NO345761B1 - A foundation and method for attaching a composite post for use in the distribution or regional network to such a foundation in the ground. - Google Patents

Description

A foundation and method for attaching a composite pole for use in the distribution or regional network to the ground.

Technical field

The invention relates to a foundation for mounting composite posts.

The invention also relates to a tool and a method for mounting the composite posts on the foundation.

Technical background

The usual method for installing poles for the distribution and regional network is to dig corrugated pipes into soil or blasted rock masses in advance, and subsequently install poles under the corrugated pipe. Wooden posts and steel masts are usually fixed with bolts where there are mountains.

There are also known foundations where the foundation is formed from two hinged parts and where the individual parts are attached to the ground and the post respectively. The publications US3311333 and US3671738 show examples of such solutions.

EP2463440 shows foundations for a traffic sign, especially those that are set up in the roadway to prevent accidents. These are light and removable signs where the sign has an L-shape at the bottom which is secured into the foundation by means of a ring-shaped part.

GB2027769 also shows a foundation for use in traffic signs with screws that press against the foundation to create friction between bolt and pipe wall.

However, none of the publications show a foundation or a method for fixing a foundation as stated in the independent requirements.

The foundation according to the present invention saves the grid operator the costs of blasting and digging rock. There will also be a significantly reduced environmental footprint of the concept, as this only requires drilling 4 holes in the rock.

The foundation also provides an improved fixing of the composite post.

The tool and procedure for installing the composite post also enables an efficient and cost-optimal installation of the post. The tool is temporarily attached to the foundation and the post and can be reused for fitting further posts.

Further advantages of the foundation are that there is no need to bardun the post or put support rods on the post, as the foundation is solid enough to take up the entire moment.

There is also no need for a crane truck or helicopter when installing using the tool. The pole must be able to be installed, for example, with an ATV with a winch. It is also an affordable installation in inaccessible places.

The foundation according to the invention is a particularly useful composite pole for use in the distribution and regional network. It is also particularly beneficial where the poles are to be installed on mountains. The unique feature of the invention is how the composite post is attached to the foundation, and the system as a whole.

Summary of the invention

The invention relates to a foundation for attaching a composite post for use in the distribution or regional grid, the foundation comprises

- a load distribution plate adapted to receive at least one fastening device for fixing in the ground. The foundation also includes

- an outer tube and an inner tube angled attached to the load distribution plate, the outer tube and/or the inner tube, respectively, are arranged to rest against a part of the composite post when the post is placed in the foundation. The foundation further comprises openings arranged transversely in the inner and outer tube respectively, arranged to receive a post bolt for securing the composite post to the foundation.

Advantageously, the foundation further comprises an outer tube and an inner tube arranged at an angle on the load distribution plate, the inner tube is concentrically arranged on the inside of the outer tube, the inner and outer tube have a mutual distance corresponding to the thickness of the part of the composite post which is in contact with the foundation so that this part fits in the space between the inner and outer tube.

Advantageously, the openings in the outer tube have a larger diameter than the diameter of the openings in the inner tube.

Advantageously, the openings in the inner tube are threaded.

Advantageously, the inner and outer tubes are annular.

Advantageously, the inner and outer tube are perpendicularly arranged on the load distribution plate.

Advantageously, the load distribution plate, inner and outer tube form an integrated unit.

Advantageously, the foundation comprises at least one opening to respectively receive a fastening device, such as a rock bolt.

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The invention also includes a method for attaching a composite post for use in the distribution network or the regional network to a foundation as stated in one of claims 1-5 by means of a tool comprising a foundation part and a post part hingedly connected at one end so that the post part can rotate about an axis passing through a hinged end connecting the post part and the foundation part by means of the tool that the method includes the steps:

- connect the foundation part to the foundation,

- connect the post part to the composite post,

- rotate the post part with the composite post around the axis towards the foundation so that the composite post is guided towards the foundation and can be attached to it,

- connect the foundation to the composite post using post bolts that are passed through openings in the inner and outer tube, as well as openings in the composite post.

