NL2013205B1 - Explosion and bullet proof wall construction. - Google Patents

Abstract

The invention relates to an explosion and bullet-proof wall construction (10), comprising: - a first barrier (12A) and a second barrier (12B), - a plurality of barrier connections (16) between the first and second barrier in the form of vertical frames (15), wherein each vertical frame comprises a first upright (14A) associated with the first barrier and a second upright (14B) associated with the second barrier, and wherein each vertical frame further comprises connections (39) between the first and second uprights comprises - an inner zone (18) located between the first and second barrier, wherein at least one barrier comprises a plurality of protective slats (20), the protective slats being directed obliquely upward, going from the outside to the inside , to capture and deflect a shock wave from an incoming explosion or an incoming projectile.

Description

Short indication: Explosion-proof and bullet-proof wall construction

FIELD OF THE INVENTION

The present invention relates to an explosion and bullet-proof wall construction and to a method for providing protection against explosions and bullets. The wall construction also offers protection against other incoming projectiles.

BACKGROUND OF THE INVENTION

Explosion-proof and bullet-proof wall constructions are known. US2013239793A1 discloses a structure that includes stacked containers 122, 132. The containers are box-shaped elements. The wall according to US2013239793A1 appears in practice to be complex and complex to construct. EP1746379A1 discloses a wall construction with a single set of slats in an inner zone. The wall comprises reactive (or explosive) armor mounted on the slats. The wall construction according to EP1746379A1 is rather complex. DE10028753A1 discloses a wall construction with plates that form a zigzag formation in top view. DE10028753A1 has a limited capacity to stop explosions. BE1013819 discloses a closed wall construction. The wall construction according to BE1013819 is not very efficient and fairly complex. US3765299A discloses a wall construction with internal slats that are covered by a front plate and an end plate. The wall construction according to US 3765299A is not very efficient in absorbing a shock wave from an explosion. DE3633349A1 discloses another wall structure for providing protection against bullets. The wall construction according to DE3633349A1 is quite complex and expensive to manufacture. US2004261332 discloses a wall construction that is quite massive and for this reason is expensive to build. Moreover, this wall construction is very heavy. DE202012101350 discloses an anti-terror wall construction that has two walls and an inner zone that is filled with concrete or a similar material. The device according to DE202012101350 is rather complicated to build. Moreover, this wall construction is very heavy.

None of the known wall constructions offers an effective explosion and bullet-proof wall that can be built relatively simply and in a cost-effective manner.

PURPOSE OF THE INVENTION

It is an object of the invention to provide an explosion and bullet-proof wall construction that solves at least one of the problems of the known wall constructions.

It is an object of the invention to provide an explosion and bullet-proof wall construction that is relatively simple, relatively light and can be built in a relatively cost-effective manner.

It is another object of the invention to provide an alternative explosion and bulletproof wall construction.

SUMMARY OF THE INVENTION

In order to achieve at least one goal, the present invention provides an explosion-proof and bullet-proof wall construction, comprising: - a first barrier and a second barrier positioned at a distance from each other, - a plurality of barrier connections between the first and second barrier in the form of vertical frames, wherein the vertical frames are spaced at regular intervals, with each vertical frame comprising a first post associated with the first barrier and a second post associated with the second barrier, and each vertical frame further connecting between the first and second uprights, - an inner zone that is between the first and second barrier, and that is substantially empty, wherein at least one barrier comprises a plurality of protective slats, the slats being located between a first upright and a second extending adjacent upright of a barrier, wherein the protective slats are directed obliquely upward, going from the outside to the inside, in order to absorb a shock wave of an incoming explosion or an incoming projectile and to deflect it upwards, the blades defining obliquely upwardly directed channels between them, the blades and the obliquely upwardly directed channels form a partially closed, partially open structure, wherein the slats retain a portion of an incoming shock wave and the channels are adapted to cause another portion of the incoming shock wave to pass through the barrier and upwards and wherein the slats are constructed to bear forces of an explosion or incoming projectile on the vertical frames, and wherein the vertical frames are constructed to bear the forces on the ground.

The present invention further relates to a method of providing protection against an explosion or against a bullet or other incoming projectile, the method comprising applying a wall construction according to the invention and protecting a target object with the aid of the wall construction.

