CZ308397B6 - Articulated steel mining joist to cover the ceiling at the point of contact between the face and the corridor - Google Patents

Abstract

The mine steel articulated ceiling beam (2) for covering the ceiling against falling rock from the overburden at the point of contact of the face with the corridor comprises a common ceiling (2') connected to the end section of the mine mechanized reinforcement (1) adjacent to the corridor. To the common ceiling (2′) of the section of the mine mechanized reinforcement (1) is connected from above a welded box part (8) formed by at least two ribs (9), which are interconnected by an upper plate (11). In the inner space (15) of the box part (8), at least one ceiling (14) is placed between the ribs (9), which can slide out of the ceiling (2) in the direction of the corridor. The beam (17) of the ceiling (14) has a foldable side support (30) at its end (17')

Description

Mining steel articulated ceiling to cover the ceiling at the point of contact of the face with the corridor

Field of technology

The invention relates to a mine steel articulated ceiling, which is part of the outermost section of a mechanized mine reinforcement intended to cover the ceiling against rock falling from overburden at a point where a face and a corridor meet during coal or other mineral mining, especially in deep mines.

Prior art

If the mining tunnel is not excavated parallel to the face during coal mining in deep coal mines or even during the mining of another mineral in other mines, an unsecured space is created at the point where the face and the hall meet each other against rock falling from the overburden. At this point, between the last section of the mechanized mining reinforcement and the corridor, there is a danger for the operating crew and also for other installed mining equipment located in the area.

To eliminate the described danger, i.e. to cover the gap created between the face and the corridor, for example, a method is currently used in which another section of mine mechanized reinforcement protrudes into the corridor. The disadvantage of this solution is the very need to add / remove a section of mine mechanized reinforcement during mining, which is time consuming. The disadvantage is also the limitation of the space in the corridor in cases where the corridor is used and subsequently used.

To cover the described gap against the rock falling from the overburden, a tilting side cover is currently also used at the extreme section of the mechanized mine reinforcement adjacent to the corridor. However, the disadvantage of the solution with a hinged side cover is its much lower load capacity. In the case of high pressures from the overburden, the ceiling can push the tilting side cover and cause rock to spill into the operator's movement area.

Another way of covering the described gap is to secure it with the help of wooden reinforcement. With this solution, wooden struts and an artificial ceiling are built into the free space between the last section of the mechanized mining reinforcement and the corridor. This is very time consuming and slows down mining. Higher demands are also placed on transport and wood consumption.

The essence of the invention

The object of the invention is to provide a new solution for securing a space against rock falling from an overburden at a point where a face and a corridor meet each other, which would eliminate the above-mentioned disadvantages either completely or at least to a large extent.

This task is solved by the presented construction of a mine steel articulated ceiling to cover the ceiling against falling rock from the overburden at the point of contact of the face with the corridor. The ceiling consists of a common ceiling formed by a welded frame, which contains the base plate, webs, beds, handles and other parts for connection to the section of mine mechanized reinforcement.

The essence of the solution according to the invention is that a box part consisting of at least two with respect to the longitudinal axis of the base ceiling is connected to the surface of the base plate of the frame of the common ceiling by the last section of the mechanized mining reinforcement, which adjoins the corridor slabs of a common ceiling of perpendicularly arranged ribs, which are interconnected by an upper slab. At the same time, parallel to the longitudinal axis of the base plate of a conventional ceiling, the box part has openings on both its edges - mutually opposite openings and the left side opening and

- 1 GB 308397 B6 right side hole. The box part is adapted to accommodate at least one ceiling, which is loosely arranged in its inner space between the ribs. The ceiling is slidable outwardly from the interior of the box member via the left side edge or the right side edge of the base plate of the conventional ceiling by means of at least one extendable force element, either a left side opening or a right side opening. Which side opening leads the ceiling from the ceiling to the space towards the corridor or the ceiling into the ceiling depends on the setting of the last section of the mine mechanized reinforcement during mining. If the adjacent corridor with the last section of the mine mechanized reinforcement is on the right, then when looking at the section of the mine mechanized reinforcement from the pillar side to the collapse, the ceilings slide out of the ceiling / slide into the ceiling also on the right. Conversely, if the adjacent corridor with the last section of the mine mechanized reinforcement is on the left when looking at the section of the mine mechanized reinforcement from the pillar side to the landslide, the ceilings extend from / to the ceiling.

