RU2431770C1 - Underground storage of liquefied natural gas - Google Patents

Abstract

FIELD: construction.

SUBSTANCE: storage is arranged below earth level (1) at the elevation that prevents freezing of the earth surface during the longest possible storage of gas. The storage is enclosed along the perimetre from the soil massif with a concrete wall of "wall in soil" type (2) and comprises a reinforced concrete reservoir (5) arranged on the base from compacted soil (3) and a heat insulation layer (4), and this reservoir at its external side surface is surrounded with a pliable layer (6) and is coated from inside with layers of heat insulation (7) and hydraulic insulation (8). The storage is equipped with a process well that exits the reinforced concrete reservoir to earth surface. On the concrete wall of the "wall in soil" type above the roof of the reinforced concrete reservoir below earth surface there is a support reinforced concrete ring (14), where guy ropes (15) coated with anticorrosion material are attached to support the roof of the reinforced concrete reservoir. The upper of the reinforced concrete reservoir roof, guy ropes and the support reinforced concrete ring to soil surface are filled with a layer of light heat insulation material.

EFFECT: possibility of increased capacity storages construction.

1 dwg

Description

The invention relates to an underground LNG storage and backup system, namely, economical, fire and explosion-proof storage facilities located below ground level, and can be used to accumulate and issue LNG to consumers, especially where there is not enough or no pipeline natural gas, and to cover peak gas consumption (in the peak shaving system). The application of the invention allows you to create effective structural solutions of LNG storage tanks of increased diameter. This will increase the storage capacity to large and extra large volumes, and, as a result, reduce the cost per unit (1 m ³ ) of LNG stored in it.

The prototype of the proposed technical solution is “LNG storage facility” [1] - (RF Patent for the invention No. 2232342 dated July 10, 2004, IPC F17C 1/00, B65G 5/00) located below ground level at a mark that prevents freezing of the earth’s surface during the longest estimated storage of LNG, enclosed along the perimeter from the soil mass with a concrete wall of the “wall in soil” type, containing a reinforced concrete tank located on the basis of compacted soil and a heat-insulating layer, insulated and waterproofed from LNG from the inside, equipped with an pipelines for filling and dispensing LNG and its vapors in the technological mine, the technological mine leaving the tank to the surface of the earth is equipped with hermetic hatches and a ladder, and the top of the concrete tank is covered with a layer of heat-insulating material. LNG storage facility [1] solves the problems of improving the safety, reliability of the LNG storage and reducing the daily loss of the stored product (for underground storage facilities of large and extra large volumes).

However, when constructing a LNG storage facility according to [1] large and super large diameters, problems arise in creating a reinforced concrete tank roof both during its erection (construction) and when it is backfilled with heat-insulating material from above. The problem can be solved by creating a more convex roof (increasing the curvature of the dome) or by increasing its thickness, which leads to unreasonably high cost indicators for the construction of the entire LNG storage facility. At the same time, the creation of internal formwork over the entire roof area of a reinforced concrete LNG tank of large and extra large diameter is also problematic and, as a result, expensive.

These shortcomings set the task of creating a large and extra-large diameter LNG storage facility with a lightweight reinforced concrete tank roof. At the same time, questions of its construction and the provision of its strength characteristics when backfilling the roof with a heat-insulating material and a layer of soil should be solved by cheap (economical) and well-known methods.

The task of creating the roof of the reinforced concrete reservoir of LNG storage tanks of large and extra large diameters is solved by applying its support with the help of cables that are evenly stretched from the roof to the reinforced concrete support ring located above the roof of the reinforced concrete tank (its dome). Moreover, the entire roof structure of the reinforced concrete tank with cable-stayed and reinforced concrete support ring is below ground level and is covered with a layer of heat-insulating material.

In other words, this problem is solved by the fact that in the LNG storage facility located below ground level at a mark that prevents freezing of the ground surface during the longest estimated storage of LNG, enclosed along the perimeter of the soil mass with a concrete wall of the wall in the ground type, containing located on the base from a compacted soil and a heat-insulating layer, a reinforced concrete tank along the outer cylindrical (side) surface, surrounded by a compliant layer and insulated from the inside and waterproofed from LNG, with filled with pipelines located in the technological mine for filling and dispensing LNG and its vapors, with the technological shaft coming out of the reinforced concrete tank to the surface of the earth, equipped with hermetic hatches and a ladder, the top of the concrete tank is covered with a layer of light heat-insulating material, the roof of the reinforced concrete tank of the underground storage is made with cable stays, stretched from the roof of the reinforced concrete tank to the supporting reinforced concrete ring located in the concrete wall of the "wall in the ground" type above the roofs concrete tank and below the ground surface, shrouds coated corrosion-resistant coating and covered with a layer of lightweight thermal insulation material.

