BRPI0621718A2 - brick and rod system; and three-dimensional rectangular brick for wall construction - Google Patents

Abstract

BRICK AND ROD SYSTEM; AND THREE-DIMENSIONAL RECTANGULAR BRICK FOR WALL CONSTRUCTION. It is a brick and rod system (4, 5A, 5B) for the construction of walls with high resistance to gravitational, lateral and extreme cyclical forces. This system allows the construction of a wall made of bricks reinforced with a frame of rods (4, 5A, 5B). The brick of this system is a rectangular block with horizontal (1) and vertical (3) protrusions and cavities (2) allowing horizontal and vertical insertions with the adjacent bricks on the wall. The brick is also drilled by holes (15) that are aligned with the holes (15) of the vertically adjacent bricks of the wall, thus forming a continuous vertical hole (15) that crosses the entire height of the wall. The rod (4, 5A, 5B) of the system goes through the continuous hole (15) of the wall.

Description

"BRICK AND ROD SYSTEM; AND THREE-DIMENSIONAL RECTANGULAR BRICK FOR WALL BUILDING".

BACKGROUND OF THE INVENTION

1. FIELD OF THE INVENTION

The present invention relates to the field of construction of brick walls that fit horizontally and vertically.

In the field of the present invention, in order to reduce the use of adhesives or mortar, the described walls are constructed of bricks having protuberances and cavities that fit horizontally and vertically. Bricks with protuberances and cavities that are fixed horizontally and vertically have also been described with the aid of high lateral strength building walls to uniform and cyclical forces of nature. However, a brick and rod system has not been described for wall construction where the use of adhesive or mortar is reduced, which also results in walls with high lateral stiffness and high resistance to extreme uniform, cyclic and gravitational forces.

2. DESCRIPTION OF PRIOR ART

In the prior art wall construction has been described using bricks with protuberances and cavities that fit horizontally and vertically resulting in walls where the use of adhesive or mortar is reduced, and with high resistance to uniform and cyclical forces of nature. Specifically, Nanayakkara describes in US Pat. Nos. 6,550,208 B2 (April 22, 2003), N - US 6,105,330 (August 22, 2000), and N - US 6,578,338 Bl (June 17, 2003) ), bricks or blocks with a horizontal and vertical jointing system, with reduced use of mortar, resulting in walls with high lateral resistance to natural and cyclic forces. U.S. Patent No. 6,550,208 B2 describes a brick having complementary positive and negative external geometries, and a continuous vertical cavity, which results in horizontal and vertical fittings between adjacent bricks for the construction of walls that could have continuous vertical cavities. .

However, neither in the prior art nor in the Nanayakkara patents is there a description of a brick or block similar to that described in the rod brick system of the present invention. The brick or block described in the Nanayakkara patents has positive and negative external geometries that are different from the brick protuberances and cavities of the present invention. Moreover, there is no example in the prior art describing a brick with perforations or holes specifically adapted to the diameter of a rod having the function of reinforcing the fittings that are formed by the bulges and cavities of the horizontally and vertically adjacent bricks of a wall. . The rod brick system of the present invention allows the construction of walls, such as retaining walls, or other type of walls with high lateral rigidity and high resistance to extreme uniform, cyclic and gravitational forces. The brick and rod system of the present invention also provides flexible fittings between horizontally and vertically adjacent bricks for the construction of walls that are less susceptible to fractures in the event of earthquakes or earthquakes.

DESCRIPTION OF THE INVENTION

The present invention provides a brick and rod system, wherein said system is characterized by a three-dimensional rectangular wall-building brick, wherein the brick is defined by the three Cartesian coordinates Χ, Υ, Z, wherein the geometric axis horizontal X defines the length of the brick, the vertical geometric axis Y defines the height of the brick, the horizontal geometric axis Z defines the width of the brick, and a rod; wherein the brick is a solid block comprising:

The. an upper horizontal surface and a lower horizontal surface defined by the axis X and Z;

B. a vertical anterior surface and a vertical posterior surface defined by the geometry axis ZeY;

ç. two vertical side surfaces defined by the geometric axis X and Y;

d. a symmetrical protrusion of rounded convex geometry that originates in the middle of the brick's anterior vertical surface in the direction of the X-axis, wherein said protrusion fits precisely into a horizontally adjacent block with the cavity described in e.g. and wherein the base of the protrusion on the vertical anterior surface of the brick, defined in the same direction as the geometric axis Z, is shorter than the maximum diameter of the convex protrusion geometry;

and. a symmetrical cavity of concave geometry which originates in the middle of the brick's posterior vertical surface in the direction of the X-axis, wherein said cavity fits precisely into a horizontally adjacent block with the protrusion described in d .; and wherein the length of the cavity aperture over the vertical posterior surface of the brick, defined in the same direction as the Z axis, is smaller than the maximum diameter of the hollow concave geometry;

f. two protrusions of cylindrical concave geometry located symmetrically in the middle of the upper horizontal surface of the brick in the direction of the geometric axis Y, wherein said protrusions fit precisely into vertically adjacent blocks with the cavities described in g .; and wherein the diameter of each bulge base on the upper horizontal surface of the brick is greater than or equal to the diameter of the cylindrical portion of the bulge;

g. two cavities of cylindrical concave geometry symmetrically located in the middle of the lower horizontal brick surface of the Y axis, wherein said cavities fit precisely into vertically adjacent blocks with the protrusions described in f .; and wherein the diameter of each cavity aperture over the lower horizontal surface of the brick is greater than or equal to the diameter of the cylindrical part of the cavity;

