DE102014011748A1 - Securing part for a shaft - Google Patents

Abstract

The present invention relates to a securing element (11, 21, 31, 41, 51, 61, 71) for securing a hollow and radially symmetrical element (3) movable about a longitudinal axis in a predetermined position, wherein the securing element (11, 21, 31 , 41, 51, 61, 71) comprises a head region (13, 37, 43, 53) and an opposite base region (33, 55) and the base region (33, 55) within the movable element (3) with the movable element (3). 3) via an engagement (29) and wherein the head region (13, 37, 43, 53) is bent in such a way that the securing element (11, 21, 31, 41, 51, 61, 71), when in the movable element (3) is inserted in the head area out of the movable element (3) and projects beyond a radially symmetrical end (17) of the movable element (3) and wherein the head area (13, 37, 43, 53) over the radially symmetrical end (17) of the element (3) to evert is that a gap between at least a part de s head portion (13, 37, 43, 53) and the radially symmetrical end (17) of the movable element (3) is formed and a radially symmetrical end (21) of the head part (13, 37, 43, 53) by contact with at least one holding element ( 9, 23, 65) the securing element (11, 21, 31, 41, 51, 61, 71) between the at least one holding element (9, 23, 65) and the engagement (29) braced. Furthermore, the present invention relates to a corresponding method.

Description

The present invention relates to a device for securing a hollow and radially symmetrical element movable about a longitudinal axis in a predetermined position and to a corresponding method.

Connecting elements for transmitting power are generally based on a shaft, a joint or an axle, which transmits an applied force by rotation over a distance to a driven element. Since such a transmission of force also undesirable forces, such as. Pressure, shear or friction forces occur, fasteners are usually exposed to high loads, so that respective fuses are also exposed to considerable loads for fixing the respective connecting elements in their predetermined position and should be tolerant to such pressures.

In the prior art devices for securing fasteners are described.

The publication DE 20 2013 105 196 U1 discloses an axial screw for a ball bearing for pressing against an axle.

The publication DE 10 2007 028 948 B3 relates to a tool for mounting a machine element on a shaft, wherein a circling in a circumferential groove of the shaft retaining ring axially against the machine element biased, the shaft enclosing spring element is supported. It is provided that a first tool part axially biases the spring element during assembly and the second tool part pushes the locking ring to the circumferential groove of the shaft, so that after the axial biasing of the spring element of the locking ring can be latched into the circumferential groove.

In the publication DE 10 2012 214 914 A1 a bearing with bearing rings is described with a plurality of rolling elements for rotatably supporting the bearing rings about a common axis and the rolling elements axially supporting two-legged board body, wherein a first leg of the board body interacts with the rolling elements and a second leg of the board body with the bearing ring. The connection between the second leg of the flange body and the bearing ring is made in particular by a ring which engages simultaneously in a Lagerringnut and a Bordkörpernut.

A device for transmitting a torque from an internal combustion engine to an accessory is in the document DE 10 2007 012 510 A1 presented. It is described that a hub with a driver element and a pulley are connected to form a one-piece mounting unit in the axial direction with each other and the securing element is arranged on the thus formed one-piece mounting unit.

The publication DE 36 22 299 A1 relates to a shaft bearing, in which two axially biased angular roller bearings whose inner rings sit on a shaft between the shaft connected to stops, so that an attachment of the inner rings is achieved on the shaft, wherein one of the inner rings with Treffsitz and the other inner ring with sliding fit on the Shaft sits and both rings with end profiles rotatably engage each other, so that axial relative movements are possible.

Against this background, a fuse element for securing a hollow and radially symmetric member movable about a longitudinal axis in a predetermined position, the fuse element comprising a head portion and an opposite base portion, and the base portion within the movable member is to be engaged with the movable member via a mesh and wherein the head portion is bent so that the securing member, when inserted into the movable member, protrudes in the head portion out of the movable member and beyond a radially symmetric end of the movable member, and wherein the head portion so toward the radially symmetrical end of the element that is, that there is a space between at least part of the head area and the radially symmetrical end of the movable element, and a radially symmetrical end of the head part contacts the securing element by contact with at least one retaining element the at least one retaining element and the engagement clamped.

