Steering device and method for steering the same

Abstract

A steering device having two rudder plates vertically suspended at a distance from an outer edge of a propeller. The rudder plates are biaxially arranged and symmetrically rotate around a screw shaft within a propeller radius from a screw shaft center, on a propeller rotation plane, and are turned from aside the propeller to downstream of the propeller by rotation of the steering shafts, each of which is driven independently by two hydraulic driving mechanisms. The steering action of the steering device has two modes: the two-independent mode, where the plates rotate in the same direction, and the two-same direction modes, where the plates move in different directions. A method for steering the same to enhance a thrust flow by increase in a propeller rate is also provided.

Claims

1. A steering device having a driving mechanism rotating a steering shaft, and a power mechanism driving this, wherein the steering shaft is biaxially arranged rotatably to have vertical rotation axes located on both sides of a screw shaft, two rudder plates are located lateral to a propeller at the time of straight travelling, each of the two rudder plates connects to the corresponding steering shaft, each of the two rudder plates turn around the rotation axis of the corresponding steering shaft and connects to the corresponding steering shaft, while a position of center of the rudder plate is movable, and each of the two rudder plates turn at least in a range from aside of a propeller to a downstream of the propeller by rotation of the two steering shafts.

2. The steering device according to claim 1, wherein both of the two rudder plates face each other across the propeller, and turn around the propeller with a same rudder angle.

3. The steering device according to claim 2, wherein a rudder angle range exceeds 70 degrees, and the two rudder plates turn so as to almost block a propeller slipstream.

4. The steering device according to claim 1, wherein each of the rudder plates is formed into a L-letter type, where the rudder plate is extended laterally from the steering shaft and then suspended downwardly.

5. The steering device according to claim 2, wherein the rudder plates have cambers on surfaces thereof which are opposite each other.

6. The steering device according to claim 1, wherein the rudder plates have a limit of a chord length, which is allotted when one rudder plate is arranged at a propeller slipstream, and a wing thickness of the rudder plate is smaller than a wing thickness allotted when one rudder plate is arranged at the propeller slipstream.

7. The steering device according to claim 1, wherein the driving mechanism performs by freely switching each mode of a two-independent mode in which the two rudder plates are turning-driven independently of each other and a two-same direction mode in which the two rudder plates are both turning-driven in the same direction.

8. The steering device according to claim 7, wherein in the two-independent mode, the rudder plate on a broadside opposite to a veering direction is turned from aside of the propeller to behind of the propeller by rotating the steering shaft, and simultaneously with this, or before or after this, the other rudder plate on a broadside on a veering direction side is turned from aside of the propeller with a rudder angle of 90 degrees behind of the propeller.

9. A method for steering the steering device according to claim 8 comprises the two-independent modes turning the rudder plate on a broadside opposite to a veering direction from aside of the propeller to behind of the propeller by rotating the steering shaft, simultaneously with this, or before or after this, turning the other rudder plate on a broadside and veering direction side from aside of the propeller with a rudder angle of 90 degrees behind of the propeller, and after turning of the two rudder plates, further, increasing the propeller rotational speed more than the propeller rotational speed at the time of a ship condition with straight course keeping.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) FIG. 1 A side view of a stern of a ship to which a first embodiment of the present steering device is applied.

(2) FIG. 2 A plane view of the steering device in connection with the first embodiment at the time of steering.

(3) FIG. 3 A front view of the same device.

(4) FIG. 4 A perspective of the same device.

(5) FIG. 5 A perspective of a gear driving mechanism of the same device.

(6) FIG. 6A A perspective of a crank driving mechanism in connection with another embodiment of a driving mechanism of the same device.

(7) FIG. 6B A perspective of a crank driving mechanism in connection with another embodiment of a driving mechanism of the same device.

(8) FIG. 7 A plane view/a front view of the same device at the time of direct traveling.

(9) FIG. 8 A plane view/a front view of the same device at the time of starboard turning.

(10) FIG. 9 A plane view/a front view of the same device at the time of larboard turning.

(11) FIG. 10 A plane view/a front view of the same device at the time of stopping.

(12) FIG. 11 A comparison view between uniaxial turning of the same device at the time of stopping.

(13) FIG. 12 An arrangement view of a rudder plate and a propeller of the same device.