The invention offers an effective alternative to known wall constructions. The wall construction is suitable for providing protection against explosions, bullets of different caliber and RPGs (Rocket Propelled Grenade). An explosion or incoming projectile will usually strike a hole in the first barrier, but will not pass through the second barrier. The power of the explosion or the projectile is weakened by the first barrier and dispersed in the inner space so that the explosion or the incoming projectile no longer passes through the second barrier. An RPG has a tail piece that will linger in the first barrier, as a result of which the RPG will no longer pass through the second barrier.

The invention offers a relatively light and simple wall construction that can be built relatively quickly.

In one embodiment, both barriers have said slats, and the slats of the first barrier have an inverted slope as the slats of the second barrier. This results in a mirror-symmetrical construction that can be built quickly.

In one embodiment, at least one horizontal frame extends between each two adjacent vertical frames and is attached to both vertical frames, and the vertical frames and the horizontal frames together form a self-supporting structure. The self-supporting construction makes a simple and well-arranged construction possible. First the self-supporting structure is built and then the panels are mounted.

In one embodiment, a plurality of slats are each arranged on a frame to form a slat panel that is mounted as a stand-alone component on two vertical frames, and in particular a plurality of slat panels are arranged one above the other between adjacent vertical frames. . This embodiment has the advantage of rapid assembly and simplicity of construction. Several slat panels can be arranged one above the other between adjacent uprights.

In one embodiment, the wall structure has no roof and the inner zone is open at the top, and thus provides an escape route for guiding an incoming shock wave up through the inner zone and through an opening between the upper ends of the first and second barrier out. This configuration effectively dampens the shock. In one embodiment, the inner zone is empty, with the exception of the trusses.

In one embodiment, a rear edge of each slat is at a higher level than a front edge of a slat located directly above it, so that the wall, viewed from the outside, has a closed appearance. This causes the barrier to block a substantial portion of an incoming shock wave from an explosion. In addition, the closed appearance prevents an incoming bullet or other projectile from passing through the barrier without hitting a slat. In front view, the front part of a slat overlaps with the rear part of a slat located below.

The angle that the slats make with the horizontal can vary within wide limits. If the slats are relatively steeply oriented (and the angle is therefore relatively large), relatively less material is required. If the slats are relatively flat (and the angle is therefore relatively small), the wall construction has more stopping power. In one embodiment, the slats extend at an angle of 15-80 degrees with the horizontal.

In one embodiment, the slats are only connected to the ground via the vertical frames. This provides a simple and effective construction.

In one embodiment, a distance D between the slats is between 20 and 80 percent of a width W of the slats.

In one embodiment, the distance between the first barrier and the second barrier is 0.5 -1.5 meters, in particular 0.7 -1.0 meters. This distance provides a strong wall construction.

In another embodiment, the first barrier and the second barrier are not interconnected in the intervals between the posts. This provides a simple and effective construction. In one embodiment, the wall construction has no frames other than the frames connecting the first and second barriers.

In general, the first and second barriers are vertical, resulting in a simple construction. In one embodiment, the trusses, the slats and the uprights are made of steel. This is a strong and cost-effective material.

It is also possible for the first and second barriers to be arranged obliquely and to form essentially a triangle or a trapezoid in side view, the point or the short side of which is directed upwards.

In one embodiment, the distance between the first and second barrier measures less than 50 percent of the height of the wall construction, in particular less than 20 percent of the height of the wall construction.

In one embodiment, a steel girder is arranged under each frame for supporting the wall construction and providing a connection to the foundation. The steel beam is transverse to the main direction of the wall construction.

In one embodiment, the slats essentially only transmit horizontal forces at their ends, via the vertical frames.

In one embodiment, the slats of each barrier all have the same slope. This provides simplicity of construction. In a further embodiment, the slats are all placed directly above each other.

In one embodiment, the wall construction does not have a reactive or explosive armor, but is a passive construction.

In one embodiment, the slats have a length of 1 - 5 meters, in particular 2 - 4 meters, the length corresponding to the distance between the posts.

In one embodiment the distance between the posts is 1 - 5 meters, in particular 2 - 4 meters.

