This invention is in the field of network connector devices and more specifically systems for connecting networks in a daisy chain configuration.
Daisy chaining is the simplest way to connect a network. Devices connected by a daisy chain are connected one to another in series and a message that is sent on the network has to travel down the chain from one device to another. Compared to other network topologies, daisy chaining is relatively slow, however in applications that do not require large amounts of data transfer and fast transfer rates, daisy chaining is a common practice and daisy chain networks are common in industrial control networks.
One common standard that uses a daisy chain configuration for networking devices is the RS-485 standard. While RS-485 devices may be quite common, there are other protocols that specify or can use a daisy chain network configuration such as Apple's LocalTalk™ and many types of industrial applications.
While networked devices using the RS-485 protocol have always been common in industrial systems, such as larger scale heat and ventilation systems, with the decrease in price of control systems, smaller scale control systems are becoming more common. One area using networked devices that can use a daisy chain topology is home automation and especially home HVAC systems.
In order to setup devices in a daisy chain network, a cable has to be strung to each of the devices in the network. With the exception in some cases of the first and last devices in a daisy chain network, each device in the network requires a cable running to it from a previous device and another cable running from it to the next device.
Daisy chaining connections utilize termination resistors on each end of the network to ensure that every transceiver is directly connected to the main current path. Transceivers placed outside the termination resistors daisy chain may not be able to correctly sense the voltage drop and “hear” the transmission. In this way “star” wiring configurations are not allowed for daisy chained networks such as RS-485.
The disadvantage of wiring the network in this fashion is that there must be some overall plan to the creation of the network. The devices must be planned to some degree because a cable running from the previous device must be connected to the device and a different cable must be run to the next device. This requires the person setting up the network to know where the previous device is as well as the location of the next device. Knowing the placements of the devices may not be overly complicated when the network is small and centralized in one area, but often these daisy chain networks have long distances between devices and these devices might be in different locations that are not in sight of each other. For example, in a HVAC system for a house, the devices connected to the chain network will typically be a controller near the furnace and a number of thermostats connected to the daisy chain network and spread throughout the house. Each thermostat device connected to the network will likely be situated in a different room or location of the house from other devices and it will not always be easy to determine in which direction to run the cable to and from each device.
Additionally, some of the protocols such as RS-485 networks require a termination resistor at the end of the network. This requires one of the devices to serve as the last device and the network must be planned to end at the device that has the termination resistor in it.
Not only must the daisy chain network be planned to some degree, but it can also be complicated to add new devices to the network. To add a new device, the network must be disconnected from one of the device and the new device incorporated into the chain. Again, the location of the previous device and next device must be known, which might not be that easy to determine if the network is spread throughout a large building and numerous rooms.
The different standards for daisy chain networks also specify the type of cable that is required in order to connect the devices. RS-485, for example, specifies certain minimum standards for cable and requires the cable to be a twisted pair in order to use balanced differential signals to reduce or eliminate the effect of interference in the cables.
There are many cables available that meet the recommendations for the different daisy chain network protocols and there are cables that are specially designed for use with these applications. These cables are quite specialized and although daisy chain networks are common, they are not as common as other more standard types of networks. This often makes the special cabling more costly and harder to find because of its lower production. Also, electricians are often not familiar with these types of specialty cables.
In more recent years a number of more standard cable specifications have arisen that are not specifically made for daisy chain networks. One very common type of standard cable is referred to as Category 5 cabling. These standardized cables often include a number of conductors or wire strands and standardized connections to increase the ability of these standard cables to be used in a number of different applications i.e. category 5 consists of four twisted pairs of copper wire terminated by RJ45 connectors.
Because these standard cables can be used in so many applications and circumstances and some, like Category 5 wire, are in common use, they are manufactured in very large quantities which generally makes them cheaper than other specialty cables, easier to find and electricians and other installers are more often more familiar with their use.
It is an object of the present invention to provide a system and apparatus that overcomes problems in the prior art.
The present invention provides, in a first embodiment, a master network device for creating a network in a daisy chain configuration. The master network device comprises a network component configured to operate on a daisy chain network and comprising an output port and an input port for connection to the daisy chain network; and a connector hub operative to connect a plurality of network devices in a daisy chain network with cables, wherein each cable comprises two conductors. The connector hub comprises a plurality of sequential cable interfaces including a first cable interface and a last cable interface, each cable interface comprising a pair of conductor connectors, each conductor connector operative to connect one conductor of a connected cable to a connecting circuit. The connecting circuit is configured such that one of the conductor connectors of the first cable interface is connected to the output port of the network component and the other of the conductor connectors of the first cable interface is connected to one of the conductor connectors of a next cable interface; the other of the conductor connectors of the next cable interface is connected to one of the conductor connectors of a succeeding cable interface, and conductor connectors of the subsequent succeeding cable interfaces are connected sequentially in the same manner; and the other of the conductor connectors of the last cable interface is connected to the input port of the network component.
