DE19532493A1 - Determining depth of blanket mirror in salt cavern - Google Patents

Abstract

Determining the depth of the blanket mirror in salt caverns, esp. during removal of brine from salt caverns, using a gaseous blanket comprises determining the depth of the blanket mirror from the parameters of injected and/or removed liquid medium.

Description

The invention relates to a method for determining the depth of the blanket level in Salt caverns, especially for the isolation of salt caverns, using a gaseous blankets.

The isolation of caverns in salt formations serves on the one hand to create underground cavities for storing or depositing liquids, gaseous or solid substances, and / or for brine extraction for industrial purposes Further processing. The importance of storing gaseous substances such as natural gas, nitrogen or compressed air.

When caverns are isolated in the salt rock, the Process, a medium that is inert to water is used as a blanket. The Blanket is specifically lighter than water. It will be in one of the outer flush pipe tour Downstream annular space pressed into the hole, spreads on the in the Brine from the cavern and thus limits the soling process upwards. As a blanket come liquids such as oil, diesel and liquefied gas, but also gases such as for example nitrogen and air. The use of natural gas as a blanket will described for example in DE 43 19 941 A1. Natural gas can be used both as Blanket medium as well as serve as a storage medium.

To control a targeted separation process, however, knowledge that is as precise as possible is required the depth of the blanket mirror is required. The conditions differ for the determination of the blanket level when using salt caverns of a gaseous blanket significantly different from those used in the solution using a liquid Blankets. The solution under a liquid blanket results from the small Compressibility tendency of the media involved the amount of escaping brine inevitably from the amount of water pumped in. If no blanket is pumped in or subtracted, the depth of the blanket-brine level remains approximately constant.

When used under a gas cap, the blanket is very compressible. Therefore there there is no inevitable connection between the fed Amount of hot water and the escaping amount of brine. It may well be over one a larger amount of process water can be fed in than brine for a longer period of time  is removed. In such a case, the blanket mirror moves in the cavern up. If, on the other hand, more brine is removed than process water is added, the blanket mirror moves down. Because of the compressibility of the blanket this blanket mirror movement also takes place when no blanket is removed or Blanket is added. In principle, partially mineralized water can also be used Layered water or unsaturated brine can be used.

The depth at which the blanket level is set is not only dependent on the hot water Brine balance depends, but also on the respective cavern contour. The However, the contour of the cavern is subject to constant due to the ongoing sol process Change.

Tracking the blanket-brine level is even more problematic, though a controlled lowering of the blanket level during the solution (there is more brine taken as process water added) or a controlled blanket level increase (more process water is added than brine is removed). So moves z. B. in a blanket level lowering the blanket level in lower Cavern areas that have been in solution for a long time and therefore have considerable volume and Show contour changes.

The following options are generally known, the depth of the blanket-brine contact to follow when brining under gas:

• - By means of measuring electrodes arranged on the outer rinsing line, under Taking into account the electrical conductivity of the brine, it can be determined whether the Blanket mirror is located above or below such an electrode. The number of However, electrodes is limited. Furthermore, the depth range that can be controlled is strong narrowed down. The effort to install the electrodes on the outer rinsing line is considerable and very expensive.
• - By means of control tubes attached to the outer rinsing line and led up to the surface may or may not occur when the blanket level is lowered based on one that has taken place gas breakthrough can be determined whether the blanket level is located below or above the tube shoe of such a control tube. The However, the number of control tubes is limited. The controllable with it The depth range is severely limited by the rigid attachment to the rinsing line Effort to install the control tubes on the outer rinsing line is considerable. In the Extension of a gas cavern already in the storage process by means of a solution is not enough space to place such control tubes in the blank ring space.
• - A periodic measurement of the blanket-brine contact can be done using geophysical measurement process carried out through the rinsing lines in the cavern  will. To do this, the separation process must generally be interrupted. Such Measurements are very expensive.
• - A continuous measurement of the blanket-brine contact can be accomplished by a measuring probe which is pulled out of the inner rinsing line and tilted upwards. However, this method has the following disadvantages:
  • - Due to the length of the measuring probe, the tube shoe of the inner sol tube tour must be set significantly higher than in the normal case. This severely limits the possibilities of achieving cavity growth.
  • - The measuring probe is bound for the entire Soldauer.
  • - There is a not inconsiderable risk that the measuring probe will be knocked off by falling salt areas.
  • - Due to the concentration distribution, which is variable over the height, calibration and thus an exact evaluation of the pulse transit time measurement is not possible with an ultrasound measurement method. The values obtained in this way would have to be regarded as highly faulty.
  • - The measuring process is expensive.

