EP2776628B1 - Ground covering for sports areas, and method for producing it - Google Patents

Description

The invention relates to a floor covering for sports surfaces and in particular for tennis courts and a method for producing a corresponding floor covering.

Coverings for sports surfaces and especially for tennis courts are known in the art. Usually just floor coverings for tennis courts in two basic categories, namely hard courts on the one hand and sand or clay meadows are divided on the other hand; the latter are also referred to as "clay courts".

Hard courts have relatively good playing characteristics, namely an even ball jump and a high ball speed. In addition, only a small amount of care and irrigation is required for hard courts. A disadvantage of conventional hard courts are the relatively high production costs, the high ball and shoe abrasion, a high ball jump and high stress on the ligaments, tendons and joints of athletes or players through the blunt and hard surface.

In contrast, in sand courts, the advantages are low production costs, a low ball speed, longer ball changes, good damping properties as well as advantageous turning and sliding properties of the athletes or players. A disadvantage of clay courts is the higher maintenance costs in comparison, the low frost resistance, the need for constant irrigation and an unequal ball jump.

Due to the advantages and disadvantages described, attempts have already been made in the prior art to simulate the play and sliding behavior of a pebble sand pad with simultaneously improved maintenance properties.

Thus, for example. EP 0 358 209 A2 and the DE 201 00 678 U1 a tennis court covering having a first layer of a resilient polymeric material and a second layer of hard sand solidified with a binder. As a sliding layer, a non-solidified clay layer is provided.

However, a problem of such a coating is a permanent rubbing of the scattered sliding layer, so that a high abrasion and thus wear of the lining is given. In addition to the need for frequent maintenance due to wear, the abrasion further reduces the water permeability of the thus ground lubricating material after only a short period of time. As a result, the covering becomes largely impermeable to water, which severely impairs controlled start and stop movements of the athletes or players as well as the sliding properties of the covering that are currently required in tennis sports. Therefore, in such a covering, the playing characteristics are already significantly deteriorated after a short playing time.

The DE 201 00 678 U1 and the EP 1 811 086 A1 disclose tennis court coverings with a carrier layer of granular rock material and a sliding layer of brick meal, wherein the brick meal is applied without binding to the carrier layer.

The DE-OS 2 258 566 proposes here to introduce brick flour in the not yet hardened surface of the base layer of coarse mineral material.

On the basis of the above-mentioned problems, it is an object to provide a floor covering for sports surfaces and in particular for tennis courts, which on the one hand has the advantageous playing characteristics of a clay court, but with improved care and maintenance properties.

The object is achieved by a floor covering for sports surfaces and in particular for tennis courts according to claim 1 and a corresponding method for producing a floor covering according to claim 8. The dependent claims describe preferred embodiments of the invention.

According to the invention, the floor covering has at least one layer with a first mineral particle material, a second particle material and a binder. An average grain size of the second particulate material is smaller than an average grain size of the first particulate material. The first particulate material is bound with the binder. The first mineral particulate material is repeatedly broken according to the invention.

The floor covering according to the invention thus has at least one layer with two particle materials which have different average particle sizes from one another.

In this case, the first mineral particulate material forms an open-pore scaffold due to the larger grain size, so that the second particulate material is at least partially disposed in the spaces formed by the scaffold - hereinafter referred to as "depot zones".

In the context of the present invention, the term "particle material" is understood to mean a (solid) substance which consists essentially of a large number of individual particles or grains and is also referred to as a particulate or granular medium.

The first particulate material is bound by the binder according to the invention, i. H. the individual particles of the first material adhere to one another in the layer of the coating and thus form a film-like composite. Naturally, it is not necessary in this case for each grain of the first particle material to be bound appropriately, or for it to be an entirely "rigid" composite. As explained in the following, it is rather preferred if the binder also has a certain elasticity in the cured state.

