Frame transmission and communication network

What is claimed is: 1. A method of transmitting frames in a communication network interconnecting a plurality of synchronized nodes of a Process Control (PC) or Substation Automation (SA) system, wherein the nodes periodically transmit regular frames comprising time-critical data, and wherein the nodes non-periodically transmit sporadic frames, the method comprising: transmitting, by each node of the plurality of nodes of the Process Control (PC) or Substation Automation (SA) system, at the beginning of a common transmission period, a regular frame; receiving, by at least one node of the Process Control (PC) or Substation Automation (SA) system, regular frames from a first neighboring node, and forwarding within the common transmission period, the received regular frames to a second neighboring node, and delaying, by the at least one node of the Process Control (PC) or Substation Automation (SA) system, transmission of a sporadic frame until forwarding of all received regular frames is completed, wherein the communication network is a ring, comprising: transmitting, by a node of origin, a frame and a duplicate frame to a first and second neighboring node, respectively, with the frame and the duplicate frame being identified by means of a redundancy identifier, and wherein the redundancy identifier comprises the length of the frame, comprising: verifying, by the node of origin and prior to transmission of a sporadic frame or a duplicate sporadic frame, whether the transmission of the sporadic frame or of the duplicate sporadic frame can be completed before the start of the next transmission period, based on the redundancy identifier comprising the length of the frame. 2. The method according to claim 1 , comprising: delaying transmission of the sporadic frame until an end of a regular phase dedicated to the transmission of regular frames is observed. 3. The method according to claim 1 , comprising: verifying, by the at least one node and prior to transmission of the sporadic frame, whether the transmission of the sporadic frame can be completed before the start of the next transmission period. 4. The method according to claim 1 , comprising: queuing, by the at least one node, a regular frame received from the first neighboring node and to be forwarded to the second neighboring node in a regular queue; and queuing, by the at least one node, a regular frame from an application hosted by the node and to be transmitted to the second neighboring node in a different queue. 5. A communication network, comprising: a plurality of interconnected and synchronized nodes of a Process Control (PC) or Substation Automation (SA), system, wherein at least one node periodically transmits regular frames comprising time-critical data, and wherein at least one node non- periodically transmits sporadic frames, each node of the network comprising: means for transmitting, at the beginning of a common transmission period, a regular frame, receiving regular frames from a first neighboring node of the Process Control (PC) or Substation Automation (PC) system, and for forwarding, within the common transmission period, the received regular frames to a second neighboring node; and means for delaying transmission of a sporadic frame until forwarding of all received regular frames is completed, wherein the communication network is a ring with a frame and a duplicate frame being sent, by a node of origin, to a first and second neighboring node, respectively, and with the frame and the duplicate frame being identified by means of a redundancy identifier, and wherein the redundancy identifier comprises a length of the frame, and wherein each node of the network comprises means for verifying, prior to transmission of a sporadic frame or a duplicate sporadic frame, whether the transmission of the sporadic frame or of the duplicate sporadic frame can be completed before a start of the next transmission period, based on the redundancy identifier comprising the length of the frame. 6. The communication network according to claim 5 , wherein each node in the network comprises means for delaying transmission of the sporadic frame until an observed end of a regular phase is observed. 7. The communication network according to claim 5 , wherein each node of the network comprise means for verifying, prior to transmission of the sporadic frame, whether the transmission of the sporadic frame can be completed before the start of the next transmission period. 8. The communication network according to claim 5 , wherein each node pertains to an Intelligent Electronic Devices (IED) of the Process Control (PC) or Substation Automation (SA) system. 9. The communication network according to claim 6 , wherein each node pertains to an Intelligent Electronic Devices (IED) of the Process Control (PC) or Substation Automation (SA) system. 10. The communication network according to claim 7 , wherein each node pertains to an Intelligent Electronic Devices (IED) of the Process Control (PC) or Substation Automation (SA) system. 11. The communication network according to claim 5 , wherein each node pertains to an Intelligent Electronic Devices (IED) of the Process Control (PC) or Substation Automation (SA) system. 12. The communication network according to claim 5 , wherein each node pertains to an Intelligent Electronic Devices (IED) of the Process Control (PC) or Substation Automation (SA) system.