BR112020022789A2 - set of building blocks - Google Patents

Abstract

  SET OF BUILDING BLOCKS. A set of building blocks of the type consisting of parallelepiped bodies having internal cells, having at least a first face and a second fitting face between the blocks, is described, with the set comprising a first base block having at least two sections of different heights that form a staggered body, in the form of two staggerings, and a second interchangeable block having at least two sections of different heights that form a lying "T" body, with the upper part of the "T" being arranged vertically and the leg of the "T" being laid out horizontally.

Description

BUILDING BLOCK SET FIELD OF THE INVENTION

[001] The present invention relates to a set of building blocks, which can also be called bricks, of the type used in the construction of buildings, houses, building walls, etc., which allows a quick erection of the walls, favored due to the better contact, coupling and / or fitting between blocks, allowing the use of adhesives in the construction and with the walls, finally presenting a very low thermal transmission factor in comparison with the traditional walls, providing significant savings in the construction of the walls and obtaining better thermal coefficients.

BACKGROUND OF THE INVENTION

[002] With the current ecological awareness, the factors of thermal and energy conservation are assuming more and more prominence in the construction of walls, walls, partitions and houses in general. One of the most important factors is the fact that energy consumption is taken into account, which makes it possible to keep environments cool in times of high temperature and to conserve internal heat in times of cold. For this to happen, the walls must have constructive characteristics that make it possible to obtain the most ideal conditions possible.

[003] On the other hand, the fastest and most efficient types of construction have also been increasingly imposed in terms of time and structural reliability. In these constructions, a variety of stone materials are used, such as clay bricks, cement mortar blocks, stones and the like, of the same or similar origin to those already mentioned. The blocks or bricks can be placed down to the bone, although the usual thing is that they are coupled with mortar, which is the bonding material formed by the combination of agglomerates and agglomerates, composed of cement, fine aggregate and water. The traditional union between the bricks of a wall is based on the application of mortar over all its contact surfaces. This mass of cement is much more thermally conductive than the brick itself, which generates a thermal bridge through it between the internal trailer and the external wall trailer, which are at different temperatures. With this, the desired insulating effect is significantly reduced, with the consequent loss of energy conservation, generating pathologies inside the residences, since the ceramic film is not continuous, causing temperature differences between the cement areas and the brick. Among the pathologies, it is possible to mention differences in coloring in the paintings. On the other hand, the trends and potential regulations of construction in different climatic zones favor the economy and the conservation of energy.

[004] The inventor of the present invention developed a brick bonding system which he disclosed in his Argentine patent application No. P 090105139, and which has been improving over time, achieving more advanced developments in relation to the coupling and joining of bricks or blocks , also taking advantage of the use of adhesives belonging to the new technologies available on the market. The system of joining the said patent application by the same inventor not only made it possible to facilitate the coupling of the building blocks, accelerate the erection of any wall or wall composed of such blocks, but also improved the factors of thermal conservation of the walls.

[005] However, as mentioned, the same inventor continued to develop his own inventive concepts to obtain a new set of blocks that significantly improves construction times, as well as the process of erecting a wall, reduces costs, and achieves a reduction increase in the thermal transmission coefficient, improving the pathologies of the wall.

SUMMARY OF THE INVENTION

[006] It is therefore an objective of the present invention to provide a new set of building blocks that facilitates tasks and reduces the construction times of a wall, while providing a construction where its walls, and / or walls, and / or partitions, have a low coefficient of thermal transmission.

[007] It is also an objective of the present invention to provide a set of building blocks of the type in which the blocks are made of parallelepiped bodies with internal cells, and having at least a first face and a second face to fit between the blocks, in that said first face has a first cavity open to the outside and said second face has a second cavity open to the outside, with a projection extending from said second cavity, and with the edges of that second cavity defining a plane geometric below which said second cavity has a volume V2, and said projection projecting out of said geometric plane defining a projecting end, with said projecting end showing a volume Ve, where Ve <V2, and with said first cavity presenting a volume V1, where V1> Ve.

[008] It is also an objective of the present invention to provide a wall or an improved wall, formed by a new design of the building blocks coupled and adhered by an adhesive bonding material between the blocks, where all this allows the construction of a wall, wall and / or partition in a much faster and more practical way, and with a very low thermal transfer factor.

[009] It is also an objective of the present invention to provide a set of building blocks of the type in which the blocks are formed by parallelepiped bodies with internal cells, having at least a first face and a second contact face, in which said first face has at least one flat face and said second face has at least one flat face, with both flat faces defining, each of them, respective geometric planes between which an adhesive bonding material is disposed between the blocks, with said adhesive material being selected from the group consisting of adhesive paste or adhesive paste of an epoxy, cementitious composition, or any other that for its use requires low thickness, including double-sided adhesive tapes, that is, with opposite faces containing adhesive. The adhesive material is applicable without distinction with traditional or thin thicknesses.