(14) FIG. 13 A front view including a propeller at a rudder plate portion of a steering device in connection with a second embodiment (the case where a lower portion of a reverse L-letter type rudder plate includes an arc shape).

(15) FIG. 14 A side view of the same device.

(16) FIG. 15 A perspective of the same device.

(17) FIG. 16 A side schematic view of a stein of a ship using a steering device in connection with a third embodiment.

(18) FIG. 17 A front schematic view of a rudder and a steering shaft of the same device.

(19) FIG. 18 A perspective schematic view of a rudder and a steering shaft of the same device.

(20) FIG. 19 A horizontal sectional B-B schematic view of a driving mechanism of the same device.

(21) FIG. 20 A plane schematic view/a front schematic view of the same device at the time of starboard turning in a two-same direction mode.

(22) FIG. 21 A plane schematic view/a front schematic view of the same device at the time of larboard turning in a two-independent mode.

(23) FIG. 22 A front view including a propeller of a rudder plate portion of a steering device in connection with a fourth embodiment (case where a rudder plate includes a canted portion).

(24) FIG. 23 A side schematic view of a stein of a ship using a steering device in connection with a fourth embodiment.

(25) FIG. 24 A perspective of the same device.

(26) FIG. 25 A graphic view for comparing experimental, result of a steering force of each of a two-independent mode/a two-same direction mode of a model steering device in connection with one embodiment of the present invention.

MODE FOR CARRYING OUT THE INVENTION

(27) Each embodiment of the present steering device will be illustrated below. FIG. 1 is a side view of a stern of a ship equipped with a steering device according to a first embodiment (interior of a ship is a sectional view), FIG. 2 is a vertical view of the same steering device at the time of steering, FIG. 3 is a front view of the same steering device, and FIG. 4 is a perspective of the same steering device.

(28) A steering device according to a first embodiment comprises a propeller 20 attached to a rear end 11a of a stern tube 11 of a ship hull 10, two rudder plates 30, and a mechanism driving rudder plates 30 via a steering shaft 40. Two rudder plates 30 are arranged on both sides of the propeller 20. A cambered shape 31 is formed inside two rudder plates 30. The Front ends of two rudder plates extend forward of the plane formed by a propeller rotation plane. The length of this protrusion can be extended forward in such a way that it does not interfere with the ship hull 10, the length depends on a wave created by a ship hull shape 10 and an economical vessel speed, and also depends on the straightening water flow between the two rudder plates 30, a use mode such as a forward thrust generated by the camber 31 of the rudder plates 30, and the water viscous resistance. It may be optimized under these constraint conditions. The two rudder plates 30 may be also rudder plates 30 having no camber 31, and in this case aims at a low fluid resistance of the rudder plates 30 and the straightening effect on vortex generation in the vicinity of a stein.

(29) The rudder plates 30 exhibit a reverse L-letter plate shape as shown in a front view 3, and are fixed at the steering shaft 40 which is rotatably supported by the ship bottom portion of the ship hull 10. At the time of steering; with rotation of the steering shaft 40, the rudder plates 30 turn around the propeller as shown in FIG. 2. By turning of the rudder plates 30 around the propeller as shown in FIG. 2 rather than rotation around a shaft on a plate surface. This increases the deflected flow of the propeller slipstream, and turning performance is improved.

(30) The two rudder plates 30 have such a shape that a thrust for impelling the ship hull 10 forward is generated by the effect of the camber 31. By tilting the rudder plates 30 at 10 degree or less relative to a ship center line by making a front thickness greater than a rear thickness, the rudder plates are arranged so as to have a suitable attack angle, they have an optimal rudder plate shape having little resistance on a flow in the vicinity of the stern of the ship hull 10 while increasing a propeller efficiency, and an overall greater forward thrust can be obtained.

(31) Upon rotation of the steering shaft 40 by the driving mechanism, shown in FIG. 1 and FIG. 5, each driving shaft is freely rotated using a bevel gear 120 and an electric servomotor mechanism 130. When the two rudders are turned so as to be closed simultaneously from a direction seen from a ship stein 11 of FIG. 1 toward a center, they can be positioned as shown in FIG. 2 and FIG. 10, and can be used as a brake at the time of an emergency. In addition, the electric servomotor mechanism 130 exerts the same effect in the case of a hydraulic servomotor mechanism, or a mechanism of a combination of an electric servomotor and a hydraulic servomotor.

