Systems and methods for multi-core radiators

What is claimed is: 1. A radiator system for cooling an internal combustion engine, the radiator system comprising: a first radiator core having a first inlet and a first outlet; a second radiator core having a second inlet and a second outlet; an inlet manifold connected to the first inlet and the second inlet; an outlet manifold connected to the first outlet and the second outlet; a cooling fluid circuit configured to circulate a cooling fluid through the inlet manifold, the first radiator core, the second radiator core, the outlet manifold, and the internal combustion engine; a first valve positioned on the inlet manifold to control a flow of the cooling fluid through the first radiator core; an ambient air temperature sensor configured to sense a temperature of ambient air; a cooling fluid temperature sensor configured to sense a temperature of the cooling fluid within the cooling fluid circuit; a fan configured to drive the ambient air across the first radiator core and the second radiator core; a fan speed sensor configured to sense a rotational speed of the fan; and a memory device having stored therein instructions for, based on an output of at least one of the ambient air temperature sensor, the cooling fluid temperature sensor, and the fan speed sensor, opening the first valve to allow for parallel flow of the cooling fluid through the first radiator core and the second radiator core between the inlet manifold and the outlet manifold; and closing the first valve to interrupt the flow of the cooling fluid through the first radiator core between the inlet manifold and the outlet manifold. 2. The radiator system of claim 1 , wherein the first radiator core has a first coolant volume and the second radiator core has a second coolant volume, wherein the first coolant volume and the second coolant volume are equal. 3. The radiator system of claim 1 , further comprising a second valve positioned on the inlet manifold to control the flow of the cooling fluid through the second radiator core, wherein the second valve is opened and closed based on the output of at least the ambient air temperature sensor. 4. The radiator system of claim 3 , further comprising: a third radiator core comprising: a third inlet connected to the inlet manifold; and a third outlet connected to the outlet manifold; and a third valve positioned on the inlet manifold to control a flow of the cooling fluid through the third radiator core. 5. The radiator system of claim 1 , wherein the ambient air temperature sensor is mounted to a frame or an exterior of an operator station of a haul truck to provide an indication of the ambient air temperature. 6. The radiator system of claim 5 , further comprising: a first motor configured to operate the first valve; and a controller in electronic communication with the ambient air temperature sensor and the first motor, the controller configured to operate the first motor based on the output of two or more of the ambient air temperature sensor, the cooling fluid temperature sensor, and the fan speed sensor. 7. The radiator system of claim 6 , further comprising: a second valve positioned on the inlet manifold to control the flow of the cooling fluid through the second radiator core; and a second motor configured to operate the second valve, wherein the memory device has stored therein: one or more temperature thresholds where ambient operating temperatures are sufficient for using only one of the first radiator core and the second radiator core to cool the cooling fluid; and instructions for closing the first valve or the second valve if the ambient air temperature is below at least one of the one or more temperature thresholds, wherein ambient air temperature sensor readings from the ambient air temperature sensor to compare to the one or more temperature thresholds are obtained before the internal combustion engine is started. 8. A method of controlling a flow of a cooling fluid through a radiator system having a plurality of radiator cores, the method comprising: flowing the cooling fluid through the radiator system and an internal combustion engine, the radiator system comprising a first radiator core and a second radiator core; sensing a first temperature of ambient air with an ambient air temperature sensor; comparing the first temperature of ambient air to a first threshold ambient air temperature; sensing a speed of a fan configured to drive the ambient air across the first radiator core and the second radiator core; comparing the sensed fan speed to a threshold fan speed; sensing a temperature of the cooling fluid flowing through the radiator system; comparing the sensed temperature of the cooling fluid to a threshold cooling fluid temperature; opening a first valve positioned on an inlet manifold of the radiator system to allow for parallel flow of the cooling fluid through the first radiator core and the second radiator core if the first temperature of ambient air is greater than or equal to the first threshold ambient air temperature, the sensed fan speed is greater than or equal to the threshold fan speed, or the sensed temperature of the cooling fluid is greater than or equal to the threshold cooling fluid temperature; and closing the first valve to reduce the flow of the cooling fluid through the first radiator core if the first temperature of ambient air is below the first threshold ambient air temperature, the sensed fan speed is below the threshold fan speed, or the sensed temperature of the cooling fluid is below the threshold cooling fluid temperature. 9. The method of claim 8 , wherein reducing the flow of the cooling fluid through the first radiator core comprises using a controller to automatically operate a first motor to close the first valve. 10. The method of claim 9 , wherein using the controller to automatically operate the first motor to close the first valve is based on an output of the ambient air temperature sensor to limit thermal fatigue and associated cracking in the first radiator core, wherein ambient air temperature sensor readings from the ambient air temperature sensor to compare to the first threshold ambient air temperature are obtained before the internal combustion engine system is started. 11. The method of claim 9 , wherein flowing the cooling fluid through the radiator system further comprises flowing the cooling fluid through a third radiator core. 12. The method of claim 11 , further comprising: comparing the first temperature of ambient air to a second threshold ambient air temperature; and closing a second valve positioned on the inlet manifold to reduce the flow of the cooling fluid through the second radiator core if the first temperature of ambient air is below the second threshold ambient air temperature. 13. The method of claim 12 , wherein reducing the flow of the cooling fluid through the second radiator core comprises using the controller to automatically operate a second motor to close the second valve. 14. The method of claim 13 , further comprising: opening the first valve or the second valve if the sensed fan speed is above the threshold fan speed. 15. The method of claim 13 , further comprising; opening the first valve or the second valve if the sensed temperature of the cooling fluid is above the threshold cooling fluid temperature. 16. A radiator system for cooling an internal combustion engine, the radiator system comprising: a first radiator core having a first inlet and a first outlet; a second radiator core having a second inlet and a second outlet; an i