Apparatus for controlling air flow to engine room of vehicle and air flow control system including the same

What is claimed is: 1. An apparatus for controlling air flow to an engine room of a vehicle, the apparatus comprising: vertical support units provided as a pair; a plurality of flaps provided to be unfolded or folded in the vertical support units; a delivery unit configured to selectively fold or unfold the flaps; a rotary unit configured to selectively rotate the flaps; and a controller configured to control operations of the delivery unit and the rotary unit according to operational states of a vehicle. 2. The apparatus of claim 1 , wherein the vertical support units include guide rails having a width narrowed downwardly, wherein stoppers are provided in the plurality of flaps and have sizes corresponding to widths of the guide rails such that the plurality of flaps are placed in preset positions of the guide rails. 3. The apparatus of claim 2 , wherein the delivery unit includes: a delivery screw provided in any one of the guide rails; a delivery plate supporting a lowermost flap among the plurality of flaps, and engaged with the delivery screw to adjust a position of the lowermost flap when the delivery screw rotates; and a delivery motor selectively rotating the delivery screw. 4. The apparatus of claim 3 , wherein the rotary unit includes: rotary gears respectively coupled to the plurality of flaps; a rotary screw provided in another guide rail and selectively engaged with the rotary gears; and a rotary motor selectively rotating the rotary screw. 5. The apparatus of claim 4 , wherein the rotary motor is a servo motor configured to rotate in forward and reverse directions and is controlled in revolutions per minute (RPM) and rotating speed. 6. The apparatus of claim 4 , wherein the rotary screw is a flexible gear configured to be selectively engaged with the rotary gears. 7. The apparatus of claim 2 , further comprising: an operating motor selectively rotating a delivery screw or a rotary screw, wherein the delivery unit includes: the delivery screw provided in any one of the guide rails; and a delivery plate supporting a lowermost flap among the plurality of flaps and engaged with the delivery screw to adjust a position of the lowermost flap when the delivery screw rotates, and the rotary unit includes: rotary gears respectively coupled to the plurality of flaps; and the rotary screw provided in another guide rail and selectively engaged with the rotary gears. 8. The apparatus of claim 7 , wherein the operating motor is a servo motor configured to rotate in forward and reverse directions and controlled in RPM and rotating speed. 9. The apparatus of claim 7 , wherein the rotary screw is a flexible gear that is configured to be selectively engaged with the rotary gears. 10. The apparatus of claim 7 , further comprising: an operation conversion unit selectively engaging the operating motor and the delivery screw or the rotary screw. 11. A system for controlling air flow to an engine room of a vehicle, the system comprising: a fan shroud in which a cooling fan including a fan motor and a fan blade is installed; an apparatus for controlling the air flow to the engine room of the vehicle including vertical support units provided as a pair, a plurality of flaps provided to be unfolded or folded in the vertical support units, a delivery unit configured to selectively fold or unfold the flaps, and a rotary unit configured to selectively rotate the flaps; and a controller configured to control operations of the delivery unit, the rotary unit, and the cooling fan according to operational states of the vehicle. 12. The system of claim 11 , wherein the fan shroud and the apparatus for controlling the air flow to the engine room of the vehicle are provided between an engine and a radiator. 13. The system of claim 12 , further comprising an encapsulation covering the engine. 14. The system of claim 12 , wherein operation modes of the system for controlling the air flow to the engine room of the vehicle include: a first mode in which the plurality of flaps are unfolded to be completely closed and the cooling fan is turned off; a second mode in which an operating rotational angle of the plurality of flaps in the unfolded state is controlled and the cooling fan is turned off; a third mode in which the plurality of flaps in the unfolded state are completely opened and the cooling fan is turned off; and a fourth mode in which the plurality of flaps are folded and an operation of the cooling fan is controlled. 15. The system of claim 14 , further comprising an atmospheric temperature sensor configured to measure an atmospheric temperature and output a corresponding signal; a speed sensor configured to measure a speed of the vehicle and output a corresponding signal; an air-conditioning pressure sensor configured to measure internal air-conditioning pressure and output a corresponding signal; an air-conditioning switch sensor configured to measure an operating signal of an air-conditioning switch and output a corresponding signal; and a refrigerant temperature sensor configured to measure a refrigerant temperature and output a corresponding signal, wherein the controller determines an operational state of the vehicle based on the corresponding signals from the sensors, and controls operations of the delivery unit, the rotary unit, and the cooling fan in any one of the first to fourth modes according to the operational state of the vehicle. 16. The system of claim 15 , further comprising an intercooler temperature sensor configured to measure a temperature of the intercooler and output a corresponding signal, wherein the controller further obtains a signal from the intercooler temperature sensor to determine an operational state of the vehicle, and controls operations of the delivery unit, the rotary unit, and the cooling fan in any one of the first to fourth modes.