KR20140068034A - Propeller with small duct, and ship - Google Patents

Abstract

The propeller with a small duct according to the present invention has a propeller 10 mounted on the stern of the hull 1 and a duct 20 mounted on the front of the propeller 10 and having a diameter Ddin of the duct 20, Is set to 20% or more and 50% or less of the diameter Dp of the propeller 10 and the pitch H of the propeller 10 is set to a maximum value at the blade root of the propeller of the propeller 10, And the pitch of the bellows decreases in the direction of the radius (R), which is the minimum in the direction of the radius (R). The energy saving device combines the features of the large duct and the medium duct, And by disposing the small duct 20 close to the front of the propeller 10, the cavitation is suppressed in the actual sea area where the load A of the degree increases and then the propeller 10) in the radial direction (R) of the small duct 20 is optimized by using the interference with the small duct 20 The.

Description

Propeller and vessel with small duct {PROPELLER WITH SMALL DUCT, AND SHIP}

The present invention relates to a ship having a propeller mounted on the stern of a hull, a propeller with a small duct having a duct mounted in front of the propeller, and a propeller with a small duct.

A conventional duct installed near a propeller includes a large duct having a diameter larger than that of a propeller covered with a propeller, and a medium duct disposed slightly in front of the propeller, which is slightly smaller than the diameter of the propeller.

A large duct of the type covered with a propeller is called a duct propeller and is treated as an effective propeller when the propeller is integrated with a high load (degree of load) degree. This is because interference between the propeller and the duct is large, and it is reasonable to treat the performance in consideration of the interference as a propeller.

On the other hand, a medium duct slightly smaller than the propeller diameter in front of the propeller is treated as an energy-saving device and is not considered to be a propeller. This is because the interference between the duct and the propeller is not so large, and rather the interference between the hull and the duct is large.

Therefore, in the performance test of a medium-sized duct, a resistance test is carried out with a duct in the hull. This is based on the recognition that the duct is part of the hull.

In large ducts, since the interference with the propeller is large, the efficiency increases in the actual sea where the load is increased. However, cavitation occurring between the propeller and the duct becomes a problem, It is rarely adopted.

With respect to the medium-size duct, the configurations shown in Patent Documents 1 to 7 have already been proposed.

Patent Document 1 discloses a duct having a diameter smaller than a diameter of a propeller and having a cross-sectional shape inwardly convex.

Patent Document 2 discloses a duct having a diameter substantially equal to the diameter of a propeller, which is close to the concept of a large duct and is a duct having a non-axially symmetric shape as viewed from the lateral direction. However, A duct having a protruding degree of a convex shape is enlarged at the upstream side of the duct.

Patent Document 3 discloses a duct having a non-axisymmetric shape as viewed from the side. However, the diameter of the rear end of the duct is 50 to 80% of the diameter of the propeller, and the horizontal distance between the rear end face of the duct and the outer periphery of the propeller is 10 to 30 %. ≪ / RTI >

Patent Document 4 discloses a duct having a diameter smaller than a diameter of a propeller although the duct is a non-axially symmetric shape as viewed from the side.

Patent Document 7 discloses a propulsion device in which the pitch at the blade root of the propeller is slightly increased, reduced at the center, and increased again at the blade tip.

Patent Document 1: JP-A-9-175488 Patent Document 2: Japanese Utility Model Utility Model Publication No. 56-32396 Patent Document 3: Microfilm (Patent issued by the Patent Office on Feb. 21, 1991), which describes the contents of the specification and drawings attached to the application form of Japanese Utility Model Application No. 2-20180 (Japanese Utility Model Application No. 3-17996) Patent Document 4: JP-A No. 2008-143488 Patent Document 5: JP-A-2007-331549 Patent Document 6: JP-A-2002-220089 Patent Document 7: JP-A-10-264890

However, since the medium duct placed in front of the propeller is weak in interference with the propeller, the same effect as the duct propeller in the actual sea area where the load of the propeller is increased by the wind wave can not be expected as much.

