EP0544639A1 - Isolating plate to be driven into masonry walls and process and apparatus for its manufacture - Google Patents

Abstract

In order to make it easier to drive in an insulating panel (1) for waterproofing masonry structures, that region (2) of the front edge (3) of the insulating panel (1) which is directed towards the masonry structure during driving-in is designed in a wedge shape, this preferably being achieved by grinding, forging or rolling. <IMAGE>

Description

The invention relates to an insulating plate for driving into masonry and to a method and a device for producing such an insulating plate.

The draining of damp walls is a long-standing problem which, despite numerous and sometimes very different approaches, has not really been solved satisfactorily. The methods currently used in this context can essentially be divided into three groups: firstly, the chemical methods, in which liquid insulating materials are pressed into the masonry, which bind there and thus prevent the rise of liquid; secondly, the electrical processes, in which damp masonry is usually to be drained by means of electro-osmosis; and thirdly, the mechanical processes in which corrosion-resistant insulating sheets are used to interrupt the transport of moisture into higher regions of the masonry.

While the two first-mentioned groups do not show satisfactory dehumidification results for a variety of reasons, which are not of interest here, the last-mentioned group has one hundred percent success with the majority of average masonry, since the mechanical interruption or shut-off of the moisture in higher Regions of the masonry transporting capillaries acts absolutely and reliably, but on the other hand it still has to fight with certain problems and the associated restrictions in various special masonry designs, which complicate or hinder the introduction of the insulating plates into the masonry.

Especially with the above-mentioned, for example from AT-PS 335.689, insulating plates for driving into masonry, problems of the last type mentioned can occur if, for example, the mortar sand in the joint into which the insulating plate is to be driven is too fine and Penetration of the insulating plate opposes great resistance to an even closer contact between the individual grains of sand. Another advance the front edge of the insulating plate facing the masonry during driving is severely hampered, since the individual grains of sand in the area of this front edge can only be pushed further and subsequently displaced or distributed laterally. Similar problems also occur with mortar joints, in which the addition of binders (such as cement) makes the mortar too hard and too dense for the grains of sand in the mortar to become even closer together.

Problems of the type mentioned can furthermore occur when driving in such insulating plates e.g. also occur if the ratio of the thickness of the mortar joint to the thickness of the insulating plate to be driven in becomes too small, since then the compression ratio for the joint mortar becomes too large.

With all the difficulties mentioned, in particular with larger wall thicknesses, there is still increased friction on the surfaces of the insulating plate which have already been driven in, which in the worst case can lead to the drive being stopped because, due to the limited thickness of the insulating plate, the impact force of a hammer or the like acting on the insulating plate is not can be enlarged as required without causing the insulating plate to bulge.

The object of the present invention is to improve an insulating plate of the type mentioned in such a way that the disadvantages of the known insulating plates do not occur and that, particularly in the case of the unfavorable masonry or joint designs mentioned, isolation of the in a simple manner using the proven mechanical methods mentioned Masonry becomes possible. Furthermore, a simple and inexpensive method for producing such an improved insulating plate and a device for this production are also to be specified.

In the case of an insulating plate for driving into masonry, the stated object is achieved according to the invention in that the region of the front edge of the insulating plate facing the masonry during driving is wedge-shaped. This makes the distribution or displacement of the masonry components at precisely this front edge, which is essentially responsible for the further advancement of the area of the front edge of the insulating plate when it is driven into the masonry - in particular the distribution of the mortar sand grains or other mortar parts consisting of solid particles in the case of driving in the insulating plate in a mortar joint of the masonry - significantly improved or facilitated, so that the driving in can be carried out with much less force on the insulating plate. Since less force has to be used to drive in, the thickness of the Insulating plate are reduced without fear of bulging the same when driving. With the reduced thickness of the insulating plate, its leading edge and thus the area of the material to be displaced or compressed on it becomes narrower, so that overall, masonry which cannot be renovated with such insulating plates to be driven in can be treated with this effective method.

