CA2454400A1 - Guyed single-tube pylon for supporting communications antennae - Google Patents

Abstract

The invention relates to a pylon which is used to support guyed-type communications antennae, particularly for mobile telephony, and which consists of a central shaft (10) comprising several vertical sections Si which are embodied by horizontal elements (21) and at least two types of guys, namely: a first series of guys (16) which are distributed around the shaft and which are deployed between the top of said shaft, or close thereto, and the ground where they are anchored, thereby fulfilling the bracing function; at least one second series of guys (17, 18, 19) which are distributed around the shaft and which are deployed between at least two of the horizontal elements (20, 21), thereby creating supports Ai along the length of said shaft. Both types of guys are more or less vertical at least between the top of the shaft and the A1 horizontal element located closest to the ground, with possible breaks occurring in the slope. The structure of the inventive pylon, which is extremely narrow, has very little visual impact on the environment and occupies a very small ground surface area. Moreover, said pylon provides secure, easy access to the antennae. The invention also relates to a range of pylons of all heights making use of a tube that can be standardised.

Description

Guyed single-tube pylon for support telecommunications antennas.
Technical sector of the invention s The present invention relates to the technical sector of pylons for telecommunication antenna supports, and in particular for support telephone antennas, and similar applications.
Prior art 1 o We know in this field so-called freestanding pylons, of the type shown in Figure 1 attached, or guyed type, as shown in figure 2.
The purpose of these pylons is to allow positioning in height and in pointing the antennas of various telephone operators, in particular, 15 to allow optimal coverage of the territory.
It is naturally essential that (orientation of these antennas is extremely stable, the permissible tolerance being of the order of 1 °
depointing (the "depointing" being the angular spacing of the perpendicular to the antenna, relative to the pointing direction imposed), 2o or even less than 1 °, in particular in the case of beam parabolas radio (tolerance 20 minutes of maximum angle).
There are several types of such pylons, in particular with square section or triangular, with or without cross bars or metal spacers, etc ...
Those skilled in the art are fully aware of these pylons, and there is no point in having them 2s describe further. In general, the obligation of rigidity leads to of the ~~ 8i ~~~ ~~ ~~~ ~~~ '~

2 heavy structures, very unattractive, where stability is obtained either at by means of metallic structural elements such as braces, spacers, etc ... or many guy wires.
For these pylons, and in particular for the guyed pylons, we have of ca ~ ul matrices for many years, allowing to calculate very correctly the geometries, constraints, thicknesses or diameters of structural elements, cables, etc ... to obtain stability required.
On the other hand, we have seen that this operates at the expense of aesthetics, and that the 1 o heavy structures led to high cost prices. The costs of were also high (concrete bases, assembly time etc ...).). The footprint is more important.
These materials obviously go against trends in that have emerged over the last one to two decades.
~ s In addition, the current and foreseeable evolution of technologies in terms of will worsen the impact of pylons on the landscape of a on the other hand, and on budgets. Indeed, for the first mobile phone technologies it was necessary to provide a pylon about every 30 km; current technologies impose, on the same 2o naturally traced, pylons every 15 I ~ n approximately; the UMTS standard barrels will require pylons every 3 I ~ n approximately (these values are good obviously orders of magnitude).
We will therefore witness an increasing proliferation of pylons, and therefore an increasingly acute severity of the aforementioned problems.
25 Admittedly, the heights of pylons evolve in the opposite direction: we pass from 45 m for first technologies to around 30 - 35 m to date and about 20 m for UMTS. However, the overall impact will be more and more notable, despite a lower pylon height.

3 There is therefore an important and recognized need for the design of pylons less expensive in terms of material cost, installation, maintenance, and impact significantly less marked in the landscape.
We can immediately see that these objectives are contradictory: indeed, s reducing the visual impact, for example, imposes a priori more fines.
This can certainly meet the goal of cost reduction, the problem being however that (no solution is known to date to alleviate the structure enough to reduce enough (visual impact, while retaining the imperative requirement of rigidity and solidity of the pylon.
o Technical problem posed The technical problem posed is therefore, faced with reduction objectives significant manufacturing and installation / maintenance costs, and equally important reduction in visual impact, to design a new structure which achieves these objectives WITHOUT degrading the rigidity and ~ s mechanical characteristics of the pylon.
The problem just stated is compounded by the fact that no one knows no calculation matrices allowing to define pylons other than those in Figures 1 and 2. This is particularly true for pylons guyed, for which the only known matrices do not correspond 2o as with the types of figure 2.
Another problem is that it must remain possible to access easily and safely to the telecommunications antennas located at top of the pylon, to repair, change, repoint, and operations like. In the prior art, this problem was easily solved by employment 2s of simple scales. We also used platforms or decking allowing secure access. Collective security then aims to prohibit horizontal and vertical access. These secure accesses are expensive and have a great hold. They are moreover unsightly. The objective here is to generally a "light" structure, the skilled person will understand 3o easily that what was easy in a voluminous structure will not be not in an optimized structure.

