EP3428364B1 - Device for securing reinforcing elements - Google Patents

Description

The invention relates to a device with a base body for holding reinforcement elements for reinforced concrete components, wherein the base body has at least one receptacle or at least one support for a reinforcement element and in which recesses are provided in the region of the base body.

Furthermore, the invention relates to a device for producing a component made of reinforced concrete, comprising at least one formwork device and at least one device for holding reinforcement elements.

Furthermore, the invention relates to a component made of reinforced concrete, comprising at least one reinforcement element and at least one device for holding reinforcement elements.

A component made entirely of concrete can in principle absorb compressive forces to a high degree, but is only very limited in its ability to absorb tensile forces.

In order to achieve improved load-bearing capacity, concrete parts are therefore often provided with reinforcement elements. The reinforcement elements are typically made of steel and are often rod-shaped. Traditionally, the rod-shaped reinforcement elements are connected to one another using wires and fixed in their respective positions. This type of working method leads to a very high workload, and under the conditions of a construction site, only limited accuracy and reproducibility can be achieved with regard to the positioning of the reinforcement elements.

In order to achieve increased positioning accuracy and to reduce the amount of work required, the use of special devices for holding and positioning the reinforcement elements has been known for many years. The corresponding components are typically made of plastic and have one or more holders or supports into or on which the reinforcement elements can be inserted or placed. The holders are often designed in a similar way to clips or with elastically springy legs.

Classic areas of application in the construction industry are the production of columns, walls, beams, ceilings or foundations made of concrete or reinforced concrete.

There are various requirements for the use of such holding devices, also known as spacers, which are also regulated in special standards, such as DIN.

The basic requirement for such a spacer is to ensure a defined distance between the reinforcement elements, such as reinforcement wires / reinforcement bars, and the formwork during the production process of a concrete part and thus also the distance between the reinforcement elements and the concrete surface after the production of the concrete part.

The distance between the reinforcement elements and the nearest concrete surface is called concrete cover and is determined by a standardized minimum concrete cover, for example 10 mm, is limited to a minimum distance. In practice, the nominal dimension of the concrete cover results from the sum of the minimum concrete cover and a provision dimension, which is intended to cover, for example, dimensional deviations from bending and laying of the reinforcement or the type and installation of the reinforcement.

Based on the installation dimension, which is derived from the nominal dimensions of the transverse bars and longitudinal bars of the reinforcement, there is a permissible dimensional deviation of +/- 1 mm (installation dimension less than or equal to 40 mm) or +/- 2 mm (installation dimension greater than 40 mm) for the spacing dimensions of a spacer.

In general, any introduction of foreign material into the concrete means a weakening of the concrete body with regard to various loads that can act on it. This results in a requirement that the material introduced into the concrete with the spacers is selected and dimensioned in such a way that the concrete is weakened as little as possible.

In addition to the foreign material introduced, a weakening of the concrete can also occur due to inadequate concrete flow around the spacers when pouring the concrete part, as the components of the concrete can, for example, separate and thus voids or areas of reduced strength can arise in the concrete.

Different forms of spacers are already known for different types of applications. There are wheel-shaped spacers, point-shaped spacers, linear spacers and surface-shaped spacers. Depending on the design, the spacers have fastening devices for reinforcement elements.

Wheel-shaped spacers have a wheel-shaped support structure, the radial outer surface of which serves as a support surface on a formwork. In the area of the center of the wheel-shaped spacer, it has a mounting device that serves to hold a reinforcing bar. To hold the reinforcing bar in The holding device has a corresponding spacer, usually a funnel-shaped feed structure, which interrupts the support structure.

Point-shaped spacers are directional spacers, as they generally only ensure a distance between the formwork and the reinforcement element in one direction defined by the structure of the spacer.

