WO2025162590A1 - Gable-shaped connection, gable-shaped connectable joining part and the production thereof, method for connecting joining parts, use of a gable-shaped connection for connecting joining parts, and multi-part connected component - Google Patents

Abstract

The present invention relates to a gable connection for connecting a first joining part (11) having a negative gable-shaped portion, and a second joining part (12) having a positive gable-shaped portion. The negative gable-shaped portion and the positive gable-shaped portion each comprise at least one step (30) having a joining surface. The gable-shaped portions are designed to be complementary in such a way that the positive portion can protrude at least partially into the negative portion, forming at least one joint (20) between the joining surfaces, which at least one joint (20) is at least partially filled with a filler. For sufficient hold, the joining surfaces have unevennesses of the order of magnitude from 1 μm to 10 mm and/or, in plan view, the height and width of the at least one step (30) are at an angle α ≥ 90° to one another. The invention further relates to gable-connectable joining parts and to the production thereof, to a method for connecting joining parts, and to a use of a gable connection for connecting joining parts, in particular made of FRC concrete slabs.

Description

_{Gable connection, gable-connectable joining part and its} production, method for connecting joining parts, use of a gable connection for connecting _{joining parts and multi-part joined component} The present invention relates to a gable connection for connecting joining parts, a gable-connectable _{joining part and its production, a method for connecting joining parts and a use of a} gable connection for connecting joining parts. In building construction, classic reinforced concrete ceilings have been used to date. Due to the steel reinforcements, these ceilings _{can absorb not only high compressive forces but also high tensile forces and are therefore particularly stable. Unfortunately, reinforced concrete ceilings also require a large amount of} starting materials, particularly concrete, and also have a high dead weight. The initial production of such a reinforced concrete ceiling on site at the construction site does not always run smoothly due to a certain dependence on the prevailing weather conditions. Frost, extreme heat, or heavy rainfall can affect the setting process of the concrete and thus influence the quality of the reinforced concrete slab, which is why weather conditions _{must be taken into account during its construction. An alternative to} traditional reinforced concrete in the form of FRC slabs (FRC = Fiber Reinforced Concrete) is already known from WO2014/040653 A1. Here, an FRC slab, the P220116 PCT Can absorb _{compressive and tensile forces comparable to reinforced concrete slabs} , _{can be manufactured off-site and not only on the construction site with significantly lower material consumption - and thus also dead weight.} The size of the FRC slabs is essentially limited by the transport of the slabs from the production site to the construction site, which limitation in turn is reflected in the maximum size of an FRC slab. In order to avoid this limitation, among other things, the present invention has set itself the object of _{providing an alternative connection for joining parts. A further} object of one aspect of the present invention is to provide a gable-connectable joining part. A still further object of one aspect of the present invention is to provide an alternative method for joining parts. A still further object of a further aspect of the present invention is to provide a use of a gable connection for connecting parts. A still further object of a further aspect of the present invention is _{to provide a multi-part component, in particular a concrete component. The joining parts can be} , for example, concrete joining parts and, in particular, FRC joining parts. P220116 PCT The object of providing an alternative connection is achieved by a gable connection according to claim 1. Said gable connection comprises a first joining part with an upper side and a negative gable-shaped section, which negative gable-shaped section represents a recess. The gable connection further comprises a second joining part with an upper side and a positive gable-shaped section, which positive _{gable-shaped section represents a projection. The} negative gable-shaped section and the positive _{gable-shaped section each comprise at least one step.} Furthermore, the negative gable-shaped section and the positive gable-shaped section each have joining surfaces aligned with one another along the at least one step. Furthermore, the negative gable-shaped section and the positive gable-shaped section are designed to be complementary in such a way that the positive gable-shaped section can protrude at least partially into the negative gable-shaped section. _{In the connected state, the positive gable-shaped section projects} at least partially into the negative gable-shaped section in such a way that one or more joints are formed between at least a part of the joining surface of the negative gable-shaped section and a part of the joining surface of the positive gable-shaped section. The one or more joints are at least _{partially filled with a filler. Furthermore,} at least a part of the surface of the joining surface of the negative P220116 PCT and the positive gable-shaped section has unevenness in the range of 1 µm to 10 mm. Alternatively or additionally, at least one of the at least one step of the first joining part has _{a width, a height, and an angle α, viewed from its upper side} . Alternatively or additionally, at least one of the at least one step of the second joining part has _{a width, a height, and an angle α, viewed from its} upper side. _{The angle α is greater than or equal to 90°, in particular greater than 90°, and more particularly greater than 90° and less than or equal to 110°, so that the height and width of the at least} one step _{are not orthogonal to each other in a plan view of the upper side, and the at least one} step _{tapers along its height and with increasing distance from its width.} The term "gable" originally comes from _{house construction and refers to the triangular surface} in the roof structure. This refers to the wall section whose upper corner is the roof ridge and whose sides are the roof edges. The lower end of the gable triangle is the cross connection of the lower corners _{of the roof edges. This definition can ultimately be modified} and applied to a joining part with a basic structure on which a projection is arranged, _{forming the gable. Although the gable-shaped section according to the invention is} not necessarily triangular, but can also have a different geometry, it is advantageous if the gable-shaped section ("gable" can be used as a synonym for P220116 PCT) used) widens toward the base structure, which _{can be understood figuratively as "triangular," i.e., narrow at the top and wide at the bottom. Conversely, these} considerations also apply to the negative gable-shaped section, which, however, does not stand away from the base structure but rather protrudes into it, essentially _{"eating out" material from it. If the gable-shaped section comprises} only one step, it can, for example, have a rectangular shape, such as a square shape, or even the _{shape of a trapezoid when viewed from above, either as a projection (=} positive) or as a recess (= negative). The term "step" also originates from the field of house construction and usually refers to a single _{part of a staircase used for ascending or descending.} The step essentially comprises two _{adjacent surfaces: a tread and a rising surface,} which creates the difference in height. According to the invention, the tread corresponds to the width of the step when viewed from above onto the top side of the joining part, and the rising surface _{corresponds to the height of the step. If there is more than one step in a} gable-shaped section, the shape of a stepped gable is created, also known as _{a stepped gable, stepped gable, or cat-step gable. The} number of steps on the left and right sides of the gable-shaped section can be identical, or there can even be mirror symmetry, or the number of steps on the left and right sides can differ, which means _{that mirror symmetry cannot be achieved. Along} the height and/or width of the steps, i.e., in the P220116 PCT In construction jargon, one or more joining surfaces extend along the tread and/or riser. The joining surface(s) of the negative and positive gable sections face each other, i.e., are aligned. A single, continuous joining surface can form along the steps, but there can also be several individual, non-connected joining surfaces. If, for example, the positive gable section penetrates the negative gable section to such an extent that direct contact occurs in some places, these "contact surfaces" are not considered part of the joining surface(s), since contact at that point does not _{create a joint into which filler can be poured. The term "complementary" is} to be strictly understood as "opposing but complementary properties of an object." The negative and the positive gable-shaped section are such opposing objects (recess vs. projection) which complement each other in that they can be inserted into each other and, together with the joint or the _{filler to be filled into the joint, form a complete or supplemented new object. It is important within the meaning of the invention that} complementary is not designed so closely that, when the negative and the positive gable-shaped section are at least partially inserted into each other, there is only a contact surface and no joining surface, i.e. _{no joint remains. A suitable filler can be, for example, a} binding agent such as an adhesive or mortar, but also, for example, _{sand. Furthermore, the joint can be filled, for example, by} attaching a barrier, for example in the form of a (e.g., P220116 PCT A wedge-shaped board, which _{is driven into the joint from the top side of the joining parts,} for _{example, and reduces the joint size so that the joining parts are "wedged". For} better adhesion of the gable connection, the joining surface(s) can be roughened or roughened, i.e., not smooth. A non-smooth surface is noticeable by a microstructure on the surface, which shows _{unevenness on a scale of,} for example, 1 µm to 10 mm. Further examples of the scale of unevenness _{include: - 1 µm to 5 mm; - 1 µm to 2 mm; - 1 µm to 1 mm; - 1 µm to 500 µm; - 1 µm to 100 µm; - 1 µm to 10 µm; - 1 mm to 10 mm; - 1 mm to 5 mm; - 500 µm to 2 mm; - 100 µm to 1 mm; - 100 µm to 500 µm; - 50 µm to 100 µm; - 100 µm to 2 mm; - 200 µm to 5 mm.} The angle α, which indicates the relationship between the "tread" and the "rising" surface of a step, can be 90° or P220116 PCT more. At an angle α greater than 90°, the "climbing surface" inclines towards the "treading surface". _{Further examples of a range of the angle α} include: - _{90° ≤ α ≤ 120°; - 90° ≤ α ≤ 110°; - 90° ≤ α ≤ 105°; - 90° ≤ α ≤ 100°; - 90° ≤ α ≤ 98°; - 90° ≤ α ≤ 95°; - 90° ≤ α ≤ 93°; - 90° ≤ α ≤ 92°; - 90° < α ≤ 120°; - 90° < α ≤ 110°; - 90° < α ≤ 105°; - 90° < α ≤ 100°; - 90° < α ≤ 98°; - 90° < α ≤ 95°; - 90° < α ≤ 93°; - 90° < α ≤ 92°; - 95° < α ≤ 120°; - 93° < α ≤ 110°; - 92° < α ≤ 105°; - 91° < α ≤ 100°; - 91° < α ≤ 98°; - 91° < α ≤ 95°; - 90.5° < α ≤ 93°; - 90.1° < α ≤ 92°.} P220116 PCT _{In one example, the angle α of the at least one step of the first joining part and the at least one step of the second joining part are} "substantially" identical with respect to the aligned joining surfaces. The angle can actually be exactly the same. However, since _{the strengthening effect of the connection also occurs with a} certain deviation, the term "substantially" encompasses a certain range. For example, it is _{advantageous if the angle α of the at least one step of the first joining part and the angle α of the at least one} step of the second joining part _{deviate from each other by a maximum of 5°, in particular a maximum of 2°, and more particularly a maximum of 1°.