[010] For the purposes of the present invention, a flat face is a face of the brick that does not have cavities or protrusions that form a fit, with the flat face being able to have any textures, grooves, ribs, etc.

DESCRIPTION OF THE DRAWINGS

[011] For greater clarity and understanding of the object of the present invention, this object was illustrated in several figures, in which it was represented in one of the preferred forms of incorporation, all of which are exemplary, where: - Figure 1 is a side view of a first block or base block according to an embodiment of the invention, wherein the parallelepiped body is a body having two sections of different heights that form a stepped body with two steps;

Figure 2 is a perspective view of the base body of figure 1;

Figure 3 is a side view of a first block or base block according to another embodiment of the invention, where the parallelepiped body is a body having three sections of different heights that form a stepped body with three steps;

Figure 4 is a perspective view of the base body of figure 3;

- Figure 5 is a side view of a second block or interchangeable block according to the invention, in which the parallelepiped body is a body having two sections of different heights that form a lying "T" shaped body;

Figure 6 is a perspective view of the base body of figure 5;

Figure 7 is a side view of a wall according to the invention, erected with the first block or base block of figures 2 and 3 and with a plurality of interleaved blocks of figures 5 and 6;

- Figure 8 is a side view of two blocks about to be fitted, where the first face showing the first cavity of a lower block and the second face showing the second cavity and the projection of an upper block are visible;

- Figure 9 is a side view of the two blocks in figure 8 already fitted and adhered with an adhesive material, such as mortar;

Figure 10 is a side view of a first block or base block according to another embodiment of the invention, where the parallelepiped body is a body having two sections of different heights that form a stepped body with two steps;

Figure 11 is a perspective view of the base body of figure 10;

Figure 12 is a side view of a first block or base block according to another embodiment of the invention, in which the parallelepiped body is a body having three sections of different heights that form a stepped body with three steps;

Figure 13 is a perspective view of the base body of figure 12;

- Figure 14 is a side view of a second block or interchangeable block according to the invention, in which the parallelepiped body is a body having two sections of different heights that form a lying "T" shaped body; Figure 15 is a perspective view of the base body of figure 14; Figure 16 is a side view of a wall according to the invention, raised with the first block or base block of figures 10 to 13, and with a plurality of interleaved blocks of figures 14 and 15; - Figure 17 is a side view of two blocks about to be joined, where the adhesive bonding material between the blocks is visible; Figure 18 is a side view of the two blocks in figure 17 already adhered with an adhesive material; - Figure 19 shows in section an alternative wall according to the invention; Figure 20 shows a side perspective view of the wall in figure 16; and - Figure 21 shows a side perspective view of the wall in Figure 19.

DETAILED DESCRIPTION OF THE INVENTION

[012] Referring to the figures, it is observed that the invention proposes a set of building blocks, where the term block is understood in a general concept that includes any type of brick, hollow or partially hollow, having individual cells, having partitions internal, blocks, etc., made of any material, be it stony, with light aggregates of volcanic origin, or annealed or red bricks, concrete blocks, cementitious, plastics, polymeric, etc.

[013] According to a form of incorporation that may be preferred, it is a brick of the type called a thermal brick, such as for example a thermal concrete brick which is a prefabricated piece in the shape of a rectilinear prism, or parallelepiped, having one or more sections, out of step or staggered, manufactured with light aggregates for use in the construction of walls, walls, partitions, etc. It can be manufactured with light aggregates of volcanic origin, so that the blocks can have properties higher than those of annealed or red bricks and those of normal concrete blocks.

[014] The blocks can be manufactured with light aggregates to obtain a final product that, due to its lightness, has excellent thermal properties in comparison with traditional systems for building walls. Its main application is in the construction of housing walls, commercial spaces, etc., where thermal efficiency is sought. However, anyone skilled in the art will realize that the set of blocks of the invention can be used in different applications and in different materials.

[015] The set of blocks of the invention comprises at least two types of blocks to which reference will be made below, in detail, with a first type of block or base block, which can be observed in figures 1 to 4 according to two alternatives , and a second block or intercalable block, which can be seen in figures 5 and 6. These bricks or blocks allow the construction of walls as shown in figures 7 to 9.

