EP0708863A1

EP0708863A1 - Structure of a walking surface for horses, in particular for a riding area and a method of producing the same

Info

Publication number: EP0708863A1
Application number: EP95919449A
Authority: EP
Inventors: Norbert Funke; Ferdinand Leve
Original assignee: Funke Kunststoffe GmbH
Current assignee: Funke Kunststoffe GmbH
Priority date: 1994-05-13
Filing date: 1995-05-12
Publication date: 1996-05-01
Also published as: CZ328995A3; WO1995031606A1; HUT74233A; AU2527395A; PL312581A1; DE29522213U1; DE4416943C2; SK164295A3; PL176888B1; DE4416943A1; HU9600011D0

Abstract

The proposed walking surface for horses, in particular for riding areas, and the method of producing the same are simple and inexpensive, ensure strength and good water regulation and allow horses to walk safely. To that end, a lattice board layer (63) made of interconnected floor lattice boards (1) is laid on the foundation soil (50). The floor lattice boards (1) consist of a plurality of contiguous cells in a honeycomb structure. Each cell has a floor opening in a closure base, a cell wall diameter approximately equal to the diameter of a horse's hoof (100) and grooves situated approximately centrally on each upper edge of the cell walls of each cell. Tread layer material (61) which is applied to the lattice board layer (61) fills the cells and forms a layer which is simultaneously a tread layer, support layer and separation layer (62, 64, 65).

Description

Construction of a movement area for horses, in particular riding arena construction, and method for its production

The invention relates to a structure of a movement surface for horses, in particular a riding arena structure, in which a supporting, separating and footing layer is applied to a foundation, and a method for its production.

In addition to riding arenas, the movement area structure should also be suitable for paddocs, polo courts and the like.

A construction of a movement area for horses is known from DE 38 39 543 AI, the procedure being as follows: a drain mat is placed on a surface and a grid pattern is arranged on the drain mat. It consists of individual rectangular boxes, each with a side length of 625 mm and a partition height of 100 mm. The box-shaped grid elements are divided and reinforced on the inside by diagonally arranged partition walls. The vertical corner edges of the square grid elements are each joined together like a checkerboard. A grit made of porous lava stone is poured into the grid structure thus formed as a base layer, which ensures water flow. Then a cover layer is poured on. A disadvantage is that the lava stone chips filled into the grid can only be compacted to a certain degree without losing their water-carrying properties. If such a movement surface built up with great effort is mounted, the fact that the grids are designed to be substantially larger than a horse's hoof results in the covering layer being mixed with the chippings and, as a result, in the clogging of the water guiding layer. In addition, the upper narrow surfaces of the side walls can be exposed, on which the horse can slide and injure itself, especially when jumping. In addition, normal grit is not suitable for the footing and is therefore avoided.

⁵ A construction of riding arena movement areas is also out

HOFFMANN, Gerlinde; WAGNER, Hans-Dietrich: Orientation aids of the equestrian and stable construction, 5th edition, FN-Verlag der DEUTSCHEN REITERLICHEN VEREINIGUNG GmbH, Warendorf 1992, pp. 125-134. Here ⁽ ** ⁾ the structure has a building ground and a superstructure. The building ground consists of a substructure, which may be provided with fillings. Any drainage that may be necessary is laid in the ground.

5 Then the surface of the subsoil is leveled and provided with a slope. A base layer is applied thereon, a release layer on the base layer and a footing layer on the release layer. The base layer serves as a stable base. Since it must be permeable to water and frost-resistant, coarse gravel is used here. The base course can be dispensed with if the subsoil itself fulfills these requirements. The separating layer has the task of having a water-removing and water-storing effect. It 5 is made of water-permeable mineral concrete or water-permeable asphalt. The footing is then applied to the separating layer. The separating layer made of concrete or bitumen tends to clog. This requires extensive cleaning. If this cleaning is no longer possible, a new set-up must be carried out. A riding arena constructed in this way is very expensive.

