SE410579B - PROCEDURE FOR SAFE UNDERGROUND STORAGE OF CRYOGENA PRODUCTS - Google Patents

Description

7 201M34 second, the outer system circulates medium with a temperature below 0 ° C in order to cause the storage space and the first circulating system enclosing sealing shell formed around the latter system by freezing all water contained within in the shell area existing rock, which shell prevents liquid water from penetrating from the outside in the direction of the storage space and prevents gases from leaking into the environment from the same.

In the following, the invention as well as the prior art will be described in more detail with reference to the accompanying drawing, in which Fig. 1 shows a schematic vertical section through a horizontal cylindrical or round type underground layer in accordance with the invention with a large number of boreholes for the internal circulation system, drilled near and along the rock surface of the cavern or cast in a concrete wall inside a cavity of sludge, chalk or sand (Fig. shows only one rock cavity), Fig. 2 shows a schematic vertical section of a horizontal or round type sub- earth layer in accordance with a modification of the same invention with a large number of circulation channels for the internal circulation system located between the actual outer rock wall or a cast concrete wall and the inner insulated layer wall (Fig. shows only one rock cavity), Fig. 3 is a perspective view of a rock storage cavern auxiliary tunnels which together with those between d the same drilled holes 1 constitute the external circulation system for freezing a protective screen; furthermore, horizontally drilled holes 17 for the internal circulation system are shown and finally examples of boreholes 16 for injection in the cavern area are indicated, Fig. 4 is a schematic vertical section of two circulation systems, from a horizontal cavern, showing those built on the two separate tunnel systems as a base ; the two tunnel systems have connecting boreholes drilled perpendicular to the longitudinal axis of the cavern, Fig. 5 is a diagrammatic schematic illustration of the distribution of water vapor pressure in the cavern area.

In Fig. 5: 7801M34 10 15 20 25 30 35 14- a) solid line denotes the pressure of the saturated water vapor at start-up but before water removal measures have been taken; no drying gas dashed line shows the actual water vapor pressures some time after commissioning; no drying gas b) actual vapor pressures when using a drying gas, c) distribution of temperatures some time after start-up and d) water vapor pressures when applying the diffusion principle.

When applying the initially proposed method mentioned above, the cracking of the rock wall by temperature contraction can be avoided by heating the rock wall in an underground storage facility by means of a medium, in particular a gas, which is pumped around in a circulation system, a duct system, which is later preferably located inside the rock, around the storage cavern and near its surface, whereby the temperature of the stored cryogenic condensed gases can be well below 0 ° C.

Hereinafter, this circulating system is referred to as the internal circulating system. By adding heat to this system, a temperature barrier is created around the same.

A problem associated with such storage of liquefied gases is the difficulty of arranging a suitable drainage system, sealing the subterranean rock and the task of preventing water in the vapor phase from migrating towards the storage cavern, the latter phenomenon involving a sublimation process, if the temperature is below OOC. To solve the drainage problem, an additional second circulation system, which works during OOC, has been arranged.

According to known physical laws, water vapor travels to areas where the water vapor pressure is lowest, ie to the coldest place, unless the water vapor pressure has been reduced in another way. One way to prevent this undesired water movement would be to provide a so-called "cold trap" at a temperature below the storage temperature and outside the storage, ie between the environment and the storage, but due to the serious rock cracking problem at a low temperature 10 15 20 25 30 35 7801413-1 This solution is of little interest when storing gases such as LNG with very low boiling points. A cold trap at an intermediate level, where no cracking of the rock takes place, i.e. about -40 ° C to -50 ° C, would reduce the water vapor pressure there and thus reduce the speed at which the water moves towards the layer. If an annular low temperature zone is arranged in order to solve the drainage problem and act as a cold trap (see below) by using a second external circulation system on the outside t of both the bearing and the internal circulation system, in which the latter place the temperature barrier is located, such arrangements operate as an electrically ohmic resistor and thus reduce the rate of water migration to the reservoir, but the migration of water will not cease completely due to the potential drop in residual water vapor pressure, unless further action is now taken. This situation has been approximately illustrated in Fig. 5a, schematically showing a water vapor pressure diagram, the solid line indicating the approximate water vapor pressures at the temperatures in question, the dashed line the actual water vapor pressure after some time of operation. According to the previously mentioned known method, therefore, a cold trap was proposed, since the water vapor pressure around the temperature barrier would not be fully developed and saturated, which means that water from the surroundings would still tend to move towards colder areas along the storage wall. The effect of a cold trap, created by passing drying gas with extremely low water vapor pressure through the internal circulation system with its connecting cracks, cavities and pores, would be that the area around this internal circulation system will attract moisture from both the environment as the bearing wall. The lower the temperature can be kept, the lower the water migration rate will be. Fig. 5b schematically shows an approximate diagram of when using such a drying gas with internal circular water vapor pressure, practically no water content in the ion system, which system is located close to and around the cryogenic cavern. .

