DE102018103138A1 - Rivet thread element and component arrangement with rivet thread element - Google Patents

Abstract

The invention relates to a rivet thread element (1, 30, 41), in particular rivet nut or rivet screw, having an insertion shaft (3) which can be inserted into an opening (11, 49) of a component to be connected, and one adjoining the insertion shaft (3) A head portion (2, 31) having a width (b) greater than an outer diameter (d) of the insertion shaft (3), the insertion shaft (3) comprising an elastically and / or plastically deformable upset portion (5). Furthermore, the invention relates to a component arrangement (9, 24, 35) with such a rivet threaded element (1, 30, 41). In order to provide a rivet thread element, which allows a reliable anti-rotation with low demands on the tolerances to be maintained, the invention provides that the head part (2, 31) has a non-circular outer profile (4) through which, in cooperation with a head part (2, 31 ) receiving component (10, 18, 19, 20, 26) an anti-rotation device can be produced.

Description

The invention relates to a rivet threaded element, in particular a rivet nut or rivet screw, with an insertion shaft, which is insertable into an opening of a component to be connected, and a subsequent to the insertion head portion having a width which is greater than an outer diameter of the insert shaft, wherein the insert comprises an elastically and / or plastically deformable compression portion. Furthermore, the invention relates to a component arrangement with such a rivet threaded element.

Riveting threads can be provided as rivet nuts with an internal thread, or as rivet screws have an external thread. About the compression portion of the rivet threaded element, the thread can be riveted to a component.

Rivet nuts, which are called with the possibility of one-sided assembly and blind rivet nuts, make it possible to attach a female thread with relatively low installation effort force and / or positive locking in components. Likewise, rivet screws, which are also called blind rivet screws, offer the possibility of frictionally and / or positively fixing an external thread to components with little installation effort. At the same time, rivet nuts or rivet screws can also serve as a connecting element without the associated screw or nut, in that components are already connected to one another with the riveting process.

A rivet nut of the above type is used in the DE 9001069 U1 described. To connect two components by means of a rivet nut, the rivet threaded element is first inserted into a prefabricated hole of a first component. Subsequently, the second component is placed on the first component and fixed with a screw inserted into the rivet thread element on the first component. During the screwing, the riveting process takes place, whereby a tensile force is applied to the thread of the rivet nut via the screw. A deformation section provided above the thread is plastically deformed by the tensile force and forms a bead-like formation, by means of which the rivet thread element is positively connected to the first component.

Alternatively, the rivet threaded element can first be riveted to the first component, without fixing the second component. For this purpose, spindles can be used, which are screwed into the internal thread of the rivet nut. Subsequently, a tensile force can be applied to the shank of the rivet nut, thus producing a compression and a positive connection with the component.

A problem of the riveting operation via the screw connection is that the rivet thread element on the first component must be secured against rotation in order to be able to absorb the torsional forces required for the screw connection. In order to prevent unintentional twisting, the insert shaft can therefore be provided with an anti-twist device. In the EP 1 557 577 A2 For example, a rivet nut is shown with a male shank, which has a hexagonal profile, abut the edges of which during the assembly process to inner surfaces of this hexagonal designed hole in the first component and thus secure the rivet threaded element against rotation.

The WO 99/42732 shows a rivet nut, which is movably inserted into a first prefabricated hole of a component. In order to ensure the mobility, the inner diameter of the hole is slightly larger than the outer diameter of the inserted shaft portion of the rivet nut, so that even with compressed rivet nut mobility remains. Adjacent to the first prefabricated hole, a second, smaller hole is provided in the component into which engages a rigidly connected to the rivet nut torque arm, which prevents rotation of the rivet nut.

A disadvantage of the known rivet thread elements is that the opening of the component for receiving the insertion shank of the rivet thread element, on which the positive locking of the rivet thread element is manufactured with the component, must be profiled at the same time for the required rotation. This results in close tolerances for this opening, which can result in an increased installation effort, or the transmission of the torque occurring during the riveting process takes place with only a low degree of reliability.

