EP0587155A1 - Plant for making fresh concrete - Google Patents

Abstract

A novel plant (1) for the production of freshly mixed concrete is proposed which suffices with lower investment costs compared with conventional concrete plants. For this purpose, a plurality of silo chambers (14) for various concrete components are arranged within a common silo housing (1) as tower silo. This results in short conveying paths in the production sequence and a uniform, compact design of the overall plant. As a result of the construction according to the invention, the concrete plant can be constructed in particular by means of a cost-effective steel structure. <IMAGE>

Description

The invention relates to a concrete plant for the production of fresh concrete according to the preamble of claim 1.

Fresh concrete is mainly used in large quantities at large construction sites and is delivered to the corresponding construction sites by truck with a concrete mixing attachment from fresh concrete plants. In the fresh concrete plants, the concrete must be made available in the desired quality and in sufficient quantity.

Concrete plants of this type include silos for the individual concrete components, ie: cement, sand, gravel or the like, the components mentioned additionally being present in different properties, for example with regard to their grain size. The starting materials are usually dosed with a weighing device finally to be mixed in a mixing device to the desired fresh concrete. Then, as is known, the concrete is filled into concrete transporters and used.

In conventional concrete plants, the storage of the raw materials, the weighing device and the mixing device are far apart. The transport between these apart locations is done by conveyor belts. The long conveying paths and the structural necessity when building such a concrete plant mean an immense effort.

In addition, bulk goods that contain moisture, such as sand or gravel, must be protected from excessive cold in winter, because the freezing of the water contained in the bulk material will lose the free-flowing properties of the bulk material, which will make handling of these goods considerably more difficult.

The object of the invention is therefore to propose an arrangement for the various devices necessary for the production of fresh concrete, which entails lower investment costs when building the concrete plant and which enables the short transport routes of the concrete components during the production of the concrete. In addition, simple and energy-saving cold protection for moist bulk goods such as sand or gravel should be made possible.

This object is achieved by the characterizing features of claim 1.

Accordingly, in a concrete plant according to the invention, several silo chambers for different components of the later fresh concrete are built within a common silo housing.

This provides a structure for the concrete plant which, thanks to its compact design, significantly reduces investment costs. The transport routes are considerably shortened because the individual components are in close proximity to one another and to the processing points.

Advantageous further developments and improvements of a concrete plant according to the invention are possible through the measures specified in the subclaims.

For a compact design, it is advisable to arrange the silo chambers around a common center with adjoining or paired common partitions. As a result, the full cross section of the silo housing is used to store the concrete components.

To simplify the construction, the silo chambers are arranged in the form of a polygon with the same side lengths or a circle, the partitions of the individual chambers extending from the circumference of the polygon or the circle to the center.

Such a symmetrical design allows individual components to be used in large numbers, thereby reducing costs.

For the cement chambers, it is advisable to provide a cone or angled surfaces arranged in a funnel shape on the underside. Such a cone or funnel enables the cement chambers to be completely emptied. Such total emptying is beneficial for the quality of the fresh concrete, since in this way the cement cannot age excessively.

In the sand or gravel chambers, the underside can be formed more easily in the form of a horizontal bottom, whereby so-called trigger slide valves for dosing the bulk material are to be provided.

In order to achieve the desired protection against cold, an insulation layer in the outer wall of the silo housing is recommended. The application of such temperature insulation is in turn facilitated by the compact and symmetrical design and is therefore less expensive.

The insulation layer of the silo housing can be completed by a pipe system in the outer wall of the housing. It is important to note that fresh cement contains a not inconsiderable amount of residual heat when it is delivered. With a pipe system in which a heat-conducting medium circulates, this residual heat can be distributed to all silo chambers of the concrete plant. The advantages of using this residual heat for tempering the moist bulk goods are obvious and do not require any further explanation.

In order to save a separate conveying device, the weighing device for dosing the individual fresh concrete components can be attached directly below the silo chambers. The bulk goods trickle into gravity by themselves into the weighing device.

For the same reason, it is advisable to arrange the mixing device below the weighing device and to provide the filling device for the finished fresh concrete on its underside.

If, in addition, an entrance for a concrete transporter is installed in the bottom floor of the concrete plant, so that it can enter under the filling device, the concrete plant manages completely without additional conveying devices once the silo chambers are filled.

Since the entrance for the concrete transporter requires a significantly smaller area than the cross-section of the silo housing entails, additional rooms such as laboratory, storage, water and heating rooms can be provided on the bottom floor of such a concrete plant.

As a result of the measures mentioned, the concrete plant has a symmetrical elongated, possibly even cylindrical shape. The cross section of the entire structure remains the same from top to bottom. Due to this uniform and compact design, a steel structure is recommended for the realization of the concrete plant.

