EP2643133A2 - Mold for producing molded concrete blocks - Google Patents

Abstract

The invention relates to a mold for producing molded concrete blocks with multiple molding cavities which are separated from one another by intersecting intermediate wall panels. The aim of the invention is an advantageous design of the intersection points of the intermediate wall panels with the additional lateral support of slot edges.

Description

 Mold for the production of concrete blocks

The invention relates to a mold for the production of concrete blocks. Molds for the industrial production of concrete blocks in concrete molding machines typically have a plurality of mold cavities arranged side by side and separated from one another by intermediate walls. The entirety of the mold cavities is also referred to as a stone field, the marginal mold cavities being limited to the outside of the stone field by outer walls. In particular, for tall molds, for example for the production of hollow blocks, at least the intermediate walls are typically formed by wall plates which are directly or indirectly connected to each other and on the outer walls and form a substantially rigid box. The mold cavities are open at the top and at the bottom, and the wall plates are formed continuously vertically between a lower and an upper boundary plane of the mold. At the top of the mold, the stone field is usually surrounded by a cover frame surface, which may be formed in particular by exchangeable wear plates. The mold cavity limiting wall surfaces are exposed to considerable mechanical stresses, especially static by high side pressure of the concrete, at the top of pressure plates, and dynamically by abrasion of moving during shaking and demolding along the wall surfaces granular components of the concrete amount to reduce wear by abrasion the surfaces of the side walls advantageously hardened. Hardening gives case hardening a higher resistance to wear than nitriding, but it also poses a greater risk of forgiving molds and having to be reworked after curing with great effort. While in forms in which intermediate walls extend only in one direction between opposite outer walls, the compounds of the intermediate walls with the outer walls in a relatively simple manner dimensionally stable executable, this is significantly more difficult in forms with running in different directions and at intersections intersecting partitions.

Welded connections of the wall panels at intersection points form stable connections, but weaken wear resistance after hardening and increase the danger of fatigue fracture. Forms with wall plates welded before curing often show a strong distortion after hardening. Weld-free connections can for example be given by the fact that the intermediate walls are designed in a first direction as passing over the entire stone field first wall plates and extending in a second direction transverse thereto intermediate walls only between two first wall plates and connectors on their first wall plates assigning faces are positively connected to the first wall plates. US 4,249,358 describes molds having intersecting wall panels as partitions and exterior walls of

Form nests of a stone field, which are inserted at intersections on opposite aligned slots comb-like into each other and outside the stone field without welding attached to a mold frame.

The invention has for its object to provide an advantageous structure of a form with intersecting at intersections wall plates. The invention is described in the independent claim. The dependent claims contain advantageous refinements and developments of the invention.

The positive fixing of the edges of a slot of a partition wall plate by means of holding structures on the other partition plate of a crossing point advantageously results with little effort without welding or additional mechanical fasteners ne support with high stability of existing at the intersection point connector of two partition plates. In particular, a lateral deviation of the wall panels from the vertical course in the region of the opening of the slot, for. B. under the influence of hydrostatic pressure in the concrete amount.

In the above, below, vertically, horizontally, etc. let and in the following from a regular operating position of the mold in a molding machine, in which the mold rests with a lower boundary plane on a horizontal flat surface and the mold cavities in the vertical direction in the have substantially constant cross-section.

Due to the positive fixing advantageously occurring even deformations of the intermediate wall panels can be compensated again from a previous hardening process. The support structures are advantageously formed as depressions, in particular as grooves in the wall surface of a first of the two intermeshed at the junction point wall plates in which the edges of the slot of the second of the two wall plates are supported. Of particular importance is the transverse support of the edges of the downwardly open slots. Preferably, at an intersection, the edges of the slots of both intersecting mated partition panels are mutually fixed to support structures of the respective other partition panel and supported against a change in position parallel to the wall surface of the panel structures having the support structures.

