FI57166C - PLASTPROFILLIST - Google Patents

Description

L · .rftl ADVERTISEMENT CHA / Lt ^ (11) UTLÄGGNINGSSKRIFT ^ & 0

JgJS C (45) Patent ny ^ n ^ tty 10 v6 1930 ^ ^ (51) Kv.lk. '/ Tnt.CI. * £ 06 B 7/23 SUOM I —FI N LAN D (21) I4t * n « lh »k« mui —P «t * nt» n * ölii * ln | 762791 (22) HaktmtopiWI — An »öknln |» dif 30.09 * 76 (FI) (23) Alkupaivt — GHtlgh «tadag 30.09 * 76 (41) Interpreters for public— Blhrlt offsntllf 31.03.78

ntmttl. j · r.klrt.rlh «llltu. NlhtMU ^ J. kuLLullutauo pvm.- OA AO ftA

P »t * nt> och r * fl <t« r * tyr «lMn 'AmMon uthcd odi utl-skrlfteo publkerad 29.02.00 (32) (33) (31) Request for Privilege — Begird Priority (71) Schlegel GmbH, Bredowstr . 33, 2000 Hamburg 71 », Federal Republic of Germany-Förbundsrepubliken Tyskland (DE) (72) Frank Eggert, Hamburg, Federal Republic of Germany-Förbundsrepubliken Tyskland (DE) (7 ^) Oy Kolster Ab (5U) Plastic molding - Plastprofillist

The invention relates to a plastic extruded mold strip comprising a fastening part and an active part, such as in a sealing profile, the fastening part having a fastening groove, such as especially in wooden structural parts, by pressing a shank which is relatively hard and has teeth to the side. should pay attention to the groove wall.

Such toothed arms can only compensate for slight width tolerances. They also have the downside that removing them from the mounting groove usually causes damage to the wood.

It is an object of the invention to provide a mold list which is of the type mentioned above and which does not have these disadvantages.

According to the invention, the arm supports on one side, in a stress-free state, an elastic deformable tongue projecting almost perpendicularly from the arm, which is a relatively soft material, and which adheres to the second groove wall to receive the groove width tolerances. 2 57166 with an average thickness in the unstressed condition of at least half its length and in the area close to the shaft at least 90% of the minimum groove width present, reduced by the thickness of the shaft.

In the context of the invention, a relatively hard material is to be understood as one which, when pressed into the fastening groove, does not form at all or forms only to a small extent. A relatively soft material must be understood to mean one which, when installed, allows the tongue to be bent and pressed from the sides. The elasticity must be the same as that of the rubber-elastic material and must ensure the deformation forces which guarantee that it remains in the groove during normal operating times and temperatures.

The moldings according to the invention are preferably used for sealing doors and windows. The mounting groove is then milled into the wood section with a milling machine. In this case, the given width of the groove may be reduced due to wear on the cutter * blade and backfeeding of the wood. These minus tolerances are relatively small, namely regularly well below 10%. In contrast, the plus tolerances, i.e. the increase in the width of the groove, can be greater than a given dimension, namely up to 30%, although such large deviations are rare. It is therefore essential to strive for a secure foundation and a groove width close to the given dimension, in which case, in exceptional cases, with large plus tolerances, it is sufficient to impose considerable resistance against the removal of the mold strip.

When the soft tongue on the other side of the arm part is relatively long and the elastic force is obtained only by bending this tongue, the gripping force obtained is relatively small. Moreover, this force is distributed over a relatively large area where the tongue rests on the corresponding wall of the groove. It has been found that such a large-area combination is disadvantageous in terms of maximum clamping force. If an attempt is made to pull out the arm of a mold strip with such a tongue, then the tongue slides, without changing its relative position relative to the arm part, along the corresponding groove wall.

In principle, the very compact language according to the invention behaves differently. Because it is formed, at least in the area near the shaft, very thick, namely as thick or almost as thick as the available tongue space between the shaft part and the groove wall, normal bending with a certain bending radius is not sufficient to push it inside the groove. It must also be pressed into the pile by pressing from the side near the shaft. In this way, it is made to settle on the corresponding groove wall with high force and hard abrasion of 3 57166. If an attempt is now made to pull the mold strip out of the fastening groove »then the abrasion between the tongue and the groove wall is so great that the tongue adheres to the groove wall so that it is compressed by the relative movement between the shaft and the groove. After reaching a position where the longitudinal direction of the tongue is transverse to the direction of the arm and groove wall and where the transverse force caused by the tongue is maximum, the tongue pops around on the other side (bottom of the groove). The abrasion resistance it then generates is substantially lower than before, but this state is practically not achieved because the tongue resistance with which it resists pulling the mold strip to an intermediate position in which its longitudinal direction is perpendicular to the arm direction is greater than the forces normally encountered in the mounting direction.