Linear spacers are elongated and have a contact surface on their underside for resting on a formwork and a contact surface on their upper side for supporting, as a rule, several reinforcement elements or one reinforcement element at several points. The distance between the lower and upper sides is the height of the linear spacer and determines the thickness of the concrete cover.

A further requirement regarding the spacers arises in the case of linear spacers, which are mainly used when pouring horizontal concrete geometries, such as ceilings. Depending on the orientation of the linear spacers in the concrete body, a length limit is provided, which is generally 350 mm or can be less depending on the dimensions of the width and height of the component. However, if the spacers are installed parallel to the main stress direction, a length limit is generally not necessary.

When used in exposed concrete, additional requirements include the smallest possible contact area of the spacers on the formwork and minimal indentation of the spacers into the formwork or minimal marking of the spacers on the concrete surface.

Corresponding plastic spacers are already being used in the DE 20 2008 011 704 U1 , the DE 20 2010 012 953 U1 , the DE 20 2010 000 058 U1 and the EP 3 002 380 A1 The corresponding spacers are extremely inexpensive as individual parts, but for larger concrete components a large amount of the corresponding spacers are required, so that reduced production costs are sought with at least the same functionality as before. In addition, the volume taken up by the spacer(s) within the reinforced concrete represents potential weak points, so that a reduction in the corresponding material quantities of the spacers is also sought for static reasons.

From the DE 9310210 U1 A spacer made of plastic for reinforcing elements of concrete parts is already known. A ring-like structure of the spacer is described, whereby the spacer can be pushed onto a reinforcing element using a central recess and an insertion opening.

In the DE 20 2013 000785 U1 a linear spacer is described which, starting from a linear central part, has laterally projecting triangularly delimited wing-like side areas in a longitudinal direction. Document DE 20 2013 000785 U1 discloses the preamble of claim 1.

The EN 90 01 298.4 describes a spacer that has wing-like extensions that protrude laterally from a linear main part. According to different embodiments, these can be either triangular or limited by curved contours or rectangular or trapezoidal.

In the JP2012-237140 again describes an annular spacer that can be pushed onto a reinforcement element using an insertion opening. One object of the present invention is therefore to construct a device of the type mentioned in the introduction in such a way that the device has a reduced component volume while maintaining high functionality and stability.

This object is achieved according to the invention by the features of claim 1. In particular, the respective wall thicknesses are dimensioned in such a way that the required mechanical strength values are achieved, but not exceeded several times as is usual in the prior art. In addition, in the area the body of the spacers is provided with recesses, the size of which is dimensioned according to the invention such that as much concrete as possible can be arranged in these areas when pouring the respective components, so that the reinforced concrete component achieves increased strength values.

A further object of the invention is to provide linear spacers of the aforementioned type which can be connected to form a spacer assembly formed from a plurality of linear spacers in such a way that the spacer assembly behaves statically approximately like a single part.

This object is achieved according to the invention by using linear spacers which have connecting devices which realize both a high load-bearing capacity and easy connectability.

In a first variant of a holding device according to the invention, this is designed as a linear spacer whose base body is wave-shaped in one direction. The linear spacer has a length l, a width b and a height h, with the height h determining the thickness of the concrete cover. The bulges of the wave shape are arranged in the direction of the width b.

In the base body with the thickness d of the linear spacer according to the invention, regularly distributed recesses are arranged, which reduce the volume of the spacer and enable improved concrete flow and thus less weakening of the concrete. According to the invention, the recesses are circular.

Depending on the height h and thickness d of the base body, the linear spacer according to the invention is designed for loads of at least 250 N up to over 1000 N.

The base body of the spacer can be divided into three, preferably repeated, form elements, at least in the area between the connecting devices. The first form element is the right-hand shaft head, the second The first form element is the shaft flank and the third form element is the left-hand shaft head. The bends of the base body are arranged in the area of the shaft heads, while the base body is mostly straight in the area of the shaft flanks. Preferably, at least one recess is arranged in the base body in the area of each form element.