The presented securing element is preferably configured in one piece and engages in a movable, hollow and radially symmetric element, such as a shaft for transmitting a force of, for example, an internal combustion engine or an electric machine, so that the element thereby secured or fixed in a predetermined position is and the element moves only on a predetermined by the securing element movement path. It is provided that the securing element according to the invention is designed such that a head part of the securing element protrudes from the movable, hollow and radially symmetrical element and is bent such that there is a gap between at least part of the head area and the radially symmetrical end of the element and the radially symmetrical End of the head part by contact with at least one holding element, the example. At or in the Near the movable, hollow and radially symmetrical element is arranged, the securing element clamped between the holding element and provided in the movable, hollow and radially symmetrical element engagement.

Due to the gap between at least part of the head region and the radially symmetrical end of the element, the radially symmetrical end of the element is not in contact with the head region of the securing element, so that a transition of rotational energy of the movable element, for example. In the form of friction or Heat energy can not occur.

Furthermore, the securing element is due to its design as a one-piece curved securing element suitable to deform along its longitudinal axis, d. H. to be deflected or compressed along its longitudinal axis and to spring back after an eventual deflection or compression back to its original shape. By a flexible or resilient configuration of the securing element, the movable, hollow and radially symmetrical element, d. H. for example, the shaft, with a predetermined tolerance, d. H. a game, be fixed in its predetermined position.

In a transfer of forces to the movable, hollow and radially symmetric element, for example. In a vehicle mediated by rotational, pulling and / or centrifugal forces, the movable, hollow and radially symmetric element is constantly displaced in the longitudinal direction, it may be advantageous in that the element is the displacement, i. H. For example, the deflection or compression tolerated in the longitudinal direction to a certain degree or follows the shift, so that the securing element also for such a change in movement in the longitudinal direction, d. H. along its longitudinal axis, must be designed to move the movable, hollow and radially symmetrical element back to its originally predetermined position after being displaced beyond a defined point, for example by pulling forces imparted by the curved head on the element arranged intervention to be transmitted.

In an embodiment of the presented securing element, it is provided that the securing element is bent in the head region in such a way that the base region of the securing element is bent largely parallel to respective walls of the movable, hollow and radially symmetrical element or such that the base region of the securing element runs trapezoidally, so that the gap between a part of the head area and the radially symmetrical end of the element continues into the element and the securing element is in contact with the movable, hollow and radially symmetrical element only in the region of the engagement.

Under an element, i. H. a movable, hollow and radially symmetrical element is to be understood in the context of the present invention, a tubular device, in particular a shaft, which provides in its interior an engagement for the presented securing element.

In a further possible embodiment of the securing element according to the invention it is provided that the head region is bent such that the securing element is resiliently movable along its longitudinal axis.

Due to the inventively provided bending of the head part of the securing element, the securing element is designed for receiving compressive and tensile forces along its longitudinal axis, so that the securing element can be compressed and deflected along its longitudinal axis and provides corresponding counterforces during an upsetting or deflection process, so that the securing element moves back to its original shape after a deflection or compression movement and, by means of such a return movement, moves the hollow radial element connected to the securing element via the engagement and thereby secures the element in its predetermined position.

The presented security element can be adapted by various embodiments of the bends in the head area and / or in the base area to a respective element to be secured or to predetermined forces to be expected, for example, the bends steeper, flatter, higher, lower, round, square, wavy , with a number of turns or even flat, so that the force applied by the securing element counterforce to a deflection or compression force is always sufficient to move the securing element and the movable, hollow and radially symmetrical element back into their respective starting position. Furthermore, it is conceivable that the bends vary in a material thickness used.

In a further possible embodiment of the presented securing element, it is provided that the base area has at least one recess.

