EP0010238A1 - Building block for tall buildings with recesses for inserting insulating material, and process for the manufacture and use of such a building block - Google Patents

Abstract

Recesses (1, 2) which run the whole length of the block are formed in it for the insertion of insulating slabs (4). To improve thermal insulation, particularly at the abutting faces of the blocks, the insulating slabs (4) are arranged in such a way that they can be removed and moved or displaced in the longitudinal direction of the block in the recesses (1, 2), which, for this purpose, are wider at the outside of the block than the insulating slabs (4) but hold the insulating slabs (4) firmly in the inside of the blocks. In production of the blocks, shaping in the vertically upright position is facilitated by the fact that, according to a preferred embodiment of the block, at least some of the faces (24) of the block which extend in the longitudinal direction are inclined to produce a taper of the cross-section of the block counter to the longitudinal direction. <IMAGE>

Description

The invention relates to assembly blocks for building construction with recesses for inserting insulating material for thermal insulation and to a method for producing such assembly blocks. The invention is also concerned with the appropriate use of the blocks.

Hollow blocks with pockets are known (DE-PS 1 946 869; DE-OS 2 508 151 or DE-OS 2 553 123), into which comb-shaped insulating plates, e.g. in the form of rigid foam pieces to improve thermal insulation. It is unfavorable for the thermal insulation to regularly interrupt the insulating plate inserts on the stone crosspieces due to the construction (in the longitudinal direction between the individual plate parts), which creates so-called cold bridges. The insulation is also usually interrupted on the abutting surfaces of the stones. In addition, the introduction of the preformed rigid foam pieces in the known mounting blocks is associated with considerable effort.

Wall blocks are also known which contain two slot-like recesses filled with insulating material, which can penetrate the entire stone horizontally parallel to the direction of the wall and which extend over a considerable vertical distance from the top and bottom into the stone (BE-PS 710 667). In these blocks, too, an interruption in the thermal insulation on the abutting surfaces of the stones is practically unavoidable.

Furthermore, the production of the known wall blocks is associated with considerable effort, especially if stones of different lengths or designs are desired in accordance with the requirements for construction. To produce assembly blocks that should have an exact stone height in the edge area, it was previously customary to manufacture the stones on the vibrating machine in the horizontal position corresponding to their later laying, and the height deviations that were unavoidable due to the vibrating process by milling the bearing surfaces, e.g. balance with a machine according to DE-PS 1 427 712. Apart from the effort required for this, the horizontally lying stones take up a lot of space on the base of the vibrating machine.

The invention, as characterized in the claims, solves the problem of creating easily and quickly relocated mounting blocks with integrated thermal insulation, which enable almost uninterrupted thermal insulation and can be produced with less effort than before.

The assembly block described here has the advantage, among other things, that the insulating plates in all areas of the wall (both in the stone material itself and in the vertical and horizontal mortar joints) can achieve consistently high thermal insulation and there are no cold bridges. Thanks to the possibility of being able to move the insulating plates horizontally in the recesses, this advantage also applies to walls with non-standard, i.e. more or less any, longitudinal dimensions. The movability of the insulation panels also allows them to be or door openings are preferred so that windproof heat insulation takes place. Small cavities that may arise contain standing air, which is known to provide similar thermal insulation to the insulating inserts themselves. The horizontal, continuous arrangement of the insulating plates means that the assembly blocks can be produced both on vibrating machines with vertical production and on extrusion presses with horizontal production.

The assembly block described here is preferably to be manufactured standing on its abutting surface. Due to the conically tapering cross-sectional shape of a preferred embodiment of the stone, the removal of the shape used for production, which has correspondingly inclined inner surfaces, is facilitated by the freshly shaken stone, since the unavoidable frictional forces, especially with larger ones, on a sheet a plurality (for example, 12 or 16) of stone-forming shapes can be significantly reduced. This "vertical production" in turn has the advantage that the tolerances of the stone height, i.e. a precise spacing of the plane-parallel bearing surfaces (provided only at the edge regions of the stone) can be maintained without the previously required complex milling process. Only these contact surfaces, which touch without mortar, determine the position of the stones during dry installation. Furthermore, in the case of vertical production, significantly more blocks can be accommodated in a mold on a common sheet than in the previously usual horizontal production, e.g. on a 110 X 140 cm sheet 20 blocks instead of 8 blocks of usual size. The shape itself requires less effort than before. Another advantage is that four different types of stone with the same cross-sectional profile but different stone lengths can be produced with a single block shape. All that is required is to change the amount of concrete and the depth of impression of the stamp on the production machine.

