CS198180B2 - Method of constriction of the mine reinforcement of the mine or tunnel workings drifts driven by the explosive works - Google Patents

Abstract

1522687 Mine and tunnel linings RUHRKOHLE AG 19 Dec 1975 [24 Dec 1974] 52015/75 Heading E1F In a method of supporting a mine or tunnel driven by shotfiring, a crown segment canopy is preassembled from segments 4, 5 of crowns 16-20, distance pieces 13, 14 and at least one lagging mat 21, preferably made from wire mesh. After assemblage e.g. at A 3 and using an erector, the canopy is conveyed into freshly advanced drift A 1 and lifted to the position indicated by chain lines so that distance pieces 25, 26 and lagging mats 22 can be connected between the canopy and the previously set assembly in drift A 2 . The canopy is then further raised into contact with the roof (the position indicated by solid lines), and additional segments 6 and legs 3 are positioned, adjustment being made so that the cross-section of each individual support adapts to the local crosssection of the drift, the periphery of each support contacting the rock at several points, and no backfilling being necessary. As shown, the adjustment for each support is provided by a hydraulic leg 3 acting through a butt cap 2. Alternatively the length of overlap between segments may be varied or the legs and additional segments may be hinged to the canopy and straightened until the supports make tight contact with the rock.

Description

BACKGROUND OF THE INVENTION The present invention relates to a method of constructing mine reinforcements in tunnel or tunnel tunnels embossed by blasting operations, in which a plurality of reinforcements with joist segments and then other segments and / or uprights are successively deposited using spacers and reinforcement mats.

Corridors driven by blasting operations have an irregular cross-section because the tear openings are directed not only in the direction of the corridor, but also outwards, so that the cross-section of the corridor increases from the beginning to the end of one run. Depending on the lead-in length and the thickness of the passageway profile, the radial difference between the smallest and the largest cross-section can be, for example, 2 to 35 cm. In addition, cavities between reinforcement and rock must be filled according to safety regulations. This requirement is based on various considerations, such as the fact that reinforcement can only perform its various functions when it rests on the rock, and the fact that hazardous mine gases accumulate between the reinforcement and the rock if cavities remain.

It is already known to clean, in particular, the corridor ceiling after a single haunch, then to advance the already extended reinforcement of the extended rail in front of the foremost joist segments and to store the respective joining areas at the desired joist spacing.

The ceilings of this lead-in region are then usually joined by spacers. The load-bearing covering, which provides effective protection against falling stones, can only be modified after the reinforcement has been completed with uprights. This covering is formed, for example, by reinforcing mats, consisting of several welded longitudinal and transverse rods, and so-called hand-sized pieces of rock, which lie behind the covering and fill the cavities. These cavities are usually the result of blasting operations, but they can also be caused by local fracture of the rock.

This known method has a number of drawbacks. It assumes that the crews are concentrated on the face and is therefore unsuitable for increasing punching performance. In addition, it is the cause of frequent accidents because it is necessary to work under either unsecured or imperfectly secured corridor ceilings. In addition, it requires particularly good co-operation of punches, which implies experts who are hardly able to obtain for the construction of mines or for the construction of tunnels. Also, the reinforcement already prepared does not satisfactorily fulfill its function, since the rock is first released and only then loads the reinforcement.

Measures of various kinds are already known to remedy the various deficiencies mentioned. Thus, for example, the attempt is to carry out blasting operations only in the intended profile and thereby reduce the proportion of work required for filling cavities. However, cavities cannot be completely prevented due to the abovementioned blasting properties. Furthermore, attempts have been made in this. direction to make. the reinforcement of the corridor was placed under the prestressed rock. Given the need to fill the gaps behind the reinforcement, these attempts were not successful. However, it is not necessary to fill the gaps behind the cover. due to relevant safety regulations possible, especially in corridors hit by blasting operations.

Development · ¹ therefore seeks to stamping machine in which · the · start by creating machines .. full or partial amputation. For machines with full cutting, it is usually used as an auxiliary. for reinforcement uses erector. However, such punches are very expensive and technically complicated. Therefore, it is often not possible to use them in the construction of corridors. .

