JP2017069916A - Power line communication module - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a power line communication module capable of eliminating a design load on a user in installing the module.SOLUTION: A power line communication module 1 includes a PLC/AC superposition circuit 10, a HD-PLC operation circuit 20, and a power supply circuit 30, on a board on which a connector pin 41 for connecting with an AC line 3 and a connector pin 42 for connecting with a mother board 2 are provided. The power supply circuit 30 supplies a plurality of voltages to the HD-PLC operation circuit 20 in order to drive components of the HD-PLC operation circuit 20. The HD-PLC operation circuit 20 comprises a base band 21, a drive amplifier 22, a BPF 23, a FlashROM 24, and an XTAL 25 in order to transmit/receive a PLC signal.SELECTED DRAWING: Figure 3

Description

  The present invention relates to a power line communication module.

  There is an increasing demand for services using communication in buildings such as smart houses. However, radio waves may not reach due to the structure of buildings such as steel bars and stone. When wireless radio waves do not reach, wire connection (telephone line communication) is sometimes used to construct the line, but the line work requires a meeting and is troublesome.

  For this reason, power line communication has been proposed in place of telephone line connection requiring construction. As power line communication, for example, HD-PLC (registered trademark), home plug (registered trademark), and the like are disclosed. An HD-PLC product as an example of such power line communication includes a master (master unit) and a slave (slave unit), and can perform bidirectional communication.

  FIG. 1 illustrates an example in which an air conditioner is used as a slave unit as an example of a PLC product. The Host device 500 (for example, a personal computer) is connected to the HD-PLC product 400 (master) via a LAN or a serial port 410 (for example, RS232 standard (Recommended Standard 232 or the like)).

  In FIG. 1, an air conditioner motherboard 200 is provided with an air conditioner CPU 210 and an HD-PLC operation circuit 221 provided in an HD-PLC product 220 (slave). Furthermore, in order to connect the HD-PLC operation circuit 221 and the AC line 310, a superimposing circuit 230 for superposing a high frequency on the power from the AC line 310 is installed externally (for example, Patent Document 1).

  With such a configuration, when operating on the host device 500, the signal reaches the CPU 210 on the air conditioner side through the HD-PLC products 220 and 400 and the power lines 330, 320, and 310, and the air conditioner operation can be performed via the power line. become.

Japanese Patent Laying-Open No. 2015-070511

  When using the HD-PLC module as described above, it is necessary to externally design a circuit for superimposing the power line (AC) and the PLC signal on the motherboard. In order to design a PLC / AC superposition circuit, special know-how is required, such as using pattern wiring to make it less susceptible to noise, and using parts with characteristics designed for PLC communication. Therefore, the design load is heavy for users who do not have PLC technology.

  SUMMARY OF THE INVENTION In view of the above circumstances, an object of the present invention is to provide a power line communication module that solves the above-described problems and eliminates a user's design load during installation.

  In order to solve the above problems, according to one aspect of the present invention, a power line communication module (1) includes a power line communication operation circuit (20) that provides power and electronic communication, a power line (3), and a power line communication operation circuit ( 20) and a superimposing circuit (10) for superimposing a high frequency on the power from the power line (3).

  In addition, the said reference code is a reference to the last, and description of a claim is not limited by this.

  According to one aspect of the present invention, it is possible to eliminate a user's circuit design load when installing a power line communication module.

It is explanatory drawing of the system by which the power line communication board | substrate of a prior art example is arrange | positioned. It is the schematic of the power line communication module which concerns on one Embodiment of this invention. It is a block diagram of the power line communication module which concerns on one Embodiment of this invention. It is a circuit diagram of the superposition circuit arrange | positioned at the power line communication module which concerns on one Embodiment of this invention. FIG. 5 is a layout diagram showing positions of components in the superposition circuit of FIG. 4 on the substrate of the power line communication module. (A) is an example of a wiring pattern on the front substrate of the superimposed circuit in FIG. 5, and (B) is an exemplary wiring pattern on the substrate on the back side of the superimposed circuit. (A) is an example of the wiring pattern in the board | substrate on the front side of the communication operation circuit and power supply circuit of the power line communication module which concerns on one Embodiment of this invention, (B) is an example of the wiring pattern in the board | substrate of the back side.

  Hereinafter, embodiments for carrying out the present invention will be described with reference to the drawings. In the drawings, the same components are denoted by the same reference numerals, and redundant description may be omitted.