Recesses designed as first grooves in the extension of a first slot as holding structures in the wall surface of a first partition wall are advantageously formed over the entire extent of the first partition walls in extension of the first slot, so that the edges of the second slot over the entire length of the first grooves in this hedge and are fixed in a form-fitting manner. In a particular development, the engagement depth of the edges of the second slot in the first grooves may be greater in a starting region located at the opening of the second slot than in a region spaced from the slot opening. For this purpose, preferably, the first grooves have a constant cross-section over their vertical longitudinal extent and the edges of the second slot in the initial region facing each other pointing projections. In the area spaced from the slot opening, a slot edge then has a greater distance from the bottom of the slot than at the beginning. In particular, the projections can also rest firmly against the groove bottoms, without the mating of the intermediate wall plates at the point of intersection being appreciably impeded.

Advantageously, the outer walls of the mold cavities of the stone field are also bounded by wall plates, hereinafter referred to as outer wall panels. The partition plates may also preferably via comb-like slot connectors at crossing points with intermediate Wall panels and / or other outer wall panels to be connected without welding. At these crossing points, other forms of connection can be given. Relative fixing of outer wall panels to one another and to the intermediate wall panels preferably takes place outside of the stone field, for which purpose the partition panels advantageously protrude laterally beyond the outer wall panels with projections. Advantageously, no welds are performed on the Formnester limiting plate sections. In particular, connecting elements can be arranged on outer surfaces of the outer wall panels and / or intermediate wall panels, which effect a relative vertical fixation of intermediate wall panels and outer wall panels.

In a particular embodiment can be provided on two opposite sides of the stone field of the this limiting outer wall panels away from the stone field in addition to the outer wall panels substantially parallel additional plates which form with the outer wall panels and crossed to running partition panels blank spaces. Due to the spacing from the stone field, welding joints with the intersecting partition plates can be produced on the additional panels without impairing the wear resistance of the hardened wall surfaces of the mold cavities.

Advantageously, the mold has an outline which is substantially rectangular in plan view and bounded by longitudinal sides and transverse sides, and flanges for clamping into a molding machine on both lateral sides, but not on the longitudinal sides, by means of which the mold is filled during filling of the mold cavities and during a vibrating operation Solidification of the concrete amount to concrete blocks on the vibratory pad with high force is pressed. While in the aforementioned US 4 249 358 the largest In the case of a mold adapted to a vibratory base, the maximum loads during the vibrating operation occur, in particular the underlay applying upward forces to the lower edges of the wall plates of the mold and the Maschineneinspannung exercise downward forces on the flanges on the transverse sides. Advantageously, in the case of the intermediate wall panels which are particularly stressed during deflection and pass through between the two transverse sides, a narrowing of the slot opening associated with a deflection of these intermediate wall panels is particularly advantageously absorbed by supporting the slot edges on the transverse wall panels and a deflection can be kept very low. Advantageously, the length of the downwardly facing slots is not more than 45%, in particular not more than 40% of the total height of the intermediate wall panels. In the transversely extending intermediate wall panels, the length of the upwardly open slots then at least 55%, in particular at least 60% of the total height of the partition plates.

The invention is illustrated below with reference to preferred embodiments with reference to the figures still in detail. Showing:

Fig. 1 shows a complete form in an oblique view, Fig. 2 is an assembled view of components of the form

 according to FIG. 1,

3 shows the wall panels to the shape of FIG. 1 in an assembled position, two nested wall panels, a longitudinal wall panel in various views, a Querwandplatte, an enlarged section of a slot, the view of FIG. 7 with a view parallel to the wall surfaces normal, a view into the slot from below, an oblique view of an upwardly open slot, a A sectional view of a section of a crossing point, a crossing point from below a crossing point from above, an enlarged view of a slot end area, an enlarged view of a support area, a variant of a mold construction, 17 shows a detail from FIG. 16.

Fig. 1 shows a view obliquely from above a complete mold for the production of hollow blocks, to which the invention is explained below. Plotted with a shape-related, rectangular x-y-z

Coordinate system, whose x-y plane in the regular operating position of the form is horizontal and whose z-direction indicates the vertical direction. The x-direction is also referred to below as the transverse direction and the y-direction as the longitudinal direction.

