RU2782340C1 - Plug connector and plug connector assembly - Google Patents

Abstract

FIELD: electrical engineering.

SUBSTANCE: plug connector (1) for the electrically conductive connection of the electrical cable (4) connected to it with the mating plug (2) contains at least one electrically conductive contact (10), an insulating inner housing (12), which has a fastening section (122) for fixing the contact (10), a conductive outer housing (14), which has a fastening section for fixing the inner housing (12), and this plug connector (1) further contains the first shielding element (146) electrically connected to the conductive outer housing (14), which can penetrate through the insulating outer layer of the cable (4) connected with a plug connector and creates an electrical contact with the electromagnetic shielding layer in the insulating outer layer of the cable (4) to provide an additional electromagnetic shielding function for the cable (4).

EFFECT: invention aims to provide a plug connector that provides additional electromagnetic shielding function and solves the described problem of transmission of high voltages and/or high currents.

15 cl, 14 dwg

Description

FIELD OF TECHNOLOGY

The present invention relates to a plug connector for connecting to a mating plug in the fast connection technique, in particular for the transmission of high currents and with good EMC (electromagnetic compatibility) properties. The invention further concerns a plug connector assembly with such a plug connector and such a mating plug.

BACKGROUND OF THE INVENTION

With the development of science and technology, the desire of the authorities to use green energy became stronger. Therefore, in many industries, electrical energy is increasingly being used, for example, in the automotive industry, in particular in railway transport and in road transport. In this case, there are special performance requirements with regard to current transfer. For example, charging such vehicles requires the transmission of power at high voltages and/or high currents. Therefore, there is a particular need for plug-in connectors that can withstand high currents.

In the prior art, cables for the transmission of high voltages and high currents have already been improved. For example, an EMC layer, namely an electromagnetic shielding layer, is provided in the outer insulating layer of the transmission cable, which prevents the magnetic field caused by high voltages or high currents being transmitted from interfering with the normal operation of nearby electronic devices. However, some of the existing plug connectors only provide a shielding function against electromagnetic interference inside the current or signal-transmitting plug connector, in particular for contacts, which is insufficient for the transmission of high voltages and high currents.

DISCLOSURE OF THE INVENTION

Accordingly, the present invention is directed to providing a plug connector that provides an additional electromagnetic shielding function and solves the problem of high voltage and/or high current transmission as described.

According to one aspect of the present invention, a plug connector is provided for electrically connecting a cable connected thereto to a mating plug, comprising at least one conductive contact; an insulating inner case which has a fastening portion for fastening the contacts; a conductive outer case which has a fastening portion for attaching the inner case. Said plug connector further comprises a first shielding element electrically connected to the conductive outer casing, which can contact the insulating outer layer of the cable connected to the plug connector and thereby make electrical contact with the electromagnetic shielding layer in the insulating outer layer of the cable in order to provide additional electromagnetic shielding function for the cable.

According to the invention, the first shielding element creates respectively an electrical connection with the conductive outer casing and the electromagnetic shielding layer of the cable. Therefore, an additional electromagnetic shielding function can be created inside the cable and the plug connector, with which the electromagnetic interference requirements for external electronic devices are met when high voltages or high currents are transmitted.

In one preferred embodiment of the present invention, the first shield element is formed in the shape of an inverted triangle, the upper side of which is in conductive contact with the conductive outer casing, while the lower tip is in electrical contact with the electromagnetic shielding layer of the cable.

In another preferred embodiment of the present invention, the first shielding element is made of a metal, this metal being a stainless metal. Preferably, this metal is an aluminum alloy whose surface is electroless nickel-plated.

Alternatively or additionally, the first shielding element may consist of copper, steel, aluminum and/or brass, or at least contain these materials.

In a further preferred embodiment of the present invention, said plug connector comprises a second shielding element placed in a conductive outer housing, which can be in electrical contact with the conductive outer housing of the plug connector and with the conductive outer housing of the mating plug connected to the plug connector to provide additional electromagnetic shielding. cable function.

