EP0009451A1 - Telescopic mast - Google Patents

Abstract

It includes elements (21, 22-212) slidingly arranged one inside the other, and at least two hoisting cables (25, 26, 27) mounted so that the result of the pulls they exert, for erection , or vertical. Preferably, each cable is, before erection, attached to all the elements to be hoisted and the erection is carried out by successive sliding of each element in the element which is immediately below it, means being provided for detaching the cables of each element after the end of the hoisting of said element.

Description

The invention relates to a mast, pole or other construction, or support, intended to be erected vertically.

Masts or tall posts are difficult to transport and their installation is generally a long and difficult operation which requires the intervention of several workers.

This is why telescopic masts have been proposed comprising elements mounted to slide one inside the other in order to facilitate their transport, the sliding of an element in the lower element being effected by means of a cable. hoisting.

But in most known masts of this kind, the lifting effort of each element is not strictly vertical, which can cause a jamming which opposes the erection of the mast. A solution to this problem has however already been proposed; but this solution is complicated to implement, requiring a large number of pulleys assigned to each element. In addition, in known telescopic masts, the attachment of the hoisting cable to the elements to allow the elements to slide one after the other is also complicated. Finally, the means which hold the elements integral with one another when the mast is erected are, in known telescopic masts, of relatively expensive construction.

The invention overcomes these drawbacks.

The telescopic mast according to the invention is characterized in that it comprises several hoisting cables actuated by the same winch and distributed in such a way that the result of the hoisting forces which they exert is vertical.

The erection of the mast can thus be carried out without incident, without risk of jamming.

For the hoisting to have the maximum efficiency and so that the cables are not stressed too much, it is preferable that the strand of each cable directly attached to the element being hoisted is, from start to finish hoisting, vertical direction or near vertical. For this purpose, each cable passes over a pulley located above the elements in the collapsed or contracted condition of the mast, this pulley being mounted movable to move towards the element to be hoisted under the effect of the hoisted weight applying to the pulley via the cable.

In the preferred embodiment of the invention, each cable being, before erection, attached to all the elements and the erection of the mast being effected by successive sliding of each element in the element immediately below, the mast comprises means for detaching the cables from the elements one after the other after the end of the sliding of each element. The cable attachments to the elements can thus be particularly simple, without a pulley, since it obviates the need to keep the cables attached to the elements in the erected mast.

In one embodiment, the hoisting cables also constitute supporting shrouds and, during the erection of the mast, a winch device winds up a hoisting cable and at the same time unwinds this same cable in its stay forming part. It is then advantageous for the winch device to include a cable accumulator making it possible to keep the shrouds taut despite the difference between the length of each cable which is wound to hoist an element and the length of each cable that must be unrolled to obtain the necessary increase in the length of the shroud during hoisting.

The elements of the telescopic mast are advantageously made of plastic, preferably of reinforced plastic, and to retain the mast in erect condition, these elements, with the exception of the basic element, include an elastic tab at their lower part. attached to a wall of the element and obtained by molding with the latter, this tab moving away from the wall when the element is released from the lower element so as to be able to rest on a platform that this lower element in its upper part.

Such means which prevent unwanted contraction of the mast are particularly simple to make and use.

• la figure 1 montre un mât érigé;
• la figure 2 est une vue de dessus du mât affaissé;
• la figure 3 est une vue analogue à celle de la figure 1 mais le mât étant au début de son érection;
• la figure 4 est une vue de côté du corps de mât dans sa condition contractée;
• la figure 5 est une vue en perspective selon la flèche F de la figure 4;
• la figure 5a montre le sommet d'un bras vertical;
• la figure 5b est un schéma montrant un mât et des éléments du corps de mât;
• la figure 6 est une coupe montrant, à plus grande échelle, un détail du mât représenté sur la figure 5;
• la figure 7 est une vue de dessus de la figure 4;
• la figure 8 représente un élément de corps de mât;
• la figure 9 est une vue de dessus de l'élément représenté sur la figure 8;
• la figure 10 est, à plus grande échelle, une coupe selon la ligne 10-10 de la figure 8;
• la figure 11 est, à plus grande échelle, une coupe selon la ligne 11-11 de la figure 8;
• la figure 12 est, à plus grande échelle, une coupe selon la ligne 12-12 de la figure 8;
• la figure 13 est une vue partielle en coupe verticale de la base du mât;
• la figure 13a est une coupe selon la ligne 13a-13a de la figure 13;
• la figure 14 est une vue en coupe verticale montrant de façon schématique le mât en cours d'érection;
• la figure 14a représente une partie d'un élément de corps de mât;
• la figure 14b montre le fond de l'élément de base du corps de mât;
• la figure 14c montre une extrémité de patte élastique d'un élément de corps de mât;
• la figure 15 est une vue schématique d'ensemble, en coupe verticale, d'un mât en condition contractée;
• la figure 16 montre un dispositif de treuil;
• la figure 17 montre une partie d'élément de corps de mât pour une variante.

