CN107848615A - The rudder configuration structure of ship - Google Patents
The rudder configuration structure of ship Download PDFInfo
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- CN107848615A CN107848615A CN201680042566.8A CN201680042566A CN107848615A CN 107848615 A CN107848615 A CN 107848615A CN 201680042566 A CN201680042566 A CN 201680042566A CN 107848615 A CN107848615 A CN 107848615A
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- rudder
- propeller
- rotary shaft
- face
- ship
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- 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
-
- 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
- B63H2025/066—Arrangements of two or more rudders; Steering gear therefor
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- Engineering & Computer Science (AREA)
- Combustion & Propulsion (AREA)
- Mechanical Engineering (AREA)
- Ocean & Marine Engineering (AREA)
- Measurement Of Velocity Or Position Using Acoustic Or Ultrasonic Waves (AREA)
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Abstract
The problem of the present invention is the rudder configuration structure for providing a kind of ship, and it is shortening the chord length of rudder, while stern configuration is easy, maneuvering performance can be made mutually to coordinate with propulsive performance.A kind of rudder configuration structure of ship, there is 1 propeller and multiple rudders, the rotary shaft of multiple rudders or so to be asymmetricly arranged in the propeller face of propeller for it, and multiple rudders or so are asymmetricly arranged in the propeller face of propeller.In the ship with 1 propeller (1) and 2 rudders (10,11), the rotary shaft (A of 1 rudder (10) in 2 rudders10) it is arranged at the middle of propeller face (3), the rotary shaft (A of another rudder (11)11) it is arranged at the side (right string S sides) that propeller (1) declines in the rotation of the inside of propeller face (3).
Description
Technical field
The present invention relates to the rudder configuration structure of ship.
Background technology
In the past, as shown in Figure 8, in the quarter of the hull 5 of ship, setting is installed on propeller shaft 2
Propeller 1 and the rudder 100 being installed on rudder stock, rudder 100 are rotated centered on rotary shaft A.Herein, the shape as rudder will
Element, including form the chord length of the length of ship length direction, the chord length L with the rudder 100a shown in Fig. 8 (a)1Compare, Fig. 8
(b) the chord length L of the rudder 100b shown in2It is shorter.In addition, with the short amount of chord length, Fig. 8 (b) propeller 1 is located at Fig. 8's (a)
The rear of propeller 1.
On the other hand, the configuration on propeller and rudder, in the ship with 1 propeller and 1 rudder, such as Fig. 9 institutes
As showing, rudder 100 is set on the hull center line C (on the extended line of propeller shaft 2) at the rear of propeller 1.Fig. 9 (a) is
The figure of the configuration of propeller and rudder is watched from hull rear, Fig. 9 (b) is watches the configuration of propeller and rudder above hull
Figure.In addition, label 3 represents the propeller face described when propeller 1 rotates, the arrow around propeller face 3 represents spiral
The direction of rotation of oar 1.In addition, symbol P represents larboard direction, symbol S represents starboard direction.
In addition, the configuration on propeller and rudder, in the ship with 1 propeller and 2 rudders, as shown in Figure 10
Like that, the small line C (extended line of propeller shaft 2) in the hull from the rear of propeller 1, towards two string sides, with same distance
(D101=D102) and position away from setting rudder 101,102.Figure 10 (a) is watches the configuration of propeller and rudder from hull rear
Figure, Figure 10 (b) is watches the figure of the configuration of propeller and rudder above hull.In addition, label 3 represents that propeller 1 rotates
When the propeller face described, the arrow around propeller face 3 represents the direction of rotation of propeller 1.In addition, symbol P represents left string
Direction, symbol S represent right chord line.Then, rudder 101,102 is in the propeller face 3 for being symmetrically arranged at propeller 1
Internal state.
In addition, the configuration on propeller and rudder, in patent document 1 and patent document 2, describes following inventions,
In the invention, independently of 1 rudder being arranged on the hull center line of rear propeller, set respectively in two string sides of hull
Rudder.
In addition, in patent document 3, following inventions are described, in the invention, are turned round by being set on the rudder of left and right
Turn, being in the shape of rudder in itself, left and right is asymmetric, reduces resistance caused by stream after the propeller for encountering rudder, improves pushability
Energy.
