ES2385994A1 - Accelerating nozzle for watercraft in a free navigation condition - Google Patents

Abstract

The invention relates to an accelerating nozzle for watercraft in a free navigation condition. The invention provides improved performance in watercraft as a result of the nozzle wherein: the line containing the chord (9) of the contour of the nozzle intersects with the axis of symmetry of the lower cylindrical part of the nozzle, upstream of said nozzle the difference between the outer radius of the nozzle and the inner radius is between 0.050D and 0.076D, D being the inner diameter of the nozzle the outer surface (8) of the nozzle is cylindrical and the inlet edge has a cross-sectional curvature radius of between 0.01019D and 0.004D. The nozzle forms part of a propulsion system which, in turn, forms part of a watercraft.

Description

SYNTHETIC ACCELERATING FIXED NOZZLE FOR WATER VESSELS IN FREE NAVIGATION CONDITION.

Technical sector The invention relates to a symmetrical fixed accelerator nozzle for watercraft in free navigation condition, being part of the ship propulsion system floating or underwater aquatic.

State of the art Clarification of technical concepts: The feed coefficient J = VJnDp • Where VA is the forward speed of the propeller, n the number of revolutions per second of the propeller and Op the diameter of the propeller. Traction coefficient or total thrust Ktt = T I p n2 Op4, I feel T the traction or thrust total of the propeller and the nozzle together, and p the density of the water. Load index CT = (T) I (% p Vl "/ 4 Op2). Free navigation condition: when sailing with exclusively indoor cargo; in this condition the load index CT has a value between 1.5 and 3 in Cruising speed at 80% of nominal power. Drag or pull navigation condition: when navigating by pulling a web fishing or towing to another ship; in this case the speed of the ship is very small in relation to the thrust or shot of the propulsive system constituted by an open propeller or by a nozzle propeller, it is said that the propulsive system is very charged, the index CT load is above the value 4; only ships in this condition navigate fishing trawlers and tugs, when they are doing their job specific. Coefficient of thrust of the propeller. = Tpi T, where Tp is the thrust exerted by the propeller only and T the thrust exerted by the propeller-nozzle assembly. In the open propeller (without nozzle) is worth 1, in accelerating nozzles less than 1 and in decelerating nozzles more of 1. Some coefficients are used, with the factor O or L to indicate some distances in function of the inside diameter of the nozzle O or the axial length of the nozzle L. Al multiplying the coefficient by the concrete value in each case of D or L gives us the concrete measure In nozzles the ratio LID, axial length of the nozzle divided by the inner diameter of the nozzle, is an essential reference. It is called a liquid vein, when a liquid is driven by a propeller, in the case

which occupies us, inside the same liquid, differentiating itself from the rest of the same liquid that surrounds the vein by its kinematic characteristics, both downstream of the propeller above all, and upstream of the propeller. In a watercraft it is called a nominal wake in any plane perpendicular to the length of the ship, to the kinematic characteristics of the water in said planes around the ship, this happens when the ship is towed; and effective wake is the one that takes place in self-propelled when the propeller or propellers push to the ship; in this case the most notable difference is presented from the plane of the downstream propeller, when the propeller generates a liquid vein clearly differentiated by its kinematic characteristics from the rest of the kinematic characteristics of the surrounding water, especially higher speed, causing a lot turbulence, therefore much friction and therefore loss of performance of the propulsive system. A naval propeller generates, in a certain direction, an effective wake speed downstream with axial, tangential and radial components. The axial component is the most important in terms of module. Angle of attack of a profile is the one that forms the line that contains the rope with the general direction of the fluid that falls on said profile. The greater the angle of attack of a profile in this case of nozzle with respect to the general direction of the current, the greater is the coefficient of lift and therefore the lift and the acceleration that it induces inside the nozzle. Codaste: continuation of the keel of the watercraft by stern, both in floating ships and in submarine ships. Horn: support of the propeller tree in the codaste. In the ratio of areas Ae / Ao, Ae refers to the total surface of the blades and Aa refers to the area of the scanning disc. At the moment for the propulsion of aquatic ships in condition of free navigation, the nozzle "19A" developed by "MARIN" "Maritime Research Institute Netherlands" is used in the 1960s, the nozzle "HR" commercialized by the company "Wartsila" in the 1990s, and the nozzle "Rice speed" marketed by the "Rice Group" company of Mexico in the 1990s; in all of them the UD ratio is very about 0.50; the line containing the rope of each profile intersects the axis of symmetry of the nozzle downstream of it; the difference between the outer radius of the nozzle and the inner radius is approximately 0.10D, in the three nozzles mentioned; the outer surface is not cylindrical in any of them. In patent document ES2317799 (A1) filed on 01/08/2008, published on 04/16/2009, and granted on 03/04/2010 a propulsion system with nozzle for ships in free navigation condition is presented. The rest of the nozzles that are used

