CZ278958B6 - Fastening detail - Google Patents

Abstract

Multi-function, integrally moulded, plastic fasteners which function in hollow, thick or solid support members such as walls or partitions comprise a collapsible anchoring element connected, integrally, to a base element. The anchoring element is capable of movement between a closed minimal-dimension fully collapsed position, suitable for insertion within a hole; and a fully opened anchoring position suitable for use with a thin or hollow support, when the collapsed anchor passes completely beyond the hole.

Description

The invention relates to a fastener, in particular a multifunctional molded plastic fastener, for fastening objects to hollow, thick or solid support surfaces, for example walls or partitions.

BACKGROUND OF THE INVENTION

The multifunctional plastic expansion fasteners described in U.S. Pat. No. 3,651,734 have had immense commercial success worldwide. Such a component acts as a wedge in a solid wall and, in addition, can open when inserted into the hollow wall so that it forms a solid anchor on the other side of the wall. Modified embodiments of these fasteners are limited in use. Although the fastener described in U.S. Pat. No. 4,182,061 has a higher load-bearing capacity, it is intended only for fastening to a hollow wall. The expansible dowels, for example according to U.S. Pat. Nos. 4,142,440 and 4,518,291, are intended exclusively for fastening to solid walls.

For all of these fasteners, a hole of sufficient diameter must first be drilled in the support surface, for example in the wall, to pass through the anchoring element of the component. It is desirable that the diameter of the hole be as small as possible to minimize damage to the wall in addition to aesthetic reasons, to facilitate drilling, particularly in masonry or concrete, and to avoid having to fill a cavity too large after removing the fastener. A number of fasteners, particularly those intended for hollow walls, are designed in such a way that their anchoring elements can be folded or folded over to reduce the necessary size of the borehole. Attempts to reduce the intrinsic dimensions of the anchoring elements to such an extent that the diameter of the borehole is substantially reduced resulted in only a reduced load-bearing capacity of the fastener.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a multifunctional fastener that can be used to fasten objects to a fastener. hollow, thick or solid walls with through holes of reduced dimensions, wherein the fastener should have the same or increased load capacity as compared to components that require larger through holes.

SUMMARY OF THE INVENTION

This object is accomplished by a fastener for attaching objects to a support surface, for example a wall consisting of a hollow cylindrical base, extending at one end thereof into separate elongated arms which are pivotally movable between a clamped position of minimum dimensions and an open position, provided on both their facing longitudinal sides with a profiled rim which engages in the clamped position of the arms according to the invention, the essence of which is that the inner ends of the arms are connected to each other by a pivot joint provided with a hole coaxial with the guide hole in the base and for insertion of a fastening element, wherein the inner space formed in the base has a size and shape equal to or greater than the size and shape of the two halves of the pivot joint when the arms are fully closed.

-1GB 278958 B6

The fastening component according to the invention thus represents a hinged anchoring element connected to the base element, the connection being an integral connection. The anchoring element may move between a fully closed position in which its arms are in a clamped position in which it is of the smallest dimension and is therefore suitable for insertion into a hole or hole in the support surface, and between a fully open anchor position in which the fastener is applicable to hollow walls or partitions and the anchoring element extends completely beyond the opening provided in the support surface. The position of the anchoring element relative to the support surface depends on the nature of the support surface. This relative surface may be such that the anchoring element lies entirely within the hole in the solid support surface, or only such that the anchoring element passes completely beyond the support surface, as is the case when fastened to the hollow support surfaces. In thick walls, the anchoring element is in an intermediate position where it partially lies inside the hole and partly lies behind it. The base always remains fixed inside the hole. For fastening to very thin walls, the base is preferably connected to an outer flange which supports anchoring on a relatively thin bearing surface.