H. two vertical cylindrical holes that completely pierce the brick, wherein said longitude of the holes in the direction of the geometric axis Y is defined from the apex of the convex geometry of the protuberances described in f. to the apex of the concave geometry of the described cavities. in G.; and wherein said identical holes and vertically adjacent brick holes in a wall are aligned in the direction of the vertical geometric axis of the wall to form continuous vertical holes that traverse the entire height of the wall;

i. a vertical cylindrical hole that completely pierces the brick, wherein the length of said hole in the direction of the geometric axis Y is defined from the top horizontal surface of the brick to the bottom horizontal surface of the brick; and wherein said orifice is located in parallel between the two orifices described in h .; and wherein said hole and hole of equal diameter described in j. of the vertically adjacent bricks, are aligned in the direction of the vertical geometric axis of a wall to form a continuous vertical orifice that traverses the height of the wall; and wherein said holes have a diameter that adjusts to the diameter of the rod such that the rod can be introduced through the continuous hole through the height of the wall; j. a vertical cylindrical hole that completely pierces, in the direction of the Y axis, the protrusion described in d., wherein the length of the orifice is defined from the center of said upper horizontal surface of the protrusion to the center of said lower horizontal surface of the protuberance; wherein said hole and the vertically adjacent holes of brick of equal diameter described in i., are aligned in the direction of the vertical geometric axis of a wall, to form a continuous vertical hole that traverses the height of the wall; and wherein said holes have a diameter that adjusts to the diameter of the rod such that the rod can be introduced through the continuous hole through the height of the wall;

wherein the longitude of the rod is equal to or exceeds the longitude of the height of the wall; and wherein the rod is introduced vertically through the continuous vertical holes described in i. and j .;

and wherein sturdy fittings are created between vertically and horizontally adjacent bricks to construct a wall allowing the introduction of a frame made up of a plurality of rods, thus resulting in a structure with greater lateral stiffness and greater resistance to uniform, cyclic and extreme gravitationals. The brick and rod system of the present invention also provides flexible fittings for the construction of earthquake or earthquake resistant walls. In another aspect, the present invention provides a brick which is characterized by a rounded convex geometry, symmetrical protrusion that originates on one of the brick side surfaces, wherein said protrusion fits precisely into the cavity described in e.g. of a horizontally adjacent brick; and wherein the base of the protrusion on the lateral surface, defined in the same direction as geometric axis X, is less than the maximum diameter of the convex protrusion geometry.

In another aspect, the present invention provides a brick characterized by a rounded convex geometry, symmetrical protrusion that originates on one of the side vertical surfaces of the brick, wherein said protrusion fits precisely into the cavity described in e.g. of a horizontally adjacent brick; and wherein the base of the protrusion on the lateral vertical surface, defined in the same direction as geometric axis X, has a length less than the maximum convex geometry diameter of the protrusion; and wherein the protrusion length in the direction of the Z axis defined from the convex protrusion geometry apex to the base on the brick side surface is between 26% and 65% of the brick width Z.

In another aspect, the present invention provides a brick characterized by a 90 degree right-angle channel on both edges, in the direction of the Y axis, of the vertical front face; and a 90 degree right-angle channel on both edges, in the direction of the X-axis of the lower horizontal surface.

In a further aspect, the present invention provides a brick characterized by a 90 degree right-angle channel on both edges, in the direction of the Y axis, of the vertical anterior surface; a 90-degree right-angle channel on both edges in the direction of the Y axis of the vertical rear surface; a 90-degree right-angle channel on the two edges in the direction of the X axis of the upper horizontal surface; and a right angle of 90 degrees on both edges, in the direction of the X axis, of the lower horizontal surface.

A further aspect of the present invention provides a contained stem comprising:

i. a pipe whose length is equal to the height of the brick; wherein the tube functions as a female screw; and wherein the pipe has an internal thread wherein the screw described in ii. will be screwed.

ii. a male screw having a length equal to or less than the pipe length described in i., wherein the male screw has an external thread; and wherein said screw internally fits in its upper half to a tube like that described in i., and in its lower half to another tube such as that described in i .; and wherein the formed fit joins the two pipes that could be inserted into two of the vertically adjacent bricks; Wherein a continuous contained rod is formed and consists of a plurality of tubes and a plurality of male screws.

In another further aspect, the present invention provides a contained stem comprising stem fragments wherein the length of each stem fragment is one and a half times (1.5X) the length of the brick height, and wherein each fragment of stem is formed by three parts defined as first part, second part and a third part; wherein the three parts have exactly the same length, such that each part has a length equal to one third of the length of the stem fragment; wherein the first part is an end of the stem fragment; and wherein the first part is hollow with an internal thread, thus constituting the part that functions as a female screw of the rod fragment; and wherein the second part is in the middle of the stem fragment between the first part and the third part; and wherein the second part is solid; and wherein the third part is solid with an external thread; and wherein the third part is located at the opposite end to the end constituted by the first part; and wherein the third part is the part that acts as the male rod fragment screw; and wherein the first part of a rod fragment is screwed to the third part of another identical rod fragment, and wherein a plurality of identical rod fragments which have been screwed together form the contained rod. In a further aspect, the present invention provides a brick which is characterized by a rounded convex geometry, symmetrical protrusion that originates in the middle of the vertical anterior surface of the brick in the direction of the geometric axis X, wherein said protrusion fits precisely and the horizontally adjacent block with the cavity described in e .; and wherein the base of the protrusion on the vertical anterior surface of the brick, defined in the same direction as the geometric axis Z, has a length less than the maximum diameter of the convex protrusion geometry; and wherein the protrusion length in the direction of the X-axis, defined from the apex of the protrusion's convex geometry to the base on the vertical anterior surface of the brick, is between 26% and 65% of the width Z of the brick.

Another further aspect of the present invention provides a brick which is characterized by concave geometry, a symmetrical cavity that originates in the middle of the vertical rear surface of the brick in the direction of the geometric axis X, wherein said cavity fits precisely into the protrusion described in d. . ; and wherein the length of the cavity opening over the brick's posterior vertical surface, defined in the same direction as the Z axis, is less than the maximum diameter of the hollow concave geometry; and wherein the length of the cavity in the direction of the X-axis, defined from the apex of the hollow concave geometry to the opening on the vertical back surface of the brick, is between 26% and 65% of the brick width Z.

In another further aspect, the present invention provides a brick which is characterized by two protrusions of cylindrical convex geometry located symmetrically in the middle of the upper horizontal surface of the brick in the direction of the Y axis, wherein said protrusions fit precisely into the blocks. vertically adjacent to the cavities described in g .; and wherein the diameter of each base on the upper horizontal surface of the brick is greater than or equal to the diameter of the cylindrical portion of the bulge; and wherein the longitude of the protuberance in the direction of the Y axis from the convex geometry apex of the protuberance to the base on the upper horizontal surface of the brick is between 26% and 65% of the brick width Z.

In another further aspect, the present invention provides a brick which is characterized by two cavities of concave and cylindrical geometry symmetrically located in the middle of the lower horizontal surface in the direction of the geometric axis Y, wherein said cavities fit precisely into the blocks vertically. adjacent to the bulges described in f .; and wherein each aperture diameter of the cavity over the lower horizontal surfaces of the brick is greater than or equal to the diameter of the cylindrical part of the cavity; and wherein the length of the cavity in the direction of the geometric axis Y, defined from the apex of the hollow concave geometry to the cavity opening on the lower horizontal surface of the brick, is between 26% and 65% of the width Z of the brick. .

