DE202008017283U1 - Asphalted traffic area - Google Patents

Abstract

Paved traffic area with a defined in the traffic area (1) recess (7), and with a in the recess (7) arranged, a cavity providing protective device (3), wherein in the recess (7) a flowable during introduction, solidified load transfer medium (13) is introduced, and wherein the load transfer medium (13) with the protection device (3) at least partially in contact, characterized in that the load transfer medium has a mastic asphalt (13), which at least partially in contact with the protective device (3) ,

Description

The The invention relates to a paved traffic area with a defined in the traffic area recess. In the recess, a protective device providing a cavity is arranged, wherein a flowable in the recess, solidified load transfer medium is introduced. The load transfer medium is at least partially in contact with the protective device. Furthermore, the invention relates to a use of a load transfer medium for a paved traffic area.

Out the prior art it is known in a paved traffic area to provide a recess in which a trained as a cable conduit Protective device is arranged. As a load transfer medium, which is at least partially in contact with the cable protection tube is placed in the recess concrete. A subsequent successful Hot installation of further asphalt layers leads at the asphalted traffic area, that the concrete covered by an asphalt superstructure.

at Such paved traffic areas are often seen even before the expiry of the lifetime of adjacent paved traffic areas, in which no cable protection tube is installed and which otherwise are structurally identical, structural damage in the area of the laid cable protection tube. This damage, for example in the form of cracks, the lesser a thickness, the more blatant an asphalt superstructure of the concrete is and the heavier load changes the paved traffic area is exposed. Just in heavily loaded traffic areas, such as aircraft traffic areas, this is disadvantageous.

task The present invention is therefore an asphalted traffic area to create the type mentioned, which is a reduced susceptibility to damage having.

These Task is solved by the independent claims solved. Advantageous embodiments with appropriate Further developments of the invention are in the dependent claims specified.

at the paved traffic area according to the invention formed with a defined in the traffic area Recess and with a arranged in the recess, a cavity Providing protective device is in the recess at Introducing flowable, consolidated load transfer medium brought in. The load transfer medium here has a mastic asphalt on, which with the protection device at least partially in Contact is. As mastic asphalt, unlike rolled asphalt, liquid is processable and does not need to be condensed is so a particularly extensive contact of the protective device with the Load transfer medium achievable. In addition, the Mastic asphalt in an advantageous manner with temperature changes and / or load changes a similar material behavior, as a part of the paved traffic area adjacent to the recess.

Of the Invention is based on the finding that damage during Using concrete as the guard contacting load transfer medium an incompatibility of the rigid structural behavior of the concrete beam with the otherwise flexible load reaction of the paved traffic area to the cause. Damage to the paved traffic area when using concrete as a load transfer medium additionally favored by the fact that insufficient time for the concrete to set, which with four to six days must be available is before the superstructure of other asphalt layers in the hot installation was created. In this case, the hot superstructure escapes the concrete the moisture required for setting. For a hydration, ie the chemical mineralogical reaction of the Cements with the water, is then not enough water to disposal.

has the load transfer medium, which with the protective device at least in areas contact, in contrast, a mastic asphalt On, so are particularly short installation times at the same time reduced Vulnerability feasible. Preferably, a predominant, in particular more than 80%, preferably more than 95% of the amount of Load transfer medium provided by the mastic asphalt. Especially the load transfer medium in the recess can completely be formed by the poured asphalt.

As well are construction-related paragraphs or depressions avoidable. After rapid solidification of the load transfer medium, so cooling the cast asphalt is one particular rapid release of paved traffic area possible. Because the mastic asphalt cavities are significantly better, namely largely complete, fills as concrete is also compared to the use of concrete as a load transfer medium a water entry under a surface of the asphalted Traffic area avoidable.

According to an advantageous embodiment of the invention, at least one material property of a bituminous binder of Gussasphalts is at least substantially equal to a material property of a binder, which is a to the Recess adjacent portion of the asphalted traffic area has. Such a material property may include, for example, a rigidity at a comparatively low outside temperature or a flexibility at a comparatively high outside temperature. Further material properties can be detected, for example, by means of key figures defined in DIN standards for bitumen. In particular, with a particularly extensive agreement of a variety of material properties of the binder of Gussasphalts and adjacent to the recess asphalt layers a uniform material behavior of the paved road surface can be achieved.

