DE102017003161A1 - Plug-in device, method and use - Google Patents

Abstract

The invention relates to a plug-in coupling device for receiving a first RJ connector at a first end and a second RJ connector at a second end, comprising data coupling means for connecting a plurality of data conductors of the first RJ connector to a plurality of data conductors of the second RJ connector; and a power coupling means for connecting a plurality of power conductors of the first RJ connector to a plurality of power conductors of the second RJ connector, wherein the data coupling means and the power coupling means are electrically separated from each other. The invention further relates to a method for producing a coupling between a first RJ connector and a second RJ connector and a use of the plug-in coupling device for coupling a first RJ connector with a second RJ connector.

Description

The invention relates to a plug-in coupling device for coupling a first RJ connector with a second RJ connector, a method for producing a coupling between a first RJ connector and a second RJ connector, and a use of a plug-in coupling device for coupling a first RJ connector with a second RJ connector.

The field of the invention lies in the field of data link technology, in particular in the field of data link coupling technology, and in particular in the field of the coupling of current and data-conducting RJ connectors. Many modern electronic devices can be equipped with data transmission cables for transmission of e.g. Usage data are connected. Such devices therefore often require a power connection and a data connection, making a common power and data cable an efficient supply solution. Especially in the field of twisted-pair cables with RJ connectors, this has already been implemented through Power-over-Ethernet protocols. This data conductors are used for power transmission, whereby the maximum transferable power is limited. Twisted-pair cables with separate conductors require special RJ connectors, which have separate data contacts and power contacts. However, such special RJ connectors can not be coupled together with conventional RJ connector couplings.

Therefore, it is the object of the invention to provide a plug-in device for RJ connector, which can couple two RJ connectors with separate conductors and data conductors together.

One aspect of the invention relates to a plug-in device for receiving a first RJ connector at a first end and a second RJ connector at a second end, comprising data coupling means for connecting a plurality of data conductors of the first RJ connector to a plurality of data conductors the second RJ connector and a power coupling means for connecting a plurality of power conductors of the first RJ connector with a plurality of power conductors of the second RJ connector, wherein the data coupling means and the power coupling means are electrically separated from each other.

Here, the first and second connectors may be any family member of the RJ connector category, with the first and second RJ connectors preferably belonging to the same RJ connector category. In particular, the first RJ connector may be received along the first connection direction at the first end and the second RJ connector may be received along the second connection direction at the second end. In this case, the first and the second connecting direction preferably run parallel to one another. However, it is also possible that the first and second connection directions are not parallel to each other, thereby enabling an angled plug-in coupling device.

The data coupling device is designed to transmit a data stream of the first RJ connector to the second RJ connector and vice versa. For this, the data coupling means may comprise at the first end a first data contact element for each of the plurality of data conductors of the first RJ connector, each first data contact element being adapted to contact exactly one associated data conductor of the first RJ connector. The data coupling means may also have at the second end a second data contact element for each of the plurality of data conductors of the second RJ connector, each second data contact element being adapted to contact exactly one associated data conductor of the second RJ connector. The data coupling device is further configured to cross connect each of the first data contact elements to a second data contact element, thereby enabling transmission of the data stream from the first RJ connector to the second RJ connector and vice versa. "Crossed" in this sense means that in a planar circuit diagram of the data coupling device each imaginary line connecting a first data contact element and the associated second data contact element, each further imaginary line, each connecting a further first data contact element with the correspondingly associated second data contact element , crosses. In particular, crossed contacts of the cross-cable technology are known to the person skilled in the art, whereby in the case of the first data contact elements or the second data contact elements, certain data contact elements or contact leads are interchanged in a known manner.

The power coupling device is configured to transmit a current for operating an electrical device from the first RJ connector to the second RJ connector and vice versa. For this purpose, each of the first RJ connector and the second RJ connector separate power conductors for conducting the current, the are formed separately from the data conductors. The power coupling device may include at the first end a first power contact element for each of the plurality of power conductors of the first RJ connector, each first power contact element configured to contact exactly one associated power conductor of the first RJ connector. The power coupling device may also have at the second end a second power contact element for each of the plurality of power conductors of the second RJ connector, each second power contact element configured to contact exactly one associated power conductor of the second RJ connector. The power coupling device is further configured to connect each of the first power contact elements crossed to a respective second power contact element, thereby enabling transmission of power from the first RJ connector to the second RJ connector and vice versa. "Crossed" in this sense means that in a planar circuit diagram of the power coupling device, each imaginary line connecting a first power contact element and the associated second power contact element connects each further imaginary line each connecting a further first power contact element to the correspondingly associated second power contact element , crosses. In particular, crossed contacts of cross-cable technology are known to the person skilled in the art, with the first power contact elements or the second power contact elements interchanging certain power contact elements or line wires in a known manner.