These and other aspects of the invention will be elucidated and better understood with reference to the following detailed description accompanying the accompanying drawings. Equal reference numbers indicate equal parts.

BRIEF DESCRIPTION OF THE FIGURES

Figure 1 shows a front view of the wall construction according to the invention.

Figure 2 shows a sectional side view of a barrier of the wall construction according to the invention.

Figure 3 shows an isometric view of the wall construction in exploded state.

Figure 4 shows an enlarged partial cross-section in side view of a barrier of the wall construction according to the invention.

Figure 5A shows a front view of a frame of a slat panel.

Figure 5B shows a front view of a slat panel.

Figure 5C shows an isometric view of a slat panel.

Figure 5D shows an isometric view of a frame of a slat panel.

Figure 6A shows a side view of a slat suspension.

Figure 6B shows a side view of a spacer.

Figures 7A, 7B show top views of the wall construction.

Figure 8 shows a side view of the mounting of the wall construction.

Figure 9 shows a top view with two wall constructions according to the invention and a protected object between them.

Figure 10 shows a side view of an alternative wall construction.

DETAILED DESCRIPTION OF THE FIGURES

Figures 1, 2, 3 and 4 show the explosion and bulletproof wall construction 10. The wall construction 10 comprises a first barrier 12A and a second barrier 12B (generally also indicated by 12), which are placed at a distance 42 from each other. The first and second barrier 12 are vertical. The first barrier and the second barrier define an inner zone 18 located between the barriers. The inner zone is essentially empty.

The wall structure has no roof and the inner zone is largely open at the top and thus provides an escape route around an incoming shock wave through the inner zone and through an opening 28 between upper ends 30 of the first and second barrier up and to to conduct outside.

The wall structure 10 comprises a plurality of barrier connections 16 between the first and second barrier 12. The barrier connections 16 between the first and second barrier are designed as vertical frames 15. The vertical frames are placed at a regular distance 29 from each other. The vertical frames 15 are transverse to a main direction of the wall construction. Each vertical frame includes a first upright 14A that is associated with the first barrier and a second upright 14B that is associated with the second barrier, each vertical frame further has connections between the first and second uprights.

Both barriers have a plurality of protective slats 20, the slats being horizontally between a first post 14A and a second adjacent post 14A horizontally. The protective slats are directed obliquely upward, going from the outside to the inside, in order to absorb a shock wave of an incoming explosion or an incoming projectile and to deflect it upwards.

The slats and the obliquely upwardly directed channels form a partially closed, partially open construction. The slats are spaced apart from each other, and thereby define upwardly directed channels 24 between them. The slats stop a portion of an incoming shock wave and the channels are adapted to cause another portion of the incoming shock wave to pass through the barrier and deflect upwards.

The slats are constructed to transfer forces from an explosion or incoming projectile directly or indirectly to the vertical frames, and the vertical frames are constructed to transfer the forces to the ground.

Figure 3 shows that two horizontal frames 102 extend between each of two adjacent vertical frames. A horizontal frame 102 is arranged halfway up the height of the wall structure and a horizontal frame 102 is arranged on the top. The horizontal frames extend between two vertical frames 15. The vertical frames 15 and the horizontal frames 102 together form a self-supporting structure 75.

The horizontal frames also form wind connections and for that purpose comprise crosses in top view.

Figure 3 also shows that the slats 20 are grouped in slat panels 100 which are mounted as a stand-alone component on two vertical frames 15 of a barrier. Three lamella panels (100, 100 ", 100") are arranged one above the other between adjacent vertical frames. Another number is also possible and it is also possible that only one slat panel is arranged between every two vertical frames.

The uprights 14, like the vertical frames, are arranged at regular distances 29 from each other. The uprights are vertical. The uprights 14 of the first and second barrier are positioned directly opposite each other. The uprights are generally vertical steel profiles, and can in particular be square or rectangular tubes 17. In another embodiment, the uprights can be made of wood. Each vertical frame is designed as a framework 26. Each framework comprises a vertical upright 14A of the first barrier and a vertical upright 14B of the second barrier. The trusses furthermore comprise profiles 39 which extend between the uprights, both horizontally and diagonally. The vertical frames and the slats are made of steel. Both the uprights and the profiles 39 can be box profiles, so that the trusses consist entirely of box profiles.