4 Summary of the invention The present invention very surprisingly solves all of these problems, and achieves all the objectives set, thanks to a completely new structure based on the use of very vertical shrouds, and of two different types each fulfilling a different function.
Detailed description of the invention The invention therefore relates to a pylon for supporting antennas of telecommunications, in particular of mobile telephony, of the type "Guyed", characterized in that it comprises io - a central drum 10 comprising several vertical sections Si materialized by horizontal elements 21, and - at least two types of guy lines a first series of guy lines 16, distributed around said barrel, and deployed between the top or substantially the top of the bole and the ground, where they 1 s are anchored, fulfilling a guying function - at least a second series of guy lines 17, 18, 19, distributed around of said barrel, and deployed between at least two of said horizontal elements 20, 21, fulfilling a function of creating "supports" Ai along the bole.
The base of the barrel rests on a platform or plate 14 secured to the ground by 2o an anchor 15.
According to a preferred embodiment, the pylon is characterized in that - said guys of the two types (that is to say of the two series) are substantially vertical at least between the top of the barrel and the element horizontal A1 closest to the ground, - and in that the base of the barrel rests on a platform or plate 14 secured to the ground by an anchor 15.
By "substantially the top of the barrel" it will be understood that the first type guy line can be attached to its upper part on an area close to the s top of the barrel, in A5 or possibly A4. An example will be given to illustration title, not limitafrf, in attached Figure 3, with fixing higher in A5. It will also be understood that it is impossible to better define this characteristic, since the details of realization will depend in a certain measure of climatic conditions (winds, etc.), of the specifications ~ o loads, number and weight of antennas, desired height for ensure optimal coverage, etc., all factors that the skilled person can easily master by simple adaptation to the reading of the description which will follow and concrete examples which will be indicated.
The “guy line” function describes the classic function of guy lines.
~ s The "support creation" function concerns one of the original features major of the invention. A person skilled in the art knows that, on any pylon, one seeks to create "supports" which are carefully calculated points on the barrel and where Ion places metal elements, cross bars, spacers, and parts of the same order, or shroud attachment points in the case of 2o guyed pylons in Figure 2, so that we "immobilize"
the points in question, that is to say that we withdraw at these points the maximum of freedom of movement, in particular of oscillation. The result is a curve effort, well known to those skilled in the art, which undulates in the form of sinusoid from the top of the pylon to the ground, canceling out at the 25 supports.
According to the invention, it has been possible to achieve appropriate supports using shrouds, which makes it possible to lighten the structure considerably (reduction of the mass of material in the barrel, absence of spacers, cross bars, etc.) and also considerably reduce the visual impact. Indeed, 3o unlike the cross braces, the supporting shrouds “melt”
easily in the landscape.