Advantageously, the method further comprises

- removal of the tool from the foundation.

The method further comprises connecting an auxiliary support assembly to the composite post prior to connecting the post part to the composite post.

Brief description of the figures

Figure 1 shows a perspective view of the foundation with a section of the composite post,

Figure 2a-2b illustrates an embodiment of the foundation with the composite post seen from the side and from above,

Figure 3 illustrates a section through the foundation and the part of the composite post which is attached to it,

Figure 4 illustrates a bolt for use in fixing the composite post,

Figures 5a-5b show a first embodiment of the tool for use in mounting the composite post to the foundation in its simplest form,

Figures 6a-9b show a second embodiment of the tool for use in mounting the composite post to the foundation at different positions, seen from the side and in perspective,

Fig. 10a-10f show the tool according to another embodiment when the composite post is arranged vertically above the foundation, seen from different angles.

Figure 11a-11c shows a setup for installing the composite post to the foundation using the tool.

Figure 12 shows a perspective view of the installation.

Detailed description of the invention.

The word composite post means a post made from a mixed material of fiber and matrix. This can typically be fiberglass and a thermosetting plastic, but can also be other types of fibers and matrices. In our case, the poles are made of fiberglass and polyurethane. This type of pole is particularly suitable for use as a pole for use in the transmission of electricity in the distribution or regional network.

Advantageously, the composite post is hollow. However, the foundation is also applicable to composite posts for use for other purposes.

The foundation is particularly suitable for areas where the ground is mountainous.

Threaded braces from the foundation down into the ground provide good support for the foundation.

Figures 1-3 show an embodiment of a foundation 1 according to the invention. Figure 1 shows that the foundation 1 is attached to the ground on one side and to a composite post 2 on the other side. Figures 2a and 2b respectively show the foundation 1 with the composite post 2 seen from the side and from above.

In the example in the figure, the foundation 1 is attached to the ground using four fastening devices in the form of rock bolts 6, 7a, 7b. The fixing devices 6, 7a, 7b comprise threaded rods 6 which are fixed vertically to the ground and nuts 7a, 7b which are fixed above and below the foundation 1 in order to keep the foundation 1 stable. This is explained in more detail in connection with the procedure.

The foundation 1 further comprises a load distribution surface 3 and an inner and outer pipe 4, 5. In its simplest form, however, the foundation 1 can comprise an inner 5 or outer pipe 4. The foundation 1 can be made of galvanized steel, but is not limited to this material.

The inner and outer tubes 5, 4 are arranged concentrically and have a mutual distance to each other. This distance is parallel. The distance is defined by the thickness of the hollow composite post 2 so that the part of the post which is attached to the foundation 1 can be placed in the space between the inner and outer tube 5, 4. As shown in the figures, the inner and outer tube 5, 4 are also arranged perpendicular to the load distribution plate 3. A section showing the foundation 1 with the composite post 2 positioned in the space between the inner and outer tube is shown in Figure 3.

The load distribution plate 3 transfers load from post 2 to rock bolts 6, 7a, 7b as well as the inner and outer tubes 5, 4 which transfer loads to post 2.

Transverse openings are arranged in the inner tube 5, the outer tube 4 and the post 2. The openings are aligned so that each of the openings in the inner tube 5, the outer tube 4 and the post 2 correspond and form horizontal open lines when the post is placed in the foundation 1.

The post 2 in the figure is connected to the inner and outer tubes 5, 4 via sixteen post bolts 10 which are passed through these openings in the inner and outer tubes 5, 4, as well as the post 2. The invention is not limited to sixteen post bolts 10. The number of post bolts 10 can be more or less than sixteen as long as the post 2 is properly attached to the foundation 1. Design of the post bolts 10 is shown in detail in Figure 4 and explained in more detail below.

