EA025725B1 - Support structure for drive or return stations used in underground mining - Google Patents

Abstract

The present disclosure relates to a support structure for drive stations or return stations or the like used in underground mining. A support structure (13) for drive or return stations (11) for use in underground mining includes a base plate (15) resting on a floor (14) and a pivotable carrier (22), to which the drive or return station (11) to be supported is connectable, wherein the pivotable carrier (22) is height-adjustable and fixable at different heights relative to the base plate (15). The base plate (15) is provided with at least two spaced-apart support post elements (20), on each of which a plurality of first locking holes (26) is disposed at different heights. The pivotable carrier (22) is disposed on a support device (21), which is provided with post guides (25) that accommodate the support post elements (20) in a height-adjustable manner. The post guides (25) include second locking holes (27), which are lockable with selected ones of first locking holes (26) using locking bolts.

Description

This invention relates to a supporting structure for drive units or return units, etc., used in underground mining, having a base plate lying on the bottom of the mine, and a pivot bracket to which a supported drive or return unit is connected, the pivot bracket being adjusted according to height and is fixed relative to the base plate.

State of the art

Driving and returning installations for chain scrapers (downhole scraper conveyor) or mountain plows that are used in underground mining must be height-adjustable due to changing local conditions in the developed face and / or in recoil drifts in order to be able to adapt machines to changing conditions. For this purpose, support structures are used in which a plurality of support blocks stacked on top of each other are located between the base plate and the rotary conveyor. The support blocks can be removed or inserted separately to change the height of the drive unit or return unit supported in this way. In the design disclosed in patent No. 20207017 I1, the supporting blocks are fastened to each other by a screw connection. In the design disclosed in patent No. 20313946 I1, the fastening is made using a wedge connection.

Despite the much simpler installation and dismantling of the supporting boxes in comparison with the previously known screw connection, thanks to the wedge connection disclosed in patent No. 20313946, the installation and removal of the supporting boxes in the known supporting structures are associated with relatively high costs. In addition, the conveyor or mountain plow, driven by a head pulley located on such a supporting structure, must be turned off for a relatively long time period in order to change the number of supporting boxes stacked on top of each other. In addition, well-known structures require storage space for currently unused supporting boxes, which often leads to problems in tight spaces, which are a limitation of underground mining.

Supporting structures in the field of underground mining are disclosed in patents ΌΕ 20207017 I1 and ΌΕ 20313946 I1. In addition, patent No. 1483951 B describes a supporting structure for conveyors for underground mining, and patent No. 1283178 A describes a supporting structure used in the field of underground mining for conveyor means for ore delivery.

The present invention is directed, at least in part, to improving or overcoming one or more of the disadvantages of the prior art.

SUMMARY OF THE INVENTION

According to the present invention, a supporting structure of the aforementioned type is described, with which a simpler and faster adjustment of the swivel conveyor relative to the base plate is possible, and with which the storage problem of the supporting blocks can be effectively solved.

The base plate may be provided with at least two spaced supporting elements, on each of which a plurality of first locking holes may be made at different heights, and the pivoting container may be located on the supporting device, which is provided with guides that fix the supporting elements in height. The guides may include second locking holes, which may be with selected holes from the first locking holes using locking bolts.

In some embodiments, lifting cylinders mounted between the base plate and the supporting device can be used to adjust the height of the swivel conveyor relative to the base plate.

In some embodiments, the number of lifting cylinders corresponds to the number of supporting elements, and the lifting cylinders can be respectively located close to the supporting elements.

In some embodiments, two transverse sections of the guide plate with second locking holes can be provided for each of the supporting elements. Supporting elements are located between two transverse sections of the guide plate, which form the guides.

In some embodiments, the implementation of the supporting device may include two approximately And-shaped pressure plates, and their transverse racks form sections of the guide plate, and the crossbar located between them forms a holder for the swivel bracket.

In some embodiments, sections of the guide plate may protrude laterally above the supporting members, and the lifting cylinders can be respectively mounted in transversely protruding sections that are bounded at least partially transversely by the protruding sections of the guide plate.

