DE19627465A1 - Excavated material processing with additive admixture - Google Patents

Abstract

The excavated material is contained in a mobile bucket separator, pref. fitted to an excavator. The required additive quantity is supplied from the dispenser to the bucket separator, where the excavated material and additive are mixed together. During mixing the excavated material is separate to obtain grain-size determined material suitable for compacting and structural use. Such material is disposed into suitable locations, such as pits and trenches and compacted there. After compacting checks, the results are communicated to the dispenser for further use.

Description

The present invention relates to a method for processing excavation material material with admixture of aggregate as described in claim 1 is.

In the context of construction work, it is very often necessary to start with a Excavation must be made to build buildings or to conduct to lay in the ground. It is mandatory that unloaded earth excavation is no longer deposited in landfills, but has to be recycled. So it is So usually no longer possible, for refilling construction pits or also use trenches, for example material obtained from gravel pits the. Rather, an attempt must be made to at least unload the excavated earth Refill to use. However, this is not always easy possible. The reason for this are a. Grain sizes present in the excavation, which too are not suitable for reinstallation. The reinstallation of the trenches, for example In accordance with DIN 4033, drainage ducts and pipe guidelines are used for execution.

The relevant regulations initially make separation unsuitable Grain sizes of the excavated material required. The screening and mixing However, the floor alone is generally of no use for reinstallation. The Floors are usually too wet and do not have the required load-bearing capacity. The The remaining material is in most cases always for reinstallation not yet suitable, especially as far as cohesive soil material is concerned. It must then add an additive in a further step the or stabilizing additives in order to mix the separated Excavation material with the aggregate can ultimately be dismantled  to receive lifting material.

There are different ways of separating and adding additives Devices known.

The separation can take place with a so-called blade separator, which is offered under the trade name "ALU SM". This well-known Bucket separator is particularly suitable for use with wheel loaders and excavators is suitable. The back wall of the blade separator consists of turning quickly the waves, which are equipped with disks. Between the disks are out interchangeable mallets attached. The carrier device, for example the wheel loader or the excavator on which the bucket separator is arranged takes this Material like with a conventional shovel. With hydraulic drive then the waves are rotated. Through the energy input normal soils, but especially cohesive soils from the scree containing them separated and emerge through the spaces between the disks. Through the Clay floes and clayey material are broken down and in certain grain sizes separated. The debris remaining in the shovel - and thus the material that is not suitable for reinstallation - will then dumped separately.

If it is now necessary, the material that has escaped and is free of debris Various devices are known for further processing. Which devices are used, for example, is out of time document BMT, construction machinery and construction technology 5 6/1996. At the "Mixed-in plans "process uses large stationary systems that are only available at larger notes are profitable. As a mobile system, the "mixed-in-mobile plans "process known, in which further processing in one ago Conventional truck mixers for ready-mix concrete are made to deliver the mix directly to the To be able to transport the installation site. In the "mixed-in-place" process further processing directly at the installation location using push crawlers and floor milling. In terms of process engineering, the "mixed-in-place" processes, ie. H.  Preparation and homogenization of the sealing material at the installation site, and the "mixed-in-plant" process, the mixing in stationary plants, differ the. From the aforementioned article it is also apparent that grain-improved State-of-the-art additives can only be prepared in stationary systems. Hence come for that "Mixed-in-place" process only high-quality sealing materials in Question that does not require an additive.

Binding agents are incorporated into soils on large-scale earthworks pose, for example, with mobile tiller cutters with certain penetration depth fen or in stationary mixing plants.

Also known is the mobile ARAN mixing system, which uses a wheel loader the excavated material to be processed is loaded. Via an order volume this gets into the mixing trough. There is first the necessary water amount added. A metered addition then takes place somewhat delayed rer aggregates directly from a dosing vehicle via a specially for this Purpose-developed injector. The plant works continuously. The intensely mixed material comes on after passing through the mixing trough Discharge conveyor and can be used from there directly on free-standing trucks be loaded. This system is also required for profitability reasons that larger tones are processed.

In the Allgemeine Bauzeitung, issue 26/95, a soil preparation Center described, in which stationary rotation in a large plant separators are used, and if there is a pre-separation of rubble of cohesive soil is required, including vibro rod sizers that work with wheel loaders can be loaded.

