EP4115480A1 - Single-pair ethernet device, single-pair ethernet system and method for installing a single-pair ethernet system - Google Patents

Abstract

In order to increase flexibility, a single-pair ethernet device (10a-f) is proposed, which is preferably part of a single-pair ethernet system (42a-f), comprising a first input contact (12a-f) and a second input contact (14a-f), which are provided for electrically contacting a single-pair ethernet input conductor pair (16a-f), comprising a first output contact (18a-f) and a second output contact (20a-f), which are provided for electrically contacting a single-pair ethernet output conductor pair (22a-f), comprising a first conducting path (24a-f), which electrically conductively connects the first input contact (12a-f) to the first output contact (18a-f) in at least one operating state, and comprising a second conducting path (26a-f), which electrically conductively connects the second input contact (14a-f) to the second output contact (20a-f) in the operating state.

Description

Single-pair Ethernet device, single-pair Ethernet system, and method for installing a single-pair Ethernet system

The invention relates to a single-pair Ethernet device according to claim 1, a single-pair Ethernet system according to claim 12 and a method for installing a single-pair Ethernet system according to claim 13.

It is already known from the prior art to form an Internet network by connecting a router to one end of a main line, another end of the main line having a terminating resistor and a plurality of T-pieces being arranged on the main line, each of which has a stub line leads to a device. This solution has the disadvantages that due to the terminating resistor, no power and data can be transmitted over the Internet network, and the stub lines must not exceed a length of 30 cm, which greatly limits flexibility in terms of the design of the Internet network. Furthermore, it is not possible to expand the Internet network by simply connecting additional lines.

The object of the invention is in particular, but not limited to, to provide a generic device with improved properties in terms of flexibility. The object is achieved according to the invention by the features of claims 1, 12 and 13, while advantageous refinements and developments of the invention can be found in the subclaims.

A single-pair Ethernet device is proposed, which is in particular part of a single-pair Ethernet system, with a first input contact and a second input contact, which are provided for electrical contacting of a single-pair Ethernet input conductor pair, with a first output contact and a second output contact, which are provided for electrical contacting of a single-pair Ethernet output conductor pair, with a first conduction path which connects the first input contact to the first output contact in an electrically conductive manner in at least one operating state, and with a second conduction path, which rather, in the operating state, the second input contact connects to the second output contact in an electrically conductive manner.

A flexible configuration of the single-pair Ethernet system can be achieved by such a configuration. By connecting the single-pair Ethernet input conductor pair to the single-pair Ethernet output conductor pair via the line paths, a length of stub lines which lead from the single-pair Ethernet conductor pairs to devices can advantageously be minimized. A terminating resistor can particularly advantageously be dispensed with, so that a simultaneous transmission of power and data is made possible by the single-pair Ethernet system. Furthermore, the single-pair Ethernet system can preferably be adapted in a simple manner by connecting and / or removing single-pair Ethernet devices.

It would be conceivable that the single-pair Ethernet device forms the entire single-pair Ethernet system. The single-pair Ethernet system preferably comprises a distributor, in particular a router and / or power distributor, and at least one device. The single-pair Ethernet system advantageously has a plurality of connection points to each of which a device can be connected and / or from which a device can be removed. The device is preferably part of the single pair Ethernet device. The single-pair Ethernet device is preferably provided to enable connection to a remaining single-pair Ethernet system and / or removal of the device. The single-pair Ethernet device particularly preferably forms at least part of the connection point; it would also be conceivable for the single-pair Ethernet device to have the entire connection point. Alternatively, the single-pair Ethernet device can have a short-circuit plug and be provided to provide connections that are free of connected devices to be bridged. The distributor is intended to supply the device with data and / or power. The single-pair Ethernet system is advantageously part of a smart home application, the device particularly advantageously having a sensor and / or actuator of the smart home application. It would be conceivable that the single-pair Ethernet system is part of a data network, whereby the device could have a network chip. The single-pair Ethernet system preferably forms a network for supplying devices with data and / or power, which is advantageously installed, for example, in a household and is particularly advantageous. allows any removal and connection of devices for supplying the devices, for example by means of common plug connections.

The single-pair Ethernet system preferably comprises a plurality of single-pair Ethernet input conductor pairs and single-pair Ethernet output conductor pairs, at least one of the single-pair Ethernet input conductor pairs being electrically conductively connected to the distributor at one end is. Each device of the single-pair Ethernet system is advantageous with a single-pair Ethernet input conductor pair, which is technically arranged between the respective device and the distributor, and a single-pair Ethernet output conductor pair, which is between the device and further Ge devices of the single-pair Ethernet system is arranged, electrically connected. The single-pair Ethernet system particularly advantageously has at least one terminating device which is free of electrically conductive connections to a single-pair Ethernet output conductor pair. The connecting device can preferably be converted into a normal device by simply connecting a single-pair Ethernet output conductor pair to the terminating device. The devices are particularly advantageously connected in series, with the single-pair Ethernet output conductor pair of a first device being identical to the single-pair Ethernet input conductor pair of a second device immediately following the first device. In particular, the distributor is electrically connected to the device in the form of a daisy chain via the single-pair Ethernet input conductor pairs and the single-pair Ethernet output conductor pairs. A “daisy chain” is to be understood as a chain of electrical components, with an initial link in the chain, in this case the distributor, with a subsequent chain link, in this case the device, over all further links arranged between the initial link and the chain link Chain links, in particular other devices and / or short-circuit plugs, is electrically connected.

