DE102016204662A1 - screw - Google Patents

Abstract

The invention relates to a screw connection (1) comprising at least two components (3, 4) connected to one another via at least one screw unit (2), in particular vehicle components, wherein a first component (3) has at least one first bore (5) and one second component ( 4) has at least one second bore (6) and an at least partially with an external thread (18) provided threaded shank (7) of the screw unit (2) through the bores (5, 6). On a first component (3) facing side of the second component (4) is circumferentially around the second bore (6) radially inwardly into the second bore (6) passing recess (10, 22) arranged. The screwing unit (2) comprises at least one displacement body (12, 19, 28) arranged on a side of the first component (3) facing away from the second component (4), whose underside (13, 20, 29) facing the first component (3) at least partially complementary to the recess (10, 22) is formed. The screw unit (2) is designed such that the displacement body (12, 19, 28) when tightening the screw unit (2) in the direction of the second component (4) is displaceable, so that it a the first bore (5) circumferential portion ( 17) of the first component (3) at least partially in the recess (10, 22) urges and thereby plastically deformed.

Description

The invention relates to a screw connection, comprising at least two interconnected via at least one screw unit components, in particular vehicle components, wherein a first component at least a first bore and a second component has at least a second bore, and wherein an at least partially provided with an external thread threaded shaft of the screw unit passes through the holes.

Screw connections are used in various areas of technology to connect load-transferring components to one another. For example, in automotive production components in the form of suspension components or stiffening struts can be connected via screw connections with body components.

Usually, connections of components to a body of a vehicle are frictionally constructed. However, due to relative hole tolerances of bores on the components connected to one another via a plurality of screw connections, a form-locking connection of the components via the screw connections is not possible. The force or frictional connections between components are required in particular because of so-called Funktionsmaßtoleranzketten.

If the coefficients of frictional engagement given in a parting line between interconnected components are too low, measures to increase the coefficient of friction may be necessary. In this case, for example, relatively small stampings on the harder component can be formed, which are pressed into the surface of the softer component when a screw connection is tightened by the screw prestress generated thereby. The stampings are conventionally fine, only a few 10ths of mm high rib-like, knob-like or annular structures.

However, the stampings must be formed in advance in separate and cost-increasing manufacturing processes on the respective harder component.

If, on the other hand, both components have the same hardness in the connection region, an additional harder intermediate element with corresponding embossings on both sides can be used, for example, for the components, which is arranged in the connection region between the components before tightening a screw connection. In addition to the additional cost of such intermediate elements, such a friction-increasing measure causes an increase in the number of parting surfaces, which in turn is associated with increased settling phenomena in screw connections.

A further problem with conventional screw design is compliance with safety against slippage. In order to be able to maintain safety, so high preload forces would often be required that, in particular for soft component materials, such as aluminum to exceed the maximum permissible surface pressure on the components would. To avoid this, conventionally additional screws or screws with larger dimension are used, which is associated with an increase in weight and in production sometimes requires more expensive means of production, such as. Supported screwing devices or electronic ceiling-mounted screwdrivers for an over-elastic screw tightening.

An object of the invention is to enable an improved connection of components via at least one screw unit.

This object is solved by the independent claim. Advantageous embodiments are set forth in particular in the dependent claims, each of which taken alone or in different combinations with each other can represent a further developing or advantageous aspect of the invention.

A screw connection according to the invention comprises at least two interconnected via at least one screw unit components, in particular vehicle components, wherein a first component at least a first bore and a second component has at least a second bore and at least partially provided with an external thread threaded shaft of the screw unit passes through the holes. On a side facing the first component side of the second component, a radially inward into the second bore recess is arranged circumferentially around the second bore. The screw unit comprises at least one displacement body arranged on a side of the first component facing away from the second component, the underside facing the first component being at least partially complementary to the depression. The screw unit is designed in such a way that when the screw unit is tightened, the displacement body is displaceable in the direction of the second component so that it at least partially forces a section of the first component circulating the first bore into the recess and thereby deforms plastically or elastically.