In some embodiments, the first locking holes and the second locking holes may be arranged in pairs, the heights of each pair of the first and / or second locking holes being offset from each other. Fine adjustment can be achieved by arranging the plurality of (second) locking holes on the rails at different heights from each other. In this case, the interval between the second locking holes in the guides is different from the interval between the first locking holes in the supporting elements. For example, the interval between the second lock holes is slightly smaller or larger, but not many times larger than the interval between the first lock holes.

In some embodiments, the implementation of the supporting elements can be made in the form of transverse racks And-shaped reinforcing bracket located on the base plate and welded to it. In this case, the cross posts may protrude upward from the base plate.

In some embodiments, the lifting cylinders may be mounted on the base plate above the supporting elements of the cylindrical base, which may be mounted on the base plate at various heights. In such an embodiment, for example, it may be possible to introduce one or more separators between each supporting element of the cylindrical base and the base plate. In this case, after removing the locking bolts, the height adjustment can be performed by pulling the lifting cylinders up to the highest position in which the rotary conveyor can be lifted by the lifting cylinder without dividers, as a result of which the rotary conveyor is fixed in this position by introducing the locking bolts through the aligned locking holes. Then, the lifting cylinders can be retracted, as a result of which the supporting elements of the cylindrical base are lifted from the base plate, so that one or more dividers can be inserted between each supporting element of the cylindrical base and the base plate. When the lift cylinders are extended again, they are then supported by the spacer (s) on the base plate, and as a result, after releasing the lock, they can return to the position for further raising the swivel bracket so that one or more additional spacers can be inserted between each supporting element of the cylindrical base and base plate.

In this design, the height adjustment of the swivel conveyor relative to the base plate can be performed in a simple and effective way, namely by aligning the second locking holes made on the rails with the first locking holes on the supporting elements, while these first locking holes can be located on each of desired heights, and then the insertion of locking bolts through the first and second locking holes, whereby the supporting elements can be fixed together ste with guides in interference fit.

In addition, it is possible to install a lifting cylinder on all sides by placing cover sheets at all ends of the transversely protruding parts of the guide plate segments. In this case, the cladding sheet may connect the two sections of the guide plate, whereby a space defined by the sections of the guide plate, the cladding sheet and the supporting member is formed. One lifting cylinder may be located in each cavity thus formed.

Additionally, lifting cylinders acting between the base plate and the supporting device can be installed in a simple, quick and accurate way to adjust the height of the pivoting bracket relative to the base plate.

In the case where two support elements can be presented on the base plate to support the swing arm, two lift cylinders are desirably mounted about two respective support elements, and the lift cylinders can then be controlled so as to prevent jamming in the support elements or jamming in the rails.

In this design, the swivel bracket, which can be supported by the bars of the I-shaped pressure plates, can be lowered very deeply, in particular if the cross posts of the pressure plates can protrude upwards so that the crossbars located between them can form the deepest part of the support device.

In order to be able to achieve a wide adjustment range of the support device, even with compact lift cylinders having a relatively low lift height, the lift cylinders can be mounted on the base plate by means of corresponding cylindrical elements, and sections of the transverse guide may include locking holes.

Additional features and advantages of the present invention will become apparent from the following description and the accompanying drawings, in which a preferred embodiment of the present invention will be explained in more detail using an exemplary embodiment.

Brief Description of the Drawings

FIG. 1 shows in perspective a drive unit for a downhole conveyor used in underground mining in the transmission area to the drift conveyor in accordance with the invention;

FIG. 2 shows an embodiment of a support structure in perspective;

- 2,025,725 of FIG. 3 is a perspective view of the support structure of FIG. 2 in assembled condition; FIG. 4 depicts a support structure in longitudinal section;

FIG. 5 is a side view of the support structure of FIG. 4 and partially in section along the line VV of FIG. 4;

FIG. 6 is a perspective view of a base plate and additional dividers mounted thereon.