The mastic asphalt may include road bitumen and / or polymer modified bitumen and / or be low temperature cast asphalt. The cast asphalt may preferably comprise exclusively road-building bitumen or polymer-modified bitumen as binder or consist entirely of low-temperature cast asphalt. The requirements for road construction bitumen are, for example, in DIN EN 12591 suitable for polymer modified bitumen in the DIN EN 14023 Are defined. Low-temperature cast asphalt is distinguished from mastic asphalt, which is road-bitumen or polymer-modified bitumen, by a reduced processing temperature. Low-temperature cast asphalt can already be processed at around 200 ° C. In contrast, an installation of road bitumen or polymer-modified bitumen usually takes place at installation temperatures of up to 240 ° C. It is particularly advantageous to use road-bitumen for the mastic asphalt if the binder of the sub-area of the asphalted traffic area adjoining the recess is also road-bitumen. In an analogous manner, it is preferable to use polymer-modified bitumen as the binder of such a cast asphalt, which is introduced into an asphalt traffic area with polymer-modified bitumen as binder. Similarly, low temperature molten asphalt offers as a load transfer medium in a recess formed in an asphalt pavement made of low temperature asphalt.

In a further advantageous embodiment of the invention, the recess are formed as a slot and the protective device as a conduit. Such a slot can be provided particularly precisely, for example, by milling into the existing paved traffic area. By means of a conduit as a protective device a particularly uniform load transfer over the mastic asphalt is achievable. As a conduit is especially a cable protection tube into consideration. Depending on the number and diameter of subsequently introduced into the empty pipe cables, the empty pipe can be a corresponding to the DIN EN ISO 6708 given nominal diameter of DN 25 to DN 200, preferably from DN 40 to DN 150, have. Such conduits are commercially available, particularly inexpensive available and flexible. Furthermore, when using the empty pipe at the location of a cable joint for laying the cable, it is possible to decouple the civil engineering work from the electrical work. In addition, the use of the empty tube makes it possible to accommodate comparatively many, in particular comparatively thick, cables in the empty tube.

When Advantageously, it has shown here, when the slot has a width which, at least in the region of the empty tube to be inserted is greater than a maximum lateral extent of the empty pipe. The empty tube is therefore preferred to respective side walls the slot spaced in the slot. This is a particularly extensive, in particular longitudinally watertight, Sheathing of the empty pipe accessible with mastic asphalt. Such comprehensive embedding of the empty pipe leads due to the Vault effect at ideal conditions for deriving introduced Loads.

From It is also an advantage if the slot has a depth, which is greater than a sum of a maximum Height extension of the empty pipe and a thickness a cover layer of a portion adjacent to the slot the asphalted traffic area. This ensures that even with a renewal of the cover layer, the empty pipe unimpaired can remain in the recess. This is a particularly permanent Solution for arranging the empty tube in the given asphalted traffic area. Especially if a distance between a highest point of the empty pipe and the topcoat is about one centimeter, is in a renewal of the cover layer damage the Empty pipe avoidable.

If a supply cable is instead laid in a recess designed as a cable joint in the paved traffic area, this is only accompanied by a very limited service life of the paved traffic area. When filling the cable joint with respect to the adjacent material of the asphalt layers to soft material, the flanks of the recess are not stable, on the other hand, when using a too rigid material breaks the cable joint out. As a result, when using cable joints damage to the paved road surface are common. In addition, the cable is so close to the surface when laying in the cable joint that comparatively easy damage to the cable, especially when renewing the surface layer of the paved road surface, can take place. These disadvantages are avoided by using the sufficiently deep arranged empty tube bar.

In a further advantageous embodiment of the invention is that in particular designed as a winding tube, empty tube made of a fiber-reinforced, in particular fiberglass reinforced, plastic formed. Such, for example an epoxy resin as plastic winding tubes are cheap can be produced, commercially available and have, inter alia, the material technical preference on that they by contact with mastic asphalt not be affected. Furthermore, they are light, dimensionally stable and have a high mechanical strength and chemical resistance on. A winding tube made of glass fiber reinforced epoxy resin resists particularly well with the incorporation of Gussasphalts associated thermal and mechanical loads.

