EP2864234A2 - Steep conveying installation for open cast mining - Google Patents

Abstract

The present invention relates to a steep conveying installation (1) for arranging on a slope (10) of an open‑cast mining glory hole, by means of which raw materials (11) can be transported from a lower height level (12), in particular from a mining floor (12) of the open‑cast mine, to an upper height level (13), in particular formed by a soil (13), comprising a line (14) arranged on the slope (10). According to the invention, a first conveying basket (15) and a second conveying basket (16) are provided, which conveying baskets (15, 16) can be displaced on the line (14) between the lower height level (12) and the upper height level (13) and which are designed to receive the raw materials (11), wherein the conveying baskets (15, 16) are connected to one another via at least a common traction means (17).

Description

 Steep conveyor for the Tagebay

Description

The present invention relates to a steep conveyor system for placement on an embankment of an opencast mine, with the raw materials from a lower level, in particular from a mining base of the open pit, to an upper level, in particular formed by a soil, are transportable, comprising one on the slope arranged route.

STATE OF THE ART

From DE 199 63 464 A1 discloses a steep conveyor system for arrangement on the slope of an open pit mining judge is known. With the high-lift system, lorries loaded with the raw materials can be carried over the height distance between the mining pit of the open pit and the upper level, namely the ground. The steep conveyor system has a vehicle accessible by lorries on stage, via a traction means, formed by several ropes, can be pulled over the height distance between the degradation base and the ground up. This provides an alternative to overcoming the altitude distance by driving a suitably designed road through the trucks, which leads from the lower mining base of the open pit to the high ground. Lorries used in mines or in other mining operations cause high costs, and the driving speed over the road to overcome the height distance must often be very low. In addition, there is a considerable wear of the trucks, which causes further costs.

With the proposed conveyor system, this height distance can be overcome on the inclined movable platform, but there is the disadvantage that the driver of the truck to drive on the mining base and to drive on the higher ground, since the driver must leave the trucks when the trucks be pulled up with the conveyor.

Another disadvantage arises from the fact that the trucks have a very high weight, which can be up to half of the payload. Consequently, a conveyor to promote the payload and in addition to promoting the weight of the truck must be sized accordingly large.

DISCLOSURE OF THE INVENTION

It is therefore the object of the invention to provide a steep conveyor for arrangement on a slope of a surface construction judge, which overcomes the above-described disadvantages of the prior art and which causes the smallest possible structural complexity at a high production capacity. In particular, the task of creating a steep conveyor with a high flexibility, which does not necessarily require a truck to promote the job arises. This object is achieved on the basis of a steep conveyor for surface mining according to the preamble of claim 1 and a system according to claim 18 with the respective characterizing features. advantageous

Further developments of the invention are specified in the dependent claims.

The invention includes the technical teaching that a first conveyor basket and a second conveyor basket is provided, which conveyor baskets are movable on the route between the lower height level and the upper height level and which are designed to receive the raw materials, wherein the conveyor baskets on at least one common Traction means communicate with each other.

Due to the construction of the steep conveyor system according to the invention, the capacity for conveying the raw materials from the lower height level to the upper height level is significantly increased. In particular, the advantage is achieved that not the mass of the trucks must be transported through the steep conveyor over the height difference between the lower and the upper height level. However, the increase in the conveying capacity arises in particular in that two conveyor baskets forming a counterweight to one another are used and can be moved on the route, so that the mass of the conveyor baskets cancel each other out. This ensures that the steep conveyor must be designed only to the maximum mass of raw materials to be conveyed, since the mass of the conveyor baskets can be neglected. In particular, however, there is an energetic advantage, since no empty masses that do not form the useful mass, must be transported over the height between the lower and the upper height level.

The possible pendulum operation of the conveyor baskets, however, creates the further advantage of an increased conveyor speed since a conveyor cage can be loaded at the lower height level, while a conveyor cage can be unloaded at the upper height level. Thus, the loading and unloading of the first and second conveyor cage can overlap, so that the effect of two parallel used conveyor baskets can be advantageously exploited. With particular advantage, the conveyor baskets can be dimensioned such that a conveyor cage can receive the raw material load of a truck so that a truck loaded with a load of raw materials can transfer these raw materials to the complete filling of a conveyor cage in this.

Advantageously, a filling device for filling the conveyor baskets can be provided in the region of the lower height level of the route. In particular, the raw materials can be transferred by means of the filling device from vehicles, for example, from large trucks into the conveyor baskets. For example, the filling device may have a filling funnel, through which the raw materials from the vehicle can be guided into a filling opening of the conveyor baskets. Preferably, the vehicle may have a tiltable loading device, so that the raw materials are poured by tilting the loading device through the filling funnel into the filling opening of the conveyor baskets. The filling device may be located in the region of the degradation base, and a ramp may be provided, in particular as part of the filling device, on which vehicles can be driven to a level slightly above the conveyor baskets. If a conveyor cage is located in the lower position of the route, the raw materials can be transferred to the conveyor cage through the emptying of the vehicle slightly above the filling opening.

