RU2631289C2 - Element of changing crosswind direction to prevent sedimentation - Google Patents

Abstract

FIELD: construction.

SUBSTANCE: element of changing the crosswind direction for the installation on open terrain contains the base slab from the bottom for fixation on the terrain, a central rack projecting from the base slab, with a large number of guide plates mounted thereon. The guide plates are provided on the rack in the vertical direction with the cross-shaped bevel. The length of the guide plates increases upward from the base slab.

EFFECT: reducing or preventing sediments of snow, alluvial sand, or anything similar.

12 cl, 5 dwg

Description

The invention relates to an element of changing the direction of the crosswind with the signs of the restrictive part of paragraph 1 of the claims, which is intended to be installed in an open area, in particular in places critical from the point of view of winds, such as mountain ridges, etc. If strong lateral winds occur in such places in open areas, then, as a rule, solid particles brought by the air, for example, sand or snow, are deposited. Such deposits of snow, for example, on mountain peaks in winter, can lead to the danger of snow avalanches if such deposits, for example, through repeated detonations are not purposefully eliminated. However, regular detonations of dangerous snow canopies in the mountains are expensive and sometimes insufficient to effectively prevent avalanches.

To date, the so-called snow retention shields have also been used in the prior art to influence unwanted snow accumulations due to wind. Such shields installed at critical points in the area purposefully contribute to the accumulation of snow to prevent blowing, for example, snow or sand on the road, etc. Such shields, however, are not suitable in order to prevent the accumulation of solid particles from the air due to the strong side wind, the so-called sedimentation, really in any situation. The traditional avalanche elements presented below in the prior art for installation in critical places of a mountainous area provide either a change of direction or destruction of descending snow avalanches or rock avalanches. That is, they are not suitable for purposefully preventing the occurrence of such kind of rock avalanches or snow avalanches.

Based on this, the objective of the proposed invention is to create an element of changing the direction of the crosswind for installation in an open area, with the help of which it is possible to purposefully prevent the occurrence of deposits of solid particles from the air. An element of changing the direction of the crosswind in accordance with the invention should be further made as simple as possible with the possibility of mounting in an open area.

This problem is solved by an element of changing the direction of the crosswind in accordance with the characteristics of paragraph 1 of the claims. Preferred embodiments and refinements of the invention are the subject of the dependent claims.

An element of changing the direction of the crosswind in accordance with the invention, which is provided for installation in an open area for purposefully preventing the formation of deposits of snow, sand, etc., has a base plate from the bottom for fixing on the ground, a central rack protruding from the base plate, as well as a large number of rack-mounted guide plates for changing the direction of the wind, and characterized in that the guide plates are provided on the rack in vert crosswise mowing and that the length of the guide plates from the base plate in the upward direction increases. The guiding plates of the lateral wind direction changing element catching and purposefully changing the direction of the wind are thus provided so that they protrude from the strut in the vertical direction so that they form the largest possible grip area for the emerging lateral wind. The length of the guide plates in the lower zone is less and increases in the upward direction, so that a kind of trapezoidal shape is formed, the width of which is greater from above than at the lower end of the side wind direction change element. All guide plates are mounted on a central protruding pillar, so that the side wind direction changing element can be mounted self-supporting and free-standing, without the use of additional fixing cables and similar structures. In accordance with the invention, a base plate is provided for mounting and installing an element for changing a side wind direction on the bottom side, on which a central pillar is rigidly mounted. The base plate is used to install and fix the element in the ground at a certain point in the open area, in which purposeful prevention of the deposition of solid particles from the air is required. Due to the increasing upward direction of the guide plates, the lateral wind direction changing element has an increased area in the upward direction that is opposed to the wind incident on it. Through such measures in accordance with the invention, lateral winds are captured in a targeted and enhanced manner and, according to the type of effect, nozzles with the formation of enhanced turbulence are conducted downward. These enhanced swirls in the area of the crosswind direction change element reliably prevent the formation of solid particles from the air, for example, sand or snow. When an element of changing the direction of the crosswind in accordance with the invention is installed in critical places in mountainous terrain, for example, on mountain rowing or on mountain peaks, it is possible to prevent the occurrence of avalanches due to undesirable local clusters using relatively simple means, since particles are not deposited at the points of installation of the elements for changing the direction of the crosswind, but are carried away further with the wind that has purposefully changed its direction. The crosswind direction changing element according to the invention thus prevents the occurrence of unwanted deposits (sedimentation) in an open area with a relatively simple structural form. In this case, we can talk about the deposition of alluvial sand or the deposition of snow. The crosswind direction changing element according to the invention can preferably be installed in groups of several such elements in the corresponding locally problematic places on the ground. Each of the elements by itself, due to the presence of a central rack, is extremely durable and can be installed independently. Installation and installation of an element of changing the direction of the crosswind is a relatively simple measure due to the fact that only for a central rack on the ground a foundation or foundation plate must be made in advance.

