ES2226012T3 - AIR PUMP PROVIDED WITH A COVER. - 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

Air pump provided with a cover.

The present invention relates to air pumps, that is, bombs dropped from an airplane, and more specifically, to aerial pumps to penetrate hard targets.

A pump normally includes a hard shell which has a hollow interior space to hold a material explosive. The physical characteristics of the pump, including the weight, center of gravity, moments of inertia, and shape aerodynamics, affect the free fall response of the pump, whether or not a guide package is included with the pump.

Bombs dropped from airplanes, including guided or unguided free fall bombs, glide pumps, and the pumps with reinforced load, must pass rigorous tests in the field that include the safe exit of the launch plane and the target arrival accuracy. These tests should be performed with Each type of plane that will carry the bomb. Therefore the development of new weapons is subject to delay and expense significant before the weapon receives certification for its use.

The capacity of a pump, or other projectile, of penetrate a target is proportional to the mass and velocity of projectile impact and inversely proportional to the area in cross section of the pump. That is, the greater the kinetic energy and the smaller the cross-sectional area, The greater the penetration that can be expected. However, the adaptation of an existing pump for greater penetration reducing The external diameter of the pump can also lead to changes of the properties of mass, such as weight, center of gravity, moment of inertia, and aerodynamic properties, all which can affect the flight characteristics of the pump. These changes also require pump certification adapted for use.

US-A-5,656,792 describes an artillery ammunition ballistic projectile for attacks on bunkers, underground shelters, shelters or the like. The artillery ammunition known for US-A-5,656,792 includes a body of Penetration surrounded by a wrap. The penetration body has an ogive shaped nose section and a cylindrical body central long. The surrounding envelope includes a nose cone in ogive shape connected to the almost cylindrical shirt. The part front of the nose cone carries a proximity fuze.

To use the ammo fire tables of already known artillery, the outer contour and the mass of projectile with envelope correlate with values corresponding from known projectiles. The shell projectile with the penetration body inside it is designed to be ballistically equivalent to the ammunition currently used.

However, air bombs and ammunition of artillery are not comparable, since artillery ammunition fires from a gunner firing device and follows a ballistic path towards a target. An aerial bomb, in contraposition, is launched from a deployment plane and can be lead your way to the target so that your path is not simply ballistic. As indicated above, the Certification of an aerial pump for use requires slow testing and expensive.

Therefore, an object of the present invention is to provide an aerial bomb that overcomes the difficulty of the certification This object is achieved with an aerial bomb according to the claim 1.

More specifically, the present invention provides a pump that has a penetrating charge head improved, that is, a loading head that penetrates more Deep in a protected target. Preferably, the pump is substantially identical in aerodynamic and mass properties at A certified pump As a result, a pump of the present invention can be easily certified by function similarity with the existing pump for use in an airplane. Also, if desired, The pump of the invention can use existing guide packages Available for certified pump.

To avoid slow and expensive delays necessary to certify a new pump, another embodiment preferred of the invention provides a pump that emulates the free fall properties of an existing pump relative to the Certification, while providing the loading head the desired enhanced penetration capacity.

According to the invention, the loading head is a Penetration body shaped for better penetration into the white by a smaller cross-sectional area in comparison with an existing certified pump. One wrapped aerodynamics mounted around the load head emulates the shape of the certified pump, and preferably the weight, the center of gravity and the moments of inertia of the pump (the body of penetration and envelope) closely approximate the properties of The existing pump.

Brief description of the drawings

The invention will be better understood by reference to The following detailed description in conjunction with the accompanying drawings, in which:

Figure 1 is a side view of a pump according to the invention.

Figure 2 is a sectional side view of a Pump penetration body of figure 1.

Figure 3 is a perspective view exploded from the pump in figure 1 illustrating the various components of the envelope and penetrator assembly.

Figure 4 is a side view of a pump with A mounted guide package.

Figure 5 is a sectional view of a portion of nose of the load head with envelope showing the joint structure for a nose guide unit.

Figure 6 is a sectional view of a front clamp of the shell.