The data coupling device and the power coupling device are in this case formed electrically separated from each other. In particular, the power contact elements and the data contact elements are formed separately at each of the first and the second end, so that a data transmission via the data coupling device without operation of the power coupling device and vice versa is possible. The separate formation of the data coupling device and the power coupling device makes it possible to operate electrical devices efficiently, which obtain their data and their current via an RJ plug connector. In addition, it is also possible to couple together RJ plug connectors without separate power conductors, since the data coupling device can transmit the data stream even without operation of the power coupling device.

In a preferred embodiment, the power coupling device of the plug-in device comprises at least two, preferably exactly two, first power contact elements at the first end for making electrical contact with the first RJ connector and at least two, preferably exactly two, second power contact elements at the second end Making an electrical contact with the second RJ connector. The at least two first power contact elements may in this case be arranged on an opposite side of the first end with respect to the first data contact elements. This means that the first data contact elements are arranged on a first or lower side of the first end, while the first power contact elements are arranged on a second or upper side of the first end, wherein the first side of the first end of the second side of the first end opposite. The at least two second power contact elements may be disposed on an opposite side of the second end with respect to the second data contact elements. This means that the second data contact elements are arranged on a first or lower side of the second end, while the second power contact elements are arranged on a second or upper side of the second end, wherein the first side of the second end of the second side of the second end opposite. By such an arrangement, a possible crosstalk or a possible interference between power contact elements and data contact elements can be prevented or reduced. The first side of the first end and the first side of the second end may in this case be formed on a same side of the plug-in coupling device.

In a further embodiment, the power coupling device is further configured to transmit at least 48 V DC or AC a power of at least 95W, preferably at least 110W, more preferably at least 145W and / or at most 200W, preferably at most 170W, more preferably at most 150W , The power coupling device may further be designed to transmit at least 48 V DC or AC a current of at least 2A, preferably at least 2.5A, more preferably at least 3A and / or at most 10A, preferably at most 5A, more preferably at most 4A.

In another embodiment, the data coupler of the plug-in device connects the plurality of data conductors of the first RJ connector to the plurality of data conductors of the second RJ connector, the data coupler having data contact elements at the first end for establishing a data connection with the first one Cross-connect RJ connector with data contact elements at the second end for establishing a data connection with the second RJ connector.

In another embodiment, the power coupling means connects the plug-in coupling device to the plurality of power conductors of the first RJ connector crossed to the plurality of power conductors of the second RJ connector, the power coupling means comprising power contact elements at the first end for making electrical contact with the first end first RJ connector crossed with power contact elements at the second end for making an electrical contact with the second RJ connector connects.

In a further embodiment, the data coupling device and the power coupling device of the plug-in coupling device are at least partially formed on a printed circuit board. The printed circuit board can in particular be designed as a PCB (printed circuit board) or as a flex PCB (flexible PCB). In this case, the printed circuit board may in particular be designed to be connected to the first and second data contact elements and power contact elements. In addition, the printed circuit board may be formed to cross-connect the first and second data contact elements and / or to cross-connect the first and second power contact elements. Such a printed circuit board enables a simple and cost-effective construction of the plug-in coupling device. In an alternative embodiment, the data coupling device is at least partially formed on a first printed circuit board and the power coupling device is at least partially formed on a second printed circuit board. The first printed circuit board may in this case be designed, in particular, to be connected to the first and second data contact elements. In addition, the first printed circuit board may be formed to cross-connect the first and second data contact elements. In this case, the second printed circuit board may in particular be designed to be connected to the first and second power contact elements. In addition, the second printed circuit board may be formed to cross-connect the first and second power contact elements. By such a construction on two separate printed circuit boards, a modular manufacturing of the plug-in coupling device can be made possible and furthermore a possible crosstalk or a possible interference between the data coupling device and the power coupling device can be prevented or reduced.

