DE202017100908U1 - Granulated thermoplastic filling material - Google Patents

Abstract

Granulated thermoplastic filling material prepared or preparable by a process consisting of or comprising the following steps: a) providing at least one mineral constituent and at least one binder, preferably a bitumen-containing binder, and optionally one or more further constituents, and heating and mixing the provided Ingredients to a temperature in the range of 70 to 250 ° C, preferably from 150 to 200 ° C, more preferably to 180 ° C, to obtain an asphalt premix (V), wherein the total amount of mineral / n Bestanteil (s) , based on the total weight of the asphalt premix (V), is in the range from 40 to 99% by weight, preferably from 75 to 98% by weight, more preferably in the range from 90 to 96% by weight, b ) Introducing the asphalt premix (V) from step b) into a continuously rotating vessel and continuously moving the asphalt premix (V) in said vessel for cooling the asphalt premix (V) and for the preparation of the granulated thermoplastic filler, c) addition of one or more, preferably mineral, release agents and / or other / further ingredients in dry, dissolved or dispersed form to the asphalt premix (V) and / or during the introduction of the asphalt premix (V) into the continuously rotating vessel in step b) and / or to the asphalt premix (V) or granulated thermoplastic filler during the continuous agitation in step b), wherein the solvent or Dispersing agent, if any, due to the temperature of the asphalt premix (V) or the granulated thermoplastic filling partially or preferably completely evaporated while the temperature of the asphalt premix (V) or the granulated thermoplastic filling further lowers, d) carrying out the granulated thermoplastic filling material from the continuously rotating Beh e) optionally partial or complete removal of particles having a diameter of> 30 mm, if present, preferably of> 15 mm, if present, more preferably of> 8 mm, if present, so that preferably a granulated thermoplastic filling compound is obtained, wherein at least 90 wt .-% of the filling compound as particles having a diameter of ≤ 30 mm, preferably of ≤ 15 mm, more preferably of ≤ 8 mm, are present, and / or optionally partial or complete removal of particles with a diameter of <0 , 5 mm, if present, preferably <1.0 mm, if present, more preferably <2.0 mm, if present, so that preferably a granulated thermoplastic filling material is obtained, wherein at least 90% by weight of the filling material is particles with a diameter of ≥ 0.5, preferably of ≥ 1.0 mm, particularly preferably of ≥ 2.0.

Description

The present invention relates to a granulated thermoplastic filling composition which is particularly suitable for removing surface damage in concrete, paving or asphalt surfaces or for closing boreholes or closing roadway breaks or for closing joints of building structures.

Suitable construction methods for the maintenance of asphalt roads with high expansion and / or depth are generally described in the relevant regulations and leaflets, for example in US Pat "Additional Technical Terms of Contract (ZTV) Asphalt" as well as in "Additional Technical Terms of Contract and Guidelines for the Constructional Conservation of Traffic Areas - Asphalt Constructions" ZTV BEA-StB 09/13 , The structural measures described in the aforementioned regulations require predominantly the use of large equipment with correspondingly high staff requirements. Economically applicable, the known structural measures only for larger areas and high volume requirements. In particular, the conventional methods can not economically and / or permanently eliminate small-volume damage phenomena of non-uniform nature, such as, for example, holes of differing depth and width, cavities, punctures, gaping cracks, shallow abrasions and the like.

DE 100 10 451 A1 describes a process for the preparation of a thermoplastic filler for the removal of surface damage in concrete or asphalt surfaces or for incorporation into joints of buildings, in the first chippings, sand, a flour-fine material and a bituminous binder at a temperature of about 180 ° C to 240 ° C are homogeneously mixed. Thereafter, a coolant is added in shock to the mix in constant motion. The highly adhesive before the coolant addition mass of viscous consistency is transferred by this shock-like addition of a coolant in a granular granular granules with no composition, by a very high surface tension of the various components of the mix. This small granules can be transformed by heating in a pourable or spreadable filler with high adhesive power.

A disadvantage of the in DE 100 10 451 A1 described method is that the preparation of the granules requires the use of a coolant, and that the granules obtained has an undefined grain size. In addition, the granules for producing the filling material must be locally heated in a warm-up boiler in order to convert it into a pourable or spreadable putty.

EP 2 899 172 A1 relates to a thermoplastic filler prepared or preparable by a process comprising or consisting of providing a particular mineral mixture and a binder in a particular mixing ratio, heating and mixing the components provided to obtain an asphalt premix, cooling and comminuting the cooled asphalt premix to particles each having a diameter of 12 mm or less, mixing the premix thus obtained with one or more release agents and screening small particles so that a thermoplastic filler is obtained from particles having an average diameter in the range of 2 to 12 mm.

