DE102021206241A1 - Connector and electrically driven air delivery device - Google Patents

Abstract

The invention relates to a connector (10) with at least one elongate contact part (7,8,9) which is electrically conductive and has two ends which are inserted into two electrically conductive receiving bodies in order to connect the electrically conductive receiving bodies via the elongate contact part (8th ) to connect electrically with each other-
In order to improve the connector (10) in terms of production technology and/or functionality, the elongated contact part (8) has a convex contact contour at each of its ends, with which the elongated contact part (8) is arranged in the respective electrically conductive receiving body such that a electrical contact between the electrically conductive receiving bodies and the elongate contact part (8) is maintained even with an axial offset and/or angular offset.

Description

The invention relates to a plug connector with at least one elongate contact part which is electrically conductive and has two ends which are inserted into two electrically conductive receiving bodies in order to electrically connect the electrically conductive receiving bodies to one another via the elongate contact part. The invention also relates to an electrically driven air supply device for supplying air to a fuel cell system, having a housing which includes a power connection device and a control connection device.

State of the art

From the German Offenlegungsschrift DE 10 2019 207 438 A1 discloses an electrically assisted turbocharger with a compressor housing, a stator core connected to the compressor housing of an electric motor coupled to the turbocharger and an electronics housing of the electric motor connected to the stator core. From the European patent address EP 3 641 068 B1 a plug connector with a connector plug and a connector socket is known, which comprises an annular socket part and a lamellar basket arranged at least partially inside the annular socket part.

Disclosure of Invention

The object of the invention is to provide a plug connector with at least one elongate contact part which is electrically conductive and has two ends which are inserted into two electrically conductive receiving bodies in order to electrically connect the electrically conductive receiving bodies to one another via the elongate contact part, in particular for use in or on an electrically driven air supply device for supplying air to a fuel cell system, with a housing that includes a power connection device and a control connection device, to improve production technology and/or functionality.

In a connector with at least one elongate contact part, which is electrically conductive and has two ends, which are inserted into two electrically conductive receiving bodies in order to electrically connect the electrically conductive receiving bodies to one another via the elongate contact part, the object is achieved in that the elongate Contact part has a convex contact contour at each of its ends, with which the elongate contact part is arranged in the respective electrically conductive receiving body in such a way that electrical contact between the electrically conductive receiving bodies and the elongate contact part is maintained even with an axial offset and/or angular offset. Due to the convex contact contour on the elongated contact part, tolerance compensation movements are made possible during assembly of the connector. The plug connector is a plug-in connection device that is designed in several parts. The plug-in connection device is abbreviated as a plug-in connector. The plug connector preferably comprises a plurality of elongate contact parts, in particular three elongate contact parts, which serve to provide a 3-phase alternating current which arrives, for example via an inverter, at a control connection device of an electrically driven air delivery device. The control connection device is electrically connected to the power connection device of the electrically driven air supply device via the plug connector. The mounting positions of the power connection device and the control connection device on the electrically driven air supply device can vary due to the manufacturing process. This can lead, for example, to a longitudinal axis of the elongate contact element not always being able to assume its ideal axial direction between the two connection devices. For example, an axis offset and/or an angular offset can occur, which is undesirable per se, but cannot be ruled out or cannot be completely ruled out due to the manufacturing process. The ends of the elongate contact part have, at least in part, preferably a substantially spherical geometry to produce the convex contact contour. In cross section, this results in a convex curvature at the contact contour against which the respective electrically conductive receiving body rests in order to produce the electrical contact. The convex contact contour provides the advantage that the position and contour of a contact line or line of contact between the ends of the elongate contact part and the respective electrically conductive receiving body does not change when the axial offset and/or angular offset, which is undesirable per se, has to be compensated. The line of contact or line of contact advantageously always remains in the same place and has, for example, a circular contour with the same contact forces.