In a further embodiment, the plug-in coupling device is designed to be Power-over-Ethernet-compatible. For this purpose, the data-coupling device is designed to transmit an operating current for an electrical device and thus partially to take over the function of the power coupling device. This makes it possible to additionally supply devices with electric current, which draw their power via Power-over-Ethernet. For this purpose, the data coupling device is designed to be at least IEEE 802.3bt compatible. In a further embodiment, the data coupling device is designed to have a current of at least 2 A, preferably at least 3 A, most preferably at least 3.75 A and at most 10 A, preferably at most 5 A, most preferably at most 4 A in each case at least 45 V DC or 30 V AC, preferably 75 V DC or 50 V AC and a maximum of 150 V DC or 100 V AC, preferably a maximum of 90 V DC or 60 V AC to transmit.

In another embodiment, the plug-in coupling device is configured to couple a first RJ-45 connector and a second RJ-45 connector. In particular, the male coupling device is configured to couple the first RJ-45 connector and the second RJ-45 connector when the first RJ-45 connector and the second RJ-45 connector are each formed with or without separate power conductors.

In a further embodiment, the plug-in coupling device further comprises a housing, wherein the housing comprises two substantially equal-part housing shells and the housing at least partially surrounds the plug-in coupling device. "Essentially" means in this sense comprehensively small, production-related deviations. By a gleichleicheilige training of the two housing shells a simplified and cost-effective manufacturing process of the housing is made possible. The housing shells can furthermore be designed to engage with one another in an operating state of the housing shells, in which the two housing shells at least partially surround the plug-in coupling device, in order to block mutual slipping of the two housing shells. The two housing shells may also be designed to engage in the operating state with the plug-in coupling device, so that a relative slippage between the plug-in device and the housing shell is blocked. The two housing shells may further comprise at least one latching mechanism, which is designed to lock with the plug-in coupling device in the operating state of the housing shells, as defined above, and thus releasably secure the housing shells to the plug-in coupling device. Thus, a secure fit of the housing is ensured on the plug-in device. The housing can protect the plug-in coupling device from damage and external influences, and electrically isolate the plug-in coupling device to the outside.

In a further embodiment, the plug-in coupling device further comprises a Shield element which surrounds the plug-in device at least partially and substantially shields from external electromagnetic fields. The shield element may in this case consist of a metal or conductive plastic or material, whereby the shield element surrounds the plug-in coupling device as a Faraday cage and thus shields it to the outside. The shielding element may be formed in several pieces and at least partially surround the housing. In this case, the screen element can engage the housing and / or the plug-in coupling device in an operating state of the screen element in which the screen element at least partially surrounds the plug-in coupling device, in order to block the screen element from slipping relative to the plug-in coupling device. In a preferred embodiment, the housing is also designed as a shielding element, and thus a separate shielding element need not be provided, whereby the manufacturing process of the plug-in coupling device is simplified.

In a further embodiment, the plug-in coupling device further comprises a latching device, which is designed to fasten the plug-in coupling device to a complementary latching mechanism of an external fastening frame. The latching device may be formed in particular on the housing and / or the shielding element. The external mounting frame can here be any object to which the plug-in coupling device is to be attached, such as e.g. a frame, a table box or a control box or control cabinet. The latching device is not limited to a latching mechanism, but can be realized by any attachment method, such as e.g. Gluing, clamping, screwing, pressing or any other friction fit.

Another aspect relates to a method of making a coupling between a first RJ connector and a second RJ connector, comprising providing a male coupling device for receiving the first RJ connector at a first end and the second RJ connector at a second end, wherein the plug-in coupling device comprises data coupling means for connecting a plurality of data conductors of the first RJ connector to a plurality of data conductors of the second RJ connector and a power coupling means for connecting a plurality of power conductors of the first RJ connector to a plurality of power conductors of the second RJ connector, wherein the data coupling means and the power coupling means are electrically separated from each other. The method further includes receiving the first RJ connector at the first end and receiving the second RJ connector at the second end.

Here, the first and second connectors may be any family member of the RJ connector category, with the first and second RJ connectors preferably belonging to the same RJ connector category. In particular, the first RJ connector may be received along the first connection direction at the first end and the second RJ connector may be received along the second connection direction at the second end. In this case, the first connection direction and the second connection direction preferably run parallel to one another. However, it is also possible that the first and second connection directions are not parallel to each other, thereby enabling an angled plug-in coupling device.