In a further aspect, the present invention provides a brick which is characterized by two vertical cylindrical holes that completely pierce the brick, wherein the length of said holes in the direction of the Y axis is defined from the apex of the convex geometry of the protuberances described in f. to the apex of the concave geometry of the cavities described in g .; and wherein these two holes and the identical holes of the vertically adjacent bricks in a wall are aligned in the direction of the vertical geometric axis of the wall to form continuous vertical holes that completely cross the height of the wall; and wherein the diameter of the two holes fits the diameter of the rod;

and wherein the length of the rod is equal to or exceeds the length of the height of the wall; and wherein the rod is vertically introduced through the continuous vertical holes of the wall.

Further objects and advantages of the present invention will become more apparent from the description of the figures, the detailed description of the invention and the claims.

BRIEF DESCRIPTION OF DRAWINGS

Figure 1 is a three-dimensional view of one embodiment of the brick and rod system of the present invention. Figures 2A and 2B are three-dimensional views of stem fragments.

Figure 3 is a three-dimensional view of one of the brick embodiments of the present invention.

Figure 4 is a two-dimensional view of the upper horizontal surface of one of the brick embodiments of the present invention.

Figure 5 is a two-dimensional view of one of the vertical side surfaces of one of the brick embodiments of the present invention.

Figure 6 is a two-dimensional view of a sagittal plane cutting the channel in half, in the direction of the geometric axis Z, which passes through one of the holes that pierce one of the brick embodiments of the present invention.

Figure 7 is a three-dimensional view of one of the brick embodiments of the present invention.

Figure 8 is a two-dimensional view of the upper horizontal surface of one of the brick embodiments of the present invention.

Figure 9 is a three-dimensional view of one of the brick embodiments of the present invention.

Figure 10 is a two-dimensional view of the upper horizontal surface of one of the brick embodiments of the present invention.

Figure 11 is a three-dimensional view of one of the brick embodiments of the present invention. Figure 12 is a two-dimensional representation of a side plan of a wall constructed with one of the brick embodiments of the present invention.

Figure 13 is a two-dimensional representation of a side plan of a wall constructed with a plurality of one brick embodiment and a plurality of rods of the present invention.

Figure 14 is a three-dimensional view of one of the brick embodiments of the present invention.

Figure 15 is a two-dimensional view of the upper horizontal surface of two of the brick embodiments of the present invention.

Figure 16 is a two-dimensional view of a plane cutting in the direction of the geometric axis Z passing through one of the holes that is applied from the protuberance and the vertical cavity and vertically piercing one of the brick embodiments of the present invention.

Figure 17 is a two-dimensional view of one of the vertical side surfaces of one of the brick embodiments of the present invention.

Figure 18 is a three-dimensional view of one of the brick embodiments of the present invention.

Figure 19 is a two-dimensional view of the upper horizontal surface of two of the brick embodiments of the present invention.

Figure 20 is a three-dimensional view of one of the brick embodiments of the present invention. Figure 21 is a two-dimensional view of the upper horizontal surface of two of the brick embodiments of the present invention.

Figure 22 is a three-dimensional view of one of the brick embodiments of the present invention.

Figure 23 is a two-dimensional view of the upper horizontal surface of one of the brick embodiments of the present invention.

Figure 24 is a two-dimensional representation of a side plan of a wall constructed with one of the brick embodiments of the present invention.

Figure 25 is a two-dimensional representation of a side plan of a wall constructed with a plurality of one brick embodiment and a plurality of rods of the present invention.

Figure 26 is a three-dimensional view of one of the brick embodiments of the present invention.

Figure 27 is a three-dimensional view of one of the brick embodiments of the present invention.

Figure 28 is a three-dimensional view of one of the brick embodiments of the present invention.

Figure 29 is a three-dimensional view of one of the brick embodiments of the present invention.

DETAILED DESCRIPTION OF THE INVENTION

Figure 1 shows a three-dimensional view of one of the brick embodiments and two of the rod embodiments (4), (5A) and (5B) inserted into the brick. Figures 2A and 2B show two embodiments of the stem fragment that is embedded in other stem fragments that form a composite stem. The brick is defined as shown in Figure 7 by the three Cartesian coordinates Χ, Υ, Z where the horizontal geometry axis X defines the length, the vertical geometry axis Y defines the height and the horizontal geometry Z defines the width.

Figures 5 and 6 show that the brick has an upper horizontal surface (6) and a lower horizontal surface (13).

Figures 3, 4 and 5 show the anterior vertical surface (7) and the anterior vertical surface (8) of the brick.

Figures 4 and 6 show the two vertical side surfaces 14 of the brick.

Figures 3 and 4 show a brick embodiment comprising a rounded protuberance of symmetrical convex geometry (1), which originates in the intermediate part of the anterior vertical surface (7) of the brick, wherein said protuberance (1) it fits precisely into a horizontally adjacent brick with a symmetrical hollow of concave geometry (2) that originates from the intermediate part of the rear vertical surface (8) of the brick. Figure 4 shows that the longitude of the base of the protuberance (9) on the anterior vertical surface (7) of the brick is shorter than the maximum convex geometry diameter of the protuberance (10). Figure 4 also shows that the length of the cavity aperture (11) on the posterior vertical surface of the brick is less than the maximum diameter (12) of the cavity's concave geometry. Figures 3, 4, 5 and 6 show two protrusions (3) of cylindrical convex geometry located symmetrically on the intermediate part of the upper horizontal surface of the brick. Said protuberances (3) fit precisely into the vertically adjacent blocks with cylindrical concave geometry cavities (16) (Figure 5) situated symmetrically on the intermediate part of the lower horizontal surface (13). In Figure 6, it can be seen that the base diameter (18) of each protrusion on the upper horizontal brick surface is greater than or equal to the diameter of the cylindrical part (17) of the protrusion (3). Also, in Figure 5, it can be seen that the diameter of the opening (19) of each cavity in the lower horizontal surface (13) of the brick is greater than or equal to the diameter of the cylindrical part (20) of the cavity (16).

Figures 1 to 8 show two vertical cylindrical holes (15) that completely pierce the brick, and the length of said holes is defined from the convex geometry apex (21) (Figure 5) of the protuberances (3). to the apex of concave geometry (22) (Figure 5) of the cavities (16).