A preferred embodiment of the plug connector is characterized in that at least one end of the elongate contact part has the shape of a ball head. This advantageously allows tolerance compensation movements in different directions. In addition, the shape of the ball head at the end of the elongate contact part provides the advantage that a convex contact contour can be dispensed with on the electrically conductive receiving body. According to a further exemplary embodiment, the electrically conductive receiving body can also be equipped with a convex contact contour. This can advantageously be a snapping or snapping the assembly of the elongated contact part can be realized. For this purpose, the electrically conductive receiving body can advantageously be equipped with elastically deformable lamellae.

A further preferred exemplary embodiment of the plug connector is characterized in that the ball head is connected in one piece to the elongate contact part. The shape and size of the ball head is advantageously adapted to an axial offset and/or angular offset that is to be expected. The one-piece connection between the ball head and the elongate contact part simplifies its assembly.

A further preferred exemplary embodiment of the connector is characterized in that the spherical head is connected to the elongated contact part in a form-fitting, force-fitting and/or material-fitting manner. The ball head is fastened, for example, with the aid of a fastening device. The fastening means comprises, for example, a nut screwed onto a threaded rod piece which extends from the elongate contact part and through a corresponding through-hole in the ball head. The attachment means may also include a screw for attaching the ball head to the elongate contact member. The elongate contact part with the separate ball head may be easier to manufacture.

Another preferred embodiment of the plug connector is characterized in that at least one end of the elongate contact part is spaced so far in an axial direction from an axial end of the electrically conductive receiving body that elongate contact parts can be used that have different lengths due to tolerances. The size of a possible length compensation can be adjusted via the size of the distance between the end of the elongate contact part and the axial end of the electrically conductive receiving body.

Another preferred embodiment of the connector is characterized in that the connector includes a bearing device for the elongated contact part, which allows tolerance compensation movements of the elongated contact part relative to the electrically conductive receiving bodies when the electrical connection between the electrically conductive receiving bodies is made with the elongated contact part, wherein the bearing device for the elongate contact part comprises an elastically deformable bearing element which is arranged with two opposite ends together with one of the electrically conductive receiving bodies in two housing parts of the plug connector. As a result of the bearing device claimed, the elongate contact part can perform tolerance compensation movements to a limited extent during assembly of the plug connector, without the electrical connection between the electrically conductive receiving bodies being impaired. The bearing device for the elongate contact part makes it possible to compensate for tolerances in a particularly advantageous manner, even with relatively low or normally high insertion forces. In addition, the durability or current-carrying capacity of the electrical contacting can be improved by the bearing device. The electrically conductive receiving body serves to establish an electrical connection with the elongate contact part. The elastically deformable bearing element enables the desired tolerance compensation movements of the elongate contact part in the respective housing part. The elasticity of the elastically deformable bearing element enables relative movements between the rather rigid elongate contact part and the likewise rather rigid housing part. In addition, the elastically deformable bearing element performs at least one additional function, for example a damping function and/or a sealing function.

A preferred exemplary embodiment of the plug connector is characterized in that the elastically deformable bearing element is formed from an electrically insulating material and also has a sealing function and/or a damping function. The electrically insulating material from which the elastically deformable bearing element is formed is preferably a plastic material, in particular an elastomer. Its sealing function reliably prevents a medium from penetrating into the electrically conductive receiving bodies. The cushioning function cushions shocks that could cause the electrical connection to loosen or be interrupted.

A further preferred exemplary embodiment of the connector is characterized in that the elastically deformable bearing element has sealing contours at its ends. The sealing contours at the ends of the elastically deformable bearing element can include, for example, ribs or lamellae, which on the one hand serve to provide the sealing function and on the other hand improve the elastic deformability of the bearing element.

A further preferred exemplary embodiment of the connector is characterized in that the elastically deformable bearing element is positively connected between its ends to the elongate contact part. The interlocking connection includes, for example, a collar formed on the elongate contact portion and engages in a complementary groove provided in the elastically deformable bearing element. The federal government is advantageously arranged centrally, based on the longitudinal direction of the elongate contact part. The positive connection prevents relative movements between the elongate contact part and the elastically deformable bearing element in the axial direction.