Detailed description

In FIG. Figure 1 shows, in general, the transmission device used in underground mining between the face conveyor and the drift conveyor and indicated by 10. For clarity, only one drive unit 11 of the face conveyor and one pit of the conveyor 12 of the drift conveyor are shown along which scraper elements drawn by the chain (not shown) transport the extracted product from the downhole conveyor to the drift conveyor in the longitudinal direction of the drift, as is widely known.

The drive unit 11 of the downhole conveyor is located above the bottom of the excavation 14, adjacent to the drift conveyor laterally by the support structure 13. This support structure 13 of the drive unit 11 is the subject of the present invention and is shown in more detail in FIG. 2-6.

The support structure 13 has a support plate 15 lying on the bottom of the mine 14. The support plate 15 is provided with a surrounding reinforcing frame 16 having two end spars 16 a and two spars 16 b screwed to the longitudinal sides of the support plate 15. A reinforcing bracket 17 having an approximately I-shaped the form is fixedly fixed in the center on the base plate 15, mainly by welding the lower beam of its transverse bracket 18 with the base plate 15. The reinforcing bracket 17 has struts 19 located at the two ends of the transverse beam bracket (bridge) and protrude upward from the base plate 15. Stands 19 form support stands 20 for the support device 21, which can be fixed to the support stands 20 at different heights above the base plate 15, as will be described in more detail below. A swivel bracket 22 is located on the support device 21, and the drive unit 11 is mounted on the support device 21, as shown in FIG. one.

The supporting device 21 has two approximately I-shaped fixing plates 23 with transverse protruding legs that form portions 24 of the guide plate. The guide plate sections 24 respectively comprise guides 25 between which one of the supporting elements 20 is located. Both supporting elements 20 have several first locking holes 26, which are arranged in pairs and across at different heights on the supporting elements 20. The second locking holes 27a, b are made in sections 24 of the guide plate of the supporting device 21. The two locking holes 27a, b are not located at the same height relative to the base plate 15, but are offset relative to each other in the vertical direction. More specifically, they are offset by a distance corresponding to at least half the vertical distance between the two first locking holes 26.

The second locking holes 27 in the sections 24 of the guide plate are arranged so that when mounting the supporting device 21 on the supporting stands 20, the second locking holes 27 can be aligned with the first locking holes 27. That is, each external 27a of the second locking holes is aligned with the corresponding four external 26a from the first locking holes in each support stand 20, and each inner 27b of the locking holes is aligned with the corresponding four inside with tram 26b from the first locking holes in each support stand 20.

As shown in FIG. 2, 3 and 5, sections 24 of the guide plate (in particular, at least the guides 25) extend laterally outside the support arms 20 towards the end spars 16a, forming a cavity 28 between them for installing the hydraulic lifting cylinder 29. A cylindrical base 30 of each a hydraulic lifting cylinder 29 is mounted above the supporting element of the cylindrical base 31 on the base plate 15, and the upper connecting head of the piston rod of the lifting cylinder 29 is pivotally connected to the supporting device.

The fixing plates 23 of the supporting device 21 and the crossbars located between the transverse struts 24 together form a holder 33 for the pivot bracket 22. The pivot bracket 22 is rigidly connected, for example, by welding with two fixing plates 23 in the holder 33. The pivot conveyor 22 includes essentially, a lower connecting plate 34 welded to the supporting device 21, and a flange plate 36 that rotates relative to the connecting plate 34 about a vertical axis of rotation by means of a hinge connection 35. The base 37 is rotatably connected about a horizontal axis 36 to the flange plate 36 and to the drive unit 11. Thus, the base 37 is rotatably mounted around two axes so that the angle of the drive unit 11 relative to the supporting structure 13 can be adjusted as known in prior art transmission devices.

Lifting cylinders 29 can be extended or retracted to adjust the height of the swivel

- 3 025725 of the bracket 22 with respect to the base plate 15 and, thus, to set the desired height of the drive unit 11. When the first and second locking holes 26, 27 become aligned with each other, the supporting device 21 is fixed at a predetermined height using the locking bolts 38 which are introduced through coaxial locking holes 26, 27. The base 37 is able to rotate around two axes relative to the supporting device 21, which ensures that the head of the drive unit 11 located on the base 3 7 retains the desired orientation in the downhole conveyor, which it drives, or can automatically self-establish in this position.

