HU202614B - Manual wall and floor element as well as buried curb cradling member - Google Patents

Abstract

The present invention relates to lightweight concrete, preferably perlite concrete, to a masonry and slab element (20), and to a retaining wireframe element. The former is a T-shaped body whose legs (1) and rib (2) are both 1/4 of the total length of the element (a), while the width (b) of the rib (2) is half the length of the element (20). . On one side of the element (20) there are cylindrical pins (5) and octagonal cross-sections (4) for receiving the pins (5) on the other side. There is a dry connection between adjacent elements. Between the slab elements (20), concrete steel slabs extend, which work together to iron the slab monolithic reinforced concrete beams. The wreath-forming elements have stems perpendicular to one another, and the lower surface of the lower shank is provided with pins (5) of the same shape, size, and distribution as the hand-held masonry and slab elements (20), which can provide a dry connection between the wreath-forming elements (1). figure). EN 202 614 B Scope of the description: 5 pages, 9 drawings -1-

Description

FIELD OF THE INVENTION The present invention relates to a hand masonry and ceiling element as well as a remnant wrought iron formwork element.

In addition to industrialized panel construction, the construction industry has always played a significant role in the construction of hand-built blocks, especially in family houses, terraced houses and condominiums, since the use of this technology does not require lifting machines, which facilitates domestic work. Increasingly stringent thermal regulations are easier to meet with hand-built masonry units, usually made of lightweight concrete than with other construction methods. The importance of manual masonry block construction is expected to increase in the future.

The hand-masonry block systems currently used are essentially disadvantageous in two respects. On the one hand, blocks and wall joints, as well as wall joints, have to be carved into blocks, which entails a loss of material and a considerable extra labor cost; on the other hand, a curing agent - mortar - must be used between the rows of elements, under and over one another, and between adjacent elements, which is also a labor-intensive and material-intensive operation and is detrimental to the thermal insulation of the entire masonry. 25

It is an object of the present invention to provide a hand masonry and ceiling element that eliminates the need for carving elements at the corners, coffees and wall joints, apart from a minimal number of elements, and eliminates the need for mortar under and over each other. between building blocks

The invention is based on the recognition that, with proper geometry, all nodes can be formed using the same masonry element. The present invention is further based on the discovery that when masonry units (blocks) located below or above each other are joined by pin-to-nest connections, no mortar 40 is required to ensure the stability of the wall.

Based on these findings, the object of the present invention has been solved by the use of a top view T-shaped hand masonry element characterized in that: - in the wall-mounted position in the top view and in the slab-mounted position in the side view; 1 / 4th of the length of the cell, 50% of the nominal length of the rib and 1 / 4th of the width of the cell; a nest in the region of one of the T-shaped surfaces and pins which fit into the nests of a respective other element in the region of the other T-shaped surface; they have longitudinal geometric center axes between nests and pins. It is preferred that the longitudinal geometric center axes pass through the intersections of a geometric square mesh constructed along the T-shaped surfaces having a distance of 1/8 of the total nominal element length. . "Nominal Element Length" means (hereinafter referred to as "60") that the dimensions of the element may differ from the specified values by values corresponding to the manufacturing tolerances.

In a further embodiment, the nests are top or side views of a regular polygon, such as octagonal 65, rectangular or hexagonal, or circular, and the pins are cylindrical or truncated. It is further preferred that the nests are delimited by four to four sides, octagonal pins in top and side views, and grooves perpendicular to each other extending between adjacent octagonal pins and extending between cylindrical or conical pins on the other side. and the longitudinal geometric center axes passing through the pins of the octagonal planes pass through the intersections of squares whose distance between them is 1/8 of the total nominal length of the longitudinal geometric center axis. In this case, it is expedient if the grooves and ribs have the same width or preferably the same depth or height, or if the element having octagonal pins has half pins in its circumferential region and quarter pins in its corners, and The grooves between the projections protrude to the outside of the element.

According to another feature of the invention, the sockets extend into elongated cavities formed inside the element and are closed by a sealing plate in the region of the end of the element containing the octagonal pins.

