. Torque transfer means 35 is comprised of a housing 56 to contain and support the sheave segment shaft 57, the extension into chamber 34 of rudder port 58 and mating gears 60, 61 mounted respectively to shaft 57 and post 58. Gears 6:) and 63 provide an angular ratio between the rotation of the sheave segment and rudder, but more importantly provide the correct directional rotation of the rudder in response to hawser steering effort.
For this case the angular displace -to depress a toggle joint 64 between the two torque transfer means35. The toggle joint in turn forces plungers 65 arranged for guided engagement through housing 56 to the mesh with teeth of a gear. Thus the rudders may-be locked with zero angularity with respect the barge centerline for minimum .drag (resistance) and zero lift (steering thrust) as when backing the barge; or with the rudders locked 90 from said centerline then serve to brake against motion of the barge respective its centerline as when mooring the barge to a dock.
In FIG. 12 the monitoring means 40 is suitably mounted on boat 10 to control towing winch 13 with deviation off course of the towed barge as indicated by the abnormal departure of hawsers from the boat stern 21. In this arrangement one of the dual drums is made to haul-in while the other pays-out the wire hawser. Other arrangements are optional to the need. as for instance only one wire may be shortened or lengthened respective the other wire left fixed in length for the existing conditions. A pair of pivotal armsare selec tively disengaged by clamp means 71; so that manual control of the towing winch can be manipulated as from the pilot house when the vessels are closecoupled. Port drum 72 and starboard drum 73 are held to position by brakes 74 (spring lockedrsolenoid released). Motors 75 are indicative of whatever means is I employed to selectively power individual drums. Yokes m o a I m 't'lfl 'ffornnng the rearmost part of the pivotal. arms in case of FIG. I with the barge veered to the port side,
hawsers l4 and 15 are at a deflected angle to 14' and 15. This therefore causes switch 77 to activate the port motor and starboardsolenoid brake release. Refinements not shown in FIG. 12 would include limit switches to interrupt corrective control to permit response of the barge to assume a changed position. With a persistent force'against a barge todemand continuous repeated action, the monitoring means centerline- 78 may be realigned. for the duration of that persistent force to establish agreement in departure as a temporary normal condition, thus the rudders would then be retained. at some angular set respective the barge centerline.
In FIG. 13 a boom 18- is shown to extend from the stern of barge 11 to provide an overhung end above the boat It) brought to a safe distance astern of the barge to effect the transfer of a man therebetween as needed to manipulate appurtenances especially having to do with mooring the barge to a dock as is customarily required. The pivotally mounted boom 80 contains a track 81 to receive a trolley 82 placed there by a man with a pole on the boat. A stirrup 83 fixed to a line 84 reeved over a sheave 85 mounted on the trolley provides footing for a man to be raised by other men haul-- ing on line 84 until a stay 86 can be hooked into the trolley by the raised marnself-haul along the boom to a drop laddcrpermits the man to board the barge, whereupon the pivotally mounted boom 80 is hauled inboard of the barge;
In FIG. kithe spreader bar 18 is shown to be pivotally mounted to the stern 21 of boat 10 by a universal joint'90 and extends to the prow 25 of barge 11 in em gagement with one of a series of protrusions 91 that provide an end support of bar 18 in an approximately mean horizontal position with the two vessels respond- 'sist in the lift of the bar 18 from storage on boat 10 by means of winch '94 for an initial connection with universal joint 90; thereafter to provide the support of the extended bar to effect engagement to the barge prow. Shortening of the hawsers draws the vessels to a limited close spacing when the spring loadedtelescopic feature 95 becomes seated to provide a solid compression column. FIGS.- 14 and 15 taken together shows the spring assembly 95 at both ends to indicate this combinationor onfy one end so titted. When the vessels assume a position whereby the ends of bar 18 are not at the mean position as above the compression of the spring feature 95 extends the reach between ends to retain thebar integrity as a toggle connection. With such action the winch means 94 is slacked off only enough not to interfere in the play of the bar, but remains connected-in to reassume support of the bar as needed and to remove the bar when interfering with other operations.
In FIG. 14 when a barge is to be disconnected, the hawser socket 96 is disconnected from the special chain link 97 after retrieving wire with buoy 98 has been fixed to link 97 and cast overboard. Thus chain length 21 can be let go to hang suspended from pengeneral arrangement is continued now to disclose a method to link the several barges together. A pair of under-rider pendants 19 of equal'length with socket ends are connected to the special chain links 97 of adjacent barges. Thus when hawser lengths are changedrespective each other, that effect is conveyed to all pivotal beams and rudders simultaneously to provide the individual steering of each barge in the train.