In the EP 2 899 172 A1 Although described thermoplastic filling material does not require the use of a coolant for the production of granules and has a very well-defined and uniform particle size, but the crushing step in the manufacturing process results in a large amount of small particles that need to be separated. This leads to a relatively large amount of waste material, which can have a negative effect on the production costs.

The invention is accordingly based on the prior art, the object to provide an improved, more economically producible thermoplastic filling material with which, especially in the short term, even small-scale damage phenomena can be eliminated economically and permanently.

• a) Bereitstellen von wenigstens einem mineralischen Bestandteil und wenigstens einem Bindemittel, vorzugsweise einem Bitumen-haltigen Bindemittel, sowie optional einem oder mehreren weiteren Bestandteilen, und Erhitzen und Vermischen der bereitgestellten Bestandteile auf eine Temperatur im Bereich von 70 bis 250 °C, bevorzugt von 150 bis 200 °C, besonders bevorzugt bis 180 °C, um eine Asphalt-Vormischung (V) zu erhalten, wobei die Gesamtmenge an mineralischem/n Bestanteil(en), bezogen auf das Gesamtgewicht der Asphalt-Vormischung (V), im Bereich von 40 bis 99 M.-%, vorzugsweise von 75 bis 98 M.-%, besonders bevorzugt im Bereich von 90 bis 96 M.-%, liegt,
• b) Einbringen der Asphalt-Vormischung (V) aus Schritt b) in einen kontinuierlich rotierenden Behälter und kontinuierliche Bewegung der Asphalt-Vormischung (V), bevorzugt über einen Zeitraum von 5 bis 30, besonders bevorzugt von 10 bis 20 Minuten, in besagtem Behälter zur Abkühlung der Asphalt-Vormischung (V) und zur Herstellung der granulierten thermoplastischen Füllmasse,
• c) Zugabe eines oder Zugabe von mehreren, vorzugsweise mineralischen, Trennmitteln und/oder anderer/weiterer Bestandteile in trockener, gelöster oder dispergierter Form zur Asphalt-Vormischung (V) vor und/oder während des Einbringens der Asphalt-Vormischung (V) in den kontinuierlich rotierenden Behälter in Schritt b) und/oder zur Asphalt-Vormischung (V) bzw. granulierten thermoplastischen Füllmasse während des kontinuierlichen Bewegens in Schritt b), wobei das Lösungsmittel bzw. Dispersionsmittel, falls vorhanden, aufgrund der Temperatur der Asphalt-Vormischung (V) bzw. der granulierten thermoplastischen Füllmasse teilweise oder vorzugsweise vollständig verdampft und dabei die Temperatur der Asphalt-Vormischung (V) bzw. der granulierten thermoplastischen Füllmasse weiter absenkt,
• d) Herausbefördern der granulierten thermoplastischen Füllmasse aus dem kontinuierlich rotierenden Behälter,
• e) optional teilweises oder vollständiges Entfernen von Partikeln mit einem Durchmesser von > 30 mm, falls vorhanden, bevorzugt von > 15 mm, falls vorhanden, besonders bevorzugt von > 8 mm, falls vorhanden, sodass vorzugsweise eine granulierte thermoplastische Füllmasse erhalten wird, worin wenigstens 90 M.-% der Füllmasse als Partikel mit einem Durchmesser von ≤ 30 mm, bevorzugt von ≤ 15 mm, besonders bevorzugt von ≤ 8 mm, vorliegen, und/oder optional teilweises oder vollständiges Entfernen von Partikeln mit einem Durchmesser von < 0,5 mm, falls vorhanden, bevorzugt von < 1,0 mm, falls vorhanden, besonders bevorzugt von < 2,0 mm, falls vorhanden, sodass vorzugsweise eine granulierte thermoplastische Füllmasse erhalten wird, worin wenigstens 90 M.-% der Füllmasse als Partikel mit einem Durchmesser von ≥ 0,5, bevorzugt von ≥ 1,0 mm, besonders bevorzugt von ≥ 2,0, vorliegen.

