This application claims priority to Korean Patent Application No. 10-2013-0050147, filed on May 3, 2013, which is incorporated herein by reference in its entirety.
1. Field of the Invention
Exemplary embodiments of the present invention relate to a cylindrical underwater vehicle with a propulsion control blade mounted to the rear thereof for controlling propulsion of the underwater vehicle; and, particularly, to a cylindrical underwater vehicle with a vertical end plate attached to a partially movable rudder, including a vertical end plate which is formed to have a regular width in a longitudinal direction of the underwater vehicle and is mounted on a circumference thereof in order to improve a control force for the underwater vehicle.
2. Description of Related Art
A cylindrical underwater vehicle, such as a torpedo moving under water, includes, at the rear thereof, a propeller to generate a propulsive force, a duct to protect the propeller, propulsion control blades to control a propulsion direction of the cylindrical underwater vehicle under water, etc.
For example, a propulsion control blade as shown in
Such a partially movable rudder allows overall movement of the underwater vehicle to be controlled by the fixed plate 121 and additionally rotates the movable plate 122 by a desired angle, so that the propulsion of the underwater vehicle may be accurately controlled.
However, the partially movable rudder of the cylindrical underwater vehicle according to the prior art cannot help having a limited shape.
Since the cylindrical underwater vehicle such as a torpedo has a maximum diameter equal to or less than an inner diameter of a launch tube, the partially movable rudder, namely, the fixed plate 121 and the movable plate 122 cannot help being limited in size and shape.
According to the propulsion control blade of the prior art, due to the above-mentioned limit of the shape, a vortex is generated at an edge portion of the propulsion control blade while fluid moves from a high-pressure portion to a low-pressure portion by a pressure difference between opposite surfaces of the propulsion control blade.
For example,
Since such a vortex causes a reduction in lift and an increase in resistance, the propulsive force of the underwater vehicle may be decreased and further the underwater vehicle may not be accurately controlled.
An embodiment of the present invention is directed to a cylindrical underwater vehicle with a vertical end plate attached to a partially movable rudder, including a vertical end plate which is formed in a radial direction of the underwater vehicle so as to improve a control force and decrease a drive moment by reducing a vortex at an upper end portion of a movable plate or a fixed plate in a propulsion control blade of the cylindrical underwater vehicle.
Other objects and advantages of the present invention can be understood by the following description, and become apparent with reference to the embodiments of the present invention. Also, it is obvious to those skilled in the art to which the present invention pertains that the objects and advantages of the present invention can be realized by the means as claimed and combinations thereof.
In accordance with an embodiment of the present invention, a cylindrical underwater vehicle with a vertical end plate attached to a partially movable rudder, including a fixed plate formed to radially extend, and a movable plate, a front end of which is rotatably mounted to the rear of the fixed plate, includes a first vertical end plate which is formed to have a regular width in a longitudinal direction of the underwater vehicle at an upper end portion of the movable plate and is mounted perpendicular to the movable plate.
The first vertical end plate may have an arc-shaped upper side in section.
The first vertical end plate may have the upper side in section, formed to have the same curvature as an inner surface of a launch tube into which the underwater vehicle is loaded and launched.
The fixed plate and the movable plate may be provided in plural numbers to be arranged along a circumference of the underwater vehicle at equal intervals by a given angle, and the first vertical end plate may be formed for each of the plural movable plates.
The cylindrical underwater vehicle may further include a second vertical end plate which is formed to have a regular width in a longitudinal direction of the underwater vehicle at an upper end portion of the fixed plate, is mounted perpendicular to the fixed plate, and is formed in a circumferential direction of the underwater vehicle.
The second vertical end plate may have an arc-shaped upper side in section.
The second vertical end plate may have the upper side in section, formed to have the same curvature as an inner surface of a launch tube into which the underwater vehicle is loaded and launched.
The fixed plate may be provided in plural numbers to be arranged along a circumference of the underwater vehicle at equal intervals by a given angle, and the second vertical end plate may be formed for each of the plural fixed plates.
A front end of the first vertical end plate may have an arc shape, and a rear end of the second vertical end plate may be formed to come into linear contact with the front end of the first vertical end plate.
The rear end of the second vertical end plate may be formed to have the same curvature as the front end of the first vertical end plate.
Exemplary embodiments of the present invention will be described below in more detail with reference to the accompanying drawings. The present invention may, however, be embodied in different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete, and will fully convey the scope of the present invention to those skilled in the art. Throughout the disclosure, like reference numerals refer to like parts throughout the various figures and embodiments of the present invention.
Hereinafter, a cylindrical underwater vehicle with a vertical end plate attached to a partially movable rudder according to embodiments of the present invention will be described with reference to the accompanying drawings.
The cylindrical underwater vehicle 10 with a vertical end plate attached to a partially movable rudder according to embodiments of the present invention includes vertical end plates 23a and 23b which are formed to have a regular width in a longitudinal direction of the underwater vehicle 10 at respective upper end portions of a movable plate 22 and a fixed plate 21 and are mounted on a circumference thereof so as to be perpendicular to the movable plate 22 and the fixed plate 21.
A first vertical end plate 23a is mounted at the upper end portion of the movable plate 22 so as to be perpendicular to the movable plate 22 in a longitudinal direction thereof.
The first vertical end plate 23a is mounted at the upper end portion of the movable plate 22, namely, at a position farthest away from an axial center of the underwater vehicle 10.
In addition, the first vertical end plate 23a is formed in the longitudinal direction of the movable plate 22. Here, the first vertical end plate 23a may be formed along a portion of a length of the movable plate 22, and preferably be formed all over the length of the movable plate 22.
