阅读说明：本技术 锚固点部件 (Anchor point component ) 是由 M.弗伊齐克 于 2021-04-23 设计创作，主要内容包括：锚固点部件包括下部件2连带用于将锚固点部件1连接在物体上的连接元件4,并且包括相对于上部件2围绕连接元件4的纵轴线可旋转的上部件3,其具有用于连接锚固件或系牢件的连接件8,上部件3可沿轴向相对于下部件2逆向于复位弹簧10的复位力移位,在第一位置中上部件3相对于下部件2可自由旋转,并且在第二位置中上部件3转矩配合地作用在连接元件4上,所述连接元件4具有沿径向突伸的支承盘6,并且上部件3具有在所述支承盘6的径向侧面上支承该支承盘6的支承盘支承部9,连接元件4具有旋转同步轮廓13且上部件3具有与其适配的旋转同步轮廓19,其能通过上部件3从其第一位置至第二位置的轴向移位而与连接元件4的旋转同步轮廓咬合。(The anchor point component comprises a lower part 2 with a connecting element 4 for connecting the anchor point component 1 to an object, and an upper part 3 which is rotatable relative to the upper part 2 about the longitudinal axis of the connecting element 4, with a connection 8 for connecting an anchor or a tie, the upper part 3 being displaceable in the axial direction relative to the lower part 2 counter to a restoring force of a restoring spring 10, in a first position the upper part 3 being freely rotatable relative to the lower part 2, and in a second position the upper part 3 acting in torque-fit on the connecting element 4, the connecting element 4 having a radially projecting support disk 6, and the upper part 3 having a support disk support 9 which supports the support disk 6 on a radial side of the support disk 6, the connecting element 4 having a rotation synchronization contour 13 and the upper part 3 having a rotation synchronization contour 19 adapted thereto, which can engage with the rotationally synchronous contour of the connecting element 4 by axial displacement of the upper part 3 from its first position to its second position.)

1. An anchorage component comprising a lower part (2, 2.1) with a connecting element (4, 24) for connecting the anchorage component (1, 1.1) to an object to be fixed or manipulated with the anchorage component, and an upper part (3, 3.1) which is rotatable relative to the lower part (2, 2.1) about the longitudinal axis of the connecting element (4, 24), the upper part (3, 3.1) having a connecting piece (8, 8.1) for connecting an anchor or a tie-down, the upper part (3, 3.1) being displaceable in the axial direction relative to the lower part (2, 2.1) counter to the restoring force of a restoring spring (10) or a restoring spring device, in a first position the upper part (3, 3.1) being freely rotatable relative to the lower part (2, 2.1), and in a second position the upper part (3, 3.1) acting in torque-fit on the connecting element (4), 24) Wherein the connecting element (4, 24) has a radially projecting bearing disk (6, 6.1) and the upper part (3, 3.1) has a bearing disk bearing (9) which bears the bearing disk (6, 6.1) on a radial side of the bearing disk (6, 6.1), and wherein the connecting element (4, 24) has an outer rotational synchronization contour (13, 13.1) which is arranged at a distance from the bearing disk (6, 6.1) in the direction of the shank (5) of the connecting element, and the upper part (3, 3.1) has a rotational synchronization contour (19) which is adapted to the rotational synchronization contour, the rotational synchronization contour (19) of the upper part being able to engage with the rotational synchronization contour of the connecting element (4, 24) by an axial displacement of the upper part (3, 3.1) from its first position to its second position.

2. The anchor point component according to claim 1, characterized in that the rotational synchronization profile of the connecting element (4, 24) is provided by a radially protruding shim (13, 13.1) or shim section, whereby the connecting element (4, 24) has a non-rotationally symmetrical outer side in the region of its shim (13, 13.1) or shim section.

3. The anchor point component according to claim 2, characterized in that the rotational synchronization profile provided by the rotational synchronization profile shim (13, 13.1) has four identical profile sections arranged at the same angular spacing from one another, seen in the circumferential direction of the connecting element (4, 24).

4. The anchor point component of claim 3 wherein the rotational synchronization profile is square in cross-section with rounded designed corners.

5. The anchor point component according to any one of claims 2-4, characterized in that the rotation-synchronized profile washer (13, 13.1) projects circumferentially in a radial direction with respect to the side of the connecting element (4, 24).

