SE508833C2 - Method for extracting a vertical rock compartment with an elliptical or oval cross section and a rock compartment made by the method - Google Patents

Abstract

The present invention refers to a method for excavating a vertical rock cavern having an elliptical or oval cross section, whereby access from ground level to the cavern takes place via a ramp or through a vertical shaft, and that the cavern is intended for the storage of bulk products, e.g. gas and/or fluids. Vertical rock caverns combine a good environment for storage with favourable rock stability in the surrounding rock, which is a pre-requisite for being able to construct caverns with large spans. However, the work of excavating a vertical rock cavern has not been carried through in a sufficiently efficient manner as the work has, among other things, taken place on far too many levels. The procedure according to the invention is distinguished in that a roof section (2) and a bottom section (3) are developed on at least two levels, and that the volume existing between them is bench drilled, blasted and removed.

Description

15 20 25 30 35 508 833; number of work cycles and a concentration of the work to preferably only the roof space's roof resp. bottom part. With the features according to the invention, the advantage is achieved that unloading can be carried out simultaneously on two levels in the bottom of the rock chambers, which enables the significant rock volume obtained from the pallet mining to be unloaded very quickly from the occupied rock chamber. At the bottom of the rock chamber, a unique collection point is obtained which provides the space for collecting any particles that precipitate from the medium stored in the rock chamber. The vertical shafts between the upper and lower load level in the rock space bottom portion here have a funnel-shaped design, whereby precipitated particles from the stored medium are led further down to the permanent bottom level. In order to facilitate drainage and to enable cleaning of the bottom part of the rock space, it is conceivable to coat certain wall sections with concrete and arrange a flushing system in the bottom tunnels of the rock room.

During rinsing, sludge and waste are suitably transported to a collection point arranged for the purpose.

The method according to the invention utilizes the most modern technology in underground mining, especially with regard to drilling and blasting, and combines this with well-thought-out floor plans. Regarding the roof section, this means a simple preparation, a rational drilling and blasting of the large underlying room volume.

It also allows permanent monitoring of the roof stability and enables efficient ventilation during both the construction and operation phases. In the bottom part, this means a branched arrangement of sites in at least two levels that combine an efficient unloading of the rock during the construction phase with a protected access and plan visible floor plans for installation, inspection and service during the operational phase.

Rock rooms with an elliptical or oval cross-section offer, in comparison with rock rooms with a circular cross-section, a significantly larger storage volume at the same room width, which is of great importance when storing bulk products.

The object of the present invention is realized by means of a method and a rock chamber which have obtained the features stated in the appended claims. Preferred parts resp. designs are defined in the dependent claims.