According to the invention, the anchoring element consists of at least two interlocking sections which engage in the clamped position of the fastening component in which it has the smallest dimensions. The ends of the intermeshing sections serve to firmly engage the external fastener, such as an anchor bolt, screw, nail, and the like, at a point away from the base. Due to the gap between the base and the anchoring element, the fastener can function as an anchor in a solid or thick wall as well as in a hollow or thin wall, depending on the wall thickness and the distance between the base and the anchoring element. Such a gap also increases the load-bearing capacity of the fastener in solid or thick walls where the anchoring element does not fully open behind the wall. This is due to a higher wedge effect caused by a greater angle between the engaging sections and the wall of the hole when the angle peak is outside the base. Moreover, in thick walls, this greater angle increases the weight of the intermeshing sections that extend beyond the rear edge of the hole; this increases the shear strength and load-bearing capacity of the component. Increased load-bearing capacity is particularly noticeable when the drill hole is higher than the fastener and the angular difference is greater.

The intermeshing sections are provided with peaks and depressions which lie in a plane perpendicular to the surface of the sections and which contact each other in the closed position of the anchoring element. The projections and depressions are of such dimensions and relative to each other that they may engage with each other. In addition, the protrusions have dimensions such that they can be compressed between the wall and the anchor bolt when the fastener is inserted in a solid or thick wall and the anchor element is therefore not fully opened. As a result of such compression, the bearing capacity of the component is increased.

insertion into the hole of file no. 673 035 described in the cited US publications, areas of sawtooth or wavy shape. These contact the inserted elongated fastening bolt, thereby facilitating the expansion of the anchor of all of these fastening bolts.

Expansible fasteners for solid material and described in German Pat. and expansible dowels, have an inner undulating surface of the element, for example an element, to the inner surface of the hole. In the components, the fastening element extends through the base. For this reason

-2GB 278958 B6 du are not expanding fasteners of this type usable for attaching objects to hollow walls. In addition, the height and depth of the teeth must be increased towards the end of the anchoring element to facilitate contact of the bolt with the entire surface of the fastener. Such an increase in the height of the teeth is suitable for the use of a fastener in a solid wall, but it is disadvantageous for fastening to hollow walls, since the bearing sections have reduced strength due to being too thin.

The projections and depressions of the interlocking sections of the fastener of the invention may have a sinusoidal shape or any other periodic alternating pattern. It is desirable that the interlocking sections each have at least two sets of juxtaposed protrusions and depressions that extend in the direction of the borehole axis when the fastener is in a closed folded position in which it has minimal dimensions. In such an embodiment, the protrusions and depressions are offset so that the protrusions of one set are opposed to the depressions of the other set, so that when folded, substantially all of the protrusions and depressions mesh together and form a substantially full surface. By this arrangement, the load-bearing capacity of the component for mounting on hollow or thick walls is considerably increased, since nowhere the material is excessively weakened. The thickness of the interlocking sections at the base of the depression should never be less than about half of the original thickness in order to avoid excessive weakening of the anchoring element and avoiding a higher load from the correct position. The variations in the depths and dimensions of the depressions must correspond to the dimensional changes in the projections that fit into the depressions. For aesthetic and manufacturing reasons, it is recommended that the recesses and projections have the same dimensions.

In order to further compensate for the reduction in load-bearing capacity induced by depressions, it is possible to use a reinforcing device. A suitable embodiment of the reinforcing device is a reinforcing rib extending lengthwise between the two adjacent sets of protrusions and depressions. The stiffening rib, which is preferably made of one-piece material of the intermeshing sections, protrudes vertically from at least the lower level of the depressions to a height not exceeding half the thickness of the intermeshing sections. In fact, at a higher height, the reinforcing rib would prevent the projections from engaging in the recesses in the closed position of the anchoring element. When the depressions and projections are clamped and the maximum rib height is high, there remains a very narrow gap between the facing sections of the reinforcement rib, which serves to guide the inserted fastening element between adjacent projections and depressions. Thus, the male fastening element essentially slides over smooth surfaces so as to form a wedge and provide high strength in the relatively compressible material of the fastening element, for example polypropylene. Less compressible materials, such as nylon, require a larger gap between the two sections of the stiffening rib in order to insert a screw into the fastener. In such materials, the screw bites into the surface of the reinforcing rib, causing a holding force.

