ES2982740T3 - Work comprising a set of blocks - Google Patents

Abstract

The invention relates to a structure (10) comprising a set of blocks (15), each block (15) having an upper face (35) and a lower face (40), at least two axes (A) and, for each axis (A), a protuberance (60), a duct (50) and a cavity (75), each protuberance (60) being arranged on the upper face (35), each cavity (75) being arranged on the lower face (40), each duct (50) extending along the corresponding axis (A) and being defined by the block (15), each cavity (75) of a block (15) receiving a protuberance (60) of a block (15) immediately below the block (15) in question. Each protrusion (60) and the corresponding cavity (75) are configured to allow rotation about the axis (A) between the blocks (15), at least one connecting element (20, 25A, 25B) being received within the two conduits (50) to block at least one degree of freedom between the blocks (15). (Automatic translation with Google Translate, without legal value)

Description

DESCRIPTION

Work comprising a set of blocks

[0001] The present invention relates to a work, in particular an impact protection or containment work.

[0002] Structures are often used to stabilise ground and protect people and property from possible damage due to ground movements or falling materials. Some of these structures are fixed to a slope, such as a retaining wall or a net, which allows rolling masses such as rocks falling from a wall to be stopped and which provide good dissipation of kinetic energy. These structures are fixed with braces or bolts fixed into the slope. Other structures consist of a stack of blocks, materials or gabions and their mass allows them to retain the ground or interrupt the path of rolling blocks.

[0003] However, these structures are not optimized. In fact, the anchoring operations, using bolts or ties, are long or complex since they require the creation of holes in the slope which will be filled with cement to allow the fixing of the bolts or ties. During these operations, the workers working on the installation of the structure are not protected. In addition, the weight structures formed by the stacking of blocks or materials require a strong grip on the ground, which is not always available, and allow a low dissipation of the kinetic energy of the rolling blocks. In addition, these structures are long to build.

[0004] Furthermore, in many cases it is necessary for the work to be erected in an area of complex topography, for example along a route that is not straight. WO2013/022902 A2 describes a work according to the preamble of claim 1.

[0005] An object of the invention is therefore to propose a work which requires low ground adhesion, whilst being simple and quick to install or dismantle and allowing good dissipation of kinetic energy.

[0006] For this purpose, a work is proposed, in particular for impact protection or containment, the work comprising a set of blocks and at least one connecting element, the blocks being distributed on several superimposed levels according to a vertical direction, so that each block has an upper face and a lower face, each block having at least two axes parallel to the vertical direction, such that each block includes, for each axis, a protuberance, a duct and a cavity, each protuberance being arranged on the upper face, each cavity being arranged on the lower face, such that each cavity has a bottom delimiting the cavity according to the vertical direction, each duct extends according to the corresponding axis and is delimited by the block, each duct passes through the block according to the vertical direction and opens into the first corresponding cavity, each cavity of a block belongs to a block level different from the lowest level housing a protuberance of a block of a block level immediately lower than the block considered, the axis of the cavity is coincident with the axis of the cavity. protuberance received in the cavity, each protuberance and the cavity in which said protuberance is received are configured to allow a relative rotation about the axis of the protuberance between the block that includes the protuberance and the block that includes the cavity, at least one joining element being received jointly in the two conduits, with the joining element configured to block at least one degree of freedom between the blocks in which the joining element is received about an axis perpendicular to the vertical direction. According to the invention, the protuberance includes a plurality of projections arranged along a circle centered on the axis of the protuberance, with each projection extending in the vertical direction from the upper face.

[0007] Thanks to the invention, the blocks can be quickly and easily joined together to form a structure that is highly resistant and requires little ground grip. In particular, the possibility of rotation between the blocks 15 in a horizontal plane makes it possible to easily adapt the shape of the structure to the topography.

[0008] According to other advantageous but non-mandatory aspects of the invention, the work includes one or more of the following features, taken in isolation or according to all technically possible combinations: - the protuberance is a truncated cone-shaped projection centered on the axis;

- each projection has an external face configured to rest against a lateral face of the cavity in which the protuberance is housed, such that the external face has the shape of part of a truncated cone centered on the axis;

- each projection is formed by a portion of a pin removable with respect to the corresponding block; - each block includes, for each axis, an annular slot arranged on the upper face, a portion of each pin being housed in the slot;

- each cavity has a second lateral face delimiting the cavity in a plane perpendicular to the vertical direction, the second lateral face being a part of a truncated cone extending along the axis of the cavity; - at least one connecting element is jointly fixed to two of the blocks delimiting the ducts in which the connecting element is housed;

- at least one connecting element is configured to prevent a relative translation according to the vertical direction of the blocks delimiting the ducts in which the connecting element is housed;

- at least one connecting element includes a flexible link such as a cable or a chain;

- at least one connecting element includes a rigid link such as a bar or a tube;

- at least one connecting element is housed in ducts delimited by a plurality of blocks superimposed according to the vertical direction, the connecting element being fixed to the lower face of the block belonging to the lowest level and to the upper face of the block belonging to the highest level;

- at least one connecting element, such as a bar or a tube, is configured to bear against the walls of the ducts in which the connecting element is housed to exert on these walls a force that opposes a translation between the blocks along an axis perpendicular to the vertical direction or a relative rotation of the blocks in which the connecting element is housed around an axis perpendicular to the vertical direction;

- each block has a height measured according to the vertical direction, at least one connecting element configured to bear against the walls of the ducts in which the connecting element is housed to exert on these walls a force opposing a translation between the blocks according to an axis perpendicular to the vertical direction and/or a relative rotation of the blocks in which the connecting element is housed about an axis perpendicular to the vertical direction having a length measured according to the vertical direction, the length being greater than or equal to the height of a block;

- each duct presents a rotational symmetry around the corresponding axis;

- the blocks are arranged vertically in a staggered pattern;

- each block extends along a principal direction in a plane perpendicular to the vertical direction, such that the axes of the block considered define a plane parallel to the principal direction, a distance measured along the principal direction between the axes in particular being greater than or equal to half a length of the block considered measured along the principal direction.

- each block has at least one lateral face delimiting the block in a plane perpendicular to the vertical direction, such that each block also delimits, for each cavity, at least one passage extending in a lateral direction perpendicular to the vertical direction and opening into the cavity and onto a lateral face;

- the work includes at least two blocks that are integral with each other by means of a metal element housed in a passage of each of the blocks considered; and

- the work extends along an extension direction in a plane perpendicular to the vertical direction, with each block extending along a main direction in a plane perpendicular to the vertical direction, the angle between the extension direction and the main direction of at least one block being strictly greater than zero, in particular greater than or equal to 15 degrees.

[0009] The characteristics and advantages of the invention will become apparent from reading the description given below, provided solely by way of non-limiting example and made with reference to the attached drawings, in which:

[Fig. 1] Figure 1 is a perspective view of an example of a work according to the invention comprising a set of blocks,

[Fig. 2] Figure 2 is a cross-sectional view of a block of Figure 1,

[Fig. 3] Figure 3 is a cross-sectional view of the work of Figure 1, and

[Fig. 4] Figure 4 is a perspective view of a block of another example of work according to the invention.

[0010] A first example of work 10 is shown in Figure 1.