[016] Said two types of blocks are also presented, in an alternative form of the invention, with support and / or junction and / or coupling faces that are generally flat, be they smooth, textured, ribbed, grooved, etc., as shown in figures 10 to 15. The walls erected with these alternative blocks are shown in figures 16 to 19.

[017] As can be seen in figures 1 and 2, the first block or base block, indicated with the general reference 1, is a block having a plurality of internal cells 2 that extend side by side in the block, separated by internal partitions 3. The block has two sections 4, 5 of different heights, which form a staggered body, in the form of two staggerings. The outer walls of the block may have roughnesses that favor coupling, thermal dissipation, handling, adhesion to adhesive materials, such as towing, etc. The block has at least one first face 7, 8 on an upper end of each one of said sections 4, 5, and the face has a cavity 9, 10 designed to form a socket with a block mounted on top of the base block, together with the use of an adhesive material, such as mortar, as will be described in detail with respect to figures 8 and 9. The aforementioned mortar generates a fluid fit, giving solidity to the wall, since the union between the bricks does not occur exclusively by adhesion, but also generates a mechanical fit.

[018] According to another form of incorporation, illustrated in figures 3 and 4, the base block, indicated in this form of incorporation with reference number 11, is similar to base block 1, with the difference that, instead of being made up of two sections, it has three sections 12, 13 and 14, also of different heights, which form a staggered body, in the form of three staggerings. As in the case of the block in figures 1 and 2, sections 12, 13, 14 have at their upper end a first face having cavities 15, 16, 17, being, as indicated, the same as in block 1. Both block 1 and block 11 have a base face 18 designed to be supported on the ground to start the construction of the wall, as can be seen in figure 7.

[019] The set of blocks of the invention further comprises, as indicated, a second block or interchangeable block, illustrated in figures 5 and 6 and indicated with the general reference number 19. As well as the base block 1, 11, the intercalable block 19 has a plurality of internal cells 20 that extend side by side in the block, separated by internal partitions 21. The block has two sections 22, 23 of different heights, which form a staggered body, or staggered, T-shaped sections. "lying down, with the upper part of the" T ", indicated with the general reference number 24, preferably positioned vertically during the erection of the wall, and with the" leg "of the" T ", indicated with the general reference number 25 , being horizontally arranged, thus generating interruptions with all vertical and horizontal unions between both sides of the wall.

[020] The upper part 24 and the "leg" 25 of the lying "T" have respective upper ends where, in each of them, a first face 26, 27 is defined, which presents a first cavity 28, 29 open to the outside. Unlike the base block 1, 11, the interchangeable block 19 has interlocking bottom faces. More particularly, the upper part 24 and the "leg" 25 of the lying "T" have respective lower ends where, in each of them, a second face 30, 31 is defined which has a second cavity 32, 33 open to the outside, and also a projection 34, 35. The cavity 32, 33 and the projection 34, 35, arranged on the second face, or the lower face of the sections 22, 23, are intended to form a socket with a cavity 9, 10, 15, 16 .17 of a base block disposed below the interchangeable block 19, or with a cavity 28, 29 of another intercalable block, disposed below, during erection of the wall. The interleaving of these blocks in a wall can be seen in the wall illustrated in figure 7. However, the fit between the blocks, using an adhesive material, will be described in more detail with respect to figures 8 and 9.

[021] With respect to construction and other material characteristics, roughness, etc., block 19 can have all the characteristics of base block 1, 11. The base and intercalable blocks can be made of any material that meets the structural requirements of desired construction and also to thermal requirements. For example, they can be made of ceramic, cement, plastic, or any material that allows to form blocks that adapt to the construction conditions of the fitting and the fluid used for fitting. The material that will be housed in the cavities 7, 8 of figure 1, for example, to achieve the union between blocks, fulfilling the function of fitting fluid, can be of cementitious origin, or be of polyurethane or any material that allows its flow in said connection cavities.

[022] Figure 7 shows a wall, wall or partition built with the set of blocks of the invention. It can be seen that the base of the wall consists of at least one base block that can have two, three or more sections. In the embodiment shown, the base block of three sections 11 shown in figures 3 and 4 was used. Once the base block 11 has been assembled or fixed, the interchangeable blocks 19 are assembled on top of it. Thus, block 19 (a) is placed first, then block 19 (b), and above it block 19 (c), and so on until the desired height is reached. As can be seen, the blocks are coupled and retained by their lying "T" shape, alternating the upper parts 14 and the "legs" 25 of the "T", however, fundamentally, they are fixed to each other by means of the fitting of the first and second faces having their cavities and protrusions, as will be described in relation to figures 8 and 9.