In addition, the medium duct disclosed in each patent document does not optimize the load distribution in the radial direction of the propeller that governs the efficiency by using the interference with the small duct. In addition, large ducts which can expect interference can not be applied to large-sized ships having a large propeller diameter because of cavitation problems.

In Patent Document 7, since the pitch at the tip of the propeller is increased, the cavitation increases at the tip of the propeller.

Therefore, the present invention is an energy saving device having both characteristics of a large duct and a medium duct, and a small duct is arranged close to the front of the propeller in the form of a propeller, And to optimize the load distribution in the radial direction of the propeller that controls the efficiency by suppressing the cavitation by using the interference with the small duct.

In a propeller with a small duct corresponding to claim 1, a propeller mounted on the stern of a hull and a small duct having a duct mounted in front of the propeller, wherein the diameter of the duct is 20% of the diameter of the propeller, Or more and 50% or less, and the pitch of the propeller is set to a maximum value at the roughening portion of the propeller, and a minimum value at the end portion of the propeller is reduced to a radially decreasing pitch. According to the present invention as set forth in claim 1, the duct can be made to approach the propeller without causing cavitation by making the diameter of the duct 20% or more and 50% or less of the diameter of the propeller by combining the duct with the bellows- By setting the pitch to be the pitch reduction pitch, the radial load distribution of the propeller which controls the efficiency is optimized by the interference with the duct by increasing the suction effect at the central part of the propeller in the sea area where the load of the propeller is increased by the wind wave can do. In addition, cavitation generated at the end of the propeller can be suppressed by setting the propeller pitch to the maximum value at the peak portion of the propeller and to the minimum value at the end portion of the propeller. According to the present invention as set forth in claim 1, since the duct is 20% or more and 50% or less of the diameter of the propeller, it is possible to increase the efficiency of the propeller with small and lightweight, low frictional resistance, low vibration, low noise and low cost.

The present invention described in claim 2 is characterized in that, in the propeller having the small duct according to claim 1, the maximum value of the pitch is set to 120% or more and 160% or less with respect to the minimum value of the pitch. According to the present invention described in claim 2, the suction effect at the central portion of the propeller can be increased, and an optimum load distribution can be obtained.

According to a third aspect of the present invention, in the propeller having the small duct according to the first or second aspect, the distance between the rear end of the duct and the front edge of the propeller is set to 0.5% or more and less than 10% do. According to the present invention described in claim 3, the duct can be brought close to the propeller without causing peeling due to the suction effect of the propeller of the bodily sensation pitch, and the interference effect between the duct and the propeller can be enhanced.

According to a fourth aspect of the present invention, in the propeller having the small duct according to any one of the first to third aspects, the sectional shape of the duct is convex inward, the convexity of the convex shape is made larger on the upstream side of the duct, (Camber ratio) is set to 6% or more and 16% or less. According to the present invention described in claim 4, even when the camber ratio is set to 6% or more and 16% or less, lifting force (lifting force) that propels the hull forward as a component force without causing peeling due to the suction effect at the center portion of the propeller ) Can be increased.

According to a fifth aspect of the present invention, in the propeller having the small duct according to any one of the first to fourth aspects, the duct is an accelerated duct having a smaller inner diameter on the downstream side than the inner diameter on the upstream side. According to the present invention described in claim 5, the suction effect at the central portion of the propeller and the lift force for propelling the hull forward as a component force can be further enhanced.

According to a sixth aspect of the present invention, in the propeller having the small duct according to any one of the first to fifth aspects, the center of the duct coincides with the axial center of the propeller. According to the present invention as described in claim 6, ducts and propeller shafts of non-axisymmetric type can be provided at low cost because they are easy to manufacture and install as compared with ducts which are shifted from the central axes of the ducts or provided with inclination angles.

