shared data for article "Bulk electrical power extraction through tunnel transmission technology from renewable energy concentrated zones"

The shared data is generated from the Finite Element simulations.The data is supported for the article*Bulk electrical power extraction through tunnel transmission technology from renewable energy concentrated zones*The autors are below:*Haoyang Fan, Qi Huang, Zhenyuan Zhang, Arsalan Habib Khawaja, Kaiji Liao，Xiaotian Tang & Mohammad Shahidehpour*Please contact: hwong@swust.edu.cnAnd belows are the data files:*1. Signle Conductor Electromagnetic Results*Shows the magnetic strength and electric field with the distance change for GIL and AC, DC Cable, respectively.We have extracted a one-meter section extending horizontally to the right from the center of the two conductorsWhich is the positionAnd the magnetic strength and the electric field at the positions are givenIn paper, the data is related to Supplementary Figure 2.*2. AC Tunnel Cable Temp*Shows the AC Cable Conductor loss, Sheath Loss, and Temperature (which are the average temperature of all six conducotors) change as the distance between the lines increases (for the trefoil installation scenario, it is the distance between two sets of circuits L (L=-2*X1), while for the wall-mounted installation, it is the distance between adjacent two lines). In paper, the data is related to Fig. 4a.*3. DC Tunnel Cable Temp*Shows the DC Cable Conductor loss, Sheath Loss, and Temperature (which are the average temperature of all six conducotors) change as the distance between the lines increases (for the trefoil installation scenario, it is the distance between two sets of circuits L (L=-2*X1), while for the wall-mounted installation, it is the distance between adjacent two lines). In paper, the data is related to Fig. 4a.*4. GIL Tunnel Temp*Shows the GIL Conductor loss, Sheath Loss, and Temperature (which are the average temperature of all six conducotors) change as the distance between the lines increases. In paper, the data is related to Fig. 4c.*5. AC Tunnel Ventilation*Change the Ventilation distance L, the average air velocity v, and the current, show the Conductor and air temperature for ventilation optimization.In paper, the data is related to Fig. 5b.*6. DC Tunnel Ventilation*Change the Ventilation distance L, the average air velocity v, and the current, show the Conductor and air temperature for ventilation optimization.In paper, the data is related to Fig. 5c.*7. GIL Tunnel Ventilation*Change the Ventilation distance L, the average air velocity v, and the current, show the Conductor, Shell, and air temperature for ventilation optimization.In paper, the data is related to Fig. 5d.