WO2007057305A1

WO2007057305A1 - Method for transferring portable goods

Info

Publication number: WO2007057305A1
Application number: PCT/EP2006/068059
Authority: WO
Inventors: Karl-Heinz Gerlach
Original assignee: Siemens Aktiengesellschaft
Priority date: 2005-11-15
Filing date: 2006-11-03
Publication date: 2007-05-24
Also published as: DE202006020911U1; EP1949131A1; DE102005054840A1

Abstract

The invention relates to a method for transferring portable goods in open-cast mining between a first moving transfer apparatus (4) and a second moving transfer apparatus (5), with a base station (10), which is arranged on the second moving transfer apparatus, transmitting a base signal which is received by a multiplicity of transponders (13) which are each associated with reference points (9) of the first moving transfer apparatus (4), with the transponders (13) sending transponder signals to the base station (10). The relative position, the relative movement direction and/or the relative speed of the two transfer apparatuses (4, 5) with respect to one another are determined with the aid of the signal delay times, and the movement of at least one of these two transfer apparatus (4, 5), is determined on the basis of these control signals, preferably in a control apparatus (12). The invention allows safe, reliable and efficient transfer of portable goods in open-cast mining, especially in adverse conditions.

Description

description

Method for transferring bulk material

The invention relates to a method for transferring bulk ^¬ well, in particular for the transfer of rendem in surface mining to transportie ^¬ bulk material, wherein the handover between a first movable transfer device and a second movable transfer device takes place. The invention also relates to a transfer system for such bulk material with a first movable transfer device and with a second movable transfer device. The invention also relates to an open pit mining system.

In open-cast mining, transport devices such as belt conveyors are used to transport bulk goods. To reduce example ^¬ as lignite opencast devices such example ^¬ as bucket wheel or bucket chain excavators used. Bucket wheel excavators are also used for example for the removal of kaolin, clay, sand, clay, chalk, gravel, coal, limestone or overburden. The excavated by means of an open-pit device such as a bucket wheel excavator Good is usually passed in the form of bulk material to a transport device. Bulk material is transferred in opencast mining at many points, for example from a transport device to another transport device, from an open pit device to a transport device or from a transport device to an open pit device. The transfer of bulk material is usually carried out with the help of at least two movable transfer devices. If the transfer of bulk material should not be interrupted when one of the transfer devices is moved, the other transfer device must be tracked for this movement. Presently, this tracking is controlled measure of operating personnel by eye and is therefore not always sufficient ge ^¬ precisely. The object of the invention is to allow a more efficient and safer transfer of bulk material in the open pit.

This object is achieved by a method for transferring bulk material, in particular for transferring bulk material to be transported in opencast mining between a first movable transfer device and a second movable transfer device, wherein a base station arranged on the second movable transfer device sends out a base signal, wherein a plurality of transponders which are associated with reference points of the first movable transfer device, the base signal receives and transponder signals ^¬ outside, which are received by the base station, wherein the relative position of the two transfer devices is determined to each other with the aid of the transponder signals.

In this way, the position of the two transfer devices relative to one another can always be reliably and precisely determined. This is also the case when position determination is made more difficult by the rough conditions often encountered in open pit mining. The method according to the invention also works in clearly limited visibility conditions, such as open-pit mining, e.g. Dusting is common, extremely reliable.

Advantageously, the relative speed of the two transfer devices to each other can be determined under the help of the transponder signals. By determining the Re ^¬ lativgeschwindigkeit the two transfer devices, ie, by determining the direction of movement and speed of the two transfer apparatuses to each other, the reliability of the method of the invention is invested in expanding ^¬.

Advantageously, the relative position or the relative speed of the two transfer devices can be determined according to the principle of three-dimensional triangulation. Thus, the accuracy of the method is further improved. Advantageously, in each case one transponder can be used for each reference point of the first movable transfer device.

Advantageously, at least three, preferably eight, transponders are used, depending on the device geometry.

Advantageously, active transponders are used. In this way, a reliable functioning of the method can be ensured, in particular in the case of disturbing influences.