Since the steep conveyor system according to the invention has a first conveyor cage and a second conveyor cage which can alternately occupy the lower position on the route on a first side and a second side of the route, the filling funnel can have two openings which are arranged next to each other and allow the first opening Filling the first conveyor cage on a first side of the route and the second opening allows the second conveyor cage to be filled on the second side of the route. With particular advantage, the filling device can form a structural unit with the route.

According to a further particularly advantageous embodiment of the conveyor baskets, these may have emptying openings arranged below the filling opening, through which the raw materials from the conveyor baskets can be emptied while maintaining the position of the conveyor baskets. In particular, the emptying of the Carrying baskets are maintained while maintaining the position relative to the route. The conveyor baskets may have guide rollers which are guided on guide rails of the route. By arranged below the filling opening emptying the conveyor baskets can be emptied in their arrangement on the route. For emptying the conveyor baskets, the emptying openings have respective emptying flaps which are locked by means of a corresponding latch closure, and for emptying the conveying baskets the latch closure can be unlocked and the emptying flap can be opened.

With further advantage, the route can extend beyond the upper height level, so that the raw materials can be transferred by gravity from the conveyor baskets into at least one device, which serves in particular for further processing and / or further transport of the raw materials and arranged substantially on the ground or . is set up. Gravity is thus exploited to fill the conveyor baskets in their lower position on the route and gravity is also utilized to empty the conveyor baskets in their upper position on the route, preferably above the surface of the earth. In particular, the conveyor baskets perform a linear movement between their lower and their upper position, without the conveyor baskets must be led out in their movement and in their position from the linear movement on the route.

According to a further advantageous embodiment of the steep conveyor system according to the invention, the further processing the raw material device may be designed as a crushing device, in particular as a crusher, or as a transport device, in particular as a conveyor belt. Thus, the raw materials from the conveyor baskets, for example, first be transferred to the crushing device, in particular poured, followed by the transport device, so that the raw materials can be transported, in particular to a collection point or, for example, on other vehicles that drive the upper height level.

A significant advantage of the coupling of the steep conveyor system with a further processing device, in particular a crusher, is that the processing device can be carried out so that always exactly one raw material charge can be entered from the conveyor cage in the further processing device. For example, the crusher may have an upstream raw material storage in which the raw material from the conveyor basket is first poured, and during a delivery cycle in which the conveyor baskets are conveyed over the route, the crusher can operate continuously until the next conveyor basket discharged into the raw material storage again so that there is always a quantity of raw material in the raw material store. Consequently, in a discontinuous conveyance on the route a continuous discharge of the crushed material is possible and there is no intermediate storage such as a bunker or the like necessary.

Another advantage of the combination of the steep conveyor with a further processing device results from the fact that no separate foundation is required for the attachment of the system on the upper height level, since the weight of the processing device, in particular a crusher, can already be used for foundation formation, and the arrangement of the drive unit on a rear side of the crushing plant only serves to stabilize the entire system in conjunction with the mass crusher for foundation formation or for foundation replacement.

The traction means may be connected to a drive unit, which is preferably arranged at a distance from the upper end of the route on the ground and wherein the traction means is guided via drive wheels of the drive unit. At the upper end of the route upper pulleys can be fixed and arranged on the conveyor baskets lower pulleys with the conveyor baskets, and between the upper and lower pulleys, the traction means can each form at least one wind device in the manner of a pulley. For example, a first pulley block and a second pulley block may be associated with the first conveyor cage. Both pulleys may be formed from a continuous traction device, which passes through the drive unit. The wind devices can form a double acting pulley to halve the tensile force, preferably a four-acting pulley to quarter the tensile force and more preferably an eight-acting pulley to quench the traction in the traction means. The tensile force corresponds to the force that must be introduced by the drive unit in the traction means. The traction means may preferably be formed from one or more, in particular parallel, guided steel cables.

The traction means has a first and a second Zugmittelende, and the entire steep conveyor system can be operated with a single continuous traction means. The two traction means ends can preferably be arranged in each case on a length compensating means, and by means of the length compensating means, the traction means ends can in particular be retractable independently of one another or one further traction medium length can be released in each case.

By drawing or releasing a Zugmittellänge the height position of the respective conveyor cage, which is assigned to the side of the respective Zugmittelendes be adjusted. For example, the position of the conveyor basket on the sloping route may depend on its loading, since the traction means may have an elastic elongation depending on the loading of the conveyor baskets. If, for example, an upper vertical position for emptying the raw material has to be approached with the conveyor basket, and if, for example, the weather basket is located at a stop in the lower vertical position, the height position of the upper conveyor basket can be adjusted by appropriately pulling in or releasing a traction medium length. Overcoming the actual delivery height can thus be done with the drive unit, and for fine adjustment of the height position of the conveyor basket, in particular in the upper height position is carried out by the length compensation means. This may for example comprise a hydraulic unit or a carriage which is guided on corresponding rails and the length compensating means can draw or release the traction means on the Förderkorbseite on which the conveyor cage is in the upper position, while the lower conveyor basket is seated, for example on a stop. Furthermore, the length compensation means can serve to permanently release a further, in particular larger Zugmitteliänge if the route must be extended by progressive mining in the open pit in depth. The route can, for example, be carried out in such a way that the lower height level can be lowered step by step, in particular on the quarrying pit of the opencast mine. Consequently, the length of the traction means must also be increased, and the Längenausgleichttelt may be designed for permanent release of an additional Zugmittelänge. For example, the length compensating means comprise a cable drum which is guided on rails For brief Einjustierung a desired height of the conveyor baskets, the cable drum over the rail length can be changed accordingly in their position, so that only short cable lengths are released or retracted. If the traction means are to be permanently extended, for example, if the excavation bottom is lowered, the cable drum can be unwound while maintaining the position of the side drum on the rail, wherein the short-term height adjustment of the conveyor basket by drawing or releasing a further Zugmittellänge means of a dynamic process the cable drum can be superimposed on the rail for each conveyor cycle the unwinding of the traction means of the cable drum.