The object is achieved primarily by a granulated thermoplastic filling compound or preparable by a method consisting of or comprising the following steps:

• a) providing at least one mineral constituent and at least one binder, preferably a bitumen-containing binder, and optionally one or more further constituents, and heating and mixing the constituents provided at a temperature in the range of 70 to 250 ° C, preferably 150 to 200 ° C, more preferably to 180 ° C, to obtain an asphalt premix (V), the total amount of mineral particulate (s), based on the total weight of the asphalt premix (V), being in the range of From 40 to 99% by mass, preferably from 75 to 98% by mass, particularly preferably in the range from 90 to 96% by mass,
• b) introducing the asphalt premix (V) from step b) into a continuously rotating one Container and continuous movement of the asphalt premix (V), preferably for a period of from 5 to 30, more preferably from 10 to 20 minutes, in said vessel for cooling the asphalt premix (V) and for producing the granulated thermoplastic filling material,
• c) addition of or addition of several, preferably mineral, release agents and / or other / further ingredients in dry, dissolved or dispersed form to the asphalt premix (V) before and / or during the introduction of the asphalt premix (V) into the continuously rotating vessel in step b) and / or the asphalt premix (V) or granulated thermoplastic filler during continuous agitation in step b), the solvent or dispersant, if present, due to the temperature of the asphalt premix (V ) or the granulated thermoplastic filler partially or preferably completely evaporated while the temperature of the asphalt premix (V) or the granulated thermoplastic filler mass further lowered,
• d) conveying out the granulated thermoplastic filling material from the continuously rotating container,
• e) optionally partial or complete removal of particles with a diameter of> 30 mm, if present, preferably> 15 mm, if present, more preferably> 8 mm, if present, so that preferably a granulated thermoplastic filling material is obtained, wherein at least 90 M .-% of the filling compound as particles having a diameter of ≤ 30 mm, preferably of ≤ 15 mm, more preferably of ≤ 8 mm, are present, and / or optionally partial or complete removal of particles with a diameter of <0.5 mm, if present, preferably <1.0 mm, if present, more preferably <2.0 mm, if present, so that preferably a granulated thermoplastic filling material is obtained, wherein at least 90% by weight of the filling compound is a particle Diameter of ≥ 0.5, preferably of ≥ 1.0 mm, more preferably of ≥ 2.0, are present.

In the context of the present invention, the terms "grain size" and "diameter" preferably refer to the maximum spatial extent of a grain or particle.

Preferably, in step a) of the process, homogeneous mixing of the mineral component (s) and binder (s) in the resulting asphalt premix (V) occurs. This homogeneous mixing and heating of the constituents in step a) preferably leads to the activation of certain advantageous material properties (for example, mixing and heating may cause crosslinking of certain polymers in the bitumen, if present).

According to a preferred embodiment, in step a) of the process, the at least one mineral constituent and the at least one binder are provided by a single substance, preferably by natural asphalt containing mineral and binder fractions.

According to a preferred embodiment, the continuously rotating container is inclined in steps b) and c) of the method. Due to the negative slope, the granulated thermoplastic filling compound according to the invention is conveyed gravimetrically to the container outlet. The pitch is variable and is adjusted such that the granular thermoplastic filling compound according to the invention when removing from the continuously rotating container in step d) has a temperature of about 15 to 25 ° C, preferably of 20 ° C.

In the context of the present invention, the term granulation is understood to mean the transformation of either large particles and / or very small particles having different particle sizes into a particle size-narrow particle size distribution. Granulating is a technique that is used in many areas and usually serves to be able to process the substance better (further). Accordingly, the granulated thermoplastic filling material according to the invention described in steps b) and c) of the process is to be understood as meaning a mixture which has a narrower particle size distribution in comparison with the asphalt premix (V).

According to another preferred embodiment, in step c) water or aqueous solutions are used as solvents or dispersants, if used.

The granulated thermoplastic filling material according to the invention is particularly advantageous since, for example, by the continuous movement of the asphalt premix (V) or the granulated thermoplastic filling compound during cooling in step b) and during the addition of a mineral release agent and / or other / further constituents in step c) a cohesion of the particles is effectively prevented and thus a very uniform particle size is achieved. Depending on, for example, the choice of the particle size of the mineral constituents, the amount and type of added binder and the speed of the continuously rotating container in steps b) and c) granulated thermoplastic filling compositions according to the invention having different particle sizes can be combined with one narrow particle size distribution using the same production line. By the possibility of admixing various other / further constituents in step c) as defined above, it is furthermore possible to produce various types of thermoplastic filling compounds according to the invention with functional properties for a very wide variety of applications. It can thus be flexibly responding to the needs of different customers and it can be made in a simple manner and with the same production line customized thermoplastic filling compositions. In addition, the production of scrap material is minimized.

