Method for calculating maximum output current of multiple thyristor converters connected in parallel

What is claimed is: 1. A method for calculating a maximum output current of multiple thyristor converters connected in parallel, comprising the following steps: step 1 : setting an operating time (t) and determining a time for outputting a long pulse current according to an actual demand; step 2 : assuming a trigger angle for a subsequent output current calculation; step 3 : calculating a maximum output current of a single converter according to an output current model for the single converter; step 4 : equally dividing a total output DC current into a plurality of parts according to a working duration of six converter bridge arms, thereby obtaining a pulse operating current of a single bridge arm; step 5 : checking whether a present junction temperature of a thyristor is below a limiting temperature using the pulse operating current obtained in step 4 based on a thermal resistance model for the thyristor, if no, correcting the trigger angle, and repeating step 2 to step 5 until the present junction temperature of the thyristor is below the limiting temperature; step 6 : giving a present trigger angle to provide guidance for actual experimental operations; and step 7 : giving the maximum output current of multiple converters connected in parallel based on the maximum output current of the single converter in combination with a current-sharing coefficient for converters. 2. The method for calculating a maximum output current of multiple thyristor converters connected in parallel according to claim 1 , comprising establishing an equivalent impedance model by using a multiple parallel-connected converter system to obtain a calculation formula for the maximum output current of multiple converters connected in parallel, wherein the model is established as follows: the converter system is divided into an alternating current (AC) side and a direct current (DC) side; on the AC side, a grid side is connected to step-down transformers through high voltage buses, and the step-down transformers are connected to rectifier transformers that are connected to input ends of converters through AC buses; and on the DC side, output ends of the converters are connected to DC reactors for balancing current through DC buses and finally connected to a load; a number of step-down transformers is assumed as M, with each step-down transformer being connected with N converter branches, wherein both M and N are positive integers, each branch comprising the rectifier transformer, the AC bus, the converter, the DC reactor, the DC bus and the load; and since a plurality of branches are connected in parallel, currents of all branches are input together to the load by a DC busbar. 3. The method for calculating a maximum output current of multiple thyristor converters connected in parallel according to claim 2 , comprising: enabling parameters of the AC side to be equivalent to those of a secondary side of the rectifier transformer based on parameters of the converter system. 4. The method for calculating a maximum output current of multiple thyristor converters connected in parallel according to claim 1 , comprising: implementing a system impedance connection based on a relationship between an output voltage and an input voltage of a thyristor converter. 5. The method for calculating a maximum output current of multiple thyristor converters connected in parallel according to claim 1 , comprising checking a maximum withstand current of a single converter by using the thermal resistance model for the thyristor, and multiplying the maximum withstand current by a number of the converters connected in parallel and the current-sharing coefficient to obtain an actual maximum output current of the multiple converters connected in parallel. 6. The method for calculating a maximum output current of multiple thyristor converters connected in parallel according to claim 1 , comprising performing iteration to determine a trigger angle at a maximum withstand current of the single converter. 7. The method for calculating a maximum output current of multiple thyristor converters connected in parallel according to claim 1 , wherein: the limiting temperature is 125° C.