The drive unit may, for example, have two drive wheels about which the traction means is preferably wound with a total deflection angle of at least 360 ° and preferably of at least 540 °. The large total deflection angle ensures that the traction means does not slip on the drive wheels and that the frictional forces are sufficiently great to transmit the drive torque of the drive wheels to the traction means. For this purpose, own two parallel driven drive wheels, each associated with a motor-gear unit, wherein a first motor-gear unit cooperating drivingly with the first drive wheel and a second motor-gear unit with the second drive wheel. The traction means can be wound around the first drive wheel by 90 ° and guided to the second drive wheel. The second drive wheel, which rotates in the same plane as the first drive wheel, is looped by the traction means at an angle of 180 ° and is guided back to the first drive wheel. This is also at an angle of 180 ° looped with the traction means, and the traction means is guided back to the second drive wheel and wraps around this again by 90 °. This results in 3x180 ° loops .. whereby preferably results in a total wrap angle of 540 °. The motor-gear units can be driven in synchronism with each other via a corresponding control, so that the drive torques placed on the drive wheels preferably have the same values.

Another particular advantage is achieved in that the respective wind device, ie the pulley, is formed with a first traction means and with at least one further traction means. Thus, the traction means can together form the first pulley for lifting and lowering the first conveyor basket and together the second pulley for lifting and lowering the second conveyor basket, wherein the drive wheels of the drive unit are also wound by at least two traction means. The two traction means can preferably be guided in parallel over their entire length. Of course, more than two traction means can be performed in parallel, and it can also be three or more traction means form the pulleys in a parallel arrangement.

By increasing the number of individual traction means they can be formed with smaller dimensions, so that the overall dimensions of the steep conveyor system does not increase, preferably even reduced. In particular, the diameter of the drive wheels, but also the diameter of the pulleys, can be made smaller, which reduces the overall dimensions of the steep conveyor. If, for example, two traction means in the form of ropes are guided in parallel, the traction force in the respective traction means is halved. If three or more ropes are used in parallel, then the force in the single rope is divided by the number of parallel ropes. It is particularly advantageous that the pulleys can be formed with parallel traction means with a corresponding number of bottles, which also reduces the tensile force resulting in traction means. For example, over the entire Zugmittellänge two parallel traction means is provided, the drive wheels may include at least one umschlungenes of a first traction means drive wheel and at least one umschlungenes of a second traction mechanism drive wheel _"and the drive wheels can be preferably arranged to rotate about a common axis. In this case, the drive wheels, which are accommodated on the common axis and are wrapped by the two traction means, also be made in one piece.

Also, a first drive wheel and a second drive wheel may be provided and looped around by the first traction means, and it may be provided a first drive wheel and a second drive wheel, which is looped around by the second traction means. Overall, thus, for example, four drive wheels may be provided in two parallel traction means, which are each driven in pairs on two mutually parallel axes.

The present invention is further directed to a production cascade with at least two steep conveyor systems, wherein the lower height level of an upper steep conveyor to the upper height level of a lower Steilförderaniage followed, and in particular between the steep conveyor means for transferring the raw materials from the lower steep conveyor to the upper steep conveyor are provided. The delivery cascade can also be formed, for example, from more than two individual steep conveyor systems, and regardless of a limited maximum head of a single steep conveyor, a delivery cascade can overcome any head. The means for transferring the raw materials between the steep conveyor systems, for example, include corresponding Umfülltrichter, and a conveyor basket, which is located in the upper position of a lower steep conveyor, can transfer the raw materials through its emptying opening by means of Umfülltrichters in the filling opening of a conveyor basket, located in the lower position of an overhead steep conveyor. Consequently, the raw materials can be conveyed beyond unlimited heights despite a technically limited maximum head of a single steep conveyor with a feed cascade according to the present invention. The present invention further relates to a system with a steep conveyor system, with the raw materials from a lower conveying level, in particular from a mining base of an open pit, to an upper level, in particular formed by a soil, are transportable and it is a crushing device for crushing the raw materials provided, wherein the system has at least one route and a first conveyor cage and a second conveyor cage, which conveyor baskets on the route between the lower height level and the upper height level are movable and which are adapted to receive the raw materials, wherein the conveyor baskets via at least one common traction means communicate with each other and wherein the crushing device is arranged at the lower or at the upper height level of the steep conveyor system and with this particular forms a structural unit. For example, the crushing device can be designed as a crusher. Furthermore, a device for further transport of the raw material may be part of the system according to the invention. The transport device can in particular connect to the comminution device, which is arranged at the upper height level. The features and advantages of a steep conveyor system described above can also be taken into account for a system with such a steep conveyor system,