The present invention has for its object a method for Preparation of excavated material with the addition of an aggregate to propose which is reliable, fast, flexible and above all in  Is economical in terms of smaller quantities.

The object is achieved by the method specified in claim 1.

With the proposed method, the blade separator known per se gate used in a previously unknown manner by a required Amounts of aggregate directly into the bucket separator before mixing begins or separation process is given. The dosing device for the Zu Impact can be made from relatively small-sized devices exist, such as a silo and a conveyor in the form a screw or a conveyor belt. Ultimately, to realize the The method according to the invention only applied devices that in Normally there are construction sites, especially if they are used for excavation excavator needed anyway is also used to close the bucket separator Taxes. So it can initially not or not built-in floors Buildable excavation material can also be prepared where, for example Tillage due to the limited space, such as. B. in trenches, can not be used or where the use of mobile or stationary mixing plants are not profitable because of the quantities involved. Furthermore, the proposed method without large volumes a large area of construction site equipment can be saved. With The present process can achieve the intended recycling targets for the first time can also be implemented economically when processing excavated material. In addition, resources are conserved, as gravel and gravel from pits and Quarries are hardly needed for re-installation. Furthermore Protected areas for landfill of unusable excavated material and in particular, the materials no longer have to be used, as is the case with mobile systems or stationary large systems is required over long distances on the Roads are transported, resulting in CO₂ emissions on the one hand and on the other the traffic load on our roads is greatly reduced.

It is useful if the introduction of the proposed by  Process now built-in material at designated locations, such as for example in trenches or construction pits, then the excavated material ßend is compacted and a compaction control, in particular by means of a dynamic plate printing device, takes place to the determined results of the Compaction control directly or indirectly to the metering device for the Amount of aggregate to be sent to change there if necessary dosing the required amount of aggregate. In order to it is possible to process the excavated material in terms of its properties check immediately to determine if necessary the dosage of aggregate change as soon as possible in order to improve or at least the required to be able to ensure the load-bearing capacity for the corresponding construction project. The measurement results can be transmitted via radio or also via direct data transmission to control the dosing device for the aggregates.

Furthermore, it may be advantageous if the material that can be built in is obtained is temporarily stored in order to then trans to be ported.

It is useful if the metering device from a silo, which the Aggregate contains a controllable output device for the aggregate fabric and a conveyor belt or a screw for transporting the issued aggregate exists. The above facilities are in As a rule, it is available at the construction site and it is not necessary to purchase it additional facilities to achieve the desired success.

The output device can advantageously be controlled via a time switch, thereby increasing the predetermined amount of aggregate for each operation receive.

The output device can advantageously be controlled via a remote control.  

Depending on the requirements, the aggregate consists of binders, ins special lime, cement, lime powder, the aforementioned materials also mixed as an additive can be added.

The blade separator, which is known per se, thus becomes a complete preparation processing of excavated material with equilateral separation of unwanted grain sizes and with the addition of aggregates to obtain installable used according to material.

Based on a flow chart, a particularly preferred one is given below Process sequence described on a trench construction site.

A pipe trench 2 is shown , in which a pipe is to be laid. Excavation takes place with an excavator 4 in the area 6 of the pipe trench 2 . The soil is loosened by the excavator 4 at the trench construction site and the excavated material is brought to a nearby central processing site 10 by trucks 8 .

At the processing station 10 , the excavated material is picked up by a second charger, here a second excavator 12 . A bucket separator 14 is arranged on the excavator 12 for receiving. Before the blade separator 14 is put into operation, after the untreated excavated material has been taken up, it is moved to a metering device for additives, here consisting of a silo 16 with a screw 18 arranged underneath. There, a predetermined amount of additives is first added to the bucket separator 14 to the excavated material located therein.

The blade separator 14 is then moved further to a nearby intermediate storage facility 20 . There, the blade separator 14 is put into operation and, in addition to a separation of undesired grain sizes, that is to say a separation of debris, a mixing process between the excavated material and the added aggregate takes place at the same time. While the unwanted grain sizes remain in the shovel separator, the now treated and ready-to-install, remaining material is accumulated on the intermediate storage 20 by leaving the shovel separator 14 after the treatment after running through the shafts to unlock the excavated material while simultaneously mixing with the aggregate.

