EP1728737A1 - Flat bottom tanks system for the storage of combustible and/or environmental damaging liquids - Google Patents

Abstract

The tank for storing inflammable or hazardous liquids has a steel false bottom (6). A pressure compensating filling (3) is positioned between this and the base (1) of the tank which has an open-pore structure and is made from a mixture of rigid and flexible particles held together with patches of flexible glue (32), leaving gaps (31) between them. Cavities (7) for mounting sensors are left in the filling. The sensors are connected to an exterior analysis unit (9) and detect leaks. An independent claim is included for the filling.

Description

Flammable liquids present in large volumes must be stored in correspondingly large containers, tanks or the like in a manner which ensures that in the event of leakage of the container and in particular the bottom of the container from the liquids stored there nevertheless no danger to the Environment goes out.

In general, this is done by double-walled execution of the shell of the container, in particular the container bottom, and by at least periodic monitoring of the cavity between the two container walls.

Not only for the new construction, but also for the refurbishment of tank systems, a number of different methods for the production of testable for their tightness tank sleeves have been proposed and used in practice.

This also applies to the flat bottom tank systems. Here, the arrangement and execution of monitored in the sense of the above remarks cavities limited to the bottom area of the tanks, since these facilities are free in a drip pan.

The bottoms of the tanks are usually made of steel with a thickness of 10 mm and coated with a corrosion inhibitor. A corrosive attack on these soils can emanate both from the liquid medium stored in the tank and from the ground. While the corrosive attack by the stored medium can be prevented by means of a coating or post-coating, the corrosion on the underside of the bottom is uncontrolled and without the possibility of an intervention preventing or stopping the same. Each revision checks the layer thickness of the welded steel plates forming the bottom and requires replacement of individual plates of insufficient material thickness.

It is therefore necessary that the bottoms of tank farms must be verifiable in terms of their layer thickness.

Flatbed tanks usually have diameters between 20m and 80m. The mass of liquids stored in the tanks is considerable and the forces acting on the bottoms of the tanks are therefore great. As a rule, this has the consequence that the trays or the plates forming the same are subject to great changes in the case of changes in the fill level of the tanks or, in the extreme case, if they are completely emptied or completely filled. In depleted tanks, soils often rise with amplitudes up to 50 cm and more compared to the position of the soils when the tanks are fully filled.

Even with an inspection of empty flat-bottom tanks, there are considerable up and down movements of the floor panels.

Conventional, high-quality, and therefore particularly firmly adhering anticorrosive coatings of the floors can just partially follow these extreme deformations without damage. A coating of the floors with such coating materials or glass fiber reinforced composite materials (GRP) is therefore easily possible.

Monitorable cavities, so z. B. between an outer and an inner bottom of the tank, can be integrated into existing tanks only with great effort.

Lifting the entire tank and installing new foundations and supports or the installation of a second, remote steel floor is associated with considerable costs and, especially for this reason, currently not practiced in this form.

It was therefore for a time trying to create the desired cavity in that it itself is part of the floor coating, so to speak, is integrated into the same. So-called spacer fabric, in particular made of glass fibers, allows the production of cavities in the coating according to the principles of fiberglass construction.

The spacer fabric integrated in the coating consist of two fabric cover layers, which are held at a distance from one another by the web threads connecting to one another and extending approximately perpendicularly to the cover layers. After impregnation with resin, the web threads of the spacer fabric - preferably one used with the trade name PARABEAM - automatically set to a respective predetermined height. This makes it possible in the simplest way to produce highly rigid and pressure-resistant sandwich laminates, wherein cavities remain between the two cover layers of the spacer fabric, from which the samples as mentioned above can be taken for the determination of possible leaks.

However, these cavities or the same structures contained stiffen the construction significantly, an effect that in other context, such. B. in aircraft, ship od. Like. Is quite desirable. In the case of tanks, however, the movements and deformations of the steel base as described above lead to the destruction of this type of coating when the quantity of liquid in the tank changes. The reason for this is that rigid cavities can not absorb the movement and deformation forces evenly. The forces occurring during the deformation of the bottoms of the tanks are focused point and / or line and In some circumstances, the cavity composite coating applied to the bottom of the tank may destroy the tank when it is first filled.