The top of the spacer forms the support element for at least one reinforcement element, for example a reinforcement bar or a reinforcement mat, while the bottom forms the support for positioning the spacer on a formwork. The bottom defines the contact surface of the linear spacer.

In the area of the underside of the spacer according to the invention, further recesses or gaps are arranged in the base body, which further reduce the volume of the spacer, improve the concrete flow and reduce the contact area on the formwork. The remaining structure of the base body in the area of the underside creates contact elements for the spacer.

In the region of the ends of the base body, the linear spacer according to the invention advantageously has a connecting device with which two or more of the linear spacers can be connected to form a linear spacer assembly.

According to the invention, the connecting devices are preferably realized as recesses in the base body of the spacer, so that the base bodies of the spacers to be connected can each be plugged into one another in the region of at least one first shaft.

In a particularly preferred embodiment, the connecting device in the region of a first end of the spacer is designed as recesses in the first two shaft flanks that are open to the top and the connecting device in the region of a second end of the spacer is designed as recesses that are open to the bottom formed in the first two wave flanks, so that two linear spacers according to the invention can be connected in the region of the connecting devices by interlocking the connecting structures and a connection that can be loaded at least in the transverse direction can be realized.

In a preferred embodiment of the invention, the recesses on the underside are arranged predominantly in the area of the shaped elements designed as wave flanks. In a particularly preferred embodiment of the invention, the recesses on the underside are designed such that the contact surfaces of the spacer on the formwork or the support elements are arranged exclusively in the area of the wave heads and, if necessary, additionally in the area of the connecting devices.

In particular, a symmetrical arrangement of the support elements around the vertex of each shaft head is considered.

In order to reduce the weakening of the concrete, particularly with regard to cracking, the wave shape is designed such that the connecting lines of a vertex of a wave head intersect with the adjacent vertices of the wave heads on the opposite side of the base body of the linear spacer according to the invention at an angle α in a range from 50° to 70°, preferably at an angle α of 55° to 65°, particularly preferably at an angle α of about 60°.

In a linear spacer designed according to the invention with a wave-shaped base body of length I of approximately 350 mm, at least 4 wave heads are formed to provide uniform support for the at least one reinforcement element. In a preferred embodiment, at least 10 wave heads are formed along the length I of the linear spacer and in a particularly preferred embodiment, 20 wave heads are formed.

The width b of the linear spacer according to the invention is in an advantageous embodiment in a range between 10 mm and 50 mm, in a preferred embodiment of the invention in a range between 20 mm and 40 mm, in a particularly preferred embodiment in a range between 25 mm and 35 mm. The basic shape of the linear spacer according to the invention, which is open due to the wave shape, enables particularly good concrete flow when producing a concrete part.

In a particularly advantageous embodiment of the invention, the linear spacer is flexible in the transverse direction such that a spacer or a spacer assembly formed from several spacers can be bent around any recess in a concrete part.

Plastic is particularly intended as the material for the base body. The linear spacer according to the invention can preferably be manufactured using extrusion and punching.

In another embodiment according to the invention, the holding device is designed as a linear spacer whose base body has diamond-shaped shaped elements.

The diamond shape of various form elements of the base body enables a particularly high mechanical strength of the spacer with comparatively low material usage and the corresponding component volume.

In a further embodiment, the holding device is designed as a point-shaped spacer.

A point-shaped spacer has a holding device for a reinforcement element, at least two support elements designed as arms and a feed structure which facilitates insertion of the reinforcement element into the holding device.

In a preferred embodiment of the invention, the feed structure is funnel-shaped.

The undersides of the arms form the contact surface of the spacer on or at the formwork. The distance between the underside of the arms and a support element of the mounting device thus determines the thickness of the concrete cover when using a spacer according to the invention.

By exerting pressure on the opposite outer surfaces of the arms, the funnel-shaped feed structure can be spread open similar to the principle of a clothespin, so that the insertion of a reinforcement element into the holding device can be further supported.