Currently, apart from the three mentioned above, they are for trawlers

and tugs, such as the "37" and "38" nozzles developed by "MARIN"; "AHT"

developed by "MAN Diesel &Turbo"; another one developed by Josip Gruzling,

DE3840958 (A1) with date of submission 06/02/1987 and date of publication

5

06/07/1990, also published as US4789302 (A), marketed by a company

Canadian; and "Rice thrust." Trawlers use both the condition of

Free navigation for your trips to fishing sites as the condition

of drag for its specific task and it is for this reason that many use the nozzle

"19A" when traveling fuel consumption prevails, as the

1 o

nozzles specifically designed for dragging or pulling in the navigation condition

free give very low performance; in drag or pull condition the coefficient of

Feed J is very low and the total tensile coefficient KTT is very high. For ships

military decelerating symmetric nozzles are used.

In the nozzles "19A" and "HR" for ships currently used in condition of

fifteen

free navigation, the rounded leading edge has a radius of curvature in profile

from 0.01410 for "19A" and 0.0216D for "HR"; the sweeping plane of the center of the

blade tips of the propeller perpendicular to the axis of symmetry of the nozzle is at the

same distance from the inlet edge of the nozzle as from the trailing edge of the nozzle

nozzle; in profile the line tangent to the convex convex inner surface at 0.046L

twenty

downstream of the inlet edge forms an angle with the axis of symmetry of the nozzle

higher than 34 ° at the "HR" and "Rice speed" nozzles and above 40 ° at the "19A" nozzle.

The nozzles that are currently used produce a lot of resistance (drag) in

comparison with the power used especially when navigating with indexes of

CT load less than value 3, in the free navigation condition.

25

Documentary References:

US5799394 (A) priority 05/02/1996, published 01/09/1998

DE4325290 (A1) priority 07/28/1993, published 02/02/1995

W08911998 (A1) priority 06/01/1988, published 12/14/1989

JP58085792 (A) priority 11/16/1981, published on 05/23/1983

30

JP52099597 (A) priority 02/17/1976, published 08/20/1977

US2139594 (A) priority 08/02/1936, published on 12/06/1938

The technical problem that currently exists is the relatively low performance of the

propulsive systems for ships in free navigation condition with speed of

35

cruise up to a maximum of 18 knots (which is the limit for current nozzles) by

losses in the effective wake (called axial losses), due to losses of

drag of the nozzle and by the low coefficient of support Cl that is obtained with

the current profiles for CT load indexes below the value 3. The effort to achieve greater performance in the propulsive systems has been constant by all researchers and research groups of both companies and universities, especially since the crisis of oil from 1973 to the present.

The technical advantage provided by this invention lies in reducing axial losses, greatly reducing the drag of the nozzle, and significantly increasing the coefficient of lift Cl with the consequent acceleration of water in the plane of sweeping of the propeller, all of which combined contributes to a significant increase in the efficiency of the propulsive system.

