ITVR20120180A1 - METHOD FOR MAKING AN INTERNAL METAL WALL IN A TANK AND TANK WITH A DOUBLE WALL. - Google Patents

Description

METHOD OF MAKING AN INTERIOR WALL OF METAL IN A

TANK AND TANK HAVING A DOUBLE WALL

DESCRIPTION

The present disclosure refers in general to the field of storage tanks. In particular, the present disclosure refers to a method for making an internal wall in a tank and to a tank having a double wall, i.e. an external wall and an internal wall.

Storage tanks, both underground and above ground, have a very wide field of application and use. Particular reference is made here to underground or above ground tanks for the storage of potentially polluting liquids. Examples of these tanks are underground tanks for storing automotive fuels in service stations, underground storage tanks for chemical products in the chemical industries, underground storage tanks for diesel or fuel oil for heating buildings.

For many decades these tanks have been made with a single wall, which for example is a cylindrical steel shell, which delimits the internal liquid storage chamber.

A common problem with single-walled tanks is that the break in the continuity of the wall (for example, the formation of holes or cracks caused by corrosion) causes a leakage of the liquid contained in the tank and an environmental pollution of the surrounding soil.

This problem is particularly felt for an underground tank: since the underground tank is not visible from the outside, it is practically impossible to promptly notice the formation of holes or cracks in the tank wall. Therefore, the tank can lose the liquid for a long time causing heavy pollution, without the tank manager being aware of what is happening.

The removal and replacement operations of a damaged underground tank are very expensive and time-consuming, both for the construction work to be carried out, for the cost of the new tank, and for the need to clean up the polluted soil.

In order to at least partially solve these drawbacks, methods have been developed for transforming a single-walled tank into a double-walled tank avoiding the need to dig up the underground tank.

For example, U.S. Pat. US 4,739,895 plans to create a double-walled bottom inside the tank, using aluminum sheets to create an internal wall. The aluminum sheets have reliefs that protrude towards the external wall, so as to leave a gap between the internal wall and the external wall.

Since the aluminum sheets are not available in sufficient size to cover the entire tank with a single sheet, a plurality of sheets are arranged adjacent to each other with overlapping edges; the overlap is covered with a glass-fiber reinforced tape and arranged over the overlap. The whole is then covered with a layer of epoxy resin, which incorporates the fiberglass tape and holds it in place.

The operations described above are carried out by operators who enter the tank and work in it.

Furthermore, as described for example in US patent no. US 4,613,922, the gap between the internal wall and the external wall can be monitored over time to identify any leaks in the contents of the tank. For example, a vacuum is created in the cavity, which is then constantly monitored. When the vacuum is no longer maintained in the cavity, it means that there has been a loss of liquid through one of the walls.

These processes for transforming tanks from single wall to double wall, while advantageous from many points of view, have some drawbacks which have not yet been overcome.

In particular, the inventor of this disclosure has realized that the joint between the aluminum sheets obtained in the manner described above can give rise to problems both during the construction of the internal wall and during the subsequent use of the tank.

First of all, the use of the glass fiber tape implies a processing phase that is laborious and delicate, due to the need to correctly arrange the tape on all joints; this also involves prolonged processing in the tank. Furthermore, the fiberglass tape, while being able to have an adhesive face that adheres to the aluminum sheets, is in fact held in position by the epoxy resin layer in which the tape remains embedded. Basically, fiberglass tape creates a kind of joint seal, but still does not ensure a stable joint between aluminum sheets over time. Not even the resin layer ensures a stable joint. For example, the aluminum sheets, the tape and the resin layer have thermal expansion coefficients that are different from each other and therefore over time there may be relative stresses and displacements of the tape with respect to the aluminum sheets and of the aluminum sheets with respect to to the resin, the repetition of which over time can lead to the collapse of the joint.

The efforts and relative movements can also be caused by the loading (with tank truck) and unloading cycles of the product contained in the tank during use.

A similar problem is encountered in the case in which the tank is intended to be used under pressure. In fact, the fiberglass tape arranged as described above does not prevent a relative rotation of one aluminum sheet with respect to the other around the edge of the superimposed sheet: since the tape is arranged only on one face of the overlap of the aluminum sheets (i.e. , above the overlap, on the inside), it is not able to ensure a stable and immobile junction in all directions. A high pressure in the tank, sudden changes in temperature or the loading phase can therefore lead to relative movements of one aluminum sheet with respect to the other.

Since the epoxy resin coating layer is thin (in fact it has a thickness of about 1 mm), it can be damaged and punctured by the relative movements of the aluminum sheets, with consequent breakage of the continuity of the internal wall and the formation of passage points for leaks of liquid contained in the tank. The present disclosure therefore starts from the technical problem, identified by the inventor, of providing a method of making an internal wall in a tank that allows to overcome the aforementioned drawbacks with reference to the known art and / or to achieve further advantages.

This is achieved by providing a method for making a second wall according to independent claim 1. The technical problem is also solved by a tank according to independent claim 11.

Particular embodiments of the object of the present disclosure are defined in the corresponding dependent claims.

A first aspect of the solution proposed by the present disclosure is to use a structural glue to join together the pieces or sheets of metal sheet which form the second wall of the tank, ie the internal wall. Basically, the sheet metal pieces are glued together with a glue having a high mechanical strength and which, after hardening, creates a non-removable fastening between the glued pieces.

This is useful for creating an internal wall in the tank which, although formed by several pieces of metal sheet placed side by side, from a mechanical point of view behaves as if it were a single piece. In particular, the structural glue can be arranged over the entire region of flanking between two adjacent sheet metal pieces, interposed between one piece and the other, so as to obtain a solid joint that is resistant in all directions of stress. This is useful to avoid relative displacements of a piece of sheet metal with respect to adjacent sheet pieces when the tank is under pressure or when it is subjected to thermal changes or loading and unloading cycles.

The risk of the formation of cracks in the internal wall during the drying of the resin and subsequently during the loading / unloading cycles of the tank is therefore greatly reduced or even eliminated thanks to the fact that the bonding of the sheet metal pieces to each other creates an internal wall very resistant that behaves as if it were a single piece.

In particular, in one embodiment the sheet metal pieces are partially overlapped with each other in overlapping regions along the edges of the sheet metal pieces and the structural glue is interposed between one piece and the other in the overlapping regions. . This is useful for obtaining a particularly strong and resistant joint, thanks to the extension of the overlapping surface on which the structural glue is located.

On the contrary, the reinforced tape used in the known art has at most one adhesive face that sticks to the metal sheets, without however creating a resistant joint. In fact, the adhesive of the tape itself is not very resistant and creates a removable fastening that is not able to oppose the relative movements of the sheets and cannot effectively resist the stresses during the loading / unloading cycles. Furthermore, the realization of the joints using structural glue, instead of using a reinforced adhesive tape to be superimposed on the overlapping regions between the sheet metal sheets, is useful to simplify the working process and to reduce the time the operators stay inside. of the tank, thus increasing the safety of the operators themselves.

In fact, the reinforced tape of the known technique is an additional member with respect to the sheet metal sheets and must be arranged in a very precise way to ensure that the reinforced tape covers the joint well and is well centered with respect to the latter. During the positioning of the reinforced belt, the sheet metal (which are not yet bound together) could also accidentally move relative to each other. Relative displacements of the sheets and of the reinforced adhesive tape may also occur during the application of the epoxy resin coating.

Therefore it is evident that the known technique requires considerable specialization of the operators, who must be very careful to avoid that errors in positioning the belt or displacements of the sheet metal can compromise the efficiency of the internal wall obtained.

In the method according to the present disclosure, on the other hand, the glue can be distributed in the gluing regions with a greater tolerance and with less precision (possibly, abounding for safety and placing the glue in a wider region than the effective overlap), without that this goes to the detriment of the final result. Furthermore, the glue grip begins already at the moment of contact between the edges of the sheet metal pieces (i.e., just after positioning a piece of sheet metal against another piece of sheet metal) and this is useful to reduce the risk of relative displacements between the pieces during the execution of the procedure.

These simpler operations to perform lead to a reduction in the time during which the operators remain inside the tank; since the inside of the tank is a potentially dangerous environment, shorter residence times reduce the risk of accidents.

Indeed, the sheet metal pieces can be provided with glue even before being introduced into the tank. In other words, the sheet metal pieces are prepared for gluing before their placement in the tank. For example, the sheet metal pieces are supplied already provided with glue arranged along at least one edge region, in which the glue is protected by a removable film or film. Consequently, the operations to be performed inside the tank are further reduced because the glue distribution phase on the sheet metal pieces is carried out outside the tank instead of inside the latter.

In particular, the pieces or sheets of metal sheet are made of a ductile material, specifically aluminum or an aluminum alloy.

A second aspect of the present disclosure, which may be an aspect independent of the first aspect mentioned above, is to use an adhesive or a glue to fix each piece of sheet metal to the first wall, i.e. to the inner face of the outer wall. In particular, an adhesive can be used that creates a removable fastening, or alternatively a glue that creates a non-removable fastening after drying or hardening of the glue.

Unlike the known art in which the aluminum sheets are simply placed on the internal face of the external wall of the tank or at most are attached to the internal face by means of a double-sided adhesive tape which creates a weak removable fastening, according to the present disclosure the sheet metal pieces are fixed on the internal face of the external wall directly by means of adhesive or glue, so that the internal wall is stably bonded to the external wall.

This is useful to avoid unwanted movement of a piece of sheet metal with respect to the other both during the construction of the internal wall and during the use of the double-walled tank obtained.

The fastening of the sheet metal pieces to the first wall (external wall) can be used in combination with the structural bonding of the sheet metal pieces to each other, or independently of it. For example, the individual pieces of sheet metal could be fixed by means of adhesive or glue to the first wall, while the junction between the adjacent sheet pieces could be made using a glass fiber reinforced tape as in the prior art described above.

Similarly to what is described above, the adhesive or glue for fixing the sheet metal pieces to the first wall can be prepared on the sheet metal pieces before they are introduced into the tank.

The method according to the present disclosure can also be applied to a tank which was built with a double wall and in which one of the two walls is damaged and no longer holds; it is therefore also possible to refurbish a double-walled tank. In this case, the method makes it possible to create a further internal wall that covers the already existing internal wall.

Further advantages, characteristics and methods of use of the object of the present disclosure will become evident from the following detailed description of an embodiment thereof, presented by way of non-limiting example.

It is however evident that each embodiment of the object of the present disclosure can present one or more of the advantages listed above; in any case, it is not required that each embodiment have all the listed advantages simultaneously.

Reference will be made to the figures of the attached drawings, in which:

Figure 1 represents a partially sectional perspective view of an underground tank according to the present disclosure;

Figure 2 represents a sectional view of a portion of the tank of Figure 1, according to a section line II-II in Figure 1;

Figure 3 represents an enlarged detail of a piece of sheet metal used in a method according to the present disclosure;

Figures 4 to 6 schematically represent successive steps of a method according to the present disclosure;

Figure 7 represents an enlarged view of a detail VII of Figure 6;

Figure 8 represents a coil of sheet metal according to the present disclosure, in a step of cutting a piece of sheet metal;

Figure 9 represents a piece of sheet metal obtained from the coil of Figure 8. A double-walled tank obtained by a method according to the present disclosure is shown in Figure 1, where the tank is indicated with the reference number 1. The tank 1 it has a substantially cylindrical shape, with a cylindrical lateral surface 11 and two opposite heads 12, 13.

The tank 1 delimits and encloses an internal chamber 18, or useful volume, suitable for receiving a liquid product (for example an automotive fuel or a chemical substance) or other substance to be stored in the tank 1. In Figure 1 the lateral surface 11 is partially sectioned to show the inside of the tank 1.

At the top of the tank 1 there is a manhole access well 14 in communication with the internal chamber 18. The pipes (not shown) for loading and unloading the product stored during use pass through the manhole well 14. of the tank 1. Through the same manhole well 14 the operators can enter the internal chamber 18 to carry out the operations of the method of the present disclosure and the maintenance operations.

The tank 1 is buried in a ground 9. In Figure 1 the ground plane of the ground 9 is shown interrupted to show at least a part of the tank 1. When installed on site, the tank 1 is completely buried and surrounded by the ground 9; only the top 140 of the manhole well 14 is at the level of the ground level of the ground 9 to allow the inspection of the tank 1 and access to the internal chamber 18 in case of need.

In any case, the method of the present disclosure is also applicable to non-buried or only partially buried tanks. In the case of tanks that are not buried or only partially buried, the method is preferably applied only to the lower part of the internal chamber 18, that is, where a loss of product towards the ground can occur.

Initially, the tank is single-walled, ie it has a single shell or external wall 21 which includes the lateral surface 11 and the two opposite heads 12, 13 and delimits the internal chamber 18. The external wall 21 is for example made of steel.

Since initially only the external wall 21 is present, which would therefore be directly in contact with the product stored in the tank, any hole or crack or lesion passing through the wall 21 would cause at least a partial leakage of the stored product, which would then pour into the soil 9 surrounding and pollute it.

To prevent a risk of uncontrolled soil pollution 9, the regulations currently in force in many countries require that underground tanks must be double-walled and with a leak detection system.

The problem therefore arises of transforming underground single-walled tanks already in operation into double-walled tanks that comply with the legislation, without being forced to unearth the tank itself. In the known art, as mentioned, processes have already been developed for this purpose, for example those described in US 4,613,922 and US 4,739,895.

The process according to the present disclosure is described below; the steps of the process which are carried out according to the known art are not described in detail because they are already in the knowledge of the person skilled in the art; on the other hand, the steps of the process which differ from the known art are described in detail. After emptying the tank and intercepting the loading and unloading pipes, the sump 14 and internal chamber 18 are cleaned, as well as the aspiration of any dangerous vapors. Using an explosimeter, it is verified that the conditions inside the tank are not dangerous for the operators who have to enter it.

The internal surface, that is the internal face 211 of the external wall 21, is cleaned and subjected to sandblasting to eliminate all encrustations. After sandblasting, the internal surface 211 is checked to identify any corroded areas, which in the case are treated to block corrosion and to restore the integrity of the external wall 21.

A first layer 25 of resin (for example epoxy resin) is preferably applied by spray over the entire internal surface 211 of the external wall 21. After the resin has dried, a resin coating layer 25 is thus obtained which adheres perfectly to the face. 211 of the external wall 21, covering it completely. The first resin layer 25 is checked, for example with a scintillograph, to verify that it does not have holes or irregularities, which are repaired if necessary.

Suction pipes (not shown) are arranged and fixed on the first resin layer 25, which allow to monitor a gap 29 that is created between the external wall 21 (which is therefore a first wall) and the internal wall 22 (which is then a second wall). In particular, the suction pipes are arranged so as to draw in the lowest point of the interspace 29 and are connected to the outside by passing through the manhole 14.

The internal wall 22 is then built, which is constructed using a plurality of pieces 30 of metal sheet. In particular, the metal sheet is made of a ductile metal, which is preferably aluminum or an aluminum alloy. Reference will therefore be made in the following to aluminum sheet and aluminum pieces 30; however, it is understood that other ductile materials could be used, such as copper or iron or alloys.

The sheet metal pieces 30 are essentially portions of aluminum foil, for example having a thickness S30 of 0.3 mm. Each piece 30 has for example a length L30 between 100 and 2000 cm and a depth P30 of 70 cm.

The aluminum sheet or sheet has a textured or knotty profile, that is, it has a plurality of protuberances 40 which protrude from a face 31 of the sheet. The protrusions 40 are regularly distributed on the surface of the sheet. In practice, each piece of sheet metal 30 has a first face 31 from which the convexities 401 of the protuberances 40 protrude, and a second face 32 into which the concavities 402 of the protuberances 40 sink. The protuberances 40, which rise from the bottom 310 of the first face 31 and have a top 41, they can have a truncated pyramid shape, a truncated cone, a paraboloid, a hemisphere, a rib, or other shape. Basically, each protuberance 40 has a convexity 401 which protrudes from the first face 31 of the piece of sheet metal 30 and a corresponding concavity 402 which is sunk into the second face 32 opposite the first face 31.

The protuberances 40 are made and arranged in such a way that no region of the first face 31 is isolated from the rest of the first face 31. In other words, when the sheet 30 is placed on a plane so that the tops 41 of the protuberances 40 touch the support plane (i.e., with the first face 31 of the sheet 30 facing the support plane), between the support plane and the bottom 310 of the first face 31 there is defined an interspace which passes around the protuberances 40 and in which there is no they are closed regions with respect to the other regions of the cavity, that is, inaccessible from the other regions of the cavity. As will become clearer in the following, this is useful for obtaining a gap 29 which is continuous and can be monitored.

The pieces of aluminum sheet 30 are introduced into the inner chamber 18 and are positioned next to each other on the first layer of resin 25. Each piece of sheet metal 30 is positioned so that the first face 31 with the convexities 401 of the protuberances 40 faces the first resin layer 25 itself, i.e. causing the tops 41 of the protuberances 40 to rest on the first resin layer 25.

In other words, the first face 31 is intended to be adjacent to the internal face of the external wall 21, in particular to the first resin layer 25 which covers the face 211 of the external steel wall 21. The second face 32 of the piece of sheet metal 30 is instead intended to face the internal chamber 18 of the tank 1.

According to the present disclosure, as shown in Figure 4 for the illustrated embodiment, each piece of aluminum sheet 30 is fixed on the first layer of resin 25: the first face 31 of the piece of sheet metal 30, or at least the tops 41 of the protrusions 40 is sprinkled with glue or adhesive 45 (by way of illustration, a brush 49 is shown in the figures to indicate the step of sprinkling the glue / adhesive substance); The piece of sheet metal 30 is then positioned and pressed towards the first layer of resin 25, so as to obtain the fixing of the piece of sheet metal 30 on the resin 25 and therefore to the internal face of the first wall 21.

Alternatively, the glue or adhesive substance 45 can be distributed on the first resin layer 25 instead of on the first face 31 of the sheet metal piece 30.

In a first version, a glue 45 is used, that is a substance whose drying or hardening creates a stable fixing which is not removable (unless the parts fixed to each other are destroyed). Basically, an industrial glue is used to achieve a structural bonding of the sheet metal piece 30 on the first resin layer 25.

In a second version an adhesive substance 45 is used, that is a substance which creates a removable fixing of the sheet metal piece 30 on the first resin layer 25; for example the fixing can be removed using suitable solvents or with a mechanical action. In this second version the sheet metal pieces 30 can be more easily detached from the first wall 21, for example during a disposal of the tank 1 at the end of its life or during a subsequent reconstruction of the internal wall 22.

This distinction in meaning between “glue” and “adhesive substance” is to be considered valid throughout this disclosure.

For example, the glue or the adhesive substance 45 has a very low solvent content, so that it can be managed according to the 94/9 / EC regulation on the regulation of equipment intended for use in areas at risk of explosion; preferably, it takes less than ten minutes to reach 50% of the final mechanical strength and requires less than 24 hours to reach the final mechanical strength.

After placing a first piece of sheet metal 30 on the internal face of the first wall 21, other pieces of sheet metal 30 are arranged next to the first piece. According to an aspect of the present disclosure, the sheet metal pieces 30 are partially overlapped (for example with an overlap of 3-10 cm) with each other and are glued together by means of a glue 35 for gluing aluminum on aluminum. That is, this glue 35 is a structural glue which creates a non-removable fixing between the sheet metal pieces 30.

As shown in Figure 5 for the illustrated embodiment, an edge band or region 34 of the second face 32 of a first piece of aluminum sheet 30a already positioned (and fixed to the first resin layer 25) is sprinkled with the structural glue 35 for its entire length L30. A second piece of aluminum sheet 30b to be positioned is placed next to the first piece of sheet metal 30a with a partial overlap, i.e. so that an edge band or region 33 of the first face 31 of the second piece 30b overlaps the edge region 34 of the first piece 30a and to the structural glue 35.

An overlapping region 37 is thus obtained along the edges of the sheet metal pieces 30a, 30b, with the structural glue 35 which in the overlapping region 37 is interposed between the first piece 30a and the second piece 30b. In other words, in the overlapping region 37 a sandwich structure is created formed by the edge regions 33, 34 of the pieces 30a, 30b and by a layer of glue 35 between them.

For example, the overlap region 37 has a width L37 between 3 and 10 cm.

When the structural glue 35 has set, that is, it has hardened or dried, a very strong bond is obtained between the two pieces of sheet metal 30a, 30b, which behave mechanically as if they were a single piece.

The mechanical strength (e.g., tensile, shear or bending) of the overlap region 37 joined with the structural glue 35 is comparable to or greater than the mechanical strength of the sheet metal piece region 30 which is not superimposed on other sheet metal pieces 30.

To further improve the mechanical strength of the joint between the two pieces of sheet metal 30a, 30b, in the overlapping region 37 the pieces 30a, 30b are superimposed on each other so that the convexities 401 of the protuberances 40 of one are inserted and received in the concavities 402 of the protuberances 40 of the other. The structural glue 35 is interposed between the convexities 401 and the concavities 402 received into each other.

For example, the structural glue 35 has a shear tensile strength (i.e. a shear failure value) which is higher than 10 N / mm <2>, in particular higher than 20 N / mm <2> and even more in detail of 25 N / mm <2>.

Preferably, the glue 35 has a very low solvent content, manageable according to the 94/9 / EC regulation, it takes less than ten minutes to reach 50% of the final mechanical strength and less than 24 hours to reach the final mechanical strength.

For example, glue 35 is based on methyl methacrylate. An example of glue 35 commercially available and which can be used in the method of the present disclosure has the characteristics reported in the following table. A glue 45 for fixing the piece of sheet metal 30 on the resin 25 can have the same characteristics.

NON-CURED PRODUCT

Chemical basis: Methyl methacrylate

Appearance: Pasty

Viscosity at 20 ° C: Adhesive 21,000 mPa · s Activator Very fluid liquid Evaporation time 5 minutes of the activator at 20 ° C:

Effectiveness of the activator after maximum 30 days of application at 20 ° C:

Working temperature: from 10 ° C to 30 ° C Polymerization temperature: from 6 ° C to 40 ° C

POLYMERIZED PRODUCT

Average tensile strength of sandblasted aluminum 25 N / mm <2>

cut after 7 days at 20 ° C and with sandblasted steel 21 N / mm <2> application of the activator on a galvanized steel 6 N / mm <2>

side only (DIN 53281-83): Sandblasted stainless steel 26 N / mm <2>

GRP (epoxy resin)

roughened 16 N / mm <2> Resistance to temperature: from -50 ° C to 130 ° C, up to 180 ° C for 30 minutes Peel strength on 6 N / mm

aluminum:

Coefficient of thermal expansion 70 · 10 <-6> K <-1>

linear:

Although not shown in the figures, it is understood that the first face 31 of the second piece of sheet metal 30b (or the corresponding region of the first layer of resin 25) is also sprinkled with glue or adhesive substance 45 before positioning the second piece 30b next to the first piece 30a, to also fix the second piece 30b to the outer wall 21.

We proceed in a similar way with the positioning and gluing of other pieces of sheet metal 30, until the entire external wall 21 is internally coated, both on the internal face of the lateral surface 11 and on the internal face of the two heads 12, 13. In substance , each piece of aluminum sheet 30 is glued at its edges to other pieces of aluminum sheet 30 next to it, obtaining an internal wall 22 formed by pieces of aluminum sheet 30 glued together by means of structural glue 35.

The inner wall 22, or second wall, is a closed shell which has an outer surface (formed by the first faces 31 of the sheet metal pieces 30) adjacent to the inner face of the outer wall 21, and an inner surface (formed by the second faces 32 of the pieces of sheet metal 30) which faces the internal chamber 18 delimited and enclosed by the second wall 22 itself.

The use of a structural glue 35 to join together the pieces of aluminum sheet 30 allows to create a joint having a very high mechanical resistance. The tensile strength (in a direction parallel to the surface of the sheet metal pieces 30) in the overlapping regions 37 is comparable to, or even equal to or greater than, the tensile strength of the aluminum sheet piece 30 in the non-overlapping region. In other words, the junction regions 37 between the sheet metal pieces 30 can be stronger than the rest of the inner wall 22.

In practice, the internal wall 22 basically behaves as if it were a single body formed by a single aluminum sheet. This is useful for having a double-walled transformed tank which has a duration over time and a resistance to pressure, as well as a resistance to thermal expansion, which is greater than the double-walled tanks according to the known technique.

The second wall 22 can in itself be fluid-tight, that is, a sealing or a second layer of resin is not required to ensure the seal against infiltration of fluid between one piece of sheet metal 30 and the other; in particular, the junction or overlapping regions 37 can be fluid-tight thanks to the structural glue 35 which creates a seal between the glued sheet metal pieces 30a, 30b.

Between the inner wall 22 and the outer wall 21 (more particularly, between the inner wall 22 and the first resin layer 25) there remains a gap 29, thanks to the fact that the protuberances 40 of the sheet metal pieces 30 act as spacers between the first resin layer 25 and the bottom 310 of the first face 31 of the sheet metal pieces 30. In particular, the protrusions 40 are made on the sheet 30 so that the interspace 29 is continuous, ie without closed or isolated regions.

A second layer 27 of resin (for example epoxy resin) is preferably applied by spray on the internal surface of the internal wall 22, thus covering the second faces 32 of the sheet metal pieces 30. As an alternative to the spray application of the resin, the latter it could be applied with a lamination process.

After drying of the resin, a resin coating layer 27 is obtained which adheres to the aluminum sheet pieces 30 and completely covers the inside of the tank 1. This is useful for protecting the sheet metal pieces 30 from the product that will be stored in tank 1, ensuring compatibility with the product itself and giving the double wall system a long life. Furthermore, the second coating layer 27 can increase the fluid tightness of the internal wall 22.

The second resin layer 27 is also checked, for example with a scintillograph, to verify that it does not have holes or irregularities, which are repaired if necessary.

The second resin layer 27 is in turn coated with a layer of electrically conductive material 28, for example a conductive resin. The conductive layer 28 is connected, through the manhole well 14, to the grounding of the tank 1. The conductive layer 28 allows the static electricity and any potential differences that are created in the internal chamber 18 of the tank 1, thus ensuring that there are no sources of ignition in tank 1.

A tank 1 was thus obtained, in which the internal storage chamber 18 is separated from the ground 9 by a double wall 21, 22, as required by the regulations on underground tanks: the first wall 21, i.e. the external wall, is the wall original of the tank 1 before the transformation intervention, while the second wall 22, that is the internal wall, was formed using the pieces of aluminum sheet 30, which were joined together by means of the structural glue.

A pressure difference is applied in the interspace 29 between the first wall 21 and the second wall 22. In particular, the interspace 29 is preferably placed in depression (through the suction pipes) at about -0.7 bar. The pressure in the interspace 29 is constantly monitored during the use of tank 1 to verify that it remains stable over time, or in any case in a range between -0.25 bar and -0.7 bar.

The stability of the maintenance of the depression, for example, indicates that the interspace 29 is watertight and that there are no infiltrations or leaks from the internal chamber 18, so that there is no risk of product spillage from the internal chamber 18 to the ground 9.

A significant increase in the pressure in the interspace 29, or in any case a significant variation thereof, indicates instead that there has been an infiltration or leak through one of the two walls 21, 22 and that therefore a maintenance intervention is necessary before there is a loss of product to the ground 9. In the event, the leakage points are sought and repaired.

Since, as previously mentioned, the interspace 29 is continuous, it has the same pressure at all points: a leak through any point of the second wall 22 would increase the pressure throughout the interspace 29. Therefore, for monitoring it is it is sufficient to measure the pressure in a single point of the interspace 29.

In the case of a tank that is not buried or only partially buried, as already mentioned, the covering of the external wall 21 by means of the sheet metal pieces 30 can be limited only to the lower part of the lateral surface 11 and of the heads 12, 13, i.e. where there is is the risk of a leak to the ground. In this case, therefore, the inner wall 22 has a smaller extension than the outer wall 21 and forms an open shell instead of a closed shell; however, a gap 29 remains defined between the external wall 21 and the internal wall 22.

In a variant embodiment, the pieces of aluminum sheet 30 are provided with a layer 350 of glue 35 along the band or border region 34 before being introduced into the tank 1. In other words, each piece of sheet metal 30 is supplied with the layer 350 of glue 35 is already present, so that it is not necessary to distribute the glue 35 when the piece of sheet metal 30 is positioned inside the tank 1. The use of pieces of sheet metal 30 with already prepared glue 35 simplifies the work of the operators and reduces the time spent by operators inside tank 1.

If the glue 35 is of the bi-component type, a first component could be arranged on the edge region 33 of the first face 31 of the sheet metal piece 30 and a second component on the edge region 34 of the second face 32. In this way, during positioning with overlapping of the sheet metal pieces 30a, 30b, the first component on a sheet metal piece 30b would mix with the second component on the other sheet metal piece 30a to obtain the activation of the glue 35.

Similarly, the first face 31 of each piece of sheet metal 30 can also be provided with a layer 450 of glue or adhesive substance 45 (for fixing to the first wall 21) before being introduced into the tank 1, i.e. the piece of sheet metal 30 is supplied with the layer 450 of glue or adhesive substance 45 already prepared.

To protect the layer 350 of structural glue 35 and / or the layer 450 of glue or adhesive substance 45 before use, the layers 350, 450 are protected by respective removable films 355, 455, for example in plastic material.

For example, the pieces of sheet metal 30 are obtained by cutting from a coil 5 of aluminum sheet which is wound to form the coil 5 itself. The coil 5 has a layer 350 of structural glue 35 along its edge 54 and has a layer 450 of glue or adhesive substance 45 on a first face 51 of the sheet. Layers 350, 450 are protected by respective removable protective films 355, 455.

Each piece of sheet metal 30 cut from the reel 5 will therefore have an edge 34 provided with structural glue 35, which is a portion of the edge 54 of the reel 5, and a first face 31 provided with glue or adhesive substance 45, which is a portion of the first face 51 of the coil-wound sheet 5.

In variant embodiments, the reel 5 and / or the sheet metal pieces 30 are supplied prepared with only one of the two layers 350, 450 of glue or adhesive substance, i.e. only one of the two layers 350, 450 is already present before the introduction into the tank 1. The missing layer of glue or adhesive substance can be distributed during the process steps inside tank 1.

In embodiments of the present disclosure, the sheet metal pieces 30 are not fixed by glue or adhesive substance 45 to the inner face of the outer wall 21. Therefore, in these variants, the glue / adhesive substance 45 and the layer 450 are neither present. nor used.

The method according to the present disclosure can also be applied to a tank which was built with a double wall and in which one of the two walls has been damaged and no longer holds. The process is substantially similar to what has been described above, with the difference that in this case a further internal wall is created which covers the pre-existing internal wall. The pre-existing internal wall therefore represents the "first wall" of the description above, while the additional internal wall (made of pieces of glued metal sheet) represents the "second wall".

The object of the present disclosure has been described up to now with reference to its embodiments. It is to be understood that other embodiments may exist which pertain to the same inventive core, all falling within the protection scope of the claims set out below.

Claims (16)

CLAIMS 1. Method for making a second wall (22) in a tank (1) having a first wall (21) which encloses an internal chamber (18), comprising the steps of: - providing a plurality of pieces of metal sheet (30, 30a, 30b); - introducing this plurality of metal sheet pieces (30, 30a, 30b) into the internal chamber (18) of the tank (1); - arrange the pieces of metal sheet (30, 30a, 30b) next to each other to form an internal lining of the first wall (21); - join together the pieces of metal sheet (30, 30a, 30b) by means of a structural glue (35) suitable for creating a structural bond between the pieces of metal sheet (30, 30a, 30b), with obtaining a second wall ( 22) formed by pieces of metal sheet (30, 30a, 30b) glued together. Method according to claim 1, wherein said structural glue (35) has a shear tensile strength which is greater than 10 N / mm <2>. Method according to claim 1 or 2, wherein said pieces of metal sheet (30, 30a, 30b) are provided with a layer (350) of structural glue (35) which is arranged on at least one edge (33, 34) of each piece of metal sheet (30, 30a, 30b), said layer (350) of structural glue (35) being present on said at least one edge (33, 34) before introducing the piece of metal sheet (30, 30a , 30b) in the inner chamber (18). Method according to any one of the preceding claims, wherein each piece of metal sheet (30, 30a, 30b) is fixed to an inner face (211, 25) of the first wall (21) by means of a glue or an adhesive substance (45 ). Method according to claim 4, wherein a first face (31) of each piece of metal sheet (30, 30a, 30b) is provided with a layer (450) of glue or adhesive substance (45), said layer ( 450) of glue or adhesive substance (45) being present on said first face (31) before introducing the piece of metal sheet (30, 30a, 30b) into the internal chamber (18), said first face (31) being intended to be adjacent to the inner face (211, 25) of the first wall (21). Method according to claim 3 or 5, wherein, before introducing the piece of metal sheet (30, 30a, 30b) into the inner chamber (18), said layer (350, 450) of structural glue (35) and / or glue or adhesive substance (45) is protected by a removable film (355, 455). Method according to one of claims 3, 5 or 6, wherein the step of providing a plurality of sheet metal pieces (30, 30a, 30b) includes the sub-steps of: - providing a coil (5) of sheet metal, said coil (5) being provided with a layer (350) of structural glue (35) along at least one edge (54) of the coil (5) and / or being provided with a layer (450) of glue or adhesive substance (45) on a first face (51) of the metal sheet which is wound in a coil (5); - cutting said coil (5) into pieces, obtaining said plurality of pieces of metal sheet (30, 30a, 30b), each piece of metal sheet (30, 30a, 30b) having at least one edge (33, 34) provided a layer (350) of structural glue (35), which is a portion of said at least one edge (54) of the coil (5), and / or a first face (31) provided with a layer (450) of glue or of adhesive substance (45), which is a portion of said first face (51) of the coil-wound metal sheet. Method according to any one of the preceding claims, wherein, in the step of arranging the metal sheet pieces (30, 30a, 30b) next to each other, the metal sheet pieces (30, 30a, 30b) are partially overlapping each other in overlapping regions (37) along the edges (33, 34) of the metal sheet pieces (30, 30a, 30b), the structural glue (35) being interposed between the sheet metal pieces metallic (30a, 30b) in said overlapping regions (37). Method according to claim 8, wherein said pieces of metal sheet (30, 30a, 30b) have a knotty profile comprising a plurality of protuberances (40) protruding from a first face (31) of each piece of metal sheet (30 , 30a, 30b), said first face (31) being intended to be adjacent to an inner face (211, 25) of the first wall (21), each protuberance (40) having a convexity (401) protruding from the first face ( 31) and a corresponding concavity (402) sunk into a second face (32) opposite the first face (31), said protuberances (40) being intended to act as spacers to create a gap (29) between the first wall (21) and the second wall (22), in which, in the phase of arranging the pieces of metal sheet (30, 30a, 30b) partially overlapping each other, the convexities (401) of the protuberances (40) of a piece of metal sheet (30b) are inserted into the concavity (402) of the protuberances (40) of another piece of metal sheet (30b) in the respective overlapping region (37), the structural glue (35) being interposed between said convexity (401) and said concavity (402). 10. Use of a structural glue (35) to make a second wall (22) in a tank (1) having a first wall (21) which encloses an internal chamber (18), said structural glue (35) being used to join pieces of metal sheet (30, 30a, 30b) together to form a second wall (22) which internally covers the first wall (21). 11. Tank (1) having a first wall (21) and a second wall (22), in which the second wall (22) internally covers the first wall (21), the second wall (22) being formed by pieces of sheet metal metal (30, 30a, 30b) arranged next to each other, in which the pieces of metal sheet (30, 30a, 30b) are joined together by means of a structural glue (35) suitable for creating a structural bond between the pieces of metal sheet (30, 30a, 30b). Tank (1) according to claim 11, wherein each piece of metal sheet (30, 30a, 30b) is fixed to an inner face (211, 25) of the first wall (21) by means of a glue or an adhesive substance ( 45). Tank (1) according to claim 11 or 12, wherein the metal sheet pieces (30, 30a, 30b) are partially overlapped with each other in overlapping regions (37) along the edges (33, 34) of the pieces of metal sheet (30, 30a, 30b), the structural glue (35) being interposed between the pieces of metal sheet (30a, 30b) in said overlapping regions (37). Tank (1) according to claim 13, the second wall (22) being a shell in which the mechanical strength of the overlapping regions (37) joined with the structural glue (35) is comparable to or greater than the mechanical strength of the regions of non-overlapping metal sheet. Tank (1) according to any one of claims 11 to 14, wherein the second wall (22) formed by the metal sheet pieces (30, 30a, 30b) is fluid-tight, the structural glue (35) creating a fluid tight seal between one piece of metal sheet (30a) and the other piece of metal sheet (30b). Method, use or tank (1) according to any one of the preceding claims, wherein said pieces of metal sheet (30, 30a, 30b) are made of a ductile metal, in particular they are pieces of aluminum or aluminum alloy sheet. aluminum. CLAIMS 1. A method for making a second wall (22) inside a tank (1) having a first wall (21) which encloses an inner chamber (18), comprising the steps of: - providing a plurality of pieces of metal sheet (30, 30a, 30b); - introducing such a plurality of pieces of metal sheet (30, 30a, 30b) into the inner chamber (18) of the tank (1); - positioning the pieces of metal sheet (30, 30a, 30b) next to each other to form an inner lining of the first wall (21); - joining the pieces of metal sheet (30, 30a, 30b) to each other by means of a structural glue (35) adapted to provide a structural bonding between the pieces of metal sheet (30, 30a, 30b), to obtain a second wall (22) formed by pieces of metal sheet (30, 30a, 30b) glued together. 2. The method according to claim 1, wherein said structural glue (35) has a shear strength that is greater than 10 N / mm <2>. 3. The method according to claim 1 or 2, wherein said pieces of metal sheet (30, 30a, 30b) are provided with a layer (350) of structural glue (35) which is prearranged on at least one edge (33, 34 ) of each piece of metal sheet (30, 30a, 30b), said layer (350) of structural glue (35) being provided on said at least one edge (33, 34) before introducing the piece of metal sheet (30, 30a , 30b) into the inner chamber (18). 4. The method according to any one of the preceding claims, wherein each piece of metal sheet (30, 30a, 30b) is attached to an inner face (211, 25) of the first wall (21) by means of a glue or an adhesive substance (45). 5. The method according to claim 4, wherein a first face (31) of each piece of metal sheet (30, 30a, 30b) is provided with a layer (450) of glue or adhesive substance (45), said layer (450 ) of glue or adhesive substance (45) being provided on said first face (31) before introducing the piece of metal sheet (30, 30a, 30b) into the inner chamber (18), said first face (31) being intended to be adjacent to the inner face (211, 25) of the first wall (21). 6. The method according to claim 3 or 5, wherein, before introducing the piece of metal sheet (30, 30a, 30b) into the inner chamber (18), said layer (350, 450) of structural glue (35) and / or glue or adhesive substance (45) is protected by a removable film (355, 455). 7. The method according to one of claims 3, 5 or 6, wherein the step of providing a plurality of pieces of metal sheet (30, 30a, 30b) includes the sub-steps of: - providing a roll (5) of metal sheet, said roll (5) being provided with a layer (350) of structural glue (35) along at least one edge (54) of the roll (5) and / or being provided with a layer (450) of glue or adhesive substance (45) on a first face (51) of the metal sheet that is wound in a roll (5); - cutting said roll (5) into pieces, to obtain said plurality of pieces of metal sheet (30, 30a, 30b), each piece of metal sheet (30, 30a, 30b) having at least one edge (33, 34) provided with a layer (350) of structural glue (35), which is a portion of said at least one edge (54) of the roll (5), and / or a first face (31) provided with a layer (450) of glue or adhesive substance (45), which is a portion of said first face (51) of the roll-wound metal sheet. 8. The method according to any one of the preceding claims, wherein, in the step of positioning the pieces of metal sheet (30, 30a, 30b) next to each other, the pieces of metal sheet (30, 30a, 30b) are partially overlapped with each other in overlapping regions (37) along the edges (33, 34) of the pieces of metal sheet (30, 30a, 30b), the structural glue (35) being sandwiched between the pieces of metal sheet (30a, 30b) in said overlapping regions (37). 9. The method according to claim 8, wherein said pieces of metal sheet (30, 30a, 30b) have an embossed profile comprising a plurality of protuberances (40) protruding from a first face (31) of each piece of metal sheet (30 , 30a, 30b), said first face (31) being intended to be adjacent to an inner face (211, 25) of the first wall (21), each protuberance (40) having a convexity (401) that protrudes from the first face (31) and a corresponding concavity (402) sunk in a second face (32) opposite to the first face (31), said protuberances (40) being intended to act as spacers to create an interspace (29) between the first wall (21) and the second wall (22), wherein, in the step of positioning the pieces of metal sheet (30, 30a, 30b) partially overlapping each other, the convexities (401) of the protuberances (40) of a piece of metal sheet (30b) are inserted into the concavities ( 402) of the protuberances (40) of another piece of metal sheet (30b) in the respective overlapping region (37), the structural glue (35) being sandwiched between said convexities (401) and said concavities (402). 10. Use of a structural glue (35) to make a second wall (22) inside a tank (1) having a first wall (21) which encloses an inner chamber (18), said structural glue (35) being used to join together pieces of metal sheet (30, 30a, 30b) to form a second wall (22) that internally lines the first wall (21). 11. A tank (1) having a first wall (21) and a second wall (22), wherein the second wall (22) internally lines the first wall (21), the second wall (22) being formed by pieces of metal sheet (30, 30a, 30b) positioned next to each other, wherein the pieces of metal sheet (30, 30a, 30b) are joined together by a structural glue (35) adapted to provide a structural bonding between the pieces of metal sheet ( 30, 30a, 30b). 12. The tank (1) according to claim 11, wherein each piece of metal sheet (30, 30a, 30b) is attached to an inner face (211, 25) of the first wall (21) by means of a glue or an adhesive substance (45). 13. The tank (1) according to claim 11 or 12, in which the pieces of metal sheet (30, 30a, 30b) are partially overlapped with each other in overlapping regions (37) along the edges (33, 34) of the pieces of metal sheet (30, 30a, 30b), the structural glue (35) being sandwiched between the pieces of metal sheet (30a, 30b) in said overlapping regions (37). 14. The tank (1) according to claim 13, the second wall (22) being a shell in which the mechanical strength of the overlapping regions (37) joined together by the structural glue (35) is comparable or greater than the mechanical strength of the non-overlapping regions of metal sheet. 15. The tank (1) according to any one of claims 11 to 14, wherein the second wall (22) formed by the pieces of metal sheet (30, 30a, 30b) is fluid-tight, the structural glue (35) creating a fluid-tight seal between a piece of metal sheet (30a) and the other piece of metal sheet (30b). 16. Method, use or tank (1) according to any one of the preceding claims, wherein said pieces of metal sheet (30, 30a, 30b) are made of a ductile metal, in particular they are pieces of sheet of aluminum or aluminum alloy.