The post bolt 8 is made with a threaded part 15 in the innermost part which extends to the inner tube 5 in the foundation 1 which has threaded openings. The post bolt 8 will thus be driven forward and pressed through the composite post 2. The post 2 here has pre-drilled holes with tight tolerance, so that when the post bolts 8 are installed it will be a "tight fit", and no slack. The post bolt 8 further has an intermediate part 13. Between the part 13 comprises a conical part 14 after the threaded part 15 to more easily enter holes in the post 2 and an intermediate part part 16 with a larger diameter than the threaded part 15 to ensure a tight fit to the opening in the post 2. against a head part 11 of the post bolt 8, the bolt 8 has an outer part 17 with an even larger diameter to provide good engagement with the bolt hole in the outer tube 4, but without creating difficulties for entry before this part 17 engages. The outer part 17 can correspondingly comprise a conical part 18 and an outer part part 12. The inner and outer tubes 5, 4 on both the inside and the outside are arranged to relieve the bolts 8 sufficiently to take up the significant moment that occurs when bending the post 2.

The post bolt 8 also includes the head portion 11 at the outer end. This head portion 11 has a larger diameter than the opening in the outer tube 4 to form a stop for the post bolt 8 when it is inserted into the foundation 1 and the post 2.

Figure 5-10f shows different designs of a tool 20, 20' for use in installing the composite post 2 to the foundation 1 in different positions from the start of assembly until the post 2 is arranged over the foundation 1 ready to be dropped onto it.

Figures 5a and 5b show a first embodiment of the tool 20, 20' in its simplest design.

Figure 6a-figure 10f shows another embodiment of the tool 20, 20'. Identical elements have the same reference number on the two versions of the tools.

The tool 20, 20' comprises a foundation part 21 which is designed to be attached to the foundation 1. The foundation part 21 is illustrated in the figures as two elongated elements 21a which are connected by a strut 21b at one end. Each of the elongated elements 21a has brackets 25 which can be attached to the foundation 1 via each of the threaded rods 6. The figures show two brackets 25 attached to each of the elongated elements 21a.

The tool 20, 20' further comprises a post part 22 which is designed to be attached to the post 2. The post part 22 is illustrated in the figures as a frame of two elongated elements 22a and two transverse elements 22b. These are connected together and arranged to enclose the post 2. The elongate elements 22a are hingedly connected to the elongate elements of the foundation part 21a.

The elongate elements 22a and the transverse elements 22b have transverse openings that fit with openings in the post 2 so that the post 2 can be attached to the post part via bolts 24.

In use, the post part 22 can rotate about an axis A which coincides with the center axis of a stay 23. This means that the tool 20, 20' can control the movement of the post 2 from a lying position to a standing position where the post 2 is aligned to to fit in the foundation 1.

Figure 5a shows the first version of the tool seen from the side in a position where the post is lying placed in the tool 20, in an approximate initial position for this version. In this position, the tool 20 is attached to the foundation 1 and the post 2. Figure 5b shows the tool 20 from Figure 5a in a position where the post part 22 has been brought closer to the foundation part 21 to align the post 2 over the foundation 1.

This figure shows the brackets 25 in more detail. The openings for attaching the brackets 25 to the foundation part 21 can be oblong in order to have wiggle room when attaching to the foundation 1. The openings are also oblong / slot-shaped in order to be able to adapt to different sizes of foundations, for example 9, 11 and 13 meter high masts or posts. The bottom diameter can be slightly different on the different posts 2. Similarly, on the strut or shaft 21b, washers are placed between the foundation part 21 and the post part 22 in order to be able to adapt to different foundations 1.

Figure 6a-figure 10f shows a second embodiment of the tool 20'. Identical elements have the same reference number on the two versions of the tools.

