DE20118797U1 - Device for protecting objects against terrorist attacks by means of airplanes, missiles and other missiles - Google Patents

Description

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Device for protecting objects against terrorist attacks by aircraft, rockets and other missiles

The innovation relates to a device according to the generic term of the first protection claim. The innovation is applicable wherever objects such as nuclear power plants, buildings, bridges or repositories for radioactive substances are to be protected from terrorist attacks by aircraft, rockets or other missiles.

Following the attacks on the World Trade Center on September 11, 2001, the demand for the shutdown of nuclear power plants and the protection of other vital or dangerous objects, such as interim storage facilities, high-rise buildings, chemical plants, supply centers, bridges, dams, etc. against terrorist attacks by aircraft, has become ever louder and, due to threats, more acute.

The measures introduced so far, such as increased airspace surveillance, overflight bans, etc., are inadequate and can be circumvented. They cannot be implemented in the case of chemical plants and dams, which pose just as much of a risk as nuclear power plants.

Nuclear power plants are the focus of the discussion, as they represent a particularly dangerous potential. Older nuclear power plants are not protected against aircraft crashes. In newer nuclear power plants, the reactor vessels are protected against aircraft crashes by strong containment walls. The design was based on the impact of a Starfighter and later a Phantom fighter plane without activating the weapons carried on board at a speed that is typical for these aircraft. This assumed an accident and not an attack.

In future terrorist attacks, it must be expected that large aircraft carrying passengers or cargo, small aircraft or other aircraft will be directed against the above-mentioned objects. Passenger aircraft have many times the mass of a fighter aircraft.

It is not known how a cotainment system would survive an attack with such flying objects. However, older nuclear power plants are not designed to withstand such stresses.

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The possible dangers of such an attack are to be countered in the following way:

- Structural measures

- Increased personnel monitoring

- More intensive baggage and passenger checks
Airspace surveillance
Overflight bans

- Interceptors with authorization to shoot down (also civil aircraft) - Air defence from the ground

- Safety measures on the aircraft

- Construction of a second shell around the reactor building

- Shutdown of nuclear power plants

However, these measures are only feasible to a limited extent and have gaps caused by human error, so that further measures are required to ensure the safety of the objects at risk, which are expensive and time-consuming.
The aim of the innovation is therefore to develop a device with which the aforementioned endangered objects can be protected against terrorist attacks by aircraft, rockets and other missiles, whereby the personnel expenditure for operating the objects should be low.

This object is achieved by a device according to the features of the first claim.

Subclaims reflect advantageous embodiments of the innovation.

The proposed solution provides that the object to be protected is protected at least in the direction of attack by ropes, nets, bars or grilles.

Objects to be protected include endangered or dangerous objects such as nuclear power plants, interim storage facilities for radioactive substances, high-rise buildings, chemical plants, supply centers, bridges or dams.

The protection against the approaching object, which has already been mentioned, follows in the way that the interception devices, such as ropes, nets, bars or grilles, which surround the structure to be protected on one or more sides and also upwards, intercept, destroy and divert the approaching object, which happens by absorbing its impact energy

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is initially reduced by the interception device, whereby the impact energy is either intercepted, broken up or reduced.

The arresting device, if it is ropes or nets, is tensioned in a frame between supports. These supports can be arranged and tensioned either in the direction of attack or around the entire building.

With individual ropes or nets, it is also possible to temporarily stretch them out in the direction of attack using one or more tethered balloons. Grids and poles are also held in a frame between supports. For the stability of the supports, it is advantageous to use guy ropes to secure them.

The supports can be installed in the ground in front of or around the object to be protected, or on the object to be protected itself. This can prove advantageous for nuclear power plants, residential buildings, bridges or dams. In any case, it is advantageous to install damping elements between the interception devices and the supports, which absorb part of the energy of the impact through their spring effect.

It is also advantageous to arrange several interceptors one behind the other, whereby it is also advantageous to arrange the interceptors at an angle so that the impacting missile is deflected as far as possible. It is also advantageous to arrange inertial masses on the supports. For certain types of objects to be protected, such as buildings, it is advantageous to support the protective device on the building to be protected using a profile frame. For certain objects it can also be advantageous to arrange the protective device in a star shape around the object to be protected.
If the safety nets are used, they can be set up permanently. However, it is also possible to fold or pull up the safety net in the event of danger.

Furthermore, it is possible to arrange explosive charges on the nets which are detonated when approached or touched, whereby the flying object is at least partially destroyed, which leads to a fragmentation of the impact mass and thus reduces the damage.

The innovation has the advantage that the objects mentioned cannot be immediately destroyed by aircraft, rockets or other missiles, but are destroyed or damaged by the impact of the protective device.