6. The anchor point component according to any one of claims 1 to 5, wherein the rotation-synchronous profile of the upper component (3, 3.1), adapted to the rotation-synchronous profile of the connecting element (4, 24), is provided by an inner wall (19) of a disc-shaped annular body (11) that is set back inwards with respect to the radial terminal end of the supporting disc support (9).

7. The anchor point component according to claim 6, characterized in that the top side of the disk-shaped annular body (11) acts on the bearing disk (6, 6.1) of the connecting element (4, 24) in its freely rotatable position relative to the lower component (2, 2.1).

8. The anchor point component according to any one of claims 1 to 7, characterized in that the upper component (3, 3.1) has a support projection (20) extending in the axial direction, which radially surrounds, in particular surrounds, the lower component (2, 2.1), the inner wall of the support projection bearing on the outer wall of the lower component (2, 2.1).

9. The anchor point component according to any one of claims 6 to 8, characterized in that a return spring (10) or a return spring device is supported on the side of the disk-shaped annular body (11) facing away from the bearing disk (6, 6.1).

10. The anchor point component according to any one of claims 1 to 9, characterized in that the lower component (2, 2.1) has a circumferential groove which is open in the axial direction to the upper component (3, 3.1), in which groove the return spring (10) or the return spring device is mounted.

11. The anchor point component according to claim 10, characterized in that the radially outer arm (21) of the lower component (2, 2.1) delimiting the encircling groove (12) constitutes with its end facing the upper component (3, 3.1) a stop for limiting the axial movability of the upper component (3, 3.1) relative to the lower component (2, 2.1).

12. The anchor point component according to any one of claims 1 to 11, characterized in that the wave spring (10) or the wave spring group is designed as a return spring.

13. The anchor point component according to any one of claims 1 to 12, characterized in that the connecting element (4, 24) has a radially protruding connecting washer (16) which snaps into a radially inwardly open connecting groove (17) of the upper component (3, 3.1), by means of which snapping the connecting element (4, 24) is positively connected in the axial direction on the lower component (2, 2.1).

14. The anchor point component according to any one of claims 1 to 13, wherein the connecting element is a bolt (4, 24).

15. The anchor point component according to any one of claims 1 to 13, wherein the connecting element (24) is a sleeve with an internal thread (23).

16. The anchor point component according to any one of claims 1 to 14, characterized in that the connecting piece of the anchor point component (1, 1.1) is designed as a lifting ring (8, 8.1).

Technical Field

The invention relates to an anchor point part comprising a lower part with a connecting element for connecting the anchor point part to an object to be fixed to or manipulated with the anchor point part, and the anchor point part comprises an upper part which is rotatable relative to the lower part about the longitudinal axis of the connecting element.

Background

Such anchor point members are commonly used to lift objects. The anchor point parts are connected with their lower part to the object to be lifted by means of connecting screws designed as bolts, wherein a plurality of anchor point parts are usually used for lifting the object in order to hang corresponding lifting rigging. In order to align the lifting eye, which is suspended from the lifting eye, in accordance with the direction of the tensile force acting on it when a lifting device is applied, the lifting eye is rotatable relative to the connecting screw. The same characteristics of a bail are also desirable when the bail is used to tie an object.

The anchor point component is usually only retained on the object to be lifted or secured during lifting or securing. The suspension ring is therefore screwed into a threaded bore of an object to be handled, which is provided for this purpose and is equipped with a complementary internal thread, by means of a connecting screw provided with a threaded section. If the anchor point component is no longer needed, the anchor point component is unscrewed from the object again. Therefore, frequent screwing in and out of such anchor point members is a typical operation required at the time of its use. In order to simplify this process, DE 4403785 a1 provides that a screwdriver, which can be coupled to the head of the screw, is connected to the eyelet, and that the screwdriver performs a screwing movement through the eyelet into the connecting screw. It is provided here that the connecting screw is designed, for example, as a socket head cap screw and that the screwdriver comprises a suitable tool. The screwdriver itself comprises, for attaching itself to the suspension ring and for introducing a torque, a bracket which is guided around the arc-shaped portion of the suspension ring. If the hexagonal tool of the screwdriver is seated in the hexagonal socket of the connecting screw, the connecting screw is connected to the eyelet with a torque fit after the play, which may be present between the arc of the eyelet and the bow, has been overcome. The connection screw can thus be operated by the rotary movement of the suspension ring without additional tools. In order to attach the screwdriver to the suspension ring, the bow of the screwdriver, which surrounds the suspension ring, has a widened opening through which the arc-shaped part of the suspension ring is guided in order to attach the screwdriver to the suspension ring. In order to achieve a torque transmission from the suspension ring to the connecting screw in order to achieve not only a loose screwing-in or unscrewing of the connecting screw into the respective threaded hole of the object, but also a defined fixing of the connecting screw and thus a defined fixing on the anchoring point part of the object, the screwdriver must have sufficient stability. The necessary provision of a widened mounting opening in the region of the bracket can counteract this in some way. Therefore, certain requirements are put forward on the screw driver.

