SK280282B6 - Isolating plate, process and apparatus for its manufacture - Google Patents

Abstract

In order to make it easier to drive in an insulating panel (1) for 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 (4). A process can be characterised in that the region (2) of the front edge (3) of the insulating panel (1) is formed into a wedge-like shape. An apparatus for manufacturing said insulating panel (1) contains a forming device (10) which forms the region (2) of the front edge (3) into a wedge-like shape, which device (10) is movable in relation to its front edge (3).

Description

Field of the invention

The invention relates to an insulating board adapted to be driven into a masonry as well as to a method and apparatus for producing such an insulating board.

BACKGROUND OF THE INVENTION

When drying wet masonry, it is still an unresolved problem to find a suitable insulating material that perfectly ensures the impermeability of the entire masonry profile. The methods used for the subsequent formation of insulating screens can be divided into three groups: the first group can include chemical processes which incorporate liquid insulating substances into the wet masonry, which bind in the masonry and prevent further rising of moisture. The second group consists of electrical treatments based on the use of electro-osmotic ejection of moisture from masonry, and the third group may include mechanical processes which incorporate insulating strips and screens of corrosion-resistant material into the masonry to interrupt the wicking path of moisture to higher parts of masonry.

While the first two groups of post-insulating treatments have not found greater application in practical applications for reasons that need not be discussed in detail here, the post-treatment of the third group is almost 100% successful for most masonry types because mechanical interruption or capillary closure in the masonry forming the paths for the transport of moisture to the higher parts of the masonry means a perfect closure of the possibility of moisture transport. Rather, this method encounters other problems and imposed constraints on some types of masonry due to their unfavorable internal construction, where the insertion of insulation boards is difficult or even impossible in some cases.

Especially with the insulation boards according to AT-PS 335 689, the abovementioned problems can occur when the sand in the mortar forming the filler in the masonry into which the insulation board is to be inserted is too fine, so that when the insulation board is driven in pushing the individual grains of sand in the mortar on top of each other to great resistance to the board penetration. Thus, a further resistance to the front edge of the insulation board is given considerable resistance, since the individual grains of sand can only be pushed back or pushed to the sides in the region of the front edge of the insulation board. Similar problems also arise in poppy joints in which the mortar is very hard and very dense due to the high binder content, especially cement, so that it has a higher density than when the individual grains are placed close together on the mortar.

Further problems may arise when driving the insulation boards, for example, in those cases where the ratio of mortar thickness of the mortar to the thickness of the insulated insulation board is too small, since then the compaction ratio for the mortar is too great.

All these problems, in addition to the increased thickness of the masonry, are further increased by friction on the surfaces of the impacted insulation boards, which in some unfavorable cases may even lead to a complete stopping of the impacting process, since it is not possible to exert any great force on it or by large impacts of the hammer or other tool, as this would deform and bulge the insulation board.

SUMMARY OF THE INVENTION

SUMMARY OF THE INVENTION It is therefore an object of the present invention to provide an insulating board of this kind in which the disadvantages mentioned do not occur and which, even under unfavorable conditions, can be successfully incorporated into masonry or mortar joints in order to achieve perfect masonry insulation. It is also an object of the invention to provide a simple and inexpensive manufacturing process for the production of such an insulating board, as well as an improved apparatus for carrying out this method.

This object is achieved by the insulating board according to the invention, which is characterized in that the insulating board is wedge-shaped in its front region at its leading edge facing the masonry. In this way, by pushing the insulating board into the masonry, a significantly more favorable pushing or pushing of the masonry material at the front edge of the insulating board is achieved and also a more favorable pushing of the sand grains and other filler filler particles when the insulating board is inserted into the mortar joint. boards, which need less force, which must be applied to the insulation board. Since less force is sufficient to drive the insulation board, its thickness can be reduced without the risk of its bulging during the drive. By reducing the thickness of the insulating board, the front edge area and the subsequent part of the insulating board are thus considerably thinner, so that masonry, which has not previously been treated by introducing additionally installed insulating elements, can be treated according to the invention.

According to a preferred embodiment of the invention, the wedge profile of the leading edge region is substantially symmetrical with respect to the intended central axis of the cross-section, guided perpendicularly to the surface of the insulating board in the driving direction. This ensures that the penetration of the insulation board or the compression of the mortar in the masonry filling range or part of the masonry when the insulation board is pressed in is symmetrically distributed on both sides of the insulation board, so that the reaction forces of mortar or masonry material act symmetrically on the insulation board. otherwise deform mainly in the area of its leading edge.

