EP1803865A1 - Precision building block - Google Patents

Abstract

Concrete block has shell made of artificial stone consisting of first, lower and second, upper layer supporting surfaces, front and also surrounding surfaces, which together form essentially a cube. When the block blank is produced, a channel is formed to receive a load-bearing body. First and second surfaces are each respectively formed on a even plane. The first lower surface runs slightly conically that is obliquely to the second lower surface. The channel is slightly conically shaped and the inclination runs oppposed to the supporting surfaces.

Description

The invention relates to a block as well as a trowel produced using such blocks.

From the construction practice the production of plan masonry in the so-called thin bed process with a joint thickness of 1 to 3 mm is known. When creating such a masonry masonry z. As calcium silicate blocks used with small dimensional tolerances, which make it possible to comply with said low joint thickness of 1 to 3 mm. Such sand-lime bricks have a lower and an upper bearing surface and peripheral surfaces, wherein the bearing surfaces are parallel to each other and the peripheral surfaces to each other due to production conical.

For bridging masonry openings, in particular door and window openings, falls are used. Such falls are for example made of U-shaped shells of the material of the masonry (U-stone), and it is known in practice to fill the formations (gutters) with reinforced concrete, so as to obtain a resilient to bending fall.

A fall in which a cross-sectionally U-shaped shell is filled with concrete, for example, from DE 200 03 280 01 known. Another lintel with a cross-sectionally U-shaped shell is made DE 32 43 976 Al known.

In addition, for aerated concrete masonry from the DE 20 2004 010 687 U1 a proposal is known to introduce a continuous core hole in finished cured aerated concrete blocks, Aligning several aerated concrete blocks with their core holes in alignment with each other and pour out the channel formed by the core holes together with a reinforcement placed therein with concrete.

As a result of the manufacturing process, the falls made from U-stones have an uneven upper bearing surface due to the concrete poured into it. This means that at this point the mortar joint can not be performed in the thin-bed process. However, the provision of normal mortar on a construction site that creates masonry masonry, an additional logistical, technical and financial problem.

The invention has for its object to provide a planum available, which facilitates the creation of a masonry masonry in the thin bed process in the field of masonry openings.

The solution of this object is achieved according to the invention with the features of claims 1 and 6, respectively.

According to the invention, a planer is provided with an envelope made of artificial stone, which has an enveloping body having both a first, lower bearing surface and a second upper bearing surface and peripheral surfaces, which together essentially describe a cuboid, wherein further in the enveloping body by shaping formed in the production of a planar blank, a channel which extends substantially parallel to the bearing surfaces and is designed to receive a structure in the manner of a beam or a load-bearing body. By providing the storage areas through the enveloping body ensures that the joints of a masonry created with such a planer have a more uniform thickness, whereby the mortar application is facilitated during the masonry and safer and permanently crack-free joints result, even in the Dünnbettverfahren can be created. Since the bearing surfaces are more uniform than bearing surfaces which are available through a cast concrete, grout spreads even more evenly on these bearing surfaces, and there is also no risk that a patch stone comes to rest under displacement of all grout on a projection of concrete in which case the gap would be interrupted in such a case. This is especially true if the first and the second bearing surface are each designed plane.

According to the invention, a first, z. B. the lower bearing surface slightly conical to a second, z. B. upper bearing surface, further wherein the introduced in the enveloping body by shaping a planer blank channel is also slightly conical and has an opposite to the bearing surfaces extending inclination. Such a block can be produced particularly advantageously by compression molding in a stone press, without the risk that the Planstein blank can not be formed after pressing. Preferably, both bearing surfaces are slightly conical or inclined in the same direction.

With this configuration, the preferred embodiment of the invention intentionally turns away from the known production methods in which mutually parallel bearing surfaces are already produced when the blank is being produced. Although the conicity is very small and not important from the viewpoint of construction technology and the processor, it is a valuable advantage for the production of the tiles, as the amount of rejects in the production can be so effectively reduced. With the simultaneous design of a conical channel, the requirement is created to connect several blocks together to form a resilient to bending device, with which wall openings can be safely bridged.

Despite the abandonment of mathematically parallel storage surfaces created by using the inventive blocks in the thin bed process joints are less vulnerable to cracks, as joints known masonry using poured shells, since the bearing surfaces have a defined by the shape of the blank geometry.

A preferred material for the envelope is sand-lime brick, since this has good static and acoustic properties.

