BR102022009120A2 - TAPERED POLE WITH MIXED CONNECTION AND POLE INSTALLATION METHOD - Google Patents

Abstract

The present invention relates to a conical post with mixed connection (900), which comprises a conical base module (100) and at least one conical module (200), wherein: the thicknesses of the walls of each module of the conical post with mixed bond (900) decrease upwards; and the connection between the modules comprises a mixed connection, wherein the mixed connection comprises: telescopic joint (1000) and nuts (104, 204), wherein the nuts (104, 204) are used in conjunction with at least one of: screws, pin and rivet.

Description

Technical Field

[001] The present invention patent belongs to the field of mechanical engineering, thin-walled conical pole structures, and can be applied to metallic structures for telecommunications or electrical energy transmission infrastructure.

Introduction

[002] The present invention patent refers to a conical post structure with mixed connection for fixing the modules of a thin-walled structure. This solution features the telescopic joint (slip-joint), which consists of sliding between the modules of the post structure, together with the fixation using screws and nuts in the fitting between the pieces.

Fundamentals of the invention

[003] Posts for use in telecommunications infrastructure are made up of a single vertical element that can be made of reinforced concrete, or formed by circular steel tubes. They have structures to support antennas of various models, dimensions and the most varied loads.

[004] The posts can have connections between the modules by screwed flanges, passing through the modules fixed by screws or by slip-joint.

[005] When using screwed flange connections, it is possible to observe greater loss of material and difficulty in manufacturing the flanges, in addition to the possibility of generating fissures and cracks due to the action of the wind in the region where the flange is welded to the wall of the structure.

[006] In the connection between modules fixed by screws, we can observe other problems, such as the high manufacturing cost due to the need to use a large number of screws to guarantee resistance to the efforts to which the modules are subjected and due to the fact that the distributed loads the modules in the screws and in the respective holes in the walls of the post begin to show deformations, causing the connections to weaken.

[007] Therefore, the manufacture of lighter and more resistant poles is a constant challenge for manufacturers of this type of product around the world.

State of the art

[008] There are several known solutions in the state of the art for the connection element of conical post modules, such as document US2012/0317918A1, entitled “Joint of metal segments of a tower”, which presents a method for connecting metal segments of a tower by means of bolted flanges.

[009] The solution presented in document US2012/0317918A1 reveals the union between modules by means of screwed flanges, which makes the manufacturing and installation of the flanges difficult, since material losses occur and the possibility that, according to the action wind, cracks or cracks are formed in the region where the flange is welded to the structure wall. Furthermore, in the cited document, the union between the modules also depends on the application and curing of a paste that contributes to the transfer of load from one segment of the tower to another and reduces fatigue in the connected elements, which makes the process more costly and Late.

[010] Another patent document whose solution may be mentioned is document US3936206, entitled “Tubular Pole Sliding Joint Construction”, which describes a sliding joint construction for a tubular post section of a power pole, such as for transmission electrical or lighting, wherein a male fitting of one tapered post section fits telescopically within a female fitting of another tapered post section. The female connection is provided with a support strip that runs along its seams. The male connection is provided with slots extending along the frame along the length of the slip connection. Two plates are welded inside the male connection and extend longitudinally from each slot.

[011] The solution presented by document US3936206 reveals the use of the telescopic joint in the module unions, where the female section of the tubular post is provided with metal support strips, which are welded and extend along its seams, being fitted into the cracks in the male connection of the structure. In the case of applying the solution to telecommunications towers, which are more robust structures, the efforts generated due to the action of the wind, mainly bending moment, are greater and, therefore, would make the solution as presented unfeasible, since it would be necessary to provide reinforcement addition to the structure, which would make it difficult to manufacture the angled parts and to weld them to the internal part of the structure.

[012] Another patent document whose solution may be mentioned is document US6191355, entitled “Multi-sectional power pole with telescopic conical connections”, which describes a multi-sectional power pole that includes at least two straight tube sections, which are joined and connected by a telescopic joint. The telescopic joint preferably consists of two corresponding tapered sections, with one attached to each post section. The telescopic joint is compressed with the help of rings, which are attached to the tube, a corresponding protuberance and cavity. The two tapered sections are fastened together with screws that pass through the female tapered section and are threaded into the male tapered section of the telescoping joint.

[013] The solution presented by document US6191355 reveals a multi-sectional power pole that uses large amounts of welding to join the straight section with the conical section, which ends up damaging the resulting structure, as the efforts decrease as it approaches from the top, while the amount of welding remains the same, resulting in extra weight and wasted material throughout the structure.

