JP2021097398A - Plug and outlet for PLC - Google Patents

Abstract

To provide a plug and an outlet capable of receiving and supplying direct current power of different voltages, and communicating using power lines (PLC).SOLUTION: A plug 4 includes: reception electrodes 423a to 423d and 424a to 424d capable of receiving direct current power of different voltages; and a first connector 46 capable of transmitting and receiving PLC signals. An outlet 3 includes: supply electrodes 34a to 34d and 35a to 35d capable of supplying the direct current power of different voltages; and a second connector 36 capable of transmitting and receiving the PLC signals.SELECTED DRAWING: Figure 4

Description

The present invention relates to a plug and an outlet capable of receiving / supplying DC power and communicating using a power line (PLC: Power Line Communication).

PLC is a technology for performing data communication by superimposing a carrier wave on a power line drawn into each home such as AC100V and AC200V. As shown in FIG. 12, a network is constructed by connecting a PLC modem 91 to an outlet 92 arranged in each room in the home. When the plug provided in the PLC modem 91 is plugged into the outlet 92, power is supplied to the PLC modem 91, the PLC signal as a communication signal is superposed on the power signal and sent out, and the PLC signal superimposed on the power signal is sent out. Is received separately from the power signal.

The PLC signal superimposed on the power signal by the PLC modem 91 and output to the power line is received by the PLC modem 91 connected to another outlet 92 through the home power line PL arranged in the home, or It is connected to the Internet via a public line 94 such as an existing optical fiber via a parent PLC modem (not shown) provided on the secondary side of an outdoor transformer TF through a power meter WM and a lead-in power line 11. It is transmitted to the server 96, the database 97, the mobile terminal 98, and the like.

On the other hand, the communication signal sent from the public line 94 such as an optical fiber is superimposed on the power signal by the parent PLC modem (not shown) provided on the secondary side of the transformer TF, and the lead-in power line 11 and the watt-hour meter WM. It is sent to the home through, taken out from the home power line PL by the PLC modem 91 connected to the outlet 92, and received by a home appliance such as a personal computer. This makes it possible, for example, to turn on / off home appliances at home from an SNS terminal such as a smartphone while away from home.

As described above, the PLC system uses the service line 11 already provided in the general household and the power line PL in the house arranged in the house as a communication line, and can provide a communication line with less burden on the consumer. There are advantages.

The electric power drawn into the home from the transformer TF by the lead-in power line 11 is branched into a plurality of electric powers in the distribution board D and supplied to the outlet 92 or various home electric devices (terminals), respectively. From the viewpoint of checking the electric capacity and ensuring the safety of indoor wiring, the distribution board D is equipped with a limiter Li, a main breaker Br, and a plurality of branch breakers 5, and the home power line PL is connected to these breakers 5. doing. In some areas, the limiter Li is not installed on the distribution board D. Since the PLC signal is attenuated each time it passes through these main breaker Br and branch breaker 5, it may be necessary to arrange a relay device or the like for amplifying the signal voltage on the distribution board or the like in the PLC system.

Therefore, in order to suppress the attenuation of the PLC signal, a technique for transmitting and receiving the PLC signal by bypassing the main breaker Br and the branch breaker 5 has been proposed (for example, Patent Documents 1 and 2), but the main breaker Br and the branch breaker Even when the PLC signal is transmitted and received by bypassing 5, there is a problem that the PLC signal separated from the AC power signal still contains a lot of noise.

Therefore, it has been studied to superimpose a PLC signal on DC power for transmission and reception (for example, Patent Document 3).

JP-A-2015-23505 JP-A-2010-62887 JP-A-2010-40204

As a result of the study by the present inventor, it was confirmed that the noise of the PLC signal was reduced when the PLC signal was superposed on the DC power and transmitted / received. In addition, since most household electric devices are driven by DC power, if the home power supply is changed to DC power, there is an advantage that the AC / DC power conversion device for each electric device, which has been required in the past, becomes unnecessary. Be done.

However, the voltage of the DC power driven by the electric equipment for home use differs depending on the electric equipment (for example, 5V, 12V, 24V, 48V, etc.). When the power supply was DC power, it was necessary to individually prepare outlets with different supply voltages according to the working voltage of the electrical equipment.

The present invention has been made in view of such conventional problems, and an object of the present invention is to provide a plug that can receive direct current power of different voltages and can perform communication (PLC) using a power line. There is.

Another object of the present invention is to provide an outlet and a power strip capable of supplying direct current power of different voltages and capable of communication (PLC) using a power line.

The plugs according to the present invention that achieve the above object are plugs capable of receiving direct current power and communicating using a power line (PLC), and three or more plugs capable of receiving direct current power of different voltages. It is characterized by having a receiving electrode of the above and a first connector capable of transmitting and receiving a PLC signal.

The plug body having the above configuration has a plug body and a protrusion protruding from the surface of the plug body in the insertion direction of the plug body, and the three or more receiving electrodes are formed on the surface of the protrusion. It may be provided.

In the insertion plug having the above configuration, a hole portion recessed from the tip surface in the direction opposite to the insertion direction may be formed in the protrusion portion, and the first connector may be provided in the hole portion.

In the plug having the above configuration, the three or more receiving electrodes may have a larger surface area as the voltage of the received power increases.

The outlet according to the present invention that achieves the above object is an outlet capable of supplying DC power and communicating using a power line (PLC), and has three or more supply electrodes capable of supplying DC power of different voltages. And a second connector capable of transmitting and receiving a PLC signal.

