Master cylinder and electronic brake system including the same

What is claimed is: 1. A master cylinder for an electronic brake system in which the master cylinder includes a cylinder body connected to a reservoir and provided with a bore, one end of which is opened in a longitudinal direction, a piston configured to be movable forward and backward within the bore, and at least one master chamber configured to discharge a pressing medium in response to a displacement of the piston, the master cylinder comprising: a pedal simulator provided in the bore, spaced apart from the piston, and configured to provide reaction force in response to pressure from a brake pedal; a simulation chamber formed in the bore, the simulation chamber separated from the master chamber by the pedal simulator; a simulation passage connecting the simulation chamber to the master chamber; and a simulation valve provided in the simulation passage, and configured to control flow of the pressing medium in response to an opening/closing operation thereof, wherein when the electronic brake system normally operates, the simulation valve is closed to prevent the pressing medium from flowing between the master chamber and the simulation chamber in a manner that movement of the piston is restricted and the pedal simulator operates such that the simulation valve receives reaction force. 2. The master chamber according to claim 1 , wherein the pedal simulator includes: a reaction force piston configured to be slidably movable within the bore, and be directly pressurized by the brake pedal; a damping member provided in contact with the reaction force piston, and configured be pressed and provide reaction force in response to movement of the reaction force piston; and a support member spaced apart from the reaction force piston so as to support the damping member. 3. The master chamber according to claim 2 , wherein the pedal simulator further includes: a reaction force spring supported by the support member, and configured to provide reaction force after being pressurized in response to movement of the reaction force piston. 4. The master chamber according to claim 3 , wherein the reaction force piston includes: a coupling groove in which one end of the damping member is inserted; and an extension portion extending from an outer circumference of the reaction force piston, and configured to support one end of the reaction force spring. 5. The master chamber according to claim 4 , wherein the support member includes: an insertion groove in which other end of the damping member is inserted; and a flange portion extending from an outer circumference of the support member, and supporting other end of the reaction force spring. 6. The master cylinder according to claim 1 , wherein: when the electronic brake system abnormally operates (i.e., fallback mode), the simulation valve is open to allow the pressing medium to flow between the master chamber and the simulation chamber in a manner that the piston moves from the pedal simulator while being in press contact with the pedal simulator, and the pressing medium contained in the master chamber is transmitted to at least one wheel cylinder installed in at least one wheel after passing through the simulation chamber. 7. The master chamber according to claim 1 , wherein the bore includes: a first bore formed in a manner that the piston is movable forward and backward therein, resulting in formation of the master chamber; and a second bore, a diameter of which is longer than that of the first bore, configured to form the simulation chamber. 8. An electronic brake system comprising: a master cylinder including: a cylinder body connected to a reservoir, the cylinder body having a bore, one end of which is opened in a longitudinal direction, a piston configured to be movable forward and backward within the bore, first and second master chambers respectively formed in bores located at front and rear sides of the piston, and configured to discharge a pressing medium; a pedal simulator provided in a bore, spaced apart from the piston, and configured to provide reaction force in response to pressure from a brake pedal, a simulation chamber separated from the first master chamber by the pedal simulator, the simulation chamber formed in the bore, a simulation passage configured to connecting the simulation chamber to the first master chamber, and a simulation valve provided in the simulation passage, and configured to control flow of the pressing medium in response to an opening/closing operation thereof; a hydraulic-pressure supply device configured to operate by an electrical signal of a pedal displacement sensor detecting a displacement of the brake pedal; a hydraulic control unit provided with first and second hydraulic circuits, each of which controls flow of hydraulic pressure applied to wheel cylinders installed in wheels by controlling hydraulic pressure discharged from the master cylinder or the hydraulic-pressure supply device; a first backup passage connecting the simulation chamber to the second hydraulic circuit; a second backup passage connecting the second master chamber to the first hydraulic circuit; a cut valve provided in the second backup passage, and configured to control flow of the pressing medium; an electronic control unit configured to control the hydraulic-pressure supply device and a plurality of valves based on information about hydraulic pressure and information about a displacement of the brake pedal; a first reservoir passage through which the simulation chamber communicates with the reservoir; and a second reservoir passage through which the second master chamber communicates with the reservoir, wherein the first reservoir passage is provided with an inspection valve that controls flow of the pressing medium. 9. The electronic brake system according to claim 8 , wherein one end of the first backup passage is branched from a location interposed between the inspection valve and the simulation chamber in the first reservoir passage, and other end of the first backup passage is connected to the second hydraulic circuit. 10. The electronic brake system according to claim 9 , wherein: the second hydraulic circuit includes at least one inlet valve configured to control hydraulic pressure flowing into each wheel cylinder, and at least one outlet valve configured to control hydraulic pressure discharged from each wheel cylinder; and the other end of the first backup passage is connected to a downstream side of the outlet valve in the second hydraulic circuit. 11. The electronic brake system according to claim 8 , wherein: the first hydraulic circuit includes at least one inlet valve configured to control hydraulic pressure flowing into each wheel cylinder, and at least one outlet valve configured to control hydraulic pressure discharged from each wheel cylinder; and one end of the second backup passage is connected to the second master chamber, and other end of the second backup passage is connected to a location interposed between the inlet valve and the outlet valve in the first hydraulic circuit. 12. An electronic brake system comprising: a master cylinder including: a cylinder body connected to a reservoir, the cylinder body having a bore, one end of which is opened in a longitudinal direction, a piston configured to be movable forward and backward within the bore, first and second master chambers respectively formed in bores located at front and rear sides of the piston, and configured to discharge a pressing medium; a pedal simulator provided in a bore, spaced apart from the piston, and configured to provide reaction force in response to pressure from a brake pe