In FIG. 4 and 5, the lifting cylinders are shown elongated almost to their maximum working volume. Due to their limited stroke length, without additional measures in the embodiment shown, they would not be able to raise the supporting device 21 so far as to reach the two highest positions. In order to be able to move the support device 21 to one of the two highest positions, the lift cylinders 29 can be extended to the position shown in FIG. 4 and 5, and the locking bolts 38 are inserted through the second uppermost of the outer control holes 26a. Then, by pulling the lifting cylinders 29 into this fixed state, the cylindrical bases 30 are lifted from the base plate 15 with supporting elements 31 located on the cylindrical bases 30. As soon as the lifting cylinders 29 are completely retracted, between the supporting plate 15 and each supporting element 31 of the cylindrical base may be one or more intermediate inserts 39 shown in FIG. 6. The contact point of the supporting elements 31 of the cylindrical base relative to the base plate 15 is then moved up. By extending the lifting cylinders 29, the supporting device 21 can then be moved further upward by an additional distance that corresponds to the effective thickness of the intermediate inserts 39.

Although preferred embodiments of this invention are described in this document, improvements and modifications may be made thereto without departing from the scope of the following claims.

Claims (9)

CLAIM 1. Support structure (13) of a drive or return installation (11) used in underground mining, comprising a support plate (15) made with the possibility of installation on the bottom of the mine (14) and provided with at least two spaced support supports ( 20), on each of which a plurality of first locking holes (26) are made at different heights, a supporting device (21) provided with guides (25), between which respective supporting supports are arranged with height adjustment (20), the swivel bracket (22), which is associated with a supported drive or return installation, is made with the possibility of adjustment and fixation at different heights relative to the base plate (15) and is located on the supporting device (21), while supporting stands (20) have first locking holes (26) arranged in pairs on supporting elements 20, guides (25) are provided with second locking holes (27) arranged in pairs with the possibility of blocking with holes selected from the first locking from versts (26) with the help of locking bolts (38), and the first (26) and / or second (27) locking holes, arranged in pairs, are offset from each other in height. 2. The supporting structure (13) according to claim 1, characterized in that it comprises lifting cylinders (29) installed between the supporting plate (15) and the supporting device (21). 3. The supporting structure (13) according to claim 2, characterized in that the number of lifting cylinders (29) corresponds to the number of supporting stands (20), and they are located close to the supporting stands (20). 4. The supporting structure (13) according to any one of claims 1 to 3, characterized in that the supporting device (21) includes two transverse sections (24) of the guide plate for each of the supporting stands (20), while the transverse sections ( 24) contain second locking holes (27). 5. Support structure (13) according to any one of claims 1 to 3, characterized in that the supporting device (21) includes two approximately I-shaped fixing plates (23), while the transverse struts of the I-shaped pressure plate (23) ) form the transverse sections (24), and the crossbar located between the transverse posts of the I-shaped fixing plates (23) forms a holder (33) for the swivel bracket (22). 6. Supporting structure (13) according to claim 4 or 5, characterized in that the transverse sections (24) protrude laterally outside the support supports (20), and the lifting cylinders (29) are respectively placed in cavities (28) bounded at least partially transversely by the protruding parts of the transverse sections (24). 7. Support structure (13) according to any one of claims 1 to 6, characterized in that the supporting stands (20) are made in the form of racks (19) of a C-shaped reinforcing bracket (17) located on the base plate and welded with it, while the uprights (19) are directed upward from the base plate (15). 8. Support structure (13) according to any one of claims 1 to 7, characterized in that the lifting cylinders (29) are mounted on the support plate (15) by means of the corresponding supporting elements of the cylindrical base (31) mounted on the support plate (15) on different heights. 9. The supporting structure (13) according to claim 8, characterized in that it contains intermediate inserts (39) located between the supporting elements of the cylindrical base (31) and the base plate (15).