  In the following embodiment, an HD-PLC will be described as an example of a power line. However, the method of mounting the power line communication module according to the present invention is not limited to the HD-PLC standardized in Japan, and is not limited to the US / Europe. Standard home plugs (HOME PLUG) frequently used in China, Chinese standard IGRS (Intelligent Grouping and Resource Sharing), and the like may be used.

  FIG. 2 shows a schematic diagram of a power line communication module according to an embodiment of the present invention.

  As shown in FIG. 2, in the embodiment of the present invention, a superimposing circuit for superimposing a power line and a PLC signal line necessary for HD-PLC is provided on the power line communication module.

  Therefore, when the present invention is used, a user (for example, an electric wiring person or the like) simply connects the output portion (of the superimposed circuit) of the power line communication module 1 to the AC line 3 on the mother board 2 with the connector pin 41, and the device ( A power line communication function can be added to an air conditioner or the like.

  In FIG. 2, an AC line (power line) 3 and a power line communication module 1 (for example, HD-PLC side module) are connected by a connector pin (pin header connector) 41, and a PLC signal (high frequency signal) and an AC signal (AC voltage) are connected. Input / output.

  In the power line communication module 1, the PLC / AC superimposing circuit (superimposing circuit) 10 couples (superimposes) the PLC signal and the AC signal (power). The coupled PLC signal is input to an HD-PLC operation circuit (power line communication operation circuit) 20.

  The HD-PLC operation circuit 20 transmits in a waveband OFDM (HD-PLC side module has 2-4 PAM (pulse amplitude modulation)) transmission system in a frequency band of 2 to 28 MHz (provides power and electronic communication). Wavelet OFDM is an OFDM (Division Multiplexing Communication) modulation method using Wavelet transform that has the property of being orthogonal on both the time axis and the frequency axis.

  In addition, although the embodiment of the present invention is mounted and an air conditioner is described as an example in which power and electronic communication are provided, the mounting example of the present invention is not limited to an air conditioner. For example, the power line communication module of the present invention is mounted on a motherboard that controls the power supply of hot water supply systems, surveillance cameras, solar power generation systems, lighting equipment, electrical appliances (washing machines installed in houses, refrigerators, etc.), household fuel cells, etc. can do.

  Moreover, you may use for "EoC" (Ethernet (trademark) over Coaxial cable) which connects to the internet using the coaxial cable for televisions. You may mount in the motherboard of the electric power supply system to an electric vehicle. In addition, use of power lines in systems such as multimedia distribution (IPTV) by broadband, Smart Grid, smart meter, Home Energy Management System (HEMS), Building Energy Management System (BEMS), and Mansion Energy Management System (MEMS) The power line communication module of the present invention may be applied.

  FIG. 3 is a block diagram of a power line communication module according to an embodiment of the present invention. As shown in FIG. 3, the power line communication module 1 is provided with a PLC / AC superposition circuit 10, an HD-PLC operation circuit 20, and a power supply circuit 30 on a substrate B. On the board B, connector pins 41 for connecting to the AC line 3 and connector pins 42 for connecting to the mother board 2 are provided.

  The power supply circuit 30 supplies a plurality of voltages to the HD-PLC operation circuit 20 in order to drive the components of the HD-PLC operation circuit 20.

  As shown in FIG. 3, the HD-PLC operation circuit 20 includes a baseband 21, a driver amplifier 22, a bandpass filter (BPF) 23, a FlashROM 24, an XTAL 25, and the like for transmitting and receiving PLC signals.

  The baseband (BASEBAND) 21 includes an AFE (Analog Front End) 26 and a RAM (Random Access Memory) 27. The baseband 21 is a waveform adjustment circuit that adjusts a waveform and processes a signal with respect to a waveform before modulation for transmission and a band of a received information signal after demodulation. The waveform adjustment circuit includes a transmission side drive circuit and a reception side drive circuit.

  The AFE 26 adjusts an analog signal input from the motherboard CPU 201. The RAM 27 temporarily stores information necessary for signal adjustment and signal processing in the baseband 21 and the AFE 26. Note that the baseband 21 may further include an SDRAM (Synchronous Dynamic Random Access Memory) that operates in synchronization with a clock signal of a fixed period of the system bus.

  The driver amplifier 22 amplifies the signal output from the baseband 21 and excites it to a high frequency.

  The BPF 23 includes an inductor, a capacitor, and the like. After receiving the PLC / AC from the AC line 3, the noise-carrying waveform passes through the BPF 23, so that only the waveform of a specific frequency band related to the PLC is extracted, and the normal power (alternating current) is removed. It is burned.