For easier connections, the ribs are formed with an outwardly decreasing cross-section or / and the grooves have an inwardly decreasing cross-section, and if the sockets have an inwardly-decreasing cross-section and / or an outwardly-decreasing cross-section of the pins.

According to a further feature of the invention, when the element is used as a slab element, one or more reinforcing steel reinforcing bars with one or more reinforcing steel bars, preferably perpendicular to the longitudinal geometric center axes of the nests and pins, are integrated into the element and extend laterally from the ribs. contain; in this case, it is advantageous for the reinforcing steel legs to have bent ends and the rib height to extend to about half.

In another embodiment, the nests are regular hexagons and the pins that fit into them are circular in cross-section, the latter having the same or substantially the same diameter as the regular hexagon.

The remaining crown shuttering element of the present invention is preferably used in combination with the manual masonry and flooring elements described above. The crown-forming element consists of having perpendicular stems and one end having perpendicular ribs, preferably cylindrical or tapered, and having perpendicular ribs connecting the anchors, preferably along the intersections of the square mesh. , such that the lateral distance of the longitudinal geometric pivot axes passing through the intersections of the grid is 1/4 of the nominal element width.

Both the manual masonry and slab elements and the remaining crown formwork elements can be made of lightweight concrete such as perlite.

The invention will now be further understood from the accompanying drawings

EN 202 614 Β, which describes one embodiment of the masonry and ceiling element, the remaining formwork and the possibility of assembling the elements. In the drawings, Fig. 1 is an axonometric view of the masonry and slab element;

Figure 2 is a plan view of the masonry and ceiling element of Figure 1;

Figure 3 is a bottom view of the element of Figure 1; Figure 4 is a sectional view of the masonry and ceiling element taken along line A-A in Figure 2;

Fig. 5 is a view showing a line 1-4 of Figs. Fig. 2A is a slab element shown in its installed position;

Figure 6 is an axonometric view of a residual corona formwork member;

1-4 in Fig. 7; FIG.

Fig. 8 illustrates the manner in which a wall corner is formed in Figs. FIG.

Figure 9 is an axonometric view of a wall connection node;

Figure 10 shows the design of the upper end of the wall;

all. FIG. 4A is a view showing a way of connecting a raised wall made of the elements of the invention and a slab made using the elements;

Figure 12 illustrates a solution for fitting a door and window structure to a wall made of elements according to the invention;

Figure 13 illustrates a preferred way of storing and transporting elements on a pallet;

Figure 14 is a front view of the stack of Figure 13.

As shown in FIGS. 1 to 5, a hand-masonry and ceiling element according to the invention (hereinafter referred to as "20 elements") is a T-shaped body having a length a, a width b and a height m ₂ (Fig. 1). The element 20 may be made of lightweight concrete such as perlite concrete, having a size of 60 cm, b of 30 cm, and our size ("useful" height) of 30 cm ₂ (total or structural height) 34 cm. The correlation Ab = - whatever the specific dimensions involved - must always exist, while the value of mi, m ₂ is arbitrary within practical limits and functionally, for the purposes of the invention, does not depend on that dimension. The stems of the element 20 are designated by reference numerals 1 and 2 by their perpendicular ribs.

The two opposite surfaces of the element 20, the upper surface and the lower surface of which are mounted in the wall, are arranged in a sectioned manner to allow a dry groove-like connection of the superimposed elements.

One is the one shown in Figures 1-4. In Figures 1 to 4, the upper surface comprises octagonal pins 3 separated by a slot 4 and a slot 8 s (Figs. 1 and 2). The pins 3 extend / spaced over the bottom of the slots 8 (Figures 1 and 4). The nest 4 extends into the cavities 4a extending inside the element, which are closed at the other end by a closing plate 7 (bottom plate). The longitudinal axis of the pin 3 is denoted by x and the longitudinal axis of the cavities 4a is denoted by reference letter y.

In the plan view, the legs 1 of the T-shaped element 20 have both C 1 and C ₂ widths (Figures 1 and 2), and the rib 2 of length 2 also has C ₃ = ± · width, that is, extends 1 It stems from.

The adjacent longitudinal axes x are d = a apart, and d = o o is the distance between adjacent y axes. In other words, both the x-axis and the y-axis pass through the intersection points of a square.