The mineral, multiply fractured first particulate material forms an open-pore scaffold, resulting in an advantageously stable construction of the floor covering. Due to the large number of smaller connection or bonding zones on the individual particles, the floor covering according to the invention has advantageous properties similar to a hard surface, namely a certain surface elasticity, which ensures an advantageous ball bounce. The binder also ensures that the water absorption of the particles of the mineral first particulate material is limited, which increases the frost resistance. The covering is thus particularly durable, since there is hardly any wear on the surface.

The invention combines the advantageous properties of a hard court with those of a clay court. The covering has only a low maintenance and can be installed on any existing substrate. In addition, the padding allows a controlled gliding, whereby a uniform ball jump and an average ball speed is achieved.

Due to the structure with first and second particle material, the coating is also "combi-elastic", which brings decisive advantages with regard to the pressure load and is gentle on the joints.

For example, in an adult athlete with a weight of about 70-90 kg, the coarse-grained first particulate material when running or jumping for a large force exertion by the mentioned surface elasticity. On the other hand, in an athlete, for example a child with a weight of about 30-40 kg, the second particle material contained in the depot zones exerts a point-elastic function. This ensures that the pressure on the ligaments, tendons and joints and the back muscles are protected.

Furthermore, the coating is largely resistant to wear, since due to the material combination only a small amount of wear occurs.

The second particulate material may have any suitable configuration, however, wherein the average grain size of the second particulate material is less than the average grain size of the first particulate material such that the second particulate material may at least partially fill the depot zone resulting from the first material.

As already discussed at the beginning, the first particle material is mineral and multiply broken. In this case, all suitable mineral substances come into consideration, which are present in particle form, for example. As a grain mixture or granules. In the context of the present invention, "mineral" materials are understood as meaning all minerals, in particular granite, basalt, quartz and, in particular, clay minerals, but also further processed materials, such as ceramics, ash, slag, brick chippings or turf material.

The second particulate material may likewise comprise a suitable grain mixture or granules.

According to the invention, both the first particulate material and after a subset of the second particulate material is bound with the binder. The binder may in this case be a natural and / or synthetic binder. For example, a suitable binder may comprise a cement and / or a polymer material and in the latter case, for example, epoxy resins and / or polyacrylates, in particular Polymethacrylate. The binder is preferably weather-resistant and / or water-impermeable.

The shape of the individual particles of the first and second particulate material is not restricted. However, the first mineral particulate material is multiply or doubly fractured mineral material, i. a mineral that is artificially minced. As a result, a substantially cubic shape of the particles is given, whereby the bond in the layer and the formation of sufficiently large Depotzonen is improved. Naturally, the first particulate material may have a smaller proportion of non-multiply fractured particles.

Suitably, the first particulate material has doubly crushed chippings and in particular clay granules.

According to a preferred embodiment of the invention, the second particulate material also optionally comprises a mineral material, with the second particulate material particularly preferably comprising quartz powder and / or calcined clay. As a result, once again improved durability properties of the covering are achieved.

According to the invention, the second particulate material comprises an elastic granulate. In this case, the second particle material may comprise a proportion of elastic granules, for example in admixture with a mineral material. Alternatively, the second particulate material may be completely formed as elastic granules.

The granules may be made synthetically or naturally. Preferably, the elastic granules of ethylene-propylene-diene rubber (EPDM) and / or styrene-butadiene rubber (SBR).

The floor covering according to the invention or the at least one layer can have first and second particle material in any desired mixing ratio, namely in accordance with the desired properties, in particular with regard to elasticity and ball speed.

Preferably, the layer has a thickness between 15-50 mm, and preferably 25 mm, i. the particulate materials are applied in an appropriate amount. After applying the first particulate material and before applying the second particulate material, the first particulate material should preferably be stripped or smoothed with a suitable device. Expediently, the layer thus formed has a proportion of interspaces or depot zones of 10 - 60% and in particular 40% by volume, which, as described at the outset, are filled at least partially by the second particle material in the finished covering.

