Classifications

• • B—PERFORMING OPERATIONS; TRANSPORTING
  • B63—SHIPS OR OTHER WATERBORNE VESSELS; RELATED EQUIPMENT
  • B63H—MARINE PROPULSION OR STEERING
  • B63H25/00—Steering; Slowing-down otherwise than by use of propulsive elements; Dynamic anchoring, i.e. positioning vessels by means of main or auxiliary propulsive elements
  • B63H25/06—Steering by rudders
  • B63H25/38—Rudders
• • B—PERFORMING OPERATIONS; TRANSPORTING
  • B63—SHIPS OR OTHER WATERBORNE VESSELS; RELATED EQUIPMENT
  • B63H—MARINE PROPULSION OR STEERING
  • B63H25/00—Steering; Slowing-down otherwise than by use of propulsive elements; Dynamic anchoring, i.e. positioning vessels by means of main or auxiliary propulsive elements
  • B63H25/06—Steering by rudders
  • B63H25/38—Rudders
  • B63H2025/388—Rudders with varying angle of attack over the height of the rudder blade, e.g. twisted rudders

Definitions

• the invention relates to a rudder for ships according to the preamble of claim 1.
• Ship rudders such as full-floating rudder or balance rudder, with or without hinged fin, are known in various embodiments.
• a rudder blade with two superimposed rudder blade sections, the propeller facing front nose strips are offset from each other such that the one nose bar to port or starboard and the other nose bar are offset to starboard or port side, wherein the two side wall surfaces of the rudder blade converge in an end bar facing away from the propeller.
• the nose strips of the two rudder blade sections are offset from each other, so that the nose strip of the upper rudder blade section to port and the nose strip of the lower rudder blade section to starboard or the nose strip of the upper rudder blade section to starboard and the nose strip of the lower rudder blade section are offset to port, respectively obtained two mutually mirror-inverted cross-sectional profiles of the two rudder blade sections.
• the further inventive embodiment according to claim 2 provides for the arrangement of the ship's rudder in conjunction with his rudder stock in a rowing koker stock.
• the rudder blade has two superimposed sections, the propeller facing the leading edge strips are offset such that the one nose bar to port and the other nose bar are moved to starboard, the two side wall surfaces of the rudder blade converge in a propeller facing away from the end bar , wherein the rudder trunk bearing is provided as a cantilever beam with a central inner longitudinal bore for receiving the rudder stock for the rudder blade and extending into the rudder end connected to the rudder blade, wherein for supporting the rudder stock a bearing in the inner longitudinal bore of the rudder trunk bearing is arranged, with its free end in a recess, confiscation o.
• the rudder stock is led out in its end with a portion of the rudder trunk and connected to the end of this section with the rudder blade, with no storage between the rudder blade and the rudder trunk is provided and wherein the connection of the rudder stock with the rudder blade is above the propeller shaft center, wherein the bottom bracket is arranged for the storage of the rudder stock in the rudder trunk in the end of the rudder trunk.
• the upper rudder blade portion of the rudder blade has a cross-sectional profile extending from a front of the leading edge bar to the rear end bar and up to a maximum profile thickness conically widening front surface and a to the front Surface subsequent and to the rear end bar conically tapered rear surface is formed, the two of a in The longitudinal surface portion of the rudder blade extending centerline formed front surface portions have different sizes, of which the larger surface portion is located on the port side and the smaller surface portion starboard side lying, wherein the two formed by the center line in the rear region of the cross-sectional profile surface portion are the same, and that the lower rudder blade portion the rudder blade has a cross-sectional profile extending from a front surface extending from the leading edge of the nose strip to the rearward end edge and conically widening to a maximum profile thickness and one adjacent to the front surface and forming the rear surface, the two of a front surface portions formed in the longitudinal direction of the rudder blade have different sizes,
• the two propeller-side surface portions of the cross-sectional profile of the upper rudder blade portion have edge regions with a flat arc and a curved arc, the two facing away from the propeller surface portions of the cross-sectional profile of the upper rudder blade portion tangentially extending edge region, wherein the surface portion is located on the starboard side with the edge region with a curved arc ,