In addition to the post part 22 and the foundation part 21, this embodiment has an auxiliary support 26. This part is hinged on the same axis A as the foundation part 21 and the post part 22 at one end. The auxiliary support 26 can be designed as two elongated elements 26a which are connected by a cross beam 26b. At the free end of the auxiliary support 26, a control device 27a and a fastening device 27b are arranged. The control device 27a is shown in figure 10c as beams or. which is arranged to extend along the post 2.

The beams are held together by a cross beam as shown in the figure. The fastening device 27b is shown in the embodiment as a band or. which extends around the periphery of the post 2. The control device 27a and the fastening device 27b thus fasten the tool 20' to the post 2 in a distance from the end point of the post 20. This means that the tool according to this design provides additional support when mounting the post 2 in the foundation 1. The fastening device 27b and the control device 27a are hingedly attached to the support part in points 28b, 28a respectively. The auxiliary support 26, the fastening device 27b and the control device 27a form an auxiliary support assembly 26, 27a, 27b.

Figures 6a-6b show the tool 20' according to another embodiment in an initial position where the post is positioned lying in the tool bed 20'. In this position, only the auxiliary support assembly at the steering device 27a and the fastening device 27b are attached to the post 2.

Figures 7a-7b show the tool according to another embodiment where the post part 22 of the tool 22 is guided towards the post to be attached to the end of the post 2.

As shown in the figure, the auxiliary support 26 can be hinged attached to the rod 21b via an extension 29. This can also be firmly connected to the auxiliary support 26. The auxiliary support 26 can also be hinged directly to the rod 21b.

Figures 8a-8b show the post part 22 attached to the end of the post 2 by means of bolts 24.

Figure 9a, 9b shows the tool 20' in a position where the post 2 is on its way up to be positioned against the foundation 1.

Figures 10a-10f show the tool 20' in end position. In this position, the post 2 is vertically aligned and aligned in position above the foundation 1 or alternatively placed in the foundation 1. Figures 10a-10f show the system from different angles such as from different sides and from above.

The procedure for installing a composite post 2 in a foundation 1 as Installation procedure. This is illustrated in Figure 11a-c and Figure 12 for the tool according to the second embodiment.

1. The foundation part 21 of the tool 20, 20' is mounted on top of the foundation 1. It is further attached to the threaded rods 6 which protrude somewhat on the upper side of the foundation 1.

2. The post is fixed in the post part 22 of the tool 20. This is done in the version according to figure 5a-5b using four special bolts 24. It is a preferred version to fasten the post 2 to the tool with four bolts 24 in order to have post 2 which is fixed on all sides and thus obtain a stable post 2. The number of bolts 24 is not limited to this number, however. The post 2 and the tool 20, 20' can be attached in other appropriate ways as long as the attachment mechanism is easy to attach and provides a stable fixing of the post 2 in the tool.

As shown in Figure 11a, the tool 20' according to the second embodiment is attached to the post 2 via the auxiliary support 26 before the post part 22 is lifted into place on the post. This auxiliary support 26 provides an additional support to make the construction easier, and that it will make it easier to attach the post 2 in the post part 22.

The post part attached to the post 22 using special bolts 24 as mentioned above.

3. A winch wire 31 is attached to the free end of the composite post 2 and an associated winch 30 pulls the composite post 2 up to a vertical position.

4. The bolts that are fixed between the tool 20, 20' and the post 2 are loosened and the post 2 will enter the foundation 1. The post 2 can then be attached to the foundation 1 by the bolts 8 as explained earlier.

5. After the post 2 has been attached to the foundation 1, the tool 20, 20' is removed by detaching the tool 20, 20' from the foundation 1.

It may also be appropriate for a rope to be attached around the post on the opposite side of the winch to control the speed when the post approaches vertical position.

In addition, a spacer 32 is shown in figures 11b, 11c and 12. This spacer 32 is mounted between the post and the wire 31 and prevents the wire 31 from lying right next to the post when the post 2 is raised to a vertical position.