According to a preferred embodiment of the method, only particles with a diameter of> 30 mm, if present, preferably> 15 mm, if present, particularly preferably> 8 mm, if present, are partially or completely removed in step e), so that preferably a granulated thermoplastic filling compound is obtained in which at least 90% by mass of the filling compound are present as particles having a diameter of ≦ 30 mm, preferably ≦ 15 mm, particularly preferably ≦ 8 mm. According to this embodiment, therefore, particularly fine fractions, if present, remain in the granulated thermoplastic filling compound, whereas particularly coarse fractions are removed.

According to another preferred embodiment of the method, in step e) only particles with a diameter of <0.5 mm, if present, preferably of <1.0 mm, if present, particularly preferably <2.0 mm, if present, partially or completely removed, so that preferably a granulated thermoplastic filling compound is obtained, in which at least 90% by mass of the filling compound are particles having a diameter of ≥ 0.5, preferably 1.0 mm, particularly preferably ≥ 2.0, available. According to this embodiment, particularly coarse fractions, if present, remain in the granulated thermoplastic filling compound, whereas particularly fine fractions are removed.

According to a particularly preferred embodiment of the method, particles having a diameter of> 30 mm, if present, preferably> 15 mm, if present, particularly preferably> 8 mm, if present, and particles having a diameter of <are produced in step e) 0.5 mm, if present, preferably <1.0 mm, if present, more preferably <2.0 mm, if present, partially or completely removed, so that preferably a granulated thermoplastic filling material is obtained, wherein at least 90 M. -% of the filling compound as particles having a diameter of ≥ 0.5 mm to ≤ 30 mm, preferably from ≥ 1.0 mm to ≤ 30 mm, more preferably from ≥ 2.0 mm to ≤ 30 mm, more preferably from ≥ 0 , 5 mm to ≤ 15 mm, more preferably from ≥ 1.0 mm to ≤ 15 mm, more preferably from ≥ 2.0 mm to ≤ 15 mm, more preferably from ≥ 0.5 mm to ≤ 8 mm, further preferably from ≥ 1.0 mm to ≤ 8 mm, more preferably from ≥ 2.0 mm to ≤ 8 mm. According to this embodiment, particularly fine and particularly coarse fractions, if present, are removed from the granulated thermoplastic filling compound.

Those embodiments of the granulated thermoplastic filling material according to the invention in which particles with a diameter of <0.5 mm, if present, preferably of <1.0 mm, if present, particularly preferably <2.0 mm, have been partially or completely removed particularly advantageous for example for use in (asphalt) repair work. In such repair work, the granulated thermoplastic filling composition according to the invention is preferably poured cold into, for example, a pothole in the asphalt, heated or heated with a gas burner or the like and then compacted. By removing the particularly fine portions of the filling compound, the formation of a closed surface during filling is prevented, and thus the heat of the gas burner (or the like) can easily penetrate deeply into the filling compound and heat or heat it quickly and efficiently. The repair work can be carried out in such a way that saves time and energy.

According to a further preferred embodiment, the following further step takes place between step a) and step b) of the method as defined above:
Application of the asphalt premix (V) obtained in step a) to a multi-part conveyor belt system with in each case increasing speed of the conveyor belts for spatial equalization of the asphalt premix (V).

Such an embodiment is particularly advantageous, since the spatial equalization of the particles of the asphalt premix (V) prior to introduction into the continuously rotating container in step b) results in the particles falling into the container one after the other and thus causing agglomeration of the particles Particles in the continuously rotating container is prevented or minimized. This leads to a further reduction of reject material and to the production of a granulated thermoplastic filling composition according to the invention with a particularly uniform particle size. In addition, the said further step, if present, serves as the first step of cooling the asphalt premix (V) obtained in step a).

In the presence of said further step between steps a) and b) of the process, in step b) the asphalt premix does not become (V) from step a) introduced into the continuously rotating container, but the equalized on the conveyor belt asphalt premix (V).

• (i) 0 bis 30 M.-%, bevorzugt 0 bis 25 M.-%, besonders bevorzugt 0 bis 15 M.-%, Füllstoff aus mineralischen Bestandteilen mit einer Korngröße von ≤ 0,063 mm,
• (ii) 0 bis 100 M.-%, bevorzugt 20 bis 100 M.-%, besonders bevorzugt 35 bis 100 M.-%, einer Gesteinskörnung aus Gesteinskörnern mit einer Korngröße im Bereich von > 0,063 mm bis ≤ 2 mm,

und

• (iii) 0 bis 85 M.-%, bevorzugt 0 bis 70 M.-%, besonders bevorzugt 0 bis 60 M.-% einer Gesteinskörnung aus Gesteinskörnern mit einer Korngröße von > 2 mm,

wobei wenigstens einer der Bestandteile (i) bis (iii) > 0 M.-% ist.According to a further preferred embodiment, the asphalt premix (V) or the granulated thermoplastic filler comprises a mineral mixture consisting of or containing, in each case based on the total weight of the mineral mixture,

