EP0510501A1 - Fastening anchor - Google Patents

Abstract

The fastening anchor has a plate section (1) and a pin section (2) protruding from it. These two sections are designed as a one-piece plastic moulding. A disc-shaped sheet part (4) is tightly welded to the plate section (1). A threaded rod (6) is screwed into the blind hole (3) of the pin section (2). The disc-shaped sheet part (4) is made of a plastic which can be connected in a sealing manner to a respective sealing layer (5). The fastening anchor is inserted with its pin section (2) into predrilled holes of a respective substrate and is, for example, adhesively bonded therein. The object to be anchored is to be connected to the threaded rod (6). There is thus a sealing layer surrounding the threaded rod (6), which sealing layer consists of the sheet part (4), the plate section (1) welded to it, and the pin section (2). This results in an impermeable anchor-fastening construction for surface seals, since the disc-shaped sheet part (4) is likewise connected in a sealing manner to the respective sealing layer of large area. The fastening anchor can be used for surface seals in the building and construction industry. <IMAGE>

Description

The present invention relates to a fastening anchor for tightly anchoring an object in a stone substrate, a continuous sealing layer being arranged between the object to be anchored and the stone substrate. It also relates to a lining of ceilings and walls of buildings, which lining has a continuous sealing layer acting as a surface seal, on which a layer of concrete is arranged and with a plurality of fastening anchors designed according to the invention for the layer of concrete. It further relates to a lining of ceilings and walls made of rock in underground construction, which lining has a first layer of concrete applied to the rock, which is separated from a second layer of concrete by a continuous sealing layer acting as a surface seal, and with a multiplicity of those designed according to the invention Fixing anchors for the second layer of concrete.

When lining ceilings and walls of buildings, e.g. made of concrete, the basic material of the building applied a sealing layer, which e.g. is applied in a flowable state and then hardens or has the form of plastic sheets. A layer of reinforced concrete is applied to this sealing layer. This layer of concrete must obviously be anchored and for this purpose fastening anchors are used, which are anchored in the basic material of the building. It is now evident that these fastening anchors penetrate the sealing layer, which means that the sealing is interrupted.

Furthermore, the lining of tunnels, tunnels, caverns and shafts, etc. in underground construction is like follows created. A layer of concrete is first applied to the surface of the excavated rock, ie after the reinforcing bars have been attached, shotcrete is sprayed on. On top of this layer of concrete comes a sealing layer in the form mentioned above, followed by another layer of reinforced concrete. This second layer of concrete must obviously be anchored and for this purpose fastening anchors are used, which are anchored at least in the first layer of concrete and possibly also in the rock. It is now evident that these fastening anchors penetrate the sealing layer, which means that the sealing is interrupted.

In both cases there is therefore a fundamentally leaky point which must be sealed further. Many suggestions have already been made and implemented, e.g. arranging clamping flanges with putty. However, these known designs are either very labor intensive or did not lead to the desired permanent absolute seal. The known designs also have the disadvantage that the anchor rods have to be made of a rustproof or corrosion-resistant material, because they are not protected against corrosion in the transition area of the base material or rock / shotcrete to the sealing layer.

The invention seeks to remedy this. The invention, as characterized in the claims, achieves the object of providing a fastening anchor for the tight connection of an object in a stone substrate, in which a plate section is integrally connected to a pin section to be inserted into the stone substrate, in which pin section a blind hole extending from the plate section is formed, which plate section is connected on its side facing away from the pin section with a disk-shaped film part, the diameter of which is larger than the diameter of the plate section and is connected with a continuous sealing layer can be welded integrally, a threaded rod intended for connection to the object to be carried being screwed into the blind hole.

The advantages achieved by the invention are essentially to be seen in the fact that a continuous sealing layer is made possible, which extends around a fastening anchor and thus there are no leaks. The result is a penetration-free anchor fastening construction for surface seals, since the disk-shaped film part, which is advantageously made of plastic, can be sealingly connected to a respective large-area sealing layer made of plastic by welding.

The lining of ceilings and walls of buildings equipped with such fastening anchors, which lining has a continuous sealing layer acting as a surface seal, on which a layer of concrete is arranged, the fastening anchors projecting into the basic material of the building is characterized in that the peg section of the respective beams runs through the sealing layer and is inserted in a hole in the base material of the building and is locked therein by means of a connecting material, preferably adhesive mortar, the plate section resting on a side region of the sealing layer facing away from the base material and being tightly connected to it, and that section of the threaded rod protruding from the blind hole is embedded in the layer of concrete and carries at least two nuts, which are used, for example, to support a reinforcement plate, such that a penetration-free anchor fastening Arrangement for the surface seal is present, in which the threaded rod corrosion-encasing pin portion as a seal and at the same time as a force-transmitting body between the Basic material of the building and the threaded rod bearing the layer of concrete acts.