Advantageously, passive transponders can be used. Thus, e.g. the installation costs for the transponder can be reduced, since in particular no separate energy supply for the transponder must be provided.

Advantageously about 1 can be used as base signal and a transponder signal microwave signals, preferably with a wavelength Zvi ^¬ rule mm and about I m can be used.

Advantageously, radio wave signals can be used as the base signal and as the transponder signal, preferably with a wavelength between about 10 ^"1 m and about 10 ⁴ m.

Advantageously, the relative position and / or the relative speed of the two transfer devices can be displayed on a display device. In this way, the operator of the first and / or the second transfer device is provided with better and possibly also clearer information.

Advantageously, the second movable transfer device of the movement of the first movable transfer device can be tracked taking into account the determined relative position and / or relative speed. Such a particularly fast reliable and accurate tracking and thus a reliable transfer is guaranteed transfer devices of bulk material between the over ^¬. Advantageously, at least one actuating signal for at least one actuator of the second movable transfer device can be determined for automatic tracking of the second movable transfer device taking into account the determined relative position and / or relative speed.

With advantage, for automatically tracking the second movable transfer device, taking into account the determined relative position and / or relative speed, at least one actuating signal for a chassis of the second movable transfer device can be determined with the aid of a control device.

Advantageously, at least one control signal for at least one actuator of the first movable transfer device is determined for automatic tracking of the second movable transfer device taking into account the determined relative position and / or relative speed.

Advantageously bulk material can from the first mobile Überga ^¬ before direction become the second movable transfer device passed.

With advantage, bulk material can be transferred from the second movable transfer device to the first movable transfer device.

The object underlying the invention is also achieved by a transfer system for bulk material in open pit with a first movable transfer device and a second movable transfer device, wherein the second movable transfer device comprises a base station for emitting a base signal and for receiving transponder signals, wherein the first movable transfer device has a multiplicity of transponders for receiving the base signal and for transmitting transponder signals, wherein means for determining the relative position of the two transfer destinations directions are provided to each other taking into account the transponder signals.

The advantages of the transfer system according to the invention are analogous to those of the method according to the invention.

Advantageously, the transfer system for carrying out the method described above is formed in one or more of its characteristics.

Advantageously, a control device may be provided, which, taking into account the determined relative position and / or relative speed, is designed to give actuating signals to at least one actuator of the second movable transfer device.

The object underlying the invention is also achieved by an open pit system with one or more of the transfer systems described above, with at least one transport device, which at least one first

Having transfer device and with at least one day ^{¬ building} device, which has at least one second transfer device.

Advantageously, the transport device may be a belt system.

Advantageously, the transport device can be a tripper car, the transfer device a discharge conveyor, the open-plan construction device a stripping device and the second transfer device a receiving carriage.

Advantageously, the first transfer device may be a loading table, the open pit device a mining device and the second transfer device a loading trolley.

Advantageously, the open pit device may be a bucket wheel excavator. Advantageously, the open-pit system may have a control device which, taking account of the determined relative position and / or relative speed, is designed to give actuating signals to at least one actuator of the first movable transfer device.

The object underlying the invention is also achieved by an open pit apparatus which is designed for use in an open pit mining system described above and which has a transfer device, a base station for emitting a base signal and for receiving transponder signals and a control device.

In the following, details and further advantages of the invention will be explained by way of example with reference to the drawings. Show it:

1 shows a schematic example of the construction of a Überga ^¬ be, FIG 2 is a schematic example of the arrangement of compo ^¬ components of the system for determining position,

3 shows an example of a configuration of a system for determining and controlling Posi ^¬ tion.

1 shows a transport system 1 with a transport device 2. The transport system 1 can be designed as a conveyor system, for example as Abraumbandanlage. The transport device 2 may, for example, be a tripper car with a discharge belt as the first movable transfer device 4. In the example shown, bulk material is transferred from the first movable transfer device 4 of the transport device 2 to the second movable transfer device 5 of the open pit device 3. Accordingly, the open-pit construction device 3 can be, for example, a spreader with a receiving trolley or support trolley as a movable transfer device 5. The second movable transfer device 5 has a receiving hopper 6 by means of which bulk material from the first movable Transfer device 4 is passed to the second movable transfer device 5. The open pit device 3 has in the example shown a belt device 11 for transporting the bulk material, which is formed by two conveyor belts.