Prior art document
Patent document
Patent document 1:4-No. 1098 publications of JP Beneficials
Patent document 2:JP opens clear 61-No. 171691 publications in fact
Patent document 3:2010-No. 95239 publications of TOHKEMY
The content of the invention
The invention problem to be solved
But there is the problem of following, i.e. if the total length of ship is limited by modes such as bay limitations, with spiral shell
It is difficult to revolve oar, the configuration of rudder, in addition if ship type, main frame maximization caused by the increase of stern volume, then cause degradation,
The improvement of performance is difficult.
With respect to the situation, as shown in Fig. 8 (a), if can shorten the chord length of rudder, stern configuration is easy, and
And the roomy degree of stern can be reduced, but in contrast, because the effect of rudder is deteriorated, therefore maneuvering performance reduces.
On the other hand, people consider, rudder 101,102 as shown in Figure 10, shown in patent document 1 and patent document 2 in
As the string side of hull two adds the occasion of rudder, maneuvering performance is improved by increasing the quantity of rudder, still, the increasing of the quantity of rudder
Adding causes the variation of propulsive performance.
In addition, the purpose in the invention described in patent document 3 is that the shape of rudder in itself by making left and right is in a left side
It is right asymmetric, propulsive performance is improved, the purpose of the invention does not lie in the raising of maneuvering performance.
The invention reside in solving above-mentioned past problem, the present invention provides a kind of rudder configuration structure of ship, wherein, contracting
The chord length of short rudder, while stern configuration is easy, maneuvering performance can be made mutually to coordinate with propulsive performance.
The open scheme of invention
In order to solve above-mentioned problem, the rudder configuration structure of ship of the invention is related to 1 propeller and multiple rudders
The rudder configuration structure of ship, it is characterised in that rotary shaft of above-mentioned multiple rudders or so is asymmetricly arranged at above-mentioned propeller
In propeller face, above-mentioned multiple rudders or so are asymmetricly arranged in the propeller face of above-mentioned propeller.
In addition, " rotary shaft of rudder is arranged in propeller face " refers to is watching the left and right of the rotary shaft of rudder from hull rear
The occasion of the position (position in beam of hull direction) in direction, it is contained in the left and right in propeller face described during propeller rotation
In the range of direction.In addition, " rotary shaft of rudder or so is asymmetricly set " refers to is watching the rotary shaft of rudder from hull rear
Left and right directions position (position in beam of hull direction) occasion, the rudder of left and right when on the basis of the centre of propeller face
The position of rotary shaft is asymmetric.
Similarly, " rudder is arranged in propeller face " refers to is watching the position (ship of the left and right directions of rudder from hull rear
The position of body width) occasion, be included in the range of the left and right directions in propeller face described during propeller rotation.Separately
Outside, " rudder or so is asymmetricly set " refer to watched from hull rear the left and right directions of rudder position (beam of hull direction
Position) occasion, the position of the rudder of left and right when on the basis of the centre of propeller face is asymmetric.
It is further preferred to, it is characterised in that the rotary shaft of 1 rudder in above-mentioned multiple rudders is arranged in above-mentioned propeller face
Middle.
It is further, best, it is characterised in that in above-mentioned multiple rudders, rotary shaft is arranged at the middle in above-mentioned propeller face
Rudder beyond the rotary shaft of rudder be arranged at left and right either side in above-mentioned propeller face.
Further, it is best, it is characterised in that in above-mentioned multiple rudders, rotary shaft is arranged at the middle in above-mentioned propeller face
Rudder beyond the rotary shaft of rudder be arranged at the side that in the rotation in above-mentioned propeller face propeller reduces.
Again, it is preferred to, it is characterised in that the rotary shaft of 1 rudder in multiple rudders with middle in the way of being spaced apart
The left and right either side being arranged in above-mentioned propeller face, the rotary shaft of the remaining rudder in above-mentioned multiple rudders according to middle every
The mode for opening larger space is arranged at opposite side in above-mentioned propeller face.
It is further preferred to, it is characterised in that multiple rudders are 2.
