TWM606664U - Ethernet module - Google Patents

Abstract

This creation discloses an Ethernet module, including circuit board, network transformer, power chip, Type-C socket and network chip. The network transformer includes four sets of channel units, and each set of channel units includes a pair of first differential signal pins, a pair of second differential signal pins, and two power pins. One of the first differential signal pins and one of the second differential signal pins of each channel unit is connected to the network chip; the two power pins of each channel unit are respectively connected to the power chip and the network chip; four groups of channel units The other first differential signal pin and the other second differential signal pin are respectively connected to the four sets of differential signal pairs included in the Type-C socket. The created Ethernet module has the advantage of small overall size.

Description

Ethernet module

This creation relates to a network module, especially an Ethernet network module.

The existing Ethernet module basically uses RJ45 sockets to provide users with a network connection route. Because the RJ45 socket has a predetermined size specification, it is difficult to reduce the size of the entire Ethernet module.

This creation discloses an Ethernet module, which is mainly used to improve the existing Ethernet module using RJ45 sockets. Because RJ45 sockets have established size specifications, it is difficult to reduce the size of the entire Ethernet module problem.

One of the embodiments of the present invention discloses an Ethernet module, which includes: a circuit board, a LAN transformer, a power chip, a Type-C socket, and a PHY Chip . The network transformer is fixed on the circuit board. The network transformer includes a transformer body and four sets of channel units. Each set of channel units has six pins. The six pins included in each set of channel units are defined as a first power supply. Pins, a second power supply pin, a first positive differential signal pin, a first negative differential signal pin, a second positive differential signal pin, and a second negative differential signal pin. The power chip is fixedly arranged on the circuit board, and the power chip is connected with the first power pins included in each group of channel units of the network transformer. The Type-C socket is fixedly arranged on the circuit board. The Type-C socket includes a socket body and 24 connection pins. The socket body has a jack, and 8 connection pins are defined as a first positive differential signal sending pin. , A first negative differential signal sending pin, a first positive differential signal receiving pin, a first negative differential signal receiving pin, a second positive differential signal sending pin, a second negative differential signal sending pin , A second positive differential signal receiving pin and a second negative differential signal receiving pin. Among them, the four channel units are respectively defined as a first channel unit, a second channel unit, a third channel unit, and a fourth channel unit, the first positive differential signal sending pin and the first negative differential signal sending pin The first positive differential signal pin and the first negative differential signal pin of the first channel unit are respectively connected; the first positive differential signal receiving pin and the first negative differential signal receiving pin are respectively connected to the first positive differential signal pin of the second channel unit The differential signal pin and the first negative differential signal pin; the second positive differential signal sending pin and the second negative differential signal sending pin are respectively connected to the first positive differential signal pin and the first negative differential signal of the third channel unit Pin; the second positive differential signal receiving pin and the second negative differential signal receiving pin are respectively connected to the first positive differential signal pin and the first negative differential signal pin of the fourth channel unit. The network chip is fixedly arranged on the circuit board, and the network chip is connected with the second power pin, the second positive differential signal pin and the second negative differential signal pin included in each group of channel units of the network transformer.

One of the embodiments of this creation discloses an Ethernet module, which includes: a circuit board, a LAN transformer, a Type-C socket, a power chip, and a network chip (PHY Chip) . The network transformer is fixed on the circuit board. The network transformer includes a transformer body and four sets of channel units. Each set of channel units has six pins. The six pins included in each set of channel units are defined as a ground pin. , A power supply pin, a first positive differential signal pin, a first negative differential signal pin, a second positive differential signal pin, and a second negative differential signal pin. The Type-C socket is fixedly arranged on the circuit board. The Type-C socket includes a socket body and 24 connection pins. The socket body has a jack, and 8 connection pins are defined as a first positive differential signal sending pin. , A first negative differential signal sending pin, a first positive differential signal receiving pin, a first negative differential signal receiving pin, a second positive differential signal sending pin, a second negative differential signal sending pin , A second positive differential signal receiving pin and a second negative differential signal receiving pin, of which 4 connection pins are all defined as a bus power pin. Among them, the four channel units are respectively defined as a first channel unit, a second channel unit, a third channel unit, and a fourth channel unit, the first positive differential signal sending pin and the first negative differential signal sending pin The first positive differential signal pin and the first negative differential signal pin of the first channel unit are respectively connected; the first positive differential signal receiving pin and the first negative differential signal receiving pin are respectively connected to the first positive differential signal pin of the second channel unit The differential signal pin and the first negative differential signal pin; the second positive differential signal sending pin and the second negative differential signal sending pin are respectively connected to the first positive differential signal pin and the first negative differential signal of the third channel unit Pin; the second positive differential signal receiving pin and the second negative differential signal receiving pin are respectively connected to the first positive differential signal pin and the first negative differential signal pin of the fourth channel unit. The power chip is fixedly arranged on the circuit board, and the power chip is connected with the four bus power pins of the Type-C socket. The network chip is fixedly arranged on the circuit board, and the network chip is connected with the power pins, the second positive differential signal pins and the second negative differential signal pins included in each group of channel units of the network transformer.