In Figure 12, it can be seen that the holes (15) and the identical holes (15) of the vertically adjacent bricks in a wall are aligned in the direction of the vertical geometric axis of the wall to form continuous vertical holes that are applied along the wall. wall height. Figures 3 to 12 show a cylindrical vertical hole (23) which completely punctures the brick, the length of said hole being defined from the upper horizontal surface (6) of the brick to the lower horizontal surface (13). Brick The hole (23) lies parallel between the two holes (15). Figures 3-5, 7, 8 and 12 show a vertical cylindrical hole (24) that fully punctures the protrusion (1). The length of said hole (24) is defined from the center of the upper horizontal surface of said protuberance (1) to the center of the lower horizontal surface of said protuberance (1).

In Figure 12, it can be seen that the hole (23) and the hole (24) with diameter equal to the vertically adjacent bricks are aligned in the direction of the vertical geometric axis of a wall to form a continuous vertical hole that is applied to the along the height of the wall. In Figure 13, it can be seen that the diameter of the holes (23) and (24) fit into the diameter of a rod (4), (5), (26) or (27) (Figures 1 and 2). such that the rod can be introduced through the continuous hole that is applied along the height of the wall.

In Figure 13, it can also be seen that the rod length is equal to or exceeds the length of the wall height. In addition, it can be seen that the rod is vertically introduced through the continuous vertical holes that resulted from the alignment of the holes (23) and (24) (Figures 12 and 13). Figures 7 and 8 show another embodiment of the brick of the present invention. In this embodiment, the brick does not have cavity (2), resulting in a brick with a flat posterior vertical surface (8). This brick could be the leading brick in a horizontal strip of bricks.

Figures 9 and 10 show another embodiment of the brick of the present invention. In this embodiment, the brick does not have the protrusion (1), resulting in a brick with a flat anterior vertical surface (7). This brick may be the last brick in a horizontal strip of bricks.

Figure 11 shows another embodiment of the brick of the present invention. This embodiment shows a brick which is characterized by a symmetrical protrusion (28) with rounded convex geometry that originates on one of the brick side surfaces (14). Said protuberance fits precisely into the cavity (2) of a horizontally adjacent brick.

In Figure 23, it can be seen that the base of the protrusion (29) on the lateral surface has a length less than the maximum diameter (30) of the convex protrusion geometry (28).

The described brick and rod system allows the formation of sturdy fittings between the vertically and horizontally adjacent bricks to construct a wall that allows the introduction of a skeleton consisting of a plurality of rods, thus resulting in a structure with great rigidity. lateral and high resistance to extreme uniform, cyclic and gravitational forces. In addition, the brick and rod system with rounded convex horizontal protuberances (1), rounded concave horizontal cavities (2), rounded cylindrical convex vertical protrusions (3) and rounded concave vertical cavities (16) allows the formation of flexible fittings for the construction of walls less susceptible to fracture formation in the event of seismic or earthquake movements.

Figures 14 to 21 show other embodiments of the present invention, wherein the brick comprises:

The. a symmetrical protuberance (1) of the rounded convex geometry that originates at the intermediate part of the anterior vertical surface (7) of the brick, with the longitude (31) (Figures 15 and 19) of the protuberance defined from the apex (33) of the convex geometry of the protrusion (1) to the base (32) on the anterior vertical surface (7) of the brick is between 26% and 65% of the width Z of the brick;

B. a symmetrical cavity (2) of the concave geometry that originates from the intermediate part of the posterior vertical surface (8) of the brick, and the longitude (34) (Figures 15 and 21) of the cavity defined from the apex (35) of the geometry concave from the cavity to the opening (36) in the posterior vertical surface of the brick is between 26% and 65% of the width Z of the brick;

ç. two protuberances (3) of the cylindrical-convex geometry situated symmetrically on the intermediate part of the upper horizontal surface (6) of the brick, with the longitude (37) (Figure 16) of the protuberance defined from the apex (21) of the geometry. from the protuberance to the base (38) on the upper horizontal surface (6) of the brick is between 26% and 65% of the width Z of the brick.

d. two cavities (16) of cylindrical-concave geometry located symmetrically on the intermediate part of the lower horizontal surface (13), with the longitude (39) (Figure 16) of the cavity defined from the apex (22) of the concave geometry of the The cavity to the opening (40) of the cavity in the lower horizontal surface (13) of the brick is between 26% and 65% of the width Z of the brick.

Figures 22 and 23 show another embodiment of the brick having a symmetrical protrusion (28) of rounded convex geometry that originates on one of the side surfaces (14) of the brick, with the longitude (41) (Figure 22) of the defined protuberance. from the apex (42) of the convex protrusion geometry to the base (29) on the brick side surface (14) is between 26% and 65% of the brick width Z.

Figures 24 and 25 show an embodiment of the present invention which is characterized by a brick with two vertical cylindrical holes (15) which completely pierce the brick, these holes (15) and identical holes (15) of vertically adjacent bricks in each other. a wall are aligned in the direction of the vertical geometric axis of the wall to form continuous vertical holes that are applied along the height of the wall; and wherein the diameter of the holes fits into the diameter of a rod. In Figure 25, it is shown that the length of a rod is equal to or exceeds the length of the wall height. In the same Figure 25 ', it can be seen that the rod can be introduced through the continuous hole that is applied along the height of the wall.

The continuous holes in the wall that are shown in Figure 24 can also be used to insert vertically through the wall cable lines for electricity, gas pipes. telephone cable lines, etc.

Figure 26 shows another embodiment of the brick of the present invention. In this embodiment, the brick is characterized by a 90 degree right-angle channel at both edges (44), in the direction of the Y axis of the anterior vertical surface (7); a right angle of 90 degrees at both edges (45) in the direction of the Y axis of the posterior vertical surface; a right angle of 90 degrees at both edges (46), in the direction of the X axis, of the upper horizontal surface; and a right angle of 90 degrees at both edges (43) in the direction of the X-axis of the lower horizontal surface. Figure 27 shows another embodiment of the brick of the present invention. In this embodiment, the brick is characterized by a right angle of 90 degrees at the two edges (47), in the direction of the geometric axis Y of the anterior vertical surface; and a right angle of 90 degrees at both edges (48) in the direction of the X-axis of the lower horizontal surface. Figures 28 and 29 show other embodiments of the brick of the present invention wherein the bricks are half the length, in the direction of the geometric axis X, relative to other adjacent bricks such that these bricks are situated horizontally at the beginning or end. of the horizontal bands of bricks, further creating ends with other vertically adjacent horizontal bands of bricks, which result in a wall with a continuous vertical border.