[0011] The structure 10 is, for example, a containment structure. In particular, the structure 10 rests against a wall or a slope of a terrain or a cliff that the structure 10 is capable of containing. As a variant, the structure 10 is a structure for protection against impacts, in particular caused by falling materials. In this case, the structure 10 is installed at the foot of a slope and is configured to stop materials falling, sliding or rolling along the slope, such as blocks of rock. According to another variant, the structure 10 is a structure for containment and protection against falling materials.

[0012] The work 10 comprises a plurality of blocks 15, at least one connecting element 20, 25A, 25B and an optional set of anchoring elements 30. According to the embodiment shown in the figures, the work 10 comprises a set of connecting elements 20, 25A, 25B, and a set of complementary elements 25C.

[0013] For work 10, a first X direction, a second Y direction, and a vertical Z direction are defined. The first X direction is perpendicular to the second Y direction and the vertical Z direction. The second Y direction is also perpendicular to the vertical Z direction. Thus, the first X direction and the second Y direction define a horizontal plane.

[0014] The blocks 15 are distributed in several superimposed levels according to the vertical direction Z. The plurality of levels comprises a first level N1 and at least a second level N2. Four levels N1, N2, N3, N4 are shown in Figure 1. However, the work 10 may include a variable number of levels, according to needs.

[0015] Among the levels N1, N2, N3, N4, the first level N1 is the lowest level. For example, the first level N1 is the lowest level of the work 10 and is supported on the ground 17. The second level N2 is immediately above the first level N1. By "immediately above" it is meant that at least one element of the second level N2 is supported by at least one element of the first level N1. The first level N1 is then called the "level immediately below" the second level N2.

[0016] A third level N3 is immediately superior to the second level N2. A fourth level N4 is immediately superior to the third level N3.

[0017] According to the example shown in Figure 1, the first level N1 includes four blocks 15, the second level N2 includes three blocks 15, the third level N3 includes two blocks 15 and the fourth level N4 includes a single block 15. However, the number of blocks 15 of each level N1, N2, N3, N4 may vary.

[0018] As illustrated in Figure 1, the work 10 is made up of blocks 15 arranged vertically in a staggered pattern. By "staggered" is meant in particular that a phase shift, measured according to the second direction Y, between the blocks of two successive levels N1, N2, N3, N4 is strictly greater than zero.

[0019] For example, the offset is equal to half of the first length L1. Thus, each block 15 belonging to a level N2, N3, N4 different from the first level N1 is supported by two blocks 15 of the immediately lower level N1, N2, N3. In particular, each block 15 of a level N1, N2, N3 different from the highest level N4 supports up to two blocks 15 of the immediately higher level N2, N3, N4.

[0020] It should be noted that embodiments may also be envisaged in which the blocks 15 of different levels N1, N2, N3, N4 are aligned with each other according to the vertical direction Z, in particular in which the offset is substantially equal to zero.

[0021] The work 10 extends, for example, along the second direction Y. Thus, the second direction Y is sometimes referred to as the "extension direction". However, embodiments are also contemplated in which the work 10 is curved or has an angle.

[0022] The blocks of each level N1, N2, N3, N4 are, for example, aligned with each other according to the second direction Y. Thus, work 10 is a wall that has a single thickness of blocks according to the third direction X.

[0023] According to a variant, work 10 is a wall having two or more block thicknesses according to the first X direction. In this case, work 10 can also be considered as the meeting of juxtaposed walls according to the first X direction.

[0024] An example of block 15 is shown in Figure 2 in cross section on a vertical plane perforated by the Z and Y directions.

[0025] Each block 15 extends horizontally according to a main direction of the block 15. The main directions of the blocks 15 are, for example, confused. Each main direction is, for example, the second direction Y.

[0026] As a variant, an angle between the main directions of two blocks 15 of the same level N1, N2, N3, N4 is different from zero, for example greater than or equal to 15 degrees, in particular greater than or equal to 30 degrees.

[0027] According to a variant, at least one block 15 has a main direction forming a non-zero angle with the second direction Y, along which the work 10 extends. The angle is for example greater than or equal to 15 degrees, in particular greater than or equal to 30 degrees.

[0028] Each block 15 has an upper face 35, a lower face 40 and at least one first lateral face 45. Each block 15 is delimited according to the vertical direction Z by its upper face 35 and by its lower face 40.

[0029] According to a particular embodiment, each block 15 includes at least one reinforcing element 42, in particular two reinforcing elements 42.

[0030] Each block 15 delimits at least two conduits 50, an anchor hole 55 and two passages 57. It should be noted that the anchor hole 55 and the passages 57 are optional.

[0031] Each block 15 has a first length L1, measured according to the second direction Y, between 0.38 meters (m) and 6.2 m.

[0032] Each block 15 has a first width i1, measured along the first direction X, between 0.18 m and 3 m.

[0033] Each block 15 has a first height H1, measured in the vertical direction Z between the upper face 35 and the lower face 40, between 0.2 m and 3.2 m.

[0034] Each block 15 is made of concrete. For example, concrete is a lightweight concrete, i.e. a concrete that includes inclusions of a material lighter than concrete. The inclusions are for example balls or aggregates of a material lighter than concrete.

[0035] Concrete is, for example, reinforced concrete.

[0036] As a variant, block 15 is made of a mixture of concrete and a polymer such as polystyrene.

[0037] In another variant, the block 15 includes a metal container filled with a filler material. A filler material is a material used to increase the mass of the block 15 relative to the mass of the empty container. The filler material is, for example, a polymer material. For example, the polymer material is a polymer foam such as a polyurethane foam.

[0038] The box thus includes a filling member and an orifice allowing the injection of the filling material into the box.

[0039] Alternatively, the filling material is water. When the filling material is water, the box also includes a draining device capable of allowing the water to be evacuated from the box.

[0040] As a variant, the filling material is sand.

[0041] As a variant, some blocks 15 include a drawer that does not contain filler material.

[0042] It should be noted that non-metallic materials, for example a plastic material, can also be used for the drawer.

[0043] According to a variant, the box is openwork, for example consisting at least partially of a grid, in particular a metal grid. For example, the box is a gabion.

[0044] Each upper face 35 is substantially planar. In particular, each upper face 35 is perpendicular to the vertical direction Z.

[0045] At least two protuberances 60 are arranged on each upper face 35.

[0046] By "protrusion" is meant a portion of block 15 or a referenced element that extends from upper face 35 and is configured to engage a cavity 75 of another block 15.

[0047] In the embodiment shown in Figures 1 to 3, each protuberance forms a single projection 60 extending in the vertical direction Z from the upper face 35 towards the outside of the block 15.

[0048] Each protuberance 60 has, for example, a rotational symmetry about an axis A, in particular an axis A parallel to the vertical direction Z.

[0049] According to a particular embodiment, each protuberance 60 is shaped like a truncated cone.

[0050] Each protuberance 60 has a terminal face 65 and at least one second lateral face 70.

[0051] The terminal face 65 delimits the protuberance 60 according to the vertical direction Z.

[0052] Each terminal face 65 is, for example, perpendicular to the vertical direction Z.

[0053] Each second lateral face 70 extends between the upper face 35 and the terminal face 65. The second lateral face 70, or the second lateral faces 70 together, delimit the protuberance 60 in a plane perpendicular to the vertical direction Z.

