DE20314665U1 - Arrangement for flat covering of ground elevations has support construction to hold cover elements at distance from surface of elevation, and support construction and/or cover elements have means to gather solar energy or rainfall - Google Patents

Abstract

The arrangement for the flat covering of ground elevations (1) has a support construction to hold cover elements (5) which are located at a distance from the surface (3) of the elevation and at least partially cover it. The support construction and/or the cover elements have means which serve for the winning of solar energy and/or rainfall. The ground elevation may be constructed as a sound attenuation wall (2) on a motorway, and the support construction is installed on the sloping side (6) facing away from the motorway.

Description

The invention relates to an arrangement to the flat Coverage of site surveys, like bulk or waste dumps, noise barriers or flood dams or the like. With an at least partially inclined and / or curved surface.

There are currently such surveys, such as, in particular, industrial bulk material or waste dumps and are unused. Commercial use is not possible, even agricultural use is hardly feasible. Partially used site surveys, like noise barriers for noise protection or flood dams for flood protection have a high manufacturing cost of earthwork. The characteristics of their Profitability is, if they are set up at all can, extremely difficult to investigate.

The invention is therefore the object The invention is therefore based on the object of terrain surveys through intensive use of energy and environmental resources supply economic use or their economy to increase.

Terrain surveys through intensive Use of energy and environmental resources of an economic Supply use or to increase their profitability.

The task is characterized by the Features of claim 1 solved further features of the invention emerge from the associated subclaims.

The invention is based on the following of embodiments are explained in more detail. The associated Illustrations show the model of the arrangement as a solar system a noise barrier of a motorway and a model of the arrangement as a solar system with winter sports facilities on a slag heap. It is shown in detail in

1 a simulated, perspective view of the soundproofing wall with solar system,

2 1 shows a schematic representation of the soundproofing wall with details of the supporting structure of the solar system in a sectional view,

3 an image of a waste dump with a simulated arrangement of a flat cover by a solar system,

4a . b . c three illustrations of a model of the supporting structure with cover elements in side view and in different positions,

5a . b . c three illustrations of a model of the supporting structure with cover elements in front view and in different positions,

6a . b two images of the model of a conical slag heap with supporting structure, cover elements and winter sports facility in a view from the south and north.

In 1 provides a special terrain survey 1 , designed as a noise barrier 2 a highway, on the surface of which 3 a solar system 4 is attached to the generation of solar energy, in the longitudinal direction of the noise barrier 2 can be continued. This allows the soundproofing wall 2 , which serves to reduce road traffic noise, be used for further economic use. Because of the low installation effort and the weather resistance of the system parts, a photovoltaic system consisting of solar modules is particularly suitable for this. The solar modules are on the cover elements 5 attached or form these self-supporting. The solar system is advantageous 4 on the sunlit slope side facing away from the road 6 of the noise barrier 2 arranged. This prevents pollution of the solar modules from road traffic and distraction effects from the solar modules that hinder road traffic. At the same time is the slope side 6 of the noise barrier 2 most economically usable, which is mainly oriented in the directions south-east-east to south-west-west in relation to central European latitudes and thus the more energy-efficient surface 3 of the noise barrier 2 represents. The cover elements 5 are due to the supporting structure 7 kept at the foot level 8th of the soundproofing wall is fixed and, moreover, mainly on the surface 3 of the noise barrier. In a sectional view in 2 across the soundproofing wall 2 and the solar system 4 are details of the supporting structure 7 schematically visible. The supporting structure 7 consists of at a distance from each other at the foot level 8th of the soundproof wall based foot elements 9 on the noise barrier 2 supported straps 10 and the connectors attached to it 11 in the longitudinal direction of the noise barrier 2 are aligned. foot element 9 and carrier 10 are advantageously made of monolithic in-situ concrete, which is the manufacture of the supporting structure 7 makes it much more economical and ensures its lasting durability. Of course, the foot elements 9 and the carrier 10 also prefabricated and then assembled on site. The bearers 10 are only slightly in the compacted underground 12 of the noise barrier 2 embedded in the lateral position stability of the carrier 10 to ensure. The peculiarity of the supporting structure 7 is that there are no foundation components in the terrain survey 1 , especially in the noise barrier 2 intervention. For the manufacture of sound insulation walls 2 In some cases, waste materials and shredded materials from worn roadways with increased environmental emission values are used, which do not allow a foundation for buildings. Are the connectors 11 in a Inexpensive variant made of wood, can be placed under plastic angles 13 prevent moisture penetration and thus rotting. On the connectors 11 are the cover elements 5 with the solar modules rigidly installed. In the gaps 14 rainwater can run between the cover elements. To erode the surface 3 Avoiding by dripping water are perpendicular to the gaps 14 water-repellent erosion control strips 15 in the longitudinal direction of the noise barrier 2 provided that can also be used for rainwater collection in a possible curved or U-shaped design.