• Figur 1 eine isometrische Darstellung eines Montageblockes mit eingesetzten Isolierplatten;
• Figur 2 einen Querschnitt durch den Montageblock nach Figur 1 (längs der EbeneII-IIin Figur 3), wobei die Ausbildung der Lagerfuge ersichtlich ist;
• Figur 3 eine Draufsicht auf den Montageblock, wobei die Stoßfugenausbildung ersichtlich ist;
• Figur 4 eine Draufsicht eines durchtrennbaren Montageblockes (Trennstein);
• Figur 5 eine Draufsicht eines Wandstückes aus den Montageblöcken mit einer Innenwandeinbindung;
• Figur 6 einen Querschnitt des Wandstückes der Figur 5 in der Ebene VH-VI mit der Innenwandeinbindung;
• Figur 7 eine Draufsicht des Trennsteines gemäß Figur 4 mit einer vertikalen Schlitzanordnung;
• Figur 8 einen Querschnitt durch den Montageblock gemäß einer abgewandelten Ausführungsform;
• Figur 9 und 10 jeweils im Schnitt einen zur Herstellung eines Montageblockes der hier beschriebenen Art verwendbaren Formenstempel bzw. eine Steinform, in der eingefüllter Beton mit dem Stempel von oben verdichtet und der Stein auf die vorgesehene Länge gedrückt wird;
• Figur 11 den Querschnitt durch die auf einem Produktionsblech stehende Steinform gemäß Fig. 10;
• Figur 12 einen auf dem Produktionsblech stehenden entschalten Montageblock in Draufsicht;
• Figur 13 die Seitenansicht des entschalten Montageblocks;
• Figur 14 und 15 die zweite bzw. erste Mauerwerksschicht in Form eines Eckverbandes, wobei das Auftragen des Lager- und Stoßfugenmörtels gezeigt ist;
• Figur 16 und 17 Beispiele einer Wandgesteltung im sogenannten schleppenden Verband; und
• Figur 18 bis 21 einen Normalstein, einen Schlitzstein, einen 2/3-Stein bzw. einen 1/3-Stein jeweils in Draufsicht.

The invention is explained in more detail with reference to the drawing. Show it:

• Figure 1 is an isometric view of a mounting block with inserted insulating plates;
• Figure 2 shows a cross section through the mounting block of Figure 1 (longitudinal the level II-II in Figure 3), wherein the formation of the bed joint can be seen;
• Figure 3 is a plan view of the mounting block, the butt joint formation is visible;
• Figure 4 is a plan view of a severable mounting block (dividing stone);
• Figure 5 is a plan view of a wall piece from the mounting blocks with an inner wall binding;
• Figure 6 shows a cross section of the wall piece of Figure 5 in the plane VH-VI with the inner wall integration;
• FIG. 7 shows a top view of the dividing stone according to FIG. 4 with a vertical slot arrangement;
• Figure 8 shows a cross section through the mounting block according to a modified embodiment;
• FIGS. 9 and 10 each show, in section, a mold stamp which can be used to produce an assembly block of the type described here, or a stone mold in which filled concrete is compacted with the stamp from above and the stone is pressed to the intended length;
• FIG. 11 shows the cross section through the stone mold according to FIG. 10 standing on a production sheet;
• FIG. 12 is a top view of a disconnected assembly block standing on the production sheet;
• FIG. 13 shows the side view of the disengaged assembly block;
• FIGS. 14 and 15 the second or first masonry layer in the form of a corner bond, the application of the bearing and butt joint mortar being shown;
• Figures 16 and 17 examples of wall design in the so-called dragging association; and
• 18 to 21 a normal stone, a slit stone, a 2/3 stone or a 1/3 stone, each in a top view.