According to the invention, the holding device is realized as a support element, which is to be aligned in the direction of the formwork to which the concrete cover is to be adjusted with the spacer, and a clamping device, which enables the reinforcement element to be fixed in the holding device.

According to the invention, the geometry of the clamping device is designed for specific diameters of reinforcement bars.

In a preferred embodiment of a point-shaped spacer, this additionally has a closure device in the region of the funnel-shaped feed structure, by means of which the feed structure can be closed and the clamping force fixing the reinforcement element in the holding device can be increased.

In addition, the lockability of the spacers according to the invention makes it possible to achieve a higher degree of torsional stability of the spacer on the reinforcement element.

In a particularly preferred embodiment of the point-shaped spacer, it has replaceable arms so that the concrete cover can be adjusted by mounting appropriately dimensioned arms on the remaining base body of the spacer.

The closure device is preferably designed as a latching structure, which is realized by oppositely designed structures in the end region of the funnel arms of the feed structure.

In order to reduce the amount of material used in the production of the spacers and to reduce the amount of foreign material introduced into a concrete body, the point-shaped spacer has a structure that is essentially reduced to the outer walls and web-like connecting elements between the functional elements.

In order to reduce the contact area, a point-shaped spacer in a preferred embodiment has nose-like extensions in the area of the arms.

In a further embodiment, the holding device is designed as a wheel-shaped spacer.

The wheel-shaped spacer has a support body and a holding body that can be connected to one another and, if necessary, separated from one another. The wheel-shaped support body serves to support the spacer on a formwork and has a connecting device with which a holding body, which serves to hold a reinforcement element, can be connected to the support body to form a spacer.

A plurality of support elements are arranged on the radial outer surface of the wheel-shaped spacer.

The two-part design of the spacer according to the invention enables an individual material combination depending on the requirements. In addition, the two-part design of the spacers according to the invention enables lower average manufacturing costs for the wheel-shaped spacers due to higher quantities in the production of the support bodies, since these can be produced independently of the dimensions of the reinforcement elements.

A device for producing a concrete part has at least one formwork device and at least one device for holding reinforcement elements for components made of reinforced concrete. The device for holding reinforcement elements for components made of reinforced concrete is designed as a spacer having a base body, wherein the base body has at least one holding device designed as a receptacle or at least one support for at least one reinforcement element and wherein a concrete cover is determined by the distance between a support element for a reinforcement element and at least one contact surface of the spacer, characterized in that recesses are arranged in the region of the base body, through which a reduced volume of the spacer and an improved concrete flow are realized when pouring the reinforced concrete component.

A component made of reinforced concrete has at least one reinforcement element and at least one device for holding reinforcement elements for components made of reinforced concrete. The device for holding reinforcement elements for components made of reinforced concrete is designed as a spacer having a base body, wherein the base body has at least one holding device designed as a receptacle or at least one support for at least one reinforcement element and wherein a concrete cover is formed by the distance between a support element for a reinforcement element and at least one contact surface of the spacer. is intended, characterized in that recesses are arranged in the region of the base body, through which a reduced volume of the spacer and an improved concrete flow are realized when pouring the reinforced concrete component.

Fig. 1

eine perspektivische Darstellung eines punktförmigen Abstandhalters mit optimierter Wandungsstruktur,

Fig. 2

eine Seitenansicht des punktförmigen Abstandhalters gemäß Figur 1,

Fig. 3

eine gegenüber der Darstellung in Figur 1 abgewandelte Ausführungsform,

Fig. 4

eine weitere Ausführungsvariante des Abstandhalters,

Fig. 5

eine weitere Ausführungsform eines Abstandhalters in Radform,

Fig. 6

eine perspektivische Darstellung von Einzelteilen zum Abstandhalter gemäß Figur 5,

Fig. 7

eine perspektivische Seitenansicht eines linienförmigen Abstandhalters,

Fig. 8

eine Seitenansicht des Abstandhalters gemäß Figur 7,

Fig. 9

eine perspektivische Darstellung eines linienförmigen Abstandhalters mit wellenartiger Wandungsstruktur,

Fig. 10

eine Seitenansicht des Abstandhalters gemäß Figur 9 und

Fig. 11

eine Seitenansicht in Längsrichtung des Abstandhalters gemäß Figur 9.