According to a particularly preferred embodiment of the invention, it is provided that the wedge profile of the region of the front edge is essentially symmetrical with respect to an imaginary center line of a cut made perpendicular to the surface of the insulating plate in the driving-in direction. This ensures that the displacement or compaction which is exerted from the area of the front edge of the insulating plate onto the joint mortar or the surrounding masonry components when driving in the insulating plate takes place symmetrically to both sides of the insulating plate, which on the other hand also means that the reaction forces of the mortar or Masonry work symmetrically on the insulating plate or its front edge and do not deflect or deform it.

In a further embodiment of the invention it is provided that the tip of the wedge profile is broken or rounded, which offers the particular advantage over an at least largely unbroken tip, which can also be advantageous for different applications, that small stones or the like do not have any uncontrolled, can cause asymmetrical deformations of the leading edge with the associated disadvantages.

According to a particularly preferred further embodiment of the invention, it is provided that the wedge profile in the rear region facing away from the tip is wider than the thickness of the remaining insulating plate. This significantly reduces the friction between the insulating plate surface following the front edge and the surrounding compacted mortar or masonry, since the driving-in channel is widened in relation to the insulating plate thickness by the arrowhead-like wedge profile.

In the latter context, a further embodiment of the invention is particularly advantageous, according to which a step to the adjacent area of the insulating plate is provided in the rear area of the spline. This level improves the friction reduction effect discussed above.

In a further embodiment of the invention, the wedge profile itself can be essentially triangular, which is particularly advantageous for the production and a constant displacement or compacting of the mortar or Masonry ensures in the area of the front edge of the insulating plate to be driven.

According to other developments of the invention, the wedge profile can, however, also have essentially convex or concave side edges, which, depending on the application or consistency of the mortar joint, etc., enables adjustment for optimum driving-in properties.

According to a particularly preferred further embodiment of the invention, the wedge-shaped area on the front edge of the insulating plate, like the entire plate, can be profiled, preferably corrugated, transversely to the driving direction, which advantageously increases the transverse stability of the area of the front edge and the entire plate. The corrugated design of an insulating plate itself is also known per se from the aforementioned AT-PS 335.689.

In the method according to the invention for producing an insulating plate for driving into masonry, it is provided that the area of the front edge of the insulating plate facing the masonry during driving is formed in a wedge shape, which increases the advantages already described above in connection with the insulating plate itself with regard to driving in the plate or with regard to the displacement and compression of the material to be moved at the front edge when driving in the plate.

In order to produce an insulating plate made of metallic material, in particular stainless steel, it is provided in a further development of the invention that the area of the front edge is deformed into a spline profile by grinding, hammering or rolling. The first-mentioned grinding enables simple manufacture of largely any flank shape of the wedge profile. When hammering or rolling, an improvement in the standing properties of the leading edge to be driven in can be achieved by the cold deformation that occurs.

In the shaping of the wedge profile, this can be made wider in a further embodiment of the invention in the rear area facing away from the tip than the cross section of the undeformed insulating plate, which results in an arrowhead-like design of the wedge profile in the connection area of the other insulating plate, which has the advantages already described above with regard to Reduces the friction when driving in the insulating plate.

According to a particularly preferred further embodiment of the method according to the invention, after the wedge-shaped design of the front edge, the insulating plate can be profiled, preferably corrugated, transversely to the driving direction. will. Carrying out the corrugation after the wedge-shaped formation of the front edge ensures that the wedge profile of the region of the front edge remains essentially symmetrical with respect to an imaginary center line of a cut made perpendicular to the surface of the insulating plate in the driving-in direction - the advantages achieved thereby have already been set out above.

The device according to the invention for producing an insulating plate for driving into masonry is characterized by a shaping arrangement which can be moved relative to the front edge of the insulating plate facing the masonry for wedge-shaped formation of the region of this leading edge, which means that the region of the leading edge in is rapidly shaped for mass production the way described is possible.

According to a preferred embodiment of the invention, the shaping arrangement can have at least two grinding wheels arranged opposite one another with respect to the insulating plate and symmetrically interleaved on the front edge to be machined, the direction of rotation of which is selected such that the resulting grinding burr in the rear area facing away from the tip of the ground wedge profile faces these widened the cross section of the undeformed insulating plate. This means that an arrow-shaped wedge profile can be produced on the front edge of the insulating plate in one continuous operation.

