JP2016074291A - Single-propeller and front-mounted twin-rudder ship - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a structure of a ship capable of improving fuel economy and capable of making a load amount per overall length of the ship large.SOLUTION: Rudders 12 are provided in symmetrical positions with respect to a center line of a ship, ahead of a propeller 11 and in the rear of a buttock line, respectively. In addition, a stern thruster 40 is provided ahead of the propeller so that an effect brought about by the stern thruster 40 can be expected.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a single propeller having a propeller shaft and two rudders in the bow direction of the propeller, and a front twin ladder ship.

Ships are used as a means to transport goods and people in large quantities and efficiently.
Therefore, since it is important for ships to safely call and navigate the intended route, the ship's propulsion mechanism and rudder mechanism have evolved and evolved.

The basic elements required for a rudder are turning performance (a performance that shows how quickly the course can be bent when the rudder is kept turning), and needle maintenance (course stability: how to run straight These are often contradictory functions, but various attempts have been made to make them compatible.
Due to the ship's rotational performance, the relationship with the ship's main body, the effect of water flow on the rudder, etc., it has become common for the stern to be attached in tandem at a position behind the propeller.

  The effect of the rudder is the same as that of airplanes and other wing theory, and it is well installed in a limited space at the stern.

The rotational performance of the rudder depends on the lateral thrust acting on the surface of the rudder. This is the lift that acts on the control surface. In a theoretically uniform laminar flow, lift is expressed by the following equation as the performance of the rudder alone.
Lift (F) = 1 / 2ρV ²・ sin α ・ A ・ Fp
Where V: Water inflow speed to the rudder
α: Inflow angle with respect to rudder of influent water
A: Effective area for rudder lift
Fp: The gradient of the direct pressure coefficient of the rudder alone
ρ: Seawater density

  On the other hand, in order to increase the lift of the rudder, it is known in Patent Document 1 that, in a special ship, two rudders are provided in parallel at a position behind the propeller on the stern.

JP 2003-26096 A

  Although the configuration of Patent Document 1 has the advantage that the lift can be increased, there is no idea of improving fuel consumption, reducing the price of a built ship, or increasing the load per ship.

  SUMMARY OF THE INVENTION Accordingly, a main object of the present invention is to provide a ship structure that can improve fuel consumption, increase the load per ship, and reduce the construction ship price.

The present invention that has solved the above problems is as follows.
<Invention of Claim 1>
A single propeller and a front twin-ladder ship, each of which has a rudder in front of the propeller and behind the buttocks line and symmetrically with respect to the center line of the ship.

(Function and effect)
A rudder was provided at each position symmetrical to the center line of the ship. The rudder area required to ensure the necessary turning performance and needle-keeping performance (course stability) for a ship of a certain size is as follows: It can be as small as 25% to 50% per rudder area. The total area of the two rudders is the same as or slightly larger than the conventional one rudder. It is desirable to provide the rudder so that the clearance between the propeller and the bottom line is as small as possible.
In general, it is necessary for the rudder to be submerged from the sea level when sailing. The ability to reduce the rudder area according to the present invention means that the draft depth can be reduced during voyage, and as a result, the output of the main engine can be reduced at the same boat speed, and the fuel efficiency is improved.
On the other hand, by providing a stern thruster in front of the propeller, the effect of the stern raster can be expected.
The “buttock line” means a stern shape line cut along a vertical plane parallel to the hull center longitudinal section. In particular, it refers to the line formed by the intersection line with the parallel part of the hull.

<Invention of Claim 2>
The single propeller and the front twin ladder ship according to claim 1, wherein a stern thruster is provided in front of the propeller and behind the buttocks line, and a propeller axis of the stern thruster passes through each rudder plate surface.

(Function and effect)
By providing a stern thruster on the stern side, it is possible to improve trajectory correction in narrow harbors and ship maneuverability in taking off and landing.
On the other hand, when a ship is navigating at a low speed such as in a harbor, the rudder is very ineffective. Therefore, ship steerability is enhanced by activating the Stern thruster and causing the water flow to collide with the rudder plate surface.

<Invention of Claim 3>
The single propeller and the front twin ladder ship according to claim 3, wherein the stern thruster is located 3 to 25 m ahead of the propeller.

(Function and effect)
The stern thruster is preferably located 3 to 25 m ahead of the propeller. When located 3 to 25 m ahead of the propeller, it was found that the trajectory correction in a narrow port and the ship maneuverability by the stern thruster at the takeoff and berth were suitable positions.

<Invention of Claim 4>
The single propeller and the front twin ladder ship according to claim 1, wherein the rudder has left and right symmetrical rudder surfaces.