By means of recesses in the base region, a material expenditure required for producing the securing element can be reduced and the securing element can be provided with a possibility for pivoting in itself. By A pivoting of the securing element in itself, ie, for example, from a first side of the securing element relative to a second side of the securing element, a rotational energy introduced or acting in the securing element can be damped or buffered so that the head area of the securing element only becomes active begins to turn a defined rotational energy on the fuse element.

In a further possible embodiment of the presented securing element is provided that the engagement is designed as a clip connection.

By using a clip connection, the fuse element can be easily, effectively, robustly and safely connected to the movable, hollow and radially symmetric element. In particular, in connection with a base part, which has at least one recess, it is possible that the securing element only needs to be inserted for mounting or for insertion into the movable, hollow and radially symmetrical element, so that due to the recesses of the base region during insertion compresses into the hollow radially symmetric element and expands only at the designated engagement within the movable, hollow and radially symmetrical element and which extends into engagement for engagement with the movable, hollow and radially symmetrical element Fuse element thereby positively and irreversibly connects with the movable, hollow and radially symmetric element.

In a further possible embodiment of the presented securing element is provided that the securing element is formed from a metallic part.

By using a one-piece metallic body, from which the securing part is configured, the securing part can be produced inexpensively. Further, a one-piece design of a metallic part allows a uniform distribution of tensile and / or compressive forces within the fuse element, so that a deformation movement of the fuse element is easy to estimate or calculate and the bends in the head part of the fuse element according to a respective arrangement or accordingly respective expected forces in a particular application can be selected.

In a further possible embodiment of the presented securing element is provided that the at least one retaining element has a surface which is characterized by a low sliding friction.

In particular, in the event that the respective holding elements are designed as rigid, fixed to a base body parts, it is provided that respective holding elements, which engage or abut ends of the head part to fix the securing element in its position in the contact area between Head part and retaining element have a surface that shows a low sliding friction. Such surfaces can be constructed, for example, from Teflon, polished metal, ceramic or any other technically suitable material with a low coefficient of friction.

In a further possible embodiment of the presented securing element, it is provided that the at least one retaining element comprises guides for receiving the head area.

In order to guide the securing element or the ends of the head region of the securing element on a predetermined path in a movement about the longitudinal axis of the securing element, it is provided that the holding element, which is in contact with respective ends of the securing element, has guides which, for example the retaining element are incorporated or are arranged on the retaining element and which act on the ends of the head element of the securing element, if it moves away from its predetermined trajectory.

In a further possible embodiment of the presented securing element is provided that a material thickness of the securing element varies in the head area.

Due to a variable material thickness, d. H. Walls of different thicknesses, can be influenced on a spring constant or on a deflection or compression movement counteracted force, so that, for example, at a high expected deflection or compression force rather thick material and a rather low expected A thin material can be used and at the same time, for example, at the radially symmetrical end of the securing element, in the head region a predetermined to a predetermined leadership in a holding element material thickness is predetermined.

In a further possible embodiment of the presented securing element is provided that rolling elements are selected as holding elements.

By using rolling bearings for fixing or for clamping the fuse element according to the invention, the fuse element can be braced material-friendly, since at A shear movement of the movable, hollow and radially symmetrical element will only affect the rolling bearing.

Furthermore, the present invention relates to a method for securing a hollow axis and a radially symmetrical element movable about a longitudinal axis in its position by means of a securing element, wherein the securing element comprises a head region and an opposite base region and wherein the base region is arranged within the movable element the base portion engages the movable member such that the head portion bent so that the securing member projects out of the member in the head region and beyond a radially symmetrical end of the member and is slipped over the end of the member such that there is a gap between at least a part of the head portion and the radially symmetrical end of the element is present, wherein the securing element is braced with a radially symmetrical end by contact with at least one holding element between the at least one holding element and the engagement by the Securing element, a tensioning force is exerted by the head portion on the at least one holding element.

The inventive method is used in particular for the use of the fuse element according to the invention.