An alternatively preferred material is clay material, which can be processed by extrusion molding and by a subsequent firing process, whereby even in the production of parallel bearing surfaces can be produced, which in turn serves to form a uniform, thin joint. In contrast to known clay bricks is dispensed with the formation of vertical channels.

The production of the circumscribed by Stein envelope by pressing already in the production of the blank has over the drilling another valuable advantage. So it is possible to make the cross section of the future reinforced concrete beam so that tensile and compressive zones are reinforced, but otherwise material can be saved. This optimized shaping takes place in one operation without additional effort in production and depends only on the shape of the selected mandrel or the die. The production of two or more recesses in the stone is possible without significant additional effort.

The advantages of the invention are also evident in a tumb-lintel according to claim 6, which consists of at least a first and a second block according to one of claims 1 to 5, wherein the blocks are arranged in such a line, that the channels of the blocks are aligned with each other and filled with a concrete mixture. For a tarmac fall therefore independent protection is claimed.

In a preferred embodiment of the tine fall according to the invention results in the formation of a sawtooth-like inner wall of the stone (channel), which in addition to the non-positive connection between reinforced concrete and sand-lime brick still results in a positive connection. This form-fit causes an improved load transfer from the masonry in the force-bearing reinforced concrete beams of the fall.

A special increase in strength can be achieved if the reinforcement contained in the load-bearing reinforced concrete beam is prestressed.

Further advantageous embodiments and modifications of the invention will become apparent from the dependent claims and from the description in conjunction with the drawings.

• Fig. 1 einen Planstein gemäß einer ersten bevorzugten Ausführungsform der Erfindung aus Kalksandstein im Schnitt,
• Fig. 2 den Planstein in Fig. 1 in einem Schnitt gemäß der Linie II-II,
• Fig. 3-3d Ansichten auf die Stirnseiten weiterer bevorzugter Ausführungsformen erfindungsgemäßer Plansteine,
• Fig. 4 einen Plansteinsturz gemäß einer bevorzugten ersten Ausführungsform der Erfindung, wobei der Plansteinsturz geschnitten dargestellt ist,
• Fig. 5 einen Plansteinsturz gemäß einer bevorzugten zweiten Ausführungsform der Erfindung im Mauerwerksverbund, wobei der Plansteinsturz geschnitten dargestellt ist,
• Fig. 6 einen Schnitt durch eine weitere Ausführungsform eines erfindungsgemäßen Plansteins,
• Fig. 7 eine perspektivische, teilweise geschnittene Darstellung zweier erfindungsgemäßer Plansteinstürze zur Verdeutlichung der Herstellung dieser Stürze und
• Fig. 8 einen Abstandshalter zur Herstellung erfindungsgemäßer Plansteinstürze.

Show it:

• 1 is a plan view of a first preferred embodiment of the invention of sand-lime brick in section,
• 2 shows the plan in Fig. 1 in a section along the line II-II,
• FIGS. 3-3d are views of the end faces of further preferred embodiments of planers according to the invention;
• Fig. 4 is a tumble lintel according to a preferred first embodiment of the invention, wherein the tumble lintel is shown cut,
• 5 shows a tumble lintel according to a preferred second embodiment of the invention in the masonry composite, wherein the tumb lintel is shown in section,
• 6 shows a section through a further embodiment of a planform according to the invention,
• 7 is a perspective, partially cutaway view of two inventive rockfall lintels to illustrate the production of these falls and
• Fig. 8 shows a spacer for the production Plansteinstürze invention.

The plano 100 shown in Fig. 1 according to a preferred first embodiment of the invention comprises an enveloping body 102 which consists of sand-lime brick. On this enveloping body 102, a first lower bearing surface 104, a second upper bearing surface 106 and peripheral surfaces 108, 110, 112, 114 are formed, wherein the first lower bearing surface 104, the second upper bearing surface 106 and the peripheral surfaces 112, 114 are conical to each other. This conicity is chosen so that the enveloping body 102 can be molded out of a mold safely in the production of the corresponding envelope body blank, but the taper is so small that it is negligible from the viewpoint of construction technology and the processor. In the figures, namely in Fig. 1, 2, 4 and 5, the taper is shown oversubscribed to illustrate the principle.

In the enveloping body 102, a channel 116 is formed by shaping during the production of the blank blank, which is located in the Extends substantially parallel to the bearing surfaces 104, 106 and the wall surface 118 is conical. The inclination of the wall surface 118 is reversed with respect to the inclination of the first lower bearing surface 104, the second upper bearing surface 106 and the peripheral surfaces 112, 114, respectively.

