Safety device for a fall restraint

Abstract

A safety device for a fall restraint includes an anchoring member (1) to which the fall restraint can be coupled directly or indirectly, and a fastening element for a firm and durable connection to an object (10). The fastening element is formed by a flexible fastening flap (11) which extends laterally from the device and which is intended and adapted to bring about the firm and durable connection to the object.

Claims

1. A anchoring device for a personal fall protection restraining a person from falling from an elevated surface of an object, said anchoring device comprising: an anchoring member for securing said personal fall protection, directly or indirectly, fastening means that, during use, provide a firm and reliable connection of said anchoring device to said object, and a substantially flat, substantially rigid body that comprises said anchoring member, wherein said fastening means comprise a flexible fastening flap that extends laterally from said rigid body and that is, during use, glued, welded, fused or otherwise adhered without a penetrating mechanical fastener to an exposed surface of said object to create a physical bond with said elevated surface in order to provide said reliable connection of said anchoring device to said object, wherein said substantially flat, rigid body comprises a flange-shaped first member and a flange-shaped second member that enclose a portion of said flexible fastening flap therebetween to form said anchoring device as a pre-formed assembly that is ready to be adhered to the object by means of said flexible fastening flap.

2. The anchoring device according to claim 1, wherein at least one of said flange-shaped first member and said flange-shaped second member is provided at an inner side with attaching members which extend into said flexible fastening flap.

3. The anchoring device according to claim 1, wherein said flange-shaped first member and said flange-shaped second member are provided at their centre with cup-shaped profiles which are nested into each other.

4. The anchoring device according to claim 3, wherein said flange-shaped first member and said flange-shaped second member are mutually connected by means of a central screw bolt with nut, said screw bolt protrudes through said flap and is received together with said nut at least partly in the cups, and the anchoring member is connected, or at least connectable, to a free end of the screw bolt.

5. The anchoring device according to claim 4, wherein the anchoring member comprises a fixing eyelet which is connected releasably to the screw bolt.

Description

(1) The invention will now be further elucidated on the basis of a number of exemplary embodiments and a drawing. In the drawing:

(2) FIGS. 1-2 show a first exemplary embodiment of a safety device according to the invention;

(3) FIGS. 3-4 show a second exemplary embodiment of a safety device according to the invention, respectively in perspective view and in cross-section;

(4) FIGS. 5-7 show respectively a first and second perspective view and a cross-section of a third exemplary embodiment of a safety device according to the invention;

(5) FIG. 8 shows a top view of a fourth embodiment of a safety device according to the invention;

(6) FIG. 9 shows a cross-section of a fifth embodiment of a safety device according to the invention;

(7) FIGS. 10-11 show a sixth embodiment of the safety device according to the invention, respectively in perspective and in cross-section;

(8) FIG. 12 shows a seventh embodiment of the safety device according to the invention in perspective; and

(9) FIGS. 13-15 show an eighth embodiment of the safety device according to the invention in perspective view.

(10) The figures are otherwise purely schematic and not drawn to scale. Some dimensions in particular may be exaggerated to a greater or lesser extent for the sake of clarity. Corresponding parts are designated as far as possible in the figures with the same reference numeral.

(11) A first exemplary embodiment of a safety device for a fall restraint according to the invention is shown in FIGS. 1 and 2, respectively in perspective view and in cross-section. The device comprises a strong anchoring member 1 in the form of a fastening member formed on an outer end of a heavy screw bolt 2. In this embodiment both parts are manufactured from stainless steel. On an opposite end the screw bolt 2 is provided with a metric screw thread (M16) for receiving thereon a locking nut 3 with interposing of a washer 4. A standard fall restraint, for instance a safety line of a fall-arrest harness or safety harness, can be secured to the fixing eyelet in usual manner, for instance by means of a preferably locked karabiner hook or snap hook, in rapid and reliable manner. The device finds particular application for temporarily securing workpeople during operations at height on an object such as a house, apartment building or industrial installation. The device is herein connected permanently to the object.

