DE3627049C1 - Pipe-rotating mechanism for pneumatic stowing lines - Google Patents

Abstract

In a pneumatic stowing line with which the waste in underground coal mining is conveyed into the worked space, the requisite zonal dismantling of the pneumatic pipe bend in the face/roadway transition area involves substantially reduced idle time and is ergonomically more favourable owing to the fact that a mating pipe is arranged in front of the pneumatic pipe bend, which mating pipe has a rotatable pipe connection and is acted upon by a pipe-rotating mechanism via which the pneumatic pipe bend can be swung into the roadway after separation of the coupling from the face line. After the swivelling operation, the line laid in the roadway is then pushed into the new position via telescopic devices, whereupon the pneumatic pipe bend can then be swung back into its initial position and attached to the correspondingly displaced line laid at the face. The rotating mechanism has a lifting piston, the horizontal movement of which is converted via a coarse-thread shaft into a rotary movement, in the course of which a toothed disc sitting on the free end of the coarse-thread shaft is in engagement with rack elements which are fastened to the rotatable section of the mating pipe. <IMAGE>

Description

The invention relates to a blow offset line for Bringing mountains into the mined space, especially in underground coal mining, consisting of the with blow-off pipes equipped with quick-release couplings and the blowpipe elbow through which the blowoff flow in the longwall section crossing area from the mining section is redirected into the longwall.

In the blow molding operations in the coal industry The operating point is loaded underground with backfill material through a first in the Mining accompanying route and then running in the face Blow offset line. The backfill material is at the strut entrance deflected by a blowpipe elbow and then by the Blow offset line running in the face to the discharge transported (DE-OS 28 29 664). Driving up routes in mining is very expensive, so if possible with one smallest possible route cross-section is driven. Just there is one in the area of the longwall crossing particular tightness because there due to the machine aggregates, the EH-Bahn etc. Plants have a special need for space. As for the blow offset line in the face Line crossing area because of the necessary diversion there is an additional space requirement Space requirements in this area are also required. It is particularly disadvantageous that with each blow field the manifold dismantled and in the area of the new blowing field must be reassembled, so that at least two, usually three clutches released and the individual Pipe sections can be transported by hand. Because of the This not only brings unfavorable space organizational but also ergonomic problems with yourself. Although the one running in the mining section Blow offset line mechanized via telescopic pipes can only be extended for the changeover the blowpipe elbow a time consuming and physically stressful work required.

The invention is therefore based on the object Relocation of the blow offset line in the longwall crossover area to mechanize and in particular ergonomically improve and thus reduce the idle times due to the process.

The object is achieved in that the blowpipe elbow positioned in the excavation line Pipe tube is arranged, which with a rotatable Pipe connection and a pipe slewing gear is equipped, which in turn has a rotary drive and a gear part has that on the struck on the blowpipe elbow Section of the fitting tube is arranged to act in a rotating manner.

This makes it possible by simply loosening the last clutch or if an additional fitting tube in the Longwall area is provided, the coupling there, then around the blowpipe elbow with the possibly provided Swing the fitting tube into the route and so far, that during the subsequent advancement of the in the mining section bleeding offset line a nudge of the Blowpipe elbow can not occur on the expansion. The whole Blow offset line will then move into its new position with existing ones Telescopic tubes moved, while the pipe run in the longwall is flat if it is pushed into the new position on the longwall construction, then both after reaching their new position Swiveling the blowpipe elbow back very quickly connected by only one coupling to be brought. The explanation of this already shows that a significant simplification of the invention entire workflow in the face Line transition area is possible, with the described design of the tubular slewing gear a safe and thus an ergonomically advantageous solution is specified.

After appropriate training of the present Invention has the rotary drive of the tubular slewing gear  Reciprocating piston on the one forming the transmission part Steep thread shaft slidably arranged and with a adapted internal thread is equipped. In this manner and way the horizontal movement of the reciprocating piston converted into a rotary motion, by means of suitable Then gear the manifold from one to the other Position can be pivoted. Particularly advantageous is that such a piston with the in this Any hydraulic fluid, oil or area Air can be operated so that good Adaptation is definitely given. Another advantage is that the whole mechanics with one simple control can be equipped without the There is a risk that incorrect handling could endanger operator enters.