When Furthermore, it has been shown to be advantageous if an overlap a crest of the protective device with the load transfer medium is greater than a maximum height extension one brought into the asphalted traffic area Underfloor components, in particular an underfloor fire. This is Ensure that the underfloor component, such as by running a vertical hole through the mastic asphalt and through the protective device, to a cable located in the cavity of the protection device is connectable. At the same time is so achievable that the underfloor component with a surface of asphalted Traffic area flush in closing the paved traffic area is recoverable. These the protective device is the empty pipe and the underfloor component the serving as a light underfloor fire, so is this way a wiring of the underfloor fire with two or more in to manage the empty pipe cables.

From It is also advantageous if a bottom of the recess by a asphaltically bound base course of the asphalted traffic area is formed. This ensures that the base layer of the paved traffic area largely undisturbed is and so a particularly homogeneous support for an asphaltic Superstructure provides. The asphaltic base layer can here in particular of a hydraulically bound support layer, about a cement-containing support layer, be subordinate.

When Furthermore, it has proven advantageous if at least one wall the recess has at least partially an adhesion promoter. So can in particular side walls of the recess pretreated with a pressure-sensitive adhesive or by spraying with a Bituminous spray against dissolution be secured by loose material from the side wall.

According to one Another advantageous embodiment of the invention is the mastic asphalt placed in layers in the recess. This is a shortening the cooling time of Gussasphalts achievable. The required Cooling time depends primarily on one Width of the recess from. A duration of the cooling time to be provided is advantageously very predictable here.

According to one further advantageous embodiment of the invention on a surface of the load transfer medium having Recess scraper material applied. So can by applying for example, from Abstrecksplitt and / or Abstreusand the surface be provided with a desired grip. Especially So can the grip of the surface of the recess to a Grip of the adjacent to the recess portion of the adapted to paved traffic area.

From It is also advantageous if a gap between a side wall the recess and the solidified load transfer medium a Verfugungsmittel having. This reflects the fact that a cooling of the cast asphalt to a replacement of the cast asphalt of the side walls of the recess leads. By the subsequent Inserting a grout in the joint is an intrusion of water in the paved traffic area in the area the recess particularly largely avoidable. For the grout is it advantageously a permanently elastic grout, for example, a permanently elastic bitumen-based hot casting, which can be processed at a temperature of about 160 ° C. is.

In a further advantageous embodiment of the invention is Load transfer medium in the region of the recess covered by a cover layer, which a portion of the adjoining the recess asphalted Traffic surface is designed to cover. Thereby is a particularly large flatness of the asphalted traffic area attainable, since a uniform covering layer both in the range of Recess as well as in the side adjacent to the recess Part of the traffic area is formed.

Furthermore, such a provision of a common, in particular new cover layer is advantageous if a plurality of recesses are relatively close to each other with protective devices introduced in each case. If the covering layer is carried out in a timely manner, ie comparatively quickly after the introduction of the cast asphalt into the recess, then in particular the introduction of a grouting agent into the joint between the side wall of the recess and the groove can be made solidified load transfer medium can be dispensed with. The installation of the new, common cover layer can take place, in particular, following a surface milling of the existing cover layer and an upper layer of the cast asphalt in the region of the recess.

A comparatively flat paved traffic area is also then provided when a surface of the recess with a cover layer of a portion of the adjacent to the recess paved traffic area flush is trained.

According to one further advantageous embodiment of the invention, the asphalted Traffic area a below a cover layer arranged, Having a support layer underlying binder layer, which at least partially adjacent to the load transfer medium in the recess. Even with such, at least three-layered construction of the asphalted Traffic area is poured asphalt as a load transfer medium particularly suitable for discharging loaded loads.

The paved traffic area may be a flying surface, For example, a runway, a runway or a Apron, and / or one suitable for heavy goods traffic Traffic area include. Especially with such, strong Load changes exposed asphalted traffic areas The use of mastic asphalt as a load-bearing medium is particularly special high degree suitable for a reduced susceptibility to damage paved traffic area with respect to load changes contribute.

After all it has been shown to be advantageous when a to the protective device adjacent space of the recess at least until under a cover layer the asphalted traffic area completely with Mastic asphalt is filled. This is a particularly big one Homogeneity of the load transfer medium in the recess guaranteed.

According to one Another aspect of the invention, the above object is achieved by the use of a load transfer medium for a paved traffic area, which is one in the traffic area defined recess formed and arranged in the recess, Having a cavity providing protection device. in this connection is in the recess the flowable during insertion, solidified load transfer medium introduced. As the load transfer medium, which is at least partially in contact with the protective device, a mastic asphalt introduced into the recess is used.

