EP3702551B1 - Use of a feedthrough for pouring and a feedthrough assembly - Google Patents

Description

The present invention relates to the use of a feedthrough and a feedthrough arrangement for casting into a potting material.

A wall or floor element is cast from the grouting material, typically concrete. In the course of this, the bushing is cast in, so that a pipe element of the bushing then keeps a passage opening between the opposite side surfaces of the wall or floor element. The casting material is poured into a formwork that defines one side surface of the wall or floor element (when casting a wall, the opposite side surface is usually also defined by a formwork, see below in detail).

The EP 0 300 210 A1 shows a pipe holder for encasing a protective pipe in concrete into a wall, which is attached with its base 1 to the inside of a formwork.

The EP 2 194 212 A1 shows a formwork box 1 with a housing 2 for casting in concrete, which can be attached to a formwork 19. At one end of the housing 2 there is an opening 5 through which the pipe 20 to be concreted can be inserted. This document discloses the generic terms according to claims 1 and 14.

The EP 0 275 113 A1 shows different versions of a wall duct for pipes and cables at different angles to the wall normal.

The DE 37 06 936 A1 shows a formwork box with externally mounted, projecting insertion openings 5, each of which is provided with removable end pieces.

The present invention is based on the technical problem of specifying an advantageous use.

This is achieved according to the invention with the use according to claim 1 and with an implementation arrangement according to claim 14. The pipe element of the bushing is cast obliquely into the wall or floor element, i.e. at an angle to a surface normal on the side surface. At an axial end of the tubular element, a hollow body is arranged, which is placed on the formwork before casting and then defines a cavity in the casting material at the axial end of the tubular element. This extends axially to the side surface of the wall or floor element, so to a certain extent represents an extension of the tubular element.

The cavity defined by the hollow body is also wider in relation to the inner diameter of the tubular element. This creates space for handling at the end of the tubular element; for example, a closure cap inserted into the tubular element during casting can be easily accessible. As discussed in detail below, after casting and stripping, for example, a cable can be laid through the pipe element and with a sealing system be sealed against the pipe element. The hollow body can also provide good accessibility for inserting or operating such a sealing system, see below in detail.

Preferred embodiments can be found in the dependent claims and the entire disclosure, which is to be read on both usage and device aspects, namely in any case implicitly refers to all claim categories. The disclosure also relates in particular to implementation arrangements or wall or floor elements that result from the use described.

The oblique course of the pipe element in the wall or floor element can be advantageous, for example, in that a line or a connected protective tube that is then routed through can also be brought to the wall or floor element at an angle, so that, for example, minimum bending radii are not exceeded . This can e.g. B. with regard to laying cables on the outside of the building, the cable does not have to be laid away from a branch with multiple changes in curvature or under very strong curvature. On the inside of the building, the sloping guide can be an advantage in terms of space requirements, for example; the sloping pipe can be used, for example. B. easier to lay along the wall or floor element.

The angle between the center axis of the pipe element and the surface normal can be, for example, at least 20° or 30°, with possible upper limits at e.g. B. at most 70° or 60°; Particularly preferred can be e.g. B. be around 45°.

Alternatively, it may seem easier at first glance to place a correspondingly slanted pipe element directly onto the formwork instead of the hollow body. However, this pipe end would then have an elliptical shape, and a correspondingly adapted closure cap would ultimately mean additional effort. The inventor's initial considerations also included placing a foam body on the tubular element instead of the hollow body. To get through However, if there is a cable, this would have to be removed, which means a lot of work and sometimes does not allow a clean connection to the wall or floor element, see below in detail.

The information “axial” and the “axial direction” refer to the center axis of the pipe element; The pipe opening of the pipe element extends along this. The tubular element can be rotationally symmetrical about the central axis and, in the preferred case of a circular cross section, rotationally symmetrical, so the central axis is a corresponding axis of symmetry. The distance from the center axis is taken in the distance directions perpendicular to the center axis; they correspond to the radial directions in the case of a circular shape. Unless explicitly stated to the contrary, “outwards” means away from the center axis, and “inwards” towards the center axis.

The hollow space is delimited by the hollow body to the outside, i.e. in the distance directions, at least over a circumferential angle range, and is not necessarily completely circumferential due to the oblique arrangement. In other words, the hollow body delimits the cavity in any case in those distance directions that point into the wall or floor element. By definition, the cavity should extend axially up to a plane in the side wall surface of the wall or floor element.