A further anchor point part is known from DE 4336779C 2, which is designed such that a torque for connecting a bolt to an object to be handled can be introduced into the lower part or its bolt via the upper part. The upper part of the anchor point component has a hood-shaped connecting part, by means of which the upper part is connected to the lower part. The cap-shaped connection extends over the entire upper side of the lower part, whereby the screw head is also completely covered. Thereby preventing contaminants from entering the screw head upper and lower parts. An inner hexagonal contour is provided in the inner side of the cap-shaped connection, into which a screw head of the screw, which is designed as a hexagonal head, engages when a torque is to be transmitted from the upper part to the screw. The upper member is axially movable relative to the lower member. The torque-engaging engagement of the threaded-part head of the screw of the lower part with the rotary drive contour of the upper part is cancelled as soon as a force having a component oriented axially with respect to the longitudinal axis acts on the upper part. The rotary drive profile of the upper member is then pulled out of the screw head. When the head of the screw is completely removed from the rotation transmission profile of the upper part, the upper part can rotate freely with respect to the lower part.

However, in this prior art, torque cannot be applied to the head of the screw of the bolt by means of a tool. In this known anchor point component, the handling thereof is also not completely problem-free, since special care is required when introducing forces into the anchor point component, in particular when the forces acting on the upper part are not aligned with the axis of rotation of the anchor point component. In the event that a force acts on the upper member with a shear component, the upper member typically attempts to rotate in the direction of the applied force. In order to be able to withstand the risk of the bolt and thus the anchor point part unintentionally becoming loose from the object to be handled in the event of such forces being introduced into the upper part, when the upper part is also in torque-engaging engagement with the screw head, the upper part must be manually moved relative to the lower part into an anchor point part use position in which the upper part can freely rotate relative to the lower part. But this is costly and cumbersome.

In order to avoid the above-mentioned problem described in DE 4336779C 2, an improved anchor point part has been developed, in which the upper part is displaced in the axial direction relative to the lower part counter to the restoring force of a restoring spring or restoring spring device, wherein in a first position the upper part is freely rotatable relative to the lower part and in a second position the upper part acts rotatably on the screw head of the bolt. The bolt has an outer rotational synchronization contour, in particular a hexagonally embodied rotational synchronization contour. The upper part has, in the region of the base of its two suspension link arms, on their sides facing each other, in each case a rotation-locking cam projecting laterally. When the upper part is freely rotatable relative to the lower part, the rotational synchronization cam is located above the head of the screw at an axial distance as viewed in the direction of the threaded shaft of the screw. If the upper part is moved against the force of the return spring or the return spring arrangement in the direction of the lower part, the screw head is located between the rotational synchronization cams of the upper part with two mutually parallel rotational synchronization faces, so that with the rotation of the upper part a torque is introduced into the screw head of the screw and thereby rotates the screw head. Such anchor point parts are known from the document DE 202019102552U 1.

Even if the anchor point component in principle meets the mechanical requirements set for it, it is still desirable that the anchor point component be designed compactly in terms of the necessary height.

Disclosure of Invention

Based on the prior art discussed, the object of the invention is therefore to provide an anchor point component according to DE 202019102552U 1, which is also of compact design in terms of its necessary height while maintaining the advantageous properties of the aforementioned anchor point component.

Said object is achieved according to the invention by an anchor point part having the features of claim 1.