The effect of invention
According to the present invention, in the rudder configuration structure with 1 propeller and the ship of multiple rudders, due to can be by will be more
Rotary shaft of individual rudder or so is asymmetricly arranged in the propeller face of propeller, multiple rudders can left and right be asymmetricly arranged at spiral shell
In the propeller face for revolving oar, therefore the rectification effect flowed after the propeller for the propeller that 1 direction can be attained at and rotated.Then,
In order that stern configuration easily, shortens the occasion of the chord length of rudder, compared with the occasion of 1 rudder, maneuvering performance improves, and
And by symmetrically setting multiple rudders, propulsive performance is difficult to reduce.Further, since can shorten the chord length of rudder, stern is matched somebody with somebody
Put easily, the small elongated ship type of design resistance, therefore the propulsive performance of hull in itself can be improved.
, can will be multiple in addition, the rotary shaft of 1 rudder in multiple rudders is arranged at the occasion of the middle in propeller face
1 rudder in rudder is arranged at the middle in propeller face, further improves the performance for the rudder for being arranged at middle.
Further, in multiple rudders, the rotary shaft of the rudder beyond the rudder for the middle that rotary shaft is arranged in propeller face is set
The occasion for the left and right either side being placed in propeller face, multiple rudders can be asymmetricly easily set for left and right.
Further, in above-mentioned multiple rudders, rotary shaft is arranged at the rotation of the rudder beyond the rudder of the middle in propeller face
Axle is arranged at the occasion of the side that propeller reduces in the rotation in propeller face, it is possible to provide in the spiral that 1 direction rotates
The rectification effect flowed after the propeller of oar, degree that can be higher and maneuvering performance is mutually coordinated with propulsive performance.
In addition, the rotary shaft of 1 rudder in multiple rudders is arranged at above-mentioned propeller in the way of being spaced apart with middle
Left and right either side in face, the rotary shaft of the remaining rudder in above-mentioned multiple rudders with middle in the way of larger space is separated
The opposite side being arranged in above-mentioned propeller face, in the occasion, even if in the case of being that middle is not provided with rudder, can still hold
Easily left and right asymmetricly sets multiple rudders.
In addition, be the occasion of 2 in multiple rudders, because the quantity of rudder is few, therefore can in the case where structure is excessively complicated,
Left and right is asymmetricly set.
More than, it is proposed, according to the invention, the rudder configuration structure of following ships can be provided, wherein, shortening the chord length of rudder, ship
While tail configuration is easy, maneuvering performance can be made mutually to coordinate with propulsive performance.
Brief description of the drawings
Fig. 1 is the figure of the rudder configuration structure for the ship for representing embodiments of the present invention 1;
Fig. 2 is the figure of the rudder configuration structure for the ship for representing embodiment 2;
Fig. 3 is the figure of the rudder configuration structure for the ship for representing embodiment 3;
Fig. 4 is the figure of the rudder configuration structure for the ship for representing embodiment 4;
Fig. 5 is the figure of the rudder configuration structure for the ship for representing embodiment 5;
Fig. 6 is the figure of the rudder configuration structure for the ship for representing embodiment 6;
Fig. 7 is the figure of the rudder configuration structure for the ship for representing embodiment and comparative example;
Fig. 8 is the side view for the stern section for representing ship;
Fig. 9 is the figure of the rudder configuration structure for the ship for representing existing example;
Figure 10 is the figure of the rudder configuration structure for the ship for representing existing example.
Embodiment
Referring to Fig. 1~Fig. 6, the rudder configuration structure of the rudder for ship of embodiments of the present invention is illustrated.First, it is right
The common item of 1~embodiment of embodiment disclosed below 6 illustrates.
Embodiment disclosed below is for the propeller 1 being arranged in the quarter of the ship 5 shown in Fig. 8 and rudder 100
The embodiment of configuration structure.In addition, by the big rudder 100a of chord length as relative Fig. 8 (a), it is such using Fig. 8 (b)
The short rudder 100b of chord length, while on the quarter configuring easy, makes its maneuvering performance mutually coordinate with propulsive performance.In addition, though
1 rudder is only described in fig. 8, and still, in embodiment disclosed below, with respect to 1 propeller sets multiple rudders.
In addition, in Fig. 1~Fig. 6 each figure, it is corresponding to scheme (a) to watch the configuration of propeller and rudder from hull rear
Figure, it is corresponding to scheme (b) to watch the figure of the configuration of propeller and rudder above hull.In addition, symbol 3 is represented in propeller
The propeller face described during 1 rotation, the arrow around propeller face 3 represent the direction of rotation of propeller 1.In addition, symbol P tables
Show larboard direction, symbol S represents starboard direction.In addition, symbol A represents the rotary shaft of respective rudder.An in addition, left side for respective rudder
The position (position in beam of hull direction) of right direction is true according to rotary shaft A situation is set in the where of left and right directions
It is fixed.