• the two propeller-side surface portions of the cross-sectional profile of the lower rudder blade portion have edge region with a flat arc shape and a curved arc curve, the two Having the propeller facing away from the surface portions of the cross-sectional profile of the lower rudder blade portion tangentially extending edge regions, wherein the surface portion is located with the edge region with arched bow course port side.
• FIG. 1 shows a rudder assembly of a rudder blade with a rudder stock and a propeller associated with the rudder blade
• FIG. 2A is a perspective view of the rudder blade
• FIG. 2B is a front view of the rudder blade of FIG. 2A
• Fig. 4 is a top view of the cross-sectional profile of the upper rudder blade portion of the rudder
• Fig. 5 is a top view of the cross-sectional profile of the lower rudder blade portion of Fig. 6 shows the rudder assembly with rudder stock mounted in the rudder rod bearing and the attachment point of the rudder stock above the propeller shaft center with the rudder blade
• Fig. 7 a vertical section along the line Vll-VII in Fig. 6 and
• Fig. 8 is a schematic representation of the bearing assembly between the rudder stock and the rudder trunk.
• reference numeral 110 designates a hull, 120 a rudder rod bearing, 100 a rudder blade, and 140 a rudder stock.
• the rudder blade 100 is associated with a propeller 220.
• the rudder blade 100 according to FIGS. 2A, 2B and 3 has two superimposed rudder sections 10, 20, whose front nose strips 11, 31 facing the propeller 220 are offset in such a manner that one nose strip 11 moves to port BB and the other nose strip 21 to behind Starboard SB are offset.
• the two side wall surfaces 100a, 100b of the rudder blade 100 merge into an end bar 30 facing away from the propeller 220.
• the upper and lower rudder blade sections 10, 20 of the rudder blade 100 are formed as follows:
• the upper rudder blade section 10 has, according to FIG. 4, a cross-sectional profile 12 which is formed by a front surface 14 which tapers conically from the front nose strip 11 to the end rail 30 up to a largest profile thickness 13.
• a rear surface 15 extending to the end bar 30 connects, which tapers to the end bar 30.
• the front surface 14 is subdivided by a center line M1 extending in the longitudinal direction of the rudder blade 100 into two surface sections 14a, 14b which have different sizes.
• the larger surface portion 14a is located on the port side and the smaller surface portion 14b facing the starboard side.
• the rear surface 15 is also divided from the center line M1 into two surface portions 15a, 15b.
• the two surface portions 15a, 15b are the same size and have the same shapes.
• the two propeller-side surface sections 14a, 14b of the cross-sectional profile 12 of the upper rudder blade section 10 have edge regions 16, 16a with a flat curved path 16'a, the two propeller 220 facing away from the surfaces 15a, 15b of the cross-sectional profile 12 of the upper rudder blade section 10 tangentially extending edge regions 17th 17a.
• the surface portion 14b with the edge region 16a with a strongly arched curve 16'a is located on the starboard side.
• the lower rudder blade section 20 has, according to FIG. 5, a mirror-inverted cross-sectional profile 22.
• This cross-sectional profile 20 extends from a conically widening from the leading edge 21 to the end bar 30 and to a maximum profile thickness 23 surface.
• Adjoining this front surface 24 is a surface 25 which extends toward the end strip 30 and tapers to the end strip 30.
• the front surface 24 is subdivided by a center line M2 running in the longitudinal direction of the rudder blade 100 into two surface sections 24a, 24b which have different sizes.
• the larger surface portion 24b is located starboard side and the small surface portion 24a is facing the port side.
• the rear surface 25 is also divided from the center line M2 into two surface portions 25a, 25b.
• the two surface portions 25a, 25b are the same size and have the same shape.
• the two propeller-side surface portions 24a, 24b of the cross-sectional profile 22 of the upper rudder blade portion 20 have edge regions 26, 26a with a flat arc 26 'and a curved arc 26'a, the two facing away from the propeller 220 surfaces 25a, 25b of the cross-sectional profile 22 of the lower Ruderblattabiteses 20 tangentially extending edge regions 27, 27a have.
• the surface portion 24b with the edge region 26'a with a strongly arched curve 26'a is located on the port side.
• the design and arrangement of the two rudder blade sections 10, 20 provides that the propeller 220 associated nose strip 11 of the upper rudder blade section 10 port side to the center line M1 and the nose strip 21 of the lower rudder blade section 20 starboard side lying to the center line M2, wherein the two rudder blade sections 10, 20th in the rear region of the rudder blade 100 are brought together in an end strip 30.
• the two rudder blade sections 10, 20 of the rudder blade 100 are arranged with their cross-sectional profiles 12, 22 relative to one another in such a way that the side wall sections of the rudder blade, which in the region of the highly curved curved courses 16'a and 26'a of the surface portions 14b and 24b are starboard side and port side, then the surface portion 14b of the cross-sectional profile 12 starboard side and the surface portion 24b of the cross-sectional profile 22 are facing port side, so that the nose strips 11, 21 of the two rudder blade sections 10, 20 port side and starboard side lie.
• the invention also includes an embodiment of the rudder, according to which the two rudder blade sections 10, 20 of the rudder blade 100 are arranged with their cross-sectional profiles 12, 22 to each other such that the side wall portions of the rudder blade, in the region of the highly curved arc curves 16'a and 26'a of the surface portions 14b and 24b are port side and starboard side, then the surface portion 14b of the port side cross-sectional profile 12 and the surface portion 24b of the starboard side cross-sectional profile 22 are facing, so that the nose ledges 11, 21 of the two rudder blade sections 10, 20 starboard side and on the port side.
• reference numeral 110 denotes a hull, 120 a rudder trunk bearing, 100 a rudder blade and 140 a rudder stock.
• a fin 135 is hinged.
• the rudder blade 100 has a preferably cylindrical recess 155 for receiving the free end 120 b of the rudder trunk bearing 120.
• the rudder rod bearing 120 is provided as a cantilever with a central inner longitudinal bore 125 for receiving the rudder stock 140 for the rudder blade 100.
• the rudder trunk bearing 120 is sufficiently formed to the rudder blade 100 connected to the rudder end.
• the rudder trunk bearing 120 has a bearing 150 for supporting the rudder stock 140, wherein preferably this bearing 150 is arranged in the lower end region 120b of the rudder trunk bearing 120.
• the rudder stock 140 is led out with its end 140b with a section 145 from the rudder trunk bearing 120.
• this extended portion 145 of the rudder stock 140 is fixedly connected to the rudder blade 100 at 1 0, but also here a connection is provided which allows a release of the rudder blade 100 of the rudder stock 140 when the propeller shaft is to be replaced.
• the connection of the rudder stock 140 in the area 170 with the rudder blade 100 is above the propeller shaft center 200, so that only the rudder blade 100 must be removed from the rudder stock 140 for the expansion of the propeller shaft, while pulling out the rudder stock 140 from the rudder trunk 120 not is necessary, since both the free lower end 120b of the rudder trunk bearing 120 and the free lower end of the rudder stock 140 are above the propeller shaft center.
• the rudder blade 100 is provided with a recess or recess indicated at 160.
• the rudder trunk bearing 120 is provided as a cantilever with a central inner longitudinal bore 125 for receiving the rudder stock 140 for the rudder blade 100. Furthermore, the rudder trunk bearing 120 is formed reaching into the rudder blade 100 connected in the rudder end and has in its inner bore 125 a bearing 150 for supporting the rudder stock 140 in the rudder trunk bearing 120. With its free end 120 b, the rudder trunk bearing 120 extends into a recess 160 in the rudder blade 100, the rudder stock 140 being led out of the rudder trunk bearing 120 in its end region 140 b with a section 145.
• this extended portion 145 of the rudder stock 140 is connected to the rudder blade 100, wherein the connection of the rudder stock 140 with the rudder blade 100 above the propeller shaft center 200 is lying.
• the inner bearing 150 is preferably provided in the end region 120b of the rudder trunk bearing 120.
• the invention is not limited to the embodiments described above and illustrated in the drawing. Deviations in the arrangement of the bearing in the area of the rudder trunk bearing 120 and the rudder stock 140 are also within the scope of the invention as another embodiment of the cylindrical recess 160 in the rudder blade 11.
• the inventively constructed rudder arrangement o. In ships as well as in floating platforms o. applicable.

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• Engineering & Computer Science (AREA)
• Combustion & Propulsion (AREA)
• Mechanical Engineering (AREA)
• Ocean & Marine Engineering (AREA)
• Chemical & Material Sciences (AREA)
• Toys (AREA)
• Structures Of Non-Positive Displacement Pumps (AREA)
• Physical Or Chemical Processes And Apparatus (AREA)
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Cited By (5)

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• 2004
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