By "substantially vertical" is meant the fact that almost all of the guys 16 and 17, 18, 19 have an alpha slope close to the vertical, or even vertical for some of them, i.e. an inclination of 0 °
(vertical) at 3, 5, 10, 15 ° approximately.
Only the very bottom part (i.e., for example order of size, about 1/5 to 1/4 of the height of the barrel starting from the ground, say in section S1) guy lines 16 “guy lines” will be tilted according to an alpha angle of the order of 30 - 45 °, i.e. close to the angles of shrouds of the prior art (Figure 2), approximately 45 °.
o We thus obtain footprints on the ground, or "guy lines", cf.
Figures 16 to 22, extremely weak, of the order of a few meters, which is quite surprising.
This “verticality” of the shrouds is made possible by the creation of support Ai by other guys, 18, 19, which can themselves be vertical or almost vertical, cf. Fig. 3, or 16 - 22. This results in a hold much lower on the ground, and a great reduction in visual impact. Indeed, the flared part of the shrouds, according to the invention, that is to say in section S1, is close to the ground and blends easily into the landscape, while 4/5 or approximately 3/4 of the height of the pylon according to the invention (sections S2 to S5 or 2o more) are very narrow and give an impression of lightness and semi transparency.
According to a particular embodiment, the arrangement of the stays 16 "of guy line "has at least one slope break at least one end 25 of an element 21.
FIG. 3 shows an embodiment comprising two breaks in slope of the stay cable 16, at the level of A4 and A2.
Note that this use of at least one, preferably two, such ruptures slope, which is an entirely preferred embodiment of the invention, because allowing an even greater "verticality" of the shrouds, and a n / a improvement in mechanical characteristics allowing a reduction additional diameter of the barrel (thus saving material and decrease in visual impact) could not be calculated by humans from job. As we have seen, software for calculating guyed towers does not have only been available for a few years, and only for Guyed pylons of the type of those in Figure 2. One of the merits of s the invention is therefore also to have however sought a solution in this path, which seemed totally impractical, and to have succeeded in define ~ .n certain rules which will be understood by those skilled in the art at the read the examples below.
Those skilled in the art will naturally understand that, without a cala ~ l or 1 o possibly empirical rules, it is impossible to construct a pylon, because it is impossible to solve the well-known technical problems of resistance of materials, therefore of sizing of parts and choice materials, tracüon of cables (a cable works only in traction and never in compression), compression forces on the barrel at ~ s level of its base, definition of appropriate "supports", etc.
According to a preferred, nonlimiting embodiment, the guys 16 have a function the guy lines are located furthest to the outside of the barrel, and the guy lines with the function of creating supports are fixed inward by compared to the barrel. See Fig. 3.
2o According to yet another particular embodiment, the shrouds with the function of guy lines are formed by single cables 16 from the top or substantially the top of the barrel, down to the ground, which slide in means sliding 25, e, 30, formed in said horizontal elements 21, 22, 26, separating said vertical sections.
2s According to a particular variant, the barrel 10 has a cross section cylindrical or oval or triangular or square. We prefer the cylindrical section.
According to yet another particular embodiment, the shrouds of the two types are distributed regularly around the barrel.
According to a particular embodiment, the pylon comprises at least three 3o series of shrouds of the two types, thus distributed.

According to yet another particular embodiment, the pylon has four such series.
According to a preferred embodiment, the pylon comprises at least three vertical sections S1 to S3, and up to eight such sections S1 to S8.
s According to yet another particular embodiment, it comprises at least four vertical sections S1 to S4.
According to a nonlimiting exemplary embodiment, it has five sections vertical S1 to S5.
Those skilled in the art will understand that the number of vertical sections Si is io depending on the height of the pylon and the conditions of the specifications, themselves depending on the location, the number and weight of antennas, etc ... and that there is no precise limit.
We can consider a pylon that has six, seven or eight sections vertical, or more, with suitable guy lines.
15 A person skilled in the art will know how to master this data and adapt it to reading of description and examples.
Other characteristics and advantages of the invention will be better understood from the reading of the description which will follow, and with reference to the attached drawing sure which FIG. 1 represents a pylon of the prior art, of the freestanding type, with crossbars 2, spacers 3, stiffening the outer tubes 1, a work platform for installers and repairers 4, fitted with a guardrail 5, and carrying various antennas 6, 7. The installer or the repairer accesses the platform by means of a ladder 8 of which only the 25 lower elements have been represented. Another embodiment of Freestanding pylon of the prior art, very widespread, is shown in the figure 13, with a central access ladder.

We also know how to perform, cfi. Figure 13, so-called monotube pylons which are formed of a massive barrel of large diameter on which runs an access ladder.
The prior art also includes square section pylons (EdF) which have evolved into pylons with three tubes arranged in a so-called triangle "Tubular triangular", even more visible in the landscape, but bidder less wind resistance, the monotube being the current evolution.
- Figure 2 shows an anterior wax pylon of the type "Guyed" (see also figure 13), a first guyed mode being shown on the right, with 11 guy lines each anchored ~ o (13) in the ground 9, and a second guy mode being shown on the left part with the guys 11 joining in a single anchor 14. We note the very steep slope of the shrouds (around 40 - 50 °) and the very big footprint. The barrel rests on a “ball joint” 14 resting on a base concrete 15.
This type of guy, and the types very close, are the only ones that knew how to calculate in the prior art. No attempt has been made to deviate from this solution, despite its obvious disadvantages, including its cost , its grip on the ground and its visual impact, and despite the knowledge established that these drawbacks were to worsen considerably, of the technical obligation to bring the pylons closer and closer, cf. this-above. We did not think possible to define other matrices of ca ~ ul ri to realize other shrouding technologies.
The merit of the invention is to have sought, and succeeded, in overcoming this prejudice.
- Figure 3 shows a particular and non-limiting embodiment of the invention.
In this figure, the pylon has - a barrel 10 comprising 5 vertical sections S1 to S5, delimited by horizontal structural elements 20, 21, the intersection of the elements horizontal 20, 21 with the barrel delimiting thereon four "supports" A1 to 3o A4;