The peculiarity of the underlying project idea is that existing site surveys 1 , which were built as earth fillings primarily for the purpose of noise protection on the federal highway, are used for an ecologically meaningful effect - for example for the generation of solar power. Otherwise, the areas in question are fallow and need to be maintained by the public sector. This entertainment is made public by the operator of the solar system 4 decreased for many years.

The soundproof walls 2 have an inclination that results from the fact that the earth is filled up and can be regarded as ideal for the purposes of solar energy generation, so that when the project is carried out there is no further elevation as a substructure for the construction of the solar system 4 is necessary in order to achieve the best possible solar radiation on the solar modules. The solar system 4 is only on a supporting structure made of concrete and wooden beams 7 on the site survey 1 (Earth fill) applied.

The other peculiarity is that for fastening the solar system 4 not in the surface 3 of the noise barrier 2 is interfered with by foundations, but the concrete beams 10 because of their weight and because of one at the foot level 8th of the soundproof wall foundation (foot element 9 ) find a permanent hold. In this respect, environmentally harmful interventions in the soundproof walls 2 avoided by foundations. With the realization of the project idea, it appears possible to erect noise barriers 2 to generally provide for the disposal of used materials in large quantities in highway construction when planning the highway, since they can be refinanced through energy generation. They can also result from the use of a solar system 4 resulting significant reductions in carbon dioxide are included in the environmental balance sheet and thus incorporated into the necessary balance sheet for the construction of the motorway.

With the installation of solar systems on the soundproof walls 2 A separate use of space for large-scale solar systems on the freeway can be significantly reduced or even completely saved, as a result of which the intervention in areas used for agriculture, for example, can be reduced. A design analogous to the extraction of energy and environmental resources from soundproof walls is also possible, for example, on the side of the embankment or water storage basin facing away from the slope.

In 3 is a solar system 4 on another site survey 1 , designed as a conical slag heap 16 , which arises, for example, when mining a mining or opencast mine. On this dump 16 is the supporting structure 7 with the cover elements 5 , on which, for example, solar modules of a photovoltaic system can be attached. On the geometric axis of rotation 17 the conical spoil tip 16 is the supporting structure 7 by means of a storage block founded at the summit of the spoil tip 18 around the geometric axis of rotation 17 rotatably attached and is around the circumference of the conical spoil tip 16 in a tour 19 with a running structure 20 method. 4a . b . c and 5a . b . c show model details of the fastening of the cover elements 5 on the supporting structure 7 and their possible synchronous, revolving rotary movement about their central axis 21 due to the special connecting elements that cover the elements 5 connect with each other. These connecting elements connect the cover elements 5 to the side of the cover elements 5 and above and below the central axis 21 , Thus there are rotational movements of the cover elements 5 possible with a rotation angle of more than 180 °. The connections of the cover elements 5 among themselves also have a stabilizing effect on the entire construction. Any position of the cover elements for optimal solar energy generation 5 can be set with the solar modules because they can be operated simultaneously using both axes of movement (center axis 21 and geometric axis of rotation 17 ) can follow the course of the sun. At the same time there is a shading of the waste dump 16 realized, which can be energetically effective for air-conditioned areas of the winter sports facility (see 6a . b ). A vertical position to the horizontal of the terrain and a position of the cover elements which has been pivoted through more than the rotation angle of 90 ° of the vertical position 5 (Tilt over the cover elements 5 ) serves to repel snow, hail and rain from the solar modules. In a mutually stepped position, the cover elements 5 for drainage of precipitation to the foot of the lowest arranged cover element 5 where rainwater can be drained off for further use in a suitable sewer or collector. At the same time, the waste dump is 16 through targeted positioning of the cover elements 5 can be estimated from directed driving rain and erosion. The connection of the cover elements 5 could advantageously be done with ropes on the top and lower end of the supporting structure 7 to be redirected via rollers. One or more of these roles could simultaneously with one or more drives for pivoting the cover elements 5 be provided. However, it is also possible for each individual cover element 5 to be provided with a drive. But it can also rigidly attached cover elements in one position 5 can be used only around the geometric axis of rotation 17 are movable. This has the advantage that the additional load of the support structure 7 , which involves a movable construction for the cover elements, is avoided. It is also possible for the cover element 7 is formed by a self-supporting solar module to also reduce weight.