The invention is based on the object of specifying a construction of a movement area for horses, in particular the construction of a riding arena, and a method for its production which are simple and inexpensive and have a high level of stability, good water regulation ability and safe movement of the horses on the Allow movement area.

According to the invention, the object is achieved in a structure by the features of claim 1 and by a method according to claim 11.

The advantages achieved by the invention are in particular that the grid plate layer with the components of the footing material present in the cup elements takes on both the function of the base layer and that of the separating layer, the dimensions taking into account the size of the horse's hooves.

Because of these mechanical and structural properties, the filled grid plate layer is able to take on the function of a base layer. Another and very important advantage is that the grid plate layer is water-permeable due to the openings. Together with the material present in the cells, it thus acts as a separating layer in such a way that it is permeable to water and drains off excess water.

The grid plate layer can be in one piece or be formed in several parts. In the case of a one-piece construction, the base plate is manufactured in one piece with the openings and the cup elements above. In the case of a multi-part construction, the base plate with the openings is produced and the individual cup elements are fastened thereon.

Metals, surface-coated or surface-refined metals, plastics or recycled plastics are suitable as materials for the production of the grid plate layer, also in combination. The floor grid layer is frost-resistant. The openings in it are so large that they cannot tend to clog. Due to its configuration and other properties described, the

Bottom grid plate layer all requirements with regard to shear strength, that is to say a resistance to inclined forces which are exerted by the occurring hooves of the running and jumping horses.

Another advantage is that the cup elements increase the sure-footedness and the forces acting on the separating layer can be absorbed in such a way that the pedal layer does not slip on the separating and supporting layer. If a horse steps on such a superstructure with its hooves, the tread has shear strength compared to the separating and supporting layer. Another very important advantage is that the grid plate layer can be laid out directly on an essentially flat soil, which can be partially overgrown with grass. The grid plate layer ensures that the load is no longer transferred point-wise, but rather in terms of area, and thus counteracts compaction of the subsoil. The apertured base layer with the cup elements is formed by the features of claim 2.

In addition to the hexagonal structure, the cup elements can have a square or other polygonal, a round, an oval, an ellipsoidal and / or further prismatic shape; they can also partially enclose the openings, for example in an octagon with one side left open.

Due to the height of the individual cells and the length of their side walls, each preferably about 34 mm (± 5 mm) with a wall thickness of preferably about 1.5 - 15 mm, a very stable grid plate layer is designed, which can absorb high loads. The floor openings are permeable to water, so that the composite floor grilles take over the function of the separating and supporting layer. The cutouts prevent the horse's hoof from sliding on the exposed grid plate layer. The cutouts at the top of the cells also have the effect that moisture stored inside the cells can spread outwards more easily.

The floor grilles are light, easy and quick to install (up to 40 m ² per person per hour). This not only gives top sports clubs the opportunity to build a wing for entering moving horses, that is to say a riding arena or the like, that meets the highest and highest demands, but also rural riding clubs or private individuals.

It is advantageous to regulate the water permeability and the water storage by means of a collar pointing the bottom opening in the direction of the interior of the cell. enough. When water occurs on the footing, it is passed on downward, reaches the boundary layer below the base plate and is thus discharged through the openings as excess water. The collar, which can be varied in height, makes it possible to store water in this part of the individual cells. This has the effect that the moisture remaining in the footing layer can be regulated in a targeted manner.

It is advantageous if the upper edge of the walls of each cell is at least partially provided with an elastic layer. This elastic layer dampens the force emanating from the striking horse's hooves and has an elastic effect and is also non-slip.

It is advantageous if the base plate of the base grid plate is at least partially provided with a second elastic layer. It is possible to apply both elastic layers on both sides of the individual cells. This ensures that the grid plate layer can be provided on one or both sides with an elastic layer. The formation of such elastic layers is particularly advantageous in jumping and dressage riding tournaments.