The embodiments of the invention are described below in conjunction with the drawings in which:

• Figure 1 shows an erected mast;
• Figure 2 is a top view of the collapsed mast;
• Figure 3 is a view similar to that of Figure 1 but the mast being at the beginning of its erection;
• Figure 4 is a side view of the mast body in its contracted condition;
• Figure 5 is a perspective view along arrow F of Figure 4;
• Figure 5a shows the top of a vertical arm;
• Figure 5b is a diagram showing a mast and elements of the mast body;
• Figure 6 is a section showing, on a larger scale, a detail of the mast shown in Figure 5;
• Figure 7 is a top view of Figure 4;
• Figure 8 shows a mast body member;
• Figure 9 is a top view of the element shown in Figure 8;
• Figure 10 is, on a larger scale, a section along line 10-10 of Figure 8;
• Figure 11 is, on a larger scale, a section along line 11-11 of Figure 8;
• Figure 12 is, on a larger scale, a section along line 12-12 of Figure 8;
• Figure 13 is a partial view in vertical section of the base of the mast;
• Figure 13a is a section along line 13a-13a of Figure 13;
• Figure 14 is a vertical sectional view schematically showing the mast being erected;
• Figure 14a shows part of a mast body member;
• Figure 14b shows the bottom of the base member of the mast body;
• Figure 14c shows an elastic tab end of a mast body member;
• Figure 15 is a schematic overview, in vertical section, of a mast in contracted condition;
• Figure 16 shows a winch device;
• Figure 17 shows a part of mast body element for a variant.

The telescopic mast comprises (FIGS. 1 to 3) a mast body consisting of twelve elements 2 ₁ to 2 ₁₂ mounted to slide one inside the other; the elements 2 ₂ to 2 ₁₂ are all of the same height while the basic element 2 ₁ has a slightly greater height. Each element has, in horizontal section, the shape of an equilateral triangle. The crown element 2 ₁₂ is intended to support, for example a platform 3 for an antenna (not shown).

The lower element 2 ₁ comprises a base plate 4, also in the form of an equilateral triangle, which is connected by means of three jacks, such as the jack 6, in the vicinity of its vertices, to another plate 5 likewise shape and same dimensions forming a base.

The jacks allow the base 4 to be moved away from the base 5 in order to keep the mast vertical even if the base rests, as shown in FIG. 1, on an inclined ground 8.

At the vertical edges 9, 10 and 11 of the element lower 2 ₁ are articulated, near the base plate 4, tubular booms respectively 9 ₁ , 10 ₁ and 11 ₁ (FIG. 1), the ends 12, 13, 14 of which are distant from the mast are practically at the level of the part top of element 2 ₁ . Short bracing bars 9 ₂ , 10 ₂ , 11 ₂ are arranged between the booms and the upper parts of the corresponding edges 9, 10, 11 (FIG. 2) and make it possible to keep the booms in a fixed position relative to the element of base 2 ₁ .

The respective ends 12, 13 and 14 of the booms 9 ₁ , 10 ₁ and 11 ₁ , define an equilateral triangle (Figure 2) and between these ends are stretched cables ₁ 5, 16 and 17. Other cables 15,, 16 ₁ and 17 ₁ are stretched between the media 9 ₃ , 10 ₃ , 11 ₃ of the booms. These cables 15 ₁ , 16 ₁ and 17 ₁ contribute, like the braces 9 ₂ , 10 ₂ , 11 ₂ , to keep the booms in position and to constitute a non-deformable assembly.