According to the invention, when tightening the screw unit, the first component is targeted by the contact with the displacement body in the area the compound plastically or elastically deformed and at least partially in the recess of the second component, for example in the form of a body component, urged. Since the underside of the displacement body facing the first component is formed at least partially complementary to the depression, the plastically or elastically deformed portion of the first component positively engages in the depression on the second component. The positive connection is in this case created in particular by obliquely or parallel to a longitudinal central axis of the threaded pin extending contact surfaces on the plastically deformed portion and the recess. The plastic or elastic deformation of the first bore circumferential portion is completed as soon as a balance between the biasing force generated by the screw unit and the reaction force in the first component. This is the case when the plastically deformed section bears against the second component within the recess. On the other hand, in addition to the frictional engagement caused positive engagement between the components can be transmitted significantly higher transverse to the longitudinal central axis of the threaded shaft forces acting over a conventional purely frictionally acting screw. When designing the screw connection, the restoring force of the elastic portion of the deformation of the section which rotates the first bore must be taken into account with regard to the tightening torque.

The plastic deformation of the section surrounding the first bore can amount to several mm, whereby larger forces per positive engagement can be transmitted than with conventional laminations only a few 10 mm high. As a result, in certain cases, the screw unit can also be dimensioned smaller than a conventional screw unit, which brings weight, space and cost advantages.

A further advantage of the screw connection according to the invention lies in its significantly greater independence from existing and customary tolerances in body construction, in particular with respect to positional tolerances of bores on the first component and bores on the second component, since the plastic deformation on the first component takes place only when tightening the screw unit , Thus, the plastic deformation takes place precisely at the respectively required point ("form to fit").

The screw connection according to the invention may also comprise two or more screw units for the corresponding frictional and positive connection of the components. For this purpose, the first component and the second component have a corresponding number of first bores or second bores. The components can be made of a metal sheet. Alternatively, the second component may be made of a composite material.

The depression on the second component can be formed by reducing the material thickness of the second component in the connection region. Alternatively, the circumferentially extending around the second bore portion can be arranged at least partially offset from the rest of the second component.

The displacement body may be made of metal or a composite material. The underside of the displacement body may be formed partially or completely complementary to the recess. Complementary means here that the underside of the displacement body is at least partially formed as a negative of the depression.

When tightening the screw unit of the displacement body is displaced in the direction of the second component, which means that the distance between the displacement body and the second component is reduced. In this case, the displacement body comes into contact with the portion of the first component which revolves around the first bore and carries it along. As a result, this section is at least partially forced into the recess and thereby plastically deformed.

According to an advantageous embodiment of the displacement body is formed by a head of the threaded shaft having a screw head or by a nut screwed onto the threaded shaft. The former is associated with a smaller number of components, whereby the assembly of the screw connection is simplified. An embodiment of the displacement body by a nut screwed onto the threaded shank is advantageous in particular with regard to the mounting of the composite bodies, since only relatively small, specially manufactured displacement bodies have to be mounted.

According to an alternative advantageous embodiment, the displacement body is designed as a longitudinally displaceable guided on the threaded shank washer. In this way, the screw can be adapted by the choice of a suitable displacement body and the arrangement of the same on the threaded shaft in a simple and cost-effective manner to the respective circumstances. It is also possible to produce such a screw only the special displacement body, while can be used for the formation of the other components of the screw on conventional Schraubverbindungsbauteile. Preferably, the washer is captively arranged on the threaded shaft.

A further advantageous embodiment provides that the recess is at least partially frusto-conical with a lateral surface extending at least partially straight or curved in cross-section. Runs the lateral surface in the cross section straight, the recess is formed as a truncated cone. If the lateral surface in the cross section of the first component is curved away (concave), a spherical segment-shaped configuration of the recess is given. Alternatively, the recess may also be partially frusto-conical and partially spherical-segment-shaped. Since the underside of the displacement body facing the first component is formed at least partially complementary to the depression, the underside corresponding to the depression can be at least partially truncated cone-shaped and / or spherical segment-shaped. The lateral surface of the recess can also extend completely straight or curved in cross section.

A further alternative advantageous embodiment provides that the recess is cylindrical. In this case, the bottom of the depression formed on the second component and the underside of the displacement body can be flat. The displacement body can be formed for example by a conventional cap screw, nut or washer. The recess may be formed, for example, circular cylindrical.

According to a further advantageous embodiment, a means for lubricating, sealing and / or anti-rotation locking is arranged between the displacement body and the first bore portion of the first component and / or between the first bore portion of the first component and the recess. For example, a lubricant may be applied to the underside of the displacer body to achieve lower force requirements for plastic working on the first component during tightening of the screw unit. The agent can be given, for example, in a capsule-encapsulated form. If the means for unscrewing suitable, can be prevented with the means that the screw unit, for example, by the action of vibration dissolves. If the means is suitable for sealing, the screw connection can be sealed with the means.

