NO334265B1 - Holds for reinforcement at a distance from a surface - Google Patents

Description

The invention relates to a reinforcement holder as stated in the introduction to claim 1, and in particular a holder for reinforcing mesh or the like which is to be fixed in a material, such as insulation boards or the like. The invention is particularly aimed at attaching reinforcing mesh to insulating mats used in tunnels, mountain halls and other rock spaces.

Such tunnels, mountain halls and rock rooms are often lined internally with insulating material, such as mats of polyethylene foam or similar, which are covered with shotcrete after installation. The concrete is reinforced with reinforcing mesh that is fixed in rock bolts, at a certain distance from the insulating material.

In order to ensure that the reinforcing mesh is kept at this specific distance from the insulating material both when the shotcrete is applied and while it hardens, and thus to be able to control the positioning of the reinforcement in the cross-section of the concrete, a number of holders are additionally placed between the insulating material and the reinforcing mesh. Such holders are often referred to as reinforcement chairs.

Known holders of this type comprise a threaded part which is screwed into the insulating material, and an outwardly projecting attachment part to which the reinforcing mesh is attached. In one type, the fastening part comprises a stem with a through hole through which the installer must pass a steel wire (bonding wire) to anchor the reinforcing mesh.

Another type is described in Norwegian patent no. 307267, where the fastening part comprises an element placed at a distance from the threaded part (and thereby the insulating material). This element comprises a sleeve which is rotatably supported on the holder's projecting stem and which is provided with two plastic hooks. The two hooks are placed next to each other and each face their own way along the trunk's longitudinal axis. The curvature of the hooks is dimensioned for the current rebar thickness. To attach the reinforcing mesh to the element, the fitter must turn the holder and the fitting tool 90°. This places an additional physical strain on the fitter, in addition to requiring high precision from the fitter to ensure that the reinforcing wire is placed at the specific point between the hooks. Furthermore, the hooks provide a relatively small contact surface for the rebar. This can be a disadvantage as the concrete is applied under high pressure, which results in large dynamic loads on the holder.

As a further example of relevant prior art, SE0303523 is mentioned where an alternative design for attaching reinforcing mesh is presented.

A holder for reinforcement to be placed at a distance from a surface has therefore been produced, comprising a stem with an attachment part for attachment to a material below the surface and a holding part and a distance part in between. The attachment part comprises at least one helical thread which runs around the stem, preferably with increasing thread diameter, from a first end of the stem and to an area at the distance portion. Furthermore, the holding part comprises a first holding element and a second holding element, whereby the reinforcement is held between the first and the second holding element. The first holding element and the second holding element are provided with respective substantially planar and opposing surfaces, which surfaces are placed substantially normal to the longitudinal axis of the stem. The holder is characterized by the fact that the second holding element is provided with a plurality of holes, through which a fastening wire for the reinforcement can be passed.

In one embodiment, the first holding element and the second holding element comprise disc-shaped elements. The stem preferably passes through the center of the respective discs.

The thread may be provided with discontinuities or steps, placed at regular intervals on the thread.

In one embodiment, the first end of the stem is provided with a number of perforation elements, which in use engage with the surface and the material below this before the thread and which ensure that any film on the surface is broken, whereby the thread's engagement with the material is facilitated.

In one embodiment, a stop element is placed on the stem in an area of the distance portion which is closer to the fastening part than the holding part. In its embodiment, the stop element comprises a mainly flat surface which faces the thread in the fastening part and the surface of the stop element is placed mainly normal to the longitudinal axis of the stem, whereby the stop element defines a limit for how far the holder is screwed into the material below the surface. Stop element can comprise a disk-shaped element, where the stem preferably passes through the center of the stop element.

In one embodiment, the other end of the stem is provided with an engagement portion for screwing the holder into the insulating material, in the form of a hexagonal groove recessed in the stem for engagement with an allen key or the like. Preferably, the inner walls of the recessed groove are provided with a plurality of projecting parts, whereby an Allen key or the like that is inserted into the recessed groove can be held in place until the holder is fixed in the material.