According to a seventh aspect of the present invention, in the propeller having the small duct according to any one of the first to sixth aspects, the duct is mounted on the end of the ship which is covered with the stern tube or stern tube of the hull through a support . According to the present invention described in claim 7, the flow can be taken in from the entire front surface, the interference with the propeller can be strengthened, the efficiency can be improved, and the rear portion of the duct can be easily attached.

According to an eighth aspect of the present invention, there is provided a propeller having a small duct according to any one of the first to seventh aspects, characterized in that the inner surface of the duct has a fixed blade for counterflowing the flow to the propeller . According to the present invention as set forth in claim 8, the flow introduced into the duct flows into the propeller as a counter flow through the fixed blade, thereby further improving the propeller efficiency.

According to a ninth aspect of the present invention, in the propeller having the small duct according to the eighth aspect of the invention, the strut also serves as a fixed blade, and the strut is twisted in a direction opposite to the rotating direction of the propeller. According to the present invention as set forth in claim 9, since the support is used as the fixed blade by rotating the rotor by the support, the structure is simplified.

A ship corresponding to claim 10 is characterized by having a propeller with a small duct according to any one of claims 1 to 9. According to the present invention as set forth in claim 10, it is possible to provide a ship with high propeller efficiency in a sea area where load is increased.

According to the propeller having the small duct according to the present invention, the duct can be downsized by combining the duct with the bellows propeller. By making the diameter of the duct 20% or more and 50% or less of the diameter of the propeller, . Thus, by setting the pitch of the propeller to the bodily sensed pitch, it is possible to increase the suction effect at the central portion of the propeller in the actual sea area where the load of the propeller is increased by the wind wave and to increase the radial load distribution of the propeller, Can be optimized. In addition, cavitation generated at the tip of the propeller can be suppressed by setting the propeller pitch to the maximum value at the peak of the propeller and to the minimum at the tip of the propeller.

Further, according to the propeller having the small duct according to the present invention, since the duct is 20% to 50% of the diameter of the propeller, it is possible to increase the efficiency of the propeller with small and light weight, low frictional resistance, low vibration, low noise and low cost.

Further, when the maximum value of the pitch is set to 120% or more and 160% or less with respect to the minimum value of the pitch, the suction effect at the central portion of the propeller can be enhanced and the optimum load distribution can be obtained.

If the distance between the rear end of the duct and the front edge of the propeller is set to 0.5% or more but less than 10% of the diameter of the propeller, the duct can be brought close to the propeller without causing peeling due to the suction effect of the propeller of the bodily sensation pitch , The interference effect between the duct and the propeller can be enhanced.

When the cross-sectional shape of the duct is convex inward and the convexity of the convex shape is increased on the upstream side of the duct, the camber ratio is set to 6% or more and 16% or less when the camber ratio is 6% The lifting force for propelling the hull forward as a component force can be increased without causing peeling by the suction effect at the center of the propeller.

When the duct is an accelerated duct having a smaller inner diameter on the downstream side than the inner diameter on the upstream side, the suction effect at the central portion of the propeller and the lifting force for propelling the hull forward as a component force can be further increased.

Also, when the center of the duct is aligned with the axial center of the propeller, compared to a duct which is provided with a non-axisymmetric duct or a propeller shaft and a central axis of the duct is provided with an inclination angle, can do.

In addition, when the duct is mounted on the ship's stern tube or stern tube covered with the stanchion through the stanchion, the flow can be taken in from the entire front surface and the efficiency can be improved by strengthening the interference with the propeller Together, it is possible to easily add the back of the duct.

In addition, in the case where the inner surface of the duct has a fixed blade for directing flow to the propeller, the flow introduced into the duct flows into the propeller as a counterflow by the fixed blade, thereby further improving the propeller efficiency have.

In the case where the strut also serves as a fixed blade and the strut is twisted in the direction opposite to the rotation direction of the propeller, the strut can also serve as a fixed blade by rotating the strut by the strut, simplifying the structure.