According to the invention, it is preferable that the projections at the upper end have a slight bias towards the interior, so that when the projections are inserted into the depressions, the projections contact the adjacent section of the reinforcement rib. As a result of this frictional engagement, the engaging sections automatically remain in a closed position corresponding to the minimum dimensions so that the fasteners can be fastened automatically by a gun or other tool used for rivets. Fastening

These components, in particular those described in U.S. Pat. Nos. 3,651,734 and 4,181,061 require manual handling in which the anchoring element must be held in a clamped position with minimum dimensions in order to be inserted into a through hole in the support surface. However, the frictional engagement between the projections and the reinforcing rib must be releasable when the bolt, screw or nail is inserted into the base of the fastener. The automatic engagement between the projections and the reinforcing rib is thus used to automatically grip the anchoring element; in embodiments without a reinforcing rib, adjacent projections may engage the friction engagement, thus fulfilling the same task.

According to a most preferred embodiment of the invention, the fastener is of molded plastic and is provided with a base in the form of a sleeve in which there is an opening for receiving an elongated outer fastener. The base is connected at one end to columnar uprights which protrude outward from it and merge into an anchoring element in the form of two opposing arms. Above the interior of the fastener, the ends of the two arms lie together so that the arms can be folded together to form a composite anchoring element which can be inserted into a hole in a hollow or solid wall. The arms surfaces that face away from the base in the extended position and face toward each other when the anchoring element is tilted are provided with two sets of projections and depressions. The projections and depressions extend in a direction parallel to the length of the arms and are offset relative to each other such that the projections of one set are opposed to depressions of the other set lying on the opposite side of one arm. Thus, when the arms are folded together, substantially the entire projections and depressions on both arms engage to form a smooth surface with minimal cross-section. After inserting the fastener into a hole in a thick or solid wall, an elongate fastener such as a bolt, bolt, nail, or pin is inserted into the hole in the base of the fastener so that it touches the ends of the shoulders at a position above the base and then engages at least some engaging protrusions and depressions. In this application, the projections of the arms are compressed by the action of a fastening element, such as a bolt, and the arms can consequently extend a greater distance from the longitudinal axis of the fastening element than if they were connected directly to the base. This greater elongation angle increases the load-bearing capacity of the component, as the engagement between the component and the wall of the hole is more tight. In those applications where the anchoring elements cannot fully expand, for example in a thick wall, the load-bearing capacity increases due to the increased weight of the material of the anchoring element behind the drilled hole in the wall and thus due to the increased shear strength.

After inserting the fastener into a hole in a hollow wall or the like having approximately the same or less thickness than the length of the base and the uprights, an elongate fastener is inserted into the opening of the base. The fastening element engages the inner ends of the arms so as to promote their full opening and return to the extended position. The arms therefore remain anchored behind the inaccessible inner surface of the wall. In this case, the fastening element does not engage the projection.

-4GB 278958 B6

Overview of the drawings

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is an axonometric view of the fastener and shows how the fastener is molded when the fasteners are in the open position; FIG. 2 is a plan view of the fastener of FIG. 1; Fig. 3 is a side view of the component of Fig. 1 in sectional view 3-3 in Fig. 2, Fig. 4 is a front elevational view of the fastener of Figs. 1 to 3 in the stowed position of the anchoring elements; Fig. 1 to 4 illustrating its attachment in a hollow wall; Fig. 6 schematically shows a side view of a component showing its attachment in a solid wall; and Fig. 7 shows a schematic front view of a component of Figs.