The outlet having the above configuration may have an insertion portion into which the insertion plug can be inserted, and the three or more supply electrodes may be provided on the inner peripheral surface of the insertion portion.

Further, the outlet having the above configuration further has a detection unit for detecting the attachment / detachment of the insertion plug to the insertion unit, and the power supply is started and stopped based on the detection signal by the detection unit, and the insertion plug becomes When mounted on the insertion portion, power supply is started after the receiving electrode of the insertion plug and the supply electrode come into contact with each other, and when the insertion plug is detached from the insertion portion, the difference is obtained. The power supply may be stopped before the receiving electrode of the plug and the supply electrode are separated from each other.

Further, in the outlet having the above configuration, the plug may have a convex portion as a detected portion, and the detecting portion may be configured to detect the movement of the convex portion and generate a signal.

Further, in the outlet having the above configuration, the convex portion has a locking portion that can be locked to the insertion portion, and the locking portion is released from the state in which the insertion plug is attached to the insertion portion. It may be configured to prevent.

In the outlet having the above configuration, the second connector may be provided so as to project from the inner side surface of the insertion portion in a direction opposite to the insertion direction.

In the outlet having the above configuration, the three or more supply electrodes may have a larger surface area as the voltage of the supply power increases.

A built-in control means is further provided in the outlet having the above configuration, and the built-in control means can control the power on / off of an electric device receiving electric power from the outlet by a control signal via a PLC. May be.

A table tap according to the present invention that achieves the above object is a table tap having a power cord, a plug portion provided at one end of the power cord, and an outlet portion provided at the other end of the power cord. The plug portion is provided with three or more receiving electrodes capable of receiving DC power of different voltages and a first connector capable of transmitting and receiving PLC signals, and the outlet portion has different voltages. It is characterized by including three or more supply electrodes capable of supplying DC power and a second connector capable of transmitting and receiving a PLC signal.

The table tap having the above configuration is further provided with a built-in control means, and the built-in control means can control the power on / off of an electric device receiving electric power from the table tap by a control signal via a PLC. It may have a certain configuration.

According to the present invention, it is possible to supply and receive DC power of different voltages, and it is possible to reduce noise contained in a PLC signal separated from a power signal.

It is a schematic circuit diagram which shows one Embodiment of the PLC system using the plug 4 and the outlet 3 which concerns on this invention. It is a circuit diagram which shows an example of the coupler which can be used in this invention. It is a perspective view which shows an example of the outlet 3 which concerns on this invention. It is a perspective view which shows an example of the plug 4 which concerns on this invention. It is a perspective view which shows the modification of the outlet 3 which concerns on this invention. It is a perspective view which shows the modification of the plug 4 which concerns on this invention. It is a figure explaining that the detection switch 50 detects that the plug 4 of FIG. 6 was inserted into the outlet 3 of FIG. It is a figure explaining that the plug 4 is locked to the outlet 3 by the locking claw, and the plug is detected by the detection switch 50. It is a figure which shows the other form of the detection part which can be used in this invention. It is a figure which shows the other form of the detection part which can be used in this invention. It is a perspective view which shows an example of the table tap T which concerns on this invention. It is a figure which shows the configuration example of the conventional PLC system.

Hereinafter, the plug and the outlet according to the present invention will be described in more detail with reference to the drawings, but the present invention is not limited to these embodiments.

FIG. 1 is a schematic circuit diagram showing an embodiment of a PLC system using a plug and an outlet according to the present invention. As shown in FIG. 1, the commercial power reduced in voltage by the transformer TF (see FIG. 12) is sent to the AC / DC power converter 6 by the lead-in power line 11 through the watt-hour meter WM. Then, the AC / DC power conversion device 6 converts the AC power into DC power and supplies the AC power to the distribution board D provided at a predetermined position in the house. Since the main body of the watt-hour meter WM is usually housed in the housing H, it is desirable that the AC / DC power conversion device 6 be arranged in the housing H of the watt-hour meter WM. .. Further, the AC / DC power conversion device 6 may be installed between the main breaker Br and the branch breaker 5 as long as it is on or after the secondary side of the watt-hour meter WM.

The watt-hour meter WM used in the present invention is not particularly limited, and conventionally known ones can be used, but a smart meter having a communication function in addition to measuring the electric energy is preferable. This is because signal communication between the inside of the house and the outside of the house can be performed by using the communication function of the smart meter. Currently, there are three communication methods for smart meters: wireless multi-hop communication method, N communication method (using communication carriers such as mobile phones and WiMAX), and PLC method. A method suitable for the above is appropriately selected and used.

The distribution board D includes a limiter Li, a main breaker Br, a switching unit 21, and a plurality of branch breakers 5a, 5b, 5c ... (They may be collectively referred to as "branch breaker 5"). And are provided. A storage battery B is connected to the switching unit 21, and a photovoltaic power generation SC is connected to the storage battery B.

As the AC / DC power converter 6, a conventionally known one can be used. The AC / DC power converter 6 converts, for example, AC (alternating current) 100V to DC (direct current) 48V. Then, as will be described later, the power conversion device 33 of the outlet 3 further DC / AC conversion or DC / DC conversion to obtain the power and voltage that can be used by the terminal.

The limiter Li is a device that cuts off the power supply when a current of amperes or more specified by a contract with an electric power company flows. As the limiter Li used in the present invention, conventionally known ones can be used. Depending on the electric power company, the limiter Li may not be required.

The main breaker Br detects the current in the entire home and breaks the circuit when the rated current is exceeded. As the main breaker Br used in the present invention, conventionally known ones can be used.