According to a further advantageous embodiment, the second bore is formed as a threaded bore into which the threaded shank is screwed. As a result, no further threaded hole providing component is required, which is accompanied by a simplified assembly and a weight reduction.

According to a further alternative advantageous embodiment, the screw unit comprises a arranged on the second component nut, which is screwed onto the threaded shank. The nut may be supported on the side facing away from the first component side of the second component or at least partially embedded in the second component. There may also be an anti-rotation, which prevents the mother rotates when tightening the screw relative to the second component. Examples include Einzieh-, riveting, punching and welding nuts.

According to a further alternative advantageous embodiment, the screw unit comprises a arranged on the second component, positively engaging in the second bore and at least in the direction of the first member axially fixed to the second component body with a threaded bore into which the threaded shank is screwed. The body may, for example, have a radially outwardly facing collar arranged on the side of the second component facing away from the first component, via which the body is axially fixed in the direction of the first component to the second component. Preferably, the body is axially fixed in both directions on the second component and connected thereto captive with the second component. Preferably, the body is secured against rotation relative to the second component.

Advantageously, the body comprises a collar engaging radially in a part of the recess and pointing radially outward. By this collar or its engagement in the recess of the body is axially fixed in a direction away from the first component direction on the second component.

Further details, features and advantages of the invention will become apparent from the following description and the figures. Show it:

1 a schematic sectional view of an embodiment of a screw according to the invention in a non-tightened state;

2 a schematic sectional view of in 1 shown screw in an attracted state;

3 a schematic sectional view of another embodiment of a screw according to the invention in an attracted state; and

4 a schematic sectional view of another embodiment of a screw according to the invention in an attracted state.

In the figures, the same or functionally identical components are provided with the same reference numerals.

1 shows a schematic sectional view of an embodiment of a screw according to the invention 1 in an unclothed condition.

The screw connection 1 includes two via a screw unit 2 interconnectable components 3 and 4 , A first component 3 includes a first bore 5 and a second component 4 includes a second bore 6 , An at least partially provided with an external thread, not shown threaded shaft 7 the screw unit 2 passes through the holes 5 and 6 , The second hole 6 is designed as a threaded hole into which the threaded shaft 7 is screwed. The second component 4 can be a body component of a vehicle, so that the first component 3 over the screw connection 1 can be connected to a body of the vehicle. The second component 4 is in the area of the second hole 6 reinforced trained. The threaded shaft 7 makes a part of a head 8th having head screw 9 ,

On one of the first component 3 facing side of the second component 4 is circumferential around the second hole 6 a radially inward into the second bore 6 passing recess 10 arranged. The depression 10 is frustoconical with a straight cross-section lateral surface 11 educated.

The screw unit 2 includes one on a second component 4 opposite side of the first component 3 arranged displacement body 12 of which the first component 3 facing underside 13 partially complementary to the depression 10 or their lateral surface 11 is trained. In particular, the displacement body 12 radially inward in the direction of the first component 3 pointing conical or frustoconical section 14 on, at the radially outward a flat formed section 15 of the suppression body 12 followed. The displacement body 12 is as a longitudinally displaceable on the threaded shaft 7 guided washer trained. The displacement body 12 rests on one of the first component 3 facing bottom of the head 8th the head screw 9 from. The head 8th includes a radially outwardly facing collar 16 whose outer diameter corresponds to the outer diameter of the displacement body 12 equivalent.

The screw unit 2 is formed such that the displacement body 12 when tightening the screw unit 2 by the biasing force generated in the direction of the second component 4 is displaceable, so he drills the first hole 5 encircling section 17 of the first component 3 at least partially into the depression 10 urges and thereby plastically deformed, as in a final assembly in 2 is shown. In 1 is a condition of the screw connection 1 shown in which the tightening of the screw unit 2 starts. The section 17 is not yet plastically deformed, but just trained.

Between the displacement body 12 and the first hole 5 encircling section 17 of the first component 3 and / or between the first bore 5 encircling section 17 of the first component 3 and the depression 10 may be arranged not shown means for lubricating, sealing and / or non-rotational locking.

2 shows a schematic sectional view of in 1 shown screwed connection 1 in an attracted state. By already tightening the screw unit 2 became the repressive body 12 in the direction of the second component 4 shifted so that it by tightening the screw unit 2 generated preload force the the first hole 5 encircling section 17 of the first component 3 at least partially into the depression 10 pushed and thereby plastically deformed. The section 17 is between the bottom 13 of the suppression body 12 and the lateral surface 11 the depression 10 clamped and engages positively in the depression 10 one. As a result, in addition to a frictional connection or frictional engagement, a form fit between the two components 3 and 4 educated.