[023] Both the base blocks 1, 11 and the intercalable block 19 have, between their sections 4, 5; 12, 13, 14; and 22, 23, corresponding spacings that separate the sections. Thus, in block 1, at least one intermediate cell 36 is arranged, preferably comprising several cells or aligned gaps, which separate said sections 4, 5 from each other and define a spacing 37 between the vertical projections of said sections 4, 5, as can be seen in figure 1.

[024] In turn, block 11 has at least one intermediate cell 38, 39, which preferably comprises several cells or aligned gaps, which separate said sections 12, 13, 14 from each other and define spacing 40, 41 between the vertical projections of the referred sections 12, 13, 14, as can be seen in figure 3.

[025] Likewise, the intercalatable block 19 has, between its sections 22, 23, a spacing formed by at least one intermediate cell 42, which preferably comprises several cells or aligned gaps, which separate the mentioned sections 22, 23 one from others and define a gap 43 between the vertical projections of said sections 22, 23, as can be seen in figure 5.

[026] As seen in figure 7, when the blocks are fitted together, the spaces and gaps formed by the intermediate cells 36, 38, 39 and 42 form air chambers 44, 45. Said air chambers represent by themselves respective thermal barriers, interrupting the heat transmission from the external walls. However, although this construction reduces the thermal transmission factor to convenient values, these chambers can also house, according to the concepts of the invention, respective plates of insulating material, as indicated by reference number 46 in figure 7. The insulating material it can be any material selected from polymeric foam, expanded polyurethane, rock wool, glass wool, cardboard, according to the thermal demand of the wall. This way, a wall adapted to the desired physical or climatic needs is obtained, and it may be sufficient to leave the gaps without insulation, making the wall quite flexible to the desired requirements. It should be noted that the air chambers 44, 45 and the insulating material 46 are strategically arranged in areas where there is no material continuity or the presence of adhesive materials, such as in the grooves formed between the first and second groove faces between the blocks .

[027] According to the invention, these fittings are formed in order to reduce or optimize the use of adhesive material, such as mortar, bonding pastes, binders, etc., and the retention between the blocks is improved. This is achieved through the special design of the first and second faces of the blocks, and, more particularly, thanks to the development of the cavities 9, 10, 15, 16, 17, 28, 29 and the cavities 32, 33 with projections 34, 35.

[028] The mentioned fitting is shown in more detail in figures 8 and 9, where the first cavity will be identified with reference number 9 according to figure 1, and the second cavity and projection with reference numbers 32 and 34 respectively, according to figure 5, for example. To more easily explain the fitting phenomenon, it can be said that the cavity 9 has edges 47, 48 through which a geometric plane P1 can pass, and the cavity 32 has edges 49, 50 through which a geometric plane P2 can pass. . Cavity 9 has, enclosed under the P1 plane, a V1 volume intended to receive any adhesive material used in the type of construction in question, such as a material selected from a mixture of cement, polyurethane foam, epoxy mixtures, and any other adhesive material that can flow through the cavities, responding to the boss 51.

[029] It is known that this adhesive material, for example mortar, is applied in estimated quantities on the faces of the bricks or blocks to be joined. Generally, the mortar is applied in excess and, when the bricks are touching each other, the mortar escapes from the sides. This mortar is a better temperature conductor than brick, so it works as a better thermal transmission bridge. The inventor of the present invention proposed to define exactly the amount of mortar needed, without excessive waste and without the excess present between the faces of the blocks or bricks to form a thermal transmission bridge. For this, the cavity 9 has a volume that receives the mortar M, which is placed until the edges 47 and 48 are level, without having to go beyond the level of the plane P1, as shown in figure 8, facilitating the level to be leveled with the amount of material needed.

[030] In turn, the second fitting face, of the block above, has the cavity 32 and the projection 34, intended to penetrate the cavity 9 when the blocks are inserted, as observed in figure 9. Here you can also be seen that the cavity 32 presents, enclosed below the plane P2, a volume V2 destined to receive part of the adhesive material that was placed inside the cavity 9. As a characteristic of the invention, the protrusion 34 protrudes outside the aforementioned geometric plane P2 , defining a projecting end 51 that has a volume Ve. These quoted volumes are not random, but maintain a relationship between them, with the volume Ve being less than V2, and with the volume V1 being greater than Ve, or whose sum is equal to Ve. With this design and volumetric ratios, an excellent fit will be obtained with an optimum amount of mortar used.

[031] As can be seen, after the upper block was coupled over the lower one, the projection 34 pushed the mortar M upwards causing it to rise and enter the cavity 32, involving the protruding end 51 and generating a retention through portion 52 of the mortar. As can be seen, there is no mortar material disposed in the joints between the edges 47, 49 and 48, 50, which is very convenient to avoid the formation of a thermal transmission bridge formed by the mortar in these joints.

