CZ2011189A3 - Modular system of building prefabricated parts - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a modular building prefabricated system (10, 20, 30, 40, 50), particularly prefabricated structural elements for a wall or partition wall, comprising a pair of separate building elements having a unit height (vj) of which each structural element is provided a vertically oriented dovetail joint for interconnecting separate building elements, wherein one of the pair of building elements is a face plate (1, 2) and the other of the pair of building elements is a bonding block (3, 4, 5, 6). The modular building prefabricated system comprises at least one further face plate (11, 21) and / or at least one other bonding block (3, 4, 5) having a different height than the unit height (vj). Another face plate (11, 21) and / or another binding block (3, 4, 5) are provided with a corresponding dovetail joint portion.

Description

Modular system of prefabricated buildings

Field of technology

A modular system of prefabricated buildings, in particular prefabricated building blocks for retaining walls or partitions, comprising a pair of separate building elements having a unit height, each building element being provided with one part, a dovetail joint for interconnecting the separate building elements and vertically oriented / ryhia9výaa =. spQjena, wherein one of the pair of building elements is a face plate and the other of the pair of building elements is a bond block.

State of the art

The construction industry uses a number of prefabricated means in order to simplify the construction work carried out on the construction site while maintaining the required quality of construction. For example, in terms of residential and similar buildings, or the construction of industrial buildings, the requirements for the building components used can be well established.

The situation is somewhat different in connection with constructions whose purpose is landscaping and ensuring the requirements for their statics. This is about achieving the required quality of construction in terms of its technical parameters, especially long-term strength and good appearance, while the obvious prerequisite is a reasonable acquisition cost.

The solution according to CZ 2001-4554 A3 are blocks which, after assembly, form a horizontal cavity. On the upper surface of the block there is a groove in the direction of the cavity, on the lower surface 25 of the block there is a shaped longitudinal protrusion in the direction of the cavity corresponding to the cross section of the groove on the upper surface. The layers of blocks are inserted into each other in the direction of the built wall by a longitudinal protrusion and a groove. In addition, a continuous retaining strip can be inserted in the groove, under which, for example, a reinforcing mesh (usually geotextile) is inserted over a certain length of the built wall, which is then covered with soil behind the reverse side of the wall, thus anchoring the wall in this soil.

/ PV-201T-189 / ‘, PS3735GŽ1V /4:4.2011/ 9.3.2012- /

The blocks according to CZ 20β54 U1 are provided with a groove in the upper surface and a tongue in the lower surface in the horizontal direction from the point of view of the built wall. A longitudinal geogrid holder can be inserted into the groove, which is attached to the protrusions of the holder. The upper row of blocks holds the holder in the wall, the geogrid is essentially horizontally anchored 5 / in the backfill of soil on the reverse side of the wall.

The solution according to CZ 22S | 624 B1 designs blocks in an "H" -shaped view with n oblique edges extending from the "bar" of the letter "H". On the reverse side of the blocks, there are shaped recesses for fixing the "anchor" formed by strips of polyester resin reinforced with glass fiber, which are anchored in the backfill 10 'on the reverse side of the wall.

CZ 253 ^ 41 B1 proposes vertically arranged blocks with a floor plan in the shape of the letter "H". These blocks are connected together by a continuous armature placed in vertical channels running through the blocks, thus forming pillars. They are arranged at distances from each other and, after the formwork has been placed, are cast in a monolithic part 1 of the retaining wall which binds the pillars.

Identical shaped blocks with a parallel upper and lower surface are situated horizontally in the built wall according to CZ 280 ^ 189 B6. In the upper surface there are holes for inserting pins, the free bones of which protrude from the upper surface, in the lower surface there are approximately triangular cavities, the inlet opening of which is substantially larger than the diameter of the pins. In the middle part of the blocks there are large vertical through-cavities, the upper layer blocks located on the lower layer blocks being situated relative to each other so that the pins enter the cavities, while the blocks can be moved one after the other within the cavity area or otherwise curved or irregular walls. The large through-cavities of the blocks of the built wall 25 form continuous substantially vertical cavities along the entire height of the wall, which are then connected by rebars and concrete grout.