[0054] When the protuberance 60 is in the form of a truncated cone, the terminal face 65 is a disk. In this case, the protuberance 60 has a single second lateral face 70, which surrounds the projection in a plane crossing the vertical direction Z. In this case, the second lateral face 70 is in the form of a portion of a truncated cone.

[0055] The terminal face 65 has, for example, an external radius between 4.5 centimeters (cm) and 72 cm, for example equal, with a precision of 10%, to 18 cm.

[0056] The base of the truncated cone, that is to say the face of the truncated cone opposite the terminal face 65, has for example a radius between 5 cm and 84 cm, in particular equal, with an accuracy of 10%, to 21 cm.

[0057] Each axis A is, for example, spaced from the other axis A by a distance between 20 cm and 3.2 metres, for example equal to 80 cm.

[0058] The A axes are, for example, aligned with each other according to the Y direction. In other words, the A axes define a plane parallel to the Y direction.

[0059] The axes A are spaced apart from each other, according to the Y direction, by a distance greater than or equal to half of the first length L1 of the block 15 considered. Each axis A is, for example, equidistant from the first lateral faces 45 delimiting the block 15 according to the X direction.

[0060] According to a variant, each protuberance 60 is a cylinder extending along axis A.

[0061] According to another variant, each protuberance 60 has the shape of a portion of a sphere, in particular a hemisphere.

[0062] According to another variant, each protuberance 60 has a polyhedral shape, for example in the form of a truncated pyramid extending along the axis A. The pyramid is for example a regular pyramid, the second lateral faces 70 being thus identical to one another. It should be noted that other polyhedral or non-polyhedral shapes may also be contemplated for the protuberances 60.

[0063] Furthermore, protuberances 60 including a plurality of projections extending in the vertical direction Z from the upper face 35 may also be contemplated, as will be described below.

[0064] Each protuberance 60 has a height, measured in the vertical direction Z between the upper face 35 and the terminal face, less than or equal to 1/3 of the first height H1 of a block 15, in particular between 1 cm and one third of the first height H1, for example equal to 5 cm, with an accuracy of 10%.

[0065] Each bottom face 40 is perpendicular to the vertical direction Z.

[0066] The lower face 40 of each block 15 of a block level (N2, N3, N4) different from the lowest level (N1) abuts against the upper face 35 of a block (15) of the level (N1, N2, N3) immediately below.

[0067] Two cavities 75 are arranged on each lower face 40.

[0068] Each cavity 75 corresponds to a protuberance 60 of the block 15 considered. For example, each cavity 75 is aligned according to the vertical direction with the block 15 considered.

[0069] Each cavity 75 extends towards the interior of the block 15 from the lower face 40. In particular, each cavity 75 extends towards the interior of the block 15 along the axis A of the corresponding protuberance 60.

[0070] Each cavity 75 is capable of accommodating a protuberance 60 of a block 15 supporting the block 15 in which the cavity 75 is arranged. In particular, each cavity 75 is configured, with the protuberance 60, to allow relative rotation between the blocks 15 considered around the axis A of the protuberance 60 and of the cavity 75.

[0071] Each cavity 75 has, for example, a rotational symmetry about the axis A of the corresponding protuberance 60.

[0072] According to a particular embodiment, each cavity 75 is shaped like a truncated cone.

[0073] Each cavity 75 has a bottom 80 and at least a third lateral face 85.

[0074] The bottom 80 is perpendicular to the vertical direction Z. Each third lateral face 85 extends between the bottom face 40 and the bottom 80. The third lateral face 85, or the third lateral faces 85 together, delimit the cavity 75 in a plane perpendicular to the vertical direction Z.

[0075] The background 80 has, for example, a radius between 5 centimeters (cm) and 76 cm, for example equal, with a precision of 10%, to 19 cm.

[0076] The base of the truncated cone, i.e. the face of the truncated cone opposite the bottom 80, has for example a radius between 5.5 cm and 88 cm, in particular equal, to an accuracy of 10%, to 22 cm. This base forms a circular opening opening into the bottom face 40.

[0077] It should be noted that the shape of each cavity 75 may vary.

[0078] The cavity 75 has a depth, measured in the vertical direction Z, strictly greater than the height of the corresponding protuberance 60. The depth is, for example, between 1.5 cm and 24 cm, in particular equal to 6 cm.

[0079] The first side face(s) 45 delimit the block 15 in a plane perpendicular to the vertical direction Z.

[0080] Each first lateral face 45 is, for example, perpendicular to either the first direction X or the second direction Y. In this case, the block 15 is substantially parallelepiped.

[0081] According to a variant shown in Figure 1, the first side faces 45 each have two chamfers 90 and a central portion 95 perpendicular to one of the first direction X and the second direction Y. When the central portion 95 is perpendicular to the first direction X, the two chamfers 90 delimit the central portion according to the second direction Y and have a slight angle with the first direction X. When the central portion 95 is perpendicular to the second direction Y, the two chamfers 90 delimit the central portion according to the second direction Y and have a slight angle with the first direction X.

[0082] As a variant, the block 15 includes a parallelepiped central portion, for example delimited by the central portions 90, and two semi-cylindrical end portions 97. The end portions 97 frame the central portion, and may each be centered on a corresponding axis A. However, variants may also be contemplated in which the end portions 97 are not each centered on an axis A of a protuberance 60.

[0083] Each axis A is, for example, equidistant from the first lateral faces 45 that delimit the block 15 according to the X direction.

[0084] Each duct 50 extends along the axis A of a protuberance 60. This duct is then said to be "coaxial" with this corresponding protuberance 60.

[0085] Duct 50 passes through block 15 in the vertical direction Z.

[0086] By "pass-through" is meant in particular a conduit 50 which is open at both ends.

[0087] In the example shown in Figures 1 to 3, the duct 50 opens into the cavity 75 and into the corresponding protuberance 60. In particular, the duct 50 opens into the end face of the protuberance 60 and into the bottom 80 of the corresponding cavity 75.

[0088] A variant may also be contemplated in which the duct 50 opens on the upper face 35 and is described below.

[0089] Each duct 50 is, for example, cylindrical with a circular base around the axis A. As a variant, parallelepiped or polyhedral ducts 50 can also be contemplated.

[0090] Each duct 50 has a diameter strictly smaller than the diameter of the corresponding terminal face 65, for example between 3 cm and 60 cm, in particular equal to 15 cm.

[0091] According to one embodiment, the end of the duct 50 which opens onto the end face 65 has a chamfer. In particular, the diameter of the part of the duct 50 having the chamfer increases from the diameter of the rest of the duct 50 to a value strictly greater than this diameter. A difference between these two values is, for example, between 1 cm and 28 cm, in particular equal to 7 cm. According to one embodiment, a difference between the external diameter of the end face 65, equal to twice the radius of the end face 65, and the maximum diameter of the chamfer between the duct 50 and the end face 65 is equal to 14 cm.

[0092] Each anchoring hole 55 passes through the block 15 from one of the side faces 45 to another side face 45, such that the two side faces 45 considered delimit the block 15 according to the first direction X. The anchoring hole 55 extends according to a direction included in a plane which also includes the directions X and Z. In this plane, an angle between the direction according to which the anchoring hole 55 extends and the first direction X is between 0° and 70°.