It is therefore an object of the present invention to provide a rivet thread element or a component arrangement with a rivet thread element, by means of which or by the tolerances to be complied with with small demands on the rivet thread element during assembly and / or disassembly of a component connected via the rivet thread element.

This object is achieved by a rivet threaded element according to claim 1. Furthermore, the object is achieved with a component arrangement according to claim 3 or 4 and a method according to claim 13.

By the head part of the rivet threaded element at its opposite to the insertion direction pointing end has a non-circular outer profile, through which in conjunction with a head member receiving component an anti-rotation can be produced, the function of the rotation of the shank of the rivet threaded member is displaced to the head part of the rivet threaded element. The rotation can be produced by the use of the head part in a non-round and / or at least partially adjacent and / or complementarily configured receiving opening of a component. Because of the larger diameter or larger circumference of the head part of this can transfer greater mounting moments, wherein the transmittable torque is sufficiently large, even with larger tolerance deviations of the head part.

Other embodiments, modifications and improvements will become apparent from the following description and the appended claims.

The rivet thread element is preferably configured as a rivet nut with a threaded portion and a compression portion extending between the threaded portion and the head portion. By means of a spindle or threaded bolt screwed into the threaded section, compressive force can thus be applied to the swaging section in order to compress the swaging section. In a component arrangement with a rivet threaded element according to the invention, a first component can have an opening for inserting the insert shaft, the first component having a head receiver can. In a further embodiment of a component arrangement with a rivet threaded element according to the invention, a first component with an opening for insertion of the insert shaft and a second component for attachment to the first component may be provided, wherein the first and / or the second component may have a head receiving. The head receptacle serves primarily to prevent rotation, in order to prevent the components from being assembled or disassembled, or during riveting of the rivet threaded element, e.g. via a screw or a nut to prevent twisting of the rivet threaded element. When the head part is inserted, the head receiver can adjoin it in sections and thus form the anti-twist device together with the head part. The height of the head part can be designed such that the torque required for releasing screws inserted into the rivet thread element can be reliably transmitted from the head part to the head receptacle.

In known rivet threaded elements, the head part often projects beyond the adjoining surface of the component even after the assembly of the rivet thread element, as a result of which components which are to be screwed over the rivet thread element rest on the head part after their assembly. To solve this problem, the head receptacle in the insertion direction may have a depth which corresponds at least to the height of the head part. The head receptacle can allow a complete countersinking of the head part of the rivet thread element, so that after the screwing of the component arrangement no forces act on the head part. At the same time, the lowest possible headboard height H be sought in order to keep the required size of the head recording as small as possible.

A standard connection comprises two components to be connected, in which the second component is placed on the first and connected by a screw. But it can also be connected three and more components. In particular, if the attachment of a third component is planned via the rivet threaded element on the first and second component, the head receptacle can be arranged in the second component. The first and the second component can then already with the riveting, i. the positive connection of the rivet threaded element, are interconnected. Alternatively, the first component may comprise a head receptacle. The rivet threaded element can thus be used for mounting in the component and riveted via the thread in the insert shaft, even before a second component is placed on the first component.

According to an expedient development of the invention, the head receptacle in the second component can be formed by an opening designed as a passage opening, in particular a passage opening for the head part, through which the head part can be passed. The second component can be configured as a supplement or form a supplement. The second component or the supplement can remain after the assembly of a third component between the first and third component. With a through opening, the second component thus creates a space between the first and third component, in which the head part of the rivet thread element remains, wherein side walls of this space form the anti-rotation device for mounting or dismounting the rivet threaded element and the associated fastening screw or nut. For this purpose, the second component, at least in the region of the head part receptacle, has a height which at least corresponds to the height of the head part in order to completely accommodate the head part of the rivet thread element.

