US 20050248441 A1
A method and apparatus for modifying a three-phase power distribution network in a building in order to provide data communication by using a Power Line Carrier (PLC) signal to an approximate electrical central location point of the power distribution system remote from the data entry point of the building. A passive coupler device is attached to a centrally located service panel. The passive coupler receives the Power Line Carrier (PLC) signal from the remote entry point in the building and conditions the signal for entry at the service panel onto each phase of the three phase power distribution network.
39. A system for interfacing a communication device with a multiple-phase power network residing in a building, wherein the multiple-phase power network includes multiple power wires with each power wire corresponding to a respective phase of the multiple-phase power network, and wherein the multiple-phase power network also includes a first service panel located within the building, the system comprising:
an electronic network coupled to the communication device via a first interface, wherein the first interface does not include any power wire of the multiple-phase power network residing in the building;
wherein the electronic network includes one or more carrier current couplers each providing an electrical interface between the communication device and a respective power wire of the three-phase power network at the first service panel, and wherein the electronic network is configured to split a first communication signal received from the communication device and feed the split communication signal to each power wire of the multiple-phase power network at the first service panel through the one or more carrier current couplers such that the first communication signal can be effectively distributed throughout at least a portion of the building.
40. The system according to
41. The system according to
42. The system according to
43. The system according to
44. The system according to
45. The system according to
46. The system according to
47. The system according to
48. The system according to
49. A method for interfacing a communication device with a three-phase power network residing in a building, wherein the three-phase power network includes at least three power wires each corresponding to a respective phase of the three-phase power network, and wherein the three-phase power network also includes a first service panel located within the building, the method comprising:
receiving a first communication signal from a communication device;
splitting the communication signal into three portions; and
feeding the portions of the split communication signal to each power wire of the three-phase power network at the first service panel such that the first communication signal can be effectively distributed throughout at least a portion of the building receiving at least one of the power wires.
50. The method according to
51. The method according to
52. The method according to
53. The method according to
54. A system for interfacing a communication device with a three-phase power network residing in a building, wherein the three-phase power network includes at least three power wires each corresponding to a respective phase of the three-phase power network, the system comprising:
an interface means for providing an electrical interface between the communication device and the three-phase power network;
wherein the interface means splits a first communication signal received from the communication device into three portions and simultaneously feeds the split communication signal to each power wire of the three-phase power network at a common location such that the first communication signal can be effectively distributed throughout at least a portion of the building receiving at least one of the power wires.
55. The system according to
56. The system according to
57. The system according to
58. The system according to
59. The system according to
This application claims the priority of Provisional Application Ser. No. 60/326,205, filed October 2, 2001, the disclosure of which is expressly incorporated by reference herein.
The ability to interconnect computers and other intelligent devices is a common requirement wherever people live and work today. The electrical connection required to form this local area network (LAN) has traditionally been accomplished by installing dedicated data wiring both inside buildings and between clusters of buildings. A number of wireless (i.e. radio) methods have also been developed and deployed to address this need.
More recently, technology to allow electric power wiring infrastructure to simultaneously transport data at high rates has been realized. This Power Line Carrier (PLC) technology typically uses modulated radio frequency (RF) signals below 50 MHz conducted on the power wiring to transport the data.
There are significant practical advantages offered by PLC technology—namely that electrical wiring, of necessity, must be installed and that data connectivity can therefore be immediately added at little (or no) additional cost, particularly in existing buildings. Similarly, electrical outlets are ubiquitous within modem buildings and significant operating convenience is realized when data is simultaneously available at every outlet.
Another advantage of PLC technology is that the range that can be achieved is significantly greater than wireless methods, particularly in commercial buildings constructed of heavier materials that severely attenuate wireless signals. Yet another advantage of PLC technology over wireless methods is that the data is inherently more secure since a physical connection is required to join the network.
The invention described here addresses several important problems that arise in the installation and use of PLC technology for local area data networks.
Most contemporary LANs are configured in a “hub and spoke” topology where a central server device supports a number of users and also provides a gateway to the Wide Area Network (WAN) and/or the Internet. Maximum utility for a PLC network is obtained when its' physical configuration mirrors the logical topology of the LAN, i.e. when the PLC gateway is effectively located at the “electrical center” of the space such that every outlet is served with the best possible PLC signal. This point is often a rarely accessed electrical panel in a service closet or the basement and is almost never co-located with other data processing equipment. The invention provides a simple means to remotely inject the PLC signals at this optimal point.
Another important issue, particularly in commercial buildings, is that 3-phase electrical power/wiring is commonly used and adequate coverage of a PLC network within the building is achieved only when all three phases are excited with the PLC signal. The invention provides for the simultaneous excitation of all 3 phases of power wiring with a single PLC signal.
Yet another related issue arises during the installation of PLC networks in environments that have natural barriers to the signals (or block them entirely). A common situation is where a building has been modified and all sections no longer share a common source of electrical power. Another common situation is where power is supplied from a central point and then distributed to sections of the space via transformers, often for purposes of distribution efficiency or electrical isolation. The invention also provides a simple and flexible means to inject a single PLC signal into any number of remote points as required to obtain adequate coverage.
The system according to the present invention interfaces a communicating signal with a three-phase power network of a building by feeding a power line carrier signal to a remotely located coupling device which is constructed to enable each of the three phases to be supplied with the PLC signal from the remote signal source. In another respect of the present invention, the signal can be fed to two or more different parts of a building having different electrical isolation qualities with respect to PLC signal by providing separate coupling device for each part of the building.
Other objects, advantages and novel features of the present invention will become apparent from the following detailed description of the invention when considered in conjunction with the accompanying drawings.
Embodiments of the current invention are directed to improving data connectivity afforded by PLC technology. While the carrier current coupler apparatus described here provides the means to effect the physical connection to the building power wiring, much of the improvement derives from identifying the appropriate point(s) at which to inject the PLC signal.
One common objective is to inject the PLC signal from a single, centralized device (often called a “gateway”) into the building wiring in such a way that all receptacles in the building receive adequate signal for a second device (often called a “terminal”) plugged in there to function properly. The attenuation of PLC signals along arbitrary runs of wiring is difficult to predict and highly variable so it is generally not possible to supply all receptacles with equal signal levels. A more achievable objective is to have the building and all of its' receptacles taken together as a system be well-behaved, i.e. where no single receptacle is completely cut off from the PLC signal and where the signal amplitude decreases in a reasonably predictable fashion with distance from the signal injection point.
An optimized system which maximizes use of the passive coupler arrangement is to connect the carrier current coupler (20) to service panel (30), inject the PLC signal from gateway (40) into the building at that point and measure the data throughput performance at a number of receptacles by any commonly available means.
An additional dimension to be considered is the common use of 3-phase power in commercial buildings. In this case, service panel (30) contains 3 hot wires (often referred to as “L1”, “L2” and “L3”), a neutral and a ground wire. The object of the original building wiring plan was to balance the load across all 3 phases so roughly ⅓ of the receptacles (35) downstream will ultimately be connected to each of L1, L2 and L3. Therefore, to provide PLC signals to all receptacles, the signal must be split and fed to all 3 phases simultaneously.
If installation is completed as discussed previously and acceptable data throughput results are obtained, no further work is necessary. On the other hand, one may find (referring once again to
The foregoing disclosure has been set forth merely to illustrate the invention and is not intended to be limiting. Since modifications of the disclosed embodiments incorporating the spirit and substance of the invention may occur to persons skilled in the art, the invention should be construed to include everything within the scope of the appended claims and equivalents thereof.