Tripolar VSC-HVDC transmission system and method

What is claimed is: 1. A tripolar VSC-HVDC control method for controlling a tripolar VSC-HVDC system adopting three conductors to transmit DC power, the system comprising: a rectifier and an inverter formed by a three phase six-bridge arms modular multilevel converter (MMC) respectively, midpoints of 1, 2, 3 phase units of the rectifier and inverter are connected with a secondary side of a converter transformer, and two converter valves of fully controlled semiconductor devices are arranged between poles 1 and 2 on the DC side of the rectifier and inverter respectively, positive poles of the rectifier and inverter are connected with a pole 1 DC line by a smoothing reactor, negative poles of the rectifier and inverter are connected with a pole 2 DC line by a smoothing reactor, and connecting points of the upper and lower converter valves of the rectifier and inverter are connected with a pole 3 DC line by a smoothing reactor, the method comprising: controlling current directions of the poles 1 and 2 to be constant without change; periodically modulating a current fixed value between a maximum and a minimum, wherein a ratio of the maximum to the minimum of the current fixed value is 2, the pole 3 current is a difference value between the pole 1 and pole 2 , and the fixed value of the direct current of the pole 3 is the minimum of the fixed values of the direct current of the poles 1 and 2 ; periodically changing a current direction of the pole 3 , wherein DC voltage polarity of the poles 1 and 2 is constant without change; controlling triggering of the upper and lower converter valves of the rectifier and the inverter to cause a pole 3 line to operate in parallel with a pole 1 line or a pole 2 line periodically, thereby changing the DC voltage polarity of the pole 3 periodically and ensuring unchanged DC power direction of the pole 3 . 2. The tripolar VSC-HVDC control method according to claim 1 , wherein the rectifier and inverter include three phase six-bridge arms, each of which is formed by serially connecting at least one submodule and one bridge arm reactor, and upper and lower bridge arms in each phase form a phase unit together. 3. The tripolar VSC-HVDC control method according to claim 1 , wherein submodules of the MMC are of half-bridge structures if the three conductors adopted by the system are cables, and the submodules of the MMC consist of two clamp double submodules if the adopted three conductors are an overhead line. 4. The tripolar VSC-HVDC control method according to claim 1 , wherein the two converter valves on the DC side of the rectifier or inverter between the poles 3 and 2 are switched on, and the two converter valves between the pole 3 and pole 1 are turned off when the voltage of the pole 1 line is positive, the pole 1 current is a current fixed value maximum, the voltage of the pole 2 line is negative, and the pole 2 current is a current fixed value minimum, so that the pole 3 line and the pole 2 line operate in parallel, the pole 3 line has negative voltage, the pole 3 current order is a current rated value minimum, and the pole 3 current direction is the same as that of the pole 2 , and that the two valves on the DC side of the rectifier or inverter between the poles 3 and 1 of are switched on, the two valves between the poles 3 and 2 are switched off when the pole 1 is switched to the current fixed value minimum from the current fixed value maximum, and the pole 2 is switched to the current fixed value maximum from the current fixed value minimum, so that, the pole 3 line and pole 1 line operate in parallel, the pole 3 line has positive voltage, the pole 3 current order is a current fixed value minimum and the pole 3 current direction is the same as that of the pole 1 .