The single-pair Ethernet input conductor pair and / or the single-pair Ethernet output conductor pair are / is advantageously each designed as cable cores of a two-wire cable, preferably a two-wire copper cable. The single-pair Ethernet input conductor pair and the single-pair Ethernet output conductor pair are preferably designed to be identical to one another; alternatively, the single-pair Ethernet input conductor pair and the single-pair Ethernet output conductor pair could be designed differently from one another. The single-pair Ethernet input conductor pair and / or the single- Pair Ethernet output conductor pair at one end, in particular at both ends, each have a chain connector, via which the single-pair Ethernet input conductor pair and / or the single-pair Ethernet output conductor pair with the distributor and / or the device and / or the short-circuit plug, in particular to form an off the daisy chain, can be connected in an electrically conductive manner. The chain connector preferably has four pins, which are electrically conductively connected in pairs to one wire of the single-pair Ethernet input conductor pair or the single-pair Ethernet output conductor pair. It would also be conceivable that the chain connector has only two pins, one of which is electrically conductively connected to a wire of the single-pair Ethernet input conductor pair or the single-pair Ethernet output conductor pair.

The input contacts and / or output contacts are advantageously designed as pins of at least one connector. Alternatively, the input contacts and / or output contacts could be designed as open ends of conductor tracks, which could be arranged, for example, on a circuit board. In a further alternative embodiment, the input contacts and / or output contacts could be formed in one piece with the single-pair Ethernet input conductor pair and / or single-pair Ethernet output conductor pair. “In one piece” should be understood to be at least cohesively connected, for example by a soldering process, and particularly advantageously formed in one piece. The input contacts and / or output contacts are preferably part of a bridge connector via which the device is connected in an electrically conductive manner to the rest of the single-pair Ethernet system. Alternatively, the input contacts and / or the output contacts could be part of the shorting plug. The bridge connector and the device are preferably mounted on a printed circuit board; alternatively, the bridge connector could be designed as an adapter to which a connector can be connected which is electrically conductively connected to the device.

A “line path” is to be understood as a structural unit that provides an electrically conductive connection between two points. For example, the line path could be formed in one piece with a wire of a cable and / or in one piece with a conductor track on a printed circuit board and / or in one piece with a pin of a connector, preferably the bridge connector. The entire line path is advantageous In one piece, the conduction path could alternatively have a plurality of sub-units that are electrically conductively connected at least in the operating state.

“Provided” is to be understood as specifically designed and / or equipped. Since an object is provided for a specific function, it should be understood that the object fulfills and / or executes this specific function in at least one application and / or operating state.

It is also proposed that the first conduction path has a first forwarding, in particular a first branch, and the second conduction path has a second forwarding, in particular a second branch, the forwarding being provided for electrical connection to a device. It would be quite conceivable that the line paths would have further forwardings. The first forwarding preferably connects a remaining first conduction path and an input line to one another in an electrically conductive manner. The second forwarding preferably electrically connects a remaining second conduction path and an output line to one another. The input line and the output line advantageously form a stub line, which connects the device to the rest of the single-pair Ethernet system in an electrically conductive manner. The stub line could, for example, be used as conductor tracks on a printed circuit board that is electrically connected to the device, and / or as cable cores of a cable that is electrically connected to the device, and / or as pins of an adapter connector to which a connector, which is connected to the device in an electrically conductive manner, can be plugged in, be formed. This allows a flexible configuration of the single-pair Ethernet system to be achieved. The single-pair Ethernet system can advantageously be equipped with any number of forwarders in order to connect any number of devices in the form of a daisy chain, which can have any number of linked chains and / or chain rings, to the distributor to connect electrically conductive.

In an alternative embodiment, the first line path could be formed in one piece with the single-pair Ethernet input conductor pair and / or the second line path could be formed in one piece with the single-pair Ethernet output conductor pair. In this alternative embodiment, it would be possible that the input contacts and output contacts are each designed as partial areas of the single-pair Ethernet input conductor pair and the single-pair Ethernet output conductor pair. In addition, the line paths in This alternative embodiment integrally forms with pins of the chain connector. In this alternative embodiment, the first conduction path preferably connects the first input contact, the first output contact and a first pin of the chain connector in an electrically conductive manner. In this alternative embodiment, the second conduction path particularly preferably connects the second input contact, the second output contact and a second pin of the chain connector in an electrically conductive manner. In this alternative configuration, the chain connector particularly preferably has two pins.

In addition, it is proposed that the single-pair Ethernet device has a circuit board which has at least one of the and preferably both forwarding lines. The first conduction path and / or the second conduction path preferably has at least one open conductor path end of the circuit board. In particular, the first routing and / or the second routing is designed as a sub-area of conductor tracks of the circuit board. The input contacts and output contacts are advantageously designed as pins of the bridge connector. Alternatively, the input contacts and the output contacts could be designed as open conductor track ends of the circuit board. It would be conceivable that the first line path and / or the second line path is arranged completely on the circuit board or in the bridge connector. Preferably, the first line path and / or the second line path extends over part of the circuit board and part of the bridge connector. Thereby, a construction of the single-pair Ethernet device can be improved. A length of the stub line can advantageously be kept small.