And Figure 7 is a sectional view of a tail of the envelope showing a mounting structure of a unit of tail fin

Detailed description

Figure 1 is a side view of a pump with envelope 20 according to the invention. Pump 20 includes a body of penetration 24 or loading head (shown in figure 2) and a shell 40 formed to emulate the aerodynamic shape of a existing certified pump. In the exemplary embodiment, the pump 20 is configured to emulate the BLU-109 / B pump, it is that is, the outer shape of the shell 40 is substantially identical to the outer shape of the hard shell of the BLU-109 / B. In addition, weight, center of gravity, and the moments of inertia of the pump 20 are substantially identical to the physical characteristics of the BLU-109 / B.

Therefore, pump 20 will have the same free fall and aerodynamic properties that the emulated pump, and as a result it can be transported on any plane for which The emulated pump is certified. In addition, the pump 20 can be Use with any appropriate guide package for the emulated pump. However, the improved pump 20 avoids slow and expensive certification tests because it is certified by similarity With the certified pump. The invention thus provides a pump. aerial that improves the function of an existing pump, but it certify for use emulating the handling characteristics and Aerial launch of the existing pump.

The invention is not limited to emulating a pump certified concrete, such as BLU-109 / B, which use here as an example, but, as experts in the subject by the following description, the invention can be directed to improvements in other existing pumps.

The penetration body 24 in the embodiment illustrative is intended for a better penetration capacity of the White. The penetration body 24 includes a housing made of a hard, dense material, such as steel, tungsten, or depleted uranium. The penetration body 24 is narrower than the housing of the emulated pump to provide a smaller sectional area cross. The penetration body 24 has an interior space hole 26 that an explosive may contain. Space 26 opens in the tail end of body 28 and extends towards the projection 30, leaving a section of solid nose. A bulkhead 32 is attached to penetration body 24 to close the hole in the tail and to support the mounting of a fuze that activates the head of load, as described better below.

In the proposed example of the BLU-109 / B as the certified pump, the body of Penetration 24 is narrower than a BLU-109 / B, but it has thicker walls to conserve most of the BLU-109 / B weight. According to the realization For example, the penetration body 24 has a weight (loaded with an explosive charge) that is between 80% and 90% of the weight of the BLU-109 / B. The reduced diameter with approximately the same weight increases the penetration capacity of the body of penetration compared to the BLU-109 / B focusing kinetic energy in a smaller impact area. Be understands that the invention is not limited to a diameter or ratio in particular weight compared to an emulated pump. The diameter and the weight of the loading head must be selected, for example, for the desired penetration and explosion functions, within of the limitation that the total weight of the loading head and the wrapped is approximately equal to that of the emulated weapon.

The penetration body 24 is configured in nose end 30 with an ogive that has a radius of variable curvature The outer shape of the nose end 30 leads to a central cylindrical portion 34. The outer diameter of penetration body 24, measured in the cylindrical position central 34, is 27.2 cm (10.7 inches), compared to a outer diameter of the BLU-109 / B 37.1 cm (14.6 inches) in a central portion. The thickness of the wall 36 Penetration body surrounding hole 26 is 5.74 cm (2.26 inches).

Figure 3 is an exploded view of the shell 40 and penetration body 24. Shell 40 includes a front clamp 42 and a rear clamp 44 that are fixed to the central portion 34 of the penetration body 24 in spaced relationship The clamps 42, 44 are of a construction in two pieces, each having a couple of elements semi-cylindricals that are screwed together around the body of penetration 24. The clamps 42, 44 are sized in the internal diameter to fit tightly in the body of penetration 24 to provide support positions for handling and storage trays on land. It mounts safety pins (not shown) in holes in the body of penetration 24 and extend out of it to hook coupling holes in clamps 42, 44. The pins safety prevents the clamps 42, 44 from moving longitudinally and rotate relative to the penetration body 24 during the ground handling of the pump and while it is transported on a plane.