} The presence of unevenness or an angle α > 90° is sufficient to provide the gable connection with sufficient stability under tension or compression on or into the plane of the joining parts. The unevenness does not necessarily have to be specifically manufactured/created, but can already be inherently present due to the porosity of the concrete of a concrete joining part. In an embodiment of the gable connection according to the invention, which _{can be combined with any of the embodiments yet to be mentioned and those already mentioned, unless contradictory, the mutually aligned joining surfaces of the negative and the positive gable-shaped section represent} at least P220116 PCT They represent planes that are partially parallel to one another and inclined relative to the top surface of the joining parts. _{Where the angle α indicates the extent to which the "rising surface" is inclined towards the} "tread surface" of the step, the _{angle β indicates whether the "rising surface" and/or the "tread surface"} are tilted or inclined relative to the top surface of the joining part. If the "rising surface" and "tread surface" are at _{an angle of β = 90° to the top surface, the joining surfaces do not represent inclined planes. However, if the angle β ≠ 90°,} the joining surfaces are represented by inclined planes at that point. If the joint to be filled or filled with filler is bordered by two inclined planes, which are ideally also aligned essentially parallel to each other, the joint holds particularly well and the gable connection is strengthened. "Substantially" parallel, in the context of the invention, means that the inclined planes of the aligned joining surfaces do not have to be strictly parallel to each other, but the strengthening effect of the connection also _{occurs when the angle β of the first joining part and the} second joining part _{deviate from 90° in the same direction, i.e., both angles β are either greater or} less than 90°. Ideally, the difference between the _{angle β of the first joining part and the second joining part} is max. 5°, in particular max. 2°, and further in particular max. 1°. _{Examples of a range of the angle β} include: - _{90° < β ≤ 120°;} P220116 PCT _{- 90° β ≤ 110°; - 90° < β ≤ 105°; - 90° < β ≤ 100°; - 90° < β ≤ 98°; - 90° < β ≤ 95°; - 90° < β ≤ 93°; - 90° < β ≤ 92°; - 95° < β ≤ 120°; - 93° < β ≤ 110°; - 92° < β ≤ 105°; - 91° < β ≤ 100°; - 91° < β ≤ 98°; - 91° < β ≤ 95°; - 90.5° < β ≤ 93°; - 90.1° < β ≤ 92° - 60° ≤ β <90°; - 70° ≤ β <90°; - 75° ≤ β <90°; - 80° ≤ β <90°; - 82° ≤ β <90°; - 85° ≤ β <90°; - 87° ≤ β <90°; - 88° ≤ β <90°; - 60° ≤ β <85°; - 70° ≤ β <87°; - 75° ≤ β <88°; - 80° ≤ β <89°; - 82° ≤ β <89°; - 85° ≤ β <89°; -} P220116 PCT - _89.9°. Especially in the case of loads caused by transverse forces, i.e. bending, an angle β ≠ 90° additionally stabilizes the gable connection. In general, however, the tensile load, especially in building construction, is higher than the bending load, which means that the roughness of the surface of the joining surface or an angle α > 90° plays a more relevant role. In an embodiment of the gable connection according to the invention, which _{can be combined with any of the embodiments yet to be mentioned and those already mentioned, unless contradictory, the negative gable-shaped section and the positive gable-shaped section each comprise} at least a first and a second step. From the top side of the first joining part or the second joining part, the first and second steps have _{a width or a left width and a right width, as well as a left height and a right height. The} inclined planes relative to the upper side of the joining parts are _{arranged, for example, along the width of the first step} and/or along the left width of the second step _{and/or along the right width of the second step and/or along the left height of the first step and/or} the right height of the first step and/or the left height _{of the second step and/or the right height of the second} step. P220116 PCT In one example, all joining surfaces along the entirety of the two steps are represented by inclined planes. In another example, which _{allows for easier production of the joining parts, only the joining surfaces along the height of the steps are} designed as inclined planes. In yet another example, only the joining surfaces along the width of the two steps are represented by inclined planes. One possibility for producing the inclined planes is, for example, sawing the positive gable-shaped section to size or sawing out the negative gable-shaped section using a wider saw blade with a thickness of, for example, 1 cm to 3 cm, in particular 1.5 cm to 2.5 cm. In an embodiment of the gable connection according to the invention, which _{can be combined with any of the embodiments yet to be mentioned and those already mentioned, provided that they do not contradict each other, the mutually aligned joining surfaces of the negative and the positive gable-shaped section represent} at least two pairs of planes that are partially substantially parallel to one another and inclined relative to the upper side of the joining parts. _{Preferably, the inclined planes of one pair are} aligned opposite to the inclined planes of the other pair. In an example in which the gable-shaped sections are formed in two stages and, for example, an inclined plane serves as a joining surface along the height of the steps of the negative and positive gable-shaped section, P220116 PCT would be located, there would be two areas on the left and right hand side in which the joining surfaces are inclined planes _{, and thus four such pairs. For example, the pair arranged at the height of the first step can} be inclined with _{an angle β > 90° (e.g. 93°) and the pair arranged} along the height of the second step with an angle β < 90 ° (e.g. 88 °), so that the orientation alternates from pair to pair. In an embodiment of the gable connection according to the invention, which _{can be combined with any of the embodiments yet to be mentioned and those already mentioned, provided they do not contradict each other, the} aligned joining surfaces of the negative and the positive gable-shaped section _{represent an even number of pairs of planes that are partially essentially parallel to one another and inclined with respect to the upper side of the joining parts. The inclined planes of one half of the pairs are aligned opposite to the inclined planes of the other} half of the pairs. In particular, as already given in the example in connection with the embodiment mentioned directly above, they are oriented alternately in pairs, so that the inclined planes of adjacent pairs are oriented opposite to each other. In an embodiment of the gable connection according to the invention, which can be combined with any of the embodiments to be mentioned and those already mentioned, P220116 PCT _{Unless contradictory, the at least one step of the first joining part and the} at least one step of the second joining part have a width or a left width and a _{right width as well as a left height and a right height} when viewed from the top side of the first joining part or the second joining part _{. The unevennesses are formed along the} joining surface of the negative gable-shaped section, which joining surface extends along one width or the left width and/or the right width of the at least one step. Alternatively or additionally, the unevennesses are formed along the joining surface of the negative gable-shaped section, which joining surface extends along the left height and/or the right height of the at least one step. Alternatively or _{additionally, the unevennesses are formed along the joining surface of the positive gable-shaped section, which} joining surface _{extends along one width or the left width and/or the right width of the at least one step. Alternatively or additionally, the unevennesses are formed along the joining surface of the positive gable-shaped section, which joining surface} extends along the left height and/or the right height of the at least one step. In an embodiment of the gable connection according to the invention, which _{can be combined with any of the embodiments to be mentioned and those already mentioned, unless contradictory, the} P220116 PCT positive gable-shaped section n steps, where n _{is a natural number, in particular a number from} 2 to 20 inclusive, further in particular from 4 to 12 inclusive and again further in particular from 5 to 9 inclusive. In an embodiment of the gable connection according to the invention, which _{can be combined with any of the embodiments yet to be mentioned and already mentioned, unless contradictory, the negative gable-shaped section comprises n steps, where n is a natural number, in particular a number from} 2 to 20 inclusive, further in particular from 4 to 12 inclusive and again further in particular from 5 to 9 inclusive. In an embodiment of the gable connection according to the invention, which can be combined with any of the embodiments yet to be mentioned and already mentioned, unless contradictory, the number of steps of the positive gable-shaped section is identical to the number of steps of the negative gable-shaped section. In an embodiment of the gable connection according to the invention, which can be used with each of the P220116 PCT and _{can be combined with the embodiments already mentioned, unless contradictory, the positive gable-shaped section projects} into the negative gable-shaped section in such a way that at least n/2 of the n _{steps of the positive gable-shaped section project completely} into the negative gable-shaped section. In particular, at least 3/4 n of the n steps of the _{positive gable-shaped section and more particularly n-1 of the n steps of the positive gable-shaped section project} completely into the negative gable-shaped section. The greater the proportion of the positive gable-shaped section that projects into the negative gable-shaped section, the more stable the gable connection. Optimally, however, the projection is not so complete or the geometry of the gable-shaped sections, which are complementary within the meaning of the invention, is selected such that a joint is formed along the entire height of the lowest step of the positive gable-shaped section (optimally on the left and right hand side). In an inventive embodiment of the gable connection, which _{can be combined with any of the embodiments yet to be mentioned and those already mentioned, provided that they do not contradict this, n-1 of the n steps of the positive gable-shaped section protrudes} completely _{into the negative gable-shaped section. The} lowest step of the positive gable-shaped section protrudes at least partially, in particular half of its P220116 PCT _{Height and further in particular 3/4 of its height into the} negative gable-shaped section. In an embodiment of the gable connection according to the invention, which _{can be combined with any of the embodiments yet to be mentioned and those already mentioned, provided they do not contradict this, the gable connection has} an overall width and an overall height. The overall height is greater than the overall width, in particular by a factor of 1.05 up to and including 5, further in particular by a factor of 1.05 up to and including 3, further in particular by a factor of 1.05 up to and including 2. A corresponding ratio of overall height to overall width leads to a particularly stable _{gable connection. However, the ratio should not be too} extreme (e.g. factor 10), since otherwise the reinforcements (in the case of joining parts = FRC plates) could be separated more easily if there is a pull in the direction of the width of the steps. In an inventive embodiment of the gable joint, which _{can be combined with any of the embodiments yet to be mentioned and those already mentioned, provided they do not contradict each other,} the first joining part and the second joining part are three-dimensional objects with the dimensions height, width, and thickness. The thickness represents the smallest dimension of the _{three dimensions, with the joining surfaces extending along} P220116 PCT _{of thickness. The first joining part and the second joining part are, in particular, concrete slabs, more particularly, FRC slabs. One embodiment} of the FRC slab is the CPC slab. The letters "FRC" in FRC slabs stand for "Fiber _{Reinforced Concrete." FRC slabs are described, among other things, in} WO2014/040653 A1, the content of which is to be understood as part of the disclosure of the present application. FRC slabs are prestressed with fibers, for example made of carbon, glass, Kevlar, basalt, steel, natural fiber, or the like, whose cross-sectional area is, for example, less than 5 ^mm² , and have a thickness of a few centimeters (e.g., 1 cm to 10 cm). The width and length, in turn, range from a few meters (1 m, 2 m, ..., 5 m, etc.) up to 10 m or even 20 m up to 40 m. The reinforcement of the slabs can be based on different spacing and arrangements of the fibers relative to one another. Further details can _{be found in WO2014/040653 A1. Since the fibers used have very high tensile strength and are preferably non-corroding,} they can be used to produce particularly load-bearing, thin concrete slabs. The reinforcement cover of three to four centimeters required for conventional reinforced concrete slabs is no longer necessary. In comparison _{, FRC slabs are therefore significantly thinner and lighter – yet offer the same load-bearing capacity.