This has meant that providers of such coatings based on spacer fabric for flat-bottomed tanks have virtually disappeared from the market.

Due to these and other unfavorable experiences in practice, flat-bottom tank systems are currently being rehabilitated with the consent of the authorities, in particular by repairing the steel floor and by carrying out corresponding anti-corrosion coatings without a cavity.

1. 1.) Herstellung einer Isolierschicht auf dem bestehenden Boden eines Tanks und Einziehen eines zweiten Stahlbodens. Der neue Stahlboden ist dadurch vom Untergrund isoliert, und somit ist eine Korrosion vom Untergrund her für einen längeren Zeitraum verhindert. In den meisten Fällen wird eine derartige Isolierschicht aus Bitumen eingesetzt.
2. 2.) Herstellung einer selbsttragenden GFK-Schicht auf dem bestehenden Stahlboden. Die auf der Innenseite des Tankbodens ausgebrachte Schutz-Schicht ist gegenüber Feuchtkorrosion beständig und wirkt selbst dann noch als dichter Boden, wenn der darunter liegende Stahlboden bereits durchkorrodiert ist.
3. 3.) Eine Kombination der beiden gerade genannten Verfahren, wobei ein neuer GFK-Boden auf eine vorher erstellte Isolierschicht aufgetragen wird.

Essentially, the following systems are used today:

1. 1.) Making an insulating layer on the existing bottom of a tank and drawing in a second steel bottom. The new steel floor is thus isolated from the substrate, and thus corrosion from the ground is prevented for a longer period of time. In most cases, such an insulating layer of bitumen is used.
2. 2.) Production of a self-supporting GRP layer on the existing steel floor. The protective layer applied to the inside of the tank bottom is resistant to damp corrosion and even acts as a dense floor when the steel floor underneath is already corroded.
3. 3.) A combination of the two methods just mentioned, wherein a new GRP flooring is applied to a previously prepared insulating layer.

However, the current state of the art is - not least from the point of view of the legislature - still unsatisfactory, since a control of the required per se plant safety, for example, by the latter tank bottom protection systems and remediation process is practically impossible. The consequence of this is increased investment risk and reduced inspection intervals, which cause considerable costs.

At this point it should be mentioned that in the DE 2843174 A1 a double-walled storage container for liquids is described. There, a vacuum is maintained in the space between the two tank shells, a suction and measuring line introduced there allows the monitoring and registration of a leak in the container. The space is filled with a porous material. It is called there as such with synthetic resin bonded Einkornsand.

The DE 4322859 A1 and the US 4756033 A show line arrangements for the drainage of the bottom body of a container.

It is now an object of the present invention to provide long-term leak-monitored flat-bottom tanks, in which inspection intervals of z. B. 15 years or longer are possible.

In-depth investigations have shown that the training of possibly permanent, monitorable cavities which are in direct contact with the bottom surface of the steel tank, only by using sufficiently elastic and ductile material is possible to follow the above-described movements in the deformation of the soil when changing the mass of the tank contents, Simultaneously However, this material requires that it be able to easily withstand the weight force caused by the stored medium, ie in particular up to 4 bar pressure.

In detailed attempts to produce porous or interspersed with materials materials has been found that a combination of granular or lumpy material and not just sand, in particular of such grain material having a substantially a Einkorn aggregate corresponding particle size spectrum, and a the individual grains, moldings od. Like. Binding binders has proven best.

However, in order to achieve the high deformations of tank bottoms and the same od without breaking. The like. Comprehensible material, in the present case, however, to solve the problem here task all in "rigid" combinations of aggregate and binder as not applicable be considered. Such "rigid" porous masses are z. B. mono-grain concrete, epoxy resin bonded quartz sand or gravel, polyester-bound gravel od. Like.

It was therefore to be assumed that only to a certain extent could "yielding" systems or material combinations lead to the solution of the problem posed here to success.

