BR102012032350A2 - SYSTEM AND METHOD FOR TRANSMITTING AC POWER AND COMMUNICATION SIGNS - Google Patents

Abstract

SYSTEM AND METHOD FOR TRANSMITTING AC POWER AND COMMUNICATION SIGNS This is a system that is designed to transmit AC power and communication signals between a first location and a second location via a communication path that includes at least one inductive load (5) and at least one switching means (13) for switching power to said at least one load. The control means (14) are adapted to control said at least one switching means such that if said power is activated during a particular power phase, it is disabled during the opposite power phase and if said power is activated. power is disabled during a particular power phase, it is activated during the opposite power phase.

Description

"SYSTEM AND METHOD FOR TRANSMITTING AC POWER AND COMMUNICATION SIGNS"

Field of the Invention

This invention relates to transient protection in a communication system, for example, in a subsea fluid production well communication and power system.

BACKGROUND OF THE INVENTION In subsea fluid well communication and power systems, voltage transients inherently associated with on / off switching of inductive loads are potentially very harmful, as communication modems are directly coupled (electrically connected) to lines. in order to implement power communication systems (COP). High voltage transients can damage submerged and topside modems used in COP-based communication systems and submerged and topside power distribution transformers.

Brief Description of the Invention According to the invention from one aspect, there has been provided a system for transmitting AC power and communication signals between a first location and a second location by means of a communication path including at least one charge. and at least one switching means for switching power to said at least one load, the system including control means adapted to control said at least one switching means such that if said power is activated during a particular power phase, it is deactivated during the opposite power phase and if said power is deactivated during a particular power phase, it is activated during the opposite power phase. According to the invention from another aspect, a method has been provided for transmitting alternating current power and communication signals between a first location and a second location by means of a communication path including at least one inductive load and at least five. at least one switching means for switching power to said at least one on and off load, the method comprising controlling said at least one switching means so that if said power is activated during a particular phase of power , it is deactivated during the opposite phase of power, and if said power is deactivated during a particular phase of power, it is activated during the opposite phase of power.

Preferably, said control means are further adapted to control said at least one switching means such that, in response to deactivation of said power, a direct current is applied to said at least one inductive load and, in response to actuation. Of said at least one switching means for activating said power, said power is activated during a phase of the power which results in a magnetization of said at least one inductive load as opposed to that which results from direct current.

At least such an inductive load could be in said first

location.

At least one such inductive load could be in the second

location.

At least one of such switching means could be in said first location.

At least one of such switching means is in said second

location.

Said at least one inductive load typically comprises a winding of a transformer. A system according to the invention typically comprises a communication and power system for a submerged well and a method according to the invention is typically performed on such a system. In such cases, typically, said first location is a topside location and said second location comprises a subsea electronics module.

Brief Description of the Drawings Figure 1 is a schematic diagram of a typical power and communication system for an underwater fluid production well;

Figure 2 is a schematic diagram of an embodiment of such a system according to the invention;

Figure 3 is derived from oscilloscope traces to illustrate transient problems;

Figure 4 is a schematic diagram of a second embodiment of a system according to the invention; and Figure 5 is a schematic diagram of part of a third

embodiment of a system according to the invention.

Detailed Description of the Invention Figure 1 shows a typical COP-based control system for an underwater fluid production well (eg hydrocarbon) in which the topside alternating current (AC) power grid from a mains supply 1 (for example, on a surface platform), is fed to transformers 2 in subsea electronics modules SEM1, SEM2 - SEMN in respective fluid production wells, by means of a power switch 3, a circuit breaker 4 , a topside transformer 5, a communications block filter 6, a circuit breaker 7, and an umbilical cable 8 between the topside and submerged wells. Control communications are overlaid under control electronics control 9 to AC power after breaker 7 by a modem 10 and a data signal filter 11. When power switch 3 or a breaker 4 or 5 is operated, high voltage transients occur at points 12 of the system, which is the result of reactive power rapidly discharged into the system. Remaining magnetic energy stored in inductive elements (transformers and inductors) is rapidly discharged through the system and high transient binding currents occur, with potentially catastrophic consequences.