In this case, the first vertical end plate 23a is mounted perpendicular to the movable plate 22. Since the first vertical end plate 23a and the movable plate 22 are mounted perpendicular to each other, the first vertical end plate 23a is formed to have a regular width in the longitudinal direction of the underwater vehicle 10.
Accordingly, the first vertical end plate 23a has a “T” shape when viewed from the rear in a state of being mounted to the movable plate 22.
Particularly, since the underwater vehicle 10 is loaded into a launch tube 15 and an upper surface of the first vertical end plate 23a is tightly closed to an inner surface of the launch tube 15, an upper side of the first vertical end plate 23a which comes into contact with the inner surface of the launch tube 15 has an arc shape in section (see
More preferably, the upper surface of the first vertical end plate 23a is formed to have curvature equal to the inner surface of the launch tube 15.
The fixed plate 21 is mounted in plural numbers along the circumference of the underwater vehicle 10 at equal intervals by a given angle, and the movable plate 22 is mounted for each fixed plate 21. Consequently, the first vertical end plate 23a is also provided in plural numbers to be arranged along the circumference of the underwater vehicle 10 at equal intervals by a given angle.
A second vertical end plate 23b is formed at the upper end portion of the fixed plate 21 so as to have a regular width in a longitudinal direction of the fixed plate 21, and is mounted perpendicular to the fixed plate 21.
The second vertical end plate 23b is also formed at the outermost upper end portion of the fixed plate 21 so as to be tightly closed to the inner surface of the launch tube 15.
The second vertical end plate 23b may be formed along a portion of a length of the fixed plate 21, as shown in
In addition, since the second vertical end plate 23b is formed perpendicular to the fixed plate 21, a connection portion of the fixed plate 21 and the second vertical end plate 23b has a “T” shape in section.
Moreover, an upper side of the second vertical end plate 23b which comes into contact with the inner surface of the launch tube 15 has an arc shape in section. Preferably, the arc shape is formed to be equal to the curvature of the inner surface of the launch tube 15, and thus the upper surface of the second vertical end plate 23b is tightly closed to the inner surface of the launch tube 15. Here, the second vertical end plate 23b preferably has the same cross section as the first vertical end plate 23a, and particularly the upper sides of the first and second vertical end plates 23a and 23b are preferably formed to be equal to each other in section.
The second vertical end plate 23b is preferably formed for each fixed plate 21 which is provided in plural numbers along the circumference of the underwater vehicle 10.
Such a second vertical end plate 23b preferably has the same sectional structure as the first vertical end plate 23a.
In addition, a rear end of the second vertical end plate 23b is formed to come into contact with the first vertical end plate 23a.
In this case, since the movable plate 22 formed with the first vertical end plate 23a is rotatably mounted relative to the fixed plate 21 formed with the second vertical end plate 23b, a front end of the first vertical end plate 23a has an arc shape and the rear end of the second vertical end plate 23b is formed to be spaced apart from front end of the first vertical end plate 23a by a predetermined distance. Particularly, the rear end of the second vertical end plate 23b is preferably formed to have the same curvature as the front end of the first vertical end plate 23a.
The following description will be given of an operation of the cylindrical underwater vehicle with a vertical end plate attached to a partially movable rudder according to embodiments of the present invention having the above configuration.
The first vertical end plate 23a is formed at the upper end portion of the movable plate 22. Thus, a vortex generated due to a pressure difference at the end portion of the movable plate 22 is reduced, thereby improving a control force of a propulsion control blade, namely, of a partially movable rudder.
To this end, when modeling the movable plate 22 and the first vertical end plate 23a in the partially movable rudder to view the distribution of a vorticity field depending on whether the first vertical end plate 23a exists or not, it may be seen that the vortex generated at the end portion of the movable plate 22 is reduced by the first vertical end plate 23a.
That is,
When comparing the above result to
Meanwhile,
Since the movable plate 22 is rotatably mounted to the fixed plate 21, the force acting depending on the rotation angle in the Y direction is varied. This is shown in
Moreover,
Accordingly, when synthetically viewing
In accordance with a cylindrical underwater vehicle with a vertical end plate attached to a partially movable rudder according to the exemplary embodiments of the present invention, it may be possible to reduce a vortex generated at an end portion of a fixed plate or a movable plate by a vertical end plate mounted on a circumference of the underwater vehicle at the end portion of the fixed plate or the movable plate.
Since the vortex is reduced at the end portion of the fixed plate or the movable plate, it may be possible to decrease a reduction in lift and an increase in resistance due to the vortex. As a result, it may be possible to enhance a control force of a propulsion control blade with respect to the underwater vehicle.
In addition, since the control force of the propulsion control blade with respect to the underwater vehicle is enhanced, it may be possible to decrease a drive force required to drive the movable plate in the propulsion control blade in order to generate the same control force.
Furthermore, since a less drive force is required to exhibit the same control force, design degrees of freedom for a space of the rear of the cylindrical underwater vehicle may be improved and the size of components required for drive may be minimized. Therefore, additional devices such as a proximity magnetic sensor may be installed in such an additionally obtained space.
While the present invention has been described with respect to the specific embodiments, it will be apparent to those skilled in the art that various changes and modifications may be made without departing from the spirit and scope of the invention as defined in the following claims.
Number | Date | Country | Kind |
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10-2013-0050147 | May 2013 | KR | national |
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Entry |
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Chulmin Jung et al., “Flow Analysis Around a Partially Movable Control Fin with End Plate,” The Korea Institute of Military Science and Technology 2012 Annual Conference, 2012. |
Number | Date | Country | |
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20140326169 A1 | Nov 2014 | US |