According to a preferred embodiment of the invention, the guide plates for changing the direction of the crosswind are arranged on the stand at a certain distance from each other in such a way that a series of permeable intermediate spaces are formed between the guide plates. The wind-conducting elements of the lateral wind direction changing element formed by the guide plates are thus provided with a relatively large area, however, due to the presence of intermediate spaces, they have a certain permeability. This, on the one hand, has the advantage that the elements do not form a barrier over the entire surface and can be seen through. Intervention in nature is thus relatively small. On the other hand, these elements due to the presence of intermediate spaces between the guide plates are less susceptible to damage by very strong winds, which, in particular, in mountainous areas often occur. Thus, long-term installation and stability of the elements are guaranteed. In accordance with this preferred aspect, the interstitial spaces can be, in particular, half the width of the guide plates, so that there is always guaranteed a sufficiently large deflecting surface for the wind falling on it, which contributes to a swirl in the direction of the earth due to the nozzle effect and provides reliable prevention of local sedimentation.

According to a further preferred embodiment of the invention, the guide plates are at least at their free ends connected to each other so that they form four sails of the type of sail that crosswise protrude from the strut of the wind-conducting element. The guide plates consisting of separate elements are thus reliably connected to each other so that, despite their permeability, they form a joint stable component for purposefully changing the direction of the winds. The individual guide plates can be connected, for example, by means of a rigid connection, such as welding with rods or profile elements. Alternatively, the connection can also be carried out by means of flexible elements, for example, wire ropes or similar elements. The guide plates connected to each other protrude respectively crosswise from the central post and form a kind of trapezoidal sail, with a greater width at the upper end than from the ground.

According to a further preferred embodiment of the invention, the upper and lower transverse beams crosswise protruding from the stand are provided for securing and further protecting the guide plates. If there are such upper and lower crosswise protruding pepper beams, then the guide plates protruding on the sides can be reliably and firmly fixed, without significantly increasing the mass of the entire element as a whole. Guide plates can be provided, for example, in the form of very thin metal sheets, which themselves do not have great intrinsic stability, however, when combined with transverse beams, which can be implemented, for example, in the form of tube profiles, they acquire the necessary strength in regarding arising winds even with strong winds. The fastening and installation of the guide plates between the transverse beams can be carried out in this way in various ways: by firmly welding to the longitudinal rods, by inserting the guide plates into the recesses, by fixing the cables stretched between the crossed beams, etc.

According to a further preferred embodiment of the invention, the base plate, on which the stand is vertically fixed, is made of two parts and is provided with an auxiliary system during installation, preferably of the pipe-to-pipe type. The base plate may consist, for example, of the first plate of the element and the second pit of the bottom, and the plate of the element is firmly connected to the rack, and the bottom plate is provided for installation in the ground. The bottom plate may consist of metal and / or a combination of metal and concrete material, so that a reliable foundation is formed for the installed element to change the direction of the side wind. For installation in accordance with the invention, an auxiliary system is provided, for example, according to the type of system of pipes inserted into each other: the bottom plate has, for example, a pipe of a smaller diameter, onto which a slightly larger diameter pipe of a stand of a direction changing element can be mounted side wind. The position, thus, already during the primary orientation of the element, the change in the direction of the side wind is reliably fixed, and installation requires, for example, only screwing both elements of the base plate with each other. This facilitates, first of all, installation on a terrain without access roads by helicopter through the air. For this, only one single worker is needed on earth. In addition, the necessary intervention in the surrounding nature is therefore minimal.