In the drawings: Fig. Shows a vertical longitudinal section in the center of the room through the roof portion and bottom portion of the rock space according to the present invention; Fig. 2 is a horizontal section through the roof portion of the rock chamber according to the invention; Fig. 3 is a vertical transverse section in the center of the room through the roof portion and the bottom portion of the rock space according to the invention; Fig. 4 is a vertical longitudinal section through the center of a room of a roof portion of the rock chamber according to the invention when the preparation work is completed; Fig. 5 is a horizontal section through the roof portion according to Fig. 4, wherein vertical transverse partial sections of said roof portion are also shown in Fig. 5; \\ SKEA \ SYS \ USERS \ LEG \ dok \ arkiv \ P33461SEDOC 10 15 20 25 30 35 Fig 6 Fig 7 Fig 8 Fig 9 Fig 10 Fig 11 Fig 12 Fig 13 Fig 14 Fig 15 Fig 16 Fig 16 Fig 18 Fig 19 Fig 19 Fig Fig. 21 Fig. 22 Fig. 23 Fig. 24 Fig. 25 Fgw Fg fi 508 833 a vertical section through the roof portion showing drilling of roof pillars; a horizontal section through the roof portion according to Fig. 6; a vertical longitudinal section in the center of the pipe through the bottom part of the rock chamber with two load levels and temporary ridge; a horizontal section through both load levels according to Fig. 8; a vertical transverse section through the center of the rock space according to Fig. 8; a vertical longitudinal section in the center of the room through the rock space with pallet drilling of vertical long holes; a vertical transverse section in the center of the room through the rock chamber with pallet drilling of vertical longitudinal holes; a vertical longitudinal section in the center of the room through the rock chamber with marked blasting sequences; a horizontal section through the rock space according to Fig. 13 with numbered blasting sequences; In a vertical transverse section in the center of the room through the rock chamber with marked blasting sequences; a vertical longitudinal section in the center of the room through the rock space schematically showing drilling of the temporary ridge; a vertical transverse section in the center of the room through the rock space schematically showing drilling of the temporary ridge; a vertical longitudinal section in the center of the room through the rock chamber at the end of rock work; a horizontal section through the roof portion of the rock chamber at the end of rock work; a horizontal section through the bottom part of the rock chamber at the end of rock work; a vertical transverse section in the center of the pipe through the rock chamber at the end of rock work; a vertical longitudinal section in the center of the room through the roof portion of the rock chamber with bolt reinforcement schematically shown; a horizontal section through the roof portion of the rock chamber and schematically showing bolt reinforcement in a number of partial sections through the roof portion; a vertical transverse section in the center of the room through the roof portion schematically showing bolt reinforcement; a vertical longitudinal section in the center of the room through the roof portion of the rock chamber with ventilation holes between the rock chamber and the fl functional locations; a horizontal section through the roof portion of the rock chamber and schematically showing the ventilation holes in a number of partial sections through the roof portion; a vertical transverse section in the center of the room through the roof portion schematically showing the ventilation holes; \\ SKEA \ SYS \ USERS \ LEG \ dok \ arkiv \ P3346lSEDOC 10 15 20 25 30 35 '508 833 "% Pig 28- Pig 31 different sections through the rock space according to the invention when a hydraulic cage is arranged around the rock body.

In Pig 1-3 according to the Selection Procedure, work begins on the preparation of at least one but in this case two fl functional locations 1, roof portion 2 and a bottom portion 3 in the order now mentioned. The multi-function locations 1 constitute a platform for cable bolting of the roof portion 2 and house ventilation equipment. An overview of the rock chamber invention is shown. during the construction phase. In the operational phase, they are used for inspection of the stability of the roof section 2 and for evacuation / supply of air when the rock chamber is filled / emptied.

The roof section 2 is the workplace for pallet breaking, which is the largest operation in terms of volume. From there, the vertical long-hole drilling takes place down to the bottom part 3, the loading of the boreholes and the blasting of the pallet rock.

The bottom part 3 is used for the unloading of the blasted rock during the construction phase and for pumping / pumping out the products to be stored in the operational phase, as well as for collecting sedimentary deposits from the products.

Access to the rock chamber from the ground surface is achieved through a ramp or through a vertical shaft. The choice between these is primarily determined by the depth of installation of the rock chamber. Nonetheless, a ramp is the most advantageous alternative from a time and cost point of view at relatively close installation depths (down to about 300 m), while the shaft alternative is preferable at installation depths below. The choice between these alternatives determines the mode of transport of the rock masses up to the ground surface. As a result of the selection procedure according to the invention, access to the rock chamber is needed only in two places; the roof section 2 and the bottom section 3, respectively. The two areas are the main workplaces.

The roof section 2 is reached from the ramp / shaft via two horizontal locations 4, see Pig 1 and 2, which connect to the short sides of the rock chamber at the height of the roof level 2's initial level.

The roof section 2 is also connected to the multifunction locations 1 above the roof section 2, whereby, as pointed out above, the fl functional locations 1 are used, among other things, for roof reinforcement, ventilation and stability monitoring.

All unloading takes place from the bottom part 3 of the rock chamber, in two levels Sa and 3b. The upper level 3b exists only during the construction phase. It therefore has a temporary design with a substantially wedge-shaped ridge 5, see Pig 1 and 3, centrally in the longitudinal direction of the rock chamber. The ridge 5 extends from one short side of the rock space to the other short side. The ridge 5 is surrounded by the cargo trench 6, see Pig 3, which runs along the long sides of the rock chamber.