Alternatively, other means could be used mechanical hooks to prevent the movement of the clamps 42, 44 in the penetration body 24. For example, grooves longitudinal formed in the penetration body 24 could hook nerves extending from clamps 42, 44 or the  outer surface of penetration body 24 and surfaces internal of the clamps 42, 44 could be formed as rough surfaces to provide greater friction between surfaces.

Safety pins and clamps they are designed so that they have a material resistance of so that they break under the impact force of the pump in a target to help the penetration body 24 shed of envelope 40 for better white penetration.

The top of each clamp 42, 44 includes mounting holes for lugs 48, 50 to mount the pump in an aircraft lift system. The separation of lugs 48, 50 and their position relative to the center of gravity of pump 20 is identical to that of the selected weapon, in the embodiment illustrated, BLU-109 / B.

By adapting other certified pumps, you can use a single clamp, depending for example on the requirements of space and cargo transport. This realization is not part of this invention.

Envelope 40 also includes elements of coating that form the outer surface and are configured so that they have the aerodynamic characteristics of the pump emulated Coating elements include a nose cone 60 mounted on the nose 30 of the penetration body 24, and a tube front 62 mounted between nose cone 60 and clamp front 42. The nose cone 60 and the front tube 62 are fixedly attached, and the front tube 62 is fixed to the front clamp 42. A nose ring 64 helps to fix the nose cone 60 in position and provides a structure of assembly for a nose guide unit, represented in the Figures 4 and 5.

The front end 61 of the nose cone 60 is cylindrical in shape and extends longitudinally forward of the penetration body 24. The cylindrical end that extends forward 61 is designed so that, to the impact of the head of load on a target, break away from the penetration body 24, to facilitate the penetration body 24 stripping off the front portion of the envelope.

Between the front clamp 42 and the clamp rear 44 a top sheath 70 and a bottom sheath are fixed 72. The bottom sheath 72 becomes thick enough, typically approximately 1.3 cm (0.5 inches), for contribute to support the weight of the pump during handling in ground with conventional lifting equipment, and to discharge the pump in storage trays. The upper sheath 70 includes a switching plate 74 cooperating with a switch indication of release on the aircraft, which is used to indicate the release of the bomb from the plane.

To the rear of the rear clamp 44, the coating is finished with a rear tube 76 and a tail tube 78. In the illustrated embodiment, the tail tube 78 is flared out to emulate the tail shape of the BLU-109 / B. A tail ring 80 is held in the pump tail end and shell, and provides a mounting structure for an aerodynamic tail unit; be show exemplary tail units in figures 4 and 7.

The clamps 42, 44 provide support for pump handling and ground storage in racks, trays and elevators. Additional support is obtained through support rings that are installed between the body of penetration 24 and the coating elements in the positions of  support 82, 83 shown with the arrows. The support rings they can be, for example, profile rings in "T" or "H", and they are placed so that they bridge the space between the coating and penetration body 24 to help support the weight of the body.

The unit 20 shown in Figure 1 is designed so that it has the same length, weight, center of gravity, and aerodynamic shape than the certified weapon selected As experts in the field will appreciate, the weight and the center of gravity can be adjusted by ballasting the body of penetration 24 or envelope 40, by adding or removing material in selected positions. For example, the length of the hole 26, or the thickness of the walls 36 of the penetration body can be easily changed to regulate the weight and center of gravity. The components of the envelope, in particular, the clamps 42, 44, can also be adapted in weight and / or size to regulate the center of gravity and the total weight.

Figure 4 is a side view of the pump with wrapped 20 with a attached guide package. The guide package includes a nose guide unit 102 having devices of target detection (not shown), and a tail fin unit 104. The nose guide unit 102 has fins 106 which are controllable by the nose guide unit 102 to direct the pump during free fall and a folding set of fin stabilization. The guide package, including fins, not part of this invention, except that the wrapped is designed to accept the assembly of a package of guide, as explained below.

As depicted in Figure 5, the hoop of nose 64 sits on the nose end of the penetration body 24, and is fixed to the front end of the penetration body and to the nose cone 60 of the shell. The nose ring 64 includes a circumferential groove 66 that accepts a coupling rib 103 of the nose unit 102. A retaining ring 68 fixes the unit of nose 102 to the nose ring 64.

