DE102021128085A1 - Screw for forming a screw connection and method - Google Patents

Abstract

The invention relates to a screw (2) for forming a screw connection (1), which has a screw head (5) and can be subjected to a torque (10) by means of an impulse screwing tool (9) and can thereby be screwed into a threaded element (6), the Screw head (5) is designed as an inner support (12), which is designed in such a way that the screw connection (1) can be formed by screwing in the screw (2) using the impulse screwing tool (9).

Description

The invention relates to a screw for forming a screw connection according to the preamble of patent claim 1. The invention also relates to a method for screwing in a screw according to the preamble of patent claim 7.

A screw for forming a screw connection can be seen as known from the general state of the art. By means of the screw, two components that are designed separately from one another can be connected to one another by screwing. For this purpose, the screw can be subjected to a torque by means of a screwing tool and thereby screwed into a threaded element of one of the components.

It is the object of the invention to create a screw for forming a screw connection and a method for screwing in a screw, so that the frictional behavior of the screw can be particularly improved when the screw is screwed in.

According to the invention, this object is achieved by a screw for forming a screw connection with the features of patent claim 1 and by a method for screwing in a screw with the features of patent claim 7 . Advantageous configurations of the invention are the subject matter of the dependent patent claims and the description.

A first aspect of the invention relates to a screw for forming a screw connection. The screw has a screw head and can be subjected to a torque by means of an impulse screwing tool and can thereby be screwed into a threaded element. In other words, in order to screw or turn the screw into the threaded element, the torque provided by the impulse screwing tool can be applied to the screw, in particular via the screw head. In other words, the torque provided by the impulse screwing tool can be transmitted by the impulse screwing tool, in particular via the screw head, to drive the screw onto the screw, as a result of which the screw can be screwed into the threaded element.

The fact that the screw can be subjected to the torque by means of the impulse screwing tool and can thus be screwed into the threaded element can be understood to mean in particular that the screw connection can be formed using impulse screwing technology. Screwing the screw into the threaded element can in particular be referred to as a screwing-in process.

By applying the torque to the screw using the impulse screwing tool, the screw can be rotated through a rotational angle about a central axis of the screw relative to the threaded element, whereby the screw can be screwed into the threaded element. In other words, by turning the screw relative to the threaded element, the screw can be screwed into the threaded element. The relative turning of the screw can be effected by applying the torque to the screw.

For example, the screw is intended to connect at least two components by means of screwing, in particular by means of the impulse screwing technique. In this case, a first of the components can comprise the threaded element, with the screw connection being able to be formed by screwing the screw into the threaded element. Alternatively, both components can have a respective threaded element into which the screw can be screwed to form the screw connection. The screw connection can be formed by the components and the screw.

The impulse screwing tool can be understood in particular as a tool for screwing in and loosening screws or nuts. The impulse wrenching tool has a drive motor, by means of which the impulse wrenching tool can be operated. This means that the torque can be provided indirectly via the drive motor, by means of which the screw can be acted upon or is acted upon for screwing it into the threaded element. The torque can be transmitted to the screw via an output spindle of the impulse screwing tool, in particular directly. In the case of the impulse screwing tool, the output spindle is not mechanically connected to the drive motor. A power transmission or torque transmission between the drive motor and the output spindle is preferably carried out via a fluid, for example

Oil. In other words, the drive motor and the output spindle are coupled to one another via the fluid, in particular in a torque-transmitting manner, as a result of which the output spindle can be driven by the drive motor via the fluid.

The torque provided by the pulse tool and applied to the screw can have an oscillating or threshold-like torque curve of the torque. In particular, this can be referred to as a pulse-shaped torque curve. Thus, a force introduction or torque introduction to the screw caused by the impulse screwing tool and provided for applying the torque to the screw can run in the form of impulses or oscillating.

