SE410430B - FACILITY FOR STORAGE OF PETROLEUM PRODUCTS AND OTHER FLUIDA IN BERG - Google Patents

Abstract

The invention relates to a plant for storage of fluids, e.g. petroleum products, in rock, said plant comprising a plurality of cavities 10-14, 20-24, 30-34, 40 excavated in the rock. Each and any of said cavities has a generally cylindrical shape with a circular or oval cross- section, whereby each cavity forms a storage space, the walls of which being formed by the rock and directly absorbing the pressure of the fluid stored in the cavity. The cavities are arranged with their central axes standing vertically, and the vertical height of the cavity is greater than or equal to the diameter of its cross-section. The distance from each cavity to adjacent cavities is equal to or greater than the diameter of the cross-section of the cavity. In a horizontal cross- section of the whole system, the centres of the cross- sections of the cavities as seen are positioned in a two- dimensional pattern. <IMAGE>

Description

. Another object of the invention is to provide a plant in which the cavities are so arranged and constructed that the blasting of them is greatly facilitated and so that the costs of subsequent reinforcement is reduced.

According to the invention, the cavities are located at substantially the same depth, and each cavity has in horizontal section a substantially circular or above shape, and seen in a horizontal cross-section throughout the plant, the circular or oval horizontal sections of the cavities have their centers located in the corners of regular polygons, all of which have the same number of sides.

"Regular polygon" means a polygon in which all sides have the same length and all angles are equal. A regular polygon can always be inscribed in a circle, which passes through all the vertices, and whose midpoint thus also constitutes the center of the polygon.

In an embodiment of the invention, said polygons consist of pentagons of different sizes, which are arranged with a common center point. The cavities will thus be arranged in concentric circles. An additional cavity may be provided so that its center axis coincides with the center of these circles.

In another embodiment of the invention, said polygons consist of equilateral and equal triangles, which together form a net with triangular meshes.

Each cavity suitably has a height which is much larger than its diameter. This means that the bedrock in which the plant is located is utilized better in depth, which provides the opportunity for a more compact plant and thus better economy regarding the utilization of the land area and if the stored product is heated also better heat economy. This also makes it easier to design the facility with regard to prevailing local rock pressures. Although the cavities will always be facing with their largest cross-section against the horizontal main compressive stresses in the rock, which are normally greater than the vertical pressure, the circular horizontal section is advantageous for the pressure absorption. Because the cavities according to the invention will be arranged in a regular pattern, a good pressure distribution in the rock between the cavities is obtained.

Each cavity is provided at the top with a suitably conical roof. petrol and crude oil. Furthermore, the plant according to the invention enables a better and safer heating by making the pumping system with associated pipelines shorter and simpler.

For all types of stored products, better inflow to the pumps is obtained because the cavities have their greatest extent in the vertical direction. The plant results in better operating conditions when storing oil on a water bed, as it is easy to obtain larger vertical distances between the different control levels at the interface between oil and water. The separating surface between oil and water can be placed so that a considerable emulsion layer can be allowed and so that a large control height is obtained for the water pumps. The water pumps can be placed with sufficient depth to the bottom to have sufficient sludge space underneath. The bottom cavity is also suitably conically designed with the tip pointed downwards. In the lower part of the conical bottom, a circular pump shaft of concrete can be designed, which provides good inflow of oil and leaking water and means that the leaking water can be easily separated. The concrete shaft also protects pumps and instruments against falling stone. The funnel-shaped bottom also enables a simpler final emptying of the cavities. The conical shape of the bottom also results in a smaller total area of the interface between oil and water when storing oil on a water bed. This results in less area of the emulsion layer, thereby facilitating the separation between oil and water.

At the plant according to the invention, it is also possible to arrange water curtains between the cavities. A special advantage is that the water curtain holes can be drilled in parallel, which gives a better curtain and less drilling work than is the case if the water curtains are fan-shaped.

Because the cavities are designed with a cylindrical main part and a conical roof and conical bottom, the drilling and blasting work during the uptake of the cavities is facilitated and the reinforcement costs are reduced. The invention will be described in more detail below with reference to the accompanying drawings.

Fig. 1 shows in perspective a plant according to the invention.

Fig. 2 schematically shows the geometric configuration in which the cavities at the plant according to Fig. 1 are arranged.

Fig. 3 schematically shows the geometric configuration of the cavities in another embodiment.

Figs. 4-6 show different stages in the uptake of a cavity.

In Fig. 1, l denotes the bedrock, in which the plant is located 10 78 20 25 30 35 40 7892027-8. 14 is located at a certain depth below the ground surface 2. The embodiment shown in Fig. 1 comprises a total of sixteen cavities. How these cavities are arranged in relation to each other is clearest seen from Fig. 2, which schematically shows a horizontal section through the entire plant.

