DE3844776C2 - Roof support for mining gallery - Google Patents

Abstract

The roof of a mine gallery is supported by arches made from corrugated sheet steel. Each arch (1) is constructed from a number of curved corrugated sheets (4) which are joined to each other by a joint in the form of a box made of corrugated sheet steel so that the joint has a deg. of resilience.A number of such arches are joined together side by side to extend along the length of the gallery. The edges of the sheets have flat flanges (4.1) by which adjoining arches are bolted together. When the arches are placed in position the gap between the arches and the gallery wall is filled with rapid hardening concrete

Description

The invention relates to a compliance and / or spacing element as a connecting element for frame parts, formwork elements and the like of expansions for underground mine lines and shafts, which from opposite side walls with connections for the Supporting and connecting the frame parts, formwork elements and the like is limited, wherein between the side walls in Expansion circumferential direction deformable means with predefinable deformation resistance are provided.

From DE-AS 14 83 898 a flexible route expansion is curved reinforced concrete segments known to their front End faces with resilient pads, which hinge points of expansion. These connection points are not closer explained. Accordingly, this design has changed since Not able to enforce registration in 1966.

Resilience elements are, however, in detail in DE-PS 32 10 530 shown. These are pipes that are perpendicular to the line joint are arranged and integrated in the concrete mortar. The connection of these compliance elements with the adjacent segments of the Removal takes place via pegs. In case of giving way, the pipes compressed while destroying the mortar embedding. These Mortar embedding has the disadvantage that initially a very considerable amount Licher deformation pressure must be built up before a Compliance. This deformation pressure must be sufficient to to destroy the mortar bed. Then there is a risk that the Deformation pressure built up is at the same time so great that the pipes suddenly collapse. There is also a risk that this will happen destroyed mortar bed no longer holds the pipes and the Compliant elements lose their function.  

DE-PS 32 10 529 goes even further than DE-PS 32 10 530 this patent specification is a flexible route expansion known Resilience and / or spacing elements as a connecting element for Frame parts, formwork elements and the like of extensions for shows underground pit lines and shafts. Beyond that this document can still be seen that the compliance or Spacer element from opposing plates Side walls is limited, between which deformable means with predetermined deformation resistance are provided, the compliant Form speed elements with connections for the frame parts. The well-known However, compliance and / or distance elements are not yet practical.

The invention is therefore based on the object To provide resilience and / or distance elements for the rough operation underground are particularly suitable.

According to the invention this is achieved in that the compliance elements arranged from side walls and between the side walls Deformation profiles exist, the deformation profiles in essentially an M or W-shaped cross-sectional shape  exhibit. In a structurally simple way is by an appropriate off the defined flexibility of the Supported frame parts of the inner formwork or the outer shell of the extension depending on the expected loads to reach. To expand a z. B. underground mine route such components in different training or shape, for. B. with several groups of deformation professionals arranged one above the other len, which is also in a substantially the radius of curvature the position appropriate to the expansion can be fixed to each other, ready are held so that, depending on the expected loads corresponding number of elements in the required places be provided in a structurally simple and easy to install manner can.

With regard to further essential configurations of the connection elements is based on the subclaims, the drawing and the following Description referred. The drawing shows:

Fig. 1 shows schematically in front view an embodiment of a closed configuration according to the invention with a schematic representation of individual resilience and distance elements, and

Fig. 2, 3 and 4 embodiments of compliance and distance elements according to the invention in perspective single position.

In the drawing, the pit section to be expanded is generally numbered 1 and the bottom of the section 2 . The mountains surrounding the route expansion are not illustrated in detail. The track extension 3 consists of an inner shell of lining frame parts 4 to be arranged successively in the extension longitudinal direction, made of corrugated steel sheets, the number of which can be varied in the route circumferential direction and also in the longitudinal direction. For lining up the lining frame parts 4 of the inner shell in the direction of route expansion, these each have angled edge approaches 4.1 , which overlap in pairs in the longitudinal direction and z. B. by means of screw connections to each other and thus to be releasably attached from the inside of the route.

The track extension 3 has an outer shell, not shown in detail, made of fast-curing building materials or the like backfill material, which can be brought behind the lining frame parts by means of known methods during track expansion, so that it connects the track extension 3 close to the mountains. In the illustrated embodiment of the Ausbaues the filled in the be of the corrugated profiling of the lining frame parts 4 and the mountains delimited spaces backfill material forming the outer shell so that each lining frame part 4 is associated with an outer shell segment circumferential direction in Ausbauum. The individual lining frame parts 4 have a curvature which is adapted to the radius of curvature of the pit section 1 to be removed and are variable in position in the circumferential direction of the expansion and are therefore also fixed to one another in a circumferential manner. The outer shell segments assigned to an individual lining frame parts 4 are also position-changeable within predeterminable limits and are therefore also supported against one another in a manner that is flexible in terms of their circumference. This position-changing support is achieved in the illustrated embodiment of the expansion by individual lining frame parts 4 supporting resilience elements 5.1 , 5.2 , 5.3 , which also form spacers for the outer shell segments until they rest on each other over the entire surface after consumption of the respective resilience path. In the example shown, the sealing of the individual segments of the outer shell is effected during the backfilling or curing process in order to achieve a free play stretch between the outer shell segments by inflatable cushions which are movably guided in the longitudinal direction of the cushion. It is also possible to take over the sealing function through a corresponding structural design (extension) of the resilience elements or spacers.