DETAILED DESCRIPTION OF THE INVENTION

The fastening component 10 according to FIGS. 1 to 7 comprises a sleeve-like base 1 provided with a guide opening 2 for the passage of the elongate fastening element 16 shown in FIGS. 5 to 7. The guide opening 2 is preferably dimensioned such that a threaded fastening element 16, for example a screw, has been screwed into it. The base 1 is generally rounded and is connected to the column uprights 3, which are preferably in one piece with it. The webs 3 extend outwardly from the axis of the base 1 and merge into a pair of opposing arms 4. On the side opposite to the arms 4, the base 1 has a flange 5 that abuts on the outer surface of the wall 17a when the fastener 10 is inserted. The flange 5 preferably has about 75% larger area than the cross-section of the cylindrical base 1. The outer side of the base 1 is provided with anti-rotation ribs 6 which bite into the wall material 17a, 17b, 19, 20 and prevent rotation. fasteners 10 during installation. The outer edges of the webs 3 preferably protrude from the outer shell of the base 1 and act as reinforcement elements and additional anti-rotation elements, as shown in FIG. 3.

The inner ends 9 of the arms 4 lie outside the base 1 and, together with the uprights 3 and the upper surface of the base 1, nearest the arms 4, define the interior space 8. The interior space 8 has dimensions such that when the arms 4 are folded together for insertion into a hole in the wall, the webs 2 flex flexively inwardly toward the axis of the base 1 so that the inner ends 9 of the arms 4 swing inwardly into the interior space. 4. The groove 7 at the upper end of the base 1 is oriented transversely to the arms 4, so that the material of the swivel joint 13 of the two arms 4 fits downwards and pivots downwards into the interior 8 after folding the two arms together. fasteners 10 (FIG. 4).

Giant. 1 to 3 and 5 show the arms 4 in the open position as they are molded during manufacture. The upper surfaces of the arms 4 facing away from the base 1 are each provided with two sets of protrusions 10a, 10b and depressions 11a, 11b which are offset relative to each other so that the protrusions 10a lie on each arm 4 opposite the depressions 11b while the protrusions 10b lie opposite depression 11a. Thus, the projections 10a, 10b and depressions 11a, 11b together form wedge joints when the arms 4 are folded together as shown in Figure 4: the projections 10a of each of the two arms 4 engage in the depressions 11a of the other arm 4, and the projections 10b fit into the depressions. 11b. This will create

-5GB 278958 B6 anchoring element with minimum cross-section. The ends of the arms 4 on the side where the depressions 11a, 11b and the protrusions 10a, 10b are formed are end flat surfaces 12 which abut against each other when the arms 4 are tilted, thereby facilitating complete and uniform folding of the arms 4.

The inner ends 9 of the arms 4 are preferably joined together by a pivot joint 13 of such a small thickness that it can be bent, so that the inner ends 9 of the arms 4 are deflected into the interior space 8 once the arms 4 have folded together. The pivot 13 is provided with an aperture 14 coaxial with the guide aperture 2 in the base 1 and permits the elongate fastening element 16 to pass therethrough. As shown in FIG. 5. In the thick walls 19 of FIG. 6 and the solid walls 20 of FIG. 7, the locking engagement between the fastening element 16 and the arms 4 is distributed to varying degrees between the fastening element 16 and the periphery of the opening 14 and the projections 10a, 10b. As a result of this construction, a fastening structure with a high load-bearing capacity is produced in all positions. Although the fastener 10 is shown in the drawings with a rotatable joint 13 provided with an opening 14 for the passage of the fastener 16, the same engagement would occur if the inner ends 9 of the arms 4 were not joined but would only lie close together so as to form engagement with the fastening element 16 inserted.