The mounting block shown in Figs. 1 and 2 has two horizontally in the longitudinal direction, i.e. parallel to a wall to be erected, the entire stone continuously penetrating recesses 1 or 2, of which the one recess 1 extends vertically downwards starting from the top of the stone at a given distance from the one side surface of the stone. The other recess 2 has the same given distance from the other side surface and extends vertically upwards starting from the underside of the stone. Insulation plates 4 such as e.g. rigid rigid foam panels used. The special mutual arrangement of the cutouts 1 and 2 or of the insulating plates 4 also allows the insulating plates 4 of the two layers to be aligned vertically when the blocks are also mutually laid in two vertically successive layers, as can be seen in FIG. 6. The respective panels touch each other on their end faces and thus interrupt a cold bridge on the entire, relatively large mortar joint.

The two recesses 1, 2 extend vertically beyond the center of the stone to such a depth that they overlap in the central region of the stone over a considerable vertical distance. This interrupts the horizontal "cold flow" in the central area of the stone or in any case forces it to take a larger route through the stone material, which is also insulating. The stone material can consist of pumice, leca, brick material, etc. The special mutual arrangement of the insulating plates 4 according to FIG. 2 and according to FIG. 6 also makes sense. With regard to the vapor pressure gradient which arises in every building due to the temperature differences and which practically always runs obliquely from the top downwards to the outside. With the described assembly block, the vapor diffusibility of the wall remains in everyone Get trap because the insulating plates 4 form a resistance, but the remaining insulating stone material has sufficient diffusion ability.

As can also be seen in FIG. 2, the cutouts 1, 2 taper conically from the top and bottom of the stone to the center of the stone, and at their inner end they are preferably dimensioned so narrow that the insulating plates 4 can be clamped there. If the insulating plates 4 are inserted into the recesses 1, 2 in the construction, which is facilitated by a width of the recesses at the outer end of which slightly exceeds the plate thickness, and the plates are then pressed lightly towards the center of the block, they are clamped by the conical taper. The described shape of the recesses also initially facilitates any horizontal displacement of the insulating plates 4 in their recesses in accordance with the particular needs of the building. For the subsequent clamping of the plates there are also beads 3 located on the side surfaces of the recesses 1, 2 e.g. in the form of vertical bead-like webs. The insulating plates are used so that they protrude laterally from their recess at one end and engage in an adjacent block when erecting a wall. Preferably, 1.2 insulating plates 4 with the same dimensions are used in the two recesses. In special cases, insulating plates with the length of several assembly blocks can also be used.

The cutouts 1, 2 are expediently approximately triangular in cross section at their inner end. This improves the static stability of the stone and also favors the flow of material when it is poured into the molds. The resulting cavities are not filled by the generally rectangular insulating plates 4, but they contain standing air, which also achieves an insulating effect and the "cold flow" is further diverted or extended. The triangular shape can also be modified up to an approximately semicircular cross section.

The assembly blocks shown in FIGS. 1 to 4 can be produced on normal production machines for hollow trestles, the horizontal recess 1 being produced by a mold core and the recess 2 by pulling a sword. The core and the sword are slightly conical towards the center of the stone in accordance with the shape of the recesses described. At the same time, the beads 3 mentioned can also be formed. The described arrangement of the recesses 1, 2 or the continuous insulating plates 4 also allows the use of stone production machines which, e.g. working in the brick industry in the strand process. The assembly block can be produced from a perforated stone material on an extrusion press, as shown in FIG. 8, the holes distributed over the entire stone cross-section ensuring even better thermal insulation, since the "cold flow" is further dissipated or interrupted. To accommodate the bedding mortar, a mortar bed 6 can be pressed in and shaken during production with a complaint plate. The webs 7 which remain here can first be produced to a height exceeding the desired stone height and, after the mounting block has hardened, machined plane-parallel with a special milling machine (e.g. according to DE-PS 1 427 712) and milled by a few millimeters.

However, the assembly blocks are preferably produced without milling in the manner explained in more detail below with reference to FIGS. 9-13. In addition, the invention can also be applied to assembly blocks which are produced in the region 10 without extremely precise height tolerances of the webs 7 and the support surfaces. Stone height tolerances are then compensated by applying the appropriate thickness of bedding mortar, which, however, requires the use of a cord and spirit level for each layer laid. The special insulating effect by the plates 4 is essentially retained in this case too; only in the area of the bed joints could smaller mortar areas become visible due to the stone height deviations.

