EP0804661A1

EP0804661A1 - Process and device for lining a static support with plastic boards

Info

Publication number: EP0804661A1
Application number: EP95908246A
Authority: EP
Inventors: Ernst Rohringer
Original assignee: Steuler Industriewerke GmbH
Current assignee: Steuler Industriewerke GmbH
Priority date: 1994-02-01
Filing date: 1995-02-01
Publication date: 1997-11-05
Anticipated expiration: 2015-02-01
Also published as: WO1995021305A1; DE4403014A1; AU1663895A; ATE188004T1; DE59507496D1; ES2139884T3; EP0804661B1

Abstract

A process and device are disclosed for lining a static support (1) with plastic boards (2). The plastic boards (2) are linked to the static support (1) by a plurality of anchors (3) with a mounting technique that compensates during mounting for thermal expansion differences that cause the displacement of the positions of the board holes and anchors (3). In spite of the plurality of anchoring points, a uniform flank contact between the board (2) and the anchor (3) is ensured at all fastening points. Static calculations concerning the fastening points may thus be performed. Special measures are proposed in order to reduce the forced material stresses in the plastic boards (2) due to differential expansion.

Description

Device and method for lining a static support with plastic plates

The invention relates to a device and a method for covering e.g. Apparatus or structures from e.g. Sheet steel or concrete as a static support by means of large plastic plates. The plastic plates are fastened to the substrate by means of metal anchors or dowels, which are pre-assembled in a fixed division on the substrate or placed during plate installation. The plastic plates are connected to the subsurface in a material-appropriate manner using these anchors or dowels.

Plastic sheets, in particular made of polyolefins such as polyethylene (PE) or polypropylene (PP), are suitable due to their special material properties, such as chemical resistance, abrasion resistance, anti-adhesive surface, weldability etc., for linings to protect the static carrier in particularly, but with the restriction that the very high thermal expansion is difficult to control. Pre-screwed linings made of plastic sheets, in particular of thermoplastics, have in the past regularly failed when they were exposed to larger and / or regular temperature fluctuations. Welding or gluing of the plates to one another exacerbates the frequency of damage. As a result, thermal expansion of the material which is otherwise possible at least at the plate edges in the event of temperature changes is prevented. Prevented thermal expansions, that is to say forced stresses in the plastic plates, led to high mechanical loads in the anchoring points, usually screw fastenings. Precise pre-drilling of anchor holes in the plastic plates, a prerequisite for an even load distribution on all anchors, is xis not possible. Even small temperature fluctuations during assembly cause dimensional changes in the hole pitch in relation to the anchor pitch due to the high material expansion. In order to be able to push the plates over the anchors, the holes have to be drilled larger than the diameter of the anchors. This creates an annular gap between the anchor and the plate bore. In the event of a plate expansion during assembly, this causes the bores to be shifted to the center point in relation to the anchors. This leads to an eccentricity of the annular gap. Since the thermal expansion of the plastic plates in front is up to 15 times the static support and thus the anchor pitch, considerable tolerance supplements and thus annular gap widths must be provided. This prevents the anchors from fitting into the bores with a non-positive fit joint between the anchor and the reveal. However, this frictional connection is a prerequisite for an even load distribution of the stresses occurring in the plates and acting on the large number of anchors. The force transmission due to static friction in the screw connection acting on other materials, such as steel, is not possible in the case of plastic sheets, in particular made of polyolefins, due to the special material properties, so the plastic sheets can continue to move within the tolerance specified by the annular gap. This results in uneven perforation pressures, which in the worst case lead to material failure, to tears in the holes. The failure of individual fastening points leads to an additional load on other points, which in turn are now overloaded. This dynamic damage leads to a quick and irreparable failure of the entire lining.

Lining techniques with plastic plates have been developed which avoid the disadvantages described. For this purpose, the panels are provided with a large number of plastic anchors distributed on the back of the panels and poured into concrete or mortar as lost formwork. By the Pouring the anchors into concrete or mortar will completely embed them. All anchors therefore bear in equal parts. Linings produced in this way, which are described in EP-A-0 059929, are able to withstand considerable, unevenly distributed and rugged temperature changes as permanent stress. The disadvantage is the fact that a solid mortar or concrete support layer must always be used to fasten the panels, which places economic and technical limits on assembly technology. This is particularly the case with the lining of sheet steel apparatus.

In contrast, the object of the invention is to provide a device and a method for lining a static carrier with plastic plates on a static carrier, in which a mortar or concrete carrier layer for the lining can be dispensed with and instead Known, inexpensive and simple techniques of fastening by means of preassembled anchors or dowels can be applied without the disadvantages associated therewith being to be feared.