[0093] Each anchoring hole 55 is, for example, cylindrical with a circular base and has a diameter between 4 cm and 64 cm, in particular equal, with a precision of 10%, to 16 cm.

[0094] Each anchor hole 55 is configured to allow the passage of a drilling tool and/or an anchor bolt. For example, at least one block 15 is anchored to the ground by an anchor bolt housed in an anchor hole 55. In particular, the anchor hole 55 opens on the two corresponding side faces 45 by means of two openings.

[0095] Each passage 57 extends from a corresponding cavity 75 to a side face 45, into which the passage 57 opens. Each passage 57 extends, for example, along the first direction X.

[0096] Each passage 57 has, for example, a depth, measured according to the vertical direction Z, equal to the depth of the corresponding cavity 75. Each passage 57 has a width, measured according to the second direction Y, for example between 6 and 100 cm, in particular equal, with an accuracy of 10%, to 25 cm.

[0097] The blocks 15 are arranged so that each cavity 75 of a block level N2, N3, N4 different from the lowest level N1 accommodates a protuberance 60 of a block 15 of the immediately lower level N1, N2 or N3. In particular, when the blocks 15 are arranged in a staggered pattern, the cavities 75 of the same block 15 accommodate protuberances 60 corresponding to two different blocks 15.

[0098] It should be noted that, for each block 15, the number of protuberances 60 of the block 15 considered that are housed in the cavities 75 of a block 15 of an immediately higher block level N2, N3, N4 may vary between zero and two.

[0099] For example, if the block 15 considered does not support any other block 15, there is no protuberance 60 of this block housed in a cavity 75.

[0100] If the block 15 supports only one other block 15, when the blocks 15 are arranged in a staggered pattern, a single protrusion 60 of the block 15 considered is housed in a cavity 75 of the block 15 of the immediately higher level. When the blocks 15 are aligned according to the vertical direction Z, and are not arranged in a staggered pattern, the two protuberances 60 are housed in the cavities 75 of the block 15 of the immediately higher level.

[0101] If the block 15 supports two other blocks 15, when the blocks 15 are arranged in a staggered pattern, a single protuberance 60 of the block 15 considered is housed in a cavity 75 of each of the two blocks 15 of the immediately higher level, as can be seen in Figure 3.

[0102] The ducts 50 leading into the bottom 80 of the cavity 75 and into the terminal face 65 of the projection housed in the cavity communicate with each other. In particular, the axes A of the cavity 75 considered and of the protuberance 60 housed in the cavity 75 merge.

[0103] Thus, when two blocks 15 or more are superimposed, the conduits 50 that communicate with each other form a single channel that allows passage from the upper face 35 of the block 15 that belongs to the highest level N2, N3, N4 to the lower face 40 of the block 15 that belongs to the lowest level N1.

[0104] In this case, the "highest level" means the level N1, N2, N3, N4 of blocks to which the highest block 15 belongs among the blocks 15 delimiting the channel. This highest level may vary from one channel to another, in particular if the number of blocks 15 varies from one level N1, N2, N3, N4 to another.

[0105] Each connecting element 20, 25A, 25B is housed jointly in two conduits 50 communicating with each other, in particular in two conduits 50 sharing a common axis A. In particular, each connecting element 20, 25A, 25B is housed in a conduit 50 coaxial with a protuberance 60 of a block 15 and in the conduit 50 opening into the bottom 80 of the cavity 75 in which the protuberance 60 is housed.

[0106] Each connecting element 20, 25A, 25B is configured to lock at least one degree of freedom between the blocks 15 in which the connecting element 20, 25A, 25B is housed.

[0107] For example, each connecting element 20, 25A, 25B is configured to prevent a translation and/or a relative rotation of the blocks 15 in which the connecting element 20, 25A, 25B is housed. Each connecting element 20, 25A, 25B is configured, in particular, to prevent a translation along an axis perpendicular to the vertical direction Z and/or a relative rotation about an axis perpendicular to the vertical direction Z of these two blocks 15.

[0108] Each connecting element 20, 25A, 25B is made of a metallic material such as steel, in particular stainless steel or galvanized steel.

[0109] According to the embodiment shown in Figures 1 to 3, the set of connecting elements 20 includes a set of first connecting elements 20 and a set of second connecting elements 25A, 25B. It should be noted that embodiments may also be contemplated in which the set of connecting elements comprises only first connecting elements 20, or conversely only second connecting elements 25A, 25B.

[0110] Each first connecting element 20 is configured to prevent a relative translation according to the vertical direction Z between the blocks 15 in which the first connecting element 20 is housed. In particular, the first connecting element 20 is configured to exert on the blocks 15 in which the first connecting element 20 is housed a force that opposes said translation.

[0111] Thus, the first connecting element 20 prevents a relative rotation of these blocks 15 around an axis perpendicular to the vertical direction Z since such a displacement would necessarily entail a relative displacement of these blocks 15 according to the Z direction due to the fact that the blocks 15 considered are superimposed. Such a rotation would in fact entail a rotation of the blocks 15 around a contact point located at the intersection of a lateral face 45 with a lower face 40 or upper face 35, and therefore a relative displacement of these blocks 15 according to the Z direction.

[0112] Each first connecting element 20 is jointly fixed to at least two of the blocks 15 that delimit the ducts 50 in which the first connecting element 20 is housed.

[0113] According to one embodiment, each first connecting element 20 is fixed to the lower face 40 of the block 15 of the lowest level N1, N2, N3 among the blocks 15 in which the first connecting element 20 is housed and to the upper face 35 of the block 15 of the highest level N2, N3, N4 among these blocks.

[0114] Each first connecting element 20 includes, for example, a flexible link such as a cable or a chain. However, other types of first connecting elements 20 may also be contemplated, for example a rod or a tube.

[0115] Each first connecting element 20 is fixed, for example, to the corresponding upper face 35, in particular to the terminal face 65 of the protuberance 60, by a bar or a plate passing in a cable loop and resting against the upper face 35 or the terminal face 65 of the protuberance.

[0116] Each first connecting element 20 is fixed, for example, to the corresponding lower face 40, in particular to the bottom 80 of the cavity 75, by a bar or a plate passing in a cable loop and resting against the bottom 80.

[0117] According to one embodiment, each first connecting element 20 is housed jointly in each of the conduits 50 of a set of conduits 50 communicating with each other. In particular, if at least three conduits 50 communicate with each other, that is to say if a channel is pierced by at least three conduits 50 delimited by three or more superimposed blocks 15, the first connecting element 20 is housed jointly in each of these conduits 50. The first connecting element 20 is configured to prevent a relative displacement according to the vertical direction Z of each of the blocks 15 delimiting the conduits 50 in which the first connecting element 20 is housed with respect to the other blocks 15 delimiting these conduits.

[0118] According to one embodiment, each first connecting element 20 is jointly fixed to the upper face of the block 15 of the highest block level N2, N3, N4 among the blocks 15 delimiting the ducts 50 in which the first connecting element 20 is housed and to the lower face 40 of the block 15 of the lowest level N1 among the blocks 15 delimiting the ducts 50 in which the first connecting element 20 is housed.