[014] The document entitled “The Slip-joint Connection, alternative joint between pole and tower”, authored by DOWEC, dated October 2, 2003, discloses module junctions through slip-joint, or telescopic connections, with lengths of fittings that are at least twice the covered diameter, which ends up generating a large consumption of sheets in the fitting between the modules, increasing the weight and final cost of the structure.

[015] There is, therefore, space for a conical post with a telescopic joint with the addition of a screw in the covered section that provides a reduction in the leverage effect created on the modules and ensures a significant reduction in the weight of the post.

[016] There is, therefore, space for a conical post with mixed connection, which: a) provides greater security and reduces the leverage effect created between the modules; b) makes it possible to reduce the length required for fitting between the sliding joint parts; c) reduce the number of screws in the installation; d) significantly reduce the weight of the post; and e) increase fatigue resistance.

Objectives of the invention

[017] One of the objectives of the present invention is to provide a conical post with mixed connection, in accordance with the characteristics of claim 1 of the attached set of claims.

[018] Another additional objective of the present invention is to provide a method of installing the pole, in accordance with the characteristics of claim 15 of the attached claim table.

[019] The other characteristics are found in the claims dependent on the claim framework.

Description of the figures

[020] For a better understanding and visualization of the object of the present invention, it will now be described with reference to the attached figures, representing the technical effect obtained, in which: Figure 1: presents a front view of a conical base module in accordance with the present invention; Figure 2: shows a front and side sectional view of the base conical module of Figure 1; Figure 3: shows a front and top sectional view of a conical base module of Figure 1; Figure 4: shows a front and top sectional view of a conical module according to the present invention; Figure 5: shows a conical post with mixed connection with several modules coupled by mixed connection, in accordance with the present invention; Figure 6: presents an approximate view of the joint of two modules present in the conical post with mixed connection in Figure 5; and Figure 7: shows a schematic view representing the telescopic joint of the present invention. Detailed description of the invention

[021] A conical post with mixed connection (900), or post (900) comprising a conical base module (100) and at least one conical module (200) and in which the connection between the modules comprises a mixed connection.

[022] The conical base module (100), according to the present invention, comprises a plurality of holes (101), a plurality of windows (102), a plurality of angles (103), a plurality of nuts (104 ) and a flange (105), in which the base conical module (100) is preferably metallic and has thin walls.

[023] Additionally, the base conical module (100) comprises a larger base diameter that tapers to a smaller top diameter so as to allow other conical modules to slide through the area outside the top of the conical module. of base (100) until generating a fitting, in which the outer diameter of the top of the base conical module (100) corresponds to the lower inner diameter of another conical module, allowing another conical module to be fitted and locked onto the conical module from base (100) to a height (h), as represented, in a non-limiting way, by Figure 7.

[024] Furthermore, the walls of the conical base module (100) are formed by line segments, which cause the conical base module (100) to have a polygonal shape when viewed from above, as can be seen in Fig. 3. This polygonal shape allows the other conical module to fit with the base conical module (100), in order to facilitate correct and precise alignment between the holes (101) and nuts (104), between the fitted modules.

[025] The holes (101) of the base conical module (100) are through holes and equally distributed at the end opposite to the end of the flange (105), being arranged at the same height around the body of the conical module (100 ), preferably, the holes (101) are arranged in at least two rows of different heights, so as to maintain at least one pair of holes (101) on each face of the polygonal profile of the conical base module (100).

[026] The windows (102) of the conical base module (100) are distributed in the same height line around the conical base module (100), in which, preferably, four windows (102) are distributed with equal distances from each other and below the bottom row of holes (101), so that the windows (102) can be opened and closed even when another conical module is fitted over the base conical module (100).

[027] Additionally, the windows (102) are spaces that can be opened outwards, in order to allow operations such as welding, screwing and maintenance to be carried out inside the conical base module (100) when it is covered by another conical module.

[028] The angles (103) of the conical base module (100) are distributed around the conical base module (100), where, preferably, two angles (103) are distributed at equal distances from each other.

[029] Additionally, the angles (103) are located on the same height line around the conical base module (100), in order to provide a contact interface for a technician, so that he can carry out the installation of the conical base module (100) by applying a force to the angles (103) and pushing the conical base module (100) downwards.