Normally, the switch 21 supplies the power converted from alternating current to direct current by the AC / DC power conversion device 6 to each terminal via the branch breaker 5 and also supplies it to the storage battery B. The electric power supplied to the storage battery B is stored in the storage battery B. Further, the storage battery B is connected to the photovoltaic power generation SC, and the electric power generated by the photovoltaic power generation SC is stored in the storage battery B. On the other hand, in the event of a power failure, the stored power of the storage battery B is supplied to the terminal via the switching unit 21 and the branch breaker 5.

The branch breaker 5 is divided according to the application such as "lighting equipment on the second floor" and "living room outlet on the first floor", and breaks the circuit when the current used exceeds the rated current. As the branch breaker 5 used in the present invention, a conventionally known one can be used.

As shown in the circuit diagram of FIG. 1, one of the AC / DC power converters 6 connected to the transformer TF (see FIG. 12) via the watt-hour meter WM on the primary side. A lead-in power line 11 including a sex line N and two power lines L1 and L2, for a total of three lines, is connected. Then, the AC / DC power converter 6 converts the AC power into DC power, and the AC / DC power converter 6 connects the connecting line 12 consisting of two trunk lines to the primary side of the extension limiter Li. There is. The limiter Li and the main breaker Br are connected by a connecting line 13. A plurality of branch breakers 5 are connected to the connecting line 14 after the connecting line 14 extends from the limiter Li and passes through the switching unit 21.

Then, a home power line PL is connected to the secondary side of each branch breaker 5. The home power line PL is wired indoors and connected to an outlet 3 or a terminal arranged at a predetermined position, respectively. The outlet 3 includes an insertion unit 31, a PLC modem 32 that superimposes and separates a power signal and a PLC signal, and a power conversion device 33. The power conversion device 33 includes a DC / AC power conversion device that converts DC power into AC power and a DC / DC power conversion device that converts DC power into a predetermined voltage.

Terminals such as air conditioner Ac, lighting equipment LE, and personal computer PC have a plug 4 for receiving power supply, and the plug 4 is connected to the plug 31 of the outlet 3 to connect the terminal. Power is supplied to the machine and PLC communication becomes possible.

According to the PLC system of the present invention in which the PLC signal is superimposed on the DC power signal as described above and the PLC signal is separated from the DC power signal, the conventional PLC system in which the PLC signal is superimposed / separated on the AC power signal can be used. In comparison, the noise contained in the PLC signal separated from the power signal is significantly reduced, and the communication accuracy is improved.

Further, from the viewpoint of suppressing the attenuation and noise of the PLC signal, it is desirable to transmit and receive the PLC signal by bypassing the main breaker Br and the branch breaker 5. As shown in FIG. 1, first couplers 7a to 7c are attached to the secondary side of each branch breaker 5. Further, a second coupler 8 is attached to the connection line 12 connected to the primary side of the limiter Li. The first couplers 7a to 7c and the second coupler 8 are devices for superimposing the PLC signal on the DC power signal and / or separating the PLC signal from the DC power signal, and are composed of an inductive coupler and a capacitive coupler. To.

FIG. 2 shows a circuit diagram showing an example of a coupler that can be used in the present invention. The coupler shown in this figure separates the PLC signal from the coupling circuit unit 71, the transmission circuit unit 72 that amplifies the PLC signal and superimposes it on the DC power signal, and transmits it, and the DC power signal captured through the coupling circuit unit 71. It has a receiving circuit unit 73. The PLC signal separated from the DC power signal by the receiving circuit unit 73 is sent to the control unit C, while the PLC signal sent from the control unit C is superposed on the power signal by the transmitting circuit unit 72 and sent out.

The control unit C controls which of the first couplers 7a to 7c or the second coupler 8 superimposes the PLC signals sent from the first couplers 7a to 7c and the second coupler 8 on the DC power signal. For example, in the PLC system shown in FIG. 1, when an operation signal (PLC signal) such as an on / off signal of an air conditioner Ac or a set temperature signal is output from a personal computer PC, the operation signal is converted into a DC power signal by the PLC modem 32. It is superposed and sent to the branch breaker 5c through the outlet 3 and the home power line PL. Then, the operation signal sent toward the branch breaker 5c is separated from the DC power signal by the first coupler 7c attached to the secondary side of the branch breaker 5c and sent to the control unit C. The control unit C superimposes the operation signal from the PC on the DC power signal by the first coupler 7b attached to the secondary side of the branch breaker 5b to which the home power line PL that sends power to the air conditioner Ac is connected. The operation signal superimposed on the DC power signal passes through the home power line PL, is separated from the DC power signal by the PLC modem 32 of the outlet 3, reaches the air conditioner Ac, and the operation of the air conditioner Ac is controlled.

When the operation signal of the air conditioner Ac is sent from outside the house by using the communication function of the watt-hour meter (smart meter) WM, the operation signal is AC by the PLC modem (not shown) in the watt-hour meter WM. It is superimposed on the DC power signal after being converted from AC to DC by the / DC power conversion device 6 and sent to the limiter Li via the connection line 12. Then, as shown in FIG. 1, the operation signal is separated from the DC power signal by the second coupler 8 provided on the primary side of the limiter Li and sent to the control unit C. In the same manner as described above, the control unit C uses the first coupler 7b attached to the secondary side of the branch breaker 5b to which the in-house power line PL that sends power to the air conditioner Ac is connected to transmit the operation signal from the PC to the DC power signal. Superimpose on. The operation signal superimposed on the DC power signal passes through the home power line PL, is separated from the DC power signal by the PLC modem 32 of the outlet 3, reaches the air conditioner Ac, and the operation of the air conditioner Ac is controlled.