Blocks with a parallel upper and lower surface and with the same width (distance between the face and back surface of the block) corresponding to the wall thickness are subject to protection CZ 300 ^ 29 B6. The side walls of the blocks are non-parallel, which makes it possible to form straight, wavy or otherwise curved layers from the blocks. The individual layers are bound together by pins inserted in holes and / or grooves in the upper and / or lower surfaces. Some blocks have continuous vertical large cavities, 'PS3735CŽ11 /

9.3.2012 / • PV-2011-189- /

4.4.201V both for the purpose of reducing weight, on the other hand, are usable for concrete grouting connecting multiple layers.

/

CZ-EP 1415ÍD53 T3 proposes blocks with a parallel upper and lower surface í i í »and with the same width (distance between the face and the back surface of the block) corresponding to the wall thickness. The side walls of the blocks are non-parallel, which allows the blocks to form layers that are straight, wavy or otherwise curved. There are alternatives and combinations thereof, where, for example, straight grooves are formed in the lower surface of the wall, guide pin holes in the upper surface, alternating vertical straight grooves and vertical straight protrusions in the side walls. In the middle part of the block, large vertical cavities are formed for accommodating vertical reinforcing means and / or concrete grout, and reinforcing bars placed in grooves in the upper surfaces of the blocks can also tie a number of blocks in one layer of blocks.

Block-shaped monoblocks with a large cavity oriented vertically in terms of l?

block orientations in the built retaining wall are subject to protection according to FR 2.658Í217 A1. All four or at least two opposite vertical walls are provided with vertical dovetail grooves and / or corresponding protrusions.

In one alternative, dovetail grooves are formed in two opposite walls of one group of blocks, the other groups of blocks having corresponding protrusions. There is a large mutual clearance between the grooves and the protrusions. These blocks 20 are used to assemble a curved bonded outer retaining wall, with the tight dovetail grooves and their corresponding protrusions on two other surfaces of the other blocks making it possible to assemble anchor walls connected to the outer wall. The anchor walls protrude radially from the outer retaining wall, the mutual radial gaps are then covered with soil.

, Relatively flat large blocks with relief cavities according to FR

IN

2729409 A1 are designed for the construction of vertical or sloping retaining walls. To

A keyway with a cross-section of an isosceles trapezoid is formed in the middle area of the blocks in the middle area of the blocks, one side wall of the block having the same inclination as the slope of the keystone side of the keyway. The construction 3d includes wedges which have the shape of this groove, the length of one side of the wedge being about twice the height of the block. The wedge can always connect two adjacent blocks placed on top of each other. If the blocks are oriented with the wider part of the groove upwards, using 'PV 2011-189-í ‘‘ PS3ť35'ďž2l

4/4/2011; ^9.3.2012 A vertical wall is assembled in the wedges, on the contrary, the wider part of the groove is oriented downwards, an inclined wall is assembled with the help of wedges, the slope of which corresponds to the slope of the trapezoidal groove wall.

Γ

US 4990032 proposes a retaining wall formed by "left" and "right" blocks, with which they have a face. On the opposite side are arranged massive anchor-shaped ribs open towards the ground backfill. In an alternative embodiment, the open ribs are provided with horizontal grooves into which horizontal anchors formed by steel reinforcement gratings can be fastened after the wall has been erected.

7

US §174688 proposes means for strengthening less steep embankments. 10. The system comprises low hollow flexurally rigid blocks, the front wall of which is planar, the back forming a flat arc, which is connected by a crossbar to the center of the front wall at the point of greatest rise of the arc. The individual rows of blocks located in the longitudinal direction of the embankment are bound by concrete rods pointing into the ground of the embankment, the individual rows of blocks are spaced apart by the length of the embankments, thus creating 15 "steps" determining the slope of the embankment. For a steeper embankment, the height of each step is created by two superimposed panels. The panels are bound to each other by rods provided with holes at the ends for inserting vertical anchor pins embedded in the ground.

v y

The solution according to US § 820305 proposes a concrete block with one rib in the shape of the letter "T" or with two ribs in the shape of the Greek letter "tt". The surface of the part of the block corresponding to the horizontal part of these letters is the front or back of the retaining wall, the ribs provided with grooves pointing towards the inside of the wall. In the direction of the wall length, horizontal reinforcing bars are placed in the grooves of the blocks, which are additionally bound by vertical bars. The largest wall thickness is given by two blocks which practically touch the rib, the smallest wall thickness when the blocks are inserted is given by the length of the rib and the thickness of the front and back of the block. The thickness of the retaining wall can decrease upwards within this stated range. In an alternative design, the interior of the wall is additionally filled with concrete. In another alternative embodiment, the retaining wall is formed of a single layer of blocks forming the face, and is fastened in the ground backfill on the reverse side or in a concrete grout between the soil and the blocks by means of ribs, a vertical armature and long anchor rods connected thereto.