Explanation of the invention. The solution to the technical problem raised above consists in the use of a fixed symmetrical accelerator nozzle for watercraft in free navigation condition, which comprises: In the sense of general water circulation, first a converging convex interior surface, then an interior surface cylindrical and finally a divergent convex interior surface, with the final part downstream presenting a very pronounced divergence of more than 500 with respect to the axis of symmetry of the nozzle; the UD ratio is between 0.40 and 0.60, with L being the axial length of the nozzle profile and O the inside diameter of the nozzle; with a single nozzle for each propeller; the converging inner surface is joined to the outer surface by means of a toroidal surface, with circumference as a generatrix, forming the inlet edge of water in the nozzle, and the divergent inner surface and the outer surface of the nozzle coincide in a living edge (not rounded), forming the trailing edge of the water from the nozzle; the profile of the nozzle is exactly the same at 3600 coverage. According to the invention, the line containing the nozzle profile rope, which runs from the front end of the inlet edge to the rear end of the outlet edge, forms an angle with the axis of symmetry of the nozzle, of such that they intersect at a point upstream of the nozzle (to increase the coefficient of lift Cl with respect to the current nozzles where the crossing occurs downstream); the difference between the outer radius of the nozzle and the inner radius of the nozzle is between 0.0500 and 0.0760, (to considerably reduce the drag of the nozzle, because for load coefficients below the value 3 the influence of the suction of the propeller does not reach greater radial distance); the outer surface of the nozzle is cylindrical along its entire axial length from the leading inlet edge to the trailing edge of the water in accordance with the general direction of water circulation (to avoid detachment of the boundary layer in this area and therefore the turbulence); the entrance edge, with circumference as a generatrix of the toroidal surface, has a radius of curvature in profile, of said circumference, between 0.010190 and 0.0040 (so that the penetration of the nozzle in the fluid causes less resistance); The scanning plane of the center of the propeller blade tips, perpendicular to the axis of symmetry of the nozzle, is closer to the inlet edge of the nozzle than to the outlet edge of the nozzle (so that the suction effects of the propeller are more noticeable on the convergent inner surface which results in greater thrust of the nozzle); in the profile of the nozzle the line tangent to the convex inner surface converging by a point at an axial distance of 0.046L downstream of the inlet edge, forms an angle with the axis of symmetry of the nozzle between 20 ° and 30 ° (as a point to define a characteristic slope that has a lot of influence on the strength of the profile); and the axial length of the posterior divergent surface is manifestly greater than the axial length of the anterior convergent surface between 15% and 25% (to delay the detachment point of the boundary layer, having a less pronounced divergence, up to section of pronounced divergence of more than 50 °).

Specifically, the difference between the outer radius of the nozzle and the inner radius of the nozzle is 0.0630; the UD ratio is 0.4970; the inlet edge of the nozzle has a radius of curvature in profile of 0.010190; the scanning plane of the center of the propeller blade tips perpendicular to the axis of symmetry of the nozzle is located at a distance of the leading edge of 0.4564L; and in the profile of the nozzle the line tangent to the convex inner surface converging by a point at an axial distance of 0.046L downstream of the inlet edge, forms an angle with the axis of symmetry of the nozzle of 26 °.

This fixed symmetric accelerator nozzle for watercraft in free navigation condition, is part of a floating or underwater watercraft, with an engine that is attached and imparts turning movement to the propeller shaft of the propulsion system constituted by the propeller and said nozzle .

The nozzle with all these characteristics acts together with the propeller (influence

or mutual interaction), increasing the performance of the propeller-nozzle system, compared to those currently used, which are naturally the most efficient to date.

