EP0391427A2 - Process and apparatus for environmentally safe preparation of an asphaltic mixture using recycled asphalt - Google Patents

Abstract

A method and a device for the environmentally friendly preparation of asphalt mix with reuse of broken old asphalt and the addition of new material such as gravel, grit or sand are created, the old asphalt portion (M _A ) in a first drum device (1) and the Proportion of new material is processed in a second drum device (2) and the polluted exhaust gases from the first drum device (1) are introduced into the burner area of the second drum device (2). Here, the second drum device (2), which is driven in counterflow, is divided into two sections (13) and (14), the new material (M _N ) being processed in the first section (13), and that in the exhaust gases contaminants (CH _x , CO) contained in the first drum device (1) are burned out in the second section by intensive mixing with the burner flame, and then the resulting hot gases for processing the new material (M _N ) in the first section (13) second drum device (2) can be initiated.

Description

The invention relates to a method and a device for the environmentally friendly preparation of asphalt mix with reuse of broken old asphalt and addition of new material such as Gravel, grit or sand, the old asphalt portion being processed in a first drum device and the new material portion being processed in a second drum device and the pollutant-laden exhaust gases from the first drum device being introduced into the burner area of the second drum device.

Such a method and a corresponding device for this are known from DE-OS 34 41 382. There, the old asphalt portion is heated in the first rotating drum device in the co-current process under the conditions of largely avoiding damage to the old bitumen, in a second rotating drum device the new material is heated higher than the old asphalt part in the counter-current process, and that separated and heated to different temperatures, old asphalt and new material portions after leaving the respective drum devices in at least one further mixer and adjusted there if necessary with renewed heat supply and addition of fresh bitumen and filler material to the end product. The CH _x and CO contaminated and contain the finest bitumen particles exhaust gases from the first drum device are introduced directly into the second drum device and heated under the influence of the burner acting in the second drum device so high that the pollutants are burned or decomposed, the in the second drum device further heated exhaust gases together with the burner gases be used to heat the new material to temperatures above those of the old asphalt. It is furthermore provided that the exhaust pipe leading from the first drum device opens directly adjacent to the burner in the second drum device, ie the pollutant-laden exhaust gases from the first drum device are thus transported as close as possible to or into the burner flame.

The operation of such a system described above in the past years has shown that the CH _x and CO components in the exhaust gases of the first drum device through the introduction into the second drum device, which is operated at a higher temperature, are actually reduced but not completely eliminated by combustion will.

For this purpose, the second drum device would have to be operated at even higher temperatures between approximately 800 to 1000 ° C., and the exhaust gas from the first drum device should be mixed as evenly as possible with the hot combustion gases of the burner of the second drum device. The high temperature has the disadvantage that the new material is heated too high and therefore cannot be added immediately after leaving the second drum device to the old asphalt portion discharged from the first drum device in the compulsory mixer, because this old asphalt portion is heated to a maximum of only 220 °, advantageously to 180 °.

It is therefore an object of the present invention to provide a method and also a device which, on the one hand, significantly improve the known environmentally friendly method, in particular, completely remove CH _x and CO components from the exhaust gases to be released to the environment, and on the other hand Ensure that the new material processed in the second drum device is processed to a maximum of 300 ° C, but advantageously only up to the optimal temperature of approx. 200 ° C.

This object is achieved for the above-mentioned method in that the second drum device works in countercurrent and is essentially divided into two sections, the new material portion being processed in the first section and before reaching the second section in which the burner is arranged with its burner flame, is led out of the second drum device, the pollutant-laden exhaust gases from the first drum device are intensively mixed with the combustion gases of the burner flame in the second section of the second drum device, and the pollutants such as CH _x , CO and finest bitumen particles are burned out and then all of them Exhaust gases as hot gas for the preparation of the new material portion are passed through the first section and then out.
In contrast to the known methods described above, can be achieved on the basis of this proposed solution that the pollutant fe in the exhaust gases from the first drum device in the burner area of the second drum device is completely burned out, ie the CH _x and CO components are destroyed, but on the other hand the new material is processed at the desired optimum temperature and can be removed from the drum device.

The intensive mixing of the exhaust gases from the first drum device with the combustion gases of the burner of the second drum device advantageously takes place in that the exhaust gases are introduced with swirl into the second section of the second drum device.
The swirl of the exhaust gases is brought about by a tangential introduction of the latter into the second section.
This above-described introduction of the exhaust gases into the second section ensures particularly intensive mixing with the combustion gases.

The burner flame is advantageously also swirled by appropriate introduction of the primary air into the burner.
The swirl of the exhaust gases can be either the same or opposite to the swirl of the burner flame or the combustion gases.
The formation of a special section of the drum device reserved only for the burnout of the pollutants makes it possible to form a precisely defined flame or gas duct which promotes the burnout of the pollutants. In particular, by the be special swirling of the exhaust gases and, if appropriate, the primary air for the burner, an intensive mixing of the burner flame on the one hand with the exhaust gases to be burned out on the other hand can be achieved.