[030] The nuts (104), of the conical base module (100), are nuts (104) corresponding in internal diameter and quantity with the holes (101), in which the nuts (104) are welded concentrically with the holes ( 101) and, together with screws, serve as a means of fixing between the base conical module (100) and another conical module.

[031] The flange (105), of the conical base module (100), has a circular shape and comprises reinforcement ribs that connect the flange (105) to the conical base module (100), where the number of ribs is proportional to the number of vertical line segments present in the base conical module (100).

[032] Additionally, the flange (105) comprises at least one anchor hole to provide a fixed fit of the conical base module (100) with the foundation of the structure.

[033] Furthermore, the flange (105) receives anchor bolts, equally spaced around the flange (105), in order to install the conical base module (100) on the foundation inserted into the ground.

[034] A conical module (200), according to the present invention, comprises a plurality of holes (201), a plurality of windows (202), a plurality of angles (203) and a plurality of nuts (204), the holes (201), angles (203) and nuts (204), are located at both ends of the conical module (200), in a mirror configuration, one with respect to the other, in which, additionally, the conical module (200 ) is preferably metallic and has thin walls.

[035] Additionally, the conical module (200) comprises a larger base diameter that tapers to a smaller top diameter in order to allow other conical modules to slide through the area outside the top of the conical module (200 ) until generating a fitting, in which the external diameter of the top of the conical module (200) corresponds to the lower internal diameter of another conical module, allowing another conical module to be fitted and locked onto the conical module (200) until a height (h), as represented by Figure 7.

[036] Furthermore, the walls of the conical module (200) are formed by line segments, which cause the conical module (200) to have a polygonal shape when viewed from above. This polygonal shape allows the other conical module to fit with the conical module (200), in order to facilitate correct and precise alignment between the holes (201) and nuts (204) of the fitted modules.

[037] The holes (201), of the conical module (200), are through holes and equally distributed between the opposite ends of the conical module (200), being arranged at the same height around the body of the conical module (200), Preferably, the holes (201) are arranged in two rows of different heights, in the upper region and two rows of different heights, in the upper region of the conical module (200) in order to maintain at least two pairs of holes (201) in each face of the polygonal profile of the conical module (200).

[038] The windows (202) of the conical module (200) are distributed in the same height line around the conical module (200), in which, preferably, four windows (202) are distributed at equal distances from each other and below the bottom row of holes (201), so that the windows (202) can be opened and closed even when another conical module is fitted over the conical module (200).

[039] Additionally, the windows (202) are spaces that can be opened outwards, in order to allow operations such as welding, screwing and maintenance to be carried out inside the conical module (200) when it is covered by another conical module .

[040] The angles (203) of the conical module (200) are distributed around the conical module (200), in which, preferably, two angles (203) are distributed at equal distances from each other.

[041] Additionally, the angles (203) are located on the same height line around the conical module (200), in order to provide a contact interface for a technician, so that he can install the module conical module (200) by applying a force to the angles (203) and pushing the conical module (200) downwards.

[042] The nuts (204), of the conical module (200), are nuts (204) corresponding in internal diameter, positioning and quantity with the holes (201), in which the nuts (204) are welded concentrically with the holes ( 201) and, together with screws, serve as a means of fixing between the conical module (200) and another conical module.

[043] The conical module (200) can be repeated as many times as necessary, until forming an object that has the desired height, so that at least one next subsequent module (300) has upper and lower internal diameters smaller than the module previous.

[044] Furthermore, all modules of the resulting structure have a diameter ratio such as the ratio of the conical module (200) and the subsequent module (300), that is, the inner lower diameter of the subsequent module (300) is corresponding with the upper outer diameter of the conical module (200).

[045] The post structure (900), according to the invention, comprises a thin-walled structure that is divided into two or more modules (100, 200, 300, 400, 500, 600, 700, 800), in that the post (900) uses a mixed connection between its modules (100, 200, 300, 400, 500, 600, 700, 800).

[046] Additionally, the wall thicknesses of each post module (900) decrease upwards, so that the upper post module (900) has thinner walls than the lower module.

[047] The mixed connection of the modules (100, 200, 300, 400, 500, 600, 700, 800), on the post (900), comprises: telescopic joint (1000) and nuts (104, 204), in which the nuts (104, 204) are used in conjunction with at least one of: screws, pins, rivets, among others.

