WO2023186769A1 - Hybrid plug connector part for plugged connection to an associated hybrid mating plug connector part - Google Patents

Abstract

A hybrid plug connector part (1, 2) for plugged connection to an associated hybrid mating plug connector part (2, 1) comprises an insulating body (10, 20) and an engagement element (14, 24) that is arranged on the insulating body (10, 20) and is able to be brought into engagement with a mating engagement element (24, 14) of the hybrid mating plug connector part (2, 1) along a plugging direction (E). A wall (140, 240) runs around the plugging direction (E) on the engagement element (14, 24). At least one first electrical contact element (15, 25) for transmitting a data signal is arranged on the engagement element (14, 24). At least one second electrical contact element (12, 13, 22, 23) is used to transmit an electrical power signal. Provision is made here to arrange, on the wall (140, 240), an electrically conductive shielding section (16, 26) that runs around the plugging direction (E), is formed by a coating and serves to electrically shield the first electrical contact element (15, 25) arranged on the engagement element (14, 24), wherein the shielding section (16, 26) extends entirely around the at least one first electrical contact element (14, 24), but not around the at least one second electrical contact element (12, 13, 22, 23).

Description

Hybrid connector part for plug-in connection with an assigned hybrid mating connector part

The invention relates to a hybrid connector part for plug-in connection with an associated hybrid mating connector part according to the preamble of claim 1.

Such a hybrid connector part has an insulating body and an engagement element arranged on the insulating body, which can be brought into engagement with a mating engagement element of the hybrid mating connector part along a plug-in direction. A wall on the engagement element runs around the insertion direction. At least a first electrical contact element for transmitting a data signal is arranged on the engagement element. The hybrid connector part also has at least one second electrical contact element for transmitting an electrical power signal.

Such a hybrid connector part is used to transmit both electrical power signals and electrical data signals and therefore functions in a hybrid manner to transmit power and data. Circuits for transmitting the data signals on the one hand and for transmitting the electrical power on the other hand are electrically separated from one another. In this way, an electrical data and power connection, for example for connecting an electrical machine, can be established via a single connector.

In connectors that are used to transmit data signals, an electromagnetic shielding element is usually used, which electromagnetically shields the electrical contact elements for transmitting the data signal in order to suppress interference with the data signal from other circuits and signals.

In an insulating body known from DE 10 2012 111 646 B4, a shielding element in the form of a shielding cross is formed in one piece with the insulating body and is metallically coated using an MID process.

DE 10 2011 052 792 B4 also describes an insulating body with a cross-shaped shielding element that has a conductive coating.

From DE 10 2006 012 337 B3 an electrical connector is known in which a contact chamber is coated on an outer surface with a conductive layer. The object of the present invention is to provide a hybrid connector part that enables shielding of first contact elements for transmitting a data signal in a simple, space-saving manner.

This task is solved by an object with the features of claim 1.

Accordingly, an electrically conductive shielding section, which runs around the plug-in direction and is formed by a coating, is arranged on the wall for electrically shielding the at least one first electrical contact element. The shielding section extends circumferentially around the at least one first electrical contact element, but not around the at least one second electrical contact element.

In the hybrid connector part, an engagement element with a circumferential wall is formed on an insulating body. The engagement element can be formed by a plug-in opening that can be brought into engagement with a plug-in dome of the hybrid mating connector part. In this case, the wall defines the plug-in opening as a circumferential boundary wall. Alternatively, the engagement element can be formed by a plug dome, which can be brought into engagement with a plug opening of the hybrid mating connector part. The wall then extends around the plug-in dome and thus forms a circumferential lateral surface of the plug-in dome.

A first electrical contact element for transmitting a data signal is arranged on the engagement element. Spatially separated from the engagement element, the hybrid connector part also has at least one second electrical contact element for transmitting an electrical power signal. In this way, the hybrid connector part can transmit data signals and also electrical power signals.

In order to electromagnetically shield the at least one first electrical contact element for transmitting the data signal, a shielding section is provided, which is formed by a coating on the wall of the engagement element. The shielding section covers the wall and extends circumferentially around the insertion direction around the engagement element, so that the at least one first electrical contact element is arranged in a plane perpendicular to the insertion direction within a space surrounded by the shielding section. The at least one first electrical contact element is therefore located within the shielding section and is therefore electromagnetically shielded from the outside by the shielding section, so that in particular a disturbance caused by the electrical power signal transmitted via the at least one second electrical contact element is suppressed or at least reduced.