  A filter used in the BPF 23 is, for example, a SAW filter. SAW filter (Surface Acoustic Wave (SAW) filters the desired frequency used for communication using surface waves propagating on a piezoelectric substrate on which comb-shaped electrodes included in the SAW filter are formed. After that, the BPF filter circuit can be downsized and improved in performance by using the SAW filter.

  Here, in the block diagram and the layout diagram, an example in which one filter is mounted has been described. However, a plurality of SAW filters having different frequency bands may be mounted to increase the number of bands so as to correspond to a plurality of countries. .

  As a method for separating transmission and reception, in the baseband 21, the transmission enable signal and the reception enable signal are individually separated and output, and the driver amplifier 22 or the BPF 23 is driven in accordance with each enable signal. . In the baseband 21, the transmission enable signal and the reception enable signal are not output at the same time, and transmission and reception are separated by driving only one of the transmission side drive circuit and the reception side drive circuit.

  As an example, the baseband 21, the FlashROM 24, the XTAL 25, and the driver amplifier 22 form a transmission side circuit α. The baseband 21, the Flash ROM 24, the XTAL 25, and the BPF 23 form a reception side circuit β.

The baseband 21 has functions such as UART, GPIO, I ² C, and PWM as data interface specifications for exchanging data with the CPU 201 on the motherboard 2 side.

  For example, a UART (Universal Asynchronous Receiver-Transmitter) converts serial transfer data and parallel transfer data to each other.

  GPIO (General Purpose Input / Output) is a general-purpose input / output. When it operates as an input, it reads digital signals from other parts of the electric circuit. When it operates as an output, it controls other devices and notifies signals. Do.

I ² C (Inter-Integrated Circuit) is a method of serial communication with peripheral devices, and mainly realizes high-speed communication with an EEPROM memory IC or the like.

  Also, PWM (Pulse Width Modulation) is modulated by changing the ratio (duty ratio) of ON (HIGH) and OFF (LOW) widths of a pulse wave (square wave) using a pulse width modulation method.

  The HD-PLC operation circuit 20 is connected to a power supply circuit 30 for driving the baseband 21, the driver amplifier 22, the flash ROM 24, the XTAL 25, and the like with different drive voltages.

  The power supply circuit 30 includes, for example, Rg31, 32, and 33, which are power supply ICs such as a switching regulator (Regulator). Rg31 generates a 1.5V voltage and supplies it to the baseband 21. Rg32 generates a 3.3V voltage and supplies it to the baseband 21, the FlashROM 24, and the XTAL25. Rg33 generates a 10.5V voltage and supplies it to the driver amplifier 22.

  FIG. 4 is a circuit diagram of the PLC / AC superposition circuit 10 provided in the power line communication module 1 of the present invention.

  As shown in FIG. 4, the PLC / AC superposition circuit 10 includes a surge absorber 11, a common mode choke coil 12, capacitors 13 and 14, and a coupling transformer 15 in order to superimpose a high frequency on an AC current (power). ing. The PLC / AC superimposing circuit 10 further includes a connector pin 41 for connecting to the mother board 2.

  The surge absorber 11 is provided to prevent a transient abnormal voltage or abnormal current generated on the AC line 3 due to a lightning strike or static electricity (ESD) at the circuit entrance.

  The common mode choke coil 12 is a common mode noise suppressing transformer.

  Capacitors 13 and 14 are coupling insulating capacitors.

  Here, the capacitors 13 and 14 each have a capacitance of 0.2 μF to 0.4 μF, for example, and the inductor of the common mode choke coil 12 has an effect of suppressing common mode noise.

  With such capacitance value setting, the impedance of the capacitor 13 and the capacitor 14 is sufficiently high for a commercial frequency such as 50 Hz or 60 Hz, for example, with respect to the frequency of the power line communication signal such as 10 kHz to 450 kHz. Becomes sufficiently low impedance. Furthermore, the impedance of the inductor constituting the common mode choke coil 12 is sufficiently low for commercial frequencies such as 50 Hz or 60 Hz, for example, and is sufficient for frequencies of power line communication signals such as 10 kHz to 450 kHz. High impedance.

  Since the common mode choke coil 12 has a structure in which two conductors are wound around one core (a ferrite core in the case of high frequency), four terminals are provided. The winding directions of the two conducting wires (coils) are opposite to each other.

