DE10238964A1 - Double-walled industrial storage tank for toxic or water-contaminating liquids, has pressure sensors in the inner tank and outer inter-wall space connected to evaluation electronics so that a leak can be automatically detected - Google Patents

Abstract

Liquid containing tank has inner and outer hulls (1, 2) with the inner hull forming a liquid storage space (4). Between inner and outer hulls is a capture space (5) in which any leaking liquid is captured. The inner storage space has a pressure sensor (6) at least for measurement of hydrostatic liquid pressure, while the capture space also has a pressure sensor (7). A signal recording device records and outputs the pressure signals. The inventive tank is intended for above ground use.

Description

The invention relates to a double-walled liquid tank with remote monitoring Fill Level and leak control.

It is, for example, from the EP 1 153 882-A1 known to equip a liquid tank with a level measuring device and electronic data transmission in order to remotely organize a needs-based delivery. It is also known that this delivery can take place without involving the tank operator if the supplier has free access to the tank. Such freely accessible tanks are usually underground tanks that are stored outside of buildings in the ground.

Underground tanks require complex structural measures to ensure that the stored water polluting liquids in the event of a leak, do not penetrate the surrounding soil can. That is why underground tanks for storing water-polluting liquids are usually double-walled executed. About that In addition, leakage warning devices are prescribed, which immediately have a Inform the leakage that has occurred.

They are automatic leakage test known, which are based on the principle that between the walls of a double-walled tanks an air pressure or negative pressure is generated and sensors are provided which the Identify pressure drop or pressure increase in the event of a leak. The tank itself has atmospheric pressure on. Furthermore, processes with the same effect are known Leakage diagnosis with the help of a control liquid column, which in pneumatic or hydrodynamic connection to the interior of the double-walled Storage vessel stands. Here is a change the level of the liquid column a leak.

The majority of underground tanks are made Made of metal. Metal requires extensive protection against Environmental influences, to prevent rusting in the long term. In addition to protective coatings Sand beds are prepared from bitumen under the earth to make tops objects to keep away from the outer walls. A direct touch of the metallic outer walls such items carries the risk of electricity flows due to galvanic processes. By training said galvanic element there is an extremely accelerated rusting at certain points.

General disadvantage of from State-of-the-art underground tanks with leak monitoring is the high price, the technical facilities and the special design of the tank.

As an alternative to expensive underground tanks there are known tanks that can be installed above ground. Around the liquids stored in it to protect from frost, these tanks are housed in closed rooms, preferred in basements. A design of these tanks that does not require any additional leak protection measures, stands for in a drip pan any leaking liquid to be absorbed. The drip pan can also be designed as an outer shell be and is then structurally connected to the tank. such Tanks are particularly inexpensive if they are made of plastic and are manufactured industrially.

A disadvantage of the previously described embodiment is the fact that these tanks are visually monitored for proper functioning once a week Need to become. Moreover they usually stand not in freely accessible Rooms. The disqualifies them for pure remote monitoring for stock control.

It is the object of the invention to create a tank that is cheaper than a conventional underground tank, but can still be set up for automatic delivery accessible by third parties is. At the same time, the total purchase cost of such Tanks should be low and reliable leak control possible. Furthermore, it is desirable that the level and the leakage signals a constant Subject to control so that in the operating state "leakage" or "emptying" from the outside, e.g. by an operating company, appropriate measures can be taken.

This task and similar Tasks are solved by a tank with the features of claim 1. Advantageous Embodiments of the invention result from the subclaims.

In the liquid tank according to the invention it is preferably an industrially producible one double-walled tank, which comprises an inner shell and at least one outer shell, made of plastic. The inner shell delimits the tank space Liquid absorption and storage. The outer shell surrounds the inner shell on all sides and at least up to a height that of the maximum filling level of the interior equivalent. The distance between the inner shell and outer shell is usually small, i.e. a few centimeters (e.g. 0.3 to 15 cm). Because the outer shell always forms a total volume that at least partially the volume of the interior includes and for every level of the interior exceeds the volume of the interior - in relation to the full height of the interior - forms the outer shell effective leakage protection for the inner shell.

The double-walled liquid tank is preferred to protect against mechanical environmental influences in a jacket made of solid material, the coat still preferred Outside is surrounded on all sides by the soil. Preference is given to the jacket material a mineral material such as concrete is used.

The casing cover preferably consists of one or more industrially manufactured elements, which are brought into the earth as a whole or assembled as individual parts in the earth. at for example, an advantageous embodiment of the jacket is a construction made of standardized concrete rings. The jacket can be designed both in a liquid-tight and in a liquid-permeable form.

The top opening of the jacket leaves in a preferred Design to lower the tanks into the shell structure. she will closed with a removable lid.

The tank corresponds structurally to one Tank that for above-ground storage of water-polluting liquids is suitable. Around to monitor this tank remotely, it is with level sensors and leakage and directly or indirectly with remote data transmission equipped. For this be two pressure sensors used. A sensor is in the interior (inner Sensor) installed, the other in the space between the tank and the outer shell (collecting space) of the tank (outer sensor).