According to such a system, since the operation signal (PLC signal) is transmitted by bypassing the main breaker Br and the branch breaker 5, the signal attenuation during transmission is suppressed.

Here, the AC / DC power conversion device 6 is provided in the housing H in which the watt-hour meter WM is housed. As a result, when the watt-hour meter WM is a smart meter, it is possible to connect to a communication network outside the home by using the communication function of the smart meter. In particular, when the communication method of the smart meter is wireless multi-hop communication method and N communication method, the PLC signal transmitted from inside the house to outside the house by the PLC modem (not shown) in the watt-hour meter WM is While separated from the DC power signal and transmitted wirelessly, the PLC signal transmitted from outside the house to the inside of the house is superimposed on the DC power signal and sent to the home power line PL via the connection line 12. That is, since the PLC signal communicated between the inside of the house and the outside of the house is not superimposed on the AC power, low noise communication is possible as compared with the conventional case where the PLC signal is superimposed on the AC voltage signal.

(Outlet)
Most terminals such as home electric devices in recent years are driven by DC power, but since the conventional home power supply is AC power, AC power is used inside the terminal or in a plug extending from the terminal. It was converted to DC power. On the other hand, in the PLC system of the present invention, since the home power supply is DC power, it is not necessary to convert AC power into DC power when using the terminal. However, even with DC power, the drive voltage differs depending on the terminal, so the outlet 3 used in the PLC system of the present invention includes a power conversion device 33. The power conversion device 33 includes a DC / AC power conversion device that converts DC power into AC power, and a DC / DC power conversion device that converts the voltage of DC power.

In the DC / AC power conversion device, a terminal that converts the DC voltage converted into a DC voltage of 48V by the AC / DC power conversion device 6 and sent to the outlet 3 into an AC power such as 100V, and drives the AC power. Can be supplied to. In the DC / DC power conversion device, for example, the DC voltage converted into a DC voltage of 48V by the AC / DC power conversion device 6 and sent to the outlet 3 is 0V, 5V, 12V, 24V, 48V, 50V, 100V, 150V. It is converted to multiple DC voltages such as, and can be selectively used according to the working voltage determined by the terminal.

FIG. 3 shows a perspective view showing an example of the outlet 31 of the outlet 3 according to the present invention. The insertion port 31 shown in FIG. 3 has an insertion portion 31a for AC power and an insertion portion 31b for DC power. Since the insertion portion 31a for AC power has the same shape and structure as the conventional one, the description thereof will be omitted here.

The plug-in portion 31b for DC power has a hole shape into which a plug 4 described later can be inserted, and includes a plurality of supply electrodes corresponding to different supply voltages in the hole. Specifically, the insertion portion 31b for DC power has a first hole portion 311 having a square opening and a predetermined length in the depth direction, and a first hole portion 311 at the center of the inner side surface of the first hole portion 311. It has a second hole portion 312 having an opening smaller than the hole portion 311 and having a predetermined depth direction length.

Grooves 313a to 313d extending in the depth direction with a predetermined width are formed at the central portions of the four inner side surfaces of the first hole portion 311 in the left-right direction or the up-down direction (only the grooves 313a and 313b are shown in FIG. 3). Supply electrodes 34a to 34d (only supply electrodes 34a and 34b are shown in FIG. 3) are formed on the bottom surfaces of the grooves 313a to 313d.

Further, grooves 314a to 314d extending in the front-rear direction with a predetermined width are formed on the four inner side surfaces of the second hole portion 312 in the central portion in the left-right direction or the up-down direction, respectively (only the grooves 314a and 314b are shown in FIG. 3). , Supply electrodes 35a to 35d (only supply electrodes 35a and 35b are shown in FIG. 3) are formed on the bottom surfaces of the grooves 314a to 314d. With such a structure, the insertion portion 31b has eight supply electrodes 34a to 34d and 35a to 35d. For example, 24V DC power is supplied to the supply electrodes 35a to 35d, and the supply electrode 34a is a ground electrode and supplies. 12V DC power is supplied to the electrodes 34b and 34d, and 5V DC power is supplied to the supply electrodes 34c. From the viewpoint of safety, high-voltage power is supplied to the supply electrodes located away from the opening of the first hole, that is, the supply electrodes 35a to 35d provided on the inner surface of the second hole 312. It is desirable that a low voltage is supplied to the supply electrodes 34a to 34d provided on the inner peripheral surface of the first hole.

Further, the second USB connector 36 is formed so as to extend toward the front in the central portion of the inner side surface of the second hole portion 312, and the tip of the second USB connector 36 is formed in the first hole portion. It is located slightly out of reach of the back side of 311.

(Plug-in plug)
FIG. 4 shows a perspective view showing an example of the plug 4 according to the present invention. The plug 4 of FIG. 4 is provided at the tip of the power cord 40 extending from the terminal device, and can be plugged into the plug 31b of the plug 31 of the outlet 3 shown in FIG. .. That is, the plug 4 has a substantially rectangular parallelepiped plug body 41 in which the power cord 40 extends from the rear surface, and a protrusion 42 formed on the front surface of the plug body 41 and projecting forward (insertion direction). Have. The protrusion 42 has a square columnar first protrusion 421 protruding forward and a cross-sectional shape perpendicular to the front-rear direction protruding forward in the central portion of the front surface of the first protrusion 421, which is smaller than that of the first protrusion 421. It has a square columnar second protrusion 422. A quadrangular hole 43 recessed rearward is formed on the front surface of the second protrusion 422, leaving a flange portion having a predetermined width inward from the outer peripheral edge, and a USB second is formed in a substantially central portion of the rear surface of the hole 43. 1 The connector 46 is formed so as to extend in the forward direction.