In addition, the circuit board could have at least one of the and preferably both line paths. Advantageously, in this embodiment, the pins of the bridge connector are identical to the open conductor ends of the circuit board. As a result, a construction of the single-pair Ethernet device can be simplified. It is advantageous to dispense with pins of the bridge connector that are formed separately from conductor tracks on the circuit board.

In addition, it is proposed that the single-pair Ethernet device has the bridge connector which has one of the and preferably both forwarding lines. It would be conceivable that the circuit board and the bridge connector each have one of the further lines, preferably either the circuit board or the bridge connector connect both redirects. In an embodiment in which the printed circuit board and the bridge connector each have one of the routings, the first input contact and / or the first output contact is preferably a pin of the bridge connector and the second input contact and / or the second output contact is an open conductor end formed the circuit board. The bridge connector advantageously has a bridge connector housing, within which the first forwarding line and / or the second forwarding line is arranged. The first forwarding line and / or the second forwarding line is preferably designed as a sub-area of conductor tracks of the bridge connector. Thereby, a construction of the single-pair Ethernet device can be improved. A length of stub lines can advantageously be kept small.

The bridge connector preferably has at least one of the and preferably both line paths. This can simplify a construction of the single-pair Ethernet device. The circuit board can advantageously be dispensed with.

In addition, it is proposed that the single-pair Ethernet device has an adapter plug connector, in particular the adapter plug connector, which is part of an adapter and to which the forwarding lines are connected in an electrically conductive manner. An “adapter” is to be understood as an electrical component which has a first connector, in particular the bridge connector, and a second connector, in particular the adapter connector, with a further first connector, in particular the chain connector, being connectable to the first connector and a further second plug connector, in particular a plug connector which is electrically conductively connected to the device, can be connected to the second plug connector and wherein the further first plug connector and the further second plug connector differ with regard to a plug geometry. It would be conceivable that the adapter connector is connected to the circuit board in an electrically conductive manner; in particular, pins of the adapter connector could be connected to open conductor track ends of the circuit board in an electrically conductive manner. The bridge connector is preferably designed as a separate adapter, the pins of the bridge connector advantageously being connected in an electrically conductive manner to the pins of the adapter connector. The bridge connector particularly preferably has four pins which are connected in an electrically conductive manner to two pins of the adapter connector via the forwarding lines. This allows a flexible Design of the single-pair Ethernet device can be achieved. Different adapter connectors can advantageously be used to connect different types of devices to the rest of the single-pair Ethernet system.

It is also proposed that the single-pair Ethernet device has a cable with two cable cores, to which the forwarding lines are connected in an electrically conductive manner.

It would be conceivable that the cable is electrically conductively connected to the circuit board, in particular the cable cores could be electrically conductively connected to open conductor track ends of the circuit board. The bridge connector is preferably designed as a separate adapter, with wires of the cable advantageously being connected in an electrically conductive manner to the pins of the bridge connector. The bridging connector particularly preferably has four pins which are connected in an electrically conductive manner to the cable cores via the forwarding lines. It would be possible for the cable cores to be permanently connected to the device in an electrically conductive manner. The cable preferably has at least one connection plug connector for connection to the device. A flexible configuration of the single-pair Ethernet device can hereby be achieved. The cable can advantageously be used as an extension cable in order to connect the device to the rest of the single-pair Ethernet system in an electrically conductive manner.

In a further embodiment of the invention, it is proposed that the first conduction path and the second conduction path are each free of, in particular effective, further lines. “Effective forwarding” should be understood to mean forwarding that electrically conductively connects a remaining conduction path to at least one electrical functional unit, for example the circuit board and / or the adapter connector and / or the cable and / or the device. The single-pair Ethernet device preferably has a short-circuit plug which has the input contacts, the output contacts and the forwarding lines and advantageously a direct line of current and / or data from the first input contact to the first output contact and from the second input contact to the second output con tact provides. A flexible configuration of the single-pair Ethernet device can hereby be achieved. Single-pair Ethernet input conductor pairs and single-pair Ethernet output conductor pairs can advantageously be connected to one another in an electrically conductive manner. A number of devices of the single-pair Ethernet system can be particularly advantageous in a simple manner by exchanging bridge connectors. and short-circuit plugs can be varied without interrupting the daisy chain.