The amount of the second particulate material may preferably be selected to include a majority, and especially at least 75, and most preferably at least 80 percent, of the second particulate material in the voids, i. the second particulate material is applied with "excess".

The corresponding slight excess of the applied second particulate remains on the surface. This allows a further improved sliding or a controlled braking. Because due to the presence of small excess on the surface and the substantially unbound particles forms in front of the shoe of the player in sudden stop movements a "brake wedge", which presses with high pressure against the edges of the Depotzonen. A further improved control of the movement is therefore advantageously possible.

According to the invention, a subset of the second material is bound by the binder. That the granules or particles of the subset are contained in the more or less solid composite of first particulate material and binder. For example, a suitable coating may be obtained by applying the second particulate material during the setting time of the binder, i. at a time when the binder is still partially liquid and not fully set.

The present preferred embodiment of the flooring according to the invention allows adjusting the elasticity of the covering depending on the application and the desired application. In the case of the present preferred embodiment, the subset described above is associated with the binder and the first particulate material, ie the individual Grains or particles of the subset stabilize the composite of the first particle material and binder. The elasticity of the coating is correspondingly reduced. The respective bound subset can be adjusted by appropriate choice of the setting time prior to the order of the second particulate material. The further the setting of the binding agent has already progressed during the application, the smaller is the bound subset in the later finished covering and the higher is its elasticity. Preferably, the subset based on the second particulate material is between 1-10%.

As already mentioned, the first particulate material and the second particulate material may have all suitable configurations, grain shapes and grain sizes as long as the average grain size of the second particulate material is smaller than the average grain size of the first particulate material.

Suitably, the average particle size of the first particulate material is between 3-20 mm, preferably between 4-10 mm and more preferably between 6-10 mm. The average particle size of the second particle material may alternatively or additionally preferably be between 0.1 and 5 mm, particularly preferably between 0.1 and 1.5 mm, and expediently between 0.5 and 1.2 mm. The use of the above-described second particulate material without zero component is particularly advantageous because a corresponding coating requires no irrigation and thus in the interior (eg. In tennis halls) and outdoors in all climates all year round playable.

According to a preferred embodiment of the invention, the second particulate material is applied in an amount of 0.8 to 4 kg / m 2 and in particular 1.5 kg / m 2, which has proven to be particularly advantageous in the case of the grain size mentioned above.

As already discussed, the binder can be a natural and / or synthetic binder. According to a preferred development of the invention, the binder has at least one water-impermeable polymer material.

Suitably, the binder is a polyurethane binder. The binder may in this case, for example, consist of polyurethane-forming prepolymers or already contain (partially) prepolymerized polyurethane. The polyurethane binder is particularly preferred a (one-component) PUR-diphenylmethane diisocyanate. Such a material cures by moisture to form CO ₂ to a solid, elastic and insoluble film, which is also film-like and thus impermeable to water. Accordingly, the particles of the first and possibly the subset of the second particulate material are largely covered with a thin PUR film. Naturally, it is possible that the binder also in this case further components, such as, for example, further polymer components and / or crosslinking agent.

The content of the binder based on the amount of the first particulate material should be appropriately selected. Suitably, the proportion of binder is between 3-13%, preferably 7%. Particularly preferably, the binder has a viscosity, depending on the temperature, of about 8000 mPa * s to 3000 mPa * s and more preferably 4500 mPa * s, in order to minimize or at least increase the binding of the binder to the individual particles at higher temperatures above 20 ° C. . to avoid.

Suitably, the at least one aforementioned layer of flooring is a play layer, d. H. the layer which closes the floor structure at the top and thus is in direct contact with the players or the sports equipment. It is thus an elastic sliding coating for sports surfaces according to the invention.

Another aspect of the present invention relates to a method for producing a floor covering for sports surfaces and in particular tennis courts.