The supporting structure 7 is with the bearing block 18 on a modeled massive static core 22 attached, which can also be used as a substructure for stabilizing the subsoil of the spoil tip and in a superstructure over the top of the cone-shaped spoil tip 16 can protrude. The higher the bearing block 18 through the superstructure of the static core 22 is positioned above the summit, the greater the distance between the supporting structure 7 and thus the cover elements 5 to the surface 3 the spoil tip 16 ,

6a . b shows the use of the dump 16 to obtain the energy and precipitation resources in combination with an ice and snow sports facility with covered, air-conditioned downhill or toboggan runs 23 on the same slag heap 16 , which uses the resources obtained.

The arrangement described above can vary depending on the length of the supporting structure 7 intercepted in sections. The interception and the circular movement of the supporting structure 7 takes place with a running structure 20 , for example from rail-guided wheels or from sliding surfaces with sliding film depending on the size or weight of the supporting structure 7 can be carried out to reduce the required rotational movement force. The axes of rotation (center axis 21 ) of the cover elements 5 whether horizontally or vertically aligned is in their center of gravity in order to minimize this rotational force.

The open structure of the entire construction allows for rear ventilation and thus prevents overheating of the construction or the surfaces and thus increases the efficiency of solar modules. Since certain weather situations are mutually exclusive, for example sunshine and rain, it is possible to achieve an optimal adaptation to any weather situation through this construction. Another advantage of this construction is that in certain weather situations, for example hail, the cover elements 5 can be averted from this danger with the solar modules. By tracking and aligning the cover elements 5 it is possible to protect areas underneath (e.g. planting areas) and structures (e.g. winter sports halls) from erosion and intense sunlight, thus reducing damage and energy costs. To do this, the distance between the supporting structure 7 with the cover elements 5 from the surface 3 the spoil tip 16 be chosen so that the free movement of the entire device is guaranteed over underlying surfaces and structures. The highest possible efficiency is achieved if the device can follow the sun for the entire duration of the sunshine. With a northern latitude of 51 degrees, this means a tracking of approximately 240 degrees.

There would be an optimal use of energy if the tracking system could turn around its axis once in a day and thus automatically follow the sun. If the necessary freedom of construction is not guaranteed, the tracking system must be returned to the point of sunrise on the horizon after sunset. The greater the possibility of inclination of the device to the vertical, the greater the irradiated area of the cover elements 5 when the sun is low (sunrise / sunset). The inclination of the construction and the size and number of cover elements 5 With the solar modules, the local conditions can be adapted, for example, according to latitude, as well as the need. As the size of stationary solar systems increases, it becomes more difficult to keep them free of snow in the winter months and to protect them in dangerous situations. This disadvantage is largely eliminated by the proposed arrangement.