According to a further preferred embodiment of the invention, the guide plates or four wind-conducting elements formed from the guide plates are additionally fixed by means of upper and / or lower struts at the upper and / or lower ends of the rack. Spacers can be implemented, for example, by means of ropes or rods inclined from the free end or central zone of the guide plates or transverse beams to the central strut. Through the use of such struts, stability and resistance to emerging winds are further enhanced. Without a significant increase in the mass of the element, a very strong structure can thus be obtained for the purpose of changing the direction of the wind. The spacer may consist, for example, of tensioned wire ropes that are secured to the connecting flanges. The spacers in the embodiment presented for consideration can, however, be carried out in a rigid form, for example, in the form of welded rods. An advantage of the compact and relatively lightweight design of the crosswind direction changing element is that it can be mounted independently on the terrain, that is, no interfering side fastenings are required via wire ropes or similar elements, which would accordingly require a large number of attachment points and the presence of a concrete foundation or similar structure.

According to a further preferred embodiment of the invention, the catching and wind direction-changing guide plates consist of sheets of metal material profiled or ribbed in the longitudinal direction. Thus, the guide plates can be made of comparative thin sheet material and are, therefore, very light. This results, in general, in facilitating the design of the entire element of changing the direction of the crosswind, which is an advantage, especially when transported by helicopter for installation on the ground in the absence of access roads. The guide plates with profiling or reinforcing ribs in the longitudinal direction are furthermore quite stable, so that deformation due to strong wind can be prevented.

According to a further preferred embodiment of the invention, the guide plates are rigidly mounted in a corresponding peripheral frame, which, for its part, is mounted on a rack. Thus, for example, four crosswise projecting lateral guide plates, respectively, are firmly connected inside the frame and form a compact unit. The frame may consist of welded pipe profiles and increases the stability and strength of the element. The guide plates themselves on the respective frames are firmly fixed in the required position. The frame itself can be mounted on a central pillar, for example, with the possibility of a connector by screw connection with corresponding flanges or similar elements.

According to an alternative embodiment of the invention, the respective guide plates of the group of guide plates, which form a common wind-conducting element, are interconnected by connecting cables between the upper and lower transverse beams and fixed in their position. For example, at the free end of the guide plates, the first connecting cable between the upper and lower transverse beams can be stretched, and in the central zone one connecting cable or several connecting cables can be provided, which respectively fix the guide plates in four directions and with the desired vertical orientation.

According to a further preferred embodiment of the invention, a rotation lock is provided for mounting the anti-rotation element. Fixation from rotation can be realized, for example, by means of a pin or screw in the foundation plate, which enters the corresponding hole. Other means of rotation fixation are also possible. Fixation from rotation has the advantage that the element of changing the direction of the crosswind during the occurrence of crosswind cannot rotate, so that a strong turbulence of the crosswind and its targeted removal towards the bottom are constantly guaranteed.

According to a further preferred embodiment of the invention, means are provided for preventing the rotation of the element during transport by helicopter or similar device by air. An element of changing the direction of the side wind can thus be simply captured by the hook of the helicopter and reliably transported by air to the installation site. When hoisting with a crane, rotation is also prevented. Means for preventing the rotation of the lateral wind direction changing element during transportation by air can be implemented, for example, in the form of a protruding rod with a wind cone at the free end. The rod protrudes from the side of the lateral wind direction changing element and has a wind cone at its end, so that the element therefore remains in the corresponding position and cannot rotate in the air. Other means to prevent rotation of the element during transportation by air may also be provided.

According to a further preferred embodiment of the invention, the length of the guide plates in the direction from bottom to top is approximately doubled. That is, the lowermost guide plate is about half the length of the uppermost guide plate. Thus, the surface for a purposeful change in the direction of the headwind in the direction from the bottom up increases quite strongly, as a result of which an even more effective change in the direction, redirection and swirl of the air as a result of the mentioned nozzle effect is achieved. Thereby, an even more effective prevention of solid deposits in the area and around the side wind direction changing element is guaranteed.

Other advantages, features and objectives of the proposed invention are apparent from the following description of exemplary embodiments. The invention is explained in more detail below on the basis of exemplary embodiments with reference to the attached drawings, in which:

FIG. 1 is a perspective view of a crosswind element according to the invention according to a first embodiment of the invention;

FIG. 2a, 2b is a side view and a top view of a side wind direction changing element according to the first embodiment of FIG. one;

FIG. 3 is a side view of a crosswind element according to the invention according to a second embodiment;

FIG. 4 is a side view of a crosswind element according to the invention according to a second embodiment during installation.