The fastener 10 has a central stiffening rib 15 that is formed on both arms 4 between the two sets of protrusions 10a, 10b and depressions 11a, 11b (Figs. 2 and 3). The stiffening rib 15 strengthens the folding arms 4 and thus compensates for their weakening due to depressions 11a, 11b. In addition, the upper edges of the protrusions 10a, 10b are inclined slightly inwardly as shown in FIG. 3, and thus they rub against the opposing wall of the reinforcing rib 15 as the arms 4 are folded together to slip into the hole in the wall to form a fastening component 10 minimum dimensions. This frictional engagement keeps the fastener 10 in a collapsed shape, having minimal dimensions (FIG. 4) until the arms 4 open as required. As a result, the fastener 10 is suitable for automatic insertion, for example by a gun. If desired, the fastener 10 can be retracted and the arms 4 can be opened in a single firing process.

The elongate stiffening rib 15 serves a further purpose, namely to form a narrow guide for receiving the elongate fastening element 16. When the fastening element 16 passes through the openings 14, it is centrally oriented between the projections 10a, 10b. With the exception of a slight gap between opposing sections of the reinforcing rib 15, the moving bolt or other fastening element 16 is surrounded by a virtually rigid material so that displacement of the plastic material of the sections of the reinforcing rib 15 produces a maximum wedge effect.

The surfaces of the arms 4 lying on the opposite side to the protrusions 10a, 10b and the depressions 11a, 11b are preferably rounded, so that when the arms 4 fold together before being inserted into a hole in the wall, a cylindrical formation is formed which easily slides into the hole of essentially the same diameter. This increases the wedge effect of the fastener 10 when fastened by the fastening element 16 in a solid or thick wall

-6GB 278958 B6

19, 20.

The arms 6 move in a pivoting motion when opening and tilting, i.e. moving from the expanded position of FIGS. 1 and 3 to the stowed position of FIG. 4, so that once folded together from the stowed position they remain in the stowed position or remain in the deployed position on opposite sides of the unstable center of the pivoting movement. This is achieved in that the inner ends 9 of the arms 4 have dimensions such that, when the arms 4 swing, the legs 3 act as springs on the inner ends 9 of the arms 4 and the center of the pivoting movement of the arms 4 lying in the pivot joint 13. When the inner ends 9 of the arms 8 are separated but lie close together, the wrench, screw or other fastening element 16 moves the arms 8 from the folded to the unfolded position.

The fastener 10 according to the invention may be provided on the base 1 with an external holding device as shown in FIG. For example, the holding device may be in the form of a band 1 ', a hook, a ring, a roller and the like.

Giant. 5 to 7 illustrate a fastener 10 mounted on a two-layer wall 17a, 17b and a thick wall 19 and 20 respectively. The fastener 10 is locked in the fastened position by an elongated threaded fastener 16 that is at least approximately the same length as the total length of the fastener 10 In all the applications of Figures 5 to 7, the fastener 10 is first clamped by folding the arms 6 together (Figure 4). After insertion into the hole in the wall 17a, 17b, 19, 20, the anti-rotation ribs 16 bite into the material of the wall 17a, 17b, 19, 20 and the fastener 10, for example a threaded bolt, is inserted so far that the head 18 is flush with the flange 5.

Giant. 5 shows a fastener 10 inserted into a two-layer wall 17a, 17b that is approximately as thick as the length of the base 1 and the webs 3. The screw which has passed through the guide hole 2 engages the inner ends 9 of the arms 8 and forces them out of the interior 8 at the pivot point 13 so that they move to the extended locked position by pivoting movement. In this position, the fastening member 10 is firmly retained in the hole in the wall 17a, 17b because the bolt presses on the inner ends 9 of the arms 6, causing the rigid arms 8 to be pressed against the inner surface of the wall 17a, 17b. The fastening component 10 is therefore reliably locked and the connecting element 16 is firmly gripped in its opening 2. Any fastening object to be fixed to the wall is then clamped between the screw heads 18 and the flange 5. Moreover, the two layers of the wall 17a, 17b are overpressed. to each other by the action of the fastener 10.