This object is achieved with the features of the claims.

In the solution, the invention is based on the following basic ideas:

A corresponding number of anchors are placed on the surfaces of a static support to be provided with a lining (plastic plates). As a rule, dowels for concrete structures and welding studs for steel structures. The plastic plates provided for the lining are provided with a perforation corresponding in number and division to the set anchors. But it is also possible to provide the plastic plates with anchors and the static support with a corresponding perforation. Here the The diameter of the perforation is kept so large that the plates or the support can still be pushed over or onto the preassembled anchor despite the possible temperature fluctuations during assembly and the associated change in the hole pitch dimensions. An annular gap remains between the anchor and the hole reveal (inner hole wall) of the hole, the shape of which depends on the plate expansion and which is eccentric to the anchors. In order to fix the plate position and to ensure a uniform load absorption by the large number of anchors, it is necessary to secure a non-positive connection between the perforations on the one hand and the anchors on the other hand, across the variable annular gaps. According to the idea of the invention, the problem is solved in that between all anchors and perforations, across the annular gap, a load-bearing material bridge is installed so precisely at the moment of assembly that the forces are uniform over the entire surface of the armature and the perforation Surface pressure can be derived. As a result, the surface pressures occurring can be calculated and can be limited in advance by constructive measures, for example by increasing the hole reveal, in the permissible height. Static verification of the anchor construction with special consideration of the material-specific properties of plastics is possible. In addition, special measures can be used in the plates to reduce the forced stresses resulting from suppressed thermal expansion. For assembly-technical reasons, a large number of anchors are generally preassembled on the static support, whereupon the predrilled lining plates are pushed over the anchors for fastening and fastened using the techniques according to the invention. However, the same fastening techniques can also be used when drilling the lining plate and concrete as a static beam.

A particular advantage of the device according to the invention lies in its easy disassembly and thus repairability. The invention is particularly suitable for the liquid-tight lining of containers or channels.

The invention is explained in more detail below with reference to the drawings.

Show it:

1 to 6 different embodiments according to the invention,

7 and 8 process steps for producing a further embodiment according to the invention, and

9 and 10 further embodiments according to the invention.

Common to all the representations is the basic idea of the invention, according to which an annular gap of different shape between the lining plate or carrier and anchor must be bridged at the fastening points by a material bridge seated on a fitting joint.

According to FIG. 1, a lining plate 2 facing the stress side, which is provided with a multiplicity of bores 28, is screwed onto the carrier 1 to be clad with screw connections consisting of anchors 3, nuts 13 and clamping disks 4. In the case of sheet steel as a static support 1, the anchors 3 are usually welding bolts, in the case of concrete they are dowels, both of which are made using known technology. The lining plate 2 made of plastic cannot simply be fixed to the support 1 by unscrewing it, since the special properties of plastics, in particular the thermoplastics mainly used, namely low surface strength and partially waxy surface, do not enable sufficient static friction to suppress thermal expansion. This is an essential difference to steel parts. If the screw connection is correct, the forces must be transferred there by static friction. A power transmission by means of flank contact, special measures are also required for steel connections, such as the previously usual riveting method, in which the full-surface flank contact was achieved by "riveting", that is to say that the anchor emerges in the perforated area. The removal of the constraining stresses that occur must therefore take place via a load-bearing, form-fitting connection between the plastic plate 2 and the armature 3. For this purpose, the annular space 9 present between the anchor 3 and the reveal 8 is filled with a material 5 which adapts to the shape of the annular space. By rapid solidification of the material 5, this acts as a material bridge between the hole reveal 8 and anchor 3, so that a force-transmitting positive connection is produced. A plastically processable putty or flowable injection mortar can be used as material 5, which is injected through an opening 23 present in the clamping disc 4. The annular space can also be filled by puttying a putty 5 before the screw connection, the putty hardens so quickly that changes in the ambient temperature cannot have an effect on the positional change in the annular gap due to expansion. In many cases, the perforation reveal pressure to be expected from the expansions in the lining plate will exceed the permissible material values. The lining plate 2 then has to be reinforced in the area of the perforation 8 by welding or gluing of reinforcing rings 7 in the factory, or the plates are provided with reinforcing rosettes in one production step. The required number of anchors can be minimized by correctly designing the anchor and hole reveal dimensions. The joint seam 12, with which the reinforcement ring 7 is applied to the lining plate 2, should be produced over the entire surface by heating element or rotary or friction welding or by full-surface gluing. A further possibility of the required positive connection between the plastic plate 2 and the armature 3 is that the clamping disc 4 is equipped with a deep profile 14, which is caused by the contact pressure of the nut 13 or by special Measures such as heat, ultrasound or milling are sunk into the surface of the lining plate 2 at the time of mounting each individual anchor. Due to the material contact between the armature 3 in connection with the clamping disc 4 on the one hand and the plate 2 on the other hand, a force-fitting transfer of force from the plate 2 to the armature 3 is achieved. Depending on the level of the surface pressures occurring in the depressions 14, the force transmission by the depression can be used alone or as an alternative support for the other techniques described. As a result of this mechanical clawing, the removal of forced stresses is achieved directly between the lining plate 2 and the armature 3 via the clamping disk 4. In order to allow the air to escape from the annular space during the filling of the putty 5, 7 ventilation grooves 17 are arranged on the underside of the reinforcing ring. To cover the screw nut 13 in a sealed manner, a cover cap 15 is placed on the lining plate 2 via a weld seam or adhesive seam 16 or by means of a seal. The static support 1 can be protected against possible atmospheric moisture by a paint 19. Due to the reinforcement ring 7 or a spacer ring placed for this purpose, a gap 18 is created between the static support 1 and the lining plate 2, which serves as thermal insulation or as a monitoring space and the position of which can be stabilized by spacers 20. As a measure to reduce the stresses caused by suppressed thermal expansion and thus the forces occurring in the fastening points, particularly when using thick plastic plates and the high temperature expansions to be expected, the lining plate 2 can be preformed between the anchors 3 with slightly bowl-shaped depressions 29 . Subsequent temperature expansions of the lining plate 2 then act in a further and reversible manner or flattening of the bowl shape in accordance with the material. As an alternative to the embodiment shown, the reinforcement rings 7 can also be on the other side of the lining arrange the plate, i.e. facing the load side, otherwise the same design.