PREFERRED EMBODIMENT OF THE INVENTION

Further, measures improving the invention will be described in more detail below together with the description of a preferred embodiment of the invention with reference to FIGS. It shows:

Figure 1 is a view of a steep conveyor system according to the present invention

 Invention,

2 shows a view of two conveyor baskets with pulleys formed by a traction means, a perspective view of the lower height level with a filling device for filling the conveyor baskets with raw material from vehicles, a view of the upper height level with a conveyor basket from which raw materials are transferred to a device, a perspective view of a conveyor cage, a view of a locking device on a conveyor cage in a locked state, the view of the locking device on a conveyor cage in an unlocked state, a schematic view of a drive unit for driving the conveyor baskets, a schematic view of the drive wheels of the drive unit in operative connection with a traction means, a schematic view of the wind devices designed as pulleys consisting of two Parallel guided traction means in a first embodiment, the wind device with two traction means in a further embodiment, a further arrangement of the drive wheels of the drive unit, of two Traction means are entwined and the arrangement of the drive wheels of the drive unit, which are looped by two traction means according to another embodiment. Figure 1 shows an embodiment of a steep conveyor system 1 with the features of the present invention. The inclined conveyor 1 is disposed on an embankment 10 of an open-pit mine, and the slope 10 extends from a lower height level 12 to an upper height level 3. The lower height level 12 is formed by the mining floor 12 of the open pit and the upper height level 13 is formed by the soil 13, and the soil 13 thus exemplifies the height level on which the raw material 11 can be transported on.

The steep conveyor system 1 has a route 14 which extends from the lower height level 12 to above the upper height level 13 away. The route 14 is attached to the sloping embankment 10, and to extend the route 14 above the upper height level 13 also serves a supporting structure 26 to which the route 14 is attached continuously extending.

In the Abbausohie 12, the steep conveyor 1 has a filling device 18, and it is shown loaded with raw material 1 1 vehicle 19, which can pass the raw material 11 by means of the filling device 18 to the steep conveyor system 1. In the area of the upper height level 13 is shown as a structural unit with the structure 26, a device 24 which forms a crushing device 24, for example in the form of a crusher. Also shown is a device 25 which forms a transport device 25 and serves for the further transport of the raw material 11.

The steep conveyor system 1 according to the invention has a first conveyor cage 15 and a second conveyor cage 16, and the conveyor baskets 15 and 16 can be moved on the route 14 between the lower height level 12 and the upper height level 13. The two conveyor baskets 15 and 16 are coupled to each other via a common traction means 17, and the traction means 17 is exemplified as a steel cable.

To drive the conveyor baskets 15 and 16 via the common traction means 17 is a drive unit 27 which is spaced from the structure 26 on the ground 13th arranged and anchored in this. The traction means 17 in this case passes through the drive unit 27, and while, for example, the second conveyor basket 16 is pulled up in the direction of the upper height level 13, the first conveyor basket 15 is lowered in the direction of the lower height level 12. For this purpose, the drive unit 27 is operated in a first functional direction, and to bring the first conveyor cage 15 back towards the upper height level 13, while the second conveyor basket 16 is lowered again towards the lower height level 12, the drive unit 27 is in a second opposite Function direction operated. Thus, a pendulum operation of the conveyor baskets 15 and 16 is created, and the net mass of the first conveyor basket 15 can compensate for the net weight of the second conveyor basket 16, so that the masses of the conveyor baskets 15 and 16 need not be moved by the drive unit 27 against gravity, since the Compensate for each other via the traction means 17.

The traction means 17 forms between upper pulleys 28, which are arranged on the supporting mechanism 26, and lower pulleys 29 which are arranged on the respective conveyor baskets 15 and 16 and thus movable, a pulley for the respective conveyor cage 15 and 16. Thus, the required Traction force that must be introduced by the drive unit 27 in the traction means 17, less than the mass of the raw material 1 1 in the respective conveyor baskets 15 and 16th

Figure 2 shows schematically the arrangement of the wind devices 30 of the traction means 17 between the upper pulleys 28 and the lower pulleys 29, and the wind devices 30 are formed as 8-pulleys 30. Both the upper and the lower pulleys 28 and 29 each have four sheaves, and of the - not shown here - drive unit 27 to be introduced into the traction means 17 traction is only one-eighth of the weight of the conveyor baskets 15 and 16 and the raw material 11, to carry them with the raw material 1 1 above the slope in the direction shown Pfegeirichtung.