(32) FIG. 7 shows arrangement of the rudder plates 30 when travelling straight ahead, FIG. 8 shows the turning state of the rudder plates 30 at the time of right turning, FIG. 9 shows the turning state of the rudder plates 30 at the time of left turning, and FIG. 10 shows the turning state of the rudder plates 30 at the time of stopping if the two shafts can be driven independently by the driving mechanism as shown in FIG. 5, turning positions from FIG. 7 to FIG. 10 become possible, it results in a steering device which affords a high stopping force by imparting a rudder angle of 90 degree relative to the ship hull 10 by the propeller slipstream at the time of emergency stopping, while providing the effect that the rudder plates 30 are positioned on both sides of the propeller to impart a high propulsive efficiency without positioning in the propeller slipstream when straight cruising, and freely deflects and straightens a water stream of the propeller 20 in order to turn a ship, and assures good turning performance. FIG. 11 shows an possible position of a rudder plate 230 which has turned around a steering shaft 240 at the time of emergency stopping in the case where the steering shaft is uniaxial, and a possible turning arc 230 of the rudder plate in this case is additionally shown in FIG. 20. In the case of two steering shafts, since the rudder plate turning radius becomes small by each turning, when two steering shafts each have a turning mechanism, the rudder plate 230 can approach a position closer to the propeller as compared with the case of a one steering shaft, a rudder angle can approach vertically relative to a propeller screw shaft, and the braking effect can be maximized.

(33) FIG. 6A and FIG. GB show other version in which the gear driving mechanism of FIG. 5 is a crank mechanism. As shown in FIG. 6A, by rotating the steering shaft 40 by a mechanism of a hydraulic cylinder 100 and a crank mechanism 110, two rudder plates 30 can be freely turned. This is an embodiment in which oil pressure is a power source, and since an oil pressure system is frequently used in a ship it can be utilized for this purpose so the driving device in connection with the present invention can be realized at a smaller cost.

(34) According to the steering device shown in FIG. 6B, the crank mechanisms driving two steering shafts are connected, and two steering shafts are rotated by conjunctive synchronization. A conjunctive synchronous rotation of two steering shafts by crank mechanisms has an advantage that steering becomes easy, and a steering device mechanism may be also simple. In the case of this embodiment, two rudder plates do not cooperatively make a movement so as to almost block the propeller slipstream, and increase in a stopping force in the case of sudden stop cannot be obtained, but by arranging two rudder plates on both sides of the propeller at the time of direct traveling, two effects of capable of turning rudder plates to the slipstream side of the propeller at the time of rotation of a ship while obtaining high propulsive performance, and obtaining high turning performance can be achieved.

(35) FIG. 13 is a front view including a propeller of a rudder plate portion of a steering device in connection with a second embodiment, FIG. 14 shows a side view of the same, and FIG. 15 shows a perspective of the same. The second embodiment is different from the first embodiment in the following points.

(36) The second embodiment is the case where an arc shape is included at a lower portion of the reverse L-letter type rudder plate of the first embodiment, and provides the effect of realizing the effect imparted by the first embodiment by requiring a smaller steering device driving mechanism. The second embodiment will be illustrated below.

(37) In the second embodiment, a steering shaft 40 from which a rudder plate 30 is suspended, is arranged laterally from a center of a propeller 20 at a distance D, and is fixed on a ship bottom 10. Herein, D is a numerical value smaller than a propeller radius R. An upper portion of the rudder plate 30 is constructed into a reverse L-letter type, and the rudder plate 30 suspended from the ship bottom 10 is isolated from the steering shaft, center by R?D+?. ? is a gap between a propeller rotation radius and the rudder plate. A central portion of the rudder plate 30, that is, a portion lower than a horizontal line passing through a propeller center shaft is a ? arc, and is configured to be slightly isolated from, and opposite to the rudder plate which is similarly suspended from an opposite steering shaft. Herein, parameters of R, D and ? are optimally designed in view of various elements such as propeller performance, rudder performance, a ship type and the like.