The invention has for its object to provide a method with which the brine under a gaseous blanket, the depth of the blanket mirror is inexpensive and reliably determined as well as its change of position over a longer period of time can be tracked with little effort.

Based on this task, a method is proposed for the solution, the According to the invention, the depth of the blanket mirror by determining parameters of the fed and / or the liquid medium is determined.

The invention is based on the consideration that with precise knowledge of the one and the brine volume in the cavern at a certain time The position of the blanket mirror in the cavern at the time of the cavern contour can be determined. However, it must be taken into account that the dissolving Salt is subject to a volume contraction and the brine in the cavern Is subject to temperature changes. By means of precise measurements of the one and quantity flows fed out, their temperature and their mineralization and thereon based calculations are therefore in any time intervals in the cavern located brine volume balanced. Thereby find temperature-related Changes in volume in the cavern are taken into account as well Volume contraction processes when dissolving salt z. B. in water. Subsequently the contour changes taking place due to the set brine regime in  each modeled brine-filled part of the cavern and the current location of the blanket brine Level in the cavern determined with progressive contour development. Thus the Disadvantages of the above-mentioned prior art avoided.

Process water, partially mineralized stratified water or Brine used.

Furthermore, the parameters can only be determined on the day. this has the advantage that no expensive installations are carried out during the day have to.

It is particularly advantageous to determine the necessary parameters during the ongoing sol process, since the brine process for measuring the depth of the blanket level does not have to be interrupted.

The parameters can also be changed during the exclusive extraction of brine or mineralized during the exclusive supply of process water Layered water or brine can be determined.

It is also advantageous to determine the depth of the blanket mirror for any technically sensible point in time (e.g. at the end of a shift or on working days), with which a continuous tracking over time is enabled, especially in 1 to 48 hours Intervals at which the depth of the blanket level is determined and thus a sufficiently precise one Statement about its temporal development can be made.

In order to arrive at a reliable statement in the separation process about where to look the blanket level is set after a time interval (e.g. after 1, 6, 8, 12 or 24 hours) has to be through the procedure

• - The incoming and outgoing flows, their temperature and their mineralization measured,
• - the volume of the brine in the cavern is determined taking into account the following factors:
  • - Volumes of the media fed in and out, in particular brought in process water and removed brine volumes, taking temperature and mineralization into account
  • - Temperature change in the brine in the cavern as well
  • - volume contraction of the salt when dissolving,
• - Sol process modeling for the period under review and the Contour development in the area below the blanket-brine mirror based on
• - the depth of the blanket-brine level, which reappears, as well as other characteristics the cavern is calculated and compared with the target values.

These evaluations show to what extent the new depth of the blanket-brine contact agrees with the targets and in which direction corrections in the next time interval is required.

The method according to the invention enables a considerable reduction in the number of or even waiving geophysical measurements within a brine stage possible. In addition, the process of lowering the blanket level may be required or raising the blanket level can be tracked and controlled in a targeted manner.

The invention is explained below with reference to an embodiment shown in the drawing. The Fig. 1 shows the Blanketspiegelabsenkung during the sole extension of a ligand already partially filled with gas cavern.

To build a cavern, a cavern bore is first sunk to the required level. An outer tube tour 1 is inserted into the hole and this is cemented to the surface 2. If a cavern has already been created and partially filled with storage gas, a gas feed tube tour 3 is attached to the outer tube tour, which is opposite the outer tube tour 1 in the lower one Area is sealed by a packer 10 . The annular space between the outer tube tour 1 and the gas delivery tube tour 3 is filled with a protective liquid 4 . A pressure line 5 is connected to the gas delivery tube tour 3 , via which the gas, which functions as a blanket, enters and exits the cavern.