A steel structure that runs straight through from the floor to the top edge with a comparatively simple housing is an extremely cost-effective alternative when building such a system.

A load elevator, which is arranged on the side of the housing, is recommended for filling the high silo chambers. The bulk materials that he conveys to the top level of the concrete plant can then be conveyed on a conveyor belt under the roof of the housing in the middle.

A distributor arm, which can be pivoted about the individual silo chambers with an axis of rotation located in the middle of the housing, is supplied by the conveyor belt with the bulk material conveyed upwards by the load elevator. The distributor arm has its own conveyor system, for example a conveyor belt, and is therefore able to fill the various silo chambers depending on its rotational position.

The multi-chamber system described also proves to be of great advantage when filling the silo chambers, since the same conveyor system is used for each chamber.

An embodiment of the invention is shown in the drawing and is explained in more detail in the following explanations.

Fig. 1

einen schematischen Längsschnit durch ein erfindungsgemäßes Betonwerk,

Fig. 2

den oberen Teil aus Fig. 1 in vergrößerter Darstellung,

Fig. 3

den unteren Teil aus Fig. 1 in vergrößerter Darstellung,

Fig. 4-6

drei Querschnitte durch das Betonwerk auf verschiedenen Ebenen und

Fig. 7

eine Außenansicht eines erfindungsgemäßen Betonwerks.

Show it

Fig. 1

a schematic longitudinal section through a concrete plant according to the invention,

Fig. 2

the upper part of FIG. 1 in an enlarged view,

Fig. 3

the lower part of FIG. 1 in an enlarged view,

Fig. 4-6

three cross sections through the concrete plant on different levels and

Fig. 7

an external view of a concrete plant according to the invention.

1 shows a concrete plant 1 with a filling room 2, a silo room 3, a weighing room 4 and a mixer room 5. To the side of the concrete plant 1 there is a load elevator 6 with an ejection nozzle 7, under which the receiving end 8 of a conveyor belt 9 is located. The conveyor belt 9 ends above a conveyor hopper 10. Below this conveyor hopper 10, a distributor arm 11 is arranged to be pivotable about an axis of rotation 12. Its ejection opening 13 is located above silo chambers 14 which have cross members 15. In the middle of the silo room 3 there is a staircase 16 which leads from the weighing room 4 into the filling room 2. On the underside of the silo chambers 14 there are filling hoppers 17 with additional scales 18. Below of the aggregate scales 18, a hopper 19 which opens into a mixer 20 is provided. Below the mixer 20 there is a filling device 21, below which a schematically represented concrete transporter 22 is located in the entrance 23. The entrance 23 is on the bottom floor 24 of the concrete plant.

Filling room 2 and silo room 3 are shown enlarged together with the components contained therein in FIG. 2, as are the weighing room 4, the mixer room 5 and the bottom floor 24 in FIG. 3. The execution of the building in the form of a steel structure can be recognized by means of various struts 25, which are indicated in the area of the bottom floor 24. The outer skin 26 of the building is double-walled.

To produce fresh concrete, the starting components are first introduced into the respective silo chambers 14 provided for this purpose via the load elevator 6, the conveyor belt 9 and the distributor arm 11. The introduction of the bulk goods is of course not always necessary, since the silo chambers 14 have a large holding capacity. If required, the individual concrete components are metered via the filling hopper 17 and the addition scales 18 according to the desired concrete quality and added to the mixer 20 by means of the filling hopper 19. After the fresh concrete has been mixed, it is filled into a concrete transporter 22 for transport to the respective destination. The entire arrangement manages with minimal funding routes, since the individual processing points are close together. For the individual processing steps within the concrete plant after the silo chambers 14 have been filled, no additional driven conveying devices are required, since gravity can be used for the transport of goods during the production process. The thick double-walled outer skin 26 ensures good temperature insulation.

In winter, in particular, the residual heat of the cement in some of the silo chambers 14 can be used to warm up moist bulk goods in other silo chambers. In addition, such a simple construction of an inexpensive steel construction, which is continuous from bottom to top, as indicated by the struts 25 in the bottom floor 24, is accessible.

4 shows a cross section through the filling chamber 2. In this exemplary embodiment, it has the shape of an equilateral nine-corner. Partitions 27, which extend from the corner points 28 to the center point 29, divide the cross section into nine sub-segments, which form the silo chambers 14. Four of these segments 14 are covered by floor covering sheets 30, which can be placed if necessary, so that the entire filling space 2 is accessible via the floor covering surface 30. In the middle there is a grating 31, which serves as a catwalk when the flooring sheets 30 are removed. Each of the silo chambers 14 can be visually inspected via this grating 31. The grating 31 can be reached via the centrally located staircase 16.