  When a common mode (high commercial frequency) current flows through the coil of the common mode choke coil 12, magnetic flux is generated by the electromagnetic induction phenomenon in each coil, and the directions of the generated magnetic flux become the same direction, so that the mutual magnetic flux is strengthened. Therefore, the function as an inductor is enhanced.

  On the other hand, when a current in a differential mode (commercial frequency with low commercial power) flows through this coil, the generated magnetic fluxes are in opposite directions, so the magnetic fluxes cancel each other. As a result, the differential mode current does not function as an inductor. At this time, the capacitors 13 and 14 have high impedance, and the amount of current passing through the capacitors 13 and 14 decreases. Therefore, the leakage current from the capacitors 13 and 14 is reduced, and the risk of electric shock can be reduced.

  In addition, there are two types of AC input terminals (plugs) for general household power supplies in Japan: L (live) and N (neutral). For safety reasons, the L terminal is on the non-ground side of the commercial power supply and the N terminal is on the ground side. You are instructed to connect. As a result, when a ground fault occurs (short circuit between the AC line and the ground line) inside the power supply, the built-in fuse of the L terminal is blown to protect against electric shock. If there is an FG (A) terminal (fuse terminal, ground terminal) of the power source, it is connected to the ground to prevent electric shock and noise.

  Here, in the case of a three-port outlet, such as an OA device, white goods, or an outlet with a ground terminal used in an air conditioner installation place, there is little mistake in connecting L, N, and E.

  However, in the case of a two-port outlet, such as a general household 100V outlet (JIS C 8303 2-pole outlet 15A 125V parallel type) in Japan, for example, the user mistakenly inserts L and N into the appliance (reverse) Connecting). Even if the L and N terminals are reversely connected and the FG terminal is not connected to the plug connected to the AC line 3, the power supply failure and characteristics do not change.

  Therefore, two capacitors are provided in consideration of safety. Further, by providing two capacitors, it is possible to prevent the wiring from being detoured and to shorten the wiring length.

  The coupling transformer 15 is a signal coupling transformer that couples signals, and an insulating transformer that removes noise and the like due to a capacitor.

  The PLC signal generated by the HD-PLC operation circuit 20 is input from the driver amplifier 22 to the coupling transformer 15. The PLC signal superimposed on the power of the AC power line and output from the coupling transformer 15 is connected to the BPF 23 in the HD-PLC.

  In the embodiment of the present invention, as a method of superimposing a communication wave on a signal line, a part selection for separating an AC line and a PLC signal line is performed.

  Here, in Japan, the permissible value of each component in the indoor broadband power line carrier communication facility is defined in Article 44, Paragraph 2, Item 2 of the Radio Law Enforcement Regulations. Therefore, the resonance Q values of the capacitors 13 and 14, the common mode choke coil 12, and the coupling transformer 15 so as to be within the allowable values (2 to 15 MHz: 30 dBμA, 15 to 30 MHz: 20 dBμA) of power line communication defined by the Radio Law. It is necessary to adjust.

  In order to satisfy this law, in the superposition circuit used in the HD-PLC operation circuit of the present invention, the common mode choke coil 12 and the coupling transformer 15 are selected according to the frequency band (2 to 28 MHz) used by the PLC. . For example, in the present embodiment, a 240V withstand voltage coil is used.

  Therefore, since a component suitable for the superimposing circuit (noise performance of PLC usage band 2 MHz to 28 MHz and good pass characteristics) is selected, communication deterioration due to the component is reduced.

  In addition, in the conventional example, when the superimposing circuit is assembled on the motherboard, it is necessary to obtain the model for the broadband power line carrier communication facility based on the above-mentioned law for the parts used on the motherboard, which causes a trouble for the user. .

  Therefore, in the present invention, since the joule unit on which the superimposing circuit is installed can be applied in advance for the type designation acquisition of the radio wave method (broadband power line carrier communication equipment), the user need not apply for the type acquisition.

  Here, it is preferable to use the same components for the choke coil 12 and the coupling transformer 15. Since the withstand voltage (for example, 240V) can be made uniform by sharing the parts, the withstand voltage is improved and the application for obtaining the above-mentioned model is only one part.

Depending on the product, for example, when a surge absorber is installed near the power line communication module 1 on the motherboard side, the surge absorber of the power line communication module 1 can be omitted. With this configuration, it is possible to further reduce the size of the superposition circuit and the power line communication module on which the superposition circuit is mounted.
FIG. 5 is a layout diagram showing the positions of components on the substrate of the PLC / AC superposition circuit 10.