To this end, the following is explained in more detail:

The floor of flat-bottom tank systems made of steel, if this is designed in one layer, is statically regarded as a membrane. By filling and emptying this membrane is stretched or compressed. Experience has shown that more or less significant deformations of the ground surface in the emptied state occur from a floor area of 800 m ² (diameter 62 m). The deformations are u. A. depends on the thickness of the floor panel. Due to the welding stresses generated by the generally overlapping welded floorboards, these deformations are difficult to predict and locally significant. It is to be expected with radii of curvature of down to one meter.

Floor structures of a few centimeters have no stiffening effect on the subject areas and spans. You must therefore be able to follow the movements of the soil in order not to be destroyed, the higher the layer thickness of such structures and the lower the radii of curvature of the Deformation, the more elastic or ductile the linings must behave in order to absorb the strains in the outer region of the curve.

The contents of the tank system exert pressure on the floor surface. The floor construction must therefore be designed so that the structure does not yield under the sealing layer. This not only applies to vertical forces, but also to lateral loads. The material of the substructure must therefore not be pushed by "Walk" movements of the soil to the side.

The need for a pressure-stable, yet bendable, ductile construction has been found to require a specific composition of the incorporated layer. This must once consist essentially of pressure-stable material, such as e.g. Quartz gravel, which is connected in such a way that the distance of the individual grains from each other is small and a sideways movement is prevented. Such constructions are almost incompressible under pressure and heavy loads, since the forces are derived directly to the ground. If the binder between the grains consists of a rigid material, e.g. made of cement, non-elastic synthetic resin od. Like., So the structure is pressure-stable, but can not adapt to curvatures of the substrate.

Are now elastic and / or ductile binder such. As polyurethanes, elasticized epoxy resins, silicones, flowers od. Like. Used, such an adjustment is possible. Prerequisite, however, is a corresponding extensibility of the binder used and the presence of cavities, in which a deflection of the binder is possible.

For example, a radius of curvature of one meter in the ground with a 25 mm thick layer leads to a surface increase of about 2.5%. Because along the surface only a small part, ie z. For example, if 5% of the cross-section, binder is present between the grains, an elongation of at least 50% is required to follow such curvature while maintaining the bond between the grains. Thicker layers require correspondingly greater strains.

Similar values are to be expected in case of deformation of the tank bottom during filling or emptying of the tank.

It has now been found that by the addition of elastic solids, the elongation behavior can be significantly improved and in this way the binder is much less stressed and the balancing contact between binder and grain always remains upright. In question is an admixture of elastic plastics, rubber granules od. Like. To the rigid, pressure-stable materials. The proportion of elastic material should be chosen so that the Pressure stability does not diminish significantly. The proportion of elasticizing additives must be aligned with the required pressure stability. At a required compressive strength of 400 kPa z. For example, according to experience, a proportion of elasticizing material is approximately in the range of 5-10% volume low.

The invention thus relates to a flat-bottom tank system according to the preamble of claim 1, which has the features mentioned in the characterizing part of the invention.

The claim 2 calls for the granular or lumpy base material of the arranged in the cavity between the two bottoms of the tank pressure compensation body particularly preferred materials to be used here, the shape of the grains, moldings od. Like. Limits are set only by the fact that it is not an at least partially dense "packing together" of the moldings may occur, whereby the necessary to fulfill the purpose of the invention empty spaces between the grains, moldings od. Like. Are too small or even disappear, so that the "pores" between the grains and the Connection between the same, so the patency or "open porosity" within the visco-elasto-plastic pressure compensation body is guaranteed.

By selective choice of the proportions of rigid grain material to elastomer grains or -Formkörpern, both preferably present substantially as Einkorn material present, the elastoplastic or mechanical "flexibility" of the pressure compensation body forming mass targeted to the respective given requests to the same be set. At the beginning of the studies, this ratio was estimated to be between 80:20 and 20:80, based on the total intrinsic volume of the rigid and elastic bodies, but it was found that over-weighing of the rigid material was important and beneficial.