This is true, not only in normal cases where the groove dimension is close to or smaller than the given dimension, but in principle also with considerable plus tolerances. Although then the lateral compression of the tongue is not so great in the normal mounting state, the tongue is in a relatively steep position with respect to the groove wall so that despite less compression during the strip strip removal movement it grips the groove wall and resists pulling out with increasing resistance.

It is clear from this functional description that this is crucial for the compact shape of the tongue (large thickness in relation to the mounting groove and small length). The advantages of this condensed shape would not be achieved if “the tongue is provided with cuts to facilitate bending or other changes in cross-section. It thus comes to mind that at least the area close to the tongue arm is dense, i.e. notched. In connection with the sealing feature, the installation situation comes to mind. It does not matter if, in the unstressed state of the tongue, there are any cuts on the compressed side when it is bent, provided that these are continuously closed during bending to such an extent that they do not reduce the resistance of the tongue to lateral compression.

In this context, the region close to the tongue arm is to be understood as the area of the tension-free tongue between the line and the line forming the wall of the opposite groove.

It is preferred that the average thickness of the fastening tongues in the region close to the shaft is approximately equal to the given width of the groove by a measure of the thickness of the shaft. This does not mean that the tongue can be fitted into a groove of a given width without forcing bending, namely bending is known to be bound to suction with a small radius 57166. The shaping of the tongue by bending is thus influenced in the groove, the width of which is close to the given value, in addition to the lateral compression of the tongue.

Suitably, the average thickness of the fastening tongues in the vicinity of the shaft is about two thirds of the length of the tongue.

Because the tongue adheres to the corresponding groove wall, it may be provided with ribs and / or edges in the corresponding area to increase abrasion.

It is further preferred that the fastening tongue is in a stress-free state, inclined at 80-60 °, relative to the direction of the arm part.

In the case of the invention, the parts of the profile serving for fastening in the groove are asymmetrical and the forces acting in the release direction face, depending on the direction, a different release resistance. With an arrangement of the fastening and acting parts in such a way that the release forces occur in the usual way as unilaterally asymmetrical, it is therefore expedient to design the arrangement in such a way that the maximum release resistance is always achieved.

This is especially true when using the moldings according to the invention as a door or window seal. In addition, the fastening part of the mold strip is located on the opposite surface of the outer or inner frame of the window or door, whereby the sealing tongue is fastened to one end of the fastening part. In addition, in a much-used arrangement, the retaining groove is arranged so that it, more precisely, the wall of the groove is in the same transverse line as the abutment surface. For this use case, it is expedient for the fastening tongue of the mold strip according to the invention to be arranged on the side of the arm remote from the abutment surface. This is how an increased resistance to external forces is obtained. The shape strip can also be better scrolled. Furthermore, this results in a better foundation of the retaining portion on the abutment surface, especially when the attachment portion is bent to form a bias on the abutment surface.

In another arrangement, which is also often chosen, the fastening groove is cut perpendicular to the abutment surface. This means that the shank of the mold strip is arranged in an angular cross-section with respect to the fastening part resting on the abutment surface. Since the sealing tongue is attached to the other cross-sectional end of the fastening part in the usual way, it is arranged offset from the arm. If the sealing tongue of the mold strip is affected by a force on the abutment surface, the arm part is also affected by the moment. According to the invention, there is a particularly secure position of the mold strip and a high release force »when the fastening tongue is arranged on the side of the arm to which the active part of the fastening part is fastened.

The invention will now be described in more detail with reference to the drawing, which illustrates preferred embodiments.

In Fig. 1 there is a cross-section of a tension-free hill shank of a mold strip, Figs. 2 and 3 are a corresponding cross-sectional view of a shank in a mounting groove, Fig. * + Is a sealing profile in a built-in state, Fig. 5 is another embodiment of such a sealing profile.

In the drawing, all cross-sectional parts of the mold strip are to be relatively hard material diagonally from top left to bottom right, while relatively soft profile parts are diagonally left to bottom right.

According to Figure 1, the relatively hard material arm 1 has teeth 2 on one side which act on the groove wall 3, while the other side of the arm 1 has a soft material lip H which is permanently welded to the arm 1 by extruding both parts together. In the example shown, the tongue is arranged at the lower end of the arm 1, but it can also be inserted a little higher, when it is desired, so that the forces generated by it are evenly distributed on the teeth 2.

It is noted that the tongue H is placed very tightly, at least in the area between the part 5 of the shaft 1 on the opposite side of the teeth 2 and the line 7 describing the wall 6 of the groove, in the tension-free state of the tongue. The distance between lines 5 and 7 is approximately the same as the thickness of the tongue in this area.