One of the embodiments of this creation discloses an Ethernet module, which includes: a circuit board, a LAN transformer, a Type-C socket, a power chip, and a network chip (PHY Chip) . The network transformer is fixed on the circuit board. The network transformer includes a transformer body and four sets of channel units. Each set of channel units has six pins. The six pins included in each set of channel units are defined as a first power supply. Pins, a second power supply pin, a first positive differential signal pin, a first negative differential signal pin, a second positive differential signal pin, and a second negative differential signal pin. The Type-C socket is fixedly arranged on the circuit board. The Type-C socket includes a socket body and 24 connection pins. The socket body has a jack, and 8 connection pins are defined as a first positive differential signal sending pin. , A first negative differential signal sending pin, a first positive differential signal receiving pin, a first negative differential signal receiving pin, a second positive differential signal sending pin, a second negative differential signal sending pin , A second positive differential signal receiving pin and a second negative differential signal receiving pin, of which 4 connection pins are all defined as a bus power pin. Among them, the four channel units are respectively defined as a first channel unit, a second channel unit, a third channel unit, and a fourth channel unit, the first positive differential signal sending pin and the first negative differential signal sending pin The first positive differential signal pin and the first negative differential signal pin of the first channel unit are respectively connected; the first positive differential signal receiving pin and the first negative differential signal receiving pin are respectively connected to the first positive differential signal pin of the second channel unit The differential signal pin and the first negative differential signal pin; the second positive differential signal sending pin and the second negative differential signal sending pin are respectively connected to the second positive differential signal pin and the second negative differential signal of the third channel unit Pin; the second positive differential signal receiving pin and the second negative differential signal receiving pin are respectively connected to the second positive differential signal pin and the second negative differential signal pin of the fourth channel unit. The power chip is fixedly arranged on the circuit board, the power chip is connected with the four bus power pins of the Type-C socket, and the power chip is connected with the first power pins of each group of channel units. The network chip is fixedly arranged on the circuit board, and the network chip is connected with the second ground pin, the second positive differential signal pin and the second negative differential signal pin included in each group of channel units of the network transformer.

In summary, the Ethernet module created by this creation uses Type-C sockets to replace the RJ45 sockets of the conventional Ethernet modules, which can greatly reduce the overall size of the Ethernet module.

In order to have a better understanding of the features and technical content of this creation, please refer to the following detailed descriptions and drawings about this creation, but these descriptions and drawings are only used to illustrate this creation, and not for any protection scope of this creation. limit.

In the following description, if it is pointed out, please refer to the specific drawing or as shown in the specific drawing, it is only used to emphasize in the subsequent description, and most of the related content appears in the specific drawing. However, it is not limited that only the specific drawings can be referred to in the subsequent description.

Please refer to FIG. 1 and FIG. 2 together. FIG. 1 shows a schematic diagram of the created Ethernet module 100, and FIG. 3 shows a block diagram of the created Ethernet module 100. The Ethernet module 100 includes: a circuit board 1, a LAN transformer 2, a power chip 3, a Type-C socket 4, and a network chip (PHY Chip) 5. The network transformer 2, the power chip 3, the Type-C socket 4 and the network chip 5 are fixedly arranged on the circuit board 1. In practical applications, the operating frequency band of the Ethernet module 100 created by this invention is between 1MHz and 500MHz, and the input impedance is between 93.5Ω and 126.5Ω.