In one embodiment, a connecting element is placed at the other end of the stem and protrudes from it, for screwing the holder into the insulating material, in the form of a hexagonal structure for engagement with a socket wrench or the like.

In one embodiment, the external walls of the connecting element are provided with a plurality of projecting parts, whereby a socket wrench or the like can be held in place until the holder is fixed in the material.

The first holding element may comprise a circular disk element or a star-shaped disk element, for example with six spikes.

In one embodiment, the opposing surfaces are arranged with a mutual distance that is at least twice the diameter of the reinforcement, whereby the holder can be placed in a reinforcing mesh where two rebars cross each other.

The invention is suitable where the material under the surface is an insulating material in the form of mats, plates or a sprayed-on, hardened foam material.

The invention finds particular application in connection with reinforcement work in tunnels, mountain halls or other rock spaces.

One purpose of the invention is to provide faster assembly and less strain on the fitter, and a better anchoring of the reinforcing mesh. Furthermore, the holder according to the invention will be able to be used on reinforcing mesh with greater variation in wire dimension than is the case with the known technique.

These and other characterizing features of the invention will be explained in further detail in the following description of an embodiment, with reference to the accompanying figures, where: Figure 1 shows a first embodiment of the reinforcement holder according to the invention, seen from the side; Figure 2 is a perspective drawing of the reinforcement holder shown in Figure 1; Figure 3 is a perspective drawing of a second embodiment of the reinforcement holder according to the invention; Figure 4 is a perspective drawing of a third embodiment of the reinforcement holder according to the invention; Figure 5 shows a fourth embodiment of the reinforcement holder according to the invention, seen from the side; Figure 6 shows an embodiment of the reinforcement holder according to the invention, seen from one end, and an enlarged section of the screw-in groove, seen along the longitudinal axis of the holder; Figure 7 is an enlarged section of the area marked "A" in Figure 2, and shows in particular a radial step on the thread; Figure 8 is a perspective drawing of an embodiment of the reinforcement holder according to the invention, placed adjacent to a reinforcement mesh.

The holder, or reinforcing chair, according to the invention comprises a stem 6 with an attachment part and a holding part, arranged against the stem's first end 2 and second end 17, respectively. The attachment part comprises in the described embodiment a spiral thread 4 and is separated from the holding part by a spacer 10. As shown in the figures (see figure 1), a helical thread 4 runs from an area at the first end of the stem 2 and a bit along the stem 6. A stop element, in the form of a circular flange 8, is arranged on the stem 6 just inside the thread 4. When installing the holder, screw the attachment part into the insulation mat until the flange 8 comes into contact with the surface of the insulation mat, indicated by a dashed line m in figure 1. The spacer 10 ensures that the holder part (and thereby the reinforcement 28) is sufficiently lifted out from the surface m of the insulation mat, and it is advantageous that this distance part is open and slim so that the concrete easily flows in between the flange 8 and the holding part, and voids in the concrete are avoided. Such voids weaken the concrete layer in terms of structure and can also cause the insulation to ignite in the event of a fire in the tunnel.

With reference to Figures 1 and 2, the holding part comprises a first holding element 12 and a second holding element 14, both of which are provided with respective substantially planar and opposing surfaces 1,3. As shown, the holding elements 12, 14, and also the opposing surfaces 1, 3, are placed mainly normally on the longitudinal axis of the trunk 6. The rebar or the reinforcing mesh 28 is thus placed and held between the first and the second holding element. Figure 8 shows this, and illustrates a case where the holder is placed in a corner or crossing point between two rebars in the web.

In the embodiment shown, the first holding element 12 and the second holding element 14 are disk-shaped elements, and the stem 6 passes through the center of the respective disks. With this design, great flexibility is achieved during assembly, as the holding elements do not need to be in any specific position to engage with the rebar, and the disc-shaped elements provide a relatively large contact surface. This can be seen most clearly in figure 8. As the concrete is applied with great pressure, there is an advantage to a large construction surface. It provides a good weight distribution and good stability in the plane of the material, and skewed loads on the attachment part can thereby be avoided.