To ensure that the reciprocating piston is pushed over does not rotate or co-rotate via the high-helix shaft, is the reciprocating piston over a in a guide groove movable wedge secured against twisting. He can the necessary movement in the horizontal direction execute, but must the steep thread shaft turn without the slightest danger, that part of his movement is not translated into rotary motion becomes. Appropriate and stable training is where the rotary drive with reciprocating pistons parallel to the axis Pipes arranged in the mining section and fixed to the section of the fitting tube assigned to the last tube connected is. So that the whole long works in the Discharge line lying blow off line as fixed point, around the last piece of the pipe string with the blowpipe elbow as mentioned above. An additional Support of the rotary drive or tubular slewing gear is thus advantageously not necessary. The steep thread shaft too is advantageously secured here against horizontal Move by placing a trunnion on the surrounding  Housing is secured against moving. she can thus perform the necessary rotational movement without it can move in the horizontal direction. An exact This means that the forces exerted by the reciprocating piston are transmitted secured.

The turning forces are simple and practical Transfer further to the blowpipe elbow by pressing on the Bearing journal at the free end of the high-helix thread shaft on the blowpipe elbow section Triebstockelemente is arranged combing. This training of the gearbox is special for underground mining advantageous because it is contaminated and therefore affected cannot occur. Rather, the rotational movement of the Toothed lock washer passed safely onto the blowpipe elbow or on this, so that it is easy after releasing the coupling and quickly turned or swiveled into the new position can be. Another possibility is that One lock washer on the blowpipe bend in the section assign acting chain or the pulley as Form chain drive pulley, so as to To safely transmit rotary motion on the blowpipe elbow.

An effective seal in the turning area is after an appropriate embodiment of the invention achieved that the two sections for rotatable pipe connection overlapping each other and with one non-rotating seal are provided. Especially in underground mining with its special burdens is such a twist-proof seal especially from Advantage because they have a long life of the tubular slewing gear guaranteed overall. The seal itself is there from a rubber ring arranged between two sliding washers, which are assigned to the mutually rotatable sections. The rubber ring is thus despite the twisting occurring stress achieve a long service life,  creating the desired beneficial life for the whole Pipe turning gear is secured.

The pipe connection is still special Expenses appropriately adjusted by the fixed Section a piece of pipe placed on the outside with is provided with a groove and that on the rotatable portion a piece of pipe provided with an extension and in the area surrounding the adjacent section Recesses for holding wedges that can be driven into the groove is equipped. So that is a simple and convenient Locking of the two sections of the fitting tube given, which is a rotational movement, but not a horizontal shift allowed. Nevertheless, the fixing by the holding wedges offers adequate security when moving in Longitudinal direction of the pipe string, so that the necessary and desired stability is guaranteed.

Falling out or being accidentally removed the holding wedges from their groove is prevented in that the wedges through one on the expanded pipe section slide-on locking ring are secured.

An additional fuse for the seal forming rubber ring is created in that it is between the non-ferrous metal discs are pressed into the notches or grooves in the vertical contact surfaces the pipe pieces are formed, are embedded, wherein in addition to the sliding washers the rubber ring Binding slip rings are provided. The rubber ring is thus like in a housing that protects it Sliding parts completely surrounded, this housing the vertical Contact surfaces in corresponding grooves or notches is housed, thus an optimal even Is always exposed.  

The invention is characterized in particular by that for the first time with the blowing offset line according to the invention the opportunity is created to flip the Track mechanization to mechanize and so far process-related dead times can be significantly reduced. The Shortening dead times is particularly important and of of great importance in companies with medium thickness, where the working conditions are less favorable than in large ones Thicknesses. With the present solution, the Accident risk in the workplace so anyway particularly vulnerable area longwall crossing be significantly reduced. It is also advantageous that the tube slewing gear in the longwall section crossing area existing drive energies can access it is simple in construction and takes up little space, so that the narrow area anyway only insignificant experiences more stress.

More details and advantages of the Subject of the invention result from the following Description of the accompanying drawing in which a preferred embodiment with the necessary Details and individual parts is shown. Show it:

Fig. 1 is a perspective representation of the route Streb- transition region with the Blasversatzleitung,

Fig. 2, the swivel working in section,

Fig. 3, the rotatable pipe connection in section and

Fig. 4 shows the rotatable pipe connection in a perspective view.

In coal mining, the blow-off line is usually led through the so-called head section to the longwall and then redirected into the longwall in the longwall crossover area. This is exactly the point shown in FIG. 1. The blow displacement line ( 1 ) is shown exactly in the area of the deflection point, with ( 2 ) the strut and ( 3 ) the mining route. It is clearly shown in FIG. 1 how the blow offset line ( 1 ) is guided between the expansion bends ( 5 , 6 ) into the strut ( 2 ) here with a correspondingly equipped blow pipe elbow ( 4 ). In addition to the extension arches ( 5 , 6 ), hydraulic rams ( 7 ) arranged in the longwall to support the hanging part must also be taken into account, whereby it becomes clear how narrow this longwall crossover area is. Previously, both the coupling ( 13 ) on the last pipe ( 8 ) in the route and the coupling ( 14 ) on the last pipe ( 9 ) had to be knocked off when the blowing offset line ( 1 ) was extended, in order to then insert the blowing pipe elbow with the attached short pipes into the to bring new with ( 4 ', 8' and 9 ' ) designated position. It was still necessary to release the couplings that were directly assigned to the blowpipe elbow ( 4 ). The effort for this is correspondingly large.