The network transformer 2 includes a transformer body 20 and four sets of channel units (labeled as a first channel unit 21A, a second channel unit 21B, a third channel unit 21C, and a fourth channel unit 21D in FIGS. 1 and 2), each The group channel unit has six pins. The six pins included in each group of channel units are respectively defined as a first power pin 211, a second power pin 212, a first positive differential signal pin 213, a first negative differential signal pin 214, A second positive differential signal pin 215 and a second negative differential signal pin 216. The first power pin 211 and the second power pin 212 are arranged on opposite sides of the transformer body 20, and the first positive differential signal pin 213 and the second positive differential signal pin 215 are arranged on the transformer body 20 opposite to each other. The first negative differential signal pin 214 and the second negative differential signal pin 216 are arranged on opposite sides of the transformer body 20, the first power pin 211, the first positive differential signal pin 213 and the first The negative differential signal pin 214 is arranged on the same side of the transformer body 20, and the second power pin 212, the second positive differential signal pin 215 and the second negative differential signal pin 216 are arranged on the same side of the transformer body 20. In practical applications, each group of channel units can be signaled through the first positive differential signal pin 213, the first negative differential signal pin 214, the second positive differential signal pin 215, and the second negative differential signal pin 216. And the four groups of channel units can be used for signal transmission through multiple pins contained in them at the same time.

The power chip 3 is connected to the first power pins 211 of each group of channel units of the network transformer 2. In practical applications, the circuit board 1 can also be provided with a power socket (not shown), the power socket is electrically connected to the power chip 3, and the power socket is used to provide a wire insertion, and is independent of the Ethernet module 100 The power supply of the Type-C socket 4 and the network chip 5 can provide power to the power chip 3 through wires and power sockets. The power chip 3 can convert voltage and current to provide the power required by the Type-C socket 4 and the network chip 5 in operation.

As shown in Figures 1 to 3, Figure 3 shows the front view of the Type-C socket 4 created by this invention. The Type-C socket 4 includes a socket body 40 and 24 connection pins. The definition of the 24 connection pins of the Type-C socket 4 referred to in the following embodiments is in accordance with the specifications of the USB Implementers Forum (USB-IF), and the Type-C socket 4 referred to below is Comply with the relevant specifications of the USB Standardization Organization United States (USB-IF).

The socket body 40 has a socket 401 for inserting a connection wire with a Type-C connector. One end of each connection pin is located in the socket 401, and the other end of each connection pin is fixed to the circuit board 1. 24 Eight of the connection pins are defined as a first positive differential signal sending pin 41, a first negative differential signal sending pin 42, a first positive differential signal receiving pin 43, and a first Negative differential signal receiving pin 44, a second positive differential signal sending pin 45, a second negative differential signal sending pin 46, a second positive differential signal receiving pin 47, and a second negative differential signal receiving pin 48.

The first positive differential signal sending pin 41, the first negative differential signal sending pin 42, the second positive differential signal receiving pin 47, and the second negative differential signal receiving pin 48 are located on one side of the jack 401. The differential signal receiving pin 43, the first negative differential signal receiving pin 44, the second positive differential signal sending pin 45, and the second negative differential signal sending pin 46 are located on the other side of the jack 401, and the first positive differential signal The signal transmitting pin 41 and the first positive differential signal receiving pin 43 are arranged facing each other, the first negative differential signal transmitting pin 42 and the first negative differential signal receiving pin 44 are arranged facing each other, and the second The positive differential signal transmitting pin 45 and the second positive differential signal receiving pin 47 are disposed facing each other, and the second negative differential signal transmitting pin 46 and the second negative differential signal receiving pin 48 are disposed facing each other.

The four channel units are respectively defined as a first channel unit 21A, a second channel unit 21B, a third channel unit 21C, and a fourth channel unit 21D, the first positive differential signal sending pin 41 and the first negative differential signal The sending pin 42 is respectively connected to the first positive differential signal pin 213 and the first negative differential signal pin 214 of the first channel unit 21A; the first positive differential signal receiving pin 43 and the first negative differential signal receiving pin 44 are respectively Connect the first positive differential signal pin 213 and the first negative differential signal pin 214 of the second channel unit 21B; the second positive differential signal sending pin 45 and the second negative differential signal sending pin 46 are respectively connected to the third channel unit The first positive differential signal pin 213 and the first negative differential signal pin 214 of 21C; the second positive differential signal receiving pin 47 and the second negative differential signal receiving pin 48 are respectively connected to the first positive of the fourth channel unit 21D The differential signal pin 213 and the first negative differential signal pin 214. In practical applications, the various connection pins of the Type-C socket 4 may be connected to the related pins of the channel units of the network transformer 2 through related conductive lines located on the surface or inner layer of the circuit board 1, for example. Sexual connection.