The foundation 1 is attached to the ground prior to this installation process by drilling a number of holes in the ground 10 using a template. In the embodiment shown in the figures, this corresponds to four holes. One in each corner of the load distribution plate 3.

Furthermore, threaded rod 6 is fixed in the ground with a template. The threaded rods 6 can be attached in other ways that are appropriate to obtain a firm connection between the threaded rods 6 and the ground 10.

The foundation 1 also has openings arranged in the load distribution plate 3 arranged to receive the threaded rods 6. The foundation 1 can thus be threaded onto the threaded rods 6, and the foundation 1 can be further attached to the ground. This is done in the embodiment by screwing nuts 7a, 7b on the top and bottom of the foundation 1 as shown in Figure 2. There is therefore a nut 7a above and a nut 7b below each bolt hole in the foundation 1. The foundation 1 is leveled and then adjusted on a well-known way.

The tool can also be operated hydraulically, electromechanically or by other actuation mechanisms, for example threaded rod or trapezoidal screw, driven by a crank or drill to move the post part 22 between the outer positions of the tool to place the post 2 on the foundation 1.

Claims (8)

Changed set of requirements 1. A foundation (1) for attaching a composite pole (2) for use in the distribution or regional network to the ground, the foundation comprises - a load distribution plate (3) adapted to receive at least one fastening device (6, 7a, 7b) for fastening in the ground, the foundation (1) comprises - an outer tube (4) and an inner tube (5) attached at an angle to the load distribution plate (3), characterized in that the outer tube (4) and the inner tube (5) are respectively arranged to rest against part of the composite post (2) when the composite post (2) is placed in the foundation (1), the foundation (1) further comprises openings arranged transversely in the inner and outer tube (5, 4) respectively, adapted to receive a post bolt (8) for securing of the composite post (2) to the foundation (1). 2. The foundation according to claim 1, wherein the foundation (1) further comprises an outer tube (4) and an inner tube (5) arranged at an angle on the load distribution plate (3), the inner tube (5) being concentrically arranged on the inside of the outer tube (4 ), the inner and outer tube (5, 4) have a mutual distance that corresponds to the thickness of the part of the composite post (2) that is in contact with the foundation (1) so that this part (2) fits in the space between the inner and the outer tube (5, 4). 3. The foundation according to claim 1 or 2, in which the openings are aligned so that each of the openings in the inner tube (5), the outer tube (4) and the composite post (2) correspond and form horizontal open lines when the composite post (2) is placed in the foundation (1). 4. Foundation according to one of claims 1-3, in which the openings in the outer tube (4) have a larger diameter than the diameter of the openings in the inner tube (5). 5. The foundation according to one of claims 1-4, in which the opening in the inner tube (5) is threaded. 6. Method for attaching a composite post for use in the distribution network or the regional network to a foundation as specified in one of claims 1 - 5 using a tool (20, 20') comprising a foundation part (21a, 21b) and a post part (22a, 22b) ) the hinge connected at one end so that the post part (22a, 22b) can rotate about an axis (A) which passes through a hinged end (23) which connects the post part (22a, 22b) and the foundation part (21a, 21b) characterized by that the procedure includes the steps: - connect the foundation part (21a, 21a) to the foundation (1), - connect the post part (22a, 22b) to the composite post (2), - rotate the post part (22a, 22b) with the composite post (2) about the axis (A) towards the foundation (1) so that the composite post (2) is guided towards the foundation (1) and can be attached to it, -connect the foundation (1) to the composite post (2) using post bolts (8) which are passed through openings in the inner and outer tube (5, 4), as well as openings in the composite post (2). 7. The method according to claim 6, wherein the method further comprises removing the tool (20, 20') from the foundation (1). 8. The method according to claim 6 or 7, wherein the method further comprises connecting an auxiliary support assembly (26, 27a, 27b) to the composite post (2) prior to connecting the post part (22a, 22b) to the composite post (2).