} A special embodiment of an FRC slab is the _{CPC slab. The letters "CPC" stand for "carbon} prestressed concrete" and describe the concrete slabs reinforced with thin prestressed carbon strands, which can be used according to the invention and are particularly suitable for P220116 PCT. _{delicate yet resilient. A special feature of CPC} panels is that, thanks to the prestressing provided by the fibers, they _{remain extremely rigid even under pure tensile load and crack-free under service load. This is a particular advantage when} used as a base structure. Even when used as a panel, they can absorb extremely high shear forces without cracking while maintaining high rigidity. Typical FRC panels used for concrete ceiling elements are between 10 and 100 mm thick, in particular between 20 and 60 mm, e.g. 25 mm or 30 mm, especially 40 mm with regard to fire protection, and have, for example, a four-layer CFRP reinforcement. In terms of expansion, the FRC panels can be several meters long and wide. For example, 1 m x 2 m, 2 m x 2 m, 2 m _{x 4 m up to 20 m x 40 m. A maximum width of 2.4 m is preferred} , as this still allows for problem-free road transport. However, a width of up to 3.5 m or even up to 6 m is also possible, although this may require more difficult transport conditions. The length of the FRC panels is preferably determined by the floor area of the rooms to be spanned or the building dimensions and is typically in the range of approximately 4 m or 5 m up to 12 m or even 20 m. The underside and the top side of an FRC panel are usually identical. In an embodiment of the gable connection according to the invention, which _{can be combined with any of the embodiments to be mentioned and those already mentioned, provided that they do not contradict each other, a distinction is made between the} P220116 PCT A continuous joint is formed between the joining surface of the positive gable section and the joining surface of the negative gable section. Generally speaking, the larger the joining surface, the more stable the gable connection. If a continuous joint is formed, the entire area along the steps is used as the joining surface, thus achieving optimal joining between the joining parts. In an embodiment of the gable connection according to the invention, which _{can be combined with any of the embodiments yet to be mentioned and those already mentioned, provided they do not contradict each other, the} overlap height of the joint of the at least one step, which results from the height of the at least one step of the first joining part less the height of the joint of the at least one step, is at least equal to or greater than the width of the joint of the at least one step, in particular by a factor of 1.5 to 5.0, more particularly by a factor of 2.0 to 3.0, or even 3.0 to 4.0. If the overlap height is at least as large as the width of the joint, the gable connection is further strengthened. If the width of the joint is smaller than the overlap height, a type of predetermined breaking point is created in the connection, at _{which the connection fails under excessive load.} P220116 PCT In an embodiment of the gable connection according to the invention, which _{can be combined with any of the embodiments yet to be mentioned and those already mentioned, unless contradictory, the negative} gable-shaped section and the positive gable-shaped _{section have the same number of steps. Alternatively or} additionally, the negative gable-shaped section _{and/or the positive gable-shaped section} are mirror-symmetrical. The plane of symmetry runs centrally (with respect to the width of the first step) through the gable-shaped section from the top side to the bottom side (virtually parallel to the thickness) of the joining part. The further object of an aspect of the present invention of providing a gable-connectable _{joining part is achieved by a joining part according to claim 15. Said gable-connectable joining part is in particular a} concrete slab, furthermore in particular an FRC slab, furthermore in particular a CPC slab. The gable-connectable joining part has an upper side and comprises at least one negative gable-shaped section, which represents a recess, or at least one positive gable-shaped _{section, which represents a projection. The negative gable-shaped section and the positive} gable-shaped section each comprise at least one step. In particular, they each comprise 2 to 20, more particularly 4 to 12, and again more particularly P220116 PCT _{including 5 to 9 steps. The} negative gable-shaped section and the positive gable-shaped section each have _{a joining surface along at least one step. At least part of the} surface of the joining surface of the negative or positive gable-shaped section has unevenness in the order of magnitude of 1 µm to 10 mm. Further ranges of _{magnitude have already been disclosed in connection with the} gable connection and naturally apply equally to the gable-connectable joining part. Alternatively or additionally, at least one of the at least one step has _{a width, a height and an angle α, viewed} from the top side of the joining part, _{which angle α is ≥ 90°, so that the height and width of the at least one step are not orthogonal to one another and} the at least one step tapers along its height and with increasing distance from the width. Examples and _{ranges for the angle α have already been disclosed in connection} with the gable connection and, of course, apply equally to the gable-connectable joining part. _{Alternatively or additionally, the joining surface of the negative or positive gable-shaped section represents} at least partially a plane inclined relative to the upper surface of the joining part. Examples and ranges for the angle β, the indicator for _{the "inclination" of the plane, have already been disclosed in connection with} the gable connection and, of course, apply equally to the gable-connectable joining part. P220116 PCT _{Typical FRC plates used for gable-jointed components are between 10 and 100 mm thick, in particular between 35 and 80 mm thick, further} in particular between 40 and 70 mm thick, e.g. 40 _{mm or 50 mm, in particular 60 mm or 70 mm.} In an embodiment of the gable-connectable joining part according to the invention, which can be combined with any of the embodiments yet to be mentioned and those already mentioned, provided they do not contradict each other, _{the joining surface of the negative or positive gable-shaped section at least partially represents} two planes inclined relative to the upper side of the joining part. _{The negative or positive gable-shaped section} comprises at least two steps which, viewed from the upper side of the joining part _{, have a width or a left width and a right width and a left height and a right height, wherein the planes inclined relative to the upper side} of the joining part are arranged along the _{width of the first step and/or along the left width} of the second step and/or the right width of the second step and/or the left height of the first step and/or the right height of the first step and/or along the left height of the second step and/or the right height of the second step. Alternatively or additionally, the at least two inclined planes have different inclinations, in particular inclinations in opposite directions. Alternatively or additionally, the number of inclined planes with a first slope and a corresponding P220116 PCT opposite inclination approximately identical. Alternatively _{or additionally, the inclined planes alternate with a} first inclination and an opposite inclination. In an embodiment of the gable-connectable joining part according to the invention, which can be combined with any of the embodiments yet to be mentioned and those already mentioned, provided they do not contradict this, at least part of the surface of the joining surface of the negative or positive gable-shaped section has unevenness in the order of 1 µm to 10 mm. Further ranges of this order of magnitude have already been disclosed in connection with the gable connection and naturally apply equally to the gable-connectable joining part. The negative or positive gable-shaped section comprises at least two steps (which, viewed from the top side of the joining part, have a width or a left width and a right width and a left height and a right height. The unevennesses are arranged along the width of the first step and/or along the left width of the second step and/or the right width (of the second step and/or along the left height of the first step and/or the right height of the first step and/or along the left height of the second step and/or the right height of the second step. In an embodiment of the gable-connectable joining part according to the invention, which can be combined with any of the embodiments to be mentioned and those already mentioned P220116 PCT can be combined, unless contradictory, the joining part has at least two negative gable-shaped sections representing a recess or _{at least two positive gable-shaped sections representing a projection. The at least two negative} gable-shaped sections or the at least two positive gable-shaped sections are directly adjacent, _{i.e. directly adjacent to one another, or arranged at a distance} from one another. In an embodiment of the gable-connectable joining part according to the invention, which can be combined with any of the embodiments yet to be mentioned and those already mentioned, unless contradictory, the joining part has at least two _{negative gable-shaped sections representing a recess and} at least one positive _{gable-shaped section representing a projection or alternatively at least one} negative gable-shaped _{section representing a recess and at least two positive gable-shaped sections representing a projection. The negative} gable-shaped sections and the positive gable-shaped section, or the negative gable-shaped section and the _{positive gable-shaped sections, are arranged alternately} and/or directly adjacent or spaced apart from each other. The number of gable-shaped sections per joining part, as well as their design (positive or negative), and their arrangement (e.g., alternating positive and negative, always n negative, then n positive, etc.) can be adjusted. P220116 PCT how firmly such a joining part can be connected to a _{complementary (in the sense of the connection) designed} second joining part. The number and in particular the arrangement also determine in which spatial directions and with how many further joining parts a gable connection can be established. In an embodiment of the gable-connectable joining part according to the invention, which can be combined with any of the embodiments yet to be mentioned and those already mentioned, provided there is no contradiction thereto, _{the at least one negative gable-shaped section representing a recess and/or the at least} one positive gable-shaped _{section representing a projection are arranged along part of the periphery or along} the entire periphery of the gable-connectable joining part _{. An arrangement is given in particular along one,} two, three or four of the side lengths of a gable-connectable joining part with a quadrangular, in particular rectangular or square shape in plan view. Furthermore, an arrangement, in particular along at least the periphery of a circular sector, in particular along the periphery of all circular sectors, of a gable-connectable joining part with a round shape in _{plan view is provided. Such a gable-connectable joining part} has, in particular, between 2 and 8 circular sectors, which are preferably of equal size. P220116 PCT The yet further object of an aspect of the present invention of providing a method for producing a gable-connectable joining part is achieved by a method according to claim 20. Said method comprises the steps, preferably carried out in the order mentioned: - _{providing a three-dimensional object,} in particular a concrete slab, furthermore in particular an FRC slab, furthermore in particular a CPC slab, as a joining part blank, wherein the three-dimensional object has the dimensions height, width and thickness, where the thickness has the smallest extent of the three dimensions; - _{forming the negative gable-shaped section or the positive gable-shaped section by} severing a part of the joining part blank along its thickness, in particular severing by at least one of the following techniques: water jet cutting, CNC milling, sawing with a wide, preferably at least 20 mm wide saw blade. Waterjet cutting, for example, offers the advantage that the joining surfaces automatically _{acquire a surface roughness with unevenness in the range of 1 µm to 10 mm. Sometimes, the porosity of the concrete is sufficient to achieve an unevenness that allows sufficient adhesion,} or "jamming," of the filler to the joining surfaces. When sawing with a wide saw blade, the P220116 PCT In this work step, not only the gable-shaped sections are obtained, _{but also inclined planes representing at least part} of the joining surfaces. In an embodiment of the method according to the invention, which can be combined with any of the embodiments yet to be mentioned and those already