The network chip 5 is connected to the second power pin 212, the second positive differential signal pin 215, and the second negative differential signal pin 216 included in each group of channel units of the network transformer 2. In practical applications, the network chip 5 can be connected to the second power pin 212 and the second positive differential signal pin included in each group of channel units through related conductive lines located on the surface or inner layer of the circuit board 1. 215 and the second negative differential signal pin 216 are electrically connected.

Please refer to FIG. 4, which shows a schematic diagram of the second embodiment of the Ethernet network created by this invention. The biggest difference between this embodiment and the aforementioned first embodiment (as shown in FIG. 2) is that the Ethernet module 100 may also include a filter circuit 6, which is fixedly arranged on the circuit board 1 (as shown in FIG. 1). Show), the filter circuit 6 is connected to the first positive differential signal pin 213 and the first negative differential signal pin 214 of each group of channel units of the network transformer 2, and the filter circuit 6 is connected to the first positive differential signal of the Type-C socket 4. Signal sending pin 41, first negative differential signal sending pin 42, first positive differential signal receiving pin 43, first negative differential signal receiving pin 44, second positive differential signal sending pin 45, second negative differential The signal sending pin 46, the second positive differential signal receiving pin 47 and the second negative differential signal receiving pin 48, and the filter circuit 6 is used to filter the signal transmitted between the network transformer 2 and the Type-C socket 4 In order to improve the transmission quality of the signal.

Please refer to FIG. 5, which shows a schematic diagram of the third embodiment of the Ethernet network created by this invention. The biggest difference between this embodiment and the aforementioned first embodiment (as shown in FIG. 2) is that two of the pins of each group of channel units are defined as a ground pin 217 and a power pin 218, and the ground connection Pin 217 is used for grounding, power pin 218 is connected to network chip 5; four of the connection pins of Type-C socket 4 are defined as bus power pins 49, and four bus power pins 49 are connected to power Wafer 3. In other words, in this embodiment, one of the first power pins 211 included in each group of channel units in the first embodiment (as shown in FIG. 2) used to connect to the power chip 3 is changed to ground In this embodiment, the aforementioned power chip 3 (as shown in FIG. 2) is changed to four bus power pins 49 connected to the Type-C socket 4.

Please refer to FIG. 6, which shows a schematic diagram of the fourth embodiment of the Ethernet network created by this invention. The biggest difference between this embodiment and the aforementioned third embodiment (as shown in FIG. 5) is that the Ethernet module 100 may also include a filter circuit 6, which is fixedly disposed on the circuit board 1 (as shown in FIG. 1). Show), the filter circuit 6 is connected to the first positive differential signal pin 213 and the first negative differential signal pin 214 of each group of channel units of the network transformer 2, and the filter circuit 6 is connected to the first positive differential signal of the Type-C socket 4. Signal sending pin 41, first negative differential signal sending pin 42, first positive differential signal receiving pin 43, first negative differential signal receiving pin 44, second positive differential signal sending pin 45, second negative differential The signal sending pin 46, the second positive differential signal receiving pin 47 and the second negative differential signal receiving pin 48, and the filter circuit 6 is used to filter the signal transmitted between the network transformer 2 and the Type-C socket 4 The noise in order to improve the transmission quality of the signal.

Please refer to FIG. 7, which shows a schematic diagram of the fifth embodiment of the Ethernet network created by this invention. The biggest difference between this embodiment and the foregoing first embodiment (as shown in FIG. 2) is that the power chip 3 is also connected to four connection pins of the Type-C socket 4 defined as bus power pins 49. That is, the power chip 3 of this embodiment is connected to the first power pin 211 of each group of channel units of the network transformer 2 and the four bus power pins 49 of the Type-C socket 4 at the same time.

Please refer to FIG. 8, which shows a schematic diagram of the sixth embodiment of the Ethernet network created by this invention. The biggest difference between this embodiment and the aforementioned fifth embodiment (as shown in FIG. 7) is that the Ethernet module 100 may also include a power shunt circuit 7, which is fixedly arranged on the circuit board 1 (as shown in FIG. 1) . The power chip 3 is connected to the power shunt circuit 7, and the power shunt circuit 7 is connected to the first power pin 211 of each channel unit of the network transformer 2 and the four bus power pins 49 of the Type-C socket 4 at the same time. , The power chip 3 appropriately distributes power to the network transformer 2 and the Type-C socket 4 through the power shunt circuit 7.