(38) In order to turn the reverse L-letter type rudder plate 30 around the steering shaft 40 with a horizontal portion of a L-letter type being an arm, the rotational inertia moment becomes great in proportion to a length of an arm to be turned, as compared with the case where the portion is rotated around the steering shaft in a form of inclusion of the steering shaft in a rudder plate surface in the conventional steering device. Then, as a power device driving the steering shaft, a larger shaft than before becomes necessary, and disadvantage arises in respect of a combination with a ship type, and an economic efficiency, in some cases. Even in such a case, if it becomes possible to reduce the inertia moment as much as possible so that a smaller steering device driving power source may be used, a more preferable steering device excellent in energy saving and an operational efficiency can be provided. Herein, since the inertia moment I of a mass point in at a distance r from a rotation center satisfies:
I=mr.sup.2equation (1),
concerning a portion lower than a horizontal axis line of a propeller central line of a reverse L-letter type rudder plate portion of the steering device in connection with the first embodiment shown in FIG. 3, when a part of the rudder plate is a ? arc shape as in FIG. 13 showing this embodiment, the distance from the steering shaft rotation center is reduced and, therefore, the inertia moment is reduced in proportion to the square thereof.

(39) Since a necessary driving force is in proportion to the inertia moment, and a driving energy is also in proportion to the inertia moment, in the steering device in accordance with the second embodiment shown in FIG. 13, it results in that a smaller power mechanism is enough, and energy saving is realized. Energy saving is one object of the present invention, and this satisfies the aims of the invention.

(40) In the second embodiment, a camber 31 is formed on a surface opposite to two rudder plates, that is, inside the rudder plates (FIG. 15). The camber aims at improving propulsive performance by a thrust generated by the wing shape. Although the camber 31 is also formed in the first embodiment, in the rudder plate of the steering device in accordance with the second embodiment, by making a rudder plate lower portion of a reverse L-letter type a ? arc shape, the rudder plate becomes closer to the propeller, and since a water flow velocity in the vicinity of the camber is increased, the secondary effect that a thrust becomes greater, as it would with a fixed nozzle and an improvement in propulsive performance is greater can be expected.

(41) Then, a third embodiment of the steering device will be illustrated. FIG. 16 is a side view of a stern of a ship equipped with the steering device in accordance with the third embodiment (the interior of a ship is shown by a sectional view), FIG. 17 is a front view of the same steering device, and FIG. 18 is a schematic view of a perspective of a rudder portion of the same steering device.

(42) Also in the third embodiment, likewise the first embodiment, the steering shafts 40 are each arranged at a distance D smaller than a radius R of a propeller 20 from a screw shaft center 5, a rudder plate surface of the rudder plate 30 facing the propeller 20 is vertically arranged at a positive minimum distance a from an outer edge of the propeller 20 having a radius R on a rotation plane of the propeller 20, and the rudder plate surface is characterized in that a turning radius is defined by a distance in which a radius r is represented by the following equation:
r=R?D+?(>0;R>D,?>0)equation (1)
from aside of the propeller 20 to a slipstream side of the propeller 20 by rotation of two steering shafts 40, the rudder plate surface is turned at a radius r from aside of the propeller to be downstream of the propeller by rotation of the steering shaft, the rudder is placed on both sides of the propeller, two rudders each have the steering shaft, the steering shaft is attached off-center inside the rudder plate, and each steering shaft rotates independently. This configuration defines that a rudder face of the rudder plate forms a face isolated from the steering shaft, and a rotation axis by the steering shaft is not present in line with the rudder face, and makes the meaning of turning clear and, at the same time, defines that the rudder plate is positioned laterally isolated at a distance a from the propeller rotation surface outer edge. The steering shaft has a more compact configuration that it is arranged on an inner side than a propeller radius, and makes clear a difference between rudder plate arrangement of the conventional steering device of two rudders (see FIG. 2 of Patent Literature 1). That is, this is a preferable embodiment in a point that a turning radius is reduced, a turning moment of the rudder plate can be reduced in proportion to the square of a turning radius r, and it becomes possible to miniaturize a driving mechanism and a power mechanism, and consequently, this leads to energy saving which is an object of the present invention.