In a preferred embodiment, the hollow body has a flange with which it is placed on the formwork. In general, the hollow body “placed” on the formwork can rest directly on the formwork, i.e. on a formwork element or a formwork panel. On the other hand, a film (covering film), for example, can also be arranged between the hollow body and the formwork, which can, for example, temporarily close the cavity and is removed after demoulding. Such a film could, for example, be applied to the flange just mentioned. The laterally projecting flange can also be advantageous, for example, in that it creates a certain stabilization of the hollow body.

In a preferred embodiment, an attachment surface of the flange, with which it is pressed against the formwork or lies against it, has a width of at least 2 cm, with at least 3 cm, 4 cm or 5 cm being further, increasingly preferred in the order in which they are mentioned lower limits are. Possible upper limits can be, for example, a maximum of 40 cm, 30 cm or 20 cm. The width of the flange is taken in a plane containing the side surface, namely perpendicular to the length of the attachment surface. Along the length, it can, for example, result in the smallest dimension of the attachment surface. After demoulding and, if necessary, removing a cover film, the attachment surface of the flange is exposed facing away from the wall or floor element. It then lies in one plane with the side surface formed by the casting material.

A surface seal is preferably applied to this side surface, for example a thick bitumen coating. In this respect, the flange can advantageously enable such a surface seal to be worked on; this can be painted or glued onto the attachment section. This allows a good overlap with the surface sealing to be achieved, for example to ensure the tightness of the connection.

According to a preferred embodiment, the attachment surface of the hollow body is self-contained all around, i.e. it is provided continuously without interruption in relation to a revolution around the central axis of the tubular element. The hollow body can thus, for example, prevent penetration of grouting material or concrete or concrete milk on all sides. When pouring, a closure element is preferably placed on the attachment surface, which closes the cavity and is arranged between the formwork and the attachment surface, for example a thin plate or film. The attachment surface preferably has the width mentioned above over the entire circumference.

The hollow body and the tubular element are assembled, i.e. assembled as separately manufactured parts.

The bushing has a flange element which is arranged on the axial end of the tubular element. The flange element extends away from the pipe element in the distance directions, preferably completely circumferentially (in all distance directions). The flange element is placed on a bottom part of the hollow body, the latter delimits the cavity axially, and in the opposite direction it is open.

The tubular element can be constructed in several parts in the axial direction, i.e. composed of several tubular pieces. However, a pipe section of the pipe element arranged on the flange element is formed in one piece with the flange element, preferably monolithically (this pipe section can then form the pipe element on its own or together with other pipe sections). “One-piece” means that it cannot be separated from one another in a non-destructive manner, for example, manufactured as a two-component injection molded part or joined together. “Monolithic” means formed without material boundaries inside (apart from statistically distributed inclusions), for example injection molded as one component. The flange element is arranged axially at the end of the pipe element, which can simplify assembly on the formwork, for example in the case of a wall element (no recess required).

The combination of flange element and attached hollow body can be advantageous, for example, in that the smaller flange element sits stably on the pipe element of the bushing and can therefore also create a certain stability for the hollow body. The structure of assembled parts can also open up modularity; for example, an identical bushing can be installed in another application without a hollow body, for example. B. the local conditions do not require inclined cable routing. This means that the hollow body can open up different applications for one component (the bushing). Regardless of the installation situation of the bushing, with or without a hollow body, a cable can then be routed through it; The use of identical bushings can be advantageous in that the same sealing system is used to seal the bushing against the line can find application. The use of identical pipe elements creates a certain degree of universality (can be combined with identical closure caps/sealing systems); the combination with the hollow body opens up a certain degree of flexibility with regard to different applications.

Preferably, that bottom surface of the hollow body to which the flange element of the bushing is placed is flat, at least in some areas. This can create good contact between the flange element and the hollow body; the bottom part of the hollow body is preferably flat overall. The flange element is preferably inserted into the hollow body, i.e. arranged on the bottom surface of the hollow body facing the cavity.