[048] The telescopic joint (1000), of the modules (100, 200, 300, 400, 500, 600, 700, 800), occurs by sliding between the modules (100, 200, 300, 400, 500, 600, 700 , 800), more specifically, in the telescopic joint (1000) the weight of the structure above the joint and the conical shape of the joint cause the friction force. The sliding joint connection is carried out in such a way that the upper and lower module of the section fit together perfectly. This means that both connected modules make contact with the entire sliding joint.

[049] In the telescopic joint (1000), the inclusion of the screwed section results in a reduction in the amount of plate used, in which the height of the sliding joint (h) is 0.1 to 1.9 the average diameter (d) of the module sliding joint, preferably once the average diameter (d) of the module sliding joint.

[050] The angle (a) (alpha) between the module wall (500) and the vertical line (550) varies between 1° and 30°.

[051] The method of installing the post (900) comprises the steps of: I. installing the base module (100) connected to the foundation by means of a flange (105), connected by anchor bolts concreted in a concrete block inside from soil; II. slide the upper module over the top of the base module (100), joining the modules (100, 200, 300, 400, 500, 600, 700, 800); III. ensure correct positioning by manually activating a fixing device, which forces the upper module onto the lower module, placing it in the correct position; IV. fix the screws in at least two rows of screws (201), from the outside to the inside, in the fitting area between the modules where the necessary nuts (104) are already welded internally; and V. repeat the process when assembling each module (100, 200, 300, 400, 500, 600, 700, 800), according to the application needs.

[052] As a non-limiting example of the present invention, when assembling subsequent modules (200, 300, 400, 500, 600, 700, 800), the upper module is correctly positioned over the lower module, achieving the necessary lateral friction. In the covered section are the holes that receive the screws, these screws can be placed from the outside to the inside, or from the inside to the outside, and the nuts that will guarantee the tightness are already welded inside the walls of the post (900).

[053] In a preferred embodiment, both the base conical module (100) and the conical module (200) of the conical post with mixed connection (900) are produced from metallic alloys.

[054] In an alternative embodiment, at least one of the holes (101, 201) is threaded.

[055] In another alternative embodiment, the nuts (104, 204) are positioned on the external side of the conical modules (100, 200).

[056] In another alternative embodiment, multiple angles (103, 203) can be distributed along the modules (100, 200, 300, 400, 500, 600, 700, 800), in order to provide additional contact interfaces, facilitating the fitting and installation of these modules (100, 200, 300, 400, 500, 600, 700, 800).

[057] In yet another alternative embodiment, a square frame surrounds the angles (103, 203), so that one of the edges touches one of the ends of one of the angles (103, 203), while the opposite end of the square frame touches an hydraulic jack, which is positioned inside the frame and, when activated, applies a force that brings the conical modules (100, 200) closer to each other.

Final considerations

[058] The present invention reveals a structure with greater security and which uses a telescopic joint in conjunction with fixation by screws and nuts in the covered section between the modules. The present invention also does not use paste, or glue, between the segments of the post (900), in order to provide a stronger and more reliable connection between its modules.

[059] It is clear that the measurements and relationships between measurements described for the present invention may vary according to the dimensioning of the modules (100, 200) and post (900). However, these measures and their relationships are highly reliable and reproducible, in addition to being highly efficient and effective.

Conclusion

[060] It will be easily understood by those skilled in the art that modifications can be made to the present invention without departing from the concepts set out in the description above. These modifications should be considered as falling within the scope of the present invention. Consequently, the particular embodiments described in detail above are only illustrative and exemplary and not limiting the scope of the present invention, to which the full extent of the attached claims and any and all equivalents thereof must be given.

Claims (15)