The first exemplary embodiment of the crosswind element 10, which is presented in various views in FIG. 1, 2a and 2b will be explained below. Element 10 changing the direction of the crosswind is designed for installation in an open area, for which purpose, at the lower end of element 10, a foundation plate 1 is provided from the bottom. The base plate 1 is depicted in this case with four set screws that are screwed into the corresponding holes with internal thread, and are screwed to the installation site or to the counter plate for fastening to the (not shown) foundation. Element 10 changing the direction of the crosswind mainly consists of a central strut 2, on which protruding guide plates 3 are mounted crosswise on the sides, which serve to purposefully change the direction or swirl of the winds falling on element 10. Guide plates 3 in this embodiment are provided with a cross-shaped protrusion in four directions from the central strut 2, and they are mounted between the upper transverse beams 4 and the lower transverse beams 5. Direction The support plates 3 have a shorter length in the lower zone, which continuously increases in the upward direction. The guide plates 3 thereby form, respectively, respectively, together four trapezoidal wind-conducting elements 30, which are clearly visible, in particular, in a side view from FIG. 2a. These wind-conducting elements 30 serve for purposefully capturing, swirling and taking the lateral wind incident on them down to the area around the lateral wind direction changing element 10 in order to prevent the deposition of solid particles from air, for example, sand or snow, in a targeted manner. For this, the guide plates 3 of the wind-conducting elements 30 have an increased length in the upward direction, as a result of which a kind of nozzle effect occurs when the wind hits them, which contributes to the swirling and redirection of the wind together with the solid particles in the air, without creating their deposits around the element 10 changes in the direction of the crosswind. When, in this way, a large number of such elements 10 of changing the direction of the crosswind are established in a terrain critical from the point of formation of deposits (for example, on a ridge or on a mountain ledge), it is possible, for example, to purposefully prevent the occurrence of snow deposits . Due to this, the formation of snow avalanches can be effectively prevented, since even before the formation of unwanted snow accumulations, taking into account the wind rose and the terrain, their formation can be reliably prevented by using the invention. Another area of application of this type of crosswind direction changing element is the prevention of sedimentation, i.e. sediment, for example, sand from air in deserts or on the coasts of water bodies. And in this case, the crosswind direction changing element serves to purposefully effectively prevent the occurrence of deposits around the element 10 by trapping and changing the crosswind direction using four wind-conducting elements 30 that crosswise protrude from the strut 2, which consist of a large number of separate guide plates 3. Otherwise Compared to traditional fences or barriers, the occurrence of deposits of snow or sand from the leeward side is prevented. ony.

In the first embodiment shown in FIGS. 1, 2a and 2b, guide plates 3 are mounted between the upper and lower transverse beams 4, 5 in the form of square pipe profiles by connecting cables 9. The connecting cables 9 are mounted on mounting flanges on the pipe profiles of the transverse beams 4 5 and hold the corresponding guide plates 3 in the desired position. The guide plates 3, which can be made, for example, from a thin metal sheet, are mounted, respectively, at a distance from each other so that, respectively, intermediate spaces are formed approximately half the width of the guide plates 3. Element 10 changes the direction of the side wind thus not completely closed and can be seen through. The intermediate spaces between the guide plates 3 also have the advantage that the elements 10 with very strong winds are not at risk of being torn off or damaged by the wind. In the first embodiment, the central post 2 projects slightly above the upper transverse beams 4, forming the end of the wind-conducting elements 30. On the upper and lower transverse beams 4, 5, corresponding struts 6, 7 are installed between the lower and upper end of the post 2, as well as approximately in the middle transverse beams 4, 5. Spacers 6, 7, which can be implemented, for example, in the form of tensile wire ropes or metal rods, increase the stability of the element 10 changes the direction of the side wind, do not increase Single over its total weight. The spacers 6, 7 also serve to perceive the tensile stress created by the connecting cables 9, so that the wind-conducting elements 30 are stretched like sails with an increasing width in the upward direction. In this embodiment, the four transverse beams 4, 5, respectively, protruding crosswise from the strut 2, respectively, are also mounted by means of mounting flanges and corresponding screw connections. Alternatively, the transverse beams 4, 5 can, however, also be rigidly connected to the post 2, for example, by welding metal pipes. Removable mounting by means of mounting flanges and screw connections, however, has the advantage that the transportation of the side wind direction changing element 10 is facilitated and less volume is required. The crosswind direction changing element 10 in accordance with the invention is provided with relatively large surfaces for impact of the wind, changing its direction and its targeted further implementation. By means of the guide plates 3 extending crosswise in four directions, sedimentation of solid particles from the air is also guaranteed when the wind direction changes. The wind can get on the element 10 changes the direction of the crosswind from all directions, without the formation on the reverse side (leeward side) of deposits, for example, snow or sand, which is the case when using traditional fences or similar structures that are installed in winter to hold snow drifts , for example, on the sidelines of main roads.