2, lining panels 2 are pushed over the anchors 3 connected to the static support 1. The annular space between the profiled anchor surfaces and the hole reveals 8 is filled with material 5. Due to the special profiling or design of the anchor surfaces 10 and perforations 8, the solidified material 5 achieves a force transmission acting in every direction, namely via a precisely fitting material press fit. The holes 28 in the plate 2 are covered by welded-on or glued-on cover caps 15.

According to FIG. 3, lining plates 2 with or without reinforcement ring (s) 7 are screwed into place in welded nuts 21 by means of screws 22 which are countersunk. With concrete as a static beam, dowels can be placed in the concrete instead of nuts. The annular spaces are in turn pressed with putty 5 via the filling openings 23 provided in the screws 22. The lining is closed in the area of the screws 22 towards the stress side with welded or glued covering caps 15 over the joint 16. As an alternative possibility for the design of the hole reveal 8, a bore which tapers conically towards the loading side is shown. This facilitates the replacement of lining plates in the event of a repair, since lining plate 2 can be easily removed after loosening the screws 22. With sufficient thickness of the lining plates and a mathematical check of the perforation reveal, the reinforcing rings 7 can be dispensed with.

Alternatively, reinforcement rings can be arranged on the other side of the plate, with otherwise the same design. 4, the lining plates 2 are fastened to the static support 1 by means of anchors 3. The anchors 3 reach into an opening in the reinforcing rings 7 welded, glued or otherwise molded onto the lining plate 2. Both the surface 10 the anchor 3 and the perforations 8 are profiled in such a way that the putty 5 injected through openings 26 causes mutual anchoring. This profiling is necessary in particular in the case of thermoplastics such as the polyolefins for power transmission, since no adhesive contacts are possible on their surface. The filler openings 26 are then closed by welding or adhesive plugs. This results in a smooth, dense lining surface on the load side.

5, the lining plates 2 are fastened from the inside via anchors 3 to a sheet metal jacket 1 serving as a static support. The anchors 3 are preassembled from the outside in a fixed division through the bores 28 of the sheet metal jacket 1 as a screw insert. The lining plate 2 is pushed onto the armature 3 with its reinforcement rings 7, which are attached in the same pitch. The predetermined annular gap between the armature 3 and the reinforcement ring 7 permits tolerances due to thermal expansion in the division between the armature 3 and the reinforcement ring 7 during assembly. The annular gap is filled with a material 5 to produce a direct material bridge between the armature 3 and the hole reveal 8 of the reinforcing ring 7, as described under FIG. 4. The force transmission in the axial direction of the armature is effected by its profiling 10 and the profiling 10 of the hole reveal via the material filling 5. When the lining plate 2 is replaced, the anchor 3 can be unscrewed from the outside of the static support 1 and the material 5 in a simple manner.