The lining of ceilings and walls made of rock in underground construction equipped with such fastening anchors, which lining has a first layer of concrete applied to the rock, which is separated from a second layer of concrete by a continuous sealing layer acting as a surface seal, the fastening anchors being in the second layer Protruding concrete is characterized in that the peg section of the respective carrier runs through the sealing layer and is inserted in a hole penetrating at least the first layer and possibly continuing into the rock and is locked in the same by means of a connecting material, preferably adhesive mortar, the plate section bears on a side region of the sealing layer facing the space broken out in the rock, and the disk-shaped film part in its outer section e projecting in a radial manner over the plate section in the radial direction if necessary, it bears against a side region of the sealing layer facing the space broken out in the rock and is tightly connected to it, and that the section of the threaded rod protruding from the blind hole is embedded in the second layer of concrete and carries at least two nuts, e.g. serve to support a reinforcement plate in such a way that there is a penetration-free anchor fastening arrangement for the surface seal, in which the pin section enveloping the threaded rod in a corrosion-protecting manner serves as a seal and at the same time as a force-transmitting body between the rock and / or the first layer of concrete and the threaded rod carrying the second layer of concrete works.

The continuous sealing layer usually consists of a flowable plastic or of sheets of soft PVC or another plastic. Accordingly, that from the pin section and plate section existing carrier advantageously consist of hard PVC or another plastic and the disc-shaped film part made of soft PVC or another plastic. The plate section of the carrier can thus be connected to the disk-shaped film part by hot air welding or a connecting material, which disk-shaped film part in turn can be welded absolutely tightly by hot air welding or with a connecting material to the continuous sealing sheet or layer.

The subject matter of the invention is explained in more detail below with reference to the drawings, for example.

• Figur 1 einen Befestigungsanker,
• Figur 2 einen Schnitt durch eine Auskleidung mit einem Befestigungsanker nach Figur 1, bei einem Bauwerk, und
• Figur 3 einen Schnitt entsprechend der Figur 2 einer Ausführung im Untertagebau.

It shows:

• 1 shows a fastening anchor,
• Figure 2 shows a section through a lining with a fastening anchor according to Figure 1, in a building, and
• Figure 3 shows a section corresponding to Figure 2 of an execution in underground construction.

According to FIG. 1, the fastening anchor has a one-piece carrier made of plastic, preferably hard PVC in this exemplary embodiment, which is formed from a plate section 1 and a pin section 2 protruding therefrom. Alternatively, the spigot section can be made of hard PVC and the plate section thus formed in one piece from soft PVC. It can be seen that the outer wall 10 of the pin section 2 is structured in the form of a coarse thread. This results in extremely high pull-out forces of the pin section 2 inserted in a bore. This structuring of the outer wall 10 of the pin section 2 could, for example, take the form of a coarse screw thread. In the pin section 2, a blind hole 3 is formed, which is equipped with an internal thread. A threaded rod 6 with a screw thread 7 is screwed into this blind hole 2.

The carrier is tightly connected to a plate-shaped film part 4 in the plate section 1. This disk-shaped film part 4 consists of soft PVC, which material is here the same as that of the sealing layer or sealing membrane, with which, as will be shown below, the fastening anchor has a sealing effect. The plate section 1 of the carrier is welded to the disk-shaped film part 4 by means of hot air welding, so that there is no space at any point between the plate section 1 and this film part 4. This means that the entire surface area, see FIG. 1, over which the plate section 1 rests on the film part 4 is welded, so that there is absolute tightness, since the plate section 1 and the disk-shaped film part 4 are in one piece at this point. Instead of hot air welding, a suitable connecting material can be used to connect the plate section 1 to the film part 4.

A nut 8 is further screwed onto the threaded rod 6, which is made of a suitable metal or steel. This nut 8 serves as a locking nut for a reinforcement to be described. A washer 16 is also shown purely for example. There is also a lock nut 9 with its washer 21. Obviously, other structural arrangements made of metal and / or plastic can be used instead of the locking nuts 8 and 9.

The embodiment shown in FIG. 2 relates to the use of the fastening anchor in a building, for example in a building construction, in which, for example, a suspended ceiling (reference number 13 in FIG. 2) and a sealing layer 5 in the form of plastic sheets between the suspended ceiling 13 and the Base material 18, here concrete, with the reinforcement not shown, is present.

