System and method for optimizing the integration of engines and vehicle driveline retarders

The invention claimed is: 1. A coolant diverter system comprising: a coolant diverter body comprising a housing, the housing comprising: a coolant inlet opening, a driveline retarder outlet opening in fluid communication with the coolant inlet opening, a driveline retarder inlet opening in fluid communication with the driveline retarder outlet opening, the driveline retarder outlet opening and the driveline retarder inlet opening configured to be in fluid communication with a driveline retarder, a coolant outlet opening in fluid communication with the driveline retarder inlet opening, and a bypass passage fluidly coupling the coolant inlet opening and the coolant outlet opening, the bypass passage comprising: a bypass passage inlet in fluid receiving communication with the coolant inlet opening, the bypass passage inlet positioned between the coolant inlet opening and the driveline retarder outlet opening, and a bypass passage outlet in fluid providing communication with the coolant outlet opening, the bypass passage outlet positioned between the driveline retarder inlet opening and the coolant outlet opening; one or more thermostat valves positioned in the housing and configured to control the flow of coolant through the coolant outlet opening; a valve positioned in the housing, the valve configured in a first valve orientation to fluidly couple the coolant inlet opening to the driveline retarder outlet opening in isolation from the bypass passage, the valve configured in a second valve orientation to fluidly couple the coolant inlet opening to the driveline retarder outlet opening and the bypass passage, the driveline retarder remaining operational to provide braking when the valve is configured in the second valve orientation; and a valve controller configured to receive operation data regarding the driveline retarder, the operation data indicating a braking event and a temperature of the driveline retarder being below a predetermined temperature threshold, the valve controller configured to place the valve in the second valve orientation in response to the braking event and the temperature of the driveline retarder being below a predetermined temperature threshold. 2. The coolant diverter system of claim 1 , wherein the valve controller is configured to place the valve in the first valve orientation responsive to the operation data indicating the temperature of the driveline retarder being at or above a predetermined temperature threshold. 3. The coolant diverter system of claim 2 , wherein the predetermined temperature threshold includes a predefined acceptable time differential rate of change of the temperature of the driveline retarder over a predefined amount of time. 4. The coolant diverter system of claim 2 , wherein the predetermined temperature threshold is a value. 5. The coolant diverter system of claim 2 , wherein the predetermined temperature threshold is based on a hysteresis of the temperature of the driveline retarder. 6. The coolant diverter system of claim 1 , wherein the valve controller is configured to selectively place the valve in one of the first and second valve orientations responsive to temperature data regarding a coolant used in the coolant diverter system. 7. The coolant diverter system of claim 1 , wherein the valve includes at least one of a pop-valve and a throttle-valve. 8. The coolant diverter system of claim 1 , wherein the valve is configured to, in a third valve orientation, to fluidly couple the coolant inlet opening to the bypass passage in isolation from the driveline retarder outlet opening. 9. The coolant diverter system of claim 1 , wherein the coolant diverter body further includes a radiator bypass circuit. 10. The coolant diverter system of claim 1 , further comprising: a driveline retarder condition module configured to generate an activation signal in response to activation of the driveline retarder and in response to operation data indicating the temperature of the driveline retarder being at or above a predetermined temperature threshold; and a valve control module coupled to the driveline retarder condition module, the valve control module configured to: generate a first valve control signal in response to receipt of the activation signal, the first valve control signal configured to cause the valve to move to the first valve orientation, the valve moving to the first valve orientation from the second valve orientation. 11. The valve control system of claim 10 , wherein the valve includes at least one of a pop-valve and a throttle-valve. 12. The valve control system of claim 10 , wherein the valve is configured to in a third valve orientation fluidly couple the coolant inlet opening to the bypass passage in isolation from the driveline retarder outlet opening. 13. An engine system comprising the coolant diverter system of claim 1 , the engine system further comprising: an internal combustion engine including a driveline component, the driveline retarder coupled to the driveline component for applying braking force to the driveline component; a coolant circulation system coupled to the internal combustion engine and fluidly coupled to the housing of the coolant diverter body; a driveline retarder supply channel coupling the driveline retarder to the driveline retarder outlet opening in the housing, the driveline retarder supply channel including a first vent; a driveline retarder return channel coupling the driveline retarder to the driveline retarder inlet opening in the housing, the driveline retarder return channel including a second vent; and a vent bypass channel coupling the first vent to the second vent. 14. The coolant diverter system of claim 1 , further comprising: a driveline retarder condition module structured to determine that a driveline retarder in a vehicle is in one of an activated state or a deactivated state responsive to at least one of the temperature data and received vehicle operation data, the vehicle operation data indicative of an operating condition of the vehicle; and a valve control module coupled to the driveline retarder condition module, the valve control module structured to generate one of a first valve control command and a second valve control command responsive to a determined state of the driveline retarder; wherein the first valve control command is generated in response to the determined activated state, and wherein the first valve control command is configured to cause the valve to move to the first valve orientation; wherein the second valve control command is generated in response to the determined deactivated state, and wherein the second valve command is configured to cause the valve to move to the second valve orientation. 15. The valve control system of claim 14 , wherein the valve includes at least one of a pop-valve and a throttle-valve. 16. The valve control system of claim 14 , wherein the valve is configured to, in a third valve orientation, fluidly couple the coolant inlet opening to the bypass passage in isolation from the driveline retarder outlet opening. 17. A method of controlling coolant flow to a driveline retarder, the method comprising: receiving operation data regarding a driveline retarder, the operation data indicating a braking event and a temperature of the driveline retarder being below a predetermined temperature threshold; and causing a valve positioned in a housing of a coolant diverter body of a coolant diverter system to move from a first valve orientation to a second valve orientation in response to the braking event