Special use of the arrangement on industrial bulk or waste dumps:

• - When using this arrangement on a newly poured conical dump 16 , the solid, static core 22 in the geometric axis of rotation 17 be used to stabilize the heap by connecting (stranding) with the surface 16 contribute.
• - To prevent large surfaces from slipping 3 to prevent steep slopes are graded. This Gradations that run around the mountain can advantageously be used to intercept the supporting structure 7 be used. This also gives the option of a continuous tracking of the supporting structure 7 by 360 degrees.
• - With a complete superstructure of the waste dump 16 With a tracking device, the surfaces relevant for solar heat and solar power generation can be 3 (Sector of approx. 90 degrees) can be covered with dedicated solar modules The rest of the surfaces 3 (Sector of approx. 270 degrees) can with cover elements 5 can be equipped without solar modules. This enables a full-surface use of rainwater and thereby prevents unwanted erosion and unwanted penetration of water in, for example, heaps with environmentally harmful material.
• - The rainwater collected can be selectively combined with facilities for utilizing industrial water on the surface 3 be distributed. This enables agricultural management.
• - By overbuilding the spoil tip on all sides 16 is a better distribution of forces on the static core 22 given.
• - The Rainwater can be found in open catch basins or in closed ones collection containers are collected, which in variable filling for force or weight distribution could serve on the complex device.

1

Geländeerhebung

2

Schallschutzwall

3

Oberfläche

4

Solaranlage

5

Abdeckelement

6

Böschungsseite

7

Tragkonstruktion

8

Fußniveau des Schallschutzwalles

9

Fußelement

10

Träger

11

Verbinder

12

verdichteter Untergrund

13

Kunststoffwinkel

14

Zwischenraum zwischen Abdeckelementen

15

Erosionsschutzstreifen

16

kegelförmige Abraumhalde

17

geometrischen Drehachse

18

Lagerblock

19

Führung

20

Fahrkonstruktion

21

Mittenachse des Abdeckelementes

22

statischen Kern

23

Abfahrts- oder Rodelpisten

LIST OF REFERENCE NUMBERS

1

site survey

2

Soundproofing Wall

3

surface

4

solar system

5

cover

6

slope side

7

supporting structure

8th

Foot level of the noise barrier

9

foot element

10

carrier

11

Interconnects

12

compacted underground

13

Plastic bracket

14

Space between cover elements

15

Buffer strips

16

conical slag heap

17

geometric axis of rotation

18

bearing block

19

guide

20

driving construction

21

Center axis of the cover element

22

static core

23

Downhill or toboggan runs

Claims (33)