In the example shown, the transport device 2, e.g. the tripper car, with the aid of a chassis 14 along the transport system 1 movable and has a funnel 15, passes through the bulk material to the first movable transfer device 4. The open pit apparatus 3, here e.g. the spreader, has a main landing gear 8 and a secondary chassis 7 associated with the second mobile transfer device 5.

FIG. 2 shows-schematically illustrated-the transport device 2 with the first movable transfer device 4. In the example shown, three reference points 9 are arranged on the transport device 2 or on the first movable transfer device 4. A base station 10, not shown in detail in FIG. 2 (see FIG. 3), is arranged on the open pit device 3 (see FIG. 1) or on the second movable transfer device 5. The base station 10 or the receiving and transmitting unit of the base station 10 is assigned to the origin of a relative coordinate system with the spatial coordinates X, Y, Z.

In the event that bulk material is transferred from the transport device 2 by means of the transfer devices 4, 5 to the open pit device 3 (see FIG. 1), the direction of movement of the bulk material is symbolically indicated in FIG. For this case, the receiving hopper 6 of the second transfer device 5 is shown symbolically.

FIG. 3 shows a plurality of transponders 13 which are assigned to the reference points 9 (see FIG. 2) of the transport device 2 or the first transfer device 4 of the transport device 2 in a manner not shown in detail, and correspondingly to the transport device 2 or to the transfer device 4 are arranged. The transponders 13 can be active and / or passive, if appropriate also semi-active. The base station 10 sends signals to the transponders 13, which at least partially send the transponders 13 back to the base station 10.

The base station 10 and the transponder 13 together with not shown means for evaluation a location system, preferably based on microwave, with the help of which the relative position, the direction of movement and the

Speed of the two transfer devices 4, 5 relative to each other can be determined very accurately. The bearings between the base station 10 and the transponders 13 are preferably converted into vectors in a relative coordinate system in the location system. This evaluation is carried out advantageously in an evaluation unit of the Ba ^¬ sisstation 10. The evaluation unit may for example, also as part of the control device 12 or as one with the base station 10 and with the control device 12 gekop- pelte unit may be provided. Based on the values being ^¬ th data of the bearings adjustment signals can be determined for actuators 3 of one or both transfer devices 4, 5 and the transport apparatus 2 and / or the open-cast mining apparatus.

Preferably, the results of the bearings are converted in a control device 12 into control commands for the movement of the second movable transfer device 5 and for the movement of the open pit device 3, respectively.

Such control signals can reasoning apparatus 12 are given to a secondary suspension 7 of the second movable transfer device 5, for example of the Steue ^¬.

The location system may use radio wave signals alternatively or in addition to microwave signals. The relative Po ^¬ sition, the movement direction and / or the speed of the transfer devices 4, 5 are each other thereby pre- preferably determined on the basis of signal propagation times. Signals passing from the base station 10 to the transponders 13 are referred to as a base signal. Signals passing from the transponders 13 to the base station 10 are referred to as transponder signals. The locating system works with methods of signal processing known from radar technology, in particular with the determination of signal propagation times.

The opencast mining device 3 may, for example, have a secondary chassis 7 configured as a crawler chassis for the second movable transfer device 5. In particular bucket wheel excavators and spreaders are often equipped with crawler tracks open construction devices 3. Based on the Or ^¬ tion system determined control signals can be ge of the control device 12 of the second movable transfer device 5, for example, gege ^¬ ben to such a crawler. Control signals can be given by the control device 12 but not only to a chassis 7, but alternatively and / or additionally to other involved actuators of the open pit device 3, the transport device 2 and the transfer devices 4, 5. Thus, the control device 12, for example, control signals for Influencing the inclination of a first transfer device 4, designed as a discharge belt, of a transport device 2 designed as a tripper car.