In general, the bushing, in particular the tubular element, and the hollow body are preferably already fixed in position relative to one another when placed on the formwork, before casting, i.e. cannot be rotated, tilted or moved relative to one another; They are preferably fixed in position before or when they are attached to the formwork. According to a preferred embodiment, the hollow body has a pipe socket on the base part, and this pipe socket and the pipe element of the bushing are placed one inside the other. This can create stability; for example, it is possible to prevent the hollow body from tipping or slipping (also independent of any stabilization via a flange element of the bushing). The “being nested” means that one is arranged within the other (based on the distance directions), preferably the pipe element in the pipe socket. The pipe socket is provided in one piece, particularly preferably monolithically, with the rest of the hollow body, in particular with its base part (or also side walls and, if necessary, flange). The pipe socket can extend axially, for example, over at least 1 cm, 2 cm or 3 cm away from the bottom part of the hollow body, with possible upper limits at e.g. B. a maximum of 20 cm or 15 cm. A certain axial extent creates stability; an upper limit can, for example, be of interest with regard to the geometry of the tubular element or the manageability.

The hollow body and the bushing are preferably connected to one another via a joint connection, preferably glued to one another. The joining or adhesive connection could generally also be formed, for example, between the flange element of the bushing and the bottom part of the hollow body. With the joining or adhesive connection, the hollow body and the bushing are preferably not only fastened to one another, but also sealed against one another. By applying a surface seal to the flange as discussed above, a continuous seal can be created up to the inner volume of the pipe element; this is then, for example, later sealed with a sealing system against a line routed through it, see below.

The joining or adhesive connection is preferably formed between the pipe socket of the hollow body and the pipe element of the bushing. This can e.g. B. be advantageous in that the pipe parts can offer comparatively smooth surfaces apart from the curvature, for example in comparison to a flange element with stiffening ribs. Since the adhesive connection is arranged further inside, there may also be an advantage in a reduced amount of adhesive (smaller radius). The joining or adhesive connection exists between the inner wall surface of one part and the outer wall surface of the other, in the preferred case of the pipe element inserted into the pipe socket between the inner wall surface of the pipe socket and the outer wall surface of the pipe element.

According to a preferred embodiment, the hollow body has a plurality of side walls which laterally delimit the cavity (in the distance directions outwards). These side walls are each designed to be flat. The hollow body can in particular have two opposite, triangular side walls which are connected to one another by a further side wall (this is preferably rectangular). The cavity therefore preferably has the shape of a three-sided prism. Compared to more complex geometries, simple shaping can be advantageous, for example in terms of manufacturability.

In a preferred embodiment, the hollow body is generally a thermoformed part. It can in particular be made of a thermoplastic, which is heated for shaping and then pressed or pulled into the mold (e.g. in the axial direction), for example by excess pressure (e.g. compressed air) and/or negative pressure. An advantage of this can be, for example: B. lies in the fact that comparatively thin wall thicknesses can also be achieved, which e.g. B. can still enable a weight-optimized structure despite the size of the hollow body. In general, even regardless of the thermoforming, the hollow body can, for example, have a wall thickness of at least 1 mm or 2 mm, with possible upper limits being, for example, at most 8 mm, 6 mm or 5 mm. The wall thickness can be taken, for example, on a respective side wall of the hollow body, perpendicular to the respective side wall.

As already mentioned, the casting material is preferably concrete. Furthermore, the subject matter preferably relates to a wall element, particularly preferably a building wall. When casting a wall element, the side surface opposite the side surface with the hollow body is typically also delimited by formwork. Their formwork elements or panels and those on which the hollow body is placed lie opposite one another. The end of the tubular element opposite the hollow body could, for example, rest against the formwork at an angle or be guided through a hole in the formwork (both, however, require effort).

In a preferred embodiment, a further hollow body is therefore arranged at an end of the tubular element axially opposite the hollow body, which extends to an opposite side surface of the wall or floor element and defines a further cavity there. Although this could also be of interest in the case of a floor element, it preferably concerns a wall element. The further hollow body defines another cavity. This is preferably also wider than the inner diameter of the tubular element (at least over a rotation angle range). In general, with regard to the preferred embodiment of the further hollow body, reference is made to the above disclosure regarding the first hollow body; the two hollow bodies are particularly preferred structurally identical to each other. For example, they can be produced with the same mold. On the tubular element they are then not only mirrored to one another, but also arranged twisted (preferably by 180°). The attachment surfaces of the hollow bodies are preferably parallel to one another (parallel offset).