The described for the asphalted traffic area preferred embodiments and advantages also apply for the use of the invention Load transfer medium.

Of Furthermore, the above object is achieved by a paved traffic area with one in the traffic area defined recess formed with one in the recess arranged, a cavity providing protection device, wherein a flowable in the recess, solidified load transfer medium is introduced, and wherein the Load transfer medium at least partially with the protection device is in contact. Here is the load transfer medium which at least partially in contact with the protective device, at least proportionately prepared by introducing a Gussasphalts in the recess.

In Advantageously, this is after the manufacture of the recess cleaned the recess and / or at least one wall the recess at least partially with a bonding agent Mistake. By cleaning the recess is a special good joining of the cast asphalt with a section adjacent to the recess reach the asphalted traffic area. additional and alternatively, the primer serves an improved connection of cast asphalt to this sub-area.

When Furthermore, it has proven to be advantageous if a predetermined altitude the protective device in the recess and / or a predetermined Distance of the protective device to a side wall of the recess by means of a when introducing the Gussasphalts the protective device position-retaining holding means is attached. As such Holding means can be used, for example, a wooden wedge or the like be, by which a floating of the protective device, in particular at the initial introduction of Gussasphalts, preventable is. Alternatively or additionally, the protective device by means of an iron bar or the like within the recess adjusted, in particular centrally arranged.

From It is also advantageous if the load transfer medium by introducing of Gussasphalts made in at least two layers in the recess is. This is a particularly short installation time of a backfilling achievable with Gussasphalts, as the multi-layer built mastic asphalt faster than one inserted into the recess in a single operation Mastic asphalt cools and solidifies faster. Such production of the load transfer medium in multiple layers is especially at a comparatively large depth the recess advantageous.

When It has proven advantageous in this case if the load transfer medium at least proportionately manufactures so that a second layer of Gussasphalts depending on a temperature of a first layer of the introduced into the recess casting asphalt is introduced. For example, the second layer of Gussasphalts on the first layer applied when a temperature of the first layer from initially more than 200 ° C to 120 ° C has dropped. A monitoring of the temperature of the casting asphalt is also advantageous in terms of traffic clearance, since already at a surface temperature of about 60 ° C up to 70 ° C of poured asphalt rolling over the asphalted Traffic area, in particular heavy goods vehicles, is possible.

Preferably The paved traffic area includes a cavity providing protective device whose position in the finished paved road surface is made in such a way that a defined recess in the asphalted traffic area an insertion of the protective device takes place in the recess, wherein then introducing a flowable, the protective device at least partially contacting load transfer medium in the recess takes place. Subsequently, an increase takes place the strength of the load transfer medium. This increase the strength of the load transfer medium is a result of cooling the load transfer medium, which is one in the recess introduced poured asphalt acts.

in this connection can advantageously introducing the Gussasphalts and increasing the strength is repeated in succession, in particular, repeated twice to ensure rapid installation to reach.

To the solidification of the load transfer medium, an upper layer of Load transfer medium and a top layer of paved traffic area in a laterally adjacent to the recess portion of the asphalted traffic area are removed and subsequently the paved traffic area with a recess covering the be provided new cover layer. This new, uniform topcoat is covered So evenly both the recess and at least partially, the adjacent to the recess portion the asphalted traffic area.

Further Features of the invention will become apparent from the claims, the figures and the description of the figures. The above in the description mentioned features and feature combinations and the following mentioned in the description of the figures and / or in the figures alone shown features and feature combinations are not only in the each specified combination, but also in other combinations or used alone, without the scope of the invention to leave.

Further Advantages and details of the invention will become apparent from the following Description of a preferred embodiment and by reference the figures. Showing:

1 a schematic sectional view of a paved traffic area with a slot formed in the traffic surface and with an arranged in the slot empty tube, as a load transfer medium into the slot a mastic asphalt is introduced;

2 a section through an area formed as Vorbetriebsfläche asphalted traffic area, in which an underfloor fire is connected to a misplaced in the empty conduit connection cable;

3 a temperature curve in the slot according to 1 introduced second layer of Gussasphalts; and

4 a temperature curve in the slot according to 1 introduced third layer of cast asphalt.