The data coupling device is designed to transmit a data stream of the first RJ connector to the second RJ connector and vice versa. For this, the data coupling means may comprise at the first end a first data contact element for each of the plurality of data conductors of the first RJ connector, each first data contact element being adapted to contact exactly one associated data conductor of the first RJ connector. The data coupling means may also have at the second end a second data contact element for each of the plurality of data conductors of the second RJ connector, each second data contact element being adapted to contact exactly one associated data conductor of the second RJ connector. The data coupling means is further arranged to cross-connect each of the first data contact elements to a respective one of the wide data contact elements, thereby enabling transmission of the data stream from the first RJ connector to the second RJ connector and vice versa. "Crossed" in this sense means that in a planar circuit diagram of the data coupling device each imaginary line connecting a first data contact element and the associated second data contact element, each further imaginary line, each connecting a further first data contact element with the correspondingly associated second data contact element , crosses. In particular, crossed contacts of the cross-cable technology are known to the person skilled in the art, whereby in the case of the first data contact elements or the second data contact elements, certain data contact elements or contact leads are interchanged in a known manner.

The power coupling device is designed to generate a current for operating an electric power Device from the first RJ connector to the second RJ connector and vice versa. For this purpose, each of the first RJ connector and the second RJ connector separate power conductors for conducting the current, which are formed separately from the data conductors. The power coupling device may include at the first end a first power contact element for each of the plurality of power conductors of the first RJ connector, each first power contact element configured to contact exactly one associated power conductor of the first RJ connector. The power coupling device may also have at the second end a second power contact element for each of the plurality of power conductors of the second RJ connector, each second power contact element configured to contact exactly one associated power conductor of the second RJ connector. The power coupling device is further configured to connect each of the first power contact elements crossed to a respective second power contact element, thereby allowing current to be transferred from the first RJ connector to the second RJ connector and vice versa. "Crossed" in this sense means that in a planar circuit diagram of the power coupling device, each imaginary line connecting a first power contact element and the associated second power contact element connects each further imaginary line each connecting a further first power contact element to the correspondingly associated second power contact element , crosses. In particular, crossed contacts of the cross-cable technology are known to the person skilled in the art, whereby in the case of the first power contact elements or the second power contact elements certain power contact elements or power wires are interchanged in a known manner.

The data coupling device and the power coupling device are in this case formed electrically separated from each other. In particular, the power contact elements and the data contact elements are formed separately at each of the first and the second end, so that a data transmission via the data coupling device without operation of the power coupling device and vice versa is possible. The separate formation of the data coupling device and the power coupling device makes it possible to operate electrical devices efficiently, which obtain their data and their current via an RJ plug connector. In addition, it is also possible to couple together RJ plug connectors without separate power conductors, since the data coupling device can transmit the data stream even without operation of the power coupling device.

In a preferred embodiment, the method includes establishing electrical contact of the male coupling device with the first RJ connector and establishing electrical contact of the male coupling device with the second RJ connector. Here, the power coupling device of the plug-in device comprises at least two, preferably exactly two, first power contact elements at the first end for making electrical contact with the first RJ connector and at least two, preferably exactly two, second power contact elements at the second end for producing an electrical Contact with the second RJ connector. The at least two first power contact elements may in this case be arranged on an opposite side of the first end with respect to the first data contact elements. This means that the first data contact elements are arranged on a first or lower side of the first end, while the first power contact elements are arranged on a second or upper side of the first end, wherein the first side of the first end of the second side of the first end opposite. The at least two second power contact elements may be disposed on an opposite side of the second end with respect to the second data contact elements. This means that the second data contact elements are arranged on a first or lower side of the second end, while the second power contact elements are arranged on a second or upper side of the second end, wherein the first side of the second end of the second side of the second end opposite. By such an arrangement, a possible crosstalk or a possible interference between power contact elements and data contact elements can be prevented or reduced. The first side of the first end and the first side of the second end may in this case be formed on a same side of the plug-in coupling device.

In a further embodiment, the data coupling means of the plug-in coupling device connects the plurality of data conductors of the first RJ connector crossed to the plurality of data conductors of the second RJ connector.

In another embodiment, the power coupling means connects the plug-in coupling device to connect the plurality of power conductors of the first RJ connector with the plurality of power conductors of the second RJ connector.