• (i) 0 to 30% by mass, preferably 0 to 25% by mass, particularly preferably 0 to 15% by mass, of a mineral filler with a particle size of ≦ 0.063 mm,
• (ii) 0 to 100% by mass, preferably 20 to 100% by mass, particularly preferably 35 to 100% by mass, of an aggregate of rock granules having a particle size in the range of> 0.063 mm to ≦ 2 mm,

and

• (iii) 0 to 85% by mass, preferably 0 to 70% by mass, particularly preferably 0 to 60% by mass, of an aggregate of rock grains having a particle size of> 2 mm,

wherein at least one of the components (i) to (iii) is> 0 mass%.

Depending on the intended field of application of the thermoplastic filling composition according to the invention (for example as putty for correcting small cracks or for filling large holes in asphalt surfaces), the skilled person can select or set the respective suitable mineral mixture composition. Advantageously, different thermoplastic fillers with different mineral mixtures can be used. So it is e.g. conceivable that when filling large holes, first a thermoplastic filler with mineral components of relatively large grain size and then a thermoplastic filler with mineral components smaller grain size are introduced.

According to a further preferred embodiment, the asphalt premix (V) or the granulated thermoplastic filler comprises one or more constituents of the group consisting of polymers, preferably elastomers and plastomers, polymer granules, polymer powders, waxes, preferably FT waxes, wax powders, rubber powders, rubber granules , Natural asphalt powders, natural asphalt granules, fatty acid amides, hydrated lime, cellulose pulps, colored pigments, rejuvenators, limestone flours, modified limestone flours, zeolites, rock flours and adhesion promoters, preferably adhesion promoters selected from the group consisting of fatty polyamines, fatty monoamines, amino soaps and nitrogen compounds.

According to a further preferred embodiment, the asphalt premix (V) or the granulated thermoplastic filling compound, preferably the component (i) of the mineral mixture, if present, comprises one or more constituents from the group consisting of limestone flours, modified limestone flours, rock flours , Hydrated lime and zeolites.

According to a further preferred embodiment, the component (ii) of the mineral mixture, if present, based on the total weight of the component (ii) comprises 10% by mass or more, preferably 20, 30, 40, 50 or 60% by mass or more , preferably 70 M .-% or more, natural sand or consists of natural sand with a particle size of <0.063 mm to ≤ 2 mm. Under natural sand is understood in the context of the present invention, a sand that occurs in loose form in nature (as opposed to crushed sand) and was not obtained by mechanical breaking. Natural sand is better suited for the intended use as crushed sand, since the backfilling and processing of a damaged area with natural sand is easier because of lower internal friction (the processing can be done by hand and must not be done by machine).

According to a further preferred embodiment, the component (iii) of the mineral mixture, if present, consists of rock grains with a particle size in the range of> 2 mm to 22 mm, preferably of> 2 mm to 16 mm, particularly preferably of> 2 mm ≤ 5 mm.

• – der Durchmesser der Partikel der granulierten thermoplastischen Füllmasse

und/oder

• – die Korngröße der Bestandteile gemäß (i), (ii) und/oder (iii) des Mineralstoffgemischs, falls vorhanden,

und/oder

• – der Durchmesser der Partikel der Vormischung (V)

gemäß TL Gestein-StB 2004/2007 bestimmt wird bzw. werden.With regard to the particle sizes or diameters described herein, according to a preferred embodiment, the following applies:

• - The diameter of the particles of granulated thermoplastic filler

and or

• - the particle size of the constituents of (i), (ii) and / or (iii) the mineral mixture, if any,

and or

• The diameter of the premix particles (V)

according to TL Gestein-StB 2004/2007 is determined or will be.

Particularly preferably, the determination is made by screening based on the DIN EN 933-1 ,

The bitumen of the bitumen-containing binder, if present, preferably has a penetration in the range of 20 to 220 (0.1 mm), measured after DIN EN 1426 ,

It is also preferred that the bitumen has a softening point in the range from 35 to 90 ° C, preferably from 35 to 70 ° C, measured after DIN EN 1427 ,

According to a preferred embodiment, the continuously rotating container in step b) of the method as defined above is a device selected from the group consisting of granulation plate and round or granulating drum.

