Battery pack and method of controlling an electric fan in the battery pack

What is claimed is: 1. A battery pack, comprising: a battery pack housing defining an interior region having a first interior space and a second interior space, the battery pack housing having a first wall and a second wall, the first wall having an inlet aperture extending therethrough that communicates with the first interior space, and the second wall having an outlet aperture extending therethrough that communicates with the second interior space; a battery module being disposed in the first interior space of the battery pack housing proximate to the inlet aperture, the battery module having first and second end plates, a first battery cell, and a heat exchanger; the first battery cell being disposed against the heat exchanger and the first end plate, the first battery cell and the heat exchanger being disposed between the first and second end plates; the first end plate having a first end portion that extends longitudinally past a first end of the first battery cell and directly contacts the first wall below the inlet aperture; the second end plate having a first end portion that extends longitudinally past the first end of the first battery cell and directly contacts the first wall above the inlet aperture; the first end portion of the first end plate and the first end portion of the second end plate directing air from the inlet aperture to the heat exchanger, the heat exchanger configured to receive the air to cool the first battery cell; a DC-DC voltage converter being disposed in the second interior space such that the air flowing from the heat exchanger further cools the DC-DC voltage converter; an electric fan adapted to urge the air to flow from the inlet aperture through the first and second interior spaces to the outlet aperture of the battery pack housing; a first temperature sensor being disposed in the first interior space, the first temperature sensor adapted to generate a first signal indicative of a first temperature level of the first battery cell; a second temperature sensor being disposed in the second interior space, the second temperature sensor adapted to generate a second signal indicative of a second temperature level of the DC-DC voltage converter; a microprocessor operably coupled to the first and second temperature sensors such that the microprocessor receives the first and second signals, respectively, the microprocessor further operably coupled to the electric fan; the microprocessor being programmed to determine a first desired operational speed value of the electric fan based on the first temperature level of the first battery cell, the first desired operational speed being greater than zero RPM; the microprocessor being further programmed to determine a second desired operational speed value of the electric fan based on the second temperature level of the DC-DC voltage converter, the second desired operational speed being greater than zero RPM; the microprocessor being further programmed to select the first desired operational speed value if the first desired operational speed value is greater than the second desired operational speed value; and the microprocessor being further programmed to generate a first control signal that induces the electric fan to operate at an operational speed corresponding to the first desired operational speed value if the first desired operational speed value is selected. 2. The battery pack of claim 1 , wherein: the microprocessor being further programmed to select the second desired operational speed value if the second desired operational speed value is greater than the first desired operational speed value; and the microprocessor being further programmed to generate a second control signal that induces the electric fan to operate at an operational speed corresponding to the second desired operational speed value if the second desired operational speed value is selected. 3. The battery pack of claim 1 , wherein: the microprocessor being further programmed to determine an amount of electrical power being output by the DC-DC voltage converter; the microprocessor being further programmed to determine a third desired operational speed value of the electric fan based on the amount of electrical power being output by the DC-DC voltage converter; the microprocessor being further programmed to select the third desired operational speed value if the third desired operational speed value is greater than the first desired operational speed value, and if the third desired operational speed value is greater than the second desired operational speed value; and the microprocessor being further programmed to generate a third control signal that induces the electric fan to operate at an operational speed corresponding to the third desired operational speed value if the third desired operational speed value is selected. 4. The battery pack of claim 1 , further comprising a thermally conductive housing being disposed in the second interior space, the thermally conductive housing having the DC-DC voltage converter disposed therein. 5. The battery pack of claim 1 , wherein the electric fan being disposed in the second interior space proximate to the outlet aperture. 6. The battery pack of claim 1 , wherein the DC-DC voltage converter is electrically coupled to the first battery cell of the battery module. 7. A method for controlling an electric fan in a battery pack, comprising: providing the battery pack having a battery pack housing, a battery module, a DC-DC voltage converter, a first temperature sensor, a second temperature sensor, and a microprocessor; the battery pack housing defining an interior region having a first interior space and a second interior space, the battery pack housing having a first wall and a second wall, the first wall having an inlet aperture extending therethrough that communicates with the first interior space, and the second wall having an outlet aperture extending therethrough that communicates with the second interior space; the battery module being disposed in the first interior space of the battery pack housing proximate to the inlet aperture, the battery module having first and second end plates, a first battery cell, and a heat exchanger, the first battery cell being disposed against the heat exchanger and the first end plate, the first battery cell and the heat exchanger being disposed between the first and second end plates; the first end plate having a first end portion that extends longitudinally past a first end of the first battery cell and directly contacts the first wall below the inlet aperture; the second end plate having a first end portion that extends longitudinally past the first end of the first battery cell and directly contacts the first wall above the inlet aperture; the first end portion of the first end plate and the first end portion of the second end plate directing air from the inlet aperture to the heat exchanger, the heat exchanger configured to receive the air to cool the first battery cell; the DC-DC voltage converter being disposed in the second interior space such that the air flowing from the heat exchanger further cools the DC-DC voltage converter; the electric fan adapted to urge the air to flow from the inlet aperture through the first and second interior spaces to the outlet aperture of the battery pack housing; the first temperature sensor being disposed in the first interior space; the second temperature sensor being disposed in the second interior space; the microprocessor being operably coupled to the first and second temperature sensors; generating a first signal indicative of a first temperature level of the first battery cell utilizing the first temperature sensor; generating a second signal indicative of a second temperature level of the DC-DC vol