In another embodiment of the invention, however, the forming arrangement can also have at least one hammer mechanism with a profile tool for the wedge profile to be produced. It is irrelevant whether this profile tool forms both flanks of the wedge profile in one work step, or whether the wedge profile is machined separately on both flank sides in one or more work steps by different tools.

In a further embodiment of the invention, the shaping arrangement can also have at least one profile roller for the wedge profile to be produced, and here again it applies that it is irrelevant within the scope of the invention in how many individual steps the final profiling of the area of the front edge of the insulating plate takes place.

According to a particularly preferred embodiment of the invention, support rollers can be provided on both sides in the area of the action of the respective tool of the shaping arrangement for lateral support of the insulating plate, which precludes inadmissible deformations of the entire insulating plate when machining the area of the front edge.

In a particularly preferred further embodiment of the device according to the invention, in the machining direction after the forming arrangement for the In the region of the front edge of the insulating plate, a profiling device, preferably a corrugated arrangement, is arranged for transverse profiling of the entire insulating plate. This means that the insulating plate can also be mass-produced in successive operations. By processing the area of the leading edge before the corrugation or profiling of the entire insulating plate, the symmetrical configuration of the spline on the leading edge on the end product remains - with regard to the corresponding advantages, reference is made to the relevant information above.

The invention is explained in more detail below with reference to the exemplary embodiments shown schematically in the drawing. 1 to 5 show partial cross sections through insulating plates designed according to the invention in the region of the front edge facing the masonry during driving in different embodiments, FIG. 6 shows a detail from a device according to the invention for producing insulating plates, for example according to FIGS. 4 or 5, 7 shows a detail from another device according to the invention for producing, for example, an insulating plate according to FIG. 5 in a schematic oblique view, FIG. 8 shows the device according to FIG. 7 in a view perpendicular to the surface of the processed insulating plate, FIG. 9 shows the device 7 and 8 in a view along arrow IX in FIG. 8, FIG. 10 shows a view corresponding to FIG. 8 of a further device according to the invention for producing an insulating plate according to FIGS. 1 to 5 and FIG. 11 again a view along arrow XI in FIG. 10.

The insulation plates 1 shown exaggeratedly thick in FIGS. 1 to 5 and also in the further FIGS. 6 to 11 serve to drive them into masonry to be drained or the like, the capillaries in the masonry transporting the soil moisture into higher wall regions being interrupted by the insulation plate 1 and thus the moisture transport is prevented. In practice, the thicknesses of the insulating plates are usually in the range from approximately 1.0 to 1.5 mm, with materials such as stainless steel or the like preferably being used today. In order to improve or simplify the displacement or compression of the material to be removed from the driving slot when driving in the insulating plate 1 in the area 2 of the front edge 3 facing the masonry (not shown here), the area 2 in all the illustrated embodiments is wedge-shaped, wherein the wedge profile 4 in each case with respect to an imaginary center line 5 (see FIG. 5) of a perpendicular to the surface of the insulating plate 1 in the driving direction Cut is essentially symmetrical.

The wedge profile 4 according to FIG. 1 is essentially triangular, which on the one hand is easy to manufacture and on the other hand, when driving in, gives uniform force relationships with regard to the displacement or compaction of the surrounding mortar or masonry over the entire length of the wedge profile 4.

According to FIG. 2, again a triangular wedge profile is broken at the tip - the resulting bevel 6 prevents an otherwise uncontrollable deformation of a pointed front edge, which is to be feared under certain circumstances, which offers advantages particularly in the presence of larger and harder components of mortar or masonry in the driving slot.

According to FIG. 3, the wedge profile 4 has essentially concave side edges 7, the tip of the wedge profile 4 being additionally rounded at the front edge 3.

The wedge profile 4 according to FIG. 4 has essentially convex side edges 7, and is wider in the rear area facing away from the tip or front edge 3 than the thickness 8 of the remaining insulating plate 1. This arrow-shaped design makes the driving slot or channel in the masonry or expanded in the mortar joint by the protruding area 2 of the front edge more than would be required for the subsequent thickness 8 of the insulating plate 1, which leads to a reduction in the insertion friction on the subsequent plate surfaces.