According to a further preferred embodiment, the one or more or all release agents, if present, in step c) of the process are as defined above, selected from the group consisting of polymer powders, wax powders, rubber powders, natural asphalt powders, adhesion promoters, hydrated lime, Cellulose fibers, colored pigments, limestone flours, modified limestone flours, kieselguhrs, diatomaceous earths, zeolites and acrylates, preferably acrylates with polymer addition. If the abovementioned substances are added as release agents in step c), they are preferably introduced into the rear third of the rotating container. As a result, the release agent (s) added in step c), if present, arrange themselves almost exclusively on the surface of the granulated thermoplastic filling compound during the continuous rotation movement of the container.

According to a further preferred embodiment, the or one or more or all other constituents, if present, in step c) of the process are as defined above, selected from the group consisting of polymer powders, wax powders, rubber powders, natural asphalt powders, fatty acid amides , Adhesion promoters, hydrated lime, cellulose fibers, color pigments, limestone flours, modified limestone flours, zeolites and acrylates, preferably acrylates with polymer addition. Preferably, the other / further ingredients added in step c) of the process, if present, are ingredients which may contribute to functional properties of the thermoplastic filling material, e.g. to constituents that modify the deformation behavior and / or cold behavior of the thermoplastic filler. The other / further constituents added in step c), as defined above, if present, arrange themselves during the continuous rotating movement of the container, preferably within the granulated thermoplastic filling material formed or at the surface thereof.

In the following, the present invention will be described in more detail by way of examples. In the following examples, as well as in general in the context of the present invention, the abbreviation "M .-%" means percent by mass.

Exemplary compositions of thermoplastic filling compositions according to the invention: Example 1 Composition of the mineral mixture used (in step a)): Component (i): 8,0 M .-% filler from limestone flour / rock flour / hydrated lime with a Grain size of ≤ 0.063 mm Component (ii): 39.0% by weight of fine aggregate with a particle size of> 0.063 mm to ≤ 2 mm comprising 90 M .-% natural sand Component (iii): 53.0% by weight of coarse aggregate with a particle size of> 2 mm up to ≤ 5 mm (Proportion of components (i) to (iii) relative to the total weight of the mineral mixture)

Applied binder (in step a)):

• 7.14% by weight bitumen 70/100, optionally comprising FT wax
• (Proportion of binder based on the total weight of mineral constituents and binder in premix (V))

Making an asphalt premix (V):

In a first step, the components (ii) and (iii) of the mineral mixture are roughly weighed and transported via a draw-off belt for drying in a heated rotating drum. The rocks are heated here to the required temperature (about 200 ° C). The rocks are then transported via elevators for so-called hot screening via a mixing drum. Here is the recipe accurate weighing of the required rocks. Thereafter, the rock mixture falls into the mixing drum and homogenizes with the amount of filler added via a parallel path (component (i)).

In a next step, the binder is added over Bitumenleitungen. There is a batch homogenization of the individual components during the following mixing process. Thereafter, the finished, hot material (asphalt premix (V)) is loaded in transport vehicles or in silo storage. The asphalt premix (V) obtained in this way can either continue to be used immediately (see next step) or initially (temporarily) stored if necessary.

Preparation of a granulated thermoplastic filling compound (granulation):

The asphalt premix (V) obtained in the preceding step is applied for spatial equalization on a multi-part conveyor belt system with increasing speed of the conveyor belts. Subsequently, a water-soluble granulation aid (eg acrylate) is metered onto the asphalt premix (V) in the last third of the conveyor belts (about 1.5% by weight with respect to the asphalt premix (V)) and the asphalt premix ( V) is transferred to a rotary granulating drum. The mixture remains in the rotating granulating drum for 10 minutes, then the granulated thermoplastic filling material is removed from the drum. If present, particles with a diameter> 8 mm are screened off, directly or after intermediate storage on a screening device. Example 2 Composition of the mineral mixture used (in step a)): Component (i): 5.0 M .-% fillers of limestone flour / rock flour / hydrated lime with a Grain size of ≤ 0.063 mm Component (ii): 34.0% by weight of fine aggregate with a particle size of> 0.063 mm to ≤ 2 mm comprising 70 M .-% natural sand Component (iii): 61.0% by weight of coarse aggregate with a particle size of> 2 mm to ≤ 16 mm (Proportion of components (i) to (iii) relative to the total weight of the mineral mixture)

Applied binder (in step a)):

• 5.0% by weight bitumen 50/70, optionally comprising FT wax or montan wax
• (Proportion of binder based on the total weight of mineral constituents and binder in premix (V))

For making the asphalt masterbatch (V), see Example 1 above.