In a somewhat different embodiment of the invention, the exhaust gases from the first drum device can already be mixed with the primary air of the burner of the second drum device in an adjustable ratio.

The exhaust gases emerging from the second section are advantageously cooled down, so that the new material processed in the first section of the second drum device is heated by the exhaust gases to a maximum of 300 ° C. immediately before the beginning of the second section of the second drum device. This cooling of the exhaust gases takes place, for. B. by spraying water at the transition area from the first to the second section of the drum device.
This cooling process with regard to the exhaust gases at the predefined location within the drum device allows, on the one hand, a process-appropriate temperature determination for the new material intended for further processing and, on the other hand, a first cooling of the exhaust gases, so that these can be passed through the downstream filter systems without further cooling, if necessary, without destroying them.

The old asphalt portion is advantageously processed in a co-current drum device.
This mode of operation of the first drum device ensures gentle treatment of the old asphalt portion.

The object of the invention further to create a device for carrying out the method according to the invention is achieved in that the second drum device is divided into a countercurrent drum and is essentially divided into two different sections, the first section starting from the first Front wall, conveying devices are provided for the new material to be processed in this section, the burner is arranged in the second section, which is delimited from the first section by an outlet device for the new material, and a feed line for the from the first is located immediately adjacent to or in the burner Exhaust gas polluted by the drum device is provided.
This design of the second drum device ensures that there are two areas defined in terms of the method, one area being provided exclusively for the combustion of pollutants and the other area exclusively for the thermal treatment of the new material portion.

The second section of the second drum device is advantageously designed to be stationary, ie not rotating, with respect to the first section.

This design of the second section permits a structurally simpler design of the burner arrangement and the feed lines for the exhaust gas to be introduced in this section from the first drum device.

The second end wall, which closes the second section to the outside, is advantageously designed as a feed line for the exhaust gases from the first drum device.

Since the burner is also arranged in this second end wall, an embodiment integrated in the burner can be achieved by the above-described design of the feed line.

The feed line is advantageously of spiral design, and the exhaust gases are introduced tangentially into the second section in this feed line.
This training allows a special swirl of the supplied exhaust gases.

Further advantages of the device result from subclaims 15) to 20).

An embodiment of the device is explained with reference to the accompanying drawings.

• Fig. 1 eine Systemskizze einer Asphalt-Aufbereitungsan­lage,
• Fig. 2 eine Ansicht der zweiten Trommelvorrichtung in der Anlage gemäß Fig. 1,
• Fig. 3 eine Teilansicht bezüglich des zweiten Abschnit­tes der zweiten Trommelvorrichtung gemäß Fig. 2,
• Fig. 4 eine Teilansicht auf eine unterschiedliche Aus­führungsform gemäß Fig. 3 und
• Fig. 5 eine axiale Draufsicht auf die Brennerseite der zweiten Trommelvorrichtung und Fig. 3.

Show it:

• 1 is a system sketch of an asphalt processing plant,
• 2 is a view of the second drum device in the system of FIG. 1,
• 3 shows a partial view with respect to the second section of the second drum device according to FIG. 2,
• Fig. 4 is a partial view of a different embodiment according to FIGS. 3 and
• 5 is an axial plan view of the burner side of the second drum device and FIG. 3.

The device proposed for carrying out the method according to the invention forms part of an asphalt processing plant, as is shown schematically in FIG. 1.

The asphalt processing plant works essentially with two parallel drum devices 1 and 2, of which the drum device 1 for the processing of the old asphalt portion M _A in cocurrent and the second drum device 2 for the Preparation of the new material portion M _{N works} in countercurrent. Both drum devices 1 and 2 are followed by mixers 3 and 4, in which the old asphalt portion M _A and the new material portion M _{N are brought} together and brought together to form the asphalt mixture M _G to be processed.

Bitumen B and filler material F are added to the asphalt material.

The old asphalt portion M _A is drawn off from a storage device 5 via a wall scale 6 and introduced into the drum device 1, it being passed through the interior of the drum device 1 heated by the burner 7 in direct current.

This drum device 1 is provided at its end opposite the burner 7 with a schematically indicated exhaust gas line 8 and connected via this to the second drum device 2, the exhaust gas line 8 opening out adjacent to the burner 9 or possibly directly into it.

In this second drum device 2, the new material fraction M _N to be processed therein is drawn off from a storage device 11 by means of a belt scale 10 and introduced into the end wall 12 opposite the burner 9 and in counterflow through the first section 13 until shortly before the start of the second Section 14 out transported through, heated and then discharged from the second drum device 2.