Thus, synthetic or natural elastomers, in particular rubber or recycled rubber granules or similar, comparatively soft or soft-elastic granular materials or shaped bodies, can be stiffened by the proportion of quartz gravel to increase the pressure-absorbing capacity, without the visco-elastic properties of the pressure compensating body completely get lost. Conversely, of course comparatively rigid aggregate material can be elasticized and / or plasticized by admixing elastomeric, in particular rubber granulate, with a suitable granulation in each case. The prerequisite for this is in any case the use of a ductile / plastic / elastic binder as a grain binding material.

The claim 2 further calls within the scope of the invention in addition to the grain or shaped body material to be used preferred particle size ranges thereof.

The claim 3 provides information about preferred quantitative ratios between rigid and elastic grains.

It has also been found that as a binder for the grains, moldings od. Like. Partially flowing or flowable binder purely elastic binder materials are preferable, since such a certain tendency to "flow" having materials in each case changing or new geometric conditions practically force-free adapt, and that in this way, if any changes in the geometry of the cavity between the two tank bottoms any resulting shear forces between the two bottom plates of the tanks automatically degrade very quickly.

This circumstance can advantageously be taken into account by selective selection of the binders in accordance with the invention for the elastoplastic bonding of the grains, shaped bodies or the like in the mass forming the pressure compensation body.

Favorable proportions are also mentioned in A n s p r u c h 4.

In order to create the most even and smooth surface on the yes and with coarser grained material formed pressure equalization body to the upper or second floor or to the underside, it is advantageous if arranged between the same and the second floor a fine grain body or a fine grain layer is, as the claim 5 can be found.

As regards the size of the grain of this fine grain body, which is usually formed with sand, possibly also bitumen-bound, sand, particle sizes of less than 1 mm are preferred.

For tanks whose second floor is formed with fiber-reinforced plastic, it is preferable, in particular for the subsequent electrometric monitoring of the thickness of this second floor, to arrange a walk-on aluminum foil on the fine grain layer just mentioned and then to form the second floor with the fiber-reinforced synthetic resin laminate thereon, for which reference is made to claim 6.

As already mentioned, it is important in the sense of minimizing the monitoring effort, either directly probes for the detection of leaking of the tank bottom from the ground and / or from the liquid medium stored in the tank in the cavity between the two floors of flat bottom tanks, To arrange in gas or vapor form present substances or to lay there sample sampling points and lines through which gas samples from the cavity between the two floors of the tank respectively Analyzers can be supplied.

Continuous monitoring of the conditions in the false bottom cavity can best be ensured by maintaining a slight negative pressure and by a continuous pressure monitoring, which essentially corresponds to the state of the art. In order to ensure a rapid response of the system used here, perforated tubes formed along their extension with inflow openings are arranged in the pressure compensation body in a manner which ensures that the transport paths of gas through the layer up to a sample removal point as short as possible.

In this sense, the arrangement of the strands of the sampling lines in the pressure compensation body to be taken from the inlet 7 is particularly preferred within the scope of the invention.

The claim 8 has a further advantageous manner of arranging the sample removal lines and their branch strands within the pressure compensation body to the object through which the highest possible detection probability of "leakage substances" over the entire base area or within the entire volume of the pressure compensation body is guaranteed.

The claim 9 is a supplement to the measuring and alarm device can be seen by a pressure sensor.

Finally, the claim 10 calls the preferably used for the formation of the new pressure compensation body in the context of the invention, viscoplasticity having masses.

As regards the actual monitoring of the cavity between the two bottoms of the tanks with regard to the occurrence of leaks indicating substances, it is advantageous if the same takes place in two stages, since on the one hand in this way the safety can be increased and on the other hand the monitoring to one each assumed failure scenario can be adjusted.

A discontinuous qualitative monitoring of the air or gases in the cavity between the two bottoms of the tanks on entering into the "leakage substances" can be ensured by periodically removing gas samples from this cavity, which are preferably tested by gas chromatography on their ingredients ,

In this way it is possible, in the case of failure of one of the two bottoms of a tank, in particular of the "upper" floor, to determine or at least limit the occurrence and possibly also the location of the leak. Kick that stored in the tank liquid medium in only small amounts in the intervertebral cavity, this can be easily detected on the basis of the characteristic "pattern" of the volatile substances of the medium.