Accordingly, pressing the arm into the groove according to Figure 2 not only results in the bending of the tongue 4, but also in the lateral pressing. This is true at least in the most common tolerance range on both sides of the given width of the groove described by line 7. If now an attempt to pull the stem out of the groove of the arrow 8 (Fig 3) in a direction such agglomerated language '♦ can not follow the relative movement of the arm, so that the addressees of the arm downwardly oriented language deformation gives way, which leads to a further rise but poikittaispuristumiseen language and the way to larger bonding forces.

Figure 4 shows the installation of a window or door seal. In an outer or inner frame, a nail is formed by means of surfaces 9 and 10, where surface 10 forms a abutment surface. This has been continued by forming the mounting groove 11 on the same transverse line as the abutment surface. An arm 1 belonging to the fastening part 12 of the sealing strip is placed in the fastening groove. This fastening part is a flat flange which is pressed evenly on the abutment surface 10. it, as shown by the broken line 14, in the unstressed state is slightly curved so that, when installed under prestressing, it presses against the abutment surface 10. This prestressing causes a moment which the wooden structure receives in the direction of arrows 15 and 16. Torque increases as the direction of the arrow 17, a force, which may arise eg. The bonding of the sealing tongue 13 on the counter sealing surface. By said arrangement of the soft tongue 4 above the arm 1, the torque forces are transmitted to the wooden structure exclusively through the relatively hard profile parts, the tongue H being loaded by the torque forces.

A further advantage of this arrangement is that the arm 1 is substantially in line with the rest of the fastening part 12, so that the profile can be rolled lightly and without oblique bending. Finally, it is an advantage of this arrangement in that the compression of the profile of the groove 11 influence the direction of arrow 18 direction of the mounting forces in a straight line through the rod attachment part 1, without the fear of unwanted side forces due to the bending and flexing of orientation.

In the installation example of Fig. 5, the groove 19 is cut in the transverse direction with respect to the abutment surface 10. If this affects the release profile of the force, due to, for example, 13 responses to the surface of the glued tongue, in the direction of the arrow 20 and this results in one area of the arm-bending moment, which must receive the tree structure in the direction of the arrows 21 and 22. At the tongue 4, the pressure against the corresponding groove wall is thus strengthened. In this way the tongue is pressed into close contact with this wall and the frictional force increases.

As in the case of Fig. 4, the fastening part 12 can be pressed against the abutment surface 10 by prestressing.

In order to increase the frictional force of the tongue 4 relative to the corresponding groove wall, sharp ribs or edges (23) projecting according to Fig. 1 are provided, which also include a point of tongue flap from the side surface to the end surface. The average deflection of the tongue towards arm 1 is indicated by a dotted line 24.

Claims (8)

1. Extruded profile of plastic and consisting of a fastening part and effective part, for example a sealing profile, the fastening part having one in a fastening groove (11,19), especially in a wooden part, by means of compression fastening shaft (1) this material, which on one side is toothed for co-operation with a flank of the groove, characterized in that the shaft (1) on the other side (5) carries a substantially elastic shape fastening lip (4) transverse in the transverse state. ) of relatively soft material for cooperation with the second groove flange (6) and for accommodating width tolerances in the fastening groove (11,19), the fastening lip being formed by a compactly extending continuous profile portion, whose average thickness in the relaxed state At least half is as large as its length and in the shaft-close area, at least 90% of the smallest occur, with the shaft thickness reducing the not-b rescue. 2. Profile strip according to claim 1, characterized in that the average thickness of the fastening lip (4) in the shank-near region (5-7) is about as large as the reduced width of the groove with the shaft thickness. 3. Profiling list according to claim 1 or 2, characterized in that the average thickness of the fastening lip (4) in the shaft-close region (5-7) is about 2/3 of the lip length. Profile strip according to any of claims 1-3, characterized in that the surface of the fastening lip (4) intended to contact the groove (6) contains friction-increasing strips and / or edges (23). Profile strip according to any of claims 1-4, characterized in that the average slope (24) of the fastening lip (4) in the relative direction of the shaft direction is between 80 ° and 60 ° in the relaxed state. Profile strip according to any of claims 1-5, to be used as a door or window seal and an abutment portion (12) lying against the abutment surface (10), the abutment surface (10) lying in the tab with one of the flanks in the abutment groove (11). , characterized in that the fastening lip (4) is arranged on the side of the shaft (1) which is opposite to this edge. 7. Profile strip according to claim 6, characterized in that the fastening part (12) is bent (14) to produce a bias directed towards the abutment surface (10).