mentioned, provided that _{they do not contradict this, the method comprises the step of surface treatment of at least part} of the joining surface. The joining surface is created by separating a part of the joining part blank along its thickness. The surface treatment is carried out in particular by means of sandblasting. This _{achieves a surface roughness with unevenness in the order of 1 µm to 10 mm. The yet further object of an aspect of the present invention of providing an alternative method for joining parts is achieved by a} method according to claim 22. The method comprises the steps, preferably carried out in the given order: _{- providing a first gable-connectable joining part according to the invention} , which _{has at least one negative gable-shaped section; - Providing a second gable-connectable joining part according to the invention} , which _{has at least one positive gable-shaped section, wherein the} P220116 PCT negative gable-shaped section and the positive gable-shaped section are designed to be complementary in such a way that the positive gable-shaped section can at least partially protrude into the negative gable-shaped section; _{- at least partially introducing the positive} gable-shaped section of the second joining part into the negative gable-shaped section of the first joining part in such a way that one or more joints are formed between at least part of the joining surface of the negative gable-shaped section and part of the joining surface of the positive gable-shaped section; _{- at least partially filling the one or} more joints (20) with a filler. _{The further object of a further aspect of the present invention of providing a use} of a gable joint for connecting joining parts is achieved by a use according to claim 23. _{Said use comprises the use of a gable joint according to the invention for connecting or} joining at least two joining parts, which joining parts _{are in particular concrete joining parts, further in particular FRC joining parts, and preferably CPC joining parts.} P220116 PCT The yet further object of a further aspect of the present invention of providing a multi-part component is achieved by a multi-part component according to claim 24. _{Said multi-part component, which is in particular a multi-part concrete component, has at least one} gable connection according to the invention or comprises at least two gable-connectable joining parts according to the invention. _{Exemplary embodiments of the present invention are} explained in more detail below with reference to figures. Fig. 1 shows a gable connection according to the invention between two joining parts; _{Fig. 2 shows an enlarged section of the} gable connection according to the invention from Fig. 1; Fig. 3 shows an embodiment of a gable connection according to the invention between two joining parts with definitions of the dimensions; Fig _{. 4a shows an enlarged section of a} gable connection according to the invention; _{Fig. 4b shows a section AA through the section according to} Fig. 4a; Fig. 5a shows a gable connection of two joining parts according to the invention; P220116 PCT Fig. 5b shows an enlarged section of the gable connection according to the invention as shown in Fig. 5a; Fig. 5c shows a section AA through the section according to Fig. 5b; _{Fig. 6 shows an embodiment of a gable} connection according to the invention between two joining parts; Fig. 7 shows an embodiment of a gable connection according to the invention between two joining parts; Fig. 8 shows an embodiment of a gable connection according to the invention between two joining parts; Fig. 9a shows a longitudinal section through a test part having gable connections according to the invention; Fig. 9b shows a cross-section through a test part having gable connections according to the invention; Fig. 9c shows a schematic plan view of a section of a first test part having gable connections according to the invention; Fig. 9d shows a schematic plan view of a section of a second test part having gable connections according to the invention. Fig. 9e Results of a 3-point bending test performed on the first and second test pieces according to Fig _{. 9c and Fig. 9d;} Fig. 10 a schematic plan view of a section of several joining parts joined using gable joints according to the invention; P220116 PCT Fig. 11 shows an embodiment of a gable connection according to the invention between two joining parts; Fig. 12 shows a multi-part concrete component according to the invention; Fig. 13 shows an embodiment _{of a gable connection according to the invention between two joining parts; Fig. 14 shows} an embodiment of a gable connection according to the invention between two joining parts; Fig. 15 shows an embodiment of a gable connection according to the invention between two joining parts. _{Figure 1 shows a schematic plan view of a} gable connection according to the invention between a first joining part 11 and a second joining part 12. Of the two _{joining parts 11, 12, only the part is shown} which contributes to the gable connection illustrated in Fig. 1. Both joining parts 11, 12 have a gable-shaped section, wherein the two gable-shaped sections intended for interaction are designed to match one another in such a way that one gable-shaped section (here of the joining part 12) _{represents a positive gable-shaped section, i.e., is a} projection, while the other gable-shaped section (here of the _{joining part 11) represents a negative gable-shaped section} , i.e., is a recess. The negative gable-shaped section of the first joining part 11 and the positive gable-shaped section of the second joining part 12 _{are, albeit with play, designed to be joined together without} P220116 PCT Aids, i.e., taken on their own, neither form a positive _{nor a frictional connection, are designed complementarily to one another . The negative gable-shaped section of the} first joining part 11 is larger than the positive gable-shaped section of the second joining part 12. In the embodiment shown, both gable-shaped sections each have 4 steps. The four steps to the left of the first joining part 11 are provided with the reference symbols 30, 30', 30'' and 30'''. The negative gable-shaped section (here of the first joining part 11) is dimensioned such that it can at least partially or even completely accommodate the positive gable-shaped section (here of the second joining part 12). However, to form the gable joint according to the invention, the negative and positive gable-shaped sections are not aligned with each other in such a way that the joining surfaces of the gable-shaped sections directly adjoin or come into contact with each other along their entire length. Rather _{, a gap must still exist between at least a portion of the joining surface of the negative gable-shaped section and a portion of the joining surface of the positive gable-shaped section after alignment, which in turn} forms a joint 20 that can be filled with a filler to create a material connection (and thus ultimately also a positive connection) between the first joining part 11 and the second joining part 12. P220116 PCT _{Figure 2 shows an enlargement of the section of the gable joint according to the invention shown in Figure 1 in a} dashed rectangle _{. It shows the first} joining part 11, the second joining part 12, and the joint 20, bounded by the joining surface of the negative gable-shaped section of the first joining part 11 and the joining surface of the positive gable-shaped section of the second joining part 12. The microstructure of the joining surfaces of the gable-shaped sections is clearly visible in the enlargement. The _{surface of the joining surfaces is not smooth, but rough.} The structural irregularities range in size from micrometers to millimeters, for example, between 1 µm and 10 mm. This unevenness or roughness is sufficient to achieve a particularly strong connection between the first joining part 11 and the second joining part 12 by filling the joint 20 with a filler, such as mortar. Figure 3 shows a schematic plan view of a gable connection according to the invention of a first joining part 11 and a second joining part 12 _{, comparable to the gable connection shown in Fig. 1. Also shown in Fig. 3 are parameters of the gable connection and its} components: first joining part 11, second joining part 12, and _{the joint 20, which is later filled with filler material. These} parameters are used below to describe in more detail a selection _{of possible gable connections according to the invention} . Among other things, the width of the first step of the gable of the first joining part b _11-1 , the P220116 PCT Width of the first step of the gable of the second joining part b12-1, the width of the second left-hand step of the gable of the second joining part _b12-2l , the width of the second _{right-hand step of the gable of the second joining part b12-2r, the width of the third step of the gable of the first joining} part _{b11-3l, the width of the third right-hand step of the gable of the first joining part b11-3r, the width of the joint of the} third left-hand step bf _-3l , the width of the entire gable joint bg, the height of the third right-hand step of the first joining part h11-3r, the height of the fourth right-hand step of the second joining part _h12-4l , the height of the entire gable joint hg, the height of the entire gable joint without joint _hgof , the angle of the third _{left-hand step of the Gable of the second joining part α12-3l} and the angle of the first right-hand step of the gable of the first joining part _α11-1r . In the embodiment shown, the width of the first step of the gable of the first joining part _b11-1 , for example, is 30 mm, which is 10 mm wider than the width of the first step of the gable of the second joining part b12-1, which is 20 mm. The remaining _{steps of the gable of the second joining part (represented} by b12-2l and b12-2r) are all identically wide, with a _{width of 10 mm, and are thus only half as wide as the first step of the second joining part. The remaining steps –} except for the last step, here the fourth step – of the gable of the first joining part (represented by b _11-3l and b 11-3r) are all identically wide _{, also 10 mm wide. The width of the last step of the} gables can vary considerably and depends, among other things, on whether several gable connections are adjacent to each other. P220116 PCT or not. In the example shown, one can already see a further gable connection to the right and left of the gable connection described in more detail here, so that the neighboring gable connections share the last step, so to speak. The width of the fourth step of the _{second joining part assigned to the gable connection described in more detail is, as already mentioned, 10 mm, but the assigned width of the fourth step of the first joining part is only 5 mm and is therefore, if the width of the} right and left steps of this first joining part is added together, exactly 10 mm less wide than the first step of the first joining part is wider than the first _{step of the second joining part. In the embodiment shown here,} there is mirror symmetry between the left and _{right sides of the two gables. The total width} b _g of the gable connection, which is _{derived from the width of all steps of the first joining part or from the width of all steps of the second joining part, is therefore 100 mm. The angle of the third left-hand step of the gable} of the second joining part α12-3l, together with the angle of the first right-hand step of the gable of the first joining part α11-1r, represents all angles of any _{step and is 90°. The height of the third right- hand step of the gable of the first joining part h11-3r and the height} of the fourth left-hand step of the gable of the second joining part _h12-4l represent the height of all _{steps and is 10 mm. From the geometry already described, it can} be deduced that the height of the joint, shown here as an example using the height of the joint of the third left-hand step hf _-3l , which corresponds to the distance between the width of the third P220116 PCT Left-hand step of the first joining part 11 and the width of the third left-hand step of the second joining part 12 _{, is a constant 5 mm. The same applies to the} constant width of the joint of 5 mm, shown here as an example using the width of the joint of the third left- _{hand step bf-3l, which corresponds to the distance between the height of the third left-hand step of the first joining part 11 and the height of the} third left-hand step of the second joining part 12. _{From this, a height of the entire gable connection hg of 45 mm and a height} of the entire gable connection without the joint h _gof of 35 mm can be derived. Also shown is the overlap height of the _{joint, shown here as an example using the overlap height of the} joint of the third left-hand step hfue-3l, which corresponds to the height of the third left-hand step of the