If it comes now to the corrosion of the lower soil, so breaks though the negative pressure in the inter-soil cavity together, but gas chromatography can in this case the absence or absence of traces of the medium in the tank detected in the interstitial cavity become. The protection of the substrate from contamination in this case remains fully upright and the tightness of the second floor can still be monitored by gas sampling from the cavity.

The invention will be explained in more detail with reference to the drawing:

1 schematically shows a prior art, as mentioned above, spacer fabric, the Fig. 2 shows a substantially corresponding to the real conditions mass, as used according to the invention for the formation of the pressure compensation body, Fig. 3 and 4 are sectional views of two embodiments of tanks with intermediate bottom cavity monitoring device preferred within the scope of the invention, and FIGS. 5 and 6 show two advantageous types of arrangement of the sampling lines within the pressure compensation body ensuring the highest possible area coverage for sampling.

With the prior art shown in Fig. 1, but never to a satisfactory solution to the problem of monitoring tank systems on leaks leading spacer fabric 1 ', which is impregnated with a curable resin, the bottom of the for the storage of environmentally hazardous liquids to certain tanks. The spacer fabric 1 'comprises two spaced apart mutually parallel fabric cover layers 20', 21 'between which z. B. approximately steep-spirally extending web-filament or - bundle of fibers 22 'extend. Between the web thread bundles 22 'remain spaces 31' free, which communicate with each other. In the layer with the web bundles 22 ', a sampling tubes 7 is inserted with sampling openings 71, through which gas samples can be taken from the space between the two tissue cover layers 20' and 21 'and fed to an analysis system. After the resin impregnation of the spacer fabric 1 'has hardened, the second or upper bottom of the tank is formed on the layer formed therewith by application of glass-fiber-reinforced plastic. This type of training one for the removal of corrosion damage in the Gas tank indicating gas samples from the voids between the web filament bundles 22 'of the spacer fabric 1' of the tank provided analysis system has not been proven in practice, since ultimately stiff by the hardening impregnating resin material, as described above, often high deformation movements of the tank bottom when changed the filling level of the tank is not able to follow and due to the high material stress tends to disintegration.

Fig. 2 shows schematically a section through the for the formation of the present invention for the arrangement in the void 16 between the two floors and a tank provided pressure compensation body 3 according to the invention, in detail, as the surface of all substantially uniform grain size kg having approximately Aggregate grains 30, z. As gravel and rubber granulate (hatched), coated with a layer of bitumen 32, by means of which the grains 30 are at least where they touch each other, bound together. This mass of grains 30 or moldings and serving as their binder bitumen 32 is not rigid, but allowed due to their visco-plasticity small mutual relative movements of the main component of the pressure compensation body 3 forming grains 30 with each other, through which the above-described high deformations of the tank bottoms can be followed when changing the filling level of the liquid in the tank so that it does not come to a disintegration of the thus formed pressure compensation body 3. Between the grains (30) remain three-dimensional interconnected grain interstices 31 exist.

Fig. 3 shows - with otherwise identical reference numerals - a section through the region of the lower edge of a cylindrical steel tank 10 with lying on the substrate U, provided on the inside with a corrosion protection coating 2 lower or first base steel base 1 and the same towering cylinder wall 11 of the tank 10. At a distance from the first steel floor 1 and parallel to the same, the second or upper steel floor 6 is welded into the tank 10. Between the bottoms 1 and 6, a cavity 16 is formed in this way, in which the basic steel bottom 1 volldeckende, such as disc-like pressure compensating body 3 from the, as shown in more detail in the detailed detail of material bitumen 32 bonded together grains 30 and open porosity intermediate grain Rooms 31 is arranged.