Both barriers 12 comprise a plurality of protective slats 20. The slats bridge the distances 29 between the posts 14. The ends 27 of the slats are supported by the posts 14. The intervals 22 between the posts have a length 29 of 2-4 meters, in especially about 3 meters. The slats have a corresponding length 29 of 2 - 4 meters, in particular approximately 3 meters.

In another embodiment, only one barrier comprises the plurality of protective slats 20 and the other barrier is configured differently.

The slats 20 are grouped in slat panels 100. Three panels 100 are placed one above the other in the height direction, but this can also be a different number. Each panel comprises 25 - 30 slats one above the other, but this can also be a different number.

Furthermore, two vertical spacers 19 are arranged in each interval 22 to keep the slats 20 at the required distance from each other. The spacers 19 divide the intervals into three parts 56A, 56B, 56C. In one embodiment, the spacers 19 do not bear large horizontal forces on the ground. The spacers 19 can be designed as metal strips or as a corner profile, with recesses for the slats arranged therein.

Figure 1 shows an escape door 58 arranged in the barriers to allow a person to pass through the wall structure 10.

With reference to Figure 4, the slats 20 are directed obliquely upward, going from the outside to the inside, in order to deflect a shock wave from an incoming explosion or an incoming projectile. The slats extend at an angle α of 15 -80 degrees with respect to the horizontal. The slats have a deflecting effect due to being directed upwards.

The slats define diagonally upwardly directed channels 24 between them. The channels are open at the front and rear. A vertical distance between the front edges of the slats can be 50 - 80 mm.

The slats 20 and the sloping, open channels 24 form a partially closed, partially open structure. The slats 20 capture a portion of an incoming shock wave, and the channels are adapted to cause another portion of an incoming shock wave to pass through the barrier and deflect it upwards in the inner zone. The slats 20 are constructed to bear a portion of the forces of an explosion or an incoming projectile on the uprights.

Referring to Figure 4, a rear edge 32 of each slat 20 is placed at a higher level than a front edge 33 of a slat 20 located directly above it. In this way the barrier has a closed appearance. Bullets and projectiles cannot fly through.

Both barriers comprise said slats 20, and the slats of the first barrier have an inverted slope as the slats of the second barrier. In this way the wall construction is essentially symmetrical about a virtual surface that subdivides the inner zone into two equal parts.

With reference to Figure 4, a distance D between the slats is between 10 and 80 percent of a width W of the slats. The width W of the slats is between 50 and 150 mm, and is in particular 100 mm. The vertical distance 40 between the front edges is 50 - 100 mm, in particular 60 - 70 mm. A thickness of the slats 20 is between 3 and 12 mm, more in particular between 4 and 10 mm. This depends on the desired level of security.

The distance 42 between the first barrier and the second barrier is between 0.5 and 1.5 meters, in particular between 0.7 and 1.90 meters. The distance 42 between the first and second barrier is less than 50 percent of the height of the wall construction, in particular 10-20 percent of the height of the wall construction. A distance 43 between the outer sides of the uprights 14 is between 1.0 meter and 1.25 meter.

The height 44 of the wall construction can be approximately 3-10 meters, more in particular approximately 4-8 meters.

A steel girder 46 is provided under each frame 26 for supporting the wall structure and for providing a connection to the foundation. The steel beam 46 extends transversely to the main direction of the wall construction. The steel girder is supported by a further steel girder 48 which forms part of the foundation and which rests on a concrete substructure 50. The further steel girder 48 extends parallel to the main direction of the wall construction 10. A steel plate 62 extends downwards from a foot of a barrier and serves as a shield for the foundation.

It will be clear that in this embodiment the wall construction has no reactive or explosive armor and is a passive device.

With reference to Figures 5A, 5B, 5C and 5D and 6A, each slat panel 100 comprises a frame 110. The frame comprises two horizontal beams 112, two vertical elements 114 located on the side and two vertical spacers 19. The slats 20 are mounted on the frame 110. Slat panels are formed in this way, which can be mounted as a stand-alone component. This provides an advantage of rapid construction of the wall construction.