(12) For a permanent connection to the object the device is provided with fastening means in the form of a flexible fastening flap 11. This latter extends laterally from the device and with its relatively large surface area provides an attachment base for a durable fixing of the safety device to a wall or a roof of the object. In this embodiment use is made for fastening flap 11 of a flexible roof-covering material with a view to a welded connection to a like covering on the object at that location. This is more particularly a bituminous or plastic roof-covering material intended for fusing or glueing at an increased temperature to a similar roof covering such as applied on many flat roofs. The application of the safety device is not however limited to outer walls and roofs with such a type of finishing. The device can instead be for instance glued or otherwise adhered to diverse other types of roof and outer wall covering and sheeting, or be applied directly on an outer wall or roof of the object. In all cases the invention provides the option of realizing a durable and sufficiently reliable connection between the safety device on the one hand and the object or a covering thereof on the other, without affecting the integrity of the construction of the object or also without interfering therewith.

(13) In the shown embodiment the fastening flap 11 extends all around from the other part of the device. As further shown in cross-section in FIG. 2, the fastening flap is connected to two flange-like bodies 21, 22 which fit over each other and which in this embodiment are both manufactured from strong stainless steel plate. With a view to the mutual attachment, fastening flap 11 is provided in the centre thereof with a hole or opening 12 through which protrudes the screw bolt 2 with nut 3. The fastening flap herein lies enclosed between the two flange-like bodies 21,22 which are likewise provided in their centre with a bore for passage of the screw bolt. Fastening flap 11 is clamped between the two flange-like bodies 21,22 by tightening the nut onto the screw bolt, which provides a firm and durable connection. Both flange-like bodies 21,22 are moreover provided with a profile in a direction substantially transversely of a radial direction from the centre thereof, in the form of cups 25 which are formed thereon and which are nested in each other. Such a profile provides a certain pull relief in the case of a fall, and in addition provides a cavity 23 for receiving therein the free end of bolt 2 with nut 3, so that a base of the safety device nevertheless remains flat. The elevation resulting from the cups moreover provides an external drainage which prevents the entry of rainwater.

(14) The arranging of the safety device on for instance a flat roof provided with a bituminous roof-covering 10 can be carried out relatively simply and quickly with hardly any effect on the integrity of the original roof-covering. To this end the original roof-covering 10 is cleaned at the location and the device placed thereon with the lower flange-like body 21. Using a conventional burner or hot-air drier the bituminous fastening flap 11 is then fused at increased temperature with the existing bituminous roof-covering 10 to form the cohesive whole shown in FIG. 1. Because there is in principle no penetration here through the original roof-covering 10, the watertightness and integrity of the whole remains ensured. An auxiliary flap of bituminous roof-covering material can optionally be placed beforehand under the lower flange-like body 21 so as to create extra material here which will soften when the assembly is heated and will thus give a certain adhesion between flange-like body 21 and the roof-covering lying thereunder.

(15) A second exemplary embodiment of a safety device according to the invention is shown in FIGS. 3 and 4, respectively in perspective view and in cross-section. This exemplary embodiment corresponds for the most part with that described above, except that in this embodiment one of the two flange-like bodies 22 is provided with protrusions, staples or nails 26 so as to exert more grip on the fastening flap 11 clamped between the two flange-like bodies 21,22. A comparable or additional extra grip can be obtained by similar protrusions, staples or nails in the other flange-like body or by roughening the surface of one or both flange-like bodies directed toward the fastening flap. Instead of or in addition to protrusions 26, one or more ridges can also be punched into one or both flange-like bodies.

(16) FIGS. 5, 6 and 7 show respectively a first and second perspective view and a cross-section of a third exemplary embodiment of a safety device according to the invention. In this embodiment the two flange-like bodies 21,22 are provided at corresponding positions with bores 27 for receiving therein nails 28 or other through-attaching members. FIG. 5 here shows an upper side of the device while FIG. 6 shows an underside. This embodiment otherwise corresponds to the first embodiment described above. Nails 28 are forced through fastening flap 11 from one of the two flange-like bodies and are received in the corresponding openings of the other flange-like body. The fixing of fastening flap 11 to the other part of the device can thus be realized as a permanent attachment. Use can optionally be made of shorter nails, screws or other attaching members which thereby penetrate only partially into the fastening flap so that the other flange-like body is not affected. Bores 27 or other recesses can in that case be omitted from this latter flange-like body. Instead of separate nails, nails can also be applied which are welded or otherwise fixedly connected to the relevant flange-like body.