In addition, each figure is intended to indicate that the position for setting rudder, to put it more simply, rudder is shaped as quadrangle, still, show
The occasion so actually implemented, can form streamlined etc. shape.It is the shape of multiple rudders, big in addition, in the present embodiment
It is small identical, move in linkage.
Fig. 1 is the figure of the rudder configuration structure for the ship for representing embodiment 1.Propeller 1 rear set 2 rudders 10,
11.Rudder 10,11 is respectively according to rotary shaft A10、A11Centered on and rotate mode be installed on rudder stock 4,4.2 rotary shafts
A10、A11The inside in the propeller face 3 of propeller 1 is arranged in left and right directions (larboard P directions and starboard S directions).2 rotations
Rotating shaft A10、A11In 1 rotary shaft A10It is arranged at the middle (rear of propeller 1 of the left and right directions of the inside in propeller face 3
Hull center line C on).In addition, another rotary shaft A11With in itself and rotary shaft A10Between according to interval D11And the mode separated
It is arranged at the right side (starboard S sides) of the inside in propeller face 3.2 rotary shaft A10、A11Spiral is arranged in a non-symmetrical way
The inside in oar face 3.In addition, as understanding from the direction of rotation of propeller 1, rotary shaft A is set11Starboard S sides be
The side that propeller 1 declines during the rotation of propeller 1.
By like this, by 2 rotary shaft A10、A11Left and right is asymmetricly arranged at the inside in propeller face 3, rudder 10,11
Left and right is asymmetricly arranged at the inside in propeller face 3.
Fig. 2 is the figure of the rudder configuration structure for the ship for representing embodiment 2.Propeller 1 rear set 2 rudders 20,
21.Rudder 20,21 is respectively according to rotary shaft A20、A21Centered on and rotate mode be installed on rudder stock 4,4.2 rotary shafts
A20、A21The inside in the propeller face 3 of propeller 1 is arranged in left and right directions (larboard P directions and starboard S directions).2 rotations
Rotating shaft A20、A21In 1 rotary shaft A20It is arranged at the middle (rear of propeller 1 of the left and right directions of the inside in propeller face 3
Hull center line C on).In addition, another rotary shaft A21With in itself and rotary shaft A20Between according to interval D21And the mode separated
It is arranged at the right side (starboard S sides) of the inside in propeller face 3.2 rotary shaft A20、A21It is arranged in a manner of left and right is asymmetrical
The inside in propeller face 3.In addition, as understanding from the direction of rotation of propeller 1, rotary shaft A is set21Starboard S sides
For the side that propeller 1 declines in the rotation of propeller 1.In addition, the rotary shaft A of embodiment 221Close to embodiment 1
Rotary shaft A11Starboard S sides and (D is set11< D21)。
By like this, by 2 rotary shaft A20、A21Left and right is asymmetricly arranged at the inside in propeller face 3, rudder 20,21
Left and right is asymmetricly arranged at the inside in propeller face 3.
Fig. 3 is the figure of the rudder configuration structure for the ship for representing embodiment 3.Propeller 1 rear set 3 rudders 30,
31、32.Rudder 30,31,32 is respectively according to rotary shaft A30、A31、A32Centered on and rotate mode, be installed on rudder stock 4,4,4
On.3 rotary shaft A30、A31、A32The propeller of propeller 1 is arranged in left and right directions (larboard P directions and starboard S directions)
The inside in face 3.3 rotary shaft A30、A31、A32In 1 rotary shaft A30It is arranged at the left and right directions of the inside in propeller face 3
Middle (on the hull center line C at the rear of propeller 1).In addition, remaining 1 rotary shaft A31With in itself and rotary shaft A30It
Between according to interval D31And the mode separated is arranged at the right side (starboard S sides) of the inside in propeller face 3.In addition, another rotary shaft
A32With in itself and rotary shaft A30Between according to interval D32And the mode separated is arranged at the right side (starboard of the inside in propeller face 3
S sides).3 rotary shaft A30、A31、A32The inside in propeller face 3 is arranged in a manner of left and right is asymmetrical.In addition, as from spiral
The direction of rotation of oar 1 and as understanding, rotary shaft A is set31、A32Starboard S sides be in the rotation of propeller 1 propeller 1
The side of decline.