Five cavities 10-14 are arranged in an outer circle, so that their midpoints form the corners of a regular pentagon. This pentagon is indicated in Fig. 2 and the circumscribed circle 16. Further cavities 20-24 are arranged so that their center axes are located in a pentagon 25 with the circumscribed circle 26, the radius of which is slightly smaller than the radius of the circle 16. Further five cavities 30-34 are arranged with their center axes in the corners of an inner pentagon 35 with the circumscribed circle 36. Said circles and pentagons * have, a common center. Arranged around this center point is a further cavity 40. In the arrangement shown in Fig. 2, the cavities 20-24 are arranged such that their horizontal cross-section touches the circle 16, along which the cavities 10-14 are located. However, the radius of the circle 26 along which the cavities 20-24 are located may also be larger or smaller than that shown in Fig. 2. Thus, the cavities 20-24 may be located so that their central axes intersect the midpoints of their respective connecting lines between the cavities. 10-14.

The cavities 20-24 may alternatively be arranged along the same circle (16) as the cavities 10-14.

As can be seen from Fig. 1, a tunnel 3 extends from the ground surface down to the plant. The tunnel 3 branches off at a place 4, which is located at the height of the upper part of the cavities. From the place 4 a first tunnel branch 5gi extends in an inclined arc to a place 6, which is located at a level below all the cavities. A second tunnel branch 7 extends horizontally from the place 4 to the upper part of the cavity 12. The upper parts of the cavities are connected to each other by means of tunnels 8. From the lower end 6 of the tunnel branch 5 a system of tunnels 9 extends under the whole plant and this tunnel system 9 extends below each cavity. The mentioned tunnels serve as working tunnels during the blasting of the plant. From the tunnel system 9, vertical shafts 41 extend up to the bottom of each cavity. During the construction of the plant, these tunnels are first blasted, and the blasting of the cavities themselves begins both from above and from below, which will be described later in connection with Figs. 4-6.

The blasted rock mass is transported out through the tunnels. When the plant is completed, these tunnels can be used for laying pumps and pipelines. / 10 15 20 25 30 35 40 7802027-'8 5 Two tunnels 43 and 44 extend around the entire facility.

The tunnel 43 extends around the upper part of the plant and the tunnel 44 around the lower part of the plant. These tunnels are connected to each other by a plurality of vertical shafts or boreholes 45. The boreholes 45 extend not only between the tunnels 43 and 44 but also above the tunnel 43 and below the tunnel 44. The tunnels 43 and 44_as well as the boreholes 45 are filled with water_and form thus a water curtain around the entire facility. Depending on the porosity of the rock and the groundwater conditions, it may be desirable to extend the water-filled borehole curtain to the area between the facility and the ground surface and / or to the area below the facility.

The cavities are made with conical roofs and bottoms. From the top of the roof of each container, a vertical shaft 42 extends up to the ground surface. The shaft 42 can be used for laying pipelines, through which each cavity can be filled and emptied separately. Fig. 3 shows diagrammatically in horizontal section the geometric arrangement of the cavities in another embodiment of the invention.

The cavities in Fig. 3 are marked with circles, and the imaginary connecting lines between the centers of adjacent circles form equilateral triangles, e.g. the triangles 46 and 47 marked with dashed lines. These triangles thus form a regular network of triangular meshes.

The embodiment according to Fig. 3 can be designed such that its outer contour takes the form of a regular hexagon as shown by the broken line 48. However, the whole plant can also be designed in such a way that it is horizontally extended to a greater extent in one direction than in a however, perpendicular direction. This has been indicated in Fig. 3 by some cavities being drawn to the right outside the dashed hexagon 48. Such a device can be advantageous in the case that the stresses in the rock are greater in one direction than in the other. The plant should then have its greatest extent in the direction in which the rock stress is greatest. The embodiment illustrated in Fig. 3 can moreover be designed in a manner similar to the embodiment according to Fig. 1.

In Figs. 2 and 3, the horizontal section of the cavities has been shown circularly. However, within the scope of the invention, this horizontal section may also have an oval or elliptical shape. This is particularly suitable in the case that the horizontal compressive stress in the rock is much greater in one direction than in the other (towards one 'l 272027-8 10 15 20 zsf 30 35 40 6. O in the direction perpendicular) the direction. The oval or elliptical horizontal section of the cavities must then have its greatest extent in the direction in which the rock stress is greatest.

The blasting of the cavities can take place using methods known in rock blasting technology. Figures 4-6 show a suitable procedure for blasting out the cavities. It is assumed that the tunnel system described in connection with Fig. 1 is first blasted out of the rock. A tunnel 49 is driven towards the upper part of the future cavity as shown in Fig. 4. The tunnel 49 may be identical to the one shown in Fig. 1. tunnel branch 7. Between the ground surface and the future roof of the cavity, the vertical shaft 42 is driven. This shaft 42 is widened at the bottom and in this extension a drilling machine is placed, by means of which boreholes are drilled along the future conical roof of the cavity.