The first protrusion 421 and the second protrusion 422 have a shape that can be fitted into the first hole 311 and the second hole 312 of the insertion portion 31b of the outlet 3, respectively. Band-shaped receiving electrodes 423a to 423d extending in the front-rear direction with a predetermined width at the center of the four outer surfaces of the first protrusion 421 and the second protrusion 422 in the vertical and vertical directions, respectively (FIG. In No. 4, only the receiving electrodes 423a and 423d are shown) and the receiving electrodes 424a to 424d are provided so as to slightly project outward from the outer surface. The receiving electrodes 423a to 423d and the receiving electrodes 424a to 424d are provided so that the rear end side can be elastically swung around the front end side.

When the protrusion 42 of the plug 4 is inserted into the outlet 31b of the outlet 3, the first protrusion 421 of the plug 4 is inserted into the first hole 311 and the second hole 312 of the outlet 31b of the outlet 3. And the second protrusion 422 is fitted. Then, in the grooves 313a to 313d and the grooves 314a to 314d having supply electrodes 34a to 34d and 35a to 35d on the bottom surface, which are formed on the inner side surfaces of the first hole portion 311 and the second hole portion 312 of the insertion port 31, The receiving electrodes 423a to 423d and the receiving electrodes 424a to 424d, which slightly protrude outward from the outer surfaces of the first protrusion 421 and the second protrusion 422 of the insertion plug 4, enter while contacting each other. As a result, the eight supply electrodes 34a to 34d and 35a to 35d of the outlet 3 and the eight receiving electrodes 423a to 423d and 424a to 424d of the plug 4 are brought into surface contact and connected. At the same time, the second USB connector 36 on the outlet side and the first USB connector 46 on the plug side are connected. As described above, the receiving electrodes 423a to 423d and the receiving electrodes 424a to 424d are elastically deformable by sliding contact with the supply electrodes 34a to 34d and 35a to 35d.

The power line of the terminal is connected to a desired receiving electrode among the eight receiving electrodes 423a to 423d and 424a to 424d of the plug 4, that is, a predetermined receiving electrode corresponding to the DC voltage used by the terminal. Then, the desired DC power is supplied to the terminal. For example, when the DC voltage used by the terminal is 48V, the receiving electrode 35a and the receiving electrode 424b on the plug 4 side connected to the supply electrode 35a and the supply electrode 35b that supply 24V DC power on the outlet 3 side , The power line of the terminal is connected so that the supplied 24V DC power is in series. That is, the power line of the terminal is selectively connected to the predetermined receiving electrode of the plug 4 so that the sum of the DC voltages supplied from the outlet 3 side (arranged in series) becomes the DC voltage used by the terminal. At the same time, the power line of the terminal is connected to the receiving electrode 423a as the ground electrode on the plug 4 side connected to the supply electrode 34a as the ground electrode on the outlet 3 side. Further, the PLC signal can be transmitted and received by connecting the second USB connector 36 on the outlet side and the first USB connector 46 on the plug side.

(Modification example 1)
5 and 7 show a modified example of the outlet 3 and the plug 4. 5 and 6 are perspective views of the outlet 3 and the plug 4, and FIG. 7 is an explanatory view for detecting the insertion of the plug 4 into the outlet 3.

When the plug 4 is inserted into the outlet 3 and when the plug 4 is pulled out from the outlet 3, an arc discharge may occur between the supply electrode of the outlet 3 and the receiving electrode of the plug 4. In the case of DC power, the arc discharge is difficult to extinguish and is dangerous. Therefore, a detection unit for detecting the attachment / detachment of the plug 4 to / from the outlet 3 is provided, and when the insertion plug 4 is attached to the outlet 3 based on the detection signal by the detection unit, the plug 4 is received. When the power supply is started after the electrode and the supply electrode of the outlet 3 come into contact with each other and the plug 4 is separated from the outlet 3, before the receiving electrode of the plug 4 and the supply electrode of the outlet 3 are separated from each other. Try to stop the power supply.

As shown in FIG. 5, a circular engagement hole 37 is formed in the lower left of the back side surface of the first hole portion 311 of the outlet 3. As shown in FIG. 7, a detection switch 50 as a detection unit is arranged on the rear side in the axial direction of the engagement hole 37. The detection switch 50 is a so-called limit switch, and includes a rectangular parallelepiped switch body 51 and a plunger 52 that can appear and disappear outward from the switch body 51 and is always urged in the protruding direction by a spring (not shown). A thin plate-shaped lever 53 is provided, one end of which is swingably supported on the switch body 51 by a shaft 54, and the middle portion of the longitudinal direction abuts on the tip of the plunger 52. In the normal state, the plunger 52 protrudes from the switch body 51 by the urging force of a spring (not shown), and the lever 53 is in contact with the tip of the plunger 52. Then, the detection switch 50 having such a structure is arranged in the outlet 3 so that the free end side in the longitudinal direction of the lever 53 is located on the axial center of the engagement hole 37.