(17) A top view of a fourth embodiment of a safety device according to the invention is shown in FIG. 8, wherein for the sake of clarity the fastening flap, which is otherwise present, is not further shown. In this case also the device comprises two flange-like bodies 21,22 which clamp a fastening flap therebetween with which the assembly can be attached fixedly to an outer wall, roof or other wall of an object. Other than in the foregoing exemplary embodiments, the lower flange-like body 21 has a significantly larger cross-section than the upper body so as to thereby provide a larger base for the assembly. The possible forces exerted on the device during a fall are thus distributed over a larger area. The lower flange-like body 21 is also provided in this embodiment with incisions 29 running at least substantially radially from the centre thereof. These incisions allow a plastic deformation of body 21 and thus form as it were a crumple zone in the assembly. In the case of a fall the forces developing therein will result in a deformation of the body, which thereby absorbs a part of these forces. This reduces the load on the body of the falling person and thus prevents more serious injury. The upper flange-like body 22 shown here can optionally also be applied under the first flange-like body 21 so as to distribute the falling forces better over the first flange-like body 21.

(18) In addition, at least the lower flange-like body comprises in this embodiment two rings with perforations 31,32 around the cup 25 formed thereon. These perforations enhance in the first place the forming process of cup 25, which is manufactured by being pressed from a flat plate. In particular the inner ring with perforations 31 provides this deformability. In addition, perforations 31,32 allow direct material contact between fastening flap 11 and a surface 10 at the position of flange-like body 21, which enhances the mutual attachment. Perforations 31,32 also impart a certain plastic deformability to the assembly during a possible fall, whereby as with the incisions 29 a certain shock absorption is achieved. This latter is particularly the case for the outer ring with perforations 32.

(19) FIG. 9 shows a fifth embodiment of a safety device according to the invention. In this embodiment a flexible fastening flap 11 is also clamped between two flange-like bodies 21,22, the lower 21 of which has larger dimensions. A screw bolt 2 having on an outer end a fixing eyelet 1 as anchoring member passes through the centre of an assembly and holds the assembly clampingly together due to the locking nut 3 screwed thereon. In order to avoid the fastening flap 11 tearing or being otherwise damaged on a possibly sharp edge of the lower flange-like body, a peripheral edge 13 of the lower flange-like body 21 is bent so that the edge projects toward a side remote from fastening flap 11 and cannot therefore come into contact therewith.

(20) A sixth embodiment of the safety device according to the invention is shown in FIGS. 10 and 11, respectively in top view and in cross-section. Other than in the foregoing exemplary embodiments, this device comprises only one flange-like body 21 which is connected to a fastening flap 1 for instance by glueing or nailing. As in the foregoing exemplary embodiments, this flange-like body 21 provides a base for attaching an anchoring member in the form of a fixing eyelet 1 formed on a screw bolt, while fastening flap 11 is intended for glueing, welding or fusing to a surface for the purpose of a durable connection of the assembly to an object. If desired, it is also possible to make use of an anchoring member which forms an integral part with the flange-like body or is permanently connected thereto by means of welding or in other manner.

(21) Although the application of one or more flange-like bodies for fixing a fastening flap has been found exceptionally reliable and effective, the invention can also be embodied without such a body. A seventh exemplary embodiment of the device is an example hereof and is shown in FIG. 12. In this exemplary embodiment an anchoring member in the form of a closed ring 1 is coupled to a set of crossed straps 15. Using nails or staples 14 straps 15 are in turn connected mechanically to a flexible fastening flap 11 with which the assembly can be attached to an object 10.