The screw head can have a drive, referred to in particular as a drive element. The torque provided by the impulse screwing tool for applying the torque to the screw can be transmitted to the screw via the drive element. In other words, the torque can be applied to the screw via the drive element by means of the impulse screwing tool. In order to apply the torque to the screw using the impulse screwing tool, the impulse screwing tool can be connected to the drive element in a torque-transmitting manner, in particular in a form-fitting manner.

In order to particularly improve the frictional behavior of the screw, in particular the screw head, when the screw is screwed in, the invention provides that the screw head or the screw is designed as an inner carrier, which is designed in such a way that the screw connection is broken by screwing in the screw using the Impulse screwing tool can be trained. In other words, the screw or the screw head is an inner support which is specifically designed or designed in such a way that the screw can be screwed into the threaded element using the impulse screwing tool as a result of the torque applied to the screw and the screw connection can thus be formed. To put it another way, the screw designed as an internal support is provided for the impulse screwing technique. The screw head or the screw is therefore not designed as an external support that is different from the internal support.

The fact that the screw is designed in such a way that the screw connection can be formed by screwing in the screw using the impulse screwing tool can be understood in particular to mean that the screw has been specifically designed in a development process of the screw, in particular structurally, to tighten the screw using the Screw the impulse screwing tool into the threaded element. This means that the screw was designed explicitly for the torque provided by the impulse screwing tool to be applied to the screw and thus for the screw to be screwed in by means of the impulse screwing tool. The screw is thus specifically optimized for screwing in the screw using the impulse screwing tool.

The screw is preferably not provided for screwing in the screw by means of a further screwing tool that is different from the impulse screwing tool. The screw is therefore preferably not specifically designed, in particular structurally, in such a way that the screw connection can be formed by screwing in the screw using the additional screwing tool. The screw is therefore preferably not optimized for use with the additional screwing tool.

The screw can be designed at least partially, in particular completely, experimentally and/or by calculation. Thus, the development process of the screw can have experimental and/or computational parts.

“Calculated” can in particular be understood to mean a simulation or calculation. This means in particular that at least parts of the screwing-in process are calculated or simulated, in particular virtually, with knowledge gained during the simulation or calculation being incorporated into the development process or the further design of the screw. A constructive adjustment or design of the screw or the inner support can thus be carried out depending on findings or calculation results of the simulation or the calculation.

For example, a bearing surface of the screw head is specifically adapted or designed during design. When the screw connection is fully established, the screw can be supported via the contact surface on the component having the threaded element, in particular on both components. When the screw connection is fully established, the screw can directly touch one of the components, in particular the first component or the second of the components. For example, an angle of the bearing surface, referred to in particular as a cone angle, can be designed or adapted in a targeted manner during the design.

For example, the cone angle or the bearing surface, referred to in particular as the cone surface, can be specifically adjusted to a defined coefficient of friction. Under the coefficient of friction can be understood in particular a mechanical friction characterizing value, the friction in a friction pairing between the Screw head, in particular the bearing surface, and one of the components, in particular the first component or the second component, may be present.

• Mittels der Impulsschraubtechnik beziehungsweise des Impulsschraubwerkzeugs kann ein besonders vorteilhaftes Setzverhalten der Schraube beziehungsweise der Schraubverbindung bewirkt werden. Dabei kann ein Vorspannkraftverlust einer Vorspannung der Schraube beziehungsweise der Schraubverbindung besonders gering gehalten werden. Dies kann insbesondere dadurch erzielt werden, dass das von dem Impulsschraubwerkzeug bereitgestellte und die Schraube beaufschlagende Drehmoment den insbesondere als impulsförmigen beziehungsweise oszillierenden Drehmomentenverlauf aufweist. Dies kann insbesondere schwellenförmiger Anzug der Schraube bezeichnet werden. Dadurch können bereits während des Einschraubens Setzverluste der Schraube beziehungsweise der Schraubverbindung besonders gering gehalten werden. Des Weiteren kann die Impulsschraubtechnik Vorteile hinsichtlich einer Ergonomie des Schraubvorgangs aufweisen. Dies bedeutet, dass die Schraube mittels des Impulsschraubwerkzeugs, insbesondere für einen Werker, welcher den Schraubvorgang durchführt, besonders ergonomisch in das Gewindeelement eingeschraubt werden kann.