According to a preferred embodiment, a further passage is cast together with the (first) hollow body. The hollow body combines several bushings whose pipe elements open into the same cavity. So at least two, more preferably at least three or four bushings, each of which has a tubular element, are cast together with the same hollow body. Possible upper limits can be, for example, a maximum of 25, 20, 15, 10 or 8 executions. Regardless of the number, the pipe elements of the bushings are arranged next to one another; their center axes are preferably parallel to one another. This combination of the bushings with the same hollow body can be advantageous, for example, in terms of a space-saving structure (compared to placing several hollow bodies next to each other, each with exactly one bushing).

The plurality of bushings preferably each have a flange element. A respective flange element preferably has a form-fitting element, via which the feedthrough can be assembled in a form-fitting manner with another feedthrough. In the case of the hollow body with several bushings, these are preferably assembled via positive locking elements provided on their flange elements. However, a flange element with form-fitting elements can also be preferred in the case of a hollow body with a single feedthrough (identical parts/universality), in which case the form-fitting elements are then unused.

In a preferred embodiment, the formwork is removed after the casting material has hardened, for example after the concrete has hardened. When the formwork is removed, the side surface on which the hollow body is arranged is exposed. After removing the formwork, it is preferred to run a line through it Pipe element laid through, which then extends from one side of the wall or floor element to the other side. After removing the formwork, a closure or closure cover, see above, is preferably removed from the pipe element, then the line is passed through. After the formwork has been removed, the hollow body remains in the wall or floor element, so the line is laid through the hollow body and through the pipe element.

The line can generally also be a media line, for example. B. a gas, water or district heating pipe, i.e. a hollow pipe in which the corresponding medium is carried. The line can preferably be a cable, e.g. B. a data cable or preferably an electrical cable.

The line can then be sealed against the bushing with a sealing system. The sealing system can, for example, include a shrink sleeve that attaches to an outer surface of the line (by warm or cold shrinking). Such a shrink sleeve can be arranged, for example, on a system cover, which can then be z. B. is placed in the pipe element instead of the closure cover. In general, it can be preferred that the sealing system is fastened in the pipe element via the same fastening mechanism that is used to hold a closure cap in the pipe element (during pouring). The sealing system and the closure cover can, for example, be fastened in the tubular element via the same screw and/or bayonet mechanism.

The sealing system can, for example, also be implemented via a press seal, i.e. an elastomer body that is axially compressed between press bodies and, as a result, seals on the inside and outside. Such a press seal can, for example, be arranged or used in a ring insert, which in turn can be fastened in the tubular element in a similar way to the closure cover (in particular via a screw and/or bayonet mechanism). The press seal can also be designed to be segmented in the circumferential direction, for example made up of several circle segments; This can also be preferred Ring insert divide the through opening according to the segmentation (with bars).

After the formwork has been removed, a surface seal is preferably applied to the side surface of the wall or floor element, in particular the concrete wall. This is preferably worked onto the hollow body, for example glued or painted on. The surface seal is applied to an attachment surface of the hollow body, which is preferably formed by a flange, see above.

The invention is explained in more detail below using an exemplary embodiment, whereby the individual features can also be essential to the invention in other combinations within the scope defined by the appended claims.

• Figur 1 einen Hohlkörper mit vier Durchführungen in einer Schrägansicht von vorne;
• Figur 2 eine der Durchführungen gemäß Figur 1, wobei das Rohrelement der Durchführung ohne Verschlussdeckel dargestellt ist;
• Figur 3 den Hohlkörper der Anordnung gemäß Figur 1 in einer Schrägansicht von vorne;
• Figur 4 den Hohlkörper gemäß Figur 3 in einer Schrägansicht von hinten;
• Figur 5 in schematischer Darstellung eine Durchführung mit zwei Hohlkörpern in einer Seitenansicht, in einer Einbausituation;
• Figur 6 Durchführungen mit zwei Hohlkörpern in einer Schrägansicht.

Shows in detail

• Figure 1 a hollow body with four bushings in an oblique view from the front;
• Figure 2 one of the implementations according to Figure 1 , wherein the tubular element of the bushing is shown without a closure cover;
• Figure 3 the hollow body according to the arrangement Figure 1 in an oblique view from the front;
• Figure 4 the hollow body accordingly Figure 3 in an oblique view from behind;
• Figure 5 a schematic representation of a bushing with two hollow bodies in a side view, in an installation situation;
• Figure 6 Bushings with two hollow bodies in an oblique view.