In this anchor point component, the connecting element, which is embodied as a screw, for example, has a radially projecting bearing disk. The bearing disk is part of a connecting element, which is connected at least in a torque-fitting manner (or torque-locked manner) to other components of the connecting element. Usually, the support disk is molded onto the connecting element. The rotational synchronization contour is located on the side of the bearing disk facing the shaft, usually at a distance from the bearing disk in the axial direction. The rotation-synchronization contour is preferably located above the lower part, wherein in this embodiment the rotation-synchronization contour bears on the top side of the lower part on its section surrounding the connecting element opening. The adapted (or complementary, matching) rotational synchronization contour of the upper part is thus situated below the bearing disk and thus on the side facing away from the upper part. By virtue of the axial movability of the upper part relative to the lower part, the rotational synchronization contour of the upper part can engage with the rotational synchronization contour of the connecting element counter to the restoring force of the restoring spring or the restoring spring device. In this design of the anchor point component, it is preferred that the connecting element in principle does not need to have a head in addition to its bearing disk, in particular a head with a special geometry designed for rotational synchronization. It is obviously possible that the connecting element is also equipped with a conventional screw head, which is however not a necessary prerequisite for achieving the desired rotational synchronization between the upper and lower parts. By arranging the rotation-synchronization contour below the bearing disc of the connecting element, the annular base body of the lower part and the upper part and thus the upper part are all designed with a smaller height, which thereby enables a compact construction of the anchor point part.

Within the scope of this embodiment, it is provided that the rotational synchronization of the connecting element, for example a screw, by the upper part is described for the first time, wherein this rotational synchronization is not provided on or in the screw head. The arrangement of an adapted rotational synchronization contour below the bearing disk allows a design of the anchor point part with a two-point bearing of the upper part relative to the lower part to be achieved in a compact design, wherein the two bearing points between the upper part and the lower part are clearly spaced apart from one another in the axial direction of the connecting device. The first bearing position is a bearing of the connecting element-side bearing disk in or on a bearing disk bearing of the upper part on which the bearing disk is supported on its radial side. A second bearing point can be provided at a distance from the first bearing point and in a preferred embodiment. The second bearing position, in which the spacing is maintained in the axial direction, can be provided by an annular bearing projection of the upper part, which surrounds the outer side of the lower part. Typically, the support projection circumferentially surrounds the lower member. The inner wall of the annular support projection of the upper part can thereby be supported on the outer wall of the lower part. In view of such a two-point bearing, in which the two bearing points are axially spaced apart from one another, when a transverse force acts on the connecting piece of the upper part, which is designed, for example, as a suspension ring, the transverse force is particularly effectively transmitted to the object to which the lower part and the anchor point part are connected. In a preferred embodiment, provision is made in terms of two-point mounting for the diameter of the lower part, which is surrounded by the mounting projection of the upper part, to have a larger diameter than the diameter of the mounting disk of the connecting element, at least in the region of its adapted mounting section. In this way, the upper part bears on the lower part with lateral forces exerted on a larger surface, and in particular directly adjacent to the surface of the object to which the anchor point parts are connected.

In one embodiment of such an anchor point component, the shank section of the connecting element is designed between its torque-synchronous contour and the bearing disk with a larger diameter than the shank section that projects from the lower part if the connecting element is designed as a bolt equipped with an outer contour. Due to the larger diameter rod section, the connecting element is designed to be stronger in its particularly stressed section (in the case of lateral loading of the upper part) and can in this way withstand high lateral forces.

The torque synchronization profile protruding radially from the lever of the connecting element may be provided by a structure radially different from the above-mentioned profile, as long as the cross section of the connecting element is not rotationally symmetrical in the region of the torque synchronization profile. In one embodiment, it is provided that the connecting element has radially projecting spacers (Bund) or one or more spacer segments as a rotational synchronization contour. Such a rotational synchronization profile shim can be implemented circumferentially on the basis of the rod of the connecting element. The basic geometry of the shim is non-rotationally symmetrical and may for example be elliptical or polygonal, typically with rounded edges. Preferably, the adapted rotational synchronization contour is designed such that the engagement position can be realized in different angular positions of the upper part and the lower part relative to each other, for example in every 90 ° angular position. In this case, the adapted rotational synchronization profile is designed with a square cross section, usually with rounded corners, when the rotational synchronization profile shim is provided on the connecting element.