In a further embodiment of the invention, a plurality of supplements can be arranged between the components to be joined. The headrest can extend over several supplements. The total height of the head support, regardless of whether it consists of one or more components, can always be slightly greater than the height of the head portion of the rivet threaded element his. Then it is ensured that the components to be connected are clamped together.

The components that lie between the screw head and the component with the head rest are preferably designed such that a meaningful pressure cone can form. If the component with the head rest directly adjoin the head of the screw, then this can either have a sufficiently large support diameter itself, or the support diameter can be realized by attached washers or expansion sleeves. The pressure cone of the connection ideally captures a sufficiently large area of the sheet forming the headrest.

In a further embodiment of the component arrangement, the head receptacle in the first or in the second component can be formed by a depression in which the head part rests in the insertion direction. If the head part lies in a head receptacle in the second component in the insertion direction, the riveting operation, i. the attachment of the rivet thread element, at the same time the first and second components are connected to each other.

For best possible power transmission from the head part to the head receptacle, the head part can be held positively in the head receptacle. For this purpose, the head receptacle or the profile of the head receptacle in the insertion direction, at least partially complementary to the head part or the profile of the head part, in particular in the insertion direction, be formed. Alternatively, the head receptacle on opposite sides of the head part with substantially parallel surfaces abut this. There are a variety of shapes of the head mount conceivable to ensure a positive fit, which may differ by the maximum sustainable mounting moment.

According to a further variant of the invention, the component arrangement may comprise a screw for screwing to an internal thread of the rivet threaded element, which has a head with a width dimension which is greater than a width dimension of the head receptacle.

Alternatively, a washer may be provided with a width dimension larger than a width dimension of the head socket. In this way, it is possible to connect a second component with a head opening formed by a passage opening via the screw with the first component, without the positive connection between the screw and the second component is lost due to the continuous head mounting.

In order to enable a tolerance compensation or to move the components before screwing over the rivet threaded element to each other, the head receptacle can be configured in a further preferred embodiment of the invention as a slot. The slot can have approximately the width of the head part in order to act with the head part as a positive rotation. The opposite longitudinal sides of the oblong hole can rest on both sides of the head part of the rivet thread element when the rivet thread element is inserted, or can be spaced apart from it by only a small distance. Between headboard and long sides can be provided to a clearance fit.

In an alternative embodiment of the invention, the component arrangement may comprise a locking device, by which the second component can be secured against rotation on the first component. This aspect particularly relates to embodiments of the invention in which a head receptacle is provided in the second component. Thus, the head receptacle and in this recordable head part of the rivet threaded element can be secured against rotation. The locking device may be formed by a screw in one of the components and a threaded bore in the respective other component. Alternatively, the locking device may have an extension on a component, e.g. can be configured as a mandrel, and have a receiving opening for the extension to the respective other component.

In a further preferred embodiment of the invention, an adjacent rivet thread element form the rotation. The component assembly thus comprises in this embodiment at least two rivet threaded elements. Both rivet threaded elements can be used at the same time in the first and the second component to prevent twisting of the components against each other.

A method according to the invention for mounting a component arrangement comprises the steps of arranging the second component on the first component, inserting the insertion shaft of the rivet threaded element into the first component, inserting the head portion of the rivet threaded element into the head receptacle, countersinking the head portion in the head receptacle, then screwing in a screw the rivet threaded element or screwing a nut onto the rivet threaded element, wherein the rivet threaded element is secured against rotation via the head part and the head receptacle.

A screw can be screwed into a rivet nut according to the invention or a nut can be screwed onto a rivet screw according to the invention until the screw head or the nut rests and a tensile force is applied to the thread of the rivet thread element. Subsequently, the screw or the nut is further actuated until about the thread of the insertion of the rivet thread element has been sufficiently compressed for a positive connection. Throughout the screwing process, the rivet thread element is secured against rotation via the head mount. The connection between the rivet threaded element and the component is made by tightening the screw which remains in the connection. Alternatively, the rivet threaded element can be compressed by a screw-spindle. In this case, the setting of the connection between the rivet threaded element and the component can take place via a tensile force acting on the threaded portion.