Please refer to FIG. 9, which shows a schematic diagram of the seventh embodiment of the Ethernet network created by this invention. The biggest difference between this embodiment and the aforementioned sixth embodiment (as shown in FIG. 8) is that the Ethernet module 100 may also include a filter circuit 6. The filter circuit 6 is fixedly arranged on the circuit board 1, and the filter circuit 6 is connected. The first positive differential signal pin 213 and the first negative differential signal pin 214 of each group of channel units of the network transformer 2, and the filter circuit 6 is connected to the first positive differential signal sending pin 41 and the first positive differential signal pin 41 of the Type-C socket 4. A negative differential signal sending pin 42, a first positive differential signal receiving pin 43, a first negative differential signal receiving pin 44, a second positive differential signal sending pin 45, a second negative differential signal sending pin 46, Two positive differential signal receiving pins 47 and a second negative differential signal receiving pin 48, and the filter circuit 6 is used to filter the noise of the signal transmitted between the network transformer 2 and the Type-C socket 4, thereby improving Signal transmission quality

It is worth mentioning that the Ethernet module 100 mentioned in the above embodiments can be implemented by adjusting the material of the winding coil, the wire diameter of the winding coil, and the winding of the winding coil in the network transformer 2. The way, the number of turns of the winding coil, the material of the iron core, the inner diameter of the iron core, the outer diameter of the iron core, etc., to achieve impedance matching between the network transformer 2 and the Type-C socket 4, thereby improving the second The overall transmission performance of the Ethernet module 100. In addition, the user can connect to the created Ethernet module 100 through a cable with a Type-C connector, and thereby connect to the Internet.

Specifically, in practical applications, the Type-C socket 4 referred to in the foregoing embodiments includes four ground pins (GND), two configuration channel (Configuration channel) pins (CC1, CC2), The two Side Band Use pins (SBU1, SBU2) and the two USB2.0 differential signal pair pins (Dp1, Dn2, Dn1, Dp2) are grounded. In addition, in specific applications, two configuration channel (Configuration channel) pins (CC1, CC2) and two side band use pins (SBU1, SBU2) can be used according to impedance matching requirements. And two sets of USB2.0 differential signal pair pins (Dp1, Dn2, Dn1, Dp2) are connected to a 50 ohm resistor and then grounded.

The above descriptions are only the preferred and feasible embodiments of this creation, which do not limit the scope of patents of this creation. Therefore, all equivalent technical changes made using this creation specification and schematic content are included in the protection scope of this creation .

100: Ethernet module 1: circuit board 2: Network transformer 20: Transformer body 21A: The first channel unit 21B: The second channel unit 21C: The third channel unit 21D: The fourth channel unit 211: The first power pin 212: second power pin 213: The first positive differential signal pin 214: The first negative differential signal pin 215: second positive differential signal pin 216: second negative differential signal pin 217: Ground pin 218: power pin 3: Power chip 4: Type-C socket 40: Socket body 401: Jack 41: The first positive differential signal sending pin 42: The first negative differential signal sending pin 43: The first positive differential signal receiving pin 44: The first negative differential signal receiving pin 45: The second positive differential signal sending pin 46: The second negative differential signal sending pin 47: The second positive differential signal receiving pin 48: The second negative differential signal receiving pin 49: bus power pin 5: Network chip 6: Filter circuit 7: Power shunt circuit

Fig. 1 shows a three-dimensional schematic diagram of the first embodiment of the created Ethernet module.

Figure 2 shows a block diagram of the first embodiment of the created Ethernet module.

Figure 3 shows the front view of the Type-C socket of the Ethernet module created for this creation.

FIG. 4 shows a block diagram of the second embodiment of the Ethernet module created by this invention.

Fig. 5 shows a block diagram of the third embodiment of the presently created Ethernet module.

FIG. 6 shows a block diagram of the fourth embodiment of the Ethernet module created by this invention.

FIG. 7 shows a block diagram of the fifth embodiment of the Ethernet module created by this invention.

FIG. 8 shows a block diagram of the sixth embodiment of the Ethernet module created by this invention.

FIG. 9 shows a block diagram of the seventh embodiment of the Ethernet module created by this invention.