On the other hand, as shown in FIG. 6, a cylindrical pin (convex portion) 47 projecting in the forward direction is provided at the lower right of the front surface of the first protrusion 421 of the insertion plug 4. The outer diameter of the pin 47 is smaller than the inner diameter of the engagement hole 37 of the outlet 3, and the forward protruding length of the pin 47 is the pin when the plug 4 is completely inserted into the outlet 3. The length is set so that the tip of 47 comes into contact with the lever 53 of the detection switch 50 and the plunger 52 can be pushed into the switch body 51.

As shown in FIG. 7, when the plug 4 having such a structure is inserted into the outlet 3, the eight supply electrodes 34a to 34d and 35a to 35d of the outlet 3 and the eight receiving electrodes 423a to the plug 4 are inserted. 423d, 424a to 424d are in surface contact with each other, and the contact area between the electrodes increases as the plug 4 is inserted into the outlet 3. Further, when the insertion plug 4 is inserted into the outlet 3, the pin 47 of the insertion plug 4 enters the engagement hole 37 of the outlet 3. Then, just before the plug 4 is completely inserted into the outlet 3, the pin 47 of the plug 4 comes into contact with the lever 53 of the detection switch 50 and rotates the lever 53 toward the switch body 51. By the rotation of the lever 53, the plunger 52 is pushed into the switch body 51 against a spring (not shown) to turn on the detection switch 50 (FIG. 7 (b)), and the plug is inserted from the supply electrode of the outlet 3. The power supply to the receiving electrode of the plug 4 is started. In this way, power supply is started after the receiving electrode of the plug 4 and the supply electrode of the outlet 3 come into contact with each other, so that it occurs when the receiving electrode of the plug 4 and the supply electrode of the outlet 3 come close to each other. Arc discharge is effectively suppressed.

Further, when the plug 4 is pulled out from the outlet 3, the operation opposite to the case where the plug 4 is inserted into the outlet 3 is performed. That is, when the plug 4 is pulled out from the outlet 3, the contact state between the pin 47 of the plug 4 and the lever 53 of the detection switch 50 is first released, and the plunger 52 is attached with a spring (not shown). It protrudes from the switch body 51 by force. As a result, the detection switch 50 is turned from on to off, and the power supply from the supply electrode of the outlet 3 to the receiving electrode of the plug 4 is stopped. As a result, the arc discharge generated when the receiving electrode of the plug 4 and the supply electrode of the outlet 3 are separated from each other is effectively suppressed.

(Modification 2)
FIG. 8 shows another modification of the outlet 3 and the plug 4. FIG. 8 is an explanatory diagram for detecting the insertion of the insertion plug 4 into the outlet 3. As shown in FIG. 8, a pair of arm-shaped portions (convex portions) 48a and 48b having a free end at the tip (back side) are provided on both left and right side surfaces of the plug main body 41 of the insertion plug 4. .. Locking claws (locking portions) 481a and 481b projecting outward are formed at the tips of the pair of arm-shaped portions 48a and 48b, and projecting outward in the middle of the pair of arm-shaped portions 48a and 48b. The rectangular parallelepiped pressing portions 482a and 482b are formed. The back side surfaces of the locking claws 481a and 481b are inclined surfaces that are inclined outward toward the front side, and the front side surface is a vertical surface that is perpendicular to the side surface of the plug body. The locking claws 481a and 481b and the pressing portions 482a and 482b are integrally formed with the arm-shaped portions 48a and 48b. The pair of arm-shaped portions 48a, 48b are formed so that when the insertion plug 4 is completely inserted into the outlet 3, the locking claws 481a, 481b are locked in the locking holes 38a, 38b formed in the outlet. It is the position to do. Further, between the pair of arm-shaped portions 48a and 48b and the side surface of the plug main body 41, when an external force is applied to the pressing portions 482a and 482b toward the inside of the plug main body 41, the pair of arm-shaped portions 48a and 48b A gap is formed in which the portions 48a and 48b are bent so that the locking claws 481a and 481b can move inward of the plug body 41.

On the other hand, a pair of quadrangular engagement holes 38a and 38b are formed on the left and right inner side surfaces of the first hole portion 311 of the outlet 3. A detection switch 50 as a detection unit is arranged on the right side of the engagement hole 38a. More specifically, the detection switch 50 is arranged so that the free end side of the lever 53 is located on the axis center of the engagement hole 38a. Since the structure of the detection switch 50 is the same as that shown in the first modification, the description thereof will be omitted here.

When the plug 4 having such a structure is inserted into the outlet 3, the eight supply electrodes 34a to 34d and 35a to 35d of the outlet 3 and the eight receiving electrodes 423a to the plug 4 are similar to the first modification. 423d, 424a to 424d are in surface contact with each other, and the contact area between the electrodes increases as the plug 4 is inserted into the outlet 3. Then, just before the plug 4 is completely inserted into the outlet 3, the inclined surfaces of the locking claws 481a and 481b of the plug 4 come into contact with the left and right edges of the first hole 311 of the outlet 3 to form a pair. The tips of the arm-shaped portions 48a and 48b bend inward of the plug body 41. When the inclined surfaces of the locking claws 481a and 481b exceed the left and right edges of the first hole 311, the pair of arm-shaped portions 48a and 48b return to their original states due to elastic force, and the locking claws 481a and 481b The vertical surface locks into the locking holes 38a and 38b. As a result, the plug 4 is prevented from being pulled out from the outlet 3. At the same time, the locking claw 481a abuts on the lever 53 of the detection switch 50 and rotates the lever 53 toward the switch body 51. By the rotation of the lever 53, the plunger 52 is pushed into the switch body 51 against a spring (not shown) to turn on the detection switch 50 (FIG. 8 (b)), and the plug is inserted from the supply electrode of the outlet 3. The power supply to the receiving electrode of the plug 4 is started. In this way, the power supply is started after the receiving electrode of the plug 4 and the supply electrode of the outlet 3 are completely in contact with each other. Therefore, when the receiving electrode of the plug 4 and the supply electrode of the outlet 3 are close to each other, the power supply is started. The arc discharge generated in is effectively suppressed.