In FIG. 3 is a side view of a second embodiment of a crosswind element 10 in accordance with the invention. In contrast to the first embodiment described above, in this case, the guide plates 3 are mounted by means of a peripheral frame 8, and the frame 8 of four cross-beveled wind-conducting elements 30 in this case is generally mounted on the central rack 2 by means of corresponding mounting flanges and screw connections. The guide plates 3, for example, are welded into the frame 8. And here, respectively, the upper and lower transverse beams 4, 5 are provided, which together with a slightly thinner rod or profile form at the ends of the guide plates 3 of the frame 8. This form of wind-conducting elements 30 has the advantage that the individual guide plates 3 are held firmly next to each other and locked in position. In FIG. 3, respectively, an embodiment of this embodiment is shown on the left and right. While on the left side in FIG. 3, only a spacer 6 is provided on the upper transverse beam 4 between the free end of the transverse beam 4 and the upper end of the strut 2 and no lower strut is provided, in the right example, as in the first embodiment, there is an upper strut 6 and a lower strut 7, which are fixed between the strut 2 and approximately in the middle of the respective transverse beams 4, 5, and provide additional stability. In an alternative embodiment, the spacers can be completely eliminated - both in this and in the first embodiment. And in this embodiment (FIG. 3), the guide plates 3 of the lateral wind direction changing element 10 are made of relatively thin sheet material. The sheet material can be provided with longitudinally arranged profiled elements or ribs to provide rigidity, so that the guide plates 3, despite the relatively thin material, nevertheless have sufficient rigidity to withstand winds of different strengths and provide the desired effect due to swirling and wind removal down to prevent sedimentation. Other details of the lateral wind direction changing element 10, in the preferred embodiment, and in this case can also be made of metal material. The central pillar 2 in the presented examples of the invention is implemented as a round pipe. In an alternative embodiment, however, it can be implemented in the form of a pipe of rectangular cross section, as well as the upper and lower transverse beams 4, 5 in these embodiments of the invention. And here the lower end of the rack 2 is equipped with a foundation plate 1, which is reinforced by stiffening triangular struts. The base plate 1 has holes for mounting using screw connections. The installation in place of the crosswind element 10 according to an embodiment of the invention is shown in a schematic side view in the following FIG. four.

In FIG. 4 shows a situation in which an element 10 changing the direction of the crosswind, shortly before being set to a predetermined position on the ground, is moved through the air using a helicopter or a crane (not shown). For this, the hook 14 of the helicopter is suspended at the upper end of the element 10. The lateral wind direction changing element 10 for transportation is provided with means 11 for preventing the element 10 from rotating in the air, which in this case is in the form of a wind cone 11, which is mounted by means of a rod protruding to the side of the lower transverse beam 5. Thanks to this means 11 for preventing rotation the crosswind direction changing element 10 reliably moves through the air and is installed at a given point in the terrain by simply lowering it with a helicopter. On the ground, for this purpose, a concrete base plate 16 is pre-mounted on which the base plate 13 is placed, on which the plate 12 of the base plate element 1 is installed. To facilitate lowering and installing the side wind direction changing element 10, the base plate 13 is provided with a central branch pipe 15, the diameter of which is somewhat smaller than the inner diameter of the center post 2. Both plates 12, 13 of the foundation plate 1 can thus be stacked on top of each other in the form of a pipe-to-pipe system, so that the direction change element b kovogo wind directly during installation is already in the correct position and pre-fixed. Then it is only necessary to screw or otherwise connect both plates 12, 13 of the foundation plate 1 to ensure reliable fixation of the separate element 10 changing the direction of the side wind. Thus, there is no need to use lateral fastening means, such as anchor cables, which are necessary when using traditional snow guards or similar structures to vertically hold the structure even in strong winds. The means for preventing rotation in the form of a wind cone ensures that the element 10 is always oriented in the direction of the wind during transport, as explained by the arrow W in FIG. 4. After installing and securing the cross-wind direction changing element 10, the wind cone 11 together with its mounting rod is again removed and can be used for further transportation of the same type of cross-wind direction changing element 10 of the same type.