Because the shielding section is formed by a coating on the wall, the shielding section can be formed on the insulating body to save space. A separate shielding element separate from the insulating body is not required. Rather, the shielding section is formed integrally by coating directly on the insulating body, namely the engagement element of the insulating body.

The shielding section can be made, for example, from a metal material applied to the wall. For example, the shielding section can be made of a material containing zinc or copper.

For example, a metallization process, for example a thin-film technology process, can be used for the coating. For example, a metallization of the insulating body on the wall of the engagement element can be carried out by physical vapor deposition (PVD for short), by chemical vapor deposition (CVD for short), by thermal spraying or by electroplating.

In general, the coating is applied as a firmly adhering layer of a shapeless material to the surface of the wall of the insulating body. The coating can be a single layer or multiple layers. Chemical, mechanical, thermal or thermomechanical processes can generally be used as coating processes. Coating processes are defined in particular based on the initial state of the material to be applied, whereby the initial state can be gaseous (physical vapor deposition, chemical vapor deposition), liquid (e.g. spraying), dissolved (e.g. electroplating) or solid (e.g. powder coating).

The coating is preferably applied to the wall as a thin layer, for example with a layer thickness of less than 0.15 mm, preferably less than 30 pm.

In one embodiment, the hybrid connector part has two first electrical contact elements for transmitting the data signal. The shielding section extends circumferentially around the two first electrical contact elements, so that the two first electrical contact elements are arranged in a plane perpendicular to the plugging direction within a space surrounded by the shielding section. The two first electrical contact elements are therefore located radially (with a view to the plug-in direction) within the shielding section and are therefore circumferentially surrounded by the shielding section. Because the shielding section extends around the first contact elements via which the data signal is transmitted, the contact elements are shielded from the outside and in particular cannot be disturbed by the power signal also transmitted via the hybrid connector part.

The second electrical contact elements for transmitting the power signal are located outside the space surrounded by the shielding section and are therefore electromagnetically separated from the first contact elements via the shielding section, so that interference signals from the second contact elements cannot couple into the first contact elements or at least disruptive coupling is reduced is.

For example, the first two electrical contact elements can be designed to establish a single-pair Ethernet connection for transmitting an Ethernet data signal. Single Pair Ethernet describes an Ethernet transmission protocol over a pair of wires and thus a pair of contact elements on a connector part.

In one embodiment, the hybrid connector part has at least two second electrical contact elements for transmitting the electrical power signal. For example, the hybrid connector part can have at least four second electrical contact elements, of which at least two second contact elements are assigned to electrical load lines as electrical load contacts and, for example, a further contact element is assigned to a protective line and thus serves as a protective contact. In a concrete example, for example, five second electrical contact elements can be provided, wherein of the five second electrical contact elements, three contact elements are assigned to electrical load conductors (phase conductors), one contact element is assigned to a neutral conductor and one contact element is assigned to a protective conductor. For example, a three-phase alternating current signal can be transmitted via the second contact elements. The second electrical contact elements are preferably all arranged outside a space which is surrounded by the shielding section in a plane perpendicular to the plug-in direction. The second contact elements are therefore located radially (with a view to the plug-in direction) outside the shielding section and are therefore electromagnetically separated from the first contact elements within the shielding section via the shielding section, so that interference cannot easily couple from the second contact elements into the first contact elements.

In one embodiment, the hybrid connector part has a connection assembly that is connected to the insulating body of the hybrid connector part. The connection assembly can be formed, for example, by a cable with a plurality of electrical wires or by a circuit board. The connection assembly comprises at least one data line that is electrically connected to the at least one first electrical contact element. The connection assembly also includes at least one load line that is electrically connected to the at least one second electrical contact element. For this purpose, the connection assembly comprises a shielding element which is electrically connected to the shielding section on the engagement element of the insulating body.

The shielding element of the connection assembly can be formed, for example, by a tubular braided shield of a cable, within which the at least one data line of the connection assembly extends, so that the braided shield electromagnetically shields the data line. By electrically connecting to the shielding section of the insulating body, the shielding section is at the same potential as the shielding element of the connection module and is therefore included in the shielding of the connection module.

If the connection assembly is formed by a circuit board, the shielding element can be formed, for example, by one or more conductive layers of the connection assembly, which electromagnetically shield the at least one data line from the at least one load line.