/ PV-2011-1897 PS3735ČŽ ^ 1 /

4,4..2014v 9.3.2012- /

The solution according to US 5 ^ 88p78 is only suitable for a retaining wall. It comprises a substantially vertical front part formed by layers of face plates which have a vertical blind dovetail groove on the reverse side, in which a rectangular rib is always inserted by means of a rectangular rib which has one dovetail tongue arranged on both vertical edges. With one tongue the rib is connected to the dovetail groove of the face plate so that it is placed perpendicular to it, on the other its tongue other building elements of the retaining wall can be connected away from the face plate. The number of joints of individual elements reduces the rigidity of the retaining wall frame and increases the number of building elements. Due to the blind dovetail groove in the face plates 10, the individual layers are not bound vertically, which is one of the features of the protected solution.

Short connecting components with dovetail tongues for the connection of building elements, especially for partition walls, are also known from solutions according to CH 676628 A or FR 3690M81 A1. CN 201292599 Y uses dovetail joints to form ISC cladding sandwiches consisting of thin outer support plates, between which a plate of thermal insulation material is placed.

The disadvantage of the solution according to the prior art is the single purpose of the one-piece building components used. With the exception of the solutions according to U.S. Pat. No. 5,688-78, the solutions described are not suitable for the purpose of retaining walls. The individual building components do not have sufficient rigidity per se, but rather rely on the reinforcement of the system with concrete poured into the cavities of the fittings used, or further reinforcement with steel reinforcing bars and wires.

The object of the invention is to provide a prefabricated building component which allows its variable use in different conditions, which would allow variability of its use on site and, moreover, is less technologically demanding.

The essence of the invention

The object of the invention is achieved by a modular system of prefabricated buildings comprising a pair of separate building elements having a unit height, the essence of which is that it comprises at least one further face plate and / or at least one further bonding block having a different height than the unit height, the further face plate and / or the further bonding block being provided with a respective part of the dovetail joint. The different heights of the prefabricated building materials make it possible to interconnect the individual elements of the layers arranged one above the other by interconnection and thus to form a rigid structure even in the vertical direction of the building.

It is advantageous if two mutually parallel dovetail grooves are formed in the reverse side of the face plate. The wall face is then formed of face plates of unit length and of face plates of double length, which can be bound to each other.

The side vertical walls of the face plate have a bevelled side vertical wall in the region facing the reverse side. This makes it possible to create a retaining wall in the floor plan forming a convex arc.

The binding block is provided on the parallel opposite surfaces with parallel dovetail lips, which makes it possible to bind the two face plates facing each other with the reverse surfaces. The prefabricated buildings created in this way are suitable for the construction of partition walls.

The bonding block is formed as a monolith comprising two plates adjoining 2d in the shape of the letter "T", the plate arranged in the axis of symmetry of the bonding block being provided with a dovetail tongue on the surface of the opposite plate forming the "T" bar. The prefabricated building is thus created by connecting the connection block to the key plate, while the "T" bar of the connection block is parallel to the face plate. The prefabricated building is suitable for the construction of a retaining wall, the partition is a means of anchoring the prefabricated in the ground backfill.

The plate forming the "T" bar has a dovetail groove parallel to the dovetail tongue formed in the area facing away from the second plate. In this case, it is advantageous if the axis of the dovetail groove lies in the plane of symmetry of the coupling block. The connecting blocks can thus be chained towards the ground, which achieves a very good anchorage of the retaining wall in the terrain. The chaining of the "T" -shaped connecting blocks allows them to be used for the construction of a wide partition wall.