The one-piece and thus continuously running traction means 17 has two traction means ends 31 and 32, which are each arranged on a length compensation means 33, for example. The length compensation means 33 allow retraction or release of another Zugmittellänge so that the height position of both the first conveyor basket 15 and the second conveyor basket 16 can be adjusted by the length compensation means 33. For example, the second conveyor basket 16 may be located at a stop on the lower height level 12, wherein the stop is for example part of the filling device 18, and by a different feeding cycle to Förderakt loading of the first conveyor basket 15, which may be of different weight, may a variable elastic elongation in the traction means 17 result. However, in order to unload the first conveyor basket 15 with the raw material 11 in the area of the upper height level 13, it may be necessary to approach an exact height position. Consequently, for example, the traction means end 31 can be drawn or released by the length compensating means 33 in order to approach the setpoint position on the route 14 with the first conveying cage 15 and subsequently to discharge the raw material 11. In the same way, if the second conveyor basket 16 is located, for example, on the upper height level 13 and has to approach a desired position, the traction mechanism end 32 can be retracted or released by the associated length compensation means 33.

In Figure 3, the filling device 18 is shown in perspective, and the route 14 of the steep conveyor system 1 is shown in the region of the lower height level 12. On the lower height level 12, a ramp 22 is arranged, which is formed in a manner shown by Erdreichaufschüttung. Via the ramp 22, a shown vehicle 19 can be driven to a height which is located above the second conveyor cage 16 shown by way of example in the lower position. The second conveyor basket 16, which can sit on a lower stop of the route 14, has a filling opening 21 in its upper region. If the raw material is to be conveyed from the vehicle 19 through the filling opening 21 into the second conveying cage 16, the vehicle 19 discharges the raw material through a filling funnel 20 so as to ensure that the raw material passes through the filling opening 21 into the conveying cage 16. Subsequently, the conveyor basket 16 with the traction means 17, which is shown wrapped around the lower guide roller 29 on the conveyor basket 16, are pulled over the route 14 upwards. The filling funnel 20 is designed such that a further conveyor basket, which is moved on the rear side of the route 14, can be driven under a rear area of the filling funnel 20 adjacent to the vehicle 19 shown. Then, another vehicle 19 in adjacent arrangement to the vehicle shown 19 further raw material through the filling hopper 20 in the - not shown - conveyor basket 15 which may be located on the rear side of the route 14. Thus, the conveyor baskets 15 and 16 can be driven in pendulum alternately on a first and on a second side under the hopper 20 and also loaded alternately from vehicles 19 with raw material 11, which vehicles 19 alternately on the front and on the rear side of the filling funnel 20 transfer the raw material 11 into the conveyor baskets 15 and 16.

FIG. 4 shows the upper region of the route 14, which is arranged on the supporting structure 26. By way of example, the first conveyor basket 15 is shown in the upper unloading position, and the raw material 11 can pass through an emptying opening 23 from the conveyor cage 15 into a comminuting device 24, which comprises a raw material store 51 into which the raw material 11 is first input. The comminution device 24 adjoins the raw material storage 51 and is continuously fed from the raw material storage 51. The emptying opening 23 of the conveyor basket 15 is located in a lower region, whereas the filling opening 21 is arranged in an upper region of the conveyor basket 15. The conveyor cage 15 is held by the pulling means 17, which is looped through the lower guide roller 29, and the guide roller 29 is arranged on the conveyor cage 15.

The structural design of the structure 26 shows a structural unit between the steep conveyor system 1 with the route 14 and the crushing device 24. The conveyor cage 15 can be transported to a height from which the raw material 11 in a simple manner in the crushing device 24 and in the raw materials storage 51 can be poured without changing the position or the arrangement of the conveyor basket 15 on or on the route 14. The conveyor cage 15 in particular does not have to be tilted be to empty the raw material 1 1, for example, through the filling opening 21 from the conveyor cage 15.

FIG. 5 shows a perspective view of a conveyor basket 15 or 16 formed, for example, from a steel construction, on which a lower deflection roller 29 is shown arranged and which consists of four pulleys for forming the pulley 30, see FIG. 2. The filling opening 21 is defined by a upper, open area of the conveyor cage 15 and 16, respectively, formed below the lower guide roller 29, and the discharge opening 23 is formed with an emptying flap 39, which is shown in an open position. The emptying flap 39 forms a lower wall of the conveyor basket 15 or 16 and can be closed with a locking device or - as shown - are opened.

The locking device, which is provided on both sides of the discharge flap 39 and shown on the front, comprises a flap latch 40 which can be closed with a latch closure 41 in a closed position or, as shown, can be unlocked to open the discharge flap 39 , In the following figures 6 and 7, the operation of the locking device is shown in more detail.

Figures 6 and 7 show the locking device used to lock and unlock the emptying flap 39 (see Figure 5), in Figure 6 the locking device being shown in a closed position and in Figure 7 in an open position.

In Figure 6 is the Klappenriegei 40 which is arranged in a manner not shown in detail hinged to the discharge flap 39, in engagement with a latch closure 41, which is locked in the position shown by a locking means 42. The conveyor cage 15 or 16 is already in the desired emptying position, and an activation member 43 is provided, which can be moved against the latch closure 41 with a lifting means 44, for example with a lifting cylinder. FIG. 7 shows the activation member 43 which has been moved in the direction of the arrow by the lifting means 44 against the latch closure 41, without the need for moving the conveying cage 15 or 16 on the route 14 in its vertical position. By the engagement of the activation member 43 with the latch closure 41 passes against the action of the means of 42 by means of the latch lock 41 out of engagement with the flap latch 40, so that it can move in the illustrated unlocking position. Consequently, the emptying flap 39 can be opened for emptying the raw material 1 1 from the conveyor cage 15 or 18.