In the blow displacement line ( 1 ) shown in FIG. 1, a fitting pipe ( 10 ) with a rotatable pipe connection ( 11 ) and a pipe rotating mechanism ( 12 ) is arranged in front of the blow pipe elbow ( 4 ), with the help of which, for example, after the coupling ( 14 ) has been released the entire blowpipe elbow ( 4 ) is pivoted out of the face region, in order then to bring it into the position shown in dashed lines in the pivoted state and to pivot it back into the face member. The corresponding procedure is explained by arrows.

The tubular slewing gear ( 12 ) has a rotary drive ( 15 ) and a gear part ( 16 ) via which the necessary rotating or swiveling movement is exerted on the blowpipe elbow ( 4 ). A support ( 17 ) is provided in this area so that the rotatable pipe connection ( 11 ) does not have to be supported directly on the lying surface.

The fitting pipe ( 10 ) consists of two sections ( 18 , 19 ), the section ( 19 ) being firmly connected to the blowing offset line ( 1 ) running in the mining section ( 3 ), while the section ( 18 ) is connected via the pipe rotating mechanism ( 12 ) is rotatable or pivotable.

The tubular bogie ( 12 ) is further explained with reference to FIG. 2. The necessary rotary movement is first performed via the reciprocating piston ( 20 ) in the form of a horizontal movement, this reciprocating piston ( 20 ) having an internal thread ( 21 ) which is shaped corresponding to the high-helix shaft ( 26 ) so that when the reciprocating piston is pushed over ( 20 ) via the high-helix shaft ( 26 ) this is rotated by force. The wedge ( 22 ) and the guide groove ( 23 ) prevent the lifting piston ( 20 ) from rotating. The reciprocating piston ( 20 ) is protected in the cylinder housing ( 24 ) and has connections with which it can be connected to standard hydraulic suppliers.

The steep-thread shaft ( 26 ) is secured by a bearing journal ( 27 ) and a snug fit ( 28 ) in such a way that it can only rotate and cannot carry out a horizontal movement. ( 29 ) denotes the surrounding housing, ( 30 ) an outside sealing ring and ( 31 ) an inside sealing ring in the form of an O-ring, with which the entire rotary drive ( 15 ) is sealed to the outside.

On the outside of the high-helix shaft ( 26 ), a toothed washer ( 32 ) is placed, which meshes with its teeth in the pinion elements ( 33 , 34 ) attached to the section ( 18 ). The rotational movement is thus transmitted to the section ( 18 ) and thus to the blow pipe elbow ( 4 ) via the teeth ( 35 ) and the drive shaft elements ( 33 , 34 ).

The rotatable pipe connection, which is explained in more detail with reference to FIGS. 3 and 4, is identified by ( 11 ) in FIG. 2. Fig. 3 illustrates that the section ( 19 ) with a firmly seated pipe section ( 37 ) is preferably welded by a groove ( 38 ) is made on the axis-parallel side. Holding wedges ( 39 ) are inserted into this groove ( 38 ) and they penetrate the recess ( 40 , 41 ) formed in the pipe section ( 42 ). This pipe section ( 42 ) is pushed over the pipe section ( 37 ) and has a corresponding extension ( 43 ). Falling out of the holding wedges ( 39 ) is prevented by the pushed-on and secured locking ring ( 44 ), which has a flange ( 45 ) at the front, so that it is correspondingly simple and expedient to secure. With ( 46 ) an additional ring is designated, which additionally defines the locking ring ( 44 ).

( 47 ) is a dust seal and ( 48 or 48 ' ) are welded seams via which the pipe sections ( 37 or 42 ) are connected to the sections ( 19 or 18 ).