• 1 ist eine perspektivische Darstellung eines erfindungsgemäßen Nietgewindeelementes;
• 2 ist eine Draufsicht des Nietgewindeelementes der 1;
• 3 ist eine Seitenansicht des Nietgewindeelementes der 1 und 2;
• 4 ist eine Schnittansicht eines in ein Bauteil eingesetzten Nietgewindeelementes;
• 5 ist eine Draufsicht des Nietgewindeelementes mit Bauteil der 4;
• 6 ist eine Draufsicht einer ersten Ausführungsform einer erfindungsgemäßen Beilage;
• 7 ist eine Draufsicht einer zweiten Ausführungsform einer erfindungsgemäßen Beilage;
• 8 ist eine Draufsicht einer dritten Ausführungsform einer erfindungsgemäßen Beilage;
• 9 ist eine Draufsicht einer dritten Ausführungsform einer erfindungsgemäßen Beilage;
• 10 ist eine Draufsicht einer weiteren erfindungsgemäßen Bauteilanordnung mit einem Nietgewindeelement;
• 11 ist eine Schnittansicht eines in ein Bauteil eingesetzten Nietgewindeelementes gemäß der Schnittlinie A-A der 10;
• 12 ist eine Schnittansicht gemäß der Schnittlinie B-B der 10;
• 13 ist eine Draufsicht einer erfindungsgemäßen Bauteilanordnung;
• 14 ist eine Schnittansicht einer Bauteilanordnung entlang der Schnittlinie C-C der 13;
• 15 ist eine Schnittansicht einer weiteren Variante einer Bauteilanordnung entlang der Schnittlinie C-C der 13;
• 16 ist eine Draufsicht einer erfindungsgemäßen Bauteilanordnung;
• 17 ist eine Schnittansicht der Bauteilanordnung der 16 entlang der Schnittlinie D-D;
• 18 ist eine Schnittansicht der Bauteilanordnung der 16 entlang der Schnittlinie E-E;
• 19 ist eine Draufsicht eines Dritten Bauteils der Bauteilanordnung der 16 bis 18;
• 20 ist eine Draufsicht einer Beilage der Bauteilanordnung der 16 bis 18;
• 21 ist eine Seitenansicht einer weiteren Variante einer erfindungsgemäßen Bauteilanordnung.

The accompanying drawings illustrate embodiments of the invention and, together with the description, serve to explain the principles of the invention.

• 1 is a perspective view of a rivet threaded element according to the invention;
• 2 is a plan view of the rivet threaded element of 1 ;
• 3 is a side view of the rivet threaded element of 1 and 2 ;
• 4 is a sectional view of a rivet threaded member inserted into a component;
• 5 is a plan view of the rivet threaded element with component of 4 ;
• 6 is a plan view of a first embodiment of a side dish according to the invention;
• 7 is a plan view of a second embodiment of a side dish according to the invention;
• 8th is a plan view of a third embodiment of a side dish according to the invention;
• 9 is a plan view of a third embodiment of a side dish according to the invention;
• 10 is a plan view of another component assembly according to the invention with a rivet threaded element;
• 11 is a sectional view of a rivet threaded member used in a component according to the section line AA the 10 ;
• 12 is a sectional view along the section line BB the 10 ;
• 13 is a plan view of a component assembly according to the invention;
• 14 is a sectional view of a component assembly along the section line CC the 13 ;
• 15 is a sectional view of another variant of a component assembly along the section line CC the 13 ;
• 16 is a plan view of a component assembly according to the invention;
• 17 is a sectional view of the component assembly of 16 along the cutting line DD ;
• 18 is a sectional view of the component assembly of 16 along the cutting line e - e ;
• 19 is a plan view of a third component of the component assembly of 16 to 18 ;
• 20 is a plan view of a supplement of the component assembly of 16 to 18 ;
• 21 is a side view of another variant of a component assembly according to the invention.