- the barrel resting on a plate 14 anchored in a concrete base 15, - a first series of guy lines 16 with guy wire function, - a second series of guy lines 17, 18, 19 with the function of creating "Support"

5 - the first series of guy lines 16 being fixed substantially at the top of the barrel, in A5, and running up to an anchor on the ground 15, - the second series of guy lines 17, 18, 19, being fixed between the supports A4 and A3 (guy lines 17), A2 and A3 (guy lines 18) and A1 and A2 (guy lines 19).
According to a particular embodiment of the invention, the series of guy lines 1 o of guying includes a series of a single current cable from A5 to the ground and sliding at the end, or near the end, of the elements horizontal 21.
Those skilled in the art will have understood that by "series", it is meant here that the pylon comprises guy lines distributed around the barrel, which thus forms three, four, five, etc ... identical "series" of cables.
We could for example have three "series" of cables in a triangle equilateral around the barrel, and similar arrangements.
According to yet another particular embodiment, the creative shrouds support 18 and 19 are formed by a single current cable from A3 to A1 and mounted 2o sliding at the end, or in the vicinity of the end, of the element 21 at level of point A2.
In Figure 4 attached, there is shown in perspective the pylon of the Figure 3, further comprising a "hoop" 22 for supporting the antennas.
A "hoop" is an annular element fixed to the barrel 10 and intended to receive sure its surrounding telecommunication antennas.

FIG. 5 represents a particular embodiment of the invention, where of the hoops 22 are mounted around the barrel 10, and are fixed to this barrel by structural elements 26 grouped in pairs and leaving a interval e in which a stay cable can pass.
s It will be understood that, depending on the height positioning of the hoop, a guy cable will pass in the interval (upper hoop C) or not (lower hoop).
FIG. 6 represents a variant of hoop, where the hoop is fixed to the barrel by arms 28 comprising an elongated slot 30 allowing the passage of a 1 o guy cable.
The hoops should preferably be positioned in the upper part of the bole, as shown in figures 4 or 5, but the height depends only technical requirements of operators and technologies employed, the geographic location of the pylon, and other factors 15 obvious.
The antennas are represented by the reference 7. They can naturally be of different types, and be independently pointed from each other, for example from one hoop to another, as needed operators.
2o It is also possible to use supports in triangle, in square, and the like, at location spices.
According to a less preferred embodiment, the antennas can be fixed directly to the barrel.
FIG. 7 represents a preferred embodiment of the end 25 of a 25 element 21, comprising an end piece 30 itself comprising a orifice 31 for the passage of the stay cables.
Preferably, as shown without limitation in FIG. 7, the walls of the orifice 31 are formed by parts 32 in the form of a ring.

According to a particular embodiment, these parts are made of plastic.
According to yet another particular embodiment, represented in FIG. 7 and the Figure 8, the sliding rings are formed of two parts 32 of which s the geometry is adapted to correspond to the orifice 31, and comprising notches 33 allowing the installation of pins or the like for their maintenance in place.
According to yet another particular embodiment, the barrel and the hoops, supports, elements 21, arms 28, are made of steel or aluminum. Aluminum is 1 o preferred for its own well-known qualities.
It will be very interesting to use pylons whose shrouds have been prestressed with a cable pre-stretched to its final length.
This gives a clear improvement in the depointing value, which can be easily reduced, according to the invention, to 1 ° or less than 1 °, which is very 15 remarkable, given the lightness of the structure.
Generally, the cable diameters of the shrouds of shrouds will be greater than those of the diameters of the shrouds of creation of supports.
The examples below provide some baselines not 20 limiting but which will allow extrapolation by the skilled person.
Figure 9, which consists of Figures 9A, 9B, 9C, 9D, and 9E, represents a perspective view of a preferred embodiment of the invention (Figure 9A). According to this mode, the antennas are fixed directly to the barrel by arms 30, according to the possibility indicated above. These arms have 25 of the slots 30. It can be seen that the shroud 16 slides in the end 25.
Figure 9B shows the same pylon in top view.

