DE102008033585A1 - Schubdorn connection - Google Patents

Abstract

The invention relates to connection systems for connecting two components (40, 42, 240, 242) to the type of shear pin connections. According to one aspect of the invention, a sleeve (8; 108, 109; 208, 209) is arranged in a holding element (12; 112; 212) which consists of at least two different materials. According to a further idea, the connection system is designed such that the holding element (12, 112, 212) and a reinforcement (18, 118, 218) are connected in series in the axial direction of a mandrel (10, 110, 210, 211). The invention further relates to a mandrel part (6; 106; 206) and a sleeve part (4; 104; 204) of a corresponding connection system (2; 102; 202).

Description

Technical area

The The invention relates to a connection system for connecting a first Component with a second component, as is regular used for connecting concrete slabs. The connection system is of the type of Schubdornverbindung, in which in one component a mandrel part is arranged and in the other component a sleeve part, in which the mandrel in a sliding sleeve feasible is.

State of the art

Shear dowel connections of the type mentioned above for connecting two concrete slabs known in the art. Such Schubdornverbindungen serve usually to produce expansion joints in reinforced concrete. Shear dowel connections become necessary when due to loads or thermal Expansions Relative movements of the concrete components to be joined must be allowed to allow the concrete components not be damaged. The Schubdornverbindungen serve in such systems for recording and transmission of lateral forces.

at The known systems are distinguished two basic types, so-called N types and so-called Q types. Type N pushrod connections enable a movement of the reinforced concrete components to each other in the direction of a Spine axis of the thorn. In type Q connections, both a movement in the mandrel direction as well as transversely possible. Type Q connections thus have two degrees of freedom, type N compounds only one degree of freedom.

From the EP 0 773 324 A1 is a device for connecting and for absorbing transverse forces of two separated by a joint components, in which the particular concrete components are connected by means of a mandrel.

one the two end regions of the mandrel are embedded in the first component, while in the second component a sleeve inserted is, in which penetrates the other of the two end portions of the mandrel. At the thorn and at the sleeve are in each case in the area of the joint arranged flange-like discs, which is substantially rectangular are aligned to the mandrel and sleeve and which at least partially embedded in the corresponding components. According to one Embodiment, the flange-like Slices may be formed as part of plates, which to a box profile are bent and which recesses for recording of anchoring brackets, by means of which the Plates are shed in the concrete component. The thorn is in the Box profile both on the side facing the joint, as well led to the side facing away from the joint of the box profile.

adversely At this solution, however, is that by the relatively large Extension of the boxes provided in the mandrel direction long spines Need to become. These are usually made of stainless Stainless steel because they are exposed to moisture and otherwise would tend to rust. Such long spikes made of stainless steel However, they are comparatively expensive. Another disadvantage is in that the box-like plates are temperature- and age-related tend to deform, so the sleeve side no flawless Guiding the thrust pin more guaranteed can. As a result, friction noises can occur which continue in a building as structure-borne noise and so to significant impairments or even significant structural Defects lead.

From the EP 1 477 620 A1 a fastener for concrete components is known in which a profile mandrel is provided for connecting two concrete components, which has partitions padding, which allow a certain elasticity of the concrete components relative to the fastener to reduce stress peaks in the concrete components.

adversely in the known fastener there is that there is no sufficient Having edge resistance, so that the concrete in the area of the joint despite the padding can break. In addition, you can the concrete components through the required thick padding move against each other in the direction of force, so that the Maßhastigkeit the components to each other is not very large.

task

Proceeding from this, there is the task of a connection system of the type mentioned since go further educate that it allows a high-strength connection of the components without the risk of damage to two components, the connection system allows proper management of the mandrel and wherein the connection system is also more cost-effective to produce, as known from the prior art systems.

Presentation of the invention

The Invention is solved by a connection system according to claim 1 and by a connection system according to the independent claim 10. The problem is still solved by a mandrel part according to the independent claim 13 and a sleeve part according to the sibling Claim 14.