It is advantageous that each floor grid plate is provided with connecting elements according to claim 7. Thus, for example, a recess can be made in at least every second inclusion angle on an outside formed by the walls which are at an angle to one another, the recess on the opposite outside forming a compatible T-shaped hooking element in the angle formed between two chamfered walls of the same cell row opposite, on the shoulder bevels are arranged. The connecting elements enable a very simple and non-positive connection of the individual floor grid plates. The fact that two edge elements lie side by side increases the strength of the grid plate layer. On the other hand, the connecting elements designed in this way ensure that there is a closed and in particular flat grid plate layer.

The use of the floor grid panels therefore brings the following outstanding advantages:

- Elaborate earthwork is no longer necessary;

- The laying of the floor grid panels and the application of the footing can be done in-house;

- low weight of the floor grid plates (approx. 5 kg / m ² ); light and easy to install;

- reduction of overall construction costs;

- versatile;

- reusability;

- ideal combination of stability and necessary elasticity;

- near-natural joint stress;

- water reservoir, therefore little watering in summer;

- good water flow, therefore less dust pollution;

- high surefootedness and shear strength; - weather resistance.

Before laying out the grid plate layer, it is advantageous to provide the building ground with a sand layer on which the grid plate layer is arranged. Filling sand or the like is suitable as sand (cf. corresponding DIN).

The sand is poured onto the flat, at least partially overgrown soil at a height of between 50 and 200 mm and then smoothed and leveled. The sand and the bottom openings of the cells ensure a targeted drainage of the water reaching the footing. Is z. If, for example, a riding arena is built up at a point where a lot of water occurs, it is advantageous to use a somewhat thicker layer of sand. This makes it possible to derive and store the

Water in the footing possible.

It is advantageous if a nonwoven web is laid out and / or the sand layer is applied as the building ground on a planarly planed and inclined surface of a subsurface, over which the grid plate layer and the footing layer are arranged. A drainage device can be inserted into the underground in a known manner. Both measures, together with the specially designed grid plate layer, ensure targeted water absorption, drainage, storage and discharge via the drainage system to specially provided drainage shafts.

The method for solving the problem is characterized by the features of claim 10.

The advantages of the method according to the invention are in particular that the superstructure of a movement area reduced to just two layers. The grid plate layer laid out on a substrate and the footing material applied thereon realize the base layer, the separating layer and the footing layer. Elaborate earthworks can be omitted.

A layer of sand between 50 mm and 250 mm can be applied to the subsoil of the building ground. The footing material can be heaped up at a height of 80 mm to 130 mm, preferably about 100 mm, measured from the upper edge of the walls of the floor grid panels. Both the sand layer and the footing material can be leveled and leveled accordingly.

At this point it should be noted that floor grating plates are known from EP 04 00 158 AI, US 4,621,942, DE 86 22 303 Ul, EP 51 69 957 AI. They have an essentially honeycomb-like configuration and consist of a multiplicity of chambers which have an opening at the bottom. Recesses are made on the side walls. The individual floor grille panels can be hooked together by connecting elements. However, they are designed as lawn grids only for greening areas, in particular on driveways, paths, parking spaces, roadsides, etc. The chambers of the lawn grids are not completely filled with soil and the area thus formed is sown with grass seeds. The upper edge of the side walls has the task of protecting the lawn growing in the chambers from being destroyed when entering the green area. Through the opening at the bottom, the lawn is able to get into the soil below. The recesses in the side walls allow grasses to grow from one chamber to another.

The invention is explained below using an embodiment example explained in more detail.

Show it:

1 shows a riding arena structure in a schematic side view,

FIG. 2 shows a riding arena structure according to FIG. 1 with a water distribution representation,

3 shows a riding arena structure according to FIG. 2 in a schematic top view,

4 shows a floor grid plate in a schematic top view,

5 shows a section through a cell of a floor grating plate according to FIG. 3 along the line V-V

Fig. 6 shows a coated floor grid plate according to FIG. 3 in a schematic plan view and

7 shows a section through a cell of a floor grid plate according to FIG. 6 along the line VII-VII

1 consists of a building base 50, above which a superstructure 60 is arranged.