A further preferred exemplary embodiment of the connector is characterized in that the elastically deformable bearing element has a sleeve-like shape and is arranged with its ends in annular spaces between the elongate contact part and the respective housing part. The sleeve-like shape ensures that the elastically deformable bearing element completely surrounds the elongated contact part between the opposite ends of the elastically deformable bearing element. In this way, the elongate contact part can advantageously perform compensating movements in different directions relative to the housing part. The size of the compensating movements is defined by the size of the annular spaces in which the ends of the elastically deformable bearing element are arranged.

A further preferred exemplary embodiment of the plug connector is characterized in that at least one axial securing device for the elastically deformable bearing element is provided on the elongate contact part. In this way, the elastically deformable bearing element can be positioned relative to the elongate contact part in a simple manner. The axial retainer comprises, for example, an axial retainer ring located in a corresponding annular groove of the elongate contact portion. Among other things, this provides the advantage that the axial securing device can be installed in a simple manner before or after the installation of the elastically deformable bearing element.

A further preferred exemplary embodiment of the connector is characterized in that the elongate contact part has a round outer geometry. Particularly advantageously, the elongate contact part has a round cross section, in particular a circular cross section. For example, the elongate contact part is substantially in the shape of a right circular cylinder. This simplifies or improves the production and the function of the elongate contact part.

Another preferred exemplary embodiment of the connector is characterized in that each electrically conductive receiving body has a convex contact contour facing the elongated contact part, with which the electrically conductive receiving body surrounds the elongated contact part in such a way that electrical contact is also established between the electrically conductive receiving body and the elongated contact part is maintained at an axis offset and/or an angular offset. To represent the convex contact contour, the electrically conductive receiving body has, for example, an outwardly curved curvature in the contact area. This then means in particular that the electrically conductive receiving body has the shape of a partial circle in cross section, for example, in order to represent the convex contact contour.

A further preferred exemplary embodiment of the plug connector is characterized in that the convex contact contour is spaced so far in an axial direction from an axial end of the electrically conductive receiving body that elongate contact parts can be used which have different lengths due to tolerances. The size of a possible length compensation can be adjusted via the size of the distance between the axial end of the electrically conductive receiving body and the convex contact contour.

A further preferred exemplary embodiment of the plug connector is characterized in that the electrically conductive receiving body is formed from an electrically conductive sheet metal material and has elastically deformable lamellae which are used to establish the electrical connection with the elongated contact part. It is thus ensured in a simple manner that the electrical contact between the elongate contact part and the electrically conductive receiving body is not impaired, specifically not when the elongate contact part performs the tolerance compensation movements described above. The electrically conductive receiving body is advantageously arranged in a plastic bushing which, for example for insulation purposes, is arranged between the electrically conductive receiving body and the housing part in the installed state.

The invention also relates to an elongate contact part, an electrically conductive receiving body and/or a bearing device, in particular an elastically deformable bearing element, for a plug connector as described above. The parts mentioned can be traded separately.

In the case of an electrically driven air supply device for supplying air to a fuel cell system, with a housing that includes a power connection device and a control connection device, the above-mentioned object is alternatively or additionally achieved in that the power connection device is electrically connected to the control connection device by at least one connector as described above. In order to transmit three AC phases, the connection between the power connection device and the control connection device advantageously includes three plug connectors. The electrically driven air supply device is also referred to as an electrically driven air compressor. An inverter can be integrated into the housing of the electrically driven air compressor. However, the inverter can also be arranged separately outside the housing of the electrically driven air compressor.

Further advantages, features and details of the invention result from the following description, in which various exemplary embodiments are described in detail with reference to the drawing.

character list

• 1 eine perspektivische Darstellung einer Luftzuführvorrichtung mit einem Gehäuse, an beziehungsweise in dem eine Steueranschlusseinrichtung über drei längliche Kontaktteile mit einer Stromanschlusseinrichtung verbunden ist;
• 2 eine perspektivische Darstellung eines elektrisch leitenden Aufnahmekörpers für einen Steckverbinder;
• 3 ein Blechteil, aus welchem der elektrisch leitende Aufnahmekörper in 2 gebildet ist;
• 4 eine schematische Darstellung eines Steckverbinders im Längsschnitt; und
• 5 den Steckverbinder aus 4 beim Ausgleich eines Achsversatzes beziehungsweise Winkelversatzes.