Both levels 3a and 3b have loading bays 7a resp. 7b and communication locations 8a resp. 8b. The loading sites 7a of the lower level 3a are displaced in the longitudinal direction of the rock space in relation to the loading sites 7b of the upper level 3b. The communication locations 8a and 8b run \\ SKEA \ SYS \ USERS \ LEG \ doc \ archive \ P3346lSEDOC 10 15 20 25 30 35 508 833 centrally in the longitudinal direction of the rock space and branch off into the loading locations 7a resp. 7b, which open into the loading ditches 6 and form loading hatches there.

The temporary ridge 5 has two functions. First, it directs the fate towards the room periphery where the load windows are located. Secondly, it provides protection for personnel and machines during unloading of the explosives. When the unloading is complete, the temporary ridge 5 is blasted away in stages. This will be described in more detail below.

With reference to Figs 4-5, the preparation of the roof portion 2 will now be described.

From each short side of the rock chamber, two peripheral species 9 are driven up to the short central axis of the rock chamber, where the corresponding periphery from the other short side meets. The roof formwork of the 9 peripherals is adapted to the arch of the start. Furthermore, a roof card 10 is driven from the respective short side, which follows the arch of the roof arch along the long central axis of the rock space. Since the locations are operated simultaneously from both short sides, a total of six (4 + 2) drive fronts are obtained.

When all locations have met their counterpart at the rock chamber's short central axis, slots 11 burst perpendicularly from the central roof card 10 to the respective peripheral center 9. The slots 11 follow the short central axis. Now the roof portion 2 is exposed along the wall periphery of the rock chamber and along the long center line of the roof arch and four elongated roof pillars 12 support the roof portion 2, which is not yet a finished roof construction. These roof columns 12 must then be blasted away in stages until the entire roof section 2, by means of roof reinforcement, is self-supporting by the action of the arch.

The roof columns 12 are drilled up from the slots 11 and from the short sides of the rock space in a continuous working operation with substantially horizontal long boreholes 13, see Figs. 6 and 7.

The roof pillars 12 are then sprinkled in suitable ointments against the peripheries 9 and against the roof boards 10, respectively, and unloaded from these locations. When the roof pillars 12 are gone, the remaining rock heel 14 can possibly be lowered and leveled to facilitate pallet drilling, which can then start.

With special reference to Figs. 8-10, the preparation of the bottom portion 3 will now be described. Said preparation begins in the same way as for the roof section 2. From both short sides of the rock chamber, communication locations 8a and 3b, respectively, are operated at both levels. 8b along the long central axis of the rock space to the center of the room inside the future temporary ridge 5.

From the respective communication locations 8a and 8b, loading locations 7a and 7b are then driven on both sides to the theoretical wall line of the room. At the upper load level 3b, the front gables of the loading bays 7b are connected so as to have a continuous loading ditch 6 along the long wall sides of the rock space on either side of the temporary ridge 5. From the loading ditch 6, vertical openings 14 are finally blasted down to the loading bays 7a of the lower loading level 3a. Thus, the bottom part 3 is finished.

The predominant part of the rock space volume is pallet drilled with vertical long holes 15 from the roof portion 2 and down to the upper load level 3b of the bottom portion 3 to the temporary ridge 5 and to the tunnel roof trench 6, see Fig. 11-12. The drilling work is performed in a continuous operation. It neither affects nor is affected by other activities.

\\ SKEA \ SYS \ USERS \ LEG \ dok \ arkiv \ P3346lSEDOC 10 15 20 25 30 'ß 508 835 L 6 Since the entire rock chamber volume between the roof section 2 and the bottom section 3 is pallet drilled with long holes, the choice of drilling equipment is of great importance. Drilling technology has significantly improved in recent years. For the current pallet drilling, water-powered ITH (In-The-Hole) machines are preferably used. In comparison with air-powered ITH machines, a 2.5 to 3 times higher drilling subsidence and a smaller hole deviation are achieved. In comparison with water-powered top hammer machines, considerably lower drill rod costs are achieved, higher drilling power and a significantly smaller reduction of the power with increasing holding length.

