Antimicrobial UV-C treatment for automotive HVAC systems

The invention claimed is: 1. An automotive heating, ventilation and air conditioning (HVAC) system, comprising: an evaporator housing comprising an evaporator core having one or more coil fins to cool and dehumidify moisture-containing air caused to flow through the HVAC system and into a passenger compartment, the evaporator housing including air-contacting surfaces upon which water is to condense after the moisture-containing air flows thereover and is cooled and dehumidified; an air-communicating conduit operatively connected to, and downstream of, the evaporator core; a sump assembly including a side wall, a sump drain, and a sump pan having, an inner surface, the sump pan in fluid communication with the evaporator core, the sump assembly to receive water output of the evaporator core; an exterior drain assembly operatively connected to the sump assembly; and an ultra-violet-C (UV-C) light source positioned on an interior surface of the evaporator housing proximate the evaporator core and, in operation of the system, illuminates one or more coil fin surfaces, the air-communicating conduit downstream of the evaporator housing, and the sump assembly; wherein at least a portion of the coil fin surfaces, the air-communicating conduit, or the sump assembly are indirectly illuminated by the UV-C light source; and wherein the UV-C light source is arranged to, in operation of the system, deliver ultraviolet light to the coil fin surfaces, the air-communicating conduit, or the sump assembly by way of a light-affecting medium selected from a group consisting of water, a prism, a light-transporting fiber and tube. 2. The automotive HVAC system of claim 1 , wherein: the UV-C light source is a first UV-C light source; the evaporator core comprises an upstream surface and a downstream surface; and the HVAC system comprises a second UV-C light source including multiple light emitting diodes (LEDs) arranged to illuminate the upstream surface and the downstream surface of the evaporator core. 3. The automotive HVAC system of claim 1 wherein the UV-C light source has a peak emission between about 250 and about 280 nm. 4. The automotive HVAC system of claim 1 wherein the UV-C light source includes an ultraviolet light emitting diode (LED) or a high-power ultraviolet (HPUV) LED. 5. The automotive HVAC system of claim 1 wherein the UV-C light source is contained in a star base chip, chip on board, flip chip, multi-chip, strip set, printed circuit board, photonic lattice chip, or transistor case package. 6. The automotive HVAC system of claim 1 wherein the UV-C light source is mounted onto a heat sink, in a form of a passive heat exchanger, for adequate heat dissipation into a medium in contact with the heat sink. 7. The automotive HVAC system of claim 1 wherein a plurality of UV-C light sources are arranged in an array, lattice, and/or random pattern. 8. The automotive HVAC system of claim 1 further comprising a control device that, in operation of the HVAC system, controls the UV-C light source selectively to output the ultraviolet light at different wavelengths. 9. The automotive HVAC system of claim 1 comprising at least one other antimicrobial technology. 10. The automotive HVAC system of claim 1 further including a lockout sub-system, comprising a switch, to prevent skin contact. 11. The automotive HVAC system of claim 1 further comprising a control device that, in operation of the HVAC system, controls the UV-C light source selectively to output the ultraviolet light at different wattages. 12. An automotive heating, ventilation and air conditioning (HVAC) system, comprising: an air-communicating conduit operatively connected to, and downstream of, an evaporator housing; a sump assembly including a side wall, a sump drain, and a sump pan having an inner surface, the sump pan in fluid communication with an evaporator core having one or more coil fins, the sump assembly to receive water output of the evaporator core; an exterior drain assembly operatively connected to the sump assembly; an ultra-violet-C (UV-C) light source positioned on an interior surface of the evaporator housing proximate the evaporator core and, in operation of the system, illuminates one or more coil fin surfaces, the air-communicating conduit downstream of the evaporator housing, and the sump assembly; and a control device configured that, in operation of the HVAC system, controls the UV-C light source selectively to output ultraviolet light at one or both of: different wavelengths; and different wattages; wherein at least a portion of the coil fin surfaces, the air-communicating conduit, or the sump assembly are indirectly illuminated by the UV-C light source; and wherein the UV-C light source is arranged to, in operation of the system, deliver ultraviolet light to the coil fin surfaces, the air-communicating conduit, or the sump assembly by way of a light-affecting medium selected from a group consisting of water, a prism, a light-transporting fiber and tube. 13. The automotive HVAC system of claim 12 further including a lockout sub-system, comprising a switch, to prevent skin contact. 14. The automotive HVAC system of claim 12 , wherein: the UV-C light source is a first UV-C light source; the evaporator core includes air-contacting surfaces upon which water is to condense after moisture-containing air flows thereover and is cooled and dehumidified; the air-contacting surfaces of the evaporator core comprise an upstream surface and a downstream surface; and the HVAC system comprises a second UV-C light source including multiple light emitting diodes (LEDs) arranged to illuminate the upstream surface and the downstream surface of the evaporator core. 15. The automotive HVAC system of claim 12 comprising at least one other antimicrobial technology. 16. An automotive heating, ventilation and air conditioning (HVAC) system, comprising: an air-communicating conduit operatively connected to, and downstream of, an evaporator housing; a sump assembly including a side wall, a sump drain, and a sump pan having an inner surface, the sump pan in fluid communication with an evaporator core having one or more coil fins, the sump assembly to receive water output of the evaporator core; an exterior drain assembly operatively connected to the sump assembly; and an ultra-violet-C (UV-C) light source positioned on an interior surface of the evaporator housing proximate the evaporator core and, in operation of the system, illuminates one or more coil fin surfaces, the air-communicating conduit downstream of the evaporator housing, and the sump assembly; and wherein at least a portion of the coil fin surfaces, the air-communicating conduit, or the sump assembly are indirectly illuminated by the UV-C light source; and wherein the UV-C light source is arranged to, in operation of the system, deliver ultraviolet light to the coil fin surfaces, the air-communicating conduit, or the sump assembly by way of a light-affecting medium selected from a group consisting of water, a prism, a light-transporting fiber and tube. 17. The HVAC system of claim 16 further comprising a control device that, in operation of the HVAC system, controls the UV-C light source selectively to output the ultraviolet light at different wavelengths. 18. The HVAC system of claim 16 further comprising a control device that, in operation of the HVAC system, controls the UV-C light source selectively to output the ultraviolet light at different wattages. 19. The HVAC system of claim 16