[0119] Each second connecting element 25A, 25B is configured to bear against the walls of the ducts 50 in which the second connecting element 25A, 25B is housed to prevent a relative rotation of the blocks 15 in which the second connecting element 25A, 25B is housed about an axis perpendicular to the vertical direction Z. Thus, if a force is applied tending to rotate a block 15 relative to a block 15 supporting it on this block 15, the second connecting element 25A, 25B bears against the walls of the ducts 50 of these two blocks to prevent this rotation. In particular, the second connecting element 25A, 25B exerts a force on the walls of the ducts 50 in which the second connecting element 25A, 25B is housed, with the force opposing said rotation. The stress appears in particular when a force tending to generate said rotation is exerted on the blocks 15 in which the second connecting element 25A, 25B is housed.

[0120] Each second connecting element 25A, 25B is further configured to prevent a displacement of a block 15 relative to at least one other block 15 in a plane perpendicular to the vertical direction Z.

[0121] Each second connecting element 25A, 25B has a length, measured according to the vertical direction Z.

[0122] For example, at least one second connecting element 25A, 25B has a length greater than or equal to the first height H1. In order for the connecting elements 25A, 25B to traverse at least 2 blocks vertically, it may be necessary to use a complementary element 25C that allows the connecting elements 25A, 25B to function properly.

[0123] The set of second joining elements 25A, 25B includes, for example, a first set of second joining elements 25A, a second set of second joining elements 25B.

[0124] Each second connecting element 25A, 25B is, for example, a tube extending along an axis parallel to the vertical direction Z. According to one embodiment, each complementary element 25C is then a tube 25C.

[0125] In another variant that may be considered, the tube(s) 25A, 25B, 25C are replaced by bars. In other words, the tubes 25A, 25B, 25C are solid. In this embodiment, for example, no connecting element 20 is present or the connecting element 20 is located next to the elements 25A, 25<b>, 25C.

[0126] Each second connecting element 25A of the first set has a length equal, for example, to the height H1 of a block 15, to an accuracy of 10%. Each second connecting element 25A has an external diameter strictly smaller than the diameter of the ducts 50. For example, the diameter of each second connecting element 25A is greater than or equal to half the diameter of the ducts 50.

[0127] Each second connecting element 25A of the first set is housed jointly in a duct 50 of a block 15 and in a duct 50 communicating with the duct 50 in question, for example in a duct 50 delimited by a block 15 of a level immediately above or immediately below the block 15 delimiting the duct 50 in question. Thus, the second connecting element 25A prevents a relative displacement of these two blocks in a plane perpendicular to the vertical direction Z.

[0128] According to one embodiment, each second connecting element 25A at least partially surrounds the first connecting element 20 housed in the same conduits 50 as the second connecting element 25A considered. For example, the first connecting element 20 passes through the second connecting element 25A according to the vertical direction Z.

[0129] Each second connecting element 25B of the second set has a length equal, for example, to three halves of the height H1 of a block 15, to an accuracy of 10%. Each second connecting element 25B has an external diameter strictly smaller than the diameter of the ducts 50. For example, the diameter of each second connecting element 25B is greater than or equal to half the diameter of the ducts 50.

[0130] Each second connecting element 25B of the second set is housed jointly in a duct 50 of a block 15 and in a duct 50 communicating with the duct 50 in question, for example in a duct 50 delimited by a block 15 of a level immediately above or immediately below the block 15 delimiting the duct 50 in question. Thus, the second connecting element 25B prevents a relative displacement of these two blocks 15 in a plane perpendicular to the vertical direction Z.

[0131] According to one embodiment, each second connecting element 25B at least partially surrounds the first connecting element 20 housed in the same conduits 50 as the second connecting element 25B considered. For example, the first connecting element 20 passes through the second connecting element 25B according to the vertical direction Z.

[0132] Each complementary element 25C has a length equal, for example, to half the height H1 of a block 15, with a precision of 10%. Each complementary element 25C has an external diameter strictly smaller than the diameter of the ducts 50. For example, the diameter of each complementary element 25C is greater than or equal to half the diameter of the ducts 50.

[0133] According to one embodiment, each complementary element 25C at least partially surrounds the first connecting element 20 housed in the same conduits 50 as the complementary element 25C considered. For example, the first connecting element 20 passes through the complementary element 25C according to the vertical direction Z.

[0134] According to the embodiment of Figure 3, each channel perforated by at least two conduits 50 houses at least one second connecting element 25B of the second set and one element 25C.

[0135] In particular, the complementary element 25C is arranged in a lower part of the conduit 50 of the lowest block 15 among the blocks 15 delimiting the channel considered, such that this element 25C is in particular in contact with the ground 17, for example supported by the ground 17. This element 25C thus extends from the ground 17 to half the height of the block 15 of the lowest level among the blocks 15 delimiting the channel considered.

[0136] Thus, the work 10 includes a first set of second connecting elements 25A, a second set of second connecting elements 25B and a third set of elements 25C, such that each element 25C and each second connecting element 25A, 25B have a length measured according to the vertical direction Z, each block 15 has a height H1 measured according to the vertical direction Z, the length of each second connecting element 25A of the first set is equal, to an accuracy of 10%, to the height H1, the length of each second connecting element 25B of the second set is equal, to an accuracy of 10%, to three halves of the height H1, the length of each element 25C of the third set is equal, to an accuracy of 10%, to half of the height H1.

[0137] The second connecting element 25B of the second set is arranged in the conduit 50 of the block 15 of the highest level among the blocks 15 delimiting the channel considered, as well as in the upper part of the conduit 50 delimited by the block 15 of the level immediately below the highest level. Thus the second connecting element 25B extends from half the height of the block of the level immediately below the highest level to the upper face 35 of the block 15 of the highest level. For example, if the channel is delimited by two superimposed blocks 15, the second connecting element 25B is supported by the element 25C.

[0138] When three or more blocks 15 delimit the ducts 50 communicating with each other, one or more second connecting elements 25A of the first set are interposed between the second connecting element 25B and the element 25C, such that the second connecting element 25B extends in the upper half of the duct 50 delimited by the block 15 of the level immediately below the highest level between the blocks 15 delimiting these ducts.

[0139] It should be noted that embodiments may be envisaged in which the order of the second connecting elements 25A, 25B and/or the elements 25C is different. For example, according to one variant, the second connecting element 25B of the second set is arranged in the duct 50 of the block 15 of the lowest level among the blocks 15 delimiting the channel considered, as well as in the lower part of the duct 50 delimited by the block 15 of the level immediately above the lowest level.

[0140] The connecting element 25A, 25B or the lowermost complementary element 25C have openings passing through them in a direction perpendicular to the vertical direction Z, such that at least one opening is, for example, a slit. This allows access to the first connecting element 20 through the connecting element 25A, 25B or the complementary element 25C in order to fix this first connecting element 20.

[0141] According to one embodiment, each anchoring element 30 is interposed between the lowest level N1 of blocks 15 and the ground 17. Each anchoring element 30 is configured, for example, to be anchored to the ground 17 and to be fixed at the end of a first connecting element 20 in order to prevent a relative displacement according to the Z direction of the blocks 15 in which the first element 20 is housed relative to each other and to the ground 17.