With the aid of the described method, for example, the transfer of bulk material from a trained as a paddle excavator opener 3 to a trained as Strossenband transport device 2 and / or the transfer of a trolley as a scraper ausgebil ^¬ Deten transport device 2 to the receiving or supporting carriage of a Absetzers be automated.

The locating system described may, in cooperation with one or more suitable control devices 12 and / or one or more suitable display devices, at least partially replace and / or assist the operator to support the work. Unlike traditional systems, the components need one of at least two over ^¬ transfer devices 4, no longer manually downstream 5 having transfer system by operators in cabs leads are. It is besipielsweise an automatic Nach ^¬ leadership of the loading carriage on the bucket wheel excavator after the movement of a loading table on Strossenband allows. The on ^{¬ take-} car of a spreader can be tracked the movement of a tripper car. As a rule, components such as loading wagons and / or support or receiving wagons are equipped with chain suspensions.

For the technical implementation of the locating system described above, a multiplicity of reference points 9 are defined on the transport device 2, on which transponders 13 are arranged on the transport device 2 or on the first transfer device 4. At the open pit device 3, the base station 10 is preferably mounted as a combined Emp ^¬ catching and evaluation. Thus, for example, reference points 9 can be defined on a tripper car, transponders 13 can be attached accordingly and a base station 10 can be attached to the support car of the striker. Similarly, reference points 9 can be defined on Bela ^¬ detrichter a Strosssenbands and it can be a base station 10 are preferably arranged on the loading carriage of a Schau ^¬ felradbaggers.

The number of reference points 9 and, accordingly, the number 13 on ^¬ must be reasonable fit to the local, in particular the design conditions depending on the system in general, the transponders. It is preferable to ensure that a connection between at least three reference points 9 and the respective base station 10 can always be established. From the base station 10 receives the Steuerungsvorrich- tung 12, the relative position data is preferably in the form of vectors, the magnitude of a vector measure of Relativge ^¬ is speed. In the control device 12, control commands for the open-pit mine are generated from the relative position data. Device 3, in particular for the movable ^{Übergabevor ¬} direction 5 of the open pit device 3 is determined, which are preferably placed by means of software parallel to any manual operating signals of the open pit device 3. This ensures that if, for example, the

Trolley of a surface mining system is moved, the pickup trolley of the Absetzers automatically follows the discharge belt of the tripper car. Analogously, is also a positi ^¬ tioning of a Beladewagens the bucket wheel, the movements of the loading of the loading will be tracked.

An idea essential to the invention can be summarized as follows:

The invention relates to a method for transferring bulk ^¬ well opencast between a first movable transfer device 4 and a second movable transfer device 5, wherein a is arranged on the second movable transfer device base station 10 transmits a base signal ches WEL of a plurality of transponders 13, the respective reference points 9 of the first movable transfer device 4 are assigned, is received, wherein the transponder 13 transmit transponder signals to the base station 10. Under the aid of the signal transit times, the relative position, the relative movement direction and / or the relative Ge ^¬ speed of the two transfer devices 4, 5 intended to each other and there will be a basis of which control signals for the movement of at least one of the two transfer devices 4, 5, preferably in Control device 12, determined. According to a safe, reliable and efficient transfer of bulk material in the open pit, especially in adverse circumstances allows.

Claims

claims

1. A method for the transfer of bulk material, in particular for the transfer of open-cast bulk material, see between a first movable transfer device (4) and a second movable transfer device (5), characterized in that at the second movable Überga ^¬ before direction ( 5) base station (10) emits a base signal that a plurality of transponders (13) associated with reference points (9) of the first movable transfer device (4) receive the base signal and transmit transponder signals received from the base station (10) be, and that with the aid of the transponder signals, the relative position of the two Übergabevorr- (4, 5) is determined to each other.

2. The method according to claim 1, wherein the relative speed of the two transfer devices (4, 5), i. Direction of movement and speed of the two transfer devices (4, 5) to each other, is determined with the aid of the transponder signals.