Water vapor, and, depending on temperature, water wants to pass cracks and diffuse through pores in the rock towards the cold layer, if a corresponding potential drop for the water exists. If open cracks remain after sealing work, a small pressure in the internal circulation system and such a pressure in addition to the pressure in the surroundings will prevent water from leaking in. To prevent diffusion along the water vapor pressure gradient towards the bearing, a suitable carrier gas is required, which moves at a calculated higher speed in the opposite direction. It is easy and possible to measure and calculate the diffusion rate of water and steam in rocks. By arranging a pressure drop of the carrier gas in the opposite direction and using sufficient overpressure in relation to the pressure in the second external circulation system and using a suitable gas in the internal circulation system, the velocity of diffusion carrier gas: from the internal circulation system will exceed the water vapor, which later moves in the opposite direction and towards the bearing, which all results in water vapor being carried towards the external circulation system. In Fig. 5, two velocity vectors indicate the result of such an arrangement, which requires that the pressure in the bearing must mostly be slightly higher than in the internal circulation system, if the latter is to be used for leak detection purposes. The magnitude of the gas diffusion rate is about one meter per hour.

If such a diffusion process is applied, the same circulating gas, depending on the choice, may have to be selected for the two circulating systems. The drying function of the internal circulation system will, in principle, when this diffusion process is used, function as a safety measure with regard to water vapor. If the external circulation system is assigned a drying function, this can lead to settlements in the ground. When starting water is removed between the two circulation systems, a drying function can be transferred to the external circulation system, but this is then not required after this initial period.

Liquid water should in principle be avoided in the vicinity of the storage cavern, which means operating temperatures below 10 15 20 25 30 35 7801413-1 7 OOC in the storage area. The diffusion rate decreases with temperature, and a bearing wall with a lower temperature will reduce the heat losses due to the lower temperature gradient. However, enclosed zones above 0 ° C, for example in the area around the internal circulation system, can be used. If a zone with a temperature below 0 ° C could be located around the cavern and its internal circulation system, such a device would prevent water from entering the storage area through this frozen zone, which would form a protective screen, would prevent that water, which is enclosed in innumerable cracks in the rock, to flow out, wherever tunnels would be built further down the rock and holes drilled in it.

Once such cracks have been emptied, it is impossible to refill them with water, leaving cracks open and the rock permeable to gases which may possibly escape from the bearing cavern. It is therefore important to retain the water in the rock from a sealing point of view and otherwise create a situation that prevents sealing water from disappearing by flow or sublimation, the latter popularly considered to be a freeze-drying process.

Control of the humidity in the two circuits and the supply of water to the mentioned screen can therefore be important.

It must be remembered that changing the temperature of the rock is an extremely slow process, which at the same time means changing the steam pressure of the water, which in turn leads to the development of other changes in the rock, for example the process that leads to subsidence. . The problem of cracking of rocks and distribution of stresses in the rock should be kept in mind indefinitely. Each temperature difference in relation to the original natural temperature of the environment gives rise to changes, stresses and imbalances. With the use of strain gauges, humidity gauges, thermometers, pressure gauges, etc., a balanced operation of the rock cavern can be achieved with the help of electronic instruments. With two circulation systems available, each of them can be used to regulate and fix the desired temperature gradient between the two systems, each of them can thus be used to dry up the surroundings. around its own circulation system by means of a dried circulating gas, each of which can be used to seal cracks by applying pressure and each of them can be used as a safety system by using a weak vacuum to detect leaks and recycle the leaked product all in accordance with the methods previously proposed. The task of the external circulation system, however, is above all to reduce the temperature of its surroundings as quickly and as early as possible and to form an ice umbrella, whereby the drainage problem and the sealing task are largely solved. It should be noted, however, that while using the internal circulation system for sealing purposes, the external system can be used at the same time as a safety system.