According to the invention, a first particle material is mixed with a binder in a first step. The particulate material provided with the binder is then applied to at least a portion of the sports surface as long as the binder is still liquid or not fully cured. Subsequently, a second particulate material is applied to at least the part of the sports surface. An average grain size of the second particulate material is smaller than an average grain size of the first particulate material.

The above method allows the construction of a floor covering or a layer according to the aforementioned aspect of the present invention in which the first particulate material is bound by the binder and forms an open-pore scaffold, so that the second particulate material is at least partially disposed in the interstices or "deposition zones" formed by the scaffold.

In this case, the said mixing can be effected by means of a suitable mixing device and in particular a forced mixer in order to obtain a homogeneous mixture of first particle material and binder. In the context of this explanation, a homogeneous mixture is understood to mean that the individual particles of the first particle material are substantially surrounded by a thin film of binder.

The order of the mixed with the binder first particulate material can be done, for example, as a scattering order. Preferably, the first particulate material is then stripped or smoothed using a suitable apparatus, thereby forming the above-described open cell scaffold with deposition zones.

The porosity or size and number of Depotzonen this depends on the grain size and grain shape and the peel rate of the peeling process. Thus, with increased peel-off speed, the size of the deposit zones can be increased, since the individual particles or grains of the first particle material are thereby further expanded. Suitably, the order is carried out such that coated layer has a proportion of spaces or Depotzonen of 10 - 60% and in particular 40% in volume, which has been found to be particularly advantageous.

In order to combine the advantages of the resulting elastic scaffold with the advantages of a clay court, the second particulate material is subsequently applied and, for example, rolled with pressure. Alternatively or additionally, the second particulate material can be pressed into the depot zone with a vibratory screed.

According to the second particle material is applied to the previously provided with the binder first material during the setting time of the binder, ie, the second particulate material is applied to the not yet fully cured first particulate material. As a result, a subset of the second particulate material in the depot zone is bound to the particles of the first particulate material.

Advantageously, the above method further allows the adjustment of the respective desired elasticity of the floor covering by appropriate choice of time between application of the first particulate material provided with the binder and application of the second material. The longer this period of time is chosen, the smaller is the subset of the second particulate material which is bound to the first material, whereby the elasticity of the coating is correspondingly higher.

The setting time of conventional polyurethane binders is about 4 hours, so that the order of the second particulate material and thus adjusting the elasticity is easily possible.

Preferably, the first particulate material provided with the binder is applied in a thickness of about 15-50 mm and preferably 25 mm. The second particulate material is particularly preferably applied in an amount of about 0.8 to 4 kg / m ² and preferably 1.5 kg / m ² .

Fig. 1

eine schematische Schnittansicht durch einen erfindungsgemäßen Bodenbelag für Sportflächen gemäß eines ersten Ausführungsbeispiels;

Fig. 2

eine Schnittansicht gemäß des Ausführungsbeispiels aus Fig. 1 vor Auftrag eines zweiten Teilchenmaterials;

Fig. 3

das Ausführungsbeispiel gemäß Fig. 1 bei einer Stoppbewegung eines Sportlers sowie

Fig. 4

das Ausführungsbeispiel gemäß Fig. 1 bei einer Gleitbewegung eines Sportlers.

The invention will be described below with reference to exemplary embodiments. It shows:

Fig. 1

a schematic sectional view through a floor covering according to the invention for sports surfaces according to a first embodiment;

Fig. 2

a sectional view according to the embodiment of Fig. 1 before application of a second particulate material;

Fig. 3

the embodiment according to Fig. 1 in a stop motion of an athlete as well

Fig. 4

the embodiment according to Fig. 1 during a sliding movement of an athlete.

Fig. 1 shows an elastic sliding floor covering for sports surfaces and in particular for tennis courts according to a first embodiment in a partial, schematic sectional view.

As shown, the coating comprises a playing layer 4 consisting of grains or particles of a first mineral, double-refracted particulate material 1 and a second particulate material 3 exists. For clarity, only some of the grains shown are marked in the figures.

