Ventilation closure system

What is claimed is: 1. A method of fire control for a compartment using a shape memory alloy actuator, the shape memory alloy actuator having a first state in which airflow of a duct associated with the compartment is unobstructed by a damper and having a second state in which the damper obstructs the airflow of the duct, the method comprising: while the shape memory alloy actuator is in the first state, attaining, by the shape memory alloy actuator, a first temperature responsive to heat released by an exothermic reaction in the compartment; responsive to attaining the first temperature, changing, by the shape memory alloy actuator, from the first state to the second state to move the damper to obstruct airflow of the duct; and after changing from the first state to the second state, heating the shape memory alloy actuator using a heating device coupled to the shape memory alloy actuator, wherein the heating causes the shape memory alloy actuator to maintain the second state despite a reduction in heat released by the exothermic reaction. 2. The method of claim 1 , wherein the duct is coupled in flow communication with the compartment, the method further comprising dispersing a fire suppression agent into the compartment while the shape memory alloy actuator is in the second state. 3. The method of claim 1 further comprising activating the heating device responsive to activation of a switch. 4. The method of claim 1 , wherein a fire protection sensor is associated with the compartment, the method further comprising: generating, by control circuitry, an activation signal based on sensor data from the fire protection sensor, the sensor data indicating one or more of a temperature in the compartment, detection of reaction products the exothermic reaction, or detection of reaction byproducts of the exothermic reaction; and activating the heating device based on the activation signal. 5. The method of claim 4 further comprising: generating, by the control circuitry, a deactivation signal based on the sensor data from the fire protection sensor; deactivating the heating device responsive to the deactivation signal from the control circuitry; and after deactivating the heating device, changing, by the shape memory alloy actuator, from the second state to the first state responsive to the shape memory alloy actuator attaining a second temperature. 6. The method of claim 1 further comprising: receiving, from a damper state sensor, a state signal indicating that the damper is in a position corresponding to shape memory alloy actuator being in the second state; and activating the heating device based on the state signal from the damper state sensor, wherein, when activated, the heating device causes a temperature of the shape memory alloy actuator to be greater than or equal to the first temperature. 7. The method of claim 1 , wherein the exothermic reaction is an oxidation reaction supported at least partially by oxygen in the airflow of the duct, and wherein moving the damper to obstruct the airflow of the duct limits oxygen available to the exothermic reaction and increases a residency time that a fire suppression agent remains in the compartment. 8. A ventilation closure system comprising: a damper; a shape memory alloy actuator having a first state in which the damper is positioned to permit airflow in a duct and having a second state in which the damper is positioned to obstruct the airflow in the duct, the shape memory alloy actuator configured to change from the first state to the second state responsive to the shape memory alloy actuator attaining a first temperature responsive to heat released by an exothermic reaction in a compartment associated with the duct; and a heating device thermally coupled to the shape memory alloy actuator, the heating device configured to heat the shape memory alloy actuator to maintain the first temperature at the shape memory alloy actuator so that the shape memory alloy actuator remains in the second state. 9. The ventilation closure system of claim 8 , wherein the damper is directly connected to the shape memory alloy actuator and the shape memory alloy actuator is directly connected to the duct. 10. The ventilation closure system of claim 8 , wherein the damper corresponds to a flapper coupled to a vent of the duct. 11. The ventilation closure system of claim 8 , wherein the damper includes or corresponds to a blade damper, a louvre damper, a butterfly damper, a radial damper, or a round damper. 12. The ventilation closure system of claim 8 , wherein the shape memory alloy actuator comprises a torque tube, a camshaft, a spring, or a combination thereof. 13. The ventilation closure system of claim 8 , further comprising a switch coupled to the heating device and configured to selectively activate the heating device independently of the position of the damper. 14. An assembly including a ventilation closure system, the assembly comprising: a compartment; a duct configured to provide airflow to the compartment; a damper; a shape memory alloy actuator having a first state in which the damper is positioned to permit the airflow in the duct and having a second state in which the damper is positioned to obstruct the airflow in the duct, the shape memory alloy actuator in thermal communication with the compartment and configured to change from the first state to the second state responsive to the shape memory alloy actuator attaining a first temperature responsive to heat released by an exothermic reaction in the compartment; a heating device thermally coupled to the shape memory alloy actuator, the heating device configured to, when activated, heat the shape memory alloy actuator; and control circuitry coupled to the heating device, the control circuitry configured to selectively activate the heating device to maintain the first temperature at the shape memory alloy actuator so that the shape memory alloy actuator remains in the second state. 15. The assembly of claim 14 , further comprising a fire suppression device coupled to the control circuitry and configured to provide a fire suppression agent to the compartment responsive to a control signal from the control circuitry. 16. The assembly of claim 15 , further comprising a fire protection sensor configured to generate sensor data indicating one or more of a temperature in the compartment, detection of reaction products of the exothermic reaction, or detection of reaction byproducts of the exothermic reaction, wherein the control circuitry is configured to generate control signals to activate the heating device, the fire suppression device, or both, based on the sensor data. 17. The assembly of claim 15 , wherein the duct corresponds to an inlet duct of the compartment, the assembly further comprising: an outlet duct coupled to the compartment and configured to enable outlet airflow from the compartment; a second damper coupled to the outlet duct; and a second actuator coupled to the second damper, the second actuator configured to move the second damper between a first position in which the second damper permits the outlet airflow from the compartment and a second position in which the second damper obstructs the outlet airflow from the compartment, wherein the control circuitry is configured to activate the fire suppression device based on an indication that the second damper is in the second position or the control circuitry is configured to cause the second actuator to move the second damper to the second position based an indication to activate the fire suppression devi