Adjacent to the end wall 12, the second drum device 2 has an exhaust gas disposal line 15, which is connected to a filter dedusting system 16. From this filter dedusting system 16, the exhaust gases are released into the environment by means of a ventilation device 17.

The asphalt mix fractions M _A and M _N heated in the drum devices 1 and 2 are taken up by a first mixer 3, which can be designed, for example, as a double-shaft, forced and continuous mixer. In this mixer 3 fresh bitumen B from a bitumen storage container 18 and filler material F from a filler storage container 19 are again drawn off and added, mixed together and further heated so that the desired final temperature is maintained.

The mixer 3 can be followed by a structurally corresponding second mixer 4. Finally, the completely prepared asphalt mix M _{G is} withdrawn from the second mixer 4 and made available in a loading device 20 for removal.

In Figures 2 to 5, the actual object of the invention, namely the special design of the second drum device 2 is shown in more detail.

The second drum device 2 is essentially divided into two sections 13 and 14, which have different lengths.
The first section 13 is closed at one end by a first end wall 12, which end wall can contain both the total gas outlet 15 and an addition device (not shown in the figures) for the new material M _{N to} be processed in the second drum device 2.

The other end of the first section of the second drum device 2 borders on the second section 14 of the second drum device 2 and at this point a cooling device 21 is provided, which is designed, for example, as water injection. Here, the evaporation energy of the water is used in particular for cooling the hot gases. The water injection device consists, for. B. from an annular, water-carrying manifold with several nozzles distributed over the pipe length. The purpose of this arrangement is to cool the hot gases as evenly as possible over the entire drum cross section.

The second section 14 of the drum device 2 is closed off from the outside by the second end wall 22, which is designed as a feed line 23 for the exhaust gas brought in by the first drum device and contaminated with pollutants. In this end wall 22, the burner 9, which is only indicated schematically in FIG. 1, is provided as a burner 24 arranged concentrically to the longitudinal axis 25 of the second section 14.

In the exemplary embodiment described here, the diameter of the second section 14 is made smaller compared to the diameter of the first section 13 of the drum device 2, furthermore the longitudinal axis 25 of the second section 14 is offset upwards relative to the longitudinal axis 26 of the first section 13, so that the transition point between the first section 13 and the second section 14 of the drum device 2 below the second section 14 results in a distance which contains the outlet device 27 for the new material M _N.

On the inner wall of the first section 13 of the drum device, known conveyor devices are provided, not shown in the figures, which convey the new material M _N introduced into the first end wall 12 by the rotation of the drum device 2, in the embodiment described only the first one rotates Section 13 is transported to the outlet device 27.

The supply line 23 for the exhaust gas from the first drum device 1 is, seen in the axial direction, spiral, so that the exhaust gases introduced therein are introduced tangentially into the interior of the second section 14 of the drum device 2, namely in a ring along the walls of the second section 14 and concentric to the burner flame of the burner 24. This burner 24 receives the Pri necessary for the combustion of the fuel Mar air through the supply line 28, which may also be designed so that it introduces the primary air tangentially into the burner 24 and thus the burner flame experiences a swirl. The swirl of the burner flame in turn and the swirl of the exhaust gas supplied through the feed line 23 can be of the same or opposite.

In another illustration shown in FIG. 4, supply line 23 for the exhaust gases and supply line 28 for the primary air of the burner 24 are connected to one another by the line 29, i. that is, a part of the exhaust gases from the first drum device 1 and the necessary primary air are mixed with one another in a certain ratio before being fed to the burner 18. The exhaust gases, which are not fed via the burner to the drum device, are fed tangentially to section 14 of the drum device 2 via the feed line 23. Corresponding devices for setting this mixing ratio are not shown in the drawings.

Also not shown in the drawings are structural details relating to the mounting of the second drum device 2 and other measures known to the person skilled in the art.

The above-described asphalt processing plant, which is designed differently from known devices and thus carried out with respect to the second drum device, operates as described below.

The new material M _N introduced at the end wall 12 and intended for processing is transported through this first section 13 to the outlet device 27 by rotating the first section of the second drum device 2 and the conveying devices provided therein at a specific speed which can be changed. The new material M _N should not have a temperature higher than 300 ° C at its outlet, namely then together with the old asphalt portion M _A processed in the first drum device 1 in the downstream mixers 3 and 4 and with the addition of Fresh bitumen B and filler material F can be brought together and further processed without intermediate storage, namely to the final asphalt mix M _G to be used for installation in roads etc.

If the new material M _N reaches too high a temperature when the exit device 27 is reached, it is necessary to cool the very high-temperature heating gases from the second section 14 of the drum device 2, this is done by a cooling device 21, which is designed, for example, as water injection. The energy required to evaporate the water droplets is extracted from the hot gases, which results in a very effective cooling effect.