[0142] As an option, at least one block 15, in particular a block 15 of the first level N1, comprises at least one fixing hole passing through the corresponding block 15 from the upper face 35 to the lower face 40. Each fixing hole extends according to the vertical direction Z. Each fixing hole is distinct from the or from each duct 50 of the block 15.

[0143] Each fixing hole is, for example, cylindrical, in particular with a circular base.

[0144] Each fixing hole is configured for anchoring the block 15 to the ground, for example with the aid of an anchor bolt or an anchor cable passing through the anchor hole.

[0145] Each fixing hole is configured to allow the passage, through the anchoring hole, of a drilling tool from the upper face 35 to the lower face 40. The drilling tool is, for example, a drill.

[0146] For example, each block 15 of the first level N1 is fixed to the ground by a housed anchor bolt passing through the fixing hole.

[0147] The reinforcing elements 42 can be seen in Figure 2, but have not been represented in Figure 3 in order not to overload it.

[0148] Each reinforcing element 42 is configured to form an integral part with two second connecting elements 25A, 25B each housed in a respective duct 50 of the block 15 considered. In particular, each reinforcing element 42 is configured to form an integral part with two second connecting elements 25A, 25B each housed at the upper ends of the ducts 50 of the block 15 considered, or to form an integral part with two second connecting elements 25A, 25B each housed at the lower ends of the ducts 50 of the block 15 considered.

[0149] Each reinforcing element 42 is configured, in particular, to prevent a translation in a horizontal plane between the two second connecting elements 25A, 25B that form an integral part.

[0150] According to the example of Figure 1, each reinforcing element 42 is a plate drilled with two holes, such that each hole is crossed by a conduit 50 of the block 15 considered. For example, each second connecting element 20, 25A, 25B is surrounded, in a horizontal plane, by each reinforcing element 42 of the block 15 considered.

[0151] For example, each reinforcing element 42 jointly surrounds the two upper ends or the two lower ends of the two ducts 50 of the same block 15.

[0152] When the reinforcing element 42 is a plate, the reinforcing element 42 is horizontal.

[0153] It should be noted that other forms of reinforcement elements 42 may be contemplated, for example a special fitting based on molded wires or based on a cable sling.

[0154] Each reinforcing element 42 is made of a metallic material, in particular steel.

[0155] During the manufacture of the work 10, the anchoring elements 30 are placed first.

[0156] Levels N1, N2, N3, N4 of blocks 15 are placed one after another.

[0157] After the placement of each level N1, N2, N3, N4 of blocks 15, a second connecting element 25A, 25B or an element 25C is inserted into each conduit of the placed blocks 15.

[0158] In the blocks of level N1, elements 25C are inserted. In the blocks of the other levels, second connecting elements 25A or 25B are inserted, depending on whether the duct 50 into which the second connecting element 25A or 25B is inserted is intended to communicate or not with a duct 50 of a higher level.

[0159] Finally, the connecting elements 20 are placed after all the blocks 15 and all the second connecting elements 25A, 25B and the elements 25C have been placed.

[0160] The work 10 is easy to manufacture and to place, since the fit of the protuberances 60 in the cavities 75 allows the ducts 50 to be positioned precisely with respect to each other. In addition, this fit limits the movements of the blocks 15 with respect to each other in a horizontal plane. The joining elements 20, 25A, 25B then allow these easily fitted blocks to be effectively joined together to form a very strong work 10.

[0161] When each connecting element 20 is common to all the conduits 50 that communicate with each other, and thus a single connecting element 20 is provided for each channel, the manufacture of the work 10 is especially simple.

[0162] Flexible links such as cables or chains allow easy placement of the work 10.

[0163] The use of second connecting elements 25A, 25B housed in the ducts 50 makes it possible to connect the blocks 15 in the plane perpendicular to the vertical direction Z in a simple manner and in particular without complicating the positioning of the connecting element 20 when these connecting elements 25A, 25B are tubes. The choice of the two types of second connecting elements 25A, 25B and of the elements 25C superimposed on the channels formed by at least three blocks 15 makes it possible in particular to ensure simple positioning of these second connecting elements while ensuring that the stresses in said plane are well distributed over the entire surface of the ducts 50.

[0164] If the protuberances 60 are rotationally symmetrical, the placement of the blocks 15 is facilitated because during their placement a rotation of the blocks 15 relative to one another in a horizontal plane is tolerable. The truncated cone shape also facilitates the placement of the blocks 15 because a disorientation of the blocks 15 is then tolerable in which the axes A are not confused.

[0165] Furthermore, when the protuberances 60 present a rotational symmetry, a rotation between the blocks 15 around a vertical axis is possible, which allows the shape of the work 10 to be easily adapted to a change of direction.

[0166] If the A axes are aligned with each other according to the Y direction and the projections have rotational symmetry, the placement of the blocks is also simplified.

[0167] When the axes of the ducts 50 coincide with the axes of the corresponding protuberances 60, it is possible to rotate the blocks 15 relative to each other to form a curved wall in which the blocks 15 of the same level N1, N2, N3, N4 are not aligned, without having an effect on the second connecting elements 25A, 25B or on the first connecting elements 20. Furthermore, this also makes it possible to orient the blocks 15 so that their main direction is not parallel to the direction of extension of the work 10.

[0168] A staggered arrangement of the blocks 15 allows a particularly strong work 10 to be formed in a very simple manner, since it is no longer necessary for neighbouring blocks 15 on the same level to form an additional solid part.

[0169] The passages 57 allow access to the cavities 75 after the placement of the blocks 15, and in particular of the blocks 15 of the lowest level N1, and therefore to fix the first connecting elements 20 to these blocks 15 or to the anchoring elements 30 after the blocks 15 are placed. The manufacture of the work 10 is then facilitated.

[0170] Furthermore, when the work 10 is a wall having two thicknesses of blocks according to the first direction X, or more, the passages 57 also make it possible to connect the blocks 15. In particular, these blocks 15 are integral with each other by means of a metal element housed jointly in a passage 57 of each of these two blocks 15. This results in particular in simply fixing the two thicknesses of blocks 15 to each other.

[0171] In the example above, work 10 has been described in a function as a containment work or as a protection against falling materials. However, it should be noted that work 10 is also adapted to other functions. For example, work 10 is a confinement wall for a property.

[0172] Furthermore, it should be noted that embodiments may be contemplated in which the reinforcing elements 42 are not integrated into the blocks 15. For example, each reinforcing element 42 is interposed between two levels N1, N2, N3, N4 of superimposed blocks 15.

[0173] In particular, each reinforcing element 42 is integral with two second connecting elements 25A, 25B belonging to two neighbouring blocks 15 of the same level N1, N2, N3, N4. These reinforcing elements are especially adapted to form an integral part with neighbouring columns of a work 10 which do not form a staggered arrangement of the blocks 15.

[0174] In one exemplary embodiment, the blocks 15 are aligned along the vertical direction Z to form a set of columns. The blocks 15 of the same column are aligned with each other along the vertical direction Z.

[0175] In the case of a work composed of several blocks 15 aligned according to the X direction, the columns are aligned for example with each other, each block 15 of a column being located at the level of a block 15 of each other adjacent column, or, as a variant, the columns are not aligned with each other, each block 15 of a column being horizontally offset with respect to each adjacent block 15 of an adjacent column.