The stem of the present invention may be a single part stem (5) or a composite stem comprising successively joined stem fragments.

The rod fragments can be seen in Figure 1, which shows a tube (5A) whose length is equal to the height of the brick; whereas the tube acts as a female screw; and wherein the tube has an inward roughness for screwing an outer threaded male screw (5B). The male screw (5B) has a length equal to or less than the length of the tube (5A). The male screw fits internally through its upper half into one tube (5A) and through its lower half into another tube (5A), forming a socket of two tubes that can be inserted into two of the vertically adjacent bricks. The continuous composite rod consists of successive fittings formed by a plurality of tubes (5A) and a plurality of male screws (5B). In another embodiment of the present invention, the composite rod is comprised of rod fragments 26 and 27 (Figures 2A and 2B) whose length is one and a half times (1.5X) the length of the brick height. Each of these stem fragments, 26 and (27), is formed of three parts defined as first part (49), second part (50) and third part (51); whereas the three parts have exactly the same longitude, such that each part has a length equal to one third of the length of the stem fragment; wherein the first part (49) is at one end of the stem fragment; and wherein the first part (49) is hollow with an internal thread constituting the female screw part of the rod fragment; and wherein the second part (50) is in the intermediate part of the stem fragment between the first part (49) and the third part (51); and wherein the second part (50) is solid; and wherein the third part (51) is solid with external thread; and the third part (51) being at the opposite end constituting the first part (49); and the third part (51) being the part acting as the male rod fragment screw; and wherein the first stem fragment portion 49 fits into a third portion 51 of another identical stem fragment and thus a plurality of stem fragments are successively nested to form the composite stem.

One of the advantages of the present invention is the elimination of the use of mortar or adhesives between horizontally and vertically adjacent bricks in the construction of a wall. This is achieved by fitting between the symmetrical convex protuberances (1) which are perfectly complementary to the symmetrical concave geometry cavities (2) of the horizontally adjacent bricks and between the cylindrical-convex protuberances (3) which are perfectly complementary to the cavities ( 16) cylindrical-concave of vertically adjacent bricks. However, another embodiment of the present invention comprises a brick with a convex cylindrical protrusion (3) that originates from the upper horizontal surface (6) such that the cylindrical portion forms an angle (52) (Figure 16) with a slight transition. curved with the upper horizontal surface (6); while the cylindrical-concave cavity 16 originates from the lower horizontal surface (13) such that the cylindrical portion forms a right angle (53) (Figure 16) of 90 degrees with the lower horizontal surface (13). The disparity in the angle 52 formed by the protrusion 1 and the angle 53 formed by the cavity 16 creates an imperfect fit between the vertically adjacent bricks thereby creating a gap of millimeters between the vertically adjacent bricks. This void may be required by anti-seismic regulations. If necessary, said gap may be loaded with mortar.

While the disclosure provides preferred embodiments of the present invention, further changes may be made to the shape and arrangement of the parts without departing from the basic ideas and principles comprised in the following claims.

Claims (21)