These heating gases have a temperature of up to approx. 1000 ° C. when they enter the first section 13 of the drum device 2 this is necessary to burn the pollutants (CH _x , CO and finest bitumen particles). These pollutants are contained in the exhaust gas of the first drum device 1. The burner 24 in the second section 14 of the drum device 2 must therefore develop much hotter hot gases, which are required for the pollutant combustion, than would be necessary solely for the preparation of the new material.

In summary, the above-described design of the second drum device 2 within the overall asphalt preparation plant ensures that fresh asphalt mix M _G can be produced, whereby on the one hand a not inconsiderable proportion of old asphalt from broken roads etc. can be used, and on the other hand that at Treatment of the old asphalt contaminants that are inevitably formed can be removed from the total exhaust gases of the two drum devices by the afterburning, so that the cleaned total exhaust gases, after they have passed through filter systems etc., can be easily discharged into the free atmosphere.

Claims (20)

1.) Process for the environmentally friendly preparation of asphalt mix using reused broken asphalt and adding new material such as gravel, grit or sand, the old asphalt portion being processed in a first drum device and the new material portion in a second drum device the pollutant-laden exhaust gases are introduced from the first drum device into the burner area of the second drum device, characterized in that the second drum device works in countercurrent and is essentially divided into two sections, the new material portion being processed in the first section and before being reached of the second section, in which the burner with its burner flame is arranged, is led out of the second drum device, the pollutant-laden exhaust gases from the first drum device in the second section of the second drum device intensi with the combustion gases of the burner flame v mixed and the pollutants such as CH _x , CO and the finest bitumen particles burned out and then all the exhaust gases as hot gas for processing the new material portion through the first section and then led out. 2.) Method according to claim 1, characterized in that the intensive mixing of the exhaust gases from the first drum device with the combustion gases of the burner of the second drum device takes place in that the exhaust gases are introduced with swirl into the second section of the second drum device. 3.) Method according to claim 2, characterized in that the swirl of the exhaust gases is brought about by tangential introduction into the second section. 4.) Method according to claim 2, characterized in that the burner flame is swirled by appropriate introduction of the primary air into the burner. 5.) Method according to claim 4, characterized in that the swirl of the exhaust gases is rectified the swirl of the burner flame or the combustion gases. 6.) Method according to claim 4, characterized in that the swirl of the exhaust gases is opposed to the swirl of the burner flame or the combustion gases. 7.) Method according to claim 1, characterized in that the exhaust gases from the first drum device device can already be added to the primary air of the burner of the second drum device in an adjustable ratio. 8.) Method according to claim 1, characterized in that the hot gases emerging from the second section are cooled down, so that the virgin material processed in the first section of the second drum device upon exit from the drum device immediately before the start of the second section of the second drum device by the hot gases is heated to a maximum of 300 ° C. 9.) Method according to claim 5, characterized in that the cooling of the hot gases is carried out by spraying in water at the transition region from the first to the second section of the drum device. 10.) Method according to claim 1, characterized in that the old asphalt portion is processed in a co-operating drum device. 11.) Device for carrying out the method according to claims 1.) to 10.), characterized in that the second drum device (2) is a countercurrent drum and essentially different in two trained sections (13 or 14) is divided, wherein in the first section (13), starting from the first end wall (12), conveying devices for the new material (M _N ) to be processed in this section (13) are provided, in the second section ( 14), which is separated from the first section (13) by an outlet device (27) for the new material (M _N ), the burner (24) is arranged and a feed line (23) for directly in the burner (24) the pollutant-laden exhaust gas originating from the first drum device (1) is provided. 12.) Device according to claim 11, characterized in that the second section (14) of the second drum device (2) relative to the first section (13) is stationary. 13.) Device according to claim 11, characterized in that the second section (14) closing outward second end wall (22) is designed as a feed line (23) for the exhaust gases from the first drum device (1). 14.) Device according to claim 13, characterized in that the feed line (23) is spiral-shaped, and the introduction of the exhaust gases into this feed line (23) takes place tangentially into the second section (14). 5 / ... 15.) Device according to claim 11, characterized in that the second section (14) has a smaller diameter than the first section (13). 16.) Device according to claim 15, characterized in that the second section (14) with its longitudinal axis (25) with respect to the longitudinal axis (26) of the first section (13) is offset upwards. 17.) Device according to claim 16, characterized in that the outlet device (27) for the new material (M N _{) is provided} in the transition region of the first section (13) to the second section (14). 18.) Device according to claim 11, characterized in that the feed line (23) for the exhaust gases from the first drum device (1) is connected to the feed line (23) for the desire to burn (primary air) of the burner. 19.) Device according to claim 11, characterized in that a feed device (15) for a coolant is provided in the transition region of the first section (13) to the second section (14). 20.) Device according to claim 19, characterized in that the coolant is water.

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