NO175273B - expansion plug - Google Patents

Abstract

A universal plug, which is injection moulded from plastic, contains a plug head (11), an expandable plug shaft (12) and a plug foot (13). The plug shaft (12) contains expandable segments, separated by longitudinal slots (17). The plug foot (13) contains a hole with a screw thread, so that the plug can be delivered with the screw inserted and can be driven into a drilled hole by engaging on the screw head. <IMAGE>

Description

The invention relates to a plastic expansion plug with a plug head, a plug stem connected to the head, where the plug stem is divided into several, deformable segments by means of longitudinal slits, and with a plug foot, which is located at the front end of the stem and is designed as a sleeve with a bore for receiving a screw, where the foot of the plug, when the screw is tightened, bends the segments outwards as a result of an axial movement, and the segments, which are separated from each other by the longitudinal slots, each have a roughly radially outward, narrow fin which precursor in the plug's longitudinal direction.

A plug of this type is known (DE-PS 22 54 602 and FR-A-2257035). This is a so-called universal plug, which can be used both in walls with a precise cylindrical bore and in hollow chamber stone etc. Therefore, the plug is advantageously applicable in cases where the user does not know how the wall is designed, where the plug is to be arranged. Depending on the wall material, the plug is fixed differently. For cylindrical bores, e.g. in concrete, the step-like segments are easily deformed outwards and fix the plug in this way. In the case of hollow chamber stone, the segments are strongly deformed outwards, so that a conformation is formed. In both cases, it is necessary for the plug's effect that it does not rotate when the screw is screwed in. The plug is driven into the hole when inserted into it. To prevent rotation, it must sit relatively tightly in the plug hole. This leads to a pressure effect or sprain of the plug.

It is also known to arrange sharp-edged fins on the outside of the steps of such universal plugs, where the outer edges, when the screw of the plug is tightened, press into the hole wall and therefore prevent rotation in both directions. These fins, which extend in the longitudinal direction, reinforce the plug stem against buckling.

Furthermore, a plastic plug is known from DE-A13610655, which has a neck that extends over approximately half the length of the plug and a connected spreading part with longitudinal slits. This plug must be driven into the bore without the screw being inserted. When the screw is screwed in, it forms a thread on the inside of the spreading part. Further examples of the prior art are known from DE-A13426994, DE-A12504753 and FR-A-2336583.

The invention is based on the task of providing a plug of this type, which can be used to a large extent as a universal plug for the most diverse conditions, but which has been further improved with regard to its performance characteristics, in particular the torque that must be provided.

This is achieved according to the present invention with an expansion plug of the kind mentioned at the outset, which is characterized by the fact that the bore has a screw thread and the fin in the area of its radial outside and approximately in the center of its longitudinal extent, has an incision or a notch. Further features of the invention appear from the independent claims.

It will now be possible to supply the plug with a screw even before assembly, as the screw is at least partially screwed into the threads of the plug foot. In this way, the plug can be used pre-assembled for through-mounting. The introduction of the plug into the borehole can be achieved by hitting the screw head, after which the plug is no longer pressure-affected, but tension-affected. This leads to improved insertion of the plug into the borehole. When the screw is tightened and the consequent loosening of the plug segments, a small counter-torque occurs, as the resistance to screwing in of the screw is reduced. This reduces the risk of the plug turning when the screw is tightened. Precisely in the case of a through-hole installation where the plug head is no longer visible at all, turning the plug would initially be overlooked.

The reduction of the screw-in torque which is effected by means of the invention can already be achieved when the threading is not fully formed, e.g. when the diameter of the top of the thread is somewhat smaller than the corresponding screw.

The fact that the plugs are delivered pre-equipped with the corresponding screw has the further advantage that the user can be sure that a screw suitable for the plug has been used in it. A plug's holding effect is highly dependent on the correct screw being used, especially a screw with the correct diameter.

