EP0413084A2 - Projectile - Google Patents

Abstract

The invention relates to a floor (40). with an interior (42) in which payloads (46) or electronic components (48, 64) are arranged. Such storeys with sensitive inner components must still be fully functional after storage for up to 20 years. To protect the inner components (48, 64) from corrosion, the interior (42) of the projectile (40) is filled with a protective gas according to the invention. The protective gas, e.g. B. argon (Ar), nitrogen (N2), hydrogen (H2) or a corresponding gas mixture is with an overpressure of z. B. 3 bar in the interior (42) of the floor (40).

Description

The invention relates to a projectile with an interior space, in which sensitive payloads and / or electronic components are arranged, according to the preamble of claim 1.

A large-caliber floor, e.g. B. in artillery calibers 155 mm or 203 mm, in the interior of which a large number of small submunitions (bomblets) are arranged as an ejectable payload, z. B. from DE-OS 38 41 908 known (corresponding to Figure 1 of the present application). The ignition and safety device of such a submunition projectile consists of many fine mechanical small parts which are arranged within a detonator housing. The igniter housing does not close the internal ignition mechanism gas-tight to the outside.

Another large-caliber load carrier floor with three submunition floors stacked in the interior is e.g. B. from DE-OS 36 35 361 known (corresponding to Figure 2 of the present application). These submunition projectiles are provided with a projectile-forming charge and have a stabilizing parachute, a target-seeking sensor system with a transmitting and receiving antenna, as well as an energy supply unit and also an ignition and safety unit. For the storage of these peripheral components of the submunition storeys, a large-volume storage space or a space to be kept is required in the carrier storey.

From DE-PS 36 19 791 is also an ejectable from a large-caliber carrier floor or missile floor warhead capable of flight and guidance with stabilizing wings known as a submunition unit (corresponding to FIG. 3 of the present application). For final phase steering and appropriate distance ignition of a first projectile-forming active part z. B. against active armor and a second spike-forming main active part against the main armor of the target, a comprehensive target detection sensor and control mechanism with ignition and electronic units is available.

In all of these known projectiles, the submunition projectiles are provided with a corresponding explosive charge. The disadvantage here is that moisture can diffuse out of the explosive mass or is present in the gas atmosphere (air) in the free interior of the projectile body. Due to this moisture, unprotected electronic components (microchips, contacts, printed circuit boards, etc.) or small precision mechanical components (clockworks) can tend to corrode and lose their functionality - especially if stored for a long time (up to 20 years) or fluctuating temperatures.

More and more complicated interior structures will be used in future modern floors. Electronic assemblies in particular will find increasing use here. However, the functional reliability of the storeys depends on 100% corrosion protection of the inner assemblies over the entire storage period. It is therefore necessary to protect the sensitive internal components from possible corrosion.

It is an object of the present invention to provide a measure for the protection of sensitive internal components or net loads against corrosion for generic projectiles.

This object is achieved in an astonishingly simple manner in that the free interior space in the floor in which the components or payloads are arranged is filled with a protective gas. The protective gas can be a noble gas such. B. argon (Ar), helium (He), an inert gas such. B. nitrogen (N₂) or a gas with a reducing effect such. B. carbon monoxide (CO), hydrogen (H₂), ammonia (NH₄), methane gas (CH₄) or a corresponding gas.

The protective gas is expediently present in the interior of the floor with an overpressure between normal atmospheric pressure and 30 bar. The height of the overpressure is decisive for the amount of gas to be introduced and should be selected depending on the type of gas, the type of projectile, the size of the caliber, etc.

In order to work with the supporting projectiles, these usually consist of two parts that can be assembled; so z. B. the floor tip (ogive) or the floor of the floor of the remaining floor can be unscrewed. An O-ring seal and / or an adhesive and sealant and / or an external protective and sealing lacquer is generally provided in the connection area of these projectile parts. With the slightest damage (e.g. micro-hairline cracks after the projectile has dropped), in a projectile according to the invention with internal protection of the sensitive components, no harmful moisture can penetrate from the outside; Due to the existing overpressure and the resulting larger amount of gas in the interior of the storey, the protective gas acts as a barrier and can escape very slowly from the inside to the outside, so that simple but effective long-term protection is provided for the sensitive components.

Climate-resistant transport or storage containers (magazine boxes) for projectiles with moisture-absorbing agents such as, for example, are generally known. B. diatomaceous earth. A derar term measure is not appropriate for the interior of floors because of the disadvantageous increase in the dead load; just to reduce the dead load component in electronic components such. B. has been dispensed with casting with synthetic resin.

A method according to the invention for protecting sensitive components or payloads in the interior of a storey is seen in the measure that the interior is cleaned of moisture or corrosion seedlings (particles) by purging or flooding with an inert protective gas; the interior is then permanently protected against corrosion by remaining the protective gas, preferably with a certain excess pressure of, for example, about 3 bar.

The invention is explained and described in more detail below with reference to exemplary embodiments shown in the drawings.

• Figur 1 ein bekanntes Trägergeschoß für eine Vielzahl von Submunitionsgeschossen,
• Figur 2 ein anderes bekanntes Trägergeschoß für drei P-Ladungs-Submunitionsgeschosse und
• Figur 3 einen bekannten flug- und lenkfähigen Ge­fechtskopf mit Tandem-Hohlladung, bei denen jeweils die erfindungsgemäße Lehre Anwendung finden soll.