[032] According to another alternative of the invention, figures 10 to 19 illustrate other forms of incorporation of the invention based on the constructive form of the base block and the interleaving block of figures 1 to 9. To differentiate the reference numbers used in figures 1 to 9 of those used in figures 10 to 19, the latter has added the figure 100, that is, for example, the reference number 8 in figures 1 to 9 has become the reference number 108 in figures 10 to 19.

[033] As can be seen in Figures 10 and 11, the first block or base block, indicated with the general reference number 101, is a block having a plurality of internal cells 102 that extend side by side in the block, separated by internal partitions 103. The block has two sections 104 and 105 of different heights, which form a staggered body, in the form of two staggerings. The outer walls of the block may have roughness 106 that favors coupling, heat dissipation, handling, adherence to adhesive materials, such as towing, etc. The block has at least one first face 107 and 108 on an upper end of each of said sections 104 and 105, with both faces having a flat face 109 and 110 intended to adhere to form a block mounted above the top of the base block, together with the use of an adhesive material, as will be described in detail with respect to figures 17 and 18.

[034] According to another form of incorporation, illustrated in figures 12 and 13, the base block, indicated in this form of incorporation with the reference number 111, is similar to the base block 101, with the difference that instead of being composed of two sections, it has three sections 112, 113 and 114, also of different heights, which form a staggered body, in the form of three staggerings. As in the case of the block of figures 10 and 11, sections 111, 113, 114 have at their upper end a first flat face 115, 116 and 117, being, as indicated, the same as block 101. Both block 101 and block 111 have a base face 118 designed to be supported on the ground to start the construction of the wall, as can be seen in figures 16 and 19.

[035] As in the first alternative, the set of blocks of the invention also comprises a second block or interchangeable block, illustrated in figures 14 and 15 and indicated with the general reference number 119. Like the base block 101, 111, the intercalable block 111 has a plurality of internal cells 120 that extend side by side in the block, separated by internal partitions 121. The block has two sections 122 and 123 of different heights, which form a staggered body or having staggered, shaped sections "T" lying down, with the upper part of the "T", indicated with the general reference number 124, preferably positioned vertically during the erection of the wall, and the "leg" of the "T", indicated with the general reference number 125, is arranged horizontally, thus generating interruptions with all vertical and horizontal joints between both sides of the wall.

[036] The upper part 124 and the “leg” 125 of the lying "T" have respective upper ends where, in each of them, a first flat face 126 and 127 is arranged that has a totally flat face 128 and 129. Unlike the base block 101, 111, the insertable block 111 has lower contact faces. More particularly, the upper part 124 and the "leg" 125 of the lying "T" have respective lower ends where, in each of them, a second face 130 and 131 is defined which has a flat face 132 and 133. The second flat faces 132 and 133, or the bottom face of sections 122 and 123, are intended to form a groove with the first faces 109, 110, 115, 116 and 117 of a base block disposed below the interchangeable block 119, or with a face 128 and 129 of another intercalable block, set forth below

during erection of the wall. The interleaving of these blocks on a wall can be seen on the wall illustrated in figures 16 and 19. However, the fit between the blocks, using an adhesive material 134, will be described in more detail with respect to figures 17 and 18.

[037] Regarding construction and other material characteristics, roughness, etc., block 119 can have all the characteristics of base block 101 and 111. Base and interleaving blocks can be made of any material that meets the structural requirements of desired construction and also to thermal requirements.

[038] Figure 16 illustrates a wall, wall or partition built with the set of blocks of the invention. It can be seen that the base of the wall consists of at least one base block that can have two, three or more sections. In the illustrated embodiment, the three-section base block 111 shown in figures 12 and 13 was used. After the base block 111 has been assembled or fixed, intercalated blocks 119 are assembled on top of it. Thus, first block 119 ( a) then block 119 (b) is placed, block 119% (c) above them, and so on until the desired height is reached. As can be seen, the blocks are coupled and retained by their lying "T" shape, alternating the upper parts 114 and the "legs" 125 of the "T", but fundamentally they are fixed to each other through the contact of the first and second faces, having flat faces between which an adhesive material 134 is disposed, as will be described in relation to figures 17 and 18.

