ENERGYABSORBING ELEMENT FORWALL OPENINGS ANDMETHODS OFUSE THEREFOR

FIELD OF THEINVENTION

This invention relates to articles used to secure closures of wall openings against the force of an explosion. More particularly, the invention is concerned with an energy absorbing element for wall openings.

BACKGROUND OF THE INVENTION

With security being an increasing concern, many methods have been utilized to reduce the potential occurrence of injury and damage due to the force of explosions. In particular, protection is desired against inward (i.e., away from the direction of the explosion) displacement of the frame of a window or door due to the blast. Typically, protection from explosions has been provided by the use of passive barriers, such as steel reinforced doors and laminated windows. In order to maintain an adequate level of protection, as the risk has historically increased, new barrier systems have increased in weight, thickness and structural and material complexity. While this may be acceptable in certain situation where ascetics are not a concern, such a bank vault or the like, in uses such as residential homes or office buildings requiring such protection, such solutions are inadequate. In addition, they may draw attention to the high security of the building, rendering it a target for an attack.

US 6,922,957 discloses an opening in a building wall closed by a building closure such as a window or door. A mounting part of the closure arrangement is received in a space between two countersupport surfaces formed by a U-channel

or opposite L-members that protrade perpendicularly from the sill or jamb surface of the wall bounding the opening. Mounting brackets secure the U- channel or L-members to the wall. On one or both sides, a respective damping element is interposed between the mounting part and the respective adjacent countersupport surface. The damping element may be a plastically deformable metal strip. When an explosion force acts on the closure arrangement, the damping element is first plastically deformed to absorb energy, before the remaining force is transmitted into the building wall. The two damping elements on opposite sides damp forces from the positive and negative pressure waves of the explosion.

US 6,216,401 discloses a blast resistant window framework and elements thereof. It describes the construction of the sash section for holding a window pane, being capable of effectively withstanding blast pressure if applied to it. This being achieved by the sash section comprising a main member enabling inter-engagement between the profiled sash member and the outer frame; a window pane holding member for accommodating and securing an end section of window pane in said sash profiled member; a reinforced member designed to support the end portion of the window pane and transmit blast pressure, if incidentally applied to the window pane, to the main member. The structured being resilient to blast pressure due to the applied blast pressure being transmitted to the main member, which deforms to utilize the energy. The sash section may be a profiled body or be composed of multiple inter-engaged segments.

SUMMARY OF THE INVENTION According to one aspect of the present invention, there is provided an energy absorber used to secure the closure of an opening of a wall of a building from being blown inward from the force of a blast, such as one caused by a nearby explosion.

It should be noted that hereafter in the specification and claims, the term closure is meant to denote a member fitted within the opening formed in a wall, including, for example, a door or a window.

The wall comprises, at each opening, a perimeter surface facing the opening, and a closure substantially filling the space of each opening. Each closure has edges which are substantially parallel to said perimeter surface of the wall. The energy absorber has a planar wall connecting portion, a planar closure connecting portion, and a plastically deformable deforming surface therebetween. The connecting portions are substantially parallel to one another. The deforming surface is adapted to absorb, by plastic deformation, a force applied to the closure by the blast.

The energy absorber may be formed as a metal plate. It may further comprise slots formed along the plate. One of the slots may extend longitudinally along a central axis of symmetry of the absorber. The slot is centrally located along the length of the absorber parallel to the axis and, according to a particular design, is more than two thirds the length of the absorber.

According to one embodiment, the energy absorber is mounted such that the longitudinal slots extend parallel to the perimeter surface and to the respective edge and according to another embodiment the energy absorber is mounted such that the slots are perpendicular thereto.

The energy absorber may comprise two or more through-going apertures, disposed about an axis of symmetry thereof. They may optionally be disposed symmetrically thereabout. In addition, it may further comprise two additional through-going apertures, disposed symmetrically about a different axis of symmetry of the absorber. The apertures are for attachment of the absorber to the wall and the closure by inserting a fastening element therethrough.

According to another aspect of the present invention, there is provided a method of securing a closure to an opening in a building wall. The method comprises the steps of providing an energy absorber as described above, and

securing the absorber to the opening and the closure such that is lies substantially parallel to facing surfaces of the wall and closure. In this way, a force applied of the closure will be absorbed/wasted by plastic deformation of the absorber.

The absorber may be secured to the closure such that a longitudinal axis thereof lies substantially parallel to the plane of the closure. Alternatively, it may be secured to the closure such that a longitudinal axis thereof lies substantially perpendicular to the plane of the closure. In such a case, it may be bent substantially into a J-shape.

According to a further aspect of the present invention, there is provided a closure for a wall opening installed according to the above method.

BRIEF DESCRIPTION OF THE DRAWINGS

In order to understand the invention and to see how it may be carried out in practice, embodiments will now be described, by way of non-limiting examples only, with reference to the accompanying drawings, in which: Fig. 1 is a perspective view of an energy absorber according to the present invention;

Fig. 2 is a partial view of a typical window, with the absorber illustrated in Fig. 1 secured thereto;

Fig. 3A is a top close-up view of one of the absorbers secured to the window as illustrated in Fig. 2;

Figs. 3B and 3C are cross-sectional views taken along lines III-III and IV- IV in Fig. 3 A, respectively;

Figs. 4 A and 4B show examples of plastic deformation of absorbers;

Fig. 5 is a partial view of a the window illustrated in Fig. 2, illustrating another method of securing the absorber illustrated in Fig. 1 thereto;

Fig. 6A is a top close-up view of one of the absorbers secured to the window as illustrated in Fig. 5;

Fig. 6B is a cross-sectional view taken along line V-V in Fig. 6A;

Fig. 7 is a partial view of a the window illustrated in Fig. 2, illustrating still another method of securing the absorber illustrated in Fig. 1 thereto;

Fig. 8A is a top close-up view of one of the absorbers secured to the window as illustrated in Fig. 7; Fig. 8B is a cross-sectional view taken along line VIII-VIII in Fig. 8A;

Fig. 9 illustrated a method of securing the absorber illustrated in Fig. 1 to a wall when the wall, in the immediate vicinity of the window, is made of a soft material; and

Fig. 10 illustrates a method of securing one or more absorbers illustrated in Fig. 1 to a wall in a cable catch system.