first joining part 11 minus the height of the joint of the third left-hand step hf-3l. Fig. 4a shows an enlarged section of a gable joint according to the invention. The viewing direction is perpendicular to the top side of the joining parts 11, 12. The section can be located in a similar way to the section shown in Fig. 1, but the section of Fig. 4a is taken from a gable connection which differs from the gable connection shown in Fig. 1 at least in that the joining surfaces of the first joining part 11 and the second joining part 12 do not run orthogonally to the top side and the bottom side of the joining parts 11, 12, but form an inclined plane P220116 PCT The cross-section thus reveals a wedge shape. Both the upper outer edge 120a and the lower outer edge 120b of the second joining part 12 are visible, because _{their "wedge" becomes increasingly thicker in the plan view shown into the image plane} , i.e., from top to bottom, thus the inclined plane inclines toward the upper outer edge 120a. For the first joining part 11, only the upper outer edge 11a is visible in the plan view shown. In order to still be able to depict the wedge shape, which tapers into the image plane here, i.e., from top to bottom, the lower outer edge 110b of the _{first joining part 11 has been drawn in dashed lines. The} joining surface of the first joining part 11 is also an inclined plane. However, instead of a "positive" inclined plane like the joining surface of the second joining part 12, it could be described as a "negative" inclined plane, since here the upper outer edge 110a represents an overhang relative to the lower outer edge 110b. To obtain an inclined plane as a joining surface, the upper and lower outer edges of the same joining part are not congruent. The joint 20 is shown between the first and second joining parts 11, 12. Fig. 4b shows a section AA through the section according to _{Fig. 4a. As already described, both the joining surface} of the first joining part 11, which _{is located between the upper outer edge 110a and the lower outer edge 110b, and the joining surface of the second joining part 12, which} is located between the upper outer edge 120a and the lower P220116 PCT Outer edge 120b is an inclined plane, i.e. a plane that is not orthogonal to the top and bottom of the joining part. This results in _{a wedge shape in cross-section. The joining surface of the first} joining part 11 runs at an angle β ₁₁₀ , the joining surface _{of the second joining part 12 runs at an angle β 120 . The} angles β 110 and β 120 are usually 90-100°, in particular 90-95°, and are 92° in the example shown here. An offset of the upper outer edge to the lower outer edge of 1-2 mm across the joining surface is sufficient to enable reliable joining of the joining parts, _{even if there is no microstructure or rough surface} on the joining surface and the joining surfaces _{accordingly have a smooth surface.} Care _{must be taken to ensure that the angles are not too large, as} reliable joining or joining at all is then no longer possible. The upper outer edge of one joining part and the lower outer edge of the other joining part should preferably not _{overlap in the joined state in plan view. The joining parts 11, 12 are} three-dimensional objects with the dimensions height, width, _{and thickness, of which the thickness d11 of the first joining part and the thickness d12 of the second joining part are shown. The} thickness usually has the smallest extent of the three dimensions and is the dimension along which the joining surfaces 110, 120 extend. Fig. 5a shows a schematic plan view of a gable connection according to the invention between two joining parts, the P220116 PCT differs from the gable joint shown in Fig. 1 at least in that the joining surfaces of the first joining part 11 and the second joining part 12 do not run orthogonally to the top and bottom of the joining parts 11, 12, but rather represent an inclined plane. The cutout is located at a different location compared to the gable joint in Fig. 1. The joining surface of at least one of the joining parts can additionally be at least partially rough, i.e., its surface can have a roughness, for example, in the order of 1 µm to 10 mm. Fig. 5b shows the section of the gable joint according to the invention shown in Fig. 5a _{, enlarged and viewed perpendicular to the top side} of the joining parts 11, 12. It can be seen that the joining surfaces of the first joining part 11 and the second joining part 12 represent inclined planes, with the joining surface of one joining part running essentially parallel to the joining surface of the other part. A wedge shape is thus evident in cross-section AA. Both the upper outer edge 120a and the lower outer edge _{120b of the second joining part 12 are visible across the entire first step 30 and the width of the second step 30', because the "wedge" there becomes increasingly thicker in the plan view shown} into the image plane, i.e., from top to bottom, thus the inclined plane slopes toward the upper outer edge 120a. In the first joining part 11, only the upper P220116 PCT Outer edge 110a can be seen in the top view shown. In order to still be able to depict the wedge shape there, which tapers into the image plane, i.e., from top to bottom, the lower outer edge 110b of the first joining part 11 has been drawn in dashed lines. The joining surface of the first joining part 11 is also an inclined plane, but _{instead of a "positive" inclined plane, like the joining surface of the second joining part 12, it could be described as a "negative" inclined} plane across the entire first step 30 and the width of the second step 30', since here the upper outer edge 110a represents an overhang relative to the lower outer edge 110b. _{From the width of the second step 30' of the first joining part 11 to its height, the inclination of the inclined plane then reverses} , meaning that the _{lower outer edge 110b is also visible along the height, and the inclined plane becomes the "positive" inclined plane. The "wedge" there becomes increasingly thicker in} the top view shown, i.e., from top to bottom, as it enters the image plane. From the width of the second step 30' of the second joining part 12 to its height, the inclination of the inclined plane also reverses, meaning that the lower outer edge 120b is no longer visible along the height, and the inclined plane becomes the "negative" inclined plane. The "wedge" there becomes increasingly narrower in the top view shown, i.e., from top to bottom, as it enters the image plane. The transition from a "negative" to a "positive" inclined plane or from a "positive" to a "negative" inclined plane can, for example, occur from one step to another, but can also, as shown here, from the width to the height of one and the same P220116 PCT step. In general, in order to obtain an inclined plane as a joining surface, the upper and lower _{outer edges of the same joining part must not be congruent.} In the embodiment shown in Fig. 5b, the joining surfaces on the left and right sides behave identically, i.e. are mirror-symmetrical. However, it is also possible that, for example, the joining surface along the width, along the height or along the width and height of a specific step only _{represents a negative inclined plane on one side of the gable-shaped section of the} first joining part 11, but the joining surface along the width, along the height or along the width and height of the same specific step on the other side of the gable-shaped section of the first joining part 11 represents a positive inclined plane. For the second joining part 12, the situation is exactly the other way around in order to maintain the parallelism of the aligned joining surfaces. To simplify the manufacture of the joining parts, the joining surface along the first step can, for example, be simply orthogonal rather than an inclined plane. Between the sections of the joining surface formed as inclined planes, there can also be sections that are not designed as inclined planes, i.e., are simply orthogonal, for example, between a change in the inclination of the inclined plane (i.e., a change in the design of the joining surface from a "negative" inclined plane to a "positive" inclined plane and vice versa). For the stability of the gable connection, it can be advantageous if the inclined planes alternate. occur, be it from adjacent step to adjacent step or with a change within the steps from their width to their height. The alternation can also be advantageous on a larger scale, _{i.e. the gable-shaped sections are - referenced to the overall height of the gable-shaped section - divided into a} first, preferably terminal, and a second, preferably terminal, area, with the first and second areas differing in the inclination of the inclined plane. The separation of the first and second _{areas can, for example, run approximately along half the overall height} of the gable-shaped section, _{but can also be achieved by a third area whose joining surface} is not designed as an inclined plane. Referencing the total height of the gable-shaped section, all three areas can, for example, be the same size and thus make up approximately 1/3 of the total height of the gable-shaped section. However, the third area can also be twice as large as the first and second areas, so that they each only _{account for approximately 1/4 of the total height of the gable-shaped section. For} an 8-step fork-shaped section, for example, the joining surfaces of the first two steps would be designed as "negative" inclined planes, the bottom two steps as "positive" inclined planes, and the four in between would again be "neutral," i.e., not designed as inclined planes. It can also be advantageous if, in a gable-shaped section, the ratio of the joining surface designed as an inclined plane in one direction (e.g., a "positive" inclined plane) to the joining surface P220116 PCT designed as an inclined plane in the other direction (e.g. "negative" inclined plane) is essentially balanced. Essentially balanced does not strictly correspond to a ratio of 50:50, but can also easily extend to 40:60, for example. In the embodiment shown, the joining surfaces along the width and height of the first and second steps 30, 30' are designed as inclined planes. However, this is not a must; for example, only the joining surface along the height or along the width of each step can be designed as an inclined plane, the other part doing without an inclined plane. The joint 20 is shown between the first and second joining parts 11, 12. Fig. 5c shows a section AA through the section according to Fig. _{5b. As already described, both the joining surface of the} first joining part 11, which is located between the upper outer edge 110a and the lower outer edge 110b, and the joining surface of the second joining part 12, which is located between the upper outer edge 120a and the lower outer edge 120b, are inclined planes, i.e., a plane that is not orthogonal to the top and bottom of the joining part. This results in a wedge shape in cross-section. The joining surface of the first joining part 11 extends at an angle β110, while the joining surface _{of the second joining part 12 extends at an angle β120. The} angles β110 and β120 are typically 90-100°, in particular 90-95°, and are 91° in the example shown here. P220116 PCT Fig. 6 shows a schematic plan view of an embodiment of a gable joint according to the invention _{between two joining parts. Compared to Fig. 3, the shape of the positive and negative gable-shaped sections is more pointed or steeper. The height of the entire} gable joint hg is identical to the embodiment shown in Fig. 3, but the width of the entire gable joint bg is significantly narrower. The number of steps 30, 30', 30'', 30''' is also four, but _{these are narrower (e.g., by 50% compared} to Fig. 3), as can be seen from the parameters b11-1, b12-1, b12-2l, and _b11-3r . Apart from the first step of the negative gable-shaped section of the first joining part 11, the width of the steps 30', 30'', 30''' of the gable-shaped section of each joining part 11, 12 is identical, i.e. the width on the left and right sides is also _{identical. If one compares the width of these steps of the} negative gable-shaped section of the first joining part 11 with the positive gable-shaped section of the second joining part 12, they can be the same width, but do not have to be. If these steps of the negative gable-shaped section of the first joining part 11 are wider than these steps of the positive gable-shaped section of the second joining part 12, the joint 20 becomes wider with each additional step. If these steps of the negative gable-shaped section of the first joining part 11 are narrower than these steps of the positive gable-shaped section of the second joining part 12, the joint 20 becomes _{narrower with each further step until the distance between the joining surfaces} P220116 PCT _{perhaps no joint formation at all. The