It is further proposed that in at least one other operating state that differs from the operating state, in particular the further operating state, the first conduction path and the second conduction path are interrupted. The fact that the line paths are “interrupted” should be understood to mean that, in the further operating state, the line paths are divided into several sub-units that are technically separated from one another. In the further operating state, the line paths are advantageously divided into four sub-units, one of the sub-units being connected in an electrically conductive manner to one of the input contacts or output contacts. It would be conceivable that the single-pair Ethernet device has at least one switching unit, for example a relay, by means of which the single-pair Ethernet device can be switched to the operating state and / or the further operating state. In the operating state, the single-pair Ethernet conductor pairs are advantageously connected in a directly electrically conductive manner by the line paths. The operating state is preferably designed as an idle state of the single-pair Ethernet device. The conduction paths each advantageously have a pair of spring contacts, with a first spring contact being electrically conductively connected to a second spring contact of the first conduction path and a first further spring contact with a second further spring contact of the second conduction path in the operating state. The single-pair Ethernet device preferably has an interrupt connector which is particularly preferably provided to interrupt the line paths when the bridge connector is inserted. The input contacts and the output contacts are particularly preferably designed as pins of the interrupt connector. In the further operating state, the bridge connector is particularly advantageously inserted into the interruption connector and arranged between the spring contacts. The bridging plug connector advantageously has lateral contact surfaces which each contact the spring contacts in an electrically conductive manner. Particularly advantageously, the bridge connector has a further first conduction path and a further second conduction path, the further first conduction path connecting the first input contact and the first output contact in an electrically conductive manner in the further operating state and the further second conduction path connecting the second input contact and in the further operating state the second output contact connects electrically conductive. This allows an even more flexible design of the single-pair Ethernet system can be achieved. A “normally closed” short-circuit plug can advantageously be provided, which can be transferred from the operating state to the further operating state and vice versa by simply plugging in and unplugging the bridge connector. A number of devices of the single-pair Ethernet system can be changed particularly advantageously without the need to assemble or disassemble short-circuit plugs.

The single-pair Ethernet device advantageously has a connector housing which can in particular be part of the bridge connector and which at least partially encloses the first input contact and the second input contact. It would be conceivable that the connector housing exclusively at least partially encloses the first input contact and the second input contact and the single-pair Ethernet device in particular has a further connector housing which at least partially encloses the first output contact and the second output contact. The connector housing preferably encloses all input contacts and output contacts at least partially. As a result, a construction of the single-pair Ethernet device can be simplified. The device can advantageously be connected to the rest of the single-pair Ethernet system with commercially available simplex plugs or duplex plugs.

A single-pair Ethernet system is also proposed with a single-pair Ethernet input conductor pair, in particular the single-pair Ethernet input conductor pair, with a single-pair Ethernet output conductor pair, in particular the single-pair Ethernet Output conductor pair, and with at least one electrical connection point for contacting a single-pair Ethernet device, in particular the single-pair Ethernet device, the connection point with the single-pair Ethernet input conductor pair and the single-pair Ethernet output conductor pair connected is. This allows a flexible configuration of the single-pair Ethernet system to be achieved. The length of stub lines which lead from the connection point to a device connected to a remaining single-pair Ethernet system can advantageously be minimized.

The connection point is preferably designed as the chain connector and the single-pair Ethernet device is designed as the bridge connector and / or as the printed circuit board. Alternatively, the connection point and the single-pair Ethernet device could be used be formed as, in particular different, sub-areas of single-pair Ethernet conductor pairs. It would be conceivable that the single-pair Ethernet system and the single-pair Ethernet device are designed separately from one another; for example, the single-pair Ethernet device could be used as a toolkit for an adaptation, for example field assembly, of the single Pair Ethernet system be designed. The single-pair Ethernet system advantageously comprises the single-pair Ethernet device. In this way, a flexible single-pair Ethernet system can be provided. An adaptation of the single-pair Ethernet system, for example a change in a number of devices in the single-pair Ethernet system, can be advantageous by simply plugging in and / or unplugging any number of single-pair Ethernet devices be performed.

A method for installing a single-pair Ethernet system, in particular the single-pair Ethernet system, is also proposed, the single-pair Ethernet system being provided in the form of a daisy chain. In this way, a flexible and easily adaptable installation can be achieved in particular. A modular installation of the single-pair Ethernet system can advantageously be achieved.

It is also proposed that a single-pair Ethernet conductor pair be divided into an unconfigured single-pair Ethernet input conductor pair and an unconfigured single-pair Ethernet output conductor pair and at the corresponding ends of the unconfigured single-pair Ethernet input conductor pair and at least one connection point of the unassembled single-pair Ethernet output conductor pair is field-assembled. The single-pair Ethernet conductor pair is preferably cut at one point for division into the unassembled single-pair Ethernet input conductor pair and the unassembled single-pair Ethernet output conductor pair. Alternatively, the single-pair Ethernet conductor pair could consist of separate, unassembled single-pair Ethernet conductor pair parts, with one of the unassembled single-pair Ethernet conductor pair parts for use as an unassembled single-pair Ethernet input conductor pair and as a unassembled single-pair Ethernet output conductor pair is selected. The field assembly of the connection point advantageously includes techniques known to those skilled in the art for assembling cables, such as soldering and / or crimping and / or insulation displacement terminals. In particular, this enables a flexible configuration of the single-pair Ethernet System can be achieved. The connection point can advantageously be positioned at any point on the single-pair Ethernet conductor pair. The connection point can particularly advantageously be customized depending on the area of application.

In a further embodiment of the invention, it is proposed that a pre-assembled single-pair Ethernet input conductor pair and a pre-assembled single-pair Ethernet output conductor pair are provided and one end of the single-pair Ethernet input conductor pair and one end of the single Pair Ethernet output conductor pairs can be combined to form a termination point. For example, the single-pair Ethernet input conductor pair and the single-pair Ethernet output conductor pair could each be designed as a single-pair Ethernet conductor pair, at the ends of which a simplex connector is arranged, the formation of the connection point being an arrangement of the Ends in close proximity to one another or a connection of the ends, preferably to form a common duplex connector, may include. In particular, this enables simple installation of the single-pair Ethernet system. The single-pair Ethernet system can advantageously be installed without tools by simply plugging together individual components of the single-pair Ethernet system.