In order to lighten the weight and as a grip hole, which facilitates the laying of the assembly block, there is a longitudinal recess 11 in the top or bottom of the stone. The longitudinal recess 11 also serves to accommodate mortar that may have been filled in too much, i.e. of the mortar bed 6. Furthermore, the mounting block at the four corners in the butt joints receives recesses 12 for receiving the butt joint mortar. The depth of these recesses 12 is such that superfluous bedding mortar can escape from the mortar bed 6 downwards.

FIG. 4 shows an assembly block which, in addition to the features already described, has a plurality of separating grooves 13. The separating grooves facilitate sawing or hitting the block on the building if special stones are required, e.g. those with vertical slots 19 according to FIG. 7 or stones for wall connections according to FIGS. 5 and 6. In the case of wall integration, a piece of insulating plate 14 which has been sawn out can be laterally reinserted, so that the thermal insulation is not interrupted.

As already mentioned, the insulating plates 4 according to FIGS. 3 and 4 can be moved horizontally according to the needs of the building, as indicated by the arrow 15. This is in contrast to known assembly blocks, which have crossbars in their recesses for holding the outer stone shell and thereby hold the insulating inserts, and to blocks whose insulating inserts consist of fillings which are not readily removable. When using the assembly blocks described here, these can be pulled sideways, for example when erecting a wall with an uneven length, in such a way that larger distances arise between the individual blocks, as shown in FIG. 3 at 16. In this case, too, both insulating plates 4 are pulled forward so that they engage in the next block and thus seal the butt joint with a high thermal insulation effect. Another possibility is to prefer the insulating plate 4 at the end of the wall or at the wall opening for a window or a door in such a way that it ensures sealing and simultaneous insulation, for example of the window or door frames, as shown in FIG. 5 at 17. The assembly block is mainly used for erection in front of external walls and should usually be laid in rows in a whole layer of stone. Because of the required stone height precision, the first layer of stone is placed cleanly and horizontally in mortar on a ceiling or foundation. At the butt joints, the individual assembly blocks are put together dry (without mortar), the insulating plates 4 engaging in the next assembly block. Then the bedding mortar is brought into the prepared mortar bed 6 of the entire row of stones and pulled off with a board over the webs 7. The next stone layer is simply laid on top of one another in a row laying with respect to the previous layer, the surface areas 10 being placed on the webs 7. Due to the dead weight of the assembly blocks, they are sufficiently pressed into the mortar bed 6 with the elevation 18 remaining between the areas 10. Possibly. superfluous mortar is pressed into the longitudinal recess 11 or into the recesses 12 of the butt joints. An alignment of each stone layer with a cord and spirit level is not necessary when using the milled (or according to FIGS. 9 to 13 precisely manufactured) assembly blocks, and the mortar bed of the bed joints is isolated and sealed from the outside by the webs 7. When the assembly blocks are laid alternately, the bearing mortar joints, which are otherwise susceptible to a "cold flow", are interrupted and insulated by the mutual contact of the insulating plates 4.

Experience has shown that most stone materials have to be plastered outside and inside for building physics reasons. With this plastering, the recess 12 of the butt joint is automatically mortared when the plaster is started or sprayed on. The time-consuming grouting of the joints by the bricklayer, as was previously required, eliminates the time-consuming and costly process.

For structural reasons, it is expedient to incorporate interior walls in accordance with FIGS. 5 and 6 in every second layer of dividing stones according to FIG. 4. The required bindings are sawn or knocked out of the dividing stones, and when using shell blocks, the filling concrete flows into them opening. Additional anchoring is possible by inserting structural steel. However, brick walls can also be integrated in this way.

As a rule, the insulating plates 4 are inserted into the assembly blocks during manufacture. However, it is also possible to supply the insulating plates 4 loosely and to have them used on construction sites. A particularly interesting possibility with regard to optimal insulation is to use insulating plates 4 in double height and e.g. to be used continuously when laying on the building, the mounting blocks of the next row being placed over the insulating plates 4 above. Such insulating plates 4 then avoid any interruption of the insulation in the area, the mortar bed 6.

The assembly blocks can be quickly installed in rows by specialists as well as laypersons, and by simply filling the bed joints with mortar and then pulling them off with a board, there is minimal effort and a considerable saving in time and material costs. This could largely remedy the current shortage of skilled workers.