In a further preferred embodiment of the invention it is proposed that the wedge-shaped cutting edge is broken off, in other words, formed by a chamfered or rounded edge, which in some cases has the advantage that small hard stones in mortar or masonry material cannot cause undesirable, unsymmetrical and uncontrollable deformation of the leading edge of the insulating board, which could lead to a break in the connection of the insulating layer.

According to another preferred embodiment of the invention, it is proposed that the wedge profile of the insulating board be wider than the thickness of the other parts of the insulating board in its rear region facing away from the front. This greatly reduces the amount of friction between the surface of the insulating board connected to the leading edge and the surrounding mortar or masonry, since the stopper gap is formed by this rear part of the wedge profile at a thickness greater than the thickness of the insulating board.

Accordingly, a further preferred embodiment of the insulating board according to the invention is very advantageous, according to which a transition step is provided in the rear region of the wedge profile of the insulating board. This step also helps to reduce the amount of friction between the insulation board and the masonry.

This wedge-shaped profile can, in a further preferred embodiment of the invention, have a triangular shape, which is particularly adapted to the manufacturing process, and at the same time this shape facilitates evenly compacting and compacting the mortar or masonry material in the region of the leading edge of the driven insulation board.

According to another preferred embodiment of the invention, the wedge profile on the front side of the insulating board may be provided with concave or convex surfaces, the use of one of these two types of curved surfaces depending on the particular application, mortar composition and the like to achieve optimal adaptation to conditions for driving the object into the masonry.

In a further preferred embodiment of the invention, the wedge-shaped area of the insulating board behind the front edge, like the entire insulating board, is profiled perpendicular to the driving direction, for example corrugated, which substantially increases the shape stability of the front edge area.

The essence of the process for the production of the insulating board according to the invention is that the region of the front edge of the insulating board, which faces the masonry when driven in, forms a wedge-shaped shape so that a similar advantageous effect has been obtained. by explaining the nature and advantages of the insulating board, possibly in connection with pushing the masonry material into the insulating board, driven by the leading edge and the area around it.

For the production of an insulating board of metal materials, in particular of stainless steel, it is proposed in a further preferred embodiment of the invention that the front area of the insulating board be shaped by grinding, forging or rolling. By grinding, it is possible to achieve easy production of substantially any profd of the wedge region, in addition to forging or rolling, improved properties of the metal material can be achieved, in particular by cold forming it is possible to achieve resistance to deformation of the leading edge region.

When shaping the wedge profile of the front with insulating plates, the back of the wedge part facing away from the masonry may be shaped to a thickness greater than the thickness of the other parts of the insulating board to achieve a dartboard shape of the wedge part. opposing surfaces of the insulating board, so that it is possible to achieve a friction reduction in the area of the insulating board beyond the rear edge of the wedge portion.

Particularly preferably, the direction of rotation of the grinding wheels is selected such that the resulting burr extends towards the rear region of the wedge profile to a greater width than the cross-sectional thickness of the adjacent region of the insulating plate.

According to a further particularly preferred embodiment of the method according to the invention, the insulating board can be profiled in a direction perpendicular to the driving direction, in particular undulating, after the wedge has been shaped. By crimping the insulating board after the front stop has been formed, it is ensured that the wedge profile in the front edge region always remains symmetrical with respect to the central axis of the cross-section through the insulating board perpendicular to its surfaces.

The apparatus for producing an insulating board according to the invention intended for driving into masonry comprises, according to the invention, a shaping device movable with respect to the front edge of the insulating board, for wedge-forming the region of the insulating board beyond its front edge. With this device, it is possible to obtain a front region of the insulation board which is fast and suitable for mass production of boards.

According to a preferred embodiment of the invention, the shaping device may comprise two grinding wheels, disposed on both opposite sides of the insulating plate and positioned obliquely and symmetrically to the leading edge of the insulating plate. In this solution, an arrow wedge profile is formed on the front edge of the insulating board in one continuous operation.

The device may also include a forging mechanism with a profiling tool for shaping the desired wedge profile. Thereafter, it is irrelevant whether the forging creates both inclined sides of the wedge profile at the same time or whether the wedge profile is made in one or more working operations using different working tools, with different working tools acting on each side of the wedge part.