The single-pair Ethernet device, the single-pair Ethernet system and the method for installing a single-pair Ethernet system are not intended to be restricted to the applications and embodiments described above. In particular, the single-pair Ethernet device, the single-pair Ethernet system and the method for installing a single-pair Ethernet system can be one of a number of individual elements specified herein to fulfill a mode of operation described herein, Components, units and process steps have a different number.

Further advantages emerge from the following description of the drawings. In the drawing voltage, embodiments of the invention are shown. The drawings, the description and the claims contain numerous features in combination. The specialist will expediently consider the features individually and combine them into useful further combinations. Show it:

1 shows a schematic representation of a single-pair Ethernet system with a single-pair Ethernet device,

2 shows a part of a chain connector of the single-pair Ethernet system in an oblique view,

3 shows the single-pair Ethernet device in an oblique view, FIG. 4 shows the single-pair Ethernet device of FIG. 3 in a view from underneath,

5 shows a schematic flow diagram of a method for installing the single-pair Ethernet system,

6 shows a schematic progression diagram of a further exemplary embodiment of a method for installing the single-pair Ethernet system,

7 shows a further exemplary embodiment of a single-pair Ethernet device in an oblique view, FIG. 8 shows the single-pair Ethernet device of FIG. 7 in a partially opened representation, FIG. 9 shows a further exemplary embodiment of a single-pair Ethernet device in an oblique view, FIG. 10 the single-pair Ethernet device of FIG. 9 in a partially opened representation, FIG. 11 a further embodiment of a single-pair Ethernet device in an oblique view, FIG. 12 the single-pair Ethernet device of FIG. 11 in a partially opened representation, FIG. 13 a further exemplary embodiment of a single-pair Ethernet device in an oblique view, FIG. 14 the single-pair Ethernet device of FIG FIG. 13 shows a partially opened illustration, FIG. 15 shows a schematic illustration of a further exemplary embodiment of a single-pair Ethernet device in an operating state, and FIG. 16 shows a schematic illustration of the Single-pair Ethernet device of FIG. 15 in a further operating state. In the figures, only one object of multiple existing objects is provided with a reference symbol.

FIG. 1 shows part of a single-pair Ethernet system 42a. The single-pair Ethernet system 42a has a distributor 50a. The distributor 50a has a router. As an alternative or in addition, the distributor 50a could have a power distributor. The single-pair Ethernet system 42a has a plurality of single-pair Ethernet devices 10a, only one of which is shown and will be described below. The single-pair Ethernet device 10a has a device 52a. The device 52a has a sensor of a smart home application. Alternatively or additionally, the device 52a could have an actuator of a smart home application or a network chip of a computer.

The single-pair Ethernet system 42a has a plurality of single-pair Ethernet input conductor pairs 16a which are identical to one another, which is why FIG. 1 shows only one of the single-pair Ethernet input conductor pairs 16a and only below the single-pair Ethernet input conductor pair 16a shown is described. The distributor 50a and the device 52a are electrically conductively connected in the form of a daisy chain via the single-pair Ethernet input conductor pair 16a and a single-pair Ethernet output conductor pair 22a. The single-pair Ethernet system 42a has a plurality of single-pair Ethernet output conductor pairs 22a which are identical to one another, which is why FIG. 1 shows only part of one of the single-pair Ethernet output conductor pairs 22a and below only the single-pair Ethernet output conductor pair 22a shown is described. The single-pair Ethernet input conductor pair 16a and the single-pair Ethernet output conductor pair 22a are formed identically to one another. Alternatively, the single-pair Ethernet input conductor pair 16a and the single-pair Ethernet output conductor pair 22a could be designed differently from one another. The single-pair Ethernet input conductor pair 16a is designed as part of a single-pair Ethernet cable 46a, which is shown in FIG.

The single-pair Ethernet system 42a has a plurality of electrical connection points 44a which are identical to one another, which is why only one of the connection points 44a is described below. Alternatively, the connection points 44a could be designed differently from one another. The connection point 44a is used for contacting a single-pair Ethernet device 10a, which will be discussed in more detail later. is written. The connection point 44a is connected to the single-pair Ethernet input conductor pair 16a. The connection point 44a is connected to the single-pair Ethernet output conductor pair 22a. The connection point 44a is formed from corresponding ends of the single-pair Ethernet conductor pairs 16a, 22a. The ends of the single-pair Ethernet conductor pairs 16a, 22a each have a partial chain connector 48a, the partial chain connectors 48a being identical to one another, which is why only the partial chain connector 48a of the single-pair Ethernet input conductor pair 16a is described below. The partial chain connector 48a of the single-pair Ethernet input conductor pair 16a is shown in FIG. The partial chain connector 48a is designed as a simplex connector. The partial chain plug connectors 48a together form a chain plug connector 49a. The chain connector 49a is designed as a duplex connector. The chain connector 49a is formed by connecting both partial chain connectors 48a. Alternatively, the chain connector 49a could be designed as two separate simplex plugs or as a duplex socket or as two separate simplex sockets.