height} of the steps can be uniform, as is _{the case in the embodiment of this figure. Both the right and left sides of the negative and positive gable sections have an identical height, but equally the negative and positive gable sections also have} an identical _{height to each other (illustrated by h12-4l and h11-3r). The} angles of all steps of each gable section are orthogonal (illustrated by α12-3l and α11-1r). In the embodiment shown, the entire surface of the joining surface of the negative and positive gable sections has unevenness in the order of 1 µm to 10 mm (not shown). In addition to or instead of the unevenness, it is also possible for the aligned joining surfaces of the negative and positive gable-shaped sections to represent planes that are essentially parallel to one another and inclined relative to the upper side of the joining parts. Fig. 7 shows a schematic plan view of an embodiment of a gable connection according to the invention _{between two joining parts. Since the height of each step 30 to} 30'''''' is identical, be it from the right and left side of a gable-shaped section or from the positive gable-shaped section of the second joining part 12 and the negative gable-shaped section of the first joining part 11, only the height h11-3r is symbolically _{shown. The same applies, except for the width of the} P220116 PCT first step of the negative gable-shaped section of the first joining part, for the width of each step, so that this width is symbolized by the width b _11-3r . What is special about this embodiment is that it is not only "steeper," as, for example, the embodiment shown in Fig. 3, but also comprises not just four, but eight steps 30 to 30'''''' per gable-shaped section. This is achieved by not only reducing the width of the individual steps, but also _{reducing their height while maintaining a substantially} constant overall width b _g and overall height h _g . The angles of all steps of each gable-shaped section _{are orthogonal (illustrated using α11-1r). A joint 20 is formed between} the joining surfaces, which can be filled with filler material (not shown). In the embodiment shown, the entire surface of the joining surface of the negative and positive gable-shaped sections has unevenness in the range of 1 µm to 10 mm (not shown). In addition to or instead of the unevenness, it is also possible for the aligned joining surfaces of the negative and positive gable-shaped sections to represent planes that are essentially parallel to one another and inclined relative to the upper side of the joining parts. _{Fig. 8 shows a schematic plan view of an} embodiment of a gable connection according to the invention between two joining parts, which embodiment differs exclusively from the embodiment shown in Fig. 7 P220116 PCT differs in that the angle of the steps is not orthogonal but greater than 90°, for example 95° _{(see α11-1r and α12-3l, which are identical in the example shown here). The height and width of the} steps, represented by h _11-3r and b _11-3r , remain unchanged in this exemplary embodiment compared to the embodiment in Fig. 7, so that as a consequence of the angulation only the overall width b _g of the gable connection becomes slightly smaller, but the overall height hg also remains unchanged. Fig. 9a shows a longitudinal section through a test piece 80 having gable connections according to the invention. The test piece 80 has a span of 2.30 m, with the force for the bending test being applied exactly in the middle of the span (see P/2) and the test piece 80 being supported essentially at the end of the span (see small triangles). The test part 80 comprises, in addition to _{a first joining part 11 and a second joining part 12, which are joined via gable connections according to the invention, longitudinal FRC (Fiber Reinforced Concrete) webs 85} , which are arranged orthogonally to the joining parts 11, 12 along the height of the joining parts via dovetail-like connections on the joining parts 11, 12. _{Regarding the arrangement of the FRC webs 85, reference is made to PCT/EP2019/073887, filed on September 6, 2019, and} published as WO 2021/043428 on March 11, 2021. For example, Fig. 4, along with the accompanying figure description, shows a CPC concrete slab as _{the base structure with two longitudinal FRC webs 85 (only} one visible in the longitudinal section). The P220116 PCT shown _{The test part 80 according to the invention differs} essentially from the embodiment of Fig. 4 of PCT/EP2019/073887 in that the basic structure is not formed by a one-piece CPC concrete slab, but is composed of two CPC concrete slabs, which serve as the first and second joining parts 11, 12 and which _{are joined via gable connections according to the invention. Also visible in the} longitudinal section are the supports 851 of the FRC webs, the recesses 852 of the FRC webs, and the extensions 854 of the supports of the FRC webs, with which the FRC webs _{are joined into the first and second joining parts 11, 12. The position of the gable connections 10 in the longitudinal section shown is indicated in a dashed rectangle .} Fig. 9b shows a cross-section through the _{test piece 80 already shown in Fig. 9a. Since the section passes through the first joining part 11, specifically at a point where the} joining part 11 has not yet been joined, the gable joints are not visible. However, the two longitudinal FRC webs 85 are clearly visible. The FRC web 85 and the first joining part 11 have a total height of 30 cm. The first joining part 11 and the (not visible) second joining part are each 1.2 m wide. Fig. 9c shows a schematic plan view of a section of a first test piece having _{gable joints according to the invention. The test piece comprises} a first joining part 11 and a second joining part 12. The _{first joining part 11 comprises five complete negative} P220116 PCT _{gable-shaped sections, each with five steps and, at each end,} another incomplete negative gable-shaped _{section, of which approximately the lowest to the two lowest outer steps are missing. The second joining part 12} comprises five complete positive gable-shaped sections, each with five steps and, at each end, another incomplete positive gable-shaped section, of which approximately the lowest to the two lowest _{outer steps are missing. The schematic plan view} shows a total of two of the five complete negative _{or positive gable-shaped sections, which join together to form two gable connections. The total width of each} complete gable connection is given as 17.91 cm, with the step width of the first step of the first joining part 11 being 4.03 cm and the step width of the first step of the second joining part being 3.00 cm, resulting in a joint width of 0.51 cm. The step width of the additional steps of the first and second joining parts 11, 12 _{is 1.5 cm. Further dimensions can also be seen in the figure. For example, the total height of the gable joint is 20.50 cm, with a step height of 4.0 cm and a joint height of 0.5 cm. The height and width of the steps} are not orthogonal to each other in plan view, but rather form an angle of 91.60°. Fig. 9d shows a schematic plan view of a section of a second test piece comprising gable joints according to the invention. The test piece comprises a first joining part 11 and a second joining part 12. The P220116 PCT The first joining part 11 comprises five complete negative _{gable-shaped sections, each with eight steps, and at each end} , a further incomplete negative gable-shaped _{section, of which approximately only the lowest step up to the two lowest inner steps are present. The second} joining part 12 comprises five complete positive _{gable-shaped sections, each with eight steps, and at each end} , a further incomplete positive gable-shaped section, of which approximately only the lowest step up to _{the two lowest inner steps are present. The} schematic plan view shows a total of one _{complete and one cut-away of the five} complete negative or positive gable-shaped sections, which join together in two gable connections (one of which is only partially shown). The total width of each complete gable joint is _{specified as 21.8 cm, with the step width of the first step of the first joining part 11 being 3.54 cm, and the} step width of the first step of the second joining part _{being 2.5 cm, resulting in a joint width of 0.52 cm.} Further dimensions can also be seen in the figure. For example, the total height of the gable joint is 20.50 cm _{, with a step height of 2.5 cm and a joint height of 0.5} cm. The height and width of the steps are not orthogonal to each other in the plan view, but form an angle of 92.50°. Fig. 9e shows the results of a 3-point bending test performed on the first and second test pieces according to Fig. 9c P220116 PCT _{or Fig. 9d. The diagram shows the force applied at point P/2 (see Fig. 9a) in kN and the resulting deformation in mm. The 8-step gable connection fails at a maximum force of 119.5 kN, while} the 5-step gable connection fails only at a _{maximum force of 126.6 kN. The 5-step} gable connection was slightly superior to the 8-step gable connection in another respect: the fracture at failure runs less along the joint of the gable connection, but more through the gable-shaped sections of the joining parts 11, 12 themselves. It is therefore the _{material that fails sooner and not the gable connection.} Fig. 10 shows a schematic plan view of a section of several _{joining parts 11, 12, 13 joined via gable} joints 10 according to the invention, which joining parts _{have geometries deviating from purely rectangular basic shapes in plan view. The joint} resembles a seam system, wherein the lower side of the first joining part 11 is "sewn" to a section of the upper side of the second joining part 12 via several gable joints 10 (for better clarity, only one of these is provided with a reference symbol) of different configurations _{, and the lower side of the third joining part 13 is "sewn"} to another section of the upper side of the second joining part 12 via several gable joints 10 (for better clarity, only one of these is _{provided with a reference symbol) of different configurations} . Along a portion of the further outer edges P220116 PCT of the first and third joining parts 11, 13 as well as along the remaining outer edges of the second joining part 12, further joining parts are joined via gable connections according to the invention. However, due to the selected section, these are not shown in full and are only represented by their _{negative or positive gable-shaped sections,} which interact with those of the first, second and third _{joining parts 11, 12, 13. As far as the} design of the gable-shaped sections is concerned, the majority correspond to seven-stepped _{gable-shaped sections, as shown, for example, in Fig. 7 or 8. Other gable-shaped sections taper significantly} less sharply, with a very wide first step and a total of only four steps. Still other gable-shaped sections are not complete gable-shaped sections, but are partially trimmed, whereby in the immediate vicinity of the interface of more than two panels, a gable shape is usually dispensed with and merely a straight cut is made. Since this affects a relatively small portion of the contact surface of the joining parts, it has no significant impact on the stability of the overall connection of the individual joining parts. Fig. 11 shows a schematic plan view of an embodiment of a gable connection according to the invention _{between two joining parts 11, 12 that are not mirror-symmetrical} . For example, the left side of the negative gable-shaped section of the first joining part 11 shows P220116 PCT as well as the left side of the positive gable-shaped section of the second joining part 12 each has four steps (30, _{30', 30'', 30'''), the respective right sides each comprise} eight steps. This asymmetry results in a _{different design of the joint 20 on the left side compared to the right side, with a different joint height and joint width.} Fig. 12 shows a schematic plan view of a _{multi-part concrete component according to the invention comprising} a total of five joining parts 11, 12, 13, 14, 15, of which the first joining part 11 is arranged centrally and is joined at the top, bottom, left and right with one joining part each 12, 13, 14, 15. The second joining part 12 has, for example, directly adjacent and neighboring negative gable-shaped sections, three of which are explicitly drawn. The third joining part 13, in turn, has alternating and directly adjacent negative and positive gable-shaped sections, three of which are also explicitly shown. The fourth joining part 14, in turn, has positive gable-shaped sections spaced apart from one another at different distances, three of which are explicitly shown. The distance between the adjacent gable-shaped sections is, for example, half the width of a gable connection up to, for example, one to two widths of a gable connection. The fifth joining part 15 has both negative and positive gable-shaped sections; however, these are not strictly alternately arranged, but rather directly adjacent to one another. P220116 PCT Fig. 13 shows a schematic plan view of an embodiment of a gable connection according to the invention _{between two joining parts 11, 12, between which a joint 20} is formed, which is filled with filler (not shown). Contrary to the _{embodiments shown so far, the surfaces that, in plan view, constitute} the height and width of the steps 30, 30', 30'', 30''' of the individual joining parts 11, 12 and _{serve as joining surfaces 110, 120, are not flat surfaces,} but curved surfaces. For the purposes of the invention, such geometries also count as steps. It is crucial _{that the gable-shaped sections become wider with each additional step} and thus _{represent a kind of "Christmas tree" in plan view.