The main component of the subsoil 50 is its subsurface 52. A drainage device 54 can be installed in the subsurface 52. It consists of drainage pipes 54.1 and 54.2, which have a flushing shaft on one side and are connected on the other side by a collecting line 54.3, as shown in FIG. 3. The manifold 54.3 opens into a manifold 54.4. The details of the drainage device are constructed in a known manner, ie the drainage lines must have a certain gradient, at least 0.3%. The drain trenches must be filled with water-permeable materials. Subsequently, the subsurface 52 is given a surface 51 by leveling and the simultaneous application or introduction of a slope. The slope of the surface 51 can have a gable roof, pent roof or hipped roof shape. If the surface 51 is arranged in the form of a gable roof, one or more drainage pipes 54.1 and 54.2 are arranged in the region of the side halves of the surface. It is possible to attach the drainage pipes 54.1 and 54.2 directly to the edges of the surface as shown. If a pent roof configuration is used, only one drainage pipe is to be installed on the slanted side of the pent roof-shaped surface. If the surface 51 is in the form of a hipped roof, the drainage pipes are arranged in a ring.

The superstructure is arranged on the surface 51. A nonwoven web 53 can be placed on the surface 51. This is a specially water-conducting and water-permeable fleece, which is known under the name GEOTEX. It separates the superstructure from the substructure. A layer of sand 56 is then applied to the nonwoven web 53 or else directly to the surface 51. The fact that sand or another water-conducting material is used ensures that excess water can be removed. The thickness of the abovementioned sand layer 56 depends on the building ground or on the material used or on the system. It is possible to dispense with the nonwoven web 53, the drainage and / or the sand layer 56 if the building ground 50 already has the appropriate properties.

A grid plate layer 63 is laid out on a base 50 prepared in this way. In this case, floor grating plates 1 are used in a new way. Each floor grid plate 1 according to FIGS. 4-7 is manufactured in one piece and consists of a large number of contiguous polygonal, ie, hexagonal cells 2 arranged in a honeycomb structure. In a base plate 3 Each cell 2 has an approximately circular bottom opening 4 which can be surrounded by a collar 7 (see also FIGS. 5 and 7). The collar 7 enables the formation of a water reservoir at the bottom 4 'of the cell 2 when the cells 2 are filled with a footing material.

When this water reservoir is overfilled, excess water passes over the collar 7 through the bottom opening 4 into the underlying sand layer 56. The bottom grid plate 1 is preferably made of non-corroding and frost-resistant plastic. On the upper edge of each of the walls 5 forming the cells 2 there is an approximately semicircular recess 6 which, on the one hand, serves to distribute and discharge excess water stored in the individual cells 2 and contributes to stability or slip resistance.

The one-piece floor grid plate 1 can be connected to an adjacent floor grid plate by means of connecting elements, the connection elements being arranged on opposite sides of each floor grid plate 1 in such a way that hooking elements 9, 9 'are located on one side of the floor grid plate 1. are arranged, which engage in recesses 8 provided on the adjacent floor grid plate. If a hooking element 9 lies between two walls 5 which are inclined at certain angles of inclusion, the hooking element 9 is formed with corresponding bevels.

A plurality of pairs of interlocking elements 8, 9, 9 'can be arranged in each floor grid plate 1 in each fastening direction on opposite sides of the plate.

5 specifically shows that surrounding the bottom opening 4 Collar 7, the semicircular recesses 6 in the walls 5 and the recess 8 in the base plate 3 and the abutting region of the walls 5, wherein a protrusion of the connecting element 9, which has a shoulder, can be inserted into the recess, so that a Connection to an adjacent floor grid plate 1 is created. The recesses 6 can, starting from a floor grid plate surface level n, be lowered to a depth t. The depth, the rounding, the width and the like can be adapted in accordance with the respective operating conditions. The collar 7 can also be varied up to a height H, starting from the floor level B of the floor 4 '. The height of the collar is designed to be adapted to the respective water regulation conditions.