PV 2011-189 ^ 'PS3735EN_T ‘, 4.4.201 Ή 9: 3.2012- /

At least some of the building elements are made of concrete. Such a prefabricated building has a high strength and durability, which is particularly advantageous for the construction of retaining walls. In another embodiment, it is advantageous if one of the building elements is made of plastic or wood. Where these materials 5 meet the strength requirements, a favorable production price can be achieved, while its handling during transport as well as during its own construction activity is facilitated due to its weight.

Advantageously, the stiffness and strength of the prefabricated parts can be increased by using metal reinforcements.

Thanks to the modular arrangement, the prefabricated buildings according to the invention provide easy assembly, variability and high rigidity of the resulting structure. In addition to technical requirements, the building also meets aesthetic requirements.

Overview of pictures in the drawings,

Exemplary embodiments using the solution according to the invention are schematically shown in the drawing, where FIG. 1 is an oblique view of a face plate with one dovetail groove, FIG. 2 is an oblique view of a face plate with two dovetail grooves, FIG. Fig. 4 is an oblique view of a block-shaped closing binding block provided with two dovetail lips, Fig. 5 is an oblique view of a "T" shaped connecting block with a dovetail groove and a dovetail tongue, Fig. 6 is a prefabricated building block. composed of two faceplates whose backs touch, the panels being bound by higher bonding blocks analogous to the type of Fig. 3, Fig. 7 a prefabricated building of two faceplates according to Fig. 2 assembled with a gap, oriented back to back and connected by two higher elongated bonding blocks analogous to the type of Fig. 3, Fig. 8 a prefabricated building assembled from two face plates according to Fig. 2 assembled with a gap, k These are connected by two closing connecting blocks according to Fig. 4, Fig. 9 a prefabricated building assembly composed of a face plate according to Fig. 2 and two connecting blocks according to Fig. 5, Fig. 10 a part of a retaining wall made of building prefabricated according to Fig. 6; 11 shows a part of a retaining wall made of prefabricated buildings according to FIG. 9, FIG. 12 shows a part of a retaining wall made of prefabricated buildings; PS3735CZ_1ř

9.3.2012 / .'PV-2044-189-2 /4-.4,201 Η prefabricated parts analogous to the type according to Fig. 9 with a combination of different sizes of faceplates and Fig. 13 part of partitions made of modified prefabricated parts analogous to the type from Fig. 6 connected by a column composed of modified prefabricated buildings according to Fig. 7.

IN

Exemplary embodiments of the invention

The solution according to the invention proposes a system of modular components, prefabricated buildings, especially for the construction of retaining walls. Due to the relationship between retaining and dividing walls, the design also monitors the possibility of using .10 of these building components for dividing walls, baseboards and fence posts and the like.

Concrete is a particularly suitable material for the production of cast prefabricated buildings. It is obvious that at least some elements of prefabricated parts can be made of plastics, possibly of wood or crushed and bonded wood masses. It is also possible to reinforce them with suitable steel elements.

From the point of view of retaining walls, the solution according to the invention is prefabricated building elements composed of separate visible building elements and separate connecting elements. All elements, prefabricated buildings and parts of the walls made of them are shown and described in terms of the position they occupy in the built-up state.

The construction visual element is basically the face plate. In the modular system, simple face plates 1 are used in the exemplary embodiments (FIG.

1) and 11. the double face plates 2 (FIG. 2) and 21. The face plates 1, 2 have the shape of a flat block with a unit height vj, the face plates 11. 21 with a half height, i.e. 0.5 x vj. The single face plate 1.11 has a unit width sj. The double face plate 2, 21 .25 has twice the width, ie 2x sj. The thickness of all face plates is the same in the exemplary embodiment. The reverse side 12 of the face plate 1, 11 is provided in the middle with one continuous vertical dovetail groove 13. The largest width sr of the dovetail profile and the dovetail profile is uniform in the modular system. The double face plate 2, 21 is provided symmetrically on the reverse side 22 with two vertical 3d. dovetail grooves 23 with a pitch corresponding to the unit width sj. The face surfaces 24 of the face plates 1, 11, 2, 21 can be smooth or surface-treated

W-2 & 44-189- <..... / P & 373ŠČ £ Η; 4.4.201- ^, 9.3.2042 / splitting, grinding, cutting, blasting, blasting and the like. Part or all of the circumference of the face 14, 24 may be provided with a chamfer 15, 25, as shown in the case of the double face 2. In addition, in the exemplary embodiment, the rear half of the vertical side walls of the face 1, 2 faces the reverse side. 12, 22 a chamfer 16, the plane of which forms an angle of about 30 ° with the front part of the vertical side wall.