The single-pair Ethernet system 42a has a plurality of single-pair Ethernet devices 10a, which are designed to be identical to one another, which is why only one of the single-pair Ethernet devices 10a is described below. Alternatively, the single-pair Ethernet device 10a could be designed separately from the single-pair Ethernet system 42a. The single-pair Ethernet device 10a is shown in more detail in FIG. The single-pair Ethernet device 10a has a first input contact 12a. The single-pair Ethernet device 10a has a second input contact 14a. The input contacts 12a, 14a are used to make electrical contact with the single-pair Ethernet input conductor pair 16a. The input contacts 12a, 14a are designed as pins of a bridge connector 34a. The single-pair Ethernet device 10a has a first output contact 18a. The single-pair Ethernet device 10a has a second output contact 20a. The output contacts 18a, 20a are used for electrical contacting of the single-pair Ethernet output conductor pair 22a. The output contacts 18a, 20a are designed as pins of the bridge connector 34a. The bridge connector 34a is designed as a duplex plug socket. Alternatively, the bridge connector 34a could be designed as two separate simplex sockets or as a duplex connector or as two separate simplex connectors. In the event that the device 52a is designed as a terminating device, the bridge connector could Binder 34a can also be designed only as a single simplex plug socket or as a single simplex plug.

The single-pair Ethernet device 10a has a printed circuit board 32a. The device 52a is mounted on the circuit board 32a (not shown). The bridge connector 34a is connected to the printed circuit board 32a in an electrically conductive manner. The circuit board 32a has a first conductor track 54a. The circuit board 32a has a second conductor track 56a. The conductor tracks 54a, 56a are electrically connected to the device 52a. Alternatively, the conductor tracks 56a could be electrically conductively connected to a two-core cable which is electrically conductively connected to the device 52a, and / or a plug connector which is electrically conductively connected to the device 52a. The single-pair Ethernet device 10a has a first conduction path 24a. The first conduction path 24a connects the first input contact 12a to the first output contact 18a in an electrically conductive manner. The single-pair Ethernet device 10a has a second line path 26a. The second conduction path 26a connects the second input contact 14a to the second output contact 20a in an electrically conductive manner. The conduction paths 24a, 26a connect the input contacts 12a, 14a and the output contacts 18a, 20a with the conductor tracks 54a, 56a.

The first conduction path 24a has a first forwarding 28a. The second line path 26a has a second forwarding 30a. The redirects 28a, 30a are shown in FIG. Alternatively, the line paths 24a, 26a could have any number of further forwardings. The forwarding lines 28a, 30a are designed as partial areas of the conductor tracks 54a, 56a. The first forwarding 28a connects a remaining first conduction path to a remaining first conductor path in an electrically conductive manner. The second forwarding 30a connects a remaining second conduction path with a remaining second conductor track in an electrically conductive manner. The circuit board 32a has both passages on 28a, 30a. Alternatively, the printed circuit board 32a could have only one of the forwarding lines 28a, 30a or none of the forwarding lines 28a, 30a. The circuit board 32a has both conduction paths 24a, 26a. Alternatively, the printed circuit board 32a could have only one of the line paths 24a, 26a or none of the line paths 24a, 26a.

The single-pair Ethernet device 10a has a connector housing 40a. The connector housing 40a is part of the bridge connector 34a. The connector housing 40a encloses the input contacts 12a, 14a and the output contacts 18a, 20a each partially. Alternatively, the connector housing 40a could only partially close the input contacts 12a, 14a or only the output contacts 18a, 20a. The input contacts 12a, 14a and the output contacts 18a, 20a each have a partial area protruding from the connector housing 40a. The protruding partial areas are used to contact pins of the partial chain connector 48a.

FIG. 5 shows a schematic flow diagram of a method for installing the single-pair Ethernet system 42a. The single-pair Ethernet system 42a is provided in the form of a daisy chain. In a splitting step 100a, a single-pair Ethernet conductor pair (not shown) is divided into an unassembled single-pair Ethernet input conductor pair (not shown) and an unassembled single-pair Ethernet output conductor pair (not shown). The dividing step 100a comprises cutting up the single-pair Ethernet conductor pair at any point. In an assembly step 110a, the connection points 44a are field-assembled at the corresponding ends of the unconfigured single-pair Ethernet input conductor pair 16a and the unconfigured single-pair Ethernet output conductor pair 22a. The assembly step 110a follows the division step 100a. The unassembled single-pair Ethernet input conductor pair and the unassembled single-pair Ethernet output conductor pair correspond to the single-pair Ethernet input conductor pair 16a and the single-pair Ethernet output conductor pair 22a after the assembly step 110a. In a chaining step 120a, the device 52a is connected to the rest of the single-pair Ethernet system. The chaining step 120a comprises contacting the single-pair Ethernet device 10a through the connection point 44a. The concatenation step 120a here follows the assembly step 110a.