Furthermore, the present invention relates to a connecting element with a securing element, wherein the connecting element is hollow, radially symmetrical and rotatable and wherein the securing element comprises a head portion and an opposite base portion and the base portion is disposed within the connecting member so that the base portion in the connecting element via a Engages and wherein the head portion is bent such that the securing element protrudes in the head region out of the connecting element and beyond a radially symmetrical end of the connecting element and wherein the head portion is slipped over the radially symmetrical end of the connecting element such that a gap between at least a part of the Head region and the radially symmetrical end of the connecting element is present and the radially symmetrical end by contact with at least one retaining element, the securing element between the at least one Retaining element and the engagement clamped.

The presented connecting element is used in particular for transmitting forces via a rotational movement in, for example, a vehicle.

Further advantages and embodiments of the invention will become apparent from the description and the accompanying drawings.

It is understood that the features mentioned above and those yet to be explained below can be used not only in the respectively specified combination but also in other combinations or alone, without departing from the scope of the present invention.

The invention is diagrammatically illustrated by means of an embodiment in the drawings and will be described schematically and in detail with reference to the drawings.

The figures are described below overarching. Like reference numerals designate like features.

1 shows a schematic cross section through a designed as a screw fuse element according to the prior art.

2 shows a schematic cross section through a possible embodiment of the presented fuse element in a shaft.

3 shows a perspective view of another possible embodiment of the presented fuse element.

4 shows yet another perspective view of the presented fuse element.

5 shows a schematic cross section through a further possible embodiment of the presented fuse element.

6 shows a schematic cross section through the fuse element 5 in a wave.

7 shows a schematic cross section through a further possible embodiment of the presented fuse element in a shaft.

In 1 is a screw 1 shown with a wave 3 is screwed to the shaft 3 in their position in a housing 5 to secure. The screw 1 is characterized in particular by the fact that the screw 1 a thick, straight and, therefore, rigid or stiff end 7 includes, which is the wave 3 surrounds the outside and on holding elements 9 abuts the screw 1 between the holding elements 9 and the wave 3 to tense.

A possible embodiment of the presented fuse element 11 is in 2 shown. A hatched headspace 13 of the fuse element 11 know bends 15 on that over one end 17 a wave 3 protrude so that contact points 21 the bends 15 of the head area 13 of the fuse element 11 with holding elements 23 keep in touch and get between the end 17 the wave 3 and the bends 15 or the header area 13 a gap 25 forms, for example, is filled with air.

In a base area 27 of the fuse element 11 is the fuse element 11 with an intervention 29 the wave 3 in contact, leaving the fuse element 11 with a possibly occurring rotation of the shaft 3 with moves and the shaft 3 through a tension created by the bends 15 between the holding elements 23 and the interventions 29 is built, the wave 3 holds or secures with a movement in its position with respect to its longitudinal axis.

To the fuse element 11 To spare, the contact points 21 be coated with a friction-efficient surface of eg. Teflon or have correspondingly machined guides in which the bends 15 during a rotation of the shaft 3 move.

The bends 15 can be rigid and the shaft 3 As a result, fixed in position or be designed to be resilient, so that the fuse element 11 can deform along its longitudinal axis, ie expand and contract. By a deformation movement of the fuse element 11 can the wave 3 within predetermined limits also move along its longitudinal axis, so that securing the shaft 3 With a defined game, the game gently moves through a bend due to the bends 15 limiting counterforce is limited. Such a gentle limit. the game is gentle on the material for the fuse element 11 and the wave 3 , as hard collisions are avoided during, for example, jerky movements.

Another possible embodiment of the presented fuse element 31 is in 3 shown. A base area 33 extends here over a majority of the fuse element 31 , where the base area 33 recesses 35 which has a compression of the base area 33 when inserting into a corresponding shaft 3 enable. A head area 37 of the fuse element 31 is here bent radially symmetrically and formed in one piece.

In 4 is an embodiment of the presented fuse element 41 shown in which a head area 43 also with recesses 45 is provided so that the head area 43 particularly good spring, or slightly moved in the longitudinal direction. Accordingly, a buildup of counterforce to a deformation movement is rather low.