In a preferred embodiment, the ceiling is formed by a hollow welded beam, and preferably the cavity of the beam is adapted to accommodate at least one extendable force element.

Another essence of the solution according to the invention is that the extensible force element is rotatably connected in the cavity of the ceiling beam in the first holder to the ceiling beam in its first end, the opposite, second end of the extensible force element being rotatably connected in the interior via a second holder or a second opposite holder. to the box part. With this construction, the ceilings can advantageously be pushed out of the ceiling into the space towards the adjacent corridor, as required - either to the right or to the left of the last section of the mechanized mining reinforcement.

It is advantageous if the extensible force element is formed by a rectilinear hydraulic motor. The advantage of setting up a linear hydraulic motor in the cavity of the ceiling beam is that it is thus protected against damage during demanding operation in the mine.

In another preferred embodiment, a foldable side support is connected to the end of the ceiling beam, which faces the corridor, by means of joints and a rectilinear hydraulic motor. By tilting the side support, it is possible to cover an even larger space to cover the gap at the point where the face and the corridor meet each other and to secure it more against the fall of the homina from the overburden.

The proposed new ceiling solution to cover the ceiling against rock falling from the overburden at the face / corridor junction is also advantageous when used in longwall mining technology. It enables a smooth response to the changing distance between the face and the corridor without the need to add another section of mine mechanized reinforcement or additional reinforcement work. In a particularly advantageous embodiment when using several extendable ceilings from the ceiling, where the extension / retraction of each ceiling can be controlled separately and the length of their extension can be adjusted, it is then possible to react quickly to changing local conditions of covering the ceiling against hominy from overburden on crossing the face / corridor in the mine.

Explanation of drawings

The invention is described in more detail with reference to the accompanying drawings, in which Fig. 1 shows a top view of the outermost section of a mechanized mine reinforcement adjacent to the mine corridor (not shown) on the right; the ceiling comprises retractable ceilings to cover the ceiling against falling hominy from the overburden. coal or other mineral meet the face and the corridor, while the ceilings are fully inserted inside the ceiling.

Giant. 2 and FIG. 3 show, in a simplified embodiment, side views from above only of the ceiling with the ceilings extendable towards the corridor, the ceilings being fitted at their ends.

-2 CZ 308397 B6 foldable side supports, the ceiling is shown without other parts for connection to the outermost section of the mine mechanized reinforcement. Fig. 2 shows the ceilings in the fully extended state from the ceiling, Fig. 3 shows the ceilings in the fully inserted state into the ceiling.

Fig. 4 shows in a simplified embodiment a bottom view of a ceiling with extendable ceilings mounted on the ends with foldable side supports, the ceilings being shown in a state fully extended from the ceiling towards the corridor.

Giant. 5 shows, in a simplified embodiment, a top view of a ceiling with extendable ceilings fitted at the ends with foldable side supports, the ceilings being shown in a state fully extended from the ceiling towards the corridor.

Examples of embodiments of the invention

Mining steel articulated ceiling 2 intended to cover the ceiling against falling rock from the overburden in the place where during mining, especially during mining of coal or other minerals, the face front meets the corridor according to the invention is designed so that it can be used to cover the ceiling against falling rocks from the overburden on both sides, depending on whether the corridor adjacent to the last section of the mine mechanized reinforcement 1 is to the right or to the left. If the corridor is located at the right side when looking at the last section of the mine mechanized reinforcement 1 from the pillar tent, according to Figure 1 in the direction P, then the direction of extension of the ceilings 14 from the ceiling 2 is also on the right. If the corridor adjacent to the last section of the mine mechanized reinforcement 1 is on the left, it is necessary that the direction of extension of the joists 14 from the ceiling 2 is also on the left. It is possible to achieve the extension of the ceilings 14 from the ceiling 2 to the left by a simple assembly change of the positioning of the ceilings 14 in the inner space 15 of the ceiling 2, where the ceilings 14 in the ceiling 2 are rotated by 180 ° and

