JP6422020B2 - Twin skeg ship - Google Patents

Description

  The present invention relates to a twin skeg ship in which a pair of left and right skegs provided on the bottom of a stern are respectively provided with a propeller shaft.

  There is known a twin-skeg ship in which a pair of left and right skegs are provided on the stern bottom to form a tunnel-shaped bottom bottom recess between the left and right skegs, and a propeller shaft is provided on each of the pair of left and right skegs.

In such a twin-skeg ship, various proposals have been made to improve the propulsion performance.
For example, Patent Document 1 discloses a configuration in which fins extending in the left-right direction are provided between left and right skegs. In this configuration, between the left and right skegs, the flow through the part on the tunnel surrounded by the skegs on both sides hits the fins, generating lift, and propulsion performance using a part of the lift for forward force To improve.

  Patent Document 2 discloses a configuration in which fins are provided on the inner wall surfaces of a pair of left and right skegs. This fin is provided so as to have an angle of attack with respect to the vertical vortex generated between the left and right skegs. According to such a configuration, when the vertical vortex hits the fin, a lift having a forward direction component is generated, and thus the propulsion performance is improved by the forward direction component.

  Patent Document 3 discloses a configuration in which a cylindrical duct having a larger diameter on the bow side than on the stern side is provided in front of the propeller. According to this configuration, the flow to the propeller is rectified by the cylindrical duct and the propulsion performance is improved.

Japanese Patent No. 5426699 JP 2012-006556 A JP 2008-143488 A

As described above, various proposals have been made so far to improve the propulsion performance, but the flow below the bottom of the ship varies depending on the shape of the stern bottom of the hull and the like. As a result, for example, even if the configurations disclosed in Patent Documents 1 to 3 are applied, the propulsion performance is not always improved, but may be lowered. Therefore, further improvement of propulsion performance is always required.
The present invention has been made in view of the above circumstances, and an object thereof is to provide a twin-skeg ship capable of improving the propulsion performance.

The present invention employs the following means in order to solve the above problems.
According to the first aspect of the present invention, the twin skeg ship is provided on the bottom of the stern and has a pair of left and right skegs each having a cylindrical boshing protruding rearward, and the rear of each of the pair of left and right skegs. A propeller whose upper rotation direction is an inward rotation rotating from the outer side in the ship width direction toward the inner side in the ship width direction, with respect to the pair of left and right skegs, A twin skeg ship with a slow flow in the inner direction, provided only on the inner side in the ship width direction with respect to the pair of left and right skegs, out of the outer peripheral surface of the boshing, protruding from the outer peripheral surface on the inner side in the ship width direction, It extends radially from the center of rotation of the propeller, and provides an outward flow in front of the propeller, on the inner side in the ship width direction of the skeg, opposite to the inner direction that is the rotation direction of the propeller. It comprises a fin, a.

  As described above, the fin is provided only on the inner side in the ship width direction with respect to the skeg in front of the propeller, so that the fin can increase or weaken the flow in the width direction on the inner side of the propeller in front of the propeller. Thereby, the wake gain in the left and right propellers can be increased.

According to a second aspect of the invention, Tsuinsukegu ship, in the Ichitai like, in front of the propeller, is provided astride said ship width direction inner side of the skeg to said ship width direction outer bow A cylindrical duct whose outer diameter gradually decreases from the side toward the stern side may be further provided.
By comprising in this way, the flow which goes to a propeller is accelerated by passing through the inside of a duct. Accordingly, thrust in the forward direction is generated in the duct, so that propulsion performance can be improved.

According to a third aspect of the invention, Tsuinsukegu ship, in the Ichitai like, a front of the propeller, is provided only in the ship width direction inwardly relative to the skeg, toward the fore aft side A semi-cylindrical duct whose outer diameter gradually decreases may be further provided.
By configuring in this way, the flow toward the propeller is increased by passing through the duct, and thrust in the forward direction is generated, so that the propulsion performance can be improved. And according to this structure, a duct does not exist in the ship width direction outer side of skeg. Therefore, the specific resistance by the duct can be reduced as compared with the case where the duct is exposed to the outside of the skeg in the ship width direction. As a result, the thrust by the duct increases, and the propulsion performance can be improved more effectively.