In one embodiment, the rotation-synchronization profile of the upper part is provided by a respective continuous inner wall of a disc-shaped annular body projecting inwardly with respect to the radial terminal end of the supporting disc support. The disk-shaped annular body serves a dual function and, in particular, on the one hand, the radially inner wall of the annular body provides a rotational synchronization contour with which the upper part can engage with the rotational synchronization contour of the connecting element. On the other hand, the annular body, which engages the bearing disk from below and thus from behind in the direction of the connecting piece, acts as a support part and transmits the force introduced in the axial direction into the suspension ring to the connecting element.

The anchor point component may be equipped with a connecting element embodied as a bolt. It is also possible for the connecting element to be designed as an internally threaded sleeve. In this case, it is also possible for the internally threaded sleeve to be provided with a screw head, which is arranged on the side of the internally threaded sleeve facing away from the lower part, for the case in which the tool is to be used.

A return spring or return spring arrangement is located between the upper part and the lower part. In order to support a compact design in the axial direction, the restoring spring or the restoring spring device is preferably arranged partially in a circumferential groove, typically in a circumferential groove of the lower part. The extension of the return spring or of the return spring arrangement from the groove in the direction of the other component is limited to the extent required for the axial movability between the upper and lower component in order to achieve rotational synchronization.

In a preferred embodiment, it is provided that the wave spring as a spring ring is used as a return spring, since the wave spring has only a small height during assembly and nevertheless provides the necessary spring travel with sufficient force. This supports the desired compact construction in the axial direction of the anchor point part.

Drawings

The invention is elucidated below on the basis of the accompanying drawings. In the drawings:

FIG. 1: a perspective view of a first anchor point component according to the invention is shown,

FIG. 2: showing a side view of the anchor point component of figure 1;

FIG. 3: a cross-sectional view of the anchor point component along section line a-B in figure 2 is shown in a partially enlarged view,

FIG. 4: a perspective view of the bolt used as the connecting element of the anchor point component in the above figures is shown in a separate view,

FIG. 5: a perspective view of the upper part of the anchor point part of figures 1 to 4 is shown in a separate view,

FIG. 6: a cross-section of the anchor point component along section line C-D in figure 2 is shown,

FIG. 7: a side view of an anchorage point member corresponding to fig. 2 is shown, with an upper member axially displaced relative to a lower member,

FIG. 8: a longitudinal section along section line a-B of figure 7 showing the anchor point means together with a partly enlarged view,

FIG. 9: showing a cross-section of an anchor point piece corresponding to figure 4 in its position shown in figure 7,

FIG. 10: a cross-sectional view of an anchorage point member according to a second embodiment of the invention corresponding to the view of the first embodiment of the invention in figure 3 is shown,

FIG. 11: a perspective view of the anchoring mechanism of the anchor point component of fig. 10 configured as a threaded sleeve is shown, and

FIG. 12: a cross-section corresponding to the anchor point component of fig. 10 is shown with the upper component torque-fittingly engaged with the lower component.

Detailed Description

The anchor point component 1 is intended to be connected to an object in order to be able to manipulate the object, that is to say to lift or fasten the object, respectively, depending on the application, etc. The anchor point member 1 has a lower member 2 and an upper member 3. The upper member 3 is rotatably supported with respect to the lower member 2. A pin 4, which in the exemplary embodiment shown is designed as a screw, is connected to the lower part 2 as a connecting element for connecting the anchor point part 1 to an object to be handled or fastened. The pin 4 has a threaded section 5. The threaded section is used to connect the anchor point component 1 to an object to be handled, which object is to be equipped with a suitable internally threaded bore for this purpose. A bearing disk 6 is formed on the pin 4. The upper part 3, which is rotatable relative to the lower part 2 with its pin 4, has an annular base body 7, on which, in the exemplary embodiment shown, a suspension ring 8 is formed as a connecting element for connecting an anchoring element or a fastening element. A support disk recess 9 is provided on the base body 7 as a support disk support. The bearing disk 6 of the pin 4 is accommodated in said bearing disk bearing.