Arrangement for the cover sheet of terrain elevations, such as bulk or tailings, noise protection embankments or flood dams or the like., Characterized by an at least partially inclined and / or curved surface, that a supporting structure ( 7 ) for holding cover elements ( 5 ) is provided, which with at least one cover element ( 5 ) which is at a distance from the surface ( 3 ) the site survey ( 1 ) are arranged and the surface ( 3 ) the site survey ( 1 ) at least partially cover. Arrangement according to claim 1, characterized in that the supporting structure ( 7 ) and / or the cover elements ( 5 ) Have means that serve to generate solar energy and / or precipitation. Arrangement according to claim 1 or 2, characterized in that the site survey as a noise barrier ( 2 ) of a freeway and the supporting structure ( 7 ) on the side of the slope facing away from the motorway ( 6 ) of the noise protection wall ( 2 ) is arranged. Arrangement according to one of claims 1 to 3, characterized in that the supporting structure ( 7 ) has a semitrailer that is at the foot level ( 8th ) the site survey ( 1 ) is attached and essentially on the surface ( 3 ) rests. Arrangement according to claim 4, characterized in that the support bearing is spaced transversely to the longitudinal direction of the noise barrier ( 2 ) trusses ( 10 ) and foot elements ( 9 ) consists. Arrangement according to claim 5, characterized in that the carrier ( 10 ) slightly in the terrain survey ( 1 ) are embedded. Arrangement according to one of claims 5 to 6, characterized in that the foot elements ( 9 ) each consist of a concrete body and with the beams ( 10 ) are connected. Arrangement according to one of claims 5 to 7, characterized in that in each case a foot element ( 9 ) and a carrier ( 10 ) consists of in-situ concrete. Arrangement according to one of claims 5 to 7, characterized in that the foot elements ( 9 ) in the foot level ( 8th ) the site survey ( 1 ) are embedded. Arrangement according to one of claims 5 to 9, characterized in that the supporting structure ( 7 ) in the longitudinal direction of the noise barrier ( 2 ) aligned and spaced connectors ( 11 ), which on the carriers ( 10 ) are mounted. Arrangement according to one of claims 1 to 10, characterized in that the supporting structure ( 7 ) is at least partially horizontally and / or vertically displaceable. Arrangement according to one of claims 1 to 11, characterized in that the supporting structure ( 7 ) is at least partially driven. Arrangement according to claim 1 or 2, characterized in that the supporting structure ( 7 ) on a geometric axis of rotation ( 17 ) an at least partially rotationally symmetrical terrain survey ( 1 ) is rotatably mounted and at least partially around the outer circumference of the terrain elevation ( 1 ) is guided. Arrangement according to claim 13, characterized in that the supporting structure ( 7 ) is at least partially driven. Arrangement according to claim 13 or 14, characterized in that the terrain survey ( 1 ) as a conical slag heap ( 16 ) and the supporting structure ( 7 ) on the surface ( 3 ) of the conical spoil tip ( 16 ) is arranged. Arrangement according to one of claims 13 to 15, characterized in that in the geometric axis of rotation ( 17 ) the site survey ( 1 ) a static core ( 22 ) for the construction and / or for the stabilization of the terrain elevation ( 1 ) is formed on which the supporting structure ( 7 ) is rotatably mounted. Arrangement according to claim 16, characterized in that the static core ( 22 ) has a media guide shaft. Arrangement according to one of claims 13 to 17, characterized in that the supporting structure ( 7 ) in at least one tour ( 19 ) around the outer circumference of the site survey ( 1 ) is movable. Arrangement according to one of claims 1 to 18, characterized in that the supporting structure ( 7 ) can be moved pneumatically or hydraulically. Arrangement according to one of claims 1 to 19, characterized in that the cover elements ( 5 ) movable, especially around one of its central axes ( 21 ) are designed to be pivotable. Arrangement according to one of claims 1 to 20, characterized in that the cover elements ( 5 ) can be adjusted perpendicular to the horizontal. Arrangement according to one of claims 1 to 21, characterized in that the cover elements ( 5 ) are designed to be pivotable by at least 180 °. Arrangement according to one of claims 1 to 22, characterized in that the cover elements ( 5 ) are designed such that they can be used for solar power generation and / or solar heat generation. Arrangement according to one of claims 1 to 23, characterized in that the cover elements ( 5 ) are designed as precipitation guidance areas for the production of precipitation. Arrangement according to one of claims 1 to 24, characterized in that the cover elements ( 5 ) are designed as shading elements and / or weather protection elements. Arrangement according to one of claims 1 to 25, characterized in that a controller is provided which controls the movements of the supporting structure ( 7 ) and / or the cover elements ( 5 ) electronically controlled. Arrangement according to claim 26, characterized in that the control is operatively connected to a sensor system, so that the direction of movement and the speed of movement of the supporting structure ( 7 ) and / or the cover elements ( 5 ) is executable depending on the weather. Arrangement according to one of claims 1 to 27, characterized in that that facilities are provided that use the energy obtained in save a storage medium suitable for recycling. Arrangement according to one of claims 1 to 28, characterized in that that facilities are provided that measure the rainfall save in a storage medium suitable for recycling. Arrangement according to one of claims 13 to 29, characterized through the combination with an air-conditioned sports and leisure facility. Arrangement according to one of claims 13 to 30, characterized by the combination with an ice or snow sports facility with downhill and toboggan runs ( 11 ). Arrangement according to one of claims 13 to 31, characterized through the combination with plants that serve the production of plants. Arrangement according to one of claims 13 to 32, characterized by combining it with plants that use the precipitate obtained for the supply of process water in commercial facilities, leisure facilities, in buildings, use in plant production and / or for artificial snow production.