In FIG. 4 the chains 41 are connected to pad-eyes fitted to the sides of barges 24 without rudders. These chains extend forward with special chain links 97 for connection to wires 29 paid-off reels 20 mounted to the stern of the adjacent barge. Thus the rearmost barge 11 with pivotal beam and rudders depend upon conveyance of steering effort of hawsers to be transmitted through each barge 24 slightly aslant resulting fromthe propulsion force being transmitted principally through the shorter of the two hawsers.
in FIG. 16 the disposition of the rudders are shown supported by streamline appendages fixed to the stern of the barge.
in PK]. 17 the rudder is shown disposed so asto be operable through 90 from the neutral when the braking ability of the rudder is to be required as previously disclosed.
From the foregoing description, it is believed apparent that the present invention enables the accomplishment of the objects initially set forth herein. It is understood, however, that the'invention is not limited to the specific details illustrated herein.
What is claimed is: 1. In a combination of connected vessels comprising: a WP i ziarsss v at im srsdst subs...
s tgrg thereof and a ship shape pointed prow; b. a tugboat in tow of the;barge irpparts propulsigp wfi s fih i' f a s saa stss tfidrica... dual drum towing winch mounted on theiugboat; c. a pivotally mounted beam extends athwartship to the sides of the barge with beam end arrangement for connection to said hawsers; and, dgbgam to rudder interconnectingmeags tgarsmfls pi opiglsibhffbmyed through the pivotal beam to a misaligned barge relative the tugboat to activative corrective rudder angularity; 31 i n3; messiah?ll fl a fissstitadsaesssetiem -iwsrfly ls. p
I. an elong'ated flexible member having'the respective ends thereof secured to the opposite ends of said beam and an intermediate portion formed in tension transmitting engagement with a torque transfer means connected with said rudders; and, 2. a monitoring means selectively adapted to sense the change in angularityof hawser departure off 7 the tug stern, occasioned by deviation in alignment of vessels, actuates control of the towing winch to establish a differential between the pair of hawser lengths, therewith adjusting said beam to athwaitship angularity commensurate with corrective rudder angularity to reinstate vessels alignment and directional heading.- 2. An improved steering imparting draft connection between vessels according to claim 1, wherein said steering connection means further comprises:
a. a watertight tunnel extends athwartship with open ends at sides of the barge to establish the pivotal mount and accommodate a limited rotative movement of said beam in response to the said differential between hawsers;
b. a pair of tubular members fixed, respectively, to said barge adjacent the opposite sides thereof and having extended slidably the'reth-rough said elongated member;
c. .a pair of sheave segments mounted, respectively, between each of said tubular members and a post extension for said rudders provides said tension transmitting engagement;
d. grooves formed in the periphery of said sheave segments accommodate the seating of segmental lengths of said intermediate portion with ends fixed thereto to provide opposite extensions as continuations of the elongated flexible member; and,
e. mating gears fixed, respectively, to a. mounting means for the sheave segment and rudder post provides opposite directional rotative transmission of torque from said sheave segment to said rudders.
.3. An improved steering imparting draft connection between 'v esscis according to claim 2, wherein said tubular members comprises: 7
a. a watertight connection between said tunnel and tube having a. flared opening accommodates variable displacement at the entrance thereof of the elongated flexible member said slidable therethrough; and, I
b. a non-return trap connected to and intermittent the length of said tubular member intercepts coninboard discontinuousportion fixed to the beam adjacent to the pivotal axis thereof and opposite ends extending beyond the barge side to terminate with a lever arm 'angularly disposed therewith to twist the torsion bar commensurate with the force imposed by the tension in the hawser transmitted to the distal end of the lever arm;
b. journal means provide support and accommodate said twist of the torsion bar relative the pivotal beam; I
' c. bearing means accommodate free guided rotative movement of the pivotal beam within the tunnel; and, I
I d. twist of said torsion bar supplemented by elastic I yas!" I 1 2 cope with surge effect between said connected ves- I sels subject to unequal sea forces.