By like this, by 3 rotary shaft A30、A31、A32Left and right is asymmetricly arranged at the inside in propeller face 3, rudder
30th, 31,32 or so the inside for being asymmetricly arranged at propeller face 3.
Fig. 4 is the figure of the rudder configuration structure for the ship for representing embodiment 4.Propeller 1 rear set 3 rudders 40,
41、42.Rudder 40,41,42 is respectively according to rotary shaft A40、A41、A42Centered on and rotate mode be installed on rudder stock 4,4,4.
3 rotary shaft A40、A41、A42The propeller face 3 of propeller 1 is arranged in left and right directions (larboard P directions and starboard S directions)
Inside.1 rotary shaft A in 3 rudders40The middle of the left and right directions of the inside in propeller face 3 is arranged at (after propeller 1
On the hull center line C of side).In addition, remaining 1 rotary shaft A41With in itself and rotary shaft A40Between according to interval D41And every
The mode opened is arranged at the right side (starboard S sides) of the inside in propeller face 3.In addition, another rotary shaft A42With in itself and rotary shaft
A40Between according to interval D42And the mode separated is arranged at the left side (larboard P sides) of the inside in propeller face 3.Interval D41Between >
Every D42, 3 rotary shaft A40、A41、A42Left and right is asymmetricly arranged at the inside in propeller face 3.
By like this, by 3 rotary shaft A40、A41、A42Left and right is asymmetricly arranged at the inside in propeller face 3, rudder
40th, 41,42 or so the inside for being asymmetricly arranged at propeller face 3.
Fig. 5 is the figure of the rudder configuration structure for the ship for representing embodiment 5.Propeller 1 rear set 2 rudders 51,
52.Rudder 51,52 is respectively according to rotary shaft A51、A52Centered on and rotate mode be installed on rudder stock 4,4.2 rotary shafts
A51、A52The inside in the propeller face 3 of propeller 1 is arranged in left and right directions (larboard P directions and starboard S directions).Implementing
In mode 5, rotary shaft is not provided with middle (the hull center line at the rear of propeller 1 of the left and right directions inside propeller face 3
On C).In addition, 2 rotary shaft A50、A51In 1 rotary shaft A51With its centre with left and right directions (rear of propeller 1
On hull center line C) between according to interval D51And the mode separated is arranged at the right side (starboard S sides) of the inside in propeller face 3.
In addition, another rotary shaft A52With its between the centre (on the hull center line C at the rear of propeller 1) of left and right directions according to
Every D52And the mode separated is arranged at the left side (larboard P sides) of the inside in propeller face 3.Interval D51> interval Ds52, 2 rotations
Axle A51、A52Left and right is asymmetricly arranged at the inside in propeller face 3.That is, rotary shaft A51With larger space relatively spaced intermediate
Mode be arranged in propeller face 3 with rotary shaft A52Opposite side.In addition, can also according to make left and right interval on the contrary,
Every D51< interval Ds52Mode set.
By like this, by 2 rotary shaft A51、A52Left and right is asymmetricly arranged at the inside in propeller face 3, rudder 51,52
Left and right is asymmetricly arranged at the inside in propeller face 3.
Fig. 6 is the figure of the rudder configuration structure for the ship for representing embodiment 6.Propeller 1 rear set 2 rudders 60,
61.Rudder 60,61 is respectively according to rotary shaft A60、A61Centered on and rotate mode be installed on rudder stock 4,4.2 rotary shafts
A60、A61The inside in the propeller face 3 of propeller 1 is arranged in left and right directions (larboard P directions and starboard S directions).2 rotations
Rotating shaft A60、A61In, 1 rotary shaft A60Middle (the hull at the rear of propeller 1 for the left and right directions being arranged in propeller face 3
On center line C).In addition, another rotary shaft A61With in itself and rotary shaft A60Between according to interval D61And the mode separated is set
In the left side of the inside in propeller face 3 (larboard P sides).2 rotary shaft A61、A62Left and right is asymmetricly arranged at propeller face 3
It is internal.In addition, as understanding from the direction of rotation of propeller 1, rotary shaft A is set61Larboard P sides be in propeller 1
Rotation when propeller 1 rise side.