According to a fourth aspect of the present invention, in the twin- skeg ship, in the second or third aspect, the duct may be supported by an end portion or an intermediate portion on the outer peripheral side of the fin.

  According to the twin-skeg ship according to the present invention, the propulsion performance can be improved by increasing the wake gain of the propeller by accelerating or decelerating the flow in the ship width direction with respect to the skeg by the fins. .

It is the left view which looked at the stern part starboard side of the twin skeg ship which concerns on 1st embodiment of this invention from the port side. It is the rear view which looked at the stern part of the said twin skeg ship from back, and is a figure which shows the cross section D1-D1, the cross section D2-D2, the cross section D3-D3, and the cross section D4-D4 of FIG. It is a figure which shows the result of having analyzed in detail the flow field in front of the propeller on the port side of a certain twin skeg ship where a pair of left and right propellers rotate inward as viewed from the stern side. It is the rear view which looked at the stern part of the twin skeg ship in the modification of 1st Embodiment of this invention from back. It is the left view which looked at the stern part starboard side of the twin skeg ship which concerns on 2nd embodiment of this invention from the port side. It is the rear view which looked at the stern part of the twin skeg ship shown in FIG. 5 from back. It is the left view which looked at the stern part starboard side of the twin skeg ship in the modification of 2nd embodiment of this invention from the port side. It is the rear view which looked at the stern part of the twin skeg ship shown in FIG. 7 from back. It is the rear view which looked at the stern part of the twin skeg ship which concerns on 3rd embodiment of this invention from back. It is the rear view which looked at the stern part of the twin skeg ship in the modification of 3rd embodiment of this invention from back.

Hereinafter, a twin-skeg ship according to an embodiment of the present invention will be described with reference to the drawings.
(First embodiment)
FIG. 1 is a left side view of the stern portion starboard side of the twin-skeg ship according to the first embodiment of the present invention as seen from the port side. FIG. 2 is a rear view of the stern portion of the twin-skeg ship as viewed from the rear.
As shown in FIGS. 1 and 2, the twin skeg ship 1 in this embodiment includes a skeg 2 and a propeller 10.

  The stern hull 3 that is the stern 1b of the hull of the twin skeg ship 1 has an inclined surface 4s that gradually inclines upward as the stern 4 moves from the bow (not shown) side to the stern 1b side. Further, the ship bottom 4 of the stern hull 3 is formed such that the width dimension in the ship width direction gradually decreases from the bow (not shown) side toward the stern 1b side.

The skeg 2 is provided on the inclined surface 4s of the ship bottom 4 in a pair of left and right symmetrically across the inner side C in the ship width direction with an interval in the ship width direction. Each of the pair of left and right skegs 2 extends downward from the inclined surface 4s of the bottom 4 of the stern hull 3, and is provided to protrude rearward in the horizontal direction from the inclined surface 4s.
A pair of left and right skegs 2 and an inclined surface 4 s of the bottom 4 are formed below the stern hull 3 to form a bottom recess 5 surrounded by the pair of left and right skegs 2 and the inclined surface 4 s of the bottom 4. The ship bottom recess 5 is formed so that its cross-sectional area gradually decreases toward the stern 1b.

  Further, a cylindrical boshing 6 protruding rearward is provided at the rear end of each skeg 2.

The propeller 10 is provided at each rear end of the pair of left and right skegs 2. Each propeller 10 is connected to a main engine (not shown) provided in the stern hull 3 via a propeller shaft 12. One end of the propeller shaft 12 is connected to the main engine (not shown) in the stern hull 3, and the other end 12 b extends toward the stern 1 b, and protrudes from the stern hull 3 to the rear of the skeg 2 through the bossing 6. . The propeller 10 is integrally attached to the other end 12 b of the propeller shaft 12 protruding rearward from the skeg 2.
Such a propeller 10 rotates in a predetermined direction when the propeller shaft 12 is driven to rotate around its central axis by a main machine (not shown) provided in the stern hull 3, and exhibits the propulsive force of the twin skeg ship 1. To do.