An exemplary embodiment of a mine steel articulated ceiling 2 according to the invention is described in more detail when used with the end section of the mine mechanized reinforcement 1, in which the adjacent corridor is on the right when looking at the section of the mine mechanized reinforcement 1 from the pillar side in the P direction. six ceilings 14 are used to cover the ceiling against the fall of rock at the point of contact of the face with the corridor, which are slidable from the ceiling 2 towards the corridor.

In other solutions (not shown) of the mine steel articulated ceiling 2 according to the invention, the number of ceilings 14 extendable from the ceiling 2 may be different - less than six or even more than six, but at least one.

The mine steel articulated ceiling 2 according to the invention consists of a conventional ceiling 2 'consisting of a welded frame 3 comprising a base plate 4, webs 5, seats 23, brackets 6 and other parts for connection to the mine mechanized reinforcement section LK to the outer surface 7 of the base plate 4 of the frame 3. the box part 8 is formed by welding a box part 8 from above. the ribs 9 are welded from above by a top plate 11 so that it is set parallel to the base plate 4 of the frame 3 of the conventional ceiling 2L. On the sides at both its edges 36 and 37 it has a box part 8 parallel to the longitudinal axis 22 of the base plate 4. ceiling ZL, formed by vertical, mutually opposite side openings 12, 13 - left side opening 12 and right side opening 13. Inside the box part 8, six internally formed ones are formed between adjacent ribs 9. In each inner space 15 one retractable ceiling 14 is accommodated. The ceiling 14 is formed by a hollow welded box beam 17 which has an opening 19 formed in the lower part 26, in the direction of the ground. of the beam 17 of the ceiling 14 is adapted to accommodate at least one extensible force element 21. A rectilinear hydraulic motor 35 is used as the extensible force element 21. In the described example

-3 CZ 308397 B6 embodiment according to the invention, one rectilinear hydraulic motor 35 is arranged in one cavity 20 of the beam 17 of the ceiling 14. The rectilinear hydraulic motor 35 is connected to a hydraulic circuit (not shown) which controls the section of the mine mechanized reinforcement L

The opening 19 in the beam 17 of the ceiling 14 is formed for mounting and dismounting the linear hydraulic motor 35 into the cavity 20 of the beam 17 of the ceiling 14 and for its inspection in operation. The cavity 20 of the beam 17 of the ceiling 14 is adapted to position the rectilinear hydraulic motor 35 such that the rectilinear hydraulic motor 35 is rotatably connected in a first end 31 in the first bracket 33 to the beam 17 of the ceiling 14 in the first bracket 33, the second end 32 of the rectilinear hydraulic motor 35. , which is opposite the first end 31, extends from the cavity 20 of the beam 17 of the ceiling 14 into the box part 8 and is rotatably connected in the inner space 15 to the box part 8 by means of a second holder 34. By connecting the box part 8 and the beam 17 of the ceiling 14 by a rectilinear hydraulic motor 35 it is ensured that the ceilings 14 can be extended from the ceiling 2 of the end section of the mine mechanized reinforcement 1 in the direction of the corridor to the right, through the right side opening 13 outwards from the inner space 15 of the box part 8, through the right side edge 25 of the base plate 4 2ý

The length of extension of the ceiling 14 from the ceiling 2 depends on the possibilities of the length of extension of the piston rod 16 of the linear hydraulic motor 35 and on the rigidity of the construction of the ceiling 14 in the ceiling 2. Each of the six extendable ceilings 14 can be extended out of the ceiling 2 or inserted back into the ceiling 2 separately. This makes it possible to react smoothly to the changing distance between the face and the corridor.

