Direct current hybrid circuit breaker with reverse biased voltage source

What is claimed is: 1. A direct current (DC) hybrid circuit breaker (HCB), comprising: an input; an output; a mechanical switch path comprising a mechanical switch, wherein the mechanical switch path is coupled between the input and the output; a semiconductor switch path comprising a semiconductor switch connected in series with a commutation unit configured to supply a reverse biased voltage source on the semiconductor switch path, wherein the semiconductor switch path is coupled between the input and the output in parallel to the mechanical switch path; a surge arrestor path comprising a surge arrestor, wherein the surge arrestor path is coupled between the input and the output in parallel to the mechanical switch path and the semiconductor switch path or the surge arrestor path is coupled in parallel across the semiconductor switch; and a second surge arrestor coupled in parallel across the semiconductor switch, the commutation unit, or both the semiconductor switch and the commutation unit. 2. The DC HCB of claim 1 , wherein the surge arrestor is configured to absorb residual fault currents in the DC HBC upon the mechanical switch and the semiconductor switch being opened. 3. The DC HCB of claim 1 , wherein the second surge arrestor is coupled in parallel across the commutation unit, further comprising: a third surge arrestor coupled in parallel across the semiconductor switch. 4. The DC HCB of claim 1 , wherein the second surge arrestor is included in the semiconductor switch path. 5. The DC HCB of claim 1 , wherein the second surge arrestor is configured to protect the commutation unit from an over-voltage condition. 6. The DC HCB of claim 1 , wherein the surge arrestor or the second surge arrestor is a varistor, metal oxide varistor, thyristor, or any other voltage clamping circuit. 7. The DC HCB of claim 1 , wherein the commutation unit comprises a transformer and an inverter connected in parallel with a capacitor. 8. The DC HCB of claim 1 , wherein the commutation unit comprises: a capacitor; an input of the commutation unit; an output of the commutation unit; a first switch, where a first side of the first switch is coupled to a positive terminal of the capacitor. 9. The DC HCB of claim 8 , wherein the input of the commutation unit is coupled to a negative terminal of the capacitor and a second side of the first switch is coupled to the output of the commutation unit. 10. The DC HCB of claim 8 , wherein the second side of the first switch is coupled to a first side of a first winding of the transformer, a second side of the first winding of the transformer is coupled to a negative terminal of the capacitor, the output of the commutation unit is coupled to the first side of a second winding of the transformer, and the input of the commutation unit is coupled to the second side of the second winding of the transformer. 11. The DC HCB of claim 1 , wherein the commutation unit comprises: a capacitor; an input of the commutation unit, where the input of the commutation unit is coupled to a negative terminal of the capacitor; an output of the commutation unit; a first switch, where a first side of the first switch is coupled to a positive terminal of the capacitor; a second switch, where a first side of the second switch is coupled to a second side of the first switch and is coupled to the output of the commutation unit, and where a second side of the second switch is coupled to the input of the commutation unit and the negative terminal of the capacitor. 12. The DC HCB of claim 1 , wherein the commutation unit comprises: a capacitor; an input of the commutation unit; an output of the commutation unit; a first switch, where a first side of the first switch is coupled to a positive terminal of the capacitor; a second switch, where a first side of the second switch is coupled to a second side of the first switch and the output of the commutation unit, and where a second side of the second switch is coupled to a negative terminal of the capacitor; a third switch, where a first side of the third switch is coupled to the positive terminal of the capacitor and the first side of the first switch; and a fourth switch, where a first side of the fourth switch is coupled to a second side of the third switch and the input of the commutation unit, and where a second side of the fourth switch is coupled to the negative terminal of the capacitor and the second side of the second switch. 13. A direct current (DC) hybrid circuit breaker (HCB), comprising: an input; an output; a mechanical switch path comprising a mechanical switch, wherein the mechanical switch path is coupled between the input and the output; a semiconductor switch path comprising a semiconductor switch connected in series with a commutation unit configured to supply a reverse biased voltage source on the semiconductor switch path, wherein the semiconductor switch path is coupled between the input and the output in parallel to the mechanical switch path, wherein the commutation unit comprises: a capacitor; an input of the commutation unit, where the input of the commutation unit is coupled to a negative terminal of the capacitor; an output of the commutation unit; a first switch, where a first side of the first switch is coupled to a positive terminal of the capacitor; a second switch, where a first side of the second switch is coupled to a second side of the first switch and is coupled to the output of the commutation unit, and where a second side of the second switch is coupled to the input of the commutation unit and the negative terminal of the capacitor. 14. A direct current (DC) hybrid circuit breaker (HCB), comprising: an input; an output; a mechanical switch path comprising a mechanical switch, wherein the mechanical switch path is coupled between the input and the output; a semiconductor switch path comprising a semiconductor switch connected in series with a commutation unit configured to supply a reverse biased voltage source on the semiconductor switch path, wherein the semiconductor switch path is coupled between the input and the output in parallel to the mechanical switch path, wherein the commutation unit comprises: a capacitor; an input of the commutation unit; an output of the commutation unit; a first switch, where a first side of the first switch is coupled to a positive terminal of the capacitor; a second switch, where a first side of the second switch is coupled to a second side of the first switch and the output of the commutation unit, and where a second side of the second switch is coupled to a negative terminal of the capacitor; a third switch, where a first side of the third switch is coupled to the positive terminal of the capacitor and the first side of the first switch; a fourth switch, where a first side of the fourth switch is coupled to a second side of the third switch and the input of the commutation unit, and where a second side of the fourth switch is coupled to the negative terminal of the capacitor and the second side of the second switch. 15. A method of operating a direct current (DC) hybrid circuit breaker (HCB), the method comprising: detecting an over-current condition in a switch current across a closed mechanical switch in a mechanical switch path of the DC HCB; in response to detecting the over-current condition, closing a semiconductor switch and providing a reverse biased commutation voltage by a commutation unit, wherein the semiconductor switch and the commutation unit are connected in series across a semiconductor switch path of the DC HCB and the