TY - GEN
T1 - Two-phase cooling method using R134a refrigerant to cool power electronic devices
AU - Campbell, Jeremy B.
AU - Tolbert, Leon M.
AU - Ayers, Curt W.
AU - Ozpineci, Burak
PY - 2005
Y1 - 2005
N2 - This paper presents a two-phase cooling method using R134a refrigerant to dissipate the heat energy (loss) generated by power electronics (PE) such as those associated with rectifiers, converters, and Inverters for a specific application In hybrid-electric vehicles (HEVs). The cooling method involves submerging PE devices In an R134a bath, which limits the junction temperature of PE devices while conserving weight and volume of the heat sink without sacrificing equipment reliability. First, experimental tests that included an extended soak for more than 300 days were performed on a submerged IGBT and gate-controller card to study dielectric characteristics, deterioration effects, and heat flux capability of R134a. Results from these tests illustrate that R134a has high dielectric characteristics, no deterioration on electrical components, and a heat flux of 114 W/cm 2 for the experimental configuration. Second, experimental tests that included simultaneous operation with a mock automotive air-conditioner (A/C) system were performed on the same IGBT and gate controller card. Data extrapolation from these tests determined that a typical automotive A/C system has more than sufficient cooling capacity to cool a typical 30 k\V traction inverter. Last, a discussion and simulation of active cooling of the IGBT junction layer with R134a refrigerant is given. This technique will drastically Increase the forward current ratings and reliability of the PE device.
AB - This paper presents a two-phase cooling method using R134a refrigerant to dissipate the heat energy (loss) generated by power electronics (PE) such as those associated with rectifiers, converters, and Inverters for a specific application In hybrid-electric vehicles (HEVs). The cooling method involves submerging PE devices In an R134a bath, which limits the junction temperature of PE devices while conserving weight and volume of the heat sink without sacrificing equipment reliability. First, experimental tests that included an extended soak for more than 300 days were performed on a submerged IGBT and gate-controller card to study dielectric characteristics, deterioration effects, and heat flux capability of R134a. Results from these tests illustrate that R134a has high dielectric characteristics, no deterioration on electrical components, and a heat flux of 114 W/cm 2 for the experimental configuration. Second, experimental tests that included simultaneous operation with a mock automotive air-conditioner (A/C) system were performed on the same IGBT and gate controller card. Data extrapolation from these tests determined that a typical automotive A/C system has more than sufficient cooling capacity to cool a typical 30 k\V traction inverter. Last, a discussion and simulation of active cooling of the IGBT junction layer with R134a refrigerant is given. This technique will drastically Increase the forward current ratings and reliability of the PE device.
UR - http://www.scopus.com/inward/record.url?scp=33745001201&partnerID=8YFLogxK
U2 - 10.1109/APEC.2005.1452904
DO - 10.1109/APEC.2005.1452904
M3 - Conference contribution
AN - SCOPUS:33745001201
SN - 0780389751
SN - 9780780389755
T3 - Conference Proceedings - IEEE Applied Power Electronics Conference and Exposition - APEC
SP - 141
EP - 147
BT - Twentieth Annual IEEEApplied Power ElectronicsConference and Exposition, APEC 2005
T2 - 20th Annual IEEEApplied Power ElectronicsConference and Exposition, APEC 2005
Y2 - 6 March 2005 through 10 March 2005
ER -