} The geometries _{defined based on the embodiments with steps formed from flat surfaces (whereby inclined flat surfaces having an angle β ≠ 90° are also} included, see, for example, Fig. 5a-5c) _{(see, for example, Fig. 3, 6, 8) can easily be transferred to the embodiment shown here with curved surfaces. Corresponding auxiliary lines (shown in dashed lines) are drawn for the first and second steps} 30, 30'. The auxiliary lines for defining the width of the individual steps are drawn, for example, parallel to the course of the side of the joining part on _{which the respective gable-shaped section is arranged. In terms of their height, these auxiliary lines are then drawn at the transition from one step to the other (see, for example, b11-2l , b12-2l} ). For the very first step, this auxiliary line is applied at the "highest" point of this step for positive P220116 PCT gable-shaped sections 12 or at the "lowest" point _{for negative gable-shaped sections 11 (see, for example, b11-1 ). The auxiliary lines for defining the height of the individual} steps correspond to the tangents created at the transition from _{each individual step to the adjacent step. The intersection point (in the plan view, these are actually two} planes and not straight lines, _{resulting in a straight line of intersection for the 3D joining part) specifies the respective end of the} auxiliary lines, which can be _used to further define the step geometry, such as the step height (see, for example, h11-2l _{and h12-2l) and the angle α (see, for example, α11-1r, α12-1r)} . _{In the embodiment shown, the angle α of the first and second joining parts on the left side is} , for example, optionally the same size; on the right side of the gable-shaped sections _{, the angle α of the first joining part 11 is, for example, optionally larger than the angle α of the second joining part 12, as a result of which the joint 20 is narrower on the right side. Thus,} even with curved surfaces as joining surfaces, the _{means already discussed in connection with the embodiments having flat surfaces as joining surfaces, such as, for example, unevenness, an angle α ≥ 90° and/or an angle β ≠ 90°, can be used.} Fig. 14 shows a schematic plan view of an embodiment of a gable connection according to the invention _{between two joining parts 11, 12, between which a joint 20} is formed, which is filled with filler (not shown). Contrary to the previously shown P220116 PCT In the embodiments, the surfaces which, in plan view, constitute the height and width of the steps 30, 30', 30'', 30''' of the individual joining parts 11, 12 and serve as joining surfaces 110, 120, are not flat surfaces, _{but wavy surfaces. Within the meaning of the invention, such geometries also count} as steps. The decisive factor is that the gable-shaped sections become wider with each additional step and thus _{represent a type of "Christmas tree" in plan view. The surfaces formed by the} steps, formed from the flat surfaces (whereby _{inclined flat surfaces having an angle β 90°} are included, see e.g. Fig. 5a-5c) defined geometries (see e.g. Fig. 3, 6, 8) can _{be easily transferred to the embodiment shown here with undulating surfaces. For the four steps 30, 30',} 30'', 30''' corresponding _{auxiliary lines (shown in dashed lines) are drawn in the plan view. The} auxiliary lines are straight lines that represent a center line, based on which the height (see e.g. h11-4l and h12-4l) and width (see e.g. b11-2l, b12-2l) of the _{steps as well as the angle α (see e.g. α11-1r, α12-2r, α11-3l,} α12-3l) can be read off. Since the joining parts 11, 12 are usually 3D objects, the auxiliary lines are strictly speaking auxiliary planes defined by mathematical averaging. In the embodiment shown _{, for example, the angle α of the first and second joining parts on the left side is} 90°, and thus the same size. On the right side of the gable-shaped sections, _{the angle α of the first joining part 11 and the second joining part 12 is greater than 90°. This also applies to corrugated surfaces.} P220116 PCT The joining surfaces can _{be made} using the _{means already discussed in connection with the embodiments having flat surfaces as joining surfaces, such as unevenness, an angle α ≥} 90°, and/or an angle β ≠ 90°. However, to qualify as wavy surfaces in the sense of the embodiment shown, the joining surfaces should have waves whose extent differs from the unevenness by a magnitude of, for example, 1 µm to 10 mm, in particular from 1 µm to 1 mm. Fig. 15 is a schematic plan view of an embodiment of a gable connection according to the invention _{between two joining parts 11, 12. The joining parts 11, 12 are} so-called FRC panels (FRC = Fiber Reinforced Concrete), i.e., concrete panels prestressed with fibers, between which a joint 20 filled with a filler, such as mortar, is formed. The course of the fibers (= reinforcements 40) within the concrete is indicated by dashed lines, since the reinforcements 40 themselves would not be visible from a bird's eye view. The gable-shaped sections of the joining parts 11, 12 each have four steps on the left and right hand side at 30, 30', 30'', 30''', where the angle α, shown as an example _{using the angles α11-3l, α12-3l, is 90° on the left hand side,} whereas on the right hand side the angle α, shown as an example using the angles _α11-1r , _α12-2r , is more than 90°, _{e.g. 95.0°. If one now compares the reinforcements 40} running in the first and second joining parts 11, 12 on the left hand side and on the right hand side, it can be seen that P220116 PCT _{On the right hand side, where the angle α is more than 90°, part of the reinforcements 40 are severed due to the} inwardly tapered joining surface formed by the height of the right-hand steps. Here, the aim is to find the optimal working range for the desired properties of the gable connection between the reinforcement spacing (= distance between adjacent fibers) and the angle α. Cutting the reinforcement weakens the joining part itself, but an angle α greater than 90° improves the hold between the joined _{parts. In the present exemplary embodiment, for example, it would} have been more advantageous to choose a somewhat smaller angle α, e.g., between 91°-91.5°, in order to prevent the now severed reinforcements 40 from remaining intact. In order to achieve fewer severed reinforcements 40, the height, width and/or number of steps can also be modified. List of reference symbols 1 _{0 Gable connection 11 First joining part 110 Joining surface of first joining part 110a Upper outer edge of first joining part 110b Lower outer edge of first joining part 12} Second joining part _{120 Joining surface of second joining part 120a Upper outer edge of second joining part 120b Lower outer edge of second joining part 13 Third joining part} P220116 PCT _{14 Fourth joining part 15 Fifth joining part 20 Joint 21 Filler 30 Step 40 Reinforcement 80 Test part 85 FRC web 851 Support FRC web 852 Recess FRC web 854 Extension support FRC web b Width} b11 Width of gable first joining part b ₁₂ Width of gable second joining part b _11-1 Width of first step of gable first joining part b _12-1 Width of first step of gable second joining part b _12-2l Width of second step left side of gable z _{second joining part b12-2r Width of second step right side of gable} second joining part b _{11-3l Width of third step left side of gable} first joining part b _{11-3r Width of third step right side of gable first joining part} b _g Width total Gable connection b _f-3l Width joint third step left side h _Height h11-3r Height third step right side Gable first joining part P220116 PCT h12-4l Height of fourth step, left side of gable, second joining part h _f-3l Height of joint, third step, left side h _fue Overlap height of joint hfue-3l Overlap height of third step, left side of gable h _g Total height of gable connection h _gof Total height of gable connection without joint d _{Thickness d11 Thickness of first joining part d12 Thickness of second joining part α Angle} α12-3l Angle of third step, left side of gable, second joining part α11-1r Angle of first step, right side of gable, first joining part β _Angle β ₁₁₀ Angle of the joining surface of the first joining part β ₁₂₀ Angle of the joining surface of the second joining part P220116 PCT

Claims

Patent claims _{1. Gable connection comprising a} negative gable-shaped section of a first joining part (11) with an upper side, said section representing a recess, and a positive gable-shaped section _{of a second joining part (12) with an upper side, said section representing a projection, wherein: - the negative gable-shaped section and the positive} gable-shaped section each comprise at least one step (30); _{- the negative gable-shaped section and the positive} gable-shaped section _{have joining surfaces (110; 120) aligned with one another along the at least one step (30)} ; _{- the negative gable-shaped section and the positive} gable-shaped section are designed to be complementary in such a way that the positive gable-shaped section can protrude at least partially into the negative gable-shaped section; _{- the positive gable-shaped section extends at least} partially into the negative gable-shaped section in such a way that one or more joints (20) are formed between at least a part of the joining surface (110) of the negative gable-shaped section and a part of the joining surface (120) of the positive gable-shaped section; _{- the one or more joints (20) are at least partially} filled with a filler; P220116 PCT characterized in that _{- at least part of the surface of the joining surface (110;} 120) of the negative and the positive gable-shaped section _{has unevenness in the order of magnitude of 1 µm to 10 mm; and/or - at least one of the at least one step (30) of the} first joining part (11) and/or at least one of the at least one step (30) of the second joining part (12), _{which at least one step (30) of the first joining part} (11) or of the second joining part (12) has _{a width (b11-1, b11-3l, b11-3r, b12-1, b12-2l, b12-2r ), a height (h12-4l, h11-3r) and an angle α (α12-3l, α11-1r ), which angle is α ≥ 90°, in particular α > 90°, further in particular 90° < α ≤ 110°, such that the height and width of the at least one step (30) are not orthogonal to one another, and the at least one step (30)} tapers along its height and with increasing distance from the width. _{2. Gable connection according to claim 1, wherein the} mutually aligned joining surfaces (110, 120) of the negative and positive gable-shaped sections at least partially represent planes that are substantially parallel to one another and inclined relative to the upper side of the joining parts. P220116 PCT _{3. Gable connection according to claim 2, wherein the negative} gable-shaped section and the positive gable-shaped section each comprise at least a first and a second step (30, 30'), which, viewed from the top side of the first joining part (11) or the second joining part (12), have a width (b _11-1 , b _12-1 ) or a left width (b 12-2l) and a right width (b 12-2r) and a left height _{and a right height, wherein the inclined planes relative to the} top side of the joining parts are arranged along at least one of the following: _{- the width (b 11-1, b 12-1) of the first step (30); - the left width (b 12-2l) and/or the right width} (b _12-2r ) of the second step (30'); _{- the left height and/or the right height of the first} step (30); _{- the left height and/or the right height of the second} step (30'). _{4. Gable connection according to claim 2 or 3, wherein the} mutually aligned joining surfaces (110, 120) of the negative and positive gable-shaped sections represent at least two pairs of partially substantially parallel planes inclined relative to the upper side of the joining parts, and wherein, in particular, the inclined planes of one pair are oriented opposite to the inclined planes of the other pair. P220116 PCT _{5. Gable connection according to one of claims 2 to 4,} wherein the mutually aligned joining surfaces (110, 120) of the negative and the positive gable-shaped