Giant. 6 shows a fastener 10 in a wall 19 whose thickness is greater than the length of the base 1 and the legs 4 of the fastener 10 but less than the total length of the fastener 10. In this case, the bolt passes through the holes 2, 14 and comes into engagement with the opposite This results in the outer curved surfaces of the arms 6 being tightly pressed against the inner surface of the hole in the wall in a direction perpendicular to the axis of the screw, and a portion of the arms protruding from the wall 19, they will spread beyond the back surface. The angle A, clamped by the arms 6 and the axis of the screw, has a vertex at the contact point inside

These arms 9 have the ends 9 of the arms 4 and are of such a size that the arms 4 could expand apart in the wall 19 and behind the wall 19. The larger angle A provides better wedging and higher shear strength and hence greater load-bearing capacity. In this context, it should be noted that in the prior art fasteners, for example according to the cited. U.S. Pat. The holding force and the wedge effect depend on the angle whose apex lies at the point of engagement of the screw and the base. This angle is considerably sharper than that of the fastener 10 according to the invention, so that the known component has a lower load-bearing capacity. Giant. 7 illustrates a fastener 10 inserted into a solid wall 20 having a bore hole slightly greater than the length of the fastener 10.

The carrying capacity of the fastener 10 in this application is given solely by the action of the fastening element 16, for example a bolt, on the projections 10a, 10b and the arms 4 so that the rounded outer sides of the arms 4 are firmly pressed against the inner walls of the hole in radial direction acting from the axis of the fastening. In this case, the angle A ' between the arm 4 and the axis of the screw is positioned such that it has a peak at the junction point of the inner ends 9 of the arms 4 and is therefore greater than the angle of known components. and base.

The fastener 10 of the present invention, made by injection molding of polypropylene, has the required strength and flexibility for conventional applications. Instead of polypropylene, other thermoplastic materials can be used which have strength and elastic properties suitable for the intended angle. When metal reinforcing elements are embedded in a portion of the base 1 and / or the arms 4, the fastener 10 has greater strength and hence greater load-bearing capacity. The molded fastener 10 may also be made to have metal surfaces and thus be electrically conductive for use in electrical installations.

The fastening member 10 is preferably made of a molded resilient plastic, for example polypropylene. Of course, other less resilient but stronger materials such as nylon may be used. If desired, the base 1 can be molded as one piece with an external fastener that holds or supports objects on the component.

It will be understood that the fastener described and illustrated is merely an example to which the invention is not limited. Although the fastener 10 described has two opposing arms 4, other preparatory arms with a similar type of interlocking surface may be used to provide the fastener 10 with minimum dimensions for insertion into the wall. All these variations are therefore within the scope of the invention.

Claims (5)

A fastener for attaching objects to a support surface, for example a wall, consisting of a hollow cylindrical base, extending at one end thereof into separate elongated arms which are pivotally movable between a clamped position of minimum dimensions and an open position, each of the arms being on both of their facing longitudinal sides provided with a profiled rim which engage each other in the clamped position of the arms, characterized in that the inner ends (9) of the arms (4) are connected to each other by a pivot joint (13) provided with an opening (14); coaxial with a guide hole (2) in the base (1) and intended to receive the fastening element (16), the inner space (8) formed in the base (1) having a size and shape equal to or greater than the size and shape of the two halves the joints (13) with the arms (4) fully closed. The fastening component according to claim 1, characterized in that the profiled edges of each of the arms (4) are arranged offset from one another. The fastening component according to claim 1, characterized in that the pivot connection (13) is formed from the material of the component, the side facing the hollow cylindrical base (1) being thinned. The fastening component according to claims 1 and 2, characterized in that a reinforcing rib (15) is arranged between the opposed longitudinal profiled edges of each arm (4). Fastening component according to claim 4, characterized in that the reinforcing rib (15) extends perpendicularly from the lowest level of the depressions (11a, 11b) of the longitudinal profiled arms (4) and its height is half the perpendicular distance between two opposite lines extending longitudinally. on the outer surface, fully pressed against the arms (4) lying in the longitudinal plane passing through the reinforcing ribs (15).