According to a preferred embodiment, it is indeed very important to provide a space for the access of a repair technician or installer R from the ground to antennas. This possibility of access is fun problems that arose during the construction of the pylon according to the invention.
Indeed, we have seen that, in the prior art, the size of the pylons was as he easily authorized the arrangement of scales. This solution becomes ~ impossible with the pylons which were targeted by the invention, that is to say say fine structures.
According to a particular embodiment, the invention solves this problem by 1 o a pylon as shown in Figure 9, where three arms in "triangle "
allow sufficient space between two of the arms, A and B
for the passage of a technician R.
According to a particular variant, represented in FIG. 9C, the pylon has a vertical RG guide rail over its entire useful height, i.e.
say from the ground to a level of access to the antennas, and a PF platform whose geometry is adapted to correspond to the space between arms A and B, and comprising sliding means MC in the vertical rail.
According to yet another particular embodiment, this platform is removable and is installed only at each intervention of the technician, 2o who withdraws it and wins on his departure. This solves the problem of secure access to antennas, since it is impossible to access them without the platform. Today, this security is only obtained by complicated mechanical means.
In addition, the same platform can be used for several pylons, while current systems are of course fixed. The cost of security is therefore greatly reduced.
The platform can be motorized, or maneuvered by a crank, hoist or the like. It is preferably made of light alloy or aluminum, and in expanded or openwork metal. It naturally includes means of 3o anti-fall security for personnel.

FIGS. 9D and 9E represent nonlimiting modes of fixing the antennas. Figures 9B, 9D and 9E show that the invention can be adapted without problem to all types of antenna mounting and their different coupling modes.
FIG. 10 represents a non-limiting means making it possible to fix the barrels elements or arms 21. according to this mode, the arms 21 (or any other type of arms) are fixed on a circular plate 50, at (inside of which are arranged at least two semicircular plates 60 whose diameter outside corresponds to the inner diameter of the drum. We can thus insert these 1 o plates 60 in the interior of the barrel, between two sections Si and Si + 1.
Two or three such plates 60 may preferably be provided.
Those skilled in the art will naturally be able to size them.
Figure 11 shows the support point A5 and a non-limiting detail anchoring, where one uses tensioners integrated into the shrouds, this type of part being known but very advantageously used according to the invention.
FIG. 12 represents a perspective view of a nonlimiting example pylon according to the invention, with 4 different hoops and three "series" of “triangle” shrouds.
Figure 13, which consists of Figures 13A, 13B and 13C, shows 2o finally the current modes (prior art) of the most common embodiments a guyed pylon (figure 13 A, of a so-called “single tube” pylon, and of a pylon says "freestanding" with central ladder.
FIG. 14 represents a working platform C of the prior art, on a pylon with three tubes and cross bars. We have provided safety rails A, B, fixed to the tubes by padding brackets and bolts /
washers.
Figure 15, which consists of Figures 15A and 15B, shows two types of jointing for tubular pylons, by gussets (Fig 15A) or by platinum (Fig. 15B). If we compare these means to those of Figure 10, according to the invention, where the plates 60 are housed in the tube, the significant gain in terms of aesthetics in particular.
The invention will be better understood on reading the description which follows, and s non-limiting examples below.
These examples will enable those skilled in the art to reproduce the invention and to carry out extrapolations in terms of calculations, to carry out different pylons or variants, without departing from the scope of the invention.
EXAMPLES
1 o Figures 16 to 22, which each consist of Figures A (side view of the pylon) and B, C, D, E if applicable (top view of the hoops placed at each height level, as shown in each figure A), represent the range of pylons according to the invention calculated for heights of, respectively, 12, 15, 20, 25, 30, 35, 40 m.
15 The values shown in Figures 16 to 22 are either in meters or, when no unit is indicated, in mm.

Drum height 12 m Barrel diameter 300 mm wall thickness 8 mm 3 levels at 5 9 12 m 2 radius spokes 800 mm and 600 mm Guying radius 1500 mm Guying shrouds, diameter 12 mm Guy lines for the creation of supports, diameter 10 mm Height ft. 15 m Diameter ft 300 mm thickness 8 mm wall 3 levels 6 12 15 m 2 hoops 1200 mm and 800 mm Guying radius 2000 mm Guying shrouds diameter 14 mm 1 o Support stay cables 10 mm diameter Height ft 20 m Diameter ft 300 mm thickness 8 mm wall 3 levels 8 14 20 m 2 hoops 1200 mm and 800 mm Guying radius 2500 mm Guying shrouds diameter 18 mm Support shrouds diameter 12 mm Height ft 25 m Diameter ft 300 mm thickness 8 mm wall 3 levels 10 19 25 m 2 x 1600 mm and 1200 mm spokes Guying radius 3500 mm Guying shrouds diameter 18 mm 18 mm diameter support stay shrouds 1 o FIG 20 Height ft 30 m Diameter ft 300 mm thickness 8 mm wall 4 levels 8 16 24 30 m 3 spoke radius 2000 mm 1600 and 1200 mm Guying radius 4000 mm Guying shrouds diameter 22 mm Support stay cables 14 mm diameter Height ft 35 m Diameter ft 300 mm thickness 8 mm wall 4 levels 10 19 28 35 m 3 spoke radius 2400 mm 2000 and 1600 mm Guying radius 5000 mm Guying shrouds diameter 22 mm Support stay cables 14 mm diameter 1 o FIG 22 Height ft 40 m Diameter ft 300 mm wall thickness 8 mm 5 levels 12 20 28 34 40 m 4 spokes 2400, 2000, 1600 and 1200 mm Guying radius 6000 mm Guying shrouds diameter 25 mm Support shrouds diameter 18 mm It will be noted that, whatever the height of the barrel, it is possible to use the same aluminum barrel with a diameter of 300 mm and a wall thickness of 8 mm, this which was not obvious but simplified the supply so decisive.
s We find these characteristics, as well as others, such as the number cables, arms, etc. as well as the pretensioning characteristics, effort, and the depointing results, for each barrel height, in the TABLE below.
We can naturally use other materials than aluminum for the 1 o barrel or cables, in particular steel, composite materials, and the like, and the skilled person will be able to carry out the necessary transpositions from the mechanical characteristics of the material considered and of this description, in particular figs 16 to 22 and the TABLE.
The invention also covers all the embodiments and all the 15 applications that will be directly accessible to those skilled in the art at the reading of this application, of his own knowledge, and possibly simple routine tests.