Show it:

• 1 a perspective view of an air supply device with a housing on or in which a control connection device is connected to a power connection device via three elongate contact parts;
• 2 a perspective view of an electrically conductive receiving body for a connector;
• 3 a sheet metal part, from which the electrically conductive receiving body in 2 is formed;
• 4 a schematic representation of a connector in longitudinal section; and
• 5 the connector 4 when compensating for an axis offset or angular offset.

Description of the exemplary embodiments

In 1 an air supply device 1 is shown in perspective. The air supply device 1 is also referred to as an air compressor and is used in a mobile fuel cell system to provide compressed air. The mobile fuel cell system, in turn, is used in a motor vehicle equipped with the fuel cell system to provide electrical energy, which is converted into drive energy for the motor vehicle, for example via an electric motor.

The air supply device 1 comprises a multi-part housing 2 with an air connection 3, via which air is supplied, and with an air connection 4, via which compressed air is discharged. In order to compress the air, the air supply device 1 comprises, for example, a compressor wheel which can be rotated within a compressor volute.

The compressor wheel is driven by an electric motor which is arranged in the housing 2 . The electric motor includes a rotor rotatable within a stator.

The stator of the electric motor includes a power connection device 5, via which alternating current is supplied to the stator in three phases. The power connection device 5 is connected to a control connection device 6 via a plug connector 10 which comprises three elongated contact parts 7 , 8 , 9 .

The control connection device 6 is combined, for example, with a cable outlet 40 which, as indicated by three outgoing cables, is connected to a separately arranged and in 1 not shown inverter is connected. However, the inverter can also be integrated into the housing 2 of the air supply device 1 . Then the cable outlet 40 is omitted.

In the 4 and 5 the connector 10 is shown with the elongated contact part 8 in longitudinal section. The elongated contact part 8 has a circular cross-section. A length of the elongate contact part 8 is indicated by a dimension line 38 .

The ends 14, 24 of the elongated contact part 8 with the spherical heads 51, 61 are arranged in electrically conductive receiving bodies 11, 21. The electrically conductive receiving bodies 11, 21 are electrically connected to one another via the elongated contact part 8.

For example, one of the cable outlets of the control connection device 6 extends from the electrically conductive receiving body 11 . From the electrically conductive receiving body 21, for example, a 1 indicated power line 39 from. The power line 39 is connected, for example, to a stator winding (not shown) of the stator of the electromotive drive of the air supply device 1 .

The electrically conductive receiving bodies 11, 21 are each arranged in an insulating bushing 12, 22 made of a plastic material. The insulating bushing 12, 22 has the shape of a straight circular cylinder casing which surrounds the electrically conductive receiving body 11, 12. The insulating bushing 12, 22 in turn is arranged in a housing part 13, 23, which includes a receiving space for the insulating bushing 12, 22 with the electrically conductive receiving body 11, 21.

The insulating bushing 12 is open at both ends. The insulating sleeve 22 is at her in the 4 and 5 left end closed. The electrically conductive receiving bodies 11, 21 are firmly arranged in the respective associated insulating bushings 12, 22. A connection between the insulating bushings 12, 22 and the associated electrically conductive receiving bodies 11, 21 is implemented as a material bond, force fit and/or form fit.

The connector 10 includes a bearing device 20 for the elongated contact part 8 in the housing parts 13, 23, the two connection devices 5, 6 of the in 1 shown housing 2 of the air supply device 1 are assigned.

The bearing device 20 also serves to seal the plug connection 10 against external media influences. In addition, the reliability of the electrical contacting in the connector 10 is increased with the bearing device 20 .