section represent an even number of pairs of partially mutually substantially parallel, inclined planes relative to the upper side of the joining parts, and wherein the inclined _{planes of one half of the pairs are aligned opposite to the inclined planes of the other half of the pairs} , in particular alternately such that the inclined planes of adjacent pairs are aligned opposite. _{6. Gable connection according to one of the preceding claims, wherein the at least one step (30) of the first joining part (11) and the at least one step (30) of the second joining part (12) have, viewed from the top side of the first} joining part (11) or the second joining part (12), a width (b _11-1 , b _12-1 ) or a left width (b 11-3l, b 12-2l) and a right width (b 11-3r, b 12-2r) and a left height (h 12-4l) and a right height (h 11-3r), _{wherein the unevennesses are formed on at least one} of the following: _{- the surface of the joining surface (110) of the negative} gable-shaped section, which surface extends along the _{one width (b 11-1) or the left width (b 11-3l) and/or} the right width (b _11-3r ) which extends over at least one step (30); _{- the surface of the joining surface (110) of the negative} gable-shaped section, which surface extends along the P220116 PCT _{left height and/or the right height (h11-3r) of the} at least one step (30); _{- the area of the joining surface (120) of the positive gable-shaped section, which surface extends along} one width ( _b12-1 ) or the left width ( _b12-2l ) and/or the right width ( _b12-2r ) of the at least one step (30); _{- the area of the joining surface (120) of the positive gable-shaped section, which surface extends along the} left height (h12-4l) and/or the right height of the at least one step (30). _{7. Gable connection according to one of the preceding claims, wherein the positive gable-shaped section comprises n steps (30), wherein n is a natural number, a} number in particular from 2 to 20 inclusive, further in particular from 4 to _{12 inclusive, and further in particular from 5 to 9 inclusive. 8. Gable connection according to claim 7, wherein the positive} gable-shaped section projects into the negative gable-shaped section in such a way that at least n/2 _{of the n steps (30) of the positive gable-shaped section,} in particular at least 3/4 n of the n steps (30) of the _{positive gable-shaped section and further in particular n-1 of the n steps (30) of the positive gable-shaped} P220116 PCT _{Section protrudes completely into the negative gable-shaped} section. _{9. Gable connection according to claim 8, wherein n-1 of the n} steps (30) of the positive gable-shaped section protrude _{completely into the negative gable-shaped section} and the lowest one step (30) of the positive gable-shaped section protrudes at least partially _{into the negative gable-shaped section, in particular to half its height and further in particular to 3/4 of its height} . _{10. Gable connection according to one of the preceding} claims, wherein the gable connection _{has a total width (bg) and a total height (hg), wherein the} total height ( _hg ) is greater than the total width ( _bg ), _{in particular by a factor of 1.05 to} 5 inclusive, further in particular by a factor of _{1.05 to 3 inclusive, further} in particular by a factor of 1.05 to 2 inclusive. _{11. Gable connection according to one of the preceding claims, wherein the first joining part (11) and the second joining part (12) are three-dimensional objects with} the dimensions height (h), width (b) and thickness (d), in which the thickness (d) _{has the smallest extent of the three dimensions and the joining surfaces (110, 120)} P220116 PCT _{extend along the thickness (d) and/or wherein} the first joining part (11) and the second joining part (12) are concrete slabs, in particular CPC slabs. 12. Gable connection according to one of the preceding _{claims, wherein a continuous joint (20) is formed between the joining surface (120) of the} positive gable-shaped section and the joining surface (110) of the negative gable-shaped section _{. 13. Gable connection according to one of the preceding} claims, wherein the overlap height of the joint (hfue-3l) of the at least one step (30), which results from the _{height of the at least one step of the first joining part (11)} less the height of the joint (hf-3l) of the at least one _{step, is at least equal to or, in particular, by a factor of 1.5 to 5.0 inclusive, further in particular by a factor of 2.0 to 3.0 inclusive, or even of 3.0 to 4.0 inclusive, greater than the} width of the joint (bf-3l) of the at least one step (30). _{14. Gable connection according to one of the preceding claims, wherein at least one of the following is fulfilled} : _{- the negative gable-shaped section and the positive} gable-shaped section have the same number of steps _(30); P220116 PCT _{- the negative gable-shaped section and/or the positive gable-shaped section are mirror-symmetrical} . _{15. A gable-connectable joining part, in particular in the form of} a concrete slab, further in particular in the form of an FRC _{slab, with an upper side having at least one} negative gable-shaped _{section representing a recess or at least one} positive gable-shaped section representing a projection, wherein: _{- the negative gable-shaped section or the positive} gable-shaped section comprises at least one step (30), in particular including 2 to 20, further in particular including 4 to 12, and again further in particular _{including 5 to 9 steps; and - the negative gable-shaped section or the positive} gable-shaped section has a joining surface (110; 120) along each of the at least one step (30); characterized in that _{- at least a part of the surface of the joining surface (110; 120) of the negative or the positive gable-shaped} section has unevenness in the order of magnitude of 1 µm to 10 mm; and/or _{- at least one of the at least one step (30) has, viewed from the top side of the joining part, a width (b11-1} , b11-3l, b11-3r, b12-1, b12-2l, b12-2r), a height (h12-4l, h11-3r) _{and an angle α (α12-3l, α11-1r), which angle α} P220116 PCT ≥90°, so that the height and width of the at least one step (30) are not orthogonal to one another, and which angle α _{is in particular 90°< α < 110°, so that the at least} one step (30) tapers along its height and with increasing distance from the width; and/or _{- the joining surface (110, 120) of the negative or} positive gable-shaped section at least partially represents _{a plane inclined relative to the upper side of the joining part} . _{16. Gable-connectable joining part according to claim 15, wherein} the joining surface (110, 120) of the negative or the positive gable-shaped section at least partially _{represents two planes inclined relative to the upper side of the joining part and the negative or positive gable-shaped section comprises at least two steps (30, 30') which,} viewed from the upper side of the joining part (11; 12), have a width (b _11-1 , b _12-1 ) or a left width (b _12-2l ) and a right width (b 12-2r ) and a left height and a right height, wherein the _{planes inclined relative to the upper side} of the joining part are arranged along at least one of the following: _{- the width (b 11-1 , b 12-1 ) of the first step (30); - the left width (b12-2l) and/or the right width} (b12-2r) of the second step (30'); _{- the left height and/or the right height of the first} step (30); P220116 PCT _{- the left height and/or the right height of the second} step (30'); and/or wherein the at least two inclined planes have different inclinations, in particular _{inclinations in opposite directions;} and/or wherein the number of inclined planes with a first inclination and an opposite inclination is approximately identical; and/or wherein the inclined planes with a first inclination and an opposite inclination alternate. _{17. Gable-connectable joining part according to claim 15 or claim 16, wherein at least part of the surface of the} joining surface (110; 120) of the negative or positive gable-shaped section has unevenness in the order of magnitude of 1 µm to 10 mm and the negative or positive gable-shaped section comprises at least two steps (30, 30') which, viewed from the top side of the joining part (11; 12), have a width (b11-1, b12-1) or a left width (b12-2l) and a right width ( _b12-2r ) and a left height and a right height, _{wherein the unevenness is arranged along at least} one of the following: _{- the width (b11-1, b12-1) of the first step (30); - the left width (b12-2l) and/or the right width} ( _b12-2r ) of the second step (30'); _{- the left height and/or the right height of the first} step (30); P220116 PCT _{- the left height and/or the right height of the second} step (30'). _{18. Gable-connectable joining part according to one of the} preceding claims, comprising: _{- at least two negative gable-shaped sections representing a recess or at least two} positive gable-shaped sections representing a projection, wherein the at least two negative gable-shaped sections or the at least two positive gable-shaped sections are arranged directly adjacent to or at a distance from one another; _{- at least two negative gable-shaped sections representing a recess and at least one} positive gable-shaped section _{representing a projection, or at least one negative gable-shaped section representing a recess} and at least two positive gable-shaped sections representing a projection, wherein the negative gable-shaped sections and the positive gable-shaped section, or the negative _{gable-shaped section and the positive gable-shaped} sections, are arranged alternately and/or directly adjacent to or at a distance from one another. _{19. Gable-connectable joining part according to one of the preceding claims, wherein the at least one negative gable-shaped section representing a} recess _{and/or the at least one projection representing} P220116 PCT positive gable-shaped section _{are arranged along part of the} periphery or along the entire periphery of the gable-connectable joining part, in particular: _{- along one, two, three or four of the side lengths} of a gable-connectable joining part with a quadrangular, _{in particular rectangular or square, shape in} plan view; _{- along at least the periphery of one circular sector,} in particular along the periphery of all circular sectors, of a gable-connectable joining part with a round shape in plan view, wherein the gable-connectable joining part in particular has between 2 and 8 circular sectors, which are preferably of the same size. _{20. A method for producing a gable-connectable} joining part according to one of claims 15 to 19, comprising: _{- providing a three-dimensional object,} in particular a concrete slab, further in particular an _{FRC slab, as the joining part blank, wherein the three-dimensional object has the dimensions height (h), width} (b), and thickness (d), where the thickness (d) has the smallest dimension of the three dimensions; _{- forming the negative gable-shaped section or the positive gable-shaped section by separating a part of the joining part blank along its thickness (d),} in particular separating using at least one of the following techniques: water jet cutting, CNC milling, sawing with a wide, preferably at least 20 mm wide, saw blade. P220116 PCT _{21. A method for producing a gable-connectable} joining part according to claim 20, comprising: _{- surface-treating at least part of the} joining surface created by separating a part of the _{joining part blank along its thickness (d)} , in particular by sandblasting. _{22. A method for joining parts, comprising: - providing a first joining part (11) according to one} of claims 15 to 19, comprising at least one negative gable-shaped section; _{- providing a second joining part (12) according to one of claims 15 to 19, comprising at least one} positive gable-shaped section, wherein the negative gable-shaped section and the positive gable-shaped section are designed to be complementary such that the positive gable-shaped section can at least partially protrude into the negative gable-shaped section; _{- At least partially inserting the positive} gable-shaped section of the second joining part (12) into the negative gable-shaped section of the first joining part _{(11) such that one or more joints (20) are formed between at least a part of the} joining surface (110) of the negative gable-shaped section and a part of the joining surface (120) of the positive gable-shaped section; P220116 PCT _{- At least partially filling the one or} more joints (20) with a filler. _{23. Use of a gable joint according to one of claims 1 to 14 for connecting joining parts, in particular made of concrete, further in particular made of FRC} panels. _{24. Multi-part component, in particular concrete component,} comprising at least one gable joint according to one of _{claims 1 to 14 or comprising at least two gable-connectable joining parts according to one of claims 15 to} 19. P220116 PCT