Half pins 3a are provided along the edges of the element 20, and quarter pins 3b are located in the corner, and 8 grooves always protrude to the side; the nests 4 remain undivided.

In plan view, the hexagonal nests 4 are of width r (measured between two opposite sides). Four grooves 8 protrude from each nest 4, and the adjacent nests 4 are interconnected by such grooves 8 (Figures 1 and 2). The sockets 4 have a depth / depth of 20 mm.

The pins 5 (Figs. 1 and 4) protruding from the butt plate are cylindrical, have the same diameter r as the width r of the pockets 4 (see also Fig. 2), and have the same longitudinal geometric center axis as the y geometry of the pockets 4a. longitudinal axis, since the pins 5 must fit into the sockets 4 of another element. The adjacent cylindrical pins 5 are connected by ribs 6 of width; the ribs 6 thus have the same width as the grooves 8 (see fig

2). The overall length of the pins 5 is denoted by the letter g in FIG. 4 and extends / spacing over the ribs 6, i.e. to the same extent as the pockets 4 and the grooves 8 on the other opposing sheet. The pins 5 start from the closing plate 7. The ribs 6 may also have a height (e.g., 20 mm). Figures 2 and 3 show in particular that the pins 5 and the nests 4 and the grooves 8 and the ribs 6 overlap each other in plan view. In order to facilitate the alignment of the overlapping elements 20, it is desirable that the pins 5 are slightly conical and have a minimum diameter (tolerance) smaller than the width r of the pockets 4; and likewise, the width s of the grooves 8 should be slightly greater than the width of the ribs 6 (tolerance value).

The particular 60 x 30 x 34 element mentioned above contains twenty four cavities 4a, as many pins 5 and thirteen complete pins 3. The cavities make up about 30% of the 20 elements. The weight of the element (if made of peritone concrete) is about 300 kg / m ³ , the weight of the element (with a maximum moisture content of 15%) is 12.0 kg / m ³ and the compressive strength of the element is 40 kg / cm ³ . The element is antifreeze in the dry state, its surface is smooth and glossy; the element can be sawn, drilled, surface can be painted and wallpapered after finishing with cement-based material.

Preferably, the nests 4a and the grooves 8, or / and the pins 5 have a slightly expanding cross-section from the outside, or / and the pins 3 and 5 have a slightly decreasing cross-section from the inside to the outside. If the pins / height is already 20 mm and the pockets / grooves / depth is also 20 mm, the dimension change (cross-section)

(202614 Β decrease or widening) may be 1-1 mm on each side of the grooves and nests or around the circumference of the pins.

When the elements 20 are superimposed, the lower cylindrical pins 5 fit into the sockets 4 on the upper side surrounded by four pins 5, and a prehistorically dry connection is established between the individual elements. The alignment of adjacent elements 20 in a row is illustrated in FIG. Of course, in overlapping rows, it is expedient to apply the rules of brick joints when building a wall. The initial set of each element otherwise horizontally halved height of _1.2 m (1 in Figure 1 also)

It is expedient to apply the elements 20a which are applied to the foundation 9 with a smooth surface, with a layer of mortar 15 applied thereto; the elements of the second row are thus fitted with their cylindrical pins 5 into the sockets 4 of the lowest element row, i.e. there is already a dry connection between the first and second element series. The remainder of the half-sawed elements (having 5 cylindrical pins), as will be seen, can be used to parapet the openings of the door and window structures. (Of course, we can use prefabricated target elements as m _{I / z} height elements of the first row.)

After placing the starting row (Fig. 7), as mentioned above, the elements are assembled into a structural wall, the corner construction of which is illustrated in Fig. 8. It is advisable to start with two corners, in which case you need to carve up to two intermediate elements. Doors and windows can be omitted and retrofitted. Coffee design is recommended.

Figure 9 shows a way of connecting an intermediate structural wall II transverse to a main wall made of the elements according to the invention. According to this, for example, in every fourth row, two adjacent elements 35 are joined adjacent to each other by their legs 1, thereby creating a nest 10 facing the boundary space with a width b equal to the width of the rib 2.