Advantageously, it may comprise at least one profiling roll for forming the wedge part, and in this case too, it is not critical to determine the scope of the invention in how many operations the final shape of the area of the insulating board beyond its leading edge is formed.

According to a further preferred embodiment of the invention, support rollers can be provided on both sides of the insulation board in the areas of operation of the respective forming tools, to support the insulation board, which prevent undesirable deformation of the insulation board when processing its area beyond the front edge.

In a particularly preferred embodiment of the device according to the invention, a profiling mechanism, in particular a waveform shaping mechanism of the insulating board, is provided downstream of the insulating panel leading edge region of the insulating board, forming the desired board profile in a direction perpendicular to the driving direction. With this arrangement of working mechanisms and tools, it is possible to provide a successive sequence of manufacturing operations that is suitable for mass production. By working and shaping the front of the insulating board in the region of its leading edge prior to profiling, especially before corrugating the entire insulating board, the symmetrical alignment of the wedge profile at the leading edge of the final product is maintained, which brings the advantages already explained in the previous section.

BRIEF DESCRIPTION OF THE DRAWINGS

BRIEF DESCRIPTION OF THE DRAWINGS The invention will be explained in more detail with reference to the drawings, in which: FIG. 1 to 5 are cross-sectional views of the insulating panels according to the invention in the region of the leading edge of the panel, which is designed as a stop edge and faces the masonry in the working position; FIG. 6 is a perspective view of a detail of an insulation board manufacturing device, for example according to FIG. 4 or 5, FIG. 7 is an axonometric view of a detail of another forming apparatus for producing, for example, the insulating board of FIG. 5, FIG. 8 is a side view of the forming apparatus of FIG. 7 taken in a direction perpendicular to the surface of the insulating board to be treated, FIG. 9 is a front view of the forming apparatus of FIG. 7 and 8 taken in the direction of arrow IX of FIG. 8, FIG. 10 is a side view corresponding to FIG. 8, for a further exemplary embodiment of a forming apparatus according to the invention for producing the insulating board of FIG. 1 to 5 and FIG. 11 is a front view of a second exemplary embodiment of the forming apparatus taken in the direction of the arrow XI of FIG. 10th

DETAILED DESCRIPTION OF THE INVENTION

The insulating boards 1 shown in FIG. 1 to 5 and also in FIG. 6 to 11, with a slightly exaggerated thickness 8, serve to drive and insert into the dried masonry or the like, the introduction of these insulating boards 1 into the masonry in order to interrupt the capillaries which raise the moisture from the soil into the upper masonry layers. Usually, the thicknesses 8 of the insulating boards 1 in their practical use are between 1.0 and 1.5 mm, and currently the most preferred material for these insulating boards 1 is stainless steel or the like. In order to facilitate their penetration into the masonry material (not shown) in the region 2 adjoining the leading edge 3 of the insulating boards 1, the front region 2 of the insulating boards 1 is shaped in all embodiments to a wedge shape, this wedge profile 4 always being substantially symmetrical to the The axis 5 shown in FIG. 5, a cross-section taken in the insertion direction perpendicular to the surface of the insulation board 1.

The wedge profile 4 according to the example of FIG. 1 has a substantially triangular shape which, on the one hand, is very easy to manufacture and which, when pressed into the masonry, ensures a uniform distribution of the forces acting on the insulation board 1 and the mortar or masonry material around the pressed edge of the insulation board 1 4th

According to FIG. 2, the triangular wedge-shaped profile 4 is again broken off at the tip, and the thus formed chamfer 6 prevents undesired and uncontrolled deformations of the sharp front edge 3, which could occur mainly when larger and harder filler particles are present in the mortar or masonry in the area .

In the example of FIG. 3, the wedge profile 4 has substantially concave side surfaces 7, the edge of the wedge profile 4 being rounded at the front edge 3 in addition.

The wedge profile 4 according to the example of FIG. 4 is provided with substantially convex side faces 7 ' and is formed at a greater width than the thickness 8 of the remainder of the insulating plate 1 at its rear rear region facing away from the leading edge 3. By this arrow-shaped wedge profile 4, the insertion groove or insertion the channel in the masonry or masonry mortar joint forms a front region 2 following the front edge 3 with a width greater than the thickness 8 of the next insulation board 1, resulting in a reduction in the pressing friction on the surface of the insulation board 1.