(22) Apart from being applied as a discrete, local anchoring point, the device according to the invention can also be applied in a system of safety devices so as to arrange a more extended anchoring cable. An eighth exemplary embodiment of a safety device according to the invention which can be applied in such a system is shown in FIGS. 13-15. Use is made here of a set of two flange-like bodies as also applied in the above described exemplary embodiments of the invention, which may or may not be the same size and between which a fastening flap 11 is clamped. Instead of a central screw bolt with a fixing eyelet formed fixedly thereon, use is made in this exemplary embodiment of a screw bolt with a normal head. In addition to serving for the mutual attachment of the flange-like bodies 21,22 and fastening flap 11, this bolt also serves to fix a separate anchoring member 40 in the form of a cable bushing or cable guide for a safety cable 50, see also FIGS. 14 and 15.

(23) The anchoring member 40 applied here comprises a flat base 41 with an upright 43 which extends therefrom and has a bent portion 44 close to the base. Base 41 comprises a central opening 42 into which fits the central bolt 2 with which anchoring member 40 is fastened to the other part of the device. Mounted on a free end of upright 43 is a hollow tube 45 through which safety cable 50 can be guided. Hollow tube 45 can take a straight form, see FIG. 14, but preferably narrows at either side, see FIG. 13, in order to effectively guide a so-called sliding carriage over safety cable 50 during use.

(24) The anchoring member is manufactured wholly from strong, impact-resistant material. In this embodiment stainless steel is applied for this purpose, wherein base 41 and upright 43 are formed from plate steel with a thickness in the order of 4-6 mm, while the hollow tube is welded thereon. Instead of such mutually connected parts, it is also possible, depending on the chosen starting material, to apply an integral anchoring member which is then formed for instance as a casting.

(25) A number of such safety devices can be applied to guide a safety cable over a desired length in a desired path, see FIG. 15. The various safety devices are herein connected in the above described manner to a surface, or a bituminous roof-covering, by means of the flexible fastening flap. Safety cable 50 is generally received freely in the intermediate devices and attached fixedly to the outermost device. A person who goes onto a roof or to other high position where such safety devices are arranged can secure himself by means of a harness, lifeline and sliding carriage to anchoring member 50, and then has complete freedom of movement along the safety cable.

(26) In the case of a possible fall from the roof, a tensile force is in the first instance exerted on safety cable 50 via a lifeline of the harness. Owing to the height of safety cable 50 above the base 41 of anchoring member 40, caused by the height of uprights 43, this produces a considerable moment relative to this base. Owing to the pre-bent design of upright 43, this results in a controlled bending of the uprights which thereby absorb a part of the kinetic energy, while the fastening of anchoring members 40 to the other part of the device is moreover spared. Through folding down of uprights 43 the tensile force will be directed parallel to the roof surface, whereby it can be resisted in optimal manner.

(27) The device according to the invention can in principle be applied on any structural type of roof or outer wall construction, wherein the strength of the construction is of secondary importance. Examples hereof are roof coverings or wall claddings of bitumen or plastic which are wholly or partially adhered, mechanically fixed or ballasted with loose material. The application of the safety device according to the invention complies with the EN 795 standard known to the skilled person. This standard describes the requirements for the testing methods for anchor provisions intended for personal protection against falls. The two essential points from the EN 795 standard are: a static test wherein a force of 10 kN can be resisted for 3 minutes in the direction in which the force can be applied during use; and a dynamic test wherein a mass of 100 kg, connected to the anchor point with a steel cable, is stopped in a free fall of 2500 mm.

(28) Although the invention has been further elucidated above on the basis of only a number of exemplary embodiments, it will be apparent that the invention is by no means limited thereto. On the contrary, many variations and embodiments are still possible within the scope of the invention for a person with ordinary skill in the art. The different embodiments of the safety device for fall restraint according to the invention have in common that they are lightweight and can be mounted rapidly with simple means and tools. Specific to this safety device is that the force released during a fall is absorbed in elastic manner by the materials from which the device is manufactured. When the occasion demands, a plastic deformation of one or more components of the device will absorb a significant part of the kinetic energy of a fall. The forces are then transmitted to the existing covering of the roof or the outer wall or to the roof or the outer wall itself.