Show it:

• FIG. 1 shows a known carrier projectile for a large number of submunition projectiles,
• Figure 2 shows another known carrier floor for three P-charge submunitions and
• Figure 3 shows a known flight and steerable warhead with tandem shaped charge, in each of which the teaching of the invention is to be used.

In FIG. 1 , reference number 10 shows a known large-caliber bomblet projectile, in the interior 12 of which a large number (here 49 units) of small submunition storeys 14 (bomblets) are embedded. The Carrier projectile 10 has a base bleed set 16 on the rear for increasing the range and can be fired at distances of up to approximately 40 kilometers. The submunition storeys 14 are then ejected from the carrier storey 10 by means of an ejection charge 18 above a target area. The cargo space or interior 12 of the projectile 10 is filled with a protective gas which is under overpressure to protect corrosion-sensitive precision mechanical components of the non-gas-tight detonator housing of the bomblet projectiles. The excess pressure of the protective gas should be selected depending on the bullet shell strength and the volume of the interior 12 and can be between 1 and 30 bar. The caliber size and the bullet diameter are also decisive. So it can z. B. be useful, the protective gas with a higher pressure of z. B. fill in 15 bar to have a corresponding sufficient amount of gas for any leaks. With a larger bullet in caliber 203 mm it can e.g. B. be sufficient if there is a lower excess pressure of approx. 2 bar.

A similar carrier storey 20, shown in FIG. 2 , has three intelligent submunition units 24 in its interior 22. These submunitions 24 are each assigned a projectile-forming charge 38, which is at a height of z. B. is fired 120 to 15 meters above a detected and targeted target. For this purpose, such a submunition unit 24 is functionally equipped with a rotating parachute 26, a target-seeking and target-detecting sensor unit 28 with a transmitting and receiving antenna 32, as well as an energy supply unit 34 and ignition and safety unit 36. These submunition units 24 therefore require a relatively large-volume interior 22 in the carrier storey 20. To protect the components or peripheral submunition storey parts mentioned, the interior 22 is filled with an inert gas or gas mixture with z. B. Helium filled. In order to be able to accommodate a larger amount of the inert gas in the predetermined interior 22, the inert gas is under a certain excess pressure. The interior with a volume of 2.8 liters (at atmospheric pressure) can contain 7.5 liters of gas at an overpressure of approx. 3 bar. This is sufficient for permanent protection of the components.

FIG. 3 shows a warhead 40 designed as a larger submunition projectile. The warhead 40 also has an interior 42 with assemblies arranged therein. The warhead 40 can e.g. B. from a large-caliber carrier floor, a rocket or an aircraft and is flyable and steerable by means of swing-out stabilizing wing 44. The warhead 40 has a front-side sensor head 48 for target detection and distance ignition of a first active charge 46 (P-charge). Behind it, a control unit with gas generator 56 and lateral control nozzles 58 is arranged around an ignition spacer tube 52 (stand-off) carrying the front active charge 46 for the main hollow charge 54. Furthermore, an energy supply unit 62 and an ignition device 64 with an electronic delay circuit for the time-delayed initiation of the main hollow charge are provided.
Here, too, the interior 42 has been filled with a protective gas under excess pressure as corrosion protection for the installed units.

The invention can be used on all floors with sensitive internal components, for. B. also with tank ammunition, mortar shells, grenade shells, rockets, mines, water bombs, torpedoes or similar charges filled with explosives.

Reference symbol list

• 10 Bomblet main floor
• 12 interior 10
• 14 bomblet
• 16 base bleed set
• 18 discharge charge
• 20 main garret
• 22 interior 20
• 24 submunition storey
• 26 stabilization parachute
• 28 sensor unit
• 32 antenna
• 34 power supply unit
• 36 ignition device
• 38 P charge
• 40 warhead
• 42 interior
• 44 stabilizing wing
• 46 front active cargo
• 48 sensor head
• 52 Ignition spacer tube
• 54 main load
• 56 gas generator
• 58 control nozzle
• 62 energy block
• 64 ignition device

Claims (4)

1. floor (10, 20, 40) with an interior (12, 22, 42) in which payloads (14, 24, 46) or electronic components (28, 48, 64) are arranged,
characterized in that the interior (12, 22, 42) of the projectile (10, 20, 40) is filled with a protective gas to protect the internal components (28, 48, 64) or payloads (14, 24, 46). 2. projectile according to claim 1,
characterized in that the protective gas is a noble gas such. B. argon (Ar), helium (He), an inert gas such. B. nitrogen (N₂) or a gas with a reducing effect such. B. carbon monoxide (CO), hydrogen (H₂), ammonia (NH₄), methane gas (CH₄) or a corresponding gas mixture. 3. Projectile according to claim 1 or 2,
characterized in that the protective gas with an overpressure is present in the interior (12, 22, 42) of the projectile (10, 20, 40). 4. Method for protecting sensitive components (28, 48, 64) or payloads (14, 24, 46) in the interior (12, 22, 42) of a projectile (10, 20, 40) by flushing or flooding the interior ( 12, 22, 42) with a protective gas and the same remaining in the interior (12, 22, 42).

Images