In 5 is an embodiment of the presented fuse element 51 represented by straight forms in the head area 53 and base area 55 distinguished. Due to the straight forms fits the fuse element 51 particularly positive fit in the shaft 3 , where the head area 53 rather rigid and correspondingly little freedom of movement along the longitudinal axis of the securing element 51 allows. In the 5 illustrated embodiment of the fuse element 51 is space-optimized or designed to save space, with a resilient effect is still maintained. One to secure the shaft 3 required spring force can with the fuse element 51 For example, be adjusted by different material thicknesses and / or tempering.

By a tempering process of a respective material, such as a steel, the steel can be tempered to a spring steel or a tempering steel, the suspension properties of the fuse element 51 more or less supported. Furthermore, by a construction of the securing element 51 using different material thicknesses, such as, for example, a particularly thick-walled head area, in addition to suspension properties of the fuse element 51 be acted.

6 shows the fuse element 51 as it is in the wave 3 is tense. A radially symmetrical end 61 of the fuse element 51 is on a feast with the wave 3 connected part 65 a rolling bearing, so that the securing part 51 during a rotational movement of the shaft 3 himself with the wave 3 and the part 65 of the rolling bearing with, while a fixedly connected to a body part 63 the rolling bearing during a rotational movement of the shaft 3 remains rigid. By a connection of the radially symmetrical end 61 of the fuse element 51 with the part 65 the rolling bearing shear forces between the holding element and the head portion of the security part 51 reduced or avoided.

A particularly material-saving embodiment of the presented fuse element 71 is in 7 shown. Here is the fuse element 71 made of only curved shapes, so that the fuse element 71 can apply a high spring force and counteract correspondingly strong tensile or compressive forces. Due to the curved configuration of the fuse element 71 a high spring force can be implemented with low space requirement. To the high spring force of the fuse element 71 To reinforce further, the fuse element 71 made of spring steel be, so that respective bends of the head portion of the fuse element 71 can be deformed particularly far and a correspondingly high restoring force arises when the shaft 3 moves along its longitudinal axis.

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 202013105196 U1 [0004]
• DE 102007028948 B3 [0005]
• DE 102012214914 A1 [0006]
• DE 102007012510 A1 [0007]
• DE 3622299 A1 [0008]

Claims (12)