II. to initiate an intermediate transverse tree, an element 40 'having one of its limbs 1 sawed is also inserted in every fourth row; the remaining leg 1 of this member extends into the interior of the space bordered by the main wall I, and the rib 2 fits into the nest 10. This element 20 'is then connected to the other element 20 as described above. These 20 'elements are shown in FIG. its cross-trees are securely attached to the outer wall 1.

After reaching the ceiling height, the ascending wall 21 is closed with the crown shuttering elements shown in FIG. (Fig. 10) 50 This crown-forming element all has perpendicular stems 12, 13 and the lower surface of the stalk 13 is provided with cylindrical pins 5 and ribs 8 of the same shape, size and distribution. Figs. Both sides 55 of the shaft 12 of the element 11 are smooth. The width b and the length of each element may be the same as in Figures 1-4. 5a, the longitudinal geometric pivot axes y are also spaced d, where d = ± b. ⁶⁰

In the next step, using the elements 20 according to the invention, the slab 22 is made. A support rack (not shown) is provided on which the slabs for forming the slab are placed. These elements, as shown in FIG. 9a differ only in that they contain one or more U-shaped reinforcing bars 23, which are concreted in the body of the element, but whose legs 23a are provided with hooks 24 at their ends perpendicular to their surfaces. , they extend upwardly from the element (when the element 20 is mounted) and extend parallel to the rib 2 at a distance l from its lateral surfaces and extend to the height k of the surface of the element. Where the legs 23a of the insert 23 extend from the surface of the element 20; in the latter, cup-shaped bracing members 27 are concreted.

The slab 22 (Fig. 11) is constructed from the elements 20 so that their surfaces having pins 5 and 4 are not located at the bottom or at the top (Figs. 1-4), but on the sides in two opposite vertical planes, i.e. When the elements 20 are placed side by side, the pins of one element 20 always fit into the nests 4 of the other element 20 from the side. All. As shown in FIG. 5a, longitudinally open upper cavities 26 are formed between the two rows of elements 20 and also longitudinally open cavities 25 between the ridge shuttering rows 21 and the outermost rows 20 into which the reinforcing bars 23a of FIG. 5 extend. In the cavities 25.26, a beam assembly (not shown) is provided which engages with the stems 23a so that, after filling the cavities 25.26 with monolithic concrete and solidifying the concrete, a cooperatively cooperating connection is established between the members 20 and 11 , the former obviously forming the remaining formwork of the latter.

In the case of a multi-storey building, the operations detailed above are carried out at each level, as appropriate.

The windows 26 can be placed in the walls 21 as shown in Figure 12; inserting auxiliary elements in the coffee by inserting 28 auxiliary elements

The elements 20 and the crown shuttering elements 11 can be cut practically anywhere, however, it is preferable that the cutting always takes place in the axis of the grooves 8 (Figures 1-4) which are in line.

Figures 13 and 14 show that the storage and transport of the elements 20 on the pallet 30 can be performed with no gaps and thus with optimum efficiency.

The advantage of the invention is that it allows practically one type of element to construct walls and ceilings in heat-insulated form without the use of intermediate mortar layers, and with an additional residual formwork element, it is possible to construct the formwork without formwork. The slab does not require formwork either, as the elements serve as permanent formwork for monolithic reinforced concrete slabs. The variability of the elements is very high, it offers the possibility to create all cornering and intermediate bracket connections and there is practically no or minimal carving of the elements. The stability of the wall structure and the required heat-insulating properties are also ensured by dry connections only. Elements intended for slab construction can be manufactured in the same template as the wall elements, since they differ only in the protruding iron inserts. The elements according to the invention have a very wide range of applications: they can be used for both external and internal structural walls, but

EN 202 614 Β can be used for the construction of infill walls of framed buildings; tunnel formwork for molded structures for tunnel sealing; for the construction of structures that meet increased thermal requirements; for covering short and medium span spaces, on-site cast iron reinforced concrete slabs, etc. It is to be emphasized that crane is not required for the execution of the elements according to the invention - they are particularly advantageous in private construction, but due to the minimal need for labor, construction is advantageous in all areas.

The invention is, of course, not limited to the embodiments detailed above, but may be practiced in many ways within the scope of the claims.