At the ends 12, 13, 14 are fixed other cables ensuring the fixing of the mast to the ground. Thus, between the end 12 of the boom 9 ₁ and a stake 18 planted in the ground is stretched a cable 19 lying in the same vertical plane as the boom 9 ₁ . A short cable 20 is stretched between the end 14 of the boom 11 ₁ and another stake 21 in the ground. Finally, another short cable is stretched between the end 13 of the boom 10 ₁ and a corresponding stake in the ground.

The ends 12, 13, 14 of the booms also carry pulleys respectively 22, 23 and 24 over which cables 25, 26 and 27 pass (Figures 1, 15 and 16) whose movement in one direction or another is controlled by a winch mechanism 28 with cable accumulator 29. It is these cables which, at the same time, constitute the guying and are used for the hissaae. Each cable 25, 26, 27, in its guying part, passes over a pulley respectively 30, 31, 32 whose axis is integral with a fork 30,, etc. (Figures 1 and 15) to which is fixed the end of a cable 30 ₂ , ... also forming part of the guying, the other end of which is fixed to the upper part of the element 2 ₁₂ (Figure 1) .

Each cable 25, 26, 27 also passes inside the corresponding tubular boom from which it is returned to the winch mechanism 28 then, from this mechanism, inside the elements 2 in order to control the erection of the mast.

During erection, the tensions exerted on the shrouds 30 ₂ , 31 ₂ , 32 ₂ attached to the element 2 ₁₂ all have the same value and due to the regular arrangement of these shrouds at 120 ° one others around the vertical axis 1 ₁ of the mast, the component of these three tensions is vertical, which contributes to the stability of the mast.

Three tubular stakes 33, 34, 35 partially housing the jacks protrude relative to the underside 5a of the base 5 to keep this base 5 fixed to the ground.

Each cylinder, such as the cylinder 6 associated with the tubular stake 34, comprises (FIGS. 5, 13 and 13a) a threaded rod 40 passing through the base 5 through an opening 41 and which is extended by a smooth rod 44 passing through a part 45 mounted in a hole 42 in the plate 4 and ending in a head 43 with a hexagonal or square section above the plate 4.

The part 45 is composed of two parts 45 ₁ and 45 ₂ arranged on either side of the plate 4 and which are symmetrical with respect to the mean plane of this plate. The part 45 has a cylindrical tubular lower part 46 ₁ and a part 47 ₁ in the form of a spherical cap whose center is on the axis of the hole 42 and of radius greater than that of this hole. The opening 48 ₁ presented by this part 45 ₁ has a frustoconical shape that widens outwards.

The spherical bearing surface of the part 47 ₁ of the part 45 ₁ cooperates with another concave spherical bearing surface 49 ₁ which has the underside of a ring 50 ₁ secured to the rod 44. Similarly, a ring 50 ₂ secured to the rod 44 cooperates with the spherical bearing of the part 45 ₂ below the plate 4.

The thread of the rod 40 cooperates with the tarau dage of a nut 52 of rectangular or square external shape (FIG. 13a) housed in the opening 41 and having protruding on two of its external faces 52a and 52b lugs 52 ₁ and 52 ₂ with the same horizontal axis 52 ₃ and swiveling in bearings 52 ₄ and 52 ₅ presented by the base 5.

A bellows 53 surrounds the jack 6 in the space 7 separating the base 5 from the plate 4.

The axis common to the rods 40 and 44 is offset inwardly relative to the axis 34a of the tubular pile 34, because these rods can not deviate from the vertical, by pivoting around the axis 52 ₃ , that on one side only, that in which the arrow f ₂ is located in FIG. 13.

The flared openings 48 ₁ and 48 ₂ are provided to allow pivoting, around the axis 52 ₃ , of the rod 44 relative to the plate 4. During this pivoting, the spherical surfaces of the parts 451 and 45 ₂ slide on the concave spherical bearings of the rings 50 _. and 50 ₂ .

It is thus possible, by acting on the heads 43, to confer the horizontal position on the plate although the base 5 is arranged on a sloping ground.

Each of the elements 2 ₂ to 2 ₁₁ has, in cross section, the shape of an equilateral triangle (Figure 9) whose vertices are truncated, forming short sides which are parallel to the sides of the triangle opposite to said truncated vertices. Thus, each element has three large vertical lattice walls 55, 56, 57 separated by narrow vertical walls 58, 59 and 60 parallel to the opposite wide wall.