The invention is based in particular on the following findings and considerations:

• A particularly advantageous setting behavior of the screw or the screw connection can be brought about by means of the impulse screwing technique or the impulse screwing tool. In this way, a loss of prestressing force due to prestressing of the screw or the screw connection can be kept particularly low. This can be achieved in particular by the fact that the torque provided by the impulse screwing tool and applied to the screw has the torque curve, in particular as a pulsed or oscillating torque curve. In particular, this can be referred to as a threshold-like tightening of the screw. As a result, setting losses of the screw or the screw connection can be kept particularly low even during screwing. Furthermore, the impulse screwing technique can have advantages in terms of ergonomics of the screwing process. This means that the screw can be screwed into the threaded element in a particularly ergonomic manner by means of the impulse screwing tool, in particular for a worker who carries out the screwing process.

In principle, it is conceivable to use conventional connecting elements for screwing the screw into the threaded element by means of the impulse screwing tool or the impulse screwing technique, as with screwing methods that differ from the impulse screwing technique. The conventional connecting member may be a screw member other than the screw. The screwing process, which differs from the impulse screwing technique, can be understood in particular as a continuous screwing process. This means that in the continuous screwing process, the torque applied to the screw by means of the additional screwing tool does not progress in the form of a threshold or in an oscillating manner.

However, when using such a conventional connecting element when screwing in using the impulse screwing tool, in particular in the final tightening, the friction behavior of the conventional connecting element, in particular a screw head of the conventional connecting element, can be particularly poor. For example, transitions between static friction and sliding friction, in particular between the screw head and one of the components, are particularly intense or particularly frequent. This can be caused or promoted in particular by the impulse-shaped or oscillating introduction of force of the impulse screwing tool, since this means that the screw element cannot always rotate continuously when the screw is screwed into the threaded element. Thus, the rotation or the rotational movement of the screw about the central axis relative to the threaded element can take place unevenly or non-uniformly. As a result, the transition between static friction and sliding friction, which is referred to in particular as the transition from static to sliding friction, can be effected or promoted. This can be promoted or brought about in particular by the fact that when the conventional connecting element was designed, the conventional connecting element was not specifically designed for screwing in the screw using the impulse screwing tool. As a result, when using the conventional connecting element, the screw connection cannot be formed by means of the impulse screwing tool.

In contrast, the screw according to the invention is specially designed for impulse screwing technology and can therefore meet the necessary requirements of impulse screwing technology for forming the screw connection. Due to the fact that the screw according to the invention or the screw head of the screw according to the invention is designed as an internal carrier, the friction behavior of the screw, in particular of the screw head, can be particularly improved when the screw is screwed in. In this way, friction of the screw head, in particular between the screw head and one of the components, in particular in relation to a screw designed as an external support, can be kept particularly low.

This can be achieved in particular by the screw designed as an inner support having an effective friction radius that is particularly small, in particular compared to the screw designed as an outer support. In other words, a friction surface of a friction pairing of the screw head, in particular the friction pairing between the screw head and one of the components, in particular the first or the second component, is shifted inwards in the radial direction of the screw in relation to the screw designed as an external carrier. Due to the particularly low friction or the particularly small effective friction radius, the transitions between static friction and sliding friction can be particularly reduced or eliminated be kept low. As a result, the screw connection can be formed using the screw according to the invention using the impulse screwing technique. In this way, in particular, a defined prestressing force of the screw connection can be set particularly precisely and particularly securely, as a result of which the safety of the screw connection can be particularly increased when the screw according to the invention is used.

The fact that the transitions between the static friction and the sliding friction can be particularly reduced can be understood in particular as meaning that the frequency of the transitions can be kept particularly low and/or the intensity of the respective transition can be kept particularly low.