Another variant for a building sees the fastening anchors for anchoring, for example, masts on e.g. Buildings. To consider such a variant, the drawing sheet of FIG. 2 must be turned upside down, in which case the peg section 2 penetrates into the ceiling (base material 18), the plastic sheet or sealing layer 5 is sealingly applied to the ceiling and e.g. Mast feet are screwed with the thread shown in the figure.

Returning to the embodiment according to FIG. 2, the example of a suspended ceiling will now be described further.

After the concrete (the base material 18) has set sufficiently, a hole 14 is formed in the concrete 18 wherever a fastening anchor is to be used. Afterwards (according to another possibility in advance) e.g. the sealing membrane 5 from e.g. Soft PVC applied to the first layer of 12 concrete. Such waterproofing membranes are generally known and are generally used as surface seals and therefore do not have to be described in more detail. The sealing membrane 5 is cut through in each bore 14, e.g. two cuts are made in the shape of a cross. If the bore 14 is only made after the sealing membrane 5 has been applied, there is already a penetration of the sealing membrane 5 here. A hardening connecting means is now introduced into the bore 14 produced, e.g. Epoxy resin mortar. The pin section 2 can then be inserted into the bore 14, the depth of penetration of the pin section 2 into the bore 14 being determined by the abutment of the plate section 1 on the sealing film 5. The epoxy resin mortar results in a firm connection between the peg section 2 and the wall of the bore 14.

Thereafter, the disk-shaped film part 4 is welded to the underside of the sealing membrane 5 at its peripheral area outside the plate section 1.

The disk-shaped film part 4 consists of the same plastic from which the sealing sheet 5 is made. This welding can e.g. be a hot air welding. This welding creates a cohesive connection between the film part 4 and the sealing membrane 5 between the location of the circumference of the plate section 1 and the location of the circumference of the disk-shaped film part 4, which also creates an absolutely tight connection here.

As the next step, the threaded rod 6 can now be screwed into the blind hole 3 of the pin section 2.

At the lower end of the threaded rod 9, as shown for example, a reinforcement plate 15 can now be arranged, which is locked to the threaded rod 6 by the nuts 8 and 9 in the same way. Here too, in practice, other connecting parts made of metal and / or plastic, e.g. Spacers 22 may be arranged in a generally known manner. The reinforcement is then attached, for example a reinforcement network 17 here.

Finally, the second layer 13 of concrete is arranged, for example shotcrete again, in order to complete the suspended ceiling.

Particularly in the case of ceilings in building construction, a sealing, curable plastic can be applied in the flowable state instead of the sealing membrane 5.

Furthermore, the nut 19 shown in FIG. 1 with the washer 20 is not present. This means that in the embodiment according to FIG. 2 the plate section 1 is connected to the sealing membrane 4 by means of a connecting material or is welded by a heat seal.

Because of the fastening anchor or anchors, there is now a penetration-free anchor fastening arrangement for surface seals. That is, in contrast to In all known constructions, the sealing layer is not broken through at any point by a part of the fastening anchor and thus there is absolute tightness. Furthermore, the threaded rod 6 in the concrete 18 is completely protected against corrosion. For this purpose, reference is also made to FIG. 1. The sealing layer, for example the continuous sealing sheet 5 is formed, continues through the integral welding in the disk-shaped film part 4. This film part 4 is in turn integrally welded to the plate section 1, so that a continuous horizontal sealing layer is present up to the pin section 2. This sealing layer now continues in the form of the wall of the peg section 2 (the peg section 2 is formed in one piece with the plate section 1), that is to say rises vertically in FIG. 1 and bypasses the end of the threaded rod 3 at the uppermost end in order to be on the opposite end Page come down again and continue over the plate section 1, the disc-shaped film part 4 in the sealing film 5.

Consequently, there is no penetration through a sealing layer at any point, and furthermore it is not necessary through additional measures, e.g. Putty to seal leakage caused by penetrations or to seal at such places.

FIG. 3 shows an embodiment in which the lining in underground construction is shown with the aid of the fastening anchor described. The following description is based on that of FIG. 2, and accordingly only the differences from the embodiment according to FIG. 2 are dealt with.

The reference number 11 designates the rock, the rock which is pierced to build a tunnel, for example. A first layer of concrete is applied to this rock 12, for example shotcrete in a known manner. Because of The rebars obviously present here are again not clearly drawn.

After the concrete has hardened sufficiently, the holes 14 are formed through this first layer of concrete 12. The respective bore 14 can now extend into the concrete layer or even completely through it up to the rock 11. Then (according to another possibility, in advance) the sealing layer 5, e.g. flowable plastic or a sealing membrane made of e.g. Soft PVC is applied to the side of the first layer 12 of concrete facing the excavated space. The insertion of the anchoring, the sealing connection between the plate section 1 and the exemplary sealing membrane 5 and finally the arrangement of the second layer 13 of concrete here takes place according to the embodiment according to FIG. 2.