In a further embodiment, the data coupling device and the power coupling device of the plug-in coupling device at least partially formed on a printed circuit board. The printed circuit board can in particular be designed as a PCB (printed circuit board) or as a flex PCB (flexible PCB). In this case, the printed circuit board may in particular be designed to be connected to the first and second data contact elements and power contact elements. In addition, the printed circuit board may be formed to cross-connect the first and second data contact elements and / or to cross-connect the first and second power contact elements. Such a printed circuit board enables a simple and cost-effective construction of the plug-in coupling device. In an alternative embodiment, the data coupling device is at least partially formed on a first printed circuit board and the power coupling device is at least partially formed on a second printed circuit board. The first printed circuit board may in this case be designed, in particular, to be connected to the first and second data contact elements. In addition, the first printed circuit board may be formed to cross-connect the first and second data contact elements. In this case, the second printed circuit board may in particular be designed to be connected to the first and second power contact elements. In addition, the second printed circuit board may be formed to cross-connect the first and second power contact elements. By such a construction on two separate printed circuit boards, a modular manufacturing of the plug-in coupling device can be made possible and furthermore a possible crosstalk or a possible interference between the data coupling device and the power coupling device can be prevented or reduced.

In a further embodiment, the plug-in coupling device is designed to be Power-over-Ethernet-compatible. For this purpose, the data-coupling device is designed to transmit an operating current for an electrical device and thus partially to take over the function of the power coupling device. This makes it possible to additionally supply devices with electric current, which draw their power via Power-over-Ethernet. For this purpose, the data coupling device is designed to be at least IEEE 802.3bt compatible. In a further embodiment, the data coupling device is designed to have a current of at least 2 A, preferably at least 3 A, most preferably at least 3.75 A and at most 10 A, preferably at most 5 A, most preferably at most 4 A in each case at least 45 V DC or 30 V AC, preferably 75 V DC or 50 V AC and a maximum of 150 V DC or 100 V AC, preferably a maximum of 90 V DC or 60 V AC to transmit.

In another embodiment, the plug-in coupling device is configured to couple a first RJ-45 connector and a second RJ-45 connector. In particular, the male coupling device is configured to couple the first RJ-45 connector and the second RJ-45 connector when the first RJ-45 connector and the second RJ-45 connector are each formed with or without separate power conductors.

In a further embodiment, the plug-in coupling device further comprises a housing, wherein the housing comprises two substantially equal-part housing shells and the housing at least partially surrounds the plug-in coupling device. "Essentially" means in this sense comprehensively small, production-related deviations. By a gleichleicheilige training of the two housing shells a simplified and cost-effective manufacturing process of the housing is made possible. The housing shells can furthermore be designed to engage with one another in an operating state of the housing shells, in which the two housing shells at least partially surround the plug-in coupling device, in order to block mutual slipping of the two housing shells. The two housing shells may also be designed to engage the plug-in coupling device in the operating state of the housing shells as defined above, so that relative slippage between the plug-in coupling device and the housing shell is blocked. The two housing shells may further comprise at least one latching mechanism which is designed to lock with the plug-in coupling device in the operating state and thus releasably secure the housing shells to the plug-in coupling device. Thus, a secure fit of the housing is ensured on the plug-in device. The housing can protect the plug-in coupling device from damage and external influences, and electrically isolate the plug-in coupling device to the outside.

In a further embodiment, the plug-in coupling device further comprises a shield element which at least partially surrounds the plug-in coupling device and shields from external electromagnetic fields. The shield element may in this case consist of a metal or conductive plastic or material, whereby the shield element surrounds the plug-in coupling device as a Faraday cage and thus shields it to the outside. The shielding element may be formed in several pieces and at least partially surround the housing. In this case, the shielding element can engage the housing and / or the plug-in coupling device in an operating state of the shielding element in which the shielding element at least partially surrounds the plug-in coupling device in order to prevent the shielding element from slipping relative to the plug-in coupling device To block. In a preferred embodiment, the housing is also designed as a shielding element, and thus a separate shielding element need not be provided, whereby the manufacturing process of the plug-in coupling device is simplified.

In a further embodiment, the method further comprises attaching the plug-in coupling device to a complementary latching mechanism of a mounting frame. For this purpose, the plug-in coupling device further comprises a latching device, which is designed to fasten the plug-in coupling device to the complementary latching mechanism of the fastening frame. The latching device may be formed in particular on the housing and / or the shielding element. The mounting frame may in this case be any object to which the plug-in coupling device is to be attached, such as e.g. a frame, a table box or a control box or control cabinet. The latching device is not limited to a latching mechanism, but can be realized by any attachment method, such as e.g. Gluing, clamping, screwing, pressing or any other friction fit.

Another aspect relates to a use of a plug-in device according to one of the above-described plug-in coupling devices for coupling a first RJ connector with a second RJ connector.