In a further embodiment, it is provided that the screw head has the contact surface, via which the screw head or the screw is held in a fully formed screw connection, in which the screw is held in a defined installation position on the component having the threaded element via the threaded element, at least indirectly, in particular directly on which the component having the threaded element can be supported. This means that when the screw connection is completely formed or completely established, the screw is supported at least indirectly, in particular directly, via the bearing surface of the screw head, in particular in a longitudinal direction of the screw running along the central axis of the screw.

The defined installation position can be understood in particular as a target position, with the screw being arranged in its target position to form the screw connection on the component having the threaded element, in particular on both components.

In the installed position, the screw can be supported on both components via the bearing surface. When the screw connection is completely formed, the screw head preferably touches directly via the bearing surface of one of the components, in particular the first or the second component.

Support can in particular be understood to mean that the screw head and one of the components, in particular both components, are in mutual support.

One of the components, in particular the second component, preferably has a contact surface via which the screw head can be supported, in particular directly, on the component, in particular the second component, when the screw connection is fully formed, in particular in the longitudinal direction of the screw running along the central axis or is supported. Preferably, that component which is arranged closer to the screw head than the other component in the longitudinal direction of the screw has the contact surface.

The contact surface is preferably designed in such a way that the screw connection can be formed by screwing in the screw using the impulse screwing tool. Thus, the contact surface is preferably specifically designed for forming the screw connection using the impulse screwing technique. This means that the contact surface is designed, for example, in such a way that the friction occurring between the screw head, in particular the bearing surface, and the contact surface during the screwing-in process can be kept particularly low. For example, the contact surface has a particularly low coefficient of friction.

In a further embodiment, it is provided that the bearing surface has at least one contact point via which the screw head can be supported first, at least indirectly, in particular directly, on the component having the threaded element during screwing, in particular in the longitudinal direction of the screw. This means that when the screw is screwed in, the screw head is initially not supported, in particular via the bearing surface, on the component having the threaded element, with the progressive screwing of the screw into the threaded element creating a distance running in the longitudinal direction of the screw between the screw head, in particular the bearing surface , and the component having the threaded element can be reduced until the screw head is supported at least indirectly on the component having the threaded element via the bearing surface. This at least indirect support occurs at the contact point of the bearing surface first. This means that if the screw is not supported at least indirectly via the contact point on the component having the threaded element, then the bearing surface will not be supported at any other point on the bearing surface on the component having the threaded element that is at a distance from the contact point, in particular the at least is indirectly supported. Thus, during the screwing-in process, the bearing surface can only be supported via the further points on the component having the threaded element if the bearing surface or the screw head is already on the contact point the component having the threaded element is supported.

In particular, if the second component, which is arranged closer to the screw head in the longitudinal direction of the screw than the first component having the threaded element, has the contact surface when the screw connection is fully formed, then it can be provided that the screw head during screwing in mediated by the the second component having the contact surface can be supported at least indirectly via the contact point, in particular directly, first on the first component having the threaded element. This means that during the screwing-in process, the screw head can be supported via the contact surface first on the second component having the contact surface, in particular on the contact surface, at least indirectly, in particular directly, with the screw head supported on the second component having the contact surface being supported on the the second component having the contact surface can be supported, in particular directly, on the first component having the threaded element. This means that when the screw head is screwed in, it is not initially supported, in particular via the bearing surface, on the second component having the contact surface, but rather a free space is initially provided between the bearing surface and the second component having the contact surface, in particular the contact surface , wherein the free space can be reduced by progressively screwing in the screw until the screw head is supported at least indirectly, in particular directly, on the contact surface and thus on the second component via the bearing surface.

In a further embodiment, the contact point is arranged closer to the central axis of the screw in the radial direction of the screw than an outer edge of the bearing surface in the radial direction. In other words, a first distance running in the radial direction of the screw between the contact point and the central axis is smaller than a second distance running in the radial direction of the screw between the outer edge of the bearing surface and the central axis. To put it another way, the contact point is arranged closer to the central axis in the radial direction of the screw than an edge region of the bearing surface that outwardly delimits the bearing surface in the radial direction. As a result, the effective friction radius can be kept particularly small. The friction between the screw head and one of the components, in particular the first or the second component, can thus be kept particularly low.