Figure 2 (where the items corresponding to those in Figure 1 have the same reference numerals as in Figure 1) shows an embodiment of this invention, the power switching in the system that is changed by replacing the simple switch 3 with a switch With phase-controlled power output 13, the action of switch 3 is now by means of control electronics 14 that control switch 13, as well as modem 10 and filter11. More particularly, switch 13 switches power at a phase-controlled angle of the voltage waveform, typically by means of a thyristor or TRIAC. Power off and on switching is phase-controlled to ensure that the downstream load is energized at the opposite phase of power to that when switched off. For example, if the system is turned on at, as an example, half power positive cycle, it is always turned off at half negative power cycle, thus ensuring the delivery of an equal number of half power cycle. negative and positive power to the load, thereby leaving the downstream magnetic components with a residual magnetic field that should suppress (rather than reinforce) the bias current transient surge generation when the system is then powered on. (with appropriate phase synchronized power control).

The reason for this process is that switching the power supply to a transformer typically results in a residual magnetic flux stored in the core. If the power is activated at a portion of the AC power cycle polarity that reinforces this flow, then the transformer may go into saturation, which results in a large input current, and as there is no longer a change in the power flow. and thus no return electromotive force (EMF), it is only limited by the winding resistance. This high current typically results in collapse or severe distortion of the supply voltage with rapidly changing supply voltage that generates harmonics whose frequencies can invade the communication band of a COP system and corrupt communications. This, along with potential damage that can be caused by high binding currents, can be catastrophic.

Figure 3 is derived from actual oscilloscope traces recorded during power on / off tests on a SEM transformer that demonstrates this phenomenon and shows a voltage 15 (trace 15) applied to a primary transformer winding, the current ( trace 16) in the primary winding, a COP system communication output (trace 17) and a complementary (trace18) of trace 17. The phase point 19 in trace 15 where power is activated is at the beginning of a negative cycle. It can be seen that there is a large current in the primary winding (trace 16) and a collapse of the supply voltage (trace 15) that generated harmonics that resulted in noise bursts in the communication channel by COP (dashes 17 and 18).

Alternatively, a simple way to avoid the transient problem is to have a large transformer core so that it will not saturate, but this is not an option in subsea equipment where minimizing mass and volume is essential. . The above method of this invention, of ensuring that the on and off power is phase controlled, to ensure that the downstream load is energized at the opposite phase of the power supply when it is off, allows the retention of low mass and volume transformers without risk. transients cause damage and corruption in COP communication.

The above resolution of the transient problem can, however, be improved provided that if a breaker opens or the power is unintentionally cut for any other reason, the power off will not be phase controlled, and thus the required reverse phase. in recompense will not be known. This can be dealt with by adding premagnetization of the transformers. This technique involves temporarily applying a small DC voltage to the primary winding of each transformer to configure its core remanence in a known direction. This provides insight into the phase of the restored AC power required to 'oppose' this remaining flow, thus avoiding the application of power in a phase that will trigger saturation core flow and marry transient problems.

Figure 4 (where the items corresponding to those in Figure 2 have the same reference numerals as in Figure 2) shows the application of this attribute to the topside transformer 5. If breaker 4 opens a switch 20 between switch 13, and the transformer 20 5 operates for a short time and connects a DC supply circuit 21 (typically only providing about 9 volts) to the primary winding to transformer 5, which thus configures its remnant of the core in a known direction, dependent on the polarity of the applied DC power. Thereafter, the power on / off phase control led switch 13 is configured to apply, when breaker 4 is reset, the first AC power phase required to reverse the power circuit dwell configuration. DC 20,

This thus ensures that the transformer core 5 does not saturate and thus prevents the problem of high switching current, supply voltage collapse and corruption of COP communication arising without the premagnetization technique.