With the arrangement of the activation member 43, which can be moved by the lifting means 44 against the bolt latch 41, the advantage is achieved that the opening of the emptying flap 39 of the conveyor cage 15 or 16 does not have to be moved to an exact height position on the route 14 , The opening of the emptying flap 39 "on the last meter" is carried out by activating the activation member 43, and the activation can be triggered, for example, when the conveyor cage 15 has reached a minimum height, so that the raw material 11 can get into the subsequent device 24, in particular an upper stop of the conveyor cage 15 or 16 may be provided, since after emptying of the conveyor cage 15 or 16 and the associated loss of mass of the conveyor cage 15 or 16, a further movement can be prevented upwards by the stop,

Figure 8 shows a schematic structure of the drive unit 27 with a first driven drive wheel 34 and a second driven drive wheel 35, and the drive wheels 34 and 35 are not shown in detail manner with the Zugmitte! 17 entwined. The drive wheel 34 is driven by a motor-gear unit 36 and the drive wheel 35 is driven by a motor-gear unit 37. The independently operable motor-gear units 36 and 37 are operated by a common control, so that the drive torques of the drive wheels 34 and 35 are substantially equal, with the drive wheels 34 and 35 synchronously to each other. The wrap of the drive wheels 34 and 35 with the traction means 17 is shown in more detail in Figure 9. Figure 9 shows a schematic representation of the drive wheels 34 and 35, which are wrapped several times with the traction means 17. The traction means 17 wraps around each of the drive wheels 34 and 35 with a wrap angle of 270 °, so that a sufficient frictional connection for torque transmission from the drive wheel 34 or 35 is given to the traction means 17. The traction means 17 is formed only as a simple steel cable and wound around the drive wheels 34 and 35, and in the following figures 10 and 11 further possibilities are shown to provide an arrangement with traction means 17 which further reduces the mechanical load of the individual traction means 17, whereby the traction means 17 can be selected with smaller dimensions and yet to transport correspondingly large quantities of raw material 11 over the delivery height.

Figure 10 shows an arrangement of the pulleys 30 with a first traction means 17a and a second traction means 17b for raising and lowering the conveyor baskets 15 and 16. The conveyor baskets 15 and 16 are each arranged vertically movable on the traction means 17a and 17b, and the traction means 17a and 17b are wrapped around the drive wheels 34 and 35 alike.

The traction means 17a and 17b are guided substantially parallel over their entire lengths, and the parallel arrangement of the traction means 7a and 17b together form the pulleys 30. As a result, the mechanical stress of the individual traction means 17a and 17b is halved, and these can be dimensioned correspondingly smaller become.

The drive wheels 34 and 35 are each multi-track and the drive wheel 34 is divided into a drive wheel 34a and another drive wheel 34b, which rotate together about a first drive shaft 38a and are also driven together. In particular, the drive wheels 34a and 34b can be made in one piece and form the drive wheel 34 together, wherein both traction means 17a and 17b are wound around the drive wheel 34. Also, the drive gear 35 may include a drive gear 35a and a drive gear 35b, and the drive gear 35a is wound by the pulling means 17a and the drive gear 35b is wound by the pulling means 17b. The drive wheels 35a and 35b can also designed in one piece and driven together about the drive shaft 38b.

The pulleys 30 shown for conveying the conveyor baskets 15a and 15b are each designed as quadruple-acting pulleys with double-guided traction means 17a and 17b. The ends of the traction means 17a and 17b are arranged on a first side on a length compensation means 45, which is designed in the manner of a rocker. As a result, the traction means 17a and 1b can compensate for respective lengths to each other by the rocker-like length compensation means 45 can tilt accordingly at its anchorage. The opposite ends of the traction means 17a and 17b are fixed by way of example to a receiving means 46.

In a manner not shown in detail both the length compensation means 45 and the receiving means 46 can be displaced in Verl on direction of the traction means 17 a and 17 b. This can be done in a manner already described above, a compensation of the height position of the conveyor baskets 15 and 18, and the portable arrangement of the length compensation means 45 and / or the receiving means 46 achieves the same effect as the previously described length compensation means 33rd

Finally, FIG. 11 shows a further exemplary embodiment of the arrangement of the traction means 17a and 17b for forming the wind devices 30. The wind devices 30 are formed as double eight-acting pulleys 30, and the traction means 17a and 17b are around the drive wheels 34 and 35 in the manner already described wound, which are formed by respective part wheels 34a, 34b, 35a and 35b.