6 and 7, an elastic layer 10 can be applied to the floor grid plate surface level n according to FIGS. 6 and 7. This can be a rubberized, plastic elastic or similar layer of a certain width and height. The dimensions and the elasticity of this elastic layer 10 depend on the particular load conditions that occur. It is also possible to apply a further elastic layer 10 below a base plate 6 of a lawn grating element 1. The elastic layer 10 can either be designed similarly to the layer 11 already described or can be made softer or less elastic. This layer 10 can be made more elastic in that, for. B. certain soft rubber, foam rubber and the like can be applied in a thickness which can be up to 50% of the height of the individual cells 2.

With floor grid plates 1 designed in this way, the connecting elements 8, 9, 9 'are mutually hooked against one another. the grid plate layer 63 is laid out on the applied sand layer 56, as shown in FIGS. 1 and 2. The floor grilles 1 are easy and quick to install (up to 40 m ² , person / hour). They are also stable and can be loaded up to 100 t / m ² . Because the height and length of each wall 5 of each cell 2 is approximately 34 mm and the thickness of the walls is 3-5 mm, these good properties, in particular the high load-bearing capacity, can be achieved. Of course, it is also possible to dimension the cell differently in terms of its dimensions and / or the thickness of its wall thickness. The length of the cell walls can vary between 31 mm and 65 mm. With a hexagonal honeycomb shape of the cells there are 2 distances from the cell wall to the opposite cell wall from 52 mm to 97 mm and from cell corner to the opposite cell corner from 60 to 115 mm and with a square honeycomb form distances from the cell wall to the opposite cell wall from 31 mm to 65 mm and from cell corner to the opposite cell corner from 44 mm to 63 mm. The variation of the individual values depends on the respective load conditions that occur and the sizes of the horse's hooves that are to be expected.

The footing material 61 is applied to the grid plate layer 63 and the cells 2 are filled with the footing material 61 (cf. FIG. 3). Depending on the type and intensity of use, the footing 62 has a thickness of 8-13 cm. The footing material 61 usually consists of cf. HOFFMANN and WAGNER, as indicated above)

- Sand

Places with pure sand covering are less shear-resistant (elastic) than mixtures of wood or plastic chips and tend to be dusty in dry weather.

- sand with aggregates Additives such as wood chips (softwood) or plastic materials serve to improve the resistance to treading and water retention (dust binding). - wood chips (with friction)

Pure wood chips are pleasant to prepare in the early years and hardly susceptible to dust, but are at risk of rotting after a few years.

The focus of use should be taken into account in the composition of the footing material: for jumping and driving "harder", for dressage and vaulting somewhat "softer". These properties are varied by the sand used and the proportion of aggregates.

The use of suitable sand is important! River sands (possibly washed) with a grain size of approx. 0/3 with as little as possible zero components (clay, loam components, "sludge particle components") are recommended. In addition to the grain size, the grain shape and surface, the grain size distribution is used in particular for the assessment.

With regard to the wood aggregates, wood chips, sawdust, wood shavings, gate shavings etc. come into question.

"Wood chips" are understood to mean the flat (1-2 mm thick), approx. 2-7 cm long and 0.5-3 cm wide wood particles suitable for riding arenas. Depending on the quality of the sand, the wood chips used and the type of use, the proportion is 10-50% by volume, with at least 50% coarser components (1-2 mm thick, 5-7 mm long) and a maximum of 25% finer parts (Coarse sawdust should be included.

A special feature is long-fiber, coarse wood shavings (peeling shavings) that interlock well. This forms a over a relatively solid part of the footing 62 loose edition. However, such tread layers 62 are difficult to maintain.

Also recycling material, e.g. B. plastic residues, can optionally be used, as known per se.

The various components of the footing material 61 should be applied as premixed as possible, since the desired mixture does not result from the preparation or only after a very long time.