6, the armature 3 with its part 27 into the opening 28 of the reinforcing rings 7 of the lining plate 2 fitted in such a way that a material fit with a non-positive profile 10 in the perforation 8 of the reinforcing ring 7 is achieved for full-area power transmission. Alternatively, part 27 of the armature 3 could also be designed in the form of a single or double tube and pushed over the reinforcing ring 7. The prepared lining plate is inserted with the anchors 3 into bores 24 of the static support 1 in such a way that one end of the anchors 3 protrudes and is screwed in this position by nut 13 via the clamping disks 4. The forces acting on the lining plate 2, in particular from suppressed thermal expansion, are thus transmitted via direct material contact to the reinforcing ring 7 and from this to the part 27 of the armature 3 inserted with a precise fit. This, in turn, transfers the forces to the static support using a conventional screw connection with static friction metal - metal. To secure the anchor position in the bore of the static support, the annular gap required there for tolerance compensation can be filled with material 5 which is injected through the filling opening 23 of the clamping disk.

According to FIGS. 7 and 8, the lining plates 2 are attached to the static support 1 by means of prefabricated retaining rings 6, which are pressed onto the anchors 3 or screwed on via a thread 11. So that the retaining rings 6 can be used with an exact fit at each of the fastening points, despite the eccentricity and dimensional accuracy of the annular gaps 9 to be expected during assembly, that a full-surface frictional connection is achieved at the perforations 8, the annular gap 9 is directly before assembly of the corresponding retaining ring with a cutting tool 25. The retaining ring 6 is then inserted immediately. The diameter of the milling cutter or drill 25 must correspond to the maximum precalculated eccentricity of the perforations 8. The lining is covered by welding or gluing on cover caps 15 with welding or adhesive seam 16. The shape of the perforations 8 can be conical or in some other way such that when the spacer rings 6 are inserted, the lining plate 2 is screwed to the static support 1.

9 bores 24 are made in the static support 1. The anchors 3 are inserted into the bores 28 of the cladding panels 2 so precisely that a fit and thus a non-positive connection takes place in the hole reveal 8. Some of the anchors extend into the bores 24. The annular gaps 9 between the bores 24 and the anchors 3 are filled with material 5 via filler openings 23 which lead through the anchors 3. After the material fillings 5 have solidified immediately, there is a frictional connection between the anchor 3, the lining plate 2 and the static support 1. The anchor surface 10 of the anchors extending into the bore 24 can be provided with a thread-like profile. If it is also prepared with a release agent in such a way that there is no adhesion to the material 5, the anchor 3 can later be unscrewed from the material 5 in the event of a repair, which facilitates disassembly. If the cover cap 15 fits snugly on the armature 3, additional forces are dissipated via the hole reveal in the cover cap.

According to FIG. 10, the covering caps 15 are pushed over the anchors 3 with a precisely fitting fit in the perforations 8 and cover the bores 28 in the lining plates 2. The covering caps are connected to the lining plate 2 via the joining seam 16 and thus serve as a material bridge. In the case of a rotary welding process which is possible as a joining method, the snug fit in the hole reveal 8 also serves to guide the cover cap 15 during the welding process. The mating surface in the hole reveal 8 can be profiled in such a way that there is a connection between the armature 3 and the cover cap 15 via the profiling by melting or gluing during the joining process. The embodiments of the attachment points shown in the various figures can be combined as required, both with reference to the individual attachment point and with respect to different designs within the same lining.

Claims

Patent claims

1. Device for lining a static support (1) with plastic plates (2), with: a) anchors (3) arranged on the support (1) or on the plastic plates (2), b) bores (28 or 24) in the plastic plates (2) or the support (1), the diameter of the bores being dimensioned such that they can be pushed over the anchors (3), taking account of changes in position to be expected due to expansion during assembly, c ) between the anchors (3) and the plastic plate (2) or the carrier (1) via a variable annular gap

(9) a material bridge is formed on the fitting joint, which connects the anchors (3) and the plastic plate (2) or the carrier (1) in a force-locking manner, and optionally with d) additional devices for holding the art ¬ fabric panels (2) on the carrier (1).

2. Device according to claim 1, characterized in that the static support (1) is made of concrete or sheet steel.

3. Device according to claim 1 or 2, characterized gekennzeich¬ net that a positive connection between the plastic plate

(2) or the carrier (1) and the armature (3) via a material (5) filled into the annular gap (9).

4. The device according to claim 3, characterized in that the filling material (5) solidifies so quickly that movements caused by differential expansion in the annular gap (9) do not hinder the solidification process.

5. Device according to one of claims 1 to 4, characterized in that the power transmission between the plastic plate (2) or a plastic reinforcement ring (7) attached to it and the armature (3) by fitting a retaining ring ( 6) in the previously centrally drilled annular gap (9).