1 shows on average a section of a paved traffic area 1 , which in this case is a Flugbetriebsfläche. On such a flight operations area, such as a runway, runway, runway, or an apron, move among other aircraft. As optical aids for traffic management are therefore in such air operations areas so-called underfloor fire 2 one of which, when removed, is in 2 is shown. An underfloor fire 2 is a light module with at least one light source.

The electrical supply of the underfloor fire 2 takes place via a transformer shaft not shown here, which outside the paved traffic area 1 and thus at some distance from the underfloor fire 2 is arranged. For the cable connection between the transformer shaft and the underfloor fire 2 is in the asphalted traffic area 1 a conduit 3 laid, which serves as a cable protection tube and allows subsequent replacement or subsequent introduction of other cables.

In the in 1 shown empty pipe 3 are two connecting cables 4 moved to which the underfloor fire 2 is connectable. A connection cable 5 of the underfloor fire 2 is here in a vertical core drilling 6 introduced, over which in the empty tube 3 arranged connection cable 4 are accessible (cf. 2 ).

In a new investment in the paved traffic area 1 can the empty pipe 3 planned at the desired location and accordingly in the paved traffic area 1 be introduced. However, retrofitting the rolling guide, or changing a guideline or the like, may involve laying or supplementing underfloor lights 2 make necessary.

At the in 1 shown asphalted traffic area 1 is the retrofitted empty pipe 3 with comparatively low civil engineering effort and without the need for a fundamental renewal of the paved traffic area 1 in the asphalted traffic area 1 brought in.

For this was in the asphalted traffic area 1 by milling a slot 7 produced. A width 8th and a depth 9 of the slot 7 are here depending on an outer diameter of the empty tube 3 , a height extension 10 of the underfloor fire 2 (see. 2 ) and the existing structure of the paved traffic area 1 established.

Are, as shown here by way of example, two connecting cables 4 for connecting the underfloor fire 2 in the empty pipe 3 retracted, so can as a conduit 3 an empty pipe with a diameter of DN 40 can be used. Preferably, the empty tube 3 So to allow a connection of the underfloor fire 2 a diameter of DN 40 to DN 150, but are also slots 7 for empty pipes 3 with diameters from DN 25 to DN 200 can be used advantageously.

The depth 9 of the slot 7 is presently greater than the maximum height extent 10 of the underfloor fire 2 so that after making a first core hole 11 with one to record the underfloor fire 2 suitable large diameter the narrower core hole 6 for insertion of the connection cable 5 in the empty tube 3 can be executed. Generally should be between a pipe apex 3a of the empty pipe 3 and a lower edge 2a of the underfloor fire 2 be provided a distance of about two centimeters.

The width 8th of the slot 7 is larger than the outer diameter of the empty pipe 3 so that the empty pipe 3 from side walls 12 of the slot 7 is spaced. After making the slot 7 this was cleaned, so freed from milled material and debris. Subsequently, the side walls were 12 of the slot 7 with a primer, for example with a pressure-sensitive adhesive or a bituminous spray provided. Then the empty pipe became 3 in the slot 7 inserted.

As a load transfer medium was then poured asphalt 13 in a first, the empty pipe 3 covering position in the slot 7 brought in. Here came a mastic asphalt 13 used, whose material properties of those of the binder in one of the slot 7 adjoining subarea 14 the asphalted traffic area 1 are the same. So if it is in the sub-area 14 used binder is road-bitumen, is preferred for the mastic asphalt 13 also to use road construction bitumen. Analogously, an application of polymer-modified bitumen for the mastic asphalt 13 advantageous if the subarea 14 the asphalted traffic area 1 also has polymer-modified bitumen as a binder. Is in the subarea 14 Low-temperature asphalt installed so should be in the slot 7 Low-temperature cast asphalt are used. The introduction of cast asphalt 13 in the slot 7 as load transfer medium causes the paved traffic area 1 has a uniform material behavior with temperature changes and / or load changes.

By almost completely surrounding the empty tube 3 with the first layer of cast asphalt 13 is created a vaulting effect, which allows ideal conditions for deriving introduced loads.

To a floating of the empty pipe 3 when introducing the first layer of Gussasphalts 13 To prevent wooden wedges or similar holding means can be used. For centering the empty pipe and / or to hold down on a floor 15 of the slot 7 can during the installation of cast asphalt 13 Iron bars or the like can be used. In the present case is the empty pipe 3 by means of such a holding means in the slot 7 positioned.