One inventive connection system for connection a first component with a second component has a sleeve part on, which can be fixed by means of a reinforcement in the first component is. The reinforcement serves to reinforce the component and gives this a higher load capacity. Farther a mandrel part is provided in the second component by means of a reinforcement can be specified. The spine is in the connected system the two components in a sliding sleeve of the sleeve part feasible.

The Reinforcement can be part of an already existing component-side Reinforcement or may be associated with the connection system Reinforcement integrated with the system together in the components becomes.

The first and the second component exist regularly concrete, reinforced concrete or other materials used in the manufacture be shed from components.

The Both components form a joint to each other, for compensation is used by relative movements of the two components, for example, conditionally by temperature change. Preferred applications of the connection system thus exist in particular for components of large dimensions, the too large expansions with temperature changes tend, for example, bridges or larger Concrete slabs in buildings. The existing between the components For example, a joint may be filled with an elastic material, that also includes thermal insulation properties may have.

At the reinforcement of the sleeve part is a holding element for Holder of the sliding sleeve provided, which consists of at least consists of two different materials. While in contrast in the state of the art at best retaining elements are known, the consist of a material, can be with the help of at least two different Materials the requirements of a holding element for mounting realize the sliding sleeve much better.

there can be provided that the holding element partly on the one hand a particularly tensile material and partly from a part particularly pressure-resistant material, whereby the over the connection system transmitted forces especially Well received over mandrel, sleeve and retaining element and can be forwarded to the component.

By the optimization of the strength of the retaining element leaves In addition, this out of the state the construction of the known holding elements is particularly compact, what the mounting of the holding element in the production of the first Component facilitated. By the thus claimed small space In addition, it allows the retaining element can be arranged very far forward in the area of the joint. Thereby the mandrel is guided by the holding element exactly in the area, in which the largest loads through the shear pin be introduced into the holding element.

The Holding element further requires that the static calculation of the Components and the connection system only considered the joint itself must be because the mandrel so clean through the optimized retaining element is that most of the Forces on a facing to the joint end face of the components is introduced from the mandrel in the holding element and from there via the reinforcements in the components themselves. Most of expensive stainless steel existing mandrel can thus be formed very short, he only has to complete the retaining element even at maximum joint succeed.

A preferred embodiment of the retaining element of the sleeve part provides that the holding element is designed as a hollow profile, its cavity with a high-strength material, preferably high-strength Concrete is filled.

Of the high-strength concrete has a particularly high compressive strength. The retaining element then ensures that the sliding sleeve and guided in the sliding sleeve of the mandrel clean is because the compact, high-strength and thus distortion-free holding element to much less distortion than that in the prior art known large-sized holding elements. Result from this significantly lower friction stresses in the mandrel, which is a better guidance allowed and what the occurrence of friction noise minimized.

When suitable material for providing the hollow profile has Steel proved, which formed in a conventional manner as a hollow profile can be, for example by Urform- or forming process. The Retaining element is preferably made of stainless steel or stainless steel, because of this penetrating electrolyte-displaced moisture can withstand better.

Prefers the holding element is designed as a rectangular profile. rectangular profiles are extreme compared to other profiles compact, so that the holding element one over another Designs required less space. About that In addition, the retaining element can be through the flat sides of the rectangular profile especially far ahead at the component boundary or Fugue in the first component to arrange what the burden of the first Component by improved power dissipation in the relevant area reduced.

Instead of a rectangular profile can also be used as a trapezoidal profile its parallel surfaces parallel to the joint-side end face are aligned. Trapezoidal profiles allow for minimization the size of the holding part, since the trapezoid accordingly the static loads can be dimensioned.

Thereby, that with a holding element according to the invention in rectangular profile training an arrangement particularly far forward at the joint of the component is possible, the Schubdorn Beyond that, be particularly short, without the Stability of the system or the capacity of it to reduce. This leads to a considerable saving on the recommended expensive stainless steel.