According to the ship of the present invention, it is possible to provide a ship having a high propeller efficiency particularly in a sea area where load is increased.

Brief Description of the Drawings Fig. 1 is a schematic structural view of a ship having a propeller with a small duct according to an embodiment of the present invention. Fig.
Fig. 2 is a partial cross-sectional side view and a cross-sectional view of an AA showing a main part of a propeller with a small duct used for the ship; Fig.
3 is a partial cross-sectional view showing a main part of a propeller with another small duct used for the ship.
4 is a graph showing the pitch distribution of the bodily-sensible pitch propeller and the normal propeller.
5 is a graph showing the flow velocity distribution of the bodily-sensible pitch propeller and the normal propeller.
6 is a graph showing the flow velocity distribution due to the distance between the rear end of the duct and the front edge of the propeller in the propeller with the small duct.
Fig. 7 is a graph showing a load change test result simulating the drop in ship speed in wave; Fig.
Fig. 8 is a graph showing the load change test result simulating the drop in line speed in the wave. Fig.

Hereinafter, a propeller with a small duct according to an embodiment of the present invention will be described.

Fig. 1 is a schematic structural view of a ship having a propeller with a small duct according to an embodiment of the present invention. Fig. 2 (a) is a partial sectional side view showing a main part of a propeller with a small duct used for the ship, Fig. 2 3 is a partial cross-sectional view showing a main part of a propeller with another small duct used for the ship, Fig. 4 is a graph showing a pitch distribution of the bodily-sensible pitch propeller and a normal propeller, Fig. FIG. 5 is a graph showing the flow velocity distribution of the bodily-sensible pitch propeller and the normal propeller, and FIG. 6 is a graph showing the flow velocity distribution due to the distance between the rear end of the duct and the front edge of the propeller in the propeller with the small duct.

As shown in Fig. 1, the ship has a propeller 10 mounted on the stern of the ship 1 and a duct 20 mounted on the front of the propeller 10.

2 (a), the propeller 10 has a boss 11 at a central portion thereof, and the duct 20 has a rear end 22 which becomes a downstream side of the inner diameter of the front end 21, Is an accelerated duct with a small inner diameter.

The sectional shape of the duct 20 is a convex shape 23 inward and the convex shape 23 has a larger projection on the upstream side of the duct 20. The camber ratio at the maximum camber position is set to 6% or more and 16% or less. In general, when the camber ratio exceeds 8%, the small duct 20 in the present embodiment is installed close to the front of the propeller 10, and the pitch of the propeller 10 The lift can be increased without detachment even if it exceeds 8% due to the suction effect at the center portion of the propeller 10, because the bodily sensation pitch is reduced in the radial direction. By making the duct 20 an acceleration duct and increasing the camber ratio by making the sectional shape of the duct 20 convex inward, it is possible to accelerate the flow, increase the interference with the propeller 10, 1) to the front can also be increased.

The diameter of the front end 21 of the duct 20 is Ddin, the diameter of the rear end 22 of the duct 20 is Ddout, the diameter of the propeller 10 is Dp, the diameter of the front end 21 of the duct 20 is Ddin, The diameter Ddin of the front end 21 of the duct 20 is set to 50% or less of the diameter Dp of the propeller 10 and the rear end 22 of the duct 20 and the propeller It is preferable that the distance L from the front edge of the propeller 10 is 15% or less and further less than 10% of the diameter Dp of the propeller 10. It is preferable to make the distance L between the rear end 22 of the duct 20 and the front edge of the propeller 10 as close as possible. However, in order to avoid contact between the duct 20 and the propeller 10, 10) of 0.5% or more of the diameter (Dp).

