[0001] The present invention relates to an assembly for the formation of a modular tank
and its corresponding modular tank.
[0002] More precisely, the present invention relates to a tank for containing and storing
fluids, in particular water for domestic use.
[0003] Storing water is an established practice, which is put into practice where a shortage
or discontinuity occurs in the water supply. For doing that, containers are used,
made of various materials such as metals, polymers or agglomerates, which are generally
positioned close to the users, for storing and preserving water also for domestic
use.
[0004] Such tanks can be made of metallic materials, for example made of carbon steel and
subsequently galvanised or of stainless steel, and have a high structural strength,
but at the same time have a high weight and cost too. The same applies to containers
made of agglomerates, such as cement or asbestos cement (the latter now banned). Plastic
tanks have appeared on the scene for a few decades and spread thanks to their lightness
and low cost.
[0005] Plastic tanks can be made using different technologies such as injection, blow moulding
or rotational moulding, to name a few. Among these, rotational moulding is the one
requiring the lowest initial investments, as both the plant and the moulds for making
the various items cost less than the other two mentioned technologies. On the other
hand, the required level of detail of a rotationally moulded manufactured product
cannot be the same as that of a manufactured product made by injection moulding or
blow moulding. In the rotational moulding, the manufactured product is formed by gravity:
the mould subjected to a thermal cycle is rotated and the plastic powder contained
inside is distributed on the walls of the mould by gravity, forming the manufactured
product. In the injection moulding and blow moulding, the molten polymer, forced to
enter the mould, is forced to replicate the shapes of the mould itself, obtaining
a high level of detail. It is more difficult to be able to obtain more accurate detailed
shapes using the rotational technology.
[0006] Furthermore, since water storage tanks should store large quantities of water, they
have the drawback of being bulky. The incidence of transport plays a crucial role
on their final cost and on the environmental impact of such products. If for a stainless
steel tank the transport accounts for about 10%, rising to 25% for a galvanised carbon
steel tank, for plastic material tanks it reaches 50% of the final price of the manufactured
product bearing in mind the overall ecological footprint of the distribution.
[0007] To solve such issue, there are state-of-the-art modular tanks consisting of half-shells,
which, when disassembled during transport, are less bulky. Among the known solutions,
however, few of them focus on tanks for storing water, in particular water for domestic
use. Most of this type of tanks are underground tanks and have capacities exceeding
5000 litres. Regarding such tanks, any minimum leakage of the fluid contained inside
the tank cannot be appreciated by the end user due to the total accumulated volume
content and the positioning of the manufactured product.
[0008] The patent documents
US 7,854,338 and
US 8,740,005 describe manufactured products consisting of two half-shells, which are coupled together
by means of a mechanical block by interposing a gasket. Such manufactured products
consist of two exactly identical half-shells, obtained by injection moulding, making
it possible to invest in a single mould. However, in this way, the lower portion and
the upper portion are not optimised for the functions they should perform.
[0009] Furthermore, in such solutions it is envisaged to use pins for facilitating the assembly
of the half-shells and transmitting forces between the half-shells themselves, requiring
more time for assembling the half-shells.
[0010] As an alternative to the assembly techniques mentioned above, the joining of the
half-shells by welding is proposed in patent documents
US 10,723,080 and
US 10,696,448. This solution, although reliable, involves the use of expensive machinery requiring
skilled labour and also does not allow the tank to be disassembled once it has been
assembled. Furthermore, in case the welding should have discontinuities at any point,
the manufactured product cannot be used since it would have significant leakages of
the fluid contained therein. Furthermore, its assembly must be carried out by professionals
using dedicated equipment, which will affect its commercial distribution, in any case
already subjected to higher costs.
[0011] The assembly by welding is also mentioned in the patent document
US 10,427,356 B1 which describes the methods for assembling a vertically developed tank by means of
fusion welding. However, the described specific assembly method, in addition to being
laborious, requires a lot of precision for the following reasons:
- the tank, once assembled, must be tested using air to identify any leaks;
- in case of leaks, the repair would be quite expensive or even impracticable;
- the intersection area of the welding wires must be completely filled with molten material
to ensure the perimeter sealing of the entire flange;
- to guarantee that the entire flange is filled with molten material, the welding wires
must be positioned correctly and, above all, short circuits which could interrupt
the welding process without completing it correctly should be avoided;
- during the welding phase, a pressure must be applied to the entire perimeter of the
flanges to ensure that the welding process is successful; and
- the manufactured products made by injection moulding are welded with considerable
difficulty given their low thickness, and if made thicker they would be uneconomical.
[0012] Again, the patent document
US 4,333,580 describes the assembly of half-shells to form an underground housing for transformers,
generators, pumps or the like, which, however, is not suitable for containing fluids
since the upper and lower parts are opened or closed through a grid and since no gasket
is provided.
[0013] Finally, the patent document
DE 9416968 U1 describes a tank for accumulating rainwater comprising two half-shells which can
be coupled at a joint line. Each half-shell comprises a plurality of protuberances
adjacent to each other which alternate in opposite directions and which are arranged
in parallel and concordantly to the respective protuberances of the mutual half-shell
at the joint line. However, in this solution, in case of deformation, the tank would
tend to bulge on the joint line and, the mutual movement of the protuberances would
tend to make them slide one over the other, causing the gasket to lose its hydraulic
sealing. The exchange of reactions in this form is in fact concordant.
[0014] The aim of the present invention is to obtain a modular tank which is cheap to produce
and easy to assemble.
[0015] Furthermore, the aim of the present invention is to obtain a modular tank which has
a good hydraulic and mechanical sealing.
[0016] The object of the present invention is an assembly for the formation of a modular
tank for containing a fluid, said assembly comprising a first half-shell, and a second
half-shell, each half-shell providing a body having a bottom wall and side walls ending
in a terminal edge for coupling at a horizontal coupling plane with the terminal edge
of the other half-shell, said assembly further comprising a gasket which can be interposed
between said two half-shells at the terminal edges, and fastening means for securing
together said half-shells and preventing their movement along a vertical axis perpendicular
to the horizontal plane, each half-shell at the respective terminal edge providing
one or more protruding external flanges, each half-shell further providing a plurality
of vertical extensions arranged externally on the respective terminal edge projecting
along said vertical axis in an opposite direction to the body of the respective half-shell,
said assembly being characterised in that each vertical extension of each half-shell
has at least one portion parallel to said vertical axis, in that each half-shell provides
a plurality of housing seats, each housing seat being arranged externally on the respective
terminal edge and corresponding to the interspace between two vertical extensions
of the same half-shell, said interspace having no vertical extensions, and in that
said assembly is configured in such a way as to assume an assembled tank configuration
by coupling together said two half-shells with their respective terminal edges in
correspondence with said horizontal plane, arranging the vertical extensions of a
first half-shell alternately to the vertical extensions of the second half-shell and
so as to be projecting towards the mutual semi-shell in such a way that each vertical
extension of a half-shell fits into the respective interspace between two vertical
extensions of the mutual half-shell so as to be adjacent to the side wall of the body
of the mutual half-shell, interposing said gasket and securing together said one or
more protruding external flanges of the two half-shells by means of said fastening
means.
[0017] It is also the object of the present invention a modular tank for containing a fluid,
said modular tank comprising a first half-shell, and a second half-shell, each half-shell
providing a terminal edge for coupling at a horizontal coupling plane with the terminal
edge of the other half-shell, said tank further comprising a gasket that can be interposed
between said two half-shells at the terminal edges, and fastening means for securing
together said half-shells and preventing them from moving along a vertical axis perpendicular
to the horizontal plane, said modular tank being characterised in that each half-shell
at the respective terminal edge provides one or more protruding external flanges,
and in that each half-shell further provides a plurality of vertical extensions arranged
internally or externally on the respective terminal edge parallel to said vertical
axis, and a plurality of housing seats, each housing seat being arranged internally
or externally on the respective terminal edge between two vertical extensions, said
modular tank being configured in such a way as to assume an assembled configuration
by coupling together said half-shells with the respective terminal edges in correspondence
with said horizontal plane, arranging the vertical extensions of a first half-shell
alternately to the vertical extensions of the second half-shell and so as to be projecting
towards the mutual half-shell in such a way that each vertical extension of a half-shell
is fitted into the housing seat of the mutual half-shell, interposing said gasket
and securing together said one or more protruding external flanges of the two half-shells
by means of said fastening means.
[0018] In particular, according to the invention one or more holes can be obtained on said
one or more protruding external flanges for the passage of said fastening means for
securing together said half-shells.
[0019] Still according to the invention, each half-shell may comprise a plurality of protruding
external flanges, each protruding external flange having a flat surface substantially
parallel to the horizontal plane.
[0020] Always according to the invention, in each half-shell said plurality of protruding
external flanges can be arranged radially to a plane parallel to said horizontal plane
on the respective terminal edge, more particularly equidistantly on the perimeter
of the respective terminal edge.
[0021] In particular, according to the invention, each protruding external flange of a half-shell
can be spaced from the adjacent protruding external flange by such a distance that
when the modular tank is in its assembled configuration, each of the two side ends
of each protruding external flange of each half-shell overlaps a respective side end
of a protruding external flange of the mutual half-shell.
[0022] Further according to the invention, at least one half-shell may have one or more
protruding internal flanges.
[0023] Preferably according to the invention, each vertical extension of each half-shell
may be arranged on a respective protruding external flange of said plurality of protruding
external flanges or on a respective protruding internal flange of said plurality of
protruding internal flanges and each housing seat of the corresponding half-shell
may correspond to the interspace between two protruding external or internal flanges
of the same half-shell.
[0024] Alternatively, according to the invention, each vertical extension of each half-shell
can be arranged on the one protruding external flange or on the one protruding internal
flange of the same half-shell.
[0025] In particular, according to what claimed above, said plurality of vertical extensions
may be arranged radially to a plane parallel to said horizontal plane, in particular
equidistantly in correspondence with the perimeter of said single protruding external
flange or of said single protruding internal flange.
[0026] Further according to the invention, said plurality of vertical extensions may be
arranged radially to a plane parallel to said horizontal plane, in particular equidistantly
in correspondence with the perimeter of said single protruding external flange or
of said single protruding internal flange.
[0027] Still according to the invention, each housing seat of each half-shell may correspond
to the interspace between two vertical extensions of the same half-shell.
[0028] In particular, according to the invention, said plurality of vertical extensions
may be arranged radially to a plane parallel to said horizontal plane, in particular
equidistantly in correspondence with the perimeter of said single protruding external
flange or of said single protruding internal flange.
[0029] Always according to the invention, each housing seat of each half-shell may correspond
to the interspace between two vertical extensions of the same half-shell.
[0030] Furthermore, according to the invention, each vertical extension of each half-shell
may have a flat surface with vertical development, substantially parallel to the vertical
axis.
[0031] Still according to the invention, each half-shell may comprise a single protruding
external flange, each vertical extension of each half-shell may be arranged on the
respective protruding external flange and may be a shaped panel having a hooking portion,
said modular tank being configured in such a way that when said half-shells are coupled
together at the terminal edges, the respective shaped panels of a half-shell are interlocked
on the protruding external flange of the mutual half-shell at a respective housing
seat of the mutual half-shell.
[0032] In particular, according to the invention, each shaped panel of each half-shell may
have an "S"-shaped cross section and is configured in such a way that when the tank
is in its assembled configuration, a portion of said "S"-shaped section of the shaped
panel of a half-shell is arranged tangent to the external wall of the mutual half-shell.
[0033] Always according to the invention, a housing portion for said gasket may be obtained
at said terminal edge of at least one half-shell when said tank is in its assembled
configuration.
[0034] In particular, according to the invention, the gasket may have a regular section,
in particular a quadrangular or circular one.
[0035] Alternatively, according to the invention, a first half-shell may have an internal
abutting flange spaced from said terminal edge, the second half-shell may have an
"L"-shaped internal flange, when said two half-shells are coupled together said internal
abutting flange of the first half-shell and said "L"-shaped internal flange of the
second half-shell form said housing portion for said gasket.
[0036] More particularly, according to the invention, said gasket may have a "U"-shaped
cross section such as to be fitted into said "L"-shaped internal flange of the second
half-shell when the tank is assembled, wherein a first vertical wall of said gasket
is provided with a plurality of protuberances and is adapted to be fitted between
said "L"-shaped internal flange of the second half-shell and the internal wall of
said first half-shell when the tank is in its assembled configuration, and wherein
the upper wall of said gasket has a hollow internal portion such that, when the tank
is in its assembled configuration, it is in abutment and compressed between the internal
abutting flange of the first half-shell and the upper portion of the "L"-shaped internal
flange of the second half-shell.
[0037] Preferably according to the invention, said gasket may be a gasket of the FIPFG or
FIPG type, introduced in liquid phase into said housing portion obtained in one of
said two half-shells.
[0038] Furthermore, according to the invention, said tank may further comprise one or more
tie rods, at least one first half-shell may have a protruding internal flange provided
with a plurality of holes, when said tank is assembled, each tie rod couples to two
opposite sides of said protruding internal flange by means of fastening means in correspondence
with respective holes.
[0039] Preferably according to the invention, said fastening means may provide a plurality
of screws, each screw being adapted to pass through the respective holes, and said
fastening means may further provide a plurality of nuts and washers for locking said
screws in place.
[0040] Further according to the invention, said half-shells may have a flared internal shape
such as to allow half-shells of the same or different type to be stacked one inside
the other.
[0041] In particular, according to the invention, said tank may be made of polymeric material,
preferably polyethylene, or metallic material.
[0042] Preferably according to the invention, the extension along an axis parallel to the
vertical y-axis of each vertical extension of a half-shell is between five and six
times the thickness of the wall of such half-shell.
[0043] Still according to the invention, said one or more protruding flanges of each half-shell
may be integral with the wall of the respective half-shell, the vertical extensions
of each half-shell may be integral with the respective one or more external or internal
protruding flanges of the same half-shell.
[0044] Finally, according to the invention, the extension parallel to the terminal edge
of each vertical extension of a half-shell may be between two and ten times its height,
intended as the extension along an axis parallel to the vertical axis.
[0045] Modular tank obtained from the assembly described in its assembled tank configuration.
[0046] The invention will now be described for illustrative but non-limiting purposes, with
particular reference to the drawings of the attached figures, wherein:
Figure 1 shows a side cutaway view of a first embodiment of the modular tank obtained
through the assembly according to the invention;
Figure 2a shows a cutaway and front sectional view of the modular tank of Figure 1
along a plane passing through the y-axis;
Figure 2b shows the detail IIb of Figure 2a;
Figure 3 shows a side cutaway and exploded view of the modular tank of Figure 1, before
assembling the half-shells that compose it;
Figure 4a shows a cutaway and exploded front sectional view of the modular tank of
Figure 3 along a plane passing through the y-axis;
Figure 4b shows the detail IVb of Figure 4a;
Figure 5 shows a detailed perspective view of the modular tank of Figure 1, before
assembling the half-shells that compose it;
Figure 6 shows a detailed perspective view of the modular tank of Figure 1, after
assembling the half-shells;
Figure 7 shows a side cutaway view of a second embodiment of the modular tank obtained
through the assembly according to the invention;
Figure 8a shows a cutaway and front sectional view of the modular tank of Figure 7
along a plane passing through the y-axis;
Figure 8b shows detail VIIIb of Figure 8a;
Figure 9 shows a side cutaway and exploded view of the modular tank of Figure 7, before
assembling the half-shells that compose it;
Figure 10a shows a cutaway and exploded front sectional view of the modular tank of
Figure 9 along a plane passing through the y-axis;
Figure 10b shows the detail Xb of Figure 10a;
Figure 11 shows a detailed perspective view of the modular tank of Figure 7, before
assembling the half-shells that compose it;
Figure 12 shows a detailed perspective view of the modular tank of Figure 7, after
assembling the half-shells;
Figure 13 shows a side cutaway view of a third embodiment of the modular tank obtained
through the assembly according to the invention;
Figure 14a shows a cutaway and front sectional view of the modular tank of Figure
13 along a plane passing through the y-axis;
Figure 14b shows the detail XlVb of Figure 14a;
Figure 15 shows a side cutaway and exploded view of the modular tank of Figure 13,
before assembling the half-shells that compose it;
Figure 16a shows a cutaway and exploded front sectional view of the modular tank of
Figure 15 along a plane passing through the y-axis;
Figure 16b shows the detail XVIb of Figure 16a;
Figure 17 shows a detailed perspective view of the modular tank of Figure 13, before
assembling the half-shells that compose it;
Figure 18 shows a detailed perspective view of the modular tank of Figure 13, after
assembling the half-shells;
Figure 19 shows a detailed perspective and cutaway view of the modular tank of Figure
1, wherein the FEM analysis is depicted in grey scale;
Figure 20 shows a detailed perspective and cutaway view of the modular tank of Figure
19, without the vertical panels, wherein the FEM analysis is depicted in grey scale;
Figure 21a shows a cutaway and front sectional view of the modular tank of Figure
1 along a plane passing through the y-axis, comprising internal tie rods;
Figure 21b shows a cutaway and exploded front sectional view of the modular tank of
Figure 21a along a plane passing through the y-axis, before assembling the half-shells
that compose it;
Figure 22a shows the detail XXIIa of Figure 21a;
Figure 22b shows the detail XXIIb of Figure 21b;
Figure 23 shows a perspective cutaway view of the modular tank of Figure 21a;
Figure 24 shows a perspective cutaway view of the modular tank of Figure 21b;
Figures 25a and 25b respectively show a side view and a front view of a plurality
of first half-shells or upper half-shells of the modular tank of Figure 1 stacked
on one another for storage on a pallet; and
Figure 26 shows a front view of a plurality of second half-shells or lower half-shells
of the modular tank of Figure 1 stacked on one another for storage on a pallet.
[0047] With reference to Figures 1 - 6, a first embodiment of the assembly for the formation
of a modular tank according to the invention can be observed, indicated by the reference
number 10.
[0048] In the following, reference will be made directly to the modular tank obtained by
assembling different components of the assembly object of the invention.
[0049] Said modular tank 10 is preferably made of plastic material and consists of two half-shells
1, 2 which can be separated and assembled together.
[0050] The tank 10 could also be made of metallic material, even if more expensive. Preferably
polymeric materials are used, such as polyethylene (PE), preferably the tank 10 is
obtained using the rotational moulding technique. However, it can also be obtained
by injection moulding, or blow moulding, or other methods.
[0051] The tank 10 is preferably adapted to contain fluids, in particular liquids such as
water, preferably water for domestic use. The tank 10 consists of two portions, or
half-shells, an upper half-shell 1 and a lower half-shell 2, designed to be stackable,
which couple together on two specially made surfaces, between which a gasket 4 is
interposed, and which become integral with each other. This solution makes it possible
to considerably reduce the cost for transporting the manufactured products thanks
to the stackability of the half-shells, optimising the spaces intended for loads and
reducing the environmental impact of this phase of the manufactured product's life
cycle.
[0052] In particular, as can be seen in Figures 25a, 25b and 26, when they are transported
or stored for transport, a plurality of first half-shells 1 stacked on one another
and a plurality of second half-shells 2 stacked on one another are arranged.
[0053] In particular, each half-shell 1, 2 has a flared internal shape, so as to allow one
half-shell to be stacked inside the other. Each half-shell 1, 2 has side walls and
a bottom wall, which can be the upper or lower one according to the position of the
half-shell in the tank when assembled.
[0054] In some embodiments the two half-shells can be identical or distinct.
[0055] In particular, said tank 10 comprises a first half-shell or upper half-shell 1 and
a second half-shell or lower half-shell 2.
[0056] Half-shells mean two portions of a shell, in this case a tank, which are adapted
to protect the contents once they are coupled together. Such half-shells are provided
with side walls and a connecting upper or lower wall. The upper half-shell is generally
equipped with openings for accessing the contents, while the lower half-shell is generally
equipped with a flat portion or legs for resting on the ground.
[0057] In the present text, reference is made to outdoor tanks for the storage of liquids,
in particular water for domestic use.
[0058] Said modular tank 10 according to the invention also provides coupling means for
coupling said two half-shells 1 and 2.
[0059] In particular, said two half-shells 1 and 2 couple together at a coupling terminal
edge 11 or 21, corresponding to the lower edge 11 of the upper half-shell 1 and to
the upper edge 21 of the lower half-shell 2.
[0060] Said half-shells 1 and 2 couple together at said terminal edges 11, 21 along a horizontal
coupling X-plane. Furthermore, the assembly between said half-shells 1, 2 takes place
parallel to a vertical y-axis, transversal to said horizontal X-plane.
[0061] The solution according to the invention provides a fastening system for constraining
the two half-shells 1, 2 on the vertical y-axis, allowing a gasket 4 to maintain a
hydraulic sealing by its compression, and a constraint system along the X-plane which
makes it possible to reduce the rotations caused by the hydrostatic thrust and the
consequent separation of the half-shells which would cause the gasket 4 to lose compression
and, consequently, cause the hydraulic sealing to fail.
[0062] A gasket 4 is in fact interposed between the first half-shell 1 and the second lower
half-shell 2 for the hydraulic sealing of the modular tank 1, once assembled and filled
with the fluid to be stored.
[0063] The internal portions of said half-shells 1, 2 of said two coupling edges 11 and
21, in other words the portions which will come into contact with the fluid to be
contained, are shaped in such a way as to form an internal seat 3 for housing the
gasket 4.
[0064] The geometry of the gasket 4 is such as to make it possible to obtain the hydraulic
sealing once the mechanical assembly process between the two half-shells 1 and 2 has
been completed. In fact, once the two half-shells 1 and 2 are mechanically coupled,
a force on the coupling flanges 12, 22 such as to compress the gasket 4 and guarantee
the sealing will be obtained.
[0065] With particular reference to Figure 2b, it can be observed that in the specific embodiment,
a first half-shell 1, in particular the upper half-shell 1, has an internal abutting
flange 14 spaced from the respective terminal edge 11. In particular, said internal
abutting flange 14 is located in the internal part of the concavity of the half-shell
1.
[0066] The second half-shell 2, on the other hand, has an "L"-shaped internal flange 24
which departs from the respective terminal edge 21. When the two half-shells 1, 2
are coupled together, the internal abutting flange 14 of the first half-shell 1 and
the "L"-shaped internal flange 24 of the second half-shell 2 form said housing portion
3 for the gasket 4.
[0067] Furthermore, as can be always seen from Figure 2b, the gasket 4 has a "U"-shaped
cross section such as to fit onto said "L"-shaped internal flange 24 of the second
half-shell 2. As can be seen, such "U"-shaped gasket 4 therefore has two side walls
41, 45 and an upper wall 43.
[0068] Again, a first vertical wall 41 of the gasket 4 is provided with a plurality of protuberances
42 and is adapted to be fitted between said "L"-shaped internal flange 24 of the second
half-shell 2 and the internal wall of the first half-shell 1 when the tank 10 is in
its assembled configuration. Finally, the upper wall 43 of the gasket 4 has an internal
hollow portion 44 such that, when the tank 10 is in its assembled configuration, it
is in abutment and compressed between the internal abutting flange 14 of the first
half-shell 1 and the upper portion of the "L"-shaped internal flange 24 of the second
half-shell 2.
[0069] In particular, such internal hollow portion 44 will be compressed, guaranteeing the
sealing thanks to the action of the internal abutting flange 14 and to the opposition
of the "L"-shaped internal flange 24.
[0070] The study of the shapes of the tank 10 is functional to guarantee a greater seal
of the gasket 4 as the hydrostatic thrust acting on the walls of the tank 10 itself
increases.
[0071] In particular, the gasket 4 has a section functional for the purpose and made using
the most common manufacturing processes such as moulding or extrusion processes. Alternatively,
a closed-cell gasket having a regular section, for example a rectangular or circular
one, can be used. In both cases, the higher the thrust on the tank walls, the more
the gasket is compressed. In this way, the sealing is guaranteed in any operating
condition.
[0072] An alternative is the use of a liquid gasket which, during the polymerisation phase,
forms a closed-cell foam. In this case the geometry of the gasket will be dictated
by the shape of the seat on which the gasket itself will be deposited.
[0073] In particular, the liquid gasket may be of the FIPFG (formed in place foam gasket)
type, due to its main characteristic of being in a very viscous liquid state, it tends
to fill the shape that is available (seat) and, in contact with the air, begins to
polymerise forming a closed-cell foam. In this way there is a good filling of the
seat using a material which is able to fulfil the hydraulic sealing tasks in the best
possible way.
[0074] As an alternative, the liquid gasket may be of the FIPG (formed in place gasket)
type, due to its main characteristic of being in a very viscous liquid state, it tends
to fill the shape that is available (seat) and, in contact with the air, begins to
polymerise forming a compact bead. In this way there is a good filling of the seat
using a material which is able to fulfil the hydraulic sealing tasks in the best possible
way.
[0075] Each half-shell 1 or 2 also has, at the external portion of the respective terminal
edge 11 or 21, a plurality of protruding flanges 12 or 22, in particular toothed portions
12, 22 protruding from the external body of the half-shells 1, 2. Each protruding
flange 12, 22 has a flat surface substantially parallel to the horizontal coupling
X-plane.
[0076] In particular, said plurality of protruding flanges 12, 22 is arranged radially to
a plane parallel to said horizontal X-plane on the respective terminal edge 11, 21,
more particularly equidistantly on the perimeter of said terminal edges 11, 21.
[0077] Each protruding flange 12, 22 of a half-shell 1, 2 is spaced from the following flange
of the same half-shell 1, 2 by such a distance that each of its two side ends overlaps
a respective side end of a protruding flange 22, 12 of the other half-shell 2, 1.
[0078] The modular tank 10 therefore provides coupling means for coupling together the protruding
flanges 12, 22 of the two half-shells 1, 2.
[0079] In the embodiment shown in the figures, with particular reference to Figures 5 and
6, it can be observed that at the side ends of each flange 12, 22 there are respective
holes 5 arranged in such a way as to allow the passage of suitable screws 6, each
screw 6 being adapted to pass through the holes 5 obtained in the free ends of a pair
of flanges 12, 22, respectively a flange 12 of the first half-shell 1 and a flange
22 of the second half-shell 2. Such screws 6 can be locked in place by means of bolted
joints, in particular by means of nuts 7 and washers 8.
[0080] Such coupling means make it possible to create a simple and reliable mechanical block
in the external part of the tank 10, avoiding the separation of the two half-shells
1 and 2 and acting on the gasket 4 positioned in the internal seat 3 by applying an
initial compression.
[0081] Each flange 12, 22 is provided with a respective vertical extension 13, 23, in particular
an external panel 13, 23, in particular having a flat surface with vertical development,
substantially parallel to the vertical y-axis.
[0082] The external panels 13 of the first half-shell 1 are arranged on the face of the
respective flange 12 facing the second half-shell 2, and the flat panels 23 of the
second half-shell 2 are arranged on the face of the respective flange 22 facing the
first half-shell 1, in such a way that when the half-shells 1, 2 are assembled together,
the external panels 13, 23 of a half-shell 1, 2 are adjacent to the external wall
of the body of the other half-shell 2, 1. Such external panels 13, 23 make it possible
to limit the deformations induced on the coupling area, caused by the hydrostatic
thrust, which could cause a loss of compression at the terminal edges 11 and 21 and
at the gasket 4 positioned in the seat 3 with consequent leakage of the fluid contained
inside the tank 10.
[0083] In the area of a half shell 1, 2 where the external panels 23, 13 of the mutual half
shell 2, 1 are located, they act in such a way that the tank 10 is as if it were twice
as thick as the wall thickness of each half-shell 1, 2.
[0084] In fact, when the tank 10 is assembled, the external panels 12, 13 of a half-shell
1, 2 are arranged in such a way as to be adjacent and substantially tangent to the
wall of the mutual half-shell 2, 1.
[0085] This makes it possible to increase the resistance in the coupling area between the
half-shells 1, 2.
[0086] In this way, both half-shells 1, 2 offer resistance to bulging by limiting the deformations
on the mutual half-shell 1, 2 and therefore guaranteeing an optimal hydraulic sealing.
In the area where the external panels act, we can consider the manufactured product
as if it were twice as thick as the initial thickness. In this area, the reactions
are opposite since the bulging of a half-shell 1 or 2 is limited by the mutual half-shell
2 or 1 and vice versa.
[0087] In particular, such external panels 13, 23 have an extension along the vertical y-axis
such as to act on the wall of the mutual half-shell 2, 1 having a linear development
and arranged immediately after the external flange, before the curvature of the half
shell 2, 1.
[0088] If the tank 10 is made of polyethylene, since such material does not lend itself
to flat shapes due to its poor mechanical properties, the extension of the linear
portion is limited, otherwise high deformations would occur.
[0089] Preferably, the extension in height, intended as the extension along an axis parallel
to the vertical y-axis of each vertical extension 13, 23 may be between five and six
times the thickness of the wall of the same half-shell 1, 2.
[0090] As regards the extension in width of each vertical extension 13, 23 of a half-shell
1, intended as the extension parallel to the terminal edge 11, 21 of each vertical
extension 13, 23, it may be between two and three times its height along an axis parallel
to the vertical y-axis.
[0091] Like the flanges 12, 22 on which they are arranged, the external panels 13, 23 have
a discontinuous and alternating pattern, so as to offer resistance to deformations
by limiting the stresses on the mutual half-shell 2, 1.
[0092] In particular, between two flanges 12, 22 of the same half-shell 1, 2 an interspace
is created which acts as a housing seat for the vertical extension 23, 13 of the mutual
half-shell 2, 1. Said modular tank 10 is therefore configured in such a way as to
assume an assembled configuration by coupling together said half-shells 1, 2 with
the respective terminal edges 11, 21 in correspondence with said horizontal X-plane,
arranging the vertical extensions 13, 23 of a first half-shell 1, 2 alternately to
the vertical extensions 23, 13 of the second half-shell 2, 1 and so as to be projecting
towards the mutual half-shell 2, 1 in such a way that each vertical extension 13,
23 of a half-shell 1, 2 fits into the respective interspace of the mutual half-shell
2, 1, interposing said gasket 4 and securing together said one or more protruding
external flanges 12, 22 of the two half-shells 1, 2 by means of said fastening means
6, 7, 8.
[0093] The use of the external panels 13, 23 makes it possible to align and exchange mutual
forces between the half-shells 1, 2, creating continuity on the whole circumference
of the tank 10. Another aspect which should not be underestimated is the effectiveness
of the exchange of rheonomic constraints, given by the external panels 13, 23 which
act as continuous protrusions of the half-shell 1, 2 towards the opposite half-shell
2, 1 and are not elements added at a later stage, such as the pins used in known technical
solutions.
[0094] Furthermore, the centring and alignment of the half-shells 1, 2 is made easier for
the end user as, the external panels being visible, he/she is able to evaluate if
he/she is carrying out the operations in a workmanlike manner.
[0095] The solution according to the invention makes it possible to obtain systems suitable
for joining the parts in terms of quality and practicality thanks to the gasket for
an optimal hydraulic sealing, and thanks to the mechanical fastening system.
[0096] Generally speaking, the two half-shells 1, 2 are coupled in the middle along the
horizontal X-plane and in this area there is a flat horizontal part parallel to the
ground on which holes 5 are obtained to accommodate clamping screws 6 arranged along
the perimeter of the tank 10. Furthermore, the section of the area where the two half-shells
1, 2 are coupled, and the area where the gasket 4 is positioned, has been designed
in such a way as to avoid the rotation caused by the hydrostatic thrust of the flanged
part 12, 22. For this reason shapes have been exploited which tend to offer an opposite
reaction to the rotation caused by the hydrostatic thrust.
[0097] For this purpose, there are external abutment panels 13, 23 on the external part
of the half-shells 1, 2. The function of these panels 13, 23, considering that they
also act as appendages of a half-shell 1, 2 providing resistance to the opposite half-shell
2, 1, is to minimise the rotations of the flanged part. The area where the external
panels 13, 23 act can be seen as if it were twice as thick as the initial thickness
of the tank 10.
[0098] The external panels 13, 23 also have the function of facilitating the alignment between
the two half-shells 1, 2 during the assembly and installation phase.
[0099] Furthermore, since the tank 10 is to be installed above ground, it has been developed
in such a way that minimal fluid leakages do not occur in the area where the half-shells
1, 2 are coupled.
[0100] Furthermore, as shown for the modular tank 10 of Figures 21a - 24, to further reduce
the deformations on the horizontal X-plane, it could be possible to use tie rods 9
placed in the internal part of the modular tank 10 when assembled. Suitable seats
5 can be made on the internal flange 14, whose aim is to accommodate bolted joints,
formed by screws 6, nuts 7 and washers 8, and to make the tie rod 9, preferably made
of the same material as the tank 10, integral with the internal flange 14 itself.
[0101] In this way, as already stated, the horizontal thrusts and therefore the deformations
caused by the hydrostatic thrust of the fluid contained inside the tank 10 itself
are further and advantageously limited. This further solution for stiffening the tank
10 can be extended to all the embodiments described below.
[0102] Referring to Figures 7 - 12, a second embodiment of the modular tank according to
the invention can be observed, always indicated by the reference number 10.
[0103] The tank 10 of the second embodiment is similar to the one previously described and
therefore the common elements are not described and have the same reference numbers.
[0104] The second embodiment of the tank 10 according to the invention differs from the
one previously described, in particular referring to Figure 1, in that each half-shell
1, 2 has a smaller number of flanges 12, 22. Such flanges 12, 22, however, have a
greater perimeter extension.
[0105] Consequently also the vertical extensions 13, 23, in particular the external panels
13, 23, of each half-shell 1, 2 have a greater width. In particular, the width of
each external panel 13, 23, intended as the extension parallel to the terminal edge
11, 21 of the respective half-shell 1, 2, is eight or ten times the extension in height
of the vertical extension 13, 23 itself, intended as the extension along an axis parallel
to the vertical y-axis.
[0106] The smaller number of flanges 12, 22 entails a smaller number of screws and bolts,
and makes it possible to reduce the time for assembling the half-shells 1, 2 while
guaranteeing the structural strength and the hydraulic sealing which characterise
the invention.
[0107] Furthermore, as can be seen in particular from Figures 8b and 10b, at the terminal
edge 11, 21 of each half-shell 1, 2 it is provided a continuous seat 3, in particular
having a semicircle section, for housing the gasket (not shown in the figure).
[0108] In particular, at each terminal edge 11, 21 it is provided an internal flange 15,
25 which continues along the entire respective terminal edge 11, 21.
[0109] As hinted above, the modular tank 10 according to the second embodiment is advantageously
cheaper and requires a reduced installation time, given the smaller number of screws.
However, the resistance at the flanged part is lower and the deformations are higher.
[0110] Figures 13 - 18 show a third embodiment of the modular tank 10 according to the invention.
[0111] The tank 10 of the third embodiment is similar to those previously described and
therefore the common elements will not be described and have the same reference numbers.
[0112] The third embodiment of the tank 10 according to the invention differs from the second
embodiment in that each half-shell 1, 2 has a single external flange 16, 26 which
is continuous along the perimeter of the respective terminal edge 11, 21 and projecting
towards the outside of the body of the respective half-shell 1, 2. In particular,
each external flange 16, 26 has a flat surface substantially parallel to the horizontal
X-plane. On each external flange 16, 26 there is a plurality of through holes 5, arranged
so as to allow the passage of respective screws 6 for coupling together the two half-shells
1, 2.
[0113] At each external flange 16, 26 there is a plurality of vertical extensions 17, 27,
in particular, said vertical extensions are shaped external panels 17, 27. Said shaped
panels 17, 27 of a half-shell 1, 2 are arranged radially to a plane parallel to said
horizontal X-plane on the respective external flange 16, 26, so as to leave empty
spaces and are arranged alternately to the shaped panels 27, 17 of the other half-shell
2, 1.
[0114] Furthermore, each shaped panel 17 of the first half-shell 1 is arranged on the face
of the external flange 16 facing the second half-shell 2, and each shaped panel 27
of the second half-shell 2 is arranged on the face of the respective external flange
26 facing the first half-shell 1, in such a way that when the half-shells 1, 2 are
assembled together, the shaped panels 17, 27 of a half-shell 1, 2 are located adjacent
to the external wall of the body of the other half-shell 2, 1, fitted into the empty
spaces of the mutual half-shell 2, 1. Such empty spaces correspond to the interspace
between two adjacent shaped panels 17, 27 of the same half-shell 1, 2.
[0115] In particular, as can be seen in Figure 14b, said shaped panels 17, 27 have an "S"-shaped
cross section and are configured in such a way that when said modular tank 10 is in
its assembled configuration, the shaped panels 17, 27 of each half-shell 1; 2 are
interlocked on the protruding external flange 26; 16 of the mutual half-shell 2; 1.
More specifically, a first portion or first curve of the "S"-shaped section of the
shaped panel 17, 27 of a half-shell 1, 2 is therefore adjacent to the external wall
of the mutual half-shell 2, 1 and the other portion or second curve of the "S"-shaped
section of the shaped panel 17, 27 of a half-shell 1, 2 is adjacent to the external
edge of the protruding external flange 26; 16 of the mutual half-shell 2, 1. In other
words, the "S"-shaped section of the shaped panel 17, 27 hooks the protruding flange
of the mutual half-shell.
[0116] Such shaped panels 17, 27 are adapted to limit the deformations induced on the coupling
area, caused by the hydrostatic thrust, which could cause a loss of compression at
the terminal edge 11 or 21 and at the gasket positioned in the seat 3 with consequent
leakage of the fluid contained inside the tank 10.
[0117] The particular geometry of the shaped panels 17, 27 also makes it possible to have
a resistance on the vertical y-axis given that the external flange 16, 26 of a half-shell
1, 2 intersects with the shaped panel 27, 17 of the mutual half-shell 2, 1.
[0118] In this way, both half-shells 1, 2 offer resistance to bulging by limiting the deformations
on the mutual half-shell 1, 2 and therefore guaranteeing an optimal hydraulic sealing.
In the area where the shaped panels act, we can consider the manufactured product
as if it were twice as thick as the initial thickness. In such area, opposite reactions
occur since the bulging of a half-shell 1 or 2 is limited by the mutual half-shell
2 or 1 and vice versa.
[0119] The particular geometry of the shaped panels 17, 27 makes it possible to fit the
upper half-shell 1 and the lower half-shell 2 by exploiting the elastic component
of the material constituting the two parts of the tank 10 in order to pass the external
flanges 16 and 26 by the free end of the shaped panel itself 17 or 27 and at the same
time, once the half-shells 1 and 2 come into contact, makes it possible to accommodate
the external flanges 16 and 26. The operation of fitting the half-shells 1 and 2 may
occur by simple pressure and then, once the half-shells 1 and 2 come into contact,
the bolted joints can be installed.
[0120] Advantageously, the solution according to the present invention allows the two half-shells
1, 2 to be coupled in such a way as to have an excellent mechanical and hydraulic
sealing.
[0121] Furthermore, the solutions described according to the present invention make it possible
to make the coupling of the half-shells 1, 2 simple and reliable.
[0122] Advantageously, the fastening means between the half-shells of the tank do not have
added pins or mechanical inserts, using conventional fastening means such as screws
and bolts. This makes it possible to reduce the assembly time of the half-shells,
which can also be performed by non-professional personnel.
[0123] Due to the poor mechanical properties of the polymers used, to increase the resistance
of the manufactured products it was decided to work on the geometry of the manufactured
product so as to exploit certain shapes for increasing the resistance in the areas
subjected to the greatest stresses.
[0124] The tanks according to one of the described embodiments are suitable for being manufactured
using the rotational moulding technique, or even using the injection or blow moulding
techniques; thanks to the simplicity of the shapes, the material is able to flow freely
inside the mould, replicating its shape in the best possible way. The total absence
of undercuts will also allow an extremely simple extraction of the piece from the
mould.
[0125] Furthermore, another advantage of the tank according to the invention is the intrinsic
stiffness which makes it possible to have a high localised stiffness, limiting as
much as possible the deformations of the coupling area. Should the hydrostatic thrust
induce bending moments on the walls of the tank, the presence of external or internal
extensions makes it possible to hinder the induced rotations given that the wall of
a half-shell rests on the opposite half-shell offering resistance to deformations
through the exchange of mutual interactions. Thanks to the geometry of the manufactured
product, this phenomenon is present along the entire perimeter of the coupling area
and the resistance can be considered uniform. Studies carried out using a finite element
analysis (FEM) confirmed the described behavior: the same manufactured product with
(Figure 19) and without (Figure 20) the internal or external extensions presents a
deformation induced by the bending moment which is generated because of the totally
different hydrostatic thrust: present in the manufactured product without the aforementioned
extensions and absent in the manufactured product where the extensions are present.
[0126] As can be seen from Figures 19 and 20, the area where there is a darker shade of
grey corresponds to the regions where the deformation is greater, compared to the
areas with a lighter shade of gray. As can be seen, the darkest area is wider in the
version without the vertical walls of Figure 20.
[0127] In the foregoing the preferred embodiments have been described and variants of the
present invention have been suggested, but it should be understood that those skilled
in the art will be able to make modifications and changes without thereby departing
from the corresponding scope of protection, as defined by the attached claims.
1. An assembly (10) for the formation of a modular tank (10) for containing a fluid,
said assembly (10) comprising a first half-shell (1), and a second half-shell (2),
each half-shell (1; 2) providing a body having a bottom wall and side walls ending
in a terminal edge (11; 21) for coupling at a horizontal coupling plane (X) with the
terminal edge (21; 11) of the other half-shell (2; 1), said assembly (10) further
comprising a gasket (4) that can be interposed between said two half-shells (1, 2)
at the terminal edges (11, 21), and fastening means (6, 7, 8) for securing together
said half-shells (1, 2) and preventing their movement along a vertical axis (y) perpendicular
to the horizontal plane (X), each half-shell (1; 2) at the respective terminal edge
(11, 21) providing one or more protruding external flanges (12; 16; 22; 26), each
half-shell (1; 2) further providing a plurality of vertical extensions (13; 17; 23;
27) arranged externally on the respective terminal edge (11; 21) projecting along
said vertical axis (y) in an opposite direction to the body of the respective half-shell
(1; 2), said assembly (10) being characterised in that each vertical extension (13; 17; 23; 27) of each half-shell (1; 2) has at least one
portion parallel to said vertical axis (y), in that each half-shell (1; 2) provides a plurality of housing seats, each housing seat being
arranged externally on the respective terminal edge (11; 21) and corresponding to
the interspace between two vertical extensions (13; 17; 23; 27) of the same half-shell
(1; 2), said interspace having no vertical extensions, and in that said assembly (10) is configured in such a way as to assume an assembled tank configuration
by coupling together said two half-shells (1, 2) with their respective terminal edges
(11, 21) in correspondence with said horizontal plane (X), arranging the vertical
extensions (13; 17; 23; 27) of a first half-shell (1; 2) alternately to the vertical
extensions (23; 27; 13; 17) of the second half-shell (2; 1) and so as to be projecting
towards the mutual half-shell (2; 1) in such a way that each vertical extension (23;
27; 13; 17) of a half-shell (1; 2) fits into the respective interspace between two
vertical extensions (23; 27; 13; 17) of the mutual half-shell (2; 1) so as to be adjacent
to the side wall of the body of the mutual half-shell (2; 1), interposing said gasket
(4) and securing together said one or more protruding external flanges (12; 16; 22;
26) of the two half-shells (1, 2) through said fastening means (6, 7, 8).
2. The assembly (10) according to the preceding claim, wherein one or more holes (5)
are obtained on said one or more protruding external flanges (12; 16; 22; 26) for
the passage of said fastening means (6, 7, 8) for securing together said half-shells
(1, 2).
3. The assembly (10) according to claim 1 or 2, wherein each half-shell (1; 2) comprises
a plurality of protruding external flanges (12; 22), each protruding external flange
(12; 22) having a flat surface substantially parallel to the horizontal plane (X).
4. The assembly (10) according to the preceding claim, wherein in each half-shell (1;
2) said plurality of protruding external flanges (12, 22) is arranged radially to
a plane parallel to said horizontal plane (X) on the respective terminal edge (11,
21), more particularly equidistantly on the perimeter of the respective terminal edge
(11, 21).
5. The assembly (10) according to claim 3 or 4, wherein each protruding external flange
(12; 22) of a half-shell (1; 2) is spaced from the adjacent protruding external flange
(12; 22) by a distance such that when the assembly (10) is in its assembled tank configuration,
each of the two side ends of each protruding external flange (12; 22) of each half-shell
(1; 2) overlaps a respective side end of a protruding external flange (22; 12) of
the mutual half-shell (2, 1).
6. The assembly (10) according to any one of the preceding claims, wherein each vertical
extension (13; 23) of each half-shell (1; 2) is arranged on a respective protruding
external flange (12; 22) of said plurality of protruding external flanges (12; 22)
and wherein each housing seat of the corresponding half-shell (1; 2) further corresponds
to the interspace between two protruding external flanges (12; 22) of the same half-shell
(1; 2).
7. The assembly (10) according to any one of the preceding claims, wherein each vertical
extension (13; 23) of each half-shell (1, 2) has the entire flat surface with vertical
development, parallel to the vertical axis (y).
8. The assembly (10) according to any one of claims 1 or 2, wherein each half-shell (1;
2) comprises a single protruding external flange (16; 26), wherein each vertical extension
(17; 27) of each half-shell (1; 2) is arranged on the respective protruding external
flange (16; 26) and is a shaped panel (17; 27) having a hooking portion, said assembly
(10) being configured in such a way that when said half-shells (1; 2) are coupled
together at the terminal edges (11; 21) the respective shaped panels (17; 27) of a
half-shell (1; 2) are interlocked on the protruding external flange (26; 16) of the
mutual half-shell (2; 1) at the respective interspace between two vertical extensions
(27; 17) of the mutual half-shell (2; 1).
9. The assembly (10) according to the preceding claim, wherein each shaped panel (17;
27) of each half-shell (1; 2) has an "S"-shaped cross-section and is configured in
such a way that when the assembly (10) is in its assembled tank configuration, the
portion parallel to said vertical axis (y) of said "S"-shaped section of the shaped
panel (17; 27) of each half-shell (1; 2) is arranged externally tangent to the side
wall of the body of the mutual half-shell (2; 1).
10. The assembly (10) according to any one of the preceding claims, wherein a housing
portion (3) is obtained at said terminal edge (11; 21) of at least one half-shell
(1; 2) for housing said gasket (4) when said assembly (10) is in its assembled tank
configuration.
11. The assembly (10) according to claim 10, wherein a first half-shell (1) has an internal
abutting flange (14) spaced from said terminal edge (11), wherein the second half-shell
(2) has an "L"-shaped internal flange (24), wherein when said two half-shells (1,
2) are coupled together said internal abutting flange (14) of the first half-shell
(1) and said "L"-shaped internal flange (24) of the second half-shell (2) form said
housing portion (3) for said gasket (4).
12. The assembly (10) according to the preceding claim, wherein said gasket (4) has a
"U"-shaped cross section such as to be fitted onto said "L"-shaped internal flange
(24) of the second half-shell (2) when the assembly (10) is assembled, wherein a first
vertical wall (41) of said gasket (4) is provided with a plurality of protuberances
(42) and is adapted to be fitted between said "L"-shaped internal flange (24) of the
second half-shell (2) and the internal wall of said first half-shell (1) when the
assembly (10) is in its assembled tank configuration, and wherein the upper wall (43)
of said gasket (4) has an internal hollow portion (44) such that, when the assembly
(10) is in its assembled tank configuration, it is in abutment and compressed between
the internal abutting flange (14) of the first half-shell (1) and the upper portion
of the "L"-shaped internal flange (24) of the second half-shell (2).
13. The assembly (10) according to claim 10, wherein said gasket is a gasket of the FIPFG
or FIPG type, introduced in liquid phase into said housing portion (3) obtained in
one of said two half-shells (1; 2).
14. The assembly (10) according to any one of the preceding claims, wherein said assembly
(10) further comprises one or more tie rods (9), wherein at least one first half-shell
(1) has a protruding internal flange (14) provided with a plurality of holes (5),
wherein when said assembly (10) is assembled each tie rod (9) is coupled to two opposite
sides of said protruding internal flange (14) by means of fastening means (6, 7, 8)
at respective holes (5).
15. The assembly (10) according to any one of the preceding claims, when depending on
claim 2 or 14, wherein said fastening means provide a plurality of screws (6), each
screw (6) being adapted to pass through the respective hole (5), and wherein said
fastening means further provide a plurality of nuts (7) and washers (8) for locking
said screws (6) in place.
16. The assembly (10) according to any one of the preceding claims, wherein the body of
each of said half-shells (1, 2) has a flared internal shape such as to allow half-shells
(1; 2) of the same or different type to be stacked one inside the other.
17. The assembly (10) according to any one of the preceding claims, wherein said assembly
(10) is made of polymeric material, preferably polyethylene.
18. The assembly (10) according to any one of the preceding claims, wherein the extension
along an axis parallel to the vertical axis (y) of each vertical extension (13; 17;
23; 27) of a half-shell (1; 2) is between five and six times the thickness of the
wall of such half-shell (1; 2).
19. The assembly (10) according to any one of the preceding claims, wherein said one or
more protruding flanges (12; 16; 22; 26) of each half-shell (1; 2) are integral with
the wall of the respective half-shell (1; 2), wherein the vertical extensions (13;
17; 23; 27) of each half-shell (1; 2) are integral with the respective one or more
protruding external flanges (12; 16; 22; 26) of the same half-shell (1; 2).
20. The assembly (10) according to any one of the preceding claims, wherein the extension
parallel to the terminal edge (11; 21) of each vertical extension (13; 17; 23; 27)
of a half-shell (1; 2) is between two and ten times its height along an axis parallel
to the vertical axis (y).
21. A modular tank (10) obtained from the assembly according to any one of the preceding
claims in its assembled tank configuration.