  6A and 6B are diagrams showing an example of a substrate pattern of the PLC / AC superimposing circuit 10, wherein FIG. 6A shows an example of a wiring pattern on the front substrate, and FIG. 6B shows a wiring on the substrate on the back side of the superimposing circuit. An example pattern is shown.

  The PLC / AC superimposing circuit 10 mounted on the power line communication module 1 is preferably designed with a pattern layout that is not easily affected by noise and does not lower the throughput characteristic (throughput: processing capacity per second).

  In FIG. 5, the dotted line indicates the pattern of the PLC / AC superimposing circuit 10. A solid line shows a component (component). The connector pin 41 is a component of the PLC / AC superimposing circuit 10 and also functions as a pin for external connection of the power line communication module 1.

  As shown in FIG. 5, the installation area on the substrate can be reduced by arranging the components close to each other.

In the present embodiment, this proximity arrangement makes the wiring pattern routing amount as short as possible. Therefore, by shortening the wiring that propagates the superimposed AC / PLC signal, the attenuation of the signal is reduced and the influence of noise is reduced.
Specifically, in the wiring pattern on the front side of FIG. 6A and the back side of FIG. 6B, the dotted line is the wiring connected to the AC line 3 and the L phase of the plug, and the solid line is the wiring connected to the N phase.

  6A and 6B, the wiring between the connector pin 41 and the surge absorber 11 is L1, N1, the wiring between the surge absorber 11 and the common mode choke coil 12 is L2, N2, and the common mode choke. The wiring between the coil 12 and the capacitors 13 and 14 is L3 and N3, the wiring between the capacitors 13 and 14 and the coupling transformer 15 is L4 and N4, respectively, and the connector pin 28 of the coupling transformer 15 and the HD-PLC operation circuit 20 is connected. And wirings L5 and N5.

  The wires L1, N1, L3, N3, and L4, N4 are arranged on the back side (FIG. 6B), and the wires L2, N2, L5, and N5 are arranged on the front side (FIG. 6A). .

  6A and 6B, in the PLC / AC superposition circuit 10, the total number of wirings connected to the L phase (L1 + L2 + L3 + L4 + L5) is substantially equal to the total number of wirings connected to the N phase (N1 + N2 + N3 + N4 + N5). It can be seen that the wirings are of equal length.

  Furthermore, referring to FIG. 4, FIG. 5, and FIG. 6, in the superimposing circuit, the respective components are arranged close to each other and the arrangement area is small. In addition, when the arrangement area is small, each component is close, so the wiring is short.

  As shown in FIGS. 5 and 6, by shortening the PLC communication line (wiring) and making it the same length wiring, it is possible to reduce deterioration of communication quality and maintain throughput characteristics.

  As an example, the line length in the superposition circuit, that is, the line length excluding components (41, 11, 12, 13, 14, 15) from the AC line 3 to the HD-PLC operation circuit 20 is within 40 mm, such as about 35 mm. Designing.

  When a conventional module is used to configure a module provided with an operation circuit and an external superposition circuit on different substrates, there is an example in which a portion corresponding to the line length of the wiring is 50 mm or more.

  Therefore, in the embodiment of the present invention, the length of the PLC signal line routed on the substrate pattern can be shortened compared with the conventional module, so that the degradation of PLC communication characteristics can be reduced and the noise can be reduced.

  7A shows an example of a wiring pattern in a portion of the front-side substrate of the HD-PLC operation circuit 20 and the power supply circuit 30 on the substrate of the power line communication module 1, and FIG. An example pattern is shown.

  In FIG. 7, a BPF 23 and a driver amplifier 22 are disposed in the vicinity of the PLC / AC superimposing circuit 10. The BPF 23 is provided with a connector pin 28 for connecting the HD-PLC operation circuit 20 and the PLC / AC superposition circuit 10.

  A baseband 21 is disposed in the vicinity of both the BPF 23 and the driver amplifier 22. The baseband 21 is provided with a connector pin 42 that also functions as a pin for external connection of the power line communication module 1.

  Further, the power supply circuit 30 is disposed on the side away from the BPF 23 and close to the driver amplifier 22 and the baseband 21.

  Here, the reception side circuit β and the power supply circuit 30, which are the portions indicated by the thick wavy lines in FIG. 7A, are wired on the surface side of the substrate B. On the other hand, the transmission side circuit α which is a portion indicated by a thick wavy line in FIG. 7B is wired on the back side.