Preparation of a granulated thermoplastic filling compound (granulation):

The asphalt premix (V) obtained in the preceding step is applied for spatial equalization on a multi-part conveyor belt system with increasing speed of the conveyor belts. On the conveyor belt system, the asphalt premix (V) is uniformly sprinkled with a mixture of natural asphalt and rubber powder (1.5% by mass in relation to the asphalt premix (V), mass ratio of natural asphalt powder / rubber powder = 2/1) promoted the asphalt premix (V) in a granulating drum. At the beginning of the granulation process diatomaceous earth (1.0% by mass with respect to the asphalt premix (V)) is added as a granulation aid in the first third of the drum. The mixture remains in the rotating granulating drum for 20 minutes. Subsequently, the mixture is sprayed in the last third of the rotating drum for 1 minute with acrylate (0.5% by mass with respect to the asphalt premix (V)). The granulated thermoplastic filling material is then transported out of the drum and particles with a diameter> 18 mm are screened directly or later. Example 3 Composition of the mineral mixture used (in step a)): Component (i): 26.0 M .-% filler of limestone powder / rock flour / hydrated lime with a Grain size of ≤ 0.063 mm Component (ii): 50.0% by weight of fine aggregate with a particle size of> 0.063 mm to ≤ 2 mm consisting of 100 M .-% natural sand Component (iii): 24.0% by weight of coarse aggregate with a particle size of> 2 mm up to ≤ 5 mm (Proportion of components (i) to (iii) relative to the total weight of the mineral mixture)

Applied binder (in step a)):

• 11.1 M .-% bitumen 70/100, optionally comprising FT wax
• (Proportion of binder based on the total weight of mineral constituents and binder in premix (V))

For making the asphalt masterbatch (V), see Example 1 above.

Preparation of a granulated thermoplastic filling compound (granulation):

The asphalt masterbatch (V) obtained in the preceding step is introduced into a rotating granulating drum, with a granulating aid in the form of hydrated lime (0.5 M.) immediately before or after introduction into the granulating drum. % with respect to the asphalt premix (V)), preferably simultaneously with it. The mixture remains in the rotating granulating drum for 20 minutes, with diatomaceous earth (1.0% by mass with respect to the asphalt premix (V)) being metered into the last third of the drum for the last 5 minutes. The granulated thermoplastic filling compound is then transported out of the drum and particles with a diameter> 6 mm are deported. The granulated thermoplastic filling compound is stored temporarily and is ready for delivery.

Optionally, after the push-off step, a further admixing of kieselguhr (1.5% by weight with respect to the granulated thermoplastic filling compound) in a plowshare mixer can be used to increase the storage stability of the granulated thermoplastic filling material for deliveries to warmer regions and / or for further transport routes.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 10010451 A1 [0003, 0004]
• EP 2899172 A1 [0005, 0006]

Cited non-patent literature

• "Additional Technical Terms of Contract (ZTV) Asphalt" as well as in "Additional Technical Terms of Contract and Guidelines for the Constructional Conservation of Traffic Surface Pavements - Asphalt Constructions" ZTV BEA-StB 09/13 [0002]
• TL Gestein-StB 2004/2007 [0029]
• DIN EN 933-1 [0030]
• DIN EN 1426 [0031]
• DIN EN 1427 [0032]

Claims (11)