  In this embodiment, the rotation direction of the propeller 10 provided at the rear end of each of the pair of left and right skegs 2 is an inner rotation R2, R1 that rotates from the outer side in the ship width direction toward the inner side C in the ship width direction at the upper part of the propeller 10. And

A fin 20 is provided in front of the pair of left and right propellers 10. A plurality of fins 20 (for example, 3 in this embodiment) are provided so as to protrude radially from the rotation center of the propeller 10 on the outer peripheral surface of the boshing 6 provided to protrude rearward from the rear end portion of the skeg 2. Sheet).
In this embodiment, the fin 20 is provided on the inner side C side in the ship width direction with respect to the pair of left and right skegs 2. That is, the fins 20 are provided in the bossing 6 so as to protrude from the outer circumferential surface 6 s on the inner side C side in the ship width direction into the space in the ship bottom recess 5.
These fins 20 impart outward flows F1 and F2 in the direction opposite to the rotation direction of the propeller 10 positioned behind the fins 20, that is, in the upper part of the propeller 10, from the inner side C side to the outer side in the ship width direction. .

By the way, in this twin skeg ship 1, due to the shape of the bottom 4 of the stern hull 3, the flow outside the pair of left and right skegs 2 (outside in the width direction) in the bottom bottom recess 5 formed between the pair of left and right skegs 2. The flow rate is slower than
FIG. 3 is a diagram showing the result of detailed analysis of the flow field immediately before the port-side propeller 10 in the port-side skeg 2 of the twin-skeg ship 1 in which the pair of left and right propellers 10 goes inwardly. In FIG. 3, the direction of the arrow indicates the direction of the flow in the plane, the length of the arrow indicates the size of the flow, and the circle indicates the turning radius of the propeller 10.
As shown in FIG. 3, the flow in the direction opposite to the rotation direction R2 of the propeller 10 in the ship width direction inner side C, that is, in the range of θ = 0 degrees to 90 degrees to 180 degrees with respect to the port side skeg 2 An upward flow Fs is generated.

The fins 20 provided on the inner side C side in the ship width direction with respect to the skeg 2 are provided in a region where an upward flow Fs in the direction opposite to the rotation direction R2 of the propeller 10 is generated.
Thereby, the fin 20 on the port side is provided with a flow F2 in the outward direction in the upper part of the propeller 10, which is the direction opposite to the rotation direction of the propeller 10 located behind the propeller 10. The generated upward flow Fs that is in the direction opposite to the rotation direction R2 of the propeller 10 is increased and strengthened. Further, the starboard-side fin 20 is generated in front of the starboard-side propeller 10 by applying an outward flow F1 in the upper part of the propeller 10, which is opposite to the rotation direction of the propeller 10 located behind the starboard-side fin 20. The upward flow Fs, which is the flow in the direction opposite to the rotation direction R1 of the propeller 10, is strengthened.

  By increasing the upward flow Fs in the direction opposite to the rotation direction R1, R2 of the propeller 10 generated in front of the left and right propellers 10 by the fins 20 described above, the wake gain is increased in the left and right propellers 10.

  Therefore, according to the twin skeg ship of the first embodiment described above, the fins 20 extending radially only on the inner side C in the ship width direction with respect to the skeg 2 are provided in front of the pair of left and right propellers 10. By these fins 20, the flow on the inner side C side in the ship width direction can be strengthened in the skeg 2 in front of the propeller 10. Accordingly, the wake gain in the left and right propellers 10 can be increased, so that the flow can be efficiently collected and the propulsion performance can be improved.

  In particular, in the twin skeg ship 1, the flow Fs on the inner side C in the ship width direction is slower than the flow on the outer side in the ship width with respect to the skeg 2. In the twin skeg ship 1 having such a configuration, the specific resistance of the fin 20 can be reduced, and the slow flow Fs in the ship width direction inner side C of the skeg 2 is accelerated by the fin 20 in front of the propeller 10. The wake gain of the propeller 10 can be effectively increased and the propulsion performance can be improved.