The invention ensures that the plug stem has several, radially outwards, narrow fins which extend in the longitudinal direction and, when extended, drill into the wall and thus prevent the screw from turning in both directions.

These fins reinforce i.a. the stiffness of the segments of the plug stem in the longitudinal direction. But the plug must also be able to be used in hollow-chambered stone or behind slabs, where the segments must be slightly spread out so that a practical fit takes place. Here the fins cause the torque that must be applied to be increased, as they oppose deflection. Again, there is a risk of the plug turning. In order to prevent this, it is proposed according to the invention that at least one fin in the area of its radial outside has at least one notch or notch. This notch, which extends from the outside into the fin, does not eliminate the fin's effect when penetrating the bore wall and when reinforced in the longitudinal direction, especially when the notch does not extend to the outside of the segment. The notch, on the other hand, enables easier deflection of the segments.

As a further development, the segments themselves can also have at least one groove, notch etc. on their outside, which runs across the longitudinal axis of the plug. This also leads to easier screwing in and tightening of the screw, especially with stronger deflection.

It will be particularly advantageous if each segment has a fin and each segment also has a groove.

As a further development of the invention, the head of the plug can have several outer ribs which run longitudinally and which in cross-section are preferably approximately triangular with an outward-facing tip. These ribs contribute to the plug's head being securely fixed against turning in the bore, where the plug's head has a certain length along which it cannot be deformed outwards. In this way, the deformation of the plug's stem and thus the pressure effect on the wall must be kept away from the wall's surface, so that cracks do not form there.

In particular, the internal bore in the stem of the plug can be larger than the back diameter of the threads of the plug foot. This means that the screw with its threads does not attack the inside of the segments, so that they cannot be damaged.

In order to ensure easy unfolding, according to a further development of the invention, the plug can be produced with slightly outwardly bent segments.

The ribs in the plug head area preferably have a radial extent that increases in the direction of the plug head's outer, free end. Therefore, when the plug is inserted or driven in, a notch will gradually form in the longitudinal direction, and when the head of the plug is further driven in, a stronger, increasing penetration into the borehole wall is achieved.

Precisely this combination of the features proposed according to the invention, in particular that threads are provided in the bore for the base of the plug and that fins are provided that are provided with notches on the segments that are provided with grooves, leads to a plug with improved properties as a universal plug for all kind of occurring use cases.

Further features, details and advantages of the invention appear from the following description of preferred embodiments of the invention and from the drawings, where fig. 1 shows a side view of a plug according to the invention;

fig. 2 is a longitudinal section through the plug according to fig. 1;

fig. 3 shows the plug, seen in the direction of the tip;

fig. 4 is a partial section on a larger scale through

the tip of a plug according to the invention.

The plug shown in fig. 1, and which is made as an injection-molded plastic part in one piece, comprises a plug head 11, in connection with a plug stem 12, and in the tip area a plug foot 13 which follows in connection with the plug stem 12. The plug is inserted into a bore in a wall so that the free end 14 of the plug head 11 extends roughly flush with the wall. The plug's head 11, which takes up about a quarter of the plug's axial length, is not intended for expansion. The expansion which leads to fixation of the plug takes place, so to speak, exclusively in the area of the plug stem 12. Nor does the plug's foot 3, which terminates the plug and is designed as a rotationally symmetrical sleeve, expand when the screw is tightened.

The plug head 11 is provided in its circumference with several radially outwardly projecting ribs 15, which extend in the longitudinal direction. Their radial extent increases continuously from the transition area between the plug head 11 and the plug stem 12 in the direction of the plug head's free end 14. At this free end, their radial extent is greatest. There are a total of six such ribs 15, which are placed at the same distance from each other. There are two types of different ribs 15, which are arranged alternately.

The stem 12 of the plug has a series of sawtooth, ring-shaped ribs 16 which extend along the circumference in a direction transverse to the longitudinal axis of the plug. Their triangular sawtooth cross-section is arranged so that the flat flank facilitates insertion of the plug into the borehole, while the edges on the outside make extraction difficult.