In the wedge profile 4 according to the exemplary embodiment of FIG. 5, there is provided on each side one transition stage 9, which has a similar effect to reduce the amount of friction between the insulation board 1 and the various types of masonry or mortar joints in the masonry as the wedge profile 4 according to the example of FIG. 4th

The shown shapes of the wedge profiles 4 are only given as exemplary shapes, and in all cases and especially in the examples according to FIG. 4 and 5 are shown in exaggerated thickness for the sake of clarity and simplification of the display form. In addition to these exemplary shapes, it is possible to use other forms and shapes of these parts in addition to the shown wedge molds as long as the penetration of the insulating board 1 in the region of its leading edge 3 into the masonry material is achieved with advantageous compaction of the masonry material on both sides of the insulating board 1. The wedge-shaped front region 2 behind the front edge 3 of the insulating board 1 can, in addition to the entire insulating board 1, be profiled in the direction of the wheels in the pushing direction, which is not shown in the embodiments. For example, these parts may be corrugated so as to increase the transverse stiffness of the insulating board 1 as a whole and in particular its front region 2 beyond the front edge 3.

The device shown in FIG. 6 shows a shaping device 10 for forming a wedge-shaped front region 2 behind the leading edge 3 of the insulating plate 1, which is movable with respect to the leading edge 3 of the insulating plate 1, the shaping device 10 consisting in two exemplary embodiments of two grinding wheels 11 opposite each other; arranged obliquely against the machined front edge

The grinding wheels 11 are connected to respective drive mechanisms 12 and not shown holding and guiding mechanisms, the direction of rotation 13 of which is indicated by arrows, such that the sharpening 14 resulting from grinding widens towards the rear region of the wedge profile 4 away from the front edge 3 and towards the cross-section of the non-deformed insulating board 1. During such grinding, a wedge profile 4, as shown in FIG. 4 or 5.

In FIG. 6 also does not show the holding and feeding mechanisms for guiding and holding the insulating board 1, or corrugated work tools, for subsequently forming a transverse corrugated or otherwise profiled shape of the insulating board 1.

In addition to the illustrated grinding mechanism with two grinding wheels 11, other sets of grinding tools can be used to form the wedge profile 4 in the region beyond the leading edge 3 of the insulating plate 1.

According to the examples of FIG. 7 to 9, the shaping device 10 for forming the wedge front region 2 beyond the leading edge 3 of the insulating plate 1 may be provided with at least one forging mechanism 15 with a profiling tool 16 for shaping the wedge profile 4. The support rollers 17 are supported on both sides of the insulating plate 1 to support the insulating plate 1 on both sides to prevent deformation during shaping, the supporting rolls 17 being supported in bearings 18 and, if necessary, driven by means not shown. Especially from FIG. 9, it can then be seen that with larger diameters of the support rollers 17, these support rollers 17 can reach just below the lower edge of the profiling tool 16, so that even in this region, which is critical in shaping the insulation board 1, sufficient support of the insulation board 1 is ensured. from both sides. FIG. 9 it is also evident that on its underside, the insulating plate 1 is guided in a rail guide 19 which supports the insulating plate 1 against the action of the forging mechanism 15 from below and prevents deformation of the adjacent edge of the insulating plate 1.

Of course, in addition to forming the wedge shape shown by a single profiling tool 16 that generates the entire desired shape at once, it would, of course, be possible to perform this shaping by a series of successive shaping operations using several profiled profiling tools 16. It is equally irrelevant whether The mechanism 15 with the profiling tool 16 moves together with the support rollers 17 relative to the fixed insulating board 1 and whether the insulating board 1 to be processed also moves in this shaping.

It is advantageous in this shaping according to the example of FIG. 7 to 9, in which the final shape of the front region 2 beyond the leading edge 3 of the insulating board 1 is formed, to provide the reinforcement of the insulating board 1 material in these regions by cold forming which achieves more favorable properties for using the insulating board 1 for masonry or the like material or building structure.

According to the examples of FIG. 10 and 11, the forming apparatus 10 comprises two driven profiling rollers 20, 21 for forming a wedge-shaped profile 4, which, as shown in dotted line 22 in FIG. 10, carry out gradual shaping up to the final wedge profile 4, while the insulating plate 1 moves in the direction of the arrow 23. Also in this case a pair of support rollers 17 are provided which are located on both sides of the insulating plate 1 and prevent the insulation plate from bulging. 1 to the hips.