In an exemplary embodiment, the modular system comprises several types of coupling elements.

Fig. 3 shows a connecting block 3, the opposite vertical walls of which form a dovetail tongue 31. The outer dimensions of the connecting block 3 correspond to a block whose thickness corresponds to the largest width sr of the dovetail profile, the part between the dovetail tongues 31 forming a tapered neck 32 of length dk. The length d3 is given by the sum dk + 2x hr, where hr is the height of the dovetail profile. The length d3 (resp. Dk) and the height v3 differ in the modular system according to the requirements for its installation. The height v3 is equal to the unit height vi of the module system, or is half as large or smaller, ie v3 = vj ± 0.5 vj The connecting blocks 3 of length d3 shown in Fig. 3 are intended for the construction of hollow partitions, length dk here it indicates the width of the respective cavity. The second variant is a binding block 4 (not shown), the dovetail pins 31 of which are practically connected to each other, the binding block 4, i.e. 20, does not have a neck in the sense of the previous case. The length d4 of the coupling block 4 is thus given by practically two heights hr of the dovetail profile. This variant of the connection block 4 is intended for the construction of partition walls which do not have an internal cavity. The walls for which the listed elements are intended will be described below. The connecting block 3 can also be formed with only one dovetail tongue 31 in the case where it is used as a retaining wall element, which is fixed by the dovetail tongue 31 in the dovetail groove 13, 23 of the face plate 1, 2, its surface opposite the dovetail. Peru is deposited in a backfill of soil.

Fig. 4 shows a closing binding block 5, which is analogous to the binding block of Fig. 3. One side of the neck 51 is followed by a closing part 52, 3d whose length du is substantially the distance between the dovetail lips 53 and is therefore the same as the length dk from Fig. 3. Corresponds to the width of the cavity of the partition wall described below. The total length d5 of the coupling block 5 is du + 2x hr. Height v5 of the coupling block

PV 2011-189 / PS3735EN ^ 1 ^J .4.4.2011 / '9.3.2012 / is equal to the unit height vi of the module system, or is half as large or less, ie v5 = vi ± 0.5 vj.

Fig. 5 shows a "T" -shaped coupling block 6 according to the invention, the shaft 61 of which is terminated by a vertical dovetail tongue 62. A vertical continuous dovetail groove 64 is formed in the bar 63 on the opposite side of the shaft 61 in the axis of symmetry of the block. In the exemplary embodiment, a tongue 65 and a half-groove 66 are formed in the upper and lower surfaces of the partition 63 so that a form-fit connection of the superimposed bonding blocks 6 is formed. block 6 is equal to IQ of the unit height vi of the module system or is half as large or less, i.e. v6 = yj ± 0.5 vj. In an alternative embodiment, the width s6 of the partition 63 of the coupling block 6 is about 10% smaller than the unit width si of the module system.

The faceplates χ, 11, 2, 21 described above and the connecting blocks 3, 4, 5, 6 are part of the following modular prefabricated components designed especially for the construction of retaining walls or dividing walls. Fig. 6 shows a prefabricated building 10 for the construction of partitions. In an exemplary embodiment, it comprises two double face plates 2 facing each other with back sides 22 without a gap, being bound by the bonding blocks 4 described by the bonding block 3 according to Fig. 3. The height v3 of the bonding blocks 4 is chosen so prefabricated buildings 10 interconnected. Combinations of bonding blocks 4 of the lengths described above can be used for this purpose, thus ensuring that the bonding block 4 of length vj is inserted by one half in the dovetail groove 22 of the prefabricated layer 10 and the other half in the dovetail groove 22 of the prefabricated building 10 $ 2 above layers of the built partition wall. A modification of the prefabricated building 10 is a prefabricated building 20 not shown separately, which comprises two simple face plates 1 facing each other with the back sides 12 without a gap, being bound by a binding block 4.