The mold has a plurality of mold cavities FN, which pass between an upper horizontal delimiting plane visible in FIG. 1 and a lower horizontal delimiting plane, which is concealed in FIG. 1, of essentially constant cross section and are open upwards and downwards. The mold is placed in operation with the lower boundary plane on a vibratory pad of a molding machine and arranged on two opposite in the longitudinal direction y opposite transverse sides arranged machine flanges FM in a molding machine and pressed onto the vibratory pad. For a filling of the mold cavities FN with a flowable amount of fresh concrete, a filling carriage is typically moved over the mold in the x-direction. At the top of the mold dirt strips or guide rails WF may be provided.

The entirety of the plurality of mold cavities FN forms the stone field which is bounded outwardly by longitudinal outer walls AL extending in the longitudinal direction y and transverse transverse outer walls AQ extending in the transverse direction x. The outer walls AL, AQ are advantageously formed by wall panels. The mold cavity is subdivided by longitudinal intermediate walls ZL extending in the longitudinal direction y and by transverse transverse walls ZQ extending in the transverse direction x into the plurality of mold cavities. The intermediate walls intersect at points of intersection KP and are there inserted into one another in a manner described in more detail below and held together without any welds. The partition walls ZL, ZQ are also designed as wall panels and go in the longitudinal direction or transverse direction uninterrupted between the outer walls AL and AQ through the stone field. At the crossing points, the intermediate wall plates ZQ, ZL are supported horizontally against each other. A vertical fixation between longitudinally and transversely extending wall panels is advantageously carried out by connecting means outside the stone field, for which in Fig. 1 a clamping bar SL shown in the longitudinal direction is shown, which protrudes through recesses SA beyond the longitudinal outer wall panels AL protruding plate projections UQ the transverse partition plates is guided therethrough.

Form cores FK, which are held on the stone field spanning core holder strips KL, are arranged in the mold cavities FN. In the example shown in FIG. 1, in the longitudinal direction y offset from the transverse outer wall panels AQ from the stone field, additional wall panels WZ are provided, which run parallel to the transverse outer wall panels AQ and form empty spaces at the transverse sides opposite the longitudinal direction y outside the stone field , The longitudinal intermediate walls ZL running in the longitudinal direction y also run crosswise with these additional wall panels WZ and protrude with plate sections UL in the longitudinal direction beyond the additional wall panels WZ. At the top of the mold are longitudinal cover plates DL and extending in the transverse direction Cover plates DQ arranged, which are typically releasably connected as wearing parts with the mold.

The machine flanges FM are advantageously connected to the plate ends of the longitudinally extending intermediate wall panels ZL and outer wall panels AL in order to transmit the forces of the molding machine to the mold. There are no machine flanges on the long sides of the mold. When the mold is pressed onto the vibratable support via the machine flanges FM clamped in the molding machine, the mold is therefore stressed, in particular, by deflection in y-z planes.

Fig. 2 shows components of the form shown in Fig. 1 in an assembly diagram. Not shown in FIG. 2 for the sake of clarity are the mandrels FK and the core holder strips KL. In Fig. 2, the running in the longitudinal direction and transverse wall panels are still shown in the mated condition.

FIG. 3 shows exclusively the wall panels used in the mold according to FIGS. 1 and 2 in disassembled, but aligned for assembly. The longitudinal intermediate wall panels ZL and one of the longitudinal outer wall panels AL have on one side a non-planar structure, which produce recesses in side surfaces of a hollow block into which mortar or adhesive for connecting adjacent stones can be introduced. Moreover, the wall panels are essentially flat and advantageously at least approximately of the same thickness, which favors the uniform and low-distortion hardening in a common hardening process. The flatness of the plates is not mandatory, but is particularly advantageous in terms of production and common for a variety of stone shapes. In the following, therefore, without limitation, the general made of forms with longitudinally and transversely straight wall panels.