The invention provides an effective element 10 changing the direction of the crosswind, which reliably and over a large area prevents the occurrence of deposits of particulate matter from the air in place directly due to the swirl and targeted changes in the direction of the wind. The crosswind direction changing element 10 according to the invention, due to its construction with a large number of relatively thin guide plates 3, protruding crosswise from the central strut 2, has a very small mass, so that it can be transported by helicopter. The total mass of the crosswind element 10 is preferably less than 550 kg. In addition, the crosswind element 10 in accordance with the invention is a relatively small interference with the environment, since the elements should only be installed in certain places, respectively, in groups, and to prevent snow avalanches, rock avalanches and sand deposits large-area construction activities are required. The invention is not limited to the presented examples of implementation and can be modified in various ways. In particular, the shape of the guide plates may vary. In the presented embodiments, the length of the lowermost guide plate 3 is approximately half the length of the uppermost guide plate 3, so that there is a relatively large expansion of the wind-conducting elements 30 in the upward direction. Alternatively, the expansion in the upward direction can be carried out to a lesser or greater extent.

The guide plates 3 can be made using smooth or profiled sheets, i.e. relatively thin sheets, which in the longitudinal direction have stiffening elements deforming. The guide plates 3 can, however, be provided with stiffeners to ensure high stability despite the lightweight construction. The guide plates 3 can also be fixed in another way on the central rack 2 than in the presented embodiments by means of connecting cables 9 or the peripheral frame 8. For example, the guide plates 3 can be mounted by means of receiving slots in the rack 2 and by strong welding. The distance between the guide plates 3 can also vary, for example, in a targeted way, to promote greater permeability in certain areas: for example, the upper guide plates 3 can be mounted at a greater distance from each other than the lower guide plates 3 near the ground, to take into account stronger winds in the upper zone.

Claims (12)

1. Element (10) changing the direction of the crosswind for installation in an open area to purposefully reduce or prevent deposits of snow, sand, or the like, with a foundation plate (1) from the bottom for fixing on the ground, protruding from the foundation plate (1 ) a central column (2) and with a large number of guide plates (3) mounted on the column (2), characterized in that the guide plates (3) are provided on the column (2) in the vertical direction with crosswise beveling and that the length guide plates (3) from the base plate (1) in the upward direction increases. 2. Element (10) according to claim 1, characterized in that the guide plates (3) are located at fixed distances relative to each other to form permeable intermediate spaces. 3. Element (10) according to claim 2, characterized in that the guide plates (3) are connected to each other at least at their free ends in such a way that they form four type of sails crosswise protruding from the rack (2) of the wind-conducting element ( thirty). 4. Element (10) according to claim 1, characterized in that there are provided upper and lower transverse beams (4, 5) that crosswise protruding from the strut (2) for securing the guide plates (3). 5. Element (10) according to claim 1, characterized in that the base plate (1) is made of two parts and is equipped with an auxiliary system during installation, in particular, by the type of pipe-to-pipe system (15). 6. Element (10) according to any one of paragraphs. 1-5, characterized in that the guide plates (3) or four wind-conducting elements (30) formed from the guide plates (3) are additionally fixed, respectively, by means of upper and / or lower struts (6, 7) on the upper and / or lower ends of the strut (2). 7. Element (10) according to claim 6, characterized in that the guide plates (3) consist of sheets of metal material profiled or ribbed in the longitudinal direction. 8. Element (10) according to claim 6, characterized in that the guide plates (3) are rigidly mounted in the corresponding peripheral frame (8), which, for its part, is mounted on the rack (2). 9. An element (10) according to claim 6, characterized in that the guide plates (3) are interconnected by connecting cables (9) between the upper and lower transverse beams (4, 5) and are fixed in their position. 10. Element (10) according to claim 1, characterized in that it is provided with rotation lock to install the element with anti-rotation protection. 11. Element (10) according to claim 1, characterized in that means (11) are provided for preventing rotation of the element (10) when transported by helicopter or similar device by air, in particular in the form of a wind-mounted cone mounted with the possibility of a connector, which, due to the rod, is laterally perpendicular to the rack (2). 12. Element (10) according to any one of paragraphs. 1-5, 7-11, characterized in that the length of the guide plates (3) from bottom to top is approximately doubled.

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