This application claims priority to Republic of Korea application number 10-2007-0109929, filed on Oct. 31, 2007, which is hereby incorporated by reference in its entirety.
The present invention relates to a method for manufacturing a composite sabot, and more specifically, to a method for manufacturing a fiber-reinforced composite sabot for use in APFSDS (Armor Piercing Fin Stabilized Discarding Sabot) which is required to endure high pressure, wherein both Band lamination and Hoop lamination are used in manufacturing a polymer based FRP (Fiber Reinforced Plastic) for use in the sabot in order to prevent the prepreg delamination in the circumferential direction caused by the radial lamination.
Aluminum alloy is generally used for manufacturing the sabot for the APFSDS which is used for antitank guns. However, by using high-strength fabric-reinforced composite material having lower density than the aluminum for the sabot, the speed of the shell can be increased with the same energy thereby enhancing the power of the shell. Therefore wide range of research has been made in the field to manufacture lighter and more powerful sabot by replacing the metal sabot with the sabot made from polymer based fiber-reinforced material having specific strength.
The sabot is combined to the outer surface of the penetrator with three separable pieces and guides the sabot in the gun barrel, delivers the propulsive force to the penetrator, and is separated from the penetrator after the penetrator is propelled from the barrel, playing the role of structurally supporting the sabot and preventing leakage of pressure in the barrel. Therefore the weight of the sabot is very important in improving the performance of the whole system, and by making the sabot as light as possible, more propulsive force is delivered to the penetrator. Also, in order to deliver the propulsive force to the penetrator more efficiently, on the inner portion of the sabot is formed a concave-convex combining surface in the form of spiral or groove on the contacting surface with the penetrator. The outer portion of the sabot is formed so that the sabot closely contacts the barrel thereby sealing the barrel so that the pressure for the propulsive force is maintained. After the penetrator is separated from the barrel, the sabot is separated from the penetrator by friction with the air without affecting the propulsion of the penetrator.
Between the outer portion of the penetrator 2 and the inner portion of the corresponding sabot 3, is formed a concave-convex combining part 2a, 3a in the form of spiral or groove, and this concave-convex combining part 2a, 3a is formed not to be damaged considering the shearing stress from the propulsion force. The sabot produced by the conventional method is made from aluminum, and although presents no problem in endurance considering the shearing stress required at the time of propulsion, relatively high weight compared to the composite sabot causes problem in important properties of the penetrator such as aviation velocity, penetration strength on the target and other overall properties of the system.
Also, it is known that lamination in the radial direction has been adopted since the conventional lamination method in the axial or circumferential direction cannot obtain the required mechanical strength of the groove. Lamination in the radial direction uses prepreg made of unidirectional fiber or fabric fiber/resin, and the prepreg ply is laminated in perpendicular direction on the groove surface contacting the penetrator thus providing much improved shear strength compared to the above mentioned conventional lamination method in the axial or circumferential direction. However, while the required strength in the same or perpendicular direction of the surface contacting the penetrator is obtained in the radial direction lamination method, there is a problem of low adhesive strength in the direction in which the prepreg ply is laminated, and so there has been need for developing technology that can improve this strength.
Until recently, the patent applications relating radial directional lamination has been directed to the lamination technology or orientation of the fiber, for example U.S. Pat. No. 5,640,054 (Sabot segment molding apparatus and method for molding a sabot segment), and U.S. Pat. No. 5,789,699 (Composite ply architecture for sabot) and U.S. Pat. No. 6,125,764 (Simplified tailored composite architecture). The method of using high strength resin can be considered in order to reinforce the material property in the laminating direction, but the cost will be increased due to the high price of the material and complex manufacturing method.
The conventional composite sabots manufactured by the radial or circumferential laminating method also generated the delamination phenomenon from the severe bending of fiber.
The present invention has been designed to solve the above mentioned problems of prior arts, by using the Band/Hoop lamination on the outer lamination layer in the radial direction in order to prevent the prepreg delamination phenomenon and to provide an endurance from the circumferential high expansion forces.
Also the method of the present invention improved the form of lamination in segment lamination preventing the delamination problem stemming from the distortion of the fiber and also preventing the damage of the 120 degree surface when treating the sabot in manufacturing.
To solve the above problems of the prior arts, the present invention provides a method for manufacturing a fiber-reinforced composite sabot by laminating the prepreg fiber in the radial direction comprising a sub-segment forming step wherein four or more of sub-segments are formed with predetermined form by superposing a plurality of plies,
It is preferable that the reinforcing step further comprises, along with the step of laminating bands, a step of superposing two or more of plies and continuously laminating hoop on the arc surface of each piece.
Also it is preferable that a sub-segment forming step further comprises forming preliminary laminated board by superposing a plurality of plies.
Also it is preferable that the reinforcing step include further laminating the first sub-segment on the 120 degree surface.