The spacers with resilience elements 5.1 , 5.2 , 5.3 are formed by shape-changeable squeeze bodies which, depending on the direction of attack of the expected rock loads or other operational requirements, can be arranged in any number, design, length and the like at any point in the route construction 3 . As a result of the defined flexibility thus created, the outer shell can continuously exert a high degree of resistance to expansion in the required direction, even if the mountain pressures or loosening processes occur in the mountains and the resulting convergence phenomena, without directly involving the corresponding rock loads on the inner shell the resulting plastic deformations. At the same time, the inner shell is able to yield both defined in size and direction by appropriate design of the resilience elements, so that overall the closed configuration according to the invention is capable of applying a high vault resistance over the entire area immediately after the introduction, which also in the event of increasing convergence after reaching a peak value, it does not drop to an unacceptable level, but remains to a high degree or even continues to develop in a defined manner. As a result, the inherent load-bearing capacity of the rock is always optimally activated in different states of convergence. The remaining and, as a rule, unavoidable final convergences are considerably lower in the closed configuration according to the invention in comparison with known configuration systems. Because of this behavior, it is possible to use new and significantly cheaper components or building material components for the expansion parts. It can also be expedient here to provide the outer shell segments with additional reinforcement, which, however, can also be formed by the plug bolts of the inner shell for clipping to the outer shell.

The lining frame parts 4 and the resilience elements 5.1 , 5.2 and 5.3 are extremely easy to use construction parts. For example, the expansion frame parts or resilience elements to be provided in the ridge area of the pit section expansion can also be provided as pre-assembled units with the aid of e.g. B. stages and manipulators are introduced, which results in further advantages in terms of assembly friendliness and safety. In more detail not illustrated, the spacers of the outer shell segments can also be formed by separate components independent of the resilience elements, e.g. B. by sealing elements such as inflatable pillows, the ent after hardening of the backfill material by deflating the air and z. B. implemented in a next backfill position. Hollow bodies made of wood, steel or plastic can also be used as spacers, which remain in their position or can be implemented for use in a subsequent backfilling process.

As illustrated in more detail in FIGS. 2 to 4, the resilience or spacer elements 5.1 , 5.2 and 5.3 each have opposite side wall regions 6 , between which deformation profiles 7 are provided in both the longitudinal and transverse directions of the respective element. The deformation profiles 7 of the illustrated exemplary embodiments have a substantially H-shaped or W-shaped cross-sectional shape, the cross-sectional shape, the material used and the like for the response behavior of the elements important parameters can vary. In the resilience element 5.1 ( FIG. 2) supporting the track extension 3 on the track base 2 , two spaced-apart deformation profiles 7 are provided one above the other, which are fastened to one another at this point in accordance with the radius of curvature of the expansion by means of essentially straight support beams 8 . By variation z. B. the length of the support beam can also be influenced on the compliance or claim behavior of the compliance element.

In the exemplary embodiment according to FIG. 3, the deformation profiles 7 arranged one above the other are fastened to one another via the support beams 8 in such a way that they assume a position corresponding to one another which corresponds to the radius of curvature of the extension 3 in the ridge area. In the embodiment example according to FIG. 3, a size of two longitudinal and transverse deformation profiles 7 are provided on each side of the support beams 8 , each of which can also have a different response behavior in order to meet the expected loads occurring at this point in the route expansion . To connect the lining frame parts 4 with the resilience elements or spacing elements 5.1 , 5.2 and 5.3 6 holding profiles 9 are provided on the side wall regions for fixing the lining frame parts 4 . This holding profiles 9 have a corrugated profile of the lining frame parts 4 adapted shape, so that the lining lining frame parts from the interior of the route can be placed on the holding profiles 9 and by means of a suitable connection, for. B. a screw connection 4.2 , to be fixed on this.

The resilience elements or spacers 5.2 , 5.3 have coupling body 11 on one side wall and on the opposite side wall with the corresponding coupling body 11 with central openings 13 of the element adjacent in the longitudinal direction of the element, which overlaps each end face coupling flanges 12 , into the anchors for connecting the individual Elements can be pushed through. The coupling body - / - flanges-anchor connections can be designed as heavy load carriers or be equipped with such in order to hold loads. To connect the individual elements, however, other suitable connecting parts such as screws and the like or other quick-connect connections can also be used.

Claims (9)

1. Resilience and / or spacing elements as a connecting element for frame parts, formwork elements and the like of extensions for underground mine routes and shafts, which is limited by opposite side walls with connections for supporting and connecting the frame parts, formwork elements and the like, with between the side walls in Expansion circumferential direction deformable means with a predeterminable deformation resistance are provided, characterized in that deformation profiles ( 7 ) are provided between the opposite side walls ( 6 ), which have an essentially M-shaped or W-shaped cross-sectional design. 2. Connecting element according to claim 1, characterized in that at least two spaced-apart deformation profiles ( 7 ) are provided. 3. Connecting element according to claim 2, characterized in that the deformation profiles ( 7 ) can be connected to one another via support beams ( 8 ). 4. Connecting element according to claim 3, characterized in that the deformation profiles ( 7 ) by the support bracket ( 8 ) in a the radius of curvature of the extension ( 1 ) are essentially fixed position. 5. Connecting element according to claim 3 or 4, characterized in that a group of deformation profiles ( 7 ) is provided on both sides of the support beam ( 8 ). 6. Connecting element according to one or more of claims 1 to 5, characterized in that the or individual deformation profiles ( 7 ) are designed for different load limits. 7. Connecting element according to one or more of claims 1 to 6, characterized in that holding profiles ( 9 ) for fixing lining frame parts ( 4 ) or similar components are provided on the outer sides ( 6 ). 8. Connecting element according to one or more of claims 1 to 7, characterized in that the side walls have coupling bodies ( 11 , 12 ) for connecting adjacent elements in the longitudinal direction of expansion. 9. Connecting element according to claim 8, characterized in that the coupling body ( 11 , 12 ) are designed as heavy load carriers.