The present invention provides, in a second embodiment, connector hub to connect a plurality of network devices in a daisy chain network with cables, wherein each cable comprises two conductors. The connector hub comprises a connecting circuit; a primary network device interface comprising a pair of conductor connectors, each conductor connector operative to connect a conductor to the connecting circuit; and a plurality of sequential cable interfaces including a first cable interface and a last cable interface, each cable interface comprising a pair of conductor connectors, each conductor connector operative to connect one conductor of a connected cable to the connecting circuit. The connecting circuit is configured such that one of the conductor connectors of the first cable interface is connected to one of the conductor connectors of the primary network device interface and the other of the conductor connectors of the first cable interface is connected to one of the conductor connectors of a next cable interface and the other of the conductor connectors of the next cable interface is connected to one of the conductor connectors of a succeeding cable interface; conductor connectors of the subsequent succeeding cable interfaces are connected sequentially in the same manner; and the other of the conductor connectors of the last cable interface is connected to the other conductor connector of the primary network device interface.
The system allows connection of each of a plurality of network devices in a daisy chain configuration to a central location in a network. Each network device is connected to a cable with two conductors. From the central location, a signal is transmitted down a first conductor in a cable to a network device and the signal is then transmitted back from the network device down a second conductor in the cable. From the central location, the signal is then transmitted down the next cable to the next network device. The cable connections can be made with a standard plug and socket such as are readily available. In this manner, networks that operate on a daisy chain can be wired from a central location in a home run or free-form manner, yet maintain the daisy chain configuration.
While the invention is claimed in the concluding portions hereof, preferred embodiments are provided in the accompanying detailed description which may be best understood in conjunction with the accompanying diagrams where like parts in each of the several diagrams are labeled with like numbers, and where:
a through 5g are schematic diagrams of connector devices with alternate connecting circuits;
In
If the network 1 is configured in a master/slave configuration that is fairly common in daisy chain configured network, one of the network devices 121 will be the master device on the network 1 and the rest of the network devices 121 will be slave devices controlled by the master device.
The present invention uses network cable with at least two conductors in a network that allows each network device to be connected to the network by a single cable yet maintain the configuration of a daisy chain network.
Typically, if the daisy chain network is configured in a master/slave configuration, the network component 230 would be configured as the master device of the network.
Alternatively, the network component 230 could be a serial to Ethernet (or other network standard) bridge. The network component 230 would comprise an internet or other non-daisy chain network connection 231 operative to connect the network component to another network. Typically, this network connection would be a conventional Ethernet or other network connection, but it could be a wireless connection such as one that operates on the 802.11 standard for connection to a wireless network. This would allow a daisy chain network created using the master network device 220 to be in a remote location accessible over the internet or other connection. Signal to be transmitted over a daisy chain network created by the master network device 220 could be encapsulated and sent over a network to the master network device 220 where the network component 230 strips out the encapsulated signal and transmits the signal onto the daisy chain network connected to the master network device 220. In this manner, the master network device 220 could serve as a bridge between a first daisy chain network in a remote location and a daisy chain network connected to the master network device 220.
The connector hub 250 allows the connection of the network component 230 to a number of different network devices (not shown) in a daisy chain configuration. Connector hub 250 comprises a first cable interface 260, a second cable interface 270, a third cable interface 280, a fourth cable interface 290 and a connection circuit 255.
The first cable interface 260 is operative to connect to a cable comprising at least two conductors and comprises a first conductor connector 262 connectable to a first conductor of a cable connected to the first cable interface 260 and a second conductor connector 265 connectable to another conductor of a cable connected to the first cable interface 260. Both the first conductor connector 262 and the second conductor connector 265 of the first cable interface 260 are connected to the connection circuit 255. The second cable interface 270 is operative to connect to a cable comprising at least two conductors and comprises a first conductor connector 272 connectable to a first conductor of a cable connected to the second cable interface 270 and a second conductor connector 275 connectable to another conductor of a cable connected to the second cable interface 270. Both the first conductor connector 272 and the second conductor connector 275 of the second cable interface 270 are connected to the connection circuit 255. The third cable interface 280 is operative to connect to a cable comprising at least two conductors and comprises a first conductor connector 282 that is connectable to a first conductor of a cable connected to the third cable interface 280 and a second conductor connector 285 that is connectable to another conductor of a cable connected to the third cable interface 280. Both the first conductor connector 282 and the second conductor connector 285 of the third cable interface 280 are connected to the connection circuit 255. The fourth cable interface 290 is operative to connect to a cable comprising at least two conductors and comprises a first conductor connector 292 that is connectable to a first conductor of a cable connected to the fourth cable interface 290 and a second conductor connector 295 that is connectable to another conductor of a cable connected to the fourth cable interface 290. Both the first conductor connector 292 and the second conductor connector 295 of the fourth cable interface 290 are connected to the connection circuit 255.