Figure 6A shows a side view of a slat panel. It can be seen that the vertical element 114 has recesses 116 that are inclined. The ends of the slats are inserted into the recesses 116. The vertical element 114 also has a stiffening rib 118 for providing flexural stiffness and for holding the slats in place. The slats are inserted with their ends and remain in place without having to be screwed down. This results in a very simple assembly. Mounting points 120 are provided for mounting on a post 14 of a vertical frame 15. Figure 6B shows a spacer without the slats 20 therein.

With reference to figures 7A and 7B, top views are shown of the wall construction with the slat panels. The vertical elements are attached to the uprights 14 of the vertical frames. The horizontal frames 102 have longitudinal beams 121, diagonal elements 122 that serve as wind braces, and transverse beams 123. Figure 7A shows a top view of the horizontal frame 102 halfway up the height of the wall structure and Figure 7B shows a top view of the upper horizontal frame 102.

Figure 8 shows how the panels 100 are placed on the self-supporting structure. First, the self-supporting structure 75 is erected, and then the slat panels are mounted against it, on both sides. In this way the wall construction can be built quickly.

With reference to Figure 9, during operation the wall structure 10 protects a target object 55 against explosions and against incoming bullets or other projectiles. Two wall structures 10 are arranged parallel to each other and define long sides of a rectangle. The rectangle encloses a space. The short sides are defined by concrete walls 59. The concrete walls 59 can also be designed as wall constructions 10 according to the invention. The wall constructions are placed at a distance 61 from the target object 55.

Different types of target objects can be protected, such as a building, an electrical installation, a vehicle, etc ..

Referring to Figure 10, an alternative wall structure 200 is shown wherein two rows 130A, 130B of slats 20 are placed close to each other. The distance 132 between the slats is smaller than the width W of the slats.

The slats have otherwise the same characteristics as the slats of the previous embodiment as those skilled in the art will immediately see.

Vertical box profiles 136 are erected at a regular heart-to-center distance from each other. These can also be other profiles. Plates 134 are attached to each box section with recesses for the slats 20. The alternative embodiment according to Figure 10 is very cost-effective.

Detailed embodiments of the present invention are disclosed in this document. It will be understood, however, that the disclosed embodiments are merely examples of the invention and that the invention may be practiced in various ways. Therefore, specific constructive and functional details disclosed herein should not be seen as limiting, but merely as a basis for the claims and as an explanation to a person skilled in the art to implement the invention in various ways. Furthermore, the words and terms used are not to be construed as limiting, but as an understandable explanation of the invention

The word "one" used herein is defined as one or more than one. The term "multiple" is defined as two or more than two. The term "to have" is defined as include, i.e., an open term where other elements or steps are not excluded. Reference numerals in the claims are not to be construed as limiting the scope of the claims or the invention.

The mere fact that features are mentioned in different dependent claims does not mean that a combination of these features could not be used to advantage.

Claims (20)