The invention is explained below using figures in exemplary embodiments. It shows:

Fig.1

a perspective view of a point-shaped spacer with optimized wall structure,

Fig. 2

a side view of the point-shaped spacer according to Figure 1 ,

Fig.3

a comparison with the representation in Figure 1 modified embodiment,

Fig.4

another version of the spacer,

Fig.5

another embodiment of a wheel-shaped spacer,

Fig.6

a perspective view of individual parts of the spacer according to Figure 5 ,

Fig.7

a perspective side view of a linear spacer,

Fig.8

a side view of the spacer according to Figure 7 ,

Fig.9

a perspective view of a linear spacer with a wave-like wall structure,

Fig.10

a side view of the spacer according to Figure 9 and

Fig. 11

a longitudinal side view of the spacer according to Figure 9 .

Figure 1 shows a spacer (1) with an optimized material distribution. The spacer (1) has a holding device (2) for a reinforcement element (not shown). The holding device (2) is designed as a receptacle and is partially delimited by clamping elements (3). The clamping device (3) has two clamping elements which are designed as wall sections of the spacer (1). A reinforcement element is positioned within the holding device (2) on a support element (4). Support elements (5) designed as arms are used for support in the area of a formwork (not shown), the underside of which forms the support surface (6). With the help of a funnel-shaped feed structure (7), sliding the spacer (1) onto a reinforcement element is made easier and security against twisting is achieved.

In the area of the base body of the spacer (1), a plurality of recesses (8) are arranged, which reduce the volume of the spacer (1) and enable improved concrete flow.

The essential functional elements, such as support elements (5), bearing element (4) and clamping device (3), are connected to one another via connecting webs (10), so that the required mechanical stability of the spacer (1) is ensured.

The feed structure (7) can be spread open by exerting force on the pressure surfaces (11), which are realized at least by areas of the opposite outer surfaces of the support elements (5) designed as arms.

Through the side view in Figure 2 the geometric relationships are further clarified.

Figure 3 shows a modified embodiment of a point-shaped spacer (1). When the spacers (1) are mounted on a reinforcement element, the pressure surfaces (11) are pressed together, which spreads the funnel-shaped feed structure (10). The spacer (1) shown supports precise maintenance of the concrete cover by providing a directed support.

To further reduce the contact area (6) on a formwork, the spacer (1) shown has nose-like extensions (12) in the area of the underside of the contact elements (5).

Furthermore, the spacer (1) shown has a closure device (13) in the end region of the funnel-shaped feed structure (7), with which the feed structure (7) can be closed.

According to the embodiment in Figure 4 are in Figure 3 The connecting webs (10) shown in the form of transverse webs in the region of the arms (5) are omitted.

The closure device (13) has a first closure element (13a) on one side of the funnel-shaped feed structure (7) and a second closure element (13b) on the other side of the funnel-shaped feed structure (7), which is designed as a counter-profile to the first closure element (13a), so that the closure device (13) is realized as a locking device.

According to the embodiment in Figure 5 The wheel-shaped spacer (1) has an approximately rounded outer contour, the contact surface (6) of which is defined in one direction by two contact elements (5) projecting radially from the rounded outer contour. The spacer (1) shown supports, in particular, smooth sliding on thanks to the feed structure (7).

Furthermore, the base body of the wheel-shaped spacer (1) is designed in two parts. The first part of the base body forms a support body (14) and the second part of the base body forms a holder body (15).