A hybrid connector includes, in one embodiment, a hybrid connector part of the type described above and also an associated hybrid mating connector part that can be connected to the hybrid connector part along the plugging direction. In the connected position, the hybrid connector part and the hybrid mating connector part are plugged into one another, so that Engagement element of the hybrid connector part is engaged with the counter-engagement element of the hybrid mating connector part.

In one embodiment, the hybrid connector part is designed as a plug, in which the engagement element is formed by a plug dome that can be inserted into a plug opening of the hybrid mating connector part. On the engagement element in the form of the plug-in dome, the shielding section is formed on a circumferential wall by a circumferentially surrounding coating.

In another embodiment, the hybrid connector part is designed as a socket, in which the engagement element is formed by a plug opening into which a plug dome of the hybrid mating connector part can be inserted. On the engagement element in the form of the plug-in opening, the shielding section is formed by a circumferentially surrounding coating on a wall surrounding the plug-in opening.

Preferably, a shielding section is provided both on the side of the hybrid connector part and on the side of the hybrid mating connector part. A shielding section is formed by a coating on the plug-in opening and on the plug-in dome. In the connected position of the hybrid connector part and the hybrid mating connector part, the shielding sections of the hybrid connector part and the hybrid mating connector part are preferably in contact with one another in an electrically contacting manner, so that the shielding sections of the hybrid connector part and the hybrid mating connector part are at the same potential and thus a continuous shielding between connection assemblies that are the hybrid connector part and the Hybrid mating connector part is assigned, is produced.

Because a shielding section is produced on a hybrid connector part and preferably also on a hybrid mating connector part by a shielding section formed by a coating, the shielding section can be attached to the respective connector part in a space-saving manner. Additional components that require space and also make assembly more difficult are not required for shielding on the connector part.

The fact that the shielding section extends circumferentially on the respective engagement element (formed by a plug-in opening or a plug-in dome) results in effective electromagnetic shielding of the at least one first Contact element created in the area of the engagement element. The at least one first contact element is thus secured against electromagnetic influences and interference, in particular due to the transmission of the power signal to the second contact elements.

The idea underlying the invention will be explained in more detail below using the exemplary embodiments shown in the figures. Show it:

1 is a view of an exemplary embodiment of a hybrid connector part in the form of a socket, with first contact elements for transmitting a data signal and second contact elements for transmitting a power signal;

2 is a view of an exemplary embodiment of a hybrid connector part in the form of a plug, with first contact elements for transmitting a data signal and second contact elements for transmitting a power signal;

3 shows a schematic view of a hybrid connector part together with a connection assembly in the form of an electrical cable; and

Fig. 4 is a schematic cross-sectional view of the cable according to Fig. 3.

Fig. 1 shows an exemplary embodiment of a hybrid connector part 1 in the form of a socket, which can be connected to an associated hybrid connector part 2 in the form of a plug, in an exemplary embodiment shown in FIG. 2, along a plug-in direction E.

For the hybrid connector part 1 according to FIG. 1, the hybrid connector part 2 according to FIG. 2 serves as a mating connector part. Conversely, for the hybrid connector part 2 according to FIG. 2, the hybrid connector part 1 according to FIG. 1 serves as a mating connector part.

Together, the hybrid connector parts 1, 2 according to FIGS. 1 and 2 form a connector for connecting electrical connection assemblies 3, 4, for example electrical cables or circuit board assemblies. Each hybrid connector part 1, 2 is assigned to one of the connection assemblies 3, 4. By plugging in of the hybrid connector parts 1, 2, the connection assemblies 3, 4 are electrically connected to one another, for example to connect two cables to one another or to connect a cable to an electrical assembly, for example a circuit board assembly.

The hybrid connector part 1 according to FIG. 1, designed as a socket, has an insulating body 10 which forms a plug-in section 100 with a - in the exemplary embodiment shown - cylindrical outer surface with a circular cross section. Via the plug-in section 100, the hybrid connector part 1 in the form of the socket according to FIG. 1 can be brought into engagement with the associated hybrid plug-in connector part 2 in the form of the plug according to FIG. 2 along the plug-in direction E.

The hybrid connector part 1 has first electrical contact elements 15, which are arranged on an engagement element 14 in the form of a plug opening. The engagement element 14 in the form of the plug-in opening has a surrounding wall 140 and a base 141. The electrical contact elements 15 protrude from the base 141 along the plug-in direction E.