It is already known to use. in such cases of work platforms, which also have, in some embodiments, an erector for construction, which keeps the reinforcement ceilings under the ceiling until the uprights are fitted. However, the success of the mechanization of these platforms remained limited, as they had to fill in the gaps behind the corridors as before.

Also, the known measures that have been taken to date to avoid gaps in hand-sized stones could not bring any substantial improvement in the ratios. Strojní. . filling gaps, for example anhydride, requires considerable technical costs. The use of fine mesh mesh reinforcing mats allowing the filling of fine - grained material which can be filled with a mechanical shovel or compressed air can only be carried out in exceptional cases, particularly in the area of ceilings - reinforcement. so it is usually limited. corridors where correction does not imply any substantial improvement.

The object of the invention is to ensure that the reinforcement is placed directly on the rock, which allows, except in the specific cases mentioned, to completely dispense with the reinforcement required so far, in particular in the ceiling area, with the safety of the crews. as well as transport, mining and ventilation are completely satisfactory in the corridors so constructed.

In the method mentioned in the introduction, this task is solved by making from the mesh reinforcement mats of fine mesh with the attachment of the reinforcing mats and the respective spacers at least from the overhead segments of the reinforcement of one of the lead-in areas to be transported. to the first lead-in area, where it is lifted, and then the joints of the reinforcement mats and spacers are formed to the last slab of reinforced concrete, whereupon the finished reinforcements are made, whereupon the tile is lifted up to · touch with. rock and. before or during the placement of the uprights or thereafter, the cross-section of each reinforcement adapts to the partial length of the first inlet region of the first lead-in region by means of a dimensionally abutting abutment at several points in its perimeter.

According to the invention, the overhead gables provided on the one hand ensure the safety of the occupants on the face against the falling of stones from the ceiling and on the other hand allow the immediate connection of this reinforcement area and its abutment _into the rock in the already constructed and secured part of the corridor. This ensures the spatial separation of these parts of the construction from the front work, which allows · at the same time to carry out the largest part of the work on the track. After the joist panel has been moved to the lead-in area, it is first raised to a level that allows it to rest on the already existing reinforcement. Most of these work can be done under the reinforced reinforcement or under the roof of the overhead gable, so there is no greater risk to the front of the crew.

Once the joints have been formed, the ceiling shield is secured to the ceiling. · The ¹ means that the joists connected to · _{(stropnicového} · shield · optionally stropnicové segments' and / or on immovably fixed wire reinforcement mat abut · merely · V several · few · locations. Directly on the rock. Fixing the spacers and especially wire reinforcement mats and fine mesh wire mesh ensure that falling stones remain on the ceiling gable and do not jeopardize the crew in the punching process, which first removes the haunch residues and only then begins to complete the reinforcement.

According to a further feature of the method according to the invention, the joining of the reinforcement and / or spacers, generally formed by screws, in the joist panel is only tightened temporarily and definitively only after the joining panel has come into contact with the ceiling. This makes it possible to adapt each reinforcement individually to the instantaneous cross-section. For this purpose, only the props, especially those which are extendable hydraulically, can then be used. It goes without saying that other storage devices that are. known and used to store the reinforcement with prestressing on the rock. From the above. it is apparent that the corridors' joints and ceilings have a stairway which, at first glance, differs from the corridors which were built in the manner described in the introduction and which are supported by the rock by means of filled gaps.

The main advantages of the invention are that it is substantially improved. performance and safety. The main reason for the increase in performance · is the spatial separation of a large part of the works in the construction of corridors and the fact that the filling of the reinforcement is completely eliminated. The increase in occupational safety is not limited to the fact that the crews on the forehead can carry out all work either under the ceiling gable or under the reinforcement already built, but also because the rock abuts against the bottom and biased reinforcement. and the tiny cavities which remain between the fine mesh wire mesh and the rock are self-extinguishing by the peeling of small particles.

In the method according to the invention, the described adaptation of the reinforcement to the associated partial lead-in length can be realized, for example, by using the sliding legs and from several segments of the composite ceiling arch in each reinforcement by extending and bending the ceiling. The whole process is characterized by special simplicity.