The room geometry and drilling plan make it possible to blow up large volleys. New initiation technology also makes it possible to carry out the blasting in a gentle way and with a good fall. Figs. 13-15 schematically show the blasting sequence of the pallet. As can be seen in particular from Fig. 14, the blasting work begins with two so-called opening shafts 16 being taken up on either side of the temporary ridge 14 not yet formed. The opening shafts 16 widen in stages towards the middle of the room until they are joined in a continuous slot.

The pallet blasting then continues across the entire width of the room, with the pallet fronts retreating towards the respective rock chamber end. Fig. 14 shows an example of burst frequencies 1a, 1b; 2a, 2b; 3a, 3b; 4a, 4b; 5a, 5b.

The ointment size can be adapted to prevailing rock conditions. Electronic so-called micro-detonators with programmable interval times enable precision detonation of large ointments. Documented advantages are better time precision, better fragmentation, less ground vibrations and smoother rock contours.

The unloading of the blasted rock takes place in principle as in a disc landslide mine. It takes place in two levels with preferably electric LHD machines (Load-Haul-Dump) according to the load-and-carry principle. The compact room orientation eliminates the need for trucks.

During pallet blasting, when high capacity is required, both load levels 3a and 3b are used, which gives very large time savings. The arrangement allows a very high unloading capacity due to the many loading sites 7a, 7b, see for example Fig. 13. Work safety is good because all personnel work in protection inside the temporary ridge 5.

After the pallet blasting according to Figs. 13-15 has been completed and the blasted rock unloaded, drilling of the temporary ridge 5 takes place. Said drilling takes place from the upper communication location 8b, the borehole configuration 17 for the temporary ridge 5 being schematically shown in Figs. 16-17. The unloading of the blasted ridge 5 takes place partly with the loading and carrying principle from level 3b and partly by the blasting masses being guided down to the loading sites 7a for the lower load level 3a, from where the blasting masses are unloaded.

The actual rock work with the rock space according to the present invention is thus completed and in Figs. 18-21 different sections of the vertical elliptical rock space are shown at the completion of rock work.

\\ SKEA \ SYS \ USERS \ LEG \ dok \ arkiv \ P33461SE.DOC 10 15 20 25 30 'ß; 508 855 According to the exemplary embodiment, above the roof portion 2 of the rock chamber there are two fl functional locations 1, which are used for fl your purposes. During the construction phase, the functional areas are used to stabilize the roof section 2 with cable bolts and as an exhaust air outlet for ventilation. During the operating phase, it is used for monitoring the roof stability and for evacuating / supplying air during the filling / emptying of the rock chamber.

Figs. 22-24 show an example of bolt reinforcement of the roof portion 2 and the start.

Systematic or selective roof reinforcement with, for example, cable bolts 18 is carried out from the functional locations 1. Especially at large spans, ie over 50 m, systematic roof reinforcement may be necessary. Because the functional locations 1 are separated from each other along most of the length of the rock chamber, the cable bolts 18 can be distributed over a larger roof surface than would otherwise be possible. The cable bolts 18 are fitted before the roof portion 2 is exposed.

After the exposure is done, any injection of the bolt holes can be performed. It is important that the cable reinforcement is made before the exposure of the roof section 2 begins. This achieves the best effect on roof stabilization. A ventilation arrangement for the rock chamber according to the invention is shown schematically in Figs. 25-27. Flue gases and other air pollutants are ventilated with suction fl spouts (not shown) placed in boreholes 19 between the roof section 2 and fl operating locations 1. From fl operating locations 1, the exhaust air goes in a closed pipe system up to the ground surface where cleaning takes place. Alternatively, an air purification plant can be placed adjacent to the fl functional locations 1, whereby purification takes place there.