A Another particularly advantageous embodiment of the connection system provides that in the holding element a plurality of juxtaposed Mounts are arranged for several mandrels. To this Way can be a holding element of larger Length specified, in which several mandrels can be arranged next to each other and are feasible. In this way, you can get big ones Transfer loads over several parallel mandrels, without a larger mandrel diameter of a single To choose Dornes.

at the known systems are always only holders for a Sliding sleeve provided. This causes that between adjacent brackets are maintained a certain distance otherwise, the load bearing capacity of the components will not have to can be guaranteed.

Around to reduce the risk of edge chipping of the device, is further provided with advantage that on the holding element a is arranged flexible element, which is a compliance of the retaining element guaranteed in the edge area. The flexible element exists preferably one or more strips in areas possible force peaks are arranged. A special Advantage arises when the flexible elements above In addition, have sealing functions to the retaining element and the reinforcement to protect against moisture. Suitable materials are swellable bitumen or elastomers.

to Production of a Type Q Connection System According to the Invention is provided with preference that in the sleeve part to enable an additional horizontal-tangential relative displacement in the first component between sliding sleeve and hollow profile another sleeve is arranged, which has a horizontal opening has the same size or larger is considered the largest transverse dimension of the sliding sleeve.

The opening the further sleeve is preferably oval, slot-like or rectangular. The larger opening the further sleeve allows the sliding sleeve can be received in the other sleeve, and that slide the sliding sleeve in the other sleeve or can roll. Oval, oblong or rectangular openings the further sleeve allow very compact Designs of the other sleeve.

One Another advantage arises when the holding element and the reinforcement are connected in series in the axial direction of the mandrel. To the one can be achieved in that the retaining element and reinforcement are particularly easy to connect with each other Providing substantially the same materials, for example by welding. The reinforcement can also consist of structural steel, which can be welded with steel or stainless steel.

About that In addition, in this way, the holding element is particularly far ahead in the area of the joint between the first component and the second Place component, preferably directly on the edge of the component. Farther it is achieved that the reinforcement is the usual edging complies, making installation of the system particularly easy is, and that the installation of the remaining component side reinforcements in areas where no shear pin connection is provided, not hindered, is.

One Another particular advantage arises when in the mandrel part a further holding element is provided for the mandrel, the the holding element of the sliding sleeve substantially in the corresponds to different embodiments described above. This can also be thornseitig a particularly good Force introduction of the forces occurring in the second component accomplish, so here also Randabplatzungen in the second Component can be prevented and the thrust pin especially easy to install.

Prefers is in the mandrel part a guide sleeve for provided the mandrel, within which the mandrel is fixable. In this way, the mandrel part can first Mount without a mandrel and then insert the mandrel.

One first independent idea of the invention relates to a Connection system for connecting a first component with a second component having a sleeve part by means of a reinforcement in the first component can be fixed and the one Having mandrel part, by means of a reinforcement in the second component is determinable. Through a thorn of the mandrel part is a connection can be produced between the first component and the second component, wherein the mandrel in a sliding sleeve of the sleeve part is feasible.

To the one can be achieved in that the retaining element and reinforcement are particularly easy to connect with each other Providing substantially the same materials, for example by welding. The reinforcement can also consist of structural steel, which can be welded with steel or stainless steel.

About that In addition, in this way, the holding element is particularly far ahead in the area of the joint between the first component and the second Place component, preferably directly on the edge of the component. Farther it is achieved that the reinforcement is exactly the usual edge borders complies, making installation of the system particularly easy is, and that the installation of the remaining component side reinforcements in areas where no shear pin connection is provided, not hindered, is.

According to the invention provided according to the second inventive idea, that the holding element and the reinforcement in the axial direction of Dornes are connected in series. That way the retaining element attach particularly easily to the reinforcement and the holding element particularly far forward in the area of between Arrange the joint formed joints. This prevents popping out by force peaks on the first component and allows a particularly reliable guidance of the mandrel in the sleeve part.

Especially Preferably, the retaining element for holding the sliding sleeve made of at least two different materials.