5. An improved steering imparting draft connection between vessels according to claim 4, wherein said beam end arrangement incorporates a length of chain as an extension of the hawser with connection to the I said distal end of the lever arm. I 6. An improved steering imparting draft connection I between vessels according to claim 1, wherein said 2 beam end arrangement comprises:
a. a chain length extension of the hawsers with con nection to said beam ends imposes a weight creating extra sag and gradually imposed resistance to the extension of spaced relationship between vesseis consequential with surge effect of unequal sea forces therebetween; and,
. b. pendants fixed to the prow of the barge extends for connection to each. chain with length permitting free movement of said pivotal beam and restricting 7. An improved steering imparting draft connection between vessels according to claim 1, .wherein said steering connection comprises:
a. manual control of the dual drum towing winch supplants the said monitoring means selectively adapted to haul-in hawsers for a close coupled vessel spacing; and,
b. directional heading of the barge by towing effect of the tugboat supplemented by manipulation of the dual drum towing winch to alter rudder angularity, provides control of the barge in passage through restrictive channels and mooring of the barge with limited dock side accommodation respective the barge length..
8. An improved steering imparting draft connection between vessels according to claim 7, wherein further provisions to secure said close coupled vessels comprises a portable spreader bar extended from the tugboat stem to the barge prow with position retaining ing said vessels elevational relationship. I
1 An improved steering imparting draft connection between vessels. according to claim I, wherein said a. a torsion bar extends through said beam with the the chain from athwartship under-riding the barge.
means in contention with sea swells variously displacstretch of tensioned hawsers provides resilience to steering connection means comprises:
a. a locking means fixes the rudder to selected angularity respective the barge centerline to oppose forces transmitted by.the hawser or sea effect to the rudders; and,
b. rudder angularity extends'from zero angle with minimum drag to a angle with maximum drag resisting directional movement parallel to the barge centerline.
a. an arrangement of a tugboat with at least two barges in-tandem tow having rudders mounted to the stern of at least the last of the train of barges;
b. a pair of hawsers paid-out from a dual drum towing winch aboard the tugboat extends aft for connection to towing means of the first barge of the train;
c. a pair of towing chains of equal fixed length for each barge of the train having reach from connecting means with a barge for fastening to a forward extension of the train; I
d. a pivotally mounted beam extends athwartship to the sides of the barge fitted with rudders to provide said towing chain connecting means;
e. a pair of equal length wires connected into the train extends aft to provide the said forward extension for fastening to said tow chains of a subsequent barge in the train; and, I
f. tugboat propulsion forces transmitted by said pair of hawsers altered to have varying lengths are conveyed throughout the train to affect the pivotal beam angularity thereby producing corresponding corrective rudder angularity effected by beamrudder interconnecting means to maintain train alignment in response to said altered hawsers.
l 1. In a combination of connected vessels-as in claim 10, the said pair of equal length wires employed as underrider pendants shackle tothe towchains of neighboring barges to establish the interval between barges.
12. In a combination of connected vessels as in claim 10, the said pair of equal length wires extend from reels mounted to the stern of a barge for extension aft with length depending upon interval of barge spacing for connection to the adjacent tow chain.
13. In a combination of connected vessels as in claim 10, the train further comprises:
a. an auxiliary tugboat employed for utilitarian purposes serves as a supplementary power means when situated to lead in the tow of the connected vessels; I I
b. said auxiliary tugboat servesas a controlleddrag when situated at the end of the train to offset following seas effort to destroy the train progress; and,
c. said auxiliary tug serves to shuttle barges as a sepa- 10. In a combination of connected vessels compris-
Claims (15)
1. In a combination of connected vessels comprising: a. a towed barge having at least one rudder at the stern thereof and a ship shape pointed prow; b. a tugboat in tow of the barge imparts propulsion forces through a pair of hawsers paid-out from a dual drum towing winch mounted on the tugboat; c. a pivotally mounted beam extends athwartship to the sides of the barge with beam end arrangement for connection to said hawsers; and, d. a beam to rudder interconnecting means transmits propulsion forces conveyed through the pivotal beam to a misaligned barge relative the tugboat to activative corrective rudder angularity; an improved steering imparting draft connection between vessels, comprising: 1. an elongated flexible member having the respective ends thereof secured to the opposite ends of said beam and an intermediate portion formed in tension transmitting engagement with a torque transfer means connected with said rudders; and, 2. a monitoring means selectively adapted to sense the change in angularity of hawser departure off the tug stern, occasioned by deviation in alignment of vessels, actuates control of the towing winch to establish a differential between the pair of hawser lengths, therewith adjusting said beam to athwartship angularity commensurate with corrective rudder angularity to reinstate vessels alignment and directional heading.
2. a monitoring means selectively adapted to sense the change in angularity of hawser departure off the tug stern, occasioned by deviation in alignment of vessels, actuates control of the towing winch to establish a differential between the pair of hawser lengths, therewith adjusting said beam to athwartship angularity commensurate with corrective rudder angularity to reinstate vessels alignment and directional heading.
