Transformerless, current-isolated onboard charger with solid-state switching controls

The invention claimed is: 1. An onboard charging module (OBCM) for use with an alternating current (AC) power supply and a direct current (DC) high-voltage energy storage system (HV-ESS), wherein the HV-ESS is connected to a DC voltage bus, the OBCM comprising: an AC-to-DC voltage rectifier connectable to the AC power supply and connected to the DC voltage bus, wherein the AC-to-DC voltage rectifier is operable for producing a rectified DC voltage output; a DC-DC boost converter electrically connected to the AC-to-DC voltage rectifier, and having a first plurality of electronic components collectively operable for increasing the rectified voltage output; a DC-DC buck converter electrically connected to the DC-DC boost converter, and having a second plurality of electronic components collectively operable for decreasing a voltage output of the boost converter; a link capacitor electrically connected between the buck converter and the boost converter; and a set of solid-state devices, including a diode and first and second switches having opposite open/closed switching states, wherein the first and second switches are connected to a common rail of the DC voltage bus, the first switch and the diode are electrically connected between the voltage rectifier and the boost converter, and the second switch is electrically connected between the link capacitor and the buck converter; wherein the OBCM is characterized by an absence of a transformer, and is operable, via operation of the set of solid-state devices, to selectively charge the HV-ESS via the AC power supply while maintaining current isolation within the OBCM. 2. The OBCM of claim 1 , further comprising a controller programmed to control the switching state of the first and second switches via switching control signals. 3. The OBCM of claim 1 , wherein the boost converter includes an additional switch, and wherein the diode is in electrical parallel with the additional switch of the boost converter. 4. The OBCM of claim 1 , wherein the first and second switches are silicon carbide (SiC) switches. 5. The OBCM of claim 1 , wherein the first and second switches are wide-band gap (WBG) switches. 6. The OBCM of claim 1 , wherein the set of solid-state devices includes a third switch in electrical parallel with the first switch and having the same switching state as the first switch, with the first and third switches being electrically connected on respective positive and negative rails of the DC voltage bus. 7. The OBCM of claim 6 , wherein the set of solid-state devices includes a fourth switch in electrical parallel with the second switch between the DC-DC boost converter and the DC-DC buck converter and having the same switching state as the second switch, with the second and fourth switches being electrically connected on the respective positive and negative rails of the DC voltage bus. 8. The OBCM of claim 1 , further comprising a capacitor bank in electrical parallel with the buck converter on an output side of the buck converter. 9. An electrical system connectable to an alternating current (AC) power supply, the electrical system comprising: a direct current (DC) voltage bus; a high-voltage energy storage system (HV-ESS) electrically connected to the DC voltage bus; and an onboard charging module (OBCM) electrically connected to the HV-ESS via the DC voltage bus, and including: an AC-to-DC voltage rectifier connectable to the AC power supply and connected to the DC voltage bus, and operable for producing a rectified DC voltage output; a DC-DC boost converter electrically connected to the voltage rectifier, and having a first plurality of electronic components collectively operable for increasing the rectified DC voltage output; a DC-DC buck converter electrically connected to the boost converter, and having a second plurality of electronic components collectively operable for decreasing a voltage output of the boost converter; a link capacitor electrically connected between the buck converter and the boost converter; and a set of solid-state devices, including a diode and first and second switches having opposite open/closed switching states, wherein the first and second switches are connected to a common rail of the DC voltage bus, the first switch and the diode are electrically connected between the voltage rectifier and the boost converter, and the second switch is electrically connected between the link capacitor and the buck converter; wherein the OBCM is characterized by an absence of a transformer, and is operable, via operation of the set of solid-state devices, to selectively charge the HV-ESS using the AC power supply while maintaining current isolation within the OBCM. 10. The electrical system of claim 9 , further comprising a controller programmed to control the switching state of the first and second switches via switching control signals. 11. The electrical system of claim 9 , wherein the boost converter includes an additional switch, and wherein the diode is in electrical parallel with the additional switch of the boost converter. 12. The electrical system of claim 9 , wherein the first and second switches are silicon carbide (SiC) switches. 13. The electrical system of claim 9 , wherein the first and second switches are wide-band gap (WBG) switches. 14. The electrical system of claim 9 , wherein the set of solid-state devices includes a third switch in electrical parallel with the first switch and having the same switching state as the first switch, with the first and third switches being electrically connected on respective positive and negative rails of the DC voltage bus. 15. The electrical system of claim 9 , wherein the set of solid-state devices includes a fourth switch in electrical parallel with the second switch between the boost converter and the buck converter and having the same switching state as the second switch, with the second and fourth switches being electrically connected on the respective positive and negative rails of the DC voltage bus. 16. The electrical system of claim 9 , further comprising a capacitor bank in electrical parallel with the buck converter on an output side of the buck converter. 17. The electrical system of claim 9 , further comprising an AC voltage bus, a power inverter module (PIM) that is electrically connected to the HV-ESS via the DC voltage bus, and an electric machine that is electrically connected to the PIM via the AC voltage bus. 18. The electrical system of claim 17 , wherein the electric machine is a traction motor operable for delivering output torque to a vehicle transmission. 19. A vehicle comprising: a high-voltage energy storage system (HV-ESS); a transmission having an input member; an electric machine connected to the input member; an alternating current (AC) voltage bus; a direct current (DC) voltage bus; a power inverter module (PIM) that is electrically connected to the HV-ESS via the DC voltage bus, and to the electric machine via the AC voltage bus; an onboard charging module (OBCM) that is electrically connected to the HV-ESS via the DC voltage bus, and including: an AC-to-DC voltage rectifier connectable to the AC power supply and connected to the DC voltage bus, and operable for producing a rectified DC output voltage; a DC-DC boost converter electrically connected to the voltage rectifier, and having a first plurality of electronic components collectively operable for increasing the rectified DC output voltage; a DC-DC buck converter electrically connected to the boost converter