In a further preferred embodiment of the invention, said second shielding element is an annular spring washer which is in peripheral contact with the conductive outer housing of the plug connector and the conductive outer housing of the mating plug. As a result, improved electromagnetic shielding can be achieved between the plug connector and the mating plug.

In one preferred embodiment, the second shielding element may be a round spring, a triangular flat spring or a multilamella and/or this second shielding element may have brush contacts.

In another embodiment, the first shielding element may be a round spring, a triangular flat spring or a multilamella, and/or the first shielding element may have brush contacts.

These embodiments, in particular in a suitable combination, have the advantage that the respective contact contact resistance can be purposefully adapted to the requirements of the respective application.

In a further preferred embodiment of the present invention, the first and/or second shielding elements are made of stainless metal. In particular, in the case of a metal, it can be an aluminum alloy. In particular, its surface can be nickel-plated by chemical reduction.

Alternatively or additionally, the second shielding element may be composed of copper, steel, aluminum or brass, or at least contain these materials.

In one preferred embodiment of the present invention, the plug connector comprises an insulating sealing element housed in a conductive outer housing that contacts the outer insulating layer of the cable to form a watertight seal. In addition, said plug connector has an L-shaped compression element, so that, due to the connection between the fastening element of the plug connector and the conductive outer casing, a tangential force is simultaneously transmitted to the sealing element, so that this sealing element expands radially and thereby forms a strong sealing interface with cable.

In a further preferred embodiment of the present invention, the conductive outer casing is made of a metal, the metal being electroless nickel plated aluminum.

According to another aspect of the present invention, there is provided a plug connector assembly comprising the plug connector described above and a mating plug associated with the plug connector, the mating plug comprising: a conductive contact; an insulating inner case which has a fastening portion for securing this contact; and a conductive outer case which has a fastening portion for attaching the inner case. Said mating plug further comprises a third shielding element conductively connected to the conductive outer casing, which can contact the insulating outer layer of the cable connected to this mating plug and make electrical contact with the electromagnetic shielding layer in the insulating outer layer of the cable in order to provide additional electromagnetic shielding function for the cable.

In a further preferred embodiment of the present invention, the third shielding element is in the form of an inverted triangle, the upper side of which is in conductive contact with the conductive outer shell of the mating plug, while the lower vertex is in electrical contact with the electromagnetic shielding layer of the cable.

A preferred plug connector assembly is characterized in that the first shielding element, the second shielding element and the third shielding element form, respectively, electrical contact with the outer housing of the plug connector and with the outer housing of the mating plug in order to provide complete electromagnetic shielding for the cable connected via the plug connector and the mating plug , and for the plug connector assembly.

In a further preferred embodiment of the present invention, the second shielding element is made of metal, in particular stainless steel.

According to the invention, a first shielding element, a second shielding element and a third shielding element made of metal are provided, each of which is electrically connected to an EMC cable braid layer and to a conductive outer casing, which is also made of metal. As a result, both the cable and the plug connector and mating plug mated to it acquire excellent electromagnetic shielding. Thus, transmission is more reliable and stable, and electromagnetic interference is not generated for electronic devices in the surrounding area. Finally, in the prior art, many plug-in connectors intended for signal transmission do not have a shielding function, as a result of which the signals transmitted by them are subject to electromagnetic interference from the peripheral environment. The plug connector according to the invention can, however, prevent electromagnetic influences on the peripheral environment.

brief description of the drawings

The drawings show the following.