The empty pipe 3 is presently designed as a glass fiber reinforced winding tube with an epoxy resin having plastic, which is dimensionally stable and the high temperature load when introducing the Gussasphalts 13 and the mechanical load, such as when adjusting, well withstands.

The floor 15 of the slot 7 is present within an asphaltically bound base course 16 the asphalted traffic area 1 arranged. This asphaltically bound base course 16 is in the subarea 14 the asphalted traffic area 1 from an asphaltic binder course 17 superimposed on which on the upper side an asphaltically bound top layer 18 followed. The binder layer 17 For example, has a thickness of eight centimeters, the top layer 18 example have a width of four centimeters. The asphaltically bound base course 16 can, as exemplified herein, of a hydraulically bonded support layer 19 be subordinate. Below the hydraulically bonded, for example, cement-bearing, supporting layer 19 in the present case is an unbound antifreeze layer 20 arranged.

To completely fill the slot 7 with mastic asphalt 13 this is installed in three layers here. As a result, a significant reduction in the cooling time of Gussasphalts 13 achievable as opposed to installation in one operation.

Preferably, the load transfer medium is available, in particular manufactured, that mastic asphalt 13 in the slot 7 is introduced, is introduced in particular in several layers.

In an embodiment of a paved traffic area, not shown here, after solidification of the cast asphalt 13 in the slot 7 an upper layer of cast asphalt 13 and the topcoat 18 the asphalted traffic area 1 in one side in the slot 7 adjoining subarea 14 be removed. Then then the paved traffic area, ie the area of the Schlit zes 7 including the laterally adjacent portion 14 provided with a new, uniform and very even topcoat.

3 shows a diagram with a curve 21 indicating a drop in surface temperature on a second layer of the casting asphalt 13 illustrated. The temperature is here on an ordinate 22 , the time on an abscissa 23 applied. How out 3 is recognizable, is at a slot 7 with a width 8th of, for example, fifteen centimeters, a rapid and continuous decrease in the temperature of the casting asphalt sheet 13 given. In the present case, the temperature in the second layer decreased from 170 ° C to 90 ° C in a time of forty-five minutes. The second layer of cast asphalt 13 was in the slot 7 introduced when a surface temperature of the first layer had dropped to 120 ° C.

4 shows another curve 24 in a diagram according to 3 , which shows a temperature profile on a surface of the third layer of Gussasphalts 13 illustrated. Here too, a comparatively continuous but particularly rapid decrease in the surface temperature from about 190 ° C. to 90 ° C. was observed within thirty minutes. After finishing the third layer of cast asphalt 13 was on a surface of the cast asphalt 13 , which are flush with the top layer 18 of the subarea 14 is finally formed, a Abstreumaterial applied to a grip of the surface in the region of the slot 7 a grip of the top layer 18 of the subarea 14 equalize.

After cooling the cast asphalt 13 in the upper part of the slot 7 was in a respective joint between the sidewall 12 of the slot 7 and the solidified mastic asphalt 13 a permanently elastic grout 25 brought in. As a permanently elastic Verfugungsmittel 25 In the present case, a hot potting is in the paved traffic area 1 brought in. A water entry into the asphalted traffic area 1 as a result of the installation of the empty pipe 3 is avoided in the present case. Also contributes to the longitudinally watertight sheathing of the empty tube 3 through the mastic asphalt 13 at.

With carefully planned staggering of the operations for introducing the empty pipe 3 in the asphalted traffic area 1 A distance of 100 m to over 150 m can be realized within a construction time of 6 to 9 hours. This allows the introduction of the empty tube 3 For example, take place during the night during which the Flugbetriebsfläche is not available for flight operations.

Due to the rapid and particularly calculable cooling of the layers of Gussasphalts 13 in the slot 7 is a morning resumption of flight operations easily a rolling over the paved traffic area 1 possible. Already at a surface temperature of 60 ° C to 70 ° C of Gussasphalts 13 in the slot 7 In fact, a traffic clearance for the air traffic can already take place, so that the introduction of the last layer of the casting asphalt 13 only needs to be completed about forty five minutes to sixty minutes before the traffic release.

One in the way described in the asphalted traffic area 1 inserted empty pipe 3 can be used as a permanent rehabilitation measure of paved traffic areas damaged by the application of cable joints.