The following are with reference to the 1 to 21 Embodiments of the invention Nietgewindeelementes or the component assembly according to the invention described.

1 shows a rivet threaded element according to the invention 1 with a headboard 2 and an insert 3 , where the headboard 2 a width b which is larger than an outer diameter d of the inset 3 is. The inscription 3 facing bottom of the headboard 2 forms a bearing surface around the rivet threaded element used in a receiving bore of a component 1 to hold on the component.

The headboard 2 is with an external profile 4 , here in the form of a hexagon provided. The outer profile 4 allows according to the invention, together with a provided in a component head receiving a rotation of the rivet threaded element 1 , Due to the hexagonal outer profile 4 the headboard works 2 when used in an at least partially adjacent or complementary configured head shot together with the head recording as rotation.

The inset 3 is designed in sections compressible to the rivet threaded element 1 To be able to connect with a component via a positive connection. This has the insert 3 an elastically or plastically deformable compression section 5 and one to the compression section 5 subsequent threaded section 6 on. The compression section 5 can be configured elastically or plastically deformable. The deformation of the compression section 5 via a in the threaded section 6 Screwed thread, eg on a bolt or a screw, over the threaded section 6 a tensile force in the direction of the head part 2 can be applied.

In the plan view of 2 is the hexagonal outer profile 4 of the headboard 2 shown. over an opening 7 in the headboard 2 is the thread 8th of the threaded section 6 accessible.

3 shows a rivet threaded element according to the invention 1 in a side view. The thread 8th , with respect to the compression section 5 opposite the headboard 2 is arranged, is shown here as a dashed line. The headboard 2 has a headboard height H on, which is dimensioned so that over the thread 8th introduced torques can be reliably transmitted form-fitting.

4 is a sectional view of a component assembly 9 with a rivet thread element 1 in a first component 10 , The first component 10 is with an opening designed as a passage opening 11 in which of the insert shaft 3 of the rivet thread element 1 is used. The rivet thread element 1 is in a compressed state, in which the upsetting section 5 is compressed and thus a positive connection between the rivet threaded element 1 and the first component 10 consists.

The headboard 2 is in a head shot 13 , The head shot 13 is from a recess in the first component 10 educated. While the headboard 2 has an outer hexagonal profile, has the head mount 13 an elongated groove 14 on that in 5 is shown in a plan view. To hang up another, with the first component 10 to be screwed component on the first component 10 allow without leaving the extra component on the headboard 2 rests, has the head recording 13 or the groove 14 in the insertion direction e a depth t on, at least the headboard height H of the headboard 2 equal to or greater than the header height H 2 is measured. The head shot 13 takes the headboard 2 in its height thus completely on, leaving another component on the first component 10 put on and over the rivet threaded element 1 can be screwed with this, without the other component on the rivet threaded element 1 rests. In particular, at low-load connections may possibly be tolerated a support of the other component on the head of the rivet threaded element, ie when the headboard height H the depth t the head shot 13 equivalent.

In the in 5 shown groove 14 is the in 4 to see opening 11 arranged. The groove 14 is elongated in the sense of a simple production. The headboard 2 in the opening 11 used rivet threaded element 1 lies on its edge on the bottom of the groove 14 on. The flanks of the headboard 2 borders on the lateral inner surfaces of the groove 14 and thus form together with the groove 14 an anti-rotation of the rivet threaded element.