The unusable material remaining in the blade separator 14 , that is to say the scree, is dumped out on a further intermediate storage 22 .

The blade separator 14 will then move back to the processing station 10 in order to pick up untreated excavation material for further treatment. It goes without saying that very little space is required for the treatment of the excavated material and the excavator 12 does not even have to be moved in the ideal case, but can only reach the corresponding workplaces by pivoting movements and moving the excavator arm in and out.

The material which has now been treated and can be installed is preferably loaded from the intermediate storage 20 onto a further truck 24 in order to bring it back into the excavated pipe trench 2 in the region 26 . After the material which can be installed is tipped out in the region 26 , compression takes place with simultaneous compression control, in particular by means of a dynamic plate printing device. The quality and properties of the installed and compacted material can be checked immediately with regard to load-bearing capacity and other values. The result is forwarded to the metering device for the aggregate, which basically consists of the silo 16 and the screw 18 . The output of the aggregate from the silo 16 to the screw 18 is carried out via a controllable output device 28 , which is preferably controllable via a timer and is in particular also controlled by a remote control. The results obtained can necessitate a correction of the amount of additive required, which can be implemented directly in the dispensing device 28 by either dispensing more or less additive onto the screw 18 .

The transmission of the compaction values (density measurement) after checking in the area 26 of the pipe trench 2 can take place, for example, via radio communication to the personnel of the excavator 12 . From there, the output device 28 can then be controlled via a signal. However, it is equally possible to transmit the compression control values directly to the output device 28 from the area 26 .

In summary, with the method proposed according to the invention, the required additive can be introduced directly into the blade separator 14 . The aggregate is conveyed from the silo 16 into the blade separator 14 by means of a screw conveyor 18 . The auger 18 can also be operated directly from the excavator 14 via a radio remote control. The required amount of aggregate can be determined in advance in a laboratory in order to then be metered exactly via a time control by means of the dispensing device 28 , the application to the screw 18 being carried out via the dispensing device 28 , which are also controlled during operation can that changed amounts of aggregate can be applied to the screw 18 .

Reference list

2 pipe trenches
4 excavators
6 Excavation area of the pipe trench 2
8 trucks
10 processing station
12 excavators
14 blade separator
16 silo
18 snail
20 interim storage facilities
22 interim storage facilities
24 trucks
26 Installation area of the pipe trench 2
28 dispenser

Claims (7)

1. Method for processing excavated material with the addition of aggregate with the following process steps:

• a) Determination of the required amount of aggregate based on the excavated material to be processed
• b) transmission of the amount of the required amount of aggregate to a metering device for the aggregate
• c) receiving the excavated material in a movable shovel separator, which is preferably arranged on an excavator
• d) introducing the required amount of aggregate from the metering device into the blade separator
• e) Mixing the excavated material with the required amount of aggregate in the bucket separator
• f) during the mixing process, separating the excavated material to separate excavated material of a certain grain size in order to obtain a buildable and compactable material.

2. The method according to claim 1 with the further steps:

• g) Introducing the material that can be installed at locations provided for this purpose, for example in trenches or excavations
• h) compressing the introduced, installable material
• i) Compaction control of the compacted material, in particular by means of a dynamic plate printing device
• k) direct or indirect transmission of the results of the compaction control to the metering device
• l) if necessary, change the required amount of aggregate by the metering device.

3. The method according to claim 1 or 2 with the further process steps

• m) Interim storage of the recoverable material
• n) Transport of the interposed, ready-to-install material to the place of introduction.

4. The method according to any one of claims 1 to 3, wherein the Dosiervor direction consists of a silo ( 16 ) containing the aggregate, a controllable output device ( 28 ) for the aggregate and a screw ( 18 ) for transporting the output aggregate. 5. The method according to any one of claims 1 to 4, wherein the output device is controllable via a timer. 6. The method according to any one of claims 1 to 5, wherein the output device is controllable via a remote control. 7. The method according to any one of claims 1 to 6, in which the supplement material from binders, in particular lime, cement, lime powder, the aforesaid mixed materials, exists.