If there is an adjacent corridor when looking at the last section of the mine mechanized reinforcement 1 from the pillar side in the direction P to the left (the solution is not shown), the direction of extension of the joists 14 from the ceiling 2 must also be to the left. By assembly change - rotation by 180 ° setting of individual ceiling 14 and attachment of the second end 32 of the linear hydraulic motor 35 to the second opposite holder 34 'in the inner space 15 of the box part 8 of the ceiling 2 - then the ceiling 14 can be extended from the ceiling 2 of the extreme section of the mine mechanized reinforcement 1 in towards the corridor, which is on the left, through the left side opening 12 outwards from the inner space 15 of the box part 8, through the left side edge 24 of the base plate 4 of the common ceiling 2y

An even greater coverage of the ceiling space against rock falling from the overburden at the point where the face of the abutment meets the corridor during coal or other mineral extraction is achieved by providing the beam 17 of the ceiling 14 at its end 17 'facing the corridor. tiltable side support 30, which is connected to the beam 17 by means of joints 28, 29 and a straight hydraulic motor 27. By tilting the side support 30, an even larger space can be covered to cover the gap where the face and corridor meet and to secure it even more against falling hominy from the overburden.

Industrial applicability

The mine steel articulated ceiling according to the invention is intended for use at the end of the mine mechanized reinforcement to cover the ceiling against falling rock from the overburden at the point where the face meets the corridor, in mining operations for coal or other minerals. It is also suitable for use in heavy mining operations with a risk of gas or dust explosion.

Claims (5)

PATENT CLAIMS Mining steel articulated ceiling (2) for covering the ceiling at the point of contact of the face with the corridor, consisting of a common ceiling (2 ') formed by a welded frame (3) comprising a base plate (4), webs (5), beds ( 23) and brackets (6) for connection to the section of the mine mechanized reinforcement (1), characterized in that a box part (8) is connected from above to the surface (7) of the base plate (4) of the frame (3) of the common ceiling (2 '). ), which consists of at least two ribs (9) perpendicularly arranged with respect to the longitudinal axis (22) of the base plate (4) of a conventional ceiling (2 '), which are interconnected by an upper plate (11), parallel to the longitudinal axis (22). the base plate (4) of a conventional ceiling (2 ') has a box part (8) formed on both of its edges (36, 37) opposite the left side opening (12) and the right side opening (13), the box part (8) being adapted to accommodate at least one ceiling (14) which is loosely arranged in its inner space (15) between the ribs (9), the ceiling (14) being arranged by means of at least one extension. usable force element (21) through the left side opening (12) or the right side opening (13) extendable outwards from the inner space (15) of the box part (8) via the left side edge (24) or the right side edge (25) of the base plate ( 4) common ceilings (2 '). Mining steel articulated ceiling (2) for covering the ceiling at the point of contact of the face with the corridor according to claim 1, characterized in that the ceiling (14) is formed by a hollow welded beam (17), the cavity (20) of the beam (17) being adapted to provide at least one extendable force element (21). Mining steel articulated ceiling (2) for covering the ceiling at the point of contact of the face with the corridor according to claims 1 and 2, characterized in that the extensible force element (21) is in the cavity (20) of the beam (17) of the ceiling (14) an end (31) rotatably connected in the first holder (33) to the beam (17) of the ceiling (14), the opposite, second end (32) of the extensible force element (21) being connected by a second holder (34) or a second opposite holder (34 '). ) rotatably connected in the inner space (15) to the box part (8). Mining steel articulated ceiling (2) for covering the ceiling at the point of contact of the face with the corridor according to claims 1 to 3, characterized in that the extensible force element (21) is formed by a rectilinear hydraulic motor (35). Mining steel articulated ceiling (2) for covering the ceiling at the point of contact of the face with the corridor according to claims 1 to 4, characterized in that the end (17 ') of the beam (17) of the ceiling (14) facing the corridor a foldable side support (30) is connected by means of joints (28, 29) and a linear hydraulic motor (27).