Fig. 1 exploded perspective view of a plug connector according to the invention,

Fig. 2 is a sectional view of the contact of the plug connector according to the present invention,

Fig. 3 is a sectional view of the inner housing of the plug connector according to the present invention,

Fig. 4 is a sectional view of the outer housing and sliding element of the plug connector according to the present invention,

Fig. 5 is a perspective view of an assembled plug connector with cable according to the present invention,

Fig. 6 is a sectional view of the plug connector and cable after assembly, according to this invention,

Fig. 7 is a detailed perspective view of a mating plug according to the invention,

Fig. 8 is a sectional view of the contact of the mating plug according to this invention,

Fig. 9 is a sectional view of the inner housing of the mating plug according to the present invention,

Fig. 10 is a sectional view of the outer housing of the mating plug according to the present invention,

Fig. 11 is a perspective view of a mating plug with cable according to the present invention,

Fig. 12 is a schematic representation of the installation of a plug-in connector with a cable according to this invention,

Fig. 13 is a perspective view of the plug connector assembly with cable according to the present invention,

Fig. 14 is a sectional view of a plug connector assembly with a cable according to the present invention.

IMPLEMENTATION OF THE INVENTION

This invention is further explained in more detail on the examples of its implementation with the drawings. It should be pointed out that the exemplary embodiments discussed are only preferred embodiments and should not be considered as limiting the protection scope of the present invention. The average person skilled in the art, on the basis of the reasoning and the disclosed essence of the present invention, may realize various additional variations of the present invention, and they should be considered as falling within the protection scope of the present invention.

In addition, the terms "axial direction" and "input direction" in this invention have essentially the same meaning. However, it should be noted that the term "input direction" has directionality, while "axial direction" has no directionality. In the future, the direction of the signs "front" and "behind" is determined based on the input direction. If the plug and mating plugs according to the invention are inserted or inserted into each other and thus form a plug connector assembly, then when describing the plug connector and mating plug, the terms "front" and "rear" are not absolutely identical if the direction of insertion plug connector and mating plug are exactly opposite. This is obvious to a person skilled in the art. In addition, the terms "inside" and "outside" are defined based on the radial direction of the plug connector, the terms "inside", "inside", etc. refer to the direction passing along the radial direction and facing the center of the axis, and the terms "out", "outside", etc. refer to the direction passing along the radial direction and facing away from the center of the axis.

As shown in FIG. 1, a plug 1 according to the present invention comprises a substantially metallic contact 10, an inner housing 12, an outer housing 14, and a slider 16 which can slide over the outer housing 14.

As shown in FIG. 2, the general shape of contact 10 is essentially cylindrical, with this contact made of solid C1100 copper. Seen in the input direction, said contact comprises a contact input portion 100, a contact attachment portion 102, and a contact connection portion 104 arranged one behind the other. In this case, the inner diameter of the contact 10 in the contact insertion section 100 and in the contact attachment section 102 is smaller than the inner diameter in the contact connection section 104, and in the contact attachment section 102, a cable end surface 1022 facing away from the input direction is specified. At the junction between the contact attachment section 102 and the contact connection section 104, said contact 10 has a stop section 106 on the outer surface, the stop section 106 being an annular flange.

The contact insertion section 100 has, in its circumferential direction, a plurality of slits 1000 extending along the axial direction, which preferably extend to the contact attachment section 102. In addition, the outer surface of the contact entry portion 100 at the front end, as viewed from the insertion direction, has an external rounding in order to quickly and easily realize the insertion of the corresponding mating plug 2 into the contact 20.

Along the insertion direction, the contact 10 at the rear end of the contact insertion section 100 further has a recess 1004, this contact 10 at the front end of the contact attachment section 102 having a contact attachment recess 1020 for receiving a resilient fastener 108 made of rubber.

As shown in FIG. 3, said inner housing 12 of the plug connector 1 is an insulating housing having a substantially cylindrical overall shape and made in one piece of insulating material, preferably insulating rubber (EPDM and SR) or plastic (PPS). Seen in the insertion direction, the inner case comprises an inner case insertion portion 120, an inner case fixing portion 122, and an inner case connecting portion 124 arranged one behind the other. The outer diameter of the inner case mounting portion 122 is preferably the same as the outer diameter of the inner case insertion portion 120, while the inner diameter of the inner case mounting portion 122 is smaller than the inner diameter of the inner case insertion portion 120. Thus, an inwardly protruding protrusion is formed between the two of them, which has a blocking surface 1222 facing the insertion direction. Due to this blocking surface 1222, the contact can be protected from damage if too much insertion force is applied.

