Data alignment method, differential protector and differential protection system

What is claimed is: 1. A data alignment method for a first differential protector, comprising: obtaining, at a first time node tA, first sampled current data from a first sampling device; transmitting a first message to a second differential protector after a first transmission processing delay ta, the first message comprising the first sampled current data; receiving, at a first moment tA*, a second message from the second differential protector, the second message comprising second sampled current data and its sampling time stamp, first time information of the second differential protector related to a difference in time of reception tc from receipt of the first message to a second time node, and second time information of the second differential protector related to a second transmission processing delay td from the second time node to transmission of the second message, the second time node being a time point when a second sampling device obtains the second sampled current data; when the first differential protector is in time synchronization with the second differential protector, determining a third time node at which the first differential protector obtains third sampled current data corresponding to the sampling time stamp of the second sampled current data from the first sampling device according to the sampling time stamp, and calculating a first calculated value of the second time node at which the second differential protector obtains the second sampled current data from the second sampling device according to the first time node tA, the first moment tA*, the first transmission processing delay ta, the difference in time of reception tc, and the second transmission processing delay td, and calculating and storing a time calculation deviation tmem between the third time node and the first calculated value of the second time node; when the first differential protector loses time synchronization with the second differential protector, calculating a second calculated value of the second time node according to the first time node tA, the first moment tA*, the first transmission processing delay ta, the difference in time of reception tc, and the second transmission processing delay td, and determining the third time node according to the second calculated value of the second time node and the stored time calculation deviation tmem. 2. The data alignment method of claim 1 , wherein the calculating the first calculated value of the second time node at which the second differential protector obtains the second sampled current data from the second sampling device comprises: calculating a calculated value tp of a transmission delay of data transmission between the first differential protector and the second differential protector using the first time node tA, the first moment tA*, the first transmission processing delay ta, the difference in time of reception tc, and the second transmission processing delay td; and calculating the first calculated value using the first moment tA*, the second transmission processing delay td and the calculated value tp of the transmission delay; wherein, the calculated value tp of the transmission delay is calculated using the following formula: tp= ½( tA*−tA−ta−tc−td ); the first calculated value tB′ of the second time node is calculated using the following formula: tB′=tA*−td−tp. 3. The data alignment method of claim 1 , wherein calculating the second calculated value of the second time node according to the first time node tA, the first moment tA*, the first transmission processing delay ta, the difference in time of reception tc, and the second transmission processing delay td comprises: calculating a calculated value tp of a transmission delay of data transmission between the first differential protector and the second differential protector using the following formula: tp= ½( tA*−tA−ta−tc−td ); calculating the second calculated value tB″ using the following formula: tB″=tA*−td−tp. 4. The data alignment method of claim 1 , wherein determining the third time node according to the second calculated value of the second time node and the stored time calculation deviation tmem comprises: calculating an estimated value of the third time node from the sum of the second calculated value and the time calculation deviation tmem and taking as the third time node a time node closest to the estimated value of the third time node among a plurality of time nodes at which the first differential protector obtains sampled current data from the first sampling device; wherein the estimated value tA′ of the third time node is calculated using the following formula: tA′=tA*−td−tp+t mem. 5. The data alignment method of claim 1 , wherein when the first differential protector is in time synchronization with the second differential protector, the method further comprises: calculating and storing the time calculation deviation tmem whenever a time synchronization signal is received, or calculating and storing the time calculation deviation tmem whenever the sampled current data from the first sampling device is received. 6. The data alignment method of claim 1 , wherein the second message further indicates that the second differential protector loses time synchronization or regains time synchronization. 7. The data alignment method of claim 1 , wherein the first sampling device is a first merging unit, and the second sampling device is a second merging unit, the first merging unit and the second merging unit obtain sampled current values from different locations of the same power line respectively. 8. The data alignment method of claim 1 , wherein the first differential protector and the second differential protector use satellite timing to maintain time synchronization. 9. A differential protector comprising a processor and a memory having program codes stored thereon, the program codes, when executed by the processor, perform the data alignment method of claim 1 . 10. A differential protection system for a power line, comprising: a first sampling device and a second sampling device configured to obtain sampled current values from different locations at the power line, respectively; a first differential protector, connected to the first sampling device and configured to receive first sampled current data transmitted by the first sampling device; and a second differential protector, connected to the second sampling device and configured to receive second sampled current data transmitted by the second sampling device, wherein the first differential protector and the second differential protector are each the differential protector of claim 9 .