The upper edge 61 (FIG. 14) of each wide wall is extended towards the inside by a short horizontal rim 62 on which a return wall 63 of low height relative to that of the element depends downwards.

The lower edge 64 of each wide wall is extended towards the outside by a horizontal rim 65 on which depends upwards a return 66 of length equal to that of the upper return 63.

The returns 63 and 66 are oblique to the corresponding walls so that their free edge 63 ', 66' is further from the wide wall than their attachment to the corresponding flange 62, 65.

Each narrow wall has, according to its height, a central part 70 (FIG. 14) of constant thickness with an internal face 71 and an external face 72 and, above this central part, a part 73 of quasi-triangular section with an internal face 74 extending the face 71 of the central part 70, an external face 75 moving away from bottom to top of the extension of the face 72 and an upper face 76 forming a platform. The part 73 is extended by an upper end part 77 of the same thickness as the central part 70 but offset towards the outside with respect to the latter.

Each narrow wall has, below the central part 70, a part 78 of increasing thickness downwards with an internal face 79 extending the face 71 and an external face 80 moving away from the face 79 downwards. part 78 of the wall is extended downwards by another part 81 which is thicker than the central part and whose internal face is an extension of the faces 71 and 79 and which furthermore has at its lower end an external notch 85 limited by a ceiling horizontal 83 and a vertical face 84. The notch 85 is intended to accommodate an olive 86 secured to the cable 25, the number of cables being equal to the number of narrow walls.

The thinned lower part 82a of each narrow wall 58, 59, 60 has a central slot 86a (fig. 14a) with vertical edges 87 and 88 and oblique ceiling 89 connecting to the ceiling 83 of the notch 85. The obliqueness is direction such that the ceiling 89 opens, along an edge 90, in the face 79 above the ceiling 83.

The width of the slot 86a is sufficient to allow passage to the cable 25, but insufficient to allow passage to the olive 86.

To each of the narrow walls 58, 59, 60 is attached, in its lower part, an elastic tab 91, the elasticity tending to move this tab away from the corresponding wall. Said tab has an oblique part attachment 92 and a thicker lower part 93, its thickness being equal to the width of the platform 76; the lower edge 94 of this tab is practically level with the lower edge 95 of the narrow wall and it is intended to rest on the platform 76 of the element in which it is directly housed after sliding upwards, for the erection of the mast, of said element. The tab 91 forms a single piece with the body of the corresponding element, being obtained by molding with this body.

The lower edge 94 of the elastic tab 91 is extended inwards by a horizontal flange 125 having a transverse slot 126 (FIG. 14c) whose width is, like that of the slot 86a, sufficient to allow passage for the corresponding cable 25 , but insufficient to allow passage to an olive 86.

The wide walls 55, 56, 57 are hollowed out (FIG. 8) having vertical uprights 100 and 101 connected by braces 102, 103, 104 and 105.

The elements 2 are made of reinforced plastic. In the example, the crosspieces have a core 106 (fig. 11) of expanded foam enclosed in a sheath l07 of fiberglass and embedded in the plastic 108 and, on each side of the heart, there are cords l09 of fiber of carbon. The uprights 100, 101 are also reinforced with carbon fibers 110 (Figure 12).

The lower part of the element 2 ₁₂ is similar to the lower part of the elements 2 ₂ to 2 ₁₁ , its upper part however not comprising a platform 76 but the antenna support 3 (FIG. 1).

The upper part of element 2 ₁ is similar to that of other elements 2 ₂ to 2 ₁₁ . On the other hand, its lower part is of different constitution, presenting neither return nor elastic tab. This element 2 ₁ is of height greater than the common height of the other elements, having in its lower part a cavity 115 (FIG. 15) formed between its bottom wall formed by the base plate 4 and the upper edges 116a, 117a, 118a vertical ribs 116, 117, 118 erected on the plate 4 perpendicular the large faces of the element 2 ₁ in their middle (Figure 14b). The lower edges of the walls 56 to 60 and of the elastic tabs 91 of the other elements rest when the mast is collapsed on said upper edges 116a, 117a, 118a. The strands of the cables, of length at least equal to the height of each element 2 ₂ to 2 ₁₂ , are housed, in the relaxed state, in the cavity 115 (FIGS. 14 and 15) between the ribs.