In the wedge profile 4 according to FIG. 5, a step 9 is provided in the rear area of the same for the adjoining area of the insulating plate 1, which further improves the effect of reducing friction for various masonry or joint materials discussed above for the embodiment according to FIG. 4.

The cross-sectional shapes shown are only to be regarded as examples, in particular the arrow-shaped design of the wedge profiles 4 in FIGS. 4 and 5 is greatly exaggerated to simplify the illustration or for better visibility. Furthermore, apart from the wedge profile shapes shown, other such shapes are also conceivable, provided that only the mentioned effect of improving the material displacement or compression in the area of the driven-in front edge 3 is ensured. The wedge-shaped area 2 of the front edge 3 of the insulating plate 1 can furthermore - as is not shown here - be profiled, for example corrugated, transversely to the driving direction, as a result of which the transverse rigidity of the insulating plate 1 as a whole, and also the area 2 of the leading edge 3 specifically increases.

In the device shown in FIG. 6, a shaping arrangement 10, which is movable relative to the front edge 3 of the insulating plate 1, is provided for wedge-shaped formation of the area 2 on this front edge 3, the shaping arrangement 10 here lying opposite one another with respect to the insulating plate 1 on the front edge to be processed 3 entangled grinding wheels 11 with associated drive devices 12 and not shown holding and guide arrangements, the direction of rotation (symbolized by the arrows 13) is selected so that the resulting grinding burr in the tip of the ground spline 4 facing rear area this compared to the cross section the undeformed insulating plate 1 widened. In this way, an arrow shape of the wedge profile 4, as shown for example in FIGS. 4 or 5, automatically arises during grinding.

Also not shown in FIG. 6 are holding and feeding arrangements for the insulating plate 1 or, under certain circumstances, provided corrugating arrangements for a subsequent corrugation of the insulating plate 1 in the transverse direction.

Apart from the two interlocking grinding wheels 11, a corresponding wedge profile configuration on the front edge 3 of the insulating plate 1 could of course also be achieved with only one or with a plurality of appropriately arranged grinding wheels.

7 to 9, a forming arrangement 10 for the wedge-shaped formation of the area 2 of the front edge 3 of an insulating plate 1 has at least one hammer mechanism 15, with a profile tool 16 for the wedge profile 4 to be produced. In the area of action of the profile tool 16, the forming arrangement 10 against bulging of the plate 1, support rollers 17 are provided on both sides for lateral support of the insulating plate 1, which are held in bearings 18 and, if necessary, can also be driven in a manner not shown here. In particular, from FIG. 9 it can be seen that with a larger diameter of the support rollers 17, these could also be pulled up directly below the lower edge of the profile tool 16 in order to enable reliable lateral support in this area, which is critical when processing the insulating plate 1. Also on FIG. 9, a rail-like guideway 19 for the lower edge of the insulating plate 1 to be machined can be seen on the underside, which supports it downwards against the action of the hammer mechanism 15 and reliably prevents deformations on the associated edge.

Apart from the version shown with a single profile tool 16, the final shaping of the area 2 of the front edge 3 of the insulating plate 1 to the wedge profile 4 could, of course, also take place in several successive work steps with differently designed profile tools. It is also irrelevant whether the hammer mechanism 15 with the profile tool 16 together with the support rollers 17 moves relative to a fixed insulating plate 1 during the continuous machining, or whether the insulating plate 1 is moved in a manner not shown here.

An advantage of this type of shaping of the area 2 of the leading edge 3 into the wedge profile 4, as shown in FIGS. 7 to 9, is in any case the material hardening occurring in this area due to the cold shaping, the favorable properties for the use of the insulating plate for driving in masonry or the like results.

10 and 11, the forming arrangement 10 has two driven profile rollers 20, 21 for the wedge profile 4 to be produced, which - as indicated by the broken line 22 in FIG. 10 above - carry out a gradual deformation to the final wedge profile 4, while the Insulating plate 1 is moved past in the direction of arrow 23. Here, too, support rollers 17 are provided on both sides of the insulating plate 1, which prevent lateral bulges.