With all of the above, technical solutions are also known for additional (as well as the main) roof fastening (overlapping) with cables from the support ring (supporting elements) located above, for example, utility models presented below and the invention.

Above ground “vertical reinforced concrete prefabricated tank” [2] - (RF Patent for Utility Model No. 53342 of 05/10/2006, IPC E17H 7/00), comprising a wall of reinforced concrete panels, a bottom and a hanging cable-stay formed by radial metal cables, stretched to a support reinforced concrete support belt.

“Method of installation of Byte coating of a large-span building” [3] - (RF Patent for the invention No. 2029831 dated 02.27.1995, IPC E04B 7/14), the devices for the implementation of which comprise a coating (roof) attached to the support belts.

“The system for securing pits during the construction of underground structures” [4] - (RF Patent for Utility Model No. 83080 dated 05/20/2009, IPC E02D 17/04), containing the enclosing structure located along the perimeter of the structure, made in the form of a “wall in the ground », A major overlap (roof) supported from the temporary supporting structures (support ring) located above the major overlap by Byte guy wires.

However, such technical solutions [2], [3] and [4] were not used when creating LNG storage tanks of large and super large diameters. In addition, it is not known to use in LNG storage facilities constructive solutions for the roof of a reinforced concrete tank with cables and a reinforced concrete support ring, covered with a layer of heat-insulating material and located below ground level.

The introduction into the claims of the proposed technical solution of the sign “the roof of the reinforced concrete reservoir of the underground storage is made with cables stretched from the roof of the reinforced concrete reservoir to the supporting reinforced concrete ring” is necessary to significantly reduce the material consumption of the roof of the reinforced concrete reservoir of the LNG storage tank and increase its strength and bearing capacity, as well as simplify the technology construction.

The introduction into the claims of the sign “supporting reinforced concrete ring is located in a concrete wall of the“ wall in soil ”type above the roof of the reinforced concrete tank and below the surface of the earth” is necessary to create a supporting element for the roof of the reinforced concrete tank of the LNG storage facility - supporting reinforced concrete ring. Its location follows from the conditions for the optimal distribution of loads from the roof of the reinforced concrete tank, as well as the conditions for the exclusion of heat transfer from the soil surface to the roof elements of the reinforced concrete tank of the LNG storage facility. This feature also, like the prototype, provides a high fire and explosion hazard as a result of industrial activity or possible sabotage acts.

The introduction into the claims of the characteristic “cables are covered with an anticorrosive coating and covered with a layer of light heat-insulating material” is necessary to eliminate corrosion damage to the cables, as well as to minimize heat gain to the LNG storage facility and the absence of the “zero isotherm” on the soil surface.

The implementation of LNG storage tanks with the above set of restrictive and distinctive features of the claims is new to LNG storages, and therefore meets the criterion of "novelty."

The above set of features is unknown at this level of technological development and does not follow from the well-known rules for the design of LNG storages and their auxiliary equipment, which proves compliance with the criterion of "inventive step".

The constructive implementation of LNG storages with the above set of features does not present any structural, technical and technological difficulties, which implies compliance with the criterion of “industrial applicability”.

The drawing shows a schematic section of the LNG storage facility.

LNG storage facility is located below ground level 1 at a mark that prevents freezing of the earth's surface during the longest estimated storage of LNG. The LNG storage facility is fenced around the perimeter of the soil with a “wall in soil” type 2 concrete wall and contains a reinforced concrete tank 5 located on the base of compacted soil 3 and heat-insulating layer 4, which is surrounded by a flexible layer 6 on the outer cylindrical (lateral) surface and covered with layers inside thermal insulation 7 and waterproofing 8 from LNG. The LNG storage facility is equipped with a technological shaft 9 leaving the reinforced concrete tank to the earth’s surface 1 with pipelines 10 for filling and dispensing LNG and its vapors, as well as hermetic hatches 11 and a ladder 12. The top of the concrete tank is covered with a layer of light and cheap heat-insulating material 13, which Coal combustion waste - blast furnace slag can be used. From the wall-in-ground type 2 fixed on the concrete wall 2 of the reinforced concrete support ring 14, the roof supporting reinforced concrete tank 5 of the cable 15 are attached, which are evenly distributed over the roof of the reinforced concrete tank 5 and fixed in its reinforcing metal frame (not shown). The supporting reinforced concrete ring 14 is located above the roof of the reinforced concrete tank 5 and below the surface of the earth 1, the cables 15 are covered with an anticorrosive coating and covered with a layer of light heat-insulating material 13.