The stem 12 of the plug has three narrow slits 17, which are evenly distributed along the circumference and extend in the longitudinal direction. These slits 17, which extend throughout from the outside of the hollow plug to its inside, divide the stem 12 of the plug into three step-like segments 18. Each segment 18 can thus be deformed independently of the neighboring segments 18.

The slots 17 extend with their ends facing the outside of the wall immediately up to the ribs 15, where a rib 15 is arranged at all times in direct axial extension of each slot 17. On the opposite side facing the borehole, the slots 17 extend not all the way to the end of the plug stem 12. The end of the plug stem 12 is separated from the plug's foot 13 by an annular, groove-like recess 19. This groove-like recess facilitates swinging out of the step-like segments 18, as they slightly weaken the wall thickness.

The base of the plug is slightly conical in the area of its tip to facilitate insertion and centering in a drill hole.

Each step-like segment 18 is approximately in the middle between the neighboring longitudinal slots provided with a narrow fin 20, which extends in the longitudinal direction, see fig. 1. These fins 20 are somewhat shorter than the longitudinal slits 17 which are arranged between them. Upper fin 20 seen in plan view, fig. 1, has the shape of a narrow plate with parallel side walls. In side view, see lower fin 20 in fig. 1, outer contour proceeds slightly curved. The fins 20 gradually expand outwards at the ends facing the plug's foot 13 and they end abruptly in the area of the opposite end, such that this end 23 lies in a plane that is perpendicular to the longitudinal axis of the plug.

Each fin 20 has a notch 23, approximately in the middle of its longitudinal extent, which penetrates from the outside into the fin. The notch extends approximately to half the radial extent of the fin 20, i.e. not to the female of the fin 20 or to the outside of segment 18. The notch has a triangular shape with an approximately right angle.

At the same place in the longitudinal direction of the plug, where the fins 20 have notches 23, the segments 18 have a groove 24 which is continuous, or extends across the longitudinal axis.

Fig. 2 shows a longitudinal section through the plug. In the area of the plug head 11, it has an inner bore 25 with a relatively large diameter, and this inner bore passes via an inclined shoulder 26 into the actual inner plug space 27. In the area of the transition to the plug foot 13, the inner diameter is again reduced over an inclined shoulder 28 and goes into the bore 29 of the plug foot 13. This bore 29 is provided with internal threads 30, which are indicated in the drawing. This internal thread 30 is produced during the production of the plug by plastic injection molding. The size of the thread roughly corresponds to the threads on a screw that must cooperate with the plug. It is possible that the threads 30 are not fully formed, but e.g. only has 80$ of the actual required thread depth.

After manufacture, the plug is provided with a screw which is introduced into its inner space 27 and is screwed into the threads 30. The plug can then be used for through-mounting, i.e. it is together with its screw, whose head protrudes radially from the plug head 11, pushed through a bore in the object to be fixed and into the plug hole. Complete insertion of the plug can be achieved by striking the screw head. The plug is thus pulled into the hole, as the screw attacks in the area of the plug's foot 13. However, since the screw is screwed into the threads 30 in this area and is in contact along a relatively large surface, there is no danger of the plug being damaged or overloaded in this area.

When the plug is introduced or driven into the plug hole, the ribs 15, which have an increasing radial extent and width, will eventually cut into the side wall of the hole, so that the plug in the area of the non-deformable plug head 11 is secured against rotation opposite the hole. In connection, the screw is tightened with a screwdriver. This leads to a displacement of the plug's foot 13 in the direction of the front end, which results in expansion of the segments 18. Depending on the nature of the hole, a corresponding deformation of the segments 18 occurs. If the hole has the same diameter everywhere, which corresponds to the diameter in the front area, a power transfer takes place by the segments 18 being pressed into the wall of the bore. The fins 20 then cut into the wall.