The longitudinal intermediate wall plates ZL have upwardly leading bottom slots SU from their lower edges UK, and in the transverse intermediate wall plates ZQ slots SO are guided downwardly in a corresponding manner from the upper edges of these transverse partition plates. Also in the outer wall panels AL, AQ and the additional wall panels WZ corresponding slots are formed. The longitudinal or transverse wall panels, which cross each other in vertical projection, are inserted together with vertically aligned lower slots SU and upper slots SO. The slots are then at the intersections of the composite plates. Fig. 4 shows a further illustration of the invention, only one

Longitudinal intermediate wall ZL and a transverse intermediate wall ZQ, which are inserted into one another at a crossing point KP, so that the lower edges of both wall panels lie in a common lower boundary plane. The plug-in connection of the two wall panels in the crossing point KP ensures that both wall panels are supported on one another both in the longitudinal direction y and in the transverse direction x.

Essential to the invention is that at the intersection not only a lateral overlap of the longitudinal intermediate wall ZL is given by a slot SO of the transverse partition ZQ and a spreading of the transverse partition ZQ through a slot SU of the longitudinal partition ZL, but that in addition the slot edges of at least one slot SU or SO, preferably both slots by holding structures on the wall plate encompassed by the respective slot additionally in the horizontal direction parallel to are supported by the embraced wall plate. The edges of an upwardly open slot SO of the transverse partition wall ZQ are thereby additionally supported in the crossing point KP in the y direction, so that no deflection, in particular of the upper edge of the transverse partition ZQ in the

Slot opening may occur. In the same way, the edges of a downwardly open slot SU of the longitudinal intermediate wall ZL in the crossing point KP by holding structures on the transverse partition wall ZQ at the crossing point against a possible deformation of the longitudinal intermediate wall ZL displacement, in particular the lower edge of the UK longitudinal Supported intermediate wall by holding structures on the transverse partition wall.

In a preferred embodiment, as shown in Fig. 4 sketched such holding structures on the wall panels by grooves in extension of the slots realized. In extension of the downwardly open slots SU in the longitudinal intermediate wall ZL, upper grooves NO are formed as recesses against the surrounding plate surface. Slot edges of an upwardly open slot SO of the transverse intermediate wall ZQ are located at a crossing point KP in these upper grooves NO and thus prevent deflection of the upper edges of the transverse partition wall ZQ at the crossing point KP in the y direction when high forces occur , Similarly, in the extension of an upwardly open slot SO, lower grooves NU are provided in the transverse partition wall ZQ, and edges of a lower slot SU of the longitudinal partition ZL are in lower grooves NU of the transverse partition ZQ against dodging in the x direction supported.

The support is of particular importance in the respective slot openings, since the wall panels are here exposed to the greatest bending moments in opposing plate sides possibly unequal acting forces on the wall panels. The slots are therefore advantageously used in the rich of their openings narrowed by a small amount compared to their remaining course. In the lower slots SU are in the region of the slot opening at the lower edge of the longitudinal partition wall wall projections VU, at the upper slots SO in the transverse partition projections VO are formed, which narrow the slot width in the region of the slot opening slightly compared to the rest of the slot. Such a special design of the slots is of particular advantage for the transverse support of the particularly loaded plate edges in the region of the slot openings on the one hand and for easy mating of crossing plates in the crossing points on the other.

Of particular advantage is further that, in connection with the attachment of machine flanges FM at the opposite ends in longitudinal direction y of the longitudinal intermediate wall plates ZL, the slots in the longitudinal partition plates ZL are downwardly open. The upwardly directed forces exerted on the machine flanges FM at the ends of the longitudinal intermediate wall panels and the upward forces exerted on the lower edges UK of the wall panels by the vibratory support during the vibration process expose the longitudinal intermediate wall panels to bending stresses which try to cause a bulging of the longitudinal partition plates between the machine flanges FM upwards. In this case, the lower slots would be narrowed, but this is largely prevented by the support of the Nutenränder the lower slots SU in the lower grooves NU of the transverse partition panel in the y direction, so that by this choice of alignment of the slot openings in the longitudinal partition plates after below the bending stiffness of these plates is increased against the particular bending stresses in the molding machine during the shaking operation. The transverse partition plates ZQ are not subject to any appreciable bending stresses, since the opposing En- In the case of these transverse partition plates, there are no special forces which suppress the inherent rigidity of the mold.

The particular and different bending stresses of the longitudinal and the transverse partition plates with the machine flanges exclusively at the opposite ends of the longitudinal partition plates is also advantageously taken into account that the slot length of the lower slots SU in the longitudinal partition plates is less than the length the upper slots SO in the transverse partition plates.