In addition, the inner diameter of the inner case fastening portion 122 is substantially the same as that of the contact fastening portion 102, while this inner case fastening portion has a stepped portion 1226 in order to connect the inner case fastening portion to the resilient fastener 108 of the contact 10 inserted into the fixing recess 1020 of this contact 10, so that the movement of the contact 10 against the input direction can be prevented. Compared to the inner case fastening portion 122, the inner diameter of the inner case connecting portion 124 is larger than the inner diameter of the inner case fastening portion 122, while its outer diameter is smaller than the outer diameter of the inner case fastening portion 122. Due to this, the limiting surface 1224 of the contact and the limiting surface 1220 of the inner case are respectively defined on the inner and outer sides of the insertion site.

As shown in FIG. 4, the outer housing 14 of the plug connector 1 is made of metal, which also has a substantially cylindrical overall shape. A groove 1401 is provided on the inner surface of its front end to accommodate the elastic retaining ring 144 and thereby the inner case 12 within the outer case 14. body with the bounding surface 1220 of the inner body 12 and thereby limit the movement of the inner body 12 against the direction of insertion.

The outer casing 14 has at its rear end an inwardly extending shield element receiving portion 1406 for receiving the shield element 146 in order to electromagnetically shield the connected high current cable 6.

Further, behind the shield member receiving portion 1406 on the outer case 14, a seal member receiving portion 1408 is disposed to accommodate the resilient seal member 148 on the inside. On the outer surface of the seal receptacle 1408, threads are provided on the outer housing to create a threaded connection with the fastener 18, also made of metal, so that the resilient seal member 148 is secured to the seal receptacle 1408.

On FIG. 5 is a perspective view of a plug connector according to the invention with a cable connected to it. During installation, the insulating outer layer at the front end of the cable 4 is removed for a length of approximately 30 mm, together with the EMC braid, to free the core inside. Then the fixing element 18 of the plug connector 1, the L-shaped sealing piston ring 17 and the sealing element 148, arranged one after the other according to the invention, are pushed onto the cable 4 against the input direction. Following this, the contact 10 is pushed onto the cable core 6 until it reaches the crimping position. Now the front end section of the cable core 6 is adjacent to the cable end surface 1022 of the connecting section 102 of the contacts 10. At the crimping position, the connection section 104 of the contact 10 is squeezed with a crimping tool, so that the inner surface of the connection section 104 of the contact is firmly adjacent to the cable core 4.

At the same time or before or after this, the inner housing of the plug connector 1 according to the present invention is inserted into the outer housing 14. Namely, the inner housing 12 is inserted into the outer housing 14 against the input direction until the limiting surface 1220 of the inner housing 12 and the limiting protrusion 1402 of the outer housing 14 will not be adjacent to each other. Now inserted into the groove 1401 of the outer housing 14, the elastic retaining ring 144 jumps inward to restrict the forward movement of the inner housing 12 along the insertion direction. Thus, the inner housing 12 of the plug connector 1 is firmly fixed in the outer housing 14.

The contact 10 is inserted into the inner housing 12, on which the outer housing 14 is already mounted, until a "click" sound is heard, which indicates that the contact 10 has reached the locked position in the inner housing 12. In the locked position, the thrust section 106 of the contact 10 and the limiting surface 1224 of the contact of the inner housing 12 are adjacent to each other to prevent further forward movement of the contact 10, while the elastic fastener 108 located in the fastening recess 1020 of the contact pops out radially outward and covers the stepped section 1226 of the inner body 12 to prevent the return movement of contact 10.