Finally, the prepreg fiber material laminated in the radial direction is favorably one or more of fiber chosen from the group consisting of carbon fiber, graphite fiber and glass fiber, and the fiber prepreg fiber material is thermosetting or thermoplastic resin.
According to the method for manufacturing a fiber-reinforced composite sabot by band/hoop lamination method of the present invention, the weight of the sabot can be reduced by 30% compared to the conventional aluminum sabot. Also, the band layer protects the sabot from the expansion pressure resulting from the high impact energy inside the barrel, and the hoop layer delivers the propulsion pressure 150 to the sabot uniformly thus protecting the sabot in the outermost surface and providing optimal design requirement that can endure the destructing force of the sabot.
a) shows the configuration of the sub-segment composing a segment.
b) is a cross sectional view showing laminated sub-segment.
c) is a perspective view of a segment composing a piece.
a) is an enlarged view of the side of the piece composing a sabot.
b) is a cross sectional view showing the piece composing a sabot.
c) is a perspective view showing the piece composing a sabot.
Example of the present invention will be described with reference to the drawings attached.
In the perspective view of
The laminated plies can be used to form a sub-segment with predetermined form, or, more preferably, can be used to form a preliminary laminating plate 60 by superposing a plurality of plies as shown in
b) is a cross sectional view showing laminated sub-segment 70. The segment 80, in the form as shown in
At this step of radial directional lamination, band 90 is laminated on both 120 degree surfaces 10 and outer surface of arc surface 20 in order to prevent delamination of radial lamination due to the high expansion pressure at the time of firing. In this case, even when the band 90 is laminated on only one of the two 120 degree surfaces and arc surface 20 of each piece 140, the combining surface (120 degree surface) of the piece 140 and outer circumferential surface (arc surface) are all formed in the form reinforced by band 90 when three pieces 140 are combined since three pieces 140 are combined to form a sabot 160.
It is preferable to laminate hoop 100 on the arc surface 20 of the piece 140 to obtain further mechanical strength required in the sabot, since the fiber, as well as the band 90 and resin, can also absorb the expansion force at the time of firing. It is preferable to use the same material and same adhesive in reinforced radial directional lamination and band/hoop lamination. By using this uniform co-curing manufacturing method, delamination between radial directional lamination and band/hoop lamination resulting from the difference between different expansion coefficients of the material can be prevented. Also, in the rear part 120 which receives the most strong propulsion energy in the barrel at the time of firing, it is preferable to form a relatively thicker band/hoop lamination layer in order to secure stable separation of the composite sabot as well as for the prevention of delamination between layers of the radial lamination.
Also, there could be a delamination phenomenon stemming from the distortion of the fiber in radial direction lamination causing damage to 120 degree surface which has been laminated to reinforce the layer. To improve this phenomenon, the reinforcing sub-segment 71 of
In addition, spare processing layer 110 is laminated on the outermost layer of the arc surface of the piece 140 in order to prevent the loss of the design adopted in processing the outermost layer considering spare space in the processing. As shown in
Lastly, the pieces 140 prepared by the above method is inserted into press mold to form fiber reinforced composite sabot 160 as shown in
In forming the preliminary laminating plate by laminating the fiber prepreg ply as described above, forming sub-segment by cutting the preliminary laminating plate, forming a segment by laminating sub-segment and forming the piece by laminating the segment, the required mechanical strength of the sabot can be obtained by using the reinforcement method of band/hoop lamination of the present invention. Also, along with the method of band/hoop lamination of the present invention, the orientation method disclosed by the same applicant in Korean laid open patent application 2004-0024333, 2004-0024334 can be considered in the method of reinforced manufacturing method to obtain desirable mechanical strength of the sabot.
Although the preferable example of the present invention has been described above, it should be understood not to limit the scope of the present invention and any modification can be possible to those skilled in the art within the scope of the claims.
Number | Date | Country | Kind |
---|---|---|---|
10-2007-0109929 | Oct 2007 | KR | national |
Number | Name | Date | Kind |
---|---|---|---|
4372217 | Kirkendall et al. | Feb 1983 | A |
4735148 | Holtzman | Apr 1988 | A |
4953466 | von Gerlach | Sep 1990 | A |
4958571 | Puckett | Sep 1990 | A |
5635660 | McGovern | Jun 1997 | A |
5640054 | McGovern | Jun 1997 | A |
5789699 | Stewart | Aug 1998 | A |
6125764 | Kamdar | Oct 2000 | A |
6186094 | Kamdar | Feb 2001 | B1 |
6241506 | Kassuelke | Jun 2001 | B1 |
6279214 | Kassuelke | Aug 2001 | B1 |
7013811 | Sebasto | Mar 2006 | B1 |
7594472 | Parratt et al. | Sep 2009 | B1 |
Number | Date | Country |
---|---|---|
0982561 | Mar 2000 | EP |
0989382 | Mar 2000 | EP |
Number | Date | Country | |
---|---|---|---|
20090107355 A1 | Apr 2009 | US |