In Fig. 5, a longitudinal partition wall plate ZL is shown isolated in various views, wherein Fig. 5 (A) is an oblique view, Fig. 5 (B) is a bottom view of the lower edge and Fig. 5 (C) is a view in x Direction perpendicular to the plate surface represents. The individual design features of the longitudinal intermediate wall plate ZL are provided with the reference numerals already used in Fig. 4, so that reference is made to the explanations to Fig. 4. In FIG. 5, Roman numerals VII, VIII and IX denote areas which are shown enlarged in FIGS. 7, 8 and 9. Fig. 6 shows an oblique view of an isolated transverse partition wall plate ZQ, in which HO denotes the slot length of the upper slot SO. The slot length HO is advantageously at least 55%, in particular at least 60% of the total height HW of the wall panel. The remaining reference numerals used in FIG. 6 are identical in their designation to the reference symbols used in the preceding figures, to which reference is made.

Fig. 7 shows as a section VII of Fig. 5 (A) in an oblique view a lower slot SU in a longitudinal intermediate wall plate ZL. Fig. 8 shows the detail with view parallel to the x-direction. The bottom slot SU is open to the lower edge UK of the wall plate. In the area of the slot opening, the slot width measured in the y direction is reduced to a width dimension DU by opposed cams as projections VU. The dimension DU is matched to the wall thickness reduced in the lower groove NU of the transverse partition panel. In a region spaced from the lower slot opening, the slot SU is made wider by a small amount. In the z-direction in extension of the slot SU, an upper groove NO is formed as a recess against the wall surface of the longitudinal partition wall plate as a support structure for the slit edges of a transverse partition wall plate mated at a crossing point with the longitudinal partition wall plate ZL. The width of the groove NO in the y-direction is preferably substantially equal to the cam spacing DU. The width BO of the groove NO is tuned to the width of the upper cam VO, which is reduced in relation to the surrounding wall thickness of the transverse partition wall plate, at the opening from the slot SO open at the top.

In Fig. 9 is a bottom view of the lower slot SU of the longitudinal partition plate shown in FIG. 8 and 9, from which the opposing upper grooves NO as depressions against the wall surface and from the edges of the lower slot on both sides of the slot center projecting lower projections VU are visible. With a broken line a concealed in this view chamfer FA is indicated on the upper edge of the longitudinal partition panel. Fig. 10 shows an oblique view of a section of a transverse partition plate with an upper slot SO. Also in this example, it is provided that the slot SO is narrowed at the slot opening at the upper edge of the transverse partition panel by upper projections VO directed toward the slot center and from the slot opening in the direction of the slot opening. in a region spaced from the slot opening area, it widens again after the upper projections VO. The lower groove NU in the transverse partition wall plate is continued up to its upper edge, so that the upper projections VO do not extend in the y-direction over the entire plate thickness, but at this point in vertical projection a stepped course of the edges of the upper Slot occurs.

Fig. 1 1 shows as a sectional view in a y-z-sectional plane a section of a crossing point with a longitudinal intermediate wall plate ZL and a mating with this transverse partition plate ZQ. It can be seen in particular from the illustration according to FIG. 11 that the distance of the edges of the lower slot SU from the transverse partition wall plate in the y-direction is greater in a region spaced from the lower slot opening of the lower slot SO than in an area in the case of FIG lower slot opening, where the edges of the lower slot over lower projections VU to the slot center are formed protruding. This is particularly advantageous for the mating of the wall panels in the crossing point. This is further illustrated in a detail C shown in FIG. 15 from FIG. 11. In the detail shown in FIG. 15, a narrow gap is indicated between the lower protrusions VU and the transverse partition wall plate ZQ. However, the lower projections VU can also abut directly on the transverse partition panel ZQ in the y direction.