=2,42 m 2 K/W bzw. k-0,38 W/m²K. Durch diesen sehr hohen Wärmedämmwert können hohe Energiekosten eingespart werden.Some of the advantages explained would obviously also apply in the event that only a single cutout in the manner of cutouts 1, 2 with only one insulating plate 4 is provided in the assembly block. Because of the much better thermal insulation, however, (at least) two insulating plates 4 and in particular their advantageous arrangement with respect to one another are preferred. If the assembly block with integrated thermal insulation is made from pumice concrete with a bulk density of 0.8 kg / dm ³ , the thermal insulation value is 1 /

= 2.42 m 2 K / W or k-0.38 W / m ² K. This very high thermal insulation value can save high energy costs.

The assembly block described below according to a preferred development largely corresponds to the one described above, that is to say it has plane-parallel lower and upper openings made to an exact stone height (arrow 25 in FIGS. 13 and 17) in the edge region of the stone bearing surfaces 20, 21 (FIGS. 1 and 13) and two recesses 1, 2 (FIG. 11) formed from the top and bottom of the stone for inserting insulating plates 4 (FIG. 14, etc.) for thermal insulation and 12), which in the longitudinal direction running parallel to the wall direction, ie parallel to the support surfaces and perpendicular to the abutting surfaces, normally penetrate the entire stone continuously.

As indicated in FIG. 12, however, all or at least the most important of the longitudinal surfaces 24 (FIGS. 11 to 13) lying generally perpendicular to the abutting surfaces, with the exception of the support surfaces 20, 21, are inclined towards the longitudinal direction in the sense of a tapering of the stone cross section. In FIG. 12, the two side surfaces 40 are inclined inwards and the inner walls 1 ′ of the recess 1 are inclined outwards, running from the bottom to the top. The angle of inclination can be less than 1 °. With a stone length of 37.5 cm, a deviation of 1 to 2 mm may be sufficient. The relatively small slope, in particular of the mortar bed 6 of the bed joint (FIG. 14), the longitudinal surfaces which determine the width of the support surfaces 20, 21, the cutouts 1 and 2 and the strips which protrude on the underside of the block (in FIG. 11 above) become without laying further compensated by the bedding mortar. The side surfaces 40 may possibly be less inclined or, if necessary, even run plane-parallel.

According to FIG. 1 ₂ , retaining strips 26 for the insulating plates 4 are integrally formed on the walls of the cutouts 1, _{2 which} are conically inclined towards one another and which run in the longitudinal direction with their edges facing the insulating plates parallel to one another and to the bearing surfaces 20, 21. The widening of the recesses 1 and 2 corresponding to the cross-sectional taper facilitates the insertion of the insulating plates 4, while the non-conical strips 26, which increasingly project relative to the walls 1 ′ of the recesses, facilitate a longitudinal displacement of the insulating plates with reliable holding in the transverse direction. With retaining strips arranged transversely to the longitudinal direction, the reverse is the case.

To produce these blocks, the mold 22 shown in FIG. 10 in the section plane XX of FIG. 11 is placed on a board or sheet 23 and filled with concrete 27, which is then loaded with the stamp 28 shown in FIG. 9 and inserted into the mold from above the desired length of stone is compacted. Simultaneously, a Stoßfugenausnehmung 35 (Figure 12) eingedrüc _K t of the stamp with a corresponding projection 38th The possible different stone lengths are shown in Figures 18 to 21. At 4 ', the recesses 1, 2 for the insulating plates 4 are formed.

According to FIGS. 20 and 21, in the blocks with 2/3 or 1/3 of the normal length at one end of the stone, the outer surface remains closed and the cutouts 1, 2 in the inside of the stone end so shortly before this outer surface that the remaining bottom 33 is used for Wear plaster on the end of a wall or pillar required thickness of e.g. 1 to 2 cm. These blocks usually serve as corner stones or end stones.

If a form forming a plurality of blocks is used, in addition to the three types of stone for a wall dressing in the same form, a small number, e.g. with 16 or 20 blocks two slit stones (Fig. 19) are also produced. For this purpose, the blocks in question are pressed in adjacent to their upper abutting surface, vertical knife-like steel cores 36, with which slots are formed which, if necessary, allow stone parts 37 to be cut off. The slots are pressed in at a point such that the separable stone parts 37 are located on one side of one block or on the opposite side of the other block, so that a "right" and a "left" slot stone are available. These slit stones are designed so that they can also be processed as a normal block without separation if no special blocks are required.