While in contrast, in the prior art at most holding elements are known, which consist of a material can be with the help at least two different materials the requirements to a holding element for holding the sliding sleeve very much realize it better.

there can be provided that the holding element partly on the one hand a particularly tensile material and partly from a part particularly pressure-resistant material, whereby the over the connection system transmitted forces especially Well received over mandrel, sleeve and retaining element and can be forwarded to the component.

By the optimization of the strength of the retaining element leaves In addition, this out of the state the construction of the known holding elements is particularly compact, what the mounting of the holding element in the production of the first Component facilitated. By the thus claimed small space In addition, it allows the retaining element can be arranged very far forward in the area of the joint. Thereby the mandrel is guided by the holding element exactly in the area, in which the largest loads through the shear pin be introduced into the holding element.

Incidentally, the connection system according to the first independent idea of the invention has one or more of the other advantageous features of the invention described first on.

One Another object of the invention relates to a mandrel part of a connection system, as previously described.

One The last idea of the invention relates to a sleeve part of a previously described connection system.

Further Objectives, features and advantageous applications The invention will become apparent from the following description of a Embodiment with reference to the drawings. Make up all described and / or illustrated Features in their meaningful combination the subject of the present Invention, also independent of the patent claims and their remittances.

Brief description of the figures

It show schematically:

1 an inventive connection system according to a first embodiment in a side view;

2 a perspective view of the first embodiment obliquely from the side;

3 the system according to 1 in installed condition;

4 the system off 1 in a perspective view obliquely from above;

5 Elements of the system 1 in exploded view;

6 Elements of the system 5 in pre-assembled condition;

7 an inventive connection system according to a second embodiment in a perspective view;

8th the system off 7 in a perspective view from another angle;

9 the system off 7 with attached reinforcements in perspective view;

10 a third embodiment of the invention in perspective view;

11 the system off 10 with attached reinforcements as well

12 the system off 10 in installed condition.

embodiments

1 shows a connection system according to the invention 2 with a sleeve part 4 and a spine part 6 in aligned position.

The sleeve part 4 has a sliding sleeve 8th on, in which a thorn 10 is guided in a sliding manner. The sliding sleeve 8th consists of polyamide, which reduces the frictional forces of the mandrel 10 in the sliding sleeve 8th minimized. Other suitable plastics are PTFE, PP and the like. The sliding sleeve 8th has an inner diameter that is slightly larger than the diameter of the mandrel 10 so the thorn 10 easy in the sliding sleeve 8th is insertable.

The sliding sleeve 8th is in a holding element 12 attached, which consists of a rectangular tube 14 made of stainless steel, which is a concrete filling 16 made of high-strength concrete. The holding element 12 is on a sleeve-side reinforcement 18 welded. The reinforcing bars 18 consist of conventional reinforcing steel, for example BSt 500 S.

The construction on the side of the mandrel part 6 is the structure of the sleeve part 4 corresponding. There is a retaining element 22 provided, which is a rectangular tube 24 has that with a concrete filling 26 made of high-strength concrete. The thorn 10 is in the holding element 24 established. The holding element 24 is also on the mandrel side to a reinforcement 28 welded, which is anchored in the corresponding component (see 3 ).

The thorn 10 exists, like the rectangular tubes 14 . 24 , made of stainless steel.

On the holding elements 12 . 22 are for attachment two reinforcing bars 18 . 28 intended. Depending on the dimensions, you can also use several brackets 18 . 28 on the holding elements 12 . 22 be welded.

2 shows the connection system 2 out 1 in perspective oblique view. The holding element 22 is by means of welds 30 with the straps 28 connected. Sleeve part side, the connection between the holding element 12 and ironing 18 , corresponding.

3 shows the connection system according to the invention 2 in a side view in installed condition.

Sleeve side is a first concrete slab 40 provided, thornseitig a second concrete slab 42 , Between the first concrete slab 40 and the second concrete slab 42 is a fugue 44 formed, the relative movements between the concrete slabs 40 and 42 allows. The holding elements 12 . 22 are directly in the edge area of the plates 40 . 42 arranged and protrude at the joint-side front side of the concrete slabs 40 . 42 up to its surface. By such an arrangement can be cracks in the concrete slabs 40 . 42 To prevent particularly effective under load of use.