In the illustrated embodiment according to FIG. 1, the first electrical contact elements 15 are formed by pin contacts.

Spatially separated from the first contact elements 15, the hybrid connector part 1 has second electrical contact elements 12, which are arranged in a plug-in opening 11. The second electrical contact elements 12 protrude from a bottom 111 of the plug-in opening 11 along the plug-in direction E and are surrounded by a wall 110 of the plug-in opening 11 and are therefore arranged within the plug-in opening 11.

The second electrical contact elements 12 are designed as pin contacts. Of the four second contact elements 12 arranged within the plug opening 11, three contact elements 12 are assigned to phase conductors and thus serve as phase contacts for transmitting three electrical phase signals of a three-phase alternating current signal. One of the contact elements 12 is assigned to a neutral conductor and thus serves as a neutral contact.

A further second contact element 13 is arranged centrally within the plug-in section 100, which is assigned to a protective line and thus as a protective contact for transmitting a protective conductor potential between the hybrid connector parts 1, 2 serves. The protective contact 13 is designed as a socket contact in the exemplary embodiment shown.

While the hybrid connector part 1 according to FIG. 1 is designed as a socket with the plug openings 11, 15, the hybrid connector part 2 according to FIG. 2 is designed as a plug and has plug domes 21, 24 on an insulating body 20. First electrical contact elements 25 are arranged on a plug dome 24 that creates an engagement element and are designed as socket contacts. In contrast, second electrical contact elements 22 are arranged on a plug dome 21 and are also designed as socket contacts. A second contact element 23 in the form of a pin contact, which serves as a protective contact, is arranged centrally on the insulating body 20.

While an electrical data signal is transmitted via the first contact elements 15, 25, an electrical power signal is transmitted via the second contact elements 12, 13, 22, 23, in particular via the contact elements 12, 22 arranged within the plug opening 11 or on the plug dome 21. namely a three-phase alternating current signal. For example, a data connection in the form of an Ethernet connection, for example a single-pair Ethernet connection, can be established via the first contact elements 15, 25. In contrast, an electrical system, for example a machine, can be powered via the electrical power contacts 12, 22, so that both data signals and power signals can be transmitted between assigned assemblies via the connector formed by the hybrid connector parts 1, 2.

In order to suppress or at least reduce interference in the data signal caused by the transmitted power signal, a shielding section 16 is provided on the engagement element in the form of the plug-in opening 14 in the hybrid plug-in connector part 1 according to FIG. 1 on the wall 140 surrounding the plug-in opening 14 through a wall 140 covering coating surrounding the plug opening 14 is formed. The shielding section 16 extends circumferentially around the first contact elements 15 protruding from the bottom 141 of the plug-in opening 14 in such a way that the first contact elements 15 are arranged in a plane perpendicular to the plug-in direction E within a space surrounded by the shielding section 16. Because the second contact elements 12, 13 are arranged outside the shielding section 16, the first contact elements 15 are electromagnetically separated from the second contact elements 13 via the shielding section 16, so that interference signals from the second Contact elements 12, 13 cannot easily couple into the first contact elements 15.

In a complementary manner, in the hybrid connector part 2 according to FIG. 2, a shielding section 26 is formed by a coating on a wall 240 surrounding the engagement element in the form of the plug dome 24. The shielding section 26 extends circumferentially around the engagement element 24 and covers the wall 240, so that the first contact elements 25 are arranged in a plane perpendicular to the plug-in direction E within a space surrounded by the shielding section 26. The first contact elements 25 are thus electromagnetically separated from the contact elements 22 arranged on the plug dome 21 and also from the protective contact 23 by the shielding section 26, so that interference signals from the second contact elements 22, 23 cannot easily couple into the first contact elements 25.

When the hybrid connector parts 1, 2 are plugged in, the plug domes 21, 24 of the insulating body 20 of the hybrid plug connector part 2 according to FIG. 2 are inserted into the plug openings 11, 14 of the insulating body 10 of the hybrid plug connector part 1 according to FIG. 1 along the plugging direction E. The engagement element in the form of the plug dome 24 with the first contact elements 25 of the hybrid plug connector part 2 arranged thereon thus comes into engagement with the engagement element in the form of the plug opening 14 with the first contact elements 15 of the hybrid plug connector part 1 arranged thereon. The coating forming the shielding section 26 on the outside of the engagement element 24 thus comes into electrical contact with the coating forming the shielding section 16 on the lateral surface 140 surrounding the plug opening 14, so that the shielding sections 16, 26 are electrically at the same potential and thus the shielding potential from one hybrid connector part 1, 2 to the other hybrid connector part 2 , 1 is passed.