In the pressure compensation body 3, a sampling tube 7 is embedded with here successively arranged slot-like sampling openings 71, which is guided through the tank wall 11 to the outside and to which a corresponding flange 8 a pressure gauge 90 with alarm device 91 for the case of a pressure increase in the cavity 16 between the trays 1 and 6 and also a gas chromatograph 950 with one of them in the event of leakage and the entry of at least one of the stored in the tank 10 liquid F substance in the cavity 16 between the two floors 1 and 6 triggerable warning device 951 are connected.

At the top, the pressure compensation body 3 is covered with a, optionally also bitumen-impregnated, fine-grained sealing layer 4, which is finally closed by the second or upper steel bottom 6 at the top.

The schematic diagram of FIG. 3a shows the grain material / bitumen / pore mass of the pressure compensation body 3 provided for pressure equalization, as shown more realistically in FIG. 1.

With otherwise constant reference numerals - Fig. 4 shows a section through a tank 10 with the base bottom 1, also made of steel, but with a second bottom 6 of a fiber-reinforced resin laminate and a in the same manner as shown in FIG. 3, formed pressure compensation body third

From Fig. 4 it can be seen that between the fine grain layer 4 and the existing here of a synthetic resin laminate second bottom 6 a metal, preferably an aluminum foil 5 is arranged, through which a non-invasive electrometric determination of the layer thickness of the second bottom 6 of the tank 10th is possible.

When in Fig. 5 - with otherwise constant reference numerals meaning - shown the manner of laying the provided for the removal of gas samples from the intermediate bottom cavity 16 of the tank 10 sampling line 7 is a, about the course of a diameter of the tank bottom 1 or 6 accordingly relocated, rectilinear main branch 71 of the sampling line 7, from which branches substantially symmetrically to each other and about concentric to the wall 11 of the tank 10 and branching with their ends back to the main line 701 branching branches 702. The gray-patterned, the line strands 701 and 702 of the sampling line 7 accompanying surfaces symbolize the catchment area of virtually easily from the porous pressure compensation body 3 to the branch strands 701, 702 of the sampling line 7 passing gas samples.

In a different embodiment of the laying of the sampling line 7 in the pressure compensation body 3 as shown in FIG. 6, a total of four at right angles to each other and radially to the center Mk of the pressure compensation body 3 extending main strands 701 of the sampling line 7 are provided, of which approximately at an angle of 60 ° four rectilinear branching off before reaching a respective adjacent main strand 701 branch branches 702. Dark gray patterned are those volume areas of the Pressure equalization body 3, from which a more intense sampling can take place, while the light gray patterned areas indicate those zones in the intermediate bottom cavity 16 and in the arranged there pressure compensation body 3 from the visco-elasto-plastic mass, from which a less intense sampling can take place ,

Claims (10)