As shown in Figure 4, the same technique is applied to the 5 submerged transformers 2 housed in 1aN SEMs with DC power premagnetization applied to all SEM transformers from the topside via the umbilical cable 8. Thus, the opening of the circuit breaker 7 (or circuit breaker 4) causes a switch 22 to be operated, which momentarily connects a DC power circuit 23 to the 10 SEMs 1 through N transformers 2, followed by the configuration of a on / off phase controlled switch. 24 power to apply the correct phase of AC power when reconnected to the transformers, that is, reverse the remaining flow in the transformer cores previously configured by the DC power off.

What was described above is done under the control of electronic

topside control switch 25 actuated by switch 3 and circuit breakers 4 and 7 and connected to control switches 13, 20, 22 and 24.

Figure 5 shows an alternative arrangement for premagnetizing the transformers in the SEMs by incorporating the control, energization phasing, and circuit set required within each submerged SEM. In this case in each SEM respectively, the control electronics 26 in the SEM will have to have their power supply sustained for a few seconds when power arriving via umbilical 8 is deactivated, and it also contains the circuitry to detect the power off. power on

that a DC power circuit 27 (typically receiving power from the control electronics power supply) is momentarily connected to transformer 2 by a switch 28. In power restoration via umbilical 8, a phase-controlled switch Power ON / OFF switch (typically a TRIAC or thyristors) will not restore power to the transformer until the control electronics

26 allow it to activate at the correct phase of AC power.

Advantages of Using the Invention The key advantage is that this invention allows the use of

transformers with flow densities that are close to saturation, and therefore low volume and mass, in submerged power systems with COP communication without the problems of system component damage such as modems and communications corruption when the power supply is disabled or enabled.

Claims (18)

1. SYSTEM for transmitting AC power and communication signals between a first location and a second location by means of a communication path including at least one inductive load and at least one switching means for switching power to said at least one on and off load, the system including control means adapted to control said at least one switching means such that if said power is activated during a particular power phase it is deactivated during the opposite phase of power, and if said power is deactivated during a particular phase of power, it is activated during the opposite phase of power. A system according to claim 1, wherein said control means is further adapted to control said at least one switching means such that, in response to deactivation of said power, a direct current is applied to said one. at least one inductive load and, in response to the actuation of said at least one switching means for activating said power, said power is activated during a phase of the power which results in a magnetization of said at least one inductive load as opposed to which results from said direct current. A system according to claim 1 or 2, wherein at least one such inductive load is in said first location. A system according to any preceding claim, wherein at least one such inductive load is in said second location. A system according to any preceding claim, wherein at least one of said switching means is in said first location. A system according to any preceding claim, wherein at least one of said switching means is in said second location. A system according to any preceding claim, wherein said at least one inductive load comprises a winding of a transformer. A system according to any preceding claim, comprising a communication and power system for a submerged well. A system according to claim 8, wherein said first location is a topside location and said second location comprises a submarine electronics module. 10. METHOD FOR TRANSMITTING AC POWER AND COMMUNICATION SIGNS between a first location and a second location by means of a communication path comprising at least one inductive load and at least one switching means for switching power to said one. at least one on and off load, the method comprising controlling said at least one switching means such that if said power is activated during a particular power phase, it is deactivated during the opposite power phase and If said power is deactivated during a particular power phase, it is activated during the opposite power phase. A method according to claim 10, wherein said control further comprises controlling said at least one switching means such that, in response to deactivation of said power, a direct current is applied to said at least one load. and, in response to the actuation of said at least one switching means to activate said power, said power is activated during a phase of the power which results in a magnetization of said at least one inductive load as opposed to that which results from of said direct current. A method according to claim 10 or 11, wherein at least one such inductive load is at said first location. A method according to any one of claims 10 to 12, wherein at least one such inductive load is at said second location. A method according to any one of claims 10 to 13, wherein at least one of said switching means is in said first location. A method according to any one of claims 10 to 14, wherein at least one of said switching means is in said second location. A method according to any one of claims 10 to 15, wherein said at least one inductive load comprises a winding of a transformer. Method according to any one of claims 10 to 16, performed in a communication and power system for a submerged well. The method of claim 17, wherein the first location is a topside location and said second location comprises a submarine electronics module.