The diameter Ddin of the front end 21 of the duct 20 and the diameter Ddout of the rear end 22 of the duct 20 are set to 20% or more and 50% or less with respect to the diameter Dp of the propeller 10. The diameter Ddin of the front end 21 of the duct 20 and the diameter Ddout of the rear end 22 of the duct 20 are equal to each other in the range of 20% or more and 50% or less with respect to the diameter Dp of the propeller 10 But it may be a tubular shape. The diameter Ddin of the front end 21 of the duct 20 and the diameter Ddout of the rear end 22 of the duct 20 are more preferably set to Ddin> Ddout. The diameter Ddin of the front end 21 of the duct 20 is 35% or more and 50% or less of the diameter Dp of the propeller 10 and the diameter Ddout of the rear end 22 of the duct 20 is, It is more preferable that the diameter Dp of the propeller 10 is 20% or more and less than 40%.

It is possible to increase the efficiency of the propeller 10 by making the duct 20 of 20% or more and 50% or less of the diameter Dp of the propeller 10 small and light and having a small frictional resistance and low vibration, low noise and low cost.

The width W (length) of the duct 20 is preferably 20% or more and 60% or less with respect to the diameter Dp in order to increase the interference effect and avoid contact with the stern portion or increase in resistance. Particularly, when widely applied to general ships including large-sized ships, it is more preferable that the width W of the duct 20 is 25% or more and 50% or less with respect to the diameter Dp.

2 (a), the duct 20 is formed in an axisymmetric shape, and since the driving shaft 10a of the propeller 10 and the central axis of the duct 20 coincide with each other, Compared to a duct in which the propeller shaft and the central axis of the duct are shifted or provided at an inclination angle, it is possible to provide the duct at low cost because of easy fabrication and installation.

2 (b), the duct 20 is attached to the end portion 1a of the ship which is covered with the stems 20a, 20b, 20c, and 20d and covered with the stern tube 10b. The stern tube 10b is installed around the drive shaft 10a of the propeller 10. On the other hand, in the ship in which the stern tube 10b is exposed, the duct 20 may be directly attached to the stern tube 10b by the struts 20a, 20b, 20c, and 20d. The duct 20 is attached to both of the stern tube 10b and the ship body 1a by stanchions 20a, 20b, 20c, and 20d in the ship in which the stern tube 10b is partly exposed. Maybe.

The duct 20 is attached to the stern tube 10b of the hull 1 or the stern tube 10b covered by the stern tube 10b via the struts 20a, 20b, 20c and 20d, It is possible to easily increase the efficiency by enhancing the interference with the propeller 10, and at the same time, the rear portion of the duct 20 can be easily attached. This is advantageous when the duct 20 is attached to the existing boat by being rear-mounted. However, even when the duct 20 is mounted on a new boat, it is advantageous because it does not require machining on the outer plate of the boat 1 have.

The supports 20a, 20b, 20c and 20d are radially arranged with respect to the central axis of the duct 20, and in particular, by making the angle between the struts 20a and 20d smaller than the angle between the struts 20b and 20c , And the wake distribution can be improved.

It is preferable that the minimum number of supports is 2 and the maximum number is 5, and it is possible to further provide a support on the outside of the duct 20. [

The diameter of the rear end 22 of the duct 20 is set to be smaller than the diameter Ddin of the front end 21 of the duct 20. It is possible to improve the twisted distribution by narrowing the flow path cross section of the duct 20 toward the downstream. The cross section of the pillars 20a, 20b, 20c, and 20d may be increased toward the downstream side in addition to the inner end surface of the duct 20 being reduced in order to narrow the downstream flow path section of the duct 20. [ By improving the counter current distribution, the propeller efficiency by the small duct 20 can be further improved.

A column 20e having a twist may be provided on the inner surface of the duct 20 so as to counter flow the flow to the propeller 10 as shown in Fig. In this case, the mounting angle with respect to the ship's center line is preferably 5 degrees to 25 degrees on the side of the ship body? S, and 5 degrees to 10 degrees on the inner surface side? D of the duct 20. The flow introduced into the duct 20 is accelerated from the upstream side to the downstream side and is rotated by the propeller 10 in the direction opposite to the rotation direction of the propeller 10 by the twisted support 20e, As a result, the propeller efficiency can be further improved.