2: Network transformer

21A: The first channel unit

21B: The second channel unit

21C: The third channel unit

21D: The fourth channel unit

211: The first power pin

212: second power pin

213: The first positive differential signal pin

214: The first negative differential signal pin

215: second positive differential signal pin

216: second negative differential signal pin

3: Power chip

4: Type-C socket

41: The first positive differential signal sending pin

42: The first negative differential signal sending pin

43: The first positive differential signal receiving pin

44: The first negative differential signal receiving pin

45: The second positive differential signal sending pin

46: The second negative differential signal sending pin

47: The second positive differential signal receiving pin

48: The second negative differential signal receiving pin

5: Network chip

Claims (7)

An Ethernet module, which includes: A circuit board; A LAN transformer, which is fixedly arranged on the circuit board, the network transformer includes a transformer body and four groups of channel units, each group of the channel unit has six pins, and each group of the channels The six pins included in the unit are respectively defined as a first power pin, a second power pin, a first positive differential signal pin, a first negative differential signal pin, and a second positive differential signal pin. Signal pin and a second negative differential signal pin; A power chip, which is fixedly arranged on the circuit board, and the power chip is connected to the first power pins included in each group of the channel units of the network transformer; A Type-C socket, which is fixedly arranged on the circuit board, the Type-C socket includes a socket body and 24 connecting pins, the socket body has a jack, and 8 of the connecting pins are respectively Defined as a first positive differential signal sending pin, a first negative differential signal sending pin, a first positive differential signal receiving pin, a first negative differential signal receiving pin, and a second positive differential signal sending pin Pin, a second negative differential signal sending pin, a second positive differential signal receiving pin, and a second negative differential signal receiving pin; Wherein, the four channel units are respectively defined as a first channel unit, a second channel unit, a third channel unit and a fourth channel unit, the first positive differential signal sending pin and the first The negative differential signal sending pin is respectively connected to the first positive differential signal pin and the first negative differential signal pin of the first channel unit; the first positive differential signal receiving pin and the first negative differential signal The signal receiving pins are respectively connected to the first positive differential signal pin and the first negative differential signal pin of the second channel unit; the second positive differential signal sending pin and the second negative differential signal The signal sending pins are respectively connected to the first positive differential signal pin and the first negative differential signal pin of the third channel unit; the second positive differential signal receiving pin and the second negative differential signal Signal receiving pins are respectively connected to the first positive differential signal pin and the first negative differential signal pin of the fourth channel unit; A network chip (PHY Chip), which is fixedly arranged on the circuit board, the second power pin and the second power pin included in each group of the channel unit of the network transformer Two positive differential signal pins and the second negative differential signal pin are connected. The Ethernet module according to claim 1, wherein the Ethernet module further includes a filter circuit fixedly arranged on the circuit board, and the filter circuit is connected to the network transformer The first positive differential signal pin and the first negative differential signal pin of each group of the channel units, and the filter circuit is connected to the first positive differential signal sending pin of the Type-C socket , The first negative differential signal sending pin, the first positive differential signal receiving pin, the first negative differential signal receiving pin, the second positive differential signal sending pin, the second negative A differential signal sending pin, the second positive differential signal receiving pin, and the second negative differential signal receiving pin. An Ethernet module, which includes: A circuit board; A LAN transformer, which is fixedly arranged on the circuit board, the network transformer includes a transformer body and four groups of channel units, each group of the channel unit has six pins, and each group of the channels The six pins included in the unit are respectively defined as a ground pin, a power pin, a first positive differential signal pin, a first negative differential signal pin, a second positive differential signal pin, and A second negative differential signal pin; the ground pin is used for grounding; A Type-C socket, which is fixedly arranged on the circuit board, the Type-C socket includes a socket body and 24 connecting pins, the socket body has a jack, and 8 of the connecting pins are respectively Defined as a first positive differential signal sending pin, a first negative differential signal sending pin, a first positive differential signal receiving pin, a first negative differential signal receiving pin, and a second positive differential signal sending pin Pin, a second negative differential signal sending pin, a second positive differential signal receiving pin, and a second negative differential signal receiving pin, where four of the connection pins are all defined as a bus power pin; Wherein, the four channel units are respectively defined as a first channel unit, a second channel unit, a third channel unit and a fourth channel unit, the first positive differential signal sending pin and the first The negative differential signal sending pin is respectively connected to the first positive differential signal pin and the first negative differential signal receiving pin of the first channel unit; the first positive differential signal receiving pin and the first negative The differential signal receiving pins are respectively connected to the first