Fuse element ( 11 . 21 . 31 . 41 . 51 . 61 . 71 ) for securing a hollow and radially symmetric element which is movable about a longitudinal axis ( 3 ) in a predetermined position, wherein the securing element ( 11 . 21 . 31 . 41 . 51 . 61 . 71 ) a header area ( 13 . 37 . 43 . 53 ) and an opposite base area ( 33 . 55 ) and the base area ( 33 . 55 ) within the movable element ( 3 ) with the movable element ( 3 ) about an intervention ( 29 ) and the header area ( 13 . 37 . 43 . 53 ) is bent such that the securing element ( 11 . 21 . 31 . 41 . 51 . 61 . 71 ), when it is in the movable element ( 3 ), in the head area of the movable element ( 3 ) and via a radially symmetrical end ( 17 ) of the movable element ( 3 ) and wherein the head area ( 13 . 37 . 43 . 53 ) in such a way over the radially symmetrical end ( 17 ) of the element ( 3 ) is that a space between at least part of the head area ( 13 . 37 . 43 . 53 ) and the radially symmetrical end ( 17 ) of the movable element ( 3 ) and a radially symmetrical end ( 21 ) of the header ( 13 . 37 . 43 . 53 ) by contact with at least one retaining element ( 9 . 23 . 65 ) the fuse element ( 11 . 21 . 31 . 41 . 51 . 61 . 71 ) between the at least one retaining element ( 9 . 23 . 65 ) and the intervention ( 29 ) braced. Fuse element ( 11 . 21 . 31 . 41 . 51 . 61 . 71 ) according to claim 1, wherein the head region ( 13 . 37 . 43 . 53 ) is bent such that the securing element ( 11 . 21 . 31 . 41 . 51 . 61 . 71 ) is resiliently movable. Fuse element ( 11 . 21 . 31 . 41 . 51 . 61 . 71 ) according to claim 1 or 2, wherein the base region ( 33 . 55 ) at least one recess ( 35 . 45 ) having. Fuse element ( 11 . 21 . 31 . 41 . 51 . 61 . 71 ) according to one of the preceding claims, wherein the intervention ( 29 ) is designed as a clip connection. Fuse element ( 11 . 21 . 31 . 41 . 51 . 61 . 71 ) according to one of the preceding claims, wherein the securing element ( 11 . 21 . 31 . 41 . 51 . 61 . 71 ) is formed of a metallic part. Fuse element ( 11 . 21 . 31 . 41 . 51 . 61 . 71 ) according to one of the preceding claims, wherein the securing element ( 11 . 21 . 31 . 41 . 51 . 61 . 71 ) fixed to the movable, hollow and radially symmetrical element ( 3 ) connected is. Fuse element ( 11 . 21 . 31 . 41 . 51 . 61 . 71 ) according to claim 6, wherein the at least one retaining element ( 9 . 23 . 65 ) has a surface which is characterized by a low sliding friction. Fuse element ( 11 . 21 . 31 . 41 . 51 . 61 . 71 ) according to one of the preceding claims, wherein the at least one retaining element ( 9 . 23 . 65 ) Includes guides for receiving the head portion. Fuse element ( 11 . 21 . 31 . 41 . 51 . 61 . 71 ) according to one of the preceding claims, in which the retaining element ( 9 . 23 . 65 ) is designed as a rolling bearing. Fuse element ( 11 . 21 . 31 . 41 . 51 . 61 . 71 ) according to one of the preceding claims, in which a material thickness of the securing element ( 11 . 21 . 31 . 41 . 51 . 61 . 71 ) in the head area ( 13 . 37 . 43 . 53 ) varies. A method for securing a hollow and radially symmetrical element movable about a longitudinal axis in its position by means of a securing element, wherein the securing element comprises a head region and an opposite base region and wherein the base region is arranged within the movable element such that the base region is in the movable element engages that the head portion, which is bent such that the securing element protrudes in the head area out of the element and beyond a radially symmetrical end of the element and is slipped over the end of the element such that a gap between at least a portion of the head portion and the radially symmetrical end of the element is present, wherein the securing element is braced with a radially symmetrical end by contact with at least one holding element between the at least one holding element and the engagement by durc by the securing element a tensioning force h the head area is exerted on the at least one holding element. Connecting element ( 3 ) with a fuse element ( 11 . 21 . 31 . 41 . 51 . 61 . 71 ), wherein the connecting element ( 3 ) is hollow, radially symmetrical and rotatable, and wherein the securing element ( 11 . 21 . 31 . 41 . 51 . 61 . 71 ) a header area ( 13 . 37 . 43 . 53 ) and an opposite base area ( 33 . 55 ) and the base area ( 33 . 55 ) within the connecting element ( 3 ) is arranged so that the base area ( 33 . 55 ) in the connecting element ( 3 ) about an intervention ( 29 ) and wherein the head area ( 13 . 37 . 43 . 53 ) is bent such that the securing element ( 11 . 21 . 31 . 41 . 51 . 61 . 71 ) in the head area ( 13 . 37 . 43 . 53 ) from the connecting element ( 3 ) and via a radially symmetrical end ( 17 ) of the connecting element ( 3 ) and wherein the head area ( 13 . 37 . 43 . 53 ) in such a way over the radially symmetrical end ( 17 ) of the connecting element ( 3 ), that a space ( 25 ) between at least part of the header area ( 13 . 37 . 43 . 53 ) and the radially symmetrical end ( 17 ) of Connecting element ( 3 ) and the radially symmetrical end ( 17 ) by contact with at least one retaining element ( 9 . 23 . 65 ) the fuse element ( 11 . 21 . 31 . 41 . 51 . 61 . 71 ) between the at least one retaining element ( 9 . 23 . 65 ) and the intervention ( 29 ) braced.

Images