[0176] The columns are connected to each other by reinforcing elements 42. The geometry of the reinforcing elements is adapted as appropriate.

[0177] The dimensions or shapes of the blocks 15 may vary. For example, the work includes two types of blocks 15 of which one of the two types has a first length L1 equal to half the length L1 of the blocks 15 of the other type. In this case, the smaller blocks 15 each comprise a single conduit 50.

[0178] Furthermore, the above description has been made in the case where the vertical direction Z is the vertical of the place where the work 10 is placed. It should be noted that the vertical direction Z may differ from the vertical of the place. In all cases, the term "horizontal" is understood to mean a direction or plane perpendicular to the vertical direction Z.

[0179] Furthermore, it is possible to envisage a perforated work 10 with interconnected walls.

[0180] In one embodiment, a work 10 comprises a first wall and a second wall, the blocks 15 of each level N1, N2, N3, N4 of the first wall being aligned according to the second direction Y, with the blocks 15 of each level N1, N2, N3, N4 of the second wall being aligned according to the third direction X, and at least one block 15 of the first wall being integral with a block 15 of the second wall. According to one embodiment, this integrality can be ensured by means of a block 15 one and a half times longer than the other blocks 15 and having a third conduit 50.

[0181] In another exemplary embodiment, a work is perforated by the meeting of at least two walls parallel to each other, each wall being perpendicular to the third direction X and having a thickness of a single block 15 according to the third direction X, with at least one block 15 of one wall forming an integral part with a block 15 of the other wall.

[0182] It is also noteworthy that embodiments can be envisaged in which the first connecting elements 20 are not common to all the blocks 15 delimiting the same channel but only to two superimposed blocks. A first connecting element 20 is then provided for each pair of superimposed blocks 15.

[0183] A second example of work 10, shown in Figure 4, will now be described. Elements identical to the first example of work 10 are not described again, and only the differences are highlighted.

[0184] A case is shown in Figure 4 where each block 15 includes a parallelepiped central portion and two semi-cylindrical end portions 97. However, other shapes of blocks 15 may be contemplated.

[0185] The protuberance 60 is formed by a plurality of projections 100 spaced apart from each other.

[0186] Figure 4 shows a case where the protuberance 60 is formed by two projections 100.

[0187] Each projection 100 extends in the vertical direction Z from the upper face 35.

[0188] The duct 50 opens into the bottom 80 of the corresponding cavity 75 and into the upper face 35.

[0189] The projections 100 are configured so that the protuberance 60 allows, with the cavity 75 in which the protuberance 60 is housed, a rotation between the two corresponding blocks 15 around the axis A common to the protuberance 60 and the cavity 75.

[0190] The projections 100 are arranged, in particular, along a circle centered on the axis A of the protuberance 60. The circle has in particular a diameter strictly greater than the diameter of the duct 50. Thus, the projections 100 surround, in a plane perpendicular to the axis A, the end of the duct 50 which opens onto the upper face 35.

[0191] According to the example shown in Figure 4, the two projections 100 are equidistant from the axis A, for example diametrically opposite each other according to the Y direction.

[0192] It should be noted that the number of projections 100 may vary. For example, embodiments may be contemplated in which the protrusion includes three or more projections 100.

[0193] For example, the projections 100 are arranged at the vertices of a regular polygon centered on the axis A, the polygon including for example but not exclusively as many vertices as there are projections 100 in the protuberance. For example, the protuberance 60 includes four projections 100 arranged at the four vertices of a square. The sides of the square are, in particular, each parallel or perpendicular to the Y direction.

[0194] As a variant, the projections 100 are three, arranged at the vertices of an equilateral triangle centered on axis A, or 6 and arranged at the vertices of a hexagon centered on axis A.

[0195] By "centered on axis A" we mean that the distance between each vertex and axis A is identical for each of the vertices.

[0196] According to the example represented in figure 4, each projection 100 is parallelepiped.

[0197] As a variant, each projection 100 has an external face configured to bear against the third face 85 of the cavity 75 in which the projection 100 is coupled, each external face being a part of a surface having a circular symmetry about the axis A, this surface being common to all the projections 100 of the protuberance 60 considered. In particular, this surface is a truncated cone centered on the axis A, and each external face is thus a part of a truncated cone. According to other embodiments that may be contemplated, this surface is a part of a sphere, or is cylindrical.

[0198] Said truncated cone is identical, in particular, to the truncated cone mentioned above in the first example of work 10.

[0199] Each projection 100 is, for example, removable with respect to block 15. For example, each projection 100 is formed by a pin 100 configured to be inserted into a recess in the upper face 35.

[0200] According to the example shown in Figure 4, a single slot-shaped recess 105 is provided on the upper face 35, and each pin 100 is partially housed in the slot 105.

[0201] The slot 105 is, for example, an annular slot delimited by two concentric cylindrical surfaces in a plane perpendicular to the axis A. The slot 105 is centered, in particular, on the axis A. However, other shapes of slot 105 may be contemplated, for example a polygonal slot 105.

[0202] The slot 105 has an internal diameter between 7.5 cm and 120 cm, for example 30 cm.

[0203] The slot 105 has an external diameter between 9.5 cm and 152 cm, for example 38 cm.

[0204] The slot 105 has a depth, measured in the Z direction, between 1.25 cm and 20 cm, for example 5 cm.

[0205] As a variant, a plurality of recesses are arranged on the upper face 35, the recesses being arranged at the vertices of a regular polygon. For example, on the upper face 35 there are six recesses placed at the vertices of a hexagon whose two sides are parallel to the Y direction.

[0206] A first portion of each pin 100 is then received in the corresponding recess or slot 105, and a second portion of the pin 100 extends from the upper face 35 in the vertical direction Z to form the projection 100. Each recess is configured to hold the corresponding pin 100 in its position relative to the upper face. In particular, the recess is complementary to the corresponding portion of the pin 100.

[0207] Each pin 100 is made, for example, of a metallic material. For example, each pin 100 is made of steel, in particular stainless steel. Each pin 100 is, for example, shaped like wedges, in particular made of wood. This allows for greater flexibility in assembling the blocks during assembly.

[0208] The first part has a height, measured according to the vertical direction Z, between 3 cm and 10 cm, for example equal to 5 cm. The first part is, for example, triangular.

[0209] The second part of each spike 100 has, for example, a height measured according to the vertical direction Z greater than or equal to 1 cm, for example greater than or equal to 5 cm.

[0210] Each pin 100 is, for example, solid. Alternatively, pin 100 is hollow.

[0211] As an optional addition, each slot 105 is connected by a trench 110 arranged on the upper face 35 to a first lateral face 45. The trench 100 has a depth greater than or equal to the depth of the corresponding slot 105, and in particular is sloping from the slot 105 to the corresponding lateral face 45 so as to allow the evacuation of rainwater that could penetrate the slot 105.

[0212] It should be noted that embodiments may also be contemplated in which a single removable projection 100 is present on some of the blocks.

[0213] When the protuberance 60 includes several separate projections 100, the work 10 allows the passage of the forks of a lifting machine between the projections 100, and thus facilitates the placement of the blocks 15. In addition, said projections can be destroyed, deformed or sectioned in the event of a collision against the work 10, without the structure of the block 15 being damaged.

