Systems, methods, and devices for constant current relay control of a battery module

The invention claimed is: 1. A battery module for use in a vehicle, comprising: a plurality of battery cells; a battery terminal that facilitates electrically coupling the battery module with an electrical component in the vehicle; a contactor comprising: a switch electrically coupled between the plurality of battery cells and the battery terminal; and a relay coil electrically coupled between a high-side input and a low-side output of the contactor, wherein the relay coil is configured to generate a magnetic field to actuate the switch based at least in part on a first electrical power received via the high-side input, a second electrical power dissipated via the low-side output, or both; a relay control circuit electrically coupled to the high-side input and the low-side output of the contactor; and a processor communicatively coupled to the relay control circuit, wherein the processor is programmed to: instruct the relay control circuit to supply a first substantially constant current to the relay coil to transition the switch from an open position to a closed position when operating in a pull-in mode; and instruct the relay control circuit to supply a second substantially constant current to the relay coil to maintain the switch in the closed position when operating in a hold mode, wherein the first substantially constant current is greater than the second substantially constant current. 2. The battery module of claim 1 , wherein the plurality of battery cells is configured to output a variable voltage. 3. The battery module of claim 1 , wherein the relay control circuit comprises: a first transistor electrically coupled between the plurality of battery cells and the high- side input, wherein the first transistor is configured to control flow of the first electrical power from the plurality of battery cells to the high-side input to provide the first substantially constant current or the second substantially constant current; and a second transistor electrically coupled between the low-side output and ground, wherein the second transistor is configured to control flow of the second electrical power from the low- side output to ground. 4. The battery module of claim 1 , wherein the processor is programmed to: instruct the relay control circuit to supply the first substantially constant current by: instructing the relay control circuit to electrically connect the plurality of battery cells to the high-side input of the contactor when current of the first electrical power is increasing and less than a first upper current threshold; instructing the relay control circuit to electrically disconnect the plurality of battery cells from the high-side input when the current of the first electrical power is not less than the first upper current threshold; instructing the relay control circuit to electrically disconnect the plurality of battery cells from the high-side input when current of the first electrical power is decrease and greater than a first lower current threshold; and instructing the relay control circuit to electrically connect the plurality of battery cells to the high-side input when the current of the first electrical power not greater than the first lower current threshold; and instruct the relay control circuit to supply the second substantially constant current by: instructing the relay control circuit to electrically disconnect the plurality of battery cells from the high-side input when the current of the first electrical power is decreasing and greater than a second lower current threshold, wherein the first lower current threshold is greater than the second lower current threshold; instructing the relay control circuit to electrically connect the plurality of battery cells to the high-side input when the current of the first electrical power is not greater than the second lower current threshold; instructing the relay control circuit to electrically connect the plurality of battery cells to the high-side input when the current of the first electrical power is increasing and not greater than a second upper current threshold, wherein the first upper current threshold is greater than the second upper current threshold; and instructing the relay control circuit to electrically disconnect the plurality of battery cells from the high-side input when the current of the first electrical power is greater than the second upper current threshold. 5. The battery module of claim 1 , wherein the relay control circuit is configured to operate in the pull-in mode a duration of approximately 200 milliseconds. 6. The battery module of claim 5 , wherein the relay control circuit is configured to operate in the hold mode upon completion of the pull-in mode. 7. The battery module of claim 1 , wherein: the relay control circuit comprises: a high-side enable input configured to receive a high-side enable signal; a low-side enable input configured to receive low-side enable signal; and an override input configured to receive an override signal; and the relay control circuit is configured to: electrically connect the plurality of battery cells to the high-side input when the high-side enable signal is high and the override signal is high; electrically connect the low-side output to ground when the low-side enable signal is high and the override signal is high; and deactivate the relay control circuit when the override signal is low to transition the switch to the open position. 8. The battery module of claim 1 , wherein the relay control circuit comprises a current measurement device electrically coupled to the low-side output of the contactor, wherein the current measurement device is configured to: measure current of the second electrical power output from the low-side output; and indicate measured value of the current of the second electrical power output to the relay control circuit, wherein the relay control circuit is configured to control current flow through the relay coil based at least in part on the measured value. 9. A battery module for use in a vehicle, comprising: a plurality of battery cells; a battery terminal that facilitates electrically coupling the battery module with an electrical component in the vehicle; a contactor comprising: a switch electrically coupled between the plurality of battery cells and the battery terminal; and a relay coil electrically coupled between a high-side input and a low-side output of the contactor, wherein the relay coil is configured to generate a magnetic field to actuate the switch based at least in part on a first electrical power received via the high-side input, a second electrical power dissipated via the low-side output, or both; a relay control circuit electrically coupled to the high-side input and the low-side output of the contactor, wherein the relay control circuit: supplies a first substantially constant current to the relay coil to transition the switch from an open position to a closed position when operating in a pull-in mode; and supplies a second substantially constant current to the relay coil to maintain the switch in the closed position when operating in a hold mode, wherein the first substantially constant current is greater than the second substantially constant current; and a processor communicatively coupled to the relay control circuit, wherein the processor is programmed to: supply a first high signal to a high-side enable input of the relay control circuit to instruct the relay control circuit to electrically connect the plurality of battery cells to the high-side input of the contactor; supply a first low signal to the high-side enable input of the relay control circuit to instruct the relay control circuit