EP0170199A2 - Method of constructing a tubular subterranean hollow space - Google Patents

Abstract

1. A method of constructing a shaft protected by ground stabilisation, with a lining (12) taking up the ground pressure and a sliding layer (15) disposed between the lining and the ground (3), characterised in that the lining (12) and the sliding layer (15) are constructed in the course of advancing the depth, wherein the material forming the sliding layer (15) is introduced in a pasty state and, after it has been introduced, it is transformed into a solid state of aggregation which is maintaining during the construction period for producing the lining (12) and after completion of the shaft is reconverted to the pasty condition.

Description

The invention relates to a method for producing a shaft with a lining which absorbs the rock pressure and a sliding layer arranged between it and the rock, in the protection of a soil consolidation.

_A shaft structures of this rt be similar to horizontally extending tunnels claimed one hand, by the forces due to external loads and the other, by constraining forces as a result of movements in the surrounding soil. While the external loads are an unchangeable requirement, the stresses from constraining forces due to movements can be influenced by the type of construction.

Coercive forces are caused either in the building itself or in the surrounding mountains. Coercive forces from the building arise, for example, when the concrete of the cladding shrinks or as a result of temperature differences. Forced loads from the mountains follow, for example, from subsidence. In the mining sector, the constraints on the structures due to ground movements are particularly high.

As a rule, coal seams are mined without displacing the resulting cavity, so that in the area of mining and the surrounding area, the entire landscape and buildings are gradually lowered. The layers near the surface are influenced in a wave-like manner, corresponding to the progress of the individual mining fronts in depth. This manifests itself in the form of progressive individual depression troughs with different local depressions and horizontal pressures or strains as a result of the trough formation. In the course of time, a large number of individual waves with subsidence and strong horizontal stresses of alternating signs cover every point in the subsurface.

Shafts, such as those required in coal mining for the development of coal seams down to depths of 1,000 m and more, are usually sunk in the loose rock overlying the rock in the protection of soil consolidation by icing.

Two main construction principles are known for producing the lining of a shaft. According to one principle, a lining made of reinforced concrete is positively interlocked with the floor. In order to protect the shaft from being destroyed by the influences mentioned, such a shaft may only be dismantled at a greater distance, so that the influences described do not take effect in the region of the shaft. This means that more or less large quantities of mineral resources that are stored in these areas are not mined. This type of shaft expansion is relatively cheap to implement; however, it is uneconomical due to the fact that mineral resources are not mined in the area surrounding the shaft and because of the longer horizontal production routes required as a result.

In order to avoid these disadvantages, the principle of the so-called "sliding expansion" was developed, in which a sliding layer of bitumen is arranged between the lining and the mountains. This sliding layer mitigates the influence of the ground movements on the building in such a way that there are no unsolvable problems with its stability. This sliding expansion has the disadvantage that it is relatively expensive.

The sliding shaft expansion also takes place under the protection of a ground freeze, whereby in the course of the depths, dry masonry is first installed as an auxiliary construction to temporarily secure the mountains. The foundation for the actual lining is then laid in the deepest area of the shaft, which is then continuously listed from bottom to top as a sandwich construction with an outer, sealing steel jacket and an inner reinforced concrete shaft. The annular space between the auxiliary lining and the lining is filled with bitumen. Compared to the first construction principle, this construction method additionally requires the dry masonry as a safety extension and requires a considerably longer construction time, since the lining can only be carried out from the bottom up after the sinking and the construction of the auxiliary construction. The extension of the construction period leads to a further increase in the price, since the freezing units required to maintain the freezing of the ground must be operated during the entire construction period.

The invention has for its object to show a safer and more economical way to manufacture shaft linings according to the principle of sliding expansion.

According to the invention, this object is achieved in that the outer lining and the sliding layer are produced in the course of the progress of the depths, the material forming the sliding layer being introduced in a pasty state, after the introduction being converted into a solid physical state which is maintained during the construction period for the production of the lining and after the completion of the shaft is returned to the pasty state.

The basic idea of the invention is thus to bring about a change in the physical state of the material of the sliding layer of a sliding expansion from pasty to solid during the construction state of a shear-resistant connection between the lining of the shaft and the mountains. This makes it possible to fix the finished part of the lining to the mountain so that the lining can be made from top to bottom in the course of the depth.