DETAILED DESCRIPTION OF EXEMPLARY EMBODIMENTS

As illustrated in Fig. 1, there is provided an energy absorber, generally indicated at 10. The absorber 10 comprises several through-going apertures 12a, 12b, a first slot 14 extending a majority of the length of the absorber and located centrally along its width, and several secondary slots 16. The absorber 10 is made of a material which deforms when subjected to high forces, such as those typical from an explosion. The absorber may be of any suitable thickness, but is typically within the range of between 0.5 to 3 mm.

During installation, several absorbers 10 are mounted to the jamb 18 of a window 20, as illustrated in Fig. 2. As seen in more detail in Fig. 3A, it is fastened by means of a fastener 22, such as a screw or other suitable hardware, inserted through one of the apertures 12a and into the jamb. As seen in Figs. 3B and 3 C, the side of the absorber 10, opposite that side which had been fastened, is raised, as permitted by the first slot 14. A second fastener 22 is secured to the surface 24 of the wall which faces the opening into which the window is to be installed. In order to permit this, holes 26 may be provided in the window jamb 18 in order to provide access to the fastener while securing the absorber 10 to the wall.

It should be noted that when installing the window, the side of the absorber 10 which is fastened to the window should be closer to the interior of the structure, and the side of the absorber which is fastened to the wall should be closer to the exterior of the structure. This assumes that the explosion is expected to occur exterior to the building. When the absorber is being installed in order to protect from an explosion expected to occur in the building interior, the above should be reversed. If it is not known where an explosion will occur, or if explosions are expected in both the building interior and exterior, the number of absorbers could be doubled, with half being installed in one direction, and half in the other.

When an explosion happens in the vicinity of the window, the building wall is typically able to withstand the force resulting from the blast. However, the window is pushed out of place by the force of the explosion. As it moves, it pulls the absorber 10 along with it, causing plastic deformation thereof. Figs. 4A and 4B illustrated typical effects on the absorber 10. (It should be noted that the absorbers illustrated in Figs. 4A and 4B are of a slightly modified embodiment, which do not comprise through-going apertures 12b.) The energy expended in the plastic deformation of the absorbers 10 reduces the amount of energy available to dislodge the window. Therefore, displacement of the window is minimized, and building fenestration is preserved.

The absorber 10 may also be utilized when the geometry of the window and/or the wall does not permit installation as described above. As illustrated in Figs. 5 through 6B, the absorber 10 may be fastened to the window jamb such that is lies perpendicular thereto. A fastener 22 is inserted through one of the apertures 12b and secured to the window jamb 18. The absorber 10 is bent slightly as illustrated in Fig 6, and secured to the surface 24 of the wall which faces the opening into which the window is to be installed. An explosion on the exterior of the building will cause the absorber 10 to plastically deform under compression, crushing it.

If desired, the absorber 10 may be bent into a J-shape after being secured to the window, as illustrated in Figs. 7 through 8B. This may be useful in a situation when installation such as illustrated in Figs. 5 through 6B is desired, but the available space is limited. In order for the absorber to be effective, it must be secured to a solid portion of wall. However, there arise situations when it is desired to place the window above a relatively soft portion of construction, such as wood. In such a case, the absorber 10 may be installed as illustrated in Fig. 9. The absorber 10 is secured to the window 20 with a fastener 22 in accordance with the present invention. A solid plate 32 is secured to the surface 24 of the solid portion 34 of the wall, such that a free end overhangs the soft portion 28 thereof. The absorber 10 is secured to the free end of the plate by an auxiliary fastener 30. The absorber works in the same way as described above. It should be noted that the solid plate 32 is not expected to deform substantially in the event of an explosion. The absorber 10 may further be used in a cable catch system, wherein taut cables are installed between opposite walls, or between a floor and a ceiling, behind a window. Thus, in the event of an explosion, the cable or cables prevent the window from being propelled inwardly. The area of attachment of such an arrangement to the wall (or ceiling/floor), and incorporating the absorber 10 according to the present invention, is illustrated in Fig. 10. As seen, the cable 38 is secured to a first leg 40a of a first L-bracket 40, and a first leg 42a of a second L-bracket 42 is attached to the surface 24 of the wall which faces the cable. Two absorbers 10 are attached to the second legs 40b, 42b of the L-brackets 40, 42. Optionally, a plate 44 may be provided between the two absorbers 10, instead of the second leg of one of the L-brackets, with the L-bracket being fastened to the side of one of the absorbers, as shown in Fig. 10. A covering 48 may be provided to conceal the absorber arrangement.

Those skilled in the art to which this invention pertains will readily appreciate that numerous changes, variations and modifications can be made without departing from the scope of the invention mutatis mutandis.