Flat bottom tank system for the storage of combustible and / or polluting liquids, wherein the cylinder mold or other shape having tanks either from the outset with a standing in contact with the substrate or a substructure base and outer bottom and with a distance from the same and to the same extending substantially parallel, fluid-tight manner with the tank shell wall or with the tank side walls-connected, with the tank to be stored or stored liquid in contact second or inner bottom is formed, or this second or inner bottom has been retrofitted into the tank and wherein in the cavity between base bottom and inner bottom at least one on at least one of the ground and / or the tank interior or the liquid located in the tank substance sensitively responsive sensor or such Analytical probe or at least one to one or such a leading substance removal point is arranged, and the sensor, the probe od. The like. Data flow connected to one of the same can be supplied with sensor data display and alarm device,
characterized, - that in the intermediate or cavity (16) between the material fit or by welding, with the jacket wall (11) of the tank (10) fluid-tight second bottom (6) made of steel or between the by materially bonded to the tank Mantle wall (11) fluid-tight bonded second base (6) based on conventional or fiber-reinforced plastic and the base base (1) a substantially layer or disc-like pressure-receiving, distribution and compensation body (3) of an open porosity and viscoelastic Having properties having composition based on a with grains (30), granules or moldings formed, substantially uniform grain size (gk) having granular material or Einkorn aggregate is arranged, whose grains (30) or moldings, which partially from a rigid, pressure-resistant and partly made of a resilient, elastic material, coated with a ductile-elastoplastic binder (32) and m it is bound to each other while maintaining intergranular voids (31), and in that at least one sampling point (71) is provided in the mass which forms the pressure-receiving distribution and equalization body (3), or which is preferably pressurized or acted upon with a vacuum, Sampling line (7) is embedded, to which, preferably outside of the tank (10), at least one gas analyzer (9), preferably gas chromatograph, with analysis monitor (90) and optionally additional alarm device (91) is connected. Flat bottom tank system according to claim 1,
characterized, - that the grains (30) or shaped body of the aggregate or Einkorn aggregate in the pressure-receiving and -ausgleichskörper in the intermediate or cavity (16) between base bottom (1) and second bottom (6) of the tank (10) with rigid and with yielding grains or moldings, namely in part with elastomeric grains or shaped bodies or with an elastomeric granules formed therefrom of synthetic and / or natural elastomers, rubbers or rubbers, in particular recycled rubber, and on the other Od with grains or moldings of stone, rock, gravel od. Like. And / or concrete, steel or rigid plastic moldings od. Like. Are formed, and - That it is preferably provided that the grains or moldings of the two aggregates have substantially the same or similar average size, in particular between 2 and 12 mm, preferably between 5 and 10 mm. Flat bottom tank system according to claim 1 or 2,
characterized,
that the proportion of the aggregate mixture of elastic, yielding grains or moldings in the total intrinsic volume of the grains or moldings is 2.5 to 25%, in particular 5 to 10% by volume. Flat bottom tank system according to one of claims 1 to 3,
characterized,
that the binder (32) for the grains (30), shaped bodies or the like, in particular for the single-grain aggregate, in the mass forming the pressure-receiving, distributing and balancing body (3) with an elastoplastic polymer, in particular polyurethane, vulcanizable rubber, polysulfide polymer, silicone resin, and preferably with a, optionally polymer-modified, bitumen and / or. Like., Is formed, and the same preferred manner in an amount of at least 2% and at most 15%, in particular from 2 to 5%, in each case based on the total mass of Einkorn moldings and binder is included. Flat-bottom tank system according to one of claims 1 to 4
characterized,
in that in the intermediate or cavity (16) between base base (1) and second base (6) above the pressure receiving, distributing and balancing body (3) which is in contact with the base bottom (1) of the tank (10) a fine grain body (4) formed with fine grain, in particular with quartz or silicate fine grain or sand, which is in contact with the second base (6) of the tank (10), preferably in bulk, is arranged. Flat-bottom tank installation according to one of claims 1 to 5,
characterized,
in that , in the case of a second base (6) produced with fiber-reinforced plastic, an aluminum foil is arranged between the fine-grain body (4) and the plastic second base (6). Flat bottom tank system according to one of claims 1 to 6,
characterized,
in that the sampling line (7) arranged in the pressure receiving, distributing and equalizing body (3) is designed with a main strand (701) leading outwards, essentially corresponding to the course of the diameter of said body (3) in which each branch strands (72) branching off from said main branch (71) open out from both sides, for example corresponding to the arcs of concentric circles spaced apart from one another. Flat bottom tank system according to one of claims 1 to 6,
characterized,
in that the sampling line (7) has a plurality of, preferably four, arranged at equal angles to one another from outside the tank radially into the vicinity of the mid-point (Mk) of the pressure-receiving, distribution and equalizing body (3) guided main strands (701), in each of which from at least one side, preferably at an acute angle, branching from the same branch strands (702) open. Flat-bottom tank installation according to one of claims 1 to 8,
characterized,
in that a gas pressure measuring sensor (95), which is data flow-connected to the pressure display monitor (950) and to the alarm device (951), is additionally arranged in the pressure receiving, distributing and equalizing body (3). Pressure-receiving, -distribution and -ausgleichskörper for the arrangement in the intermediate or cavity (16) between the floors (1, 6) provided for the storage of combustible and / or environmentally damaging liquid media containers, tanks (10) , in particular flat-bottomed tanks, having a base base (1) and a second base (6) or the like, characterized
in that it is formed as specified in at least one of claims 1 to 9.

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