The desired adaptation can also be achieved according to the invention by varying the overlap of the reinforcement segments.

It is particularly advantageous to provide a further embodiment of the method according to the invention, in which at least other segments and / or props are attached and folded to form the joist gable to the joist segments, and that the hinge segments are folded up to form-rigid abutting the rock. In doing so, even more reinforcement work at the front of the corridor is reloaded and the individual working processes are further separated. In addition, the desired adaptation can be achieved more easily and more favorable reinforcement shapes are created after the adaptation.

Also in the method according to the invention, the intended fastening of the reinforcing bars and mats with fine-mesh wires to the ceiling segments can be provided in various ways. However, it is particularly advantageous to achieve high performance when the reinforcing mats in the ceiling gable are tied and thus fastened to the ceiling girders; in this case, the reinforcement mats assigned to the ends of the sophisticated shield are individually tied individually with the ceiling segments and are tied together with the ends of the connected reinforcement mats and ceiling shields between the ends of the ceiling shield.

The invention is explained in more detail below in an exemplary embodiment in conjunction with the drawing. From this explanation, other features and advantages of the method according to the invention can be recognized.

FIG. 1 is a partial cross-sectional side view of a mine passage formed by the method of construction of the mine reinforcement according to the invention, with the further operation of the method of the invention being shown in dashed lines.

Fig. 2 is a cross-sectional view taken along line II-II in Fig. 1.

The corridor shown in FIG. 1 has an arcuate cross-section. The reinforcement 24 consists of a three-quarter arched joist 1, a vacuum 2 and a hydraulic prop 3. The three-quarter arched joist 1 consists of several segments 4, 5, 6. The segments 4, 5, 6 have a trough-shaped profile. As can be seen in particular from FIG. 1, the segments 4, 5, 6 overlap at the joints 7, 8 and are connected therein by pressure. The hydraulic prop 3 is mounted under the lift 2.

The reinforcement further comprises wire reinforcing mats formed by parallel longitudinal bars 9 with which the parallel cross bars 10 are also welded to each other. A fine-mesh wire mesh 11 is welded to the grid formed by the bars 9, 19. As shown schematically in FIG. 2, the reinforcement bars or the reinforcement mats 21 thus formed are connected to the reinforcement profile by the binding wires 12. Thus, they cannot be displaced over the arch segments 4, 5.

The spacers 13, 14, 1S also belong to the reinforcement. Spacers 13 are provided on the ceiling. These are complemented by spacers 14 serving segments 5. Also, the props 6 formed by the spacers are secured by spacers 15. Since a variety of different spacings 13, 14, 15 are known, parts in the drawing part are shown only schematically.

The process according to the invention is described below.

First, the dotted and solid lines depicted, the joists 16, 17, 18, 19, 20 are formed at the front, for example in the entry area A of the corridor, a so-called joist. An erector, which is not shown in the figures, is generally used for this purpose. Lectures are known and do not need to be displayed or described. It allows to store the joists 16, 17, 18, 19, 20 in the prescribed and perceptible mutual spacing after the joists 16, 17, 18, 19, 20 have been assembled from the joists 4, 5 by adjusting the joints. 7. After this assembly, the reinforcement mats 21 are fastened to the joists 16, 17, 18, 19, 20 with binding wires 12. For this reason, the reinforcement mats 21 cannot slip after the curvature of the ceiling segments 4, 5. 18, 19, 20 fix the spacers 13, 14. This makes the joist shield stable in both the longitudinal and transverse directions.

With the erector not shown, the joist shield is advanced after it has been made from the lead-in area A of the corridor to the first lead-in area Ai after the largest part of the blasted material has been removed there. It is then raised to the dashed-out position in the first inlet region Αι. In this position, the joists of the joist plate are formed with the foremost hitherto completed reinforcement 24. In this case, the spacers 25 and 22, respectively, corresponding to spacers 13 and 14, as well as the reinforcement mats 23 corresponding to the reinforcement mats 21 are connected. This work raises the joist shield to sit on the ceiling. The ceilings, as well as the joints of the blasted rock, have stepped shoulders forming transitions between the individual sub-lengths 28, 29 and the rock 30. These sub-lengths 28, 29 are forcibly created in the opening drilling method described above. As described above, only when the roof gable is lifted. The ceiling plates 18 and 20, respectively, rest on the rock 30 with a slight overhang. only the ceiling plate 20 of the rear part of the reinforcement in the first leading zone Ai to the rock 30 of the ceiling.