In a cavern with an economically unfavorable contour 11 , the diameter 12 in the upper area has already reached the maximum permissible value. In the lower area, however, the cavern can still be expanded up to contour 13 . By using storage gas as a blanket, there is the possibility of achieving a cheaper cavity design with an economically justifiable effort.

For this purpose, the gaseous blanket 15 is first pressed into the cavern via the pressure line 5 . Brine is withdrawn from the cavern via line 9 until the blanket-brine level at the height of diameter 12 is established.

To the desired contour caverns to reach 13, the Blanketspiegel of the height of the diameter has to be 12, but lowered to the depth of the diameter of 14 under consideration of the already taken place contour development with running Aussolbetrieb.

For the expansion in question, an outer flushing tube tour 6 and an inner flushing tube tour 8 are hooked into the gas delivery tube tour 3 .

In the indirect brine process, the rinsing pipe tour 6 is connected to the domestic water system 7 and the rinsing pipe tour 8 is connected to the brine system 9 . In the direct (not shown) brine process, the rinsing pipe tour 6 is connected to the brine system and the rinsing pipe tour 8 is connected to the domestic water system. Fresh water or partially mineralized stratified water or unsaturated brine is supplied through the process water system, and brine is removed from the cavern via the brine system.

Since the blanket is compressible when brining under gas, more process water can be used pressed in, removed as brine. In such a case, the blanket level rises the cavern. The other way around, more brine can be drawn than process water are given. Then the blanket mirror moves down. The speed the blanket mirror movement is not only from the quantity balance but also from the Contour development dependent on the soling process. To become one in the soling process reliable information about where after a time interval (e.g. after 6, 8, 12 or 24 hours) the blanket level is set, the procedure will:

• - The incoming and outgoing flows, their temperature and their mineralization measured,
• - the volume of the brine in the cavern taking into account the following Influencing factors determined:
• - Considered domestic water and removed brine volumes of temperature and mineralization,
• - temperature change in the brine in the cavern,
• - Volume contraction of the salt when dissolving
• - Sol process modeling for the period under review and the Contour development in the area below the blanket-brine mirror modeled, and  
• - the depth of the blanket-brine level, which reappears, as well as other characteristics the cavern is calculated and compared with the target values.

These evaluations show to what extent the new depth of the blanket-brine contact agrees with the targets and in which direction corrections in the next time interval is required.

Claims (10)

1. A method for determining the depth of the blanket level in salt caverns, in particular during the salting out of salt caverns, by means of a gaseous blanket, characterized in that the depth of the blanket level is determined by determining parameters of the fed and / or discharged liquid medium. 2. The method according to claim 1, characterized in that as the fed medium Process water, partially mineralized stratified water or brine and as an outlet Medium brine is used. 3. The method according to any one of claims 1 or 2, characterized in that the Parameters to be determined above ground. 4. The method according to one or more of claims 1 to 3, characterized in that the parameters are determined during the ongoing sol process. 5. The method according to one or more of claims 1 to 4, characterized in that the parameters during the exclusive extraction of brine or during the exclusive supply of process water, mineralized layered water or brine can be determined. 6. The method according to one or more of claims 1 to 5, characterized in that that in the case of the media fed in and out, the media fed in and out Volumes as well as their mineralization and temperature are measured. 7. The method according to one or more of claims 1 to 6, characterized in that the brine volume in the cavern taking into account introduced and removed media volumes as well as their temperature and Mineralization, temperature changes in the brine in the cavern as well as the Volume contraction of the salt when dissolving is determined. 8. The method according to one or more of claims 1 to 7, characterized in that that the contour change for each brine-filled part of the cavern Sol modeling is determined.   9. The method according to one or more of claims 1 to 8, characterized in that based on the volume of the brine in the cavern and the determined Contour change the depth of the blanket-brine level is calculated. 10. The method according to one or more of claims 1 to 9, characterized in that the determination of the depth of the blanket level is carried out in time intervals.