When the sealing element 148 is pushed along the direction of insertion into the inside of the sealing element receiving portion 1408 of the outer housing 14, the fastener 18 is threadedly connected to the outer housing 14. In this case, the fastener 18 advances the L-shaped sealing piston ring 17 forward, so that through the surface of the L-shaped sealing piston ring 17, the sealing element 148 is evenly subjected to a tangential force (see Fig. 6), so that the sealing element 148 is compressed along the axial direction to create an expansion along the radial direction. In this way, intimate contact is made with the outer surface of the cable 4, whereby a good sealing effect is obtained. Following this, the fixing screw is tightened to securely fasten the cable 4 to the plug 1.

On FIG. 6 shows a sectional view of the plug connector 1 and cable 4 after assembly. From FIG. 6, it is clear that contact 2 is connected by means of an elastic fastening element 108 placed in the recess 1020, the contact and the stop section 106, respectively, are connected to the stepped section 1226 and the limiting contact surface 1224 on the inner side of the inner casing 12 and, thereby, are fixed in the intended position of the inner casing 12, wherein said contact cannot move forward or backward in the axial direction due to mating due to contact with the inner housing. By means of the limiting surface 1220 and the front end surface of the inner casing, the inner casing 12 fits, respectively, to the delimiting ledge 1402 of the outer casing 14 and the elastic retaining ring 144 located in the groove 1401, and thereby is fixed at the intended position of the outer casing 14, and the inner casing due to the interface between the inner case and the outer case cannot move forward or backward in the axial direction.

In addition, as the shield member 146 placed in the shield member receiving portion 1406 of the outer case 14, an annular spring whose inner shape is formed as an inverted triangle is provided. From this sectional view, it is clear that the shielding element 146 on the inside has the shape of a peak, with an inner diameter slightly smaller than the outer diameter of the insulating outer layer of the cable 6. When connecting the cable 4 and the contact 10, when it is inserted into the inner housing 12 and the outer housing 14, the shielding element 146 placed in the receiving portion 1406 for the shielding element of the outer housing 14, when the cable 4 is inserted, is inclined along the input direction, and the top on the inside of the shielding element passes through the insulating outer layer of the cable 4 and touches the EMC braid layer in the insulating outer layer of the cable, namely the electromagnetic shielding layer, so that the electromagnetic field generated by the transmission of a large alternating current cannot be transmitted to the outside. This improves the electromagnetic shielding of the cable 4.

On FIG. 7 shows a mating plug 2 intended for said plug 1. This mating plug 2 also basically comprises a pin 20, an inner housing 22 and an outer housing 24.

As shown in FIG. 8, the general shape of contact 20 is substantially cylindrical, with the contact made of solid C1100 copper. In contrast to the plug 1, said contact, when viewed in the insertion direction, only has a contact insertion section 200 and a contact connection section 202 arranged one behind the other. In this case, the inner diameter of the contact 20 at the contact insertion portion 200 is essentially the same as the inner diameter at the contact connection portion 202 . In addition, the contact insertion portion 200 is also used as a contact attachment portion and, on the outer surface of the rear end, protrudes along the radial direction outward to form an annular flange, namely the abutment portion 206. The contact insertion portion 200 at the front end has an internal rounding 2002 to facilitate alignment with the outer rounding of the contact 10 of the respective plug connector 1, so that insertion can be carried out quickly and easily. Along the insertion direction, the contact 20 at the front end of the contact insertion portion 200 has a contact attachment recess 2004 for receiving a rubber-made resilient fastener 204.

As shown in FIG. 9, the inner housing 22 of the mating plug 2 is an insulating housing having a substantially cylindrical overall shape and formed in one piece from an insulating material, preferably insulating rubber (EPDM and SR) or plastic (PPS). Seen in the input direction, the inner case comprises an inner case insertion portion 220 and a fastening portion 222 of the inner case located one behind the other. The outer diameter of the fastening portion 222 of the inner casing is preferably larger than the outer diameter of the insertion portion 220 of the inner casing. Preferably, the insertion portion 220 of the inner case is also used as a fastening contact. To this end, the middle region of the insertion section 220 of the inner casing has an annular attachment section 2202 bent inwardly. .

As shown in FIG. 10, the outer housing 24 of the mating plug 2 is made of a conductive metal, preferably nickel-plated aluminum, the outer housing also having a substantially cylindrical overall shape.