In the cross section through the silo space 3 according to FIG. 5, four cement chambers 32 and five sand or gravel chambers 33 are shown. In this illustration, special attention deserves the funnel-shaped design of the bottom of the cement chambers 32 in the form of inclined triangles 34, the points of common contact 35 of which lie at the lowest point of the cement chambers 32, so that their total emptying is possible. Such total emptying is necessary from time to time to avoid the use of aged cement.

FIG. 6 shows a cross section through the bottom floor 24 of the concrete plant with the entrance 23 for a concrete transporter 22 not shown in this figure can be clearly seen that the floor plan in the bottom floor 24 allows space for a laboratory room 36, a boiler room 37 and a tank room 38. Of course, the rooms mentioned can also be used for other purposes. An ascent 39 is shown laterally in FIG. 6, which leads to the mixer room 5, which is located above the bottom floor 24 and is therefore not shown in FIG. 6.

7 shows an external view of a concrete plant according to the invention, the simple and compact construction in particular being clear. The front of the concrete plant is essentially filled by the outer skin 26. Several windows 40 are installed at the level of the bottom floor 24, the mixer room 5 and the weighing room 4. The lower end 41 of the concrete filling device can be seen in the entrance 23. 7 also shows the load elevator 6 with its ejection nozzle 7 and the receiving end 8 of the conveyor belt 9.

The steel structure of the building is indicated in the lower area by dash-dotted lines 42 instead of struts 25 in Fig. 1. The advantages of a steel construction, particularly with such a uniform and symmetrical design, are the significantly lower investment costs compared to other designs.

The outer circumference of the filling room 2 is set back somewhat from the rest of the building, so that a tour 43 results above the silo room 3. The building roof 44 is supported on the main structure of the building via support struts 45. The illustration also clearly shows that the ascent 39 leads to a door 46 of the mixer room 5. 1 Concrete plant 23 entrance 2nd Filling space 24th lowest floor 3rd Silo room 25th Strive 4th Weighing room 26 Outer skin 5 Mixer room 27 Partitions 6 Goods lift 28 Key points 7 Chute 29 Focus 8th End of recording 30th Flooring sheets 9 Conveyor belt 31 Grating 10th Conveyor funnel 32 Cement chamber 11 Distributor arm 33 Chamber of sand or gravel 12th Axis of rotation 34 triangle 13 Discharge opening 35 Point of contact 14 Silo chamber 36 Laboratory room 15 Cross member 37 Boiler room 16 Stairway 38 Tank room 17th Filling funnel 39 Ascent 18th Additional scales 40 window 19th Hopper 41 lower end 20th mixer 42 dash-dotted line 21 Filling device 43 Tour 22 Concrete transporter 44 top, roof 45 Support strut 46 door

Claims (15)

Concrete plant for the production of fresh concrete from sand, gravel and cement or the like, with silos for storing concrete components, a weighing device for dosing individual concrete components, a mixing device for mixing and a filling device for filling the finished fresh concrete into transport containers, characterized in that several silo chambers (14) for different concrete components within a common silo housing (1). Concrete plant according to claim 1, characterized in that the silo chambers (14) are arranged around a common center with adjoining or pair-wise common partition walls (27). Concrete plant according to claim 1, characterized in that the silo chambers (14) form a polygon with the same side lengths or a circle, the partitions (27) running between the circumference and the center. Concrete plant according to one of the preceding claims, characterized in that the cement chambers (32) are provided on the underside with inclined surfaces (34). Concrete plant according to one of the preceding claims, characterized in that the sand and / or gravel chambers (33) are provided with trigger slides. Concrete plant according to one of the preceding claims, characterized in that the outer wall (26) of the silo housing (1) has temperature insulation. Concrete plant according to one of the preceding claims, characterized in that a pipe system is located in the outer wall (26) of the housing (1). Concrete plant according to one of the preceding claims, characterized in that a weighing device (18) is arranged below the silo chambers (14). Concrete plant according to one of the preceding claims, characterized in that a mixing device (20) is arranged below the weighing device (18). Concrete plant according to one of the preceding claims, characterized in that a filling device (21) is arranged below the mixer device (20). Concrete plant according to one of the preceding claims, characterized in that an entry (23) for a concrete transporter (22) is provided in the bottom floor (24) below the filling device (21). Concrete plant according to one of the preceding claims, characterized in that additional rooms, such as laboratory, storage, water and heating rooms, are provided on the bottom floor (24) of the plant (1). Concrete plant according to one of the preceding claims, characterized in that the building (1) is constructed in the form of a steel structure. Concrete plant according to one of the preceding claims, characterized in that there is a load elevator (6) for filling the silo chambers (14). Concrete plant according to one of the preceding claims, characterized in that a distributor arm (11) is provided for the targeted filling of individual silo chambers (14).

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