For example, the bearing surface has an inner surface which is delimited outwards from the outer edge in the radial direction of the screw.

The outer edge of the bearing surface in the radial direction can in particular be understood to mean an outer edge of the bearing surface in relation to the radial direction of the screw. The outer edge of the support surface can be understood in particular as an outer edge curve. The outer edge of the bearing surface preferably extends in the circumferential direction of the screw.

In a further embodiment, it is provided that the contact point is spaced the same distance from the central axis in the radial direction of the screw as an inner edge of the bearing surface in the radial direction. In other words, the inner edge of the bearing surface in relation to the radial direction of the screw is arranged at a third distance, which runs in the radial direction of the screw, from the central axis, the third distance corresponding to the first distance. To put it another way, the contact point is spaced the same distance from the center axis in the radial direction of the screw as an inner edge region of the bearing surface delimiting the bearing surface inwards. As a result, the effective friction radius can be kept particularly small. The friction between the screw head and one of the components, in particular the first component or the second component, can thus be kept particularly low.

For example, the inner surface of the contact surface is delimited inwards by the inner edge in the radial direction of the screw.

The inner edge of the bearing surface in the radial direction can in particular be understood to mean an inner edge of the bearing surface in relation to the radial direction of the screw. The inner edge can be understood in particular as an inner edge curve. The inner edge preferably extends in the circumferential direction of the screw.

In a further embodiment it is provided that the screw head is provided or coated with a coating. In other words, the screw head has the coating. By means of the coating, when screwing in, a friction torque counteracting the torque can preferably be particularly reduced. In other words, the coating is designed to keep the friction torque particularly low. How In other words, the coating is designed as a friction-reducing coating. This means that the friction torque during screwing in is lower as a result of the coating than if the screw head were not provided with the coating or did not have the coating. Thus, by means of the coating, the friction torque or the friction can be particularly reduced in a particularly advantageous manner. As a result, the transitions between static friction and sliding friction can be kept particularly low.

The frictional torque can be understood in particular as a torque that counteracts the torque acting on the screw, which acts on the screw when the screw is screwed in and results from the friction between the screw head, in particular the contact surface, and one of the components, in particular the contact surface.

The fact that the screw head is provided with the coating can in particular be understood to mean that the screw head has been coated with the coating, in particular in a manufacturing process for the screw head. The coating is preferably designed as a sliding coating.

The coating is preferably designed as a galvanic coating. In other words, the screw head is provided with the galvanic coating, by means of which the friction torque when screwing in can be particularly reduced. As a result, the transitions between static friction and sliding friction can be kept particularly low.

The coating, in particular the galvanic coating, can be formed at least partially, in particular completely, from Teflon. The coating can be designed as a microencapsulation or comprise a microencapsulation.

The coating is preferably provided with at least one lubricant. In other words, the coating is preferably lubricated. As a result, the friction or the moment of friction can be particularly reduced.

When designing the screw, in particular when setting or designing the coefficient of friction, a friction coefficient check is preferably provided, which is able to quantify breakaway processes.

The screw head preferably has a marking. In other words, the screw head is identified by the marking. As a result, it is possible to avoid confusing the screw with a conventional screw that is different from the screw, in particular in production operations, or the confusion can be prevented. The conventional screw is usually not explicitly designed for the impulse screw technique. The marking can be understood in particular as an inscription or an imprint. The inscription or the imprint can be in the form of text and/or symbols and/or images.

Information about the screw can preferably be stored in an electronic computing device, in particular a database. In this case, the screw in the electronic computing device is preferably assigned to a first category and the conventional connecting element or screw element is assigned to a second category in the electronic computing device that is different from the first category.

The information can be understood in particular as information characterizing the screw. The information preferably includes instructions on the use and/or design of the screw.