Fig. 12 shows a view at a crossing point from below. From this perspective, it is clear how the edges of the lower slot SU of the longitudinal intermediate wall plate ZL engage in the lower groove NU of the transverse partition plate ZQ and positively support the edges of the slot SU on the side edges of the lower groove in the x direction are. A reliable support is in particular in the region of the lower protrusions VU by their lower feres intervention in the grooves NU given. In FIG. 12, XI-XI denotes the sectional plane of the view according to FIG. 11, wherein it can be seen that the sectional area shown hatched in FIG. 11 for the transverse partition wall ZQ does not represent the full wall thickness of the transverse partition wall ZQ but the reduced wall thickness in the area of the lower grooves NU.

Fig. 13 shows a view vertically from above at a crossing point and illustrates the graded in this area the course of the edges of the upper slot SO with the not the full wall thickness of the transverse partition plate ZQ engaging upper projections VO. The upper slot SO may be formed engaging in the upper groove NO in an area spaced from its slot opening in the direction of the slot bottom, the engagement depth in this spaced area being advantageously less than the engagement depth of the projections VO in the groove NO. However, the upper slot SO can also have the stepped course illustrated in FIG. 13 only in the region of the upper projections VO and can be milled out to the complete wall thickness of the longitudinal intermediate wall plate ZL in a region spaced therefrom in the direction of the slot bottom Transverse support of the upper edge of the transverse partition plate ZQ in the y direction is given exclusively by the upper projections VO in the upper groove NO.

The transverse support of the edges of the slots in the intermediate wall plates in the region of the respective slot opening is particularly advantageous due to the force relationships, but not mandatory. It may also be provided a distance support over the entire length of the slots or only spaced from the respective slot openings in the direction of the slot bottom. Fig. 14 shows an enlarged detail C of Fig. 1 1, in which the design of the slot bottom of the lower slot SU is shown enlarged. In particular, the side walls of the lower slot SU pass over the slots FR in the region of their slot depth GU delimiting the depth of insertion during mating of longitudinal and transverse intermediate wall panels, thereby reliably avoiding the occurrence of high notch stresses in this area. The area of the upper slot SO in the region of its slot bottom GO is advantageously designed in the same way.

Fig. 16 shows a further embodiment of a mold with the inventive compound of longitudinal and transverse partition plates, wherein in the illustration shown in Fig. 16, the cover plates and the core holder assembly are omitted. FIG. 17 shows an enlarged detail of FIG. 16. In the form shown in FIG. 16, the transverse partition plates extending in the transverse direction x are connected to the longitudinal outer wall panels AL via plate sections UQ protruding beyond the longitudinal outer wall panels AL. The angle connectors VW are bolted to both the protruding portions UQ and the outsides of the outer wall panels AL via two vertical connector legs. Advantageously, as shown, the angle connectors VW can have an additional horizontal connector leg, which serves to screw the cover plates onto the mold. The plate sections of the transverse outer wall panels AQ transversely beyond the outer wall panel AL may be connected to the longitudinal outer wall panels AL with the same angle connectors. About additional holding elements HL, which are positively inserted into recesses of the outer surface of the outer wall panels AL and bolted to the outer wall panels AL, on the Außenwandplat- th protruding portions of core holder strips vertically down against the outer wall plates are braced.

On the transverse sides of the mold, further connection angles VF are provided, by means of which the machine flange strips FM are provided on the longitudinal sides.

Between wall panels and longitudinal outer wall panels are attached. The angle connectors VF can advantageously also serve at the same time for screwing the transverse cover plates DQ or DL on the mold. The features indicated above and in the claims, as well as the features which can be seen in the figures, can be implemented advantageously both individually and in various combinations. The invention is not limited to the exemplary embodiments described, but can be modified in many ways within the scope of expert knowledge.

Claims

Claims:

1 . Mold for the production of concrete blocks with several juxtaposed and a stone field forming mold cavities (FN), which are separated by between the top and the bottom of the mold cavity continuous partition walls, wherein the intermediate walls are formed by partition plates (ZL, ZQ), which in one piece lead the entire stone field and intersect each other at intersections (KP), wherein two intersecting partition plates (ZL, ZQ) with oppositely oriented slots (SU, SO) are inserted into each other, characterized in that at least at a first of the two at one Crossing point intersecting partition plates (ZQ) in extension of the first slot (SO) formed in this first partition wall holding structures (NU) are formed which the edges of the second of the two partition plates (ZL) formed in the second slot (SU) in one direction (y) parallel to the Wan dfläche the first partition wall plate (ZQ) and transversely to the direction (z) of the first and second slot positively fixed.