The sensors form a pair to determine the differential pressure. In normal operation, ie with a leak-free inner and / or outer shell, the outer sensor only records the atmospheric ambient pressure. The inner sensor records the atmospheric ambient pressure plus the pressure of the liquid column forming in the filled tank. The values are. transmitted by the signal unit via remote data transmission together with identification information for the tank to an evaluation unit. The difference between the two values is formed there with the aid of evaluation software. It is the basic signal for the fill level in the tank. The fill level in the tank is calculated with the help of a database that contains the information about the liquid and the tank shape - the assignment is made via the identification information for the tank. Forwarding, processing of the signals and procedures for controlling the level are in the EP 1 153 882-A1 described, which is hereby expressly made to the disclosure content of this application.

In the event of a leak in the tank the liquid runs in the outer shell. Thereby becomes the outer sensor with the additional hydrostatic pressure applied to the growing liquid column in the outer shell until he finally equalized the pressure of the inner sensor when both liquid columns same height have taken (provided both pressure sensors are on the same Height arranged). this leads to causing the differential pressure to become zero, which is either empty Inside tank or interpreted as a leak. Is the outer sensor (Collecting room pressure sensor) there is always an absolute pressure meter a leak if the displayed absolute pressure of the containment pressure sensor is above atmospheric pressure lies.

The software at the headquarters takes a time series of the transmitted Values. Therefore, it is able to recognize with high reliability whether it is actually the tank capacity is zero or whether there could be a leak.

Another security is the Possibility the recorded atmospheric External sensor pressure using the software with the values of the external sensors of other tanks to compare. You need to at least in an adjacent location all have approximately the same values. A deviation due to a leak is called an excessive atmospheric pressure visible.

Another advantageous Embodiment, the tank is in a liquid in the casing, which preferably does not endanger the groundwater. The jacket shell must liquid-tight for this purpose his. This ensures that the outer casing is also monitored for leakage can. Possibly. the tank is also in a made from a flexible plastic cover Put shell, which can preferably be closed at the top. The plastic shell forms such a second outer shell. At this execution can on a liquid-tight design the jacket to be dispensed with.

The liquid tank according to the invention offers the possibility a complete Automation of its liquid supply. The supplier can act completely autonomously. Furthermore Is it possible, the functionality to monitor the tank remotely. Its structure is due to its choice of materials and its pairing of sensors cheaper than that of an underground tank made of steel or pure special concrete.

When the liquid in the tank is fuel oil, it provides it is up to the operation of the associated heating system with the help a switch that is installed in the shell structure during the Switch off filling. This measure serves to protect the system against pollution from whirled up Particle components in the stored heating oil.

It is also possible that several liquid tanks are communicatively connected and in this case the Collection chamber pressure sensor is attached in each tank, but only the interior pressure sensor is required in a tank.

The pressure sensors are in a preferred embodiment at the deepest point of each room. They are usually on hanging on a cable or rope held in place. Under these conditions, the inner one shows Sensor a higher Pressure as the outer sensor on. The pressure change is a measure of the removal speed the liquid.

In the event of a tank leak, the pressure of the outer sensor increases and the pressure of the inner sensor falls. This leads to a relatively rapid change in the differential pressure, which indicates an excessive amount of fluid withdrawal or leakage. A plausibility check is carried out by comparison with recorded time series. The static final state of the change leads to approximately identical pressure at both sensors. That means no liquid either there is more or there is a leak. In both cases, personnel are immediately called to the tank to take action.

Another way to identify a leak is the pressure of the outer sensor with press comparable external sensors compare other tank. With a significant deviation on a tank, there is most likely a leak. In the same way, the shell of the collecting area checked for leakage. Prerequisite for this exam is the embodiment of the tank according to the invention, where the double-walled tank is in a liquid bath.

In the following, the inventive tank is further explained by means of exemplary embodiments. The 1 is a schematic diagram of the tank and serves to illustrate the invention.

The double-walled liquid tank is 1 ) and the surrounding outer shell ( 2 ) educated. The outer shell ( 2 ) acts as a collecting container in the event of leakage of the inner casing ( 1 ) and takes the filling content ( 15 ) of the interior ( 4 ) (Tank room) completely open. Inner shell ( 1 ) and outer shell ( 2 ) form a unit. The liquid to be stored is in the inner shell ( 15 ) (Useful liquid). The between inner shell ( 1 ) and outer shell ( 2 ) trained collecting room ( 5 ) is filled with atmospheric air in the normal state. The tank also shows the filler supports ( 9 ), the vent connector ( 10 ) and the interior pressure sensor ( 6 ) with its connection cable ( 6a ) on. The collecting area pressure sensor is located in the collecting area ( 7 ) with connection cable ( 7a ).

The entire double-walled tank is located in a jacket shell ( 3 ) formed jacket space ( 13 ). The jacket cover ( 3 ) is preferably surrounded by soil up to its upper edge. It is preferably a slimmer structure than in the 1 shown. The jacket cover ( 3 ) is lifted up by a preferably removable cover ( 14 ) locked.