The location of the two holding plates 12, 14 is such that there is a distance d between the opposing surfaces 1, 3, and this distance can be dimensioned in an appropriate way, for example to be greater than or equal to twice the diameter of the reinforcement 28, whereby the holder can be placed in a reinforcing mesh where two rebars cross each other, as shown in figure 8.

In the illustrated embodiment, the second holding element 14 is provided with an indicator pin 16 of a known type which is used during the spraying of the concrete to indicate the concrete thickness.

The figures also show that the fastening part is provided with a spiral thread 4 which runs around the stem 6 with increasing thread diameter from the first end 2 of the stem 6 and to an area at the distance part 10. As shown in figure 2 and figure 7 (where figure 7 shows a enlarged section of part "A" in Figure 2), the thread 4 can in one embodiment be provided with radial "steps" or discontinuities 26, placed at regular intervals on the thread, preferably in the transition between each half of the threads. When the threads 4 rotate in the insulation material when the holder is screwed into place, a pressure occurs between the edge 5 of the threads 4 and each individual cell in the foam material. As the edge 5 is not so sharp, this will stretch and/or stretch the cells somewhat before they break. Tests have shown that the cells can be very tough, allowing the thread 4 to rotate over half a turn before the cells break. These radial steps 26 will cause the cells to break so that they burst more easily. Preferably, the last turn of the thread 4 does not have this step, and the edge 5' is rounded there so that the pressure between the thread edge 5' and the cells remains, as this leads to a better hold between the screw and the foam.

With reference now to Figures 4 and 5, the first end 2 of the stem can in one embodiment be provided with a number of "teeth" or perforation elements 24. When the fitter screws the holder into the insulating mat, the teeth 24 will engage with the insulating material's surface m before the thread 4 and thereby break any film on the mat's surface m. This makes it easier for the threads to engage with the material below the surface m.

The stop flange or the stop element 8 is placed on the stem 6 in an area of the distance part 10 which is closer to the attachment part than the holding part, preferably at a distance from the thread 4. This stop element 8 is preferably also a disk-shaped element, where the stem 6 passes through the center of the stop element and preferably also has a substantially flat surface 8' which faces the thread 4 in the attachment part and is located substantially normal to the longitudinal axis of the stem. With this design, a limit is defined for how far the holder is screwed into the insulating material. As mentioned, this is shown in figures 1 and 5, where the dashed line marked m indicates the surface of the insulation mat in relation to the holder when it is screwed into place. The letter h (figure 1) indicates the height from the insulation mat surface m up to the first holding plate 12; and this part (which essentially coincides with the distance part 10) can easily be filled with concrete, as mentioned above. In a typical application, the sprayed concrete layer will have an extension from the surface m up towards the tip of the indicator pin 16.

With reference to figures 2, 4 and 6, the holder in a preferred embodiment is provided at the other end 17 of the stem with an engaging part 18 for screwing the holder into the insulating material. In the illustrated embodiment, this engagement portion has the form of a hexagonal groove 18 recessed in the stem 6 for engagement with an allen key or the like. With reference to figure 6, which shows this engaging part seen from above, the inner walls of the groove 18 can be provided with a plurality of projecting parts or beads 19 which provide a certain attachment to an allen key or the like which is inserted into the groove. The holder can thereby be more easily held in place until it is fixed in the insulating material.

With reference to Figure 4, the holder in another embodiment can also be provided with a connecting element 22 at the other end of the stem and which projects from this, for screwing the holder into the mat. This element has the form of a hexagonal structure 22 for engagement with a socket wrench or the like. The outer walls of this structure 22 can be provided with a plurality of protruding parts or beads 23 which provide a certain attachment to a socket wrench or the like. The holder can thereby be more easily held in place until it is fixed in the insulating material.

The second holding plate 14 is in one embodiment provided with a plurality of holes 15,

through which a locking wire for the reinforcement can be passed. As shown i.a. in Figure 2, the first holding plate can be shaped like a circular disc element 12 or, as shown in Figure 3, be shaped like a star-shaped disc element 20, for example with six spikes.