If, on the other hand, the plug is used in a hole chamber stone, tightening the screw will lead to the expansion of the segments 18 outwards. As a result of the recess 19, the groove 24 in the outside of the segments 18 and the notch 23 in the fins 20, the expansion of the segments 18 is facilitated and promoted. The notches 23 will nevertheless not lead to a noticeable weakening of the plug in the longitudinal direction. Together with the ability to drive the plug in with the help of the screw, so that the plug is pulled into the hole, the plug's strength is thus fully maintained, while at the same time it has an improved ability to flex in large holes.

Fig. 3 shows the plug, seen from its tip. It can be seen that the fins 20 are approximately evenly distributed over the circumference. One of the three fins runs exactly radially opposite the longitudinal axis of the plug, while the other two fins 20 run almost tangentially. In fig-3, their transverse directions, i.e. the direction of their projections relative to the circumference, lie in a plane which lies vertically opposite the third plane. This means that one of the fins 20 at all times prevents turning to the right in a favorable way, while the other prevents turning to the left in a favorable way.

In the longitudinal direction immediately behind the fins 20, a rib 15 is arranged at all times, while the other three ribs 15 are approximately centrally offset.

The plug can be provided in the area of its free end 14 with an outward facing flange, if it is not to be used for through-mounting. In this case, however, in some applications the screw had to be unscrewed from the plug again, before the plug can be placed. Equally, the advantage that the plug is delivered with an associated screw is retained and that the plug connection does not become less durable due to the use of a screw that is not intended for it.

Fig. 4 shows a section on a larger scale through the plug's foot 13. It appears that the inner space 27 has a larger diameter than the bore 29 in the front area. The bore 27 passes via the inclined shoulder 28 into the bore 29, where the threads 30 are formed in the wall of the bore, which preferably happens during the manufacture of the screw. The length of the bore 29 is chosen so that it corresponds to three full threads. The screw that is screwed into the threads 30 is thus in a flat arrangement with the base of the plug over three whole threads, so that the load that occurs when the plug is driven in with the help of the screw is distributed over a large surface. Therefore, hitting the screw does not lead to a noticeable load or even deformation of the plug, as can possibly happen when the plug itself is driven in.

Claims (9)

1. Expansion plug made of plastic with a plug head (11), a plug stem (12) connected to the head, where the plug stem is divided into several deformable segments (18) by means of longitudinal slots (17), as well as with a plug foot (13), which is located at the front end of the stem (12) and is designed as a sleeve with a bore (29) for receiving a screw, where the foot of the plug (13) bends the segments (18) outwards as a result of an axial movement when the screw is tightened . ) and the fin (20) in the area of its radial outside (21) and approximately in the center of its longitudinal extent, has an incision or notch (23). 2. Expansion plug as stated in claim 1, characterized in that the segments (18) of the plug's stem (12) have at least one groove (24), a notch or the like on their outside. which extends across the longitudinal axis of the plug. 3. Expansion plug as specified in one of the preceding claims, characterized in that the plug's head (11) has several external ribs (15) which extend in its longitudinal direction and whose cross-section is approximately triangular with an outward-facing tip. 4. Expansion plug as stated in claim 3, characterized in that the ribs (15) have a radial extent that increases in the direction of the outer end (14) of the plug's head (11). 5 . Expansion plug as specified in claim 3 or 4, characterized in that the ribs (15) have a transverse dimension that increases in the direction of the outer end (14) of the plug's head (11). 6. Expansion plug as specified in one of the preceding claims, characterized in that the inner bore in the plug's stem (12) has a larger diameter than the back diameter of the threads (30) in the plug's foot (13). 7. Expansion plug as specified in one of the preceding claims, characterized in that the plug is produced with slightly outwardly bent segments (18). 8. Expansion plug as stated in one of the preceding claims, characterized in that the thread (30) of the thread is not fully designed. 9. Expansion plug as specified in one of the preceding claims, characterized in that the length of the threads (30) in the plug's foot (13) is chosen so that at least two complete turns of thread are arranged in it.