This symmetrical nozzle, having a profile with greater peripheral length inside than outside, from the leading edge to the trailing edge, is a water speed accelerating nozzle inside the nozzle; decelerating nozzles such as the "33" nozzle of "MARIN" have a profile with greater outer peripheral length and are only used in military vessels to reduce cavitation and noise, especially if lower performance is obtained even than with an open propeller, in order to make detection more difficult; the line that contains the rope of the profile that goes from the center of the rounded anterior edge to the living edge of the trailing edge, intersects with the axis of symmetry of the nozzle upstream of it, thereby presenting a greater angle of attack With respect to the general direction of water entering to the nozzle (which is always convergent even with low CT load indexes), the lift coefficient Cl is greater and therefore the acceleration caused by this concept of the nozzle to the water that flows through it ; as it is well known at greater acceleration, greater efficiency of a nozzle, and as it is designed for CT load indices equal to or less than value 3, there is no risk of reaching values of the lift coefficient Cl greater than 1.5 with loss input; As is known, the higher the CT load index, the greater the angle presented by the general direction of the water inlet towards the nozzle with respect to the axis of symmetry of the nozzle, whereby for load indices for example 4.5 and higher, the angle of attack is positive on nozzles "19A", "HR" and "Rice speed", for lower loading rates on these nozzles, although the angle of attack is negative, there is still lift and therefore water acceleration inside the nozzle, because they are asymmetric profiles. Since the acceleration exerted by this nozzle is greater, the thrust coefficient of the propeller 't is lower for the same speed of the ship and therefore this increases efficiency; in the decelerator nozzles the thrust coefficient of the propeller 't is greater than the unit and therefore decreases the efficiency of the propulsive propeller-nozzle system as a whole. The notable minor difference between the outer radius of the nozzle and the inner radius causes a minimum drag for load indexes of value 3 or lower. Axial losses in the effective wake are reduced, since the nozzle, having the trailing edge with the maximum radius, induces the liquid vein that passes through the inside of the nozzle to reach said maximum radius downstream to join with the water coming from the cylindrical outer surface, with which increasing the diameter of the liquid vein increases the static pressure in this posterior area which is transmitted to the propeller-nozzle system as an increase in thrust and most importantly decreases the speed difference of the liquid vein downstream of the nozzle with respect to the speed of the surrounding water, whereby axial losses due to friction and turbulence in the effective wake considerably decrease. The final truncation of the nozzle with a divergence greater than 50 °, implies the detachment of the boundary layer in a plane very close to the plane of the trailing edge, where it is profitable from the point of view of efficiency, since the reverse flow in the wall it is scarce and a free expansion of the liquid vein is allowed until reaching the peripheral current from the cylindrical outer surface of the nozzle to join both downstream; lengthening the nozzle would lead to greater drag by friction. According to the observation of the flow in the cavitation tunnel, with a scale model of the "HR" nozzle that is currently used, the shedding of the boundary layer for values of the load index between 3 and 1.5 occurs in said "HR" nozzle before final truncation; With the proposed nozzle, since it presents less divergence to the truncation zone, due to its longer length, the detachment point of the boundary layer is delayed, which favors a greater free expansion of the liquid vein until it joins with the peripheral current from the cylindrical outer surface. To date, no symmetric nozzle has been constructed with a difference between the outer radius and the inner radius so small, since it has been considered that reducing the normal area (projection of the nozzle on a plane perpendicular to the axis of symmetry) would reduce its efficiency.

This proposed nozzle has the advantage of increasing the propulsive performance of the propeller-nozzle assembly and therefore reducing fuel consumption in the same proportion, in all types of watercraft in free navigation condition up to a cruising speed exceeding 20 knots , regarding the propulsive systems that are currently used; all ships whose function is towing or towing are left out, as well as all semi-planner and glider ships where both the open propeller and the water jet systems are more efficient.

Description of the drawings.

Next, we will describe a series of drawings that help to understand better the invention and presented as an illustrative and non-limiting example thereof. Figure 1 is a schematic representation in axial section of the nozzle. Figure 2 is a schematic representation of the profile of the nozzle with representation of the rope and other details. Figure 3 is an enlarged detail of the front part of the nozzle profile.

Figure 4 is a schematic representation of the propeller assembly, nozzle and nozzle supports, seen from downstream. Figure 5 is a schematic representation of the propeller system and fixed nozzle with respect to the propeller, in vertical section of the nozzle by a plane containing the axis of rotation of the propeller; and in view the propeller is represented with the blades and the core (hub), the horn (rear support of the propeller shaft), the elbow, a nozzle holder and the rudder; forming part of a ship, so that the details of the set can be well appreciated.