A prerequisite for the build-up of a hydrostatic pressure state is that a material is used for the sliding layer which has cohesion, but has no or only a very small angle of internal friction. Such materials behave like a solid up to a certain limit, but above this limit like a plastic body. In contrast, bitumen, for example, behaves like a plastic body without cohesion over the entire stress range. These properties are necessary for the construction state so that on the one hand the material does not run out of the annular space between the rock and the lining, which is open at the bottom, and on the other hand forces can be transferred from the lining to the rock. The cohesion can be changed by changing the physical state of the material of the sliding layer due to the effects of cold, for example by increasing the temperature until there is sufficient strength and a reliable bond to the mountains.

A material with these properties is, for example, a mixture of a clay mineral, such as bentonite and water; If necessary, inert fillers can also be added to the mixture, e.g. Rock powder, mainly quartz powder, limestone powder or the like. The mixing ratio of the components is chosen so that the paste-like mixture is held in the space between the lining and the mountain, which is open at the bottom, by the cohesion inherent in the mixture. Such a mixture consolidates under external pressure, a certain water content being established as a function of this pressure. The consolidation process is also associated with a reduction in volume. If the mixture is installed with the water content that corresponds to the later pressure state, it is constant in volume. However, if the water content is greater, the volume of the mixture decreases. This property also enables a division of the earth pressure loads between a fuse removal and the actual lining. At the same time, the lining is coupled to the fuse removal, since if the deformations of the fuse removal increase disproportionately, additional pressure forces are transferred to the lining via the intermediate layer.

If there is no safety expansion, a shift of the earth pressure from the lining to the floor can be achieved by specifying an amount for the consolidation deformation. This amount is a function of the water content, the layer thickness, the filler content and the effective consolidation stress. This in turn corresponds to the earth pressure that followed Load redistribution exists.

The water content of the mixture and / or the thickness of the layer are therefore expediently chosen so that the shifts corresponding to a predetermined partial relaxation of the rock can occur due to consolidation deformations of the layer.

Since the sinking of a shaft in loose rock usually takes place in the protection of a ground freeze, the use of a mixture with water as a solvent as the material for the sliding layer has the advantage that, with the same devices that are required to maintain the freezing body, the material of the sliding layer also Freezing can be brought. It ensures a firm connection between the interior and the mountains during the construction phase, during which the freezer must be maintained. After the freezing units have been switched off after the shaft has been completed and the floor has subsequently thawed, this firm connection changes back to the desired effect of a sliding expansion.

Icing of the material of the sliding layer can be left to the action of the outer freezing body. - But it can also be accelerated by carrying additional freezing units on the inside of the part of the lining that has already been produced, which act through the concrete of the lining on the underlying sliding layer or, what accelerates icing the most, can in the sliding layer even freeze pipes for a coolant circuit are carried, which are charged with the progress of the expansion with coolant.

The lining can be made of reinforced concrete; it can then be produced continuously by means of sliding formwork carried by a working platform or in sections by means of climbing formwork. The lining can also be biased in the axial direction. The longitudinal prestress should then be selected in such a way that both the compression compression of the concrete and the tensile elongation of the steel are used.

It is also possible to arrange a tight jacket made of metallic material, preferably steel, on the outside and / or inside of the lining. Finally, the lining can also consist of a steel jacket.

The process according to the invention can be used both without, as described above, and with auxiliary expansion. If an auxiliary removal is required for safety reasons, it precedes the production of the actual lining.

• Fig. 1 einen Vertikalschnitt durch einen Schacht im Zuge der Herstellung und
• Fig. 2 einen der Fig. 1 entsprechenden Vertikalschnitt durch einen Schacht mit Hilfsausbau.

The invention is explained below with reference to the drawing. It shows

• Fig. 1 shows a vertical section through a shaft in the course of manufacture and
• Fig. 2 is a vertical section corresponding to Fig. 1 through a shaft with auxiliary expansion.

To manufacture a shaft 1 according to the invention, a freezer body 3 is first produced in the loose soil 2 in a manner known per se, in the protection of which the depth can then take place. The depth is started on the terrain surface 4 in that an upper ring 5 is made of reinforced concrete, which secures the shaft mouth 6 and specifies the shaft wall with a cylindrical extension 7.

The depth is carried out in a manner known per se by means of a gripper 8, first of all from the surface 4 of the terrain, then from a working platform 9, which is lowered into the shaft on a traction cable 10. On the work platform 9 there is an annular formwork 11 for the lining 12 of the shaft made of reinforced concrete. The formwork 11 encloses an annular section 12 'of the lining 12 on the inside, on the outside and on the lower end face. It can be designed in the manner of a sliding formwork that is continuously pulled along, or also in the manner of a climbing formwork that is implemented in sections. The formation of the formwork 11 is not the subject of the invention.