(43) In this way, concerning definition between parameters, even when a turning radius r is more reduced, if a chord length of one rudder plate is a sufficient length for covering a propeller radius R, it is preferable that the turning radius r is around a half of the propeller radius R, a size of one rudder plate is defined from a relationship with a turning radius of the rudder plate in view of a chord length of the rudder plate covering the propeller radius R, and as a result, harmonization with reduction in the turning moment of the propeller is obtained, being preferable.

(44) The size of two rudder plates which are arranged on both sides of the propeller is such that one rudder plate of twin rudder configuration can be reduced compared to the rudder area which imparts the same performance of a single rudder. When a height of the rudder is the same, that is, conceptually, a rudder width in a vessel axis direction, a chord length in the case of a wing can be smaller than that of single rudder, and in this case, an aspect ratio of a wing becomes greater. Since the wing having a greater aspect ratio suppresses reduction in a lift force and increase in a fluid resistance due to wraparound from a wing end, a small rudder satisfies a required specification, a width of the rudder is reduced, a rudder face which merely undergoes a small fluid viscous resistance is formed, and a high propulsive efficiency is obtained at the time of cruising, as compared with single rudder which imparts the same rudder performance.

(45) Upon rotation of a steering shaft 40 by a driving/power mechanism 90, the steering shaft 40 is directly rotated by a rotary vane-type hydraulic motor 140 (see FIG. 18). This results in that two rudder plates 30 freely turn around the propeller 20. That is, as shown in a sectional view of a driving mechanism shown in FIG. 19, when a hydraulic oil is supplied into hydraulic chambers 132, 133 which are partitioned with a vane 134 of a vane-type hydraulic motor 140 by a power mechanism, the differential force works on the vane 134 due to a pressure difference between left and right hydraulic chambers 132, 133 partitioned by the vane, and a rotor 130 is differentially operated. It results in that the steering shaft 40 directly connected to the rotor 130 freely turns the rudder plate 30 connected to the steering shaft 40. In hydraulic chambers 132, 133, a part of a semi-cylindrical space is partitioned with the vane 134, and since the vane partitioning this can be rotated in a range of approximately 180?, a range exceeding 90?, for example, a wide rudder angle range can be supported.

(46) According to the third embodiment as stated above, the power mechanism of the driving mechanism is a vane-type hydraulic motor mechanism 140, this is directly bound to the steering shaft 40 as a dedicated mechanism for each steering shaft 40, and when rudder plates 30 are turned towards a center from a direction seen from a stern 11 of FIG. 16 so as to be closed simultaneously, two rudders can be also emergency-braked at the time of emergency as in FIG. 10, rudder plates can be positioned at a slipstream at more than 90? up to maximally 105?, and a breaking power can be maximized. In addition, the driving mechanism 90 may be any mechanism as far as it is a separate power mechanism and driving mechanism 90 which can independently drive two steering shafts 40 freely, and may directly drive the steering shafts 40 using an electric servomotor mechanism as a power source, or may drive the steering shafts 40 via a speed reduction mechanism, and if necessary, vertical/horizontal plane conversion of a rotating plane may be performed depending on arrangement configuration of each instrument.

(47) When the driving mechanism 90 is driven, it is preferable that the steering shaft can be steered by switching into at least two steering modes of a two-independent mode and a two-same direction mode. Hereinafter, according to a steering mode, motion of the rudder plate in the third embodiment will be illustrated using schematic views of a plane view/a front view of FIG. 7, FIG. 8, FIG. 20 and FIG. 21. A mechanism and a steering method appropriate to steering property of the steering mode are as follows.

(48) At the time of veering steering in the two-same direction mode, basically, rudders are symmetrically steered around the propeller, and in the case where a ship is faced in the right direction, when the rudder on a right side is moved counterclockwise in front of the propeller, and the rudder on a left side is turned, similarly counterclockwise at behind of the propeller, a rightward deflected slipstream (flow F shown with two-dot chain line of FIG. 20) is generated from a counter current (flow FR shown with two-dot chain line FIG. 20), and the effect of obtaining the desired steering property is exerted.