• 1: Datenkontaktelemente und Leistungskontaktelemente einer Steckkupplungs-vorrichtung in einem unmontierten Zustand;
• 2: Steckkupplungsvorrichtung gemäß 1 mit verbindendem PCB in einem unmontierten Zustand;
• 3: Steckkupplungsvorrichtung mit montierten Datenkontaktelementen, Leistungskontaktelementen und verbindendem PCB;
• Figur 4A und Steckkupplungsvorrichtung gemäß 3 mit einem und mit zwei 4B: montierten Gehäuseschalen;
• 5: Steckkupplungsvorrichtung gemäß 4B mit montiertem Schirmelement.

The invention will be described in more detail below with reference to exemplary embodiments shown in FIGS. Show it:

• 1 : Data contact elements and power contact elements of a plug-in device in an unmounted state;
• 2 : Plug-in device according to 1 with connecting PCB in an unmounted state;
• 3 : Plug-in coupling device with mounted data contact elements, power contact elements and interconnecting PCB;
• Figure 4A and plug-in device according to 3 with one and two 4B: mounted housing shells;
• 5 : Plug-in device according to 4B with mounted screen element.

1 shows the arrangement of first data contact elements 3A and second data contact elements 3B , as well as first power contact elements 2A and second power contact elements 2 B a plug-in device 1 , The plug-in device 1 In particular, in this exemplary embodiment, it is configured to couple a first RJ-45 connector (not shown) to a second RJ-45 connector (not shown). The first and second data contact elements each have data contacts 3A ₁ to 3A ₈ and FIGS. 3B ₁ to 3B ₈ which are exemplified in FIG 1 with reference to FIGS. 3A ₁ and 3B ₁ . The first and second data contact elements 3A . 3B are on a base plate 4 arranged the connector, wherein the base plate 4 a lower side of the plug-in device 1 Are defined. The base plate 4 consists of an electrically insulating material, preferably electromagnetically insulating material, wherein the base plate is formed, the first data contact elements 3A electrically from the second data contact elements 3B to isolate. The base plate 4 can preferably be formed in one piece and can also position elements 4A which, for positioning a printed circuit board 5 (please refer 2 and following) in complementary position element recordings 5A the printed circuit board 5 be recorded. The first data contact elements 3A are at a first end of the plug-in device 1 arranged and designed to be in contact with data conductors of the first RJ-45 connector. The first data contact elements 3A For this purpose, at least partially resiliently designed to ensure good contact with the data conductors of the first RJ-45 connector. The second data contact elements 3B are at a second end of the plug-in device 1 arranged and designed to be in contact with data conductors of the second RJ-45 connector. The second data contact elements 3B For this purpose, at least partially resiliently designed to ensure good contact with the data conductors of the second RJ-45 connector.

The first and second power contact elements 2A . 2 B are in 1 floatingly arranged as shown with the printed circuit board 5 which are connected in 2 and the following is shown. In particular, the first and second power contact elements 2A . 2 B not physically with the base in the embodiment shown 4 connected, but by an insulating gas or air from the base plate 4 separated to provide good insulation of the first and second power contact elements 2A . 2 B inside the plug-in device 1 to ensure. In further embodiments, the first and second power contact elements 2A . 2 B also in the base plate 4 be stored to provide structural stability of the plug-in device 1 to increase. The first power contact elements 2A are at a first end of the plug-in device 1 arranged and designed to be in contact with power conductors of the first RJ-45 connector. The first power contact elements 2A For this purpose, at least partially resilient, in particular designed as a resilient contact clip to a good To ensure contact with the power conductors of the first RJ-45 connector. The resilient contact clip of the first power contact elements 2A are here on an upper side of the plug-in device 1 educated. Thus, the first resilient data contact elements 3A and the first resilient power contact elements 2A preferably on opposite sides, in each case the lower and upper side of the plug-in coupling device 1 formed so that after receiving the first RJ-45 connector spring action of the first data contact elements 3A against a spring action of the first power contact elements 2A acts, ensuring a secure fit of the first RJ-45 connector and good contact. The second power contact elements 2 B are at a second end of the plug-in device 1 arranged and designed to be in contact with power conductors of the second RJ-45 connector. The second power contact elements 2 B For this purpose, further at least partially resilient, in particular designed as a resilient contact clip to ensure good contact with the power conductors of the second RJ-45 connector. The resilient contact clip of the second power contact elements 2 B are here on an upper side of the plug-in device 1 educated. Thus, the second resilient data contact elements 3B and the second resilient power contact elements 2 B preferably on opposite sides of the plug-in coupling device 1 formed so that after receiving the second RJ-45 connector, a spring action of the second data contact elements 3B against a spring action of the second power contact elements 2 B acts, which ensures a secure fit of the second RJ-45 connector and a good contact.