In fig. 1 and 2, the anchorage point component 1 shows a first position of its upper component 3 relative to the lower component 2, and in particular a position in which the upper component 3 is freely rotatable relative to the lower component 2, which is desirable for the anchorage point component in its intended use. As shown in the sectional view in fig. 3, a wave spring 10 acting in the axial direction is provided between the upper part 3 and the lower part 2, the upper part 3 being displaceable in the axial direction toward the lower part 2 against the restoring force of the wave spring. The base body 7 of the upper part 3 has a disk-shaped annular body 11 projecting radially inwards, which itself extends, as shown in fig. 3, below the bearing disk 6 of the pin 4. The lifting force acting on the lifting eye 8 is transmitted to the pin 4 and thus to the object to be handled, which is connected to the pin, by the annular body 11 engaging the support disk 6 from below in the direction of the lifting eye 8. In the position of the upper part 3 shown in fig. 1 to 3, the disk-shaped annular body 11 acts with its top side against the bottom side of the bearing disk 6 and is fixed in this position by the wave spring 10. In order to accommodate the wave spring 10, a circumferential groove 12 with a rectangular cross-sectional geometry is provided in the lower part 2, on the bottom of which groove the other end of the wave spring 10 rests.

The pin 4 has, in addition to its profiled bearing disk 6, a rotational synchronization contour washer 13. The rotational synchronization contour disk 13 is designed in the form of a disk in a circumferential manner. The outer circumferential geometry of the radially outer portion thereof is rotationally asymmetrical and, in the exemplary embodiment shown, is designed as a square with rounded corners. The rotating synchronization contour washer 13 is axially spaced from the bearing disk 6 and has a smaller maximum diameter than the bearing disk 6. The pin section 14 between the rotational synchronization profile washer 13 and the bearing disc 6 has a larger diameter than the diameter of the threaded section 5. The pin 4 is thus designed in its pin section 14 to withstand particularly high shear forces.

The rotation-synchronizing profile washer 13 is supported on an inner arm 15 of the groove 12 facing the upper part 3. The pin 4 is held in an axially positive manner on the lower part 2 by means of a connecting washer 16 as part of the pin 4, which engages in a matching, radially inwardly open connecting groove 17 of the lower part 2. The connecting washer 16 and the groove 17 are matched in size to one another, so that the pin 4 can be inserted with its connecting washer 16 from above into the pin opening 18 of the lower part 2. The rotation synchronization contour disk 13 at the same time serves here as a stop for limiting the installation depth. By this mounting process, the upper part 3 is simultaneously connected to the lower part 2.

The radially inner wall 19 of the disc-shaped annular body 11 of the upper part 3 has a profile adapted to the outer profile of the rotating-synchronization-profile washer 13, so that when the two rotating-synchronization profiles 13, 19 are engaged, a torque can be transmitted from the upper part 3 to the pin 4, thereby connecting the two parts in a torque-fitting manner.

Given that the rotational synchronization contour of the pin 4 is designed as a circumferential disk-shaped washer, a higher torque can be introduced into the pin.

The annular base body 7 of the upper part 3 has an axially extending, annular bearing projection 20. The support projection 20 surrounds the lower part 2 from the outside in the radial direction. The inner side of the support protrusion 20 and the outer side of the lower member 2 are cylindrical surfaces and are matched in size to each other so that the radially inner wall of the support protrusion 20 is supported on the radially outer wall of the lower member 2. The upper part 3 is thus supported on the outer side of the lower part 2 and is supported by the inner wall of its support disk recess 9 on the support disk 6On the radial side of the cylinder. The support of the upper part 3 relative to the lower part 2 is thereby carried out in two support positions L₁、L₂Wherein in the drawing the position L is supported₁Is a support position between the support protrusion 20 and the lower member 2, and the support position L₂This is the bearing position between the radially inner side of the bearing disk bearing 9 and the radially outer side of the bearing disk 6 of the pin 4. The mounting of the upper part 3 on the lower part 2 with its pin 4 or relative to the lower part 2 with its pin 4 is therefore referred to as a two-point mounting, wherein the two mounting positions L are two₁、L₂Axially spaced from each other. Two bearing positions L₁、L₂The spacing of (a) allows for higher lateral force absorption. In the anchor point component 1, the torque-synchronous contours of the lower part 2 and the upper part 3 are arranged in a convenient manner in two bearing positions L with the aid of the spacing₁、L₂In the meantime. This results in only a small required axial height of the annular base body 7 of the lower part 2 and the upper part 3. Accordingly, the transverse forces introduced via the upper part 3 act with correspondingly small leverage on the pin 4.

In the embodiment shown, the bearing (or bearing) is designed as a sliding bearing (or sliding bearing). The support of the upper part relative to the lower part can be designed to take place by an intermediate connection of a bearing body, for example a ball or the like.