N c ~ 0N ~ (E0 ~ E
- ~ w ~ ~ '' v ~ (DN m N ~ .__ ' tp N 0 p D ~ r ~ f ~ jr ~ ~ ~. ~ ~ N
~ N ~ ~ -r - 'ab ~ 0 0 0 at VE'_N ~ EEE
d O ~ co a ~ M ~ r 7 ~ CDO M. ~ -N '"= ~ n ~ C <) r ~~ CO ON
0 0 crid- D
N r ~ p AD
~ '~ b E ~ EEE
N (pN tnC'7, -~ 4 vr M ~ ~ ~ ~ p 0 DDD pv VN ~
.n1O ~ M r M r ~ OON
i M _ N
OO ~
bb '~ GO

EEEE

tDN tn (D

m ~?
~, ~ O ~ .. '~' .. ~ p ~ N f ~ N oor n N o, - 'cocn N, - N ~ o, ~
(ii M ~ p o0N o Y r "'aa c ~ o "t r ..-.

O_ EE m CVCO r N _ x ~ ~ O h 7 D v ~ T _ 0 C D_O <~
p '~~ iC ~ NO 07CT7O ~ "-f t0N
. No.

E ~ EE

N m N ca X r O ~ pm T r OO
~ laughed ~ co bma D? ~ m Y pm C ~ d O
not it z.
.

~ ~ E ~
r (DO r O
7 Or ~ r ~ O n ~ 7 ~ t 7 'p'p' - O c ~ N
No.
o ~
mx E
NNN r N ~ m 7 'n - rt T7 ~ i' mm <7 ~ m , C ~ ~ j , CC
uJ S

~

~ ~ ~ Uf r MM _ W _d ~ ~ f0 W m ~ ~
L7 ~
W ~ UV
~ ~ O
NOT
Q7 U ~ yv E 1.
o ~
v ~
~

_ - not .
.

Q o M ~. N ~ t CDI c ~ D_cx0_ ~ t colp C ~ J
47 r ~ NN ~ _ r a> O r r ~ XN a ~ XN ~ r ~ ~

N r ~ r C NI r u7 p the I
r 'N tt7o CD r ~ ~ tti (D r N
N l7 O
N 1 ~ N ~ ~ V ~ ~ N r ~ 'c = r ~ criN r1 M y_ .. ~ O rI M r T
' Y r !not O ~ O
nv O CrJO ~ ~ ~ c ~ D ~ IN OD C ~~ ~ IC ~ O
t ~ o ~ c ~ MT r ~ N, -, - W mo o N r lT ~ N r'I lYJr O r1 r - w - cb vr T

tn. o 1n o li ~ NM cfl ~ N cD ~ Q ~>: D
h ~ -p ~ ca, ~ 'p m ~ N ~ r 'i (r V f ~ XO ~ N
~ N =
r I r 'o1 CD CO

r II
p 'd' (Dh (flCD ~ r ~ O rr O CDO
n O lnlD N w W CD CDy GOT
N ~ pN r O ~ X rp r CD ~~ ~ r (~
cy.
OI r Ol (pr (D

rr to I ~ _0I
lii ~ d ~~ N ~ O c ~ 1 ~ cN ~ ~ ca NNM ~ ~ '~ 7 00CO
mvc ~~ p cn, _ ~.-u X o x TI

T r I

p O 11'l OIO ~ C
0 M ao ~ X ~ c7yn ~ p X .- IwN
M h NM 'O ~ f ~ d ~~ O ~ f9, NN f? ~ ~ d O ~ ~ D 0 ~ C
M ii I ~