The bearing device 20 is formed from an elastically deformable material. In this way, an elastically deformable bearing element 19 is created, which essentially has the shape of a straight longitudinal cylinder jacket.

The elastically deformable bearing element 19 is arranged with ends 15, 25 facing away from one another in annular spaces 16, 26, which are delimited radially on the inside by the elongated contact part 8 and radially on the outside by the housing parts 13, 23. The size and shape of the annular spaces 16, 26 are such that an 5 Illustrated axis offset 35 and / or angular offset 36 can be compensated by the bearing device 20 without the electrical connection between the electrically conductive receiving bodies 11, 21 with the elongated contact part 8 being impaired or even interrupted in any way.

The one-piece or one-piece design of the elastically deformable bearing element 19 also provides a protective function for the elongated contact part 8 between the two housing parts 13, 23. Between its ends 14 , 24 , the elastically deformable bearing element 19 is equipped with a collar that serves to create a positive connection 29 with the elastically deformable bearing element 19 . The positive connection 29 prevents relative movements between the elongated contact part 8 and the bearing device 20, in particular relative movements in the axial direction.

The bearing device 20 also comprises two axial locks 18, 28 for the ends 15, 25 of the elastically deformable bearing element 19.

The ends 15, 25 of the elastically deformable bearing element 19 are designed as annular bodies with ribs 41, 42 projecting radially outwards. The ribs 41, 42, which can also be designed as lamellae, in combination with the elastic deformability ensure that the bearing device 20 also remains in contact with the housing parts 13, 23 when an in 5 Axis offset 35 or angular offset 36 shown occurs.

The elastically deformable bearing element 19 , which is preferably formed from a solid material, bears radially on the inside against the elongate contact part 8 . The ends 15, 25 of the elastically deformable bearing element 19 deform radially on the outside, as can be seen in FIG 5 sees. The end 25 of the elastically deformable bearing element 19 is in 5 below much more compressed than in 5 above. Conversely, the end 15 of the elastically deformable bearing element 19 in 5 much more compressed above than in 5 below.

The elastically deformable bearing element 19 is made of an electrically non-conductive material such as an elastomer. It is thus advantageously possible to ensure compliance with clearance and creepage distances with the plug-in connection 10 . In addition, the shape and the elastic deformability of the elastically deformable bearing element 19 at its ends 15, 25 ensure adequate sealing, even when the elongate contact part 8 is inclined, as in FIG 5 is illustrated. The slanting of the elongate contact part 8 is advantageously carried out in an elastic range, so that a restoring force is applied to the elongate contact part 8 that enables reliable current conduction between the electrically conductive receiving bodies 11 , 21 via the elongate contact part 8 .

In 4 a length of the elongate contact part 8 is indicated by a dimension line 38 . The opposite ends 14, 24 of the elongated contact part 8 are spaced from the axial ends of the electrically conductive receiving bodies 11, 21 in the axial direction. Among other things, this provides the advantage that elongate contact parts 7 with different lengths 38 can be mounted.

In 4 corresponds to the dimension line 38 of a longitudinal axis of the elongated contact part 9, the in 4 with longitudinal axes of the housing parts 13, 23 is coaxial. Due to manufacturing tolerances, however, deviations from this desired coaxiality can occur.

In 5 shows how both an axial offset 35 and an angular offset 36 can be compensated for with the connector 10 . In 5 the elongated contact part 8 is slightly inclined so that the in 5 right end 14 is located lower than that in 5 left end 24 of the elongate contact part 8.

This tilting or tilting of the elongate contact part 8 is made possible by the convex contact contours 50, 60, in particular by the ball heads 51, 61, optionally in combination with the convex contact contours 17, 27 in the electrically conductive receiving bodies 11, 21. Alternatively or additionally, the electrically conductive receiving bodies 11, 21 are partially elastically deformable.

In 2 an embodiment of the electrically conductive receiving body 21 is shown in perspective. The electrically conductive receiving body 21 is, as shown in 3 sees formed from a sheet metal part 30, which is advantageously designed as a stamped part.