A second aspect of the invention relates to a method for screwing in a screw, in particular using the impulse screwing technique, in which the screw having a screw head is subjected to the torque using an impulse screwing tool and is thereby screwed into the threaded element. Advantages and advantageous configurations of the first aspect of the invention are to be regarded as advantages and advantageous configurations of the second aspect of the invention and vice versa.

By applying the torque to the screw, the screw can be rotated through a rotation angle about a central axis of the screw relative to the threaded element, as a result of which the screw is screwed into the threaded element.

In order to particularly improve the friction behavior of the screw, in particular the screw head, when screwing in, it is provided according to the invention that the screw or the screw head of the screw to which the torque is applied is designed as an internal carrier. In other words, the screw head over which the Screw is acted upon by the torque formed as the inner support. To put it another way, a screw designed as an inner support or a screw which has the screw head designed as an inner support is used for screwing in or for forming the screw connection.

In a further embodiment, it is provided that the screw is subjected to the torque and is thereby screwed into a defined installation position in which the screw is or is held on a component having the threaded element via the threaded element, with the screw head in the installation position via a bearing surface of the screw head, in particular in a longitudinal direction of the screw running along the central axis, at least indirectly, in particular directly, on the component.

Provision is preferably made for the screw head, while the screw is being screwed into the threaded element, to be supported first, at least indirectly, on the component, in particular directly, via at least one contact point of the bearing surface, in particular in the longitudinal direction of the screw, with the contact point in radial direction of the screw is located closer to the central axis than an outer edge of the bearing surface in the radial direction.

In a further embodiment, it is provided that the contact point via which the screw head is first supported, in particular in the longitudinal direction of the screw, at least indirectly, in particular directly, on the component is spaced the same distance from the central axis in the radial direction of the screw as a radially inner edge of the bearing surface.

Further features of the invention result from the claims, the figures and the description of the figures. The features and combinations of features mentioned above in the description and the features and combinations of features mentioned below in the description of the figures and/or shown alone in the figures can be used not only in the combination specified in each case, but also in other combinations or on their own.

The invention will now be explained in more detail using a preferred exemplary embodiment and with reference to the drawings. In the single figure, the drawing shows a schematic partial sectional view of a screw connection, which is formed by means of a screw according to the invention or can be formed by means of a method according to the invention.

The single figure shows a screw connection 1 in a schematic partial sectional view. The screw connection 1 is formed by means of a screw 2 . The single figure shows two components 3, 4 and the screw 2 in a schematic partial sectional view. The screw connection 1 is shown during a screwing-in process in the single figure. Thus, the screw connection 1 is not yet in its fully established state.

The screw 2 has a screw head 5 . The components 3 , 4 are or will be screwed to one another by means of the screw 2 and are thus connected to one another via the screw connection 1 . A first of the components 3 has a threaded element 6 . In this case, the first component 3 comprises a bore 7 which is provided with the threaded element 6 . The first component 3 or the bore 7 thus has the threaded element 6 designed as an internal thread. The screw 2 has an external thread 8 .

The screw 2 can be subjected to a torque 10 by means of an impulse screwing tool 9 and can thereby be screwed into the threaded element 6 . Thus, when the screw 2 is screwed in using the impulse screwing tool 9 , the torque 10 is applied and it is thereby screwed into the threaded element 6 . In this case, the screw 2 is rotated about a central axis 11 of the screw 2 relative to the threaded element 6 or to the components 3 , 4 . The impulse screwing tool 9 is shown particularly schematically in the single figure.

The screw head 5 is arranged closer to the second component 4 than to the first component 3 . The second component 4 is thus arranged between the screw head 5 and the first component 3 . As a result, the second component 4 can be held on the first component 3 by means of the screw 2 .