The support 20e may be provided on the outer side of the duct 20 and the inner side of the duct 20 may be provided with a fixed blade for rotating the flow. However, the support 20e may be rotated by the support 20e, Can also serve as fixed blades, simplifying the construction.

Figure 4 shows the pitch distribution of the bodily-pitch propeller and the normal propeller.

The propeller 10 has a radius r1 of the boss 11 and a radius r2 from the radius r1. The radius R is 1 / 2Dp and H is the pitch. The roughened portion is 20% or more and 40% or less of the diameter (Dp) of the propeller (10).

The pitch H of the propeller 10 according to the present embodiment is a bodily sensation pitch decreasing in the direction of radius R, which is the maximum value at the tip of the propeller 10 and the minimum at the tip. The comparative example shown in Fig. 4 shows a constant pitch.

The pitch H of the propeller 10 according to the present embodiment becomes the maximum value Hmax at the peak portions r1 to r2 of the propeller 10 and the maximum value Hmax as the minimum value Hmin of the pitch H ) Is 120% or more and 160% or less in consideration of propulsion efficiency and suppression of cavitation occurrence.

Fig. 5 shows the flow velocity distribution between the propeller due to the bodily sensation pitch according to the present embodiment shown in Fig. 4 and a normal propeller as a comparative example.

V is the flow velocity at the inlet side of the propeller 10, Vx is the flow velocity at the outlet side of the propeller 10, and V and Vx are both the axial flow velocities.

As shown in Fig. 5, in this embodiment, the flow velocity distribution is improved at r1 / R of 0.2 to 0.6 for the comparative example.

5, the distribution of the flow velocity near the center of the propeller 10 is improved by making the propeller 10 have a bodily sensation pitch. Therefore, the duct 20 can be formed in a small duct 20 having a small diameter Ddin, It is also suggestive of good. Since the duct 20 can be downsized, it is possible to increase the flow velocity of the roughed portion of the propeller 10, thereby increasing the interference with the increase in the pitch of the propeller 10 at the roughened portion. In addition, it is possible to produce a lightweight and low-cost product, which leads to reduction of frictional resistance because of its small surface area. In addition, since the small duct 20 can increase the flow velocity of the rising portion of the propeller 10, which is relatively slow in speed, the generation of cavitation can be suppressed and the damage, vibration, and noise of the propeller 10 can be prevented can do. In addition, since the pitch of the propeller 10 is the maximum at the wicking portion and becomes the minimum at the wicking end, it is possible to suppress cavitation generated at the end portion of the propeller 10 because the bellows pitch decreases in the radial direction.

6 shows the flow velocity distribution when the distance L between the rear end 22 of the duct 20 and the front edge of the propeller 10 in the propeller with the small duct is changed.

The distance L between the propeller 10 and the duct 20 remarkably appears at 15% or less of the diameter Dp of the propeller 10 and the distance L is less than 10% of Dp, The load distribution in the radius (R) direction of the rotor 10 is more influential. If the distance L is excessively long, the hull 1 is contacted. By making the distance L less than 10% of Dp, it is possible to prevent contact with the hull 1, and to prevent difficulty in receiving the flow from the entire front surface.

Figs. 7 and 8 show the load change test results simulating the drop in line speed in the wave.

FIG. 7 is a graph showing the propulsive efficiency when the distance between the front edge of the propeller and the rear end of the duct is changed and when the duct is not provided; and FIG. 8 is a graph showing changes in the distance between the front edge of the propeller and the rear end of the duct (Thrust) change in the case where the force is applied.

In this experiment, an Aframax tanker with Lpp (length between normal lines) = 229 m, B (width of ship) = 42 m, D (depth of ship) = 12.19 m, , Model lines of Lpp = 4.8600m, B = 0.8914m and D = 0.2587m were used.