The central part of the base 5 has bearings (not shown) on which are pivotally mounted around horizontal axes 133 ₁ , 134 ₁ and 135 ₁ (FIG. 14b) of the vertical tubular arms of rectangular section, respectively 133, 134 and 135 , each of said axes 133 ₁ , 134 ₁ , 135 ₁ being parallel to one side of the element 2 ₁ . Thus these vertical arms radiate at 120 ° from each other around the vertical central axis 11 of the mast body. The vertices 132 (FIG. 4) of these arms are above the upper edges of the elements when the mast is in contracted condition (FIG. 15) and their upper edges 1,332, 134 ₂ , 135 ₂ (FIG. 5) are oblique. The small vertical face of these arms which is connected to the lower edge 134a of the oblique edge has a window 134 ₃ (FIG. 5a) allowing passage for the cable 25 coming out of a pulley 137 with a horizontal axis 138 also being located at- above the upper edges of the elements when the mast is in contracted condition, a strand 139 on one side of this pulley going to the olive 86 at the base of element 2 ₁₂ in the contracted condition of the mast and a strand 140 ( Figure 15) on the other side entering the cavity 115. In this cavity, the cable 25 is returned by means of another pulley 141 of horizontal axis disposed at the base of the arm 134 to a horizontal strand 142 which passes over a pulley 143 also with a horizontal axis, part of which is inside the cavity 115 and the other part of which is outside, this pulley passing through an opening 144 (FIG. 16) formed in the wall 56 ₁ of element 2 ₁ on which is disposed the winch mechanism 28 with cable accumulator 29.

Such a pulley return system is provided for each of the cables 25, 26, 27. The other two pulleys which correspond to the pulley 143 for the other two cables 26, 27 are also mounted on a horizontal shaft and pass through the wall 56 ₁ through the opening 144.

After passing through the mechanism 28, the cable again enters the interior of the cavity 115 by passing over another pulley 145 having a part inside the cavity 115 and a part outside the latter and thus crossing the wall 56, through an opening 146 of position symmetrical to that of the opening 144 with respect to the median vertical axis of the wall 56 ₁ .The two other pulleys corresponding to the pulley 145 for the other two cables 26, 27 are mounted on a horizontal shaft and also pass through the wall 56 ₁ through the opening 146. The cable 25 again crosses the cavity along a horizontal strand 147 (FIG. 15) close to the bottom wall 4 while being guided by a pulley 148 of vertical axis integral with said bottom wall 4. The cable 25 then leaves the cavity 115 through an opening 150 of the narrow wall 60 ₁ of the element 2 ₁ where it is guided by a pulley 151 of horizontal axis .

The cable 25 then passes inside the tubular boom 9 ₁ whose lower end 150a, the closest to the axis 1 ₁ , surrounds the opening 150 and which has at its other end 12 the pulley 22 of horizontal axis, part of which is inside the boom and the other outside. Leaving the boom, the cable 25 has a strand 152 directed upwards then passes over the pulley 30 secured to the fork 30 ₁ and is hooked by its end 155 to the external surface of the boom 9 ₁ .

In the winch mechanism 28 (FIG. 16), the cable 25 guided by the pulley 143 first passes over approximately three-quarters of a turn of a pulley 160 of horizontal axis present at the upper part of the external face of the wall. 56 ₁ of element 2 ₁ . The cable then approaches another pulley 161 also with a horizontal axis placed immediately below the pulley 160 and from this pulley 161 it is returned to another pulley 162 with a horizontal axis of intermediate level between those of the axes of the pulleys 160 and 161, the cable entou also pulleys 161 and 162 for about three-quarters of a turn. From pulley 162, cable 25 goes to cable accumulator 29 which has at its lower part a pulley 163 of horizontal axis secured to a horizontal bar 164 which is parallel to the wall 56, and which can slide vertically along the external face of this wall S6 ₁ and, at its upper part, on the same vertical, another pulley 165 of horizontal axis. The bar 164 is recalled down by a spring 205.

The cable part 25 coming from the pulley 162 passes first on the lower pulley 163 then on the upper pulley 165, again on the pulleys 163 and 165 from where it is returned to three other pulleys 166, 167 and 168 analogous to the pulleys, respectively 162, 161 and 160. From pulley 168, the cable goes to pulley 145.