The support body (14) essentially realizes the support structure of the spacer (1) on a formwork and the holding body (15) has a holding device (2) for holding a reinforcement element.

The division into two parts allows the support geometry and the clamping geometry to be optimized according to different criteria. In addition, cost savings can be achieved by manufacturing the two individual parts separately.

Figure 6 shows the two individual parts in a perspective view. As an example, a support body (14) and three compatible holder bodies (15) are illustrated, which can be connected to form a spacer (1) by combining the support body (14) with a holder body (15).

The support bodies (15) are designed for different diameters of reinforcement elements. In particular, the design of a support body (15) for a specific diameter of a reinforcement element is carried out by means of an adapted clamping device and/or an adapted support element.

According to the embodiment in Figure 7 the spacer (1) is realized as an elongated component. A plurality of such linear spacers (1) can be connected to one another in the longitudinal direction to form a linear spacer assembly.

For connection to at least one further spacer (1), the spacer shown has a connecting device (16) at each of the two ends, wherein the structures of the connecting devices (16) are designed oppositely so that they can be plugged into one another.

The holding device (2) for at least one reinforcement element is implemented as a support which is provided by the upper side of the spacer (1). The upper side of the spacer thus also implements the support element (4) of the spacer (1).

Several support elements (5) are arranged on the underside of the base body of the spacer (1).

According to a typical embodiment, the spacer (1) has a length of approximately 350 mm. Minimal support points are provided, optimal concrete flow is supported and optimal load-bearing capacity can be achieved.

The improved concrete flow is achieved in particular by a plurality of recesses (8) which are arranged in the base body of the spacer (1).

In the illustrated embodiment of a linear spacer (1) according to the invention, diamond-shaped recesses (8) or shapes that can be produced from diamond segments or a combination of diamonds are used. In the embodiment shown, in addition to diamond-shaped recesses (8), recesses (8) with a shape corresponding to two partially overlapping diamonds are also arranged.

The diamond shape enables a high mechanical stability of the spacer (1).

Corresponding linear spacers (1) can be used when pouring concrete geometries. They are particularly used for horizontal geometries such as concrete ceilings.

During assembly, the spacers (1) are distributed on the horizontal formwork and hold the reinforcement elements at a defined distance from the formwork.

From the side view in Figure 8 In particular, the detailed geometry of the connecting devices (16) can be seen. This preferably allows for simple and detachable plugging together.

Furthermore, an arrangement of extensions (12) is realized in the area of the support elements (5) to further reduce the contact area (6).

According to the embodiment in Figure 9 a linear spacer (1) with a wave-like wall profile is provided. Such a spacer (1) can also preferably be realized with a length of about 350 mm. This spacer (1) also leads to an optimal concrete flow, in particular due to an open basic shape. Minimal support points on the formwork are achieved and the spacer (1) enables the creation of very little foreign material in the concrete.

According to a preferred embodiment, the spacer (1) is realized as an extruded component. It is cut to the appropriate length as required.

The holding device (2) of the spacer (1) for at least one reinforcement element is implemented by the upper side in the form of a support. In addition, the support element (4) is also implemented by the upper side of the spacer (1).

The base body of the spacer (1) essentially has two shaped elements, which are defined by the shaft head (17) and the shaft flank (18). A circular recess (8) is arranged both in the area of the shaft flanks (18) and in the area of the shaft heads (17).

Further recesses (8) are arranged on the underside of the spacer (1), through which the support elements (5) are formed as a remaining structure.

The support elements (5) are arranged in the area of the shaft heads (17).

In the region of the first two wave flanks (18) at both ends of the spacer (1), a connecting device (16) is realized by recesses which extend approximately from the middle of the height of the base body at one end to the top and at the other end to the bottom of the spacer (1).