1. Brick and rod system, wherein the system is characterized by a three-dimensional rectangular brick to construct walls defined by the three Cartesian coordinates Χ, Υ, Z, where the horizontal geometrical axis X defines the length, the vertical geometrical axis Y defines the height and the horizontal geometric Z define the width, and a rod; wherein the brick is a solid block comprising: a. an upper horizontal surface and a lower horizontal surface defined by the geometric axes X and Z; B. a vertical anterior surface and a vertical posterior surface 15 defined by the geometry axes ZeY; ç. two vertical lateral surfaces defined by the geometric axes X and Y; d. a symmetrical protrusion of rounded convex geometry which originates at the intermediate part of the brick vertical anterior surface in the direction of the X-axis, said protuberance fitting precisely into a horizontally adjacent block in the cavity described in e.g. the base of the protrusion on the vertical vertical surface of the brick, defined in the same direction as the geometric axis Z, is shorter in length than the maximum diameter of the convex protrusion geometry; and. a symmetrical hollow of concave geometry which originates at the intermediate part of the posterior vertical surface of the brick in the direction of the X-axis, said hollow fitting precisely into a horizontally adjacent block in the protrusion described in d .; and wherein the length of the cavity aperture in the posterior vertical surface of the brick, defined in the same direction as the geometric axis Z, is shorter than the maximum diameter of the cavity's concave geometry; f. two protuberances of cylindrical-concave geometry situated symmetrically on the intermediate portion of the upper horizontal surface of the brick in the direction of the geometric axis Y, said protuberances precisely fitting into vertically adjacent blocks in the cavities described in g .; and wherein the diameter of each bulge base on the upper horizontal surface of the brick is greater than or equal to the diameter of the cylindrical portion of the bulge; g. two cavities of cylindrical-concave geometry situated symmetrically on the intermediate part of the lower horizontal surface of the brick in the direction of the geometric axis Y, said cavities precisely fitting into the vertically adjacent blocks at the protrusions described in f .; and wherein the diameter of each cavity aperture in the lower horizontal surface of the brick is greater than or equal to the diameter of the cylindrical part of the cavity; H. two vertical cylindrical holes that completely pierce the brick, and said longitude of the holes, in the direction of the geometric axis Y, is defined from the apex of the convex geometry of the protuberances described in f. to the apex of the concave geometry of the described cavities. in G.; and said holes and identical holes of vertically adjacent bricks in a wall are aligned in the direction of the vertical geometric axis of the wall to form continuous vertical holes that are applied along the entire height of the wall; i. a vertical cylindrical hole that completely pierces the brick, the length of said hole in the direction of the geometric axis Y being defined from the top horizontal surface of the brick to the bottom horizontal surface of the brick; and wherein said orifice is parallel between the two orifices described in h .; and said hole and the same diameter hole described in j. of the vertically adjacent bricks are aligned in the direction of the vertical geometric axis of a wall to form a continuous vertical hole that is applied along the entire height of the wall; and said holes have a diameter that conforms to the diameter of the rod such that the rod can be introduced through the continuous hole that is applied along the height of the wall; j. a vertical cylindrical orifice that drills, in the direction of the Y axis, fully the protrusion described in d., the length of the orifice being defined from the center of said upper horizontal surface of the protrusion to the center of said lower horizontal surface of the protuberance; wherein this hole and the vertically adjacent holes of brick of equal diameter described in i., are aligned in the direction of the vertical geometric axis of a wall, to form a continuous vertical hole that is applied along the height of the wall; and said holes have a diameter that conforms to the diameter of the rod, such that the rod can be introduced through the continuous hole that is applied along the height of the wall; wherein the length of the rod is equal to or exceeds the length of the height of the wall; and wherein the rod is vertically introduced through the continuous vertical holes described in i. and j .; and the sturdy fittings are created between the horizontally and vertically adjacent bricks to construct a wall allowing the introduction of a skeleton consisting of a plurality of rod, thereby resulting in a structure with great lateral rigidity and great resistance to uniform forces. cyclic, and extreme gravitationals. A system according to claim 1, wherein the brick is characterized by a symmetrical protrusion of rounded convex geometry that originates on one of the vertical side surfaces of the brick, said protuberance fitting precisely into the cavity. described in le of a horizontally adjacent brick; and wherein the base of the protuberance on the vertical lateral surface, defined in the same direction as geometric axis X, is of less than the maximum diameter of the convex protrusion geometry. A system according to claim 1, wherein the brick is characterized by a right angle channel of -90 degrees at both edges, in the direction of the Y axis, of the vertical anterior surface; and a 90 degree right angle channel at both edges, in the direction of the X axis, of the lower horizontal surface. The system of claim 1, wherein the brick is characterized by a right angle of 90 degrees at both edges, in the direction of the Y axis, of the vertical anterior surface; a 90 degree right-angle channel at both edges in the direction of the Y axis of the rear vertical surface; a 90 degree right-angle channel at both edges in the direction of the X axis of the upper horizontal surface; and a right angle channel of -90 degrees at both edges, in the direction of the X axis, of the lower horizontal surface. System according to claim 1, characterized in that the rod is a composite rod comprising: a. a pipe whose length is equal to the height of the brick; whereas the tube acts as a female screw; and wherein the tube has an internal thread in which the screw described in b. will be threaded. B. a male screw having a length equal to or less than the pipe length described in a., wherein the male screw has an external thread; and said male screw internally adapting its upper half into one tube as described in a. and its lower half in another tube as described in a .; and wherein the socket formed joins the two pipes that can be inserted into two of the vertically adjacent bricks; wherein a continuous composite rod is comprised of a plurality of tubes and a plurality of male screws. System according to claim 1, characterized in that the rod is a composite rod comprising rod fragments, the length of each rod fragment being equal to one and a half times (1.5X) at longitude of the height of the brick, and each stem fragment being formed by three parts defined as first part, second part and a third part; whereas the three parts are exactly the same longitude, such that each part has a length equal to one third of the length of the stem fragment; wherein the first part is an end of the stem fragment; and wherein the first part is hollow with an internal thread thus constituting the female screw part of the rod fragment; and wherein the second part is in the middle part of the stem fragment between the first part and the third part; and the second part being solid; and wherein the third part is solid with an outer thread; and wherein the third part is at the opposite end to the end constituted by the first part; and the third part being the part acting as the male screw of the rod fragment; and wherein the first part of a rod fragment is threaded into the third part of another identical rod fragment, and the plurality of identical rod fragments that have been successively threaded together form the composite rod. 7. Brick and rod system, wherein the system is characterized by a three-dimensional rectangular brick to construct the walls defined by the three Cartesian coordinates Χ, Υ, Z, where the horizontal geometric axis X defines the length, the vertical geometric axis Y defines the height, the horizontal geometry axis Z defines the width, and a rod; wherein the brick is a solid block comprising: a. an upper horizontal surface and a lower horizontal surface defined by the geometric axis X and Z; B. a vertical anterior surface and posterior vertical surface defined by the geometric axis Z and Y; ç. two vertical side surfaces defined by the geometric axis X and Y; d. a symmetrical protrusion of rounded convex geometry which originates at the intermediate part of the vertical anterior surface of the brick in the direction of the X-axis, said protuberance fitting precisely into a horizontally adjacent block in the cavity described in e.g. whereas the base of the bulge on the vertical anterior surface of the brick, defined in the same direction as the