During the erection of the mast, the pulleys 160, 161 and 162 are driven together in rotation in the direction of the arrows.

During the collapse (or contraction) of the mast, it is the pulleys 166, 167 and 168 which are driven in rotation but in the opposite direction to that of the arrows shown.

To prevent slipping of the cables on the pulleys, the grooves of the pulleys 160, 161, 162, 166, 167 and 168 have housings for olives 86 and other olives 300 (FIG. 15) integral with the cables.

For driving the pulleys 160, 161 and 162, there is provided a horizontal shaft 170 of rectangular section (FIG. 16), for example square, intended to cooperate with a crank or a motor and of which a pulley 171 is secured on which has passed. a cable or chain 172 passing over drive pulleys (not shown) wedged on the same shafts as the pulleys 160, 161 and 162, this chain or cable 172 performing the same path around the pulleys as the cable 25 around the pulleys 160, 161 and 162.

For driving the pulleys 166, 167 and 168, a horizontal shaft 175, a pulley 176, a chain or cable 177 and drive pulleys are provided in a similar manner.

For cables 26 and 27, pulleys 160, 161 and 162 as well as 166, 167 and 168 correspond two other sets of identical pulleys mounted on the same corresponding horizontal shafts, the belt or chain 172 or 177 thus driving simultaneously, and with the same voltage, the three cables.

The accumulator 29 comprises two pulleys 165 ₁ and 165 ₂ with a horizontal axis in the same horizontal plane as the pulley 165 as well as two pulleys 163 ₁ and 163 ₂ secured to the horizontal bar 164, the pulleys 165 ₁ and 163 ₁ of on the one hand, and the pulleys 165 ₂ and 163 ₂ on the other hand being intended for guiding the cables, respectively 27 and 26.

The mechanism 28 is covered by a cover 178 (FIGS. 5 and 6), the large wall 181 of which has two openings in the center of bosses 179 and 180 convex towards the wall 56 ₁ and through which the shafts 170 and 175 pass through the wall 181.

Booms 9 ₁ , etc. are composed of a plurality of parts 185, 186, 187 (FIG. 5), etc., separable from one another, one end of each of these parts being able to fit into another end of another part, the length of these boom parts being preferably equal to or less than the height of the element 2 ₁ so that, for transport, they can be applied against the faces of this element 2 ₁ . In the transport condition, the parts 185, 186 are retained by the cables wound around the upper part of the external faces of the element 2 ₁ , as shown in 190 in FIG. 5.

To erect the mast, the crank mounted on the shaft 170 is rotated in the direction of the arrow f ₁ (fig.16), which drives the cables 25, 26, 27 in the direction of the arrows F (figs. 14 and 15) and thus causes the rise of the element 2 ₁₂ thanks to the cooperation of the olives 86 integral with the cables with the ceilings 83 of this element. When the external lower returns 66 of the element 2 ₁₂ are fully introduced into the spaces 63a (FIG. 14) separating the upper internal returns 63 of the corresponding wall of the element 2 ₁₁ and when the lower edges of the elastic tabs 91 ₁₂ rest on the platforms 76 of element 2 ₁₁ , the cables 25, 26, 27 are released by acting in the opposite direction on the shaft 170, so that the olives 86 descend below the lower edge of the element 2 ₁₂ and thus the cables 25, 26, 27 are detached from this element. The rise of the other elements is carried out in the same way.

During the erection, each tubular arm 132, 133, 134 (FIG. 5b) pivots about its respective axis 134 ₁ under the effect of the weight of the elements 2 acting on the pulley 137 via the cable and therefore on this arm via the axis 138 of the pulley. This pivoting brings the pulley 137 closer to the element being hoisted and, in this way, the cable strand 139 remains substantially vertical even at the end of the hoisting of the element, the forces exerted on the cable thus keeping their effectiveness for lifting.

The obliquity of the upper edges 134 ₂ limits the friction surface of the arms against the internal faces of the walls of the elements and, during collapse, facilitates the pivoting of these arms towards the vertical axis 1 ₁ .

Downstream of the winch mechanism 28, the cables 25, 26, 27 are unwound and are kept in tension by the action of the spring 205 of the accumulator 29 which pulls the bar 164 downwards.