The outer casing 24 has at its rear end an inwardly extending shield element receiving portion 2406 for receiving a shield element 146 to provide electromagnetic shielding for the connected high current cable 6. Said shield element 246 is made of metal and has the shape of an inverted triangle. Its outer side is in contact with the outer housing 24 to create a conductive connection, so that improved electromagnetic shielding of the cable is provided.

In addition, the outer casing 24, in its insertion portion for the outer casing 14 of the plug connector 1, along the insertion direction from front to back, has a recess 2402 for receiving a locking device, a receiving portion 2406 for a shielding element, and a receiving portion 2408 for a sealing element arranged one after the other, to accommodate blocking device 242, shielding element 246 and sealing element 248, respectively. In the present invention, in the case of the locking device 242, we are preferably talking about a plurality of locking bumps, and the recess 2402 is understood to mean several through holes extending along the radial direction through the outer casing 24, and the shielding element 246 placed in the receiving section 2406 for the shielding element is ring spring washer.

In addition, on the outer surface of the seal receptacle 2408, threads are provided on the outer housing 24 to form a threaded connection with the fastener 28, also made of metal, so that the elastic sealing element 50 is fixed in the seal receptacle 2408.

On FIG. 11 shows a perspective view of a mounted mating plug 2 according to the invention with a cable 6 connected. When mounting a mating plug 2 with a cable, this cable 6 is firmly attached to the mating plug 2 without the final step of tightening the screw. The reason is that the mating plug 2 is usually fixed in the appliance, so there is no pull force generated by pulling out the cable 6.

Of course, in one optional solution, a bolted fastening device can also be located on the fastening element 28 of the outer housing 24 of the mating plug 2, as in the outer housing 14 of the plug connector 1.

On FIG. 12 illustrates a sectional view of the mating plug 2 and cable 6 after assembly. From FIG. 12 it can be seen that the contact 20 is connected by means of the contact of the elastic fastening element 204 and the stop section 206 placed in the fastening recess 2004 to the stepped section 2204 and the limiting surface 2206 of the contact on the inner side of the inner casing 22, and is thus fixed to the corresponding position of the inner casing 22 , and due to the interface between the contact and the inner housing, the specified contact cannot move in the axial direction back and forth. The inner casing 22 is connected to the bead 2410 of the outer casing 24 by means of the bounding surface 2220 of the inner casing, and is thereby secured to the intended position of the outer casing 24, and due to the mating between the inner casing and the outer casing, the inner casing cannot move back in the axial direction. In addition, as the shield member 246 provided in the shield member receiving portion 2406 of the outer case 24, an annular spring whose inner shape is formed as an inverted triangle is provided. From this sectional view, it is clear that the shielding element on the inside is formed in the shape of a pin, its inner diameter being slightly smaller than the outer diameter of the insulating outer layer of the cable 6. When connecting the cable 6 and the contact 20, when it is inserted into the inner housing 22 and the outer casing 24, the shielding element 246, located in the receiving area 2406 for the shielding element of the outer casing 24, when the cable 6 is inserted, is inclined along the input direction, and the top on the inner side of the shielding element penetrates the insulating outer layer of the cable 6 and contacts the EMC braid layer in the insulating outer layer of the cable, namely the electromagnetic shielding layer. This improves the electromagnetic shielding of the cable 6.

On FIG. 13 and FIG. 14 illustrates a plug connector assembly, this plug connector 1 being inserted into a mating plug 2. When plug connector 1 is connected to a mating plug 2, they are first oriented relative to each other and inserted into each other. The outer housing 24 of the mating plug 2 shifts the sliding element 16 on the outer housing 14 of the plug connector back, the spring in it is compressed until the locking device 242 on the outer housing 24 of the mating plug 2 snaps into the groove 1401 provided on the outer housing 14 of the plug connector 1 In particular, in the sectional view of FIG. 14 it is clear that located in the recess 2402 of the outer housing 24, the locking device 242 of the mating plug 2 at the insertion position is connected to the slot 1401 of the outer housing 14 of the plug connector 1. Said insertion produces a "click" sound to indicate to the user that the correct insertion position has been reached. , and to prevent the user from exerting extra effort. As a result, the contact 10 of the plug connector 1 and the contact 20 of the mating plug 2 are protected to a certain extent from being damaged if too much insertion force is applied. In addition, the plug connector 1 and the mating plug 2 are prevented from being disconnected within a certain pull force range, so as to avoid deterioration in the quality of the current transmission.