In order to be able to particularly improve the friction behavior of the screw 2, in particular of the screw head 5, when screwing in, it is provided that the screw 2 or the screw head 5 is designed as an inner support 12, which is connected in such a way that the screw connection 1 is screwed in of the screw 2 can be formed by means of the impulse screwing tool 9 . Thus, the screw 2 designed as the inner support 12 is used to form the screw connection 1 as the screw 2 . This allows a friction radius between the Screw head 5 and the second component 4 acting in the screwing friction are kept particularly low. Thus, a friction torque 10a dependent on the friction radius and counteracting the torque 10 can be kept particularly low. As a result, transitions between static friction and sliding friction occurring between the screw head 5 and the second component 4 can be kept particularly low or avoided.

The torque 10 provided by means of the impulse screwing tool 9 and applied to the screw 2 can have a pulsed or oscillating course. As a result, the transitions between static friction and sliding friction could be particularly pronounced, especially if the screw 2 or the screw head 5 were not explicitly designed or provided for the impulse screwing technique and in particular were not designed as an inner support 12. This can be particularly advantageously avoided or particularly reduced by means of the screw 2 which is designed or provided explicitly for the impulse screwing technique and is designed as an inner carrier 12 .

In the exemplary embodiment, it is provided that the screw head 5 has a bearing surface 13, via which the screw head 5 is held via the threaded element 6 when the screw connection 1 is fully formed, in which the screw 2 is held in its defined installation position on the component 3 having the threaded element 6 , in particular through the intermediary of the second component 4, on the first component 3, in particular in a longitudinal direction 14 of the screw 2 running along the central axis 11, can be supported or is supported. The screw head 5 can be or is supported via the contact surface 13 on the second component 4, in particular directly, with the screw head 5 supported on the second component 4 being able or supported via the second component 4 on the first component 3, in particular directly is. Thus, in the fully formed screw connection 1, in which the screw 2 or the components 3, 4 are in their respective desired position relative to one another, the screw head 5 is in the longitudinal direction 14 via the contact surface 13, at least through the mediation of the second component 4 first component 3 supported.

In the only figure, the screw connection 1 is shown while it is being screwed in, that is to say the screw connection 1 is not yet completely formed. Thus, the screw 2 is not yet in its defined installation position in the only figure.

The only figure shows that the screw 2 or the screw head 5 touches the second component 4 directly via the bearing surface 13 . The screw head 5 is thus supported directly on the second component 4 along the longitudinal direction 14 via the bearing surface 13 . The screw head 5 is supported via the contact surface 13 on the first component 3 along the longitudinal direction 14 through the intermediary of the second component 4 . The screw head 5 or the bearing surface 13 touches the second component 4 directly at a contact surface 15 of the second component 4 .

In a further embodiment, it is provided that the contact surface 13 has at least one contact point 16, via which the screw head 5 can be supported first on the first component 3 in the longitudinal direction 14 of the screw 2 during screwing, in particular through the intermediary of the second component 4 is supported. In the only figure, the screw 2 and the components 3, 4 are shown during screwing in at the point in time at which mechanical contact between the screw head 5 and the second component 4 at the contact point 16 occurs for the first time during screwing. As a result of a radially symmetrical configuration of the screw 2, the contact point 16 in the exemplary embodiment is a contact curve. This means that a large number of contact points 16 are provided, which are arranged on a curve. The contact point 16 or the contact curve is arranged closer to the central axis 11, in particular in the radial direction 17 of the screw 2, than an outer edge 18 of the bearing surface 13 in the radial direction 17. In other words, the contact point 16 or the contact curve is in one , particularly in the radial direction 17, and the outer edge 18 is separated from the central axis 11 by a second distance 20, particularly in the radial direction 17, which is greater than the first distance 19 . As a result, the effective friction radius and thus the friction torque 10a can be kept particularly low, as a result of which the friction between the screw head 5 and the second component 4 can be kept particularly low.