[039] Both base blocks 101 and 111 and intercalable block 119 have sections 104, 105; 112, 113, 114; and 122, 123, corresponding spacings that separate the sections. Thus, in block 101 there is at least one intermediate cell 136, which preferably comprises several cells or aligned gaps, which separate said sections 104, 105 from each other and define a gap 137 between the vertical projections of said sections 104, 105, as can be seen in figure 10. In turn, block 111 has at least one intermediate cell 138, 139, which preferably comprises several cells or aligned gaps, which separate said sections 112, 113, 114 from each other and define gaps 140 , 141 between the vertical projections of said sections 112, 113, 114, as can be seen in figures 12 and 13.

[040] Likewise, the interleavable block 111 has, between its sections 122 and 123, a spacing formed by at least one intermediate cell 142, which preferably comprises several cells or aligned gaps, which separate the mentioned sections 122 and 123 from each other. others and define a gap 143 between the vertical projections of the referred sections 122 and 123, as can be seen in figure 14.

[041] As can be seen in figures 16 and 17, when the blocks are in contact with each other, the spacings and gaps formed by the intermediate cells 136, 138, 139 and 142 form the air chambers 144, 145. Said Air chambers themselves represent thermal barriers, which interrupt the transmission of heat or cold from the external walls. However, although this construction reduces the thermal transmission factor to convenient values, these chambers can accommodate, also according to the concepts of the invention, respective plates of insulating material, as indicated with reference number 146 in figure 16. The material insulation can be any material selected from polymeric foam, expanded polyurethane, rock wool, glass wool, cardboard, according to the thermal demand of the wall. This way, a wall adapted to the desired physical or climatic needs is achieved, and it may be sufficient to leave the gaps without insulation, making the wall quite flexible to the desired requirements. It should be noted that the air chambers 144, 1445 and € the insulating material 146 are strategically arranged in areas where there is no continuity of material or the presence of adhesive materials, such as in the grooves formed between the first and second faces between the blocks. Alternatively, an insulating material 135 such as that illustrated in figure 10 can be used, which allows complete insulation of the wall to prevent the passage of air, interrupting, in turn, the transmission of cold and heat from the external walls. .

[042] According to the invention, the use of adhesive material 134, which allows "coupling" or union between blocks, is reduced and optimized, being able to be selected from the group consisting of mortar, bonding pastes, binders, cement quick contact, polyurethane foam, epoxy mixtures, double-sided adhesive tapes, which improve retention between blocks. Particularly, in the present invention, adhesive mixtures are used between the flat faces, such as epoxy mixes, thin cement, or adhesive compositions, for example, adhesive tapes or strips on opposite faces, or any other system or mixture that requires low thickness, in order to allow to erect a wall, wall or partition in a much faster, practical and easy way.

[043] The coupling, union or contact between the blocks is shown in more detail in figures 17 and 18, where the first flat face will be identified by reference number 109 in figure 10, and the second flat face by reference number 132 of the Figures 14 and 15, by way of example. A geometric plane P1 passes through the flat face 109, and another geometric plane P2 passes through the flat face 132. Between said planes P1 and P2 an adhesive material 134 is arranged, such material being preferably constituted by thin application masses, whether of epoxy origin or cementitious, or by the double-sided adhesive tapes mentioned above, which, thanks to their properties and technical characteristics, allow a much faster bonding and drying or curing, with a more efficient bonding between blocks, with less material. It is well known that this adhesive material, for example, mortar, is applied in estimated quantities on the faces of the bricks or blocks to be joined. Generally it is applied in excess, and when the bricks are supported against each other to be used, this consequently allows a wall, wall or partition to be erected in a much faster, practical and easy way. In turn, because materials with low thermal conduction are used, it is avoided that they function as a "thermal transmission bridge". Thus, in addition to the optimization of operating times, the coefficient of thermal transmission is improved in relation to that obtained in patent No. P 090105139,

[044] Just apply the adhesive material and, supporting the upper blocks, the adhesive material will do its job of bonding between the blocks. On the other hand, it is not necessary to use level lines, since the level is provided by the pieces when resting on each other. In addition, high productivity in square meters is possible, since the materials are stacked on top of each other, taking advantage of the block's own rigidity and the drying speed of the adhesive material; if the wall were built with traditional joints, there would be, at first, warping of the wall due to the low mechanical resistance of conventional cementitious material.