In 6 is a second component 15 shown, which can be designed as a liner. In the second component 15 is a head shot 16 arranged, which is designed as a passage opening. The head shot 16 has here a hexagonal profile, which is substantially complementary to in 1 shown outer profile 4 of the rivet thread element 1 is designed. To insert a head portion of a rivet threaded element 1 To facilitate, is the diameter or circumference of the head receptacle 16 chosen slightly larger than the diameter or circumference of the outer profile 4 of the rivet thread element 1 ,

Distanced from the head-shot 16 is in the second component 15 a hole 17 arranged. The hole 17 serves to receive a countersunk screw for connection to a to be arranged below the second component first component. In the assembled state forms the countersunk screw with the bore 17 a locking device through which the second component 15 can be secured against rotation on a first component. This is necessary, unless otherwise an anti-rotation is guaranteed. An alternative security against rotation can alternatively be produced, for example, by a second rivet thread element, which is arranged adjacently in the same component.

7 shows a second embodiment of a second component 18 which can form an intermediate layer or insert for the assembly of a third component. There are two head shots 16 provided, which preferably have a depth which is at least the height H a head portion of a rivet threaded element corresponds. With the two head shots 16 two rivet threaded elements can be mounted simultaneously, with a head mount 16 each for the other head shot 16 or in the other head shot 16 recorded rivet thread element acts as a locking device.

8th and 9 are further embodiments of a second component 19 . 20 , which serves as an intermediate layer or supplement for the assembly of a third component. The head shots 21 . 22 are each designed as slots. The width B the head shots 21 . 22 is only slightly larger than the smallest width b of the headboard. This ensures that the head part is in the head receptacle 21 . 22 can not turn when loaded with a mounting torque. The head shot 22 of the second component 20 also has a hexagonal contour 23 on, in which two opposite edges are extended, so that there is a slot. The three corners at the ends of the head holder 22 form a partially complementary to the head portion of the rivet threaded element shaped portion which enhances the action as a locking device.

10 shows a further embodiment of a first component 29 that looks like the component of the 5 with a groove 14 is provided, which is a head intake 34 forms. In the first component 29 is a rivet threaded element 30 used. The rivet thread element 30 has a headboard 31 on, the form-fitting in the groove 14 flies and together with this a locking device 51 forms. For the best possible power transmission through the side walls of the groove 14 to reach is the head part 31 elongated. Here, the head part here has a substantially oval outline or the outline comprises two semicircles whose ends are connected to each other via two mutually parallel lines. The side surfaces forming the straight lines 32 and 33 of the head part lie on the inner surfaces of the groove 14 and form with the groove 14 a positive connection against twisting.

11 is a sectional view of the component 29 the 10 with the inserted rivet thread element 30 at the cutting line AA the 10 , The headboard height H is also slightly smaller than the depth in this embodiment of a component assembly t the one of the groove 14 formed head shot 34 ,

As in 12 shown has the groove 14 a rectangular cross-section to allow easy manufacture. In addition, the groove runs 14 here throughout the entire component 29 ,

13 is an embodiment of a component arrangement according to the invention 35 in which the head recording 36 in a second component 37 is arranged, which forms the surface in the plan view shown. To connect the components is a screw 38 used in the rivet threaded element. Under the screw head of the screw 38 is a washer 39 arranged, which the bearing surface of the screw head over the head receptacle 36 increased.

In 14 is again the component arrangement 35 the 13 in a sectional view along the section line CC the 13 shown, with here next to the first component 40 also the rivet thread element 41 you can see. The head shot 36 is formed by a through hole. The through-hole is an easy-to-manufacture slot, reducing the manufacturing of the component assembly 35 is relatively cheap.

15 is another component arrangement 42 , in which case in contrast to the component arrangement of 13 and 14 an expansion sleeve 43 is used, which usually leads due to the lower pressure cone on larger contact surfaces with respect. The transmission of the axial screw forces and usually compensated settling effects better.

