PT104508A - VESSEL - Google Patents

Abstract

VESSEL, ESPECIALLY A FIXED BANK VESSEL SPECIAL FOR DEAD WATERS AND QUICK ROTATION WITH A LITTLE SUBMERSE PART OF THE VESSEL.

Description

1 DESCRIPTION " VESSEL " The object of the invention is a vessel, particularly a fixed-bench vessel in the configuration of which any of the dimensions of any of the keel joints of the vessel with the cava forming it are a direct function of the overall length of said vessel.

In the present state of the art, vessels with their perfectly defined configuration and independent of the dimensions of the vessel itself are known, for example, among others, EP1075414, ES1038670, ES1008645 and ES1002462. The same owner-owner owns the Spanish patent P9702392 which refers to a vessel characterized in that it has a total length (L) consisting of a plurality of joints of the keel of the vessel with the successive cave from the bow to the stern, distributed in pairs separated from each other, pairs 2 to 12 a distance (L / 12) between each successive two; the pairs 1-2 and the pairs 12-13 a distance (L / 24) from each other and the pairs 1 and 13 arranged at a distance (L / 24) from the respective prow-stern end of the vessel. All of the dimensions of said pairs of keel joints of the vessel and the cave are calculated as a function of the length (L) of the vessel, with different ratios for the different dimensions of both the pairs of joints of the keel of the vessel and of the arrangement in the whole of the vessel.

In keeping with this concept, the applicant has designed another special vessel for dead water and rapid rotation with a little submerged part of the vessel, characterized by: a) the pairs of joints of the boat keel with the cave (1) - (13) are defined each one by a single equation continues y = f (x) and are arranged on the abscissa axis X with two different abscissa values for the same ordinate; b) all joints of the keel of the vessel with the cave 1 - 13 are arranged symmetrically in pairs with respect to their y-axis Y and each pair of joints of the keel of the vessel with the cavern 1 - is defined by a single continuous equation y = f (x) in which the two abscissa have the same absolute value and opposite sign.

In order to better understand the object of the present invention, a preferred embodiment is shown in the drawings, which is susceptible of accessory changes which do not detract from its foundation. Figure 1 shows an elevational view of a vessel according to the invention, which full-length hull (C) comprises a plurality of keel joints of the vessel and the cave arranged in pairs identified by references (1) to (13) - both inclusive - from its stern.

Figures 2 to 14 show, in front view, the different pairs of boat keel joints with cave (1) to (13) positioned in the coordinate axes ΟΧ, OY and each defined by their respective continuous equation y = f (x).

An example of a non-limiting practical embodiment of the present invention will now be described.

According to the invention, the full-length (L) vessel case (L) between the bow and stern ends comprises a plurality of keel joints of the vessel and the cave distributed in thirteen pairs separated from each other by equal distances (L / 12) except the first and last distal (L / 24) of both the pair of joints of the keel of the vessel with the nearest cave and the respective end of the vessel - see figure 1-.

According to the invention, the pairs of joints of the keel of the vessel with the cave 1 - (13) are each defined by a single continuous equation y = f (x) and are arranged on the axis of abscissa OX with 4 two different abscissa values for the same ordinate.

All joints of the keel of the vessel with the cave 1 - 13 are symmetrically arranged in pairs relative to their y-axis Y and each pair of joints of the keel of the vessel with the cave 1 - for a single continuous equation y = f (x) in which the two abscissa have the same absolute value and opposite sign.

The different pairs of keel joints of the vessel with the cave (1) - (13) each correspond to a continuous equation y = f (x) which is different for each keel union of the vessel with the cave or pair of keel of the vessel with the cavern (1) - (13).