[045] The advantage of reducing thermal bridges and saving adhesive material is indisputable, which represents improvements in the final wall or wall because a better thermal barrier is formed having thermal transmission factors K less than about 0.83 W / m? / k, much smaller than those of a conventional wall that has higher K factors, around 1.75 W / m? / k, and lower than those obtained through patent No. P 090105139, as can be seen in Table 1 a follow: Table 1 Final thermal transmittances U (W / m? / k) Without EPS insulation Rock wool Glass wool Insulation 2 of gap 2 = 0.039 W / (mK) | 2 = 0.040 W / (m.K) | 4 = 0.035 W / (m.K) Mortar | Polyurethane | Mortar | Polyurethane | Mortar | Polyurethane | Mortar | Polyurethane Joints 1 = 1.3 / 1 = 0.0028) 1 = 1.3 /.=0.0028] r = 1.3 /.=0.0028] r = 1.3 | = 0.0028 W / (M.K) | W / (M.K) | W / (m.K) | W / (m.K) | W / (m.K) | W / (m.K) | Wim. | W / (m.K) Without 1.02 0.86 0.87 0.77 0.88 0.77 0.86 0.76 160 | New Years | 202 | 086 om | om | om | om | om | ox | | mm With 0.99 0.83 0.85 0.74 0.85 0.75 0.84 0.74 coatings Without 0.67 0.57 0.51 0.45 0.51 0.45 250 | coatings | mm With 0.65 0.56 0.5 0.44 05 0.45 0.48 0.43 coatings Without, 0.51 0.43 0.35 0.31 0.36 0.32 0.34 0, 31 340 | coatings 7. the 0.42 0.35 0.31 0.35 0.32 0.34 03 coatings

[046] As can be seen, the arrangement of the insulating material between the air chambers helps to remarkably reduce the coefficients of thermal transmission in combination with the adhesive material that facilitates the erection tasks of walls, walls and / or partitions. It can be understood that the table is divided into joints with and without cladding, different widths of blocks formed depending on the type of staggering that compose them, and different types of insulators. In the case of having a coating, it refers to an external layer of cement coating having approximately 10 mm of thickness, and to an internal layer of plaster coating of 10 mm of thickness.

[047] Thus, it can be observed that if there is no insulator in the air chambers defined between the building blocks, without coatings, and using mortar as an adhesive material, values of thermal transmission coefficient that vary between approximately 1, are obtained 02 to 0.51, while with coatings the values vary between 0.99 to 0.50. Likewise, when using polyurethane as an adhesive material between the blocks, the thermal transmission coefficients significantly improve, obtaining values between 0.86 to 0.43 without coatings, and between 0.83 to 0.42 with coatings.

[048] When using insulating materials such as ESP, rock wool and glass in the air chambers formed by the building blocks, the thermal transmission coefficient is further reduced, using both mortar and polyurethane as an adhesive material, in the case of polyurethane be used, it further helps to reduce the coefficient of thermal transmission. As an example, using glass wool as an insulating material between the chambers, together with linings, polyurethane as an adhesive material, and a block width of 340 mm, a surprisingly high thermal transmission coefficient of 0.30 or 0.34 is obtained , if mortar is used as an adhesive material.

[049] As a non-limiting example of the invention, figure 19 shows an alternative to the building block of the present invention. As for the reference numbers in figures 10 to 18, to which the figure "100" has been added, in figure 19 the figure "200" has been added. In figure 19, a portion of a wall, wall and / or partition 201 has been illustrated, showing a base block of four sections 202, 203, 204 and 205 on which interchangeable blocks 206 are mounted alternately. Both the base block and the interchangeable block have the same characteristics mentioned above with respect to blocks 101, 111 and 119. It can then be observed that, between the flat faces 207 and 208 of the base and interchangeable blocks, respectively, polyurethane is arranged as material adhesive. Likewise, between the air chambers 209 formed between the blocks, LV glass wool is arranged as an insulating material. Through this configuration, which is not limiting to the invention, the lowest values of thermal transmission coefficient mentioned above and also in the table are obtained.

[050] As mentioned above, the inventors continued to develop building blocks capable of providing better conditions for the erection of walls, walls and / or partitions, as well as to reduce the coefficients of thermal transmission. In the case of the present invention, the building blocks are characterized by having flat faces between which an adhesive material is placed, such as low-application adhesive masses, of epoxy or cementitious origin, double-sided adhesive tapes or similar, or any other material that requires these characteristics for its application, allowing the erection of a wall, wall and / or partition in less time, in a much more practical, quick and easy way, which, combined with insulating materials arranged between the air chambers, and / or alternatively between the blocks, allow significantly lower thermal transmission coefficients, contrary to the state of the art.

[051] The advantages provided by the present invention in the procedures of erection of walls and in the results obtained are remarkable. For example, in the case of figures 1 to 9, the builder no longer needs to estimate the amount of mortar needed for an effective bond. Simply place the mortar inside cavity 9 and level the dough with a trowel, thus filling the cavities without the need for any calculation. Once supported, the upper blocks and projections 34 will do their job of fitting and properly distributing the mortar. On the other hand, it is not necessary to use level lines, since the level is provided by the pieces when resting on each other. In addition, high productivity in square meters is possible, since the materials are stacked on top of each other, taking advantage of the block's own rigidity and the drying speed of the adhesive material; if the wall were built with traditional joints, there would be, at first, warping of the wall due to the low mechanical resistance of conventional cementitious material.