An annular space 14 remains between the outer surface of the lining 12 and the wall 13 of the rock 2, which is filled from top to bottom during the manufacture of the lining 12 with a material which, in the final state, has a sliding layer 15 between the rock 2 and the lining 12 forms. This material consists of a pasty mixture of a clay mineral or the like, e.g. Bentonite and water, which also contains fillers such as e.g. Rock powder, may be added. It is pressed into the intermediate space 14 from the upper end of the last section produced. It is distributed therein, but its cohesion and adhesion to the lining 12 and / or the wall 1.3 of the rock 2 prevent it from emerging from the space 14 which is open at the bottom.

The use of water as a solvent for the mixture creates the prerequisite for this in the course the manufacture of the lining 12 introduced material of the intermediate layer 15 can also be iced over the course of the depth. This is indicated in FIG. 1 by the fact that the formwork 11 is initially followed by an area 15a of freshly introduced material, which is located in the area 15b above it at the start of freezing. It is already frozen in the area 15c lying above it and thus forms a firm, load-bearing connection between the lining 12 and the icy mountains 3.

After reaching the depth and completion of the shaft bottom, the freezing units are switched off, so that when the freezing body 3 is thawed, the material of the sliding layer 15 also thaws and thus represents the desired sliding joint between the lining 12 and the rock 2. _-

In a representation similar to that in FIG. 1, FIG. 2 also indicates how an auxiliary extension 16 is carried ahead in the course of the depth and the manufacture of the lining 12. The auxiliary extension 16 is manufactured in a manner known per se so that after reaching a certain depth a widening 17 is generated in the shaft wall 13, which serves as the foundation for a section 16 'of the brick auxiliary extension 16. This section 16 'is then brought up until it reaches the bricking of the section 16 "above it.

The auxiliary lining 16 is then followed by the actual lining 12, the material forming the sliding layer 15 in turn being pressed into the space 18 between the auxiliary lining 16 and lining 12. Incidentally, the procedure for this shaft expansion is also the same as for the sliding shaft expansion described above.

Claims (14)

1. A method for producing a shaft with a lining absorbing the rock pressure and a sliding layer arranged between it and the mountain in the protection of soil consolidation, characterized in that the lining (12) and the sliding layer (15) are produced in the course of the progress of the depths , the material forming the sliding layer (15) being introduced in a pasty state, after being introduced into a solid state which is maintained during the construction period for the production of the lining (12) and after the completion of the shaft again in the pasty state is set back. 2. The method according to claim 1, characterized in that the physical state of the pasty material by exposure to cold, e.g. Freezing or thawing is changed. 3. The method according to claim 1 or 2, characterized in that the pasty material from a mixture of a clay mineral or the like, e.g. Bentonite and water. 4. The method in particular according to claim 3, characterized in that the water content of the mixture and / or the thickness of the layer are chosen so that the shifts corresponding to a predetermined partial relaxation of the mountains can occur due to consolidation deformations of the layer. 5. The method according to claim 4, characterized in that the mixture inert fillers, mainly rock flour, such as quartz flour, limestone flour or the like, can be added. 6. The method according to any one of claims 3 to 5, characterized in that the mixing ratio of the components is chosen so that the pasty mixture in the downwardly open space (14) between the lining (12) and the mountains (2) by the the mixture's own cohesion is maintained. 7. The method according to any one of claims 2 to 6, characterized in that for icing the material of the layer (15) in this with the progress of the expansion with coolant acted upon lines are carried. 8. The method according to any one of claims 1 to 7, characterized in that the lining (12) consists of reinforced concrete and is continuously manufactured by means of a sliding formwork carried by a working platform (9). 9. The method according to any one of claims 1 to 7, characterized in that the lining (12) consists of reinforced concrete and is produced in sections by means of a climbing formwork carried by a working platform (9). 1 ₀ . Method according to claim 8 or 9, characterized in that the lining (12) is prestressed in the axial direction. 11. The method according to claim 10, characterized in that the longitudinal prestress is selected such that both the pressure upsetting of the concrete and the tensile elongation of the steel are used. 12. The method according to any one of claims 8 to 11, characterized in that on the outside and / or inside of the lining (12), a tight jacket made of metallic material, preferably steel, is arranged. 13. The method according to any one of claims 1 to 7, characterized in that the lining (12) consists of a steel jacket. 14. The method according to any one of claims 1 to 13, characterized in that in the course of the manufacture of the lining (12) in a manner known per se, the auxiliary lining (16) leading the manufacture of the inner lining is carried along and that the layer (15) between the lining (12) and the auxiliary extension (16).

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