A conveyor roller 24 is also indicated in FIG. 10 between the two profile rollers 20, 21 and, like the lower conveyor rollers 25, serves to transport and support the insulating plate 1. The lower conveyor rollers 25 are to be carried out in all cases at the outer positions opposite the profile rollers 21, 22 with a relatively large diameter in order to ensure that the deformation caused by the rolling force occurs only in the region of the front edge 3 of the insulating plate 1 to be formed. Apart from the individual conveyor rollers 24, 25, a conveyor chain or the like could of course also be provided for the same purpose, which also helps to prevent undesired deformations of the insulating plate 1.

Claims (19)

Insulating plate for driving into masonry, characterized in that the area (2) of the front edge (3) of the insulating plate (1) facing the masonry during driving is wedge-shaped. Insulating plate according to claim 1, characterized in that the wedge profile (4) of the area (2) of the front edge (3) is essentially symmetrical with respect to an imaginary center line (5) of a cut made perpendicular to the surface of the insulating plate (1) in the driving direction. Insulating plate according to claim 1 or 2, characterized in that the tip of the wedge profile (4) is broken or rounded. Insulating plate according to one of claims 1 to 3, characterized in that the wedge profile (4) is wider in the rear region facing away from the tip than the thickness (8) of the remaining insulating plate (1). Insulating plate according to claim 4, characterized in that a step (9) to the adjoining region of the insulating plate (1) is provided in the rear region of the spline (4). Insulating plate according to one of claims 1 to 5, characterized in that the wedge profile (4) is essentially triangular. Insulating plate according to one of claims 1 to 5, characterized in that the wedge profile (4) has essentially convex side edges (7). Insulating plate according to one of claims 1 to 5, characterized in that the wedge profile (4) has essentially concave side edges (7). Insulating plate according to one of claims 1 to 8, characterized in that the wedge-shaped area (2) on the front edge (3) of the insulating plate (1) as well as the entire plate (1) is profiled, preferably corrugated, transversely to the driving direction. Method for producing an insulating plate for driving into masonry, characterized in that the area (2) of the front edge (3) of the insulating plate (1) facing the masonry during driving is wedge-shaped. A method according to claim 10 for producing an insulating plate made of metallic material, in particular stainless steel, characterized in that the area (2) of the front edge (3) is deformed into a wedge profile (4) by grinding, hammering or rolling. A method according to claim 11, characterized in that when the wedge profile (4) is formed, it is located in the rear region facing away from the tip is made wider than the cross section of the undeformed insulating plate (1). Method according to one of claims 10 to 12, characterized in that the insulating plate (1) is profiled, preferably corrugated, transversely to the driving-in direction after the wedge-shaped design of the front edge (3). Device for producing an insulating plate for driving into masonry, characterized by a shaping arrangement (10) movable relative to the front edge (3) of the insulating plate (1) facing the masonry for the wedge-shaped formation of the area (2) of this front edge (3). Apparatus according to claim 14, characterized in that the shaping arrangement (10) has at least two grinding wheels (11) which are arranged opposite one another with respect to the insulating plate (1) and are symmetrically interleaved on the front edge (3) to be machined, the direction of rotation (13) of which is selected is that the grinding burr (14) which arises in the rear region facing away from the tip of the ground wedge profile (4) widens it compared to the cross section of the undeformed insulating plate (1). Device according to claim 14, characterized in that the shaping arrangement (10) has at least one hammer mechanism (15) with a profile tool (16) for the wedge profile (4) to be produced. Device according to claim 14, characterized in that the shaping arrangement (10) has at least one profile roller (20, 21) for the wedge profile (4) to be produced. Device according to one of claims 14 to 17, characterized in that in the region of the action of the respective tool of the forming arrangement (10), support rollers (17) are provided on both sides for lateral support of the insulating plate (1). Device according to one of claims 14 to 18, characterized in that in the machining direction after the forming arrangement (10) for the area (2) of the front edge (3) of the insulating plate (1) a profiling device, preferably a corrugated arrangement, for cross-profiling the entire insulating plate ( 1) is arranged.

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