The propeller 10 of the test object line has a ratio of Dp (propeller diameter) = 7 m, H / D (0.7 R) (pitch position) = 0.67, EAR (deployment area ratio) = 0.45, Rake = D = 0.148559m, H / D (0.7R) = 0.67, EAR = 0.45, Rake = 0.45, and Z = W = 4, Boss Ratio = 0.1586, Skew = 20deg, = -4.6 mm, Z = 4, Boss Ratio = 0.1586, and Skew = 20 deg were used as model propellers.

The duct 20 has a length Dp (the diameter of the front end 21) of 48%, a length Dpout of 40% of the diameter Dpout (diameter of the rear end 22) 24% of duct wing camber ratio, and 8% of duct wing camber ratio.

In this experiment, a self-propulsion test was conducted in a state in which the line speed was lowered while the number of revolutions was constant and the propeller load was increased, in order to simulate the drop in the line speed in the wave.

In Fig. 7, the propulsive efficiency is compared when the horizontal axis represents the linear velocity ratio and the vertical axis represents the propulsion efficiency, and the linear velocity ratio is reduced to 0.75.

The distance L between the front edge of the propeller 10 and the rear end 22 of the duct 20 = Dp x 6% as Embodiment 1, L = Dp x 3% as Embodiment 2, and L = Dp x 1% is used and the duct 20 is not used is shown as a comparative example.

In Example 1 to Example 3, the propulsion efficiency was higher than that in Comparative Example in any of the linear velocity ratios of 0.75 to 1.

In FIG. 8, the thrust is compared when the horizontal axis represents the propeller thrust and the vertical axis represents the duct resistance (thrust) and the propeller thrust is varied between 1.05 and 1.3.

Thrust is increased in the second embodiment than in the first embodiment, and thrust is increased in the third embodiment than in the second embodiment.

As shown in FIG. 8, the smaller the distance L between the front edge of the propeller 10 and the rear end 22 of the duct 20, the more the thrust increases.

The propeller having a small duct according to the present embodiment is provided with a propeller 10 mounted on the stern of the hull 1 and a duct 20 mounted on the front of the propeller 10, The diameter of the duct 20 can be reduced to 20% or more of the diameter Dp of the propeller 10 by combining the duct 20 with the propeller 10 having the bodily sensation pitch. It is possible to make the duct 20 approach the propeller 10 without causing cavitation. Therefore, by setting the pitch H of the propeller 10 to a maximum value at the peak of the propeller 10 and a minimum value at the end of the propeller 10 in the radial direction, the load of the propeller is increased by the wind wave It is possible to improve the suction effect at the center of the propeller 10 in the actual sea area and to optimize the load distribution in the radius direction R of the propeller 10 which dominates the efficiency by using the interference with the duct 20. Since the pitch H of the propeller 10 is maximized at the peak of the propeller 10 and minimized at the end of the propeller 10, cavitation generated at the tip end of the propeller 10 can be suppressed, The occurrence of noise, vibration, and damage to the propeller 10 can be reduced.

According to the propeller having the small duct according to the present embodiment, since the duct 20 is 20% or more and 50% or less of the diameter Dp of the propeller 10, the flow rate of the rising portion of the propeller 10 is increased The efficiency of the propeller 10 can be increased by increasing the interference with the increase of the pitch of the propeller 10 at the roughened portion. Further, it is possible to realize the propeller 10 which is small and light in weight, low in frictional resistance, low in vibration, low in noise and low in cost.

According to the propeller having the small duct according to the present embodiment, the maximum value Hmax of the pitch H is set to 120% or more and 160% or less with respect to the minimum value Hmin of the pitch H, It is possible to increase the suction effect at the center of the propeller 10 to obtain an optimum load distribution and to improve the propulsion efficiency.