By like this, by 2 rotary shaft A60、A61Left and right is asymmetricly arranged at the inside in propeller face 3, rudder 60,61
Left and right is asymmetricly arranged at the inside in propeller face 3.
The action effect of above-mentioned embodiment is illustrated below.In embodiment 1~6, for having 1 spiral shell
The rudder configuration structure of the ship of oar 1 and multiple rudders is revolved, by the way that rotary shaft of multiple rudders or so is asymmetricly arranged at into propeller 1
Propeller face 3 inside, multiple rudders or so are asymmetricly arranged in the inside in the propeller face 3 of propeller 1.Due to spiral shell
The direction of rotation for revolving oar 1 is 1 direction, therefore for stream acquisition rectification effect after the propeller of opposed helical oar 1, do not use over
Symmetrical rudder configuration structure, the asymmetrical rudder configuration structure in left and right as present embodiment is suitable.
According to the ship configuration structure of the ship of embodiment 1~6, the spiral shell for the propeller 1 that 1 direction can be attained at and rotated
The rectification effect flowed after rotation oar.Then, in order that stern configuration easily, shortens the occasion of the chord length of rudder, the field with 1 rudder
Conjunction compares, and maneuvering performance improves, and compared with the occasion for symmetrically setting multiple rudders, propulsive performance is difficult to drop
It is low.Further, since shortening the chord length of rudder, make stern configuration easy, can the small elongated ship type of design resistance, therefore ship can be improved
The propulsive performance of body in itself.
In addition, the ship configuration structure of the ship according to embodiment 1,2,3,4,6, by by 1 rudder in multiple rudders
Rotary shaft is arranged at the middle in propeller face 3, the middle 1 rudder in multiple rudders being arranged in propeller face 3, can
Further improve the performance for the rudder for being arranged at middle.
Further, the ship configuration structure of the ship according to embodiment 1,2,3,6, by the way that by multiple rudders, rotary shaft is set
The left and right either side being arranged in the rotary shaft of the rudder beyond the rudder of the middle in propeller face 3 in propeller face 3, can be easy
Left and right asymmetricly configures multiple rudders.
Further, according to embodiment 1,2,3 ship ship configuration structure, by the way that by multiple rudders, rotary shaft is arranged at
Propeller 1 declines when the rotary shaft of rudder beyond the rudder of middle in propeller face 3 is arranged at the rotation in propeller face 3
Side, the rectification effect flowed after the propeller for the propeller 1 that 1 direction rotates can be improved, degree that can be higher and
Maneuvering performance is set mutually to coordinate with propulsive performance.
In addition, the ship configuration structure of the ship according to embodiment 5, by the way that the rotary shaft of 1 rudder in multiple rudders is pressed
According to the left and right either side being arranged at the mode that middle ware separates in propeller face 3, the rotary shaft of the remaining rudder in multiple rudders
The opposite side being arranged in the way of with larger space spaced intermediate in propeller face, even in rudder is not arranged at into centre
In the case of place, still multiple rudders can be asymmetricly easily set for left and right.
In addition, the ship configuration structure of the ship according to embodiment 1,2,6, by making multiple rudders be 2, due to the number of rudder
Amount is few, therefore does not make structure excessively complicated, can left and right asymmetricly set.
More than, the ship configuration structure of ship in the embodiment, it is possible to provide the rudder configuration structure of following ships, its
In, the chord length of rudder can shortened, while stern configuration is easy, maneuvering performance is mutually coordinated with propulsive performance.
Embodiment
In order to investigate the influence of the rudder of rear propeller configuration, resistance, the self-propulsion test of backflow tank are carried out, evaluation promotes
Performance.Fig. 7 is the figure of the rudder configuration structure for the ship for representing embodiment and comparative example.
(embodiment 1)
As shown in Fig. 7 (a), 2 rudders 10,11 are set in the inside in the propeller face 3 of propeller.2 rudders
In, 1 (rotary shaft A of rudder 1010) middle (the hull center at the rear of propeller 1 of left and right directions that is arranged in propeller face 3
On line C), another rudder 11 (rotary shaft A11) according to (the rotary shaft A of rudder 1010) interval D11Mode be arranged at propeller
Right side (right string S sides) in face 3.