Granulated thermoplastic filler prepared or preparable by a process consisting of or comprising the following steps: a) providing at least one mineral constituent and at least one binder, preferably a bitumen-containing binder, and optionally one or more further constituents, and heating and mixing the provided ingredients at a temperature in the range of 70 to 250 ° C, preferably 150 to 200 ° C, more preferably 180 ° C, to obtain an asphalt premix (V), wherein the total amount of mineral constituent (s), based on the total weight of the asphalt premix (V), in the range of 40 to 99 M .-%, preferably from 75 to 98 M .-%, particularly preferably in the range of 90 to 96% by mass, b) introducing the asphalt premix (V) from step b) into a continuously rotating vessel and continuously moving the asphalt premix (V) in said vessel to cool the asphalt premix (V) and to produce the granulated thermoplastic filler; c) addition of or addition of several, preferably mineral, release agents and / or other / further ingredients in dry, dissolved or dispersed form to the asphalt premix (V) before and / or during the introduction of the asphalt premix (V) in the continuously rotating vessel in step b) and / or the asphalt premix (V) or granulated thermoplastic filler during continuous agitation in step b), the solvent or dispersant, if present, due to the temperature of the asphalt premix (V ) or the granulated thermoplastic filler partially or preferably completely evaporated while the temperature of the asphalt premix (V) or the granulated thermoplastic filler mass further lowered, d) conveying out the granulated thermoplastic filling material from the continuously rotating container, e) optionally partial or complete removal of particles with a diameter of> 30 mm, if present, preferably of> 15 mm, if present, more preferably of> 8 mm, if present, so that preferably a granulated thermoplastic filling compound is obtained in which at least 90% by mass of the filling compound are present as particles having a diameter of ≦ 30 mm, preferably ≦ 15 mm, particularly preferably ≦ 8 mm, and or optionally partial or complete removal of particles having a diameter of <0.5 mm, if present, preferably <1.0 mm, if present, more preferably <2.0 mm, if present, so that preferably a granulated thermoplastic filling compound is obtained in which at least 90% by mass of the filling compound are present as particles having a diameter of ≥ 0.5, preferably 1.0 mm, particularly preferably 2.0. Granulated thermoplastic filler composition according to claim 1, wherein the following further step takes place between step a) and step b): Application of the asphalt premix (V) obtained in step a) to a multi-part conveyor belt system with in each case increasing speed of the conveyor belts for spatial equalization of the asphalt premix (V). A granulated thermoplastic filling composition according to claim 1 or 2, wherein the asphalt premix (V) or the granulated thermoplastic filling composition comprises a mineral mixture consisting of or containing, in each case based on the total weight of the mineral mixture, (i) 0 to 30% by mass, preferably 0 to 25% by mass, particularly preferably 0 to 15% by mass, of a mineral filler with a particle size of ≦ 0.063 mm, (ii) 0 to 100% by mass, preferably 20 to 100% by mass, particularly preferably 35 to 100% by mass, of an aggregate of rock granules having a particle size in the range of> 0.063 mm to ≦ 2 mm, and (iii) 0 to 85% by mass, preferably 0 to 70% by mass, particularly preferably 0 to 60% by mass, of an aggregate of rock grains having a particle size of> 2 mm, wherein at least one of the components (i) to (iii) is> 0 mass%. A granulated thermoplastic filling composition according to any one of the preceding claims, wherein the asphalt premix (V) or the granulated thermoplastic filling compound comprises one or more constituents of the group consisting of polymers, polymer granules, polymer powders, waxes, preferably FT waxes, wax powders, rubber powders, rubber granules, Natural asphalt powders, natural asphalt granules, fatty acid amides, hydrated lime, cellulose pulps, colored pigments, rejuvenators, limestone flours, modified limestone flours, zeolites, rock flours and adhesion promoters, preferably adhesion promoters selected from the group consisting of fatty polyamines, fatty monoamines, aminose and nitrogen compounds. A granulated thermoplastic filler composition according to any one of the preceding claims wherein the asphalt premix (V) or granulated thermoplastic filler, preferably wherein component (i) of the mineral mixture, if present, comprises one or more constituents of the group consisting of limestone flours . modified limestone flours, rock flours, hydrated lime and zeolites. Granulated thermoplastic filling material prepared or preparable by a process according to any one of claims 3 to 5, wherein the component (ii) of the mineral mixture, if present, based on the total weight of the component (ii) 10 M .-% or more, preferably 70 M. -% or more, includes natural sand or consists of natural sand. A granulated thermoplastic filling composition according to any one of claims 3 to 6, wherein component (iii) of the mineral mixture, if present, consists of aggregates having a particle size in the range of> 2 mm to ≤ 22 mm, preferably> 2 mm to ≤ 16 mm preferably from> 2 mm to ≤ 5 mm. Granulated thermoplastic filling composition according to one of the preceding claims, wherein the bitumen, if present, a penetration in the range of 20 to 220 (0.1 mm) measured according to DIN EN 1426 and / or a softening point in the range of 35 to 90 ° C, preferably from 35 to 70 ° C, measured according to DIN EN 1427 has. Granulated thermoplastic filling material according to one of the preceding claims, wherein the continuously rotating container in step b) is a device selected from the group consisting of granulating disc and granulating drum. A granulated thermoplastic filling composition according to any one of the preceding claims, wherein the one or more or all release agents in step c), if present, are selected from the group consisting of polymer powders, wax powders, rubber powders, natural asphalt powders, adhesion promoters, hydrated lime, cellulosic pulps , Color pigments, limestone flours, modified limestone flours, kieselguhrs, diatomaceous earths, zeolites and acrylates. A granulated thermoplastic filling composition according to any one of the preceding claims, wherein the one or more or all of the other ingredients in step c), if present, are selected from the group consisting of polymer powders, wax powders, rubber powders, natural asphalt powders, fatty acid amides, Adhesion promoters, hydrated lime, cellulosic fibers, colored pigments, limestone flours, modified limestone flours, zeolites and acrylates.