While the inner circulation system around the cryogenic layer requires the supply of heat to establish a temperature barrier at a satisfactory level, the establishment of the ice zone, the ice umbrella, around the outer circulation system requires the removal of heat. A heat exchange between these two systems should thus be advantageous from a technical and economic point of view. As will be stated below, the construction of a double circulation system can be based on four auxiliary tunnels, which in any case must be developed for the construction of the actual storage cavern.

The need for the four inner tunnels, on which the inner circulation system is based, means the cheapest way to install the inner circulation system with the boreholes perpendicular to the longitudinal axis of the bearing. Two tunnel systems may be required instead of one to ensure better voltage equalization in the rock and facilitate the sealing problem.

Fig. 3 shows in principle how an underground layer 10 of this kind can be built. The four horizontal auxiliary tunnels ll-14 are excavated through an inclined access tunnel. Between these four horizontal auxiliary tunnels a regular net borehole 15 is then drilled, the system drilling the borehole curtains between these tunnels and the tunnels itself enclosing the actual cavern and the internal circulation system at the same time as it constitutes the actual external circulation system. By circulating a cold gas in the tunnel system 11-14 and the boreholes 15 - for this purpose a common cooling system for the two circulation systems may be used - the water in the rock in the area ll-14, 15 will freeze, forming a screen or zone of ice, which freezing procedure prevents the rock from being emptied of water during the next continued construction phase. In this way, the rock is kept impermeable, and the water flow is stopped. Larger water flows must first be stopped in a conventional way by grouting with cement.

To begin with, cooled air will be used as a cooling medium to allow construction without interruption.

The temperature of the external circulation system should be brought below 0 ° C as soon as possible to cause the water to migrate from the cavernous area to the external environment and the ice screen at an early stage. As soon as the internal circulation system is ready, hot dry air is circulated both in this system and in the cavern to remove water around the internal circulation system. A low temperature around the external circulation system will attract moisture.

By regulating the moisture content of the media carefully, by choosing a correct ratio between the pressures in the cavern, in the internal and external circulation system to apply both leakage in the circulating search and product recovery in the internal circulation system as well as water removal according to the diffusion laws, by regulating the temperature barrier and the temperature level in the external circulation system, a stable operating situation will arise, which can be described as follows after a sufficient time has elapsed after commissioning: 1) The area around the internal circulation system is dry, and all water between this system and the cavern wall has been removed. The temperature barrier is high enough to prevent cracking. A suitable choice of the gas, the diffusion gas (carrier gas), in the internal system and a suitable choice of the pressure difference between the circulation systems will remove all water between the area of the cavernous-internal circulation system and the external circulation system.

The drying function of the gas in the internal circulatory system is then to a large extent a safety measure (Fig. 5). 2) The temperature level of the external circulation system is below 0 ° C, which ensures the existence of a waterproofing screen and is so adjusted that it more or less acts as a cold trap for water vapor, which comes both from the area between the two circulating systems and from - the conditions, creating a situation with an approximate equilibrium and balance around this source of cold, the area of the waterproof screen. The humidity of the circulating stream must thus be regulated here in order to maintain a state of equilibrium and prevent unnecessary drying out of the external environment, which can lead to settlements in some cases. The lower the temperature in the external circulation system, the lower the diffusion rate of the water vapor will be and the lower the required pressure difference between the circulation systems will be. 3) The two circulation systems exchange heat.

The four auxiliary tunnels ll-14 are excavated in order to prepare the area where the actual cavern will be built.