D11Diameter × 0.211 in=propeller face 3
(embodiment 2)
As shown in Fig. 7 (b), 2 rudders 60,61 are set in the inside in the propeller face 3 of propeller.2 rudders
In, 1 (rotary shaft A of rudder 6060) middle (the hull center at the rear of propeller 1 of left and right directions that is arranged in propeller face 3
On line C), another rudder 61 (rotary shaft A60) according to (the rotary shaft A of rudder 6010) interval D61Mode be arranged at propeller
Left side (left string P sides) in face 3.
D61Diameter × 0.211 in=propeller face 3
(comparative example 1)
As shown in Fig. 7 (c), 2 rudders 101,102 are set in the inside in the propeller face 3 of propeller.2
In rudder, 1 (rotary shaft A of rudder 101101) according between the centre (on the hull center line C at the rear of propeller 1) of left and right directions
Interval D101Mode be arranged at right side (right string S sides) in propeller face 3.In addition, another rudder 102 (rotary shaft A102)
According to interval D between the centre (on the hull center line C at the rear of propeller 1) of left and right directions102Mode be arranged at spiral shell
Revolve the left side (left string P sides) in oar face 3.Interval D101=interval D102。
D101=D102Diameter × 0.211 in=propeller face 3
(comparative example 2)
As shown in Fig. 7 (d), 2 rudders 201,202 are set in the inside in the propeller face 3 of propeller.2
In rudder, 1 (rotary shaft A of rudder 201201) according between the centre (on the hull center line C at the rear of propeller 1) of left and right directions
Interval D201Mode be arranged at right side (right string S sides) in propeller face 3.In addition, another rudder 202 (rotary shaft A202)
According to interval D between the centre (on the hull center line C at the rear of propeller 1) of left and right directions202Mode be arranged at spiral shell
Revolve the left side (left string P sides) in oar face 3.Interval D201=interval D202。
D201=D202Diameter × 0.141 in=propeller face 3
4 kinds of rudders configuration on more than, on the basis of comparative example 1, the propulsive performance of measure BHP (horsepower) benchmark improves effect
Fruit.Measurement result is listed in Table 1 below.
(table 1)
The propulsive performance improvement of BHP (horsepower) benchmark | |
The Fig. 7 (a) of embodiment 1/ | - 5.2% |
The Fig. 7 (b) of embodiment 2/ | - 3.6% |
The Fig. 7 (c) of comparative example 1/ | Benchmark |
The Fig. 7 (d) of comparative example 2/ | - 4.5% |
The relative comparative example 1 for forming benchmark, in embodiment 1, confirm about 5.2% improvement.In addition, equally in reality
Apply in example 2, confirm about 3.6% improvement.In this occasion, configured by the asymmetrical rudder in left and right, thrust deduction coefficient, wake
The propulsive elements of coefficient improve.Confirm in addition, in relative right bladed propeller, 1 rudder is arranged at the occasion of right string S sides, pushability
Can be excellent.
In addition, the relative comparative example 1 for forming benchmark, in comparative example 2 of 2 rudders close to pars intermedia, confirms about 4.5%
Improvement.Like this, the occasion of 2 rudders is symmetrically being set, had by making 2 rudders close to middle, wake effect
The tendency that fruit improves.Then it is believed that even if being in propeller face, in the case that asymmetricly 2 rudders are set, reducing
The occasion at the interval of 2 rudders, still can further improve propulsive performance.
The rudder configuration structure of the ship of embodiments of the present invention is illustrated above, still, the invention is not restricted to
Above-mentioned embodiment, other various changes can be carried out.
For example in the above-described embodiment, size, the shape of multiple rudders are identical, but it is alternatively different sizes, shape
Shape.
In addition, multiple rudders act in linkage, but also can independently act.
Further, being watched from hull rear, the direction of rotation of propeller is to turn right, but can also be turned left.
Further, the quantity of multiple rudders is also greater than equal to 4.
In addition, also other rudder can be additionally set in the outside in propeller face or the front of propeller.
In addition, the configuration left and right that " left and right is asymmetric " in the present invention refers to the rudder on the basis of the rotary shaft of rudder is asymmetric,
It is asymmetric the shape of the rudder of left and right in itself or so is not referred to.If the configuration left and right of the rudder on the basis of the rotary shaft of rudder is asymmetric,
Even if then the rudder of left and right in itself to be shaped as left and right asymmetric and not related.
The explanation of label:
Label 1 represents propeller;
Label 2 represents propeller shaft;
Label 3 represents propeller face;
Label 4 represents rudder stock;
Label 5 represents hull;
Label 10 represents rudder;
Label 11 represents rudder;
Label 20 represents rudder;
Label 21 represents rudder;
Label 30 represents rudder;
Label 31 represents rudder;
Label 32 represents rudder;
Label 40 represents rudder;
Label 41 represents rudder;
Label 42 represents rudder;
Label 51 represents rudder;
Label 52 represents rudder;
Label 60 represents rudder;
Label 61 represents rudder;
Label 100 represents rudder;
Label 101 represents rudder;
Label 102 represents rudder;
Label 201 represents rudder;
Label 202 represents rudder;
Symbol A represents rotary shaft.
Claims (6)
1. a kind of rudder configuration structure of ship, it has 1 propeller and multiple rudders, it is characterised in that the rotation of above-mentioned multiple rudders
Rotating shaft or so is asymmetricly arranged in the propeller face of above-mentioned propeller, and above-mentioned multiple rudders or so are asymmetricly arranged at above-mentioned
In the propeller face of propeller.
2. the rudder configuration structure of ship according to claim 1, it is characterised in that the rotation of 1 rudder in above-mentioned multiple rudders
Rotating shaft is arranged at the middle in above-mentioned propeller face.
3. the rudder configuration structure of ship according to claim 2, it is characterised in that in above-mentioned multiple rudders, rotary shaft is set
The left and right either side being arranged in the rotary shaft of the rudder beyond the rudder of the middle in above-mentioned propeller face in above-mentioned propeller face.
4. the rudder configuration structure of ship according to claim 2, it is characterised in that in above-mentioned multiple rudders, rotary shaft is set
The spiral when rotary shaft of the rudder beyond the rudder of the middle in above-mentioned propeller face is arranged in the rotation in above-mentioned propeller face
The side that oar reduces.
5. the rudder configuration structure of ship according to claim 1, it is characterised in that the rotation of 1 rudder in above-mentioned multiple rudders
Rotating shaft is arranged at the left and right either side in above-mentioned propeller face in the way of being spaced apart with middle, surplus in above-mentioned multiple rudders
The rotary shaft of remaining rudder is arranged at the opposite side in above-mentioned propeller face in the way of larger space is separated with middle.
6. the rudder configuration structure of the ship described in any one in Claims 1 to 5, it is characterised in that above-mentioned multiple
Rudder is 2.
Applications Claiming Priority (3)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
JP2015-147277 | 2015-07-25 | ||
JP2015147277 | 2015-07-25 | ||
PCT/JP2016/071616 WO2017018357A1 (en) | 2015-07-25 | 2016-07-22 | Rudder arrangement structure for ship |
Publications (1)
Publication Number | Publication Date |
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CN107848615A true CN107848615A (en) | 2018-03-27 |
Family
ID=57884415
Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
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CN201680042566.8A Pending CN107848615A (en) | 2015-07-25 | 2016-07-22 | The rudder configuration structure of ship |
Country Status (4)
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JP (1) | JP6484339B2 (en) |
KR (1) | KR20180020260A (en) |
CN (1) | CN107848615A (en) |
WO (1) | WO2017018357A1 (en) |
Cited By (1)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN112590475A (en) * | 2020-12-25 | 2021-04-02 | 芜湖造船厂有限公司 | Electric steering structure of amphibious vehicle and control method thereof |
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- 2016-07-22 CN CN201680042566.8A patent/CN107848615A/en active Pending
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CN112590475A (en) * | 2020-12-25 | 2021-04-02 | 芜湖造船厂有限公司 | Electric steering structure of amphibious vehicle and control method thereof |
Also Published As
Publication number | Publication date |
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KR20180020260A (en) | 2018-02-27 |
WO2017018357A1 (en) | 2017-02-02 |
JPWO2017018357A1 (en) | 2018-05-10 |
JP6484339B2 (en) | 2019-03-13 |
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