Z axis, has a length less than the maximum diameter of the convex protrusion geometry; and. a symmetrical cavity of concave geometry that originates at the intermediate part of the posterior vertical surface of the brick in the direction of the X-axis, said cavity precisely fitting into a horizontally adjacent block at the protrusion described in d. ; and wherein the length of the cavity opening in the posterior vertical surface of the brick, defined in the same direction as the geometric axis Z, is less than the maximum diameter of the hollow concave geometry; f. two protuberances of cylindrical-concave geometry symmetrically situated on the intermediate portion of the upper horizontal surface of the brick in the direction of the geometric axis Y, said protuberances without precisely fitting the vertically adjacent blocks in the cavities described in g .; and wherein the diameter of each bulge base on the upper horizontal surface of the brick is greater than or equal to the diameter of the cylindrical portion of the bulge; g. two cavities of cylindrical-concave geometry symmetrically situated at the intermediate portion of the lower horizontal surface of the brick in the direction of the geometric axis Y, said cavities precisely fitting into the vertically adjacent blocks at the protrusions described in f .; and wherein the diameter of each cavity aperture in the lower horizontal surface of the brick is greater than or equal to the diameter of the cylindrical part of the cavity; H. two vertical cylindrical holes that completely pierce the brick, and said longitude of the holes, in the direction of the geometric axis Y, is defined from the apex of the convex geometry of the protuberances described in f. to the apex of the concave geometry of the described cavities. in G.; and wherein said identical holes and vertically adjacent brick holes in a wall are aligned in the direction of the vertical geometric axis of the wall to form continuous vertical holes that are applied throughout the height of the wall; and wherein the diameter of the two holes adapts to the diameter of the rod; and wherein the length of the rod is equal to or exceeds the height of the length of the wall; and wherein the rod is vertically introduced through the continuous vertical holes of the wall; and the sturdy fittings are created between horizontally and vertically adjacent bricks to construct a wall allowing the introduction of a skeleton consisting of a plurality of rods, thus resulting in a structure with great lateral rigidity and great resistance to uniform forces. cyclic, and extreme gravitationals. A system according to claim 7, wherein the brick is characterized by a symmetrical protrusion of rounded convex geometry that originates on one of the vertical side surfaces of the brick, said protrusion fitting precisely into the described cavity. in le of a horizontally adjacent brick; and the base of the protrusion on the lateral surface, defined in the same direction as the geometric axis X, is of less than the maximum diameter of the convex protrusion geometry. A system according to claim 7, wherein the brick is characterized by a right angle channel of -90 degrees at both edges, in the direction of the Y axis, of the vertical anterior surface; and a 90 degree right-angle channel at both edges, in the direction of the X-axis, of the lower horizontal surface. A system according to claim 7, wherein the brick is characterized by a right angle channel of -90 degrees at both edges, in the direction of the geometric axis Y, of the vertical anterior surface; a right angle channel of -90 degrees at both edges in the direction of the Y axis of the posterior vertical surface; a right angle channel of -90 degrees at the two edges in the direction of the X axis of the upper horizontal surface; and a right angle of 90 degrees at both edges, in the direction of the X axis, of the lower horizontal surface. System according to claim 7, characterized in that the rod is a composite rod comprising: a. a pipe whose length is equal to the height of the brick; whereas the tube acts as a female screw; and wherein the tube has an internal thread in which the thread described in b. will be threaded. B. a male screw of length equal to less than the length of the pipe described in a., the male screw having an external thread; and wherein said male screw fits internally into its upper half in one tube as described in a. and its lower half in another tube as described in a .; and wherein the socket formed joins the two pipes that can be inserted into two of the vertically adjacent bricks; wherein a continuous composite rod is formed and comprised of a plurality of tubes and a plurality of male screws. A system according to claim 7, wherein the stem is a contained stem comprising stem fragments, characterized in that the length of each stem fragment is one and a half times (1.5X) a. longitude of the height of the brick, and wherein each stem fragment is made up of three parts defined as the first part, second part and a third part; wherein the three parts have exactly the same length, such that each part has a length equal to one third of the length of the stem fragment; wherein the first part is an end of the stem fragment; and wherein the first part is hollow with an internal thread, thus constituting the part that functions as a female screw of the rod fragment; and wherein the second part is in the middle of the stem fragment between the first part and the third part; and wherein the second part is solid; and wherein the third part is solid with an external thread; and wherein the third part is located at the opposite end to the end constituted by the first part; and wherein the third part is the part that acts as the male rod fragment screw; and wherein the first part of a rod fragment is screwed to the third part of another identical rod fragment, and wherein a plurality of identical rod fragments which have been successively screwed together form the contained rod. 13. Three-dimensional rectangular brick for wall construction, where the brick is defined by the three Cartesian coordinates Χ, Υ, Z, where the horizontal geometric axis X defines the length, the vertical geometric axis Y defines the height, the geometric axis. horizontal Z defines the width, and a rod; and is characterized in that it is a solid block comprising: a. an upper horizontal surface and a lower horizontal surface defined by the axis X and Z; B. a vertical anterior surface and a vertical posterior surface defined by the geometry axis ZeY; ç. two vertical side surfaces defined by the geometric axis X and Y; d. a symmetrical protrusion of rounded convex geometry that originates in the middle of the brick's anterior vertical surface in the direction of the X-axis, wherein said protrusion fits precisely into a horizontally adjacent block with the cavity described in e; and wherein the base of the protrusion on the vertical anterior surface of the brick, defined in the same direction as the geometric axis Z, is shorter than the maximum diameter of the convex protrusion geometry; and. a symmetrical cavity of concave geometry which originates in the middle of the brick's posterior vertical surface in the direction of the X-axis, wherein said cavity fits precisely into a horizontally adjacent block with the protrusion described in d .; and wherein the length of the cavity aperture over the vertical posterior surface of the brick, defined in the same direction as the Z axis, is smaller than the maximum diameter of the hollow concave geometry; f. two protrusions of cylindrical concave geometry located symmetrically in the middle of the upper horizontal surface of the brick in the direction of the geometric axis Y, wherein said protrusions fit precisely into vertically adjacent blocks with the cavities described in g .; and wherein the diameter of each bulge base on the upper horizontal surface of the brick is greater than or equal to the diameter of the cylindrical portion of the bulge; g. two cavities of cylindrical concave geometry located symmetrically in the middle of the lower horizontal surface of the brick in the direction of the geometric axis Y, wherein said cavities fit precisely into vertically adjacent blocks with the protrusions described in f .; and wherein the diameter of each cavity aperture over the lower horizontal surface of the brick is greater than or equal to the diameter of the cylindrical part of the cavity; H. two vertical cylindrical holes that completely pierce the brick, wherein said longitude of the holes in the direction of the geometric axis Y is defined from the apex of the convex geometry of the protuberances described in f. to the apex of the concave geometry of the described cavities. in G. ; and wherein said identical holes and vertically adjacent brick holes in a wall are aligned in the direction of the vertical geometric axis of the wall to form continuous vertical holes that traverse the entire height of the wall; i. a vertical cylindrical hole that completely pierces the brick, wherein the length of said hole in the direction of the geometric axis Y is defined from the top horizontal surface of the brick to the bottom horizontal surface of the brick; and wherein said orifice is located in parallel between the two orifices described in h .; and wherein said hole and hole of equal diameter described in j. of the vertically adjacent bricks, are