In the exemplary embodiment, it is provided that the contact point 16 or the contact curve is spaced the same distance from the central axis 11 in the radial direction 17 of the screw 2 as an inner edge 21 of the bearing surface 13 in the radial direction 17. In other words In other words, the inner edge 21 is spaced apart from the central axis 11 by a third distance 22 , in particular in the radial direction 17 , the third distance 22 being the same as the first distance 19 . As a result, the effective friction radius and thus the friction torque 10a can be kept particularly low, as a result of which the friction between the screw head 5 and the second component 4 can be kept particularly low.

It is preferably provided that the screw head 5 is provided with a coating 23, which can be particularly reduced when screwing in the counteracting torque (10) of friction (10a). In the exemplary embodiment, the mechanical friction between the screw head 5 and the second component 4 can be kept particularly low by means of the coating 23. As a result, the transitions between static friction and sliding friction can be kept particularly low.

The coating 23 is preferably designed as a sliding coating. The coating 23 is preferably arranged at least on the bearing surface 13 or at least the bearing surface 13 has the coating 23 . The coating 23 is preferably in the form of a galvanic coating 24 .

Reference List

1

screw connection

2

screw

3

first component

4

second component

5

screw head

6

threaded element

7

drilling

8th

external thread

9

impulse wrench tool

10

torque

10a

friction torque

11

central axis

12

inner carrier

13

bearing surface

14

longitudinal direction

15

contact surface

16

contact point

17

radial direction

18

outer edge

19

first distance

20

second distance

21

inner edge

22

third distance

23

coating

24

galvanic coating

Claims (10)

Screw (2) for forming a screw connection (1), which has a screw head (5) and can be subjected to a torque (10) by means of an impulse screwing tool (9) and can thereby be screwed into a threaded element (6), characterized in that the screw head (5) is designed as an inner support (12), which is designed in such a way that the screw connection (1) can be formed by screwing in the screw (2) using the impulse screwing tool (9). screw (2). claim 1 , characterized in that the screw head (5) has a bearing surface (13) over which the screw head (4) when the screw connection (1) is fully developed, in which the screw (2) is in a defined installation position on a threaded element (6) having component (3) via the threaded element (6) is held on the component (3) can be supported. screw (2). claim 2 , characterized in that the bearing surface (13) has at least one contact point (16) via which the screw head (5) can be supported first on the component (3) during screwing, the contact point (16) being in the radial direction (17) of the screw (2) is arranged closer to the central axis (11) than an outer edge (18) of the bearing surface (13) in the radial direction (17). screw (2). claim 3 , characterized in that the contact point (16) in the radial direction (17) of the screw (2) is spaced the same distance from the central axis (11) as an inner edge (21) of the bearing surface (13) in the radial direction (17). Screw (2) according to one of the preceding claims, characterized in that the screw head (5) is provided with a coating (23) by means of which a friction torque (10a) opposing the torque (10) can be particularly reduced when screwing in. screw (2). claim 5 , characterized in that the coating (23) is designed as a galvanic coating (24). Method for screwing in a screw (2), in which the screw (2) having a screw head (5) is subjected to a torque (10) by means of an impulse screwing tool (9) and is thereby screwed into the threaded element (6), characterized in that that the screw head (5) of the screw (2), which is acted upon by the torque (10), is designed as an inner support (12). procedure after claim 7 , characterized in that the screw (2) is acted upon by the torque (10) and thereby in a defined installation position in which the screw (2) on a component (3) having the threaded element (6) via the threaded element (6) is screwed into the threaded element (6), the screw head (5) being supported on the component (3) in the installed position via a bearing surface (13) of the screw head (5). procedure after claim 8 , characterized in that the screw head (5) while the screw (2) is screwed into the threaded element (6) via at least one contact point (16) of the bearing surface (13) is first supported on the component (3), the contact point ( 16) is arranged closer to the central axis (11) in the radial direction (17) of the screw (2) than an outer edge (18) of the bearing surface in the radial direction (17). procedure after claim 9 , characterized in that the contact point (16) via which the screw head (5) is first supported on the component (3) is spaced the same distance from the central axis (11) in the radial direction (17) of the screw (2) as an inner edge (21) of the bearing surface (13) in the radial direction (17).

Images