By this arrangement, the high-strength holding elements 12 . 22 directly adjoin the joint is a load to be transmitted directly from the holding elements 12 . 22 taken and over the welded reinforcements 18 . 28 derived in the concrete. This enormously reduces the load on the reinforced concrete components in the area of the mandrel connection, so that they remain free of cracks for a very long time. The loads are distributed with the connection system according to the invention namely much larger area, so that the local forces on the plates 40 . 42 lower than in known Schubdornverbindungen.

4 shows the connection system according to the invention 2 in installed condition from diagonally above. Due to the compactness of the connection system 2 , the rectangular tubes 14 . 24 have in Schubdornrichtung an extension of about 20 to 40 mm, the system can be 2 easily into the rest of the on-site reinforcement 46 integrate without the on-site reinforcement 46 Changes must be made. This facilitates the assembly of the connection system 2 very. Also to the sleeve part 4 or Dornteil 6 belonging reinforcements 18 . 28 can be easily in the usual on-site reinforcement 46 integrate.

5 shows an exploded view of the connection system according to the invention 2 without sleeve-side and mandrel-sided reinforcement.

The thorn 10 is sleeve side in the rectangular tube 24 by means of a sleeve 50 made of polyamide or other suitable materials, resulting in the mandrel 10 very light in the rectangular tube 24 can bring in and what noise generation reduces relative movements. On the plastic sleeve 50 may be waived if the ambient conditions permit, for example, if appropriate noise is counteracted by other methods.

In addition, on the rectangular tubes 14 . 24 strip 52 be designed from swellable bitumen, whereby on the one hand a sealing effect is achieved. In this way, the rectangular tubes can 14 . 24 as well as the reinforcements 18 . 28 . 46 be protected against corrosion, as may occur depending on the particular field of application, in particular, since the moisture usually as an aggressive electrolyte to the rectangular tubes 14 . 24 as well as the reinforcements 18 . 28 . 46 gets, especially if the concrete components 40 . 42 Have cracks. Furthermore, swellable bitumen in the swollen state has an elasticity, which under load a low compliance between sleeve part 4 or Dornteil 6 and the concrete slabs 40 . 42 allows. In this way, voltage peaks can be further reduced, so that the concrete components 40 . 42 have an even lower tendency to crack.

For completion of sleeve part 4 and spine part 6 The sleeves are in the appropriate position in the rectangular tubes 14 . 24 introduced and fixed there, preferably by clamping or gluing. Subsequently, will in the spine part 6 the thorn 10 in the plastic sleeve introduced there 50 introduced. The thorn 10 can in the spine part 6 glued or welded, for example by spot welding.

If provided, be sealing strips 52 on the rectangular tubes 14 . 24 applied. Subsequently, the cavities 54 the rectangular tubes potted with high-strength concrete ( 6 ). sleeve part 4 and spine part 6 can be prepared in this form at the factory and used element by element at the construction site.

It is also possible, Dornteil 6 and sleeve part 4 to the on-site reinforcement 46 weld, making separate mandrel side and sleeve-side reinforcement parts are unnecessary.

The prepared components of the connection system 2 be in the on-site reinforcement 46 integrated or to the on-site reinforcement 46 welded, the spike 10 of the mandrel part 6 in the sleeve 8th of the sleeve part 4 is inserted. Then the reinforcement is boarded and poured with concrete. This will be the rectangular tubes 14 . 24 positioned adjacent to a formwork.

The 7 to 9 show a second embodiment of the invention, in which a connection system 102 is specified, which is a sleeve part 104 and a spine part 106 having, wherein the sleeve part 104 two pods 108 . 109 has, which are guided into each other. The additional sleeve 109 is formed slot-shaped and has a clear width, which is greater than the largest extension of the sleeve 108 , so that the sleeve 108 in the sleeve 109 can slide or roll. In this way, a relative movement of the components to be joined is made possible, which is useful for very large plates, in particular thermal expansion, since the components usually extend in all directions. All other components correspond to the components according to the first embodiment.