(49) In the two-independent mode, left and right rudders are independently steered. Steering in this independent mode is determined by a person, for example, a chief navigator, or a master of a ship. For example, since when a ship speed is reduced, a current speed and a discharge flow rate generated by the propeller are reduced, and become insufficient for steering, the rudder is steered in the two-independent mode being a steering mode corresponding to ship handling at the time of a low speed. On the other hand, for example, at a cruising speed in a range greater than a predetermined ship speed, performance is maintained by steering suitable for a cruising speed according to the two-same direction mode in which left and right rudders take a rudder angle opposite to each other. Even in one steerage, this is a steering device which enables different steering by either steering mode of the two-independent mode or the two-same direction mode.

(50) FIG. 21 shows the turning state of rudder plates 32, 33 at the time of steering in a starboard direction at the time of undocking, in which a side thrust flow is generated by the two-independent mode of the invention in connection with the third embodiment. In the two-independent mode, a rudder plate 33 on a port side opposite to a starboard veering direction is turned from aside of the propeller 20 to a downstream of the propeller by rotation of the steering shafts 42 at a first stage, and at the same time, the other rudder plate 32 on a starboard side is turned from aside of the propeller 20 to the downstream of the propeller by rotation of the steering shaft 41, the rudder plate is turning-driven so as to take a rudder angle of 90?, and jointly as a next stage, the propeller rotational speed is increased than that at the time of straight travelling.

(51) Even in the two-independent mode, at a low ship speed region, the rotation number of the propeller is suppressed low in normal steering, and when a propeller water stream is at a low speed, since only a weak deflected flow is generated, a sufficient turning power is not obtained. Then, in the case of starboard veering ship handling generating a thrust flow in the two-independent mode, the rudder plate 33 on a port side opposite to a veering direction is turned, for example, by 45? from aside of the propeller to the downstream of the propeller by rotation of the rudder shaft 42 at a first stage and, at the same time or as a second stage, when the other rudder plate 32 on a starboard side is turned from aside of the propeller to the downstream of the propeller by rotation of the rudder shaft 41 to take a large rudder angle of 90? to 105?, a flow is concentrated from a port to a propeller central side by the rudder plate 33 which has turned by 45?, a pressure at a central portion becomes high, on the other hand, a propeller water stream which is discharged backward from a starboard right semicircle region is blocked, by the rudder plate 32 taking a rudder angle of 90?, a flow must be toward a lateral, but is pushed by a pressure near a central portion of the propeller 20, and a flow to a lateral of a starboard in a veering direction (right) is generated. Then, ship handling similar to a thruster becomes possible by discharge of a lateral flow to the just beside a veering direction. At the time of porting the helm, left and right are inverted.

(52) Meanwhile, since almost all of a propeller water stream flows laterally, even when the propeller rotational speed is increased, a forward vessel speed is not much increased. On the other hand, when the propeller rotational speed is increased, since a water stream flowing laterally becomes fast, and a flow rate is also increased, a ship control force in the transverse direction is dramatically enhanced. That is, when veering steering in a two-independent mode is performed, as a third stage, the effect of dramatically enhancing the steering ability by increasing the rotation number of the propeller 20 is obtained. In this case, even when the propeller rotational speed is increased, a speed of a ship is not increased, and the rudder works as a thruster.

(53) At the time of veering in the two-same direction mode, the rudder plate on a side opposite to a veering direction is turned from aside of the propeller to the downstream of the propeller by rotation of the rudder shaft, and selectively, the other rudder plate is turned from aside of the propeller to the propeller upstream side by rotation of the other rudder shaft. FIG. 20 shows the turning state of the rudder plate 30 at the time of the two-same direction mode: starboard turning, and motion becomes left and right inversion to this at the time of porting the helm. In this case, as shown in FIG. 20, there is an advantage that, when both of the two rudder plates 30 face each other across the propeller 20, and are turned around the propeller 20 in the same direction, two propellers take the same motion, becoming simple, and ship handling becomes easy. When a ship is faced in the right direction, the rudder on a right side is moved counterclockwise in front of the propeller, and the rudder on a left side is turned counterclockwise similarly at behind of the propeller, thereby, a deflected water stream in a rudder angle direction can be generated, and the ship is turned in a rudder angle direction by the counteraction.