By laying the floor grid plates 1 to form a grid plate layer 63, the cells 2 of which are subsequently filled with the footing material 61, the grid plate layer thus formed takes on the function of a separating layer 65. This separating layer 65 plays a special role in the construction of the layer sequence of the riding position. Due to its special design, it is permeable to water and able to remove excess water. Since the openings 4 have a diameter which is greater than or equal to the distance from one cell wall to the opposite, this separating layer 65 thus formed does not tend to clog the pores. With the underlying sand layer 56, it is possible to vary the conductivity and conductivity of the separating layer 65.

The grid plate layer 63, the cells 2 of which are filled when the footing material 61 is applied, also takes over the function of a base layer 64. The base layer 64 serves the footing layer 62 as a stable base. Thanks to its special training, it is permeable to water, is able to drain excess water and is frost-resistant. Their thickness and structure is determined by the height and design of the floor grid plates 1 so that they are largely independent of the load capacity of up to 100 t / m ³ Load-bearing capacity of the subsoil meets the prescribed requirements.

It is therefore possible that the grid plate layer in

5 Dependence on the components of the footing material 61 arranged in and on it assumes both the function of the base layer 64 and the function of the separating layer 65. As a result, the riding arena thus constructed and hitherto constructed retains a particularly advantageous design, which has an effect particularly in terms of high load-bearing capacity and extremely low construction costs.

A superstructure 60 finished in this way has the advantage that when a horse's hoof 100 appears on the footing 62, as shown in particular in FIGS. 1 and 2, there is a force distribution 101 such that the footing 62 has the required shear strength against the obliquely acting forces and the hooves do not damage the base structure of the base layer 64. The separating and supporting layer also have such a roughness that the footing 62 cannot slip on them.

Another very important advantage is that water 70 passes through the tread layer 62 and from there is led into the cells 2 of the floor grid plate layer 63 filled with corresponding substances, in particular the substances of the separating layer material 61. The bottom openings 4 of the individual cells 2 have a water-draining effect, the collar 7 water-storing and the

Recesses 6 water-distributing. Through the nonwoven web 53 lying below the sand layer 56, the water 70 is fed in a very targeted manner to the individual drainage pipes 54.1 and 54.2 (cf. FIGS. 2 and 3). This water regulation system 5 gives the floor grille a wider range of applications. It is achieved that the footing 62 is not over-moistened because of the incident Water, which proves to be superfluous, is immediately directed into the layers underneath down to the drainage pipes and then discharged into the individual collecting shafts.

It is also achieved by the floor grid plates 1 that a certain uniform residual moisture is retained in the footing layer, so that the footing layer 62 is easy and safe to prepare. In addition, it is achieved that explosive water required for moistening the footing 62 is used more uniformly and more economically. This makes the maintenance of the riding arena easier and cheaper.

A grid plate layer 63 with a footing layer 62 placed thereon can be applied even on a flat surface 52. If the underlying surface has appropriate water-removing properties, a riding arena can be produced with very simple means of use.

It is also important that the introduction of elastic layers 10 and 11 together with the grid plate layer 63 significantly increases or varies the quality of the riding arena.

It is also possible to vary the grain size of the individual starting materials or the size of the wood additives depending on and in cooperation with the grid plate layer 63. The composition, the grain size, the thickness of the elastic layers, the height H of the collar 7 and the depth t of the recesses 6 can be determined by simple tests. Even if the floor grid plate 1 has the optimal strength, laying and liquid sinking properties in its honeycomb structure, it is entirely possible to also include the floor grid plate a square, rectangular or round structure. The cells 2 have the corresponding structure.