(Function and effect)
The present invention is not characterized by the shape of the surface of the rudder, but is intended to use a general rudder. When the rudder has a left and right symmetrical rudder surface, the maneuverability can be improved by using the two rudders synchronously, independently, or in combination.

<Invention of Claim 5>
The single propeller / front twin ladder ship according to claim 1, wherein the operation rudder is provided in the hull in front of the propeller and behind the buttocks line.

(Function and effect)
In addition to the rudder, if the operating rudder is installed in front of the propeller, for example, the rear peak tank room of the ship, the steering rudder room (steering room), etc., do not need to be extended to the rear. Compared to a ship having a single rudder, for example, it can be shortened by about 5 m to 20 m.
As a result, in the case of a cargo ship, since the volume of the cargo tank can be increased by about 5% to 15% per the same total length, the utility value of the ship is increased. In addition, the total length of the ship can be shortened and the construction ship price will be reduced.

<Invention of Claim 6>
In addition to the propeller, an additional propeller and its driving means are provided, and the additional propeller is located at a position different from the arrangement position of the propeller, and one or a plurality of the additional propellers are arranged at the bottom of the ship or at the bottom of the ship and drive the propeller. 2. The single propeller / front twin ladder ship according to claim 1, wherein a normal operation state for obtaining propulsive force and an operation state for obtaining propulsive force by driving an additional propeller can be selected.

(Function and effect)
In addition to the propeller, that is, the normal propeller, a small additional propeller and its driving means are provided. The output of the driving means of the additional propeller can be 35% or less, more preferably 25% or less of the output of the driving means of the main machine.
During loading (loading), the propeller is driven and operated in a draft state close to the planned full draft. If necessary, operate with additional propellers.
Mainly operated with a small additional propeller, returning to the port after unloading. In particular, on days when the weather is mild, there is little need to be overly strict about the stability of the ship during navigation. Therefore, it is made to run with a small additional propeller in a state where the water line is lowered.
As a result, by lowering the waterline, the apparent amount of drainage is reduced, the contact area of the outer plate with the water is reduced, the waterline area coefficient can be improved, and the effect of reducing fuel consumption is great. Become.
In addition, since a small additional propeller is driven, the output of the driving device (35% or less, more preferably 25% or less of the output of the driving means of the main engine) is sufficient, and from this point of view, the effect of reducing fuel consumption Is a big one.
When the ship departs after full loading, and shifts to normal voyage, the propeller is driven and sails in deep draft. In addition, when sailing with ballast after unloading, additional propellers will be operated after shifting to normal sailing. However, when the weather is bad, even an empty ship can be run with a small additional propeller or service propeller in a state where ballast water is filled and stabilized. If necessary, an additional propeller and a regular propeller can be used in combination.
By using an additional small duct propeller mainly during ballast voyage, the propeller submersion rate of the main propeller is reduced, and the propeller diameter of the normal propeller can be made larger than the propeller diameter according to the conventional design standard. As a result, the propeller efficiency can be increased, and the efficiency can be increased by about 5 to 7%. Thus, by adopting a larger diameter regular propeller, the propeller efficiency is increased and the required output of the main engine is reduced for the same boat speed. This greatly improves fuel efficiency.

<Invention of Claim 7>
The single propeller and the front twin ladder ship according to claim 6, wherein the additional propeller is selectable between an overhanging state and an inboard state.

(Function and effect)
When the duct propeller is overhanging out of the ship, it becomes a resistance at a deep draft, so it is desirable that the duct propeller be pulled into the ship.

  As described above, according to the present invention, it is possible to improve fuel consumption and to increase the amount of cargo per full length of the ship.

It is a front view which shows the stern part of the front of a single propeller and a front twin ladder ship. It is a bottom view of a single propeller and a front twin ladder ship. It is the bottom view seen from the rear side of a single propeller and a front twin ladder ship. It is a general | schematic front view of the ship of a loaded state in the case of providing an additional propeller. It is a general | schematic front view of the ship of the operation state by an empty load in the case of providing an additional propeller. It is a front view of an example of an additional propeller (duct propeller). It is a front view which shows the stern part of the front of the one rudder ship of the one propeller in a prior art example. It is a bottom view which shows the stern part of the front of the one rudder ship of the one propeller in a prior art example.

  First, a conventional example will be described. As an example of a tanker or a large cargo ship, as shown in FIG. 7 and FIG. 8, a propeller is a rudder ship, and an engine room 50 is arranged in a hull of a stern part. Propeller 51 is driven by rotating.