(54) At the time of veering in the two-same direction mode, the rudder plate on a side opposite to a veering direction, for example, in the case of starboard helm, the port side rudder is turned from aside of the propeller to the downstream of the propeller by rotating the rudder shaft of a port side, and in the case of portside helm, the starboard side rudder is turned from aside of the propeller to the up steam of the propeller by rotating the rudder shaft of a starboard side, deflects a propeller slipstream along a large rudder angle, provides high turning performance by a rudder force due to a counterforce. In this case, the rudder force contribute to steering performance by adding the turning moment to the ship because the rudder is positioned sufficiently isolated from a ship center line. Selectively, the other rudder plate is turned upstream of the propeller from aside of the propeller by rotating the rudder shaft, the rudder plate is arranged at a position sufficiently isolated from the ship center line as compared with a conventional rudder, and turning of one rudder plate in front of the propeller imparts the maneuverability by a counterforce received from a water stream along the vessel, and another rudder plate turning behind the propeller changes a direction of a water stream of the propeller slipstream to contribute the ship turning ability. Since the rudder is located at a position sufficiently isolated from the ship center line, the present steering device provides the rudder force which contribute to steering performance by adding the turning moment to the ship.

(55) At the ahead condition of the ship with the two-same direction rudder plate mode, both rudder plates are arranged at aside of the propeller. Since the resistance component, which is originated from a rudder behind a propeller, can be eliminated, the propulsive efficiency of a ship is increased, and higher propulsive performance can be provided compared with ship with a rudder located in a behind of a propeller. FIG. 7 shows the steering mode of the rudder in the case of ahead going. Regardless of a steering mode, at the ahead condition of the ship, the rudder plate is arranged like the rudder plate 30 shown in FIG. 7. An upward bald arrow shows a steering direction of a ship, and an upward fine arrow of a one-dot chain line schematically indicates flow of water. That is, in the case of straight course keeping ship handling, the two rudder plates 30 are retained laterally on both sides of the propeller 20. At the ahead condition of a ship, two rudders are maintained on both sides of the propeller parallel with a ship axis. Since a propeller water stream is not obstructed by the rudders, a rudder drag receiving from the flow is reduced as compared with existing two rudders arrangement behind the propeller, and higher propulsive performance can be provided. In this case, since the rudder is not placed in a high speed rotation flow of the propeller slipstream, a noise emitted from the propeller and rudder can be eliminated, and the additional effect of enabling calm cruising is also obtained, and this effect is suitable, particularly, for patrol boats, and military ships.

(56) In stop maneuver, when the propeller is stopped, at a next stage, a rudder angle exceeding 70 degree is taken in the two-independent mode, and the two rudder plates cooperate to almost block the propeller slipstream. Selectively; thereafter, the propeller may be reversed. Herein, taking a rudder angle exceeding 70 degree is preferably to take a rudder angle of 90?, or a rudder angle of up to 105 degree exceeding this, In rudder plate arrangement shown in FIG. 10, at the time of emergency stop, two rudder plates almost block the propeller slipstream near the back of it to maximize a stopping power. An object of this steering is to reset propeller driving, and thereafter, shorten the time during which the propeller rotates by the inertia to enable the propeller to reversely rotate early, in the case where sudden stop is necessary. When it is necessary to reversely rotate the propeller like this, reverse rotation of the propeller can be stopped to accelerate reverse rotation of the propeller. In addition, when both rudder plates are turned to an upstream side 45? forward as a speed reducing stage at the time of initial motion of stop maneuver, both rudder plates receive a water stream at a vessel speed, and a speed of a ship can be reduced by the counterforce thereof.

(57) When the steering device 1 in connection with the third embodiment shown in FIG. 18 is used, since two shafts each are independently driven by a hydraulic motor mechanism 140, and free turning from FIG. 20 to FIG. 21 becomes possible, it results in that there is provided the steering device 1 that, at the time of straight cruising, rudder plates 30 are positioned on both sides of the propeller 20 without positioning at the propeller slipstream, the effect of imparting a high propulsive efficiency is provided, and at the same time, at the time of emergency stopping, a rudder angle range exceeds 70 degree, the two rudder plates cooperate to turn around the propeller so as to almost block the propeller slipstream, a rudder angle, for example, of 90 degree to a ship hull 10 is imparted at the propeller slipstream to obtain a high stopping power, a water stream of the propeller 20 is freely deflected and straightened for turning a ship to maintain turning performance.