The connection circuit 255 operatively connects the output port 232 of the network component 230, the input port 235 of the network component 230, the first cable interface 260, the second cable interface 270, the third cable interface 280 and the fourth cable interface 290 in a daisy chain configuration. The output port 232 of the network component 230 is operatively connected by the connection circuit 255 to the first conductor connector 262 of the first cable interface 260. The second conductor connector 265 of the first cable interface 260 is operatively connected by the connection circuit 255 to the first conductor connector 272 of the second cable interface 270. The second conductor connector 275 of the second cable interface 270 is operatively connected by the connection circuit 255 to the first conductor connector 282 of the third cable interface 280. The second conductor connector 285 of the third cable interface 280 is operatively connected by the connection circuit 255 to the first conductor connector 292 of the fourth interface 290. The second conductor connector 295 of the fourth cable interface 290 is operatively connected by the connection circuit 255 to the input port 235 of the network component 230.
It will be readily understood by someone skilled in the art that the conductor could comprises a twisted wire pair and each conductor connector would be a pair of connectors to connect to each of the twisted wires in the pair.
In one embodiment of the invention, as illustrated in
Although
The master network device 220 comprises: first cable interface 260; second cable interface 270; third cable interface 280; and fourth cable interface 290.
The network devices 320A, 320B, 320C and 320D are network devices that require or allow connection to a daisy chain network, such as devices that can operate using the RS-485 standard. These devices could be any type of device that is useful to network in a daisy chain configuration, i.e. a number of input devices or control devices. If the network 300 is configured based on a master/slave relationship between the devices, the master network device 220 will be the controlling or master device and the network devices 320A, 320B, 320C and 320D would be slave devices.
The cables 115A, 115B, 115C, 115D and 115E comprise a first end and a second end and have at least two conductors. If the cables 115A, 115B, 115C, 115D and 115E are designed for connected network devices 320 that operate in accordance with the RS-485 standard, the two conductors will each be a twisted pair of copper wires and if the cable 115A, 115B, 115C, 115D and 115E is category 5 cable, the cable will consists of four copper wire pairs. The cables 115A, 115B, 115C, 115D and 115E could be terminated with any typical ends that allow connection to the components of the network 200, including the stripped wire ends, however, the ends would typically be RJ45 ends to allow quick snap connections to the network devices 320 in the network 300.
The connector device 110 can be any connector that is operative to maintain devices connected to it in a daisy chain configuration. For example, connector device 110 can be the connector device as shown in
The first cable interface 20, second cable interface 22 and third cable interface 24 are configured to be connectable with a cable comprising at least two conductors. The connector device illustrated in
The connecting circuit 30 operably connects the conductors of the cables connected to the cable interfaces in such a manner that the daisy chain configuration of the network is maintained. For the embodiment of the connector device as shown in
Alternatively, connector device 110 could be a connector device as illustrated in
The shorting plug 180 in
Referring again to
In operation network 300 operates as follows. Master network device 220 transmits a signal. The signal is transmitted out through conductor connector 262 of cable interface 260 and through a first conductor in the cable 115E. The signal is transmitted into connected device 110 and from connector device 110 through cable 115A and into network device 320A (if connector device 110 is the connector device illustrated in
In another embodiment of the invention the connector hub is separate from the first network device.
The primary network device interface 240 comprises an input conductor connector 242 and an output conductor connector 245 and the input conductor connector 242 and the output conductor connector 245 are operative to connect to conductors (not shown) from a primary network device (not shown). The primary network device that is connected by conductors to the primary network device interface 240 would typically be a master device if the daisy chain network is configured in a master/slave relationship, however it does not have to be. The conductors that connect the primary network device to the primary network device 240 could each comprises a single conductor and they could be wires (such as a twisted pair) or a printed circuit board wherein the primary network device interface 240 could connect to a slot on the primary network device. Alternatively, these two conductors could be enclosed in a single cable.
It will be readily understood by someone skilled in the art that the conductors could comprise a twisted wire pair and each conductor connector would be a pair of connectors to connect to each of the twisted wires in the pair.
In one embodiment of the invention, as illustrated in
Although
The cables 115A, 115B, 115C, 115D and 115E comprise a first end and a second end and have at least two conductors. If the cables 115A, 115B, 115C, 115D and 115E are for connected network devices 120 that operate in accordance with the RS-485 standard the two conductors will each be a twisted pair of copper wires and if the cable 115A, 115B, 115C, 115D and 115E is category 5 cable, the cable will consists of four copper wire pairs. The cables 115A, 115B, 115C, 115D and 115E could be terminated with any typical ends that allow connection to the components of the network 500, including the stripped wire ends, however, the ends would typically be RJ45 ends to allow quick snap connections to corresponding sockets in the components in the network 500.
The foregoing is considered as illustrative only of the principles of the invention. Further, since numerous changes and modifications will readily occur to those skilled in the art, it is not desired to limit the invention to the exact construction and operation shown and described, and accordingly, all such suitable changes or modifications in structure or operation which may be resorted to are intended to fall within the scope of the claimed invention.
Number | Date | Country | Kind |
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PCT/US2004/038992 | Nov 2004 | US | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/US2004/042931 | 12/17/2004 | WO | 00 | 12/15/2010 |