Detailed statement of a preferred embodiment. Figure 1 shows the front part 1 of the nozzle, the central part 2 of the nozzle and the rear part 3 of the nozzle; the axial length A of the front part, the axial length B of the central part and the axial length e of the rear part; the nozzle 4. the inlet edge 5 of the water in the nozzle and the outlet edge 6 of the water in the nozzle. observing how the inner walls are convergent convexes in the direction of flow in the anterior part. then the surface is straight and therefore cylindrical and then convex divergent to the rear end; This figure shows how the outer walls 8 of the profile are. straight with the same distance to the axis of symmetry 7 of the nozzle in all its axial extension and therefore the outer surface is cylindrical; the nozzle 4 has a greater thickness in the central part; the axial length e of the posterior divergent surface is 20% greater than the axial length A of the anterior convergent surface; the inner radius Ri of the nozzle, the outer radius Ro of the nozzle and its difference S of 0.0630 which coincides with the maximum thickness of the nozzle are also observed. Figure 2 shows the profile of the nozzle in which the rope 9 is represented by a line that goes from the front end of the entrance edge to the rear end of the exit edge; the scan plane 10 of the center of the propeller blade tips perpendicular to the axis of symmetry of the nozzle. represented by dashed line, observing how the axial distance H of 0.4564L to the leading edge is less than the axial distance E to the leading edge; the tangent line 11 to the profile is also represented by a point located at an axial distance F of 0.046L downstream of the inlet edge forming an angle a with a line 12 parallel to the axis of symmetry of the nozzle of 26 °. Figure 3 shows the current line G indicating the direction and general direction of the upstream fluid. immediately before entering the front of the nozzle. part of the rope 9 and the angle 13 that form both directions are also observed, in the same plane that contains the axis of symmetry of the nozzle; and also the radius r of the circumference generated by the toroidal surface of the inlet edge is observed, with the axis of rotation being the axis of symmetry of the nozzle; said radius r of the circumference has a value of 0.010190 and naturally the leading edge of the complete nozzle has a toroidal surface. In figure 4, the blades 14, the blade tips in the form of an arc coaxial to the axis of rotation, the direction of rotation of the blades indicated by arrow, the core (hub) of the propeller, and the supports 13 of the nozzle 4 that joins is at the stern of the ship, not shown in this figure. In figure 5, the nozzle 4, the propeller with its blades 14, the rudder 15, one of the two supports 13 of the nozzle, and the elbow 16 belonging to the vessel is observed. The core of the propeller (central part of the propeller) is attached to the tree and this to the ship's engine. The motor shaft passes through the interior of the horn that acts as a support at the stern end of the hull. According to the propeller-nozzle propulsion system, the rotating propeller causes less static pressure in front and greater static pressure behind, such pressures are also transmitted locally on the interior walls of the nozzle, whereby the nozzle pushes the vessel with the axial component, through the supports that connect it to the stern of the ship. Both the propeller and the nozzle push the vessel, both forming the propulsion system. The propulsion system is part of the ship. The nozzle protects the propeller from most shocks with external elements and therefore from irreversible deterioration; and also of networks and cables that could temporarily disable it.

The profile coordinates are the following for a four-blade "Kaplan" type propeller, ratio of areas AE / Ao = 0.60 and ratio UD = 0.4970; according to the ordinary representation for coordinates of nozzle profiles, the value of the abscissa is set to 100 XlL taking the values of X from the leading edge; 100 Yi / L for the value of the ordered interiors; and 100 Yo / L for the value of

the outer ones:

100 XlL

100 Yi / L 100 Yo / L

0.000

10.7648 10.7648

2,051

8.1527 12.8158

4,615

6.7280 12.8158

7,179

5.5407 12.8158

9,743

4,5908 12.8158

12,307

3.7201 12.8158

14,871

2.9286 12.8158

17,435 2.2162 12.8158

20,000 1,588 12.8158

22,564 1,0289 12.8158

25.128 0.6332 12.8158

27.692 0.3166 12.8158

30,256 0.0791 12.8158

32,820 0.0 12.8158

58,974 0.0 12.8158

66.666 0.1583 12.8158

71,794 0.3957 12.8158

76.923 0.8706 12.8158

82.051 1.5039 12.8158

84.615 1.9788 12.8158

87,179 2.5328 12.8158

89,743 3,161 12.8158

92,307 4.0368 12.8158

94.871 5.0657 12.8158

96,153

5,690 12.8158

97,435

6.4905 12.8158

98,717

7.5986 12.8158

100,000 12.8158 12.8158 The center of rotation of the radius r of the generating circumference of the toroidal surface of the entry edge is set at abscissa 100XlL = 2.051 and ordered 100Y / L = 10.7648; The length of the radius has the same value as the abscissa.

Industrial application.

This invention has industrial application in the naval industry.

Claims (4)

 1.-Fixed symmetric accelerator nozzle for watercraft in free navigation condition, which comprises: in the sense of general water circulation, first a convergent convex interior surface, then a cylindrical interior surface and finally a divergent convex interior surface, with the final part downstream presenting a very pronounced divergence of more than 50 ° with respect to the axis of symmetry of the nozzle; the LID ratio is between 0.40 and 0.60, with L being the axial length of the profile of the nozzle and O the inside diameter of the nozzle; with a single nozzle for each propeller; the converging inner surface is joined to the outer surface by means of a toroidal surface, with circumference as a generatrix, forming the inlet edge of water in the nozzle and the divergent inner surface and the outer surface of the nozzle coincide in an edge, forming the trailing edge of the water from the nozzle; the profile of the nozzle is exactly the same at 3600 coverage; characterized in that, the line containing the rope (9) of the nozzle profile, which runs from the front end of the inlet edge to the rear end of the outlet edge, forms an angle with the axis of symmetry (7) of the nozzle, so that they intersect at a point upstream of the nozzle; the difference between the outer radius (Ro) of the nozzle and the inner radius (Ri) of the nozzle is between 0.0500 and 0.0760; the outer surface (8) of the nozzle is cylindrical along its entire axial length from the leading inlet edge to the trailing edge in accordance with the general direction of water circulation; the leading edge, with circumference as a generatrix of the toroidal surface, has a radius (r) of curvature in profile, of said circumference, between 0.010190 and 0.0040; the scanning plane (10) of the center of the propeller blade tips, perpendicular to the axis of symmetry of the nozzle, is closer to the inlet edge of the nozzle than to the outlet edge of the nozzle; in the nozzle profile the tangent line (11) to the convergent convex inner surface (1) by a point at an axial distance (F) of 0.046L downstream of the inlet edge, forms an angle (a) with the axis of nozzle symmetry between 20 ° and 30 °; And the axial length (C) of the posterior divergent surface is manifestly greater than the axial length (A) of the anterior convergent surface between 15% and 25%. 2.-Fixed symmetric accelerator nozzle for watercraft in free navigation condition, according to claim 1, characterized in that the difference between the outer radius (Ro) of the nozzle and the inner radius (Ri) of the nozzle is 0.0630; the LID relationship is of 0.4970; the inlet edge of the nozzle has a radius (r) of curvature in profile of 0.01019D; the scanning plane (10) of the center of the propeller blade tips perpendicular to the axis of symmetry of the nozzle is located at a distance of the leading edge of 0.4564L; and in the nozzle profile the line tangent to the inner surface 5 convex convergent by a point at an axial distance of 0.046L downstream of the inlet edge, forms an angle with the axis of symmetry of the nozzle of 26 °. 3.-Fixed symmetric accelerator nozzle for watercraft in free navigation condition, according to claim 1 or 2, characterized in that it is part of a floating or underwater aquatic ship 10, with an engine that is attached and imparts turning movement to the propeller shaft of the propulsion system constituted by the propeller and said nozzle.