KR100549486B1 - Shrouded aerial bomb - Google Patents

Abstract

A target penetrating aerial bomb including a penetrating body (24) shaped for improved target penetration, having a narrower impact profile at approximately the same weight as an existing bomb. An aerodynamic shroud (40) encases the penetrating body (24) and emulates the aerodynamic shape of the existing bomb, and the weight, center of gravity, and moments of inertia of the bomb closely approximate those properties of the existing bomb. The bomb according to the invention may be qualified for flight by similarity to the existing bomb, and thus avoid lengthy and costly qualification procedures.

Description

Armored Drop Bomb {SHROUDED AERIAL BOMB}

The present invention relates to a drop bomb, ie a bomb dropped from an aircraft, and more particularly to a drop bomb for a target that is difficult to penetrate.

Bombs typically include a hard casing having an internal hollow space for containing explosive material. The physical properties of the bomb, including its weight, center of gravity, moment of inertia, and aerodynamic shape, all affect the free fall response of the bomb, whether or not it contains a guidance package.

Bombs released from aircraft, including free-fall guided or non-guided bombs, gliding bombs, and booster bombs, must pass rigorous testing experiments, including the safe release from the deploying aircraft and the accuracy of the release to the target. These tests should be performed for each type of aircraft that will carry bombs. Thus, the development of new weapons has significant delays and costs before the weapons are validated for use.

The performance of a bomb or other deposit through a target is proportional to the velocity and mass of the bomb's impact and inversely proportional to the cross-sectional area of the bomb. In other words, the larger the kinetic energy and the smaller the cross-sectional area, the better the permeability that can be expected. However, retrofitting existing bombs by reducing the bomb's outer diameter for better penetration can also lead to changes in mass characteristics such as weight, center of gravity, moment of inertia, and aerodynamics, all of which May affect flight characteristics. This change also requires that the modified bomb be verified in order to be used.

The present invention solves the difficulties in verification by mimicking the appropriate aerodynamic and mass properties of a qualified bomb and provides a drop bomb that provides functionality not provided by this verified bomb.

In particular, the present invention provides bombs with improved penetrating warheads, ie warheads that penetrate more deeply into protected targets, but these bombs are virtually identical to those proven in aerodynamic and mass properties. As a result, the bomb of the present invention can be easily verified by the similarity of function with existing bombs for use on aircraft. In addition, if necessary, the bomb of the present invention may use an existing guide package used for the verified bomb.

In order to avoid long-term and costly delays in verifying new bombs, the present invention provides a bomb that mimics the free fall characteristics of existing bombs involved in the verification while providing a warhead with preferably improved penetration capability. .

According to the present invention, the warhead is a penetrating body shaped for improved target penetrability through a smaller cross-sectional area compared to existing proven bombs. Aerodynamic armor mounted around the warhead mimics the shape, weight, center of gravity, and moment of inertia of the proven bombs (penetration and armor) very closely to these characteristics of existing bombs.

The invention may be more clearly understood with reference to the following detailed description in conjunction with the accompanying drawings.

1 is a side view of a bomb according to the present invention.

2 is a side cross-sectional view of the penetrating body of the bomb of FIG.

FIG. 3 is a perspective exploded view of the bomb of FIG. 1 showing various components of the armored assembly and through body.

4 is a side view of a bomb with a guide package mounted thereon;

5 is a cross-sectional view of the nose portion of an armored warhead showing an attachment structure for a nose guide unit. .

6 is a sectional view of the front clamp of the glove.

7 is a cross-sectional view of the tail of the glove illustrating the mounting structure for the tail fin unit.

1 is a side view of an armored bomb 20 according to the present invention. The bomb 20 includes a penetrating body 24 or warhead (shown in FIG. 2) and armor 40 shaped to mimic the aerodynamic shape of existing proven bombs. In this exemplary embodiment, the bomb 20 is shaped to mimic a BLU-109 / B bomb. That is, the appearance of the glove 40 is substantially the same as that of the hard casing of BLU-109 / B. In addition, the weight, center of gravity and moment of inertia of the bomb 20 are largely identical to these physical properties of the BLU-109 / B.

Thus, the bomb 20 has the same free fall and aerodynamic properties as the bombed bomb, so that the verified bomb can be transported by the verified aircraft. In addition, the bomb 20 can be used in any guidance package appropriate for the simulated bomb. However, the enhanced bomb 20 can be avoided by a long and costly flight verification test because it is verified by the similarity with the verified bomb. Accordingly, the present invention provides improved drop bombs in the function of existing bombs, and has been proven to be used by mimicking handling and drop transport characteristics of existing bombs.

As will be appreciated by those skilled in the art from the following description, the present invention is not limited to mimicking certain validated bombs, such as BLU-109 / B, used herein only as examples, and in other existing bombs. It may also be about an improvement of.