In addition, from the sectional view of FIG. 14 it is clear that the shielding element 146 located at the rear end of the outer housing 14 of the plug connector 1 passes through the outer insulating layer of the cable 4 and creates a conductive connection with the EMC braid layer inside, namely with the electromagnetic shielding layer for additional electromagnetic shielding of the cable 4. Located at the rear at the end of the outer housing 24 of the mating plug 2, the shielding element 246 passes through the outer insulating layer of the cable 6 and creates a conductive connection with the EMC braid layer inside, namely with the electromagnetic shielding layer for additional electromagnetic shielding of the cable 6. In addition, placed in the outer housing 24 of the mating plug 2, the shielding ring 250 contacts the front end of the outer housing 14 of the plug connector 1. Because the shielding element 146 is conductively connected to the metallic outer housing 14 of the plug connector 1, the shielding element 246 is conductively connected. metal outer housing 24 of the mating plug 2, and the shielding ring 250 is conductively connected to the metal outer housing 14 of the male connector 1 and to the metal outer housing 24 of the mating plug 2, the electromagnetic shielding of the cables 4 and 6 is improved, so that when high currents are only reduced electromagnetic influence on electronic components present in the peripheral environment, such as printed circuit boards, etc. The plug connector assembly with plug and mating plug according to the present invention has been explained in more detail above. However, the detailed embodiments are merely preferred embodiments, and the structure of the plug connector assembly does not limit the invention. A person skilled in the art, based on the embodiments of the present invention, can accordingly modify the specific structure of the plug connector and mating plug.

For example, such detailed structures of the inner housing, the outer housing of the plug connector and mating plug and the plug connection section or the contact holding section can be interchanged as long as the fit between them guarantees the respective function.

List of reference positions

1 plug connector

10 contact

100 contact input area

1000 slot

1002 outer rounding

1004 recess

102 contact attachment area

1020 mounting recess

1022 cable end face

104 contact connection section

106 thrust area

108 elastic fastener contact

12 inner case

120 entry area of the inner body

122 fixing section of the inner case

1220 fixing surface of the inner case

1222 blocking surface

1224 limiting contact surface

1226 stepped section

124 connecting section of the inner case

14 outer case

1401 groove

1402 limiting ledge

1404 locking groove

1406 shield element receptacle

1408 sealing element receptacle

144 elastic retaining ring

146 shielding element

148 sealing element

16 sliding element

17 L-shaped sealing piston ring

18 fastener

2 mating plug

20 contact

200 contact input area

2002 internal rounding

2004 fastening recess

202 contact connection section

204 elastic fastener

206 thrust area

22 inner case

220 inner body entry area

2202 annular mounting section

2204 stepped section

222 fixing section of the inner case

2220 inner case fixing surface

24 outer casing

2402 recess

2406 shield element receptacle

2408 sealing element receptacle

242 blocking device

246 shielding element

248 sealing element

250 shielding

28 fastener

4 cable

6 cable

Claims (25)