8th shows the system 102 from a perspective of the sleeve part 104 out of view.

9 shows the system 102 including reinforcements 118 . 128 , which by means of welds 130 on the rectangular tubes 114 . 124 are fixed.

The 10 . 11 and 12 show a third embodiment of the invention, according to which a connection system 202 is given, which is opposite to in the 1 to 7 shown first embodiment differs in that on the part of the sleeve 204 and part of the spine part 206 several pods 208 . 209 are provided for several spines 210 . 211 , The illustrated embodiment according to 10 to 12 is only an example, it can also be given connection systems with any number of sleeves and a corresponding number of thorns. With the help of the modular design can be compared to the known Schubdornverbindungen transfer significantly higher forces, since with separate Schubdornverbindungen a minimum distance must be maintained in order to maintain the structural strength.

According to 11 are according to the number of pods 208 . 209 or spines 210 . 211 Correspondingly more reinforcement bars 218 . 228 provided.

12 shows the connection system 202 in assembled condition, as in the on-site reinforcement 246 is integrated.

Not shown is another conceivable embodiment in which in a rectangular tube a plurality of sleeves or a plurality of mandrels according to the third embodiment, which are designed as type Q according to the second illustrated embodiment. LIST OF REFERENCE NUMBERS 2 connection system 116 concrete filling 4 sleeve part 118 Sleeve-side reinforcement 6 mandrel part 122 retaining element 8th sliding sleeve 124 rectangular tube 10 mandrel 126 concrete filling 12 retaining element 128 Thorn-side reinforcement 14 rectangular tube 130 welds 16 concrete filling 152 bitumen strips 18 Sleeve-side reinforcement 202 connection system 22 retaining element 204 sleeve part 24 rectangular tube 206 mandrel part 26 concrete filling 208 sliding sleeve 28 Thorn-side reinforcement 209 sliding sleeve 30 welds 210 mandrel 40 First component 211 mandrel 42 Second component 212 retaining element 44 Gap 214 rectangular tube 46 On-site reinforcement 216 concrete filling 50 Plastic sleeve 218 Sleeve-side reinforcement 52 bitumen strips 222 retaining element 54 cavities 224 rectangular tube 102 connection system 226 concrete filling 104 sleeve part 228 Thorn-side reinforcement 106 mandrel part 230 welds 108 sliding sleeve 240 first component 109 Slot-shaped sliding sleeve 242 second component 110 mandrel 244 Gap 112 retaining element 246 on-site reinforcement 114 rectangular tube 252 bitumen strips

QUOTES INCLUDE IN THE DESCRIPTION

This list The documents listed by the applicant have been automated generated and is solely for better information recorded by the reader. The list is not part of the German Patent or utility model application. The DPMA takes over no liability for any errors or omissions.

Cited patent literature

• EP 0773324 A1 [0004]
• EP 1477620 A1 [0007]

Claims (14)