The cross-section of figure 6 shows the rotational synchronisation profile of the upper part 3 provided by the inner wall 19. The cutting plane is in the plane of the pin section 14 of the pin 4. The rotation-synchronization profile of the upper part 3 provided by the inner wall 19 does not engage with the rotation-synchronization profile of the pin 4 in this position of the upper part 3 relative to the lower part 2. The anchor point part 1 is thus in its first position in which the upper part 3 is freely rotatable relative to the lower part 2. In order to transmit a torque from the upper part 3 to the pin 4, the upper part 3 is moved in the direction of the lower part 2 in the axial direction, as indicated by the thick arrow, counter to the restoring force of the wave spring 10. By the pushing movement of the upper part 3, the inner wall 19 of the disk-shaped annular body 11 engages as a rotational synchronization contour with the rotational synchronization contour of the rotational synchronization contour washer 13 of the pin 4 (see in particular fig. 9). In this position, torque can be transmitted to the pin 4 via the upper part 3. This position of the upper part 3 relative to the lower part 2 is limited by the top side of the outer arms 21 defining the slot 12. If the upper part 3 is released after the torque transmission has been completed, for example, in order to screw the pin 4 with its threaded section 5 into a suitable internally threaded bore of the object to be handled, the upper part is returned, on the basis of the energy stored in the wave spring 10, into its freely rotatable position relative to the lower part 2.

The pin 4 of the shown embodiment likewise has a hexagonal head, wherein the pin 4 can be operated with a screw wrench, if desired. The diameter of the rotating synchronizing profile washer 13 of the pin 4 corresponds to the diameter of the screw head, so that an equal torque can be introduced into the pin 4, usually via the screw head. This makes it possible to introduce a defined pretensioning into the pin without the need to provide a screw wrench on the head of the screw, for example by using a lever which, by means of a section, passes through the opening of the suspension ring 8 of the upper part 3. However, the torque cannot then be measured, at least not successfully. It is clear that instead of the pin 4 shown in the figures with its hexagonal head, the hexagonal head can also be provided with any other rotational synchronization profile, for example an internal rotational synchronization profile, such as a hexagonal rotational synchronization profile.

Fig. 10 shows an anchor point component 1.1 according to another embodiment. This anchor point component is of the same construction as anchor point component 1 and differs from anchor point component 1 only in its connecting elements. In fig. 10 to 12, the same technical features that the anchor point component 1 shown in the previous figures also has are labeled with the same reference numerals, with the addition of the suffix ". 1". In the anchor point component 1.1, the connecting element is not configured as a bolt, but as an internally threaded sleeve. The shank 22 and the internal thread 23 thus form an internally threaded sleeve 24. The anchor point component 1.1 is thus intended for connection to an object to be manipulated and/or fixed, from which a threaded rod projects, which has a thread adapted to the internal thread 23 of the internally threaded sleeve 24.

Fig. 11 shows a perspective view of the internally threaded sleeve 24. The rotating synchronization contour washer 13.1 and the bearing disk 6.1 axially spaced from the rotating synchronization contour washer are clearly shown. The internally threaded sleeve 24 is equipped with a screw head 25 in the direction of the lifting ring 8.1.

The functionality of the anchorage point component 1.1 is exactly the same as described for the anchorage point component 1 with regard to the rotational synchronization of the lower component 2.1 with the upper component 3.1. Fig. 10 shows the upper part 3.1, which engages with the rotating synchronization contour washer 13.1 of the internally threaded sleeve 24. Fig. 12 shows, in contrast, an anchor point component 1.1 which has an upper part 3.1 which engages with a lower part 2.1 in a torque-fit manner.

The invention has been described with the aid of examples. The skilled person will also be able to derive numerous other possibilities for implementing the invention without departing from the scope of protection of the effective claims, which are not necessarily detailed here within the scope of the present embodiments.

List of reference numerals

1, 1.1 Anchor Point Components

2, 2.1 lower part

3, 3.1 Upper part

4 pin

5 thread section

6, 6.1 support disc

7 base body

8, 8.1 hanging ring

9 support disc recess

10 wave spring

11 annular body

12 groove

13, 13.1 rotating synchronous contour shim

14 pin section

15 arm

16 connecting pad

17 connecting groove

18 pin hole

19 inner wall

20 support protrusion

21 arm

22 rod part

23 internal thread

24 internal thread sleeve

25 screw head

L₁,L₂A support position.