The sheet metal part 30 comprises a base 31 from which lamellae 32 extend. The sheet metal part 30 with the lamellae 32 is bent round in order to 2 represent electrically conductive receiving body 21 shown. The lamellae 32 are still curved at their free ends to represent the convex contact contour in the 4 and 5 is denoted by 27.

The elongate contact part 8 essentially has the shape of a right circular cylinder, which is equipped with a spherical head 51, 61 at its opposite ends 14, 24. The ball head 51, 61 is, for example, integrally connected to the elongated contact part.

The ball head 51, 61 serves to represent a convex contact contour 50, 60 at the respective end 14, 24 of the elongated contact part 8. The convex contact contour 50, 60 provides the advantage that the position and contour of a contact line of the two contact partners does not change. as can be seen from a synopsis of the 4 and 5 results. In 4 there is neither an axis offset nor an angular offset. In 5 both an axial offset 35 and an angular offset 36 occur.

The ball head 51 , 61 is fastened to the respective end 14 , 24 of the elongate contact part 8 with the aid of a fastening device 52 , 62 in the exemplary embodiment shown. The fastening means 52, 62 comprises, for example, a nut which is screwed onto a threaded rod piece at the end 14, 24 of the elongate contact part 8.

QUOTES INCLUDED IN DESCRIPTION

This list of the documents cited by the applicant was 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.

Patent Literature Cited

• DE 102019207438 A1 [0002]
• EP 3641068 B1 [0002]

Claims (10)

Connector (10) with at least one elongate contact part (7,8,9) which is electrically conductive and has two ends (14,24) which are inserted into two electrically conductive receptacles (11,21) to connect the electrically conductive receptacles (11,21) via the elongate contact part (8) to be electrically connected to one another, characterized in that the elongate contact part (8) at its ends (14,24) each have a convex contact contour (50,60) with which the elongate Contact part (8) is arranged in the respective electrically conductive receiving body (11, 21) in such a way that electrical contact is maintained between the electrically conductive receiving body and the elongate contact part (8) even if there is an axial offset (35) and/or angular offset (36). will. connector after claim 1 , characterized in that at least one end of the elongate contact part (8) has the shape of a spherical head (51, 61). Connector according to one of the preceding claims, characterized in that the spherical head (51, 61) is connected in one piece to the elongate contact part (8). connector after claim 1 or 2 , characterized in that the ball head (51,61) is connected to the elongate contact part (8) in a form-fitting, force-fitting and/or cohesive manner. Connector according to one of the preceding claims, characterized in that at least one end (14,24) of the elongate contact part (8) is spaced so far in an axial direction from at least one axial end of the associated electrically conductive receiving body (11,21) that elongate contact parts (8) can be used which have different lengths (38) due to tolerances. Connector according to one of the preceding claims, characterized in that the connector (10) comprises a lengthening device (20) for the elongate contact part (8), which allows tolerance compensation movements of the elongate contact part (8) relative to the electrically conductive receiving bodies (11, 21). When the electrical connection between the electrically conductive receiving bodies (11,21) is made with the elongated contact part (8), the bearing device (20) for the elongated contact part (8) comprises an elastically deformable bearing element (19) which has two opposite ends (15,25) together with one of the electrically conductive receiving bodies (11,21) is arranged in two housing parts (13,23) of the connector (10). connector after claim 6 , characterized in that the elastically deformable bearing element (19) is formed from an electrically insulating material and additionally exerts a sealing function and/or a damping function. Connector according to one of the preceding claims, characterized in that the elongate contact part (8) has a round outer geometry. Connector according to one of the preceding claims, characterized in that the electrically conductive receiving bodies (11, 21) are formed from an electrically conductive sheet metal material and have elastically deformable lamellae which serve to establish the electrical connection with the elongate contact part (8). Electrically driven air supply device (1) for supplying air to a fuel cell system, having a housing (2) which comprises a power connection device (5) and a control connection device (6), characterized in that the power connection device (5) is connected by at least one plug connector (10) according to one of the preceding claims is electrically connected to the control connection device (6).

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