The sensors ( 6 ) and ( 7 ) are via their connection cables ( 6a ) and ( 7a ) with a signal recording ( 11 ) connected, which accomplishes the voltage supply for the sensors and the signal conversion for the sensor information into dispatchable information. The processed information is sent to a data transmission unit, preferably a wireless data transmission unit with an antenna ( 12 ) passed on ( 11 ), with identification information for the tank also being passed on. The signal unit ( 11 ) is in or on the jacket ( 3 ).

The collecting room pressure sensor ( 7 ) measures the atmospheric pressure. It provides the reference for measuring the interior pressure sensor ( 6 ). The difference between the two pressures gives the hydrostatic pressure of the liquid column. In the central unit (not outlined), the data are linked to the tank and liquid data stored in a database. This creates the level information. Based on this, deliveries are triggered if necessary.

In the event of a leak on the inner shell ( 1 ) the liquid runs into the collecting space ( 5 ) until inside ( 4 ) and in the collecting room ( 5 ) The level is the same. As a result, the same pressure or approximately the same pressure acts on both sensors. The central unit will interpret this information as zero liquid level. Without further information, a tank vehicle would be put into operation for filling. The driver recognizes on site after opening the cover ( 14 ) on the shell structure that there is still oil in the tank. It is therefore clear that the "level zero" signal was caused by a leak.

In the present case, the signal from the collecting space pressure sensor ( 7 ) with other signals from corresponding sensors in other tanks, preferably neighboring ones. Typically, all containment pressure sensors must have similar pressures. Should this be the case with a collecting room pressure sensor ( 7 ) is not the case, it is very likely that leakage damage has occurred. In this case, personnel are immediately ordered to the tank.

In one possible embodiment of the inventive tank is located in the jacket space ( 13 ) a liquid that is not hazardous to water between the casing and the outer casing. This additional measure can also be used to identify a leak in the outer shell in the manner just described.

Claims (14)

Liquid tank having an inner shell ( 1 ) and at least one outer shell ( 2 ), whereby - the inner shell ( 1 ) an interior ( 4 ) for storing the liquid ( 15 ) forms, - the outer shell ( 2 ) the inner shell ( 1 ) spans to at least a height that corresponds to the maximum fill level ( 8th ) and a collecting room ( 5 ) in order to absorb liquid escaping from the interior in the event of a leak in the inner shell, characterized in that - the interior has an interior pressure sensor ( 6 ), the interior pressure sensor ( 6 ) absorbs at least the hydrostatic fluid pressure of the fluid for level measurement, - the collecting space ( 5 ) a collecting room pressure sensor ( 7 ), - a signal recording device ( 11 ) for recording and forwarding the pressure signals. Liquid tank according to claim 1, characterized in that the liquid tank from a wholly or partially below the earth's surface casing ( 3 ) which surrounds the mantle space from the soil surrounding the mantle shell borders. Liquid tank according to claim 2, characterized in that the casing ( 3 ) is formed from a mineral building material, preferably concrete, liquid tank according to one or more of the claims 2 or 3, characterized in that the jacket shell liquid-tight is trained. Liquid tank according to one or more of claims 2 to 4, characterized in that the side wall of the casing ( 3 ) is formed from superimposed prefabricated components, preferably in the form of rings. Liquid tank according to one or more of claims 2 to 5, characterized in that the casing ( 3 ) open a lid ( 14 ), which preferably has a size that allows removal of the tank. liquid tank according to one or more of the preceding claims, characterized in that the liquid tank essentially complete under the surface of the earth located. Liquid tank according to one or more of the preceding claims, characterized in that the interior and collecting space pressure sensor signals receiving signal recording device ( 11 ) is equipped with a technology that provides these signals with identification information for the liquid tank and is directly or indirectly connected to a remote data transmission device for transmission to a central unit for data evaluation. liquid tank according to claim 8, characterized in that the central unit for data evaluation a needs-based delivery and, in the event of a malfunction, maintenance and / or Repairs arranged. liquid tank according to one or more of the preceding claims, characterized in that the liquid tank has another outer shell, which is the first outer shell at least up to the height the maximum filling level of the interior surrounds and up to this height with a liquid filled is. Liquid tank according to claim 10, characterized in that the further outer casing of the casing ( 3 ) or one in the jacket room ( 13 ) located and on the jacket ( 3 ) is formed at least partially adjacent sleeve, which is preferably formed from a flexible film and can be closed at the top. Liquid tank according to one or more of the preceding claims, characterized in that the interior ( 4 ) and collecting room ( 5 ) are under ambient pressure. Liquid tank according to one or more of the preceding claims, characterized in that the interior pressure sensor ( 6 ) and collecting room pressure sensor ( 7 ) measures the absolute pressure. Liquid tank according to one or more of the preceding claims, characterized in that the interior pressure sensor ( 6 ) and the collecting chamber pressure sensor ( 7 ) are at the level of the respective floor areas.