Fig. 7 shows a prefabricated building 30 for the construction of partitions. 3d In an exemplary embodiment, it comprises two double face plates 2 facing each other with the reverse sides 22 with a gap between the hollow partitions. The face plates 2 are connected by dovetail joints to bonding blocks 3, the length dk of which determines each other

PS3735CZ-1 /

9: 3.2012 /

PV-2011'189 /. 4.4: 2011 / distance between the back sides 22 of the face plates 2. The height v3 of the connecting blocks 3 is chosen in the same way as for the prefabricated building 10.

The prefabricated building 40 according to FIG. 8 is suitable for the construction of a partition wall or for the construction of columns. Its outer surface is determined by the use of closing 5 'connecting blocks 5, the closing parts 52 of which form two opposite planar surfaces with the vertical sides of the face plates 2. The face plates 2 are connected to the closing connecting blocks 5 by dovetail joints. The height v5 of the connecting blocks 5 is chosen according to the same considerations as in the previous prefabricated buildings 10 and 30.

10 'The prefabricated building 50 shown in FIG. 9 is intended for the construction of a retaining wall. Two connecting blocks 6 are connected to the face plate 2 by dovetail joints via dovetail joints. The shanks 61 of the connecting blocks 6 connecting the face plates 2 with the partitions 63 of the connecting block 6, which are due to their area and spatial orientation an effective anchoring means in the backfill. The tongues 65 and half-grooves 66 at the upper and lower edges of the partition 63 of the bonding block 6 contribute to the mutual stability of the adjacent horizontal rows of the retaining wall. bonding blocks 6 into the backfill and increases the anchorage strength of the retaining wall.

Fig. 10 shows a part of a partition wall made of prefabricated buildings 10.

Fig. 11 shows a part of the retaining wall made of prefabricated buildings 50.

A retaining wall, part of which is shown in Fig. 12, is assembled from analogous prefabricated building elements containing bonding blocks 6 25 in combination with face plates 1, 11, 2, 21. Several bonding blocks 6 can be chained in several layers to the depth of the backfill by means of a dovetail tongue 62 at the end of the shaft 61 and a dovetail groove 64 in the crosspiece 63 of the respective connecting blocks 6.

The chamfer 16 of the rear part of the side walls of the face plates 1, 2 and the smaller width of the partitions 63 of the connecting blocks 6 make it possible to build a retaining wall from the prefabricated buildings 50, the floor plan of which is a convex arch. For example, when, 'PU201M8 ^ Z PS3735EN_1-!

4.4.201 H * 9.3.2012- / unit width net = 25 cm, width s6 = 20 cm of the partition and length d6 = 25 cm of the binding block 6, a convex arc with a radius of about 3.5 can be created using one row of binding blocks 6 ma when using three rows of chained link blocks 6, an arc with a radius of about 6.5 m. For an arc with an even smaller radius, the partitions must be shortened for the respective link blocks 6.

The prefabricated building elements 50 can be used for the construction of wide partitions by connecting a connecting block 3 to the dovetail groove 64 of the prefabricated part 50, to which a single or double face plate 1, 2 is connected to the second dovetail tongue 31 with a dovetail groove 13. In another variant, an even wider partition wall is formed by joining two prefabricated buildings 50 forming one and the other side of the wall by means of connecting blocks 3 inserted by dovetail tongues 31 into the dovetail grooves 64 of the prefabricated buildings 50.

Fig. 13 shows a part of a partition wall with a post 7 composed of prefabricated buildings 10 and 20. Two wall parts are connected to a post 7, 15 which is formed by a vertical assembly of prefabricated buildings 30, the connecting block 3 having a length d3 which is the sum two support heights hr of the dovetail profile and two face plate thicknesses 2. If the column 7 is to extend beyond the upper edge of the wall, it is possible to use prefabricated buildings 40 for this projecting part of the column, which have all four perimeter planar surfaces.

It will be appreciated that in addition to the alternative and bonded block and faceplate structures shown and the wall structures constructed therefrom, there are many other options which fall within the scope of the following claims. The building structures according to the invention can thus be used as retaining and dividing walls, masonry fences, load-bearing and other walls, foundations, stairs, foundations, garden and park accessories.

The advantage is especially the possibility to build such walls in a dry, ie enamel-free manner. At the same time, the construction of the assembled building prefabricated parts allows the casting of vertical cavities and / or their reinforcement in cases where it is suitable. Between the individual layers of building prefabricated parts, the edges of geotextiles or wire flat reinforcements can be inserted, which then create substantially horizontal tensile anchoring means in the backfill.