The accumulator 29 keeps the cables taut despite the difference between the length of cable which is wound to raise an element and the length of cable which is unwound due to the elevation of the elements 2. In fact, the length of coiled cable, for erection, is practically equal to the height of an element 2 ₂ , 2 ₃ ... while the length of cable which must be unrolled during erection is variable, being negligible during hoisting of the first element 2 ₁₂ and increasing until reaching practically the same length as that of the cable wound when hoisting the element 2 ₂ .

As is provided, to hoist the elements, three cables on which the same traction is exerted and which are arranged in a regular manner around the vertical axis of the mast, these parts of cable which carry out the hoisting of the elements contribute to the correct hoisting, without jamming.

The stability of the mast is ensured by the large length, at least equal to 0.3 times the height of the erected mast, of the booms 9 ₁ , 10 ₁ and 11, which give a lift surface with a large area.

The crank engaged on the shaft 175 can be used to increase the tension exerted on the shrouds.

Ratchet and ratchet means (not shown) are integral with the shafts on which the pulleys 161 and 167 are fixed to prevent rotation in the unwanted direction of said pulleys, that is to say a movement in the unwanted direction of the cables.

To contract the mast, a clamp or ring is used to bring the elastic tabs 91 closer to the corresponding walls, which allows each element to enter the element immediately below. During this operation, the shaft 175 is rotated so as to move the cables in the opposite direction to the arrow F ₁ and, manually, the olives 86 are gradually introduced into the notches 84 for, again, attach the cables to the mast body elements.

To help keep the elements in place relative to each other, the lower edge of a large wall of each element projects inwardly a horizontal pin 400 (Figure 14) penetrating, in the contracted condition of the mast, in a notch 401 which has the lower edge of the wall of the element which is immediately adjacent above it in erect condition.

FIG. 17 shows a variant for attaching a cable 25 'to an element 2'. In this variant, each elastic tab 220 has a lug 221 penetrating, in the collapsed condition of the mast, into an opening 222 of the narrow wall 223 with which it is associated and on which the cable 25 'is wound forming a loop 224 around this lug.

When an element 2 'is hoisted above the lower element, the elastic tab 220 moves away from the wall 223 and the lug 221 escapes from the opening 222, the loop 224 sliding on the lug and escaping from the latter, which separates the cable 25 'from the element 2'.

As a variant, the elements 2 have in section the square shape and not the triangular shape.

Claims (30)