A rudder 52 is provided behind the propeller 51, an operation rudder room (steering room) 53 above the propeller 51 is disposed, an operation rudder 54 is provided therein, and the rudder shaft 55 is a rudder (steer plate). The ship is capable of turning by means of an operation steering 54. Reference numeral 56 denotes an after peak tank chamber.
In front of the engine room 50, a cargo room 57 is arranged continuously to the bow side. 58 is a bridge.

Next, embodiments of the present invention will be described with reference to the accompanying drawings.
1 to 6 show an example of a single propeller and a front twin ladder ship of the present invention.

  The present invention is characterized in that rudders 12 and 12 are provided in front of the propeller 11 and behind the buttocks line, respectively, at symmetrical positions with respect to the center line of the ship.

  The rudder 12 may be either a balanced type or an unbalanced type in relation to the rudder shaft 12a. Moreover, it is desirable to have a symmetrical control surface as shown in FIG. The two rudders 12 and 12 can be appropriately selected from synchronous use, single use, combined use, and the like.

  By providing the rudder 12 and 12 in front of the propeller 11, the operation rudder room (steering room) 53 is also arranged in front of the propeller 11, and the operation rudder 54 is provided therein.

A Stance raster 40 can be provided in front of the propeller 11 and behind the buttocks line. Further, the propeller axis 40a of the stern thruster 40 is disposed so as to pass through the rudder plate surfaces of the rudder 12 and 12.
By providing the stern thruster 40 on the stern side, it is possible to improve the trajectory correction in a narrow port and ship maneuverability in berthing and landing.
On the other hand, when a ship is navigating at a low speed such as in a harbor, the rudder is very ineffective. Therefore, by starting the stern thruster 40 and causing the water flow to collide with the rudder plate surface, the effectiveness of the rudder is accelerated and the maneuverability is improved.

  The stern thruster 40 is preferably located 3 to 25 m ahead of the propeller.

According to the present invention, the rudder and its operating rudder are provided in front of the propeller, so that, for example, as shown in FIGS. 8 and 9, the afterpeak tank chamber 56 of the ship, the operation rudder chamber (steering chamber) 53 (see FIG. 7) and the like, and it can be shortened, for example, by about 5 m to 20 m compared to a conventional propeller having one rudder behind it.
As a result, in the case of a cargo ship, since the volume of the cargo tank can be increased by about 5% to 15% per the same total length, the utility value of the ship is increased. Also, the construction ship price can be reduced.

  The propeller 11 is a conventional propeller. As shown in FIGS. 4 to 6, in addition to the regular propeller 11, an additional propeller and its driving means are provided, and the additional propeller is located at a position different from the position where the propeller is disposed, and is provided at the bottom of the ship or at the bottom of the ship. Single propellers and front twin-ladder ships are also provided that allow one or more units to be selected from the normal operation state where propellers are driven to obtain propulsion and the operation state where additional propellers are driven to obtain propulsion. The

  FIG. 4 is a schematic front view of a ship, for example, a merchant ship 10 in a loaded state, for example, a cargo ship. This merchant ship 10 obtains propulsive force by driving a regular propeller (main propeller) 11 by a main engine (main engine) 50 such as a diesel engine. 14A is a water line in an unloaded state, the bow direction is high, and the stern direction is a bow foot (front) state intersecting the bottom line. The stern foot state is reversed and is indicated by a water line 14B in FIG.

As also referred to in FIG. 6, the ship is provided with a duct propeller 21 including an additional propeller 20 and its driving means 22.
The additional propeller 20 is located at a different position from the service propeller 11, that is, at the bow or the middle position, in addition to the bow region shown in the figure, at the bottom of the ship or at the bottom of the ship. The case of the stern position is indicated by reference numeral 20A, and the case of the intermediate position is indicated by reference numeral 20B.

The output of the driving means 22 of the additional propeller 20 is 25% or less of the output of the driving means of the main machine 50 and is small.
A normal operation state in which the propeller 11 is driven to obtain a propulsion force and an operation state in which the additional propeller 21 is driven to obtain a propulsion force can be selected.

  An example of the additional propeller 20 will be described. As the driving means 22, in addition to an electric motor, a hydraulic motor, etc., if necessary, the driving means 22 can be connected to a main machine (main engine) 50 to obtain a driving force.

The rotational driving force of the output shaft 23 by the driving means 22 is transmitted to the vertical axis 25 via a pair of bevel gears 24, and the rotational force of the propeller drive shaft 27 via a pair of bevel gears 26 provided on the vertical axis 25. And the duct propeller 21 having the duct 21A around the propeller is rotated.
On the other hand, the rotational driving force of the transmission shaft 28 by the driving means 22 is transmitted to the driving small gear 29 and the large gear 30 meshing therewith, so that the duct propeller 21 can rotate about the vertical axis 25.