MD c. ') C

TT

H

I
C ~ INL ~ LNL ~ ~ OCO
mc UQ c ~ ~ ~

C o ~ C

The ZZ ~ p ~ td ~ m _ nv ~ E ~ am U m H ~ C m C .fl O
p _G ~, p ~ o '-' OOT
~ ~ ~ m .L? ~ ~ ~ C
CZ ~ O
N ~ U
U ~
one ~

Claims (4)

22 1 “Guyed” single-tube type pylon, for antenna support telecommunications, in particular mobile telephony, or satellite dishes of Hertzian beams, characterized in that it comprises - a central shaft 10 comprising several vertical sections Si materialized by horizontal elements 21, and - at least two types of stays:
- a first series of stays 16, distributed around said shaft, and deployed between the top or substantially the top of the barrel and the ground, where they are anchored, performing a guying function - at least a second series of stays 17, 18, 19, distributed around of said barrel, and deployed between at least two of said horizontal elements 20, 21, fulfilling a function of creating "supports" Ai along the barrel - And in that the base of the barrel rests on a platform or plate 14 secured to the ground by an anchor 15.
2 pylon according to claim 1 characterized in that - the said stays of the two types (i.e. of the two series) are substantially vertical at least between the top of the shaft and the element horizontal A1 closest to the ground.
3 Pylon according to claim 1 or 2 characterized in that almost all of the stays 16 and 17, 18, 19 has an alpha slope close to the vertical or vertical, i.e. an inclination of 0° (vertical) at 3, 5, 10, 15° approx.
4 Pylon according to claim 3 characterized in that only the part quite lower, about 1/5 to 1/4 of the height of the shaft starting from the floor, section S1 of the 16 "stays" will be inclined at an angle alpha in the range of 30 - 45°.
5 Pylon according to claim 3 or 4 characterized in that it comprises “supports” Ai created by the internal stays, 18, 19.
6 Pylon according to any one of claims 1 to 5 characterized in what the layout of the guy wires 16 "staying" has at least a break in slope at the level of at least one end 25 of an element 21.
7 Pylon according to claim 6 characterized in that it comprises two breaks in the slope of stay 16, at the level of A4 and A2.
8 Pylon according to any one of claims 1 to 7 characterized in that the guy wires 16 with guying function are located furthest the outside with respect to the barrel, and the stays with the function of creating supports are attached furthest inward to the barrel.
9 Pylon according to any one of claims 1 to 8 characterized in that guy wires with guying function are formed by cables unique 16 from the top or substantially the top of the shaft, to the ground, which slide in sliding means 25, e, 30, provided in said horizontal elements 21, 22, 26, separating said sections vertical If.
10 Pylon according to any one of claims 1 to 9 characterized in that the shaft 10 is of cylindrical or oval or triangular cross section or square, preferably cylindrical.
11 Pylon according to any one of claims 1 to 10 characterized in that the stays of both types are evenly distributed around the was.
12 Pylon according to claim 11 characterized in that it comprises at at least three sets of guys of both types, distributed in this way.

13 Pylon according to claim 12 characterized in that it comprises four such series.

14 Pylon according to any one of claims 1 to 13 characterized in that it comprises at least three vertical sections S1 to S3, and up to eight such sections S1 to S8.
15 Pylon according to claim 14 characterized in that it comprises at least four vertical sections S1 to S4.
16 Pylon according to claim 15 characterized in that it comprises five vertical sections S1 to S5.
17 Pylon according to any one of claims 1 to 16 characterized in that it includes - a barrel 10 comprising 5 vertical sections S1 to S5, delimited by horizontal structural elements 20, 21, the intersection of elements horizontals 20, 21 with the shaft delimiting thereon four "supports" A1 to A4;
- the barrel resting on a plate 14 anchored in a concrete base 15, - a first series of guy wires 16 with guying function, - a second series of stays 17, 18, 19 with the function of creating supports »
the first series of stays 16 being fixed substantially at the top of the barrel, in A5, and running up to a ground anchor 15, - the second series of stays 17, 18, 19, being fixed between the supports A4 and A3 (17 guy wires), A2 and A3 (18 guy wires) and A1 and A2 (19 guy wires).
18 Pylon according to claim 17 characterized in that the series of guy wires 16 comprises a series of a single cable running from A5 on the ground and sliding at the end, or near the end, of the horizontal elements 21.
19 Pylon according to claim 17 or 18 characterized in that the stays for creating support 18 and 19 are formed by a single running cable from A3 to A1 and mounted sliding at the end, or near the end, of element 21 at point A2.
20 Pylon according to claim 17 characterized in that it comprises plus at least one "circle" 22 or annular element fixed to the shaft 10 and intended to receive on its periphery the telecommunications antennas or satellite dishes.
21 Pylon according to claim 20 characterized in that the hoops 22 are mounted around the barrel 10, and are fixed to this barrel by elements of structure 26 grouped by two and leaving between them an interval e through which a guy wire can pass.
22 Pylon according to claim 20 characterized in that the hoops are fixed to the barrel by arms 28 having an elongated slot 30 allowing the passage of a guy cable.
23 Pylon according to claim 17 characterized in that it comprises supports in triangle, in square, as supports of antennas of telecommunications or satellite dishes.
24 Pylon according to claim 17 characterized in that the antennas can be attached directly to the barrel.
25 Pylon according to claim 17 characterized in that the end 25 of an element 21, comprises an end piece 30 itself comprising an orifice 31 for the passage of the guy cables.
26 Pylon according to claim 25 characterized in that the walls of the orifice 31 are formed by parts 32 in the form of a ring.