Between the first profiling roller 20 and the second profiling roller 21, in the example of FIG. 10, a transport roller 24 is provided, which, like the lower support rollers 25, serves to support and support the insulation board

The lower support rollers 25 are in each case located at points directly opposite the driven profiling rollers 20, 21 and have a relatively larger diameter to ensure that the deformation of the insulating plate 1 caused by the rolling forces of the profiling rollers 20, 21 is Of course, instead of the individual rollers 24, 25, it is of course also possible to use, for example, conveyor chains or similar conveying mechanisms which have a similar effect and which also help to prevent unwanted deformations of the insulating board 1.

PATENT CLAIMS

Claims (21)

Insulation board for masonry driving, characterized in that the region (2) of its leading edge (3) facing the masonry during driving has a wedge profile (4). Insulating board according to claim 1, characterized in that the wedge profile (4) is symmetrical with respect to the central axis (5) of the cross-section, guided perpendicularly to its surface in the stop direction. Insulating board according to claim 1 or 2, characterized in that the edge of the wedge-shaped profile (4) is formed by a chamfered edge (6) whose width is less than the thickness (8) of the region adjoining the region of the leading edge (3). Insulating board according to claim 1 or 2, characterized in that the edge of the wedge-shaped profile (4) is formed by a curvature whose radius is less than half the thickness (8) of the region adjoining the front edge region (3). Insulating board according to one of Claims 1 to 4, characterized in that the wedge profile (4) is wider than the thickness (8) of the adjoining region in the rear region remote from the cutting edge. Insulating board according to claim 5, characterized in that the transition from the wedge profile (4) to the adjacent area is formed by a step (9). Insulating board according to one of Claims 1 to 6, characterized in that the wedge profile (4) is triangular in shape. Insulating board according to one of Claims 1 to 6, characterized in that the wedge profile (4) of the side surface (7) is convex. Insulating board according to one of Claims 1 to 6, characterized in that the wedge profile (4) of the side surface (7) is concave. Insulating board according to one of Claims 1 to 9, characterized in that the wedge-shaped region (2) is the same as the remainder of its profile, preferably corrugated, in a direction perpendicular to the driving direction. Method for producing an insulating board according to one of Claims 1 to 10, characterized in that the region (2) of the leading edge (3) of the insulating board (1), which is turned towards the masonry during driving, is shaped into a wedge shape. Method for producing an insulating board according to claim 11, wherein the insulating board is made of a metal material, in particular of stainless steel, characterized in that the area (2) behind the leading edge (3) is shaped into a wedge profile (4). grinding, forging or rolling. Method according to claim 12, characterized in that at the same time, when shaping the wedge profile (4), its rear region facing away from the blade is wider than the thickness (8) of the adjacent region of the insulating plate (1). Method according to claim 13, characterized in that the direction of rotation (13) of the grinding wheels (11) is selected such that the resulting burr (14) extends towards the rear region of the wedge profile (4) to a greater width than the cross-sectional thickness (8) of the adjacent area of the insulation board (1). Method according to one of claims 11 to 14, characterized in that the insulating plate (1) is shaped, preferably waved, perpendicular to the driving direction after the wedge-shaped front edge (3) has been formed. Apparatus for carrying out the method according to any one of claims 11 to 15, characterized in that it comprises a shaping device (10) for wedge-forming a region (2) of the leading edge (3) movable relative to the leading edge (3). insulation board (1). Apparatus according to claim 16, characterized in that the shaping device (10) is provided with at least two grinding wheels (11) which are arranged obliquely on the front edge (3) to be processed, opposing each other and symmetrically on both sides of the insulating plate. (1). The device according to claim 16, characterized in that the forming device (10) comprises at least one forging mechanism (15) provided with a profiling tool (16) for forming a wedge profile (4). Apparatus according to claim 16, characterized in that the forming device (10) comprises at least one profiling roller (20, 21) for forming a wedge profile (4) whose axis lies perpendicularly to the leading edge (3) of the insulating plate (10). 1). Device according to one of Claims 16 to 19, characterized in that support rollers (17) are arranged on both sides of the insulating plate (1) for supporting each side of the insulating plate (1) in the area of operation of each working tool of the respective forming device (10). ) against buckling. Device according to one of Claims 16 to 20, characterized in that a profiling mechanism, in particular a crimping mechanism, is arranged downstream of the shaping device (10) in order to form the transverse shaping of the entire insulating plate (1).