2. An improved steering imparting draft connection between vessels according to claim 1, wherein said steering connection means further comprises: a. a watertight tunnel extends athwartship with open ends at sides of the barge to establish the pivotal mount and accommodate a limited rotative movement of said beam in response to the said differential between hawsers; b. a pair of tubular members fixed, respectively, to said barge adjacent the opposite sides thereof and having extended slidably therethrough said elongated member; c. a pair of sheave segments mounted, respectively, between each of said tubular members and a post extension for said rudders provides said tension transmitting engagement; d. grooves formed in the periphery of said sheave segments accommodate the seating of segmental lengths of said intermediate portion with ends fixed thereto to provide opposite extensions as continuations of the elongated flexible member; and, e. mating gears fixed, respectively, to a mounting means for the sheave segment and rudder post provides opposite directional rotative transmission of torque from said sheave segment to said rudders.
3. An improved steering imparting draft connection between vessels according to claim 2, wherein said tubular members comprises: a. a watertight connection between said tunnel and tube having a flared opening accommodates variable displacement at the entrance thereof of the elongated flexible member said slidable therethrough; and, b. a non-return trap connected to and intermittent the length of said tubular member intercepts conveyance of water admitted through said flared opening for discharge through a sealed opening in the barge side to the sea.
4. An improved steering imparting draft connection between vessels according to claim 2, wherein said beam end arrangement comprises: a. a torsion bar extEnds through said beam with the inboard discontinuous portion fixed to the beam adjacent to the pivotal axis thereof and opposite ends extending beyond the barge side to terminate with a lever arm angularly disposed therewith to twist the torsion bar commensurate with the force imposed by the tension in the hawser transmitted to the distal end of the lever arm; b. journal means provide support and accommodate said twist of the torsion bar relative the pivotal beam; c. bearing means accommodate free guided rotative movement of the pivotal beam within the tunnel; and, d. twist of said torsion bar supplemented by elastic stretch of tensioned hawsers provides resilience to cope with surge effect between said connected vessels subject to unequal sea forces.
5. An improved steering imparting draft connection between vessels according to claim 4, wherein said beam end arrangement incorporates a length of chain as an extension of the hawser with connection to the said distal end of the lever arm.
6. An improved steering imparting draft connection between vessels according to claim 1, wherein said beam end arrangement comprises: a. a chain length extension of the hawsers with connection to said beam ends imposes a weight creating extra sag and gradually imposed resistance to the extension of spaced relationship between vessels consequential with surge effect of unequal sea forces therebetween; and, b. pendants fixed to the prow of the barge extends for connection to each chain with length permitting free movement of said pivotal beam and restricting the chain from athwartship underriding the barge.
7. An improved steering imparting draft connection between vessels according to claim 1, wherein said steering connection comprises: a. manual control of the dual drum towing winch supplants the said monitoring means selectively adapted to haul-in hawsers for a close coupled vessel spacing; and, b. directional heading of the barge by towing effect of the tugboat supplemented by manipulation of the dual drum towing winch to alter rudder angularity, provides control of the barge in passage through restrictive channels and mooring of the barge with limited dock side accommodation respective the barge length.
8. An improved steering imparting draft connection between vessels according to claim 7, wherein further provisions to secure said close coupled vessels comprises a portable spreader bar extended from the tugboat stern to the barge prow with position retaining means in contention with sea swells variously displacing said vessels'' elevational relationship.
9. An improved steering imparting draft connection between vessels according to claim 1, wherein said steering connection means comprises: a. a locking means fixes the rudder to selected angularity respective the barge centerline to oppose forces transmitted by the hawser or sea effect to the rudders; and, b. rudder angularity extends from zero angle with minimum drag to a 90* angle with maximum drag resisting directional movement parallel to the barge centerline.
10. In a combination of connected vessels comprising: a. an arrangement of a tugboat with at least two barges in tandem tow having rudders mounted to the stern of at least the last of the train of barges; b. a pair of hawsers paid-out from a dual drum towing winch aboard the tugboat extends aft for connection to towing means of the first barge of the train; c. a pair of towing chains of equal fixed length for each barge of the train having reach from connecting means with a barge for fastening to a forward extension of the train; d. a pivotally mounted beam extends athwartship to the sides of the barge fitted with rudders to provide said towing chain connecting means; e. a pair of equal length wires connected into the train extends aft to provide the said forward extension for fastening to said tow chains of a subsequent barge in the train; and, f. tugboat propulsion forcEs transmitted by said pair of hawsers altered to have varying lengths are conveyed throughout the train to affect the pivotal beam angularity thereby producing corresponding corrective rudder angularity effected by beam-rudder interconnecting means to maintain train alignment in response to said altered hawsers.
