Vent for use in an HVAC system

What is claimed is: 1. A vent for use in a heating, ventilation, or air conditioning “HVAC” system, comprising: a housing including an inlet for receiving airflow, an outlet for passing air into an associated room, and a passageway between the inlet and the outlet; an air turbine positioned within the passageway for selectively enabling and preventing the airflow from the inlet to the outlet, wherein the air turbine is mounted onto a longitudinally extending shaft and extends longitudinally across the outlet and has a size and shape that substantially corresponds to a size of the passageway; a motor connected to the longitudinally extending shaft; wherein the air turbine is selectively operable between a first state and a second state; wherein, in the first state, the air turbine is freely rotatable with respect to the housing so that the airflow is movable through the passageway and the outlet, and the motor converts a kinetic energy of the air turbine into electrical power that charges a power storage unit that powers a microcontroller that controls the vent; and wherein, in the second state, the microcontroller is powered by the power storage unit and is configured to control a speed of the air turbine to reach a desired temperature in the associated room by: receiving monitoring parameters indicative of the speed of the air turbine; receiving sensed environmental parameters of the associated room; and outputting, based on the monitoring parameters indicative of the speed of the air turbine and the sensed environmental parameters of the associated room, a pulse-width-modulation “PWM” signal that controls an active load circuitry that controls a load associated with the motor to modulate the speed of the air turbine and the airflow through the passageway and the outlet, wherein the speed of the air turbine is estimated by calculating an instantaneous transferred power as a function of a rectified voltage of the motor, a total current generated by the motor, and the load that is controlled by a PWM duty cycle of the PWM signal. 2. The vent of claim 1 , wherein the power storage unit comprises a supercapacitor. 3. The vent of claim 1 , wherein the longitudinally extending shaft passes through a surface of the housing. 4. The vent of claim 1 , further comprising a transceiver. 5. The vent of claim 4 , wherein the power storage unit powers the transceiver. 6. The vent of claim 1 , wherein the total current generated by the motor is a sum of a first current that is required by a power conversion circuitry that charges the power storage unit and a second current that passes through the active load circuitry and is set by the PWM duty cycle of the PWM signal. 7. The vent of claim 1 , wherein the load controls a back electromotive force associated with the motor and the speed of the air turbine. 8. The vent of claim 1 , further comprising one or more environmental sensors for monitoring one or more environmental parameters of the associated room. 9. The vent of claim 8 , further comprising a control station receiving the one or more environmental parameters and transmitting instructions to the microcontroller to operate in either the first state or the second state based on the one or more environmental parameters. 10. The vent of claim 8 , wherein the one or more environmental sensors includes a temperature sensor for monitoring a temperature of the associated room. 11. A vent comprising: a housing including an inlet for receiving airflow, an outlet for passing air into an associated room, and a passageway between the inlet and the outlet; an air turbine positioned within the passageway for selectively enabling and preventing the airflow from the inlet to the outlet, wherein the air turbine is mounted onto a shaft; a motor connected to the shaft; wherein the vent is selectively operable between a first state and a second state; wherein, in the first state, the air turbine is rotatable with respect to the housing via the airflow so that the airflow is movable through the passageway and the outlet, and the motor converts a kinetic energy of the air turbine into electrical power that charges a power storage unit that powers a microcontroller that controls the vent; and wherein, in the second state, the microcontroller is powered by the power storage unit and is configured to control a speed of the air turbine to reach a desired temperature in the associated room by: receiving monitoring parameters indicative of the speed of the air turbine; receiving sensed environmental parameters of the associated room; and outputting, based on the monitoring parameters indicative of the speed of the air turbine and the sensed environmental parameters of the associated room, a pulse-width-modulation “PWM” signal that controls an active load circuitry that controls a load associated with the motor to modulate the speed of the air turbine and the airflow through the passageway and the outlet, wherein the speed of the air turbine is estimated by calculating an instantaneous transferred power as a function of a rectified voltage of the motor, a total current generated by the motor, and the load that is controlled by a PWM duty cycle of the PWM signal. 12. A heating, ventilation, or air conditioning “HVAC” system, comprising: one or more environmental sensors for monitoring one or more environmental parameters of an associated room; a control station for receiving the one or more environmental parameters; and one or more vents, each vent including: a housing including an inlet for receiving airflow, an outlet for passing air into the associated room, and a passageway between the inlet and the outlet; an air turbine positioned within the passageway for selectively enabling and preventing the airflow from the inlet to the outlet, wherein the air turbine is mounted onto a longitudinally extending shaft; a motor connected to the longitudinally extending shaft; wherein, based on the one or more environmental parameters, the control station transmits instructions to the one or more vents to operate in either a first state or a second state; wherein, in the first state, the air turbine is freely rotatable with respect to the housing so that the airflow is movable through the passageway and the outlet, and the motor converts a kinetic energy of the air turbine into electrical power that charges a power storage unit that powers a microcontroller; and wherein, in the second state, the microcontroller is powered by the power storage unit and is configured to control a speed of the air turbine to reach a desired temperature in the associated room by: receiving monitoring parameters indicative of the speed of the air turbine; receiving sensed environmental parameters of the associated room; and outputting, based on the monitoring parameters indicative of the speed of the air turbine and the sensed environmental parameters of the associated room, a pulse-width-modulation “PWM” signal that controls an active load circuitry that controls a load associated with the motor to modulate the speed of the air turbine and the airflow through the passageway and the outlet, wherein the speed of the air turbine is estimated by calculating an instantaneous transferred power as a function of a rectified voltage of the motor, a total current generated by the motor, and the load that is controlled by a PWM duty cycle of the PWM signal. 13. The HVAC system of claim 12 , wherein the power storage unit comprises a supercapacitor. 14. The HVAC system of claim 12 , wherein each vent further comprises a transceiver. 15. The HVAC system of claim 1