  Furthermore, by providing the fin 20 in a region where the upward flow Fs generated on the inner side C side of the skeg 2 is strengthened, the wake gain of the propeller 10 can be effectively increased and the propulsion performance can be improved.

  Further, the rotation direction of the propeller 10 is an inward rotation that rotates from the outer side in the ship width direction toward the inner side C in the ship width direction at the upper part of the propeller 10. According to such a configuration, the upward flow Fs generated by the fins 20 on the inner side C side of the skeg 2 in front of the propeller 10 is opposite to the rotation direction of the propeller 10. Therefore, in the left and right propellers 10 rotating inward, the wake gain can be effectively increased and the propulsion performance can be improved.

(Modification of the first embodiment)
FIG. 4 is a rear view of the stern portion of the twin-skeg ship in the modification of the first embodiment of the present invention as seen from the rear.
In the first embodiment, the left and right propellers 10 rotate in the inward direction at the upper part of the propeller 10, but the present invention is not limited to this. As shown in FIG. 4, even in the configuration in which the left and right propellers 10 rotate outward in the upper part of the propeller 10, the fins 20 are inward in the ship width direction with respect to the pair of left and right skegs 2 as in the above embodiment. You may provide radially on the C side.

  According to such a configuration, since the fin 20 can weaken the flow in the same direction as the rotation direction of the outer propeller 10, the wake gain can be increased and the propulsion performance can be improved.

(Second embodiment)
Next, a second embodiment of the twin-skeg ship according to the present invention will be described. In the second embodiment described below, the only difference is that the duct 30 is provided in addition to the first embodiment. Therefore, the same parts as those in the first embodiment are denoted by the same reference numerals, and redundant description is omitted. .
FIG. 5 is a left side view of the stern portion starboard side of the twin-skeg ship according to the second embodiment of the present invention as seen from the port side. FIG. 6 is a rear view of the stern portion of the twin-skeg ship shown in FIG. 5 as viewed from the rear.
As shown in FIGS. 5 and 6, the twin skeg ship 1 in this embodiment includes a pair of left and right skegs 2 and a propeller 10 as in the first embodiment.
The rotation direction of the propeller 10 provided at the rear end of each of the pair of left and right skegs 2 is the inner rotations R2 and R1 that rotate from the outer side in the ship width direction toward the inner side C in the ship width in the upper part of the propeller 10. Yes.

A fin 20 is provided in front of the pair of left and right propellers 10. The fins 20 are provided radially so as to protrude from the outer circumferential surface 6 s on the inner side C side in the ship width direction in the bossing 6 into the space in the ship bottom recess 5.
These fins 20 impart outward flows F1 and F2 in the direction opposite to the rotation direction of the propeller 10 positioned behind the fins 20, that is, in the upper part of the propeller 10, from the inner side C side to the outer side in the ship width direction. .

Further, in this embodiment, a cylindrical duct 30 is provided in front of the propeller 10. The duct 30 has a circular cylindrical shape when viewed from the stern 1b side, and is arranged concentrically with the bossing 6 as a center.
The duct 30 is supported by being fixed to the end portions on the outer peripheral side of the plurality of fins 20 extending radially from the boshing 6. That is, the duct 30 is fixed to the bossing 6 with the plurality of fins 20 as support members.
The duct 30 is formed in a tapered shape so that its outer diameter gradually decreases from the bow side toward the stern 1b side. Further, the duct 30 has the same length in the ship length direction in the circumferential direction.

According to such a configuration, the upward flow Fs in the direction opposite to the rotation directions R1 and R2 of the propeller 10 is generated in front of the propeller 10 by the fins 20 provided on the inner side C in the ship width direction with respect to the skeg 2. Is increased, the wake gain is increased in the left and right propellers 10.
Further, since the outer diameter of the duct 30 gradually decreases toward the propeller 10 on the stern 1b side, the flow velocity in the duct 30 increases on the stern 1b side. Accordingly, forward thrust is generated in the duct 30.

  Therefore, according to the twin skeg ship of the second embodiment described above, the width of the ship in the skeg 2 in front of the propeller 10 by the fins 20 provided in front of each of the pair of left and right propellers 10 as in the first embodiment. The flow on the direction inner side C can be strengthened. Accordingly, the wake gain in the left and right propellers 10 can be increased, and the propulsion performance can be improved by efficiently collecting the flow.