The penetrating body 24 of this exemplary embodiment is designed for improved target penetrating ability. The penetrating body 24 includes a case molded of a hard dense material such as steel, tungsten or depleted uranium. The penetrating body 24 is narrower than the case of the bomb imitated to provide a smaller cross sectional area. The penetrating body 24 has an internal hollow space 26 that may contain explosives. This space 26 opens at the tail end of the body 28 and extends toward the nose 30 leaving the solid nose portion. A bulkhead 32 is attached to the penetrating body 24 to support mounting of a fuse that closes the opening at the tail and activates the warhead, as will be discussed in more detail below.

In the example of BLU-109 / B serving as a proven bomb, the penetrating body 24 is narrower than BLU-109 / B, but has a thicker wall to maintain most of the weight of BLU-109 / B. According to this exemplary embodiment, the penetrating body 24 has a weight (loaded with explosive charge) that is between 80% and 90% of the weight of the BLU-109 / B. The reduced diameter, which generally has the same weight, increases the penetrating ability of the penetrating body compared to BLU-109 / B by concentrating kinetic energy in a smaller impact area. It is to be understood that the present invention is not limited to a specific diameter or weight ratio for the simulated bomb. The diameter and weight of the warhead are selected for the desired penetrating and explosive function, for example, within the conditions of the total weight of the warhead and the glove, which are approximately the same as the weight of the simulated weapon.

The penetrating body 24 is in the form of a conical head with multiple radii of curvature at the nose end 30. The contour of the nose end 30 is connected to a cylindrical central portion 34. Compared to the outer diameter of BLU-109 / B of 370.8 mm (14.6 in) at the center, the outer diameter of the through-body 24 measured at the cylindrical center 34 is 271.8 mm (10.7 in). The thickness of the wall 36 of the penetrating body surrounding the bore 26 is 57.4 mm (2.26 in).

3 is an exploded view of the glove 40 and the penetrating body 24. The glove 40 includes a front clamp 42 and a rear clamp 44 that are spaced apart from the central portion 34 of the penetrating body 24. The clamps 42 and 44 are two-piece structures each having a pair of semi-cylindrical members bolted together around the through body 24. Clamps 42 and 44 are sized to fit the penetrating body 24 to provide a support location for ground handling and storage pallets. Shear pins (not shown) are mounted in the holes in the penetrating body 24 and extend outwardly to engage the engagement holes in the clamps 42, 44. During transportation on the aircraft and during the ground handling of the bomb, the shear pins prevent the clamps 42, 44 from moving longitudinally and rotating about the penetrating body 24.

Alternatively, other mechanical coupling means can be used to prevent the movement of the clamps 42, 44 on the penetrating body 24. For example, the longitudinal grooves formed in the penetrating body 24 may engage ribs extending from the clamps 42 and 44, or the outer surface of the penetrating body 24 and the inner surface of the clamps 42 and 44 may be surfaces. It can be formed as a rough surface to provide increased friction between them.

Shear pins and clamps are designed to have a material strength that breaks under the bombardment force on the target to help penetrating body 24 peel off armor 40 to better penetrate the target.

The upper portion of each clamp 42, 44 includes mounting holes for the lugs 48, 50 for mounting bombs on the aircraft suspension system. The spacing of the lugs 48 and 50 and their positioning with respect to the center of gravity of the bomb 20 of the lugs are the same as for the weapon selected, BLU-109 / B, in the illustrated embodiment.

In the modification of other proven bombs according to the invention, for example, a single clamp may be used depending on space and load transport requirements.

Glove 40 also includes an envelope member formed to form an outer surface and to have the aerodynamic properties of the simulated bomb. The envelope member comprises a nose cone 60 mounted to the nose 30 of the penetrating body 24 and a front tube 62 mounted between the nose cone 60 and the front clamp 42. The nose cone 60 and the front tube 62 are fastened together, and the front tube 62 is fastened to the front clamp 42. The nose ring 64 holds the nose cone 60 in place as shown in Figs. 4 and 5 and provides a mounting structure for the nose guide unit.

The front end 61 of the nose cone 60 is formed in a cylindrical shape and extends longitudinally forward from the penetrating body 24. The forwardly extending cylindrical end 61 is designed to break from the penetrating body 24 to help the penetrating body 24 peel off the front part of the glove upon impact of the warhead on the target.

The upper shell 70 and the lower shell 72 are fastened between the front clamp 42 and the rear clamp 44. The lower shell 72 is made thick enough to facilitate the weight of the bomb during ground handling by conventional lift devices and to typically place the bomb stably on a storage pallet (typically about 1.27 cm (about 0.5 inch)). do. The upper shell 70 includes a switch plate 74 that cooperates with a release indicating switch on the aircraft, which release signal is used to transmit a release signal of the bomb from the aircraft.