The shielding sections 16, 26 are formed by metallization on the respective wall 140, 240, for example by a coating made of a zinc material or a copper material. The shielding sections 16, 26 extend circumferentially around the plug-in direction E on the respective engagement element 14, 24 and thus circumferentially surround the second contact elements 15, 25 arranged within the shielding section 16, 26. The hybrid connector parts 1, 2 are assigned to connection assemblies 3, 4, for example in the form of electrical cables or circuit board assemblies. By plugging in the hybrid connector parts 1, 2, the connection assemblies 3, 4 are electrically connected to one another, so that data signals (via the first contact elements 15, 25) and power signals (via the second contact elements 12, 13, 22, 23) are transmitted simultaneously and in parallel can.

If a connection assembly 3, 4 is formed by an electrical cable, the connection assembly 3, 4 has line wires 42, 43, 44, which are enclosed in a cable jacket 40 and extend along the longitudinal direction of the cable, as shown in Fig. 3 and 4 is shown as an example of the connection module 4. Line wires 42 serve as data lines and are electrically connected to the respectively assigned first contact elements 15, 25, as shown in FIG. 3 as an example for the connection module 4 assigned to the hybrid connector part 2 according to FIG. Load lines 43 are connected to contact elements 12, 22. A protective line 44 is connected to a contact element 13, 23 of the associated hybrid connector part 1, 2.

3 and 4, the line wires 42 are enclosed in a shielding element 41, for example in the form of a tubular shielding braid, and extend within the shielding element 41 along the longitudinal direction of the cable 4, so that the line wires 42 are electromagnetically shielded. The shielding element 41 is electrically connected via an electrical connection 410 to the shielding section 16, 26 in the form of the coating on the associated engagement element 14, 24, as can be seen from FIG. 3 for the exemplary embodiment of the hybrid connector part 2 according to FIG. 2, so that the electromagnetic shielding is produced continuously on the connection assembly 3, 4 and the associated hybrid connector part 1, 2.

Because the shielding section 16, 26 is formed on the engagement elements 14, 24 by a coating, there is no need to provide a separate shielding element on the insulating body 10, 20. The shielding section 16, 26 therefore does not require any additional installation space, so that the hybrid connector part 1, 2 can be constructed in a space-saving manner with effective, extensive shielding on the assigned data contacts 15, 25. This can simplify assembly and also reduce costs. The insulating body 10, 20 has an electrically insulating effect and is made, for example, from a plastic material. The coating for forming the shielding section 16, 26 is applied to the plastic material of the insulating body 10, 20 by metallization.

The idea on which the invention is based is not limited to the exemplary embodiments described above, but can also be implemented in other ways.

The hybrid connector part is used for the hybrid transmission of both data signals and power signals. The number of contact elements for transmitting the data signals on the one hand and for transmitting the electrical power signal on the other hand can differ from the exemplary embodiments shown.

A hybrid connector of the type described can be used to connect any connection assemblies to one another, for example for industrial applications, for example for connecting and connecting electrical assemblies to electrical systems.

1 connector part (socket)

10 Insulating body (housing) 100 Plug-in section 101 Central section

11 plug opening 110 wall 111 base

12 contact elements (power contacts)

13 protective contact (PE)

14 Engagement element (plug opening) 140 Surrounding wall 141 Base

15 contact elements (data contacts)

16 shielding section (coating)

2 connector part (plug)

21 plug dome

22 contact elements (power contacts)

23 protective contact (PE)

24 Engagement element (plug dome) 240 Surrounding wall

25 contact elements (data contacts)

26 shielding section (coating)

3 connection assembly (cable)

4 connection assembly (cable)