The present example of a Flugbetriebsfläche described introduction of the empty tube 3 in the asphalted traffic area 1 is also advantageous in other highly frequented traffic areas, especially in traffic areas suitable for heavy traffic, which are only a few hours a construction operation available.

The present described introducing the empty tube 3 in the subsequent completely with mastic asphalt 13 filled slot 7 is also suitable for renovation paved traffic areas in which a arranged in a recess empty pipe with concrete as a load transfer medium to is sheathed. Here, the existing empty pipe including the concrete casing can be milled. Subsequently, in the slot produced by milling 7 as described herein a new, the milled empty tube replacement empty tube 3 introduced and the slot 7 with the poured asphalt 13 be filled.

Even with a complete renovation of a paved traffic area 1 in high installation is the introduction of the empty pipe 3 in the subsequent with mastic asphalt 13 to be filled slot 7 imaginable. In such a complete refurbishment in high installation becomes an existing paved traffic area 1 completely provided with a new ceiling. This can be done to the desired laying of the empty pipe 3 a corresponding recess be provided in the newly created ceiling. In a merely moderately reapplied ceiling, the slot 7 also only relatively flat milled into the existing substructure.

Also with a new installation of the paved traffic area 1 is the introduction of the empty pipe 3 in the subsequent with mastic asphalt 13 to be filled slot 7 can be used advantageously, since such a homogeneous support for the superstructure is provided.

The introduction of the empty tube 3 in the with the poured asphalt 13 filled slot 7 is also advantageous applicable when thick cable strands in the paved traffic area 1 be introduced, for example, supply cable for induction loops or supply of temperature and / or humidity measuring devices in the paved area 1 cable strands to be inserted.

QUOTES INCLUDE IN THE DESCRIPTION

This list The documents listed by the applicant have been automated generated and is solely for better information recorded by the reader. The list is not part of the German Patent or utility model application. The DPMA takes over no liability for any errors or omissions.

Cited non-patent literature

• - DIN EN 12591 [0011]
• - DIN EN 14023 [0011]
• - DIN EN ISO 6708 [0012]

Claims (24)