Reference list:

1 floor grid plate

2 cell

3 base plate

4 bottom opening

4 'floor

5 wall

6 recess

7 collar

8 recess

9, 9 'interlocking element

10 elastic layer

11 elastic layer

B floor level

H height n floor grid surface t depth

50 ground

51 surface

52 underground

53 nonwoven web

54 drainage device

54.1 Drainage pipe

54.2 Drainage pipe

54.3 Collective line

54.4 Collection shaft

54.5 Flushing shaft

56 layer of sand

60 superstructure

61 Footing material

62 footing

63 grid plate layer

64 base course

65 separation layer

70 water

100 horse hoof

101 distribution of forces

Claims

1. Building a movement area for horses, especially for a riding arena, in which on a

Soil (50) a base, separating and footing layer

(62, 64, 65) are applied, characterized in that a grid plate layer (63) is laid out on the building ground (50) in order to produce the layer sequence mentioned, wherein

- The grid plate layer (63) from an opening (bottom openings 4) provided base plate 5 (3) and

- Standing on the base plate (3), the openings

(4) partially surrounding, downwardly open, prismatic cup elements (cells 2), and 0 - the diameter of the openings (4) is greater than or equal to the clear width of the cup elements (2), the diameter of which in turn is approximately 35 mm or more ,

- And that in and on the grid plate layer (63) ° a footing material (6) is inserted and applied, which consists of materials known per se for riding arena structures, such as wood chips, sand or sand with additives, the components of which fill the cup elements (2) and, together with the grid plate layer (63), simultaneously forms the treading, supporting and separating layer (62, 64, 65).

2. Structure according to claim 1, characterized in that the grid plate layer (63) is composed of 5 interconnected and with an integrated

Base plate (3) provided floor grid plates (1), which consist of a plurality of arranged in honeycomb structure neten, contiguous cells (2) with a bottom opening made in the final base plate

(4) exist where the diameter of the clear

Width of the cells (2) approximately the diameter of one

Horse hoof (100) corresponds.

3. Structure according to claim 2, characterized in that the walls of the cells (2) are provided with recesses (6) arranged approximately centrally on each upper edge of the walls.

4. Structure according to claim 2 or 3, characterized gekennzeich¬ net that the walls of the cells (2) are at least partially provided with an elastic layer (11) at their upper edge.

5. Structure according to one of claims 1-4, characterized in that the bottom openings (4) of the base plate (1) are surrounded by a collar (7) pointing into the interior of the cell (2).

6. Structure according to one of claims 1-5, characterized in that the base plate (1) below its bottom is at least partially provided with a second elastic layer (10).

7. Structure according to one of claims 1-6, characterized in that each floor grid plate (1) is provided with connecting elements (9) in such a way that on an outside formed by the walls of the cells (2) T-shaped hook-shaped Ele duck (9) are arranged with a shoulder pointing towards the inside of the cells (2), which is opposite a recess (8) which is compatible with the hooking element (9) in the wall (5) in the corresponding row of cells on the opposite outside .

8. Structure according to one of claims 1-7, characterized in that the grid plate layer (63) on a subsoil (50) belonging sand layer (65) is arranged.

9. Structure according to one of claims 1-8, characterized in that a Vlies¬ 0 web (53) designed and / or as a building ground (50) on a planarly planed and inclined surface (51) of a substrate (52) Sand layer (56) is applied, over or above which the filled grid plate layer (63) is arranged.

10. Structure according to one of claims 1-9, characterized 5 in that a drainage device (54) is arranged in the underground (52).

11. A method for producing a construction of a movement area for horses according to claim 1 and 0, optionally further claims 2 to 10, with the following steps:

a) Laying out a grid plate layer (63) with a base plate (2) provided with openings, the openings of which are at least partially covered

Cup elements are surrounded on a building ground (50) and

b) applying a footing material (61) on and in the grid plate layer (63).

12. The method according to claim 11, characterized in that floor grid plates (1) are laid out on the building ground (50) and are connected to one another by joining 5 interlocking elements (8, 9, ').

13. The method according to claim 8, 11 or 12, characterized in that a layer of sand (56) of 50 to 200 mm in height is applied to a substrate (52) of the ground (50).

14. The method according to any one of claims 10 - 12, characterized in that the footing material (61) is applied in and on the grid plate layer such that it projects above the upper edge of the walls of the grid plates by a height of 60-130 mm.