The ventilation / drill hole 19 is drilled from the fl functional locations 1 and angled to the sides so that ventilation can take place both during the preparation of the roof section 2 and the subsequent pallet blasting. The diameter of the boreholes 19 is determined by the space requirements of the kt hubs and the required air circulation.

If the rock chamber according to the invention is to be used in applications that require cladding, the roof portion 2 and the wall sides of the rock chamber must be drained to avoid that the water pressure in the rock cracks builds up. Fig. 28-31 shows an arrangement with a curtain 20 of boreholes from the functional locations 1 down to locations 21 at the initial level of the rock space and further down to corresponding locations 22 at the height of the bottom portion 3. The drill curtain 20 surrounds the rock space about ten meters outside the same. By this arrangement a hydraulic cage is obtained which resets the groundwater pressure in the rock between the rock space and the borehole curtain 20.

When the rock chamber is filled or emptied, the air that remains needs to be evacuated or returned. This applies regardless of whether the rock chamber is unclad or clad. For this purpose, the already existing drilled ventilation holes 18 can be used to advantage.

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Claims (10)

10 15 20 25 30 35 508 833 «PATENT REQUIREMENTS A method for extracting a substantially vertical rock chamber with an elliptical or oval cross-section, wherein access from the ground surface to the rock chamber takes place via a ramp or through a substantially vertical shaft, and that the rock chamber is intended to store bull products, for example gas and / or fl uidum, k characterized in that at least one so-called fl function (1) is operated, that a roof portion (2), which is located below the orten function (1), is prepared by operating peripherals (9) defining the rock space partly laterally and laterally, that at least one roof card (10) located between the peripheries is defined which defines the curvature of the roof between the periphery centers (9), wherein said column pillars (12) formed by said drive are removed by drilling / blasting, 8b), on at least two levels (3a, 3b), along the long central axis of the rock space, that from said communication locations (Sa, 8b) load locations (7a, 7b) are operated, at at least instone said two levels (3a, 3b), up to the theoretical wall line of the rock chamber, that the rock chamber volume between the roof portion (2) and the bottom portion (3) is pallet drilled, blasted and unloaded via at least the lower level (3a) of the bottom portion (3). _ Method according to claim 1, characterized in that the drilling of the roof columns (12) takes place by means of substantially horizontal boreholes (13). Method according to claim 1 or 2, characterized in that the outer ends of the loading places (7b), at the upper load level (3b), are connected so that a continuous loading ditch (6) is obtained along the long wall sides of the rock chamber, and that from the loading ditch (6 ) vertical openings (14) are blasted down to the loading sites (7a) of the lower load level (3a). Method according to one of Claims 1 to 3, characterized in that during pallet drilling and blasting of the rock chamber volume between the roof portion (2) and the bottom portion (3), a temporary rock ridge (5) is left which extends along the long axis of the rock chamber. Method according to one of Claims 1 to 4, characterized in that two functional locations (1) are operated above the roof portion (2), which are joined to one another in the area vertically above the short sides of the rock chamber. Method according to claim 5, characterized in that reinforcement of the roof portion (2) takes place from the fl functional locations (1). Method according to claim 6, characterized in that the reinforcement is carried out in the form of systematic or selective reinforcement by means of cable bolts. Method according to claim 5, characterized in that ventilation holes (19) are drilled from the fl functional locations (1) to the roof portion (2). Vertical rock chamber with an elliptical or oval cross-section, the rock chamber comprising a roof portion (2), a bottom portion (3) and an intermediate storage space for bulk products, for example gas and / or fluid, characterized in that at least one ort site of operation ( l) is arranged above the roof portion (2), and that the bottom \\ SKEA \ SYS \ USERS \ LEG \ doc \ archive \ P3346lSEDOC? The portion (3) comprises a grain communication location (8a, 8b) extending along the long axis of the rock space, from which loading locations (7a, 7b) emanate radially. Rock chamber according to claim 9, characterized in that the roof reinforcement (18) and ventilation holes (19) are arranged between the functional location (1) and the roof structure (2). \\ SKEA \ SYS \ USERS \ LEG \ doc \ archive \ P3346ISEDOC