The shape used to manufacture the blocks can be at least partially smoothed on their surfaces by a coating. For example, chrome plating avoids Areas corresponding to the support surfaces 20, 21, especially when the shape is used for a long time. Deviations in the stone height from the nominal size. All surfaces of the mold that are at risk of wear are preferably chrome-plated or provided with another coating. The chrome plating also significantly increases the lubricity of the mold when it is lifted from the stone blank, ie it is easier to remove from the mold.

A particularly expedient and advantageous possibility of using the assembly blocks to form a corner assembly from two rows of blocks that meet at right angles, that is to say a wall corner, can be seen in FIGS. 15 and 14, which show the bottom, first stone layer of the wall or its second stone layer. As shown, a gap 30 penetrates the other block row over its entire cross section in the longitudinal direction of one row of blocks, abutting the abutting surface of the last block thereof, and a continuous insulating plate 31 is inserted into this gap. The gap 30 is located between the last normal block 41 and a block 39 forming the outer corner of the same block row, which has a smaller, namely 1/3 the length of the other blocks. This achieves perfect thermal insulation in the particularly vulnerable area of the corners of buildings; in particular, the usual signs of moisture are avoided, which are based on the fact that the outer surface exposed to the cold at a wall corner is much larger than the inner surface facing the heated interior. The short block 39, also shown in FIG. 21, is held at the corner by the bearing and butt joint mortar and bound in the transverse direction by the next stone layer. The insulating plate 31 is cut somewhat smaller as a plaster base and mortared at 32 in the outer area.

When roughly applying the bedding mortar in the mortar bed 6 with a shovel or trowel and when pulling off with the board 34, the butt joints in the recesses 35 are also mortared by lightly poking. With the dry installation of the wall, which is possible due to the precise stone height according to arrow 25 and the plane-parallel support surfaces 20, 21 of the block, an elastic and compensating mortar bed is nevertheless pulled in in a simple manner, thereby reducing the risk of cracks.

While stone lengths of e.g. 50 cm were usual, a relatively short stone length of e.g. 37.5 cm selected so that the laying weight of the stone is not too large and the pulling forces of the form remain small during stone production. This also gives a so-called "dragging bandage" according to FIGS. 16 and 17 with a 12.5 cm coverage of the butt joints, a grid dimension of 12.5 cm. To design walls, stones 1/3 (FIG. 21), 2/3 (FIG. 20) and 3/3 (FIG. 18) of the normal length are then required, which can be produced in a common mold 22, as has already been mentioned. Since 30 cm thick outer walls are preferred in residential construction for structural and structural reasons, within the framework of e.g. 12.5 cm a 1/3 stone is offset flush on the outside, creating a 5 cm wide cavity through the entire wall thickness in the form of the gap 30 in the manner explained above, which is filled with a 5 cm thick insulating plate 31. Instead of the "dragging dressing" shown, a central dressing is of course also possible.

The block 39 shown in Figure 21 with 1/3 of the normal length can not only be used for the particularly thermally insulating corner bandage according to Figures 14 and 15, but it can also stand on its butt surface (i.e. in its production position) for the bottom or top layer of stone a wall for the purpose of height compensation with good thermal insulation.

Claims (18)