As already mentioned above, recesses ( 40 , 41 ) are provided in the enveloping region ( 49 ) of the pipe section ( 42 ), which allow this part of the section to be rotated without a longitudinal displacement being possible. The seal ( 50 ) serves to seal the pipe connection, the structure of which is explained below. As explained in FIG. 3, the seal ( 50 ) consists of two sliding rings ( 51 , 52 ) and the sliding disks ( 53 , 54 ), between which the rubber ring ( 55 ) is positioned. This rubber ring ( 55 ) is secured in the corresponding notches ( 56 , 57 ) of the pipe sections ( 37 , 42 ) in such a way that it ensures a long service life and effectively seals this area, taking into account that the material to be blown with the appropriate pressure from the Blow offset line ( 1 ) must be pressed. The notches ( 56 , 57 ) are made in the vertical contact surfaces ( 58 , 59 ) of the pipe sections ( 37 , 42 ).

Fig. 4 finally explains in a perspective view the design of the two pipe sections ( 42 and 37 ) and in particular the arrangement and design of the recesses ( 40 , 41 ) in the form of slots in which the holding wedges ( 39 ) sit and the pipe connection is secure to lead.

Claims (12)

1. Blow displacement line for introducing mountains into the mined area, in particular in underground coal mining, consisting of the blow displacement pipes equipped with quick-release couplings and the blow pipe elbow, via which the blow displacement flow in the longwall area transition area is diverted from the mining line into the longwall, characterized in that that the blowpipe elbow ( 4 ) has a fitting pipe ( 10 ) positioned in the excavation section ( 3 ), which is equipped with a rotatable pipe connection ( 11 ) and a pipe rotating mechanism ( 12 ), which in turn has a rotary drive ( 15 ) and a gear part ( 16 ), which is arranged on the blow pipe elbow ( 4 ) struck section ( 18 ) of the fitting pipe ( 10 ) so as to act in a rotating manner. 2. Blown offset line according to claim 1, characterized in that the rotary drive ( 15 ) of the tubular rotating mechanism ( 12 ) has a reciprocating piston ( 20 ) which is arranged via a steep-threaded shaft ( 26 ) which forms the gear part ( 16 ) and is slidable and with an adapted internal thread ( 21 ) is equipped. 3. Blow offset line according to claim 1 and claim 2, characterized in that the reciprocating piston ( 20 ) via a in a guide groove ( 23 ) displaceable wedge ( 22 ) is secured against rotation. 4. blowing offset line according to claim 1 and claim 3, characterized in that the rotary drive ( 15 ) with reciprocating piston ( 20 ) axially parallel to the tubes ( 8 ) in the mining section ( 3 ) and fixed with this the last tube ( 8 ) associated section ( 19 ) of the fitting tube ( 10 ) is connected. 5. blowing offset line according to claim 1 and claim 2, characterized in that the high-helix shaft ( 26 ) of the gear part ( 16 ) via a bearing pin ( 27 ) on the surrounding housing ( 29 ) is guided secured against displacement. 6. blowing offset line according to claim 1 and claim 2, characterized in that on the bearing pin ( 27 ) at the free end of the high-helix shaft ( 26 ) has a toothed disc ( 32 ) in the on the blow pipe elbow ( 4 ) acting section ( 18 ) attached rack elements ( 33 , 34 ) is arranged in a combing manner. 7. blow offset line according to claim 6, characterized in that the toothed disc ( 32 ) is assigned to the blow pipe elbow ( 4 ) in the section ( 18 ) acting chain. 8. blowing offset line according to claim 1, characterized in that the two sections ( 18 , 19 ) for rotatable pipe connection ( 11 ) are arranged to overlap each other and are provided with a non-rotating seal ( 50 ). 9. blowing offset line according to claim 8, characterized in that the seal ( 50 ) consists of a between two sliding discs ( 53 , 54 ) arranged rubber ring ( 55 ) which are assigned to each other rotatable sections ( 18 , 19 ). 10. Blow offset line according to claim 8, characterized in that on the fixed section ( 19 ) a pipe section ( 37 ) is placed and on the outside with a groove ( 38 ) and that on the rotatable section ( 18 ) with an extension ( 43 ) provided Pipe piece ( 42 ) is placed and in the area ( 49 ) surrounding the adjacent section ( 19 ) is equipped with recesses ( 41 ) for holding wedges ( 39 ) which can be driven into the groove. 11. Blow offset line according to claim 10, characterized in that the holding wedges ( 39 ) are secured by a retaining ring ( 44 ) which can be pushed onto the extended pipe section ( 42 ). 12. Blow offset line according to claim 8 and claim 9, characterized in that the rubber ring ( 55 ) between the sliding discs ( 53 , 54 ) is pressed into the notches ( 56 , 57 ) or grooves which in the vertical contact surfaces ( 58 , 59 ) of the tubular pieces ( 37 , 42 ) are formed, are inserted, in addition to the sliding disks, the rubber ring additionally enclosing sliding rings ( 51 , 52 ) are provided.