27 Pylon according to claim 26 characterized in that the rings of sliding are formed of two parts 32 whose geometry is adapted to correspond to the orifice 31, and comprising notches 33 allowing the fitting of pins or the like to hold them in place.

28 Pylon according to any one of claims 1 to 27 characterized in that the shaft and the hoops, supports, elements 21, arms 28, are made of steel or aluminum.

29 Pylon according to any one of claims 1 to 28 characterized in that the stays will have been prestressed, with a pre-stretched cable at its final length.

30 Pylon according to any one of claims 1 to 29 characterized in that it has three arms in a "triangle" make it possible to spare, between two of the arms, A and B, sufficient space for the passage of a technician R.

31 Pylon according to claim 30 characterized in that it comprises a guide rail RG vertical over the entire useful height of the barrel, that is to say the floor up to a level of access to the antennas, and a PF platform whose geometry is adapted to match the space between arms A and B, and comprising sliding means MC in the vertical rail.

32 Pylon according to claim 31 characterized in that this platform is removable and is put in place only at each intervention of the technician, who removes it and takes it away when he leaves, the platform being motorized, or operated by a crank, hoist, and is made of alloy lightweight or aluminum, and in expanded or perforated metal, and comprises means fall protection for personnel.

33 Pylon according to any one of claims 1 to 32 characterized in that the arms 21 are fixed on a circular plate 50, inside of which are arranged at least two semi-circular plates 60 whose outer diameter corresponds to the inner diameter of the barrel, these plates being adapted to fit inside the barrel, between two sections Si and If+1.

34 Pylon according to claim 33 characterized in that said plate has three such plates 60.

35 Pylon according to any one of claims 1 to 34, characterized in that its characteristics are chosen from the following:
-----------Height was 12 m Barrel diameter 300 mm wall thickness 8 mm 3 levels at 5 9 12 m 2 radii hoops 800 mm and 600 mm Guy radius 1500 mm 12 mm diameter guy wires Stays for creating supports, diameter 10 mm -----------Height was 15 m Barrel diameter 300 mm wall thickness 8 mm 3 levels at 6 12 15 m 2 radii hoops 1200 mm and 800 mm Guy radius 2000 mm 14 mm diameter guy wires Stays for creating supports, diameter 10 mm Height was 20 m Barrel diameter 300mm wall thickness 8mm 3 levels at 8 14 20 m 2 radii hoops 1200 mm and 800 mm Guy radius 2500 mm 18 mm diameter guy wires Stays for creating supports, diameter 12 mm Height was 25 m Barrel diameter 300 mm wall thickness 8 mm 3 levels at 10 19 25 m 2 radii hoops 1600 mm and 1200 mm Guy radius 3500 mm 18 mm diameter guy wires Stays for creating supports, diameter 18 mm Height was 30 m Barrel diameter 300 mm wall thickness 8 mm 4 levels 8 16 24 30m 3 radii hoops 2000 mm 1600 and 1200 mm Guy radius 4000 mm 22 mm diameter guy wires Stays for creating supports, diameter 14 mm ---------Height was 35 m Barrel diameter 300 mm wall thickness 8 mm 4 levels 10 19 28 35m 3 radii hoops 2400 mm 2000 and 1600 mm Guy radius 5000 mm 22 mm diameter guy wires Stays for creating supports, diameter 14 mm Height was 40 m Barrel diameter 300 mm wall thickness 8 mm 5 levels at 12 20 28 34 40 m 4 radius hoops 2400, 2000, 1600 and 1200 mm Guy radius 6000 mm 25 mm diameter guy wires Stays for creating supports, diameter 18 mm