6. Device according to one of claims 1 to 4, characterized in that a form-fit via a ^'ker in the presence (3) supported clamping disc (4) tion with their Profilie¬ carried out (14) formed in the surface of the Art fabric plate (2) is sunk.

7. The device according to claim 3 or, characterized gekennzeich¬ net that anchors (3) are used in the bores (28), which at one end positive fit contact to the perforations (8) of the plastic plate (2) or reinforcing rings attached to it ( 7) and are inserted with the other end into bores (24) of the static support (1), so that between the anchors (3) and the bores (24) there remain annular gaps (9) which are filled with the material (5) are positively filled.

8. The device according to claim 7, characterized in that the bores (24) are dimensioned such that all differential strains can be compensated for during assembly and the armature (3) in this position with its part

(27) is screwed non-positively onto the static support (1) by a screw (3) and a clamping disk (4) without the plastic reinforcement ring

(7) exposed to the pressure caused by the tightening force.

9. Device according to one of claims 1 to 5, characterized in that a positive connection via a screw (22) with its profiling (14), which is sunk into the surface of the plastic plate (2).

10. Device according to one of claims 1 to 9, characterized in that the bores (28 or 24) in the lining plates (2) or the carrier (1) with the anchors therein with cover caps (15) by welding, gluing or Screwing on with an interposed seal are liquid-tight and gas-tight.

11. Device according to one of claims 7 to 10, characterized in that the reinforcing rings (7) welded aufge¬ in the region of the bores (28) of the plastic plates (2) are glued or already in the Plattenher ^¬ position formed.

12. The apparatus according to claim 11, characterized in that the reinforcing rings (7) on their contact surfaces with the static support (1) have ventilation grooves (17).

13. The device according to one of claims 3 to 6 and 9 to 12, characterized in that the hole reveal (8) in the plastic plate (2) and in the reinforcing ring (7) has a conical shape, so that the plastic plate

(2) after loosening the screw connection (22) easily over the anchor (3) and the material (5) can be removed.

14. Device according to one of claims 11 to 13, characterized in that the bores (28) intended for insertion of the armature (3) are formed only in the reinforcing rings (7) and do not penetrate the plastic plate (2).

15. The device according to one of claims 1 to 14, characterized in that the surface of the armature (3) with a profiling (10) and / or the perforation (8) are provided with a profiling or other shape (10), so that after the material (5) is injected, there is a positive and non-positive connection between the armature that also acts in the axial direction (3), reinforcing ring (7) and lining plate (2).

16. The apparatus according to claim 5, characterized in that the hole reveal (8) of the bore (28) and the corresponding flanks of the retaining ring (6) are conical or in another form such that after insertion of the retaining ring (6) an attachment of the plastic plate

(2) on the static support (1).

17. The apparatus according to claim 16, characterized in that the retaining ring (6) on the armature (3) via a thread or another profile (11) is screwed or clamped.

18. Device according to one of claims 1 to 17, characterized in that the static carrier (1) has a protective coating, a coating or other protection (19).

19. Device according to one of claims 1 to 18, characterized in that the gap (18) present between the plastic plate (2) and the static support (1) is used as a monitoring space for leaks.

20. Device according to one of claims 1 to 19, characterized in that between the plastic plate

(2) and the static support (1) existing gap (18) is used as thermal insulation with or without Isoliermaterial¬ filling.

21. Device according to one of claims 1 to 20, characterized in that between the plastic plate (2) and the static support (1) existing gap (18) is secured in width by spacers (20) or by inserting other intermediate layers.

22. Device according to one of claims 1 to 21, characterized in that the surfaces of the plastic plate (2) between adjacent anchors (3) are preformed slightly bowl-shaped (27), whereby the direction of expansion is predetermined at thermal expansions and a reduction of "Forced stresses are made possible by a further, prepared and reversible stretch.

23. A method for producing the device according to one of claims 1 to 22, characterized in that bores in the plastic sheets (2) and the carrier (1) are produced simultaneously.

24. The method for producing the device according to claim 14, characterized in that the material (5) through an injection opening (23 or 26), which is in the plate (2) or in the static support (1) or in the anchor

(3), injected and the injection opening (26) is then closed by a plug.

25. The method for producing the device according to one of claims 10 to 22, characterized in that the Ab¬ cover cap (15) with a snug fit on the armature (3) and then with the plastic plate (2) in the welding or adhesive process over the Seam (16) is tightly connected so that a frictional connection between the lining plate (2) via the cover cap (15) with the anchor

(3) comes about and the hole (28) in the plastic sheet (2) is covered.