On the contrary, when the insertion plug 4 is pulled out from the outlet 3, the pressing portions 482a and 482b of the arm-shaped portions 48a and 48b of the insertion plug 4 are first pressed inward. Then, the tip side of the pair of arm-shaped portions 48a, 48b bends inward, so that the locking state of the locking claws 481a, 481b with the locking holes 38a, 38b is canceled, and the plug 4 is inserted from the outlet 3. It can be pulled out. At the same time, the contact state between the locking claw 481a and the lever 53 of the detection switch 50 is released, and the plunger 52 protrudes from the switch body 51 by the urging force of a spring (not shown) (state of FIG. 8A). ). As a result, the detection switch 50 is turned from on to off, and the power supply from the supply electrode of the outlet 3 to the receiving electrode of the plug 4 is stopped. After that, the plug 4 is pulled out from the outlet 3. Therefore, an arc discharge does not occur when the receiving electrode of the plug 4 and the supply electrode of the outlet 3 are separated from each other.

In the modified example described above, the contact type limit switch 50 is used as the detection unit, but the detection unit is not limited to this, as long as it detects the attachment / detachment of the plug 4 to the outlet 3. Conventionally known ones can be used. For example, various proximity switches described in JIS C8201-5-2 can be used as the detection unit of the present invention.

FIG. 9 shows a case where the inductive proximity switch 50a is used as the detection unit, and the metal portion 471 is provided at the tip of the pin 47 provided on the plug 4 side and the inductive proximity switch 50a is provided on the outlet 3 side. .. When the metal part 471 of the pin 47 approaches the high-frequency magnetic field emitted from the detection coil (not shown) in the proximity switch 50a, an induced current due to an electromagnetic induction phenomenon flows through the metal part 471, and this current causes detection in the proximity switch 50a. The impedance of the coil (not shown) changes, the oscillation stops, and the attachment of the plug 4 to the outlet 3 is detected.

Further, FIG. 10 shows a case where the photoelectric proximity switch 50b is used as the detection unit, and the plate-shaped light-shielding plate 472 is provided on the plug 4 side and the photoelectric proximity switch 50b is provided on the outlet 3 side. The proximity switch 50b has a structure in which the light emitting element 501 and the light receiving element 502 are arranged to face each other at a predetermined distance. When the plug 4 is not inserted into the outlet 3, the light emitted from the light emitting element 501 is projected onto the light receiving element 502 in a straight line and received. On the other hand, when the plug 4 is inserted into the outlet 3, the light-shielding plate 472 of the plug 4 is inserted between the light-emitting element 501 and the light-receiving element 502 of the proximity switch 50b, and the light emitted from the light-emitting element 501 is blocked by the light-shielding plate 472. Therefore, the light receiving element 502 does not receive light. As a result, the attachment of the plug 4 to the outlet 3 is detected.

(Table tap T)
FIG. 11 shows a perspective view showing an example of the table tap T according to the present invention. The table tap T shown in FIG. 11 has a power cord 30 having a predetermined length, an insertion plug portion 4a provided at the front end of the power cord 30, and an outlet portion 3a provided at the rear end of the power cord 30. Have. In the outlet portion 3a, two insertion portions 31c for AC power and two insertion portions 31d for DC power are alternately formed at predetermined intervals in the front-rear direction. The structure of the plug 4a is the same as that of the plug 4 shown in FIG. Further, the structure of the plug-in portion 31d for DC power of the outlet portion 3a is the same as that of the plug-in portion 31b for DC power shown in FIG. A DC / AC power conversion device (not shown) is built in the outlet unit 3a, and the DC power supplied to the outlet unit 3a is converted into AC power having a predetermined voltage by the DC / AC power conversion device. It is said that it can be supplied from the power insertion unit 31c.

According to the outlet 3 and the table tap T and the plug 4 described above, AC power and DC power can be supplied and PLC signals can be transmitted and received by USB, so that it is a typical source of noise. It is possible to suppress the influence of operating noise of a certain AC power-driven microwave or motor on the PLC signal to a low level.

(Other)
In the embodiment described above, the plug main body 41 of the plug 4 and the power cord 40 are inseparably molded, but the plug main body 41 and the power cord 40 may be detachable from each other. For example, a conventionally known DC plug is provided at the tip of the power cord 40, and a DC jack is provided at the plug body 41 so that the DC plug at the tip of the power cord 40 can be inserted and removed from the DC jack of the plug body 41. According to such a configuration, it is possible to supply DC power to a conventional electric device having a DC plug via the outlet 3 and the plug 4 of the present invention.

Further, the cross-sectional shape perpendicular to the insertion direction of the insertion portion 31b of the outlet 3 and the protrusion 42 of the insertion plug 4 described above is not limited to this, and is not limited to this, for example, a columnar shape or a columnar shape. It may be a polygonal column. Further, the insertion portion 31b and the protrusion 42 may have one stage or three or more stages. Further, a protrusion may be provided on the outlet side and an insertion portion may be provided on the insertion plug side to connect the insertion plug and the outlet. Further, the supply electrode and the receiving electrode may be three or more, that is, the voltage of the DC power that can be supplied may be two or more types, and the supply electrode and the receiving electrode may be nine or more, or seven or less. May be good.