Preferred embodiment of the invention

Figure 1 shows a hollow body 1 in an oblique view from the front. This is made up of four bushings 2 (only one of them is visible in the oblique view). The following will also include additional information Figure 2 referred to which one Implementation 2 shows in an individual representation, i.e. without the hollow body 1 (the hollow body 1 is shown in detail using the Figures 3 and 4 discussed).

The bushing 2 has a tubular element 4 and a flange element 5, which is arranged on the axial end of the tubular element 4 with respect to a central axis 6 of the tubular element 4. In distance directions 7 perpendicular to the center axis 6, the flange element 5 rises outwards away from the tubular element 4 (for the sake of clarity, only one distance direction 7 is shown). In detail, the tubular element 4 is composed of several tubular element sections (not referenced in detail), with an axially end-side tubular element section 4A being formed monolithically with the flange element 5.

Figure 3 shows the hollow body 1 in an individual view, i.e. without the bushings 2. What can be seen is a cavity 30 delimited by the hollow body 1, which the hollow body 1 keeps free at the axial end of the bushings 2 or pipe elements 4. This cavity 30 is surrounded by side walls 31 of the hollow body 1, namely two triangular side walls 31a, b and a square side wall 31c. The hollow body 1 also has a flange 33, which forms a mounting surface 33.1 with which the hollow body 1 is placed on a formwork for casting, compare Figure 5 . A bottom part 32 of the hollow body 1 delimits the cavity axially. The flange elements 5 of the bushings 2 are then arranged on a base surface 32.1 of the base part 32, compare Figure 1 .

Like in particular Figure 4 As can be seen, 32 pipe sockets 35a-d are arranged on the base part, each of which accommodates the pipe element 4 of the respective bushing 2. This tube-in-tube principle creates good stability, and the respective bushing 2 is sealed against the hollow body 1 via an adhesive connection formed there.

Figure 5 illustrates how a bushing 2 with two hollow bodies 1, 50 arranged axially on the inside is cast into a wall element 51. The further hollow body 50 is constructed analogously to the description above, see also figure 6 for illustration. The hollow body 1 keeps the cavity 30 free on the side surface 51.1 of the wall element 51, the further hollow body 50 holds the further cavity 52 on the opposite side surface 51.2. Formwork is provided for casting the wall element, the hollow body 1 is placed on the formwork 53.1 Hollow body 50 to the formwork 53.2. After demoulding, for example removing the formwork 53.1, z. B. a surface seal can be applied to the side wall surface 51.1, e.g. B. a thick bitumen coating. This can then advantageously be worked onto the flange 33, i.e. painted onto the attachment surface 33.1.

Figure 6 shows an arrangement that is analogous to the description Figure 5 can be poured into a wall element 51. Four bushings 2a-d with a respective pipe element 4a-d can be seen. The flange elements 5a-d are assembled via positive locking elements 20a, b, compare Figure 2 for illustration. The structure is analogous in the axially opposite hollow body 50, but this cannot be seen in this oblique view.

According to the representation Figure 6 are, in contrast to Figure 1 , the closure caps 10a-d have already been taken out of the pipe elements 4a-d. This corresponds to a situation after casting and demoulding, before a line is laid through the pipe elements 4a-d. One advantage of the hollow bodies 1, 50 is, on the one hand, that the lines can be laid curved towards the wall element 51, i.e. they do not have to be brought in at right angles. On the other hand, the cavity 30 provides space for handling at the ends of the pipe elements 4a-d, so for example the closure covers 10a-d can be easily removed and replaced with a sealing system for sealing against the line or lines.