2. Form according to claim 1, characterized in that the holding structures are formed as recesses (NU) against the surrounding wall surfaces of the partition plates.

3. Mold according to claim 2, characterized in that the recesses are designed as grooves (NU).

4. Mold according to claim 3, characterized in that the grooves are designed with vertical edges to the surrounding wall surface.

5. mold according to claim 3 or 4, characterized in that the groove width is constant and the second partition wall plate rests at the edges of the second slot with its entire wall thickness in the grooves.

6. Mold according to one of claims 3 to 5, characterized in that the inner surfaces of the second slot in a spaced-apart from the slot opening section have a greater distance from the bottom of the grooves than at the slot opening.

7. A mold according to claim 6, characterized in that the second slot is narrowed at the slot opening relative to the spaced portion.

8. Mold according to one of claims 1 to 7, characterized in that on the second side wall plate (ZL) second holding structures (NO) for Querab- support the edges of the first slot (SO) are formed.

9. Form according to one of claims 1 to 8, characterized in that the first slot and / or the second slot at the slot opening opposite slot base to the slot longitudinal sides have transition radii of at least 10%, in particular at least 20% of the slot width.

10. Form according to one of claims 1 to 9, characterized in that the outer walls of the stone field are designed at least on two opposite sides as outer wall panels.

1 1. Mold according to claim 10, characterized in that the partition wall panels overlap the outer wall panels overlapping the stone field with projections (UL, ZU).

12. A mold according to claim 9 or 10, characterized in that the stone field are designed substantially rectangular with edges in a longitudinal direction and a transverse direction and is bounded by two mutually perpendicular to each other aligned pairs of outer wall panels.

13. A mold according to claim 12, characterized in that the outer wall panels at points intersect each other.

14. Form according to one of claims 1 1 to 13, characterized in that the projections of the side wall panels are connected by means of first angle connector with the outer surfaces of the outer wall panels, in particular screwed.

15. A mold according to claim 14, characterized in that the first angle connectors only form connections between projections of transversely extending side wall panels and extending in the longitudinal direction outer wall panels.

16. A mold according to any one of claims 10 to 17, characterized in that the stone field 5 is surrounded on its surface by cover plates and the cover plates connected via second angle connector with the side wall panels or the outer wall panels, in particular screwed.

17. A mold according to claim 16, characterized in that at least part of the second angle connector also forms first angle connector.

18. A mold according to any one of claims 10 to 17, characterized in that on the outer surfaces of at least two opposite outer wall plates arranged counter holder for core holder strips a mold core assembly.

19. A mold according to claim 18, characterized in that the counter-holders are clamped with over the outer wall panels also protruding ends of core holder strips vertically.

20. A mold according to claim 18 or 19, characterized in that the counter-holders are screwed to the outer surfaces of the outer wall panels.

21. Mold according to claim 18 or 19, characterized in that the counter-holders are held on projections of the side wall panels.

22. A mold according to claim 21, characterized in that the core holder rails in recesses of the outer wall panels einhegen and a vertical

Connection of the outer wall panels is combined with these cross-over side wall panels with a tension of the ends of the core holder strips.

23. A mold according to any one of claims 1 to 22, characterized in that on two opposite transverse sides each one designed for clamping the mold in a molding machine Flanschanordnungen are provided.

24. A mold according to claim 23, characterized in that in the longitudinal direction between the transverse sides extending side wall panels, the slots are open at the bottom.

25. A mold according to claim 24, characterized in that the height of the downwardly open slots is at most 45%, in particular at most 40% of the height of the side wall panels.

26. A mold according to any one of claims 10 to 25, characterized in that on at least two opposite sides of the outer wall plates spaced outwardly offset additional plates are arranged, which form empty spaces against the outer wall panels.

27. A mold according to claim 26, characterized in that the additional plates are welded to these overlapping side wall panels and / or outer wall panels.