3 shows a schematic sectional view of another embodiment of a screw according to the invention 1 in an attracted state.

The screw connection 1 includes two via a screw unit 2 interconnected components 3 and 4 , A first component 3 includes a first bore 5 and a second component 4 includes a second bore 6 , One at least partially with an external thread 18 provided threaded shaft 7 the screw unit 2 passes through the holes 5 and 6 , The second hole 6 is designed as a threaded hole into which the threaded shaft 7 is screwed. The second component 4 can be a body component of a vehicle, so that the first component 3 over the screw connection 1 attached to a body of the vehicle. The second component 4 is in the area of the second hole 6 reinforced trained.

On one of the first component 3 facing side of the second component 4 is circumferential around the second hole 6 one radially inside the second drilling 6 passing recess 10 arranged. The depression 10 is frustoconical with a straight cross-section lateral surface 11 educated.

The screw unit 2 includes one on a second component 4 opposite side of the first component 3 arranged displacement body 19 of which the first component 3 facing underside 20 partially complementary to the depression 10 or their lateral surface 11 is trained. The displacement body 19 is by a head of the threaded shaft 7 having head screw 21 educated.

The screw unit 2 is formed such that the displacement body 19 when tightening the screw unit 2 in the direction of the second component 4 is displaceable, so he by the tightening the screw unit 2 generated biasing force a the first hole 5 encircling section 17 of the first component 3 at least partially into the depression 10 urges and thereby plastically deformed. In 3 is the tightening of the screw unit 2 already finished. Before tightening the screw unit 2 was the first component 3 corresponding 1 with non-plastically deformed section 17 educated. The section 17 is between the bottom 20 of the suppression body 19 and the lateral surface 11 the depression 10 clamped and engages positively in the depression 10 one. As a result, in addition to a frictional connection or frictional engagement, a form fit between the two components 3 and 4 educated.

Between the displacement body 19 and the first hole 5 encircling section 17 of the first component 3 and / or between the first bore 5 encircling section 17 of the first component 3 and the depression 10 may be arranged not shown means for lubricating, sealing and / or non-rotational locking.

4 shows a schematic sectional view of another embodiment of a screw according to the invention 1 in an attracted state.

The screw connection 1 includes two via a screw unit 2 interconnected components 3 and 4 , A first component 3 includes a first bore 5 and a second component 4 includes a second bore 6 , An at least partially provided with an external thread, not shown threaded shaft 7 the screw unit 2 passes through the holes 5 and 6 , The second component 4 can be a body component of a vehicle, so that the first component 3 over the screw connection 1 attached to a body of the vehicle. The threaded shaft 7 makes a part of a head 8th having head screw 9 , according to the in the 1 and 2 shown embodiment may be formed.

Furthermore, the screw unit includes 2 one on the second component 4 arranged, positively in the second hole 6 engaging and axially on the second component 4 fixed body 23 with a threaded hole 24 into which the threaded shaft 7 is screwed. On one of the first component 3 facing side of the second component 4 is circumferential around the second hole 6 a radially inward into the second bore 6 transitional, circular cylindrical recess formed 22 arranged. The body 23 includes one in a part of the recess 22 engaging, radially outwardly facing collar 25 , The collar 25 is about one through the second hole 6 extending sleeve-shaped section 26 of the body 23 with one on the first component 3 opposite side of the second component 4 arranged, radially outwardly facing collar 27 of the body 23 connected, causing the body 23 axially with respect to the second bore in both directions on the second component 4 is fixed.

The screw unit 2 includes one on a second component 4 opposite side of the first component 3 arranged displacement body 28 of which the first component 3 facing underside 29 partially complementary to the depression 22 is trained. The displacement body 28 is as a longitudinally displaceable on the threaded shaft 7 guided washer trained.

The screw unit 2 is formed such that the displacement body 28 when tightening the screw unit 2 in the direction of the second component 4 is displaceable, so he by the tightening the screw unit 2 generated biasing force a the first hole 5 encircling section 17 of the first component 3 partly in the depression 22 urges and thereby plastically deformed. In 4 is the tightening of the screw unit 2 already finished. Before tightening the screw unit 2 was the first component 3 corresponding 1 with non-plastically deformed section 17 educated. The section 17 is between the head 8th the head screw 9 and into the depression 22 engaging collar 25 of the body 23 clamped and engages positively in the depression 22 one. As a result, in addition to a frictional connection or frictional engagement, a form fit between the two components 3 and 4 educated.