The holder according to the invention simplifies and streamlines assembly and works both for one and two strands in the reinforcing mesh, hence both at the intersection and between two intersections in a route. It also works for several sizes of reinforcing mesh. Furthermore, the holder according to the invention provides a better anchoring than existing devices.

The insulating material can be mats, sheets or a sprayed-on, hardened foam material.

Claims (16)

1. Holder for reinforcement to be placed at a distance from a surface (m), comprehensive a stem (6) with an attachment part for attachment to a material below the surface (m) and a holding part and a spacer part (10) in between where the attachment part includes at least one helical thread (4) running around the stem (6), preferably with increasing thread diameter, from a first end (2) of the stem (6) and to an area at the spacer portion (10), and where the holding part comprises a first holding element (12; 20) and a second holding element (14) whereby the reinforcement (28) is held between the first and the second holding element, where both the first holding element (12; 20) and the second holding element (14) are provided with respective mainly flat and opposite surfaces (1, 3), which surfaces are placed mainly normal to the longitudinal axis of the stem, characterized in that the second holding element (14) is provided with a plurality of holes (15), through which a fastening wire for the reinforcement can be passed. 2. Holder according to claim 1, characterized in that the first holding element (12; 20) and the second holding element (14) comprise disk-shaped elements. 3. Holder according to claim 2, characterized in that the stem (6) passes through the center of the respective discs. 4. Holds according to any of the preceding claims, characterized in that the thread (4) is provided with radial discontinuities (26), placed at regular intervals on the thread. 5. Holds according to any of the preceding claims, characterized in that the first end (2) of the stem (6) is provided with a number of perforation elements (24), which in use engage with the surface (m) and the material below it before the thread (4), and which ensures that any film on the surface (m) is broken, whereby the engagement of the thread (4) with the material is facilitated. 6. Holder according to any one of the preceding claims, characterized by a stop element (8) placed on the stem (6) in an area of the distance part (10) which is closer to the fastening part than the holding part. 7. Holder according to claim 6, characterized in that the stop element (8) comprises a mainly flat surface (8') which faces the thread (4) in the fixing part and that the stop element's surface (8') is placed mainly normal to the longitudinal axis of the stem, whereby the stop element (8) defines a limit for how far the holder is screwed into the material below the surface (m). 8. Holder according to claim 6 or claim 7, characterized in that the stop element (8) comprises a disk-shaped element, where the stem (6) passes through the center of the stop element. 9. Holder according to any one of the preceding claims, characterized in that the other end (17) of the stem (6) is provided with an engaging part (18) for screwing the holder into the insulating material, in the form of a hexagonal groove (18) recessed in the stem (6) for engagement with an Allen key or similar. 10. Holder according to claim 9, characterized in that the inner walls of the recessed groove (18) are provided with a plurality of projecting parts (19), whereby an allen key or the like that is inserted into the recessed groove can be held in place until the holder is attached in the material. 11. Holder according to any one of the preceding claims, characterized by a connecting element (22) at the other end (17) of the stem (6) and which protrudes from this, for screwing the holder into the insulating material, in the form of a hexagonal structure for intervention with a socket wrench or similar. 12. Holder according to claim 11, characterized in that the outer walls of the connecting element (22) are provided with a plurality of protruding parts (23), whereby a socket wrench or the like can be held in place until the holder is fixed in the material. 13. Holder according to any one of the preceding claims, characterized in that the first holding element comprises a circular disk element (12) or a star-shaped disk element (20), for example with six spikes. 14. Holder according to any one of the preceding claims, characterized in that the opposing surfaces (1, 3) are placed with a mutual distance (d) that is at least twice the diameter of the reinforcement (28), whereby the holder can be placed in a reinforcing mesh where two rebars cross each other. 15. Use of the holder as stated in any of the preceding claims, characterized in that the material under the surface (m) is an insulating material in the form of mats, plates or a sprayed-on, hardened foam material. 16. Use of the holder as specified in any of claims 1 - 14, in connection with reinforcement work in tunnels, mountain halls or other rock spaces.