ZPV-2041-189 /

4/4/20111

PS3735CZ_U

9.3.2012- (

List of reference marks faceplate single unit construction prefabricated faceplate single low width 12 back surface (faceplates single) dovetail groove (faceplates single) faceplate (faceplates single) edge (faceplates single) faceplate double unit to 20 construction prefabricated face plate double low back surface (double faceplates) dovetail groove (double faceplates) faceplate (double faceplates) is 25 edge (double faceplates) binding block (with neck) construction prefabricated dovetail tongue neck (binding block)

4 binding block (without neck) prefabricated building block binding block building prefabricated neck (closing binding block) closing part (closing binding block) ^of 53 dovetail pen (closing binding block) binding block (T-shaped) shank (binding block) dovetail pen (binding block in the shape of "T")

63 crosspiece ("T" -shaped block) dovetail groove ("T-shaped block") tongue (T-block blocks) half-groove ("T-block block") post dk neck length block) du length of the closing part (binding block) d3 length of the binding block d4 length of the binding block d5 length of the binding block

4ď d6 length of binding block hr bearing height of dovetail profile sj unit width sr largest width of dovetail profile s6 width of partition (binding block in "T" shape) vj unit height v3 height of binding block v5 height of binding block v6 height of binding block

Claims (11)

PATENT CLAIMS A modular system of prefabricated buildings (10, 20, 30, 40, 50), in particular prefabricated building elements for retaining walls or partitions, comprising a pair 5 'of separate building elements having a unit height (vj), each building element being provided with one parts * of a dovetail joint for interconnection. AA of separate building elements, (vertically oriented / rybrnevyg ^ spajemy wherein one of the pair of building elements is the face plate (1, 2) and the other of the pair of building elements is the connecting block (3, 4, 5, 6), characterized in that 10 comprises at least one further face plate (11, 21) and / or at least one further bonding block (3, 4, 5, 6) having a different height than the unit height (vj), the further face plate (11, 21) and and / or another connecting block (3, 4, 5, 6) are provided with a respective part of the dovetail joint. Modular system of prefabricated buildings (10, 20, 30, 40, 50) according to claim 1, characterized in that the face plates (2, 21) are provided on their reverse side with a pair of mutually parallel dovetail grooves (23). Modular building prefabricated system (10, 20, 30, 40, 50) according to Claim 1 or 2, characterized in that the face plates (1, 2) have a chamfer (16) in the region facing the reverse side (12, 22). ) side vertical walls. .20 Modular prefabricated building system (10, 20, 30, 40) according to Claim 1, characterized in that the bonding block (3, 4, 5) is provided with parallel dovetail tongues (31, 53) on two opposite surfaces. Modular building prefabricated system (50) according to claim 1, characterized in that the bonding block (6) is formed as a monolith comprising two T-shaped boards adjoining one another, the board arranged in the symmetry axis of the bonding block ( 6) is provided with a dovetail tongue (62) on the surface of the opposite plate forming the partition (63) of the letter "T". / PV-2aiM89f ¹ PS3735CZ_l ^y 4.4.201V 9.3.2012 / A modular prefabricated system (50) according to claim 5, characterized in that the plate forming the "T" partition (63) has a dovetail groove (64) formed parallel to the dovetail tongue (62) formed in the area facing away from the second plate. WITH' Modular building prefabricated system (50) according to Claim 6, characterized in that the axis of the dovetail groove (62) lies in the plane of symmetry of the coupling block (6). Modular system of prefabricated buildings (10, 20, 30, 40, 50) according to any one of the preceding claims, characterized in that at least one of the ids of the building elements is made of concrete. Modular building prefabricated system (10, 20, 30, 40) according to any one of claims 1 to 7, characterized in that at least one of the building elements is made of plastic. 10. Modular system of prefabricated buildings (10, 20, 30, 40, 50) according to 15. Any of claims 1 to 7, wherein at least one of the building elements is made of wood. Modular system of prefabricated buildings (10, 20, 30, 40, 50) according to any one of claims 8 to 10, characterized in that at least one of the building elements comprises metal reinforcements.