(58) A fourth embodiment of the steering device is the case where a lower portion of the reverse L-letter type rudder plate of the third embodiment is folded to a propeller side, and a L-letter corner is also folded, and effect of realizing the effect imparted by the first embodiment by a smaller steering device driving mechanism is provided. This will be illustrated below.

(59) FIG. 22 is a front view including a propeller of a rudder plate portion of the steering device in connection with the fourth embodiment, FIG. 23 is a side view of the same, and FIG. 24 shows a perspective of the same. The fourth embodiment is different from the third embodiment in the following points.

(60) When a reverse L-letter type rudder plate 30 is attached inside off-center from the rudder shaft 40 with a horizontal portion of a L-letter type being an arm, as compared with the case of an embodiment in which it is in center of the rudder shaft in a rudder plate plane in the conventional steering device, the rotation inertia moment becomes in proportion to the square of a turning radius, a great power mechanism for driving the rudder shaft is required, and disadvantage can occur from a view point of compatibility with a ship shape, and the economy. If the inertia moment can be reduced as much as possible so that a small steering device driving power source may be used, a preferable steering device excellent in energy saving can be provided. When a lower portion of the reverse L-letter type rudder plate of the steering device in connection with the first embodiment shown in FIG. 4 is folded to a propeller side, and a mass point distance from a rudder shaft rotation center is reduced by chamfering of a L-letter corner, the inertia moment is reduced, a driving force may be a smaller motive power mechanism, and energy saving which is an object of the present invention is realized. When the rudder plate has a plate-like form similar to a reverse L-letter type like this, this is most simple configuration among a form of the rudder plate in a point of integral formation, and is most advantageous in regards of the strength and the economy. Integral formation may be by any of processing such as welding press processing, forging processing and the like, and assembling such as bolting, riveting and the like. In this case, folding has the effect of increasing rigidity, decreasing a plate thickness, and further reducing the inertia moment.

(61) FIG. 25 shows a graphic view of experimental result of the steering effort of the present invention model implementation product device in the case where steering at the time of the two-independent mode of a model steering device in connection with the fourth embodiment is implemented. Based on the following specifications, a relationship between a vessel speed and a rudder force was obtained by an experimental model.

(62) <Specifications Around Rudder of Model Steering Device, Unit mm>

(63) Propeller radium: 2400, rudder height: 3050, chord length: 1500 at a height of 1950 or more from lower end, 1150 at a lowest end, a chord length linearly decreasing towards a lower end, maximum plate thickness: 150, steering shaft central position: 600 from ship axis center, steering shaft diameter: 340

(64) <Result>

(65) FIG. 25 shows a relative rudder force of a model rudder in a longitudinal axis relative to a model ship relative vessel speed in a transverse axis. It is seen that, in the two-same direction mode, the rudder force is increased by about 20% as compared with the conventional single rudder, and in the two-independent mode, the rudder force is remarkably improved by 50%, particularly, in a low speed region. Effectiveness of the present invention which changes a rudder steering method at the time of the two-same direction mode and at the time of the two-independent mode, and is provided with a driving mechanism of the rudder supporting this change is confirmed. When steering in the two-same direction mode is also implemented in a low speed region, the steering effort is inferior by 20% to the conventional model, and superiority of a steering method of particularly setting up a steering method in the two-independent mode using the device in connection with the present invention can be confirmed.

(66) As described above, embodiments in connection with the present invention have been illustrated, but the present invention is not limited to such embodiments, and can be implemented by various modifications in such a range not departing from the gist of the present invention.

INDUSTRIAL APPLICABILITY

(67) The present invention can be applied to a steering portion of surface ships, particularly, big ships, domestic vessels and patrol boats requiring quick ship handling even at a low speed.

DESCRIPTION OF REFERENCE NUMBERS

(68) 1 Steering device 2 Propulsive device 5 Screw shaft 10 Ship hull 11 Stern tube 12 Stern 20 Propeller 30 Rudder plate 31 Camber 40 Rudder shaft 90 Driving/Power mechanism 100 Hydraulic cylinder 110 Crank mechanism 120 Bevel gear 130 Electric servomotor mechanism or hydraulic motor mechanism 140 Rotary vane-type hydraulic motor mechanism