16 . 17 and 18 illustrate a further variant of a component arrangement according to the invention 44 , where here next to a first component 45 and a second component 46 a third component 47 is provided. The head shot 48 is from a slot in the second component 46 educated. As in the previously described embodiments, the depth is also here t the head receptacle larger than the headboard height H the head part of the rivet thread element 41 , Through the head recording 48 in the second component 46 thus arises when assembled component assembly 44 a cavity between the first component 45 and third component 47 who has the headboard 31 of the rivet thread element 41 receives and thus a direct power transmission between the first component 45 and third component 47 guaranteed. The first component 45 in 17 and 18 includes a simple through hole 49 into which the rivet thread element 41 is included. In the same way, the in 19 separately shown third component 47 a simple, round passage opening 50 to carry out a screw.

In 20 is the second component 64 the component arrangement 44 shown separately. The second component 46 can be designed as a garnish to the head intake 48 to form without fulfilling another function. That's the head shot 48 forming slot forms together with the head of the rivet threaded element a locking device which acts as a rotation. The head shot 48 can be designed much longer than the head part of the rivet thread element to be used to allow a shift or a tolerance compensation.

In 21 is another assembled component assembly 24 shown. The component arrangement 24 includes a first component 25 , a second component serving as a supplement 26 , as well as a third component 27 , In the first component 25 are two rivet threaded elements 1 used. The rivet thread elements 1 are each form-fitting by a bead in the first component 25 held. The head parts of the rivet thread elements 1 are each in a head receptacle, not shown here in the second component 26 , Because the head parts completely in the second component 26 can be included, first component 25 , second component 26 and third component 27 lie on each other without gaps. Into the rivet thread elements 1 are each screws 28 used. The screws 28 connect the first component 25 with the third component 27 , The connection forces, ie the tensile forces of the screw, are doing over the second component 26 transferred, and not over the head rest of Nietgewindeelementes 1 ,

The assembly of a component arrangement 24 can be done as follows: First, the second component 26 on the first component 25 arranged. Subsequently, the insertion of the rivet threaded element 1 in the first component 25 used, and the head part of the rivet threaded element 1 in the head receptacle of the second component. The head part can be completely sunk into the head receptacle. Then the screws 28 in the rivet thread element 1 screwed in, wherein the rivet threaded element 1 is secured against twisting over the head part and the head receptacle.

The screws 28 can be screwed in until the screw head rests and a pulling force on the threads of the rivet threaded elements 1 is applied. If the rivet threaded elements 1 have not already been compressed over a screwed spindle, carried out by further screwing the screws compression of the compression portions of the rivet threaded elements 1 ,

The specific embodiments described and illustrated are not binding upon the practice of the invention, but may be suitably modified within the scope of the present invention without departing from the scope of the present invention. Thus, all rivet thread elements shown in the embodiments are designed as a rivet nut. However, the variants shown can also be transferred to rivet screws with the same effect.

LIST OF REFERENCE NUMBERS

b

Width of the headboard

B

Width of the head shot

d

outer diameter

e

insertion

H

Headboard height

t

Depth of the head shot

1

Nietgewindeelement

2

headboard

3

deployment shaft

4

outer profile

5

compression section

6

threaded portion

7

opening

8th

thread

9

component arrangement

10

First component

11

opening

12

bead

13

head seat

14

groove

15

Second component

16

head seat

17

drilling

18, 19, 20

Second component

21, 22

head seat

23

Hexagonal contour

24

component arrangement

25

First component

26

Second component

27

Third component

28

screw

29

First component

30

Nietgewindeelement

31

headboard

32.33

side surface

34

head seat

35

component arrangement

36

head seat

37

Second component

38

screw

39

washer

40

First component

41

Nietgewindeelement

42

component arrangement

43

expansion sleeve

44

component arrangement

45

First component

46

Second component

47

Third component

48

head seat

49,50

Through opening

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 9001069 U1 [0004]
• EP 1557577 A2 [0006]
• WO 9942732 [0007]

Claims (13)