  Further, as shown in FIG. 6, the equipment including the duct propeller 21 below the ship bottom 10A is in a state of projecting out of the ship bottom 10A. However, since it becomes an obstacle during normal voyage, it can be pulled into the ship. A structure is preferred. 10B is a shielding member that closes after being pulled into the ship.

With such a ship structure, when the cargo R is loaded (loaded), as shown in FIG. 4, the main propeller 11 drives and operates the service propeller 11 in a draft state close to the planned full draft.
After unloading, especially on days when the weather is mild, or in the sea where the waves are quiet, it is not necessary to overly strict the stability of the ship when navigating. In this state, the vehicle is driven by a small additional propeller 20. In this case, as shown by the white arrow in FIG. 5, the traveling direction of the ship can be appropriately selected, and the bow and stern are monitored by the bridge 13 according to the traveling direction of the ship.
As a result, by lowering the waterline, the apparent amount of drainage is reduced, the contact area of the outer plate with the water is reduced, the waterline area coefficient can be improved, and the effect of reducing fuel consumption is great. Become.
Further, since the small additional propeller 20 is driven, the output of the driving device 22 is small, and the output of the driving means of the main machine 12 is 35% or less, particularly 25% or less, especially about 10% to 5%. From the viewpoint of navigating, the fuel consumption can be greatly reduced. A running speed of about 5 to 10 knots is sufficient on a mild day (0 to 3 on the Beaufort scale).

When the ship departs after full loading of cargo R and shifts to normal voyage, the propeller 11 is driven or used in combination and sailed in deep draft.
If the weather is bad, even if the ship is an empty ship, the ballast water BW (the ballast water storage space is not shown) is stretched and stabilized, and the small additional propeller 20 or regular service is used. It can be made to run with the propeller 11.

  If the duct propeller 21 is rotatable about the vertical axis, the duct propeller 21 can be driven and propelled in the stern direction as shown in FIG.

  When the duct propeller 21 is rotatable around the vertical axis 25 (vertical axis), the steering function can be added by appropriately rotating the additional propeller around the vertical axis in the combined operation of the additional propeller and the normal propeller. It is possible to improve the maneuvering (direction). In addition, it can be used as a slide thruster by turning it sideways when the ship berths.

  Further, the propulsion direction by the duct propeller 21 can be the bow direction. Therefore, a propeller anti-spinning device 11A for preventing rotation of the service propeller 11 can be provided.

  If necessary, the duct propellers 21 can be provided on the left and right sides of the center line of the ship. The maneuverability can be enhanced by the rotation of the left and right duct propellers 21 and 21 around the vertical axis. Moreover, when used as a slide thruster, berthing becomes even easier.

  The present invention is applicable to container ships, tankers, LNG ships, car carriers, bulk carriers, passenger ships, and the like in addition to general cargo ships.

10 ... Ship 11 ... Service propeller (Main propeller)
12 ... rudder 12a ... rudder shaft 20 ... additional propeller 21 ... duct propeller 22 ... drive means 40 ... stern thruster 50 ... main engine (main engine: drive means)
54. Operation rudder

Claims (7)

  A single propeller and a front twin-ladder ship, each of which has a rudder in front of the propeller and behind the buttocks line and symmetrically with respect to the center line of the ship.   The single propeller and the front twin ladder ship according to claim 1, wherein a stern thruster is provided in front of the propeller and behind the buttocks line, and a propeller axis of the stern thruster passes through each control surface.   The single propeller and the front twin ladder ship according to claim 3, wherein the stern thruster is located 3 to 25 m ahead of the propeller.   The single propeller and the front twin ladder ship according to claim 1, wherein the rudder has left and right symmetrical rudder surfaces.   The single propeller / front twin ladder ship according to claim 1, wherein the operation rudder is provided in the hull in front of the propeller and behind the buttocks line.   In addition to the propeller, an additional propeller and its driving means are provided, and the additional propeller is located at a position different from the arrangement position of the propeller, and one or a plurality of the additional propellers are arranged at the bottom of the ship or at the bottom of the ship and drive the propeller. 2. The single propeller / front twin ladder ship according to claim 1, wherein a normal operation state for obtaining propulsive force and an operation state for obtaining propulsive force by driving an additional propeller can be selected.   The single propeller and the front twin ladder ship according to claim 6, wherein the additional propeller is selectable between an overhanging state and an inboard state.

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