[052] On the other hand, the advantage of reducing thermal bridges and saving adhesive material is indisputable, which represents improvements in the final wall or wall because a better thermal barrier is formed with thermal transmission factors K less than about 0.83 W / m? / K, much smaller than those of a conventional wall with higher K factors, around 1.75 W / m? / K.

Claims (16)

Claims 1. SET OF BUILDING BLOCKS, of the type formed by parallelepiped bodies having internal cells and having at least a first face and a second face to fit between the blocks, such set being characterized by comprising: a first base block having at least two sections of different heights that form a staggered body, in the form of two staggerings; and a second intercalable block having at least two sections of different heights that form a lying "T" shaped body, with the upper part of the "T" being arranged vertically and the "leg" of the "T" being horizontally arranged. 2. SET OF BLOCKS, according to claim 1, characterized in that said first base block has three sections of different heights that form a stepped body, in the form of three steps. 3. SET OF BLOCKS, according to any one of the preceding claims, characterized in that, between the aforementioned sections of said first base block and second intercalable block, at least one intermediate cell is arranged, which separates said sections from one another and defines a gap between the vertical projections of these sections. 4. SET OF BLOCKS, according to claim 3, characterized in that the aforementioned first blocks are coupled and fitted together and the said gap between the vertical projections of said sections, forming an air chamber. 5. ASSEMBLY OF BLOCKS, according to claim 4, characterized in that said air chamber houses a plate of insulating material. 6. SET OF BLOCKS, according to claim 5, characterized in that said insulating material is selected from polymeric foam, expanded polyurethane, rock wool, glass wool, and cardboard. 7. SET OF BLOCKS, according to any one of the preceding claims, characterized in that the aforementioned first and second blocks are made of ceramic, cementitious or plastic materials. 8. SET OF BLOCKS, according to any one of the preceding claims, characterized in that said first face has a first cavity open to the outside and the aforementioned second face has a second cavity open to the outside, with a protrusion extending to from said second cavity, and with the edges of that second cavity defining a geometric plane below which said second cavity has a volume V2, and said projection projecting out of said geometric plane defining a protruding end, with said protruding end showing a volume Ve, where Ve <V2, and with said first cavity presenting a volume V1 maintaining the relation V1> Ve. 9. SET OF BLOCKS, according to claim 8, characterized in that the aforementioned first face, presenting said first cavity open to the outside, is arranged at an upper end of each of the mentioned sections of the staggered body. 10. SET OF BLOCKS, according to either of claims 8 or 9, characterized in that the upper part and the "leg" of the lying "T" have respective upper ends, where said first face is defined, presenting the first open cavity for the outside, with the upper part and the "leg" of the "T" lying down having respective lower extremities, where the said second face is defined, presenting the second cavity open to the outside and having the protrusion. 11. SET OF BLOCKS, according to any one of claims 8 to 10, characterized in that said first and second cavities define receptacle housings for an adhesive material selected from cementitious and polyurethane materials, polyurethane foam, and epoxy mixtures. 12. SET OF BLOCKS, according to any one of claims 1 to 7, characterized in that said first face has at least one flat face and said second face has at least one flat face, with both flat faces defining, each one , respective geometrical planes between which an adhesive material for bonding blocks is arranged, where the aforementioned adhesive material is selected from the group consisting of low-thickness adhesive masses, of epoxy or cementitious origin, and double-sided adhesive tapes. 13. ASSEMBLY OF BLOCKS, according to claim 12, characterized in that said adhesive material is a low thickness epoxy adhesive mass. 14. ASSEMBLY OF BLOCKS, according to either of claims 12 or 13, characterized in that said first flat face is arranged at an upper end of each of the mentioned sections of the stepped body. 15. SET OF BLOCKS, according to any one of claims 12 to 14, characterized in that the upper part and the "leg" of the lying "T" have respective upper ends where the aforementioned first flat face is defined, with the upper part and the "leg" of the lying "T" showing respective lower extremities where said second flat face is defined. 16. SET OF BLOCKS, according to any one of the preceding claims, characterized in that a plate of insulating material is provided that extends and expands partially or totally through the section of the blocks, in which said insulating material is selected from polymeric foam. , expanded polyurethane, rock wool, glass wool and cardboard.