1. Plug connector (1) for the electrically conductive connection of the electrical cable (4) connected to it with a mating plug (2), containing - at least one electrically conductive contact (10); - an insulating inner case (12) having a fastening section (122) for fixing the contact (10); - a conductive outer case (14) having a fastening section for fixing the inner case (12); characterized in that this plug-in connector (1) also contains a first shielding element (146) electrically connected to the conductive outer casing (14), which can penetrate the insulating outer layer of the cable (4) connected via the plug-in connector and creates electrical contact with the electromagnetic shielding layer in the insulating outer layer of the cable (4) providing an additional electromagnetic shielding function for the cable (4), moreover, this plug connector (1) contains a second shielding element (250) placed in the conductive outer casing (14), which can be in electrical contact with the conductive outer casing (14) of this plug connector (1) and the conductive outer housing of the mating plug (2) connected to this plug connector (1), providing an additional electromagnetic shielding function for the cable (4). 2. Plug connector (1) according to claim 1, characterized in that the first shielding element (146) is in the form of an inverted triangle, one side of which is in conductive contact with the conductive outer housing (14), while the lower vertex is in electrical contact with the electromagnetic shielding layer of the cable (4). 3. Plug connector (1) according to claim 1, characterized in that the first shielding element (146) is made of metal, in particular copper, steel, aluminum or brass, or at least one of these materials. 4. Plug connector (1) according to claim 3, characterized in that the metal is an aluminum alloy whose surface is chemically nickel-plated. 5. Plug connector (1) according to claim 1, characterized in that the second shielding element is an annular spring washer (250), which is in peripheral contact with the conductive outer housing (14) of the plug connector (1) and with the conductive outer housing (24) mating plug (2). 6. Plug connector (1) according to claim 1, characterized in that in the case of the first shielding element (146) and/or in the case of the second shielding element (250) we are talking about a round spring, a triangular flat spring, a multilamella and/or that the first shielding element and/or the second shielding element has brush contacts. 7. Plug connector (1) according to any one of paragraphs. 5, 6, characterized in that the second shielding element (250) is made of stainless metal, in particular copper, steel, aluminum or brass. 8. Plug connector (1) according to claim 1, characterized in that this plug connector (1) contains an insulating sealing element (148) placed in a conductive outer casing (14), which is engaged with the outer insulating layer of the cable (4) providing a waterproof seal. 9. Plug connector (1) according to claim 8, characterized in that this plug connector (1) contains an L-shaped compression element (17) for simultaneous transmission of tangential force to the sealing element due to the connection between the fastening element (18) of the plug connector (1) and a conductive outer casing (14), so that the sealing element (148) creates a radial expansion and thus forms a strong sealing interface with the cable (4). 10. Plug connector (1) according to claim 1, characterized in that the conductive outer housing (14) is made of metal. 11. Plug-in connector (1) according to claim 10, characterized in that, in the case of metal, this is an electroless nickel-plated aluminum element. 12. Node plug connector containing plug connector (1) according to any one of paragraphs. 1-11 and the mating plug (2) associated with this plug connector (1), where the mating plug (2) contains - conductive contact (20); - an insulating inner case (22) having a fastening section (222) for fixing the contact (20); - a conductive outer case (24) having a fastening section for fixing the inner case (22); characterized in that The mating plug (2) also contains a third shielding element (246) conductively connected to the conductive outer casing (24), which can penetrate through the insulating outer layer of the cable (6) connected to the mating plug (2) and creates an electrical contact with the electromagnetic shielding layer. in the insulating outer layer of the cable (6) providing an additional electromagnetic shielding function for the cable (6), wherein the first shielding element (146), the second shielding element (250) and the third shielding element (246) form, respectively, electrical contact with the outer casing (14 ) of the plug connector (1) and the outer housing (24) of the mating plug (2) providing complete electromagnetic shielding for the cable (4) connected via the plug connector (1) and connected to the mating plug (2) of the cable (6), and for connector assembly. 13. Plug connector assembly according to claim 12, characterized in that the third shielding element (246) is formed in the form of an inverted triangle, the upper side of which is in conductive contact with the conductive outer housing (24) of the mating plug (2), while the lower top is in electrical contact with the electromagnetic shielding layer of the cable (4). 14. Plug connector assembly according to claim 13, characterized in that the third shielding element (246) is made of metal. 15. Plug connector assembly according to claim 14, characterized in that the third shielding element (246) is made of stainless metal.

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