An explosion and bulletproof wall structure (10), comprising: - a first barrier (12A) and a second barrier (12B) positioned at a distance (42) from each other, - a plurality of barrier connections (16) between the first and second barrier in the form of vertical frames (15), wherein the vertical frames are arranged at a regular distance (29) from each other, each vertical frame comprising a first upright (14A) associated with the first barrier and a second upright (14B) ) which is associated with the second barrier, and wherein each vertical frame further comprises connections (39) between the first and second uprights, - an inner zone (18) located between the first and second barrier, and which is substantially empty wherein at least one barrier comprises a plurality of protective slats (20), the slats extending horizontally between a first upright (14A) and a second adjacent upright (14A ') of a barrier, wherein the protective slats are directed obliquely upward, going from the outside to the inside, in order to absorb a shock wave of an incoming explosion or an incoming projectile and to deflect it upwards, the slats defining obliquely upwardly directed channels (24) between them, the slats and the obliquely upwardly directed channels forming a partially closed, partially open structure, the slats restraining part of an incoming shock wave and wherein the channels are adapted to cause another part of the incoming shock wave to pass through the barrier and deflecting upwards, and wherein the slats are constructed to bear forces of an explosion or incoming projectile on the vertical frames, and wherein the vertical frames are constructed to bear the forces on the ground. A wall structure as claimed in claim 1, wherein both barriers comprise said slats, and wherein the slats of the first barrier have an inverted slope as the slats of the second barrier. A wall structure according to claim 1 or 2, wherein at least one horizontal frame (102) extends between each of two adjacent vertical frames (15) and is attached to both vertical frames, and wherein the vertical frames (15) and the horizontal frames (102) ) together form a self-supporting structure. Wall construction according to one of the preceding claims, in which a number of slats are each arranged on a frame (108) to form a slat panel (100) that is mounted as a stand-alone component on two vertical frames (15) and wherein in particular between adjacent vertical frames (15) a plurality of slat panels (100, 100 ', 100 ") are arranged one above the other. A wall structure according to any one of the preceding claims, wherein the wall structure (10) has no roof and the inner zone at the top is largely open, and in this way provides an escape route around an incoming shock wave through the inner zone and via an opening ( 28) to guide upwards and outwards between upper ends (30) of the first and second barrier. Wall construction according to one of the preceding claims, wherein a rear edge (32) of each slat (20) is at a higher level than a front edge (33) of a slat (20) located directly above it, so that the barrier from the outside has a closed appearance. Wall construction according to one of the preceding claims, wherein each frame is designed as a lattice structure (26), wherein each lattice comprises a post (14A) of the first barrier and a post (14B) of the second barrier. Wall construction as claimed in any of the foregoing claims, wherein the slats extend at an angle of 15-80 degrees with the horizontal. Wall construction according to one of the preceding claims, wherein a distance (D) between the slats is between 20 and 80 percent of a width (W) of the slats. Wall construction according to one of the preceding claims, wherein the distance (42) between the first barrier and the second barrier is between 0.5 and 1.5 meters, in particular 0.7 -1.0 meters. 11. Wall construction as claimed in any of the foregoing claims, wherein the first and second barrier are vertical. 12. Wall construction as claimed in any of the foregoing claims, wherein the vertical frames and the slats are made of steel. Wall construction as claimed in any of the foregoing claims, wherein the distance between the first and second barrier is less than 50 percent of the height of the wall construction, in particular less than 20 percent of the height of the wall construction. A wall construction according to any one of the preceding claims, wherein the slats of each barrier all have the same slope. Wall construction according to one of the preceding claims, wherein the wall construction does not have a reactive or explosive armor, but is a passive construction. Wall construction as claimed in any of the foregoing claims, wherein the slats have a length of 1 - 5 meters, in particular 2-4 meters, wherein the length corresponds to the distance (29) between the vertical frames. A wall construction according to any one of the preceding claims, wherein a steel girder (46) is provided under each framework for supporting the wall construction and providing a connection to the foundation, the girder being transverse to a main direction of the wall construction, and wherein a central beam (48) is arranged underneath these steel beams which extends in a main direction of the wall construction. A method of providing protection against an explosion or against a bullet or other incoming projectile, the method comprising applying a wall structure according to any of claims 1 to 22 and protecting a target object with the aid of the wall structure. A method according to claim 18, wherein first a self-supporting structure is erected which comprises vertical frames (15) and horizontal frames (102) which together form a self-supporting structure, and wherein subsequently lamella panels (100) are mounted on the self-supporting structure, wherein each slat panel comprises multiple slats. An explosion and bullet-proof wall structure (200), comprising: - a first barrier (12A) and a second barrier (12B) positioned at a distance (132) from each other, - a plurality of barrier connections (16) between the first and second barrier in the form of vertical profiles (136), - an inner zone (18) located between the first and second barrier, and which is substantially empty, both barriers comprising a plurality of protective slats (20), the slats being located extending horizontally between a first vertical profile and a second vertical profile, with the protective slats directed obliquely, going from the outside to the inside, the slats defining sloping channels (24) between them, and the slats of the first barrier and the second barrier have opposite slopes. the slats and the oblique channels forming a partially closed, partially open structure, the slats restraining part of an incoming shock wave and wherein the channels are adapted to cause another part of the incoming shock wave to pass through the barrier, and wherein the slats are constructed to bear forces of an explosion or incoming projectile on the vertical profiles (136), and wherein the vertical profiles (136) are constructed to bear the forces on the ground.