Braking apparatus for vehicle with collision avoidance mechanism

What is claimed is: 1. A braking apparatus for a vehicle comprising: a master cylinder having a length with a front and a rear, the master cylinder including a cylindrical cavity extending in a longitudinal direction of the master cylinder; an accumulator which connects with the cylindrical cavity of the master cylinder and in which hydraulic pressure of brake fluid is stored; a reservoir which connects with the cylindrical cavity of the master cylinder and in which the brake fluid is stored; a master piston which is disposed in the cylindrical cavity of the master cylinder to be slidable in the longitudinal direction of the master cylinder, the master piston having a front oriented toward the front of the master cylinder and a rear oriented to the rear of the master cylinder, the master piston defining a master chamber and a servo chamber within the cylindrical cavity, the master chamber being formed on a front side of the master piston and storing therein the brake fluid to be delivered to a friction braking device working to apply a frictional braking force to a wheel of a vehicle equipped with this braking apparatus, the servo chamber being formed on a rear side of the master piston; a spool valve which is disposed on the rear side of the master piston within the cylindrical cavity of the master cylinder to be slidable in the longitudinal direction of the master cylinder in response to an effort, as produced by a driver of the vehicle, on a brake pedal so as to switch among a pressure-reducing mode, a pressure-increasing mode, and a pressure-holding mode, the pressure-reducing mode being to establish fluid communication between the servo chamber and the reservoir, the pressure-increasing mode being to establish fluid communication between the servo chamber and the accumulator, the pressure-holding mode being to hermetically close the servo chamber; a first solenoid valve which switches between a pressure exerting mode and a non-pressure exerting mode, the pressure exerting mode being to exert the hydraulic pressure of the brake fluid stored in the accumulator on the spool valve, the non-pressure exerting mode being not to exert the hydraulic pressure of the brake fluid stored in the accumulator on the spool valve; a collision avoidance controller which works to determine whether there is a risk of a collision of the vehicle equipped with this braking apparatus with an obstacle or not, when it is determined that there is the risk of the collision, the collision avoidance controller opening the first solenoid valve to move the spool valve so as to establish the pressure-increasing mode for creating the frictional braking force applied to the wheel; an input piston which is disposed behind the spool valve within the cylindrical cavity of the master cylinder to be slidable in the longitudinal direction of the master cylinder, the input piston defining a simulator chamber between itself and the spool valve within the cylindrical cavity and being subjected to the effort, as produced by the driver of the vehicle; a spring which is disposed within the simulator chamber to transmit the effort, as inputted to the input piston, to the spool valve; and a second solenoid valve which is installed in a flow path between the simulator chamber and the reservoir; wherein the first solenoid valve is disposed in a flow path connecting between the accumulator and the simulator chamber, and wherein when it is determined that there is the risk of the collision, the collision avoidance controller closes the second solenoid valve. 2. A braking apparatus as set forth in claim 1 , wherein the first solenoid valve is implemented by a linear electromagnetic valve which is capable of regulating a flow rate of the brake fluid and works to create a pilot pressure from the hydraulic pressure of the brake fluid stored in the accumulator, the pilot pressure being exerted on the spool valve. 3. A braking apparatus as set forth in claim 1 , wherein the master cylinder has defined therein a pilot chamber which exerts hydraulic pressure of the brake fluid on the spool valve, and wherein the first solenoid valve is disposed in a flow path connecting between the accumulator and the pilot chamber. 4. A braking apparatus as set forth in claim 3 , further comprising a third solenoid valve installed in a flow path between the pilot chamber and the reservoir, and wherein when it is determined that there is the risk of the collision, the collision avoidance controller closes the third solenoid valve. 5. A braking apparatus as set forth in claim 4 , wherein the second solenoid valve is implemented by a linear electromagnetic valve which is capable of regulating a flow rate of the brake fluid. 6. A braking apparatus as set forth in claim 1 , wherein the second solenoid valve is implemented by a linear electromagnetic valve which is capable of regulating a flow rate of the brake fluid. 7. A braking apparatus as set forth in claim 2 , wherein the collision avoidance controller controls an operation of the first solenoid valve according to a braking map which represents a relation between a time elapsed from start of braking and a level of the pilot pressure. 8. A braking apparatus as set forth in claim 7 , further comprising a speed determiner which determines a speed of the vehicle, and wherein the collision avoidance controller determines the level of the pilot pressure using the braking map since the start of braking as a function of the speed of the vehicle. 9. A braking apparatus as set forth in claim 7 , further comprising an obstacle detector working to detect appearance of the obstacle within a set distance in front of the vehicle, and wherein the collision avoidance controller determines the level of the pilot pressure using the braking map since the start of braking depending upon whether the obstacle has appeared within the set distance or not.