[0214] Rotation between blocks 15 of different levels N1 to N4 is especially simple if the external faces of the projections 100 are shaped like part of a truncated cone.

[0215] The projections 100 formed by removable pins allow for easy replacement in the event of damage during a collision. Thus, the blocks 15 can be reused even when the projections have been damaged, for example during a fall of stones against the work 10.

[0216] The annular groove 105 allows the pins 100 to be positioned freely, and in particular to provide a passage between the projections 100 so as to allow the passage of a fork of a lifting machine, this passage being freely oriented. Thus, the positioning of the work 10 is made easier, in particular when the work 10 is curved or is arranged in a place where the lifting machines cannot be positioned freely, since the orientation of the lifting machine with respect to the work can thus vary.

[0217] It should be noted that the annular slot also allows the pins 100 to be positioned so that they are not arranged at the vertices of a regular polygon. In fact, the slot 105 allows great freedom of positioning of the pins 100.

[0218] The semi-cylindrical end portions 97 make it possible in particular to facilitate the rotation of the blocks 15, and to allow their free orientation relative to each other in the horizontal plane.

Claims (19)

1. Work (10), in particular for impact protection or containment, the work (10) comprising a set of blocks (15) and at least one connecting element (20, 25A, 25B), the blocks (15) being distributed on several levels (N1, N2, N3, N4) superimposed according to a vertical direction (Z), so that each block (15) has an upper face (35) and a lower face (40), each block (15) having at least two axes (A) parallel to the vertical direction (Z), each block (15) including, for each axis (A), a protuberance (60), a duct (50) and a cavity (75), so that each protuberance (60) is arranged on the upper face (35), each cavity (75) being arranged on the lower face (40), such that each cavity (75) has a bottom (80) delimiting the cavity (75) according to the vertical direction (Z), with each duct (50) extending along the corresponding axis (A) and being delimited by the block (15), such that each duct (50) passes through the block 15 according to the vertical direction (Z) and opens into the corresponding first cavity (75), each cavity (75) of a block (15) belonging to a block level (N2, N3, N4) different from the lowest level (N1) housing a cavity (75) of a block (15) protuberance (60) of a block (15) of a level (N1, N2, N3, N4) of blocks (15) immediately below the block (15) considered, the axis (A) of the cavity (75) being coincident with the axis (A) of the protuberance (60) housed in the cavity (75), the work being such that each protuberance (60) and the cavity (75) in which said protuberance (60) is housed are configured to allow a relative rotation about the axis (A) of the protuberance (60) between the block (15) including the protuberance (60) and the block (15) including the cavity (75), such that at least one connecting element (20, 25A, 25B) is jointly received in the two ducts (50), the connecting element (20, 25A, 25B) being configured to block at least one degree of freedom between the blocks (15) in which the connecting element (20, 25A, 25B) is housed, with said work characterized in that the protuberance (60) includes a plurality of projections (100) arranged along a circle centered on the axis (A) of the protuberance (60), such that each projection (100) is provided with ... (100) extends in the vertical direction (Z) from the upper face (35). 2. Work according to claim 1, wherein the protuberance (60) is a projection (60) in the form of a truncated cone centered on the axis (A). 3. Work according to any of claims 1 or 2, wherein each projection has an external face configured to rest against a lateral face (85) of the cavity (75) in which the protuberance (60) is housed, the external face being in the form of part of a truncated cone centered on the axis (A). 4. Work according to any of claims 1 to 3, wherein each projection (100) is formed by a part of a pin (100) removable with respect to the corresponding block (15). 5. Work according to claim 4, wherein each block (15) includes, for each axis (A), an annular groove (105) arranged on the upper face (35), a part of each pin (100) being housed in the groove (105). 6. Work according to any of the preceding claims, wherein each cavity (75) has a second lateral face (85) that delimits the cavity (75) in a plane perpendicular to the vertical direction (Z), the second lateral face (85) being a part of a truncated cone that extends along the axis (A) of the cavity (75). 7. Work according to any of the preceding claims, in which at least one connecting element (20) is jointly fixed to two of the blocks (15) that delimit the ducts (50) in which the connecting element (20) is housed. 8. Work according to any of the preceding claims, wherein at least one connecting element (20) is configured to prevent a relative translation according to the vertical direction (Z) of the blocks (15) that delimit the ducts (50) in which the connecting element (20) is housed. 9. Work according to any of the preceding claims, wherein at least one connecting element (20) includes a flexible link such as a cable or a chain. 10. Work according to any of the preceding claims, wherein at least one connecting element (20) includes a rigid link such as a bar or a tube. 11. Work according to any of the preceding claims, wherein at least one connecting element (20) is housed in ducts (50) delimited by a plurality of blocks (15) superimposed according to the vertical direction (Z), the connecting element (20) being fixed to the lower face (40) of the block (15) belonging to the lowest level (N1) and to the upper face of the block (15) belonging to the highest level (N2, N3, N4). 12. Work according to any of the preceding claims, wherein at least one connecting element (25A, 25B), such as a bar or a tube, is configured to rest against the walls of the ducts (50) in which the connecting element (25A, 25B) is housed so as to exert on these walls a force that opposes a translation between the blocks along an axis perpendicular to the vertical direction (Z) or a relative rotation of the blocks (15) in which the connecting element (25A, 25B) is housed around an axis perpendicular to the vertical direction (Z). 13. Work according to the preceding claim, wherein each block (15) has a height measured according to the vertical direction (Z), at least one connecting element (25A, 25B) configured to rest against the walls of the ducts (50) in which the connecting element (25A, 25B) is housed to exert on these walls a force that opposes a translation between the blocks according to an axis perpendicular to the vertical direction (Z) and/or a relative rotation of the blocks (15) in which the connecting element (25A, 25B) is housed around an axis perpendicular to the vertical direction (Z) having a length measured according to the vertical direction (Z), the length being greater than or equal to the height of a block (15). 14. Work according to any of the preceding claims, wherein each duct (50) has a rotation symmetry around the corresponding axis (A). 15. Work according to any of the preceding claims, wherein the blocks (15) are arranged vertically in a staggered pattern. 16. Work according to any of the preceding claims, wherein each block (15) extends along a main direction (Y) in a plane perpendicular to the vertical direction (Z), such that the axes (A) of the block (15) considered define a plane parallel to the main direction (Y), a distance measured along the main direction (Y) between the axes (A) being in particular greater than or equal to half a length of the block (15) considered measured along the main direction (Y). 17. Work according to the preceding claim, in which each block (15) has at least one lateral face (45) that delimits the block (15) in a plane perpendicular to the vertical direction (Z), with each block (15) also delimiting, for each cavity (75), at least one passage (57) that extends along a lateral direction (X) perpendicular to the vertical direction (Z) and that opens into the cavity (75) and into a lateral face (45). 18. Work according to the preceding claim, which includes at least two blocks (15) that are integral with each other by means of a metallic element housed in a passage (57) of each of the blocks (15) considered. 19. Work according to any of the preceding claims, wherein the work (10) extends along an extension direction (Y) in a plane perpendicular to the vertical direction (Z), each block (15) extending along a main direction in a plane perpendicular to the vertical direction (Z), such that an angle between the extension direction (Y) and the main direction of at least one block (15) is strictly greater than zero, in particular greater than or equal to 15 degrees.