From the tunnel system 9 located below the plant, vertical shafts 41 are drilled upwards towards the future bottom of the cavity.

From an extension of this shaft 41, boreholes are drilled to blast out the conical bottom of the cavity as shown in Fig. 5.

A central vertical shaft 50 is further drilled through the future cavity. When the upper part of the cavity is blasted out, the blasted material is dropped down through this shaft and through the shaft 41 to the tunnel 9, where the material falls on a conveyor, which forwards the material of a suitable truck, as shown at the bottom of Fig. 6. When the roof and bottom of the cavity are blown out, the blasting of the cylindrical main part of the cavity begins. If the cavity is to have a very large height, it may then be suitable to drive another working tunnel 51 towards half the height of the cavity as shown in Fig. 6 and from this tunnel drill and blast the lower part of the cavity, while drilling and blasting is in progress from the upper half of the cavity All the cavities do not have to have the same height. If a cavity is to have its bottom located at a higher level than the bottom of a nearby cavity, a tunnel 52 can be driven from the bottom of the first-mentioned cavity obliquely downwards towards the bottom of the adjacent cavity.

Through this tunnel 52 the blasted material in the first-mentioned cavity can fall down to the bottom of the latter-mentioned cavity and further down through the shaft 41.

In the embodiments shown, the main part of the cavities has a cylindrical shape with vertical walls, i.e. the cylindrical part has the same horizontal cross section everywhere. If in this embodiment stones were to come loose from the walls of the cavity, they can when they fall downwards scrape against the walls and cause sparking, which in turn can cause an explosion if explosive gases are present in the cavity.

To avoid this risk, the cavities can be made so that their main part tapers upwards. As a result, any loosening stones will fall freely towards the bottom of the cavity, where they hit the water bed contained therein or the surface of the stored product. It is advisable to place the plant at such a great depth that it is in its entirety below the groundwater level. always possible or desirable. If the cavities partially extend above the groundwater level, the part of the facility which is located above the groundwater level may be surrounded by a relatively dense water-filled borehole curtain and / or a screen of material, e.g. clay which is impermeable or impermeable to the fluid to be stored in the plant.

The plant according to the invention is primarily intended for storage of petroleum products such as crude oil and refined oil products. However, the plant according to the invention can advantageously also be used for storage of other liquid products such as e.g. 20 water.

Claims (8)

A plant for storing petroleum products and other fluids in rock, which plant comprises a plurality of cavities occupied in the bedrock, which form only storage spaces limited by the bedrock for said products, so that the walls of the cavity formed by the rock directly absorb the pressure of the fluid stored in the cavity, characterized in that the cavities are located at substantially the same depth and in horizontal section have a substantially circular or oval shape, and that in a horizontal cross-section throughout the plant the circular or oval horizontal sections of the cavities have their midpoints located in the corners of regular polygons, all of which have the same number of sides. Plant according to claim 1, characterized in that said regular polygons are pentagons located inside each other with a common center. 3.; Plant according to claim 2, characterized in that an additional cavity is located so that its center coincides with the common center of said pentagon. Plant according to claim 2 or 3, characterized in that it comprises an inner ring of cavities with its central axes located in the corners of an inner pentagon, and two outer rings of cavities, the central axes of which are located in the corners of two outer pentagons, whose circumscribed circles have the same or slightly different radii, each corner of one of the outer pentagons being located between two corners of the other outer pentagon. Plant according to claim 1, characterized in that the cavities are so arranged in relation to each other that, seen in a horizontal section throughout the plant, the circular or oval cross-sections of the cavities have their center points located in the corners of equilateral and equal triangles, which together form a network of triangular meshes. 9 '7802027-8 Plant according to any one of the preceding claims, characterized in that each of said cavities has a conical roof and a conical bottom. _ Plant according to any one of the preceding claims, characterized in that it is surrounded by at least two substantially horizontal tunnels in the rock, one of which tunnels is located at the level of the upper parts of the cavities and the other is located at the level of the cavities. lower parts, and the said two tunnels are connected to each other by means of vertical shafts located at regular intervals around the plant. Plant according to one of the preceding claims, in which the cavities extend at least partially above the groundwater level, characterized in that a screen of material is arranged around the part of the plant which is located above the groundwater level, e.g. ex. clay which is impermeable or difficult to permeate to the fluid to be stored in the plant. REQUIRED PUBLICATIONS: Sweden 111 525 (81 e: 143), 201 168 (81 e: 143), 218 941 (81 e: 143), 390 718 (B65G 5 / OO) US 3,068,654 (61-0.5) I