  Further, the twin skeg ship 1 in this embodiment has an outer diameter from the bow side toward the stern 1b side so as to straddle the ship width direction inner side C side and the ship width direction outer side of the skeg 2 in front of the propeller 10. Is provided with a cylindrical duct 30 that gradually decreases. By passing through the duct 30, the flow toward the propeller 10 is increased. As a result, a thrust in the forward direction is generated in the duct 30, so that the propulsion performance can be improved.

(Modification of the second embodiment)
FIG. 7 is a left side view of the stern portion starboard side of the twin-skeg ship according to the modification of the second embodiment of the present invention as seen from the port side. FIG. 8 is a rear view of the stern portion of the twin-skeg ship shown in FIG. 7 as viewed from the rear.
In the second embodiment, the duct 30 is fixed to the end portions on the outer peripheral side of the plurality of fins 20 so that the duct 30 has the same diameter as the outer peripheral side of the plurality of fins 20. Absent.
As shown in FIGS. 7 and 8, the duct 30 has a diameter smaller than the diameter on the outer peripheral side of the plurality of fins 20, and the duct 30 is fixed at an intermediate portion of the plurality of fins 20. Good.

  In such a modification of the second embodiment, the propulsion performance can be improved as in the second embodiment.

(Third embodiment)
Next, a third embodiment of the twin-skeg ship according to the present invention will be described. In the third embodiment described below, since only the configuration of the duct 40 is different from that of the second embodiment, the same parts as those in the second embodiment are denoted by the same reference numerals, and redundant description is omitted. .
FIG. 9 is a rear view of the stern portion of the twin-skeg ship according to the third embodiment of the present invention as seen from the rear.
As shown in FIG. 9, the twin skeg ship 1 in this embodiment includes a pair of left and right skegs 2 and a propeller 10 as in the first and second embodiments.
The rotation direction of the propeller 10 provided at the rear end of each of the pair of left and right skegs 2 is the inner rotations R2 and R1 that rotate from the outer side in the ship width direction toward the inner side C in the ship width in the upper part of the propeller 10. Yes.

A fin 20 is provided in front of the pair of left and right propellers 10. The fins 20 are provided radially so as to protrude from the outer circumferential surface 6 s on the inner side C side in the ship width direction in the bossing 6 into the space in the ship bottom recess 5.
These fins 20 impart outward flows F1 and F2 in the direction opposite to the rotation direction of the propeller 10 positioned behind the fins 20, that is, in the upper part of the propeller 10, from the inner side C side to the outer side in the ship width direction. .

  Furthermore, in this embodiment, a semi-cylindrical duct 40 is provided in front of the propeller 10. The duct 40 has a semicircular cylindrical shape when viewed from the stern 1b side, and is disposed concentrically around the boshing 6 on the inner side C side in the ship width direction of the boshing 6.

  The duct 40 is supported by being fixed to end portions on the outer peripheral side of the plurality of fins 20 extending radially from the boshing 6. That is, the duct 40 is fixed to the bossing 6 with the plurality of fins 20 as support members.

  The duct 40 is formed in a tapered shape so that the outer diameter of curvature of its outer peripheral surface gradually decreases from the bow side toward the stern 1b side. Further, the duct 40 has the same length in the ship length direction in the circumferential direction.

According to such a configuration, the upward flow Fs in the direction opposite to the rotation directions R1 and R2 of the propeller 10 is generated in front of the propeller 10 by the fins 20 provided on the inner side C in the ship width direction with respect to the skeg 2. Is increased, the wake gain is increased in the left and right propellers 10.
Furthermore, since the outer diameter of the duct 40 gradually decreases toward the propeller 10 on the stern 1b side, the flow on the downstream side of the skeg 2 is increased on the inner side C side in the ship width direction with respect to the skeg 2. Therefore, forward thrust is generated in the duct 40.