3. The method according to claim 1 or 2, wherein the relative position and / or the relative speed of the two transfer devices (4, 5) is determined according to the principle of three-dimensional triangulation.

4. The method according to any one of the preceding claims, wherein for each one reference point (9) of the first movable transfer device (4) each have a transponder (13) is used.

5. The method according to claim 4, wherein at least three, preferably eight, transponder (13) are used.

6. The method according to any one of the preceding claims, wherein active transponder (13) are used.

7. The method according to any one of the preceding claims, wherein passive transponder (13) are used.

8. The method according to any one of the preceding claims, wherein the base signal and transponder signals are microwave signals.

9. The method according to any one of claims 1 to 7, wherein the base signal and transponder signals are radio wave signals.

10. The method according to any one of the preceding claims, wherein the relative position and / or the Relativgeschwindig ^¬ speed of the two transfer devices (4, 5) are displayed on a display device.

11. The method according to any one of the preceding claims, wherein the second movable transfer device (5) of the movement ^{¬ movement of} the first movable transfer device (4) is tracked taking into account the determined relative position and / or relative speed.

12. The method according to claim 11, wherein for automatically tracking the second movable transfer device (5) taking into account the determined relative position and / or relative speed at least one control signal for at least one actuator of the second movable Überga ^¬ before direction (5) is determined.

13. The method according to claim 12, wherein for automatic tracking of the second movable transfer device (5) taking into account the determined relative position and / or relative speed at least one control signal for a chassis (7) of the second movable transfer device (5) with the aid of a control device (12 ) be determined.

14. The method according to any one of claims 11 to 13, wherein for automatic tracking of the second movable transfer device (5) taking into account the determined relative position and / or relative speed of at least one actuating signal for at least one actuator of the first ^¬ be moveable transfer device (4) is determined.

15. The method according to any one of the preceding claims, wherein bulk material is transferred from the first movable transfer device (4) to the second movable transfer device (5).

16. The method according to any one of claims 1 to 14, wherein bulk material is transferred from the second movable transfer device (5) to the first movable transfer device (4).

17. Transfer system for bulk material in surface mining with a first movable transfer device (4) and with a second movable transfer device (5), characterized in that the second movable transfer device (5) sisstation (10) for transmitting a base signal and for receiving of transponder signals, that the first movable transfer device (4) has a plurality of transponders (13) for receiving the base signal and for transmitting transponder signals, and that means for determining the relative position of the two transfer devices (4, 5) to each other Considering the transponder signals are provided.

18. Transfer system according to claim 17 for carrying out a method according to one of the claims 1 to 16.

19. Transfer system according to claim 18, wherein a control device (12) is provided which, taking into account the determined relative position and / or relative speed determined actuating signals to at least one

Actuator of the second movable transfer device (5) is formed giving.

20. Open-pit system with a transfer system according to one of the claims 17 to 19, with a transport device (2), which has the first transfer device (4), and with an open pit device (3) having the second transfer device (5).

21. Surface mining system according to claim 20, wherein the transport device (2) is a belt system.

22. Opencast mining system according to claim 21, wherein the transport device (2) a belt system with tripper car, the transfer device (4) a discharge conveyor, the open pit device (3) a spreader, and the second transfer device (5) is a receiving carriage.

23. Opencast mining system according to claim 21, wherein the first transfer device (4) is a loading table, the open pit device (3) a mining device, and the second transfer device (5) is a loading car.

24. Opencast mining system according to claim 23, wherein the open pit device (3) is a bucket wheel excavator.

25. Opencast mining system with a transfer system according to one of the patent claims 18 to 24, wherein a control device

(12) is provided, which, taking into account the determined relative position and / or relative speed ermit ^¬ tete control signals to at least one actuator of the first movable transfer device (4) is formed giving.

26. Open-pit construction device (3) with a transfer device (5) which has a base station (10) for emitting a base signal and for receiving transponder signals, and with at least one control device (12) configured as an open-pit device (3) for use in an open-pit system according to one of the claims 19 to 25.