Claims (10)

Fastening anchor for tightly anchoring an object (13) in a stone substrate (11), a continuous sealing layer (5) being arranged between the object (13) to be anchored and the stone substrate, characterized by a carrier which has a plate section ( 1) and a pin section (2) protruding therefrom, in which a blind hole (3) extending from the plate section (1) is formed, the plate section (1) and the pin section (2) being formed in one piece and the plate section (1) at its side facing away from the pin section (2) is tightly connected to a disk-shaped film part (4), the diameter of which is larger than the diameter of the plate section (1) and consists of a material which is integrally and tightly sealed with the continuous sealing layer (5) can be connected, and by means of a threaded rod (6) screwed into the blind hole (3), which is used to connect to the counterpart to be anchored tand serves. Fastening anchor according to claim 1, characterized in that the carrier consisting of a plate section (1) and pin section (2) consists of a material which allows a frictional connection, and that the disc-shaped film part (4) and the continuous sealing layer (5) consist of the same material. Fastening anchor according to one of the preceding claims, characterized in that the plate section (1) of the carrier is welded to the disk-shaped film part (4) and the disk-shaped film part (4) can be welded to the material of the sealing layer (5). Fastening anchor according to one of the preceding claims, wherein the sealing layer (5) a Sealing membrane is characterized in that the disc-shaped film part (4) and the sealing membrane consist of the same material and can be welded together. Fastening anchor according to one of the preceding claims, characterized in that the carrier (1; 2) consists of hard PVC and the disk-shaped film part (4) consists of soft PVC, and that the threaded rod (6) consists of metal and a screw thread (7 ) for receiving nuts (8; 9). Fastening anchor according to one of the preceding claims, characterized in that the outer wall (10) of the pin section (2) is structured in the blind hole (3) to increase its adhesive strength. Fastening anchor according to one of the preceding claims, characterized in that the outer wall (10) of the pin section (2) is structured in a thread-like manner to increase its adhesive strength in the blind hole (3). Fastening anchor according to one of the preceding claims, characterized in that the pin section (2) consists of hard PVC and its outer wall has the structure of a coarse thread. Lining of ceilings and walls of buildings, which lining has a continuous sealing layer (5) acting as a surface seal, on which a layer (13) of concrete is arranged, and with a plurality of fastening anchors according to one of Claims 1-9 for anchoring the layer ( 13) Concrete in the base material (18) of the building, characterized in that the peg section (2) of the respective carrier runs through the sealing layer (5) and is inserted in a hole (14) in the base material (18) of the building and therein by means of a Connection material is locked, the plate section (1) resting on a side region of the sealing layer (5) facing away from the base material (18) and with the same is tightly bonded, and that the section of the threaded rod (6) protruding from the blind hole (3) is embedded in the layer (13) of concrete and carries at least two nuts (8, 9) which serve to support a reinforcement plate (15), in such a way that there is a penetration-free anchor fastening arrangement for the surface seal, in which the pin section (2) enveloping the threaded rod (6) in a corrosion-protecting manner as a seal and at the same time as a force-transmitting body between the base material (18) of the structure and the threaded rod carrying the layer (13) of concrete (6) works. Lining of ceilings and walls made of rock (11) in underground construction, which lining has a first layer (12) of concrete applied to the rock (11), which is separated from a second layer (13) by a continuous sealing layer (5) acting as a surface layer. Concrete is separated, and with a plurality of fastening anchors according to one of claims 1-9 for the second layer (13) of concrete, characterized in that the peg section (2) of the respective carrier runs through the sealing layer (5) and in at least one the hole (14) penetrating the first layer (12) and possibly continuing into the rock (11) and is locked in it by means of a connecting material, the plate section (1) on a side region of the space broken out in the rock (11) Sealing layer (5) bears against the same and the disk-shaped film part (4) in its ring shape over the plate section (1) in the radial direction protruding outer section also bears against a side region of the sealing layer (5) facing the space broken out in the rock (11) and is tightly connected to it, and that the section of the threaded rod (6) protruding from the blind hole (3) in the second layer (13 ) Concrete is embedded and carries at least two nuts (8,9), which serve to support a reinforcement plate (15), such that a non-penetration Anchor fastening arrangement for the surface seal is present, in which the pin section (2), which protects the threaded rod (6) in a corrosion-protecting manner, acts as a seal and at the same time as a force-transmitting body k between the rock (11) and / or the first layer (12) of concrete and the second layer ( 13) Concrete threaded rod (6) acts.

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