Like yourself Fig. 1 The mean grain size of the second particulate material 2 is significantly smaller than that of the first particulate material 1. According to the present example, the grain size of the first particulate material 1 averages 8 mm and the grain size of the second particulate material 3 averages 0.75 mm.

For this reason, in particular in the upper region of the playing layer 4 between respectively adjacent grains of the first particulate material 1, there are gaps or "deposit zones" 5. Because the first particulate material 1 has a double refraction and thus contains essentially cubic particles, particularly advantageous depot zones or "anchoring zones" are formed. The second particulate material 3 is predominantly arranged in these Depotzonen 5, which - as in the following with respect to the 3 and 4 explains - particularly good playability and improved durability of the flooring results.

The first particulate material 1 consists in the present case of predominantly multiply broken clay material which is bound by a (one-component) binder 2, in the present case PUR diphenylmethane diisocyanate. The binder 2 forms a solid, water-impermeable and film-like film by moisture at the interfaces to form carbon dioxide.

For production, the first particulate material 1 is homogeneously mixed with a compulsory mixer so that each individual rock particle or particle of the first particulate material 1 is completely enclosed in a thin film of binder 2, such as, for example Fig. 1 indicated. In order to avoid a transesterification of the binder 2 at temperatures greater than 20 ° C., the binder 2 has a viscosity of about 4500 mPa * s. The proportion of the PU binder 2 based on the first particulate material 1 is 7%.

The thus obtained homogeneous mixture of first particulate material 1 and binder 2 is applied to an existing substrate (not shown) in a thickness of 25 mm and stripped and smoothed with a suitable device. The thus formed Layer is in Fig. 2 shown schematically.

As can be seen from the figure, an open-pored and provided with Depotzonen 5 elastic grain skeleton is given, the porosity or size and number of Depotzonen 5 is directly related to particle size and grain shape and the peel rate of the peel.

As the horizontal peel rate is increased, the individual grains of the first particulate material 1 covered with binder 2 are further pulled apart than, for example, a slow peel-off motion. The resulting grain skeleton in the present case has a proportion of 40% depot zones in the volume, i. It consists of 60% rock particles or particles and 40% deposit zones, which are filled in the finished layer 1 with second particulate material 2.

Since in the present case every single grain of the particulate material 1 is coated with an elastic and water-impermeable plastic film, no water absorption can take place since the grain skeleton has no capillary function. Furthermore, there is a large pore content and, due to the broken shape, there are also a plurality of smaller bonding and bonding zones, so that the applied particulate material 1 can not freeze. However, there is a certain elasticity or surface elasticity. In addition, the layer 4 has a permanently high water permeability.

The grain skeleton thus formed already has significant positive features of a hard court, such as. Even ball jump, low maintenance and no need for irrigation.

In order to combine the above advantages with those of a clay court, during the setting time of the binder 2, ie within 4 hours, the second particulate material 3 is applied, which here consists of an elastically synthetic granules of styrene-butadiene rubber (SBR). This is applied with little excess to the grain skeleton, distributed and / or rolled with pressure. Alternatively, this can be pressed with a vibrating screed in the Depotzonen. The finished covering with playing layer 4 is, as already mentioned, in Fig. 1 shown.

As shown there, a slight excess of about 20% of the second particulate material 3 remains at the surface, while about 80% is pressed into the depot zone 5. Of this 80% of the second particulate material 3, a partial amount of about 5% is bound by the not yet completely set binder 2 to the first particulate material 1, i. fixed to each other.

Since the second particulate material 3 was rolled or pressed under pressure into the Depotzonen 5, it comes back after the rolling due to the elasticity of the individual grains in the depot zone 5 increases to the surface. Now, if pressure is exerted on the layer 4, the elastic granules of the second particle material 3 press together, so that an elastic effect is achieved.