1.Installation block for building construction, in particular with plane-parallel support surfaces made to an exact stone height in the edge area of the stone and with recesses formed in the stone for inserting insulation material for thermal insulation, which - in the longitudinal direction running parallel to the wall direction, the entire stone, if applicable with the exception of one end area, continuously extending from the bottom or top of the stone essentially parallel to the side surfaces of the stone up to more than half of its height, characterized in that the insulating material is prefabricated in the recesses (1, 2) (4) are used, which are displaceable in the horizontal longitudinal direction of the stone, and that the recesses (1, 2) on at least one outside of the stone are wider than the insulating plates (4), on the other hand in the stone interior to hold the insulating plates (4) are. 2. Mounting block according to claim 1, characterized in that the recesses (1,2) from the top or bottom of the stone to the center of the stone conically taper and are dimensioned at their inner end so that the insulating plates (4) can be clamped there . 3. Mounting block according to one of the preceding claims, characterized in that the recesses (1,2) are round or approximately triangular in cross-section at their inner end. 4. Mounting block according to one of the preceding claims, characterized in that there are beads (3) for clamping the insulating plates (4) on the side surfaces of the recesses (1,2). 5. Mounting block according to one of the preceding claims, characterized in that the butt joints on the stone corners have preformed recesses (12) which allow an automatic co-mortaring when starting plaster and have a sufficient depth for deriving unnecessary bedding mortar. 6. Mounting block according to one of the preceding claims, characterized in that in the bottom and / or top of the stone is used as a grip hole and for receiving superfluous bedding mortar longitudinal recess (11). 7. Mounting block according to one of the preceding claims, characterized in that the insulating plates (4) are inserted so that they protrude laterally from their recess (1, 2) at one end and engage in the next block of a wall. 8. Mounting block according to one of the preceding claims, characterized in that an insulating plate, the height of which is twice as large as the depth of the recesses (1,2) provided for inserting the insulating plate, with one half in one of the recesses (1,2 ) is inserted, while its other half projects vertically from the top and bottom of the stone. 9. Mounting block according to claim 1, characterized in that with the exception of the plane-parallel bearing surfaces (20,21) substantially all or at least some of the generally 'longitudinally extending surfaces (24) of the stone against the longitudinal direction in the sense of a taper of the stone cross-section are inclined. 10. Mounting block according to claim 9, characterized in that the in the longitudinal direction of the stone conically inclined walls (1 ') of the recesses (1,2) retaining strips (26) for the insulating plates (4) are formed, which in the longitudinal direction with their edges facing the insulating plates (4) run parallel to one another and to the support surfaces (20, 21). 11. Mounting block according to one of the preceding claims, characterized in that one of the outer surfaces of the stone perpendicular to the longitudinal direction is closed and the recesses (1, 2) in the interior of the stone end so shortly before this outer surface that the remaining floor (33) carries them of plaster required thickness. 12.Procedure for producing an assembly block for building construction, in particular with plane-parallel support surfaces made to an exact stone height in the edge region of the stone and with recesses formed in the stone for inserting insulating material for thermal insulation, which in the longitudinal direction running horizontally parallel to the wall direction Push through the stone at least partially, preferably according to claim 9, using a mold in which the stone is formed on a base, in particular with shaking, and which is then pulled off upwards, characterized in that the mold (22) with its in the longitudinal direction the axis of the stone is arranged vertically on the base (23). 13. The method according to claim 12, characterized in that with a stamp (28) which presses the stone in the mold (22) to form its one abutting surface on the intended stone length, in this abutting surface at the same time a recess (35) for the butt joint mortar is pushed in. 14. The method according to claim 12 or 13, characterized in that a plurality of blocks together forming form is used, and that in a small number of blocks adjacent to their upper abutment vertical knife-like steel cores (36) are pressed, with which slots are formed be, which allow the separation of stone parts (37) if necessary. 15. The method according to claim 14, characterized in that in two of the blocks, a slot is pressed in at such a point that the separable stone parts (37) are on one side of the block or on the opposite side of the other block . 16. The method according to any one of claims 12 to 15, characterized in that a shape is used which is chromed at least on the surfaces corresponding to the support surfaces (20, 21). 17. The method according to any one of claims 12 to 16, characterized in that blocks of normal length and blocks of shorter length, e.g. 2/3 and 1/3 of the normal length can be formed by pressing the appropriate stamp in different depths. 18.Use of assembly blocks with plane-parallel support surfaces made in the edge area of the stone to an exact stone height and with recesses formed in the stone for inserting insulating plates for thermal insulation, which in the horizontal longitudinal direction running parallel to the wall direction may cover the entire stone with the exception of one Continuously push through the end area, in particular according to one of claims 1 to 11, to form a corner structure from two rows of blocks colliding at right angles, characterized in that in the longitudinal direction of one row of blocks abutting the abutting surface of the last block, a gap (30) over the other row of blocks entire cross section and a continuous insulating plate (31) is inserted in this gap, the gap (30) preferably being between the last block of normal length of the other row of blocks and a block (39) forming the outer corner of the same row of blocks, which is of a shorter length than the other blocks.

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