Fluid circuit

The invention claimed is: 1. A fluid circuit, comprising: a pump configured to deliver a working fluid; a tank that stores the working fluid; a pressure-increasing device configured to increase a pressure of the working fluid; and an accumulator configured to accumulate the working fluid which is increased in pressure by the pressure-increasing device, wherein the pressure-increasing device includes a cylinder, a piston provided inside the cylinder so as to be reciprocatable in an axial direction, and a spring configured to bias the piston toward a first axial side, a space inside the cylinder is partitioned into a back pressure chamber that is communicatable with a pump side and with a tank side and a pressure-increasing chamber that is communicatable with an accumulator side, by the piston, when the working fluid flows into the back pressure chamber from the pump, the piston is pressed to a second axial side opposed to the first axial side, and the working fluid that is increased in pressure in the pressure-increasing chamber is delivered to the accumulator side, a first switching valve configured to switch between a flow passage which allows communication between the back pressure chamber and the pump side and a first flow passage which allows communication between the back pressure chamber and the tank side, according to a change in a fluid pressure to be applied, a second switching valve configured to switch to a flow passage which applies the fluid pressure to the first switching valve, when the piston has reached an initial position on the first axial side or when the piston has reached an end position on the second axial side, and a second flow passage configured to allow communication between the back pressure chamber and the pressure-increasing chamber, a biasing force of the spring when the piston reaches the end position is smaller than a pressing force acting on the piston due to the fluid pressure caused by the pump, and a biasing force of the spring when the piston reaches the initial position is larger than a sum of a flow passage resistance force acting on the first flow passage and a flow passage resistance force acting on the second flow passage, an effective cross-sectional area of the first flow passage is larger than an effective cross-sectional area of the second flow passage, and an area ratio between an effective cross-sectional area of the first flow passage and an effective cross-sectional area of the second flow passage is larger than an area ratio between an effective pressure-receiving area of the back pressure chamber and an effective pressure receiving area of the pressure-increasing chamber. 2. The fluid circuit according to claim 1 , wherein the piston includes the second flow passage. 3. The fluid circuit according to claim 1 , wherein a check valve including a biasing portion configured for biasing in a closing direction is disposed in the second flow passage. 4. The fluid circuit according to claim 2 , wherein a check valve including a biasing portion configured for biasing in a closing direction is disposed in the second flow passage. 5. The fluid circuit according to claim 4 , wherein an area ratio between an effective cross-sectional area of the first flow passage and an effective cross-sectional area of the second flow passage is larger than an area ratio between an effective pressure-receiving area of the back pressure chamber and an effective pressure-receiving area of the pressure-increasing chamber.