To the rear of the rear clamp 44, the shell is completed by the rear tube 76 and tail tube 78. In the illustrated embodiment, the tail tube 78 extends outwardly to resemble the tail shape of the BLU-109 / B. The tail ring 80 is fastened on the tail end of the bomb and the armor and provides a mounting unit for the aerodynamic tail unit such as the tail unit as shown in FIGS. 4 and 7.

Clamps 42 and 44 provide support for ground handling and storage of bombs on shelves, pallets and lifts. Additional support is provided by a support ring installed between the penetrating body 24 and the shell element in the support positions 82, 83 shown by the arrows. The support ring may be, for example, a ring of "T" or "H" profile, and is positioned to connect the space between the shell and the penetrating body 24 in order to easily support the weight of the penetrating body.

The unit 20 shown in FIG. 1 is designed to have the same length, weight, center of gravity and aerodynamic shape as any proven weapon. As will be appreciated by those skilled in the art, the weight and center of gravity can be adjusted by adjusting the weight of the penetrating body 24 or the glove 40 by the addition or removal of material at predetermined locations. For example, the length of the bore 26 or the thickness of the through wall 36 can be easily varied to adjust the weight and center of gravity. Glove components, specifically clamps 42 and 44, may be weighted and / or sized to adjust the center of gravity and overall weight.

4 is a side view of the armored bomb 20 to which the guide package is attached. The guide package includes a nose guide unit 102 having a target sensing device (not shown), and a tail shaping unit 104. The nose guide unit 102 has a fin 106 adjustable by the nose guide unit 102 and a collapsible fin stabilizing assembly to adjust the direction of the bomb during free fall. The guide package comprising the fin does not form part of the present invention except as designed below to accommodate the mounting of the guide package.

As shown in FIG. 5, the nose ring 64 rests on the nose end of the penetrating body 24 and is fastened to the nose cone 60 of the front end of the penetrating body and the glove 40. The nose ring 64 includes a peripheral groove 66 that receives the engagement rib 103 of the nose unit 102. Retention ring 68 secures nose unit 102 to nose ring 64.                 

Figure 7 shows the tail cap mounting arrangement. The tail ring 80 includes a v-shaped groove 84 that engages a conventional ring clamp (not shown) of the tail fin unit.

The fuse 110 is provided at the tail end of the through body 24. To activate the fuse 110, a power generator 45 and a wind drive turbine are mounted to the seat 46 in the upper portion of the front clamp 42. The generator 45 is operated to generate power to activate the fuse 110 when the bomb falls free. A cable 49 connecting the generator 45 to the fuse 110 runs into the space between the armor 40 and the penetrating body 24, passes below the intermediate shell 70, and rearwards along the rear clamp 44. Passes down tube 76 and tail tube 78. The cable 49 then runs through the hole in the tail ring 80 and into the tail end of the penetrating body 24. The safety / arm device may be included in fuse 110 and may be mounted close to fuse 110 on or within armor 40.

The fuse 110 and power generator 45 are not components of the bomb except that the warhead is designed to receive a fusing system. Other suitable fusing systems can be used for the bombs.

The present invention has been described in terms of preferred embodiments, principles, and examples. Those skilled in the art will appreciate that alternatives and equivalents can be made without departing from the scope of the invention as set forth in the claims that follow.

Claims (29)

A through body having a conical head-shaped nose portion, a hollow bore extending toward the nose portion and having an opening in the tail portion; Equipped with an aerodynamic glove mounted on an outer surface of the through body, the aerodynamic glove comprising means for securing a glove to the through body, The aerodynamic shape of the glove is the same as the aerodynamic shape of the selected validated drop bomb, and the penetrating body and the glove have a weight, center of gravity, and moment of inertia similar to the weight, center of gravity, and moment of inertia of the selected validated bomb. Armored bombs, characterized in that having. The armored bomb of claim 1 wherein the outer diameter of the penetrating body is smaller than the outer diameter of the selected validated drop bomb. The armored bomb according to claim 1, wherein the explosive is filled in the bore of the penetrating body. The armored bomb according to claim 1, wherein the penetrating body is formed of tungsten. The armored bomb according to claim 1, wherein the penetrating body is formed of depleted uranium. The armored bomb according to claim 1, wherein the armored glove is formed of a material having a strength that is weaker than that of the material forming the penetrating body so that the glove can be separated from the penetrating body by colliding with a target. . The armored bomb of claim 1, wherein the means for securing the armor to the penetrating body comprises one or more clamps mounted to a central portion of the penetrating body. delete delete delete delete delete 8. The armored drop bomb of claim 7, further comprising a mounting lug fastened to one or more clamps for mounting the bomb on a transport device mounted on an aircraft. delete delete The armored bomb according to claim 1, further comprising a fuse mounted on the tail end of the penetrating body. 17. The armored drop bomb of claim 16, further comprising a safety arm device disposed proximate to the fuse. 2. The armored bomb of claim 1, further comprising means for mounting the guide nose member and the guide tail member to the warhead. delete delete delete delete delete delete delete delete delete delete delete

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