Connection system for connecting a first component ( 40 ; 240 ) with a second component ( 42 ; 242 ), with a sleeve part ( 4 ; 104 ; 204 ), which by means of a reinforcement ( 18 ; 46 ; 118 ; 218 ; 246 ) in the first component ( 40 ; 240 ) is fixable, and a mandrel part ( 6 ; 106 ; 206 ), which by means of a reinforcement ( 28 ; 46 ; 128 ; 218 ; 246 ) in the second component ( 42 ; 242 ) is fixed, whereby by a thorn ( 10 ; 110 ; 210 ; 211 ) of the mandrel part ( 6 ; 106 ; 206 ) a connection between the first component ( 40 ; 240 ) and the second component ( 42 ; 242 ) can be produced, wherein the mandrel ( 10 ; 110 ; 210 ; 211 ) in a sliding sleeve ( 8th ; 108 ; 208 ) of the sleeve part ( 4 ; 104 ; 204 ) is feasible, characterized in that at the reinforcement ( 18 ; 46 ; 118 ; 218 ; 246 ) of the sleeve part ( 4 ; 104 ; 204 ) a holding element ( 12 ; 112 ; 212 ) for holding the sliding sleeve ( 8th ; 108 ; 208 ) is provided, which consists of at least two different materials. Connection system according to claim 1, characterized in that the retaining element ( 12 ; 112 ; 212 ) as a hollow profile ( 14 ; 114 ; 214 ) is formed, whose cavity ( 54 ) with a high-strength material, preferably high-strength concrete ( 16 ; 116 ; 216 ), is filled. Connection system according to claim 1 or 2, characterized in that the retaining element ( 12 ; 112 ; 212 ) as a rectangular profile ( 14 ; 114 ; 214 ) is trained. Connection system according to one of the preceding claims, characterized in that in the holding element ( 12 ; 112 ; 212 ) a plurality of juxtaposed brackets for a plurality of thorns ( 210 . 211 ) are provided. Connection system according to one of the preceding claims, characterized in that the retaining element ( 12 ; 112 ; 212 ) by means of a flexible element ( 52 ; 152 ; 252 ), preferably consisting of one or more strips, is sealed. Connection system according to one of the preceding claims, characterized in that in the sleeve part ( 104 ) for enabling an additional horizontal-tangential relative displacement between the first component and the second component between the sliding sleeve ( 108 ) and retaining element ( 112 ) another sleeve ( 109 ) is provided, which has a horizontal opening which is equal to or larger than the largest transverse dimension of the sliding sleeve ( 108 ), wherein the opening of the further sleeve ( 109 ) is preferably oval, slot-like or rectangular. Connection system according to one of the preceding claims, characterized in that the retaining element ( 12 ; 112 ; 212 ) and the reinforcement ( 18 ; 46 ; 118 ; 218 ; 246 ) in the axial direction of the mandrel ( 10 ; 110 ; 210 ) are connected in series. Connection system according to one of the preceding claims, characterized in that the mandrel part ( 6 ; 106 ; 206 ) a second retaining element ( 22 ; 122 ; 222 ) for the thorn ( 10 ; 110 ; 210 ; 211 ), which according to the sleeve-side holding element ( 12 ; 112 ; 212 ) is formed according to one of claims 1 to 5. Connection system according to one of the preceding claims, characterized in that in the mandrel part ( 6 ; 106 ; 206 ) a guide sleeve ( 50 ) for the thorn ( 10 ; 110 ; 210 ; 211 ) is provided. Connection system for connecting a first component ( 40 ; 240 ) with a second component ( 42 ; 242 ), with a sleeve part ( 4 ; 104 ; 204 ), which by means of a reinforcement ( 18 ; 28 ; 46 ; 118 ; 218 ; 246 ) in the first component ( 40 ; 240 ) is fixable, and a mandrel part ( 6 ; 106 ; 206 ), which by means of a reinforcement in the second component ( 42 ; 242 ) is fixed, whereby by a thorn ( 10 ; 110 ; 210 ; 211 ) of the mandrel part ( 6 ; 106 ; 206 ) a connection between the first component ( 40 ; 240 ) and the second component ( 42 ; 242 ) can be produced, wherein the mandrel ( 10 ; 110 ; 210 ; 211 ) in a sliding sleeve ( 108 ) of the sleeve part ( 104 ) is feasible, characterized in that the retaining element ( 12 ; 112 ; 212 ) and the reinforcement ( 246 ) in the axial direction of the mandrel ( 10 ; 110 ; 210 ; 211 ) are connected in series. Connection system according to claim 10, characterized in that the retaining element ( 12 ; 112 ; 212 ) consists of at least two different materials. Connection system according to Claim 10 or 11, having one or more of the further features of the connection system listed in the subclaims 2 to 6, 8 and 9 ( 2 ; 102 ; 202 ) according to claim 1. Dornteil ( 6 ; 106 ; 206 ) of a connection system ( 2 ; 102 ; 202 ) according to one of the preceding claims. Sleeve part ( 4 ; 104 ; 204 ) of a connection system ( 2 ; 102 ; 202 ) according to any one of claims 1 to 12.