Planar 100 shown in FIGS. 1 and 2 is preferably manufactured in lengths of 123 mm, 248 mm and 500 mm, the length being determined in the direction of the double arrow L between the peripheral surfaces 108 and 110. The height of the block 100 measured in the direction of the double arrow H is in the example described preferably at the one peripheral surface 108 113 mm and at the opposite peripheral side 110 113 mm + 1/10 mm. From the heights of the stones processed in the plan masonry, the further preferred dimensions of the lintel height are 123 mm and 248 mm.

In the case of a 248-gauge block, the height of the face on one of the opposite sides is 108 and 110, 113 mm and 113 mm + 2/10 mm, and more preferably 113 mm and 113 mm, respectively, for a 500 mm long block + 5/10 mm. This applies analogously to the likewise preferred stone heights of 123 mm and 248 mm.

Measured as wall thickness between the peripheral surfaces 112, 114 in the direction of the double arrow D (FIG. 2), the following dimensions are preferred: 90 mm, 100 mm, 115 mm, 150 mm, 175 mm, 190 mm, 200 mm, 214 mm, 240 mm , 253 mm, 300 mm and 365 mm. As with the height, a taper is provided depending on the length of the block of + 1/10 mm, + 2/10 mm or + 5/10 mm.

The channel 116 of the block 100 in Figs. 1 and 2 is designed frusto-conical, wherein the diameter difference of the cross-sectional areas of the channel on the peripheral surface 108 to the peripheral surface 110 at a length of the stone of 123 mm 1/10 mm, with a length of 248 mm 2/10 mm and with a length of 500 mm 5/10 mm. This conicity is formed in a further preferred embodiment stronger in order to improve the load transfer from the wall.

FIGS. 3 a to 3d show further preferred embodiments of a block, wherein these blocks 200, 300, 400, 500 differ from the block 100 according to the first embodiment only by the contouring of the respective channel 216, 316, 416, 516.

Since a collapsed lintel has a pressure or a tension zone when installed, the channels 216, 316, 416, 516 are designed so that the channels 216, 316, 416, 516 have the largest possible volume for receiving a concrete reinforcement in the region of the pressure zone exhibit.

Furthermore, the position of a steel reinforcement 220, 320, 420, 520 is already illustrated in FIGS. 3 a to 3 d, wherein the channels 216, 316, 416, 516 are each designed so that the steel reinforcement 220 can be positioned as far as possible from the neutral fiber is to obtain the largest possible effect with the steel reinforcement 220, 320, 420, 520. This is possible with acceptable effort in asymmetric channel design, but not in a round bore.

4 shows a tarmac lintel 150 according to a first preferred embodiment, which consists of five face stones 100 according to a first embodiment, wherein the tiles 100 are aligned in such a way that a continuous overall channel 152 is formed, which in Fig. 4 with a concrete reinforcement is poured out. The concrete reinforcement is a load-bearing body in the sense of claim 1. In the concrete reinforcement a steel reinforcement 154 is embedded, with an all-round overlap - also on the end faces 156, 158 of the tumble lintel of 25 mm results. The individual blocks 100 are also aligned with each other so that due to the assignment of narrow side to broad side of the over-drawn in Fig. 4 illustrated step contour results in which also results in a positive locking of concrete reinforcement and block 100.

In Fig. 5, a second embodiment of a tumble 250 is shown, this tumble 250 consists of four paving stones 100 according to the first embodiment. The blocks 100 are each set with their narrow sides and their broad sides against each other so that a continuous channel 252 is formed, which is filled with reinforced concrete.

Fig. 6 shows a brick lintel in a section which also corresponds approximately to an end view. Here you can see two load-bearing reinforced concrete beams 616 with reinforcement 620 and three air-filled chambers 640 for heat insulation, the latter can also be filled with insulating material.

Fig. 7 is used to illustrate the production of a tine lintel 350 according to the invention, wherein the tilestone 350 a variant of a bullet 100 according to the first embodiment is used in which there are on the front sides of the block 700 bevels 730, which merely to simplify the presentation are omitted in the respective uppermost or lowermost block 700 in the drawing. Incidentally, the tiles 700 correspond to the plano 100 according to the first embodiment. In a further preferred embodiment, these chamfers are found only on one side of the blocks.