At the same time the Depotzonen cause 5, depending on the touchdown of the foot of a player, a controlled deceleration. Fig. 3 shows the embodiment according to Fig. 1 during a stop movement of a player. Shown here is the shoe 6 of the player in a sudden deceleration. Like yourself Fig. 3 can be seen, formed by the above-mentioned excess of the second particulate material 3, a fairly large "brake wedge", which presses with high pressure against the edges of Depotzonen 5, thus supporting a controlled deceleration. At the same time, a sliding movement of the shoe 6, as in Fig. 4 shown, thereby supported that here only a small surface pressure is given and the existing excess ensures a controlled sliding.

Since high shear forces occur on the first particulate material 1, especially in the uppermost rock layer, due to the high vertical shear forces during braking or gliding, the deposit zones 5 additionally counteract the high quantity of pressed-in second particulate material 3 as additional attachment of the individual coarse grains a vertical displacement or breaking out, since the introduced into the Depotzonen 5 second particulate material 3 has about 1.5 times the volume of a grain of the first particulate material 1.

The thus provided elastic sliding flooring with playing layer 4 thus combines the advantages of a hard court with those of a clay court. In particular, the surface does not require irrigation and can therefore be used indoors (eg in indoor tennis courts) as well as outdoors be installed in all climates year-round with low maintenance on any existing surface.

• das erste Teilchenmaterial 1 alternativ oder ergänzend zu einem Tonmaterial Granit, Basalt, Quarz, oder Ziegelsplitt aufweist,
• das zweite Teilchenmaterial 3 mineralisch ist, und

ergänzend ein elastisches Granulat aus Ethylen-Propylen-Dien-Kautschuk (EPDM) aufweist.The invention has been explained above with reference to exemplary embodiments. However, the invention is not limited to the above embodiments. In particular, the illustrated embodiments allow numerous changes or additions. For example. it is conceivable that

• the first particulate material 1 comprises, alternatively or in addition to a clay material, granite, basalt, quartz, or brick chippings,
• the second particulate material 3 is mineral, and

additionally has an elastic granules of ethylene-propylene-diene rubber (EPDM).

Claims (8)

1. A ground covering for sports areas, in particular tennis courts, at least having one layer (4) with

   - a first particle material (1),

   - a second particle material (3) as well as

   - a binder (2), wherein

   - an average particle size of the second material (3) is less than an average particle size of the first material (1),

   - the first material (1) is a mineral particle material (1) crushed multiple times

   - the first material (1) is bound by the binder (2) and

   - the second material (3) is arranged at least partially in depot zones (5) formed by the first material (1),
   wherein furthermore a subset of the second material (3) is bound by the binder (2) and wherein the second particle material (3) comprises an elastic granulate.
2. The ground covering according to one of the preceding claims, wherein the second particle material (3) is a mineral material.
3. The ground covering according to one of the preceding claims, wherein the average particle size of the first particle material (1) is between 3 - 20 mm.
4. The ground covering according to one of the preceding claims, wherein the average particle size of the second particle material (3) is between 0.1 - 5 mm, in particular 0.1 - 1.5 mm and advantageously between 0.5 - 1.2 mm.
5. The ground covering according to one of the preceding claims, wherein the binder (2) comprises at least one water-impermeable polymer.
6. The ground covering according to one of the preceding claims, wherein the binder (2) is a polyurethane binder.
7. The ground covering according to one of the preceding claims, wherein the layer (4) is a play layer.
8. A method for producing a ground covering for sports areas, in particular tennis courts, characterized by the steps

   - mixture of a first mineral particle material (1) crushed multiple times with a binder (2),

   - application of the first material (1) provided with the binder (2) to at least one part of the sports area,

   - application of a second particle material (3) comprising an elastic granulate to at least that part of the sports area, wherein an average particle size of the second material (3) is less than an average particle size of the first material (1), wherein the second particle material (3) is applied during a setting period of the binder (2).

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