  As described above, the layout of the HD-PLC operation circuit 20 is in a position where the transmission side circuit α and the reception side circuit β are combined. Therefore, the wiring can be shortened.

  Further, in the present example, the blocks that are wired in the same layer as the power supply circuit, in this example, the receiving side circuit β that is wired on the same surface Bf as the power supply circuit 30 on the surface Bf shown in FIG. On the other hand, the block that is wired separately from the power supply circuit 30, in this example, the transmission side circuit α that is wired on the back surface Br shown in FIG.

  In contrast to the example of FIG. 7 described above, the circuit that is wired in the same layer (front surface Bf) as the power supply circuit 30 and is separated from the position is the transmission-side circuit α, and is a separate layer (back surface Br) from the power supply circuit 30. The circuit that is wired and closely arranged may be the receiving circuit β.

  Therefore, either one of the transmission side circuit α and the reception side circuit β is made different in layer (front surface, back surface), and the other is moved away from the same layer, so that noise is generated for generating a desired voltage. It is possible to dispose both the transmission-side circuit α and the reception-side circuit β away from the power supply circuit 30 that is liable to generate. Therefore, noise can be reduced.

  Therefore, with such a layout configuration, the area of the substrate can be reduced while being hardly affected by noise from the power supply, and the power line communication module can also be reduced in size.

  By using the module 1 according to the embodiment of the present invention, the HD-PLC can be easily used even if the user does not design a superimposing circuit on the motherboard as in the prior art.

  The user is not required to design the PLC / AC superposition circuit section. Since the time for selecting patterns and parts for maintaining communication quality can be saved, the development period can be reduced.

  Furthermore, by simply connecting the module directly to the AC line of the motherboard, the user does not need to obtain PLC type authentication, and PLC communication can be performed, and the threshold for the user to introduce the PLC function is reduced.

  The preferred embodiment of the present invention has been described in detail above, but the present invention is not limited to the specific embodiment, and within the scope of the gist of the embodiment of the present invention described in the claims, Various modifications and changes are possible.

1 Power Line Communication Module 2 Motherboard 3 AC Line (Power Line)
10 PLC / AC superposition circuit (superimposition circuit)
11 Surge Absorber 12 Common Mode Choke Coils 13, 14 Capacitor 15 Coupling Transformer 16 Connector Pin 20 HD-PLC Operation Circuit (Power Line Communication Operation Circuit)
21 Baseband (waveform adjustment circuit)
22 Driver amplifier 23 BPF
24 Flash ROM
25 XTAL
26 AFE
27 RAM
28 Connector Pin 30 Power Supply Circuit 41 Connector Pin (Pin Header Connector)
42 Connector pin α Transmission side circuit β Reception side circuit

Claims (9)

A power line communication operation circuit for providing power and electronic communication;
A power line communication module comprising: a superposition circuit connected between a power line and the power line communication operation circuit and superposing a high frequency on the power from the power line. The superposition circuit is
A choke coil,
A capacitor,
A coupling transformer,
The power line communication module according to claim 1. The superposition circuit is
With surge absorber,
The power line communication module according to claim 2. In the superposition circuit, the wiring connected to the L phase of the power line and the wiring connected to the N phase are equal length wiring.
The power line communication module according to claim 2 or 3. The wiring in the superimposing circuit is within 40 mm,
The power line communication module according to any one of claims 2 to 4. The choke coil and the coupling transformer use the same parts,
The component has a 240V withstand voltage,
The power line communication module according to any one of claims 2 to 5. The power line communication operation circuit includes a transmission side circuit and a reception side circuit,
The power line communication operation circuit is connected to a power supply circuit that supplies a voltage to the power line communication operation circuit.
The power line communication module according to any one of claims 1 to 6. The power line communication operation circuit, the superimposing circuit, and the power supply circuit are provided on the same substrate,
One of the transmission side circuit and the reception side circuit, which is wired in the same layer as the power supply circuit, is arranged at a separated position, and one of the transmission side circuit and the reception side circuit arranged adjacent to the power supply circuit The other is wired to a different layer of the substrate from the power supply circuit
The power line communication module according to claim 7. In the power line communication operation circuit,
The transmission side circuit and the reception side circuit include a common waveform adjustment circuit,
The transmission side circuit includes a driver amplifier,
The receiving circuit includes a bandpass filter,
The power supply circuit supplies a drive voltage necessary for each component to each circuit.
The power line communication module according to claim 7 or 8.