Figure 7 illustrates an assembly arrangement of tail fins The tail ring 80 includes a V-shaped groove 84 that fits with a conventional ring clamp (no represented) of a tail fin unit.

A fuze 110 is installed at the tail end of penetration body 24. To activate fuze 110, a power generator 45, a wind-driven turbine, is mounted on a seat 46 at the top of the clamp front 42. Generator 45 is activated when the pump is on free fall to generate electrical power to activate a fuze 110. a cable 49 to connect the generator 45 to the fuze 110 is directed in a space between envelope 40 and the penetration body 24, thus passing below the middle sheath 70, along the rear clamp 44 and below the tube rear 76 and tail tube 78. Cable 49 is then directed to through a hole in the tail ring 80 and the tail end of the penetration body 24. An arm device may be included safety with fuze 110, and mount near fuze 110 inside or on the envelope 40.

The fuze 110 and the power generator 45 do not they are part of the pump except that the loading head is Designed to accommodate fuze systems. You could use others suitable fuze systems with the pump.

The invention has been described in terms of the Preferred embodiments, principles and examples. The experts in the matter they will recognize that substitutions can be made and equivalents without departing from the scope of the invention defined in the following claims.

Claims (11)

1. An air pump with casing (20), including: a penetration body (24) that has a nose section (30) in the form of an ogive; Y an aerodynamic shell (40) mounted on a outer surface of the penetration body (24), including the wrapped (40) a front clamp (42) and a clamp rear (44) mounted on a central portion (34) of the body of penetration (24) in longitudinally spaced relationship, including  each clamp (42, 44) two semi-cylindrical parts joined fixedly surrounding the penetration body (24), a nose cone (60) in the form of an ogive, a front tube (62) attached to the cone of nose (60) and front clamp (42), pods (70, 72) attached between the clamps (42, 44), a rear tube (76) attached to the rear clamp (44), and a tubular tail section (78) fixed to the tube (76), the shell (40) having an outer shape that approximates an external form of a certified pump selected 2. The air pump with casing (20) as per claim in claim 1, further including means for resist the movement of the clamps (42, 44) in relation to the penetration body (24) during handling and transport of the bomb. 3. The air pump with casing (20) as per claim in claim 2, wherein said means for resist movement include a plurality of pins safety mounted on the penetration body (24) and engaging index holes in the clamps (42, 44). 4. The air pump with casing (20) as per claim in claim 1, wherein the outer diameter of the penetration body (24) is smaller than the outer diameter of the Certified air pump selected. 5. The air pump with casing (20) as per claim in claim 1, wherein the total body weight penetration (24) and envelope (40) is approximately equal to weight of the selected certified aerial pump. 6. The air pump with casing (20) as per claim in claim 1, wherein the shell (40) is made of a material that has the resistance less than a resistance of the material that forms the penetration body (24), so that the shell (40) can be separated from the penetration body (24) by impact with a target. 7. The air pump with casing (20) as per claim in claim 1, further including a plurality of support rings (in 82 and 83) mounted between the shell (40) and the penetration body (24) to support the shell (40) during lifting, said rings being arranged (at 82 and 83) at least in the nose section and the tail section. 8. The air pump with casing (20) as per claim in claim 1, further including a generator moved by the wind (45) mounted on a seat (46) on one (42) of said clamps (42, 44) to generate electric current to a fuze (110), and a power cable (49) extending in a space between the shell (40) and the penetration body (24) from said hole to the tail end (28) of the body of penetration (24) to connect the generator (45) and a fuze (110). 9. The air pump with casing (20) as per claim in claim 1, further including means (64, 66, 68) to mount a guide nose piece (102) and a piece of guide tail (104) in one of the penetration body (24) and the wrapped (40). 10. The air pump with casing (20) as per claim in claim 1, wherein the penetration body (24) is made of tungsten. 11. The air pump with casing (20) as per claim in claim 1, wherein the penetration body (20) is made of depleted uranium.