Between the displacement body 28 and the first hole 5 encircling section 17 of the first component 3 and / or between the first bore 5 encircling section 17 of the first component 3 and the collar 25 may be arranged not shown means for lubricating, sealing and / or non-rotational locking.

LIST OF REFERENCE NUMBERS

1

screw

2

screw unit

3

first component

4

second component

5

first hole

6

second hole

7

 threaded shaft

8th

Head of 9

9

head screw

10

deepening

11

Lateral surface of 10

12

displacer

13

Bottom of 12

14

conical section of 12

15

Section of 12

16

Collar of 8th

17

Section of 3

18

External thread of 7

19

displacer

20

Bottom of 19

21

head screw

22

deepening

23

body

24

Tapping from 23

25

Collar of 23

26

sleeve-shaped section of 23

27

Collar of 23

28

displacer

29

Bottom of 28

Claims (10)

Screw connection ( 1 ), comprising at least two via at least one screw unit ( 2 ) interconnected components ( 3 . 4 ), in particular vehicle components, wherein a first component ( 3 ) at least one first bore ( 5 ) and a second component ( 4 ) at least one second bore ( 6 ) and at least partially with an external thread ( 18 ) threaded shaft ( 7 ) of the screw unit ( 2 ) through the holes ( 5 . 6 ), characterized in that - on a first component ( 3 ) facing side of the second component ( 4 ) around the second bore ( 6 ) a radially inward into the second bore ( 6 ) passing recess ( 10 . 22 ), - that the screw unit ( 2 ) at least one on a second component ( 4 ) facing away from the first component ( 3 ) arranged displacement body ( 12 . 19 . 28 ), of which the first component ( 3 ) facing bottom ( 13 . 20 . 29 ) at least partially complementary to the depression ( 10 . 22 ), and - that the screw unit ( 2 ) is designed such that the displacement body ( 12 . 19 . 28 ) when tightening the screw unit ( 2 ) in the direction of the second component ( 4 ) is displaceable so that it is a first bore ( 5 ) encircling section ( 17 ) of the first component ( 3 ) at least partially into the depression ( 10 . 22 ) urges and thereby plastically deformed. Screw connection ( 1 ) according to claim 1, characterized in that the displacement body ( 19 ) by a head of a threaded shaft ( 7 ) having head screw ( 21 ) or by a on the threaded shaft ( 7 ) screwed nut is formed. Screw connection ( 1 ) according to claim 1, characterized in that the displacement body ( 12 . 28 ) is as a longitudinally displaceable on the threaded shaft ( 7 ) guided washer formed. Screw connection ( 1 ) according to one of claims 1 to 3, characterized in that the recess ( 10 ) frusto-conical with a cross-section at least partially straight or curved extending lateral surface ( 11 ) is trained. Screw connection ( 1 ) according to one of claims 1 to 3, characterized in that the recess ( 22 ) is cylindrical. Screw connection ( 1 ) according to one of claims 1 to 4, characterized in that between the displacement body ( 12 . 19 . 28 ) and the first hole ( 5 ) encircling section ( 17 ) of the first component ( 3 ) and / or between which the first bore ( 5 ) encircling section ( 17 ) of the first component ( 3 ) and the depression ( 10 . 22 ) A means for lubricating, sealing and / or anti-rotation lock is arranged. Screw connection ( 1 ) according to one of claims 1 to 5, characterized in that the second bore ( 2 ) is formed as a threaded bore into which the threaded shaft ( 7 ) is screwed. Screw connection ( 1 ) according to one of claims 1 to 5, characterized in that the screw unit ( 2 ) one on the second component ( 4 ) arranged nut, which on the threaded shaft ( 7 ) is screwed on. Screw connection ( 1 ) according to one of claims 1 to 5, characterized in that the screw unit ( 2 ) one on the second component ( 4 ), positively in the second bore ( 6 ) engaging and at least in the direction of the first component ( 3 ) axially on the second component ( 4 ) fixed body ( 23 ) with a threaded hole ( 24 ), in which the threaded shaft ( 7 ) is screwed. Screw connection ( 1 ) according to claim 9, characterized in that the body ( 23 ) into a part of the depression ( 22 ) engaging, radially outwardly facing collar ( 25 ) having.

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