In figures 2 to 14 the different joints of the keel of the vessel were shown with the cave (1) (13). The points of the graph obtained by giving values to the respective equation continue y = f (x) for each union of the keel of the vessel with the cave (1) - (13) adjust approximately to the following (the first value represents the abscissa (x ) and the second as ordinates (y)):

Union of the keel of the vessel with the cave 1: y = fi (x): A (0,6); B (20, 44); C (34, 120)

Union of the keel of the vessel with the cave 2: y = f2 (x): A (0,4); B (20,18); C (40.51); D (60,107); E (62,113)

Union of the keel of the vessel with the cave 3: 5 y = f3 (x): A (0,3); B (20.8); C (40.18); D (60, 37); E (80.68); F (102,101)

Union of the keel of the vessel with the cave 4: y = f4 (x): A (0,1); B (20.4); C (40.9); D (60,18); E (80.35); F (100.60); G (120.89); H (128.97)

Union of the keel of the vessel with the cave 5: y = f5 (x): A (0,0); B (20.2); C (40.5); D (60.11); E (80.22); F (100.38); G (120.70); H (140.95); I (141.97) Union of the keel of the vessel with the cavern 6: y = f6 (x): A (0,0); B (20.1); C (40.3); D (60.8); E (80, 16); F (100.29); G (120.61); H (140.88); I (145.96) Union of the keel of the vessel with the cave 7: y = f7 (x): A (0,0); B (20.1); C (40.3); D (60.7); E (80,14); F (100.26); G (120.56); H (140.87); I (145.95) Union of the keel of the vessel with the cave 8: y = fe (x): A (0,0); B (20.1); C (40.3); D (60.8); E (80.15); F (100.31); G (120.60); H (140.91); I (142.95) Union of the keel of the vessel with the cave 9: y = f9 (x): A (0,3); B (20.4); C (40.7); D (60.12); E (80.22); F (100.43); G (120.73); H (137.97)

Union of the keel of the vessel with the cave 10: y = wire (x): A (0 6); B (20.8); C (40.12); D (60.20); E (80.35); F (100.60); G (120.85); H (130,100)

Union of the keel of the vessel with the cave 11: y = f ii (x): A (0,8); B (20,12); C (40.21); D (60.36); E (80.62); F (100.89); G (110,100)

Union of the keel of the vessel with the cave 12: y = f 12 (x): A (0,11); B (20, 21); C (40.41); D (60.83); E (69,103) 6

Union of the keel of the vessel with the cave 13 y = fi3 (x): A (0,14); B (20.35); C (37,106)

Lisbon, April 22, 2009

Claims (2)

A vessel, particularly a special vessel for dead water and rapid rotation with a little submerged part of the vessel which, having a total length (L) and consisting of a plurality of keel joints of the vessel with the successive cave from bow to stern distributed in thirteen pairs separated from each other, pairs 2 to 12 with a distance (L / 12) and pairs 1 and 13 arranged at a distance (L / 24) from the respective prow-stern end of the vessel, characterized in that (a) the pairs of joints of the keel of the vessel with the cave (1) - (13) are each defined by a single continuous equation y = f (x) and are arranged on the axis of abscissa OX with two values of different abscissa for the same ordinate; (13) are arranged symmetrically in pairs with respect to their y-axis Y and each pair of keel joints of the vessel with the cavern (1) - (13) is defined by a single continuous equation y = f (x) in which the two abscissa have the same absolute value and opposite sign; (c) the different pairs of joints of the keel of the vessel with the cave (1) - (13) each correspond to a continuous equation y = f (x) such that their points fit approximately to the following values: 2 ABCDEFGHI y = fi (χ) 0, 6 20, 44 34,120 y = f2 (x) 0, 4 20, 18 40, 51 60,107 62,113 II Ht X 0, 3 20, 8 40, 18 60,37 80,68 102.101 y = f4 (x) 0.11 40.4 40.9 60.18 80.35 100.60 120.89 128.97 II H, X0.020.240.5 60.11 80.22 100.38 120.70 140.95 141 97 y = f6 (χ) 0, 0 20, 1 40.3 60.8 80.16 100.29 120.61 140.88 145.96 y = f? (Χ ) 0, 0 20, 1 40.3 60.7 80.14 100.26 120.56 140.87 145.95 y = fe (χ) 0.020.140.3 60.8 80.15 100 , 31 120.60 140.91 142.95 II H) X 0, 3 20, 4 40, 7 60.12 80.22 100.43 120.73 137.97 X Mi II> 8 40, 12 60.20 80.35 100.60 120.85 130.100 y = fn (χ) 0.8 20, 12 40, 21 60.36 80.62 100.89 110.100 y = f 12 (x) 0 , 11 20, 21 40, 41 60, 83 69,103 y = fi3 (χ) 0, 14 20, 35 37,106 Lisbon, April 22, 2009