Claims (15)

1. Use of a feed-through (2), which has a flange element (5) and a tube element (4), and a hollow body (1) for casting in a casting material,

   wherein the flange element (5) is arranged axially at the end of the tube element and extends away from the tube element (4) perpendicular to a centre axis (6) of the tube element (4),

   wherein the flange element (5) is placed against a bottom part (32) of the hollow body (1),

   wherein the hollow body (1) and the tube element (4) are assembled as separately manufactured parts,

   in which use a wall or floor element (51) is produced by filling the casting material into a formwork (53.1), which formwork (53.1) defines a side surface (51.1) of the wall or floor element (51),

   wherein the feed-through (2) is cast in at an angle, i.e. the centre axis (6) of the tube element (4) lies at an angle to a surface normal on the side surface (51.1),

   and wherein the hollow body (1) is placed against the formwork (53.1) for casting in the feed-through (2) and defines a cavity (30) in the casting material axially following the tube element (4),

   which cavity (30) extends to the side surface (51.1) of the wall or floor element (51) and is larger than an inner diameter of the tube element (4) in distance directions (7) perpendicular to the centre axis (6) of the tube element (4),

   characterised in that the flange element (5) is formed in one piece with the tube element (4).
2. Use according to claim 1, in which the hollow body (1) has a flange (33), the hollow body (1) being placed with the flange (33) against the formwork (53.1) for casting in the feed-through (2).
3. Use according to claim 2, in which an attachment surface (33.1) of the flange (33), with which it is placed against the formwork (53.1), has a width of at least 2 cm.
4. Use according to any one of the preceding claims, in which an attachment surface (33.1), with which the hollow body (1) is placed against the formwork (53.1), is closed around the centre axis (6).
5. Use according to any one of the preceding claims, wherein the flange element (5) of the feed-through (2) is placed at a bottom surface (32.1) of the bottom part (32), the bottom surface (32.1) facing the cavity (30).
6. Use according to any one of the preceding claims, in which the hollow body (1) has a pipe socket (35) which is arranged on a bottom part (32) of the hollow body (1), the pipe socket (35) and the tube element (4) of the feed-through (2) being set one inside the other.
7. Use according to any one of the preceding claims, in which the hollow body (1) has a plurality of side walls (31a-c) which laterally delimit the cavity (30), wherein the side walls (31a-c) of the hollow body (1) are each planar in themselves.
8. Use according to any one of the preceding claims, in which the hollow body (1) is a thermoformed part made of plastic.
9. Use according to any one of the preceding claims, in which a further hollow body (50) is arranged at an end of the tube element (4) axially opposite the hollow body (1), which extends to an opposite side surface (51.1) of the wall or floor element (51) and there defines a further cavity (52), which follows the tube element (4) in an axially opposite manner.
10. Use according to claim 9, in which the hollow bodies (1, 30) are identical in construction to one another.
11. Use according to any one of the preceding claims, in which a further feed-through (2) is moulded in with the hollow body (1), which feed-through has a further tube element (4), the tube elements (4) of the feed-throughs (2) being arranged next to one another and leading into the same cavity (52) kept free by the hollow body (1).
12. Use according to any one of the preceding claims, in which the formwork (53.1) is removed after the casting material has hardened and a line is passed through the tube element (4).
13. Use according to claim 12, wherein a seal is applied to the side surface (51.2) of the wall or floor element (51), which is applied onto the hollow body (1) circumferentially.
14. Feed-through arrangement with a feed-through (2), which has a flange element (5) and a tube element (4), and a hollow body (1),

    and with a formwork (53.1) which is filled with a casting material for the production of a wall or floor element (51), wherein the formwork (53.1) defines a side surface (51.2) of the wall or floor element (51),

    into which casting material the feed-through (2) and the hollow body (1) are cast in,

    wherein the flange element (5) is arranged axially at the end of the tube element (4) and extends away from the tube element (4) perpendicular to a centre axis (6) thereof,

    and wherein the flange element (5) is placed against a bottom part (32) of the hollow body (1),

    and wherein the hollow body (1) and the tube element (4) are assembled as separately manufactured parts,

    and wherein the feed-through (2) is cast in at an angle, i.e. the centre axis (6) of the tube element (4) lies at an angle to a surface normal on the side surface (51.1),

    and wherein the hollow body (1) is placed against the formwork (53.1) and defines a cavity (52) in the casting material axially following the tube element (4),

    which cavity (52) extends to the side surface (51.1) of the wall or floor element (51) and is larger than an inner diameter of the tube element (4) in directions (7) perpendicular to the centre axis (6) of the tube element (4),

    characterised in that the flange element (5) is formed in one piece with the tube element (4).
15. Feedthrough arrangement according to claim 14, produced by a use according to one of claims 2 to 11.

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