1.- Telescopic mast comprising elements arranged to slide one inside the other, and cable means for erecting the mast,
characterized in that these means comprise at least two hoisting cables mounted so that the result of the pulls which they exert, for erection, is vertical, each cable being before erection attached to all the elements to be hoisted and the erection being carried out by successive sliding of each element in the element which is immediately external to it. 2. A mast according to claim 1,
characterized in that it comprises means for detaching the cables from each element after the end of the hoisting of said element. 3.- Mast according to claim 1 or claim 2, characterized in that it comprises means so that the strand of each cable fixed to the element being hoisted is, from the beginning to the end of this hoisting, vertical direction or close to vertical so that the traction exerted on each cable has maximum efficiency for hoisting. 4.- Mast according to claim 3,
characterized in that it comprises vertical arms before erection and pivoting about a horizontal axis at their base, these arms being in number equal to the number of cables and being arranged inside the elements, each of these arms having a height slightly greater than the common height of said elements and having at its upper part a pulley for deflecting and guiding a hoisting cable. 5. Mast according to any one of the preceding claims,
characterized in that each hoisting cable comprises a stay forming a stay. 6. A mast according to claim 5,
characterized in that it comprises a winch device on which, during the erection of the mast, the hoisting cables are wound and from which the shrouds are unwound, this device comprising a cable accumulator allowing the same cable can be wound and unwound according to different lengths while keeping the shrouds taut. 7. A mast according to claim 5 or claim 6,
characterized in that it comprises booms in number equal to the number of cables and at the end of each of which there is a guide pulley of a stay, the length of each boom being equal to at least 0.3 times the height of the erected mast. 8.- Mast according to claim 7,
characterized in that other cables are stretched between the free ends of the adjacent booms. 9.- Mast according to claim 7 or claim 8,
characterized in that it is fixed to the ground by stakes and cables or the like stretched between the stakes and the ends of the booms. 10.- Mast according to any one of the preceding claims,
characterized in that its base has spikes for its anchoring in the ground. 11. Mast according to any one of the preceding claims,
characterized in that it comprises a base and a cylinder means between this base and a base plate of the mast body so as to be able to vary the angle between this base and the base plate in order to facilitate the installation of the mast on sloping ground. 12.- Mast according to claim 7,
characterized in that each boom is composed of several elements associated by interlocking their ends, the length of each element being at most equal to the height of the mast in contracted condition. 13.- Mast according to claim 12,
characterized in that in transport condition, the boom elements are arranged on the external faces of the mast body in contracted condition against which they are retained by the hoisting and guy cables wound around these elements. 14.- Mast according to any one of the preceding claims,
characterized in that, in order to maintain the mast body in an erected condition, all the mast body elements, with the exception of the basic element, comprise at their lower part an elastic tab which is applied against a wall of the mast element in contracted condition and which moves away from this wall, due to the elasticity, when the element has been deployed from the lower element and then rests on a platform which this lower element presents in its upper part. 15.- Mast according to claims 2 and 14, characterized in that the distance of the elastic tab from a wall of the mast body element allows the detachment of the lifting cable from this element. 16.- Mast according to claim 15, characterized in
that each cable has olives housed in an external notch that has the lower end of a corresponding wall of each element, the cable passing through this wall through a slot open downwards. 17.- Mast according to claim 16,
characterized in that the elastic tab has in its lower part a slit rim allowing passage to the corresponding cable but preventing the olive from escaping during the erection and during the transport of the contracted mast. 18. A mast according to claim 15,
characterized in that the elastic tab has a lug penetrating into an opening in the wall opposite the mast element and on which the corresponding cable forms a loop in contracted condition of the mast, this loop escaping from the lug when the elastic tab, and therefore the lug, move away from the wall. 19.- Mast according to any one of claims 14 to 18,
characterized in that the mast elements being made of plastic, preferably of reinforced plastic, the tab is obtained by molding with the corresponding element. 20.- Mast according to any one of claims 14 to 19,
characterized in that the lower edges of the walls of the mast elements which do not have elastic tabs have upwardly directed external returns intended to penetrate into the space separating the corresponding wall from a downwardly directed internal return which is present in its upper part the mast element immediately below. 21. Mast according to any one of the preceding claims,
characterized in that the base element of the mast has at its lower part a cavity in which hang the hoisting strands of the cables before the erection of the mast. 22.- Mast according to claim 21,
characterized in that the cavity houses pulleys for deflecting and guiding the cables. 23.- Mast according to claim 6,
characterized in that the winch device is arranged against an external face of the base element of the mast. 24. Mast according to any one of the preceding claims,
characterized in that the mast elements have the general shape of a prism whose cross section is a regular polygon such as an equilateral triangle. 25. Mast according to claim 14 and claim 24,
characterized in that the vertices of the regular polygons are truncated, each element thus having narrow faces of which the elastic legs are integral. 26.- Mast according to claim 24 or claim 25,
characterized in that the number of cables is equal to the number of sides of the polygon. 27.- Telescopic mast comprising elements of mast body arranged to slide one inside the other, characterized in that to maintain the mast in erect condition, all the elements of mast body, except the element of basic, understand in their part lower an elastic tab which is applied against a wall of the element when the latter is housed in the element immediately below and which moves away from this wall, due to the elasticity, when the element has been released from the lower element and then rests on a platform that this lower element has in its upper part. 28.- Telescopic mast comprising several mast body elements arranged to slide one inside the other and cable means for erecting the mast, characterized in that, the erection being carried out by successive sliding of each element by relative to the element which surrounds it, the cable means is, before erection, attached to all the elements, means being provided for detaching the cable means from each element after the end of the hoisting of this element. 29.- Method of erection using a cable of a telescopic mast comprising elements arranged to slide one inside the other, in which the erection is carried out by successive sliding of each element in the element inferior,
characterized in that the cable being, before erection, attached to all the elements to be hoisted, it is released from each element after the hoisting of the latter, which detaches it from said element. 30.- Telescopic mast,
characterized in that it comprises a base surmounted by a base plate, a jack means between the plate and the base to vary the angle between the base and the base plate in order to facilitate the installation of the mast on a sloping ground, and a tubular tip means projecting down from the base for anchoring the mast in the ground, this tip means housing the body of the jack means.

Images