positive differential signal pins and the first negative differential signal pins of the second channel unit; the second positive differential signal sending pins and the second negative The differential signal sending pins are respectively connected to the first positive differential signal pins and the first negative differential signal pins of the third channel unit; the second positive differential signal receiving pins and the second negative Differential signal receiving pins are respectively connected to the first positive differential signal pins and the first negative differential signal pins of the fourth channel unit; A power chip, which is fixedly arranged on the circuit board, and the power chip is connected to the four bus power pins of the Type-C socket; A network chip (PHY Chip), which is fixedly arranged on the circuit board, the power pins and the second positive pins included in the channel units of the network chip and the network transformer The differential signal pin is connected to the second negative differential signal pin. The Ethernet module according to claim 3, wherein the Ethernet module further includes a filter circuit fixedly arranged on the circuit board, and the filter circuit is connected to the network transformer The first positive differential signal pin and the first negative differential signal pin of each group of the channel units, and the filter circuit is connected to the first positive differential signal sending pin of the Type-C socket , The first negative differential signal sending pin, the first positive differential signal receiving pin, the first negative differential signal receiving pin, the second positive differential signal sending pin, the second negative A differential signal sending pin, the second positive differential signal receiving pin, and the second negative differential signal receiving pin. An Ethernet module, which includes: A circuit board; A LAN transformer, which is fixedly arranged on the circuit board, the network transformer includes a transformer body and four groups of channel units, each group of the channel unit has six pins, and each group of the channels The six pins included in the unit are respectively defined as a first power pin, a second power pin, a first positive differential signal pin, a first negative differential signal pin, and a second positive differential signal pin. Signal pin and a second negative differential signal pin; A Type-C socket, which is fixedly arranged on the circuit board, the Type-C socket includes a socket body and 24 connecting pins, the socket body has a jack, and 8 of the connecting pins are respectively Defined as a first positive differential signal sending pin, a first negative differential signal sending pin, a first positive differential signal receiving pin, a first negative differential signal receiving pin, and a second positive differential signal sending pin Pin, a second negative differential signal sending pin, a second positive differential signal receiving pin, and a second negative differential signal receiving pin, where four of the connection pins are all defined as a bus power pin; Wherein, the four channel units are respectively defined as a first channel unit, a second channel unit, a third channel unit and a fourth channel unit, the first positive differential signal sending pin and the first The negative differential signal sending pin is respectively connected to the first positive differential signal pin and the first negative differential signal pin of the first channel unit; the first positive differential signal receiving pin and the first The negative differential signal receiving pin is respectively connected to the first positive differential signal pin and the first negative differential signal pin of the second channel unit; the second positive differential signal sending pin and the second The negative differential signal sending pin is respectively connected to the first positive differential signal pin and the first negative differential signal pin of the third channel unit; the second positive differential signal receiving pin and the second The negative differential signal receiving pins are respectively connected to the first positive differential signal pins and the first negative differential signal pins of the fourth channel unit; A power chip, which is fixedly arranged on the circuit board, the power chip is connected to the four bus power pins of the Type-C socket, and the power chip is connected to each group of the channel unit The first power pin is connected; A network chip (PHY Chip), which is fixedly arranged on the circuit board, the second power pin and the second power pin included in each group of the channel unit of the network transformer Two positive differential signal pins and the second negative differential signal pin are connected. The Ethernet module according to claim 5, wherein the Ethernet module further includes a filter circuit fixedly arranged on the circuit board, and the filter circuit is connected to the network transformer The first positive differential signal pin and the first negative differential signal pin of each group of the channel units, and the filter circuit is connected to the first positive differential signal sending pin of the Type-C socket , The first negative differential signal sending pin, the first positive differential signal receiving pin, the first negative differential signal receiving pin, the second positive differential signal sending pin, the second negative A differential signal sending pin, the second positive differential signal receiving pin, and the second negative differential signal receiving pin. The Ethernet module according to claim 5, wherein the Ethernet module further includes a power shunt circuit fixedly arranged on the circuit board, the power shunt circuit and the power chip Are connected to each other, and the power shunt circuit is connected to the first positive differential signal sending pin, the first negative differential signal sending pin, the first positive differential signal receiving pin of the Type-C socket, The first negative differential signal receiving pin, the second positive differential signal sending pin, the second negative differential signal sending pin, the second positive differential signal receiving pin, and the second negative differential Signal receiving pin.

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