In this position, the ceiling shield is maintained by the erector. This protects the working crew at the front, which in particular · cleans up the rest of the blast and releases the supports for the deployment of the hydraulic prop 3 or the segment 6 formed by the prop. . First, the pedestal segment 6 is fitted below the respective end of the individual joists 16, 17, 10, 19, 20. This work is conventional and therefore does not need to be described in detail.

After the support 6 has been mounted, the undercarriage 2 is inserted under the opposite ends of the joists 16, 17, 18, 19, 20 using the hydraulic support 3. Now, with the extension of the hydraulic support 3, each reinforcement is adapted · So,. This ensures that the position of the reinforcement, which is shown in the lead-in areas Az and As, respectively, is ensured. As a result, each reinforcement has a cross section that is as closely as possible adapted to the cross-section of the respective partial length 28, 29. It also achieves that the reinforcement mats 21 abut directly on the rock 30 and on the transition sections between the individual leading regions Ai, Аг , As. Thus, no gap filling is required.

In the manner described in connection with the description of Figs. 1 and 2, the corresponding reinforcement associated with the length of the face is perfectly matched by using lengthwise adjustable hydraulic props 3 'and of several ceiling segments 4, 5, 6 formed by bends in each joist 16, 17, 18, 19, 20, resulting in a desired deformation of the entire reinforcement arc when extending and prestressing.

The reinforcing mats 21 are fixedly attached to the ceiling joists 16, 17, 18, 19, 20 on the joist plates by said tie wires 12. These reinforcing mats 21 are assigned to the individual joists. The joists 16, 20 arranged at the ends of the joist panel are tied individually to the reinforcing profile. Between the joists 16, 17, 18, 19, 20, on the other hand, are the ends of the reinforcing mats facing each other. 40, 41, 42, · 43 in the first start-up area Ai · bound together and. with the corresponding joists 17, 18, 19.

Claims (6)

OBJECT OF THE INVENTION 1. · Method of construction of mine reinforcement · in corridors · mine or tunnel tunnels driven by blasting operations, in which a larger number of reinforcements with joist segments is gradually deposited first and then further segments and · uprights or segments or stiffs using spacers and reinforcing mats, characterized in that, from the reinforcing mats with wire mesh with mesh fastening of the reinforcing mats and the respective spacers, at least first of all the joist segments of the reinforcement of one of the leading regions is a joist which is transported to the first haunch. area, where it is raised · and then · connections are created. reinforcement mats and spacers to the last joist panel of the finished reinforcement, whereupon the individual engineers · are lifted up to · the contact with the rock and the cross-section of each reinforcement is adapted to the partial length of the reinforcement before or abutting at several points in its perimeter of rock. 2. Method according to claim 1, characterized in that the joining of the reinforcement segments and / or spacers provided in the joists is only temporarily fastened when the joist is formed and only tightened after the joists have been raised to the rock. 3. The method according to claims 1 and 2, characterized in that by utilizing the length adjustable leg and the multiple segments of the composite arc in each reinforcement, the arc is deformed by extending and clamping the upright, thereby adapting the reinforcement to the associated lead-in area. 4. A method according to claims 1 and 2, characterized in that the reinforcement is adapted to the associated partial length of the first leading region by different overlapping of its segments. 5. The method according to claims 1 to 4, characterized in that at least further segments and uprights, or segments or uprights, respectively, are attached to the ceiling segments when forming the joist and that when folding the reinforcement, the tilting segments are lowered. · Fixed in shape · abutment on the rock; 6. A method according to any one of claims 1 to 5, characterized in that the reinforcing mats are tied to the joists and thus fastened to the joist segments, the reinforcing mats associated with the joists being tied to the joists individually and between the ends the joist with the ends of the connected reinforcement mats and joists together. 2 sheets of drawings