Their use for establishing an external circulation system is thus a secondary issue, which is resolved to be donated. By drilling the holes 16 from these tunnels into the area of the upcoming cavern and injecting cement and epoxy plastics and similar products at low pressures, about 3 kp cm_2, the rock quality can be significantly increased, cracks sealed and cracked surfaces glued together. After the cavity has been hollowed out, a more efficient grouting can be performed from there to ensure absolute tightness with the application of pressures up to 100 kp cm_2. Then the tunnels 18-21 are built, and the bore 22 for the internal circulation system is drilled perpendicular to the longitudinal axis of the bearing. It is 780-11113-1 ll cheaper to build the internal circulation system in this way than to use a version with drill holes along the longitudinal axis of the bearing and in accordance with the version depicted in Figure 1 (17) or Figure 3 (17). The cavern is then sealed, for example, with a layer of epoxy plastic, and the insulation is applied by means of a spraying method to the sealed wall.

It should be noted in particular that according to the design philosophy of the invention it is assumed that the purpose of the insulation is first and foremost to insulate and thus reduce the heat transfer and only secondarily prevent the liquid content from reaching the rock surface. Should a crack occur in the insulation, this would only mean an infinitimal heat loss. The two circulation systems can take care of all problems that may arise due to the insulation breaking, including providing the required safety. Before data and experience have been collected, it seems safer to build two tunnel systems instead of one, which would bring the circulation systems closer together.

Claims (8)

* I801! T13 '”= l0 15 20 25 30 35 12 PATENTKRAV 1. A method of arranging storage space for liquids and liquefied gases at cryogenic temperature, the storage temperature differing from the temperature of the rock or other material formation surrounding the storage space, characterized by the measures of arranging around the storage space, outside this surrounding thermal insulation an inner first system of the storage space enclosing channels or cavities, through which a medium during heat exchange with the system surrounding matter is circulating, to arrange at an distance further away from the first system and the storage space an outer, second system of channels and cavities, in which a medium during heat exchange with the system surrounding matter is circulating, circulating through the inner, first system medium with a temperature higher than the temperature of the storage liquid in order to create a temperature barrier between the storage space and the area around the outer second cavity system beyond the first inner channel - or the cavity system and circulating medium in the second, outer system with a temperature below 0 ° C in order to cause the storage space and the first circulation system enclosing sealing shells formed by freezing all water contained within the shell area existing rock around the latter system. , which shall prevent liquid water from penetrating from the outside towards the storage space and prevent gases from leaking into the environment from the same. A method according to claim 1, characterized by the measure, to provide means for heat exchange between the media in the inner, first system and the outer, second system. 3. A method according to claim 1, characterized in that the measures, in order to form the external circulation system, arrange a number, at a distance from the intended position of the storage space, parallel to the 10 80 15 25 30 35? 801lø13 ~ 1 13 the same elongate cavities or tunnels, to connect said elongate cavities with a large number of channels, which together enclose the position of the storage space containing the rock material and the internal circulation system, the cavity system, to from said elongate cavities in the direction of storage space substantially directed towards this borehole, to introduce through said borehole a cracks and the like sealing and stabilizing composition in the rock material and to arrange in the thus stabilized and sealed rock material both the storage space and the surrounding inner system of cavities and channels. 4. A method according to claim 3, characterized in that the internal system is built up as a base extending He * a number of cavities or tunnels around and along the storage space and these cavities interconnecting channels. 5. A method according to claim 3, characterized in that the internal system is built up of channels arranged substantially along and parallel to the boundary wall of the storage space. 6. A method according to claim 1, characterized in that a pressure drop is arranged in the direction from the actual storage space towards the external circulation system. 7. A method according to claim 6, wherein - from the storage space or internal ground due to the pressure sign thereof, the circulating system originating and in the case in the direction outwards towards the external circulating system diffusing gas is used as a carrier gas, which can otherwise drive diffusing in the opposite direction. or migratory water molecules towards the external circulatory system. 8. A method according to claim 7, characterized in that means for connecting gas or carrier gas and of water from the medium in said circulation system are connected to the external circulation system as well as means for separating water from the gas and return of the same. MENTIONED PUBLICATIONS: