[0001] The present invention relates to a construction element production device comprising
an inlet hopper that feeds construction material towards an extruder that pushes the
material towards a nozzle with the shape of offset rectangular sections, a production
system including conveyor belts, the associated production system and method, and
the construction element itself, as described in the Claims, incorporating notable
innovations and benefits.
Background of the invention
[0002] There are known construction element production devices that include some of the
features mentioned in the preamble of Claim 1 for this invention. And in particular,
with respect to the construction element mentioned in Claim 14, there are multiple
construction elements, such as ceilings, perforated bricks, ceiling placards, concrete
panels, etc. which usually require a specialist for their installation.
[0003] Additionally, there are various known state-of-the-art production devices and systems.
As described in patent
CN2158P1271, a lifting cooling device for the production of refractory bricks performs the lifting
of a cooling plate of refractory bricks through a pneumatic module assembly and performs
the direct blowing of refractory bricks by the arrangement of double air blowers to
improve cooling efficiency. The device has a simple structure, is inexpensive to manufacture
and is suitable for its application.
[0004] Furthermore, patent
CN215857496 describes a polyhedral mosaic slope protection brick for a water conservation project.
The brick consists of a main body and sand-gravel material. The main body is a polyhedral
hollow structure of reinforced concrete in the form of an arrow composed of a top
face, a bottom face, two side faces, a front face and a rear face. The two side faces
are arranged in parallel, half of one side face is angled inwards to form a bell mouth,
and half of the other side face protrudes outwards to form a spout. The bell mouth
and spout are equal in shape and size and correspond to each other in position; the
front end face of the main body has the form of a sheet that protrudes outward, the
rear end face of the main body has the form of a sheet that sinks inward, and the
front end face and the rear end face have the same form and size. It has the advantages
of being a simple structure, easy to manufacture, convenient to use, highly efficient
and economical.
[0005] Additionally, patent
CN215848732 describes a regular brick production system comprising a raw material processing
device, the lower part of which is connected to a material-pushing device. High polymer
materials are combined with straw powder, related adhesives, foaming agents and similar
materials, thereby reducing the cost of the production process.
[0006] However, it is still desirable to develop a specific production device for construction
elements that allows the element to be installed without technical expertise, being
a self-assembling structure with no potential risk of incorrect installation, while
simultaneously seeking to limit sonic and thermal transmission.
Description of the invention
[0007] The purpose of the present invention is to provide a specific production device for
a construction element, with the associated system, method and element, which addresses
the aforementioned difficulties involved during installation and offers other advantages
which will be described below.
[0008] In accordance with this purpose and the first aspect of the invention, the present
invention provides a construction element production device comprising an inlet hopper
that feeds construction material towards an extruder, pushing the material towards
a nozzle, whereby said nozzle comprises at least a first and second rectangular section
offset laterally from each other and at least partially joined on one side.
[0009] In this way, a construction element is pushed out of the nozzle in the form of two
staggered blocks, which facilitates assembly on site, reduces thermal transmission
between the inside and outside of the building and reduces sound transmission. It
should be noted that the term "hopper" refers to the component through which the construction
material is introduced, preferably having a funnel shape to facilitate the dumping
of material.
[0010] The nozzle also comprises a third rectangular section, parallel to the first rectangular
section and symmetrical with respect to the second rectangular section, where the
first rectangular section and the third rectangular section are partially below the
second rectangular section. This produces a construction element of three bodies or
a triple rectangular prism, obtaining three levels, the two sides at the same height,
thus achieving greater stability of the resulting construction element once resting
on the ground or mounted on another construction element. According to one embodiment,
the production device comprises a piston with a cutting element, preferably located
at the nozzle outlet. In this way, the construction material can be sectioned as it
exits the nozzle to produce the construction element.
[0011] More specifically, the aforementioned first cutting element is a wire, so that a
clean cut is produced with no burrs when cutting the construction material and returning
to its initial position, obtaining a construction element of higher quality.
[0012] As an option, the cutting element can be in the form of a guillotine, which can have
a flat shape, or preferably a stepped shape, so that the protruding construction element
has a shape that can be longitudinally fitted with another construction element for
easier assembly and better thermal and sound insulation performance.
[0013] More specifically, the extruder comprises a cavity with a leadscrew that pushes the
construction material towards the nozzle in a way that the speed at which the material
is extruded can be regulated in order to speed up or slow down production or accommodate
the consistency of the construction material used.
[0014] It should be noted that the leadscrew is driven by a motor, allowing faster production
and more precise control.
[0015] In addition, the nozzle comprises an inlet attached to the cavity of the extruder
and an outlet, in order to provide a conduit that gives the desired shape to the construction
element in its final state.
[0016] According to another embodiment, the nozzle outlet comprises a replaceable head which
comprises at least one mouth through which the construction material passes, so that
the construction element can take various forms, depending on the configuration of
the replaceable head, and in particular of the mouth. It should be noted that the
first, second or third rectangular sections that form part of the nozzle may preferably
be part of the head and in particular the mouth located at the nozzle outlet in order
to form the construction element.
[0017] More specifically, the mouth comprises at least one inner wall and at least one horizontal
rod through which the construction material passes, forming the contour and inner
cavities or holes of the construction element, intended to house cable or ducting.
[0018] In addition, the horizontal rod is fixed to the inner wall of the mouth by means
of a flat element in order to minimize the slowing down of the material as it passes
through. It should be noted that the flat element, the inner wall and the horizontal
rod are preferably parallel to the direction of movement of the construction material.
[0019] According to another embodiment, the production device comprises a sensor at the
nozzle outlet, connected to a controller whereby when the sensor detects the presence
of construction material, the controller stops the extruder and actuates the piston
in order to make the cut that creates the construction element. The sensor therefore
measures the horizontal travel, determining the length of the resulting construction
element. As an option, the sensor may be a photocell sensor for optical detection
without the need for physical contact.
[0020] According to the second aspect of the invention, the invention refers to a production
system for a construction element, comprising the described production device in conjunction
with a conveyor belt at the exit of the nozzle, which allows the automatic transportation
of the produced construction elements and thus a higher rate of production.
[0021] It should be noted that said conveyor belt comprises a first level aligned with the
first rectangular section of the nozzle and a second level aligned with the second
rectangular section of the nozzle, such that the conveyor belt itself is adapted to
the output shape of the construction material, i.e., the shape of the construction
element.
[0022] As an option, the conveyor belt may comprise a third level aligned with a third rectangular
section of the nozzle, so that the conveyor belt can stably transport construction
elements of three rectangular bodies or prisms.
[0023] Another advantage is that the production system for the construction element comprises
a moving carriage with a cutting element, wherein the movable carriage comprises at
least a second motor in order to move along at least a first guide parallel to the
conveyor belt, from a first position to a second position and then return to the first
position. The movement of the conveyor belt is synchronized with that of the moving
carriage so that the vertical cutting of the construction element occurs cleanly to
the desired horizontal size.
[0024] It should be noted that, in the first position, the cutting element makes a cutting
movement from a first height to a second height, and in the second position the cutting
element makes a return movement from a second height to a first height. Therefore,
the cutting element does not return to the first height at the same place but after
a horizontal displacement so that it finds a gap to return to its initial height without
encountering the obstacle of the construction element or the construction material.
[0025] More specifically, the moving carriage comprises a second guide driven by a third
motor for successive displacement of the cutting element from, first, a starting point
and initial height to, second, a starting point and second height to, third, a finishing
point and second height to, fourth, a finishing point and initial height and back
to the starting point and initial height, confirming that the cutting element does
not return upwards at the same place and thus avoids the construction element and
construction material when returning to its starting position.
[0026] At this point, it is important to specify that at least the second and third motors
are stepper motors, which allows them to receive precise commands for the final turning
position. This can be achieved in conjunction with the sensor, which may be an optical
sensor, in order to determine the location of the construction element resulting from
the process, and thus act with greater precision, being self-regulating when in operation.
[0027] According to the third aspect of the invention, the invention also relates to the
method by which a construction element is produced using the production system, comprising
the following steps: i) introducing construction material into the hopper; ii) extruding
construction material towards a nozzle; iii) actuating a piston with a cutting element
when the presence of construction material is detected at the nozzle outlet; iv) collecting
the construction element using a conveyor belt and thus obtaining a construction element
comprising multiple rectangular bodies or prisms joined together by at least a partial
surface of one of their faces, where the multiple rectangular prisms, or parallelepipeds,
are partially joined together by the largest of their faces.
[0028] It should be noted that the construction element has at least one double body or
rectangular prism. However, the solution of the triple body or rectangular prism is
preferable in order to achieve greater construction stability.
[0029] As an additional advantage, the multiple rectangular prisms that constitute the construction
element are partially displaced from each other, vertically or horizontally, or preferably
both, so that subsequent assembly on site is possible with a tight fit between the
construction elements, thereby not requiring joining materials between the elements,
such as cement or mortar, and achieving good thermal and sound insulation performance.
[0030] In a preferred embodiment of the invention, the multiple rectangular prisms that
constitute the construction element include at least one longitudinally through-hole
to form a channel through successive construction elements, allowing the passage of
wiring or pipework for the building being constructed.
[0031] As a result of all the features described above, the construction element offers
greater ease of assembly, allowing individual elements to interlock and be assembled
without technical expertise, since its structure is self-assembling with no possibility
of incorrect installation. In addition, it makes it possible to hermetically seal
the construction with no detriment to the technical properties of the channels, in
particular, 70 dBA and RF 120, depending on the specific material used.
[0032] It is also important to mention that the construction element enables a clean finish
without the need for polishing, offering a wide range of sizes and weights in a wide
variety of raw materials, such as, for example, mud, micro concrete, etc.
[0033] The attached drawings show, by way of non-limiting example, a device for producing
a construction element and the associated system, method and element, constituted
in accordance with the invention. Other characteristics and advantages of the construction
element production device and associated system, method and element, subject of the
present invention, will be evident from the description of a preferred, but not exclusive
embodiment, which is illustrated by way of non-limiting example in the attached drawings.
Brief description of the drawings
[0034] For a better understanding of the description made herein, a set of drawings has
been provided wherein, schematically and solely by way of a non-limiting example,
a practical case of an embodiment is represented.
Figure 1 is a plan and profile view of the construction element, according to the
present invention;
Figure 2 is a perspective view of the construction element in various embodiments,
including two or more rectangular prisms, according to the present invention;
Figure 3 is a perspective view of the construction element mounted on a floor in various
orientations, both horizontal and vertical, according to the present invention;
Figure 4 is a perspective view of the construction element mounted on a vertical wall,
according to the present invention;
Figure 5 is a perspective view of the construction element mounted on a roof in various
orientations, both horizontal and vertical, according to the present invention;
Figure 6 is a perspective view of the construction element including three rectangular
prisms with their respective holes, according to the present invention;
Figure 7 is a schematic perspective view of the production system, including the construction
element production device and the conveyor belts, according to the present invention;
Figure 8 is a schematic perspective view of the production system, including the construction
element production device and a moving carriage, according to the present invention;
Description of a preferred embodiment
[0035] From the aforementioned figures and the adopted reference numbers, an example of
a preferred embodiment of the invention can be observed therein, comprising the parts
and elements indicated and described in detail below.
[0036] Therefore, as seen in Figure 7, the construction element production device (1) comprises
an inlet hopper (2) that feeds construction material (12) towards an extruder (21)
that pushes said construction material (12) towards a nozzle (3), where said nozzle
(3) comprises at least a first rectangular section (33) and a second rectangular section
(34) displaced laterally from each other and at least partially joined on one side
(35).
[0037] Additionally, as can be seen in Figures 6 and 7, the nozzle (3) comprises a third
rectangular section (35) parallel to the first rectangular section (33), and symmetrical
with respect to the second rectangular section (34), where the first rectangular section
(33) and the third rectangular section (35) are partially below the second rectangular
section (34).
[0038] According to one embodiment, as can be seen in Figure 7, the construction element
production device (1) comprises a piston (4) with a cutting element (41).
[0039] As seen in Figure 7, the cutting element (41) is preferably a guillotine. Said guillotine
has a square Z-shaped horizontal section, with the straight intermediate section vertically,
in the event that the nozzle (3) comprises a first rectangular section (33) and a
second rectangular section (34). Alternatively, for the embodiment in which the nozzle
(3) comprises a first rectangular section (33), a second rectangular section (34)
and a third rectangular section (35), the guillotine has a square U-shaped horizontal
section with a straight section perpendicular to each side of each of the ends of
the U.
[0040] It should be mentioned that, as can be seen in Figure 7, the extruder (21) comprises
a cavity (21a) with a leadscrew (21b) that pushes the construction material (12) towards
the nozzle (3). The leadscrew (21b) is operated by a first motor (21c), and the nozzle
(3) comprises an inlet (31), attached to the cavity (21a) of the extruder (21), and
an outlet (32).
[0041] According to a preferred embodiment of the invention, as can be seen in Figure 7,
the outlet (32) comprises a replaceable head (37) which comprises at least one through-hole
(38) for the construction material to pass through (12).
[0042] More specifically, as seen in Figure 7, the mouth (38) comprises at least one inner
wall (38a) and at least one horizontal rod(39).
[0043] Additionally, as can be seen in Figure 7, the horizontal rod (39) is fixed to the
inner wall (38a) of the mouth (38) by means of a flat element (39a).
[0044] Furthermore, as can be seen in Figure 7, the construction element production device
(1) includes a sensor (51) at the outlet (32) of the nozzle (3), connected to a controller(5),
whereby when the sensor (51) detects the presence of construction material (12), the
controller (5) stops the extruder (21) and actuates the piston (4). This sensor (51)
can be placed directly over the outlet of the nozzle (3) or a certain distance away
from the nozzle, equivalent to the length of the resulting constructive element (1).
[0045] Another aspect of the invention, as can be seen in Figure 7, is the construction
element production system (1) which comprises the production device and also a first
conveyor belt (61) at the outlet (32) of the nozzle (3).
[0046] Additionally, as can be seen in Figure 7, in the construction element production
system (1), the conveyor belt (61) comprises a first level (61a) aligned with the
first rectangular section (33) of the nozzle (3), and a second level (61b) aligned
with the second rectangular section (34) of the nozzle (3).
[0047] In a preferred embodiment of the invention, as seen in Figure 7, the conveyor belt
(61) comprises a third level (61c) aligned with a third rectangular section (35).
[0048] According to one embodiment, as can be seen in Figure 8, the construction element
production system (1) includes a moving carriage (7) with a cutting element (41),
where the moving carriage (7) comprises at least one second motor (21d) for movement
on at least one first guide (71) parallel to the conveyor belt (61), from a first
position (81) to a second position (82).
[0049] It should be noted that, as seen in Figure 8, in the first position (81), the cutting
element (41) makes a cutting movement from a first height (H1) to a second height
(H2), and in the second position (82), the cutting element (41) returns from the second
height (H2) to the first height (H1). Therefore, the cutting movement is preferably
descending on the protruding construction material (12) towards a second height (H2),
and the return movement is preferably ascending to the first height (H1), where the
first height (H1) is greater than the second height (H2).
[0050] Furthermore, as seen in Figure 8, the moving carriage (7) comprises a second guide
(72) driven by a third motor (21e) for the successive displacement of the cutting
element (41) from, first, an initial point (P1) and first height (H1) to, second,
an initial point (P1) and second height (H2) to, third, an end point (P2) and second
height (H2) to, fourth, an end point (P2) and first height (H1) and back to the initial
point (P1) and first height (H1).
[0051] And more specifically the sequence of actions would be as follows:
- i) the piece or construction element (1) exits the head (37);
- ii) the blade or cutting element (41) is lowered while the moving carriage moves at
the same speed as the extruded construction material (12);
- iii) the blade or cutting element (41) passes through the clearance space between
conveyor belts (61), both downward and upward;
- iv) the blade or cutting element (41) continues downwards to a second height (H2),
while the ejection conveyor belt (61) and the rapid conveyor belt (61) remove the
formed construction element (1);
- v) the blade or cutting element (41) reaches the bottom and rises at the other end
or end point (P2), with the construction element (1) having already been removed;
- vi) the blade or cutting element (41) returns upwards to the first height (H1), horizontally
towards the first starting point (H1), while the moving carriage (7) returns to the
first position (81);
- vii) the blade or cutting element (41) is lowered again, cutting the piece or construction
element again(1), as the construction material has now had time to move the corresponding
distance to produce a construction element of a suitable, standard size(1).
[0052] The present invention also includes the method for producing the construction element
(1) using the production system, comprising the following steps: i) introducing the
construction material (12) into a hopper (2); ii) extruding the construction material
(12) towards a nozzle (3); iii) actuating a piston (4) with a cutting element (41)
when the presence of construction material is detected (12) at the outlet (32) of
the nozzle (3); and iv) removing the construction element (1) using a conveyor belt
(61).
[0053] As seen in Figures 1 to 6, the present invention also relates to the construction
element (1) obtained by the production method, which comprises multiple rectangular
prisms (11) joined together by at least a partial surface of one of their faces (11a),
where the multiple rectangular prisms (11) are partially joined together by the largest
of their faces (11a). According to a preferred embodiment, the constructive material
(12) may be either mud or micro concrete.
[0054] It should be noted that, as can be seen in Figures 1 to 6, the multiple rectangular
prisms (11) are partially offset from each other, vertically and/or horizontally.
[0055] More specifically, as can be seen in Figure 6, the multiple rectangular prisms (11)
include at least one longitudinally through-hole (11b).
[0056] It should be noted that reference is made in the text to the following elements or
components even though they do not appear differently in the figures, being either
internal elements or integrated with other elements: leadscrew (21b), first motor
(21c), second motor (21d), third motor (21e), controller(5).
[0057] Figure 1 shows a plan and profile view of the construction element (1), with several
rectangular prisms (11) joined together along their largest faces(11a).
[0058] Figure 2 shows a perspective view of the construction element (1) in various embodiments,
including two or more rectangular prisms (11) joined together along their largest
faces(11a).
[0059] Figure 3 shows a perspective view of the construction element (1) with several rectangular
prisms (11), in several orientations, both horizontal and vertical, as part of a floor
assembly.
[0060] Figure 4 shows a perspective view of the construction element (1) as part of a wall
construction.
[0061] Figure 5 shows a perspective view of the construction element (1) in various orientations,
both horizontal and vertical, as part of a roof construction.
[0062] Figure 6 is a perspective view of the construction element (1) including three rectangular
prisms (11) with their respective holes (11b), joined along their largest faces (11a).
[0063] Figure 7 is a perspective view of the production system including the construction
element production device(1) and the conveyor belts (61). In particular, the figure
shows the hopper (2) for introducing the construction material (12) and the extruder
(21) which features a cavity (21a) and a leadscrew (21b) activated by a motor (21c).
All this connects to the inlet (31) to a nozzle (3) which also includes an outlet
(32) that connects to the corresponding head (37), according to a particular embodiment,
a first rectangular section (33), a second rectangular section (34) and up to a third
rectangular section (35), which include at least one side (36). The head (37) includes
a mouth (38) with an inner wall (38a) and multiple rods (39), joined to the inner
wall (38a) by means of a flat element (39a).
[0064] Furthermore, the production system includes a piston (4) with a cutting element (41),
preferably a guillotine (41a). It also comprises a controller (5) with a sensor (51)
at the outlet (32) of the nozzle (3), which is connected to the conveyor belt (61),
which in the present embodiment includes a first level (61a), a second level (61b)
and a third level (61c).
[0065] Figure 8 is a perspective view of the production system including the construction
element production device (1) and a moving carriage (7). Specifically, the construction
element (1) is produced from the protruding construction material (12) using a cutting
element (41) that moves on a moving carriage (7) in synchronization with the transport
belt (61), both being driven by a second motor (21d), in the case of the moving carriage
(7) on a first guide (71), and by a third motor (21e) on a second guide (72) in the
case of the cutting element (41), whereby the sensor (51) determines the position
of the construction element (1). In particular, the moving carriage (7) moves from
a first position (81) to a second position (82), while the cutting element (41) moves
vertically from a first height (H1) to a second height (H2) and horizontally from
a starting point (P1) to a finishing point (P2).
[0066] The details, shapes, dimensions and other accessory elements, as well as the components
used in the implementation of the construction element production device (1) and its
associated system, method and element, may be replaced by others that are technically
equivalent and do not depart from the essence of the invention or the scope defined
by the claims that follow the list of numerical references.
List of numerical references:
[0067]
- 1
- construction element
- 11
- rectangular prism
- 11a
- face
- 11b
- orifice
- 12
- construction material
- 2
- hopper
- 21
- extruder
- 21a
- cavity
- 21b
- leadscrew
- 21c
- first motor
- 21d
- second motor
- 21e
- third motor3 nozzle
- 31
- inlet
- 32
- outlet
- 33
- first rectangular section
- 34
- second rectangular section
- 35
- third rectangular section
- 36
- side
- 37
- head
- 38
- mouth
- 38a
- inner wall
- 39
- stem
- 39a
- flat element
- 4
- piston
- 41
- cutting element
- 41a
- guillotine
- 5
- controller
- 51
- sensor
- 61
- conveyor belt
- 61a
- first level
- 61b
- second level
- 61c
- third level
- 7
- moving carriage
- 71
- first guide
- 72
- second guide
- 81
- first position
- 82
- second position
- H1
- first height
- H2
- second height
- P1
- starting point
- P2
- finishing point
1. A construction element production device (1) comprising an inlet hopper (2) for feeding
construction material (12) towards an extruder (21) that pushes said construction
material (12) towards a nozzle (3) characterized in that comprises at least a first rectangular section (33) and a second rectangular section
(34), laterally displaced from each other and at least partially joined on one side(36).
2. A construction element production device (1), according to Claim 1, wherein the nozzle
(3) comprises a third rectangular section (35) parallel to the first rectangular section
(33), and symmetrical with respect to the second rectangular section (34), where the
first rectangular section (33), and the third rectangular section (35) are partially
below the second rectangular section (34).
3. A construction element production device (1), according to any of the preceding claims,
characterized in that comprises a piston (4) with a cutting element (41).
4. A construction element production device (1), according to Claim 1, wherein the extruder
(21) comprises a cavity (21a) with a leadscrew (21b) that pushes the construction
material (12) towards the nozzle (3), whereby the leadscrew (21b) is actuated by a
first motor (21c), and the nozzle (3) comprises an inlet (31), attached to the cavity
(21a) of the extruder (21), and an outlet (32).
5. A construction element production device (1), according to Claim 4, wherein the outlet
(32) comprises a replaceable head (37) which comprises at least one hole (38) through
which the construction material (12) passes.
6. A construction element production device (1), according to Claim 5, wherein the mouth
(38) comprises at least one inner wall (38a) and at least one horizontal rod (39).
7. A construction element production device (1), according to Claim 6, wherein the horizontal
rod (39) is fixed to the inner wall (38a) of the mouth (38) by means of a flat element
(39a).
8. A constructive element production device (1), according to any of Claims 4 to 7, characterized in that includes a sensor (51) at the outlet (32) of the nozzle (3), connected to a controller
(5) so that when the sensor (51) detects the presence of constructive material (12),
the controller (5) stops the extruder (21) and actuates the piston (4).
9. A construction element production system (1) comprising a production device according
to any of Claims 4 to 7, characterized in that comprises a conveyor belt (61) at the outlet (32) of the nozzle (3).
10. A construction element production system (1), according to Claim 9, wherein the conveyor
belt (61) comprises a first level (61a) aligned with the first rectangular section
(33) of the nozzle (3), and a second level (61b) aligned with the second rectangular
section (34) of the nozzle (3).
11. A construction element production system (1), according to Claim 10, characterized in that includes a moving carriage (7) with a cutting element (41), wherein the moving carriage
(7) comprises at least one second motor (21d) for movement along at least one first
guide (71) parallel to the conveyor belt (61), from a first position (81) to a second
position (82).
12. A construction element production system (1), according to Claim 11, wherein, in the
first position (81), the cutting element (41) makes a cutting movement from a first
height (H1) to a second height (H2), and in the second position (82), the cutting
element (41) returns from the second height (H2) to the first height (H1).
13. A construction element production system (1), according to Claim 12, wherein the moving
carriage (7) comprises a second guide (72) driven by a third motor (21e) for the successive
displacement of the cutting element (41) from, first, a starting point (P1) and first
height (H1) to, second, a starting point (P1) and second height (H2) to, third, a
finishing point (P2) and second height (H2) to, fourth, a finishing point (P2) and
first height (H1) and back to the starting point (P1) and first height (H1).
14. A method of production for a construction element (1) using the production system
according to any of Claims 9 to 13, comprising the following steps:
i) introducing construction material (12) into a hopper (2);
ii) extrusion of construction material (12) towards a nozzle (3);
iii) actuation of a piston (4) with a cutting element (41) when the presence of construction
material is detected (12) at the outlet (32) of the nozzle (3); and
iv) removing the construction element (1) using a conveyor belt (61).
15. A construction element (1) obtained through the production method according to Claim
14, comprising multiple rectangular prisms (11) joined together along at least a partial
surface of one of their faces (11a), whereby the multiple rectangular prisms (11)
are partially joined together along the largest of their faces (11a).