aligned in the direction of the vertical geometric axis of a wall to form a continuous vertical orifice that traverses the entire height of the wall; and wherein said holes have a diameter that adjusts to the diameter of the rod such that the rod can be introduced through the continuous hole through the height of the wall; j. a vertical cylindrical hole that completely pierces, in the direction of the Y axis, the protrusion described in d., wherein the length of the orifice is defined from the center of said upper horizontal surface of the protrusion to the center of said lower horizontal surface of the protuberance; wherein said hole and the vertically adjacent holes of brick of equal diameter described in i., are aligned in the direction of the vertical geometric axis of a wall, to form a continuous vertical hole that traverses the height of the wall; and wherein said holes have a diameter that adjusts to the diameter of the rod such that the rod can be introduced through the continuous hole through the height of the wall; and wherein sturdy fittings are created between vertically and horizontally adjacent bricks to construct a wall that allows the introduction of a frame made of vertical rods, thus resulting in a structure with greater lateral rigidity and greater resistance to extreme uniform, cyclic and gravitational forces. . Brick according to claim 13, characterized by a rounded convex geometry, symmetrical protrusion that originates on one of the side vertical surfaces of the brick, wherein said protrusion fits precisely into the cavity described in 13. e. of a horizontally adjacent brick; and wherein the base of the protrusion on the lateral vertical surface, defined in the same direction as geometric axis X, is less than the maximum diameter of the convex protrusion geometry. Brick according to claim 13, characterized by a right angle channel of 90 degrees on both edges, in the direction of the geometric axis Y, of the vertical anterior surface; and a right angle channel of -90 degrees on both edges, in the direction of the X axis, of the lower horizontal surface. Brick according to claim 13, characterized by a right-angle channel of 90 degrees on both edges, in the direction of the geometric axis Y, of the vertical anterior surface; and a 90 degree right-angle channel on both edges, in the direction of the Y axis of the vertical rear surface, a 90 degree right-angle channel on the two edges, in the direction of the X axis of the upper horizontal surface ; and a right angle of 90 degrees on both edges, in the direction of the X axis, of the lower horizontal surface. 17. Three-dimensional rectangular brick for wall construction, where the brick is defined by the three Cartesian coordinates Χ, Υ, Z, where the horizontal geometric axis X defines the length, the vertical geometric axis Y defines the height, the geometric axis. horizontal Z defines the width; and characterized in that it is a solid block comprising: a. an upper horizontal surface and a lower horizontal surface defined by the axis X and Z; B. a vertical anterior surface and a vertical posterior surface defined by the geometric axis Ze Y; ç. two vertical side surfaces defined by the geometric axis X and Y; d. a symmetrical protrusion of rounded convex geometry that originates in the middle of the brick's anterior vertical surface in the direction of the X-axis, wherein said protrusion fits precisely into a horizontally adjacent block with the cavity described in e; and wherein the base of the protrusion on the vertical anterior surface of the brick, defined in the same direction as the geometric axis Z, is shorter than the maximum diameter of the convex protrusion geometry; and wherein the base of the protrusion on the vertical anterior surface of the brick, defined in the same direction as the geometric axis Z, is shorter than the maximum diameter of the convex protrusion geometry; and wherein the protrusion length in the direction of the X-axis defined from the apex of the convex protrusion geometry is between 26% and 65% of the brick width Z; and. a symmetrical cavity of concave geometry which originates in the middle of the brick's posterior vertical surface in the direction of the X-axis, wherein said cavity fits precisely into a horizontally adjacent block with the protrusion described in d. and wherein the length of the cavity aperture over the vertical posterior surface of the brick, defined in the same direction as the Z axis, is smaller than the maximum diameter of the hollow concave geometry; and wherein the cavity longitude, in the direction of the X-axis, defined from the apex of the cavity's concave geometry to the opening on the brick's posterior vertical surface, is between 26% and 65% of the brick's Z width; f. two protrusions of cylindrical concave geometry located symmetrically in the middle of the upper horizontal surface of the brick in the direction of the geometric axis Y, wherein said protrusions fit precisely into vertically adjacent blocks with the cavities described in g .; and wherein the diameter of each bulge base on the upper horizontal surface of the brick is greater than or equal to the diameter of the cylindrical portion of the bulge; and wherein the longitude of the protuberance, in the direction of the geometric axis Y, from the apex of the convex protrusion geometry to the base on the upper horizontal surface of the brick, is between 26% and 65% of the brick width Z; g. two cavities of cylindrical concave geometry located symmetrically in the middle of the lower horizontal surface of the brick in the direction of the geometric axis Y, wherein said cavities fit precisely into vertically adjacent blocks with the protrusions described in f .; and wherein the diameter of each cavity aperture over the lower horizontal surface of the brick is greater than or equal to the diameter of the cylindrical part of the cavity; and wherein the cavity length, in the direction of the Y axis, defined from the apex of the cavity's convex geometry to the cavity opening on the brick's posterior vertical surface, is between 26% and 65% of the brick width Z ; H. two vertical cylindrical holes that completely pierce the brick, wherein said longitude of the holes, in the direction of the geometric axis Y, is defined from the apex of the convex geometry of the protuberances described at f. to the apex of the concave geometry of the described cavities. in G. ; and wherein said identical holes and vertically adjacent brick holes in a wall are aligned in the direction of the vertical geometric axis of the wall to form continuous vertical holes that traverse the entire height of the wall; and where sturdy fittings are created between vertically and horizontally adjacent bricks to build a wall with greater lateral stiffness and greater resistance to extreme uniform, cyclic and gravitational forces. Brick according to Claim 17, characterized by two vertical cylindrical holes which completely pierce the brick, wherein said length of the holes in the direction of the Y axis is defined from the apex of the convex geometry of the described protuberances. at 17.f. to the apex of the concave geometry of the cavities described in 17. g. ; and wherein said identical holes and vertically adjacent brick holes in a wall are aligned in the direction of the vertical geometric axis of the wall to form continuous vertical holes that traverse the entire height of the wall; and wherein said holes have a diameter that fits the diameter of identical rods such that the rods may be introduced through the continuous holes traversing the height of the wall; and wherein sturdy fittings are created between vertically and horizontally adjacent bricks to construct a wall that allows the introduction of a frame made of vertical rods, thus resulting in a structure with greater lateral rigidity and greater resistance to extreme uniform, cyclic and gravitational forces. . Brick according to Claim 17, characterized by a rounded convex geometry, symmetrical protrusion which originates on one of the brick side surfaces, wherein said protrusion fits precisely into the cavity described in 17 e. of a horizontally adjacent brick; and wherein the base of the protrusion on the lateral vertical surface of the brick, defined in the same direction as the geometric axis X, has a length less than the maximum diameter of the convex protrusion geometry; and wherein the protrusion length in the direction of the geometry axis Z, defined from the apex of the protrusion convex geometry to the base on the brick side surface, is between 26% and 65% of the brick width Z. Brick according to claim 17, characterized by a right-angle channel of 90 degrees on both edges, in the direction of the geometric axis Y, of the vertical anterior surface; and a right angle channel of -90 degrees on both edges, in the direction of the X axis, of the lower horizontal surface. Brick according to claim 17, characterized by a right-angle channel of 90 degrees on both edges, in the direction of the geometric axis Y, of the vertical anterior surface; a right-angle channel of 90 degrees on both edges, in the direction of the Y axis of the vertical rear surface, one right-angle channel of 90 degrees on the two edges, in the direction of the X axis of the upper horizontal surface ; and a right angle channel of 90 degrees on both edges, in the direction of the X axis, of the lower horizontal surface.