The traction means 17a and 17b are connected together in the region of a compensating roller 47 such that the traction means 17a and 17b merge into one another and form a single, but doubly guided traction means 17 of double length. The compensating roller 47 likewise achieves a length compensation, so that the traction means 17 has the same tensile force both in the longitudinal region of the traction means 17a and in the longitudinal region of the traction means 17b. The Zugmittelenden 48 of the traction means 17 are added to anchoring points, which can also be carried out vertically movable, wherein also according to this embodiment, the compensating roller 47 can be added vertically movable.

Figures 12 and 13 each show a further arrangement of the drive wheels 34 and 35 of the drive unit 27, as shown in Figure 8. The drive wheels

34 and 35 are looped by two traction means 17a and 17b, and the traction means 17a and 17b are guided in parallel in a manner not shown in detail, for example, and connected to the conveyor baskets 15 and 16 to move them.

The drive wheels 34 and 35 each have two grooves 49 and 50, and the first traction means 17a is guided in the respective first groove 49 of the drive wheels 34 and 35, and the second traction means 17b is in the respective second groove 50 of the drive wheels 34 and 35th guided. The drive wheels 34 and 35 rotate in each case about their drive axles 38a and 38b.

FIG. 12 shows a first variant of the wraps of the drive wheels 34 and

35 shown by the traction means 17a and 17b. The traction means 17a and 17b wrap around the drive wheels 34 and 35 by way of example each with an angle! of about 270 °, which angle, however, depends on the direction in which the ends of the traction means 17a and 17b are removed from the drive wheels 34 and 35. The example shown shows a Gesamtumschlingungswinkel of 540 °. The advantage resulting from the illustrated looping variant is an identical torque loading of the drive wheels 34 and 35 and uniform wear of the grooves 49 and 50 results. Furthermore, the drive wheels 34 and 35 can rotate about the drive shafts 38a and 38b in the same direction of rotation.

FIG. 13 shows a further variant of the wraps of the drive wheels 34 and 35 by the traction means 17a and 17b. The traction means 17a and 17b respectively encircle the drive wheels 34 and 35 at an angle of about 300 °, which angle is also dependent thereon, in which direction the ends of the traction means 17a and 17b are removed from the drive wheels 34 and 35 become. The example shown shows a Gesamtumschlingungswinkel of

600 °. The drive wheels 34 and 35 can rotate in the opposite direction of rotation about the drive axles 38a and 38b.

The resulting each by the Umschlingungsvarianten shown advantage is further a reduction in the number of required grooves of the drive wheels 34 and 35, since in the variants shown in Figures 10 and 11 for each of the drive wheels 34 and 35, four individual grooves are required and in the In the variants shown in FIGS. 12 and 13, only two grooves 49 and 50 are required for each of the drive wheels 34 and 35.

The invention is not limited in its execution to the above-mentioned preferred embodiments. Rather, a number of variants is conceivable, which makes use of the illustrated solution even with fundamentally different types of use. All of the claims, the description or the drawings resulting features and / or advantages, including structural details or spatial arrangements may be essential to the invention both in itself and in various combinations.

Designation of origin

Steep lift slope sloping embankment

 raw material

 lower height level, degradation level

 upper level, ground

 route

 first conveyor basket

 second conveyor basket

 Zugmittef

a first traction means

b second traction means

 filling

 vehicle

 filling funnel

 filling

 ramp

 emptying

 Device, comminution device

Device, transport device

 Structure

 drive unit

 upper pulley

 lower pulley

 Wind device (pulley)

 pulling means

 pulling means

 Length compensation means

 drive wheel

a drive wheel

b drive wheel Drive wheel drive wheel

b drive wheel

 Motor gear unit

Motor gear unita Drive axleb Drive axle

 discharge flap

 fold bars

bolt lock

retention means

 activating member

lifting means

 Längenausgieichmittel

receiving means

compensating roller

End of the traction device

groove

 groove

 raw material storage

Claims

P atent claims

1. Steep conveyor system (1) for arrangement on an embankment (10) of an opencast mining funnel, with which raw materials (11) are transported from a lower level (12), in particular from a mining floor (12) of the opencast mine, to an upper level (13) , in particular formed by a soil (13), can be transported, having a route (14) arranged on the embankment (10),

characterized in that a first conveyor cage (15) and a second conveyor cage (16) are provided, which conveyor cages (15, 16) can be moved on the route (14) between the lower height level (12) and the upper height level (13) and which are designed to hold the raw materials (1 1), the conveyor baskets (15, 16) being connected to one another via at least one common traction means (17).

2. Steep conveyor system (1) according to claim 1, characterized in that in the area of the lower height level (12) of the route (14) a filling device (18) is provided for filling the conveyor baskets (15, 16), in particular that the raw materials (1 1) can be transferred from vehicles (19) into the conveyor baskets (15, 16) using the filling device (18).

3. Steep conveyor system (1) according to claim 2, characterized in that the filling device (8) has a filling funnel (20) through which the raw materials (11) from the vehicle (19) into a filling opening (21) of the conveyor cage (15, 16) can be guided, the filling device (18) in particular having a ramp (22) on which the vehicle (19) can be moved to a level above the conveyor cage (15, 16) when the conveyor cage (15, 16) is in is located in a lower position on the route (14).