The distance L between the rear end 22 of the duct 20 and the front edge of the propeller 10 is set to 0.5 of the diameter Dp of the propeller 10 according to the propeller having the small duct according to the present embodiment. The duct front end 21 is prevented from touching the hull 1 of the stern section and the flow is received from the entire front surface of the duct 20 so that interference between the duct 20 and the propeller 10 The effect can be enhanced.

According to the propeller having the small duct according to the present embodiment, the flow can be accelerated by making the duct 20 an acceleration duct having a smaller inside diameter on the downstream side than the diameter on the upstream side, The suction effect at the center can be further enhanced.

According to the propeller having the small duct according to the present embodiment, by making the center of the duct 20 coincide with the axial center of the propeller 10, it is easy to manufacture and install and can be provided at low cost.

According to the propeller having the small duct according to the present embodiment, the duct 20 covers the stern tube 10b or the stern tube 10b of the hull 1 through the struts 20a, 20b, 20c and 20d It is possible to improve the efficiency by strengthening the interference with the propeller 10 and to improve the efficiency of the duct 20 including the existing boat, It is possible to easily carry out the backward addition.

According to the propeller having the small duct according to the present embodiment, the cross-sectional shape of the duct 20 is set to the convex shape 23 inside and the projected degree of the convex shape 23 is set to the upstream side of the duct 20 The flow rate can be accelerated to the upstream side where the average speed is slow and the resistance increase can be suppressed and the suction effect at the center of the propeller 10 can be further enhanced. In this case, even if the camber ratio is increased to 6% or more and 16% or less due to the suction effect, lift that propels the hull 1 forward can be increased without causing peeling.

Further, by providing a propeller with a small duct according to the present embodiment, it is possible to provide a ship with a high propeller efficiency in a sea area where load is increased.

[Industrial Availability]

According to the propeller with the small duct of the present invention, it is possible to widely apply to a general ship including a large-sized line because of its small size, light weight, low frictional resistance, low vibration, low noise and low cost.

1: Hull
1a: End of hull
10: Propeller
10b: stern tube
11: Boss
20: Duct
20a, 20b, 20c, 20d: a support (fixed blade)
Dp: Diameter of the propeller
Ddin: Diameter of shear of duct
Ddout: diameter of the rear end of the duct
H: pitch
L: Distance between the rear end of the duct and the front edge of the propeller

Claims (10)

In a propeller with a small duct having a propeller mounted on the stern of a hull and a duct mounted on the front of the propeller,
The diameter of the duct is set to 20% or more and 50% or less of the diameter of the propeller,
Wherein a pitch of the propeller is set to a maximum value at a blade root of the propeller of the propeller and is a minimum value at a blade tip, A propeller with a small duct. The method according to claim 1,
Wherein the maximum value of the pitch is set to 120% or more and 160% or less with respect to the minimum value of the pitch. 3. The method according to claim 1 or 2,
Wherein a distance between a rear end of the duct and a front edge of the propeller is set to 0.5% or more and less than 10% of the diameter of the propeller. 4. The method according to any one of claims 1 to 3,
And the camber ratio is set to 6% or more and 16% or less by increasing the protruding degree of the convex shape on the upstream side of the duct. Propellers with small ducts. 5. The method according to any one of claims 1 to 4,
Characterized in that the duct is an accelerated duct having a smaller inner diameter on the downstream side than the inner diameter on the upstream side. 6. The method according to any one of claims 1 to 5,
And the center of the duct is aligned with the axial center of the propeller. 7. The method according to any one of claims 1 to 6,
Characterized in that the duct is mounted on a stern tube of the hull or the end of the hull covering the stern tube through a strut. 8. The method according to any one of claims 1 to 7,
Characterized in that the inner surface of the duct has a fixed blade for counterflowing the flow to the propeller. 9. The method of claim 8,
Characterized in that said strut also serves as said fixed wing and said strut is twisted in a direction opposite to the direction of rotation of said propeller. A ship characterized by comprising a propeller with a small duct as claimed in any one of claims 1 to 9.

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