FIG. 6 shows a schematic progress diagram of a further method for installing the single-pair Ethernet system 42a. The single-pair Ethernet system 42a is provided in the form of a daisy chain. In a connection step 130a, the single-pair Ethernet input conductor pair 16a and the single-pair Ethernet output conductor pair 22a are provided. One end of the single-pair Ethernet input conductor pair 16a and one end of the single-pair Ethernet output conductor pair 22a are then combined to form the connection point 44a. The linking step 130a is followed by the linking step 120a, analogously to FIG. 6. In FIGS. 7 to 16, five further exemplary embodiments of the invention are shown. The following descriptions are essentially limited to the differences between the exemplary embodiments, reference being made to the description of the exemplary embodiment in FIGS. 1 to 6 with regard to components, features and functions that remain the same. To distinguish the exemplary embodiments, the letter a in the reference numerals of the exemplary embodiment in FIGS. 1 to 6 is replaced by the letters b to f in the reference numerals of the exemplary embodiments in FIGS. 7 to 16. With regard to components with the same designation, in particular with regard to components with the same reference symbols, reference can in principle also be made to the drawings and / or the description of the exemplary embodiment in FIGS. 1 to 6.

A further exemplary embodiment of a single-pair Ethernet device 10b is shown in FIG. The single-pair Ethernet device 10b has a bridge connector 34b. The bridge connector 34b has a first forwarding 28b. The bridge connector 34b has a second forwarding 30b. The redirects 28b, 30b are shown in more detail in FIG. The bridge connector 34b has a first conduction path 24b. The bridge connector 34b has a second conduction path 26b. The conduction paths 24b, 26b are designed as T-shaped subsections of conductor tracks of the bridge connector 34b.

A further exemplary embodiment of a single-pair Ethernet device 10c is shown in FIG. The single-pair Ethernet device 10c has a bridge connector 34c. The single-pair Ethernet device 10c is free of circuit boards. The bridge connector 34c has a first forwarding 28c. The bridging connector 34c has a second forwarding 30c. The redirects 28c, 30c are shown in more detail in FIG. The single-pair Ethernet device 10c has an adapter connector 36c. The adapter plug connector 36c is designed as a simplex plug. Alternatively, the adapter connector 36c could be designed as any other type of connector. The forwarding lines 28c, 30c are connected to the adapter plug connector 36c in an electrically conductive manner; this is shown in more detail in FIG. The adapter plug connector 36c is used to connect a plug connector which is electrically conductively connected to a device (not shown). Alternatively, the adapter connector 36c could be used for a connection to a further single-pair Ethernet conductor pair (not shown) in order to provide a branching of a daisy chain. A further exemplary embodiment of a single-pair Ethernet device 10d is shown in FIG. The single-pair Ethernet device 10d has a bridge connector 34d. The single-pair Ethernet device 10d is free of circuit boards. The single-pair Ethernet device 10d has a bridge connector 34d. The bridge connector 34d has a first forwarding 28d. The bridge connector 34d has a second forwarding 30d. The redirects 28d, 30d are shown in more detail in FIG. The single-pair Ethernet device 10d has a cable 38d. The cable 38d has two cable cores 58d. The lines 28d, 30d are electrically conductively connected to the cable cores 58d. The cable 38d has an adapter connector (not shown) at an end facing away from the bridge connector 34d. The cable 38d is electrically conductively connected to a device (not shown). Alternatively, the cable 38d could be used for a connection to a further single-pair Ethernet conductor pair (not shown) in order to provide a branching of a daisy chain.

A further exemplary embodiment of a single-pair Ethernet device 10e is shown in FIG. The single-pair Ethernet device 10e has a short-circuit plug 60e. The short-circuit plug 60e has line paths 24e, 26e, which are shown in more detail in FIG. The line paths 24e, 26e are each free of forwarding conditions. The line paths 24e, 26e are used for the direct electrically conductive connection of input contacts 12e, 14e and output contacts 18e, 20e of the short-circuit plug 60e.

In FIG. 15, a further exemplary embodiment of a single-pair Ethernet device 10f is shown schematically in an operating state. The single-pair Ethernet device 10f is part of a single-pair Ethernet system 42f. The single-pair Ethernet device 10f has a first line path 24f and a second line path 26f. The first conduction path 24f connects a first input contact 12f and a first output contact 18f in an electrically conductive manner. The second conduction path 26f connects a second input contact 14f and a second output contact 20f in an electrically conductive manner. The input contacts 12f, 14f and the output contacts 18f, 20f are designed as pins of an interrupt connector (not shown). The interruption connector can be plugged onto a chain connector of a single-pair Ethernet input conductor pair (not shown) and a single-pair Ethernet output conductor pair (not shown). Alternatively, the chain connector and the interruption connector could be formed in one piece, in particular identical to one another. The conduction paths 24f, 26f each have two spring contacts 70f, 72f, 74f, 76f. In the operating state, a first spring contact 70f and a second spring contact 72f of the first conduction path 24f and a first further spring contact 74f and a second further spring contact 76f of the second conduction path are directly connected in an electrically conductive manner. The operating state is designed as an idle state of the single-pair Ethernet device 10f. In the operational state, the interruption connector provides a short-circuit plug function analogous to the single-pair Ethernet device 10e of FIGS. 13 and 14. The single-pair Ethernet system 42f has a bridge connector 34f. The bridge connector 34f has lateral contact surfaces 62f. The contact surfaces 62f are electrically conductively connected to a device (not shown). In a further operating state different from the operating state, which is shown schematically in FIG. 16, the first conduction path 24f and the second conduction path 26f are interrupted. In the further operating state, the bridge connector 34f is plugged into the interruption connector. In the further operating state, the bridging connector 34f is arranged between the spring contacts 70f, 72f, 74f, 76f. In the further operational state, the input contacts 12f, 14f and the output contacts 18f, 20f are connected to the contact surfaces 62f in an electrically conductive manner. The bridging connector 34f has a further first conduction path 64f. In the further operating state, the further first conduction path 64f connects the first input contact 12f and the first output contact 18f in an electrically conductive manner. The bridging connector 34f has a further second conduction path 66f. In the further operating state, the further second conduction path 66f connects the second input contact 14f and the second output contact 20f in an electrically conductive manner. In the further operating state, the single-pair Ethernet device 10f provides a connection of the device to the single-pair Ethernet input conductor pair 16f and the single-pair Ethernet output conductor pair 22f. Reference number