4. Steep conveyor system (1) according to one of claims 1 to 3, characterized in that the conveyor baskets (15, 16) have an emptying opening (23) arranged below the filling opening (21), through which the position of the Conveyor baskets {15, 16) the raw materials (11) can be emptied from the conveyor baskets (15, 16).

5. Steep conveyor system (1) according to one of the preceding claims, characterized in that the route (14) extends beyond the upper height level (13), so that the raw materials (11) are removed from the conveyor cages (15, 16) by gravity in at least a device (24, 25) can be transferred, which is used in particular for further processing and / or for further transport of the raw materials (1 1).

6. Steiiförderanlage (1) according to claim 5, characterized in that the device (24, 25) is designed as a shredding device (24), in particular as a crusher in connection with a raw material storage 51, or as a transport device (25), in particular as a conveyor belt , wherein the raw materials (11) can preferably be transferred from the conveyor basket (15, 16) into the shredding device (24), which is preferably followed by the transport device (25).

7. steep conveyor system (1) according to one of claims 5 or 6, characterized in that the route (14) is arranged above the upper height level (13) on a supporting structure (26), so that the steep conveyor system (1) passes through the supporting structure ( 26) forms a structural unit with the at least one device (24, 25) for further processing and/or further transport.

8. Steep conveyor system (1) according to one of the preceding claims, characterized in that the traction means (17) is connected to a drive unit (27), which is preferably arranged on the ground (13) at a distance from the upper end of the route (14) and wherein the traction means (17) is guided over drive wheels (34, 35) of the drive unit (27).

9. Steep conveyor system (1) according to one of the preceding claims, characterized in that at the upper end of the route (14) upper deflection rollers (28) and on the conveyor baskets (15, 16) lower deflection rollers (29) are provided, with between the upper and lower deflection rollers (28, 29), the traction means (17) each forms at least one wind device (30) in the manner of a pulley (30).

10. Steep conveyor system (1) according to claim 9, characterized in _that the wind devices (30) have a double pulley (30) for halving a tensile force, preferably a four-fold pulley (30) for quartering a tensile force and particularly preferably an 8 -fold pulley (30) to reduce the pulling force in the middle of the pull! (17).

1 . Steep conveyor system (1) according to one of the preceding claims, characterized in that the traction means (17) has traction means ends (31, 32), which are arranged on preferably one length compensation means (33), the traction means (17) being controlled by the length compensation means (33). ) can be retracted or released with a further length of traction device.

12. Steep conveyor system (1) according to one of the preceding claims, characterized in that the drive unit (27) has at least two drive wheels (34, 35) around which the traction means (17) preferably has a total wrap angle of at least 360 ° and preferably of at least is twisted 540°.

1 3. Steep conveyor system (1) according to claim 12, characterized in that the drive unit (27) has two motor-gear units (36, 37), a first motor-gear unit (36) having at least a first drive wheel (34) and a second motor-gear unit (37) cooperates in a driving manner with at least one second drive wheel (35).

14. Steep conveyor system (1) according to one of the preceding claims, characterized in that the respective wind device (30) is formed with a first traction means (17a) and with at least one second traction means (7b), which traction means (17a, 17b) together first pulley block (30) for raising and lowering the first conveyor cage (15) and together form a second pulley block (30) for raising and lowering the second conveyor cage (16), and the drive wheels (34, 35) of the drive unit (27) from the at least two traction means (17a, 17b) are wound around.

15. Steep conveyor system (1) according to claim 14, characterized in that the drive wheels (34, 35) are wrapped around at least one of the first traction means (17a). Drive wheel (34a, 35a) and at least one drive wheel (34b, 35b) wrapped around by the second traction means (17b), the drive wheels (34a, 34b, 35a, 35b) preferably being arranged to rotate about a common drive axle (38a, 38b).

16. Steep conveyor system (1) according to claim 14 or 15, characterized in that a first drive wheel (34a) and a second drive wheel (35a) are provided and are wrapped around by the first traction means (17a) and / or that a first drive wheel (34b) and a second drive wheel (35b) is provided and is wrapped around by the second traction means (17b).

17. Conveyor cascade with at least two steep conveyor systems (1) according to claim 1, wherein the lower height level (12) of an upper steep conveyor system (1) adjoins the upper height level (13) of a lower steep conveyor system (1), and in particular between the steep conveyor systems ( 1) Means are provided for transferring the raw materials (11) from the lower steep conveyor system (1) to the upper steep conveyor system (1).

18. System with a steep conveyor system (1), with which raw materials (11) from a lower level (12), in particular from a mining floor (12) of an opencast mine, to an upper level (13), in particular formed by a soil (13) 'transportable ^' and with a shredding device (24) for shredding the raw materials (11), the system having:

a route (14),

a first conveyor cage (15) and

a second conveyor cage (16),

which conveyor cages (15, 16) can be moved on the route (14) between the lower height level (12) and the upper height level (13) and which are designed to hold the raw materials (11),

wherein the conveyor baskets (15, 16) are connected to one another via at least one common traction means (17) and

wherein the shredding device (24) is arranged at the lower or upper height level (12, 13) of the steep conveyor system (1) and in particular forms a structural unit with it.