1. Conical post with mixed connection (900), characterized by the fact that it comprises a conical base module (100) and at least one conical module (200), in which: the thicknesses of the walls of each module of the conical post with connection mixed (900) decrease upwards; and the connection between the modules comprises a mixed connection, wherein the mixed connection comprises: telescopic joint (1000) and nuts (104, 204), wherein the nuts (104, 204) are used in conjunction with at least one of: screws, pin and rivet. 2. Conical post with mixed connection (900), according to claim 1, characterized by the fact that the conical base module (100) has thin walls, in which the faces of the conical base module (100) are formed by line segments, forming a conical polygonal profile that tapers from the base to the top, in which the base conical module (100) comprises: between one and three rows of through holes (101), in which each row of holes (101) comprise a quantity corresponding to the number of holes (101) and the number of faces of the polygonal profile of the conical base module (100); between two and six windows (102) equally distributed around the conical base module (100) and below the lower row of holes (101); between two and three angles (103) are distributed on the same height line and around the conical base module (100), with equal distances between them; a row of nuts (104) corresponding in internal diameter, positioning and quantity with the row of holes (101); and a flange (105), which has a circular shape and comprises reinforcement ribs that connect the flange (105) to the conical base module (100), where the number of ribs is proportional to the number of vertical line segments present in the module conical base (100). 3. Conical post with mixed connection (900), according to claim 1 or 2, characterized by the fact that it is metallic and in which the external diameter of the upper region of the conical base module (100) corresponds to the internal diameter from the lower region of another conical module fitted over it. 4. Conical post with mixed connection (900), according to any one of claims 1 to 3, characterized by the fact that the holes (101) are arranged in two rows of different heights, so as to maintain at least one pair of holes (101) on each face of the polygonal profile of the conical base module (100). 5. Conical post with mixed connection (900), according to any one of claims 1 to 4, characterized by the fact that the flange (105) has at least one anchor bolt on the inside of the conical base module (100). 6. Conical post with mixed connection (900), according to any one of claims 1 to 5, characterized by the fact that it has thin walls, in which the faces of the conical module (200) are formed by line segments, forming a conical polygonal profile that tapers from the base to the top, in which the conical module (200) comprises: between two and six rows of through holes (201), in which the rows of holes (201) are distributed in a mirrored between the two ends of the conical module (200) and comprises an amount corresponding to the number of holes (201) and the number of faces of the polygonal profile of the conical module (200); between two and four windows (202) equally distributed around the conical module (200) and below the lower row of the upper region of the holes (201); between four and six angles (203), which are distributed in the same height line with equal distances from each other in a mirrored manner between the two ends of the conical module (200); and a row of nuts (204) corresponding in internal diameter, positioning and quantity with the row of holes (201). 7. Conical post with mixed connection (900), according to any one of claims 1 to 6, characterized by the fact that the external diameter of the upper region of the conical module (200) corresponds to the internal diameter of the lower region of another conical module fitted thereon and the internal diameter of the lower region of the conical module (200) corresponds to the external diameter of the upper region of another conical module fitted beneath it. 8. Conical post with mixed connection (900), according to any one of claims 1 to 7, characterized by the fact that the holes (201) are arranged in four rows, with each pair of rows mirroring the other and have different heights, in order to maintain at least two pairs of holes (201) at each end of the face of the polygonal profile of the conical module (200). 9. Conical post with mixed connection (900), according to any one of claims 1 to 8, characterized by the fact that the conical post with mixed connection uses mixed connection between its modules. 10. Conical post with mixed connection (900), according to any one of claims 1 to 9, characterized by the fact that it is a thin-walled structure that is divided into two or more modules (100, 200, 300, 400, 500, 600, 700, 800). 11. Conical post with mixed connection (900), according to any one of claims 1 to 10, characterized by the fact that the weight of the top modules pushes the bottom modules downwards, so as to generate a friction force between the modules. 12. Conical post with mixed connection (900), according to any one of claims 1 to 11, characterized by the fact that in the telescopic joint (1000) the height of the sliding joint (h) is 0.1 to 1.9 the average diameter (d) of the module sliding joint, preferably once the average diameter (d) of the module sliding joint. 13. Conical post with mixed connection (900), according to any one of claims 1 to 12, characterized by the fact that the angle (a) (alpha) between the module wall (500) and the vertical line (550) is between 1° and 30°. 14. Conical post with mixed connection (900), according to any one of claims 1 to 13, characterized by the fact that the modules are screwed to the covered section, where the holes (101) are located for fixing the screws in two rows of holes (201), in which these screws are installed from the outside to the inside, with the nuts (104) already welded inside the wall of the conical post with mixed connection (900). 15. Method of installing the conical post with mixed connection (900), defined in any one of claims 1 to 14, characterized by the fact that it comprises the steps of: I. carrying out the installation of the base module (100) connected to the foundation by through a flange (105), connected by anchor bolts embedded in a concrete block inside the ground; II. slide the upper module over the top of the base module (100), joining the modules (100, 200, 300, 400, 500, 600, 700, 800); III. ensure correct positioning by manually activating a fixing device, which forces the upper module onto the lower module, placing it in the correct position; IV. fix the screws in at least two rows of holes (201), from the outside to the inside, in the fitting area between the modules where the necessary nuts (104) are already welded internally; and V. repeat the process when assembling each module (100, 200, 300, 400, 500, 600, 700, 800), according to the application needs.