11. In a combination of connected vessels as in claim 10, the said pair of equal length wires employed as underrider pendants shackle to the tow chains of neighboring barges to establish the interval between barges.
12. In a combination of connected vessels as in claim 10, the said pair of equal length wires extend from reels mounted to the stern of a barge for extension aft with length depending upon interval of barge spacing for connection to the adjacent tow chain.
13. In a combination of connected vessels as in claim 10, the train further comprises: a. an auxiliary tugboat employed for utilitarian purposes serves as a supplementary power means when situated to lead in the tow of the connected vessels; b. said auxiliary tugboat serves as a controlled drag when situated at the end of the train to offset following seas effort to destroy the train progress; and, c. said auxiliary tug serves to shuttle barges as a separated part from the train between the train and a nearby port and to overtake the train progressing uninterrupted on course to final destination.
14. An improved steering imparting draft connection between vessels according to claim 10, wherein said barges have an overhanging boom at the stern thereof to accommodate the safe disposition of the boat therefrom to provide transfer means for a man therebetween.
Applications Claiming Priority (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
US23809772A | 1972-03-27 | 1972-03-27 |
Publications (1)
Publication Number | Publication Date |
---|---|
US3745958A true US3745958A (en) | 1973-07-17 |
Family
ID=22896480
Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
---|---|---|---|
US00238097A Expired - Lifetime US3745958A (en) | 1972-03-27 | 1972-03-27 | Control of towed barges |
Country Status (1)
Country | Link |
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US (1) | US3745958A (en) |
Cited By (5)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US4275677A (en) * | 1979-01-02 | 1981-06-30 | Nelson Arthur J | Tow of barges by tugs |
US4553497A (en) * | 1982-11-15 | 1985-11-19 | Nelson Arthur J | Tow of barges by tugs |
WO1988005395A1 (en) * | 1987-01-15 | 1988-07-28 | Mckenzie John S | Flap rudder and steering system |
US4798157A (en) * | 1985-04-02 | 1989-01-17 | Jean Duret | Drogue associated with a guidance system |
US20090020062A1 (en) * | 2005-12-30 | 2009-01-22 | Saik Hay Fong | Method of Intercepting and Yawing a Sailing Vessel |
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US323639A (en) * | 1885-08-04 | William p | ||
US612539A (en) * | 1898-10-18 | Thomas gilbert bowick | ||
US3336895A (en) * | 1966-01-17 | 1967-08-22 | Arthur J Nelson | Yaw control of towed barges |
US3469552A (en) * | 1968-04-05 | 1969-09-30 | Jean V Patrick | Hawser steering anti-yawing and safety mechanism for towed barges and the like |
US3611977A (en) * | 1969-12-03 | 1971-10-12 | Inge Gordon Mosvold | System and apparatus for automatically steered towed vessels |
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Patent Citations (5)
Publication number | Priority date | Publication date | Assignee | Title |
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US323639A (en) * | 1885-08-04 | William p | ||
US612539A (en) * | 1898-10-18 | Thomas gilbert bowick | ||
US3336895A (en) * | 1966-01-17 | 1967-08-22 | Arthur J Nelson | Yaw control of towed barges |
US3469552A (en) * | 1968-04-05 | 1969-09-30 | Jean V Patrick | Hawser steering anti-yawing and safety mechanism for towed barges and the like |
US3611977A (en) * | 1969-12-03 | 1971-10-12 | Inge Gordon Mosvold | System and apparatus for automatically steered towed vessels |
Cited By (7)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US4275677A (en) * | 1979-01-02 | 1981-06-30 | Nelson Arthur J | Tow of barges by tugs |
US4553497A (en) * | 1982-11-15 | 1985-11-19 | Nelson Arthur J | Tow of barges by tugs |
US4798157A (en) * | 1985-04-02 | 1989-01-17 | Jean Duret | Drogue associated with a guidance system |
WO1988005395A1 (en) * | 1987-01-15 | 1988-07-28 | Mckenzie John S | Flap rudder and steering system |
AU601796B2 (en) * | 1987-01-15 | 1990-09-20 | John S. Mackenzie | Flap rudder and steering system |
US20090020062A1 (en) * | 2005-12-30 | 2009-01-22 | Saik Hay Fong | Method of Intercepting and Yawing a Sailing Vessel |
US7748338B2 (en) * | 2005-12-30 | 2010-07-06 | Singapore Technologies Dynamics Pte Ltd. | Method of intercepting and yawing a sailing vessel |
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