2 shows the plug-in device 1 according to 1 with mounted circuit board 5 , The printed circuit board 5 here has position element recordings 5A on which are designed, the position elements 4A the base plate 4 absorb and thus slipping of the printed circuit board 5 inside the plug-in device 1 to block or prevent. position elements 4A and position element recordings 5A may further be configured to be frictionally connected, whereby the printed circuit board 5 at the base plate 4 is attached. printed circuit board 5 and base plate 4 can either be arranged directly against each other, or separated from each other by a release layer, for example a protective layer and / or an insulating layer and / or a lacquer layer. The data contact elements 3A . 3B are with the printed circuit board 5 connected, which the data contact elements 3A crossed with the data contact elements 3B combines. This is illustrated by way of example with reference to the data contact elements 3A ₁ and 3B ₁ , wherein the data contact elements 3A ₁ and 3B ₁ crossed by the printed circuit board 5 are connected. The data contact elements 3A . 3B and their connection on the printed circuit board 5 form the data coupling device 3 , The power contact elements 2A . 2 B are with the printed circuit board 5 connected, which the power contact elements 2A crossed with the power contact elements 2 B combines. The power contact elements 2A . 2 B and their connection on the printed circuit board 5 form the power coupling device 2 ,

3 shows the plug-in device 1 according to 2 with mounted structural element 6 , structural element 6 is on the circuit board 5 designed and designed, the power contact elements 2A . 2 B to guide and / or support. structural element 6 can do this from the same material as base plate 4 or another electrically insulating material. The structural element 6 can eg by gluing, clamping or latching with printed circuit board 5 and / or the base plate 4 get connected. The structural element 6 also has four guide rails 6A on which are designed, the housing shells 7 (please refer 4A and 4B ) on the plug-in device 1 to lead and slipping of the housing shells 7 to block at the plug-in device in at least one direction. The structural element 6 also has latching noses 6B which are designed to with complementary latching elements 7B (please refer 4A and 4B ) of the housing shells 7 to get into engagement and thus the housing shells 7 on the plug-in coupling device 1 to fix.

4A shows a plug-in device 1 according to 3 with a mounted housing shell 7 , The housing shell 7 is designed to be the plug-in device 1 at least partially surround and isolate to the outside and protect against damage. The housing shell 7 can for this example consist of an insulating plastic or a composite material. The housing shell 7 also has rails 7A on to the guide rails 6A of the structure element 6 take. The housing shell 7 further includes latching elements 7B , which with the locking lugs 6B of the structure element 6 can engage the housing shell 7 on the structural element 6 the plug-in device 1 to fix. latching 7A and latching noses 6A However, can also be replaced by other fixing elements, such as by an adhesive portion or a clamping portion. The housing shell 7 is designed to fit together with a similar housing shell 7 the plug-in device 1 at least partially surrounded. As a result, a manufacturing process of the housing shells 7 simplified. The housing shell 7 each has at least one housing shell projection 7C and at least one housing shell recess 7D on, wherein the housing shell projections 7C and the housing shell recesses 7D two housing shells are adapted to engage with each other to slipping the housing shells on the plug-in device 1 to block. 4B shows such an arrangement in which the two housing shells 7 are arranged on the plug-in coupling device and engage with each other. The housing shells 7 also have a connector snap-in receptacle 7E which is designed to receive the latching mechanism of a conventional RJ-45 connector. The housing shells 7 each form a connector receptacle at the first and second ends 8th , each for receiving an RJ-45 connector.

5 shows a plug-in device 1 according to 4B with mounted screen element 9 , The screen element 9 is designed, the plug-in device 1 to protect against external electromagnetic fields and is designed as a Faraday cage, which is the plug-in device 1 at least partially surrounds. For this purpose, the screen element 9 be formed of a metal or a conductive plastic. The screen element 9 can also be configured, the plug-in device 1 additionally to protect against damage.

The invention is not limited to a single embodiment mentioned above. Rather, the plug-in coupling device, the method for producing a coupling and the use of the plug-in coupling device may have any combination of any number of features of the above-mentioned embodiments and the figures.