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In the following, the innovation is explained in more detail using an example with 15 figures: The figures show:
Figure 1 and 2: Example of different design variants of interception devices

between adjacent supports

Figure 3: Example of a network of supports around an object in side

view

Figure 4: Network with supports around a reactor building in plan view

Figure 5: Network with supports around a reactor vessel, with the supports at the re

actuator are arranged

Figure 6: Inclined safety net with two supports on a reactor building in Sei

ten view

Figure 7: Tethered balloon with tether in attack direction

Figure 8: Supports with net and protection upwards

Figure 9a,9b: Profiles arranged by frames around a high-rise building in

Side view and top view

Figure 10: Section through a bridge with grating around vulnerable areas of the bridge

Figure 11: Arrangement of a safety frame around supports of the bridge of Figure 10

Figures 12 to 14: Different arrangements of protective devices around buildings

Figures 1 and 2 show various designs of arresting devices between supports 3 that are arranged next to each other, with the inertial mass 9 arranged at the upper end of the supports 3 and shock-reducing elements 10, such as rubber, hydraulic shock absorbers or springs, arranged between the net 2 and the support 3. The following can be used as arresting devices: nets 2, vertically hanging ropes 5, grids 8, profiles 17 or rods 15. Both the nets 2 and the vertically hanging ropes 5, the rods 15, profiles 17 or the grids 8 are fastened between the supports 3 by means of frames 11. Steel or a high-quality plastic is suitable as a material for the arresting devices. The devices can be permanently installed in front of the object 1 to be protected or can only be erected in the event of an attack. Figure 3 shows a reactor building 1 around which a net 2 has been stretched by means of supports 3, whereby a net 2 is also stretched upwards between the supports 3, supporting cables 6 serve to hold this net 2 and guy cables 7 stabilize the supports 3.

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Another example of how the supports 3 can be arranged is shown in embodiment 5, in which the supports 3 that hold the net 2 are attached directly to the reactor building 1. Figure 6 shows an example in which the reactor building 1 is arranged on the building 1 by supports 3, with the net 2 being arranged diagonally around the building 1 by guy ropes 7. Figure 7 shows an example in which one or more holding ropes 5 are held in the attack direction by means of a tethered balloon 4. Figure 8 shows another example in which supporting ropes 6 hold a net 2 on the supports 3 above the reactor building 1. Figure 9 shows how an object 1 to be protected, for example a high-rise building, is protected by means of profile frames 14, frames 11, supports 3, profiles 17 and a net 2 upwards. Figure 10 shows a bridge with a driving deck 13, around which gratings 8 are arranged on both sides, and the bridge pillars 16, which are surrounded by the safety frame 12. Figure 11 shows a section A-A of Figure 10 and a safety frame 12 around bridge pillars 16, the frame 11 being provided with nets 2. Figures 12 to 14 show examples of how nets 2 can be arranged as examples of various safety devices 5, 8, 15, 17 around an object 1 to be protected with the aid of supports 3.

List of reference symbols used

1. Object to be protected/reactor building, high-rise building, bridge 2. network 5 3. Support 4. Tethered balloon 5. Vertically hanging rope 6. Suspension ropes 7. Guy ropes 10 8. Grid 9. Inertial mass 10. Shock absorbers 11. Frame 12. Catch frame 15 13. Driving deck 14. Profile frame 15. Poles 16. Bridge piers 17. Profile

Claims (14)

1. Device for protecting objects against terrorist attacks by aircraft, rockets or other missiles, characterized in that an object ( 1 ) is protected at least in the direction of attack by intercepting devices such as nets ( 2 ), ropes ( 5 ), grids ( 8 ), profiles ( 17 ) or rods ( 15 ). 2. Device according to claim 1, characterized in that the soap ( 5 ) and/or nets ( 2 ) are braced by a frame ( 11 ) between supports ( 3 ). 3. Device according to claim 1, characterized in that grids ( 8 ), profiles ( 17 ) and/or rods ( 15 ) are held in a frame ( 11 ) between the supports ( 3 ). 4. Device according to claims 1 to 3, characterized in that the supports ( 3 ) are stabilized with guy ropes ( 4 ). 5. Device according to claims 1 to 4, characterized in that the supports ( 3 ) are attached to the object to be protected ( 1 ). 6. Device according to claims 1 to 5, characterized in that damping elements ( 10 ) are arranged between the supports ( 3 ) and the interception devices ( 2 , 5 , 8 , 15 , 17 ). 7. Device according to one of claims 1 to 6, characterized in that inertial masses ( 9 ) are arranged on the supports ( 3 ). 8. Device according to one of claims 1 to 7, characterized in that the interception devices ( 2 , 5 , 8 , 15 , 17 ) surround the object to be protected ( 1 ) upwards and/or on all sides. 9. Device according to claims 1 to 8, characterized in that the object to be protected ( 1 ) is surrounded by a catch frame ( 12 ) with the interception device ( 2 , 5 , 8 , 15 , 17 ). 10. Device according to one of claims 1 to 9, characterized in that the intercepting devices ( 2 , 5 , 8 , 15 , 17 ) are positioned obliquely to the direction of attack. 11. Device according to claims 1 to 10, characterized in that the supports ( 3 ) with the interception devices ( 2 , 5 , 8 , 15 , 17 ) are arranged in a zigzag manner around the object to be protected ( 1 ). 12. Device according to one of claims 1 to 11, characterized in that several interception devices ( 2 , 5 , 8 , 15 , 17 ) are arranged one behind the other. 13. Device according to claim 1, characterized in that ropes ( 5 ) or nets ( 2 ) are held by means of a tethered balloon ( 4 ). 14. Device according to one of claims 1 to 13, characterized in that explosive charges are arranged on the interception devices ( 2 , 5 , 8 , 13 , 17 ).