10 single pair ethernet device

12 first input contact

14 second input contact

16 single-pair Ethernet input wire pairs

18 first output contact

20 second output contact

22 Single-pair Ethernet output wire pair

24 first line path

26 second line path

28 first forwarding

30 second forwarding

32 PCB

34 Bridge Connectors

36 adapter connectors

38 cables

40 connector housing 42 single-pair Ethernet system 44 electrical connection point 46 single-pair Ethernet cable

48 partial chain connectors

49 chain connectors

50 distributor 52 device

54 first conductor track 56 second conductor track 58 cable core 60 short-circuit plug 62 contact surface first further conduction path second further conduction path first spring contact second spring contact first further spring contact second further spring contact splitting step assembly step concatenation step connection step

Claims

Expectations

1.Single-pair Ethernet device (10a-f) with a first input contact (12a-f) and a second input contact (14a-f), which are used to make electrical contact with a single-pair Ethernet input conductor pair (16a- f) are provided with a first output contact (18a-f) and a second output contact (20a-f), which are provided for electrical contacting of a single-pair Ethernet output conductor pair (22a-f), with a first Lei processing path (24a-f) which, in at least one operating state, connects the first input contact (12a-f) to the first output contact (18a-f) in an electrically conductive manner, and to a second conduction path (26a-f), which in the operating state connects the second input contact (14a-f) to the second output contact (20a-f) in an electrically conductive manner.

2. Single-pair Ethernet device (10a-d) according to claim 1, characterized in that the first line path (24a-d) has a first forwarding (28a-d) and the second line path (26a-d) has a second Forwarding (30a-d), the forwarding (28a-d, 30a-d) being provided for an electrical connec tion with a device (52a).

3. Single-pair Ethernet device (10a) according to claim 2, characterized by a printed circuit board (32a) which has at least one of the forwarders (28a, 30a).

4. Single-pair Ethernet device (10a) according to claim 3, characterized in that the circuit board (32a) has at least one of the conduction paths (24a, 26a).

5. Single-pair Ethernet device (10b-d) according to claim 2 or 3, characterized by a bridge connector (34b-d) which has at least one of the forwarders (28b-d, 30b-d).

6. Single-pair Ethernet device (10b-d) according to claim 5, characterized in that the bridge connector (34b-d) has at least one of the Lei processing paths (24b-d, 26b-d).

7. Single-pair Ethernet device (10c) according to one of claims 2 to 6, characterized by an adapter plug connector (36c), which is part of a

Adapter and with which the forwarding lines (28c, 30c) are connected in an electrically conductive manner.

8. Single-pair Ethernet device (1 Od) according to one of claims 2 to 7, characterized by a cable (38d) with two cable cores (58d), with which the further lines (28d, 30d) are electrically conductively connected.

9. Single-pair Ethernet device (1 Oe-f) according to claim 1, characterized in that the first conduction path (24e-f) and the second conduction path (26e-f) are each free of forwarding.

10. Single-pair Ethernet device (1 Of) according to claim 1, characterized in that in at least one other different from the operating state

Operating state the first conduction path (24f) and the second conduction path (26f) are interrupted.

11. Single-pair Ethernet device (10a-f) according to one of the preceding claims, characterized by a connector housing (40a-e) which at least partially encloses the first input contact (12a-f) and the second input contact (14a-f) .

12. Single-pair Ethernet system (42a) with a single-pair Ethernet input conductor pair (16a), with a single-pair Ethernet output conductor pair (22a) and with at least one electrical connection point (44a) for contacting a Single-pair Ethernet device (10a), in particular according to one of the preceding claims, wherein the connection point (44a) with the single

Pair Ethernet input conductor pair (16a) and the single-pair Ethernet output conductor pair (22a) is connected.

13. A method for installing a single-pair Ethernet system (42a), insbesonde re according to claim 12, wherein the single-pair Ethernet system (42a) is provided in the form of a daisy chain.

14. The method according to claim 13, characterized in that a single-pair Ethernet conductor pair is divided into an unassembled single-pair Ethernet input conductor pair and an unassembled single-pair Ethernet output conductor pair and at corresponding ends of the unconfigured single -Pair Ethernet input conductor pair and the unconfected th single-pair Ethernet output conductor pair at least one connection point (44a) is field-assembled.

15. The method according to claim 13, characterized in that a pre-assembled single-pair Ethernet input conductor pair (16a) and a pre-assembled single-pair Ethernet output conductor pair (22a) are provided and each end of the single-pair Ethernet Input conductor pair (16a) and one end of the single-pair Ethernet output conductor pair (22a) are combined to form a connection point (44a).