  Therefore, according to the twin skeg ship of the third embodiment described above, the skeg 2 is placed in front of the propeller 10 by the fins 20 provided in front of the pair of left and right propellers 10 as in the first and second embodiments. The flow on the inner side C in the ship width direction can be increased. Accordingly, the wake gain in the left and right propellers 10 can be increased, and the propulsion performance can be improved by efficiently collecting the flow.

  Further, the twin skeg ship 1 in this embodiment has a semi-cylindrical duct 40 whose outer diameter is gradually reduced from the bow side toward the stern 1b side only in the ship width direction inner side C of the skeg 2 in front of the propeller 10. It has. By passing through the duct 40, the flow toward the propeller 10 is increased. Accordingly, thrust in the forward direction is generated in the duct 40, so that the propulsion performance can be improved.

  Further, according to this configuration, the duct 40 does not exist outside the skeg 2 in the ship width direction. Therefore, the specific resistance by the duct 40 can be reduced as compared with the case where the duct 30 is exposed outside the skeg 2 in the ship width direction as in the second embodiment. As a result, the thrust by the duct 40 increases and the propulsion performance can be improved more effectively.

(Modification of the third embodiment)
FIG. 10 is a rear view of the stern portion of the twin-skeg ship in the modification of the third embodiment of the present invention as viewed from the rear.
In the third embodiment, the duct 40 is fixed to the outer peripheral side end portions of the plurality of fins 20 so that the duct 40 has the same diameter as the outer peripheral side of the plurality of fins 20. Absent.
As shown in FIG. 10, the duct 40 may have a diameter smaller than the diameter on the outer peripheral side of the plurality of fins 20, and the duct 40 may be fixed at an intermediate portion of the plurality of fins 20.
In such a modification of the third embodiment, the propulsion performance can be improved as in the third embodiment.

(Other variations)
The present invention is not limited to the above-described embodiment, and includes various modifications made to the above-described embodiment without departing from the spirit of the present invention. That is, the specific shapes, configurations, and the like given in the embodiment are merely examples, and can be changed as appropriate.
For example, in each of the above-described embodiments and modifications thereof, the plurality of fins 20 are provided radially, but the number of installations and the installation angle are not limited at all.
In the second and third embodiments, the ducts 30 and 40 are provided on the outer peripheral portion of the fin 20. However, the ducts 30 and 40 may be separately provided with a position shifted from the fin 20 in the ship length direction.

DESCRIPTION OF SYMBOLS 1 Twin skeg ship 1b Stern 2 Skeg 3 Stern hull 4 Bottom 4s Inclined surface 5 Bottom of the vessel 6 Bossing 6s Outer surface 10 Propeller 12 Propeller shaft 12b Other end 20 Fin 30 Duct 40 Duct C Ship width direction inside R1, R2 Rotation direction

Claims (4)

A pair of left and right skegs provided on the bottom of the stern, each having a cylindrical boshing protruding rearwardly;
A propeller that is provided behind each of the pair of left and right skegs and whose inner rotation direction is an inward rotation that rotates from the outside in the ship width direction toward the inside in the ship width direction, with respect to the pair of left and right skegs It is a twin skeg ship whose flow in the width direction inside is slower than the flow in the width direction outside,
It is provided only on the inner side in the ship width direction with respect to the pair of left and right skegs, protrudes from the outer peripheral surface on the inner side in the ship width direction among the outer peripheral surfaces of the boshing, and extends radially from the rotation center of the propeller. A fin that imparts an outward flow opposite to the internal rotation that is the rotation direction of the propeller on the inner side in the ship width direction of the skeg in the forward direction;
Twin skeg ship equipped with.   In front of the propeller, the skeg further includes a cylindrical duct that is provided across the ship width direction inner side and the ship width direction outer side, and whose outer diameter gradually decreases from the bow side toward the stern side. The twin skeg ship according to claim 1. 2. The twin-skeg ship according to claim 1, further comprising a semi-cylindrical duct that is provided only on the inner side in the ship width direction of the skeg in front of the propeller, and whose outer diameter gradually decreases from the bow side toward the stern side.   4. The twin skeg ship according to claim 2, wherein the duct is supported by an end portion or an intermediate portion on the outer peripheral side of the fin. 5.

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