Rivet thread element (1, 30, 41), in particular rivet nut or rivet screw, having an insertion shaft (3) which can be inserted into an opening (11, 49) of a component to be connected, and a head part (2) adjoining the insertion shaft (3) 31) having a width (b) greater than an outer diameter (d) of the insert shaft (3), the insert shaft (3) comprising an elastically and / or plastically deformable upset portion (5), characterized in that the Head part (2, 31) has a non-circular outer profile (4) through which in cooperation with a the head part (2, 31) receiving the component (10, 18, 19, 20, 26) an anti-rotation device can be produced. Rivet threaded element (1, 30, 41) after Claim 1 , characterized in that the rivet thread element (1, 30, 41) as a rivet nut with a threaded portion (6) and between the threaded portion (6) and head part (2, 31) extending upset portion (5) is configured. Component arrangement (9, 24, 35) with a rivet threaded element (1, 30, 41) according to Claim 1 or 2 , comprising a first component (10, 25) with an opening (11, 49) for inserting the insertion shaft (3), wherein the first component (10, 25) has a head receptacle (13, 34). Component arrangement (9, 24, 35) with a rivet threaded element (1, 30, 41) according to Claim 1 or 2 with a first component (10, 25) having an opening (11, 49) for inserting the insert shaft (3) and a second component (15, 18, 19, 20) for attachment to the first component (10, 25), wherein the first component (10, 25) and / or the second component (15, 18, 19, 20) has a head receptacle (13, 16, 21, 22). Component arrangement (9, 24, 35) according to Claim 3 or 4 , characterized in that the head receptacle (13, 16, 21, 22) in the insertion direction (E) has a depth (t) which corresponds at least to the head part height (h) of the head part (2, 31). Component arrangement (9, 24, 35) according to one of Claims 3 to 5 , characterized in that the head receptacle (13, 16, 21, 22) with inserted head part (2, 31) partially adjacent to these and with the head part (2, 31) forms an anti-rotation. Component arrangement (9, 24, 35) according to one of Claims 3 to 6 , characterized in that the head receptacle (13, 16, 21, 22) in the second component (15, 18, 19, 20) is formed by a passage opening. Component arrangement (9, 24, 35) according to one of Claims 3 to 7 , characterized in that the head receptacle (13, 16, 21, 22) of a recess (29) is formed, in which the head part (2, 31) rests. Component arrangement (9, 24, 35) according to one of Claims 3 to 8th , characterized in that the head part (2, 31) is held in a form-fitting manner in the head receptacle (13, 16, 21, 22). Component arrangement (9, 24, 35) according to one of Claims 3 to 9 , characterized in that the profile of the head receptacle (13, 16, 21, 22) at least partially complementary to the outer profile of the head part (2, 31) is formed. Component arrangement (9, 24, 35) according to one of Claims 3 to 10 , characterized in that the component arrangement (9, 24, 35) comprises a locking device (51), by which the second component (15, 18, 19, 20) on the first component (10, 25) can be secured against rotation. Component arrangement (9, 24, 35) according to one of Claims 3 to 11 , characterized in that the second component (15, 18, 19, 20) forms a supplement. Method for mounting a component arrangement (9, 24, 35) according to one of Claims 3 to 12 characterized by the steps of: a. Arranging the second component (15, 18, 19, 20) on the first component (10, 25), b. Inserting the insertion shaft of the rivet threaded element (1, 30, 41) into the first component (10, 25), c. Inserting the head part (2, 31) of the rivet thread element (1, 30, 41) into the head receptacle (13, 16, 21, 22), d. Sinking the head part (2, 31) in the head receptacle (13, 16, 21, 22), e. Then screwing a screw (28) into the rivet thread element (1, 30, 41) or screwing a nut onto the rivet thread element (1, 30, 41), wherein the rivet thread element (1, 30, 41) over the head part (2, 31) and the head receptacle (13, 16, 21, 22) is secured against rotation.

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