40 cable jacket

41 Shield element (shield braid) 410 Electrical connection

42 data line

43 load lines

44 Protective cable E plug-in direction

Claims

Patent claims

1 . Hybrid connector part (1, 2) for plug-in connection with an assigned hybrid mating connector part (2, 1), with an insulating body (10, 20), an engagement element (14, 24) arranged on the insulating body (10, 20), which is along a plug-in direction ( E) can be brought into engagement with a mating engagement element (24, 14) of the hybrid mating connector part (2, 1), a wall (140, 240) running around the plugging direction (E) on the engagement element (14, 24), at least one on the engagement element (14, 24) arranged first electrical contact element (15, 25) for transmitting a data signal and at least one second electrical contact element (12, 13, 22, 23) for transmitting an electrical power signal, characterized in that on the wall (140, 240) an electrically conductive shielding section (16, 26) which runs around the plug-in direction (E) and is formed by a coating for electrically shielding the at least one first electrical contact element (15, 25), the shielding section (16, 26). extends circumferentially around the at least one first electrical contact element (14, 24), but not around the at least one second electrical contact element (12, 13, 22, 23).

2. Hybrid connector part (1, 2) according to claim 1, characterized in that the engagement element (14, 24) through a plug opening which can be brought into engagement with a plug dome of the hybrid mating connector part (2, 1), or through a plug dome which can be connected to a plug opening of the hybrid mating connector part (2, 1) can be brought into engagement.

3. Hybrid connector part (1, 2) according to claim 1 or 2, characterized in that the shielding section (16, 26) is made of a metal material applied to the wall. . Hybrid connector part (1, 2) according to one of claims 1 to 3, characterized in that the shielding section (16, 26) is made of a material containing zinc or copper.

5. Hybrid connector part (1, 2) according to one of the preceding claims, characterized in that the hybrid connector part (1, 2) has two first electrical contact elements (15, 25) for transmitting the data signal, the shielding section (16, 26) extending circumferentially extends around the two first electrical contact elements (14, 24), so that the two first electrical contact elements (15, 25) are arranged in a plane perpendicular to the plug-in direction (E) within a space surrounded by the shielding section (16, 26).

6. Hybrid connector part (1, 2) according to claim 5, characterized in that the two first electrical contact elements (14, 24) are designed to establish a single-pair Ethernet connection for transmitting an Ethernet data signal.

7. Hybrid connector part (1, 2) according to one of the preceding claims, characterized in that the hybrid connector part (1, 2) has at least two second electrical contact elements (12, 13, 22, 23) for transmitting the electrical power signal, the at least two second electrical contact elements (12, 13, 22, 23) are arranged in a plane perpendicular to the plug-in direction (E) outside a space surrounded by the shielding section (16, 26).

8. Hybrid connector part (1, 2) according to claim 7, characterized in that the hybrid connector part (1, 2) has at least four second electrical contact elements (12, 13, 22, 23), wherein at least two second contact elements (12, 13, 22 , 23) are assigned to electrical load lines as electrical load contacts.

9. Hybrid connector part (1, 2) according to one of the preceding claims, characterized by a connection assembly (3, 4) with at least one data line (42) which is electrically connected to the at least one first electrical contact element (15, 25), at least one Load line (43), which is electrically connected to the at least one second electrical contact element (12, 13, 22, 23), and a shielding element (41) which electrically shields the at least one data line (42), which is electrically connected to the shielding section (16, 26) is connected.

10. Hybrid connector part (1, 2) according to claim 9, characterized in that the connection assembly (3, 4) is a cable or a circuit board. Hybrid connector, with a hybrid connector part (1, 2) according to one of the preceding claims and an associated hybrid mating connector part (2, 1) which can be connected to the hybrid connector part (1, 2) along the plug-in direction (E). Hybrid connector according to claim 11, characterized in that

Hybrid connector part (1, 2) is formed by a plug, in which the engagement element (14, 24) is inserted into a plug opening of the

Hybrid mating connector part (2, 1) is formed by a plug-in dome. Hybrid connector part (1, 2) according to claim 11, characterized in that the hybrid connector part (1, 2) is formed by a socket, in which the engagement element (14, 24) is formed by a plug opening into which a plug dome of the hybrid mating connector part (2 , 1) is pluggable. Hybrid connector part (1, 2) according to claim 12 or 13, characterized in that on the plug opening and on the plug dome there is a wall (140, 240) which runs around the plug-in direction (E) and has an electrically conductive wall (140, 240) which runs around the plug-in direction (E). , shielding section (16, 26) formed by a coating is arranged. Hybrid connector part (1, 2) according to claim 14, characterized in that the shielding section (16, 26) of the plug opening and the shielding section (16, 26) of the plug dome are in the connected position of the hybrid connector part (1, 2) and the hybrid mating connector part (2, 1 ) are electrically contacting in contact with each other.