For the production of the tufa lintel 350 from sand-lime brick are first from a lime-sand-water mixture by molding made in a stone press Planstein blanks, which are then cured in an autoclave.

After curing, the resulting blocks are stacked like a tower until the length of the desired tilestone lintel is reached. In order to achieve a rational production and to avoid overturning individual blocks, a bunch of pitfalls is made simultaneously, which is illustrated by the arrangement of two tilts in Fig. 7.

After the turrets 700 have been piled up, a steel reinforcement is introduced into the overall channel formed from the individual channels 716, to the lateral support of which various spacers 760, one of which is shown in FIG. 8, are used. The spacers 760 serve to ensure a uniform, all-round coverage of the reinforcing steel 754 with concrete, said cover is at least 20 mm, preferably 30 mm. Since it is also desired to cover the reinforcing steel 754 with concrete at the end faces, an end-face support sleeve 762 is used according to one embodiment. As an alternative to using a support sleeve, the reinforcing steel can also be held in position during production by means of a positioning device.

After introducing the steel reinforcement, which preferably consists of a round steel with a diameter of 8-20 mm, preferably 10 mm, concrete is poured into the channel 716.

The concrete 752, which is filled in liquid from above, is adjusted so that a complete filling of the entire channel 716 is achieved. In this case, the concrete also flows into the annular chambers formed by the chamfers 730, so that the blocks 700 made of lime-sandstone are virtually mortared on the front side. In addition, the annular chambers in the In the region of the joints of the tiles 700 a higher coverage of the reinforcing steel 754, whereby an improved corrosion protection is given. The chamfers should therefore have in the direction of the length of the tiles 700 at least a length of 2 to 10 mm, preferably 8 mm per stone and chamfer.

The above-described production of tilts 350 according to the invention can also be referred to as production with lost formwork. In this production, the problem of shrinkage of the concrete 752 is preferably counteracted by shaking during the filling of the concrete 752. Other suitable measures to counteract excessive shrinkage are the use of swelling cement or self-compacting concrete.

As an alternative to the production of slab lintels according to the invention by means of permanent shuttering, the use of prefabricated load-bearing beams is also suitable for producing slab lintels according to the invention, this being possible in particular in the case of paving slabs with exactly circular-cylindrical channels within the scope of the invention.

Claims (11)

Planar, comprising an artificial stone enveloping body (102), the enveloping body (102) having a first, lower bearing surface (104) and a second, upper bearing surface (106) and end surfaces (108, 110) and peripheral surfaces (112, 114), which together essentially describe a cuboid, wherein further in the enveloping body (102) by shaping during the production of a planbstone blank, a channel (116) is formed, which is adapted to receive a load-bearing body, wherein the first and the second bearing surface ( 104, 106) are each designed plane and the one z. B. first, lower bearing surface (104) to the second, z. B. upper bearing surface (106) is slightly conical or oblique, and that the channel (116) is slightly conical, with its inclination to the bearing surfaces (104, 106) is opposite. Planar according to claim 1, characterized in that both bearing surfaces (104, 106) extend conically or obliquely in the same direction. Planar according to claim 2, characterized in that the peripheral surfaces (112, 114) extend conically or obliquely in the same direction. Planar according to one of claims 1 to 3, characterized in that the enveloping body (102) consists of lime sandstone. Planar according to one of claims 1 or 2, characterized in that the enveloping body (602) consists of a clay material. Planar according to one of claims 1 to 5, characterized in that the channel (216, 316, 416, 516, 616) to the neutral chamfer asymmetrically arranged and / or asymmetrically contoured to accommodate the largest possible volume of concrete reinforcement in the pressure zone , Planar according to one of claims 1 to 6, characterized in that chamfers (730) are formed on at least one end face, preferably on both end faces. A lintel made of at least a first and a second block (100) according to any one of claims 1 to 7, wherein the blocks (100) are lined up in such a way that the channels of the blocks (100) are aligned, the channels one or more reinforced concrete beams contain. Tail lintel according to claim 8, characterized in that the reinforcement is prestressed. Tail lintel according to claim 8 or 9, characterized in that the reinforcement consists of structural steel and on all sides has a concrete cover of at least 20 mm, preferably 30 to 40 mm. Tail lintel according to one of claims 8 to 10, characterized in that the reinforcement is positioned by means of star-shaped spacers (760) prior to the introduction of the concrete.

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