Asphalted traffic area with one in the traffic area ( 1 ) defined recess ( 7 ), and with one in the recess ( 7 ), a cavity providing protective device ( 3 ), wherein in the recess ( 7 ) a flowable, solidified load transfer medium ( 13 ), and wherein the load transfer medium ( 13 ) with the protective device ( 3 ) is at least partially in contact, characterized in that the load transfer medium a mastic asphalt ( 13 ), which with the protective device ( 3 ) is at least partially in contact. Asphalted traffic surface according to claim 1, characterized in that at least one material property of a bituminous binder of Gussasphalts ( 13 ) is at least substantially equal to a material property of a binder, which is a subregion adjoining the recess ( 14 ) of the paved traffic area ( 1 ) having. Asphalted traffic surface according to claim 1 or 2, characterized in that the mastic asphalt ( 13 ) Has road construction bitumen and / or polymer-modified bitumen and / or is designed as a low-temperature cast asphalt. Asphalted traffic surface according to one of claims 1 to 3, characterized in that the recess as a slot ( 7 ) and the protective device as a conduit ( 3 ) are formed. Asphalted traffic surface according to claim 4, characterized in that the slot ( 7 ) a width ( 8th ), which at least in the region of the empty tube to be inserted ( 3 ) is greater than a maximum lateral extent of the empty tube ( 3 ). Asphalted traffic surface according to claim 4 or 5, characterized in that the slot ( 7 ) a depth ( 9 ), which is greater than a sum of a maximum height extent of the empty tube ( 3 ) and a thickness of a cover layer ( 8th ) one to the slot ( 7 ) adjacent subarea ( 14 ) of the paved traffic area ( 1 ). Paved traffic surface according to one of claims 4 to 6, characterized in that, in particular designed as a winding tube, empty tube ( 3 ) is formed of a fiber-reinforced, in particular glass fiber reinforced, plastic. Asphalted traffic surface according to one of claims 1 to 7, characterized in that an overlap of a vertex of the protective device ( 3 ) with the load transfer medium ( 13 ) is greater than a maximum height extent of one in the paved traffic area ( 1 ) introduced underfloor component, in particular an underfloor fire ( 2 ). Asphalted traffic surface according to one of claims 1 to 8, characterized in that a ground ( 15 ) of the recess ( 7 ) by an asphaltically bonded, in particular by a hydraulically bound support layer ( 19 ) subbed, support layer ( 16 ) of the paved traffic area ( 1 ) is formed. Asphalted traffic surface according to one of claims 1 to 9, characterized in that at least one wall ( 12 ) of the recess ( 7 ) has at least partially an adhesion promoter. Asphalted traffic surface according to one of claims 1 to 10, characterized in that the mastic asphalt ( 13 ) in layers in the recess ( 7 ) is introduced. Asphalted traffic surface according to one of claims 1 to 11, characterized in that on a surface of the load transfer medium ( 13 ) having recess ( 7 ) a Abstreumaterial is applied. Asphalted traffic surface according to one of claims 1 to 12, characterized in that a joint between a side wall ( 12 ) of the recess ( 7 ) and the solidified load transfer medium ( 13 ), in particular permanently elastic, jointing agent ( 25 ) having. Asphalted traffic surface according to one of claims 1 to 13, characterized in that the load transfer medium ( 13 ) in the region of the recess ( 7 ) of a cover layer ( 18 ), which covers a subarea ( 14 ) to the recess ( 7 ) adjacent paved traffic area ( 1 ) is designed to cover. Asphalted traffic surface according to one of claims 1 to 14, characterized in that a surface of the recess ( 7 ) with a cover layer ( 18 ) of a subarea ( 14 ) to the recess ( 7 ) adjacent paved traffic area ( 1 ) is designed to be flush. Asphalted traffic surface according to one of claims 1 to 15, characterized in that the paved traffic area ( 1 ) one below a cover layer ( 18 ), from a base layer ( 16 ) underlying binder layer ( 17 ), which at least partially to the load transfer medium ( 13 ) in the recess ( 7 ) adjoins. Asphalted traffic area after one of the Claims 1 to 16, characterized in that the paved traffic area ( 1 ) comprises a flight operations area and / or a traffic area suitable for heavy traffic. Asphalted traffic surface according to one of claims 1 to 17, characterized in that a to the protective device ( 3 ) adjacent space of the recess ( 7 ) at least until under a cover layer ( 18 ) of the paved traffic area ( 1 ) completely with mastic asphalt ( 13 ) is filled. Use of a load transfer medium ( 13 ) for a paved road ( 1 ), in particular according to one of claims 1 to 18, which one in the traffic area ( 1 ) defined recess ( 7 ) and one in the recess ( 7 ), a cavity providing protective device ( 3 ), wherein in the recess ( 7 ) the flowable, solidified load transfer medium ( 13 ), and wherein the load transfer medium ( 13 ) at least partially with the protective device ( 3 ) is in contact, characterized in that as the load transfer medium, which at least partially with the protective device ( 3 ) is in contact, one in the recess ( 7 ) poured mastic asphalt ( 13 ) is used. Paved traffic area, in particular according to one of claims 1 to 18, with a traffic area ( 1 ) defined recess ( 7 ), with one in the recess ( 7 ), a cavity providing protective device ( 3 ), wherein in the recess ( 7 ) a flowable, solidified load transfer medium ( 13 ), and wherein the load transfer medium ( 13 ) at least partially with the protective device ( 3 ) is in contact, characterized in that the load transfer medium, which at least partially with the protective device ( 3 ) is in contact, at least partially by introducing a Gussasphalts ( 13 ) in the recess ( 7 ) is made. Asphalted traffic surface according to claim 20, characterized in that after the production of the recess ( 7 ) the recess ( 7 ) and / or at least one wall ( 12 ) of the recess ( 7 ) is provided at least partially with a bonding agent. Asphalted traffic surface according to claim 20 or 21, characterized in that a predetermined altitude of the protective device ( 3 ) in the recess ( 7 ) and / or in a predetermined distance of the protective device ( 3 ) to a side wall ( 12 ) of the recess ( 7 ) by means of a when introducing the casting asphalt ( 13 ) the protective device ( 3 ) position-retaining holding means is brought about. Asphalted traffic surface according to one of claims 20 to 22, characterized in that the load transfer medium by introducing the Gussasphalts ( 13 ) in at least two layers in the recess ( 7 ) is made. Asphalted traffic surface according to claim 23, characterized in that a second layer of Gussasphalts ( 13 ) in dependence on a temperature of a first layer of the casting asphalt introduced into the recess ( 13 ) is introduced.