LIST OF REFERENCE NUMBERS

1

Plug-in coupling device

2

Power coupling device

2A

first power contact elements

2 B

second power contact elements

3

Data-coupling device

3A

first data contact elements

3A ₁ to 3A ₈

Data contact elements of the first data contact elements

3B

second data contact elements

3B ₁ to 3B ₈

Data contact elements of the second data contact elements

4

baseplate

4A

position member

5

printed circuit board

5A

Position member receiving

6

structural element

6A

guide rail

6B

locking lug

7

shell

7A

bar accommodation

7B

latching

7C

Shell edge

7D

Shell recess

7E

Connector locking tab receiving

8th

connector recording

9

screen element

Claims (14)

A plug-in coupling device (1) for receiving a first RJ connector at a first end and a second RJ connector at a second end, comprising data coupling means (3) for connecting a plurality of data conductors of the first RJ connector to a plurality of data conductors of the second RJ connector; and a power coupling device (2) for connecting a plurality of power conductors of the first RJ connector to a plurality of power conductors of the second RJ connector, wherein the data coupling means (3) and the power coupling means (2) are electrically separate from each other. Plug-in coupling device (1) according to Claim 1 wherein the power coupling means (2) comprises: at least two power contact members (2A) at the first end for making electrical contact with the first RJ connector; and at least two power contact elements (2B) at the second end for making electrical contact with the second RJ connector. A plug-in coupling device (1) according to any one of the preceding claims, wherein the data coupling means (3) comprises: at least two data contact elements (3A) at the first end for establishing a data connection with the first RJ connector; and at least two data contact elements (3B) at the second end for establishing a data connection with the second RJ connector. A plug-type coupling device (1) according to any one of the preceding claims, wherein the data coupling means (3) cross-connects the plurality of data conductors of the first RJ connector to the plurality of data conductors of the second RJ connector, the data coupling means (3) comprising data contact elements (3). 3A) at the first end for establishing a data connection with the first RJ connector crossed with data contact elements (3B) at the second end for establishing a data connection with the second RJ connector. A plug-type coupling device (1) according to any one of the preceding claims, wherein the power coupling means (2) connects the plurality of power conductors of the first RJ connector to the plurality of power conductors of the second RJ connector, the power coupling means (2) connecting power contact members (12). 2A) at the first end for making electrical contact with the first RJ connector crossed with power contact members (2B) at the second end for making electrical contact with the second RJ connector. Plug-in coupling device (1) according to one of the preceding claims, wherein the data coupling device (3) and the power coupling device (2) are at least partially formed on a printed circuit board (5). Plug-in coupling device (1) according to Claim 1 to 5 wherein the data coupling means (3) is at least partially formed on a first printed circuit board, and wherein the power coupling means (2) is at least partially formed on a second printed circuit board. Plug-in coupling device (1) according to one of the preceding claims, wherein the plug-in coupling device (1) is Power-over-Ethernet - compatible. A male coupling device (1) according to any one of the preceding claims, wherein the male coupling device (1) is adapted to couple a first RJ-45 connector and a second RJ-45 connector. Plug-in coupling device (1) according to one of the preceding claims, wherein the plug-in coupling device (1) further comprises a housing, wherein the housing comprises two substantially equal parts housing shells (7) and the housing at least partially surrounds the plug-in coupling device (1). Plug-in coupling device (1) according to one of the preceding claims, wherein the plug-in coupling device (1) further comprises a shield member (9) which at least partially surrounds the plug-in coupling device (1) and substantially shields from external electromagnetic fields. Plug-in coupling device (1) according to one of the preceding claims, wherein the plug-in coupling device (1) further comprises a latching device which is adapted to fix the plug-in coupling device (1) to a complementary latching mechanism of an external mounting frame. A method of making a coupling between a first RJ connector and a second RJ connector, comprising: Providing a plug-in coupling device (1) for receiving the first RJ connector at a first end and the second RJ connector at a second end, comprising data coupling means (3) for connecting a plurality of data conductors of the first RJ connector to a plurality of data conductors of the second RJ connector; and a power coupling device (2) for connecting a plurality of power conductors of the first RJ connector to a plurality of power conductors of the second RJ connector, wherein the data coupling means (3) and the power coupling means (2) are electrically separated from each other; Receiving the first RJ connector at the first end; and Receiving the second RJ connector at the second end. Use of a plug-in coupling device (1) according to one of Claims 1 to 12 for coupling a first RJ connector to a second RJ connector.

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