Claims (14)

1. Hand masonry and slab elements, characterized in that, when in the wall-mounted position in the top view and in the slab-mounted position in the side view, the length (Ci) and width (C2) of their T-shaped legs (1) are 1/4 of the total nominal length (a) , the length of its rib (2) (bj is 1/2 of the total nominal length (a) and its width (C ₃ ) is 1/4; nests (4) in the region of one of the T-shaped surfaces, and in the region of the other T-shaped surface there are pins (5) which fit into the nests (4) of the respective other element (20), the nests (4) and the pins (5) having common longitudinal geometric center axes (y) (Figures 1-5). . Element according to Claim 1, characterized in that the longitudinal geometric center axes (y) pass through the intersections of a geometric square mesh constructed on a spherical surface, the distance (d) of the intersection points being one-eighth of the total nominal element length (Figure 2). Element according to Claim 1 or 2, characterized in that the sockets (4) have a regular polygon, preferably a regular octagon, a rectangle or a hexagon, or a circular shape in top or side view, and the pins (5) are cylindrical or truncated cones. 1-4 (Figures 1-4). 4. Element according to one of Claims 1 to 4, characterized in that the nests (4) are delimited by four, four or four octagonal pins (3) in top and side views respectively, and grooves with a perpendicular axis extending between adjacent octagonal pins (3). (8) with ribs (6) of perpendicular axis extending between cylindrical or conical pins (5) on the other side, the longitudinal geometric central axes (x) passing through the octagonal pins (3) passing through the intersections of the square meshes with the distance (d) of the intersections being 1/8 of the total nominal length (a) and these longitudinal geometric center axes (x) being parallel to the longitudinal center axes (y) of the pins (5) (Figures 1-4). ). 5. An element according to claim 4, characterized in that the grooves (8) and the ribs (6) have the same width (f) and preferably their depth (f) or height ()), or substantially the same (1-4). figures). 6. Element according to any one of claims 1 to 3, characterized in that the sockets (4) extend in elongated cavities (4a) formed inside the element (20) and in the region of the end of the element (20) containing the octagonal pins (5). (7) (Figure 4). 7. Element according to any one of claims 1 to 4, characterized in that the element (20) has pins (3a) in the circumferential region of its octagonal pins (3) and a quarter pins (3b) in the corners thereof and the grooves (8) therebetween (Figures 1 and 4). 8. Element according to any one of claims 1 to 4, characterized in that the ribs (6) are formed with an outwardly decreasing cross section or / and the caterpillars (8) are formed with an inwardly decreasing cross section. 9. Element according to any one of claims 1 to 4, characterized in that the nests (4) have an inwardly decreasing cross-section and / or the pins (5) which fit into the nests (4) have an outwardly decreasing cross-section. 10. Element according to any one of claims 1 to 3, characterized in that when used as a slab element, one or more elements (1) built into the element (20) and on its sides (2) are laterally spaced from the rib (2) of the element (20). 1) a concrete reinforcing bar (23) having protruding, preferably protruding, preferably perpendicular to the longitudinal central axes (y) of the nests (4) and pins (5). (Figure 5) Element according to claim 10, characterized in that the reinforcing steel legs (23a) have bent ends (24) and extend the rib (2) to a height (c) of about half. (Figure 5) 12. Element according to one of Claims 1 to 3, characterized in that the sockets (4) are regular hexagons and the pins (4) which fit into them are circular in cross-section and the latter (r) has the same or substantially the same diameter as the regular hexagon (2). and Figure 3). 13. Remnant crown shuttering member, in particular from 1 to 12; For building structures using the elements according to any one of claims 1 to 4, characterized in that they have perpendicular legs (12,13) and on the outside of one of the legs (13), preferably cylindrical or truncated pins (5) and connecting pins (5). having lower height perpendicular ribs (6), wherein the pin (5) is preferably distributed according to the intersections of the square mesh such that the lateral distance (y) of the longitudinal geometric pin axes (b) passing through the intersections of the square mesh (b) 4 (Figure 6). 14. Element according to any one of claims 1 to 4, characterized in that the elements (20, 11) are made of lightweight concrete, preferably of perlite concrete.