Further, as already proposed by the applicant in Japanese Patent Application Laid-Open No. 2018-125830, the outlet 3 of the present invention is provided with a built-in control means (providing a device for designating an address, a relay for output, etc.). Information from the Internet or information can be transmitted to the Internet. For example, when the plug and outlet of the present invention are used in the agricultural field, information from sensors that measure indoor and outdoor air temperature, humidity, soil temperature, etc. can be transmitted through the outlet.
Further, if the outlet or the table tap is provided with the built-in control means, it is possible to remotely control the power ON / OFF of the electric device connected to the outlet or the table tap including the device having no communication function. In addition, by connecting a camera, it is possible to monitor the cultivation and growing status of agricultural products and transmit images of suspicious persons invading, fires, gas leaks, and the like.

By simply plugging it into the outlet of the present invention via the plug of the present invention, DC power corresponding to each device is supplied, and the data measured and detected by each device is superimposed on the power signal as a PLC signal. Then, it can be transmitted to a server, a database, a mobile terminal, etc. connected to the Internet via a computer or a public line in an agricultural facility. In addition, based on the transmitted detection data, a control signal is transmitted from a computer or a mobile terminal, and the temperature is adjusted to be inserted into the outlet of the present invention via the plug of the present invention installed in an agricultural facility. Various devices such as vessels and sprinklers are controlled.

According to the plug and outlet according to the present invention, it is possible to supply and receive DC power of different voltages, and it is possible to reduce noise contained in the PLC signal separated from the power signal.

3 Outlet 3a Outlet part 4 Plug-in plug 4a Plug-in plug 5, 5a to 5c Branch breaker 6 AC / DC power converter C Control unit 7, 7a to 7c 1st coupler 8 2nd coupler B Storage battery T Table tap 11 Pull-in power line 30 Power cord 31 Plugs 31a, 31b, 31c, 31d Plugs 311 1st hole 312 2nd hole 32 PLC modem 33 Power converter 34a to 34d Supply electrodes 35a to 35d Supply electrodes 36 Second connector 37 Insertion holes 38a, 38b Engagement holes 41 Plug body 42 Protrusions 421 First protrusions 422 Second protrusions 423a to 423d Receiving electrodes 424a to 424d Receiving electrodes 43 Holes 46 First connector 47 pins (convex)
48a, 48b Arm-shaped part (convex part)
481a, 481b Locking claw (locking part)
50 Detection switch (detection unit)
Ac air conditioner (terminal)
Br Main breaker LE Lighting equipment (terminal)
Li limiter PC personal computer (terminal)
PL Home power line SC Solar power generation TF Transformer WM Electric energy meter

Claims (14)

It is a plug that can receive direct current power and communicate using power lines (PLC).
With three or more receiving electrodes capable of receiving DC power of different voltages,
The first connector that can send and receive PLC signals,
A plug that features a plug. With the plug body
A protrusion protruding from the surface of the plug body in the insertion direction of the insertion plug,
Have,
The plug according to claim 1, wherein the three or more receiving electrodes are provided on the surface of the protrusion. A hole recessed from the tip surface in the direction opposite to the insertion direction is formed in the protrusion.
The plug according to claim 2, wherein the first connector is provided in the hole. The plug according to any one of claims 1 to 3, wherein the three or more receiving electrodes have a larger surface area as the voltage of the received power becomes higher. An outlet capable of supplying DC power and communicating using power lines (PLC).
With three or more supply electrodes capable of supplying DC power of different voltages,
A second connector that can send and receive PLC signals,
An outlet characterized by being equipped with. It has an insertion part where the insertion plug can be inserted,
The outlet according to claim 5, wherein the three or more supply electrodes are provided on the inner peripheral surface of the insertion portion. It also has a detection unit that detects the attachment / detachment of the insertion plug to the insertion unit.
Power supply is started and stopped based on the detection signal by the detection unit.
When the plug is attached to the plug, power supply is started after the receiving electrode of the plug comes into contact with the supply electrode, and the plug is separated from the plug. The outlet according to claim 6, wherein the power supply is stopped before the receiving electrode of the plug and the supply electrode are separated from each other. The plug has a convex portion as a detected portion, and the plug has a convex portion as a detected portion.
The outlet according to claim 7, wherein the detection unit detects the movement of the convex portion and emits a signal. The convex portion has a locking portion that can be locked to the insertion portion.
The outlet according to claim 8, wherein the locking portion prevents the plug from being detached from the state of being attached to the insertion portion. The outlet according to any one of claims 6 to 9, wherein the second connector is provided so as to project from the inner side surface of the insertion portion in a direction opposite to the insertion direction. The outlet according to any one of claims 5 to 10, wherein the three or more supply electrodes have a larger surface area as the voltage of the supply power increases. It also has built-in control means
The outlet according to any one of claims 5 to 11, wherein the built-in control means can control the power on / off of an electric device that receives electric power from the outlet by a control signal via a PLC. A table tap having a power cord, a plug portion provided at one end of the power cord, and an outlet portion provided at the other end of the power cord.
The plug portion includes three or more receiving electrodes capable of receiving DC power of different voltages, and a first connector capable of transmitting and receiving PLC signals.
The outlet unit has three or more supply electrodes capable of supplying DC power of different voltages, and
A table tap characterized by having a second connector capable of transmitting and receiving PLC signals. It also has built-in control means
The table tap according to claim 13, wherein the built-in control means can control the power on / off of an electric device that receives electric power from the table tap by a control signal via a PLC.

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