By means of connecting devices (16) implemented in this way, two spacers (1) can be connected to a wave-shaped base body by inserting one connecting device (16) into the other to form a spacer assembly. The connection has stability in the transverse and longitudinal directions due to a nesting of the spacers (1) in the region of at least one shaft.

In Figure 10 is the Figure 9 shown linear spacers (1) in a side view from one end face.

A reinforcement element (30) rests on the upper side of the spacer (1) which forms the holding device (2).

In the area of the support elements (5), the spacer (1) rests on a formwork element (40).

Claims (11)

1. Apparatus for retaining reinforcement elements for components made of reinforced concrete, designed as a spacer (1) having a main body, wherein the main body has at least one retaining apparatus (2) which is designed as a receptacle or as at least one support for at least one reinforcement element, and wherein a concrete covering of the component is determined by the distance between a bearing element (4) for the at least one reinforcement element and at least one standing surface (6) of the spacer (1), and wherein, in the region of the main body, there are arranged cutouts (8) by way of which a reduced volume of the spacer (1) and improved flowing-around of concrete during encapsulation of the reinforced-concrete component are realized, wherein the spacer (1) is designed as a linear spacer (1) having a wave-shaped main body, and wherein use is made of connecting devices (16) by way of which at least two spacers (1) are able to be connected to form a linear spacer assembly, and that the connecting devices (16) are realized by a connecting device (16) arranged in the region of a first end of the spacer (1) and a connecting device (16) arranged in the region of a second end of the spacer (1), wherein the connecting device (16) in the region of the first end of the spacer (1) is configured as a counterpart of the connecting device (16) in the region of the second end of the spacer (1), so that, by way of interengagement of the corresponding connecting devices (16) of two spacers (1), a connection of the spacers (1) is realized, characterized in that the main body has three shaped elements arranged between the connecting devices (16), specifically wave crests on the right-hand side with respect to the linear profile, wave crests on the left-hand side with respect to the linear profile and wave flanks, wherein circular cutouts (8) are arranged both in the region of the wave crests and in the region of the wave flanks.
2. Apparatus according to Claim 1, characterized in that the straight lines resulting from the connection of a vertex of a wave crest (17) to the vertices of the adjacent wave crests (17) situated opposite intersect at an angle α, where the angle α lies in an angle range of between 50° and 70°.
3. Apparatus according to Claim 2, characterized in that the angle α lies in an angle range of between 55° and 65°.
4. Apparatus according to Claim 2, characterized in that the angle α is approximately 60°.
5. Apparatus according to at least one of the preceding claims, characterized in that the standing surface (6) of the spacer (1) is reduced by additional cutouts (8) arranged in the region of the bottom side of the main body.
6. Apparatus according to Claim 1, characterized in that said apparatus is designed as a punctiform spacer (1) having at least two standing elements (5) in the form of arms and having a funnel-shaped feed structure (7), wherein the funnel-shaped feed structure (7) is able to be spread by way of an exertion of force on the pressure surfaces (11) formed by the oppositely situated outer surfaces of the arms.
7. Apparatus according to at least one of the preceding claims, characterized in that said apparatus is designed as a punctiform spacer (1) having in the region of the feed structure (7) a closure device (13) by way of which the feed structure (7) is able to be closed and the fixing of a reinforcement element in the retaining apparatus (2) is able to be intensified.
8. Apparatus according to at least one of the preceding claims, characterized in that the retaining apparatus (2) has resilient wall sections at least regionally.
9. Apparatus according to Claim 1, characterized in that said apparatus is designed as a wheel-shaped spacer (1), and in that the spacer (1) has a retaining body (15) and a support body (14) which are able to be connected to one another.
10. Apparatus according to Claim 9, characterized in that the material of the retaining body (15) and the material of the support body (14) consist of mutually different plastic mixtures.
11. Apparatus according to Claim 1, characterized in that said apparatus is designed as a linear spacer (1) having rhomboidal shaped elements.

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