The LNG storage facility should be used after the completion of its construction of the underground and ground parts, when the entire volume of pipeline and shut-off and control valves has been mounted, as well as after a full range of verification and testing works and handing over to the state supervisory authorities. LNG is supplied via the filling pipeline (piping system 10) of the storage (preferably with simultaneous filling from above and below for uniform cooling). In the initial period of cooling the reservoir 3 and freezing the soil, there are large heat inflows from the soil, but over time, during further filling of the reservoir 5, the heat inflows decrease due to a constant decrease in temperature around the storage, and subsequently the soil freezes constantly (with a decrease in heat inflows to LNG). The tank is filled at 85-90% of its usable volume. Depending on the volume of the tank, after a certain time, a stationary heat conduction process is established in it, in which the entire structure of the tank reaches constant negative (cryogenic) temperatures. Inside the tank 5, a constant cryogenic temperature and pressure (slightly higher than atmospheric) is maintained. LNG is taken from reservoir 5 through a pipeline (cryogenic piping system 10) to a consumer. A flexible layer 6 acts as a compensator, which reduces the pressure of the soil on the tank in a stationary mode of operation. Through hermetic hatches 11 and a ladder 12 located in the technological shaft 9, access is made to the tank (when it is heated and ventilated by air) and possible inspections, maintenance and repair are performed.

Construction technology of the proposed LNG storage facility

Initially, a cylindrical “wall in the ground” 2 is erected from the soil surface 1. Then, after excavation at the design mark in the cylindrical “wall in the ground” 2, a reinforced concrete support ring 14 with fastenings for cables 15 (not shown) is mounted (constructed). Then, from the cylindrical "wall in the ground" 2 below the supporting reinforced concrete ring 14, soil is selected almost to its lower mark, where the soil 3 is additionally compacted. On top of the compacted soil 3 - the foundation of a concrete wall of the "wall in soil" type 2, a layer 4 of heat-insulating material is poured over which the base of the reinforced concrete tank 5 and its walls are built, backfill (or pouring) of the compliant layer 6. Next, they are mounted in a known manner suspended on cables 15 reinforcing frame of the roof of the concrete tank and formwork. Concrete is poured onto the reinforcement cage of the roof of the reinforced concrete tank and after it is solidified and the formwork is removed, they are made sequentially: the layers of internal thermal insulation 7 and the waterproofing 8 of the concrete tank are fastened, the technological shaft 9 is built, the piping system 10 is installed in it, the airtight hatches 11, stairs 12 are produced backfilling with a layer of light and cheap thermal insulation material 13.

The technical and economic advantage of the proposed technical solution lies in the fact that, in comparison with the prototype, the proposed LNG storage facility allows for constructive solutions of LNG storage facility of increased diameter, which will increase the storage capacity and, as a result, reduce the cost per unit of LNG stored in it.

In addition, the proposed technical solution, as well as the prototype, has a high degree of fire and explosion safety both in operating conditions and in accidents and various industrial impacts, and also has environmental safety for long periods of storage of LNG and operation of the storage facility (which constantly decreasing LNG losses from evaporation). The proposed constructive solution has wide possibilities of placement on the territory of Russia in various soil conditions and has a large range of LNG storage volume. Improving safety, reliability and durability is achieved by positioning the tank to a depth, which protects the tank from possible destruction as a result of man-caused activity or sabotage acts, as well as preventing soil heaving above the tank.

Information sources

1. RF patent for the invention No. 2232342 dated July 10, 2004, IPC F17 / C 1/00, B65G 5/00, “LNG ПХ” - prototype.

2. RF patent for utility model No. 5333 dated 05/10/2006, IPC E17H 7/00, “Vertical reinforced concrete prefabricated tank”.

3. RF patent for the invention No. 2029831 of 02.27.1995, IPC E04B 7/14, "Method of installation of byte coating of a large-span building."

4. RF patent for utility model No. 83080 dated 05/20/2009, IPC E02D 17/04, “The system for securing foundation pits during the construction of underground structures”.

Claims (1)

Underground storage of liquefied natural gas, located below ground level at a mark that prevents freezing of the earth’s surface during the longest estimated storage of liquefied natural gas, enclosed along the perimeter of the soil mass with a concrete wall of the “wall in soil” type, containing located on the base of compacted soil and heat-insulating reinforced concrete reservoir, on the outer side surface surrounded by a compliant layer, insulated from the inside and waterproofed from liquefied natural gas, equipped with pipelines located in the technological mine for filling and dispensing liquefied natural gas and its vapors, the technological mine leaving the reinforced concrete tank to the surface of the earth equipped with hermetic hatches and a ladder, and the top of the concrete tank filled with a layer of light heat-insulating material, characterized in that the roof of the reinforced concrete reservoir of the underground storage is made with cables stretched from the roof of the reinforced concrete reservoir to the supporting reinforced concrete ring y, located in the concrete wall of the "wall in the ground" concrete roof above the reservoir and below the ground surface, shrouds coated corrosion-resistant coating and covered with the surface layer of soil lung heat insulating material.